General information, optic specifications, index - santral.com

Generalinformation,optic specifications,index

19.2 G E N E R A L I N F O R M A T I O N , O P T I C S P E C I F I C A T I O N S , I N D E X

Information

Safety and protection ofluminaires

• Approvals and standardsPhilips Lighting luminairescomply with the appropriatesafety rules as laid down in theEuropean standard EN 60598prepared by CENELEC (theEuropean Committee forElectrotechnicalStandardisation). Theexamination needed to verifycompliance with the standardis often carried out in themanufacturer's own testinglaboratory. Philips Lighting haschosen for independent third-party testing via the Europeanapproval mark ENEC, as anadditional guarantee of safetyand quality for its customers.ENEC replaces the formerlyused national approbationmarks in Europe and is in mostcases also the basis forapproval marks in the CEEregion.All our luminaires comply withthe most recent Europeandirectives (LVD and EMC), asindicated by the CE markingon the product.

• Ambient temperaturePhilips luminaires are designedto meet the (environmental)conditions under which theyare most likely to be used. The maximum ambienttemperature (Ta) under whicha luminaire can be safelyapplied, is indicated on thetype label on the products, ifno indication is given then theproduct is meant for amaximum ambienttemperature of 25°C.

The ambient temperaturerefers to the typical use of theluminaire: indoors oroutdoors. The majority of luminairesdeveloped for Office and Shopindoor applications show noTa, thus meaning 25°C.Most luminaires for Outdoorapplications are designed foran ambient temperature of35°C, and luminaires forIndustrial applications havemaximum ambienttemperature Ta values as highas 40 to 45°C.

The use of luminaires abovetheir specified maximumambient temperatures mayreduce safety margins, but willin any case lead to a reductionof the lifetime of the variouscomponents; especiallyelectronic equipment (ballastsand controls) is sensitive tooverheating, and lifetime willbe sharply reduced.

Although using luminaires at(extremely) low temperaturesdoes not normally affect safety,the operating (starting) of thelamp may be influenced.Fluorescent lamps should notbe used below -5°C to -10°C,whereas high-intensitydischarge lamps function welldown below -20° C. Uponrequest, special solutions areoften possible for higher orlower ambient temperatures.

• Protection against electrical shockIn normal operation as well asduring service andmaintenance, luminaires shouldprovide adequate protection

against electrical shock. Thesafety of a luminaires dependson electrical, mechanical andthermal aspects under bothnormal and fault conditions.Luminaires are classified asClass I, II or III. Class 0 (basicinsulation only) luminaires arenot recommended by PhilipsLighting. Class III is onlyapplicable to safety extra-lowvoltage luminaires.

• Protection against ingress of solidbodies, dust and moistureThe IP (Ingress Protection)system drawn up by the IEC(CIE/IEC 529:1989) definesvarious degrees of protectionagainst the ingress of foreignbodies, dust and moisture. The term ‘foreign bodies’includes things like fingers andtools coming into contact withlive parts. Both safety aspects(contact with live parts) and

harmful effects on the functionof the luminaire are defined. The exact testing method foreach IP classification isdescribed in IEC 529. Notethat the conditions during thetesting might differ from thespecific conditions in anapplication. The designation to indicate thedegree of protection consistsof the characteristic letter IPfollowed by two numeralsindicating conformity with theconditions stated in twotables. The minimum IPclassification is IP 20 (protected against fingercontact with live parts). Note that the specification andsafety of luminaires are onlysecured if the necessarymaintenance according to theinstructions of themanufacturer is carried out intime.

Safety class Symbol ProtectionBasic insulation only (not recommended)Basic insulation plus protective earthconnectorDouble or reinforced insulation, noprovision for protective earthingSupply of safety extra-low voltage

Protection against electrical shock

0

High bay luminaires illuminate an IP20 classified area.

G E N E R A L I N F O R M A T I O N , O P T I C S P E C I F I C A T I O N S , I N D E X 19.3

IK code Shock energy Description Example

IK00 -

IK01 0.15 J

IK02 0.2 J Standard Standard open luminaire

Closed luminaire with PMMA cover

IK03 0.3 J

IK04 0.5 J Standard plus Open luminaire with reinforced optical system

IK05 0.7 J

IK06 1 J

IK07 2 J Reinforced

IK08 5 J Vandal-protected Closed luminaire with polycarbonate or glass cover

IK09 10 J

IK10 20 J Vandal-resistant Closed

Symbol Application Characteristics of ceiling material

None Suitable for mounting on non-flammable surfaces Stone, concrete

Suitable for mounting on normally flammable surfaces Ignition temperature materials > 200°C; some combustion time lag

Suitable for mounting on easily flammable surfaces Ignition temperature materials < 200°C; no combustion time lag

Protection against flammability

F

F F

• Electrical safetyIf a proper earth connection isavailable, Class I luminaires areapplied. However, in situationswhere no earth connection, oronly a poor-quality earthconnection, is available, orwhere eddy currents arepresent, Class II luminairesshall be applied.

Class II street lanterns andfloodlights, and water-protectedluminaires, are often applied in(semi-)outdoor locations. Localelectricity boards can providethe appropriate advice. There isa general trend towards thespecifying of Class II luminairesin the market.

• Impact resistanceThe impact resistance of aluminaire defines theprotection of the luminaireagainst mechanical shocks. The European norm EN 50102defines the degrees ofprotection against externalmechanical impacts (IK code)and the method of testing. The luminaire housing shouldwithstand the defined energyof the mechanical shockwithout losing its electrical andmechanical safety and the basicluminaire function.

Translated into a morepractical implementation, thismeans that after withstandingthe shock, deformation of themirror and housing is allowed,although broken lamps, anunsafe electrical situation andfailure to meet the specified IPclassifications are notpermitted. The impactresistance is expressed as agroup numeral, for instanceIK06, which is related to theimpact energy in joule. Alltypes of luminaires of PhilipsLighting have a minimum

impact resistance of 0.2 J. The table shows the ten IKclassifications and the definedshock energy in joule. Forexample: an IK07 classifiedluminaire can withstand amechanical shock of apendulum hammer, a springhammer or a free-fallinghammer of 2 joule (e.g. a hammer of 0.5 kg falling0.40 m). Note that vandal-proof luminaires are notavailable: vandal-protected andvandal-resistant are the bestachievable classifications.Former national standardsused a single numeral for aspecific impact energy. To avoid confusion, acharacteristic group numeralof two figures ‘IKxx’ has beenchosen.

Impact resistance


General Information - Safety & Protection Standards

High halls, often found in the metal working industry, may be classified as IP20. In the case shown here, high bay luminairesare an economic solution.

• Ingress protectionLuminaires are not available inall possible combinations ofingress protection andmoisture protection. The most commonclassifications in the lightingindustry are:

• IP classificationsIP 20classified luminaires can beapplied indoors only if nospecific pollution rates areexpected. Offices, dry, heatedindustrial halls, shops, shoppingmalls and theatres are typicalapplication segments.IP 21/IP 22luminaires can be applied inunheated (industrial) halls andunder canopies as theluminaires are drip andcondensation water protected.IP 23luminaires and applied inunheated industrial halls oroutdoors.IP 43/44luminaires and bollards foroutdoor street lighting andstreet lanterns. Bollardsmounted at a low height areprotected against small solidobjects and rain and splashprotected. A common combination withinan industrial high-bay luminaireor street lantern is IP 43 forthe electrical part of theluminaire to secure safety andIP 54/IP 65 for the optical partof the Iuminaire to preventpollution of reflector and lamp.IP 50luminaires are applied in dustyenvironments to prevent rapidpollution of the luminaire. The exterior of IP 50luminaires can be cleanedeasily. In the food industry,closed luminaires are specifiedto prevent glass particles fromaccidentally broken lamps fromentering the production area,preventing contamination ofthe products under preparation.Although ingress protection isspecified to protect the

luminaire function, it alsomeans that particles cannotleave the luminaire housing,thereby meeting thespecification of the foodindustry. In the ‘wet’ foodindustry, luminaires meetingthe IP 50 classification shall notbe applied.IP 54is the traditional waterprotected classification.Luminaires can be cleanedwith water without anyharmful effect. Once again thisclassification is often specifiedin the food processingindustry, for industries wheredust and moisture aregenerated in the hall, and foruse under canopies.

IP 60luminaires are completelysealed against dustaccumulation, and are used invery dusty environments(wood industry, textileindustry, stone carving) and inthe food industry as explainedabove. IP 60 luminaires arerarely applied; most frequentlyIP 65/IP 66 is applied when IP 60 is required, IP 65/IP 66 isfor jet-proof Iuminaires whichare applicable where thesurroundings are cleanedfrequently by water jets, orwhere luminaires are appliedin a dusty environment.Although the luminaires arenot fully watertight, thepotential ingress of moisture

will not have any harmfuleffect on the luminairefunction.IP 65/66luminaires are often availablein impact-protected versions.IP 67/68luminaires complying to thisclassification are suitable forimmersion in water. Typical application areas areunderwater lighting ofswimming pools and fountainIighting. Deck lighting on ships shouldalso meet this classification. The test method does notimply that IP 67/68 Iuminairesmeet the IP 65/66recommendations as well.


3

0 Not protected

1

2

3

Finger protected Protected against fingercontact with live partsagainst solid objectsexceeding 12 mm indiameter

Tool protected Protection against contactwith live parts by tools,wire or similar objects over2.5 mm thick. Protectionagainst penetration of solidobjects exceeding 2.5 mmin diameter

4 Protectionagainst grain-likesolid objects

Protection against contactwith live parts by tools,wire or similar objects over1.0 mm thick. Protectionagainst penetration of solidobjects exceeding 1.0 mmin diameter.

5 Protectionagainst dustaccumulation

Complete protectionagainst contact with liveparts and against harmfulaccumulation of dust. Somedust may penetrate, butnot to the effect thatoperation is impaired

Hand protected Protected against solidobjects exceeding 50 mmin diameter

0 Not protected

1

2 Drip proofwhen tilted atangles up to 15°

Water drips have no harmful effect

Rain-proof andspray proof

Water falling at an angle of up to60° has no harmful effect

4 Splash proof Splashing water from any directionhas no harmful effect

Drip-proofagainst verticalwater drops

Water drops falling vertically haveno harmful effect

5 Jet proof Water projected by a nozzle fromany direction has no harmful effect.Nozzle diameter 6.3 mm, pressure30 kPa

6 Jet proof Water projected by a nozzle fromany direction has no harmful effect.Nozzle diameter 12.5 mm,pressure 100 kPa

First Secondnumber Description Explanation number Description Explanation

6 Protectionagainst dustpenetration

Complete protectionagainst contact with livepats and againstpenetration of dust

7 Watertight Temporary immersion in waterunder specified conditions ofpressure and time is possible,without ingress of water in harmfulquantities

8 Pressurewatertight

Continuous submersion in waterunder specified conditions ofpressure and time, without ingressof water in harmful quantities

Key to IP (Ingress Protection) numerical ratings. Protection against ingress of dust, solid objects and moisture

First number:Degree of protection against accidentalcontact with live elements

Second number:Degree of protection against ingress of moisture


2500

3000

4000

5000

6000

T (K)c

100

80

60

40

20

CRI

CRI

90-100

80-90

70-80

60-70

40-60

20-40

< 20

Tc < 2400K 2400 < Tc < 2800 2800 < Tc < 3500 3500 < Tc < 5000 Tc > 5000K

SON(-T) Comfort

Halogen HVIncandescent

* /927

Halogen LV* /930

CDM /942* /940

* /950, * /965

* /827SDW-T

* /830 * /835, * /840 * /850, * /865

* /54

HPI(-T) (Plus)* /33

* /29, * /35ML, HPL Comfort

HPL-N

SON(-T) (Plus)

SOX(-E)

Information - Colour Rendering and Colour Temperature

Colour rendering and colourtemperature - importantchoices in lightingLamps do not all emit light ofthe same colour. There is, forexample, a striking differencebetween the pronounced amberlight from standard sodiumlamps and the white light frommost other lamps. Even then,one white light is not the sameas another. To select the properlight source for their colourcharacteristics, two parametersare important: the colourtemperature of the emitted lightand the colour rendering index.

Colour temperatureThe colour of the light has animportant influence on thecolour impression of the area,the colour temperature of thelight source plays an essentialrole. Light is popularly termed‘cool’ or ‘warm’. However toenable an objective comparisonof the colour impressions fromvarious sources, subjectiveimpressions such as these areinadequate. A precise scale isrequired, and this is given by theterm ‘correlated colourtemperature’; the colourgradation of the light iscompared with the light emittedby an intensely heated iron barof which the temperature isknown. In this way, the lightcolour can be specified by avalue in (K). Four categories, asa practical guideline, are:

• 2500 - 2800 K. Warm/Cosy. The colour from incandescentlamps, fluorescent andcompact fluorescent lamps inthe colours /827 and /927 andthe SDW-T ‘White SON’lamp. Generally used for intimateand cosy environments wherethe emphasis is on a peacefulrelaxing ambience.

• 2800 - 3500 K. Warm/Neutral.The colour from halogenlamps, colour /830 and /930fluorescent lamps andMastercolour /830 lamps. Usedin places where people areactive, requiring a welcomingcomfortable ambience.

