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HM Fire Service Inspectorate Publications Section

London: The Stationery Office

ARV1 7 ~E"R 2004

:iRE SERvICE CiOuEu' . -MORETON-fN-MARSH, GLOS Gl56 ORH------

Fire Service Manual

Volume 1Fire Service Technology,Equipment and Media

Issued under the authority of the Home Office(Fire and Emergency Planning Directorate)

Physics and Chemistry forFirefighters

00108610

The Fire ServiceCollege

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© Crown Copyright 1998Published for the Home Office under licence from the Controllerof Her Majesty's Stationery Office

Applications for reroduction should be made inwriting to The Copyright Unit, Her Majesty's Stationery Office,SI. Clements House, 2-16 Colegate, Norwich, NR3 1BQ

ISBN 0 11 3411820Second impression 2001

Cover and half-title page photograph: Hampshire Fire and Rescue Service

Printed in the United Kingdom for The Stationery OfficeTJ003115 12/00 C20

P ysics and C emistryfor Firef-ghters

Preface

In order to understand how fires behave and howthey can be extinguished, it is necessary to understand some physics and chemistry. This book isdivided into three parts which will introduce thereader to the relevant physical and chemicalprocesses and then show how these work togetherin the phenomenon that we call fire.

Extinguishing fires is a matter of interrupting oneor more of these processes so that burning cannotcontinue. Firefighters will appreciate that it is,therefore, important to acquire a good understanding of what happens in a fire, in order to be able tochoose the best method available to extinguish it,and to avoid making it worse.

In the first part of this book, some of the physicalproperties of matter will be discussed. Some materials are heavier than others, bulk for bulk. Someheat up more easily than others. These and otherproperties greatly affect the way that materialsbehave when they are involved in a fire.

In the second pat1, the chemical processes relevantto fire will be discussed. Besides the burningprocess itself, the way that materials behave chemically in fire will also be discussed. It is hoped thatfirefighters will gain an understanding of the dangers that new materials present and the way theweapons they have to fight them work.

The third part of the book discusses fire extinction.

This book replaces: The Manual of Firemanship,Book I - Elements of combustion and extinction.

The Home Office is indebted to all those whoassisted in the production of this book, in particular, Edinburgh University Department of Civil andEnvironmental Engineering, Or. John Brenton andDr. Dougal Drysdale.

Physics and Chemistry for Firefighters III

Physics and Chemistryfor Firefighters

Contents

Preface

Chapter 1 Physical prop rties of matter

Density1.1 Vapour density1.2 Liquids of different density1.3 Gases of different density1.4 Matter and energy1.5 Melting, boiling and evaporation

Chapter 2 lechanics

2.1 Motion2.2 Momentum and force2.3 Work, energy and power2.4 Friction

Chapter 3 Heat and Temperature

3.1 Measuring temperature3.2 Thermometric scales3.2.1 The Celsius or Centigrade scale3.2.2 The Fahrenheit scale3.3 Other methods of measuring temperature3.3.1 The air or gas thermometer3.3.2 Using solids to measure temperature3.3.3 Thermocouples3.3.4 Electrical resistance3.3.5 Thermistors3.3.6 Comparison by brightness3.3.7 Infra-red3.4 The Kelvin scale of temperature3.5 Units of heat3.5.1 The Joule3.5.2 The calorie3.5.3 The British thermal unit3.6 Specific Heat3.7 Change of state and latent heat3.7.1 Latent heat of vaporisation3.7.2 Effect of change of pressure on boiling point and latent heat3.7.3 Latent heat of fusion3.7.4 Cooling by evaporation

ill

1

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9101011

13

1415151515151515151616161617171818181920202021

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Physics and Chemistry for Firefighters V

ehapter 4 ThernlaJ E.'pansion 23 Cl apte . 7 Combu tion 47

4.1 Thermal expansion of solids 23 7.1 The Fire Triangle 474.1.1 Coefficient of linear expansion 23 7.2 Heat of reaction and calorific values 484.1.2 Nickel-iron alloy (invar) 24 7.2.1 Oxidation 484.1.3 Allowing for expansion in large metal structures 24 7.3 What makes a flame a flame? 484.1.4 Thermostats 25 7.4 Laminar flow and turbulent flow 494.1.5 Coefficients of superficial and cubical expansion of solids 26 7.5 Premixed and Diffusion Flames 504.2 Thermal expansion of liquids 26 7.6 Practical examples of premixed flames and diffusion flames 524.2.1 Cubical expansion 26 7.6.1 The Bunsen Burner 524.2.2 The effect of expansion on density 26 7.6.2 A candle flame 524.3 The expansion of gases 27 7.6.3 Flashpoint, firepoint and sustained fires 534.3.1 Temperature, pressure, volume 27 7.6.4 Fireball 534.3.2 The gas laws 27 7.6.5 Vapour cloud explosions 534.3.2.1 Boyle's Law 27 7.7 Ignition 544.3.2.2 Charles'Law 28

~7.7.1 Spontaneous ignition temperatures 54

4.3.2.3 The Law of Pressures 28 7.7.2 Self heating and spontaneous combustion 544.3.2.4 The General Gas Law 29 7.7.3 Smouldering 554.4 The liquefaction of gases 30 7.8 Hazards of oxidising agents 554.4.1 Critical temperature and pressure 30 7.8.1 Nitric acid and inorganic nitrates 554.4.2 Liquefied gases in cylinders 30 7.8.2 Permanganates 564.5 Sublimation 31 7.8.3 Chlorates 56

7.8.4 Chromates and dichromates 56

Chapter 5 Heat tran. mi ion 33 7.8.5 Inorganic peroxides 567.8.6 Organic oxidising agents 56

5.1 Conduction 33 7.8.7 Organic peroxides and hydroperoxides 575.2 Convection 355.3 Radiation 36 Chapter 8 'imple organic ·tubstance. 59

hapter 6 The Basi of Chemistry 39 8.1 Aliphatic hydrocarbons (paraffins or alkanes) 598.2 Unsaturated aliphatic hydrocarbons 60

The Chemistry of Combustion 39 8.2.1 Olefines or alkenes 606.1 The basis of chemistry 39 8.2.2 Acetylenes, or alkynes 616.2 Atoms and molecules 39 8.3 Aromatic hydrocarbons 626.2.1 Compounds and mixtures 40 8.4 Liquefied petroleum gases (LPG) 636.3 Symbols 41 8.5 Simple oxygen-containing compounds derived from hydrocarbons 646.3.1 Using symbols to write formulae 41 8.5.1 Alcohols 646.3.2 Radicals 41 8.5.2 Aldehydes 656.4 Atomic mass 42 8.5.3 Ketones 656.5 Molecular mass 42 8.5.4 Carboxylic acids 656.6 Valency 43 8.5.5 Esters 666.6.1 Multiple valency 43 8.5.6 Ethers 666.6.2 Nomenclature 436.7 Simple equations 44 haptcr 9 Pot'mer 696.8 Use of chemical equations 456.9 Limitations of chemical equations 46 9.1 Polymers 69

6.9.1 Reality 46 9.2 Fire hazards 70

6.9.2 Physical state 46 9.2.1 Toxic and corrosive gases 70

6.9.3 Reaction conditions 46 9.2.2 Smoke 71

6.9.4 Heat 46 9.2.3 Burning tars or droplets 71

6.9.5 Rate of reaction 46

eVI Fire Service Manual Physics and Chemistry for Firefighters VU

9.2.49.2.59.2.69.2.79.2.89.3

9.3.1

ExothermsCatalystsFlammable solventsDustsSelf-extinguishing plasticsMonomer hazardsAcrylonitrile, Butadiene, Epichlorhydrin, Methyl Methacrylate, Styrene,Vinyl Acetate, Vinyl ChlorideIntermediates and hardeners[socyanates, Chlorosilanes, Epoxides

717171727272

73


Chapter 10 0 her Combu tible Solids10.1 Wood10.2 Coal10.3 Metals10.3.1 Properties of metals10.3.2 Reaction of metals with water or steam10.3.3 Reaction with oxygen10.4 Sulphur10.5 Phosporus

Chapter 11 Extigui hing Fire11.1 Classification of fires by type11.2 Classification of fires by size11.3 Extinguishing fire: Starvation, smothering, cooling11.3.1 Starvation11.3.2 Smothering11.3.3 Cooling11.4 Fire extinguishing media11.4.1 Water11.4.2 Inert gas11.4.3 Foam11.4.4 Vapourising liquids11.4.5 Carbon dioxide and inert gases11.4.6 Dry chemical powders11.4.7 Blanketing11.4.8 Beating out

Appendice'A Metrication: Conversion tablesB Material densities

Further reading

VIII Fire Service Manual

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93

, P ys·cs a d Chemistryfor Firefighters

Chapte

Chapter 1 - Physical properties of matter

t

Matter is the name given to all material things anything that has mass and occupies space. Solids,liquids, gases and vapours are all matter. Theamount of matter is known as the mass, and ismeasured in kilograms. In everyday life, the massof a solid is measured in kilograms, although forliquids, gases and vapours, we are more accustomed to using volume, the amount of space occupied by a given substance, simply because it is easier to measure. Thus, we talk about litres of petroland cubic metres of gas. However, gases, vapoursand liquids also have mass which can be expressedin kilograms.

Density

Undershmding density isextremely important fora firefightel-.

Understanding density is extremely important for afirefighter. For example, the density of a gas orvapour determines whether it will tend to rise orsink in air, and be found in the greatest concentrations at the upper or lower levels in a building. Thedensity of a burning liquid partly decides whetherit is possible to cover it with water to extinguishthe fire, or whether the firefighter will need to usefoam or other another extinguishing medium.However, another important factor is how well theburning liquld mixes with water, a property knownas miscibility.

Imagine two solid rods, both the same length andwidth, one made of wood and one from iron.Though they are the same size, the iron rod weighsmuch more than the wooden rod. The iron rod issaid to have a greater density than the wooden one.

The density of a material is defined as the mass ofone cubic metre of material. One cubic metre is thestandard "unit volume". A unit volume of iron hasa greater mass than a unit volume of wood and isthus more dense.

Calculating values for the densjties of differentsubstances enables meaningful comparisons to bemade. The density of a substance is calculated bydividing the mass of a body by its volume.

massOensity = ----volume

MIn symbols 0 = -Y-

soM=DxY

MandY=-O-

If mass is measured in kilograms (kg) and the volume in cubic metres (m)), the "units" of densitywill be kilograms per cubic metre (kg/m)). If massis in grams (g) and volume in cubic centimeters(cm'), density will be in grams per cubic centimetre (g/cmJ

).

(Note: units should always be quoted, and caremust be taken not to mix, or confuse, units.)

Physics and Chemistry/or Firefighters 1

1.1 Vapour den ity

We have previously mentioned that specific gravity is a ratio of the density of the substance in

Mercury has the very high density of 13 600 kg/m'or 13.6 g/cm' and is, therefore, 13.6 times as denseas water.

B

B

1.3 Ga e of difl'erent density

Imagine now that petrol is poured into tank (A). Aspetrol has a specific gravity of about 0.75 and willnot mix with water, it will float on the water. Forthe system to balance, the pressures created by theheads of liquid in each tank must be equal asbefore, but because petrol is less dense (lighter)than water, a greater "head" of petrol is required toproduce the same pressure at depth. Consequently,the level of petrol is higher than the level of water.If water is added to tank (B), the water will raisethe petrol in (A) and eventually the petrol will spillover, well before tank (B) is full.

Unlike many liquids, all gases and vapours arecompletely miscible. However, differences in density will affect the way in which they mix. Thus,methane (the main component of natural gas) is alight gas with a vapour density of about 0.5 (air =I). If it is leaking into a room from a faulty gasappliance, it will rise to the ceiling, entraining

A

A

Problems are causcd for thefirefighter when water is usedas an extinguishing agent whenburning liquids are present.

As petrol and 1110st otherflamm«lble liquids float onwater, they cannot besmothered by water, so theaddition of water to a fireinvolving burning liquids maycause the tire to spread fm"therthan it otherwise might havedone.

Figure 1.J Diagramsshowing the difference indensity in liquids.

t

1.2 Liquid of different density

As we have said, the density of a burning liquidpartly decides whether it is possible to cover itwith water to extinguish the fire, or whether thefirefighter will need to use foam or another extinguishing medium.

question compared with the density of water, sospecific gravity is not a sensible thing to use forgases as their densities are so low: e.g., the specific gravity of air is 0.0013. For this reason, thedensity of a gas or vapour (vapour density, usually abbreviated to VD) is given in relation to thedensity of an equal volume of hydrogen, air oroxygen under the same conditions of temperatureand pressure.

For fire service purposes it is much more convenient to compare the density of gases and vapourswith that of air. The reference gas should alwaysbe given to avoid confusion: for example, thevapour density of methane is 0.556 (air = 1), or 8(hydrogen = I).

Hydrogen is often used as a comparison for calculating vapour density because it is the lightestgas. The vapour density of air compared withhydrogen is 14.4, meaning that a given volumeof air is 14.4 times heavier than the same volumeof hydrogen at the same temperature and pressure. For carbon dioxide the vapour densitycompared with that of hydrogen is 22, so a givenvolume of carbon dioxide is about 1.5 (that is22/14.4) times as heavy as the same volume ofair at the same temperature and pressure. (If thetemperature and pressure are changed, the volume of the gas will change. This will beexplained later.)

Consider water poured into two tanks (A) and (B)(Figure 1.1) which are standing on a flat, horizontal surface and are connected by a horizontal pipeas shown. The water will assume equal levels ineach tank as, for the system to balance, there mustbe an equal "head" (or height) of water in eachtank above the lowest point of the pipe. The"head" determines the water pressure at any depth:with interconnected tanks as in Figure 1.1, the levels adjust to ensure that the pressures at the level ofthe pipe are equal.

mass of any volume of the substancemass of an equal volume of water

density of that ubstancedensity of water

Relative density =

If the density of a substance is lower than the density of water, and does not mix with water, thenthat substance will float on water. To use our previous example, the density of wood is lower thanthat of water and the density of iron is higher, sowood floats and iron sinks.

The term specific gravity or relative density issometimes used to give measure of density. Therelative density of a substance is the ratio of themass of any volume of it to the mass of an equalamount of water.

If the density of a substance islower than the density of "vater,and does not mix with (dissolvein) water, thcll that substancewill float on water.

Relative density or specific gravity has no units asthe units on the top and bottom of the equation arethe same, so they cancel each other out when theone quantity is divided by the other.

Gases and vapours have very low densities compared with liquids and solids. At normal temperatures and pressures (e.g., 20°C and 1 atmosphere) a cubic metre of water has a mass of about1000 kg and a cubic metre of air has a mass ofaround 1.2 kg.

2 Fire Service Manual Physics and Chemistry for Firefighters 3

An element is a substancewhich contains atoms which areall of' the same type.

move between atoms. An atom which has lost orgained one or more electrons in a chemical interaction will possess an electrical charge and iscalled either a positive or negative ion.

Some molecules consist of two or more atoms ofthe same kind: for example, an oxygen moleculeconsists of two oxygen atoms (02), Other molecules consist of two or more atoms of differentkinds: carbon dioxide consists of two atoms ofoxygen and one of carbon (C02), water consists oftwo atoms of hydrogen and one of oxygen (H20).Carbon dioxide and water are chemical compounds and they can, by chemical means, be splitinto their component elements. This forms thebasis of the science of chemistry, which is dealtwith in Chapter 6.

An element is a substance which contains atomswhich are all of the same type: they all have thesame number of protons. As there can be anythingup to just over 92 protons in an atom, there are,justover 92 stable elements. Atoms of different elements can combine to form molecules.

It now seems that it is not possible to get more thanabout 92 protons in a nucleus without it becomingso unstable that it falls apaI1. Otherwise, any number of protons is possible.

Atom is a Greek word meaning "indivisible': untilabout 70 years ago, it was believed that atomscould not be split into smaller particles. We knownow that this is wrong and that atoms of one element can be "split" or combined with other particles to make new atoms of other elements. (Thesubject of atomic physics is discussed in theManual of Firemanship, Part 6c, Chapter 45,Section 11.)

Energy is expended in doing work and may be inone of a number of different forms. Heat, light andelectrical energy are well known from everyday

Matter can exist in three states: solid, liquid orgas. Some substances are quite commonly foundin all three states - for example, water is found asice, liquid water and water vapour (steam) - butmost substances are, at normal temperatures,found only in one or two of the states. For example, steel is solid up to its melting point of aroundI400°C (the melting point varies according to thecomposition of the steel). Its boiling point, thepoint at which it turns into a vapour, is about3000°C. Carbon dioxide is normally a gas, butunder pressure it can be liquefied and if it is cooledsufficiently, it solidifies. Oxygen is normally a gasbut it can be liquefied at very low temperatures(boiling point -183°C).

replaced by cold air entering at low level (compare with the fireplace). If there is no openingthrough which it can escape, a pressure wiJldevelop in the burning compartment and anyoneopening a door or window into this space willrelease the pressure, which may cause an outrushof hot gases and possibly flames which couldengulf them. (See Compartment Fires andTactical Ventilation. Fire Service ManualVolume 2.)

1.4 latter and energ

When there are low and high level openings (e.g.,broken windows and a hole in the roof), the building acts as an open chimney, with flames and thehot gases escaping at high level with cold fresh airentering from below. Under these circumstances,the fire will be very intense.

AJI matter is made up of extremely small particlescalled atoms. Atoms have a central core, or nucleus which contains smaller particles called protonsand neutrons. Protons possess a positive electricalcharge. The nucleus is surrounded by a system ofelectrons, which each carry a negative electricalcharge. Atoms contain as many electrons as protons. As the number of protons and electrons arematched, and each proton possesses an equaJ andopposite charge to each electron, atoms are electrically neutral. The number and arrangement ofelectrons around the nucleus determines the chemical behaviour of the atom, that is to say, it determines which other atoms it will combine with.Chemical reactions take place when electrons

t

I

Height ofColumn ofCold Air

rounding outside air. If we consider the hot, lessdense gases inside the chimney and compare themto a column of cold, more dense air outside thechimney we have two volumes of gases of equalheight but of different densities, and are thusunbalanced. The hot gases are said to be buoyantwith respect to the cold air.

In order to restore the balance, cold air from outside flows into the base of the chimney and drivesthe hot gas out of the chimney. This would continue until the chimney is full of cold air, but in practice the fire at the base of the chimney continuously replaces the hot chimney gas which is drivenfrom the top of the chimney.

Figure 1.2 Diagram of achimney showing the travel

of convection currents.

If, however, the flow of hot gas from the chimney isprevented by a cover or damper, a pressure willdevelop at the top of the chimney, The weight of thecolumn of lighter hot gas in the chimney is notenough to balance the weight of the heavier cold outside air. This unbalanced condition is responsible fora force which drives gas from the top of an openchimney. When the top is closed the force produces apressure (which can be calculated if the densities ofthe hot and cold gases are known), and combustionproducts may escape from the fU'eplace into the room.

The same thing happens in a burning building.The air inside is heated by the fire and sobecomes lighter. It rises and will escape throughany available opening provided it can be

~Upward travel

~ of Hot Gas"",

~~

I

Cold Air I , bfY,jLJreplacing

Hot Gas I

! I

(mixing with) air as it rises to form a layer ofmethane and air mixture which will eventuallydescend to the level of the leak. (The concentrationof methane in the layer will increase as the layerdescends.) On the other hand, a leak of propanefrom a propane cylinder will produce a layer ofpropane/air mixture at low level in a similar fashion, as the vapour density of propane is roughly1.5 (air =1).

Height ofColumn ofHot Gas

All heavier-than air gases, like carbon dioxide (VD1.53, air = I) and petrol vapour (VD 2.5, air = I)will accumulate in low places such as wells andcellars, so creating dangers of asphyxia (suffocation) as well as of fire or explosion in the case offlammable vapours.

Differences in density can also be created bychanges in temperature (see Chapter 4). Increase intemperature causes expansion, and a lowering ofdensity. Understanding the consequences of this isextremely important: it can be compared with ourexample of the behaviour of petrol and water ininterconnected tanks. As an example, we can consider the case of a chimney full of the hot productsof combustion from an open fire.

The chimney and the rest of the building (Figure1.2) act rather like our two tanks containing liquidsof different densities, in that the chimney is effectively a tank full of hot light gas joined at the baseto another tank full of cold, heavy gas, i.e. the sur-


Turbine(Kinetic Energy)

Steel lined Tunnels

Generator

I

Intake IntakeTowers Gates

Reservoir(Potential Energy)

FigureJ.3 Diagram showing theconversion oj'potential into

kinelic energy.IDiagram: Nor'h Hvdro)

past each other, although they do not have complete freedom. At this point the solid melts andbecomes a liquid.

Further heating causes the temperature to increase,and the energy is stored as kinetic energy of themolecules. which move with increasing rapidityuntil they are moving fast enough to overcome thecohesive forces completely. At this point, the liquid boils and turns into a gas (or more correctly, avapour). If heat is taken away from a substance,kinetic energy of the molecules decreases and thereverse processes occur.

The evaporating molecules build up a pressureknown as the vapour pressure. At the same time,some molecules will re-enter the liquid. For anygiven temperature below the boiling point there isa definite vapour pressure at which the number ofmolecules which escape is just balanced by thenumber which are recaptured by the liquid.

Boiling occurs when the vapour pressure hasbecome equal to the surrounding atmosphericpressure, the pressure of air. Vapour then forms notonly at the surface of the liquid, but also in thebody of the liquid, and we see bubbles.

experience. There is also potential energy, whichis possessed by a body due to its position, forexample by water stored in a hydroelectic dam,and kinetic energy, which is energy possessed bya moving body, for example by the water from thedam flowing through the turbines in the turbinehall). The potential energy is converted into kinetic energy as the water flows under gravity to theturbine hall, where it is then converted into electrical energy (Figure 1.3).

The fastcr something is moving.the more kinetic energy it has.

For the vast majority of purposes we can say thatenergy cannot be created or destroyed - it can onlybe converted into another form of energy. (Notethat when some radioactive processes occur,minute quantities of mass are "lost' and convertedinto large amounts of energy.)

The firefighter is mostly concerned with energy inthe form of heat. Heat may be produced by a chemical change, such as combustion, in which we saythat chemical energy is released as heat energy.Mechanical energy or kinetic energy can also beconverted into heat energy by friction (e.g., frictional heating of brake pads).

We are familiar with the concept of temperaturefrom everyday experience. Temperature is a mea-

sure of how hot something is, and is related to how"fast" the constituent molecules are moving.

Temperature also dctermineswhich wa~' heat will flow. Heatcan only move from somethingat a high temperature to something at a lower temperature.

The molecules which make up any substance, evena solid, are continually moving, although in a solidthey vibrate around a fixed position. They alsoexert a force of attraction to each other, whichbecomes greater the closer they are together. Themovement of molecules tends to spread them outwhile the attractive force, or force of cohesion,tends to bind them together.

If a solid is heated, heat energy is stored in the substance as the vibrational energy of the molecules.As more energy is stored, they vibrate faster andtake up more space. At the same time, the temperature of the solid rises and thermal expansionoccurs.

A temperature is reached when the molecules arevibrating so much that they break free of the rigidframework in which they have been held by thecohesive forces and become free enough to slide

1.5 Melting, boiling and evaporation

The temperature at which a solid turns into a liquidis called the melting point. If we are considering aliquid turning into a solid, the temperature is calledthe freezing point, though these two temperaturesare the same for the same substance under thesame conditions. The temperature at which a liquidboils and becomes a vapour is the boiling point.

Since energy is required to overcome the forces ofcohesion when a substance melts or boils, the heatwhich is supplied during these processes does notcause a rise in temperature of the substance.Conversely. when a vapour condenses or a liquidsolidifies, it gives up heat without any fall in temperature so long as the change is taking place. So,melting or freezing, for a given substance at agiven atmospheric pressure, take place at a certaintemperature: for the transition between water andice, at normal atmospheric pressure, this takesplace at ODe. Boiling, for a given substance at agiven atmospheric pressure take place at anothercertain temperature: for the transition betweenwater and steam, at normal atmospheric pressure,this takes place at Ioo°c.

Even at temperatures below boiling point, somemolecules at the sUlface of the liquid may gainenough energy from colliding with other molecules for them to escape into the surrounding spaceas vapour. This process is evaporation.

Imagine a liquid in an enclosed space, where thereis already air, such as water in a saucepan. Even ifthe pan is not heated, evaporation will take place.

If the external pressure is increased, the vapourpressure at which boiling will take place isincreased and so the temperature must increase. Ifthe external pressure falls, the reverse is true andthe temperature at which boiling occurs will belower.

•

6 Fire Service Manual Physics and Chemistry for Firefighlers 7


Chapter 2 - Mechanics

Ch p r

f!;- -:..~ I

[:'lJlll)i~_Chapte.r will discuss how

1~~I~Et~~E~l~)i~~!ndhow thet~ ~9:~~~'!!~'.l~9_Eobjects is linked~~to t~eir:n!asJ.,.t~e energy they~ P(}s'sess a.ndtlie~forces whichf - '''i --/i". -~.- .--'I !lft.;9IjJh~m·~ ...,.t~~

2.1 Motion

It has units of metres per second (m/s), or if distance is measured in miles. and time in hours, theunits will be miles/hour (mph).

Although people tend to use speed and velocityinterchangeably, there is a difference betweenthem, Velocity has a direction associated with it: itis what we call a vector quantity.

