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EVALUATION OF FIRE PROTECTION SYSTEM AT UNIMAS
MECHANICAL LABORATORY
MASTURA MOHAMAD
This project is submitted in partial fulfillment of
the requirements for the degree of Bachelor of Engineering with Honours
(Mechanical Engineering and Manufacturing System).
Faculty of Engineering
UNIVERSITY MALAYSIA SARAWAK
2006
UNIVERSITY MALAYSIA SARAWAK
BORANG PENGESAHAN STATUS TESIS
Judul: EVALUATION OF FIRE PROTECTION SYSTEM AT UNIMAS MECHANICAL
LABORATORY
SESI PENGAJIAN: 2005/2006
Saya, MASTURA MOHAMAD
(HURUF BESAR)
mengaku membenarkan tesis * ini disimpan di Pusat Khidmat Maklumat Akademik, Universiti
Malaysia Sarawak dengan syarat-syarat kegunaan seperti berikut:
1. Tesis adalah hakmilik Universiti Malaysia Sarawak.
2. Pusat Khidmat Maklumat Akademik, Universiti Malaysia Sarawak dibenarkan membuat
salinan untuk tujuan pengajian sahaja.
3. Membuat pendigitan untuk membanguankan Pangkalan Data Kandungan Tempatan.
4. Pusat Khidmat Maklumat Akademik, Universiti Malaysia Sarawak dibenarkan membuat
salinan tesis ini sebagai bahan pertukaran antara institusi pengajian tinggi.
5. ** Sila tandakan ( √ ) di kotak yang berkenaan.
SULIT (Mengandungi maklumat yand berdarjah keselamatan atau
kepentingan Malaysia seperti yang termaktub di dalam AKTA
RAHSIA RASMI 1972).
TERHAD (Mengandungi maklumat TERHAD yang telah ditentukan Oleh
organisasi/badan di mana penyelidikan dijalankan).
TIDAK TERHAD
Disahkan oleh
(TANDATANGAN PENULIS) (TANDATANGAN PENYELIA)
Alamat tetap: Staff Quarters, Ldg. Sg. Tamok, Puan Marini Sawawi
K/B 117, 86609 Paloh, Nama Penyelia
Johor.
Tarikh: Tarikh:
CATATAN * Tesis dimaksudkan sebagai tesis bagi Ijazah Doktor Falsafah, Sarjana dan Sarjana Muda
** Jika tesis ini SULIT dan TERHAD, sila lampirkan surat daripada pihak
berkuasa/organiasis berkenaan dengan menyatakan sekali sebab dan tempoh tesis ini
perlu dikelaskan sebagai SULIT dan TERHAD
√
APPROVAL SHEET
This project report attached here to, entitle “Evaluation of Fire Protection
System at Mechanical Laboratory” was prepared and submitted by Mastura
Mohamad as partial fulfilment of the requirement for the degree of Bachelor of
Engineering with Honours in Mechanical Engineering and Manufacturing System is
hereby read and approve by:
_________________________ __________________
Puan Marini Sawawi Date
Supervisor
Faculty of Engineering
University Malaysia Sarawak
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Dedicated to my beloved family and loved ones
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ACKNOWLEDGEMENT
In the name of Allah, the beneficent, the merciful peace and blessing upon His
messenger and servant, Muhammad. There is no god but Allah and Muhammad is His
Apostle. All praise to be Allah SWT who has given me the guidance and strength to be
steadfast in my pursuit of knowledge amidst trials and challenges.
First of all, a lot of thanks to all the people who lend their hand in making this
project success. A heartfelt thank and gratitude to Puan Marini Sawawi for her
supervision, expert advice and assistance in conducting this paper. The author would
like to express lots of sincere appreciation to all Mechanical Laboratory technicians for
providing helpful advice.
The author also would like to express his gratitude to Mr. James the Fire Autority
Person at Balai Bomba Kota Samarahan who generously provided the information and
opinion on the evaluation of fire protection system.
The author is indebted to the beloved parents Encik Mohamad and Puan
Ramidah, dearly siblings Momazila and husband, Momasawilah, Mohd. Aidil and
Mohamad Razif, and not forgotten to sweetie niece Nur Batrisyia Hasanah. Sincere
appreciate to Zuraime Abdul Rahman, who inspired and supports. Not forgotten to the
colleagues for their patience, encouragement and endless support.