• 3500 - 5000 K. Neutral/Cool. The light colour from /840 and/940 fluorescent lamps as wellas Mastercolour /942 andMHN metal halide lamps. Usually applied in commercialareas and offices where a lookof cool efficiency is desired.

• 5000 K and above. Daylight and cool daylight.The light colour that bestmatches natural daylight suchas fluorescent colours /850,/865, /950 and /965.

Colour rendering indexIt is often assumed that once acolour temperature has beenchosen, the colour impression isdetermined. This is not the case.

The colour impression is notsolely determined by the colourtemperature of the light sourcebut also by the colour renderingproperties. Moreover, colourtemperature and colourrendering are completelyseparate parameters.Cool daylight and incandescentlamps have fully natural colourrendering properties. The sameis true for halogen lamps. Thereason for this is the continuousspectrum of the sources. On theother hand, most gas dischargesources have an interrupted orline spectrum. This has an influence of thequality of their colour renderingproperties, which varies fromvery poor (with SOX lowpressure sodium gas dischargelamps) to excellent (with thecolour /90 series fluorescentlamps).

In selecting a particular lamptype, a clear understanding ofthe colour rendering propertiesis essential. A fair indication isgiven by the colour renderingindex (CRI), which is astandardized scale with 100 asmaximum value. Colours arebest shown under a light sourcewith the highest colourrendering index. Incidentally, it isonly worthwhile to compareCRI values of lamps with similarcolour temperature.

In practice, three categories arenormally found.

• CRI between Ra 90 and 100. Excellent colour renderingproperties. Applications: mainly wherecorrect colour appraisal is acritical task.

Colour rendering

Outdoor applications

Excellent

Good

Moderate

PoorColours "recognisable"

Indoor applications

Excellent

Good

Moderate

"Insufficient"

Colour impression

"Incandescent-like"

"Halogen-like"

"Daylight"

"Cosy" warm white

"Crisp" warm white

Neutral white

Cool white

Lamp positioning on Tc and CRIIndoor general lighting

"functional"yellowish

"cosy"warm white

"crisp"warm white

"fresh / active"neutral-cool white

"daylight"daylight


293

79 8271 B

9271 A

8301 B

9301 A

252 A

332 B

8401 B

9401 A1A

9501 A

8651 B

9651 A

8501 B

542 A

• CRI between Ra 80 and 90. Good colour renderingproperties. Applications: in areas wherecritical colour appraisal is notthe primary consideration, yetwhere good rendition ofcolours is essential.

• CRI below Ra 80. Moderate to poor colourrendering properties. Applications: in areas wherethe quality of colour renderingis of minor importance.

This classification is of coursedependent upon the demandsthat a particular applicationmakes on a lamp. For example,an Ra of 60 is inadequate forshop lighting, but is superb forfunctional road lighting.

Proper use of fluorescent lamps Optimal solution Eventually suitable

Cool daylightNeutral whiteWarm white

Shoplighting

Philips light colours

CIE Colour rendering group

Sales areasGroceries

Meat

Textiles, leather

Furniture, carpets

Sports, games, stationery

Photo, clocks and jewellery

Cosmetics, hairdressing

Flowers

Bookshops

IndustryWorkshops

Elektro., mechanical assembly

Textile manufacture

Printing, graphical trades

Colour testing

Paintshops

Stores

Plant growers

Offices, schoolsOffice areas

Conference rooms

Teaching areas

Lobby, corridor

OthersDwellings

Restaurants

Museums

Sport, multipurpose areas

Hospital bedrooms

Treatment rooms


Optic guide – Specifications

Optics to suit all requirements

The 'optic' in a luminaire is the reflector and/or refractor systemthat controls the light direction and beam pattern of the luminaire.

It is an essential control device. Not surprisingly then, Philips offersmany different types of optics, each one designed to perform aspecific function.But which optic is best for the particular situation at hand?The function of the area to be illuminated and the task to be performed usually determine the optic and luminaire you need, whilethe ceiling system often determines the dimensions of the luminaire.However, the luminaire-optic combination must fulfil the lighting

requirements for each specific area.The number of lamps and the optic selection depends on the importance of the task to be performed in the area, and the area'sdimensions.In addition, other requirements, such as image, efficiency andaesthetics, will influence the decision.

Glare controlGlare is one important factor which often influences the performanceof lighting.There are in general two aspects described in theEuropean standard EN12464-1. (See page 14 and page 17 lighting forworkstations with display screen equipment).

Polar intensity diagram

(cd/1000lm)0-180o 90-270o

0o

180o

30o30

60o60

90o90

120oo120

100

200

300

400

500

γ


(cd/1000lm)0-180o 90-270o

0o

180o

30o30

60o60

90o90

120oo120

100

200

300

400

500

γ


(cd/1000lm)0-180o 90-270o

0o

180o

30o30

60o60

90o90

120oo120

150

300

450

600

750

γ

D7/C7 (comfort)

D6/C6/M6

D6H/C6H/M6H

Optic description:Patented OLC optic with 3-dimensional lamellae with concavestructure on the upper side made ofhigh-reflecting (H) aluminium,especially designed for TL5 lamps.Available in semi-high gloss (D7),high gloss (C7). These optics createa delta-shaped light distribution,have a optimum efficiency andprovide all-round glare control.They conform to the Europeannorm EN 12464-1.

Applications:Offices

D7/C7

LOR TL5 84%, 85%

UGRR < 19 (18, 18)

L < 200 cd/m2- 650

< 200 cd/m2 - 650

Reference UGRR for room 4H x 8H.Reflection factors 0.7/0.5/0.2 (acc. EN12464-1)For 1x49W and 1x58W

Optic description:Patented OLC optic with 3-dimensional lamellae with Fresnelstructure on the upper side made ofhigh-quality aluminium. Available insemi-high gloss (D6), high gloss (C6)and matt (M6). These optics createa delta-shaped light distribution,have a high efficiency and provideall-round glare control. Theyconform to the European norm EN 12464-1.


D6/C6/M6

LOR TLD 69%, 70%, 64%

LOR TL5 78%, 79%, 75%

UGRR < 19 (18, 18, 17)

L < 200 cd/m2- 650

< 200 cd/m2- 650

< 500 cd/m2 - 650


Optic description:Patented OLC optic with 3-dimensional lamellae with Fresnelstructure on the upper side made ofhigh-reflecting (H) aluminium.Available in semi-high gloss (D6H),high gloss (C6H) and matt (M6H).These optics create a delta-shapedlight distribution, have a optimumefficiency and provide all-roundglare control. They conform to theEuropean norm EN 12464-1.


D6H/C6H/M6H

LOR TL5 88%, 89%, 87%

UGRR < 19 (18, 18, 17)

L < 500 cd/m2- 650

< 500 cd/m2- 650

< 1000 cd/m2 - 650




(cd/1000lm)0-180o 90-270o

0o

180o

30o30

60o60

90o90

120oo120

150

300

450

600

750

γ


(cd/1000lm)0-180o 90-270o

0o

180o

30o30

60o60

90o90

120oo120

100

200

300

400

500

γ


(cd/1000lm)0-180o 90-270o

0o

180o

30oo30

60oo60

90oo90

120oo120

100

200

400

γ300


(cd/1000lm)0-180o 90-270o

0o

180o

30oo30

60oo60

90oo90

120oo120

100

200

300

400

γ

M6A/M2A

M6BD/M2BD

M2

M2WB

M6A/M2A

LOR TLD 65%, 75%

LOR TL5 74%, 79%

UGRR n.a.

Optic description:Optic with matt anodised sidereflectors, specially developed topreflector and 3-dimensional lamellae(M6A) or profiled lamellae (M2A)made from high-quality aluminium.This optic creates an asymmetricallight distribution, making it ideal forilluminating walls anddisplays/shelves. It can be combinedvery effectively with the existing M6and M2 optics in one project.

Applications:Offices, shops, schools

Optic description:Optic with matt anodised sidereflectors, specially developed topreflector and flat, profiled lamellaemade from high-quality aluminium.The light distribution from this optichas been optimised. It is bi-directional so that the maximumamount of light is produced at anangle of γ = 30˚ or 45˚. It has beenspecially designed to provide theperfect lighting for shelves on bothsides of an aisle in departmentstores and supermarkets.

Applications:Shops

M6BD/M2BD

LOR TLD 65%, 72%

LOR TL5 72%, 77%

UGRR < 25 (24)


Optic description:Optic with matt anodised sidereflectors and flat, profiled lamellaemade from high-quality aluminium.This optic has a distinctiveappearance, provides opticalguidance and has a high efficiency.

Applications:Shops, schools, general applications

M2

LOR TLD 71%

LOR TL5 80%

UGRR < 22 (21)


Optic description:.Optic with matt anodised sidereflectors and flat, profiled lamellaemade from high-quality aluminium.This optic creates a very wide-beamlight distribution and has a highefficiency. This enables widerluminaire spacing when lower levelsof illuminance or higher verticalilluminances are required.

Applications:Shops, schools

M2WB

LOR TLD 74%

LOR TL5 81%

UGRR < 25 (24)



Optic guide – Specifications


(cd/1000lm)0-180o 90-270o

0o

180o

30oo30

60oo60

90oo90

120oo120

100

200

400

γ300

Optic description:Optic with matt anodised sidereflectors made from high-qualityaluminium and greenish translucentplastic lamellae. This decorativeoptic creates a distinctive andsophisticated look, making it idealfor prestige areas.

Applications:Meeting rooms, entrances, corridors

MDG-N

LOR TLD 74%

LOR TL5 83%

UGRR < 22 (21)



(cd/1000lm)0-180o 90-270o

0o

180o

30oo30

60oo60

90oo90

120oo120

100

200

400

γ300

Optic description:Optic with white painted sidereflectors and white painted flat,profiled aluminium lamellae.

Applications:Shops, corridors, general applications

L1

LOR TLD 72%

LOR TL5 81%

UGRR < 22 (21)



(cd/1000lm)0-180o 90-270o

0o

180o

30oo30

60oo60

90oo90

120oo120

50

100

150

200

250

300

γ

Cover description:Decorative closed optic with mattanodised side reflectors made fromhigh-quality aluminium and concavepolycarbonate opal-prismatic coverwith a high efficiency. This opticcreates a distinctive andsophisticated look, making it idealfor many prestige areas.Protection class IP 40 applies for theouter side when luminaires with thisoptic are installed in closed ceilingsystems.

Applications:Meeting rooms, entrances,corridors, hospitals, kitchens,general

OD

LOR TLD 60%

LOR TL5 69%

UGRR < 25 (24)



(cd/1000lm)0-180o 90-270o

0o

180o

30o30

60o60

90o90

120oo120

150

300

450

600

750

γ

Optic description:Optic made from matt anodisedhigh-grade aluminium withasymmetrical light distribution. This optic comprises a single-shell,bevelled reflector without lamellaeand can be used as a wall washer ina variety of applications.

Applications:Offices, shops, general

A

LOR TL5 79%

UGRR n.a.

MDG-N

L1

A

OD


Optic description:Optics are high gloss specularmaterial, also blocking all reflectionsof the lamp visible in the lowerparts from all directions. Highestoptical quality reflector withinnovative coating. Reflectioncoefficient is 80%.

Architectural result:Dark ceiling with invisible lighting,complete integration of thedownlight in the architecture

Applications:Offices, schools

C

LOR 63%

UGRR 22 (22)

Product offer:Fugato downlights

Reference UGRR for room 4H x 8H.Reflection factors 0.7/0.5/0.2 (acc. EN12464-1)For 2x PL-C/2 P26WDual optic concept with metal top reflector

Optic description:.Soft glowing illumination perceivingan even, soft, brightness (at an angle> 55º). This is obtained by satinisingthe metalised optic. Reflectioncoefficient is 80%.

Architectural result:A ceiling with a clear pattern ofvisible devices, using the lightingpattern in the ceiling to enhance thestructure of the space.

Applications:Shops, offices, public buildings

M

LOR 66%

UGRR 25 (22)


Reference UGRR for room 4H x 8H.Reflection factors 0.7/0.5/0.2 (acc. EN12464-1)For 2x PL-C/2 P26WDual optic concept with metal top reflector

Optic description:Scattered moving brilliant light-patches, perceiving high illuminancespots in the ceiling.

Architectural result:The specific design quality of thescattered patterns sets the fitting as anindividual item separate from theceiling. The scattered effect isespecially useful when applied in thoseareas where people are experiencingthe downlight passing by.

Applications:Corridors, general applications,entrances

WR

LOR

UGRR n.a.


Reference UGRR for room 4H x 8H.Reflection factors 0.7/0.5/0.2 (acc. EN12464-1)Dual optic concept with metal top reflector

C (high gloss)

M (matt/satin)

WR (white reflector)

C (high gloss) + louvre Optic description:Glarefree lighting not perceiving (atan angle > 55º) any glare. Optics arehigh gloss specular material, alsoblocking all reflections of the lampvisible in the lower parts from alldirections. Highest optical qualityreflector with innovative coating.Reflection coefficient is 80%.