The line Y shows the length of a straight line connecting the starting and finishing point. The lengthand direction of this line together give the displacement of the car from the starting point.Displacement is also a vector quantity.

Imagine a body moving from a starting point A toanother point B: for example a car movingbetween two cities.

The distance travelled by the car is the length ofthe line X, The average speed the car travelled atwill be the distance travelled by the car divided bythe time taken.

distance travelledSpeed = -------time taken

Figure 2.1 Car movingfrom A to B.

Imagine a car journey from London to Bristol.Bristol is 200 km west of London, so at the end ofthe journey the car has a displacement of 200 kmfrom London. However, the distance travelled willbe longer than this though, as the roads tend to takeconvenient routes through the countryside ratherthan following peIfectly straight lines. There mayeven be times when the car is travelling NorthSouth rather than East West as it follows the road.At those times, the displacement of the car fromLondon is not increasing, so although it has speed,its velocity is zero.

x

•

A.~------------------.;:-. By

Physics and Chemistry for Firefighters 9

Momentum = mass x velocity

Momentum is the product of mass and velocity

Force is the product of mass and acceleration

When an object moves or tries to move over a surface, both the object and the surface experience africtional force along the common surface, each ina direction which opposes the relative motion ofthe surfaces.

an electron in an electric field has electrical potential energy, while a stretched rubber band has elastic potential energy.


2.4 ' riction

Even on two very flat, well-polished surfaces,there are many microscopic imperfections whichmake the contact area much smaller than it wouldseem. These imperfections may interlock and, inthe case of metal, may even weld together undervery high local pressures.

We can see, then, that this locking and bondingwill inhibit motion and that energy will be neededto overcome the frictional force. This energyappears as heat: when energy is expended on overcoming friction, heating occurs. This is the principle behind the rough strip on match boxes whichprovides the heat to start the chemical reaction in amatch, and is also why brake blocks get hot on acar or bicycle.

K' . 1 1metlc energy = 2 mv

Taking our 2 kg mass. if this is raised verticallythrough 2 m, the work done against gravity will be

where W is the work done (in Joules), F is the constant force applied (Newtons) and s is the distancemoved in the direction of the force (in metres).(The Joule (1) has units N.m, or (kg.m/s l ).m, i.e.,kg .m l /s l

: this illustrates the importance of ensuringthat a consistent set of units is used.)

Note that if the force acts in a different direction tothe direction of travel, less work will be done. Theinterested reader should refer to the various textbooks on this topic.

W=FsW =2 x 9.81 x 2

=39.24 J

Potential energy is the amount of energy that anobject possesses because of its position or thearrangement of its components.

The units are kg.m l /s l, i.e., Joules.

If something is capable of doing work. it possesses energy. The energy that a body possesses byvirtue of the fact that it is moving is called kineticenergy. The kinetic energy that a body possesses isequal to the amount of work that must have beendone to it to increase its velocity from zero towhatever velocity it has. For a mass m movingwith velocity v:

A body held above the ground has potential energy because it could do work while it is falling. Our2 kg mass raised vertically through 2 m has apotential energy equal to the work required to raiseit to that height, i.e., mass x acceleration x height(abbreviated as mgh), which as we have seen hasthe units of Joules. This is a consequence of theposition of the mass in the earth's gravitationalfield. Other forms of energy are encountered. e.g.,

The weight of a body is a measure of how strongthe force due to gravity is on an object. In everyday speech, we usually use mass and weight interchangeably, but just as the words "speed" and"velocity" have different meanings, weight andmass also have different meanings.

In this case F = 2 x 9.81i.e. the weight of the object is 19.62 N

The "force of gravity" provides an accelerationwhich acts on everything. At the earth's surface,anything which is dropped will accelerate, undergravity, at 9.81 m/s l (this quantity is often referredto by the symbol g). It also determines the forcesthat are responsible for the movement of hot, buoyant gases in fires, and as described in Chapter I.

Weight is the force due to gravity which acts on anobject. The acceleration due to gravity that anobject will experience is g = 9.81 m/s, so that amass of two kilograms experiences a force due togravity of

F= m a

W=Fs

Giving definitions of weight and velocity whichare different from those used in every day speechmay seem like an unnecessary complication, butmuch science and engineering is only possible ifevery aspect of a problem is precisely defined, andevery scientist or engineer everywhere knowsexactly what is meant by each word.

23 Work, ener y and power

Work is another every day term which has a rigiddefinition in science. If a body moves because aforce acts on it, we say that work is being done onthat object. Work is only being done if the objectmoves - if a force is being applied just to keep anobject stationary, no work is done. The mathematical expression of work is:

F= maF = 2 x 10 kg.m/s l

F= 20 N

Fire Service Manual

Force = mass x accelerationF=ma

Velocity is the rate of' change ofdisplacement.

Speed is the rate of changeof distance.

Acceleration is the rate ofchange of velocity.

10

So, a 2 kg object travelling at 10 m/s has a momentum of 20 kg.m/s

The units of speed and velocity are m/s, whilethose for acceleration are m/s l

.

Imagine that our 2 kg object is initially at rest, andthen a force is applied which makes it accelerate at10m/s l

. The applied force is equal to the body'smass times its acceleration.

22 Momentum and force

The units are kg.m/s l, which known as the Newton

(N).

-

Physics and C emistryfor Firefighters

Chapter 3 - Heat and Temperature

h er

Some of the most destructiveeffects of fire are caused byheat, so it is obvious that thefire fighter should understandthe effect of heat on materials.This chapter will discuss heHtand temlJerature, how the twoare linked and will lay thefoundations for a discussion ofthe reaction of solids, H{IUidsand gases to changes intemperature.

It is also possible to convert heat back into chemical energy or electrical energy.

In Chapter I and 2 it was stated that:

-

Energy

• is the ability to do work;

• can neither be created nor destroyed; and

• can exist in a number of different forms.

Heat is one form of energy. It can be produced bychemical means, for example by burning coal oroil, or by mechanical means, by friction. Passing acurrent through an electrical resistance also produces heat (e.g., an electric fire).

Heat can be converted into other forms of energy,for example into pressure energy in a steam boiler.

Heat always flows from high temperature to lowtemperature. If a hot body and a cold body areplaced in contact, the hot body (the one at the higher temperature) loses heat and the cold body (theone at the lower temperature) gains heat.

The fact that heat and temperature are not the samething can be seen from a simple experiment.Imagine a piece of fine copper wire held in theflame of a match. After a couple of seconds, thewire will glow red hot, which tells us that the temperature of the wire has increased to 800 - 900°C.

Now imagine a similar match held under a kettlecontaining a litre of water. There would be nonoticeable change in the temperature of the water,yet the amount of heat supplied to the wire andsupplied to the water would be roughly the same.


When the junction of wires of two different metals(for example iron and copper) is heated, an electrical potential (a voltage) appears at the junction. Acalibration can be made between the potential andtemperature, so that temperature can be measuredindirectly by measuring the potential with a sensitive voltmeter. There are various types of thermocouple, some of which are capable of recordingextremely high temperatures. (See Figure 3.2)

3.3.3 Thermocouples

3.3.1 The air or gas thermometer

3.3 Other methods of measuringtemperature

3.3.2 Using solids to measure temperature

Instead of using a liquid, a bulb containing air orsome other gas can be used. In one such thermometer, the expansion of the gas causes a shortthread of mercury to move along a scale. Thesethermometers are very sensitive, but may requirecorrection to compensate for atmospheric pressure.

The way that a solid expands when its temperaturerises can be used for temperature measurement.The expansion may be used directly, or the differing expansion of two dissimilar metals may beused. This will be discussed further in the nextChapter.

The 'Iiquid-in-glass' thermometer is not the onlymethod of measuring temperature. There are several other methods, including the following:

3.3.4 Electrical resistance

Thermocouples junctions can be made very smalland so only take a short time to heat up or cooldown. They are very good for following very rapidchanges in temperature.

The electrical resistance of a wire increases with arise in temperature and the change of resistancemay be used to measure temperature. Platinum isnormally used as it has a high melting point and ahigh 'temperature coefficient of resistance', so thata small rise in temperature produces a (relatively)

Thermometric cale3.2

3.2.1 The Celsius (or Centigrade) scale

So, to fix the lower point of the scale, the bulb ofthe thermometer is placed in melting ice, while theupper fixed point of the thermometer is determinedby placing the bulb in the steam above the surfaceof boiling water (at standard atmospheric pressure). If the pressure is different from the standardatmospheric pressure, a correction has to beapplied to the upper fixed point. The level at whichthe liquid in the thermometer stands at each of thefixed points is marked on the stem of the thermometer.

Two thermometric scales are in common use:

Two scales are in common usefor measuring temperature:·the Celsius scale andthe Fahrenheit Scale.

Two fixed points are required for the constructionof a thermometric scale. For the Celsius (orCentrigrade) scale of temperature, the meltingpoint of pure ice and the boiling point of purewater are taken as the fixed points at standardatmospheric pressure.

On this scale the lower fixed point is marked O.The upper fixed point is marked 100. The stembetween these two points is divided into 100 equaldivisions or degrees. These divisions are calledCelsius degrees.

The inventor of this scale used a freezing mixtureto give him his lower fixed point, and the boilingpoint of water for the upper fixed point. The scalewas divided into 212 equal divisions, which gavethe freezing point of water as 32°F. There are 180Fahrenheit degrees between the freezing point andthe boiling point of water (at standard atmosphericpressure).

3.2.2 The Fahrenheit scale

Figure 3./ Diagram

showing thermometer and

a comparison between the

CeLsius and Fahrenheit

thermometer scaLes.

-100'-90'

-80'-70'

-60'-50'

-40'

-30'

-20'-10'-0'

--10'- -20'

c

The thermometer consists of a narrow tube of finebore with a small bulb at one end, and sealed at theother, containing a suitable liquid. The liquid ismost commonly mercury, which has the advantages of a high boiling point (35TC), a uniformexpansion coefficient and a low heat capacity; it isalso opaque. However, its freezing point is about-39°C which makes it unsuitable for measuringtemperatures greatly below the freezing point ofwater. Alcohol has a lower freezing point (-lI2°C)but also a much lower boiling point (78°C) thanmercury. It can be is used for low temperatureswork. Coloured water is sometimes used for roughmeasurement of temperatures between the freezingpoint and boiling point of water.

Because it can only make comparisons, the humanbody cannot give a numerical value to temperaturepeople cannot step out into the street and reliablymeasure the air temperature just by the feel of the airon their skin.

Temperature can, though, be measured by makinguse of one of the effects of heat on materials. Thecommonest example is the use of the way that liquids expand as their temperature rises, the property of thermal expansion of a liquid. This is theprinciple behind the thermometer (Figure 3.1).

POIn

Point

Freezing

F

Bo 11 9212"---,,------_�_ -+. ..+

200'--

180'-

160'--

140'--

120'--

100' --

80'

60'

32' 40'20'

0'

The human body cannotmeasure temperalure~ it canonly make comparisons.

The human body cannot tell reliably whethersomething is hot or cold, it can only compare whatit is currently feeling with what it felt immediatelybeforehand. If you place one hand in a bowl ofcold water and the other in a bowl of hot water andthen, after an interval, both hands are placed in abowl of tepid water, the hand which was in thebowl of cold water will feel that the tepid water is'hot' , while that from the hot water will feel thatthe tepid water is 'cold'.

3.1 Measuring temperature

The meaning of the term 'specific heat capacity'will be discussed later.

The rise in temperature in a body to which heat issupplied is decided by three factors: the amount ofheat supplied (or "transferred") to the body, themass of the body and the specific heat capacity ofthe material from which the body is made.

14 Fire Service ManualPhysics and Chemistry for Firefighters 15

.1

Fifjure 3.3 Graph showingthe zero on the Kelvin orabsolute scale.

Note that in equations, the symbol T is normallyused for temperature, but great care must be takenin remembering which temperature scale is beingused.

3.5 Units of heat

a gas. However, all real gases will condense to liquid or solid form at low temperatures.

In the same way that length is measured in metresand temperature is measured in degrees, there areunits which are used to measure the amount ofenergy in a body - what is colloquially called"heat". The concept of energy was introduced inChapter 2, and discussed in the context of "workdone". Energy can neither be created or destroyed,but can be converted from one form into another,e.g., potential energy into kinetic energy, or chemical energy into electrical energy. The conversionprocess is never 100% efficient, and some of theenergy will appear in a different form, most commonly as "heat". Thus, some of the energy expended in bringing a moving car to rest is dissipated asheat generated by friction at the points of contactbetween the brake shoes and the brake drum.

3.5.1 The Joule (J)

The unit that scientists and engineers use to measure heat is the same as that used for energy, i.e.,the Joule, which is named after a nineteenth century Manchester brewer who became interested inhow much energy was needed to heat water. It isdefined from mechanics; where energy is the abil-

....------...--...~I V2

----------_._-----------------~

ature that it is possible to achieve. We have discussed before in the sections on melting and boiling, that the hotter a mass is, the faster the molecules that make up that body are moving. At-273°C, the molecules that make up a substancestop moving and it is not possible to cool the massany further.

Absolute temp. = Celsius temp. + 273OK = -273°C

273 K = O°C100°C = 373 K

The Kelvin or absolute scale of temperature has itszero at -273°C. Degrees on this scale are the samesize as Celsius degrees, and are denoted by thesymbol K, so

Although the Celsius scale is the most widelyused, the Kelvin scale must be used in certain circumstances - particularly when calculating howthe volume of a gas changes with temperature andpressure (see Chapter 4). This will be discussed inmore detail later, but Figure 3.3 shows how a givenmass of gas will occupy a smaller volume as itcools (assuming that it does not condense into aliquid). For most purposes, it is possible to assumethat the volume of this mass of gas is proportionalto its temperature in degrees Kelvin. Therefore, ifthe temperarure is doubled at a given pressure, itsvolume will double. Conversely, if the temperatureis halved, the volume will halve. In principle, thevolume would become zero at 0 K if it remained as

Figure 3.2 Sketch ofapyrometer of thethermo-cuuple type. Theheat sensitive element(below) is housed in a

container (above) whichprotects it from the effectsof heat and mechanicalwear and tear.

Infra-red radiation is given off by bodies (andsome gases) when they are hot. Infra-red sensorsare sensitive to this type of radiation and can bedesigned to measure the temperature of an objectby analysing the strength and the wavelength ofthe radiation.

3.3.7 Infra-red

Infra-red cameras and other sensors detect heat inthe same way that our eyes detect light. Light represents only one portion of the electromagneticspectrum - a rainbow of different types of radiation which includes, in addition to visible light,radio waves, microwaves, ultra-violet radiationand X-rays.

Infra-red radiation behaves in exactly the sameway as light, but it can pass through some thingsthat Iight can't and it is blocked by some thingsthat light can pass though. In particular, infra-redcan pass through smoke at concentrations whichblock visible light. This is why infra-red camerashave become so valuable in search and rescueoperations. The infra-red radiation emitted by anunconscious person lying in a cool environmentcan easily be detected.

The Kelvin or 'Absolute' scale of temperaturestarts at -273°C, which has been found (theoretically and experimentally) to be the lowest temper-

3.4 The Kelvin seal of temperature

large rise in resistance. Platinum resistance thermometers can measure between -200°C and1200°C. Their disadvantage is that they are largecompared with thermocouples and so do not follow rapid changes in temperature very easily.

3.3.6 Comparison by brightness

Thermistors are semiconductor devices, whichhave a negative temperature coefficient of resistance, so an increase in temperature produces adecrease in resistance. They are very robust andcan be made very small and so can follow rapidchanges in temperature. Their range is generallyfrom -70°C to 300°C. but they are less accuratethan resistance thermometers.

3.3.5 Thermistors

At temperatures above about 750°C, objects startto glow, first a dull red, changing gradually to yellow and brightening as the temperature is raised toabout 1250°C. Temperature measurements can bemade by comparing the brightness of the objectwith the filament of an electric lamp whose brightness can be altered by varying the current flowingthrough it. If the current is too low, the filamentappears darker than the object, while if it is toolarge, the filament appears brighter. When the filament "disappears" against the object, they have thesame brightness and temperature. The latter can befound indirectly by measuring the current throughthe filament.

16 Fire Service Manual Physics and Chemistry for Firefifjhters 17

L --

ity to perform work, so work and energy are measured in the same units, as in Chapter 2. One Jouleof work is done when the point at which a INewton (I N) force is applied moves through Imetre in the direction of the force.

For convenience, to save writing strings of zeroes,larger units based on the Joule are used, the kilojoule and the megajoule:

I kilojoule (1 kJ) = I 000 JI megajoule (I MJ) = I 000 kJ = I 000 000 J

[n the same way that feet and inches were replacedby metres, there are older units which have nowbeen replaced by the Joule. These will now be discussed briefly.

3.5.2 The calorie

This is defined as the quantity of heat required toraise the temperature of I gram of water through1°C. The energy content of food is often measuredin calories, though, confusingly the number of'calories' we talk about in a bar of chocolate ineveryday speech is actually the number of kilocalories.

I kilocalorie = 1000 calories.I calorie = 4.18 joules.

3.5.3 The British thermal unit (Btu)

This is the quantity of heat required to raise thetemperature of I Ib of water through 1°F.

Another British unit is the therm, which is equalto 100000 Btu (105 Btu).

I Btu = I 055 J1 therm = 105500 kJ.

3.6 Specific heat

As we have discussed, heat energy can only flowfrom a body at a higher temperature to one at alower temperature. Heat transfer continues either

until both bodies are at the same temperature (i.e.,the initially hot body has cooled and the initiallycold body has warmed), or until the two bodies areseparated. Whatever, a certain amount of heatenergy will have been transferred, which can bemeasured in Joules.

When heat is added to a body the temperaturerises. The rise in temperature of the body dependson three things:

• the amount of heat energy supplied to thebody;

• the mass of the body; and

• the specific heat capacity of the body.

The specific heat capacity of a material is the heatrequired to raise the temperature of one kilogramof the material by 1°C, and so is measured inJoules per kilogram per degree centigrade(J/kgOC). In equations, the letter c is used as asymbol for specific heat capacity.

Some texts may discuss the heat capacity of anobject. This is the specific heat capacity of the substance it is made from multiplied by the mass.They are different quantities though easily confused. [n general, the 'specific' is used when thevalue under discussion refers to a unit mass ofmaterial.

Imagine two containers, one containing water andthe other containing the same mass of oil. Nowimagine that a given amount of heat energy is supplied to each. This could be done by placing thecontainers on identical bUl11ers - ones that supplyheat at the same rate - for the same amount of time.

Both containers are equipped with thermometers.so that the temperature rise can be observed.

Now, after 3 minutes, it is found that the temperature of the oil has risen by lOoC. but the temperature of the water has only risen by 5°C in the sametime.

The masses of the oil and water are the same, andthe amount of heat energy supplied to the oil and

water was the same, so the difference in the temperature rise experienced by the two samples mustbe due to a difference in specific heat capacity.

The same amount of heat caused a greater rise intemperature in the oil than in the water. We knowthat specific heat capacity is a measure of howmuch heat it takes to bring about a one degree risein temperature in a given material. Therefore, thewater has a greater specific heat capacity than theoi I as the water showed a smaller temperature risefor a given amount of heat supplied.

In summary:The larger the specific heatcapacity of a substance, themore energy it takes to raisethe temperature by a givenamount.

The other side to this statement is that materialswith a low specific heat capacity will heat up morerapidly in a fire situation than those of high specific heat capacity.

Water has an unusually high specific heat capacity: 4 200 J/kg per °C. There are very few substances which have a higher value than this. themost notable being hydrogen at constant volume,and mixtures of certain alcohols with water.

This is one of the reasons why water is goodfor fighting fire - a given mass of water canabsorb a relatively large amount of heat energy.

Some values of specific heat capacities are shownin Table 3.1.

Substances such as petrol, alcohol and the likehave low specific heat capacities. They are alsoreadily vaporised and may produce hazardousvapours. In general, combustible materials with

Table 3.1: Specific heat capacities ofsome materials

Material c (Jlkg°C)

Water 4200

Iron 460

Aluminium 900

Copper 400

Mercury 140

Glass (ordinary) 670

Ice 2100

Earth, rock, ete. 840

Carbon tetrachloride 850

Methylated spirit 2400

Benzene 1720

Glycerol 2560

low specific heat capacities are of capable of promoting fire risks.

[It should also be noted that the surfaces ofsolids of low density, such as polyurethanefoam, also heat up very rapidly when exposed toa heat transfer process (e.g., radiant heatingfrom an electric fire). This is a result of lowthermal conductivity. Instead of heat beingrapidly transferred into the body of the solid byconduction, it "accumulates" at the surface,resulting in a rapid temperature rise. As aconsequence low density combustible materialscan be ignited very much more easily thanmaterials of high density.]

3.7 Change of state and latent heat

By 'change of state' we mean the changes betweenthe solid and liquid states (melting/freezing), liquidand gas states (boilinglcondensation), and for a relatively few pure compounds, solid and gas states(sublimation). Freezing, melting, boiling, condensation and sublimation all cause a change of state.

18 Fire Service Manual

---Physics and Chemistry for Firefighters 19

3.7.1 Latent heat of vaporisation

When a kettle is put on to boil, heat enters thewater from the kettle element and the temperatureof the water rises until it reaches 100°e.

At this temperature the water boils, that is to saybubbles of vapour form at the bottom and rise tothe surface where they burst and escape as steam.Once the water has started to boil, the temperatureremains constant at lOOoe - it doesn't get any hotter than 100°e. However, heat energy continuesflow from the element into the water. This energyis not increasing the temperature of the water, butis being used to allow the water molecules to pullthemselves apart from each other, converting thewater from the liquid state to the vapour state, i.e.,from liquid water into water vapour (steam).

Experiments show that 2260000 Joules (2.26MJ)are required to convert I kilogram of water at itsboiling point into steam at the same temperature.This is known as the specific latent heat ofvaporisation for water (latent means hidden - thelatent heat is hidden heat because it doesn't causea temperature rise). This extra heat goes into thevapour, but does not indicate its presence by producing a rise in temperature.

It is this large amount of latent heat whichmakes water mists and sprays so effective inextinguishing flames - vaporisation of the waterdroplets helps cool the flame, and cause it toextinguish.

When steam condenses to form liquid water. thesame amount of latent heat is given out. This iswhy steam can cause sel;ous burns.

The specific latent heat of vaporisation of a substance is the3lllOunt of heat energy needed tochange a unit mass of the suhstance frmn the liquid to vapourwithout a temperature change.

All liquids besides water absorb latent heat whenthey are turned into vapour. For example, 860 000 Jare required to convert lkg of alcohol into vapour atits boiling point.

Latent heat is measured in Joules per kilogram(J/kg) , although it is more usually expressed inkilojoules per kilogram (kJ/kg).

3.7.2 Effect of change of pressure on boilingpoint and latent heat

Water 'normally' boils at 100°e. By 'normally' wemean that it boils at 1000 e when the external airpressure is the standard atmospheric pressure of1.013 bars where 1 bar =105 N/m 2

. This is the pressure of air which will support 760 mm of mercuryin a mercury barometer, and so is sometimes written as "760mm mercury" or "760mm Hg".

If the external pressure israised, the boiling point israised, and if the externalpressure is lowered, the boilingpoint is lowered.

This effect is used in pressure cookers and in pressurised cooling systems for car engines, where theincreased pressure raises the boiling point of theliquid in the system.

This behaviour is also used in the storage of "liquefied gases" such as propane and butane. At increasedpressures, these gases liquefy at nOlmal temperatures,and allow large amounts of"gas" to be stored in a relatively small volume (see Section 4.4).

Raising the boiling point increases the quantity ofheat needed to raise the temperature of the coldliquid to the new boiling point, but it decreases thelatent heat of vaporisation.

3.7.3 Latent heat of fusion

Just as latent heat is taken in when water changesto vapour at the same temperature, a similar thing

happens when ice melts to form water. In this case,the latent heat is not so great. It requires 336000 J(336 kJ) to convert I kg of ice at ooe to water atthe same temperature. Likewise, when water atooe freezes into ice, the same quantity of heat isgiven out for every I kg of ice formed. This iscalled the specific latent heat of fusion of ice. Thisis not confined to water alone; other substancesabsorb latent heat when they melt and converselythey give out latent heat on solidifying. This is thelatent heat of fusion.

The definition of the specific latent heat of fusionof a substance is the quantity of heat required toconvert unit mass of the substance from the solidto the liquid state without change in temperature.The same units (J/kg or kJ/kg, etc.) are used as forthe latent heat of vaporisation.

3.7.4 Cooling by evaporation

Some liquids have a low boiling point and thuschange from liquid to vapour quite easily at ordinary temperatures: these are called volatile liquids.Methylated spirit and ether are of this type. If youdrop a little methylated spirit or ether onto yourhand, it evaporates rapidly and your hand feelscold. Some local anaesthetics work in this way,'freezing' the pain.

The cooling is brought about because, to changefrom liquid to vapour. the liquid absorbs heat energy from the hand to provide the latent heat ofvaporisation of the liquid. The hand therefore feelscold. Water would also cause the hand to becomecold but not so noticeably as methylated spirit. Thespirit has a lower boiling point than water and so itevaporates more quickly at the temperature of thehand.


b



Chapter 4 - Thermal Expansion

C apt r

In this Chapter we will discussthe practical problems and usesof thermal expansion and theways in which we can calculatethe degree of thermal expansionthat a material will experience.