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ABSTRACT
Safety is the most important aspect in life nowadays. Fire safety is one of the building
premier considerations for life safety of occupants of the building. Fire safety is a
performance characteristic of a buildings. This paper is about the evaluation of fire
protection system of Mechanical Laboratory (CNC Laboratory). From the evaluation, it
was found that the Mechanical Laboratory does not conform to BOMBA requirement,
whereby all the necessary fire protection equipment and system is not in placed. This
project has proposed the required fire protection system in accordance to BOMBA
requirement (Uniform Building By-Law, 1984 and Sarawak Building Ordinance, 1994).
Where the installation of fire extinguisher (CO2), fire alarm with break glass, panel, fire
hydrant, heat detector, smoke detector, emergency light, signage, fire door and fire
resistant window is required and the location of respective equipment is presented in this
report.
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ABSTRAK
Keselamatan adalah salah satu aspek penting dalam kehidupan. Keselamatan dari
kebakaran bangunan adalah keutamaan bagi pekerja di sesebuah bangunan. Ciri
bangunan yang baik adalah terselamat dari kebakaran. Penyelesaian perlindungan
kebakaran untuk Makmal Mekanikal (Makmal CNC) merupakan matlamat utama
penulisan kertas kajian ini. Berpandukan kehendak menentang kebakaran BOMBA,
Makmal Mekanikal tidak memenuhi syarat kerana perkakasan menentang kebakaran
tidak berada di tempat sepatutnya. Project ini memberi penyelesaian sistem penentang
kebakaran meggunakan peraturan BOMBA (Undang-undang Kecil Bangunan Seragam,
1984 dan Undang-undang Bangunan di Sarawak, 1994). Penggunaan pemadam api
karbon dioksida, loceng kecemasan serta ‘break glass’, panel, pili bomba, pengesan asap,
pengesan haba, lampu kecemasan, papan tanda, pintu rintangan api dan tingkap
rintangan api dan lokasinya disertakan di dalam penulisan ini.
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TABLE OF CONTENTS
CONTENT PAGE
TITLE PAGE
DEDICATION ii
ACKNOWLEDGEMENT iii
ABSTRACT iv
ABSTRAK v
TABLE OF CONTENT vi
LIST OF FIGURE x
LIST OF ABBREVIATION xi
CHAPTER 1 INTRODUCTION 1
1.1 Objective 3
1.2 Scope of Study 3
CHAPTER 2 LITERATURE REVIEW 4
2.1 Fire 4
2.2 Fire Protection Classification 8
2.3 Passive Fire Protection Systems 10
2.3.1 Building Material 10
2.3.2 Evacuation Route, Exits and Dead-end Situation 14
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2.4 Active Fire Protection System 16
2.4.1 Portable Fire Extinguisher 16
2.4.2 External Fire Hydrants 19
2.4.3 Hose Reel System 20
2.4.4 Automatic Sprinkler System 21
2.4.5 Automatic Fire Detection and Alarm System 24
2.4.6 Signage 28
2.5 Fire Safety Requirement and Design Guide 29
CHAPTER 3 METHODOLOGY 32
3.1 Introduction 32
3.2 Risk Evaluation 33
3.2.1 Understanding of the activities 33
3.2.2 Probability of fire starting 34
3.2.3 Equipment in the laboratory 34
3.3 Passive Building Construction 35
3.3.1 Location building 35
3.3.2 Evacuation route – number of exits, width of exits 36
3.4 Active fire protection system 37
3.4.1 Portable Fire Extinguishers 37
3.4.2 External Fire Hydrant 37
3.4.3 Hose Reel System 37
3.4.4 Automatic Sprinkler System 37
3.4.5 Automatic Fire Detection and Alarm System 37
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3.4.6 Signage 38
3.5 Evaluation and Design 40
3.6 Documentation and Presentation 40
CHAPTER 4 RESULT AND DISCUSSION 41
4.1 Introduction 41
4.2 Result 42
4.3 Design and Discussion 43
4.3.1 Passive Building and Building Materials 43
4.3.2 Evacuation Route, Exit and Dead-end Situation 44
4.3.3 Fire Extinguisher 45
4.3.4 External Fire Hydrant 46
4.3.5 Fire Detection, Alarm System and Emergency Light 58
4.3.6 Signage and exits 50
CHAPTER 5 RECOMMENTION AND RECOMMENDATION 55
5.1 Introduction 55
5.2 Conclusion 55
5.3 Recommendation 57
REFERENCES 59
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APPENDIX
Appendix A - FIFTH SCHEDULE OR SCHEDULE E 61
Appendix B - SEVENTH SCHEDULE OR SCHEDULE G 63
Appendix C - NINTH SCHEDULE OR SCHEDULE I 65
Appendix D - TENTH SCHEDULED OR SCHEDULED J 66