Architectural result:Dark ceiling with invisible lighting,complete integration of thedownlight in the architecture


C

LOR 45%

UGRR 19 (19)


Reference UGRR for room 4H x 8H.Reflection factors 0.7/0.5/0.2 (acc. EN12464-1)For 2x PL-T 42WDual optic concept with metal top reflector


0°30°60°

90°

γ30°

60°

90°

C90

C270

90°

60°

30°

90°

60°

30°

0° (cd/1000 lm)

180°120° 120°

100

200

300

LVW10671

0°

30°

60°

γ60°

90°

C180

C0

90°

30°

60¡ 40¡ 20¡ 0¡ 20¡ 40¡ 60¡ 0

3000

6000

9000

1200

1500

(cd/

1000

lm)

γ

0 ,80 0 ,80 0 ,70 0 ,70 0 ,70 0 ,70 0 ,50 0 ,50 0 ,30 0 ,30 0 ,00 Ceiling 0 ,50 0 ,50 0 ,50 0 ,50 0 ,50 0 ,30 0 ,30 0 ,10 0 ,30 0 ,10 0 ,00 Walls

0 ,30 0 ,10 0 ,30 0 ,20 0 ,10 0 ,10 0 ,10 0 ,10 0 ,10 0 ,10 0 ,00 Floors

0 ,60 0 ,38 0 ,37 0 ,38 0 ,37 0 ,36 0 ,31 0 ,30 0 ,27 0 ,30 0 ,27 0 ,250,80 0 ,48 0 ,45 0 ,47 0 ,46 0 ,45 0 ,40 0 ,39 0 ,36 0 ,39 0 ,35 0 ,341,00 0 ,56 0 ,52 0 ,55 0 ,53 0 ,51 0 ,46 0 ,46 0 ,42 0 ,45 0 ,42 0 ,411,25 0 ,63 0 ,57 0 ,61 0 ,59 0 ,57 0 ,52 0 ,52 0 ,49 0 ,51 0 ,48 0 ,512,00 0 ,75 0 ,67 0 ,73 0 ,69 0 ,66 0 ,63 0 ,62 0 ,60 0 ,61 0 ,59 0 ,572,50 0 ,79 0 ,70 0 ,77 0 ,73 0 ,69 0 ,67 0 ,65 0 ,63 0 ,64 0 ,63 0 ,613,00 0 ,82 0 ,72 0 ,80 0 ,75 0 ,71 0 ,69 0 ,68 0 ,66 0 ,67 0 ,65 0 ,634,00 0 ,86 0 ,74 0 ,83 0 ,78 0 ,73 0 ,71 0 ,70 0 ,69 0 ,69 0 ,68 0 ,665,00 0 ,88 0 ,75 0 ,85 0 ,80 0 ,75 0 ,73 0 ,72 0 ,70 0 ,70 0 ,69 0 ,67

Reflectances (%) for ceiling, walls and working plane RoomIndexk

Suspension ratio: 0

General Information - Technical data

The luminous intensity, I, is givenin the form of a polar diagram,in candela per 1000 lumens(cd/1000 lm) of the nominallamp flux. The diagram gives thelight distribution of the luminairein two planes:- In a vertical plane through the

length axis of the luminaire, theC90 - C270 plane, indicated as:

- In a plane perpendicular tothat axis, the C0 - C180 plane,indicated as:

If the light distribution of aluminaire is rotation-symmetrical, the lightdistribution in only one C planeis given.The luminous intensitydiagram provides a rough idea ofthe shape of the lightdistribution of a luminaire.

NOTES:For asymmetrical lightdistributions two planes are notsufficient for calculationpurposes. Yet in the luminousintensity diagram, only twoplanes will be given, as isinternationally accepted.

Polar intensity diagram Cartesian intensity diagramFor luminaires with a verynarrow rotation-symmetricallight distribution, the luminousintensity diagram is in the formof a cartesian diagram. This visualisation gives a muchbetter indication of the beamshape than the polar diagram.The luminous intensity in thecartesian diagram is also given inabsolute candela values.Along the horizontal axis the γ-angles of the C-plane is drawnwhile along the vertical axis theintensity values are given.

The Utalisation Factor (UF) of alighting installation representsthe percentage of the luminousflux of the lamp which reachesthe working plane in a room.The UF is dependent on:- The light distribution.- The luminaire efficiency.- The reflection of ceiling, walls

and floor of the room.- The room index.The room index k representsthe geometrical ratio of theroom, and can be expressed as:

l x wk = h(l + w)

Where:I = Length of the room (m).w= Width of the room (m).h = Height or vertical distance

between the luminaires andthe working plane (m).

The UF is a quality parameter ofthe luminaire. It can be lookedup in the table for a range ofvalues for k and a number ofreflection value combinations. Itis used for the calculation of therequired number of luminairesfor a specified illumination level,with the formula:

E x AN= Φn x UF x MF

Where:N = Required number of

luminaires.E = Specified average

illuminance (lighting level)in lux.

Φn = Nominal lamp flux perluminaire (lumen).

UF = Utalisation factor.MF = Maintenance factorA = Surface area of the room

in m2

Reduced working plane utalisation factor table When the number of luminairesis known, the averageillumination level can becalculated with:

N x Φn x UF x MFE = A

S/H RatioS/H ratio is of the ratio betweenthe spacing of the centre theluminaires to the height of theseluminaires above the workingplane.The S/H ratio is a tool toprevent too large spacingsbetween luminaires in one areawhich could lead to disturbingdifferences in illuminance. It indicates the maximum spacingbetween luminaires that isallowed to make sure that agood uniformity of theilluminance on the working planeis provided.Except for downlights whichhave rotation symmetrical lightdistributions the S/H ratio (SHR)is given in 2 directions S/H Cindicates the maximum spacingbetween the centre of theluminaires crosswise(perpendicular) to the lampaxis.S/H indicates the spacingbetween the centre of theluminaires in the length directionof the lampaxis.


γ

2

Service values of illuminance (lux)A

0 -180

90 -270

Quality ClassCIE DINABCDE

A1-23

2000 1000 750 500 <3002000 1500 1000 750 500 <300

2000 1000 500 <3002000 1000 500 <300

2000 1000 500 <300

not conform to DIN

not conform to CIE

45

55

65

75

85

10 2 2 4 6 8 10 3 2 4 6 8 104 L (cd/m )

Glare limitation diagram

Ehor(lux)

1/2 E 2x22¡0 1/2 I 2x22¡max(m) (lux) 1/2E 1/2 I h E d(m)

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

3514

879

390

220

141

98

72

55

43

0.42

0.83

1.24

1.66

2.07

2.48

2.90

3.31

3.72

0.59

1.17

1.76

2.34

2.93

3.51

4.10

4.68

5.27

500

200

100

50

b

β = Beam spread

1/2 Ι max

1/2 Ι max

1/2 Ι max

γ =85 γ =45

1,20m

Luminance curves (CIE glare safeguard)

Direct glare of a lamp/luminairedetermines the comfort andquality of the lighting installation.In the CIE guide on InteriorLighting Publication 29.2 amethod for determining theacceptable glare of a luminaire isdescribed. In this luminancediagram a number of empiricallydetermined glare limitationcurves are incorporated. Alongthe vertical axis of the diagramthe angle from azimuth of theluminaire is given. That meansthat 85° is the situation where aluminaire is seen nearly in theline with the line of sight, while45° is a luminaire viewed fromnear distance.

The luminaire glare isdetermined by the backgroundluminance, therefore the glarelimitation curves relate to theaverage illuminance in the area.For each recommendedilluminance value a limitationcurve is determined.

The table Service values ofillumi-nance (lux) gives a numberof illu-minances asrecommended by CIE(Publication 29.2) and/or DIN(5035). The column Quality classoffers the opportunity to selectthe required quality of thelighting installation, where:

AVery exacting visual tasks

B Tasks with high visual demandsTasks with moderate visualdemands calling for highconcentration

CTasks with moderate visualdemands and moderatedemands on concentration andwith a certain degree of themobility of the worker

DTasks with low visual andconcentration demand levelswith workers movingfrequently within a restrictedarea

E Interiors where workers arenot confined to a workstationbut move from one place toanother and have tasks of lowvisual demand. Interiors thatare not continuously used bythe same people

From the luminance curves ofthe luminaire one can now easilyread whether the repectiveluminaire fulfils the required

quality class for a certainilluminance. If the luminaireluminance curve remains on theleft handside of the selectedlimiting curve, the luminairefulfils the requirements of theilluminance for the chosenquality class.

The illuminated area forrotationally-symmetrical lightdistributions is visualised bymeans of isolux curves, whichindicate the horizontalilluminance in relation to thedistance from the lightsource.The shape of the isolux curves isdepending on the beam spread ofthe lightsource on the luminaire.

Isolux diagram of a beam

Beam spread

The beam spread is defined asthe angle ß (in a plane throughthe beam axis) over which theluminous intensity drops to astated percentage (usually 50%)of its peak value. In mostcatalogues, this data isgraphically presented as cones ofthe given beam spread,suggesting that there is anoticeable transition at the beamspread angle (ß) from light todark when lighting a surface.

This is also indicated in thegraph by the 1/2E0 and 1/2Imax

curves.The table gives information ofthe illuminance in the centre ofthe beam (E0) at given distancesfrom the light source. The tablealso shows the diameter of thearea where the illuminance isbetter or equal to half theilluminance (1/2E0) of theilluminance in the centre of thebeam. The last column indicatesthe diameter of the area wherethe intensity of the beam isbetter or equal to half of the Imax,the intensity in the centre of thebeam.

Our analysis indicates that sucha transition or contour is notalways found, and if transitionsare noticeable, they are seldomfound at the specified beamspread angle (ß). As a result, theuse of the beam spread angle (ß)is restricted to estimating thebeam spread of the lightingsystem considered, but shouldnot be used to predict visualcontours. For this purpose, inthose cases where a contour isvisible, we suggest specifying thesize of such a contour by givingthe visual angle at which thecontour is found, which can beexpressed as a ‘visual beam’ sizeat a distinct distance.


25 50 100 250 500 1000 h(lux)1

2

5

10

1520

30

50

100

Acc

ent

Fact

or

1m

2m

3m

VBA 2x19¡12I 2x12¡

K4

0.69

1.38

2.07

h(m) d(m) E (lux)0

1

2

3

5250

1313

583

max

Isolux diagram

E0 2 X 17 I 2 x 18

E (lux) (m) (lux)

d(m)0

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

4563

2028

1141

730

507

372

285

225

0.61

0.91

1.21

1.51

1.81

2.11

2.41

2.71

0.67

1.00

1.33

1.66

1.99

2.33

2.66

2.99

2000

1000

500

200

3.0 3.02.0 0.0 2.01.0 1.0

h(m)

(m)

1.0

2.0

3.0

4.0

5.0

20

50

50

100 100

20

12

E0

max

Imaxhor

12

12 12

Eh

Vertical illuminance table

Luminaire distance to wall

0.6 0.9 1.2 1.5

1.28 2.56 1.28 2.56 1.28 2.56 1.28 2.56

h(m) Vertical illuminance (lux)

0.5 600 600 600 600 600 600 600 600

1.0 500 500 500 500 500 500 500 500

1.5 400 400 400 400 400 400 400 400

2.0 300 300 300 300 300 300 300 300

2.5 200 200 200 200 200 200 200 200

3.0 150 150 150 150 150 150 150 150

3.5 100 100 100 100 100 100 100 100

4.0 75 75 75 75 75 75 75 75

4.5 50 50 50 50 50 50 50 50

spacing (m)

Information - Technical Data

Visual Beam diagram /1/2Imax diagram

The visual beam diagramprovides design data on the lightbeam produced by thelamp/luminaire combination(projectors and downlights). Itgives the maximum illuminancein the beam axis in lux, the visualbeam angle, and the sharpness ofthe contour as indicated by theK value. Furtermore, it informsthe designer about the diameterof the visual light patch. If nolight patch is visible the term 'novisible spot' is given in thediagram.

The visual effect whenhighlighting an object isdetermined by the contrastbetween the objects and itssurrounding background. The main lighting characteristicsof light sources to achieve therequired contrast are the sizeand contour sharpness of thevisual beam.

In a first approximation, thecontrast between an object lit bya projector and its surroundingbackground is given by the ratioEobject/Ebackground.

Visual Impact diagram

In the most diffuse generallighting schemes Ebackground isclosely related to Ehorizontal (Eh), sowe define:

Accent Factor = Espot/Ehorizontal

Extensive observations in ourlaboratories have shown that, asa useful guide for choosing thecorrect accent lighting to obtainthe planned effect, the followingtable can be used:

Accent Factor Effect2 Noticeable5 Low theatrical

15 Theatrical30 Dramatic

>50 Very dramatic

The latter two effects can onlybe achieved at very low generallighting levels. For more detailedinformation on the AccentFactor, see the relevant sectionin the 'Glossary of terms'. Thedefinitions given above can beconverted into a tool for thedesign of the visual effectsobtainable by a projector. In theVisual Impact Diagram (VID), thevisual beam, sharpness ofcontour and Accent Factor canbe read as a function of generallighting level and distance to theobject. By using these VIDs, it will bepossible to predict the effects ofprojectors by the degree ofcontrast, ranging from a ratherdiffuse to a very theatrical - oreven dramatic - appearance ofthe object lit. Moreover they canbe used in the selection processto compare different projectorswith respect to their visualeffects.