4.1 The thermal c.'pan ion of olid~

As we have discussed in Chapter One and ChapterThree, a substance, whether solid, liquid or gas,will tend to expand when it is heated as long as itis not constrained by a container, a change of stateor a change in chemical composition.

When a solid is heated, it expands in all threedimensions and, therefore, increases in length,breadth and thickness. The increase in length isoften the most important, although the increase inarea and volume due to thermal expansion can bereadily calculated by considering the increase ineach dimension

Within normal ranges of temperature, a solidwhich is "homogeneous" in structure, such as aniron bar, expands uniformly: the expansion of a barin each direction is proportional to the rise in temperature.

r4o~b()mogeneous'~: proper.ties areth~;.sa",e.iri··alfdi~ecti~ns

The expansion is also proportional to the length ofthe bar, but varies with the nature of the substanceof which the bar is made.

4.1.1 Coefficient of linear expansion

The amount by which unit length of a substanceexpands when its temperature is raised by onedegree is called the coefficient of linear expansion of the substance. The temperature scale mustbe stated. Thus we can say that the coefficient oflinear expansion of a solid is the fractionalincrease in length of unit length when its temperature is raised by one degree Celsius.

b


Contacts

AlarmBell

Invar

Brass

Battery

Physics and ChemistrY for Firefighters 25

BimetalStrip

Brass

Invar

PowerSupply

4.1.4 Thermostats

Problems of expansion are also encountered withmaterials which are poor thermal conductors. In afire situation, heating the inner face of a tall brickwall will cause that face to expand, while the outerface remains cool. This may cause the wall to leanoutwards at the top and can result in collapse of thestructure.

If one end of a bi-metallic strip is fixed, a changein temperature will cause the free end to move.

Imagine two strips of different metals with different coefficients of linear expansion. of the samelength, laid side by side. Imagine then that the temperature of the surroundings increase. As the stripswarm up, each will increase in length according toits own coefficient of linear expansion.

If the same two strips were fastened togetherthroughout their length, an increase in temperaturewould cause them to distort into a curve, formingthe arc of a circle. As the strip cooled, it wouldstraighten out again. Such a strip is known as a bimetallic strip. (Figure 4.3).

ControlKnob

\

Electrical -------Connectors

to Heater __

I

l

Even a bridge with a span of 20 m could change by14 mm between the hottest and coIdest temperatures. Allowance for this expansion is often madeby fixing one end of the bridge and resting the otheron rollers, or on a sliding bearing, so that the bridgemay expand and contract without exerting a sideload on its piers. Railway lines used to be laid in 45or 60 ft (13.7 or 18.3 m) lengths, with gaps to allowfor expansion and contraction, but modern methodsnow make it possible for the expansion to be takenup as a tension or compression in the rail, withexpansion joints at distances of about 800 m.

In buildings, the normal range of temperature isnot usually so great, since internal heating maintains a reasonable temperature in winter and thebuilding fabric protects steelwork from excessiveexternal temperatures. Nevertheless, someallowance has to be made for expansion to preventthe steelwork from distorting the walls of thebuilding, even if the allowance is only made byleaving a small clearance between the steel frameand the brickwork. In a fire situation, however, theincrease in temperature may be very great and thesituation could arise in which a long beam couldexert sufficient side load on a wall and cause it tocollapse.

Figure 4.3 Bi-metallic

thermostat

Right

Afire alarm using a

bi-metallic strip.

Left

Above a specified tempera

ture. the hi-metal strip will

bend. This causes {he elec

trical contact to be broken

\vhich results in the current

being switched off.

{he Anciell' Hi~,orir{// lv/OtlflJnellfS o{ScOlland)

l x a x liT = 1960 x 0 000 0 I2 x 60 = I Al m

Figure 4 .I Forth Road Bridge. (Photo: The R""a{ COli/mission 011

Figure 4.2 Main expansion joint at one of the main

towers on the Forth Road Bridge.

(Pho!o: FOrlh tio"d Bridge loill! Board)

Large metal structures, such as bridges, often experience large variations in temperature, so allowancemust be made for the linear expansion of the parts.

4.1.3 Allowing for expansion in large metalstructures

In large bridges, this expansion is quite large itself.For instance, the Forth Road Bridge is a steelstructure with a total length (I) of about 1960 m.The maximum temperature range between winterand summer is -30°C to +30°C. a range of liT =60

QC. Using the formula above, the difference

between the maximum and minimum lengths ofthe roadway would be:

Fire Service Manual

Though there are many nickeliron alloys. this very smallco~ffident of expansion appliesonly to th~~.p~rtiq~hlralloywhich contains< 36 %'.nickel.

4.1.2 Nickel-iron alloy (invar)

It is used for making measuring rods and tapes,watch and clock parts and other components whichneed must remain the same over a range of temperature.

Invar is an alloy of iron and nickel (64 % iron,36 % nickel) which has a coefficient of linearexpansion of 0.000 000 I per QC i.e., less than1 per cent of that of steel. This is so small as tobe negligible in most cases.

Material a (per QC)

Aluminium 0.000023

Copper 0.000017

Concrete 0.000012

Steel 0.000012

Invar steel 0.000 000 100

Common glass 0.000009

Pyrex glass 0.000003

Table 4.1 Typical values of a

Some other typical values of the linear expansioncoefficient, a, are:

For steel, the coefficient of linear expansion (denoted by the Greek letter a) is 0.000 012 per QC. Thus,a bar of steel 1 m long expands by 0.000 012 m foreach QC rise in temperature; a I km bar expands by0.000012 km (12 mm) for each QC rise in temperature, and so on.

24

4.2.2 The effect of expansion on density

Thus, the thermal expansion of mercury is about 8times that of glass, while that of alcohol is nearly50 times that of glass. This is important in thedesign of thermometers.

The change in volume of a gas caused by changesin pressure alone is the subject of the first of thegas laws, known as Boyle's Law. This states that:

Boyle'S LawFor a gas e:lt constant

temlleraturc, the volume ofa gas is inversely proportional

to the pressure UpOIl it.

These combine into the General Gas Law.

Changes in volume of a gas depend on changes intemperature and pressure. To study the interactionbetween temperature, pressure and volume, one ofthese quantities is kept constant and the dependence of the other two on each other can then bestudied. (Note: the mass of gas remains constant.)

This method of study provides the basis of thegas laws, the rules by which the behaviour ofgases can be determined.

As we have seen, each solid or liquid will expandwith rise in temperature by an extent determinedby the coefficient of cubical expansion. However,all gases expand by the same amount for the sametemperature rise.

4.3.2.1 Boyle's Law

Experiments show that if the pressure applied to agiven volume of gas is doubled, the volume is halved.If the pressure is trebled, the volume is reduced toone-third, provided the temperature is constant.

If we have a cylinder whose capacity is 1m3 it cancontain 1 m] of a gas at 1 atmosphere, but if 120 m3

of gas at atmospheric pressure are compressed andpumped into the same cylinder, the pressure will be120 atmospheres (atm). If half of the gas is allowedto escape, then the pressure will fall to 60 atm.

This is why the pressure gauge on a breathingapparatus set is a measure of how much air there isin the cylinder.

occur by conduction. This conduction IS slowbecause water is a poor conductor.

This can be explained by saying that the samenumber of molecules of the gas occupy a smallerspace and, therefore, collide with each other andwith the container walls more frequently. The pressure is due to these collisions: more collisions,more pressure.

4.3.1 Temperature, pressure, volume

Since a gas expands to fill all the available space,the volume of a gas may be changed by altering thevolume of its container. If the volume is decreased,the pressure is increased.

4.3 The expansion of gase

We can see, then, that there are three variables whichchange with each other when dealing with a gas,namely temperature, pressure and volume. Whendealing with a solid or a liquid, temperature and volume are important, but pressure is not so important.

Heating a gas increases the kinetic energy of themolecules which, therefore, move faster, and collide more frequently. So, heating a gas increases itspressure - provided its volume is unchanged. Byincreasing its volume as it is heated, the pressurecan be kept constant.

In a liquid, the molecules are much closer togetherto start with in than in a gas: the spacing of molecules in a liquid is comparable to that in a solid;though, because they are moving so quickly theydo not remain in the regular structure of a solid.Because molecules in a liquid are so close together to start with, they cannot be compressed further.This is why gases can be compressed but liquids,generally, cannot.

4.3.2 The gas laws

• Boyle's Law;

There are three gas laws:

• The Law of Pressures.

• Charles' Law; and

0.000024

0.000 190

0.001 100

Cubical expansion/°C)Material

Glass

Mercury

Alcohol

The so-called "frangible bulbs" used in many conventional sprinkler heads are sealed glass bulbsfull of liquid. These break to operate and releasewater from the head when they are heated to aselected temperature, for example, when exposedto hot fire gases accumulating under the ceiling.

The coefficient of cubical expansion of steel is0.000 036/oC, and that of many liquids is of theorder of 0 OOI;oC, i.e., about 30 times as much.Because of this, a sealed container (such as a storage tank) which is completely full of liquid may bea hazard in a fire situation (or even when exposedto strong sunlight) because of the internal pressures generated by expansion. If a pressure reliefvalve is fitted, this will allow the escape of liquid.The problem will be greatly reduced if the tank isnot completely full, and there is an air space.

Since the density of a substance is the ratio of itsmass to its volume, an increase of temperatureresults in a decrease of density; or conversely, thevolume of a given mass of the substance increasesas its temperature rises.

Water behaves in a peculiar way. Its expansion isnot uniform: the expansion between 30°C and50°C is double that between 10°C and 30°C. Oncooling below 10°C, water contracts until its temperature reaches 4°C. On further cooling itexpands until its volume at O°C is 1.000 120 timesgreater than its volume at 4°C. It also expands further when it freezes. This means that water inponds and lakes freezes from the top downwardand, once the temperature on the surface has fallento 4°C, further cooling of the lower level can only

4.1.5 Coefficients of superficial and cubicalexpansion of solids

1'1V = V x 3a x 1'1T

4.2 Therma expansion of liquid

4.2.1 Cubical expansion

Since liquids have no definite shape and, therefore,no fixed dimensions other than volume, the onlyexpansion which can be measured is that of cubical expansion.

It can be shown mathematically that the coefficientof superficial (or area) expansion of a solid is twicethe linear coefficient, and that of cubical expansionis three times the linear coefficient. Thus, theincrease in volume 1'1V of an object of volume Vwhen the temperature is increased by I'1T is:

The movement of this free end can be made toopen or close an electric circuit, to cause an alarmto be operated, or to switch off a heater. Such adevice using a bi-metallic strip in this way is calleda thermostat. (The principle is also used in rate-ofrise heat detectors.)

so that the new volume will be V + 1'1V (seeSection 4.1.1 for the equivalent equation for linearexpansion) .

The expansion depends on the external dimensionsof the solid and is not affected by any voids. Thecubical expansion of a hollow metal box is thesame as that of a solid block of the same metal ofthe same (external) volume as the box.

Since a liquid has to be contained in a vessel, theapparent expansion of the liquid is affected by theexpansion of the vessel, and the apparent expansion is, therefore, always less than the real expansion. However, the coefficient of cubical expansion of liquids is considerably greater than that ofsolids so (with the exception of water, which isdealt with below) the expansion of a liquid isalways greater than that of its container.

Consider this comparison of the cubical expansioncoefficients of glass, mercury and alcohol:


PI

'c.wL''''__ • ~ _- .' ,- , .

----..-r ~ .. -- .... - • --

~\ '-~.- ~,_ • .The~Law o[Pressures,.

,. 1)hc:prcs'surcof'agiven mass11 Qf'g~~ ,i.s":di~~ctiyptop()rtIOrial

, to.d!$ai~s~I~lle ~temperature,

i-,pro.\'idcd l thatdts \'olumeisI' . ..

~~P~~o-'J~t~nt.,

=

The three gas laws can be combined into a singlemathematical expression:

4.3.2.4 The General Gas Law

=

This is expressed mathematically as:

This general expression may be used for a givenmass of gas wh n pressure, temperature and volume all change.

Remembering this law will allow you to rememberall three - you can just remove the quantity whichis being kept constant from both sides of the equation. For example. if volume is being kept constant, remove V I from the left-hand side and V2

from the right hand side (because they are equal,they cancel), and .insert the pressure and temperature values that you know.

It is important to remember that these gas laws areapplicable to all gases provided that they remain asgases over the temperature and pressure rangeinvolved. When the temperature and pressurereach levels at which the gas liquefies, the gas lawsno longer apply.

Figure 4.6 Fire illvo!l'illg liquefied petroleum gas lanks.

Figure 4.5 Smoke layer al lap of room.

and temperature of a gas when the volume is keptconstant. This is the case when a cylinder of gas,whose valve is closed, is heated. as could happenif it were in a fire.

(Pholo: TJu' Fire F.xpenlllcllwl VillI;

(Phmo: HM Fire' Sel"l'ice IlIsjJl:'clOl"me)

=

As gases expand, their density decreases and theybecome buoyant. This is why hot air rises, how hotair balloons work and why hot smoke and firegases collect at the top of rooms.

Charles'LawThe volume of a given mass of

gas at constant pressureincreases by V::!73 of its volume

at O°C for every 1°C rise intem(Jerature.

Experiments show that all gases expand by Vm oftheir volume at O°C for each I DC rise in temperature, provided that they are maintained at constantpressure. Since the expansion for each I DC rise intemperature is quite large, it is essential to take theinitial volume at ODe. These experiments were carried out by a French scientist named Charles at thebeginning of the 19th century, and the law namedafter him states:

4.3.2.2 Charles' Law

It wiIJ be seen from Figure 3.3 (page 17), whichshows the change of volume of a gas with temperature, that the Kelvin (or Absolute) scale of temperature must be used, and that the relationshipbetween volume and temperature is:

4.3.2.3 The Law of Pressures

where V I and T 1 are the initial volume andabsolute temperature and V1 and T1 are the finalvolume and absolute temperature (the Kelvin temperature. NOT the Celsius temperature). In otherwords, the volume of a given mass of gas is directly proportional to its absolute temperature, provided that its pressure is kept constant.

The previous two Jaws lead to a third law concerned with the relationship between the pressure

= Final x Finalpressure volume

Initial x Initialpressure volume

(Photo: Hamworfhy Compressur Syslem~ Limilt'd)

Figure 4.4 Breathing Apparalus Compressor.

In practice, when a gas is compressed - for example, when a breathing apparatus cylinder ischarged, or a tyre in pumped up - heat is generated and the temperature increases: the valve getswarm. This heat is only generated by the pumpingoperation. If the pressure of the gas is measuredbefore the temperature has returned to its originallevel, Boyle's Law does not hold, since the temperature of the gas is not the same as it was beforeit was pumped in: this is why the 'constant temperature' part of the law is important - the calculations do not work if it is not fulfilled.

Mathematically, if V I and PI are the initial volumeand pressure. and V 2 and P2 are the final volumesand pressure, then

So,

28 Fire Service Manual Physics and ChemistryfOf' Firefighters 29

Table 4.2 Critical temperatures, Tcand criticalpressures, pc/or various substances

off (provided the temperature remains constant)since more liquid will evaporate to make up for thegas drawn off until all the liquid is evaporated.

When liquefied gases are stored in cylinders,allowance must be made for expansion of the liquid in case the cylinder is heated beyond the critical temperature and the liquid turns into a vapour.

= Weight of liquefied gas which may be chargedWeight of cylinder completely full of water

Fillingratio

The amount of liquefied gas which may becharged into a cylinder is determined by its fillingratio, which varies from gas to gas and depends,among other things, on the density of the liquid.

This could lead to a substantial increase in pressure, with a risk of explosion. To minimise thisdanger, cylinders are never completely filled withliquid.

In the laboratory it is possible to produce such lowpressures that the boiling point of water can bereduced to O°C and lower. When this happens, icedoes not melt to form water, but will vaporise completely as the temperature rises.

4.5 ublimation

The filling ratio for ammonia is 0.5, so that a cylinder capable of holding 10 kg of water may only becharged with 5 kg of ammonia. A cylinder of thesame size could be charged with 12.5 kg of sulphurdioxide, for which the filling ratio is 1.25.

This direct change from solid to vapour withoutforming an intermediate liquid is given the specialname of sublimation.

In order to achieve sublimation with water,extremely low pressures are required, but solidcarbon dioxide sublimes at atmospheric pressure.

At higher pressures, carbon dioxide shows the normal sequence of melting followed, at a higher temperature, by boiling, so that under pressure - andonly under pressure - it is possible to have liquidcarbon dioxide.

73.1

45.8

50.0

33.7

12.9

219.0

78.0

77.7

Pc (atm)

For c)'tinders of liquified gas,the cylinder pressure is not anyindication of the amount of gasin the cylinder.

A ';true gas' will obey the gaslaws and the pressure will fallas gas is drawn off. Thusthe pressure in the cylinder isan indication of the quantity ofgas it contains.

Tc (OC)

Water (steam) 374.0

Sulphur dioxide 157.0

Chlorine 144.0

Ammonia 132.0

Nitrous oxide 39.0

Carbon dioxide 31.1

Methane -82.1

Oxygen -119.0

Nitrogen -147.0

Hydrogen -240.0

Many materials such as fuel gases are liquified underpressure and stored and transported in cylinders.

4.4.1 Critical temperature and pressure

Other gases cannot be liquefied at atmospherictemperature no matter how great a pressure isapplied. These are the so-called' permanent gases' .However, if the temperature is lowered sufficiently, it becomes possible to liquefy them by compression (e.g., methane, oxygen).

4.4.2 Liquefied gases in cylinders

As has been noted previously, an increase in pressure raises the boiling point of a liquid.

For each gas, there is a critical temperatureabove which it cannot be liquefied by increasingthe pressure alone. For example, carbon dioxidecan be compressed to a liquid at 20°C, but at 40°Cit will remain a gas.

4.4 The liquefaction of ga 'e

Its critical temperature is in fact 31.1°C. Belowthis temperature it can be liquefied by increasedpressure and it should properly be described as avapour. Above this temperature it cannot be liquefied and is properly described as a gas, or, toemphasise the fact that it is above its critical temperature, a 'true gas'.

Many substances which are gases at normal temperatures and atmospheric pressure can be compressed to such an extent that their boiling point israised above atmospheric temperature and the gasliquefies (e.g., propane, ammonia).

Some typical values of critical temperatures andcritical pressures are shown in Table 4.2.

The pressure required to liquefy a vapour at itscritical temperature is called the critical pressure.

Liquefied gases in cylinders do not obey the gaslaws, since, below the critical temperature, anychange in temperature, pressure or volume willresult in either the liquefaction of gas or the evaporation of liquid. Thus the pressure in a cylinder ofliquefied gas will remain constant as gas is drawn


Physics an Chem·s ryfor Firefighters

Chapter 5 - Heat transmission

Ch per

b

As has been disclIssed earlier.heat alwa)'s travels fromhigh-temJle.oature regions tolow-temperature regions. Inthis Chapter, the ways in whichheat energy can flow from hotbodies to cooler bodies will bediscussed.

Heat energy always flows from regions of hightemperature to regions of lower temperature. Heatwill always flow when there is a temperature difference, no matter how small that temperature difference is.

There are three methods by which heat may betransmitted (Figure 5.1):

• conduction:

• convection; and

• radiation.

5.1 Conduction

Conduction may occur in solids, liquids or gases.although it is most clearly present in solids. In conduction. heat energy is passed on from each molecule to its nearest neighbour, with heat flowingaway from the source of heat towards low temperature regions. The transfer of heat can be imaginedto take place in much the same way as water inbuckets being passed down a line of people in a'bucket chain'. In the bucket chain each individual

will only move a very small distance to either sideof their mean position; it is only the water whichpasses on. In conduction of heat, the moleculesvibrate about a mean position and pass on heatenergy by colliding with their neighbours.

Thermal conductivity, the ability to conduct heatvaries between materials. Most metals conductheat relatively easily and are, therefore, classed asgood conductors though the ability to conduct heatvaries between metals.

c. Radiation

'-----------_._----

Figure 5.1 Diagram illustrating conduction, convectionand radiation.

EPhysics and Chemistry for Firefighters 33

Radiator

I

Makeup Tank

Figure 5.3 Convection in heated water.

called 'radiators'. Most of the heat from these radiators is in fact carried away by convection. It wasalso used in the 'thermo-syphon' system (nowlargely replaced by the pump-assisted system) ofcooling motor engines.

Convection also causes the updraft in chimneys(see Figure 1.2). When a fire occurs in a building,convection currents can convey hot gases produced upwards through stairwells (Figure 5.5) andopen lift and service shafts, thereby spreading thefire to the upper parts of buildings.

If the hot gas products escape from the upper levels,cool air must enter at low level to replaces them.This will, in addition, help to maintain the burning.

Valves

/==r---;::~=x= Supply

ISafetyValve

Figure 5.4 Small boreheating and hot water

system.

IndirectCylinder

This occurs only in liquids and gases. It takes placefor example, when a pan of water is heated (seeFigure 5.3).

On the other hand, a wooden door, though it mayburn, is initially a better barrier to heat as it is sucha poor conductor. We can see then that the relativeconductivity of building materials may be animportant factor in the fire-resisting ability of astructure.

.........Hot WaterSupply

5.2 Convection

A pan full of water is heated from the bottom on agas ring. As the water warms up, it expands and,therefore, becomes less dense, and so a given volume is lighter.

1

As the heated liquid is buoyant, it rises and colder,denser fluid takes its place at the bottom. This thenbecomes heated and so a circulation is set up. Heatenergy is carried throughout the fluid by the molecules as they move until the water is the same temperature throughout. Compare this to conduction,in which the molecules do not move from theirposition: in convection it is the movement of theliquid or gas molecules through the mass of fluidwhich spread the heat energy around.

Convection is used in domestic hot water systems(Figure 5.4) and in many heating systems using so-

Figure 5.2 Sketch showinghow fire may be spread in

a building due to theconduction of heat alongan unprotected steel girder.

Thermal conductivity is important at most stagesof a fire, but during the fully developed fire thereis the danger of fire spread. As steel conducts heatvery well, a steel girder passing through a fire wallmay conduct sufficient heat through to the neighbouring compartment (room) to start a fire there. Itis not necessary for flames to spread through thefire wall itself. (Figure 5.2).

Imagine a door built to separate rooms in case of afire. If a fire occurs, a plain steel door will conductheat rapidly to the other side, which could potentially cause the fire to spread outside the room.

Thermal conductivity in the SI system of units ismeasured in Watts per metre per degree Kelvin(W/m K).

In fact, some solids and also liquids and gases aresometimes referred to as heat insulators becausethey are such poor conductors. In general good conductors of electricity (e.g., metals) are good conductors of heat, while poor conductors of electricityare good thermal insulators (e.g., most plastics).

The best conductors of heat are silver and copper.Aluminium has about half the thermal conductivity of silver and iron about one-eighth. Non-metallic solids are poor conductors and, besides mercury, which is a metal, liquids and gases are verypoor conductors of heat.

Thermal conductivity can be measured experimentally and is usually denoted by the symbol K.

The flow of heat is measured in Joules per second(1ls) and this unit is the Watt (W). So:

I Jls = 1 W


Radio waves, microwaves, visible light and X-raysare all part of this spectrum; the only thing whichmakes one form of radiation different from another is the wavelength of the radiation. The following table shows how the different forms of radiation occupy the electromagnetic spectrum.

HeatSource

2m

----~

2m

1m

1m

2m

I~

2m

~It+-I~--------~I-----2m 2m

II

Figure 5.6 Diagram show

ing the inverse square law

as it applies to radiation.

10 3 to 10.1

10 ' to 10'

8 X 10-7 red

4 X 10-7 violet

8 X 10' to 10-'

Wavelength (m)Radiation

Microwave

Radio waves(UHF to long wave)

Visible light: from red

to violet

Infrared

Figure 5.5 Sketch showing how fire on a lower floor CUll

spread to upper floors by convection.

Ultraviolet

X-rays

4 X 10-7 to IO-~

IO-R to 10-13

Radiation travels at this speed in a vacuum, but moreslowly through matter such as air, water and glass.

• Absorption. The energy is absorbed by thebody, whose temperature is raised; and

All forms of electromagnetic radiation travel instraight lines at the speed of light, 3 x IO~ m/so

All types of electromagnetic radiation produce aheating effect when they are absorbed by a body.This will depend on the amount of energyabsorbed. A proportion of the energy radiated fromthe sun is radiated as visible light. If a body is heated above ambient temperature, it will radiate heatin the infra-red region of the spectrum. These'"energy waves" have wavelengths longer thanthose of visible light.

Different parts of the electromagnetic spectrumhave been given different names simply for convenience. What we call "visible light" is so-calledbecause energy in the interval 8 x 10 7 to 4 X 10-7 mcan be detected by the eye. "Infra-red" radiationcannot be detected by the eye as it is beyond the"red" end of the visible spectrum. It also containsless energy than visible radiation, which in turn isless energetic that ultra-violet radiation. UV radiation causes damage to biological systems, but onlya small amount reaches the surface of the earthfrom the sun as it is absorbed by the ozone layer inthe upper atmosphere.

• Reflection. The energy may be reflected backfrom the surface in the way that light is froma shiny surface. Reflected energy does notenter the body, it just "bounces off' the surface.