Appendix E - Subpart 45 of the NFPA Fire Code Construction 68
and Fire Protection Requirements for Laboratory Units
Appendix F – SCHEDULED K 72
Appendix G - HYDRANT SYSTEM TYPICAL ARRANGEMENT 73
DRAWING
Appendix H – PRESSURIZE HYDRANT SYSTEM TYPICAL 74
ARRANGEMENT DRAWING
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LIST OF FIGURE
Figure Pages
2.1 Stages of Fire Development 5
3.1 The existing Mechanical Laboratory (CNC Laboratory) 38
3.2 The existing external fire hydrant 39
4.1 Fire Door 44
4.2 Fire Extinguishers (CO2) 45
4.3 Fire Hydrants with Pillar 47
4.4 Panel, break glass and alarm bell 49
4.5 Smoke detector 49
4.6 Heat Detector 49
4.7 Evacuation Route of Mechanical Laboratory 51
4.8 New Design of Fire Protection System 52
4.9 New Location Installations and Existing Fire Hydrant 53
4.10 Location of Signage 54
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LIST OF ABBREVIATION
UBBL Uniform Building by- Law
NFPA National Fire Protection Association
mm millimeter
sq. square
m meters
CO2 Carbon Dioxide
CNC Computer Numerical Control
m 2 square meter
l liters
sq. meters square meters
l/min liter per minute
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CHAPTER 1
INTRODUCTION
Safety is the most important aspect in life nowadays. Fire safety is one of the
building premier considerations for life safety of occupants of the building. The
buildings must be designed so that in the event of fire, the occupants will be remained in
place safely, evacuate to another part of the building where it is relatively safe or totally
evacuate the building without exposed to unhealthy, hazardous or untenable conditions.
Fire safety philosophy – UBBL 84 [1] is one of the design requirements. Life
safety in buildings must be the prime consideration and this can be achieved by
minimum fire protection in respect of the various basic aspects of:
i. Means of escape for the occupants
ii. Spread of fire within the building and from one building to another
iii. Mean of detection and extinguishment of fires
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According to Jabatan Bomba dan Penyelamat Malaysia statistical report for the
year 2001, 62 deaths were reported due to incidents of fire. Incidents of fire reported
were in housing, industrial, garages, offices and shops. It was also reported that fire
causes damage and lost in assets worth more than RM 500 millions for the year 2001 in
Malaysia.
Despite the high number of fatalities, the collapse of World Trade Centre in New
York is an invaluable lesson to structural engineers. The catastrophic incident on the 11th
of September 2001 was the result of high temperature hydrocarbon fuel feed fire on
thermal insulated steel. Even though the likelihood of such carnage in building is not an
everyday event but to certain extend it has evoked the fire safety engineering and
policies on the building.
The Mechanical Laboratory is the one of the location which includes a lot of
equipment for student learning. Almost all the equipments are the electrical machine and
heavy load machines. The most important objective of using laboratory is work in a safe
environment. Many regulations administered by the government should be considered
such as building design, building material, activities done, hazardous material, fire
protection system and etc.
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In this project, the author only reviews current legislation and guidelines on fire
safety in Mechanical Lab (CNC Lab). And to present the finding of a case study to
assess the provision of these requirements in the main activities in the mechanical lab,
passive building construction, active fire protection system and fire safety management,
and evaluate the fire protection system according to Jabatan Bomba dan Penyelamat
Malaysia requirement (Uniform Building By Law,1984 and Sarawak Building
Ordinance, 1994).
1.1 Objective
i. To determine the available fire protection system for Mechanical Laboratory
(CNC Laboratory).
ii. To evaluate the fire protection system at mechanical lab according to BOMBA
requirement.
1.2 Scope of Study
Design of fire protection system for Mechanical Laboratory (CNC Laboratory) based
on BOMBA and NFPA.