ExampleIf the general lighting level Eh = 250 lux the accent factorthat can be achieved with thisparticular light source orluminaire can be read from thegraph.- 2:1 at 3m distance- 4.8:1 at 2m distance- 18:1 at 1m distance

Vertical illuminance table

Isolux diagram of vertical illuminance

For luminaires with apronounced asymmetrical lightdistribution (wall washers) theavailability of illuminance valueson a vertical plane is verypractical. The table of theaverage illuminance values onthe vertical plane for a row ofluminaires are given at fourdifferent distances from thecentre of the row of theluminaires to the wall. Theaverage vertical illuminancevalues are also specified formaximum two different spacingsbetween the luminaires of arow. In the columns the averagevalues are given at differentdistances. (heights) measuredfrom the luminaire downwardsto the reference plane.

For luminaires with apronounced asymmetrical lightdistribution (wall-washers), theavailability of illumination valueson a vertical plane, as here, isvery practical.


γ º

L <200 cd/m2L <200 cd/m2

γ º

DIN 5035/7, 1988

Demands to be satisfied bythe lightingGeneralThe monitor and its positioningmay make further or higherdemands over and above thedemands to be met by thelighting system as per DIN 5035Part 1, Part 2, Part 3 and Part 4.Apart from the requirements tobe met by artificial light as perDIN 5035 Part 1, for roomswith computer workstations. Special recommendations asgiven in the following must alsobe considered: Avoidance ofdisturbing reflections fromluminous surfaces onto themonitor.

Limitation of glareLimitation of direct glareThe limitation of direct glare byluminaires in the critical range ofthe radiation angle 45ľ ≥ γ ≥ 85ľmust satisfy at least the demandsof quality class 1 for the nexthigher value of the nominalilluminance.

Limitation of reflection onthe monitorRoom-surrounding surfaces,windows and furnishings whichare reflected on the monitormust have an average luminanceof not more than 200 cd/m2 anda maximum luminance of notmore than 400 cd/m2.Luminaires which are reflectedon the monitor must have anaverage luminance of not morethan 200 cd/m2 in the planes C0,C180, C90 and C270 for radiationangle γ which are larger than theluminance limitation angle γG.Lights which are reflected on themonitor must have a ”cut-off”angle of at least ≥ 30ľ in theplanes C0, C180, C90 and C270.

For physiological reasons amonitor inclinationof up to 20ľfrom the vertical is generallypreferred.Disturbing reflections arethereby effectively avoided,provided that the luminaires givereduced light intensities of lessthan 200 cd/m2 outside theselected cut-off angle.

If the geometric data of the computer monitor and the workstation for determining thelumi-nance limitation angle γG

are not known at the time ofspecification of the lightingsystem or if reflec-tions are tobe anticipated as a result of theroom geometry and for anyinstallation position of themonitor, then the luminancelimitation angle γG of theluminaires which may reflect onthe monitor must stay within γG = 50ľ.


180°150° 120°120° 150°

0 1H 2H 3H 4H1H0°30° 30°

90°

60°

90°

60°

4H

3H

2H

1H

0

1H

2H

3H

4H

EmaxH

(lux)(m)

SPC 930/050 1 x SDW-T 50W

(cd/1000 lm) LO1544

max I60 = max I80 = max I90 =

2214220

cdcd / 1000 lmcd / 1000 lm

0.62

250250

===

L.O.R. LA0.25 IA-0.5

1 x 2.300 lm0¡

Horizontalilluminance

3.0

3.5

4.0

31

23

18

200

160

120 50 20 10 5 2%Emax

Technical lighting data - Explanation of photometric data

POST-TOP LUMINAIRES

The luminous intensity distribu-tion of a road lighting or aresidential area lighting luminaireis presented in the form of apolar diagram. The diagram givesone, two or three curves for theintensity in cd/1000 lm in verticalplanes called C planes:

- For rotationally symmetric lightdistributions, only one curve isgiven, representing thedistribution in all C planes. Thecurve is drawn as a solid line.

- For distributions with amaximum intensity in theplane perpendicular to thelongitudinal axis of theluminaire, two curves aregiven: one for the verticalplane through the longitudinalaxis of the luminaire, called theC90 and C270 plane (broken linecurve), and one for the planeperpendicular to that axis,called the C0 and C180 plane(solid line curve).

- For distributions with amaximum intensity in a planebetween the plane through thelongitudinal axis of theluminaire and the planeperpendicular to thatlongitudinal axis, three curvesare given: one for the planethrough the longitudinal axis ofthe luminaire, called the C90

and C270 plane (broken linecurve), one for the planeperpendicular to that axis,called the C0 and C180 plane(solid line curve), and one forthe plane containing themaximum intensity, called theC[m] plane (dotted line curve).

same gamma angle to thepower -0.5. This parameteris also used to evaluatediscomfort glare.

Tilt angle.For road lighting luminairesand post-top luminaireswith comparableconstruction to roadlighting luminaires, this isthe angle between theplane of the ‘light window’(the opening that existswhen the bowl is removed)and the horizontal.

An isolux curveA locus of points on asurface at which the illu-minance has the samevalue. The curves are givenon a grid that is expressedin multiples of the luminairemounting height. The valuesof the curves are expressedas percentages relative tothe curve with the highestvalue (Emax). Emax isgiven for three differentmounting heights. Thecalculated values are givenfor the indicated tilt of theluminaire.

H Mounting height of theluminaire.

EmaxThe maximum horizontalilluminance to which theisolux curves are related aspercentage values.

Polar luminous intensity diagram Isolux curves for residential arealighting luminaires.

maxI60 The maximum luminousintensity at a gamma angleof 60° for all C planes.Expressed as an absolutevalue in cd.

maxI80 The maximum luminousintensity at a gamma angleof 80° for all C planes.Expressed as a relativevalue in cd/1000 lm.

maxI90 The maximum luminousintensity at a gamma angleof 90° for all C planes.Expressed as a relativevalue in cd/1000 lm.

L.O.R. Light Output Ratio: theratio between the luminous flux is emittedby the luminaire and theluminous flux of thelamp(s) alone.

LA0.25 The average luminance ofthe light-emitting surfaceat a gamma angle of 85° or90° (the greater of thesetwo values for all Cplanes), multiplied by thelight emitting surface areaat a gamma angle of 90° tothe power 0.25. This para-meter is used to evaluatethe discomfort glare whenlooking at a post-topmounted luminaire.

IA-0.5 The highest luminousintensity between gammaangles of 85° and 90° for allC planes, multiplied by thesurface area of the lightemitting surface for that

It is supposed that the longitu-dinal axis of the luminaire isperpendicular to the road axis. If the luminaire has no apparentlongitudinal axis, it may bepossible to take the longitudinalaxis of the lamp (PL-L or TL-D).

The polar diagram is given for atilt of the luminaire of 0°.

LVX999999999 is an internalPhilips code referring to theorigin of the photometric data.


180°150° 120°120° 150°

0 2H1H0°30° 30°

90°

60°

90°

60°

0.6

0.5

0.4

0.3

SRS 201/180

(cd/1000 lm) LVW03839-180

C0

C15

I80

61.970.9

I90

16.017.0

0.80 =L.O.R.

250

200

150

R3, Q0 = 0.08

5¡

ηE ηL

C=270¡

C=0¡

C=90¡

180¡

90¡

0¡

RoadsideKerbside

γ

C=22¡ plane

C=180¡

C0 C plane perpendicularto the longitudinal axisof the luminaire orlamp at the left side ofthe luminaire whenstanding before, andfacing the luminaire.

C15 C plane turned 15°towards the front ofthe luminaire relativeto the C0 plane.

I80 Luminous intensity at agamma angle of 80°given for the C0 andC15 planes.

I90 Luminous intensity at agamma angle of 90°given for the C0 andC15 planes.

L.O.R. Light Output Ratio: theratio between theluminous flux emitted

by the luminaire and theluminous flux of the lamp(s)alone.

R3 Class R3 in C.I.E.publication 66 ‘RoadServices and Lighting’,for the reflectionproperties of the roadsurface. Used for theluminance yield curveand the Lightingschemes.

Q0 The average reflectioncoefficient of the roadsurface for therelevant viewingdirections of a cardriver. Used for thelighting schemes.

ηE The utilisation factor.

ηL The luminance yieldfactor.

ROAD LIGHTING

The luminous intensity distribu-tion of a road lighting or aresidential area lighting luminaireis presented in the form of apolar diagram. The diagram givesone, two or three curves for theintensity in cd/1000 lm in verticalplanes called C planes:

- For rotationally symmetricallight distributions one curve isgiven, representing thedistribution in all C planes. Thecurve is drawn as a solid line.

- For distributions with amaximum intensity in a planeperpendicular to thelongitudinal axis of theluminaire, two curves aregiven: one for the vertical planethrough the longitudinal axis of the luminaire, called the C90

and C270 plane (broken linecurve), and one for the planeperpendicular to that axis,called the C0 and C180 plane(solid line curve).

- For distributions with amaximum intensity in the planebetween the plane through thelongitudinal axis of theluminaire and the planeperpendicular to thatlongitudinal axis, three curvesare given: one for the planethrough the longitudinal axis ofthe luminaire, called the C90

and C270 plane (broken linecurve), one for the planeperpendicular to that axis,called the C0 and C180 plane(solid line curve), and one forthe plane containing themaximum intensity, called theC[m] plane (dotted line curve).

It is supposed that the longitu-dinal axis of the luminaire isperpendicular to the road axis. If the luminaire has no apparentlongitudinal axis, it may bepossible to take the longitudinalaxis of the lamp (PL-L or TL-D). The polar diagram is given for atilt of the luminaire of 0°.LVX999999999 is an internalPhilips code referring to the

diagram, the utilization factor isgiven as a function of the roadwidth, expressed as a multiple ofthe luminaire mounting height.

A quick and easy way tocalculate the average horizontalilluminance for a straight roadalongside which the luminairesare equally spaced, is by usingthe utilization factor curvediagram in conjunction with thefollowing formula:

WhereEH = average horizontal

illuminanceηE = utilisation factor φL = luminous flux of the

lampn = number of lamps per

luminaire MF = maintenance factorW = width of the roadS = spacing between the

luminaires

The utilisation factor diagram isgiven for a luminaire tilt of 0°. Inmost cases the luminaires areslightly tilted, and this affects thecalculation result somewhat.

The luminance yield represents the efficiency increating luminance on a roadsurface, as determined by thelight distribution of theluminaire, the reflectionproperties of the surface and theposition of the observer.

The reference surface used inthis catalogue has reflectionproperties according to class R3of publication C.I.E. 66.

The observer position used forthis catalogue is at a distanceequal to the mounting height, tothe right (street side) of the rowof luminaires. In the luminanceyield diagram, the luminanceyield is given as a function of thewidth of the road expressed as amultiple of the mounting height

origin of the photometric data.The utilization factor ηE represents the fraction of the

luminous flux of the lamp thatactually reaches the roadsurface. In the utilization factor

ηE*φL*n*MFEH=

WS

Utilization factor diagram luminance yield diagram

Polar luminous intensity diagram


180°150° 120°120° 150°

0 2H1H0°30° 30°

90°

60°

90°

60°

0.6

0.5

0.4

0.3

0.2

0.1

0.0

SGS 101/070 1 x SON 70W I

(cd/1000 lm) MIR57370

C0

C15

I80

26.027.0

I90

2.02.0

0.66 =L.O.R. 1 x 5.600 lm

300

240

180

H

(m)

S

(m) (lux)

Uo SR

(cd/m2)

Uo Ul TI

(%)

EH L

(cd/m2)

Uo Ul TI

(%)

L

(cd/m2)

Uo Ul TI

(%)

L

R3, Q0 = 0.086 m

15¡15¡

ηE ηL

6

6

6

6

6

18

21

24

27

30

17

15

13

12

10

0.51

0.42

0.30

0.21

0.15

0.50

0.50

0.50

0.50

0.50

1.0

0.9

0.8

0.7

0.6

0.47

0.46

0.42

0.36

0.31

0.76

0.62

0.50

0.38

0.27

3.7

4.0

4.2

4.4

4.7

1.0

0.9

0.7

0.7

0.6

0.49

0.47

0.43

0.37

0.31

0.76

0.62

0.50

0.38

0.27

5.4

5.8

6.2

6.7

7.2

1.0

0.9

0.8

0.7

0.6

0.54

0.52

0.45

0.37

0.30

0.54

0.43

0.34

0.25

0.20

4.1

4.2

4.5

4.8

5.1

C20

Technical lighting data - Explanation of photometric data

Tilt angle. For road lighting luminairesand post-top luminaires withcomparable construction toroad lighting luminaires, thisis the angle between theplane of the ‘light window’(the opening that existswhen the bowl is removed)and the horizontal.

H Mounting height of theluminaire.

S Spacing between luminaires.

EH Average horizontalilluminance.

U0 Overall Uniformity: theratio between theminimum illuminance andthe average illuminance inthe field of measurement(or field of calculation).

SR Surround Ratio: the ratiobetween the averageilluminances of 5-metrewide zones on the roadside and the pavement sideof the kerb. The lowestvalues are given for the twosides of the kerb. For roadwidths less than 10 metres,the zone width is taken ashalf the road width. Thesurround ratio is recom-mended as a minimum valueby C.I.E. publication 115 toguarantee sufficient visibilityoff the kerb to enable cardrivers to anticipate roadsituations.