Some substances absorb selectively: they allowsome forms of radiation to pass, but not others.Glass, for example, allows light to pass butabsorbs infra-red radiation - so glass may be usedas a fire screen: the heat is stopped but the fire maybe seen through it. However, for other reasons,such as its tendency to break under relatively lowpressures and its behaviour at high temperatures,ordinary glass is not a good fire barrier.

Carbon dioxide and water vapour also exhibit thisproperty. The sun's radiant energy, falling on theearth passes through the atmosphere and warmsthe ground, while the resulting infra-red radiationfrom the ground is absorbed by the atmosphereand so does not readily escape back into space.This is the cause of the 'Greenhouse Effect' - asindustry, homes and transport have released morecarbon dioxide into the atmosphere, the tendencyto retain heat at the earth's surface has increased. Itis believed that this may be producing a noticeableeffect on the climate.

When radiant energy (which, of course, includesinfra-red radiation) falls on a body, there are threepossibilities:

The intensity of radiation - that is, how much energy reaches a sllIface of a given size - falls offinversely as the square of the distance from thesource of radiation. This means that at twice the distance the intensity is one quarter; at three times thedistance, the intensity is one-ninth, and so on. Thisinverse-square law is demonstrated in Figure 5.6.

The square with I metre sides placed at, say,2 metres from the source will throw a shadow with2 metre sides on a second sheet placed 4 metresfrom the source. Thus the energy falling on I m2 isthe same as that which would have fallen on an areaof 2 m x 2 m = 4 m2 at a distance of 4 m. So theenergy per square metre at 4 m is one quarter thatat 2 m, i.e. one quarter at twice the distance. This isimportant when considering the effect of radiationfrom a heat source such as a fire: a body of a givensize and composition will heat up more slowly thefurther it is away from the radiation source.

• Transmission. If energy passes through thebody without warming it, it has been transmitted through the body. For example, 'transparent' materials transmit light.

less than 10-13y (gamma)-rays

Heat is radiated as infra-red radiation, which ispart of the spectrum of electromagnetic radiation.

[The term "convective heat transfer" is used todescribe the transfer of heat between a fluid (gas orliquid) and a solid. For example, a hot object in airloses heat partly by convection. The layer of airnext to the hot surface becomes heated and, therefore, buoyant with respect to the surrounding coldair: it rises, carrying away the heat and is replacedby cold air. This in turn becomes heated, and aconvection current is set up which cools the solid.]

53 adiation

Heat may also be transmitted by a means which isneither conduction nor convection, nor requires anintervening medium. Energy from the sun passesthrough empty space to warm the earth. A radiantheater placed at high level in a room can be felt atlower levels, where neither conduction nor convection can carry it. This method of heat transmission is called radiation and does not involve anycontact between the bodies which are providingand accepting the heat. To all intents and purposes,it behaves in the same way as light ("visible radiation") in that it travels in straight lines, will castshadows, and will be transmitted through somematerials and not others.


b

Cnap1ter

6.2 Atoms and mo ecul

Physics and Chemislry for Firefighters 39

Whether the substance is single or a mixture, it ismade up from many millions of very tiny particleswhich the chemist calls molecules. (See Section1.5) A mixture will contain more than one type ofmolecule, whereas a chemical compound containsonly one type of molecule. Molecules of the samesubstance are all exactly alike in their propertiesand behaviour.

Chemists recognise two distinct classes of substances; those which consist of a single chemical(elements and compounds) and those which aremixtures. A mixture may be separated into its constituents by some physical or mechanical means;for example, a mixture of salt and sand can be separated by dissolving the salt in water, leaving thesand behind. But to separate or change a singlechemical substance, a chemical reaction isrequired.

A molecule can be said to be the smallest particleof a compound capable of existing independently.The common substance chalk occurs in largequantities and in many different forms. For example, it is found in cliffs as lumps, or as a powder; itis, nevertheless, always recognisable as the samematerial, known chemically as calcium carbonate.This material is formed from innumerable calciumcarbonate molecules. Each molecule is composedof even smaller particles called atoms. Every calcium carbonate molecule is exactly the same; eachcontains five atoms,

Molecules are formed from atoms. The number ofdifferent atoms comprising their molecules is relatively small. The molecules of all substances comprise various combinations of atoms, from approximately 90 different types of atom.


Chapter 6 - The Basis of Chemistry

The Chemistry of Combu lion

In the rest of this volume we will deal with thechemistry of combustion - the reactions by whichenergy is released in fires. Before discussing combustion in detail, it is necessary to tal k about understand some of the basic concepts of chemistry.

Up to now, we have considered the physical properties of matter and heat, the properties that decidehow bodies will behave when energy is suppliedto them.

Chemistry is a complicated subject bristling withlong and difficult names to pronounce, and withintricate formulae used by the chemist. There are,of course, many text books available to the studenton chemistry and, in presenting an opening to thestudy of fire-fighting techniques, it is difficult todecide exactly how much should be included.Many new processes and materials have becomeavailable in recent years. Firefighters are facedwith so many new substances, particularly newbuilding materials, during the course of their work,that they must have some idea how they will reactwhen involved in fire. The particular hazards ofmany flammable materials and chemicals are dealtwith separately in Parts 6b and 6c of the Manual ofFiremansbip. However, in this Chapter it is proposed to deal with those aspects of chemistry whichapply to the study of fire techniques, and to lead onto discuss some of the more hazardous chemicalsubstances from a purely chemical point of view.

Chemistry is the science of the composition ofsubstances, their properties and reactions witheach other. Substances may be solids, liquids orgases, in living or non-living systems, but all haveone common factor - they consist of chemicals.

6.1 The basis of chemistry

b

Figure 5.7 Clothing may be ignited by radiation whenplaced loo close 10 a source of radialed heat,

being placed too close to a source of radiation(Figure 5.7), as sometimes happens when peopleair clothes on a clothes horse placed too near a fire.Radiant heat from the sun passing through a glasswindow has sometimes been concentrated by anobject inside the house which acts as a lens, suchas a magnifying glass or a shaving mirror. The oldfashioned "bottle glass" used in windows will alsoconcentrate the sun's rays and could, in principle,cause a fire, but a bottle, or pieces of broken bottlecannot.

Fire Service Manual38

Many fires have been caused by radiation - one ofthe most common is clothing being ignited by

Some substances, such as pitch, transmit infra-redradiation, but absorb light.

The condition of the surface of a body affects itsability to absorb or reflect radiation. White or polished metal surfaces are the best reflectors andpoor absorbers, while matt black surfaces are badreflectors and good absorbers.

This is why white clothes, white-painted houses andcars, etc., are often used in hot climates. Snow and iceare poor absorbers of heat and reflect radiation verywell. Because of this they melt slowly in direct sunlight. Melting will occur if the air temperature is raised,and heat is transferred by convection (Section 5.2).

Good reflectors of heat are also poor radiators. Apolished silver teapot retains its heat better than ablackened teapot, in spite of silver being a goodconductor. For the so-called radiators of a hotwater system to radiate effectively they should bepainted black, not a light colour as is usually thecase. However, the principal way by which theywarm a room is by heating the air immediatelyaround them, which then rises, producing convection currents which spread heat tllroughout theroom. The other side of the coin is that the heateris being cooled by convection.

Experiments have been carried out in which coaldust or other black powders have been spread onsnow in order to accelerate melting. The sun's heatis more readily absorbed by the black powder, soits temperature rises and heat is transferred by conduction from the powder to the snow beneath.

The ability of carbon dioxide and water vapour toabsorb infra-red radiation in very narrow regionsof the electromagnetic spectrum means that theyalso emit radiation in the same regions when theyare hot. Radiation from small flames (e.g., at theearly stage of a fire) is dominated by radiationfrom these gases, specifically at wavelengths of2.8 x 10-7 and 4.4 x 10-7 m. Many infra-red detectors make use of this fact to distinguish betweenradiation from a flame and a hot solid object (suchas a heating element) which emits over a widerange of wavelengths.

6.2.1 Compounds and mixtures

They can be split by nuclear processes, which will be

discussed elsewhere.

When a symbol is written it represents one atom ofthe element. Thus: H represents one atom ofhydrogen: °represents one atom of oxygen.

A formula always represents one molecule of thesubstance and shows which atoms are present inthe molecule and how many of them there are.Thus H20 represents one molecule of water, containing two atoms of hydrogen and one atom ofoxygen, bound together chemically. Similarly carbon dioxide has the formula CO2, representing themolecule which contains one atom of carbon andtwo atoms of oxygen. If a molecule contains morethan one atom of the same type, the number ofsimilar atoms is written at the bottom right of theappropriate symbol:

since they are based on the old Latin or Greeknames. For example, the element sodium has thesymbol Na which is derived from the Latin natrium, and lead has the symbol Pb, derived fromplumbum (hence plumber, and plumb line).

6.3.1 Using symbols to write formulae

Calcium carbonateCaC03 I atom of calcium, one atom of carbon

and 3 atoms of oxygen

Phosphorous pentoxidePOs 1 atom of phosphorus and 5 atoms of

oxygen.

To represent more than one molecule we write anumber in front of the formula: thus three molecules of water are represented by 3H20. Thisgroup of three water molecules contain six hydrogen atoms and three oxygen atoms.

2MgO represents two molecules of magnesiumoxide (and, therefore, a total of two magnesiumatoms and two oxygen atoms).

6.3.2 Radicals

Certain groups of atoms, common to families ofrelated compounds, are known as radicals. A radical can be defined as: 'a group of atoms presentin a series of compounds which maintains itsidentity regardless of chemical changes whichaffect the rest of the molecule'.

Every element is assigned a symbol (see Table6.1), which is different from that of all the otherelements. A symbol may be one letter or two; inthe latter case the convention is to write the secondletter as a small letter. Thus the symbol for nickelis written Ni and not NI. NI would be interpretedas a molecule containing one nitrogen atom (N)and one iodine atom (1) (such a compound doesnot exist). In many cases the symbols are the firstletter of the name of the element, often followedby a second letter taken from that name. However,there are several common elements whose symbols bear no relationship to their modern names,

6.3 Symbols

Chemical symbols are used as a way of describingchemicals in terms of formulae, which are complete descriptions of molecules in terms of the constituent atoms. Symbols give as much informationas possible, whilst still being simple and quick touse. Formulae may also be used to describe theway that atoms in a molecule are grouped together. This information may give clues to how onechemical compound may react with another.

1

3

4

2,4,6

4,6

Valency

1.0

32.0

23.0

28.0

39.0

238.0

108.0

80.0

40.0 2

12.0 4

27.0

35.5 1,3,5,7

63.5 1,2

19.0 1

197.0 1,3

4.0 0

11

92

16

9

47

2

6

19

14

8 16.0 2

15 31.0 3

53 127.0 1,3,5,7

26 56.0 2,3

12 24.0 2

80 201.0 1, 2

10 20.0 0

7 ]4.0 3

79

29

17

20

35

13

Na

S

U

Ag

Si

K

H

He

Au

Cu

F

Cl

C

Ca

Br

Symbol Atomic Atomicnumber mass

Uranium

Sulphur

Sodium

Silver

Silicon

Potassium

Oxygen 0

Magnesium Mg

Mercury Hg

Neon Ne

Phosphorus P

Nitrogen N

Iron Fe

Hydrogen

Iodine I

Fluorine

Gold

Helium

Copper

Chlorine

Carbon

Bromine

Calcium

Aluminium Al

Name ofelement

Table 6.1 List of some elements with their atomicnumber atomic mass and valency

4-----mm10000000

I mm and10000000

When two or more atoms of different elements arechemically bound together to form molecules, allexactly the same, the substance formed is called achemical compound. For example, each molecule ofthe compound calcium carbonate contains five atomschemically bound together (one of calcium, one ofcarbon and three of oxygen). The compound formedfrom identical molecules can only be broken down orchanged by a rearrangement of the atoms, known as achemical reaction. A mixture (formed from two ormore different sorts of molecules) can be separated byphysical or mechanical means into the substances

which make up the mixture.

Substances formed entirely from one type of atomare called elements. There is an element coo'esponding to each different type of atom. Thus carbon, being formed entirely from carbon atoms, isan element. Similarly iron, containing only ironatoms, is another element. Elements may be composed of molecules made up from identical atomsjoined together, or they may be composed of single atoms. The element oxygen consists of oxygenmolecules, each molecule being two oxygen atomsjoined together, whereas the element magnesiumconsists of single magnesium atoms. When weagain consider the molecule of calcium carbonate(chalk) we find that it is composed of one atom ofthe element calcium, one atom of the element carbon and three atoms of the element oxygen, allche~ically bound together. A list of the names ofsome elements is given in Table 6.1; a full list is

given in Appendix B.

between

Atoms are the 'building blocks' of all substances.Unlike molecules, which can be broken down orchanged during chemical reactions, atoms cannotbe split chemically into anything smaller I. Duringchemical reactions the atoms rearrange to formdifferent molecules, but the atoms themselvesremain the same. They are the smallest particles totake part in chemical changes. Atoms are extremely small, their diameters being


6.4 Atomic Olass

We can then compare other atoms with hydrogento see how many times heavier they are, so that wehave the definition:

To show these radicals, formulae are often writtenwith brackets enclosing the radical and with anumber beyond the bracket to indicate how manyof these radicals are in the formula.

Several elements show more than one valency,including iron (Fe), copper (Cu) and nickel (Ni). Thevalency that the element shows depends on the particular circumstances - the other elements with whichthe element is combined, as well as on the conditionsunder which the reaction in which the compound isformed is carried out. More detailed knowledge ofthe chemistry of the element is required to predictwhich valency will be shown in any palticular reaction. However, the names of the compounds fOlmedare often adapted to help in deciding which valencystate the element is in, in that particular compound,and hence to determine the correct formula.

(1) -OUS and -le-ODS and -IC are used where an element showstwo valencies.-ODS always indicates the lower and -IC the higher valency. For example:

IronFerrous: valency 2, e.g., FeCI2ferrous chloride.FelTic: valency 3, e.g., FeCI) ferric chloride.TinStannous: valency 2, e.g., SnBr2 stannous bromide.Stannic: valency 4. e.g., SnBr4stannic bromide.

6.6.1 Multiple valency

6.6.2 Nomenclature

Potassium sulphide K2S(K valency I; S valency 2)

(3) -IDE-roE is used to indicate that a compound is madeup of two elements only. By convention, metalsare written before non-metals in names and formulae, thus:

Magnesium oxide MgO(Mg valency 2; °valency 2).

(2) Use of Roman numeralsA modern approach to the problem of multiplevalency is to indicate which valency is being usedby inserting the appropriate Roman numeral afterthe name or symbol of the element concerned, e.g.,Iron (lI) chlolide Fe(Il)CI2 •

Iron (Ill) chloride Fe(III)CI 3 ,

Tin (ll) bromide Sn(lI)Br2,Tin (IV) bromide Sn(lV)Br4

+ 3 x atomic

mass °+ (3 x 16)

+ atomicmass N

+ 14

atomicmass H

= 63

=

Molmass

6.6 Valency

When atoms combine to form molecules they doso in definite fixed ratios. For example, one sodium (Na) atom always combines with one chlorine(Cl) atom to give NaCl (common salt). but onemagnesium (Mg) atom combines with two chlorine (Cl) atoms to give MgCl2 (magnesium chloride). The 'combining power' of an atom dependson the arrangement and number of its electrons,but the mechanism of this is too complicated todiscuss easily here.

The valency of an atom tells us how many chemical bonds the particular atom, or group of atoms(radicals) will form. Valencies are given in Table 3.When molecules are formed, the atoms or radicalsgenerally combine in ratios in which the valenciesare balanced. This property enables us to work outthe correct formulae of many chemical compounds. For example, in magnesium oxide, Mghas a valancy of 2, and ° has a valency of 2. Tobalance the valencies we need one Mg atom andone °atom; hence the formula MgO.

Similarly: nitric acid HNO j , molecular mass 63;

Molecular Mass = atomic mass of sulphur +2 x atomic mass of oxygen

= 32 + (2 x 16)= 64

In potassium carbonate, potassium (K) has a valency of 1, while the carbonate radical has a valencyof 2. Potassium carbonate requires two K atoms tocombine with one carbonate radical, thus the formula is K2C03 .

In aluminium sulphate AI has a valency of 3, thesulphate radical has a valency of 2. To form thecompound, two AI atoms are required to balancethree S04 radicals (total number of "bonds" = 6),so that the formula for aluminium sulphate isAI2( S04))'

Table 6.2 A list of common radicals

Name Symbol

Valency I Ammonium NH4

Bicarbonate HC03

Bromide Br

Chlorate CI03

Chloride Cl

Cyanide CN

Hydroxide OH

Iodine I

Nitrate N03

Nitrite N02

Perchlorate CI04

Valency 2 Carbonate CO)

Sulphate S04

Sulphide S

Sulphite S03

Valency 3 Phosphate P04

6.5 Molecular mass

For example, the atomic mass of sodium is 23(written Na = 23), meaning that an atom of sodiumis 23 times heavier than an atom of hydrogen.

In the same way, molecular mass is the mass ofone molecule of the substance compared to themass of one atom of hydrogen. For example, themolecular mass of water is 18 which means thatone molecule of water is 18 times as heavy asone atom of hydrogen. Since a molecule consistsof atoms joined together. the mass of the molecule is the sum of the masses of its componentatoms. The molecular mass is found by addingtogether the atomic masses of those atoms present, thus: The molecular mass of sulphur dioxide (S02) is 64.

The mass of one atom of the elementthe mass of one atom of hydrogen

Atomicmass

Radicals are not complete molecules and have noindependent existence. For example, the formulaof one molecule of calcium hydroxide (slakedlime) is Ca(OHh, indicating that it contains onecalcium atom and two hydroxyl (OH) radicals. Themolecule contains two oxygen atoms and twohydrogen atoms, but they are always paired, asOH. Another common radical is NO j • the nitrateradical. The formula for aluminium nitrate is written Al (N03h, indicating that the trivalent aluminium atom is combined with three monovalentnitrate radicals. Schematically:

L NOJAI~-N03

NOJ

The meaning of valency is discussed in Section 6.6.A list of common radicals is given in Table 6.2.

The mass of one atom or one molecule is extremely small - of the order of 10 22 grams. It is of littlepractical value to quote the actual masses of atoms,but because atoms of different elements containdifferent numbers of protons and neutrons, knowing the mass is a big step towards identifyingwhich element the atom belongs to.

It is, therefore, important to know how heavy oneatom is in comparison with any other. The chemist,therefore, uses a relative atomic mass scale and notthe actual masses of the atoms. Various scales havebeen proposed and. for technical reasons, the onemost generally used is based on oxygen, which isgiven the atomic mass of 16.000. On this scalehydrogen has an atomic mass of 1.008. However.for normal purposes, the atomic masses can berounded off, making hydrogen equal to 1.

42 Fire Service Manual Physics and Chemistn' for Firefighters 43

• b

48

32

= 2MgO2 (24 + 16)80 unitsTwo MgOmolecules eachcontaining 1magnesium and1 oxygen atom

48=

32

will again be

+ 022 x 1632 unitsTwooxygenatoms

mass of magnesium

mass of oxygen

mass of magnesium

mass of oxygen

2 Mg2 x 2448 unitsTwomagnesIUmatoms

that two atoms of magnesium react with one molecule of oxygen to produce two molecules of magnesium oxide.

The 'units' are mass units, where one unit represents the mass of one hydrogen atom. Therefore,according to the equation, 48 units of magnesiumwill react with 32 units of oxygen to form 80 unitsof magnesium oxide. In other words the ratio:

These atoms and molecules have masses which areexpressed in terms of their atomic and molecularmasses (as described in Section 6.3). The atomicmass of magnesium is 24, that of oxygen is 16, andif we use this information together with the equation, we obtain:

An actual reaction between magnesium and oxygen will obviously involve millions of moleculesof each substance. Suppose we 'scale up' this reaction until we have two million magnesium atomsinstead of two. Then this number of magnesiumatoms will react with one miJlion oxygen atoms.

Two atoms of magnesium weigh 48 units, therefore, two million atoms of magnesium weigh48 000 000 units.

Similarly, one molecule of oxygen weighs 32units; therefore, one million molecules of oxygenweigh 32000 000 units, so that the ratio:

Mg + O2 = MgO

Consider this other example. Magnesium (a metal)burns in oxygen to form magnesium oxide (a whitepowder). Magnesium reacts with oxygen to formmagnesium oxide:

The equation above can be balanced by placingtwo molecules of magnesium oxide on the righthand side, thus:

Magnesium + oxygen = magnesium oxide

We now have equal numbers of oxygen atoms oneach side of the equation, but the magnesium is'out of balance'. By having two atoms of magnesium on the left hand side (instead of one):

2Mg + O2 = 2MgO

Mg + O2 = MgO

In this case, although there is the same number ofmagnesium atoms on each side of the equation,this is not true in the case of the oxygen atoms,where there are two on the left hand side and onlyone on the right hand side. This implies that oxygen atoms disappear during the reaction. The equation must be balanced before the equation is of anypractical use - before it can tell us how the elements combine.

Mg + O2 = 2MgO

the equation is now correctly balanced. Each sidenow contains equal numbers of each type of atominvolved. It is of course possible to balance theequation by cheating. The equation:

6.8 U e of chemical equation'

but Mg02 does not exist. A chemical equation canonly be balanced by changing the number of molecules present, not their formulae.

The balanced equation: 2Mg + O 2= 2MgO tells us

"balances" if we change the formula of magnesium oxide, thus:

This can be stated simply as: "sulphur reacts withoxygen to form sulphur dioxide". A further simplification can be made by replacing' reacts with' by"+" and 'to form' by an equals sign, "=". We thenhave:

Sulphur + oxygen = sulphur dioxidereacts with to form

6.7 'imple equation

Consider a simple chemical reaction. When sulphur (a yellow solid element) burns in air, it combines with oxygen from the air, producing acolourless gas with a pungent choking smell. Thisgas is called sulphur dioxide (formula S02)'

This final statement represents the chemical equation for this reaction. It tells us that every sulphuratom involved reacts with one oxygen molecule toform one sulphur dioxide molecule.

This statement can be simplified even further byreplacing the names of the chemicals by symbolsand formulae. (The molecules of oxygen, likethose of most common elements that are gases,contain two atoms, but sulphur, like other solidelements, is assumed to consist of single atoms.)This gives:

gives sulphites -SO)gives sulphates -S04gives nitrites -N02gives nitrates -N03

H2S03

H2S04

HN02

HNO)

1 e.g., carbon monoxide CO,2 e.g., carbon dioxide CO2,

3 e.g., sulphur trioxide S03'4 e.g., carbon tetrachloride CCI4,5 e.g., phosphorus pentachloride PCI 5 .

Sulphurous acidSulphuric acidNitrous acidNitric acid

Potassium nitrite KN02(K valency 1; N02 valency l).

(4) -ITE and -ATE-ITE and -ATE are used where a compound contains more than two elements, one of which is oxygen. For two related compounds, that named -ITEalways contains less oxygen than that named-ATE.

Sodium sulphite Na2S03(Na valency 1; S03 valency 2).

The ending -lTE and -ATE are related to the ending -OOS and -lC where the latter are used in thenames of acids. -OOS leads to -lTE and -lC to-ATE. For example:

Sodium sulphate Na2S04(Na valency l; S04 valency 2).

(5) Mono-, Di-, Tri-, Tetra-, PentaMono-, di-, tri-, tetra- and penta- are used in namesto tell how many of a particular atom or radical arepresent.

MonoDiTriTetraPenta-

Potassium nitrate KN03(K valency 1; N01 valency I).

-IDE is also used exceptionally for a few radicals,e.g., -OH hydroxide. Thus:

Calcium hydroxide Ca(OH)2(Ca valency 2; OH valency 1).

(6) Per- always denotes that there is moreoxygen present in the compound thanwould normally be the case:Hydrogen oxide (water) H20,Hydrogen peroxide H20 2,

Sodium chlorate NaCIO"Sodium perchlorate NaCl04.

44 Fire Service Manual Physics and Chemisrry for Firefighters 45

b

No matter to what extent the amounts of magnesium and oxygen are scaled up, the ratio willalways be 48/3Z. Therefore:

tion releases more heat then the first, by an amountequal to the latent heat of evaporation of water.

6.9.3 Reaction conditions

P ysics and Chemistryfor Fireighters

Chapter

Heat Sourceseh IgnitIon TemperaJUte

CG~~c':r~~'"Friction .. Chemlcaf AetJolI

Hot SUrllloCHOpen_

GasesAcetyleneButane

Cartx)O MonoxideHydrogen

Nalura} GasPropaneothers

SolidsBulky-Dust

Finely DividedCoal CorkCloth GramGrease StrawLeather SugarPaper PlasticWax othersWood

LiquidsAlcohol

Cod Uver OilKeroseneLacquor

Sunflower OilPetroleum

Paint

TU~~~I~ne

o1hers

Oxygen SourcesApproximately 16% RequiredAJr I1or'mIIlty eontams 21~ Oll.yglln

Somematal1al!lconta)l'l sulfil:iQ'1lI

oxygen W1rhln theirmektH,tp 1Q 6Vpport

burning

(from the air) and the sUlface of the fuel: this is acomplex process and in general only occurs withsolid fuels which char on heating.

A flame is a region in which a sustained, heatreleasing reaction between a fuel in the vapourstate and oxygen takes place. This region alsoemits light, usually with a strong yellow colour,though there are substances such as methanolwhich burn with a weak blue flame which cannotbe seen in strong light.