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CHAPTER 2
LITERATURE REVIEW
2.1 Fire
Fire [2] might be defined as rapid oxidation accompanied by heat and flame (or
heat and light). Fire is essentially a chemical reaction known as combustion. Fire will be
started by three factors; there are fuel, oxygen and heat. These three factors known as
fire triangle and the fire can stop by breaking the triangle. Fire will ignite the explosion,
grow rapidly (flashover), developed fire and the temperature increased slowly and the
final decay stage, the fire will burn due to the fuel or oxygen.
Fires have stages to complete the fire development. The Fire stages [1] at figure
2.1 show developments starting from ignite until fire load which fire ignites from the fire
triangle.
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Figure 2.1: Stages of Fire Development [1]
Stage 1
Ignition – Combustion can be very fast, as in a gas explosion or it can be slow
smouldering process.
Stage 2
Growth – A fire once started can grow rapidly as it creates the conditions for its own
growth. In an enclosed compartment, a critical stage may be reached where all the
combustion materials are heated to flammable concentration of gases and the fire
suddenly flashes throughout the whole compartment (flashover).
Stage 3
Development – The fire passes through a development stage after the initial rapid
growth. During this stage the fire temperature increases more slowly. However the fire
continues to spread into other areas, which then in turn continues the process of rapid
initial growth and development.
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Decay – In the final decay stage, the fire will burn itself out due to lack of fuel or
oxygen. In an enclosed rush of oxygen, e.g. breaking a window can reignite the fire with
explosive violence.
Stage 4
Fire load – The total amount of combustible materials available to fire. Certain
combustible materials release more heat than others when they burn and so contribute
more to heat than others when they burn and so contribute more to the fire load, e.g. 1 kg
of kerosene will release 46050 kilojoules of heat whereas the same weight of paper
releases about 16900 kilojoules.
Oxidation generate from the fire. Oxidation [2] is a chemical process where an
atom from the material combines with an atom of oxygen from another material to form
a new product. In other words oxidation is a carbon atom that attaches to oxygen atoms.
Heat present or given off is referred to as temperature, which measure in degrees. If heat
absorbed during reaction, it is called endothermic reaction. If heat is given off during a
reaction, it is called exothermic reaction. It is necessary for a carbon atom to unite with
two atom of oxygen in order to have complete combustion. The resultant product is
carbon dioxide (CO2). If it combines with a single atom of oxygen, carbon monoxide
(CO) will be produced.
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Carbon monoxide is a poisonous gas and toxicity. The hemoglobin in the red
blood cells will carry the oxygen in the CO 250 to 300 times more readily than they will
combine with oxygen. In a short time, they are no longer able to function adequately.
In fire safety, heat movement [1] or fire spread is one of the other factors that
have to consider. There are three sources others than direct burning that can raise the
heat level of material and increase the ignition temperature. The three are convection,
radiation and conduction.
i. Convection – Transferring heat from one location to another. It raised the hot
gasses at temperature around 800-1000ºC and convection current is blocked.
This called as ‘mushroom effect’.
ii. Radiation – Transferring heat energy as electromagnet waves. The heat transmits
to building or material not shielded from the fire.
iii. Conduction – Transferring heat between two materials. Which, the higher heat
will transmit to the lower heat.
Almost all the equipment in the mechanical lab is powered by electrical devices.
There have four possible failure modes due to different classes of defects in electrical
installation [3],
a. Overloading of electrical developed in the cables is proportional to the square of
the current, they got overheated. The insulation on cables is generally made of
materials which are damaged easily by excessive temperature. They may
therefore lose their insulating properties and lead to short circuits. Since many
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insulating materials are combustible, they may even catch fire if the temperature
rises to their ignition temperature.
b. Defects in or deterioration of electrical insulation may result in short circuits and
continuous arcing, followed by ignition of the combustible insulating materials.
Electrical arc temperature is extremely high and combustible materials in the
vicinity catch fire unless the arc is extinguished within a fraction of a second.
c. Deterioration and failure of pressure contacts between various components in the
electrical installation may result in sparking, localized overheating and burning
of combustible insulating material. In such cases, there may be no arcing initially,
but the overheating is sufficient to start a fire. Short circuits and arcing may
occur later, but they would not be the original cause of the fire.