Polar luminous intensity diagram Utilization factor diagramluminance yield diagram

Lighting schemes

L The Average Luminance.

U0 Overall Uniformity: theratio between theminimum luminance andthe average luminance inthe field of measurements(or field of calculation). Overall Uniformity shouldalways be greater than 0.4.

Ul Longitudinal Uniformity:the ratio between theminimum luminance andthe maximum luminance onthe centre line of a trafficlane. If more than onetraffic lane exists, thelowest value of all therelevant lanes is taken.Longitudinal Uniformityshould always be greaterthan 0.5 for simplesituations, rising to 0.7 forcomplex situations.

TI Threshold Increment. A figure that representsthe glare as it reduces thevisibility. It is calculated asa percentage using theveiling glare (LV) and theaverage luminance (L) asinputs:

Threshold Incrementshould always be less than10% for critical cases, risingto 20% for non-criticalcases.

of the luminaire. A quick andeasy way to calculate theaverage luminance at a fixedobserver position, of a straightroad with a surface according toclass R3, alongside which theluminaires are equally spaced, isby using the luminance yieldcurve in conjunction with thefollowing formula:

WhereL = average luminanceηL = luminance yield factor φL = luminous flux of the lamp n = number of lamps per

luminaireQ0 = average luminance

coefficientMF = maintenance factorW = width of the roadS = spacing between the

luminaires

The luminance yield curve isgiven for a luminaire tilt of 0°. Inmost cases the luminaires areslightly tilted, and this affects thecalculation result somewhat.

Lighting Schemes.The lighting schemes give thelighting results for three types ofinstallations. The types ofinstallation are as follows:

The lighting results are given for5 combinations of mountingheights and spacings, with zerooverhang.

The lighting results for theaverage luminance are given fora road surface with reflectionproperties according to class R3of C.I.E. publication 66 with anaverage reflection coefficientQ0=0.08. A maintenance factorof 1 is used. The calculatedvalues are given for the indicatedtilt of the luminaire.

_ ηL*φL*n*Qo*MFL=

WS

1.Single sidedleft

2.Single sided right

3.Staggered

4.Central suspended

5.Central twinbracket

6.Centralcatenary

TI= 65 LV

L_

0.8


1250

1000

750

500

250

KL

JM

Imax = 1044 cd/1000 lm, 62.5¡

(cd/1000 lm) LVW034040000

SNF 111-N/62.5 1 x SON-T 1 KW

2.5¡ 22.5¡ 42.5¡ 62.5¡ 82.5¡ 102.5¡122.5¡-60¡ -40¡ -20¡ 0¡ 20¡ 40¡ 60¡

1/2 Imax 1 x 130.000 lmL.O.R. = 0.66

-9¡/5¡-38¡/38¡

Main Plane

MAxis of rotation

Plane containingthe beam axis(I max )

K

L J

K

L

J

M

10¡ 20¡ 40¡ 60¡ 80¡ 100¡ 120¡

-60¡ -40¡ -20¡ 0¡ 20¡ 40¡ 60¡

1 /2

Imax

Imax

-38¡ 38¡

-9¡5¡

1/2 Imax -9¡/5¡

-38¡/38¡

Cartesian luminous lntensity diagram

1/2 Imax -8°/3°:indication of the beam width inthe main plane (KJ).

1/2 Imax -25°/25°:indication of the beam width inthe LM plane.

L.O.R. Light Output Ratio: the ratio between the the fluxemitted by the luminaire andthe flux of the lamp(s) alone.

Imax The maximum luminous intensity in the main plane,given at the angle relative tothe perpendicular to the frontof the luminaire.

Imax

FLOOD LIGHTING

The luminous intensity distribu-tion of a floodlight is presentedin the form of a cartesiandiagram. The diagram givescurves for the luminous intensityin cd/1000 lm in one plane or intwo mutually perpendicularplanes.

For floodlights in which the axisof the lamp is perpendicular tothe front of the floodlight, thecurves are given for one planethrough the axis of the lamp.

For floodlights in which the axisof the lamp is parallel to thefront of the floodlight, thecurves are given for twomutually perpendicular planes:

- The main or K J plane (solidline curve); a planeperpendicular to the front ofthe floodlight andperpendicular to the axis of thelamp, passing through the light-centre of the lamp. The anglesto the horizontal axis of thecartesian diagram for the K Jplane are relative to theperpendicular to the front ofthe floodlight. The angles onthe ‘K’ side of theperpendicular to the front ofthe floodlight are negative; theangles on the ‘J’ side arepositive.*

- The LM plane (broken linecurve); a plane perpendicularto the main plane andcontaining the maximumluminous intensity of the mainplane. The angles to thehorizontal axis of the cartesiandiagram for the LM plane arerelative to the intersection lineof the LM and K J planes. Theangles on the ‘L’ side of theperpendicular are negative; theangles on the ‘M’ side arepositive.

Imax in the K J plane is such animportant design criterion thatthe value is printed explicitly atthe top of the diagram, together

with the angle between thedirection of Imax and theperpendicular to the front of thefloodlight.The widths of the beam in thetwo planes are given by theangles of the directions of the1/2 Imax intensities; to theperpendicular to the front of thefloodlight in the K J plane, and tothe intersection line of the K Jplane and the LM plane,respectively. Angles on the rightside of the cartesian diagram arepositive, angles on the left sideare negative.

LVX999999999 is an internalPhilips code referring to theorigin of the photometric data.

* Note: in some cases (asymmetrical floodlights) the angle between the direction ofImax in the main plane and the perpendicular to the front of the floodlight is put inthe centre of the horizontal axis of the cartesian diagram for the K J plane, i.e. the direction of Imax is taken as zero degree.


Information - Glossary of Terms

This product catalogue notonly describes productfeatures, it also deals withlighting engineering aspects.These represent thefoundation of lightingengineering: most otherexpressions are derivedfrom them.

The terms and definitionsgiven below are inalphabetical order using themost common form of theterm. A morecomprehensive list of suchterms and definitions will befound in CIE Publication No.17.4 (1987), theInternational LightingVocabulary, which since itslast edition in 1970 nowembraces Publication50(845) of the IEC, The InternationalElectrotechnical Vocabulary.

Average illuminance (Eav)Illuminance averaged over aspecified surface.

Beam spread (ß)The angle (in the plane throughthe beam axis) over which theluminous intensity drops to astated percentage of its peakintensity.

Colour appearance General expression for thecolour impression receivedwhen looking at a light source.

Colour rendering General expression for theeffect of an illuminant on thecolour appearance of objects inconscious or subconsciouscomparison with their colourappearance under a referenceilluminant.

Colour rendering index(CRI)It is often assumed that once thecolour impression has beendecided, the colour renderingproperties are likewisedetermined. This is not the case.Colour temperature and colourrendering properties havenothing in common. Cooldaylight and the warm light froman incandescent lamp both haveexcellent colour renderingproperties. The same can be saidof halogen lamps. The reason for this is thecontinuous spectrum of thesources. On the other hand,most gas discharge lamps havean interrupted or line spectrum. This has an influence on thequality of their colour renderingproperties, which varies fromvery poor (with SOX low-pressure sodium gas-dischargelamps) to good (with the /90series of fluorescent lamps). In selecting a particular lamptype, a clear understanding ofthe colour rendering propertiesis essential.

This information is given by thecolour rendering index (CRI)

which is a standardised scalewith 100 as maximum value.Colours are best shown under alight source having the highestcolour rendering index.Incidentally, it is only worthwhilecomparing the indices of lampswith a similar colourtemperature. In practice, threecategories are normally found:

- CRI between Ra 90 and 100Excellent colour renderingproperties. Applications: mainlywhere correct colour appraisalis a critical task.

- CRI between Ra 80 and 90Good colour renderingproperties. Applications: inareas where critical colourappraisal is not the primaryconsideration, yet where goodrendition of colours is stilldesirable.

- CRI lower than Ra 80Moderate to poor colourrendering properties.Applications: in areas wherethe quality of the colourrendering is not important.Symbol: Ra

Colour temperature Lamps do not all emit the samecolour of light. There is, forexample, a striking differencebetween the markedly amberlight from sodium lamps and therelatively white light from mostother lamps. But even then onewhite light is not the same asanother. Because the colour ofthe light has an importantinfluence on the colourimpression of an area, thecolour temperature of the lightsource plays an essential role.Light is popularly termed ‘cool’or ‘warm’.

To be able, however, to makean objective comparison of thecolour impression from varioussources, subjective expressionssuch as these are inadequate. A precise scale is required, andis to be found in the term

‘correlated colour temperature’:the colour gradation of the lightis compared with the lightemitted by an intensely heatediron bar of which thetemperature is known. In thisway, the light colour can bespecified by a value in Kelvin (K).Four categories are normallymet in practice:

- 2500-3000 K. Warm The lightcolour from incandescentlamps, fluorescent lamps in thecolours /82 and /92, the SL*and PL compact fluorescentsources and the SDW-T‘White SON’ lamps. Generallyused for intimate and cosyenvironments where theemphasis is on ambience.

- 3000-4000 K. Neutral-white The light colour from halogenlamps, colour /83 and /93fluorescent lamps and PL 83.Blends well with light fromincandescent lamps. Employedin places where there is ingressof daylight.

- 4000-4900 K. Cool-white The light colour from colour/84 and /94 fluorescent lamps,as well as MHN metal halidelamps. Mixes well with daylight.Usually applied in commercialareas where a look of cool,crisp efficiency is desired.

- 5000 K and above. Daylightand cool-daylight The lightcolour which parallels daylightsuch as fluorescent colours /86and /95. Employed innumerous commercial andindustrial applications.

Correlated colourtemperature The temperature of thePlanckian radiator whoseperceived colour most closelyresembles that of a givenstimulus at the same brightnessand under specified viewingconditions. Unit: Kelvin, K.


Depreciation factor(depreciated)The reciprocal of themaintenance factor.

Diffuse reflection Diffusion by reflection in which,on the macroscopic scale, thereis no regular reflection.

Diffuse transmission Transmission in which, on themacroscopic scale, there is noregular transmission.

Dimmer A device in the electrical circuitfor varying the luminous fluxfrom lamps in a lightinginstallation.

Direct flux On a surface. The luminous fluxreceived by the surface directfrom the luminaires of theinstallation.

Disability glareGlare that impairs the vision ofobjects without necessarilycausing discomfort.

Discharge lampLamp in which the light isproduced, directly or indirectly, by an electric discharge througha gas, a metal vapour, or amixture of several gases andvapours.

Discomfort glare Glare that causes discomfortwithout necessarily impairing thevision of objects.

Driver stopping distance The total distance travelled whilea vehicle is being brought to rest,measured from the position ofthe vehicle at the instant thedriver has an opportunity toperceive that he should stop hisvehicle.

Emergency lightingLighting provided for use whenthe supply to the normal lightingfails.

Escape lighting That part of emergency lightingprovided to ensure that anescape route can be effectivelyidentified and used in the case offailure of the normal lightingsystem.

FadingRadiation in the form of light orheat can cause damage toobjects or merchandisedisplayed. The extent of deterioration ofobjects upon exposure to light,such as the fading of colours anddisintegration of structure andmaterial, depends on: - thesensitivity of the material andthe capacity of material toabsorb and be affected byradiant energy; - illuminationlevel; - time of the exposure toradiation; - spectral compositionof the radiation.

Flashed areaThe flashed area of a luminairein a given direction is the area ofthe orthogonal projection of theluminous surface on a planeperpendicular to the specifieddirection.

FloodlightProjector designed forfloodlighting, usually capable ofbeing pointed in any directionand of weatherproof construction.

Glare Condition of vision in whichthere is discomfort or areduction in the ability to seesignificant objects, or both, dueto an unsuitable distribution orrange of luminance or toextreme contrasts in space ortime.

Halogen lamp Gas-filled lamp containing atungsten filament and a smallproportion of halogens.

Heat accumulationA lighting installation generates anoticeable amount of heat, a mere 5%-10% of the energy

being converted into light. If the visible light is concentratedin a beam, the same resultoccurs with the invisible infraredheat radiation. As far as food,flowers, plants and certain typesof plastic are concerned, this isparticularly undesirable. Oftenthe products themselves cantake a certain degree of heat,but having to show thatparticular article to a customercan result in badly burnedfingers. Metal tools, jewelleryand watches can be included inthis category. There are, nevertheless, anumber of very suitablesolutions. Energy-saving lamps consumerelatively few watts and generatelittle heat. Heat extraction viathe general lighting ceilingluminaires is also a possibility.Doubling the distance betweenlamp and object reduces theheating effect by three-quarters.Finally, incandescent and halogenlamps with cool-beam reflectorsproduce less heat in the beam.Fitted with so-called dichroicreflectors which reflect the lightrays but permit a majorproportion of the infra-redradiation to pass, these lampsdissipate some 60%-70% of theheat behind the lamp. Needlessto say, the construction andelectrical cabling of our luminaireswithstand this heat effect.

High-pressure mercury(vapour) lamp Sodium vapour lamp in whichthe partial pressure of thevapour during operation is ofthe order of 105 Pa - forexample, HPL and HPL-Nlamps.