One way of discussing burning is in terms of thetriangle of combustion (Figure 7.1). For combustion to occur three things are necessary: heat, oxygen and fuel. Combustion will continue as long asthese three factors are present. Removing one ofthem leads to the collapse of the triangle and combustion stops.

Figure 7.1 The trianRIi> of combustion.

Flames arc so much part ofour everydHy experience thatit seems strange that there is

anything to write about regard M

in~ their nature. Certainly,every firefighter knows whatdangers names present, seeshow they can spread and isinterested in how they can beextinguished. However, manypeople, if asked what a flameactually is, would find itdifficult to produce an answer.This section aims to shed lighton the nature of names, to givethe reader an insight into theirmake-up and, especially~ tohighlight the different types offlame.

Chapter 7 - Combustion

7.1 The Fire Triangle

For combustion or burning to occur. oxygen. usually from the air, must combine with a fuel. A fuelmay be in anyone of the three states (gas, liquid orsolid) initially, but for flaming combustion tooccur, a solid or liquid fuel must be converted intoa vapour. which then mixes with air and reactswith oxygen. Smouldering combustion, on theother hand. involves a reaction between oxygen

Equations say nothing about the reaction conditions; whether heat must be used or pressureapplied.

A catalyst is a substance that alters the rate of a chemicalreaction. but does not itself undergo a chemical change.

Equations do not tell us whether heat is given outor absorbed during a chemical reaction.

6.9.4 Heat

6.9.5 Rate of reaction

Equations say nothing about the rate of the reaction; whether it is slow, fast or inherently violent;or whether or not a catalyst? is necessary to makethe reaction occur at a reasonable rate.

copper nitrate + hydrogencopper + nitric acid

6.9.1 Reality

A chemical equation must be a summary of aknown chemical reaction. For instance it is perfectly possible to write down the equation:

6.9 Limitations of chemicalequation

but such an equation is useless because it is foundthat when copper is placed in nitric acid. hydrogenis never produced. Therefore, the equation is not'telling the truth', even though the sides balance.

6.9.2 Physical state

The equations we have been considering containno information about the physical state of thechemicals. whether they are solids. liquids orgases, whether they are pure substances or are dissolved in water or some other solvent. or whetherthe solutions are dilute or concentrated.Sometimes it is important to specify the physicalstate. For example. the reaction of hydrogen andoxygen to form water vapour is associated with therelease of a certain amount of heat. If the watervapour is allowed to condense. the latent heat ofvaporisation is released. Thus, if we are quotingthe amount of heat released by the reaction ofhydrogen and oxygen. the physical form of thewater must be stated. This can be done as follows:

2Hz + Oz = 2HzO(g)2Hz + Oz = 2Hz0(1)

where g and I refer to the gaseous (vapour) and liquid states respectively. As written. the second reac-

if 48 grams of magnesium are used, 32 grams ofoxygen are needed. If 48 kg of magnesium areused, 32 kg of oxygen are needed, and 80g or 80kg of magnesium oxide will be produced. For anyother mass of magnesium, the masses of oxygenneeded and magnesium oxide produced can befound by simple proportion.

46 Fire Service Manual Phvsics and Chemistrv for Firefighters 47

7.2.1 Oxidation


Before we discuss flames, it is useful to define twotypes of gas flow: laminar flow and turbulent flow.

7.4 Laminar flow andturhulent flow

Laminar flow [Figure 7.2] is steady flow in whichtwo particles starting at any given point follow thesame path. Particles never cross each other's paths,so the particle paths are bunched together likeuncooked spaghetti in a packet. At any given time,the velocities of all particles on one path are thesame, but the velocities of particles in differentpaths might be different. Laminar flow is associated with slow flow over smooth surfaces.

In turbulent flow. [Figure 7.2] there are randomchanges in velocity and direction of the flow,although the flow as a whole is moving in a definite direction. If we consider wind blowing downa street on a windy day, leaves and litter may beblown up, down, across and around, revealinglocal changes in the flow, but the general directionof the wind is sti U down the street. Turbulent flowtends to occur in fast flows over rough surfacesand around obstacles.

surface reaches about 50 - 55°C (the firepoint, seeSection 7.6.3), the rate of evaporation is highenough for the vapours to be ignited by a smallflame, or spark, and support continuous flamingabove the surface. After the paraffin has beenburning for some time, the surface of the fuel willbe close to its boiling point, supplying flammablevapours to the flame.

Once a flame has been established and flammablevapours are rising from the fuel surface, heat andwhat are called chain carriers are produced wherethe flame reactions are occurring. A proportion ofthese will pass into the next layer of gas and startthe oxidation and heat release processes there,rather as in a relay race. Chain carriers are believedto be atoms or fragments of molecules known asfree radicals which are extremely reactive. Thetype of chemical reaction which occurs in theflame is known as a chain reaction.

In fact, there are two distinct types of flame: thepremixed flame and the diffusion flame. Theyhave different properties, though both are familiarfrom everyday experience. Understanding thateach behaves differently is imp0l1ant: under different circumstances fuel and air can combine in different ways to produce very different results.

Figure 7.2 Laminar and

turhulent f7ow.

4CJHs(N03h -3> 12C02 + lOH20 + 6N2 + O2

nitroglycerine

Nitrogen is not usually thought of as an oxidisingagent or even a reactive element, but some metalswill burn vigorously in this gas. Magnesium, aluminium and their alloys form nitrides in combus

tion reactions:

C IOH)6 + 8Cl2 -3> 16HCI + lOC

turpentine

Many organic materials (i.e., those based on carbon) will burn readily in halogen gases:

Fe20 3 + 2AI -3> Al20 3 + 2Fe + heat

thermite mixture

3Mg + N2 -3> Mg3N2

magnesium nitride

There are two distinct types offlame: the premixed flame and

the diffusion flame.

7.3 What makes a flame a flame?

If a pool of paraffin is heated. its temperature willrise and combustible vapours will evaporate fromthe surface. When the temperature of the liquid

(iv) Elements other than oxygen may be considered as oxidising agents; examples of these arechlorine and fluorine. "Combustion" may occurwith these substances; for example, hydrogen will

burn explosively with chlorine:

(iii) Oxygen may be provided by one of the materials in a mixture of compounds. The 'thermite

reaction' illustrates this principle:

(ii) The combustion may take place using oxygenwhich is contained within the burning material, thecombustible material and the supporter of combustion being together in the same compound:

= 32 743 Joules per gram (Jig)

Fire Service Manual

39292012

48

(i) The oxygen may be supplied by the air.

as one "mole" of carbon contains 12 g.

Besides calorific value, the rate of heat release isalso important. For example, burning magnesiumproduces less heat than the burning of carbon, butwhen rates of reaction are considered, we findmagnesium has a much higher rate of combustionthan carbon so that the heat is released much morerapidly. Heat release rate is now considered tobe a major factor in whether a fire will spreadover materials, and a device called a ConeCalorimeter has been developed to measure thisquantity for wall linings and building materials ingeneral as part of the assessment of their flammability and suitability for their intended use.

All combustion reactions release heat energy andare, therefore, called exothermic reactions. Thequantity of heat produced per unit weight of fuelcan be calculated and is known as the calorificvalue of the fuel. For example, when 12 grams ofcarbon (the "gram atomic mass") are burned tocarbon dioxide 392 920 Joules of heat are produced. This is the "heat of combustion", as tabulated in textbooks and handbooks: it refers to astandard amount of the fuel (the "mole") and hasunits kJlmol. The calorific value for carbon is then:

2C + O2 -3> 2CO (carbon monoxide)

2CO + O2 -3> 2C02

2H2 + O2 -3> 2H20

An oxidation reaction is a reaction which involvescombination with oxygen or other oxidisingagents. The following reactions are typical exam

ples of combustion:

(note that the oxidation of C to CO is not a flam

ing reaction: the others are).

7.2 Heat of reaction andcalorific value

______Jhnz .......

Flammability Limits (% fuel/air by volume)


Because difl"usion flames existonly at the fuel-air inte."face.there is no equivalent of burningvelocity, and no equivalent torich or lean mixtures. ortlammability limil~.

flame is the mixing process. The fuel vapour andoxygen mix with each other by molecular diffusion, which is a relatively slow process, though thehigh temperatures associated with flames increasethe rate at which diffusion occurs.

Diffusion flames themselves fall into two broadtypes. In slow-burning diffusion flames, such ascandle flames, the fuel vapour rises slowly fromthe wick in a laminar flow and molecular diffusiondominates. This type of flame is a laminar diffusion flame.

L _0 5 _79_11_13,15/Volume % Methane in Air ~

Figure 7.3 Flammabilitylimits.

Limits of Flammability

0.4

0.2-

0.3

0.1-

flame speed, which is different to the burningvelocity. For example, the burning velocity of astoichiometric methane-air flame is 0.45 m/s. Ifthe unburnt gases are no longer stationary. theflame propagates at the local flow speed plus theburning velocity. As the flame gets faster, theflame front wrinkles as turbulence is produced inthe unburnt gas, increasing the surface area of theflame front. This increases the reaction rate,increasing the rate at which burnt gas is produced,so pushing the flame front forward faster. In explosion situations, flame speeds of hundreds of metresper second can be achieved in gas-air mixtures,though the burning velocity of the mixture will bemuch lower than this. It is worthwhile making thedistinction between these terms, as some oldertexts use flame speed to mean burning velocity. Itis possible to achieve supersonic flame speeds, inwhich the combustion region is strongly coupledto a shock wave: this phenomenon is called detonation.

BurningVelocity

m/s

Diffusion flames occur at the interface where fuelvapour and air meet. Unlike premixecl flames, thefuel vapour and the oxidant are separate prior toburning. The dominant process in the diffusion

if the concentration of fuel lies between certainwell-defined limits, called flammability limits.For example, mixtures of methane and air will onlyburn if the concentration of methane in air liesbetween 5% and 15%, whereas hydrogen will burnin air at concentrations between 4% and 75%.

For each mixture of fuel and air between the flammability limits, there is a characteristic burningvelocity at which a premixed flame will propagatethrough a stationary gas.

The figures quoted for limits of flammability mayvary as there are a number of factors which mayslightly alter the value: pressure, temperature,dimensions of the test apparatus, direction offlame propagation and moisture content of themixture all have some effect. (In general, the limits widen with rise in temperature.)

Local air currents and turbulence caused by obstacles can cause a flame to move at speeds muchhigher than the burning velocity. The speed atwhich a flame moves relative to an observer is the

Within these ranges, there is an optimum mixturein which there is just sufficient fuel to use up allthe oxygen. This is the stoichiometric mixture.Mixtures containing more fuel than the stoichiometric mixture are known as rich mixtures, andones containing less fuel are lean mixtures. Thestoichiometric mixture for methane is 9.4%. A 7%mixture is lean, while a 12% mixture is rich.

Burning velocities usually lie between 0.1 and 1.0m/so They tend to peak at the stoichiometric composition and fall away towards the flammabilitylimits [Figure 7.3J. Burning velocity is dictated bythe chemical processes involved - how quickly thefuel reacts with the oxygen. The methane and oxygen molecules do not simply combine instantaneously to form carbon dioxide and water vapour,but form free radicals and intermediates such asformaldehyde and carbon monoxide along the wayto completing the reaction.

If the premixture flows into a flame with a laminarflow whose velocity is equal to the burning velocity of the mixture, the flame can be held stationary.This is how premixed flames on Bunsen burners,domestic gas rings etc., are held steady.

Fire Service Manual

A certain amount of heat energy is required to startthis reaction but more heat is produced by the reaction than it takes to initially start it. so the burningprocess is self-sustaining.

As we have seen, a flame is the region in which thechemical reactions take place which turn unburntfuel vapours into burnt gases - the combustionproducts: for example, methane and oxygen reactto give carbon dioxide and water vapour.

Not every mixture of air and fuel will burn.Depending on the type of fuel and oxidant involved(air or pure oxygen, for example), a mixture initially at room temperature and pressure will only bum

7.5 Premixed and diffusionflame

Premixed flames occur when a fuel is well-mixedwith an oxidant, e.g., 10% methane mixed with air.For ignition to occur, energy must be supplied tothe system in the form of a spark or small flame. Aself-sustaining flame will then be establishedaround the ignition source and propagate outwardsin all directions.

Gas Lower limit Upper limit

Hydrogen 4.0 75.0

Carbon monoxide 12.5 74.2

Methane 5.0 15.0

Butane 1.5 9.0

Ethylene 2.7 28.6

Acetylene 2.5 80.0

The flame consists of a zone where cold unburntgas (reactants) is transformed into hot burnt gas(products). The flame zone of a premixed flamemay be less than I mm thick. As the volume of thehot burnt gas is greater than that of the same massof cold unburnt gas, the flame front is pushed outwards from the ignition point, like the skin of aninflating balloon.

50

7.6.4 Fireball

than the firepoint and a flammable vapour/air zoneexists at some distance from the liquid surface.This may happen if there is a spillage of petrol(firepoint approx. -40°C) which forms a large pool.If an ignition source is introduced into the flammable zone, a premixed flame will flash back,igniting the fuel in the fuel-rich mixture above theliquid surface and giving rise to a large fire (turbulent diffusion flame).

In a sustained fire of this type, flames bum continuously above the surface unti I the fuel is consumed(or the fire is extinguished). In principle, combustible solids burn in the same way, although theformation of fuel vapours involves chemicaldecomposition of the solid which requires moreenergy than simple evaporation. For this reason,solids tend to burn much more slowly than combustible liquids.

A fireball can occur when a mixture of vapour andmist droplets forms a cloud containing very littleair, for example when a vessel containing pressurised liquid fuels, such as LPG, ruptures. Theoxygen concentration within this cloud is far toolow for premixed combustion to take place, but, ifthere is a source of ignition at the boundarybetween the fuel and the surrounding air, a premixed flame will flash through the flammablezone at the boundary, leading to the establishmentof a diffusion flame. The fireball has then beenestablished and will rise as it burns.

As burning progresses, instabilities are introducedin the surface of the flame increasing the surfacearea available for the reaction to take place. Thefireball will increase in size until the fuel has beenused up. Then it will shrink and extinguish.

7.6.5 Vapour cloud explosions

If a gas or vapour escapes under pressure from arupture in a storage tank or pipeline, there is likelyto be rapid mixing of the fuel with air, producing acloud of fuel-air mixture, some of which will be ofconcentrations which fall between the flammability limits. If an ignition source is present in thecloud, a premixed flame will move outwards in alldirections from the source. The flame will propa-

flame. Once the flame is established, the processof melting, evaporation and burning is self-sustaining because heat is transferred from the flameback to the wick to sustain the melting and evaporation processes.

Imagine a dish of flammable liquid, such as paraffin. A region will exist above the liquid surface inwhich the evaporating fuel vapour is well mixedwith air. If the paraffin is heated above about 40°C,this well-mixed region will become flammable that is, the vapour concentration in air is above itslower flammability limit. The lowest temperature at which this occurs is called the 'FLASHPOINT', the liquid temperature at which application of an ignition source will cause a flame toflash across the surface of the liquid. This is apremixed flame moving through the vapour/airmixture but, just above the flashpoint, it burns out,or self-extinguishes, because it has consumed allthe vapour. If heating is continued, a temperaturewill be reached at which ignition of the vapourswill lead to a "flash", followed by the developmentof a sustained diffusion flame at the surface flame.This temperature is known as the 'FIREPOINT', the lowest temperature at which therate of supply of fuel vapours (by evaporation)can sustain the flame.

7.63 FIashpoint, firepoint and sustained fires

There are several types of apparatus for determining the flash point of a liquid. The most commonis the Pensky-Martens "closed cup" test in whichthe vapours cannot diffuse away from the surface,but can achieve a uniform concentration in thehead space above the liquid surface. The Abelapparatus is also a closed cup test. The Cleveland"open cup" test gives a slightly higher flashpointthan the Pensky-Martens, but can be used to determine the firepoint. Clearly, it is always necessaryto quote the method and the type of apparatusused, and whether the result is an "open cup" or"closed cup" flashpoint. Note that the flashpoint isaffected slightly by pressure: values quoted inhandbooks, etc., are adjusted to normal atmospheric pressure. Corrections should be considered forhigh altitude applications.

The term "flash fire" is used to describe what happens if the temperature of the fuel is much greater

7.6.1 The Bunsen Burner

7.6 Practical examples of premixedflames and diffusion flames

Figure 7.4 (a) Premixedflame on a Bunsen burner

with full aeration;(b) diffusion flame.

The Bunsen burner (Figure 7.4) should be familiarfrom school laboratories. It can produces both typesof flame - premixed and diffusion. Gas is forced outof a jet at the base of the burner. If the air inlet collar at the bottom is open, air is entrained into thefuel flow and mixing occurs in the burner column.A pale blue conical flame is visible just above thetop of the burner. This is a laminar premixed flame.When the air inlet to a Bunsen burner is closed, ayellow diffusion flame results.

7.6.2 A candle flame

When a match is held close to the wick of an unlitcandle, the wax melts and rises up the wick by capillary action. There it evaporates, and a flame isestablished at the interface between the evaporating fuel and the surrounding air. The fuel and airare not mixed before burning, so this is a diffusion

YellowDiffusion

Flame

AIR

Blue- Premixed

Flame

RecombinationZone~

In a large fire (e.g., more than I m in diameter), theflames are turbulent diffusion flames, the turbulence generated by the strong buoyancy of theflames themselves. Inside the flame, there areregions of high temperature and low oxygen concentration where the fuel vapour is subjected to amixture of pyrolysis (chemical decomposition inthe absence of oxygen) and partial oxidation, leading to the formation of soot particles and productsof incomplete combustion, in particular carbonmonoxide (CO). These are the source of smoke,and of the gaseous species that render the fireproducts toxic.

In industrial burners, fuel is injected at high velocity into the air as a spray or jet. Turbulence isinduced at the interface where mixing takes place.This gives the flame an extremely large surfacearea in comparison to the relatively small surfacearea of the smooth fuel/air interface of the candleflame. In this turbulent case, it is the large interfacearea, rather than the rate of molecular diffusion,which determines the rate of mixing. This type offlame is a turbulent diffusion flame.



If they are strongly heated the nitrates of sodiumand potassium give off oxygen and the metal nitrite:

When the concentrated acid mixes with carbonaceous (carbon-containing) material there is a violent reaction giving off a great deal of heat andnitrogen dioxide (nitrous fumes). Clearly, carbonaceous materials like sawdust and wood chippingsmust never be used to soak up a spillage of thisacid. The nitrates (salts of nitric acid) are also goodoxidising agents. They are used in large quantitiesin industry and agriculture. An example is the useof molten nitrate salt baths for the heat treatmentof metals.

Concentrated nitric acid is a very powerful oxidising agent and reacts vigorously with many organiccompounds. Carbon itself reacts with the hot acid,in the following way:

relatively stable at room temperature but at hightemperatures they could be extremely hazardous.

Some of the more common oxidising agents areconsidered below.

7.8.1 Nitric acid and inorganic nitrates

Most other metal nitrates form the metal oxide,giving off nitrogen dioxide ('nitrous fumes') andoxygen.

Ammonium nitrate is widely used as an agticultural fertiliser under various trade names. It is a whitecrystalline solid, very soluble in water (all nitratesare soluble in water). It does not burn by itself, butmixing it with a fuel (e.g., sugar) produces a powerful explosive. It decomposes violently whenheated giving nitrous oxide and water:

Brown nitrous fumes (N02) are also given off onheating; decomposition is complex. These fumesof nitrogen dioxide will support combustion in asimilar manner to oxygen.

Smouldering will undergo a transition to flamingunder favourable conditions. The best documentedexamples involve cigarette ignition of upholstered furniture. The mechanism is not fully understood, and itis impossible to predict how long after the commencement of smouldering that the transition will occur.

7.7.3 Smouldering

neous combustion if slabs of foam are storedbefore the process is complete (see Chapter 10).

Nearly all combustion reactions involve oxidationwhich in its most simple form is combination withoxygen, such as the combustion of hydrogen:

Smouldering is the combustion of a solid in an oxidising gas such as air, without the appearance of aflame. The process is very slow, but smoulderingfires can go undiscovered for a very long time andcan produce a large amount of smoke. This isflammable. but it must accumulate and reach itslower flammablity limit before it can be ignited.This has been known to happen on a few, fortunately rare, occasions (e.g., the Chatham Dockyardmattress fire in November 1974).

7.8 Hazards of oxidi ing agents

Smouldering only occurs in porous materialswhich form a solid carbonaceous char when heated. Paper, sawdust, fibreboard and latex rubber canall undergo smouldering.

The oxygen in this case may be called an oxidisingagent. The word oxidation also has a broadermeaning where elements other than oxygen maybe considered as oxidising agents. For example,most metals will react with chlorine, and otherhalogens: this is also a type of oxidation.

Here chlorine is the oxidising agent.

There are certain compounds which do not necessarily burn themselves but, on decomposition,release oxygen which can greatly assist a combustion reaction. Some of these compounds may be

Spontaneous combustion should be considered asa possible cause of a fire for which there is noobvious ignition source, but it is necessary to showthat the material involved has the propensity to selfheat, and that a sufficient quantity has been storedin such a way as to provide the necessary thermalinsulation for the inside of the pile. A useful ruleof-thumb is that if the material does not produce arigid char when it is heated, it is very unlikely toself-heat to ignition.

Imagine a pile of cloths soaked in linseed oil,which have been discarded after, for example aroom has been decorated with paint or varnishcontaining a large proportion of linseed oil.

prone to this reaction, but any organic materialstored in bulk quantities may be suspect, especially if it has been stored at an elevated temperature.

As the cloth is porous. oxygen in the air will beable to reach the centre of the pile. The linseed oilwill oxidise slowly, even at room temperature,releasing heat. Because the centre of the pile iswell insulated by the surrounding cloths, heat willbuild up and the temperature will rise. As the temperature rises, the reaction rate increases - roughly for every lODC rise in temperature, the reactionrate doubles - so even more heat is given out andthe temperature rises more quickly.

If heat is being produced more rapidly than it canescape, the temperature will continue to rise to astage at which active combustion begins, usuallywell within the mass of material. Combustion willbegin as a smouldering process, burning throughto the surface of the pile where flaming combustion will be initiated.

Sometimes the action of bacteria on certain organic materials can cause a rise in temperature eventually leading to active combustion (haystackswere prone to this). Powdered material, such aspowdered coal used in power stations and somemetals, can give rise to spontaneous combustion.Stocks of coal at power stations, if incorrectlystored in very large piles, can self-heat to ignition.In the manufacture of some plastics (e.g.,polyurethane foams), the cross-linking processwhich creates the final molecular structure of thematerial is exothermic, and can lead to sponta-

Fire Service Manual

After ignition, obstacles such as process vesselsand pipework will introduce turbulence in thevapour/air mixture ahead of the flame, and causewrinkling of the flame. This will increase theeffective surface area of the flame, increasing therate of burning, and the flame speed. This can generate overpressures which under severe conditionscan cause blast damage. It is believed that thismechanism was responsible for the extensive damage caused at Flixborough in June 1974.

In this short section we will look at less obviousways in which ignition can occur.

This is the lowest temperature at which the substance will ignite spontaneously, that is the substance will burn without the application of a flameor other ignition source. This is sometimes referredto as the auto-ignition temperature.*

7.7 Ignition

For ignition to occur, sufficient heat energy is supplied to gaseous fuel and oxidant, either mixed towithin flammability limits or at the interfacebetween the fuel and the oxidant, to start a selfsustaining chemical reaction. This energy is generally supplied by a flame or a spark or a hot surface.

gate through that region of the cloud which liesbetween the flammability limits.

For some materials, the ignition temperature maybe so low that there is a danger of them ignitingunder normal conditions, or in the range of temperatures that the material would experience during day-to-day use. Such materials are normallywell documented and information availableregarding their safe handling.

7.7.1 Spontaneous ignition temperature

* The auto-ignition temperature is not a true property of amaterial. It depends on how it is measured.

Certain materials may react with oxygen at roomtemperature. Compounds such as linseed oil whichcontain carbon-carbon double bands are very

7.7.2 Self heating and spontaneous combustion

54

7.8.3 Chlorates

7.8.4 Chromates and dichromates


These compounds have a structure similar to that ofhydrogen peroxide (R20 2, arranged as H-O-O-H),with both hydrogen atoms replaced by organicgroups, thus forming an organic peroxide. If only onehydrogen is replaced, a hydroperoxide is formed.

7.8.7 Organic peroxides and hydroperoxides

As would be expected peroxides and hydroperoxidesare powerful oxidising agents and, because there is acarbon-containing part of the molecule which can beoxidised, they are highly flammable. Some are explosive and sensitive to heat and mechanical shock.Because of this they are often diluted or 'dampeddown' with either water or stable esters.

Peroxides are extensively used as catalysts, especially in the plastics industry. They are toxic andare especially irritating to the skin, eyes andmucous membranes. Skin contact and breathing ofvapours should be avoided. In all respects, organicperoxides and hydroperoxides should be treatedwith extreme caution.A great deal of heat is released in this reaction and

this could cause a fire in any nearby combustiblematerial. The fire would be made worse by theoxygen evolved.

Sodium peroxide can absorb carbon dioxide,releasing oxygen as a product:

When nitric acid reacts with organic compounds,two important types of substance are formed: organic nitrates (-N03) and nitro-compounds (-N02).