Fracture of current conducting components due to mechanical stresses or strains
may result in local arcing at the point of fracture. Electrical arc temperatures are
extremely high and combustible materials in the vicinity catch fire.
2.2 Fire Protection Classification
Based on past history and review of fire protection effectiveness, the different
fire protection methods and strategies are necessary for the various types of buildings.
According to BOMBA, it stated that two major two purpose groups for fire protection
system. There are passive fire protection and active fire protection.
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Passive fire protection is the basic thing at the building that to propose the fire
protection system. According to UBBL 134,136 and 138, and Sarawak Building
Ordinance 112, 114 and 117 for the purpose of this part , every building or compartment
shall be regarded according to its use or intended use as falling within one of the
purpose groups set out in Fifth Schedule or Schedule E (refer to appendix A). The most
modern building codes around the world have specific prescriptive requirements to
address various aspects of their design. These prescriptive requirements address passive
fire protection systems (fire resistance ratings of the structural elements). Passive fire
protections focus more on fire requirements in the building. Which comply UBBL 133
till 224 and Sarawak Building Ordinance 111 till 214.
According to BOMBA, active fire protection system focuses more on the
equipment in fire protection system. Examples of active fire protection systems (fire
sprinkler and smoke control systems), communication systems (fire detection and alarm),
and egress systems (stairs and refuge areas). UBBL 225 till 253 and Sarawak Building
Ordinance 215 till 247 comply with active fire protection system.
There are several codes that are enforced on campus relating to fires and life
safety. The major codes are Uniform Building By-law 1984 (UBBL) 134, 138 (II) Fifth
Schedules or Schedule E (refer to appendix A), Sarawak Building Ordinance, 1994
consist of 112, 114 and 117 with schedule E and the NFPA's Life Safety Code and the
NFPA codes on the various buildings and occupancies on campus. For example, UBBL
225 (1), 237 (1) tenth schedule, Sarawak Building Ordinance 215(1), state that every
building shall be provided with means of detecting and extinguishing fire and with fire
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alarms together with illuminated exit sign in accordance with the requirements as
specified in Tenth Scheduled or Scheduled J (refer to appendix D). 229(1) satisfied that
fire alarms shall be provided in accordance with Scheduled Tenth or Scheduled J (refer
to appendix D). Using and NFPA 45 is the code that the laboratories must meet on
campus (refer to appendix E).
2.3 Passive Fire Protection System
The purpose group designed checking compliance with Sixth Schedule or
Scheduled F (Permitted Limit of Unprotected Areas), Seventh Schedule or Scheduled G
(Maximum Travel Distance) (refer to appendix B), Eight Scheduled or Scheduled H
(Restriction of Spread of Flame Over Surfaces of Walls and Ceilings), Ninth Scheduled
or Scheduled I (Limits of Compartments and Minimum Periods of Fire resistance for
Elements of Structure) (refer to appendix C) and Schedule K (Schedule Showing
Minimum Number Of Exit Door Way From a Room and Required Minimum Width
Thereof) (refer to appendix F).
2.3.1 Building Material
Building materials is one of the important thing should be considered when
designed the fire protection system. According to UBBL 53(1) and Sarawak Building
Ordinance 48(1), any materials used in the erection of a building, in the structural
alteration or extension of a building, in the execution of works or the installation of
fittings, being works or fittings to which any provision of these By-laws applies or for
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the backfilling of any excavation on a site in connection with any building or works or
fittings to which any provision of these By-laws applies, shall be
i. Of a suitable nature and quality in relation to the purposes for and
conditions in which they are used
ii. Adequately mixed or prepared
iii. Applied, used or fixed so as to adequately perform the functions for which
they are designed.
Mechanical lab is fully covered with concrete wall and glass window. There have
four double leave wood doors, eight glass windows, concrete wall, concrete floor. Fire
resistance of a material is its ability to resist for a certain time without serious loss of
strength, distortion or collapse [4].
Structural concrete may be plain, reinforced, pressed or partially pressed
concrete; in addition, concrete is used in composite design [5]. In the case of concrete,
fire resistance depends on the thickness, type of construction, type and size of aggregates
and cement content. Reinforced concrete is a much better fire resistant material than
steel. Steelwork heats rapidly, and its strength drops operability in a short time. Concrete
itself has low thermal conductivity. The effect of temperatures below 250ºC is small on
concrete, but definite loss is expected at higher temperature.