High-pressure sodium(vapour) lamp Sodium vapour lamp in whichthe partial pressure of thevapour during operation is ofthe order of 104 Pa - forexample, SON and SON-Tlamps.

IlluminanceThe illuminance at a point on asurface is the quotient of theluminous flux incident on anelement of the surfacecontaining the point, and thearea of that element. The unit of illuminance is lux, lx.Symbol: E

Incandescent (electric lamp)Lamp in which light is producedby means of an element heatedto incandescence by the passageof an electric current.

Isolux curve (diagram)Locus of points on a surfacewhere the illuminance has thesame value.

Lighting levelThe term ‘lighting level’, alsoknown as ‘illuminance’,expresses a result. It indicatesthe amount of light per unitsurface area at a particular pointin the area in question. In short,how much light is falling on agiven spot. Lighting level can bemeasured yet not seen. What isperceived are the differences inthe reflection of the incidentlight. Unit: lux (lx) = lm/m2

Symbol: E

Light outputA fundamental expression inlighting engineering. The ‘lightoutput’ or 'luminous flux' valuerefers to the total amount oflight that a light source emits. Unit: lumen (lm) Symbol: Φ

Light Output RatioThe efficiency of a luminaire isexpressed in terms of its LightOutput Ratio. This is defined asthe ratio of the light output ofthe luminaire to the sum of theindividual light outputs of thelamps operating outside theluminaire. The light output ratio(LOR) so defined is the totalLOR of the luminaire and isequal to the sum of the upwardand downward LORs.



Low-pressure mercury(vapour) lamp Mercury vapour lamp, with orwithout a coating of phosphor,in which during operation thepartial pressure of the vapourdoes not exceed 100 Pa - forexample, a ‘TL’ lamp.

Low-pressure sodium(vapour) lampSodium vapour lamp in whichthe partial pressure of thevapour during operation doesnot exceed 5 Pa - for example, aSOX lamp.

LuminaireApparatus that distributes, filtersor transforms the light given bya lamp or lamps and whichincludes all the items necessaryfor fixing and protecting theselamps and for connecting themto the supply circuit.

LuminanceThe luminance in a givendirection, at a given point of areal or imaginary surface is thequotient of the luminous fluxtransmitted by an elementarybeam passing through the givenpoint and propagating in thesolid angle containing the givendirection, and the product of thesolid angle, the area of a sectionof that beam containing thegiven point, and the anglebetween the normal to thatsection and the direction of thebeam. Unit: candela per squaremetre, cd/m2. Symbol: L

Luminous efficacy This is related to the term ‘lightoutput’ and indicates thequantity of light that a particularlight source emits per watt ofelectrical energy consumed.Unit: lumen per watt (lm/W)

Luminous fluxThe quantity derived fromradiant flux by evaluating theradiation according to its actionupon the CIE standardphotometric observer.

Unit: lumen, lm. Symbol: ϕv, ϕ

Luminous intensityThe expression ‘luminousintensity’ refers to the amountof light that a light source emitsper unit solid angle(lumen/steradian) in a particulardirection. The value dependstherefore on the direction.Using this information, diagramscan be compiled that provide adirect impression of the lightdistribution from a luminaire.Luminous intensity is expressedin candelas, and sometimes incandelas/1000 lumen. Unit: candela (cd) Symbol: I

Maintained illuminanceThe average illuminance overthe reference surface at the endof the complete maintenancecycle. Note: The maintainedilluminance is the minimum valueto which the illuminance isallowed to fall.

Maintenance factorThe ratio of the averageilluminance on the working planeafter a specified period of use ofa lighting installation to theaverage illuminance obtainedunder the same conditions for anew installation. Note: The useof the term ‘depreciation factor’as the reciprocal of maintenancefactor is depreciated.

Metal halide lamp Discharge lamp in which themajor portion of the light isproduced by the radiation froma mixture of a metallic vapour(for example, mercury) and theproducts of the dissociation ofhalides (for example, halides ofthallium, indium or sodium) - forexample, HPI-T lamps.

Mounting heightThe distance between thereference plane and the lane ofthe luminaires. Power factorThe power factor in an electric

circuit is the ratio of the powerin watts to the product of ther.m.s. values of voltage andcurrent. For sinusoidalwaveforms, it is equal to thecosine of the angle of phasedifference between voltage andcurrent.

QL induction lamp (system) A lamp (system), based on thelow-pressure mercury dischargeprinciple, but devoid ofelectrodes, in which theionisation of the gas within adischarge vessel is brought aboutby the induction of a high-frequency electromagnetic field.

UniformityThe uniformity ratio ofilluminance, on a given plane, is ameasure of the variation ofilluminance over the planeexpressed as either:a The ratio of the minimum to

the maximum illuminance.b The ratio of the minimum to

the average illuminance.

NOTE: In some countries, thereciprocal of these ratios isused, characterised by valuesgreater than unity.

Utilisation factorThe ratio of the utilised flux tothe luminous flux emitted by thelamps.

Visual guidanceThe totality of measures takento give a road user anunambiguous and immediatelyrecognisable picture of thecourse of the road ahead.

Visual performance The quantitative assessment ofthe visual system in theperformance of a visual task.


Light source Damage Factor

Daylight through 4 mm window glass 0.43 - 0.68Incandescent lamp 0.08PAR 38 0.11PAR 38 cool beam 0.07Open halogen lamp 0.20Closed halogen lamp 0.12White SON lamp 0.10Open metal halide lamp 0.50Closed metal halide lamp 0.25

Fluorescent lamp colour:/827 0.19/830 0.20/840 0.21/865 0.24/927 0.15/930 0.15/940 0.18/950 0.22/33 0.24

Open Sky 4,8Overcast sky average 1.52Sunlight average (behind glas) 0.79

FR (Fading Risk) Ľ 0.02 DF x E x time (hours) where DF = Damage Factor, andE = Quantity of light per unit area, expressed in lux

K1: Is a profile spot without any spill light; this effect isachieved by equipping the luminaire with a mechanical oroptical device which cuts off the spill light; in this way, beamsof different shapes can be produced. This classification canhave high- or low-intensity beams, depending on the powerand efficiency of the system

K2: Is a spot which stands out by its sharp shift to a minimalamount of spill light; this type of beam is excellent forcreating theatrical and dramatic effects. This classification isusually associated with very high-intensity beams

K3: Has a hard shift from a high-intensity spot to spill light;the spill light is seen as a narrow ring of light around the spot. This classification is usually associated with high-intensitybeams which are very suitable for creating theatrical effects

K4: Has a soft shift from a relatively strong spot to a greatdeal of spill light; the spill light assists considerably in lightingthe general surroundings

K5: Is a uniformly wide beam without any visible spot and is,as a result, suited to general or supplementary lighting

Having no classification for thesensitivity of materials related tothe amount of damage under acertain light source, the onlyindication which can be given isthe ‘probable damage’ caused toan object, ignoring the spectralsensitivity of the objectconcerned and only taking therelative damage caused by onelight source compared toanother into account. Each lightsource can becharacterised by a damage factorDF, which yields the relativedamage caused by this sourcecompared to other sources,provided the illuminance andexposure time are constant.

Fading Risk (FR) is the damagecaused by one light source,calculated for a certain lightinglevel and a certain period of time,relative to a reference FadingRisk of 100, obtained in a ‘worst-case’ situation, viz. an object in ashop window illuminated bybright sunshine (10.000 lux) for aperiod of one hour.

Beam characteristics Accent lighting requires acontrolled beam of light,obtained by a lamp and areflector, which in many cases isintegrated into the lamp itself.The ultimate effect is largelydetermined by thecharacteristics of the beam. The important factors are theintensity, the shape and thedimensions of the light spotcreated by the beam and theamount of spill light. Spill light isthe amount of light that isallowed to spread outside theactual beam.

A 'hard-edged' beam is a lightbeam with little or no spill lightand gives a sharply definedcontrast. It lends itself to verydramatic lighting effects.

A 'soft-edged' beam, on theother hand, has a higher degreeof spill light and will thus resultin a lower contrast with thesurrounding area. The effectsare much softer than thoseobtained with a hard-edgedbeam. To help you make theright selection, Philips has aspecial classification for itsreflector lamps and lamp/reflectorcombinations, identifying five so-called K-beam factors. The finaleffect is, of course, influenced bythe contrast between theambient lighting and the lightingintensity of the beam.

Identifying the five K-beamcategoriesThe illustrations give a goodimpression of the effects of thevarious types of light beamsidentified by the Philips K-beamclassification. These effects arecreated by the relevant lightbeam only, without anysupplementary lighting.

A lighting level of 500 lux‘TL’/830 lamps results in a riskno higher than FR 2.The fading of pigments hereoccurs 50 times more slowlythan at FR 100, i.e. negligible,advisable. At an average lighting level of500 lux, an accent projector willprobably need to produce10.000 lux. And with lightsources with more ultravioletradiation in their spectrum, asmetal halide lamps without UV-filter or open halogen lamps, thedamaging radiation can reach farhigher levels, than is acceptable.



Lighting level in the spot (or illuminated object) Accent factor =

General lighting level (horizontal plane)

To obtain satisfactory effects in situations where the level ofgeneral lighting is high, powerful accent lighting should be used.

Figure Accent factor Effect1 2:1 Noticeable2 5:1 Low theatrical3 15:1 Theatrical4 30:1 Dramatic5 50:1 Very dramatic

1. Noticeable visual effect (Factor 2:1)

2. Low theatrical effect (Factor 5:1)

3. Theatrical effect (Factor 15:1)

4. Dramatic effect (Factor 30:1). Can only be achieved with relativelylow general lighting levels

5. Very dramatic effect (Factor 50:1).Can only be achieved with relativelylow general lighting levels

Accent factorWhen planning accent lighting, itis important to determine therequired effect or accent factor,which may vary from ‘noticeable’to ‘very dramatic’. The issue isthe relationship between theamount of general lighting andthe brightness of the spot. It iscalculated by dividing the lightinglevel in the spot by the generallighting level in the horizontalplane approximately 1 metreabove the floor in the directvicinity of the object.


Information - Lamp survey

Lamp Family code Lamp type Cap Colour Colour Lumen Maximum Rated Ratedin luminaire tempe- Rendering output luminous average averageproduct designation rature Index (Ra) intensity life time life time

(conv) (electr.HFP)[K] [lm] [cd] [hrs] [hrs]

Fluorescent lampsMaster TL 5 High Efficiency (HE) Super 80

TL5-14W/827 TL5 HE 14W/827 G5 2700 85 1200 20000TL5-14W/830 TL5 HE 14W/830 G5 3000 85 1200 20000TL5-14W/835 TL5 HE 14W/835 G5 3500 85 1200 20000TL5-14W/840 TL5 HE 14W/840 G5 4000 85 1200 20000TL5-14W/850 TL5 HE 14W/850 G5 5000 85 1100 20000TL5-14W/865 TL5 HE 14W/865 G5 6500 85 1100 20000TL5-21W/827 TL5 HE 21W/827 G5 2700 85 1900 20000TL5-21W/830 TL5 HE 21W/830 G5 3000 85 1900 20000TL5-21W/835 TL5 HE 21W/835 G5 3500 85 1900 20000TL5-21W/840 TL5 HE 21W/840 G5 4000 85 1900 20000TL5-21W/865 TL5 HE 21W/865 G5 6500 85 1750 20000TL5-28W/827 TL5 HE 28W/827 G5 2700 85 2600 20000TL5-28W/830 TL5 HE 28W/830 G5 3000 85 2600 20000TL5-28W/835 TL5 HE 28W/835 G5 3500 85 2600 20000TL5-28W/840 TL5 HE 28W/840 G5 4000 85 2600 20000TL5-28W/850 TL5 HE 28W/850 G5 5000 85 2400 20000TL5-28W/865 TL5 HE 28W/865 G5 6500 85 2400 20000TL5-35W/827 TL5 HE 35W/827 G5 2700 85 3300 20000TL5-35W/830 TL5 HE 35W/830 G5 3000 85 3300 20000TL5-35W/835 TL5 HE 35W/835 G5 3500 85 3300 20000TL5-35W/840 TL5 HE 35W/840 G5 4000 85 3300 20000TL5-35W/865 TL5 HE 35W/865 G5 6500 85 3100 20000

MASTER TL5 High Output Super 80 TL5-24W/827 TL5 HO 24W/827 G5 2700 85 1750 20000TL5-24W/830 TL5 HO 24W/830 G5 3000 85 1750 20000TL5-24W/835 TL5 HO 24W/835 G5 3500 85 1750 20000TL5-24W/840 TL5 HO 24W/840 G5 4000 85 1750 20000TL5-24W/850 TL5 HO 24W/850 G5 5000 85 1650 20000TL5-24W/865 TL5 HO 24W/865 G5 6500 85 1650 20000TL5-39W/827 TL5 HO 39W/827 G5 2700 85 3100 20000TL5-39W/830 TL5 HO 39W/830 G5 3000 85 3100 20000TL5-39W/835 TL5 HO 39W/835 G5 3500 85 3100 20000TL5-39W/840 TL5 HO 39W/840 G5 4000 85 3100 20000TL5-39W/865 TL5 HO 39W/865 G5 6500 85 2950 20000TL5-49W/827 TL5 HO 49W/827 G5 2700 85 4300 20000TL5-49W/830 TL5 HO 49W/830 G5 3000 85 4300 20000TL5-49W/840 TL5 HO 49W/840 G5 4000 85 4300 20000TL5-49W/865 TL5 HO 49W/865 G5 6500 85 4100 20000TL5-54W/827 TL5 HO 54W/827 G5 2700 85 4450 20000TL5-54W/830 TL5 HO 54W/830 G5 3000 85 4450 20000TL5-54W/840 TL5 HO 54W/840 G5 4000 85 4450 20000TL5-54W/850 TL5 HO 54W/850 G5 5000 85 4250 20000TL5-54W/865 TL5 HO 54W/865 G5 6500 85 4250 20000TL5-80W/830 TL5 HO 80W/830 G5 3000 85 6150 20000TL5-80W/840 TL5 HO 80W/840 G5 4000 85 6150 20000TL5-80W/865 TL5 HO 80W/865 G5 6500 85 5850 20000