7.8.6 Organic oxidising agents

Common metal peroxides, derived from hydrogenperoxide, are those of sodium (Na20 2) and barium(Ba02). Sodium peroxide is a pale yellow solidwhich reacts vigorously with water, releasingoxygen:

This decomposition may occur on heating, but canalso occur in by the presence of a catalyst: smalltraces of metallic dust, charcoal or even stronglight may be sufficient. Concentrated solutions ofhydrogen peroxide are often known as 'high testperoxide' (RTP).

gravity of 1.46 (at ODC). It is soluble in water andis used at various concentrations. Above 70 percent concentration in water it is a powerful oxidising agent and decomposes explosively:

These compounds are oxidising agents and furthermore they carry oxidisable carbon-containingmaterial within their own molecules.Consequently, both the organic nitrates and thenitro-compounds are highly flammable. Some thatcontain several nitrate or nitro groups in the molecule are explosive. Typical examples are glyceryltrinitrate (used in dynamite) and trinitrotoluene(TNT) - an important military explosive.

Most organic nitrates and nitro- compounds aretoxic and many of them, including glyceryl trinitrate, may be absorbed through the skin.

Fire Service Manual

2KCI03 - 2KCI + 302

Chlorates are often used as their sodium or potassium compounds. On heating, oxygen is released:

Potassium perchlorate (KCI04 ) has a similarchemical formula, but is, in fact, stable. Anhydrousperchloric acid (HCI04) is a powerful oxidisingagent and will explode on heating. Sodium chlorate is used as a weed killer and has also been usedin home-made explosives.

Very violent reactions occur on contact with oxidisable materials and may occur merely by friction.

Of the permanganates, sodium (NaMn04) andpotassium (KMn04) permanganates are the mostcommon. They are powerful oxidising agents andmay react violently with oxidisable organic materials. When mixed with glycerol (glycerine), spontaneous ignition occurs. With concentratedhydrochloric acid, permanganates produce thehighly toxic chlorine gas as a result of oxidation.

7.8.2 Permanganates

Ammonium nitrate can detonate, but only largequantities, and under extreme conditions.

The most common compounds of this type arepotassium chromate (K2Cr04 ) and potassiumdichromate (K2Cr20 7); these materials are yellowand orange respectively and are oxidising agents.They are soluble in water and will produce a highly combustible mixture with oxidisable substances.

7.8.5 Inorganic peroxides

Peroxides are a group of compounds which contain a higher proportion of oxygen than the 'normal' oxide. This extra oxygen is easily liberated,making these compounds good oxidising agents.Inorganic peroxides may be considered to derivefrom hydrogen peroxide (H20 2). Pure hydrogenperoxide is a clear viscous liquid with a specific

56

Pfo

ys·cs a d Chem·stryFirefighters

p r

Chapter 8 - Simple organic substances

Carbon forms a very large number of compounds,especially with hydrogen, oxygen, nitrogen andthe halogens. It forms so many compounds thatchemistry is divided into two branches:

• organic chemistry which deals with thechemistry of the carbon compounds; and

• inorganic chemistry which deals with thechemistry of all the other elements.

There are believed to be over a million stable carbon compounds, which explains why a separatebranch of chemistry is necessary to study them.

simplest member of paraffins, or alkanes, ismethane, the main constituent of natural gas. It hasthe formula CH4 and the structure of the moleculeis conveniently represented as:

H

IH-C-H

IH

Methane, CH,

The carbon atom uses each of its four valencies tojoin it to four hydrogen atoms which each have avalency of one. The CH4 molecule can also beregarded as a combination of the group:

Carbon atoms differ from almost every other typeof atom in that they are able to link up with othercarbon atoms and form chains and rings. Mostother atoms only join with others of the same kindin twos or threes. In all these organic compoundsthe valency of carbon is always four.

Organic chemicals are divided into two classes:

• aliphatic compounds, which contain chains ofcarbon atoms; and

H

IH-C--

IH

called a methyl group

• aromatic compounds which contain a specialkind of ring of six carbon atoms, known as abenzene ring.

Most organic chemicals are capable of burning.Our most important fuels, such as natural gas,petrol, paraffin and diesel oil are mixtures oforganic compounds which contain carbon andhydrogen - the hydrocarbons.

8.1 Aliphatic hydrocarbons(paraffin or aJkanes)

The aliphatic hydrocarbons are a series of compounds containing only carbon and hydrogen. The

with a hydrogen atom. Methane has well-definedchemical and physical properties. It is a relativelyunreactive gas, although it is flammable and formsexplosive mixtures with air at concentrationsbetween 5% and 15% by volume. In common withother hydrocarbons, it burns completely to produce carbon dioxide and water:

Larger molecules are built up by linking the carbon atoms together in chains. Hydrogen atoms areattached to the carbon atoms in accordance withthe valency rules. For example:

Physics and Chemist!)' for Firefighters 59

• they have similar chemical properties; and

• they form a series in which each differs fromthe next by one -CH2 unit;

200

200148

165

303

308

22

28

H-C=C-HAcetylene

Here, each carbon atom uses three of the availablevalencies to make three bonds with the other. Thistriple bond makes acetylene very reactive: it canexplode on exposure to heat or mechanical shock,even when air or oxygen are absent. Acetylene is

way of arranging the normal valency bonds of thecarbon and hydrogen is:

8.33

8.81

Table 8.1 The Paraffins or Alkanes

Name Formula Structure Vapour Melting Boiling Flash Flammable Self-ignitiondensity point point point limits temperature(A = 1) (QC) (QC) (QC) (% in air) (QC)

~ Methane CH4H 0.554 -183 -161 Gas 5 to 15 538

III I'"Dl

H-C-HI

IH

Ethane C2H6H H 1.04 -172 -89 Gas 3.3 to 12,5 510I I

H-C-C-HI IH H

Propane C3H8H H H 1.52 -187 -42 -104 2.4 to 9.5 510I I I

H-C-C-C-HI I IH H H

Isomers H H H HI I I I

n-Butane C4H lOH-C-C-C-C-H 2.046 -138.6 ~.6 -60 1.5 to 9.0 466

I I I IH H H H

iso-Butane C4H lOH H H 2,046 -160 -12 Gas 1.8 to 8.4 545I I I

H-C-C- C-HI I IH H-C-H H

IH

~ n-Pentane CSH 12H H H H H 2.48 -130 36 <-40 1.4 to 7.8 309

J:I I I I I IC H-C-C-C-C-C-H

~ I I I I IH H H H H

n-Hexane C6H l4H H H H H H 2.97 -95.6 69 -23 1.2 to 7.4 260I I I I I I

~ ~H-C-C-C-C-C-C-H

~ ~ ~ ~ ~I I I I I IH H H H H H

n-Hexadecane C16H34 7,8 18 287 >100 - 205

~ n-Heptadecane C J7H36

is:'" n-Octadecane C I8H38

8.2.2 Acetylenes, or alkynes

Other olefins can be obtained by progressivelyincreasing the length of the carbon chain. As withthe paraffins, the physical properties alter in a regular way as the size of the molecule increases (seeTable 8.2).

Acetylenes contain a carbon-carbon triple bond.The only important member is the gas acetylene(C2H2). It is an unsaturated compound and the only

H H

I I+ CI 2 ---. H-C-C-H

I ICl Cl

(Ethylene dichlorideor dichloroethane)

H H

~ /c==c

/ "'"H H(Ethylene)

Unsaturated compounds are much more reactivethan the paraffins. Not only do they burn, but theyreact readily with chlorine, hydrogen chloride,bromine, and other reagents. For example:

The reactivity of ethylene makes it an importantstarting material in the production of plastics andother synthetic materials (see Chapter 9).

where there is a double bond between the two carbon atoms. The carbon still has its valency of 4 andhydrogen that of 1, but each carbon atom uses twoof its valency bonds to link to the other carbonatom. Compounds containing double bonds (andthose with triple bonds) are known as unsaturated compounds.

H H

~ /c==c

/ ~H H

8.2.1 Olefines or alkenes

8.2 Unsaturated aliphaticydrocarbons

There is another series of aliphatic compoundsknown as the olefins or alkenes. The first memberof the series is ethylene (C2H4), the formula forwhich is represented as:

As the number of carbon atoms increases:

• melting point, vapour density, boiling pointand flash point increase; and

• solubility in water and spontaneous ignitiontemperature decrease.

• their physical properties vary in a regularway.

Ethane, C,H.

H H

I IH-C-C-H

I IH H

Propane, C,H,

H H Hwith an I I I

additional H- C- C-- C- HC atom Ibecomes I I

H H H

with anadditional C

atom becomes

Ethane, C,H.

H H

I IH-C-C-H

I IH H

Another increment in the chain length of the molecule results in propane (C3Hg), a constituent ofliquefied petroleum gas.

In principle, the carbon chain can be extendedindefinitely, until the chain consists of many thousands of carbon atoms, as in polyethylene (seeChapter 9). The longer the chain, the higher theboiling and melting points of the substance.Methane, ethane, propane and butane are all gasesat room temperature and pressure, but heavier molecules, starting at pentane, CSH12 , are liquids, andfrom hexadecane, C l6H34 they are solids.Compounds near C8H l8 (octane) are found inpetrol, those near C IOH22 , in paraffin, those nearC I4H30 in diesel oil, those near C 1gH38 in petroleumjelly (Vaseline) and those near C2sHs2 in paraffinwax. The following points may be noted concerning these compounds:

Propane is chemically similar to ethane andmethane, but once again, the physical propertiesdiffer (see Table 8.1).

Ethane (C2H6) is another constituent of natural gas.Because the molecule is larger, the physical properties are different from methane. The boilingpoint, melting point and vapour density of ethaneare higher than those of methane, whereas its spontaneous ignition temperature is lower.

Methane, CH,

H

IH-C-H

IH


Table 8.2 The Olejines or Alkenes

Name Formula Structure Vapour Melting Boiling Flash Flammable Self-ignitiondensity point point point limits temperature(A = 1) (0C) (0C) (0C) (% in air) (0C)

Ethylene C2H4H H 0.98 -169 -103.9 Gas 2.7 to 28.6 450~ /

c=c/ ~

H 11

Propylene C3H(j H H H 1.5 -185 -48 Gas 2 to 1I 495I I /

H-C-C=CI '\.H H

H H H H

I I I IH-C-C::C-C-H

I IH H

or

H H H about about

The Butylenes C4HsI I I /H

1.93 -185 -6.3 <-80 1.7 to 10.0 384H-C-C-C=C

I I "HH H

Of

H H

I IH-C-C=C

I I IGases H H-C-H H

IH

* The olefines are liquids from C,H IO to C 16H32 , and then solids.

Table 8.3 The Acetylenes or AlkYlles

Benzene

However, the six carbon atoms are linked in a special way, and benzene does not behave like anolefin. In fact, the benzene ring is remarkably stable, so that aromatic compounds - those containing the benzene ring, such as toluene - are lessreactive than olefins.

Benzene is a flammable liquid, but when it burns.the aromatic ring proves difficult to oxidisebecause of its stability: the high proportion of carbon in the molecule leads to the formation of athick black smoke. It is no coincidence that theprecursors of smoke in flames from any fuel havebeen found to have an aromatic structure. Theseare formed in the flame in regions where temperatures are high, but the oxygen concentration is low.If the fuel already contains an aromatic structure, itcan be said quite categorically that it will burnwith a very smoky flame.

Again, the physical properties of the members of thisseries vary in a regular way as the molecular weightincreases, and the chemical properties remain similar. Some aromatic compounds, especially tolueneand the xylenes are important solvents.

It is worth noting that hydrocarbons do not dissolve to any extent in water, but will float as theirspecific gravity is less than 1. Some aromatic compounds are toxic; benzene for example is highlytoxic, both as a vapour and by skin absorption ofthe liquid. Many, more complex, aromatic compounds have been identified as carcinogens.Similar compounds are to be found in smoke.

8.4 Liquefied petroleum gases(LPG)

Propane (C3Hg) and butane (C4H IO) are gases atroom temperature and pressure, but are easily liquefied using pressure alone. A very small amountof liquid will produce a great volume of gas and soby liquefying the gas a large amount can be storedin a small volume. As both gases are highly flammable and are widely used as fuel gases, installations containing the liquid gases are very widespread.


The important property for LPG is the critical temperature - the temperature above which it isimpossible to liquefy a gas by pressure alone (seeSection 4.4). For propane, the critical temperatureis 96.7°C and for butane, 152°C. When in the rightkind of container they will evaporate, increasingthe pressure until there is no further net evaporation. Thus, inside each liquid gas container there isa liquid with pressurised vapour above it. As thegas is let out for use as fuel, more liquid evaporatesto keep the pressure of the vapour at its originalvalue.

As discussed, both propane and butane are highlyflammable. If propane liquid escapes, it will quickly boil into a large amount of flammable vapour: 1litre of liquid will produce 270 litres of vapour.

The vapours of both propane and butane are heavier than air and will seek lower ground; they areodourless and colourless, though very frequently, astenching agent (mercaptan) is added.meta-xylene para-xylene

(m-xylene) (p-xylene)

CH,

OCHJ

I or#

ortho-xylene(o6xylcne)

Similarly:

(Toluene, C,Ha)

or

IH H--C--H

I IH ~c~ /H H, /c, /H~c C wllh one H atom ' C C /

I I1replaced by a I1 Imethyl radical,

C C becomes C CH/ ~C/ "'-H H/ """C:7' ""'H

I IH H

CH)

6 with a further H atom~ replaced by a methyl

I radical, becomes

Other aromatic compounds are formed by replacingthe hydrogen atoms of benzene by other atoms orgroups of atoms, such as methyIradicals. For example:

The simplest member of the aromatic hydrocarbons is benzene, C(jH(j' It has a unique structure,consisting of six carbon atoms arranged in a ring,apparently with alternating single and doublebonds:

8.3 Aromatic hydrocarbon

Vapour Melting Boiling Flash Flammable Self-ignitiondensity point point point limits temperature(A = I) (OC) (0C) (OC) (% in air) (0C)

0.91 -81 -841- ~[7.7 2.5 to 80 335

1.38 -102.7 -23 Gas 1.710 11.7 -HI

H-C .. C-C-HIH

H-CEC-H

Structure

Fire Service Manual

Acetylene C2H2

Name Formula

Melhylacetylene C3H4

*Gases

* The acetylenes are liquids from C4H 6 to C I7H32, and then solids.t Sublimes

flammable and forms mixtures in air with wideflammability limits (2.5% - 80%). Some of itsphysical properties are given in Table 8.3.Acetylene is used in the manufacture of plastics(e.g., PVC), certain chemicals and in oxyacetylenewelding. It is stored by dissolving it in acetone,which is absorbed on an inert porous material contained in cylinders.

62

The higher aldehydes (i.e. containing more thantwo carbon atoms) are rather less important.The physical properties of these materials varyin the usual way as the molecular weightincreases.

The simplest ketone is acetone [(CH3hCO] whichhas the structure:

H H

I IH-C-C-C-H

I 11 IH 0 H


8.5.3 Ketones

Acetone is by far the most commercially importantmember of the series. It is a colourless, highlyflammable liquid which is readily soluble in waterand has a minty smell. It is toxic to the extent thathigh concentrations have an anaesthetic effect andthe liquid dissolves the fats out of the skin, and socan give rise to dermatitis and skin irritations.Acetone is a very important industrial solvent formaterials such as paint removers, cellulose acetate,fats, waxes and acetylene (see Section 8.2).

The next member of the series is methyl ethylketone (MEK):

It is another important industrial solvent and closely resembles acetone, but with a higher flashpoint,etc.

8.5.4 Carboxylic acids

The carboxylic acids or 'fatty acids' are a group ofweak acids, related to the aliphatic hydrocarbonswith a similar chain structure. They all contain thegroup:

These compounds all contain the group:

H

/--C,

o

H H

I IH-C-C=O

IH

8.5.2 Aldehydes

attached to such organic groups as methyl (CHr ),ethyl (C2Hd and so on. The simplest member ofthe group is formaldehyde:

with the formula CH20. Formaldehyde is a colourless, flammable gas with a pungent suffocatingsmell, though it is more usual to find it as a 4%solution in water, which also contains a littlemethanol. This solution is called formalin andgives off flammable vapour if heated above itsflash point. This varies according to the formaldehyde and methanol concentration. The vapour istoxic. Formaldehyde is used in the manufacture ofseveral plastics, as an antiseptic and as a preservative of anatomical specimens.

The next member of the series, acetaldehyde(CH3CHO) has the structure:

and differs from formaldehyde by one CH2group. It is a colourless liquid with a strongfruity smell. The compound dissolves readily inwater, is flammable and toxic and the vapourforms explosive mixtures with air. It is used asan intermediate in the manufacture of otherchemicals and plastics.

H

IH-C-O-H

IH

Methyl alcoholCH, OH (Methanol)

with oneH atom

replaced byan O-H,

groupbecomes

Methane, CH,

H

IH-C-H

IH

As the molecular weight increases, there is a general increase in the:

• solubility in water; and

• n-butyl alcohol or n-butanol (C4HgOH).

The first few members of the series dissolve completely in water but members higher than butylalcohol are only slightly soluble. All alcohols areless dense than water: the insoluble ones float.

• melting point;

• n-propyl alcohol or n-propanol (C3H70H);and

This is accompanied by a decrease in the:

• ethyl alcohol or ethanol (C2HsOH);

• flash point.

• spontaneous ignition temperature.

The whole series of alcohols is formed by adding-CH2 groups to methanol:

• boiling point; and

Chemically the alcohols resemble each other. Thefirst members of the series are highly flammableliquids. Ethyl alcohol is sometimes used as a fueland is also used in rocket propulsion systems.Alcohols are also intermediaries in various chemical processes. Methanol and ethanol are widelyused as solvents in industry and ethanol is the mostimportant ingredient of beer, wines and spirits.Propanol and butanol are also used as solvents andsome of the higher alcohols are used to makedetergents. Nearly all alcohols are to a greater orlesser extent toxic according to type.

Fire Service Manual

When propane and butane evaporate they takeheat from their surroundings. Propane has a boiling point of -42°C at atmospheric pressure, so atnormal ambient temperatures and pressures, theliquid boils easily. This applies to vast majority ofpractical situations. However, butane has a boiling point of around -1°C, so that in winter conditions, the vapour pressure may be too low to provide a flow of fuel vapour. For this reason, "LPG"generally consists of a mixture of propane andbutane.

8.5 imple oxygen-containingcompound derived fromhydrocarbons

Full details of the storage and fire-fighting techniques associated with liquefied petroleum gaseswill be found in the Manual of Firemanship,Part 6c.

In dealing with LPG it isvital to realise that abovethe critical temperature thesubstances can only exist asgascs. Cylinders heated abovethis tempenlture arc, therefore,likely to explode.

There are many different types of organic compound which contain oxygen in addition to carbonand hydrogen. Some are reactive, and may beencountered in industrial processes (e.g., aldehydes) whereas others are relatively unreactive andare used as solvents (e.g., ketones). The moreimportant types are discussed briefly.

The structure of the commonest alcohols is similarto that of paraffins, but with one of the hydrogenatoms replaced by a hydroxyl group O-H:

8.5.1 Alcohols

64

H 0 H H

I 11 I IH-C-C-O-C-C-H

I I IH H H

Ethyl acetate,CH,COOC,H,

Acetic acid,CH,COOH

H

I /0

with the OHreplaced by the

H- C-C ethyl radical

I\ C,H" becomes

O-HH

Table 8.5 Esters

Name Formula Structure Vapour Melting Boiling Flash Flammable Self.ignitiondensity point point point limits temperature(A = 1) (OC) Cc) (0C) (% in air) (0C)

Ethyl formate HCOOC2Hs 0 H H 2.55 -79 -54 -20 28 to 16.5 45511 I I

H-C-O-C-C-HI IH H

Ethyl acetate CH2COOC2Hs H 0 H H 3.04 -84 77 -4 2 to 11.5 >427I 11 I IH-C-C-O-C-C-

I I IH H H

Ethyl butyrate C1H7COOC2Hs H H H 0 4 -93 121 25 463I I I 11H-C-C-C-C-O-

I I IH H H

Amyl acetate CH3COOCsHII H 0 H H H H H 4.5 -78.5 148 25 1.1 to 7.5 3991 I1 I I I I I

H-C-C-O-C-C-C-C-C-HI I I / I IH H H H H H

4522to 10

2.9 to !4.8 57754

163.5 72

141-22

-7.9

The esters can be thought of as being derived fromthe carboxylic acids by the replacement of the hydrogen atom in the COOH group by a methyl or otherradical. For example, "ethyl acetate" (see opposite).

Esters are flammable, colourless liquids or solidsand are usually only slightly soluble in water, onwhich they float. They have fruity smells and areoften found in fruit and in scents. The higher solidmembers of the series are found in beeswax. Theesters are used as solvents, and in pharmaceuticals,perfumery and foodstuffs. Some properties of afew esters are gi ven in Table 8.5.

8.5.5 Esters

8.5.6 Ethers

The properties of some of these acids are given inTable 8.4.

These all contain an oxygen atom -0- which joinstwo organic groups such as methyl or ethyl groups.The only one of commercial significance is diethylether (C2Hs-0-C2H3). This substance is oftenreferred to merely as 'ether'. It is a colourless, highly flammable, volatile liquid with a characteristicsmell. It is less dense than water and immiscible init. It is toxic in high concentrations and at lowerconcentrations has an anaesthetic effect.

Diethyl ether has a boiling point of 34,SOC, a flashpoint of -4.8°C, flammable limits of 1.85 to 36.5%

Vapour Melting Boiling Flash Flammable Self·ignition in air and a self-ignition temperature of l80°C. Itdensi!)' point point point limits temperature may contain a substance known as ether peroxide(A = I) (OC) (0C) (QC) (%inair) (0C)

which, if the ether is evaporated to dryness, can1.59 8 101 69 18 to 51 600 cause an explosion.

2.07 16.6 118 45 5.4 to 16 566

2.56

3.04

/0H-C

\O-H

o/

--C

~O-H

which may be found attached to various organicgroups such as methyl (-CH3) and ethyl (-C2H6).

The first member of the carboxylic acid series isformic acid, HCOOH:

Formic acid is a colourless liquid with a pungentsmell. It is toxic and can cause burns on the skin.It is used in the textile industry, in electroplatingand in the leather and rubber industries.

Table 8.4 Carboxylic acids

Name Formula Structure

Formic acid HCOOH 0

/H-C

\O-H

Acetic acid CH3COOH H

I 0I

H-C-C

I \0-"

"Propionic acid C2HsCOOH " "I I !

0

H-C-C-C

I I \O-H

" "n-butyric acid C3H-;COOH ~ "

111/"i-C-C-C-C

I I I \O-H

H H "

The next member of the series is acetic acid(CH 3COOH), which is present as a dilute solutionin vinegar. It is flammable, dissolves readily inwater and can burn the skin if concentrated. Thevapour and the concentrated acid are toxic. It isused as a solvent in chemical manufacture.


P ys·cs aor Firefig

d Chem"stryters

h p

Chapter 9 - Polymers

Many organic solids, including wood, plastics andrubbers, are polymers. This means that the molecules of which they are composed consist of verylong chains of carbon atoms which can consist ofmany thousands of atoms.

stands for the benzene ring, which is the simplestaromatic structure (Section 8.3).

Here the symbol:

or polystyrene:

Polymers such as polyethylene, polypropylene andpolystyrene soften and eventually melt at temperatures in excess of lOO-150°C. Such materials arecalled thermoplastics.

o

Polynler9.1

For many years now, chemists have been able tocreate or synthesise polymer molecules in the laboratory. Many of these have passed into commercial use as plastics and synthetic rubbers. Polymersare formed by taking small molecules with two ormore reactive groups and arranging for these tolink up end to end and form long chains. For example in ethylene H1C=CH1, the double bond can be"opened" or broken to give:

Polymer molecule

Carbon ~ Carbon~ Cross links

r~~ 11

. ~ ==rI

Thermosetting plastics do not melt but breakdown and char on heating. In these plastics, thelong chains are also linked together sideways bycarbon-carbon bonds: the material is said to becross-linked. Figure 9.1 illustrates this point, thelines representing polymer molecules and theircross-links.

Fig. 9.1 The cross-links ofpolymer molecules of thermosetting plastics.

-CH1-CH1-CH1-CH1-CH1-CH1-

which will very rapidly combine with other molecules of the same type to produce polyethylene:

Simple straight-chain polymers of this type arewell known; many of them have small side groupsattached to the chain, as in polypropylene:

which consists of a long chain of -CH1- groupsjoined to each other. In a case such as this we callethylene the monomer, polyethylene the resultingpolymer and the process polymerisation.


__________J+z:-. .

• Colouring materials.

9.2 Fire hazards

9.2.4 Exotherms

The polymerisation process may well produceheat. This is a problem for those manufacturersproducing the raw plastics (normally in pelletform for thermoplastics), but there is a highdegree of control of the processes involved, andit rarely causes a problem. However, the crosslinking or curing process involved in the manufacture of thermosetting materials may also beexothermic; for example, if blocks ofpolyurethane foam are stored before the exothermic curing process is complete, self-heating mayoccur, leading to spontaneous combustion(Section 7.7.2).

Various types of catalyst are used in polymerisationprocesses including acids, alkalis, complex organometallic compounds and organic peroxides.

Thermoplastics melt on heating and so in a fire mayform burning droplets which could help the fire tospread. Although polyurethane foams are not technically thermoplastics, they do give burning dropsof tar in a fire. On the other hand PVC, which is athermoplastic, does not give burning droplets, butmerely forms a tarry coke-like product.

9.2.3 Burning tars or droplets


9.2.5 Catalysts

9.2.6 Flammable solvents

Acids and alkalis present well known hazards. Anorgano-metallic catalyst may be in the form of aslurry in t1ammable solvents: some of these compounds, such as aluminium triethyl, react violentlywith water. Organic peroxides are oxidising agentsand, therefore, present a considerable fire risk.Under some conditions such materials can beexplosive.

Flammable liquids, such as acetone, methyl ethylketone, toluene, industrial alcohol and methylalcohol are widely used as solvents in variousprocesses and also as cleaning fluids, so may bepresent in fires on industrial premises. See alsoChapter 8.

produced, depending on the type of polyurethanefoam and the conditions of burning.

Chlorine is present in polyvinyl chloride (PVC)and certain related co-polymers, in neoprene and incertain types of self-extinguishing fibre-glass polyester resin. In PVC fires, almost all the chlorinegoes to form hydrogen chloride (HCI) gas in thefire gases. HCl is both toxic and corrosive, havinga very sharp smell and forming a corrosive solutionwith water (hydrochloric acid). Apart from corroding many metals, the acid may cause long telTnchanges in alkaline mortar. Ferroconcrete may bemuch less affected; nevertheless, copious washingafter incidents involving PVC is desirable. Otherchlorine containing polymers may also givehydrochloric acid gas and possibly other chlorinecontaining toxic compounds as well.

PTFE (poly-tetrafluoroethylene - 'Teflon') andsome related materials, such as 'Kel-F' and somesynthetic rubbers, sometimes known as 'vitons',contain fluorine.

9.2.2 Smoke

Fires involving materials which contain the aromatic (benzene) ring structure (Section 8.3) wil1tend to produce large quantities of smoke. Theseinclude polyurethanes, phenol-formaldehyderesins, polystyrene (Section 9.J), polyesters, epoxyresins and polycarbonates.

If these materials are overheated, toxic fluorinated gases are produced. If these are inhaledthrough a lighted cigarette they become moredangerous. Toxic products from decomposingfluorinated materials should not be inhaled.

Although PVC does not contain the aromaticstructure, it produces large amounts of smoke infires, because it decomposes in the solid phase toproduce aromatic structures.

If materials of this type ignite readily and burnrapidly in a fire (e.g., the early polyurethanefoams), very large quantities of thick blacksmoke will be evolved in a very short period oftime, and can lead to rapid smoke-logging ofescape routes, etc.

Many plastics contain nitrogen in addition to carbon, hydrogen and oxygen. Plastics in this category include cellulose nitrate, nylon, polyurethanefoams, melamine-formaldehyde plastics, ureaformaldehyde plastics, ABS (acrylonitrile-butadiene-styrene), some epoxy resins and nitrile rubbers. (Note that certain "natural polymers" such aswool and silk also contain nitrogen.) The fire products from these will contain nitrogen-containingspecies such as organic nitriles, hydrogen cyanideand N02 • All of these are toxic. Intense, well ventilated burning will convert most of the originalnitrogen into N02.

Many other toxic products are produced from plastics containing only carbon, hydrogen and oxygen.A whole range of toxic and COITosive species areproduced under conditions of poor ventilation.Their nature depends on the structure of the polymer, and can include aldehydes and many otherpartially oxidised products.

The class of material known as polyurethanefoams (PUF) includes the "standard PUF" introduced in the 1970's as well as the newer "combustion modified foams" which began to appear in the1980's. The standard foams have been extensivelyinvestigated and are known to produce appreciableamounts of CO and HCN in the fire gases. Other,highly toxic nitrogen-containing products may be

If plastics only contain the elements carbon andhydrogen, or carbon, hydrogen and oxygen, themain toxic gas to be expected is carbon monoxide(CO) which is formed when all organic materialsare burned in quantity. The amount of CO produced increases if there is a relative shortage ofoxygen. This gas is a well-known hazard to firefighters. As it is odourless, colourless and produced in large quantities in fires in buildings, it isresponsible for most of the fire fatalities. It canalso cause the deaths of people who are confinedto unventilated rooms with faulty gas heaters.

9.2.1 Toxic and corrosive gases

However, many synthetic polymers produce muchmore smoke than "traditional" materials such aswood, and the rate of fire growth may be muchgreater, particularly if the material melts and drips,spreading fire as a burning liquid.

Fire Service Manual

• give off large quantities of

smoke. often in a ,;ery short

space of time.

70

• Fire retardants, to make the polymer moredifficult to ignite;

• Stabilisers to inhibit degradation due toatmospheric oxidation, attack by sunlight ordecomposition under conditions of mildheating; and

• Plasticisers, mixed with some thermoplasticsto make them more pliable (e.g., PVC insula

tion);

Like any combustible materialin a fire situation, plastics andrubbers may:

• give off toxic and cOITosivegas~s; and

• Inert fillers such as china clay, wood flourand carbon black, or, in laminated plastics,sheets of paper or glass-cloth;

Plastics often have other materials mixed intothem to improve their properties or to make them

cheaper:

Industry uses the fact that thermoplastics soften ormelt when they are processed. The same techniques can not be used in thermosetting plastics.These have to be processed as short chain molecules and then heated or a catalyst added to makethe molecules cross-link.

9.2.7 Dusts

Some processes produce fine plastic dusts. Thesemay present an explosion hazard if dispersed asa suspension in air.

9.2.8 Self-extinguishing plastics

Many plastics are described as "self-extinguishing". While PVC and phenol-formaldehyde resinsare naturally so, others may be made self-extinguishing by chemical changes in the polymer molecule or by the use of special additives.

The term 'self-extinguishing' means that, while aflame may (or may not) cause the material to burn,it will not continue to burn if the applied flame isremoved. However, the term refers to the performance of plastics in a specific small scale test. In afire situation, it will burn if surrounded by otherburning materials, or perhaps on its own if a largeenough area of the plastic has been ignited to produce flames which are self-sustaining.

~self-cxtinguishing'does notmean 'non-flammable" or'non-combustible' .

9.3 Monomer hazards

this problem, monomers are flammable, andsome are toxic. It is also possible that somemonomers in bulk quantities could start to polymerise in a fire with the ensuing added hazard ofthe heat given out by the polymerisation reaction.

Some of the more notable monomers used in theplastics industry are detailed below, but the number of monomers is very large and ever increasing,so the list cannot be considered as exhaustive.

Acrylonitrile

• colourless, partially water-soluble, flammable liquid with faint, pungent smell;

• polymerises explosively with some organicperoxides or concentrated caustic alkalis;

• highly toxic: can be absorbed through theskin and also through leather; and

• used as a starting material in the manufactureof ASS (acry!onitrile-butadiene-styrene)plastics and certain synthetic rubbers.

Butadiene

• vapour at room temperature and pressures,but easily liquefiable at room temperature;

• polymerises readily, especially in the presence of peroxide catalysts or air;

• flammable; and

Methyl methacrylate

• clear liquid with acrid odour, used in themanufacture of acrylics (poly-(methylmethacrylate» ;

• flammable;

• toxic;

• polymerises exothermally with peroxide catalysts; and

• normally stabilised, but heat accelerates thepolymerisation.

Styrene

• used in the manufacture of polystyrene plastics and fibre-glass polyester resins;

• slightly yellow liquid, strong smell;

• normally stable, polymerisation greatlyaccelerated by heat or added peroxides;

• exothermic polymerisation: risk of fire andeven explosion; and

• moderately toxic, vapour is an irritant to theeyes.

Vinyl acetate

• colourless, slightly water-soluble, flammableliquid, faint odour;

• moderately toxic acts as an anaesthetic In

high concentrations;

• liquid may cause freeze burns due to rapidevaporation;

• flammable; and

• combustion gases contain hydrogen chloridewhich is both toxic and corrosive.

9.3.1 Intermediates and hardeners

Isocyanates

• used as intermediates in polyurethane foammanufacture;

• mostly brown liquids, slightly water-soluble,characteristic odour;

• skin irritants, may cause dermatitis, toxic byskin absorption;

• flammable - emit toxic gases when on fire;

• isocyanate vapours cause bronchial spasmrepeated exposure may bring sensitisation;

• great caution should be exercised in dealingwith them; and

• made harmless using special solutions ofammonia in water, to which an emulsifyingagent has been added.

As these monomers are mostly poor conductorsof heat, the heat cannot get away easily, temperatures may rise and a fire may result. In addition to

Monomers by definition are reactive compoundscapable of polymerisation. Some, like ethylene,do not polymerise very easily and need exactlythe right conditions of temperature and pressure,perhaps with a catalyst. Others, like styrene, maypolymerise by accident, due to the presence ofimpurities, water, heat or other causes, and whenthis happens a great deal of heat may be givenoul. Some monomers have to be transported witha polymerisation inhibitor added to prevent theprocess occurring spontaneously.


• slightly toxic, narcotic in high concentration.

Epichlorhydrin

• used in the manufacture of epoxy resins;

• colourless, slightly water-soluble liquid withan irritating odour;

• polymerises exothermally with acids, basesand some salts; and

• highly toxic material and in fires may produce toxic gases including phosgene.

• polymerises with organic peroxides or whenheated: and

• low toxicity, may act as an eye irritant.

Vinyl chloride

• sweet-smelling vapour at room temperatureand pressure. easily liquefied;

• severe explosion hazard when exposed toheat or flame;

In manufacture dangerous exothermic reaction causing fires can readily occur where toluene di-isocynate (TDI-) based foams are produced, but is muchless likely where the more extensively used diphenylmethane di-isocyanate (MDI) foams are made.

Chlorosilanes

• intermediates in silicone plastic manufacture;

• mostly fuming clear liquids;

• highly toxic;


Chapter 10 - Other Combustible Solids

• flammable; and

• react with water to produce hydrogen chloride gas - reaction is strongly exothermic inmany cases.

Epoxides

• Amine hardeners - generally toxic. Somemay cause dermatitis.

Physics an Chemistryfor Firefighters

10.1 Wood

Wood is a complex polymeric material of naturalorigin. In spite of the widespread use of syntheticmaterials, wood still accounts for a high proportion of the combustible material which is used inbuildings, not only as fittings and furniture, butalso as structural members. The principal constituent of wood is cellulose, a polymer of D-glucose, which occurs in all higher plants.

Many methods are available to reduce the combustibility of wood. The most successful involveimpregnating the wood with chemicals (e.g.,ammonium phosphates, etc.) which catalyse thechar-forming reaction at the expense of thedecomposition process which produces flammable vapours. The resulting vapours are of verylow flammability (mainly a mixture of CO, CO2

and H20) and will not support flame, or contribute significantly to a fire when other materials are burning.


There is a high water content in wood and the difference in moisture content between green andwell-dried wood is significant in regard to fire risk.Considerable quantities of heat are required to drytimber, due to the high latent heat of vaporisationof water.

When wood is heated, decomposition starts attemperatures of around 170D C, forming char,with the evolution of carbon dioxide, carbonmonoxide and water. The proportion of flammable vapours released at this stage is low. Above300D C, the decomposition process which produces flammable vapours becomes the dominantpyrolysis reaction, but they will be mixed withsome CO2 and H20 vapour from the char-formingprocess which still occurs, but no longer dominates. This mixture of gases and vapours is lessflammable than the decomposition productsfrom, for example, polyethylene which will be100% hydrocarbon, undiluted by non-flammablegases. This, and the fact that there is always a significant amount of char produced which providesprotection to the wood underneath, accounts forthe remarkable fire properties of wood. Forexample, (i) thick sections of wood cannot burnin isolation and (ii) thick timber beams can survive longer in a fire than unprotected steel beams,because the char forms a protective layer aroundthe sound timber below.

10.2 oal

Coal is a very complex mixture of carbon and avariety of resinous organic compounds. There aremany varieties, with harder coal containing morecarbon. Plates of inorganic, no~combustiblematerials are also found in coal: these consist of limestone and compounds of iron, magnesium andmanganese.

In large heaps, such as those used for storage ofcoal at power stations, self-heating can occur,which may lead to spontaneous combustion (seesection 7.7). The smaller the coal particles, thethe greater the danger. It is promoted by moisture, and the greater the oxygen content of thecoal, the greater the danger, so that coal, especially pulverised coal containing more than 10per cent of oxygen, may be dangerous in storage.In addition, coal dust can form an explosivemixture in air.

Storage heaps must be kept as free as possiblefrom excess of air and protected from externalsources of heat. Coal is sometimes sprayed witha high flash-point mineral oil that reduces dustiness and protects coal surfaces against oxidation.Fires in coal stacks are dealt with in the Manualof Firemanship, Part 6c.


] 0..3 lVletals

Three-quarters of all the elements are metals. To achemist a metal is a substance which can lose electrons and form positive ions (ions are chargedatoms or groups of atoms - see Chapter I). In addition, metals tend to have a group of propertiesassociated with them; if an element possesses mostof them, we describe it as a metal.

10.3.1 Properties of metals

Metals will show most of the properties listed here,although there are exceptions to most of these. Forexample, most metals are malleable and ductile can be hammered into shape and can be drawn outinto wire - but antimony is very brittle and willshatter if hammered!

(i) all, except mercury, are solids at room temperature, though they have a wide range ofmelting and boiling points;

(ii) they form positive ions;

(iii) they are malleable and ductile;

(iv) they are good conductors of heat and electricity;

(v) they can form alloys;

(vi) the oxides and hydroxides are basic (and socan be alkali solutions in water); and

(vii) most dissolve in mineral acids, normallyreleasing hydrogen.

Metals show a wide range of chemical properties,and range from dangerously reactive metals suchas sodium and potassium, to inert metals such asplatinum and gold. Metals can be arranged in an'Activity Selies' (Table 10.1).

In this Table, the most reactive metals are at the topand the least reactive at the bottom. Whateverchemical property is considered, those metals atthe top of the series react most vigorously, indeedoften violently, and those at the bottom react slowly or not at all.

Table 10.1 The activity series of metals

Metal Occurrence Reaction withwater

Potassium K Never found React with

Sodium Na uncombined cold water

* Barium Ba with other to yield

Strontium Sr elements hydrogen

Calcium Ca

Magnesium Mg Rarely found Hot metals

Aluminium Al uncombined decompose

* Chromium Cr with other water and

Manganese Mn elements Burning metals

Zinc Zn decompose

* Cadmium Cd steam

Iron Fe

Cobalt Co Very little

Nickel Ni reaction unless

Tin Sn at white heat

* Lead Pb

t HYDROGEN H

*Bismuth Bi Sometimes Inacti ve with

Copper Cu found water or steam

* Mercury Hg uncombined

Silver Ag with other

elements

Platinum Pt Found

Gold Au uncombined

with other

elements

* Indicates that breathing apparatus must be worn in an

incident involving these metals.

t Although not a metal, hydrogen is included as it also

forms a positive ion

Although hydrogen is not a metal, it is included inthe Table as it also forms a positive ion. Manyimportant metal reactions involve displacement ofhydrogen either from water or from acids.

10.3.2 Reaction of metals with water or steam

It is obviously important for the firefighter tounderstand how these heated metals will react withwater as, usually, water will be the most readily

available firefighting medium. It will be shownthat for some metals, though, the addition of watercould be dangerous or disastrous.

• Potassium to calciumThese metals react immediately with water torelease flammable hydrogen gas and leave a metalhydroxide. In some cases the hydroxide so formedis itself a corrosive alkali. In the case of potassiumthe reaction is so vigorous that the metal seems toignite immediately on contact with water. A smallpiece of sodium will move rapidly over the sUIfaceof water and if prevented from doing so, willignite. Larger pieces of these metals are in dangerof explosion on contact with water. Calcium reactssteadily with cold water but vigorously with hot.

• Magnesium to ironThese metals react little with cold water, evenwhen powdered. At higher temperatures, the reaction rate increases and a steady flow of hydrogenis produced by reaction with steam. If the metalsare already burning the reaction with cold waterbecomes very fast, producing a lot of hydrogenwhich may lead to an explosion. Going down theseries, the rate of reaction decreases until, withiron, there is little reaction unless the red-hot metalis exposed to steam.

• Cobalt to leadHere the white-hot metals must be treated withsteam before reaction will take place.

• Bismuth to goldThese metals do not react with water or steam asthey are below hydrogen in the Activity Series.

10.3.3 Reaction with oxygen

Metals at the top of the Activity Series react mostreadily in air*. Sodium and potassium are so reactive that they are stored in paraffin oil to preventoxygen reaching them. Many other metals willbum in air or oxygen with increasing difficultygoing down the series. Even metals like tin andlead will burn at very high temperatures.

* Note that reaction in pure oxygen is always much morevigorous than in air.

When a metal is powdered, it presents a very largesurface area compared with a block of the samemass. Combustion is made much easier as thepowder or dust particles are so small and can beheated extremely rapidly to the temperature atwhich they will burn. Some metallic dusts canburn or explode spontaneously when dispersedin air. When this occurs at ordinary temperaturesthe material is said to be pyrophoric (e.g., "RaneyNickel", which is a finely divided form of Nickel,used as a catalyst).

Many flammable metal powders and dusts arepyrophoric, especially magnesium, calcium, sodium, potassium, zirconium, hafnium. Some metalpowders will burn in carbon dioxide and nitrogen(e.g., magnesium) or under water. Metal powderswhen damp may also cause fires and explosions,even in the absence of air and often without warning, and in the absence of heat.

10.4 Sulphur

This is usually found either as a yellow powder(known as 'flowers of sulphur') or as yellow crystals, but it is sometimes produced as blocks orsticks. It burns with a blue flame to give sulphurdioxide:

Sulphur is used in the manufacture of rubber, insulphur compounds, such as sulphur dioxide andsulphuric acid and in certain drugs. It has a lowtoxicity, but the dust presents an explosion hazard. Sulphur dioxide, however, is a highly toxicgas with a sharp pungent odour which can be easily liquefied under pressure at ambient temperatures. It has many uses, especially as a bleachingagent and as a food preservative.

Hydrogen sulphide (H2S), which is also known assulphuretted hydrogen, is formed as a by-productfrom many chemical processes, including thedecomposition of organic sulphur compounds; forthis reason it is frequently found in sewer gases.Hydrogen sulphide has a characteristic odour ofrotten eggs and is highly toxic. It is flammableand under certain conditions can produce anexplosion risk.


•


Chapter 11 - Extinguishing Fires

ed into two groups: those that mix (are miscible)with water and those that do not (are immiscible).

Extinguishing agents are chosen according towhether the liquid fuel will mix with water or not.Agents which may be used include water spray,foam, light water. vaporising liquids, carbon dioxide and dry chemical powders.

Class CThese are fires involving gases or liquefied gasesin the form of a liquid spillage, or a liquid or gasleak, and these include methane, propane, butane,etc. Foam or dry chemical powder can be used tocontrol fires involving shallow liquid spills,though water in the form of spray is generalJy usedto cool the containers.

Class DThese are fires involving metals. Extinguishingagents containing water are ineffective, and evendangerous. Carbon dioxide or dry chemical powders containing bicarbonate will also be hazardousif applied to most metal fires. Powdered graphite,powdered talc, soda ash, limestone and dry sand arenormally suitable for Class 0 fires. Special fusiblepowders have been developed for fires involvingsome metals, especially the radioactive ones.

Electrical firesElectrical fires are not treated as a class of theirown, since any fire involving, or started by, electrical equipment must, in fact. fall into one of theother categories.

The normal procedure for dealing with an electrical fire is to cut off the electricity and use an extinguishing method appropriate to what is burning.

If this cannot be done with certainty, special extinguishing agents will be required which are non-

Physics and Chemistryfor Firef-ghters

11.1 la sification of fire by type

The current British/European Standard BS EN 2:1992 Classification oJfires defines four categoriesof fire, according to the type of material burning.

Class AThese are fires on solid materials. usually organic,leaving glowing embers. Class' A' fires are the mostcommon and the most effective extinguishing agentis generally water in the form of a jet or spray.

Class BThese are fires involving liquids or liquefiablesolids. For the purpose of choosing effective extinguishing agents, flammable liquids may be divid-

10.5 Phosphoru

Red phosphorus is relatively safe if handled withcare, and is used in making safety matches. Thewhite form, because of its toxicity, is converted tophosphorus sulphide (P4S3) for use in non-safetymatches.

The element phosphorus is extremely reactive andis found in nature combined with other elements,mostly as phosphates (compounds containing thePO.j group). It is also present in all Jiving matter.The pure element exists in two different forms: redphosphorus and white (or yellow) phosphorus.Their properties are itemised in the Manual ofFiremanship, Part 6C, Section 16. White phosphorus is extremely dangerous as it will ignite in air attemperatures as low as 30°C giving dense whiteclouds of toxic fumes of phosphorus pentoxide:

Inorganic phosphates are crystalline solids whichare normally safe unless one of the toxic metals isinvolved. Some are used as fertilisers.

Organic phosphates can be very toxic: some areused as pesticides and, for some of these, a fewdrops on the skin can prove fatal.

White phosphorus should never be touchedwith the bare hands as their warmth may causeignition; moreover, phosphorus burns heal veryslowly.


•

Physics and Chemistry for Firelighter.\· 79

Medium fire 3-7 jets

11.2 Classification of tire by size

Starvation

Smothering

1. By removing potential fuel from the neighbourhood of the fire. For example, by:

Fires can be starved of fuel (Figure 11.1, top) inthree ways:

In practice, fire extinguishing methods often usemore than one of these principles, but it will beconvenient to group them according to the mainprinciple involved.

11.3.1 Starvation

Fire extinction is largely a matter of depriving thefire of one or more of these factors, so methods ofextinguishing fire can be classified in terms ofremoving these factors:

• draining fuel from burning oil tanks;

20-jets (or more)

8-19 jets

1-2 jets, or 3 + hose reels

J-2 hose reels, or handextinguishers.

Major fire

Large fire

conductors of electricity and non-damaging toequipment. These include vaporising liquids, drypowders and carbon dioxide. Very fine water mistshave proven to be very effective at extinguishingfires using very little water, and their developmenthas been hastened recently as they are seen to bean environmentally friendly replacement forhalons. The rapid cooling that can be broughtabout by carbon dioxide extinguishers may affectsensitive electronic equipment - though it is thesmothering effect of the gas, rather than the cooling which extinguishes the fire.

To describe the size of a fire, the Central FireBrigades Advisory Council has made the following recommendation:

Minor fire

11.3 Extinguishing fire: Starvation,smothering, cooling

Small fire

• a combuslible material - fuel,

Cooling


Figure 11.1 The triangle of comhustion.Top: starvation - or the limitation of the combustible material. Centre: smothering - or thelimitation of oxygen. Bollom: cooling - or the limitation of temperature.

2. By removing the fire from the mass of combustible material - for instance, pulling apart aburning haystack or thatched roof.

• working out cargo at a ship fire;

• cutting trenches or creating fire breaks in, forexample, peat, heath and forest fires,demolishing buildings to create a fire stop;and

• counter-burning in forest fires.

3. By dividing the burning material into smallerfires which may be left to burn out or which can beextinguished more easily by other means. Thebeating out of a heath fire owes much of its effectiveness to this.

Fire Service Manual

• enough heat to bring thematerial to a certainminimum temperature.

• oxygen, usuaJly from the air,and

We have seen from the triangle ofcombustion (seeFigure 7.1), that three things are needed to allowburning to take place:

80

11.3.2 Smothering

If the oxygen supply to the burning material can besufficiently reduced, burning will cease (Figure 11. J ,

centre).

Inert gases such as nitrogen and carbon dioxidecan be used to smother a flame temporarily. Ifthese gases are vigorously discharged in the immediate vicinity of the fire, the oxygen content of the

• the latent heat of vaporisation; and

When it is applied to a fire, the extinguishingmedium - water for example - itself undergoeschanges as it absorbs heat from the fire:


(a) its temperature will rise;(b) it may evaporate (boil);(c) it may chemically decompose (not water);

and(d) it may react chemically with the burning

material.

For the extinguishing medium to achieve maximum effect, it is clear that the quantity of heatenergy absorbed when these changes occur shouldbe as high as possible. That is to say that, referringto the points above in order, in a good coolant, thefollowing properties should be as high as possible:

• the specific heat capacity;

flashpoint oil (boiling point » lOODC) can beextinguished by a high velocity sprinkler spraywhich apparently produces a water-in-oil emulsionat the surface, thus causing rapid cooling. Thisneatly avoids the problem of water sinking to thebottom of the tank before it has had much effect onthe temperature of the suIface layer.

• the heat of decomposition.

The action of water depends predominantly on (a)and (b), the latter being far more important: it takesabout six times as much heat to convert a givenmass of water at its boiling point into steam as isrequired to raise the temperature of the sameamount of water from the usual atmospheric valueto its boiling point. Water is most efficiently usedif it is applied to a fire in liquid form and in such away that as much as possible is converted to steam.The smothering effect of the steam produced at theseat of the fire is thought to play a part in assistingin the extinguishing process.

In all fire-fighting operations where water is usedit should be the aim to ensure that the proportion ofwater which escapes from the building in liquidform applied should be as low as possible.

Although extremely effective, halons are no longerused except under some exceptional circumstances, as they are known to be very harmful tothe earth's protective ozone layer. No more will bemanufactured, though such as are already in stockwill continue to be used in fixed installationswhere there is perceived to be a special risk, suchas in certain military situations.