TL5 High Output 90 de LuxeTL5-24W/940 TL5 HO 24W/940 G5 4000 92 1400 20000TL5-24W/965 TL5 HO 24W/965 G5 6500 92 1300 20000TL5-49W/940 TL5 HO 49W/940 G5 4000 92 3500 20000TL5-49W/965 TL5 HO 49W/965 G5 6500 92 3450 20000TL5-54W/940 TL5 HO 54W/940 G5 4000 92 3500 20000TL5-54W/965 TL5 HO 54W/965 G5 6500 92 3450 20000

TL5 Circular ProTL5C-22W/827 TL5 C Pro 22W/827 2GX13 2700 85 1800 16000TL5C-22W/830 TL5 C Pro 22W/830 2GX13 3000 85 1800 16000TL5C-22W/840 TL5 C Pro 22W/840 2GX13 4000 85 1800 16000TL5C-40W/827 TL5 C Pro 40W/827 2GX13 2700 85 3300 16000TL5C-40W/830 TL5 C Pro 40W/830 2GX13 3000 85 3300 16000TL5C-40W/840 TL5 C Pro 40W/840 2GX13 4000 85 3300 16000TL5C-55W/827 TL5 C Pro 55W/827 2GX13 2700 85 4200 16000TL5C-55W/830 TL5 C Pro 55W/830 2GX13 3000 85 4200 16000TL5C-55W/840 TL5 C Pro 55W/840 2GX13 4000 85 4200 16000TL5C-60W/830 TL5 C Pro 60W/830 2GX13 3000 85 5000 16000TL5C-60W/840 TL5 C Pro 60W/840 2GX13 4000 85 5000 16000


MASTER TL-D Super 80 TL-D15W/827 TL-D 15W/827 G13 2700 85 1000 15000 20000TL-D15W/830 TL-D 15W/830 G13 3000 85 1000 15000 20000TL-D15W/840 TL-D 15W/840 G13 4000 85 1000 15000 20000TL-D18W/830 TL-D 18W/830 G13 3000 85 1350 15000 20000TL-D18W/840 TL-D 18W/840 G13 4000 85 1350 15000 20000TL-D18W/865 TL-D 18W/865 G13 6500 85 1300 15000 20000TL-D30W/827 TL-D 30W/827 G13 2700 85 2400 15000 20000TL-D30W/830 TL-D 30W/830 G13 3000 85 2400 15000 20000TL-D30W/840 TL-D 30W/840 G13 4000 85 2400 15000 20000TL-D30W/865 TL-D 30W/865 G13 6500 85 2300 15000 20000TL-D36W/827 TL-D 36W/827 G13 2700 85 3350 15000 20000TL-D36W/830 TL-D 36W/830 G13 3000 85 3350 15000 20000TL-D36W/835 TL-D 36W/835 G13 3500 85 3350 15000 20000TL-D36W/840 TL-D 36W/840 G13 4000 85 3350 15000 20000

TL-D36W/865 TL-D 36W/865 G13 6500 85 3250 15000 20000TL-D38W/830 TL-D 38W/830 G13 3000 85 3350 15000 20000TL-D38W/840 TL-D 38W/840 G13 4000 85 3350 15000 20000TL-D58W/827 TL-D 58W/827 G13 2700 85 5200 15000 20000TL-D58W/830 TL-D 58W/830 G13 3000 85 5200 15000 20000TL-D58W/835 TL-D 58W/835 G13 3500 85 5200 15000 20000TL-D58W/840 TL-D 58W/840 G13 4000 85 5200 15000 20000TL-D58W/865 TL-D 58W/865 G13 6500 85 5000 15000 20000

TL-D 90 de LuxeTL-D18W/930 TL-D 18W/930 G13 3000 95 940 15000 20000TL-D18W/940 TL-D 18W/940 G13 3800 95 1000 15000 20000TL-D18W/950 TL-D 18W/950 G13 5300 98 960 15000 20000TL-D18W/965 TL-D 18W/965 G13 6500 98 870 15000 20000TL-D30W/930 TL-D 30W/930 G13 3000 95 2000 15000 20000TL-D36W/930 TL-D 36W/930 G13 3000 95 2250 15000 20000TL-D36W/940 TL-D 36W/940 G13 3800 95 2400 15000 20000TL-D36W/950 TL-D 36W/950 G13 5300 98 2300 15000 20000TL-D36W/965 TL-D 36W/965 G13 6500 98 2100 15000 20000TL-D58W/930 TL-D 58W/930 G13 3000 95 3650 15000 20000TL-D58W/940 TL-D 58W/940 G13 3800 95 3850 15000 20000TL-D58W/950 TL-D 58W/950 G13 5300 98 3650 15000 20000TL-D58W/965 TL-D 58W/965 G13 6500 98 3350 15000 20000

TL Mini Pro Super 80TL8W/840 TL 8W/840 G5 4000 85 470 10000TL8W/830 TL 8W/830 G5 3000 85 470 10000TL13W/840 TL 13W/840 G5 4000 85 1000 8000TL13W/830 TL 13W/830 G5 3000 85 1000 8000

MASTER TL-D Secura Super 80 TL-DS18W/830 MASTER TL-D Secura 18W/830 G13 3000 85 1300 10000* 10000*TL-DS36W/830 MASTER TL-D Secura 36W/830 G13 3000 85 3200 10000* 10000*TL-DS58W/830 MASTER TL-D Secura 58W/830 G13 3000 85 5000 10000* 10000*TL-DS18W/840 MASTER TL-D Secura 18W/840 G13 4000 85 1300 10000* 10000*TL-DS36W/840 MASTER TL-D Secura 36W/840 G13 4000 85 3200 10000* 10000*TL-DS58W/840 MASTER TL-D Secura 58W/840 G13 4000 85 5000 10000* 10000*

*For optimimum safety it is advised to replace the lamps after 10000 hours if any damage in the coating is noticed.MASTER TL-D Xtra

N/A MASTER TL-D Xtra 18W/830 G13 3000 83 1330 24000N/A MASTER TL-D Xtra 18W/840 G13 4000 82 1330 24000N/A MASTER TL-D Xtra 36W/830 G13 3000 83 3250 24000N/A MASTER TL-D Xtra 36W/840 G13 4000 82 3250 24000N/A MASTER TL-D Xtra 58W/830 G13 3000 83 5150 24000N/A MASTER TL-D Xtra 58W/840 G13 4000 82 5120 24000

MASTER TL-D XtremeTL-DX18W/830 MASTER TL-D Xtreme 18W/830 G13 3000 83 1350 42000TL-DX18W/840 MASTER TL-D Xtreme 18W/840 G13 4000 82 1350 42000TL-DX36W/830 MASTER TL-D Xtreme 36W/830 G13 3000 83 3250 42000TL-DX36W/840 MASTER TL-D Xtreme 36W/840 G13 4000 82 3250 42000TL-DX58W/830 MASTER TL-D Xtreme 58W/830 G13 3000 83 5150 42000TL-DX58W/840 MASTER TL-D Xtreme 58W/840 G13 4000 82 5150 42000

MASTER TL-D Reflex Super 80TL-DR18W/830 MASTER TL-D Reflex Super 80 18W/830 G13 3000 85 1350 15000 20000TL-DR36W/830 MASTER TL-D Reflex Super 80 36W/830 G13 3000 85 3350 15000 20000TL-DR58W/830 MASTER TL-D Reflex Super 80 58W/830 G13 3000 85 5200 15000 20000TL-DR18W/840 MASTER TL-D Reflex Super 80 18W/840 G13 4000 85 1350 15000 20000TL-DR36W/840 MASTER TL-D Reflex Super 80 36W/840 G13 4000 85 3350 15000 20000





TL-DR58W/840 MASTER TL-D Reflex Super 80 58W/840 G13 4000 85 5200 15000 20000TL-DR18W/865 MASTER TL-D Reflex Super 80 18W/865 G13 6500 85 1300 15000 20000TL-DR36W/865 MASTER TL-D Reflex Super 80 36W/865 G13 6500 85 3250 15000 20000TL-DR58W/865 MASTER TL-D Reflex Super 80 58W/865 G13 6500 85 5000 15000 20000

Compact fluorescent lamps without intergrated gearMASTER PL-L 4 Pin

PL-L18W/827 MASTER PL-L 18W/827/4P 2G11 2700 82 1200 15000 20000PL-L18W/830 MASTER PL-L 18W/830/4P 2G11 3000 82 1200 15000 20000PL-L18W/835 MASTER PL-L 18W/835/4P 2G11 3500 82 1200 15000 20000PL-L18W/840 MASTER PL-L 18W/840/4P 2G11 4000 82 1200 15000 20000PL-L18W/865 MASTER PL-L 18W/865/4P 2G11 6500 80 1200 15000 20000PL-L24W/827 MASTER PL-L 24W/827/4P 2G11 2700 82 1800 15000 20000PL-L24W/830 MASTER PL-L 24W/830/4P 2G11 3000 82 1800 15000 20000PL-L24W/835 MASTER PL-L 24W/835/4P 2G11 3500 82 1800 15000 20000PL-L24W/840 MASTER PL-L 24W/840/4P 2G11 4000 82 1800 15000 20000PL-L24W/865 MASTER PL-L 24W/865/4P 2G11 6500 80 1800 15000 20000PL-L36W/827 MASTER PL-L 36W/827/4P 2G11 2700 82 2900 15000 20000PL-L36W/830 MASTER PL-L 36W/830/4P 2G11 3000 82 2900 15000 20000PL-L36W/835 MASTER PL-L 36W/835/4P 2G11 3500 82 2900 15000 20000PL-L36W/840 MASTER PL-L 36W/840/4P 2G11 4000 82 2900 15000 20000PL-L36W/850 MASTER PL-L 36W/850/4P 2G11 5000 82 2900 15000 20000PL-L36W/865 MASTER PL-L 36W/865/4P 2G11 6500 80 2900 15000 20000PL-L36W/930 MASTER PL-L 36W/930/4P 2G11 3000 90 2350 15000 20000PL-L36W/950 MASTER PL-L 36W/950/4P 2G11 5300 91 2350 15000 20000PL-L40W/830 MASTER PL-L 40W/830/4P 2G11 3000 82 3500 - 20000PL-L40W/835 MASTER PL-L 40W/835/4P 2G11 3500 82 3500 - 20000PL-L40W/840 MASTER PL-L 40W/840/4P 2G11 4000 82 3500 - 20000PL-L55W/827 MASTER PL-L 55W/827/4P 2G11 2700 82 4800 - 20000PL-L55W/830 MASTER PL-L 55W/830/4P 2G11 3000 82 4800 - 20000PL-L55W/835 MASTER PL-L 55W/835/4P 2G11 3500 82 4800 - 20000PL-L55W/840 MASTER PL-L 55W/840/4P 2G11 4000 82 4800 - 20000PL-L55W/865 MASTER PL-L 55W/865/4P 2G11 6500 80 4800 - 20000PL-L55W/930 MASTER PL-L 55W/930/4P 2G11 3000 90 3650 - 20000PL-L55W/950 MASTER PL-L 55W/950/4P 2G11 5300 91 3650 - 20000PL-L80W/827 MASTER PL-L 80W/827/4P 2G11 2700 82 6000 - 20000PL-L80W/830 MASTER PL-L 80W/830/4P 2G11 3000 82 6000 - 20000PL-L80W/835 MASTER PL-L 80W/835/4P 2G11 3500 82 6000 - 20000PL-L80W/840 MASTER PL-L 80W/840/4P 2G11 4000 82 6000 - 20000