Fires can also be extinguished by separating thefuel from the flame by blasting it away. This iswhat happens when a candle is blown out and, ona larger scale oil well fires can be extinguished bythe blast from exploding dynamite. This methoddoes not work simply by depriving the flame offuel, but also by making the flame unstable whenair is supplied at high velocity in the vicinity of thefuel surface.

11.3.3 Cooling

These vaporising liquids act partly as inertingblankets similar to those mentioned in the preceding section, but mainly by chemical interference(inhibition) with the chain reactions in the flame,"mopping up" free radicals.

the number of chlorine atoms and the fourth givesthe number of bromine atoms. A fifth digit may, ormay not, be present which gives the number ofiodine atoms. For example, bromochlorodifluoromethane has a formula CF2CIBr, and so is knownas Halon 1211.

So, to extinguish a fire by cooling, the rate atwhich heat energy is lost from the burning material must be increased by removing some of the heatenergy. This reduces the temperature of the burning mass, reducing the heat release rate.Eventually, the rate at which heat is lost from thefire may be greater than the rate of heat productionand the fire will die away.

Cooling the fuel is the main way in which water isused to extinguish fires. There are many variations: for example, a tank fire involving a high

If the rate at which heat is generated by combustion is less than the rate at which it is lost from theburning material, burning will not continue.(Figure 11.1, bottom).

For larger fires, however, inerting agents aren't souseful, as the convection currents set up are sufficiently poweIfuJ to dilute the inert blanket beforethe extinguishing action can take effect. Strongwinds may have the same effect. Applying inertingagents in a liquid form, which is then vaporised bythe fire likely to be more effective, particularly asthe burning region is also cooled by this. However,inerting gases can be used to great effect inenclosed environments such as electrical cabinets.

Very fine water mists have been shown to be ableto extinguish fires using very small amounts ofwater. These have shown their worth in situationswhere haIons would previously have been usedand on offshore installations. They act mainly byinerting: a great deal of water vapour is createdwhen water mist is discharged into a confinedspace with hot suIfaces, and this smothers the fire.As the droplets are so small, they evaporate veryquickly, and can rapidly smother the flames. Theirsmall size which makes them such a good extinguishing agent also means, unfortunately, that theyare easily swept away from the fire by opposing airmovement and so are not suitable for fighting larger fires in unconfined spaces.

atmosphere may be reduced to such an extent thatburning cannot be supported. Patented mixtures ofinerting gases are now extensively used instead ofhalons in computer installations. "'Total floodingsystems" are used to protect special risks such ascomputer installations and rare book collections inlibraries. This requires that the inerting gas isreleased into a closed space, as the appropriateinerting concentration must be reached followingthe discharge, and then maintained.

In the 1970's and 80's, halogenated hydrocarbonsor halons were developed and used extensively asextinguishants. The first and probably the simplestof these was carbon tetrachloride, but it is toxicand its use was soon discontinued. A number ofothers of lesser toxicity were developed and foundfavour.

Many halons have been considered. They are identified by numbers which denote how many carbonand halogen atoms are in the molecule. The firstdigit gives the number of carbon atoms, the secondgives the number of fluorine atoms, the third gives

Fire Service Manual

Foam is an important practical smothering agent.Foams form a "blanket" over the burning suIfaceand so separate the fuel from the air, thus preventing fuel vapours from mixing with air while at thesame time shielding the suIface from direct heattransfer from the flames.

The general procedure in methods of this type is totry to prevent fresh air from reaching the to the seatof the fi re and so to allow the combustion to reducethe oxygen content in the confined atmosphereuntil it extinguishes itself. This is less effectivewhere, as in the case of celluloid, the burningmaterial contains within itself in a chemicallycombined form the oxygen it requires for combustion.

Smothering is the principle behind snuffing outcandles and capping oil well fires. The batteningdown of a ship's hold when a fire breaks out belowdecks will sometimes hold the flames in checkuntil port is reached. Small fires, such as thoseinvolving a person's clothing, can be smotheredwith a rug, blanket, etc., while the use of sand orealth on a small metal fire is a further instance ofthe same principle.

Fires can be smothered with a cloud of fine drypowder, usually sodium bicarbonate, shot from apressurised extinguisher, though research suggeststhat chemical interaction (inhibition) by the powder may be as important as the smothering action.

Another technique using the smothering principleis the use of ternary eutectic chloride powder foruse on metal fires. This is applied using a gas cartridge pressurised extinguisher. The fusing temperature of the powder is in the region of 580°C, andit is applied to form a crust over the burning metaldepriving it of oxygen from the air.

82

When the heat of a fire is considerable, as in itsearly stages, the steam formed will not be visible,but as the temperature falls the steam will condense above the fire. This is widely recognised byexperienced fire-fighters as a sign that a fire isbeing brought under control.

On the basis of thermal capacity and latentheat of vaporisation, water is an excellent fireextinguishant, since both figures are high. Thisfact, combined with its availability in largequantities, makes it by far the most useful fireextinguishant for general purposes. The role ofdecomposition is insignificant in the case ofwater, but certain substances, for example carbonates, absorb heat in this way (see the reference todry powder extinguishers under Section 2,'Smothering').

Water does not react with ordinary materials, butmay prove dangerous with some fuels, evolvingheat rather than absorbing it. Moreover, the reaction may result in the formation of a flammableproduct, thus adding fuel to the fire. The action ofwater on burning magnesium exemplifies boththese effects, since it reacts with the metal exothermically (i.e., producing heat) with the formation ofhydrogen, which is readily ignited. In the case ofother media the reaction products may be undesirable in other senses, as in the case of the halonswhich can produce toxic gases which can be hazardous in enclosed spaces.

11.4 Fire extinguishing media

11.4.1 Water

Water is the most efficient, cheapest and mostreadily available medium for extinguishing fires ofa general nature. It is used by fire brigades for themajority of fires, although the methods of application have undergone a number of improvements.

If more water is applied than is actually required tocontain and extinguish the fire, the surplus willdrain off and may seep through floors and perhapscause more damage to goods and property thanthat caused by the fire itself. Accordingly, themethod of applying water to a fire varies accordingto the size of the fire.

If only small quantities are required, portablewater extinguishers or hand pumps may be sufficient. Hose reels are used for larger fires. These arefed from a tank on the appliance and water ispumped through the tubing on the reels by meansof a built-in pump. For major fires, greater quantities of water are necessary: the built-in pumps driven by the vehicles' engines are often capable ofpumping up to 4500 litres per minute, giving thewater the necessary energy to provide adequatethrow to penetrate deep into a building.

A variation in the application of water can be madeusing nozzles that produce jets or sprays rangingfrom large size droplets down to "atomised" fog.Judicious use of this type of application can notonly cut down the amount of water used, minimising water damage, but also ensure that it is used togreatest effect. Atomised spray (fog) nozzles havebecome standard equipment on fire brigade appliances in the UK. They are quite effective whenused in the correct situations, but their range islimited. Special pumps and ancillary equipmentare used with high pressure fog, giving a greaterrange of application.

11.4.2 "Inert gas"

On cargo ships, a fire in a hold may be containedby "inerting" the space using the exhaust gasesfrom the ship's engines to displace air. These gaseshave low oxygen and high carbon dioxide concentrations. (In the past, steam has been tried as a firesuppression agent to control fires in the petrochemical industry, but it is very expensive, requiring a fixed installation and an available source ofhigh pressure steam.)

11.43 Foam

Firefighting foams have been developed primarilyto deal with the hazards posed by liquid fuel fires.

Although water is used for most firefighting incidents, it is generally ineffective against firesinvolving liquid fuels. This is because water has adensity that is greater than most flammable liquidsso, when applied, it quickly sinks below their surfaces, often without having any significant effecton the fire.

,

Finished firefighting foams, on the other hand,consist of bubbles that are produced from a combination of a solution of firefighting foam concentrate and water that has then been mixed with air.These air filled bubbles form a blanket that floatson the surface of flammable liquids. In so doing,the foam blankets help to knock down and extinguish these fires in the following ways:

• by excluding air (oxygen) from the fuel surface;

• by separating the flames from the fuel surface;

• by restricting the release of flammablevapour fro m the surface of the fuel;

• by forming a radiant heat barrier which canhelp to reduce heat feedback from flames tothe fuel and, hence, reduce the production offlammable vapour; and

• by cooling the fuel surface and any metal surfaces as the foam solution drains out of thefoam blanket. This process also produces steamwhich dilutes the oxygen around the fire;

The main properties of firefighting foams include:

• Expansion: the amount of finished foam produced from a foam solution when it is passedthrough foam-making equipment;

• Stability: the ability of the finished foam toretain its liquid content and to maintain thenumber, size and shape of its bubbles. Inother words, its ability to remain intact;

• Fluidity: the ability of the finished foam to beprojected on to, and to flow across, the liquidto be extinguished and/or protected;

• Contamination resistence: the ability of thefinished foam to resist contamination by theliquid to which it is applied;

• Sealing and resealing: the ability of the foamblanket to reseal should breaks occur, and itsability to seal against hot and irregular shapedobjects;

• Knockdown and extinction: the ability of thefinished foam to control and extinguish fires;and

• Burn-back resistance: the ability of the finished foam, once formed on the fuel, to stayintact when subjected to heat and/or flame.

The amount of air added to the foam solutiondepends on the type of equipment used. Hand-heldfoam-making branches generally only mix relatively small amounts of air into the foam solution.Consequently, these produce finished foam withlow expansion (LX) ratios, that is to say, the ratioof the volume of the finished foam produced bythe nozzle, to the volume of the foam solution usedto produce it, is 20: I or less. Other equipment isavailable which can produce medium expansionfoam (MX) with expansion ratios of more than20: I but less than 200: 1, and high expansion foam(HX) with expansion ratios of more than 200: I andpossibly in excess of 2000: l.

There are a number of different types of foam concentrate available. Each type normally falls intoone of the two main foam concentrate groups, thatis to say, they are either protein based or syntheticbased, depending on the chemicals used to produce them.

Protein based foam concentrates include:

Protein (P);FJuoroprotein (FP);Film-forming fluoroprotein (FFFP); andAlcohol resistant FFFP (FFFP-AR).

Synthetic based foam concentrates include:

Synthetic detergent (SYNDET);Aqueous film-forming foam (AFFF); andAlcohol resistant AFFF (AFFF-AR).

The characteristics of each of these foam concentrates, and the finished foams produced from them,vary. As a result, each of them has particular properties that makes them suitable for some applications and unsuitable for others.

Various types of sun·ace active agents (or surfactants) are added to many firefighting foam concen-


trates. These are used to reduce the amount of fuelpicked up by the finished foam on impact with fueland to increase the fluidity of the finished foam.Surface active agents are also used as foamingagents because they readily produce foam bubbleswhen mixed with water.

In film-forming foam concentrates, sUlface activeagents form an aqueous film of foam solutionwhich, in certain conditions, can rapidly spreadover the surface of some burning hydrocarbons toaid knockdown and extinction. This ability canmake them ideal for use in certain firefighting situations such as aircraft crash rescue. However, theassociated foam blanket tends to collapse quickly,so providing very poor security and resistance toburnback.

Water-miscible liquids, such as some polar solvents, mix freely with water and can quickly attackfinished foams by extracting the water they contain. This rapidly leads to the complete destructionof the foam blanket. Fires involving these liquidscan be extinguished by diluting them with largequantities of water. However, containment of theresulting mixture can cause problems and theapplication of sufficient quantities of water toachieve extinction can take a long time.Consequently, 'alcohol resistant' foam concentrates have been developed to deal with these particular types of liquid.

Further technical detail regarding foam will befound in the Fire Service Manual - Volume I 'Fire Service Technology, Equipment andExtinguishing Media - Firefighting Foam' anddetails of operational use - in Volume 2 - FireService Operations - 'Firefighting Foam'.

11.4.4 Vapourising liquids

This category consists mainly of halons as discussed in Section 11.3.2. Halons have the propertyof vapourising rapidly when released from theirpressurised container. The vapours are heavierthan air, but when entrained into the flames. theyinhibit the chain reactions and suppress flaming.

Due to environmental concerns, halons have largely been replaced with inerting gases (see SectionIIA.5) and fine water mists.

11.4.5 Carbon dioxide and inert gases

At normal temperatures, carbon dioxide is a gas1.5 times as dense as air. It is easily liquefied andbottled in a cylinder, where it is contained under apressure of approximately 51 bars at normal temperatures. When discharged from the cylinder.cold CO2 vapour and some solid CO2 are expelledfrom the "horn", which rapidly cools in theprocess. The solid quickly sublimes, and some ofthe liquid CO2 evaporates to maintain the pressurein the cylinder. The gas, however, extinguishes bysmothering, effectively reducing the oxygen content of the air. About 20 to 30 per cent is necessaryto cause complete extinction, depending on thenature of the burning material. In fact, materialswhich have their own oxygen "supply" will continue to burn, as will any material that tends toreact with the carbon dioxide, such as burningmagnesium. Apart from these considerations, carbon dioxide is quick and clean, electrically nonconducting, non-toxic and non-corrosive. Mostfabrics are unharmed by it.

For special risk situations, such as in transformerrooms and rare book collections in libraries, totalflooding of the compartment may be required. Forthis, fixed carbon dioxide installations may bebuilt in. However, although it is non-toxic, it is anasphyxiant at the concentrations necessary toextinguish a fire. The operation of total floodingCO2 systems requires prior evacuation of all personnel.

Carbon dioxide is also available in bulk to fireauthorities, by special arrangement with certainmanufacturers who have agreed to supply tankerscontaining to tonnes of liquid to any fire onrequest.

11.4.6 Dry chemical powders

New problems have been produced for the firefighter by the use in industry of an ever wideningrange of risks and materials.

The rise of new plastics is one example of this, andthe fabrication of reactive metals such as titanium,zirconium and beryllium is another. Sometimes.water cannot be used; on most fires involvingburning metals, the result of applying water can be

disastrous, often leading to an explosion. Newmethods of extinction have had to be evolved.

Chief among these are the dry chemical powderswhich are stored in cylinders under pressure, orwhich can be ejected by the release of gas underpressure.

The basis of most of these is sodium bicarbonate,which, with the addition of a metallic stearate as awaterproofing agent, is widely used as an extinguishant both in portable extinguishers and forgeneral application in large quantities. Apart fromstearates, other additives are sometimes used todecrease the bulk density and to reduce packing inthe cylinder. Dry powder is very effective at extinguishing flame ("'rapid knock-down"), and is particularly valuable in tackling a fire involving anincident in which someone's clothes have beensoaked in flammable liquid, and ignited.

Dry chemical is expelled from containers by gaspressure and directed at the fire in a concentratedcloud by means of specially designed nozzles. Thiscloud also screens the operator from the flamesand enables a relatively close attack to be made.Dry chemical powder can also be supplied in polythene bags for metal fires, as it is more effective tobury the fire under a pile of bags which melt andallow the contents to smother the fire.

Dry chemical powders are also tested for theircompatibility with foam, as it was discovered thatthe early powders tended to break down foam. Thetwo can complement each other on fires wherefoam is the standard extinguishant.

Ternary eutectic chloride powders have beendeveloped for some metal fires, especially for theradioactive metals such as uranium and plutonium.These contain an ingredient which melts, thenflows a little and forms a crust over the burningmetaL effectively sealing it from the surroundingatmosphere and isolating the fire.

Some burning materials, such as metals, whichcannot be extinguished by the use of water, may bedealt with by means of dry earth, dry sand, powdered graphite, powdered talc, soda ash or limestone, all of which act as a smothering agent.

Dry sand may also be used to prevent burning liquids, including paints and oils, from flowing downdrains, basement lights. etc., and for confiningshallow layers of such liquids, thus permitting theuse of foam or spray branches. On no accountshould sand be used for extinguishing fires inmachinery, such as electric motors, since its usemay well necessitate dismantling the entiremachine for cleaning, even though the fire damageis negligible.

11.4.7 Blanketing

Another fire extinguishing method is blanketing,which deprives the fire of oxygen. This is especially useful if someone's clothes are burning. Theperson should be laid down and covered or rolledin a rug, coat, jacket, woollen blanket, etc.

For dealing with fires in small utensils, such asthose containing cooking fats, the best method is tosmother the fire with a fire resisting blanket, or acloth or doormat which has been wetted first.

11.4.8 Beating out

Small fires in materials, such as textiles, etc., mayoften be extinguished by beating them out, or byrolling and screwing up the burning material tightly to exclude the air. Beating is also the methodnormally employed to extinguish heath, crop andother similar fires in rural areas when water is notreadily available.


IXAAPPE

MetricationList of SI units for use in the fire service.

Quantity and basic Approved unit of Conversion factor Quantity and basic Approved unit of Conversion factoror derived SI unit measurement or derived SI unit measurementand symbol and symbol

Length Energy, workmetre (m) kilometre (km) I mile = I .609 km Joule (1) joule (1) I British thermal unit

metre (m) I yard = 0.914m (= I Nm) kilojoule (kJ) = 1.055 kJmillimetre (mm) I foot = 0.305m kilowatt-hour (kWh) I foot Ib force = 1.356 J

I inch = 25.4 mm

PowerArea watt (W) kilowatt (kW) 1 horsepower = 0.746 kWsquare metre (m2) square kilometre (km2) I mile2 = 2.590 km2 (= I J/s = I Nm/s) watt (W) 1 foot Ib force/second

square metre (m2) I yard2 = 0.836 m2 =] .356Wsquare millimetre (mm2) I foot2 = 0.093m2

1 inch2 = 645.2 mm2 Pressurenewton/metre2 (N/m2) bar= 10' N/m2 1 atmosphere =

Volume millibar (m bar) 101 .325 kN/m2 =cubic metre (m3) cubic metre (m3) I cubic foot = 0.028 mJ (= 102 N/m 1

) 1.013 barlitre (l) (= 1O-3m3) I gallon = 4.546 litres metrehead I lb forcelin 3 =

689476 N/m2 = 0.069 bar

Volume, flow I inch Hg = 33.86 m bar

cubic metre per second cubic metre per second I foo13/s = 0.028 m3/s I metrehead = 0.0981 bar

(m3/s) (m3/s) I gall/min = 4.546 IImin I foothead = 0.305 metrehead

litres per minute(J/min= 1O-3m3/min) Heat, quantity of heat

Joule (.T) joule (1) I British thermal unit

Mass kilojoule (kJ) = 1.055 kJ

kilogram (kg) kilogram (kg) lIb = 454 kgtonne (t) I ton = 1.016 t Heat flow rate(I tonne = 103kg) watt (W) watt (W) I British thermal unit! hour

kilowatt (kW) = 0.293 W

Velocity I British thermal unit/ second

metre per second (m/s) metre/second (m/s) I foot/second = 0.305 m/s = 1.055 kW

International knot (kn) lInt. knot = 1.852 km/hI UK knot = 1.853 km/h Specific energy, calorific

ki lometre/hour (km/h) 1 mile/hour = 1.61 km/h value, specific latent heatjoule/kilogram (1/kg) kilojoule/kilogram (kJ/kg) 1 British thermal unit! Ib

Acceleration kilojoule/m3 (kJ/mJ ) = 2.326 kJ/kg

metre per second 2 (m/s2) metre/second 2 I fooUsecond2 = 0.305 m/s 2 joule/m3 (1/m3) I British thermal uniUfP

'g'=9.81 m/52 megajoule/m3 (MJ/m3) = 37.26 kJ/m3

---

Force Temperature

Newton (N) kiloNewton (kN) I ton force = 9.964 kN degree Celsius (OC) degree Celsius (0C) I degree centigrade =

Newton (N) I Ib force = 4.448 N I degree Celsius


PPE TOt B

List of the elements with atomic number atomic weight and valency Name of Symbol Atomic Atomic Valencyelement number weight

Name of Symbol Atomic Atomic Valency Iodine I 53 127.0 Ielement number weight Iridium Ir 77 192.0 3,4

Actinium Ac 89 227.0 3 Iron Fe 26 56.0 2,3

Aluminium AI 13 27.0 3 Krypton Kr 36 84.0 0

Americium Am 95 243.0 3,4,5,6 Lanthanum La 57 139.0 3

Antimony Sb 51 122.0 3,5 Lawrencium Lw 103 257.0

Argon Ar 18 40.0 0 Lead Pb 82 207.0 2,4

Arsenic As 33 75.0 3,5 Lithium Li 3 7.0 I

Astatine At 85 210.0 1.3,5,7 Lutecium Lu 71 175.0 3

Barium Ba 56 137.0 2 Magnesium Mer 12 24.0 2b

Berkelium Bk 97 249.0 3,4 Manganese Mn 25 55.0 2,3,4,6,7

Beryllium Be 4 9.0 2 Mendelevium Md 10l 256.0

Bismuth Bi 83 209.0 3,5 Mercury Hg 80 201.0 1,2

Boron B 5 11.0 3 Molybdenum Mo 42 96.0 3,4,6

Bromine Br 35 80.0 1 Neon Ne 10 20.0 0

Cadmium Cd 48 112.0 2 Neptunium Np 93 237.0 4,5,6

Calcium Ca 20 40.0 2 ickel Ni 28 59.0 2,3

CaJifornium Cf 98 251.0 iobium Nb 41 93.0 3,5

Carbon C 6 12.0 2 itrogen N 7 14.0 3,5

Cerium Ce 58 140.0 3,4 Nobelium No 102 253.0

Caesium Cs 55 133.0 I Osmium Os 76 190.0 2,3,4,8

Chlorine Cl 17 35.5 1 Oxygen 0 8 16.0 2

Chromium Cr 24 52.0 2,3.6 Palladium Pd 46 106.0 2,4,6

Cobalt Co 27 59.0 2,3 Phosphorus P IS 31.0 3,5

Copper Cu 29 63.5 1,2 Platinum Pt 78 195.0 2,4

Curium Cm 96 247.0 3 Plutonium Pu 94 242.0 3,4,5,6

Dysprosium Dy 66 162.5 3 \1Polonium Po 84 210.0 2,3,4

Einsteinium Es 99 254.0 Potassium K 19 39.0 I

Erbium Er 68 167.0 3 Praseodymium Pr 59 141.0 3

Europium Eu 63 152.0 2.3 Promethium Pm 61 145.0 3

Fermium Fm 100 257.0 Protactinium Pa 91 231.0 5

Fluorine F 9 19.0 I Radium Ra 88 226.0 2

Francium Fr 87 223.0 I Radon Rn 86 222.0 0

Gadolinium Gd 64 157.0 3 Rhenium Re 75 186.0 2,3,4,6,7

Gallium Ga 31 70.0 2,3 Rhodium Rh 45 103.0 3

Germanium Ge 32 73.0 4 Rubidium Rb 37 85.5 I

Gold Au 79 197.0 1.3 Ruthenium Ru 44 101.0 3,4,6,8

Hafnium Hf 72 178.5 4 Samarium Sm 62 150.0 2,3

Helium He 2 4.0 0 Scandium Sc 21 45.0 3

Holmium Ho 67 165.0 3 Selenium Se 34 79.0 2,4,6

Hydrogen H 1 1.0 I Silicon Si 14 28.0 4

Indium In 49 115.0 3 Silver Ag 47 108.0 I


APPE DIX B continued (,Name of Symbol Atomic Atomic Valency Sugge lions for further readingelement number weight

Sodium Na 11 23.0 1Books about Combustion, Flame and FireJ.F. Griffiths and J.A. Barnard "Flame and

Strontium Sr 38 88.0 2 Combustion". Blackie Academic andSulphur S 16 32.0 2,4,6 Professional.Tantalum Ta 73 181.0 5Technetium Tc 43 99.0 6, 7 "Thermal Radiation Monograph" The Institution

Tellurium Te 52 128.0 2,4,6 of Chemical Engineers.

Terbium Tb 65 159.0 3Thallium Tl 81 204.0

References1,3

D.D. Drysdale "An Introduction to FireThorium Th 90 232.0 4 Dynamics". John Wiley 1985.Thulium Tm 69 169.0 3Tin Sn 50 119.0 2,4 J.F. Griffiths, J.A. Barnard "Flame andTitanium Ti 22 48.0 3,4 Combustion" Blackie Academic and Professional

Tungsten W 74 184.0 6 1995.

Uranium U 92 238.0 4,6Vanadium V 23 51.0 3,5

G.B. Grant DD. Drysdale "A Review of theExtinction Mechanisms of Diffusion Flame

Xenon Xe 54 131.0 0 Fires". Fire Research and Development GroupYtterbium Yb 70 173.0 2 Publication Home Office 6/96.Yttrium Y 39 89.0 3Zinc Zn 30 65.0 2 Books about Physics

Zirconium Zr 40 91.0 4 Muncaster "A-Level Physics". Stanley Thornes(Publishers) Ltd.Nelkon and Parker "Advanced Level Physics".Heinemann Educational Books

Books about ChemistryOpen University Foundation Course in Science

General,- I. Asimov, "Asimov's New Guide to Science".(Penguin Books, 1985).

"The SFPE Handbook of Fire ProtectionEngineering" (second edition). Society of FireProtection Engineers, Boston, Massachusetts,USA.


AcknowledgementThe author would like to thank the Editor of theFire Engineers Journal for allowing portions ofthe article "Flames in Fires and Explosions" byJ. R. Brenton and DD. Drysdale to be reproducedherein.


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