MASTER PL-T 4 Pin (NEW)PL-T/4P13W/827 MASTER PL-T 13W/827/4P GX24q-1 2700 82 900 13000PL-T/4P13W/830 MASTER PL-T 13W/830/4P GX24q-1 3000 82 900 13000PL-T/4P13W/840 MASTER PL-T 13W/840/4P GX24q-1 4000 82 900 13000PL-T/4P18W/827 MASTER PL-T 18W/827/4P GX24q-2 2700 82 1200 13000PL-T/4P18W/830 MASTER PL-T 18W/830/4P GX24q-2 3000 82 1200 13000PL-T/4P18W/840 MASTER PL-T 18W/840/4P GX24q-2 4000 82 1175 13000PL-T/4P26W/827 MASTER PL-T 26W/827/4P GX24q-3 2700 82 1750 13000PL-T/4P26W/830 MASTER PL-T 26W/830/4P GX24q-3 3000 82 1750 13000PL-T/4P26W/840 MASTER PL-T 26W/840/4P GX24q-3 4000 82 1750 13000PL-T/4P32W/827 MASTER PL-T 32W/827/4P GX24q-3 2700 82 2400 13000PL-T/4P32W/830 MASTER PL-T 32W/830/4P GX24q-3 3000 82 2400 13000PL-T/4P32W/840 MASTER PL-T 32W/840/4P GX24q-3 4000 82 2400 13000PL-T/4P42W/827 MASTER PL-T 42W/827/4P GX24q-4 2700 82 3200 13000PL-T/4P42W/830 MASTER PL-T 42W/830/4P GX24q-4 3000 82 3200 13000PL-T/4P42W/840 MASTER PL-T 42W/840/4P GX24q-4 4000 82 3200 13000PL-T/4P57W/827 MASTER PL-T 57W/827/4P GX24q-5 2700 82 4300 13000PL-T/4P57W/830 MASTER PL-T 57W/830/4P GX24q-5 3000 82 4300 13000PL-T/4P57W/840 MASTER PL-T 57W/840/4P GX24q-5 4000 82 4300 13000

MASTER PL-T TOP 4 PinN/A MASTER PL-T TOP 32W/827/4P GX24q-3 2700 82 2400 13000N/A MASTER PL-T TOP 32W/830/4P GX24q-3 3000 82 2400 13000N/A MASTER PL-T TOP 32W/840/4P GX24q-3 4000 82 2400 13000N/A MASTER PL-T TOP 42W/827/4P GX24q-4 2700 82 3200 13000N/A MASTER PL-T TOP 42W/830/4P GX24q-4 3000 82 3200 13000N/A MASTER PL-T TOP 42W/840/4P GX24q-4 4000 82 3200 13000N/A MASTER PL-T TOP 57W/827/4P GX24q-5 2700 82 4300 13000N/A MASTER PL-T TOP 57W/830/4P GX24q-5 3000 82 4300 13000N/A MASTER PL-T TOP 57W/840/4P GX24q-5 4000 82 4300 13000





MASTER PL-C 4 Pin PL-C/4P10W/827 MASTER PL-C 10W/827/4P G24q-1 2700 82 600 13000PL-C/4P10W/830 MASTER PL-C 10W/830/4P G24q-1 3000 82 600 13000PL-C/4P10W/840 MASTER PL-C 10W/840/4P G24q-1 4000 82 600 13000PL-C/4P13W/827 MASTER PL-C 13W/827/4P G24q-1 2700 82 900 13000PL-C/4P13W/830 MASTER PL-C 13W/830/4P G24q-1 3000 82 900 13000PL-C/4P13W/840 MASTER PL-C 13W/840/4P G24q-1 4000 82 900 13000PL-C/4P13W/865 MASTER PL-C 13W/865/4P G24q-1 6500 80 900 13000PL-C/4P18W/827 MASTER PL-C 18W/827/4P G24q-2 2700 82 1200 13000PL-C/4P18W/830 MASTER PL-C 18W/830/4P G24q-2 3000 82 1200 13000PL-C/4P18W/840 MASTER PL-C 18W/840/4P G24q-2 4000 82 1200 13000PL-C/4P18W/865 MASTER PL-C 18W/865/4P G24q-2 6500 82 1200 13000PL-C/4P26W/827 MASTER PL-C 26W/827/4P G24q-3 2700 82 1800 13000PL-C/4P26W/830 MASTER PL-C 26W/830/4P G24q-3 3000 82 1800 13000PL-C/4P26W/835 MASTER PL-C 26W/835/4P G24q-3 3500 82 1800 13000PL-C/4P26W/840 MASTER PL-C 26W/840/4P G24q-3 4000 82 1800 13000

MASTER PL-S 4 PinPL-S/4P7W/827 MASTER PL-S 7W/827/4P 2G7 2700 82 400 13000PL-S/4P7W/830 MASTER PL-S 7W/830/4P 2G7 3000 82 400 13000PL-S/4P7W/840 MASTER PL-S 7W/840/4P 2G7 4000 82 400 13000PL-S/4P9W/827 MASTER PL-S 9W/827/4P 2G7 2700 82 600 13000PL-S/4P9W/830 MASTER PL-S 9W/830/4P 2G7 3000 82 600 13000PL-S/4P9W/840 MASTER PL-S 9W/840/4P 2G7 4000 82 600 13000PL-S/4P11W/827 MASTER PL-S 11W/827/4P 2G7 2700 82 900 13000PL-S/4P11W/830 MASTER PL-S 11W/830/4P 2G7 3000 82 900 13000PL-S/4P11W/840 MASTER PL-S 11W/840/4P 2G7 4000 82 900 13000

Compact fluorescent lamps with intergrated gearMASTER PL-T 2 Pin (NEW)

PL-T/2P13W/827 MASTER PL-T 13W/827/2P GX24d-1 2700 82 875 11000PL-T/2P13W/830 MASTER PL-T 13W/830/2P GX24d-1 3000 82 875 11000PL-T/2P13W/840 MASTER PL-T 13W/840/2P GX24d-1 4000 82 875 11000PL-T/2P18W/827 MASTER PL-T 18W/827/2P GX24d-2 2700 82 1200 11000PL-T/2P18W/830 MASTER PL-T 18W/830/2P GX24d-2 3000 82 1200 11000PL-T/2P18W/840 MASTER PL-T 18W/840/2P GX24d-2 4000 82 1200 11000PL-T/2P26W/827 MASTER PL-T 26W/827/2P GX24d-3 2700 82 1800 11000PL-T/2P26W/830 MASTER PL-T 26W/830/2P GX24d-3 3000 82 1800 11000PL-T/2P26W/840 MASTER PL-T 26W/840/2P GX24d-3 4000 82 1800 11000

MASTER PL-C 2 Pin PL-C/2P10W/827 MASTER PL-C 10W/827/2P G24d-1 2700 82 600 10000PL-C/2P10W/830 MASTER PL-C 10W/830/2P G24d-1 3000 82 600 10000PL-C/2P10W/840 MASTER PL-C 10W/840/2P G24d-1 4000 82 600 10000PL-C/2P13W/827 MASTER PL-C 13W/827/2P G24d-1 2700 82 900 10000PL-C/2P13W/830 MASTER PL-C 13W/830/2P G24d-1 3000 82 900 10000PL-C/2P13W/840 MASTER PL-C 13W/840/2P G24d-1 4000 82 900 10000PL-C/2P13W/865 MASTER PL-C 13W/865/2P G24d-1 6500 80 900 10000PL-C/2P18W/827 MASTER PL-C 18W/827/2P G24d-2 2700 82 1200 10000PL-C/2P18W/830 MASTER PL-C 18W/830/2P G24d-2 3000 82 1200 10000PL-C/2P18W/835 MASTER PL-C 18W/835/2P G24d-2 3500 82 1200 10000PL-C/2P18W/840 MASTER PL-C 18W/840/2P G24d-2 4000 82 1200 10000PL-C/2P18W/865 MASTER PL-C 18W/865/2P G24d-2 6500 80 1200 10000PL-C/2P26W/827 MASTER PL-C 26W/827/2P G24d-3 2700 82 1800 10000PL-C/2P26W/830 MASTER PL-C 26W/830/2P G24d-3 3000 82 1800 10000PL-C/2P26W/835 MASTER PL-C 26W/835/2P G24d-3 3500 82 1800 10000PL-C/2P26W/840 MASTER PL-C 26W/840/2P G24d-3 4000 82 1800 10000PL-C/2P26W/865 MASTER PL-C 26W/865/2P G24d-3 6500 80 1800 10000

MASTER PL-S 2 PinPL-S/2P7W/827 MASTER PL-S 7W/827/2P G23 2700 82 400 10000PL-S/2P7W/830 MASTER PL-S 7W/830/2P G23 3000 82 400 10000PL-S/2P7W/840 MASTER PL-S 7W/840/2P G23 4000 82 400 10000PL-S/2P9W/827 MASTER PL-S 9W/827/2P G23 2700 82 600 10000PL-S/2P9W/830 MASTER PL-S 9W/830/2P G23 3000 82 600 10000PL-S/2P9W/840 MASTER PL-S 9W/840/2P G23 4000 82 600 10000PL-S/2P11W/827 MASTER PL-S 11W/827/2P G23 2700 82 900 10000PL-S/2P11W/830 MASTER PL-S 11W/830/2P G23 3000 82 900 10000PL-S/2P11W/840 MASTER PL-S 11W/840/2P G23 4000 82 900 10000





Halogen lampsPAR16 HalogenA

HAL-P16-25-40W PAR16 HalogenA 40W 230V 25º E14 2700 100 950 2000

PAR20 HalogenA ProHAL-P20-10-50W PAR20 HalogenA 50W 230V 10º E27 2800 100 3000 2500HAL-P20-25-50W PAR20 HalogenA 50W 230V 25º E27 2800 100 1000 2500

PAR30S HalogenA ProHAL-P30S-10-75W PAR30S HalogenA 75W 230V 10º E27 2900 100 6500 2500HAL-P30S-30-75W PAR30S HalogenA 75W 230V 30º E27 2900 100 2000 2500HAL-P30S-10-100W PAR30S HalogenA 100W 230V 10º E27 2900 100 9000 2500HAL-P30S-30-100W PAR30S HalogenA 100W 230V 30º E27 2900 100 3000 2500

PAR38 HalogenAHAL-P38-10-75W PAR38 HalogenA 75W 230V 10º E27 2900 100 9500 2500HAL-P38-30-75W PAR38 HalogenA 75W 230V 30º E27 2900 100 2400 2500HAL-P38-10-100W PAR38 HalogenA 100W 230V 10º E27 2900 100 15000 2500HAL-P38-30-100W PAR38 HalogenA 100W 230V 30º E27 2900 100 3000 2500

MasterPAR20 ElectronicHAL-P20E-10-20W PAR-E 20W 230V 10º E27 3000 100 7000 5000HAL-P20E-25-20W PAR-E 20W 230V 25º E27 3000 100 1200 5000

MASTER Line ESHAL-MR50-8-20W 20W 12V 8º GU5.3 2930 100 6500 5000HAL-MR50-36-20W 20W 12V 36º GU5.3 2930 100 1000 5000HAL-MR50-8-30W 30W 12V 8º GU5.3 2980 100 11000 5000HAL-MR50-24-30W 30W 12V 24º GU5.3 2980 100 3350 5000HAL-MR50-36-30W 30W 12V 36º GU5.3 2980 100 1600 5000HAL-MR50-60-30W 30W 12V 60º GU5.3 2980 100 750 5000HAL-MR50-8-35W 12V 35W 8º GU5.3 3020 100 14000 5000HAL-MR50-24-35W 12V 35W 24º GU5.3 3020 100 4400 5000HAL-MR50-36-35W 12V 35W 36º GU5.3 3020 100 2200 5000HAL-MR50-60-35W 12V 35W 60º GU5.3 3020 100 1050 5000HAL-MR50-8-45W 12V 45W 8º GU5.3 3040 100 16000 5000HAL-MR50-24-45W 12V 45W 24º GU5.3 3040 100 5450 5000HAL-MR50-36-45W 12V 45W 36º GU5.3 3040 100 2850 5000HAL-MR50-60-45W 12V 45W 60º GU5.3 3040 100 1300 5000

MASTER Line PlusHAL-R50-10-20W 12V 20W 10º GU5.3 3100 100 6500 4000HAL-R50-24-20W 12V 20W 24º GU5.3 3100 100 1700 4000HAL-R50-38-20W 12V 20W 38º GU5.3 3100 100 800 4000HAL-R50-60-20W 12V 20W 60º GU5.3 3100 100 350 4000HAL-R50-10-35W 12V 35W 10º GU5.3 3100 100 11000 4000HAL-R50-24-35W 12V 35W 24º GU5.3 3100 100 3500 4000HAL-R50-38-35W 12V 35W 38º GU5.3 3100 100 1600 4000HAL-R50-60-35W 12V 35W 60º GU5.3 3100 100 700 4000HAL-R50-10-50W 12V 50W 10º GU5.3 3200 100 15000 4000HAL-R50-24-50W 12V 50W 24º GU5.3 3200 100 5200 4000HAL-R50-38-50W 12V 50W 38º GU5.3 3200 100 2300 4000HAL-R50-50-50W 12V 50W 60º GU5.3 3200 100 1100 4000

MASTER Line 111 HAL-MR111-8-30W 12V 30W 8º G53 3000 100 23000 4000HAL-MR111-24-30W 12V 30W 24º G53 3000 100 4000 4000HAL-MR111-45-30W 12V 45W 8º G53 3000 100 33000 4000HAL-MR111-24-45W 12V 45W 24º G53 3000 100 5300 4000HAL-MR111-45-45W 12V 45W 45º G53 3000 100 1900 4000HAL-MR111-8-60W 12V 60W 8º G53 3000 100 48000 4000HAL-MR111-24-60W 12V 60W 24º G53 3000 100 8500 4000HAL-MR111-45-60W 12V 60W 45º G53 3000 100 2800 4000

Brilliantline Pro (35mm)HAL-PR35-10-20W 12V 20W 10º GU4 3000 100 4800 4000HAL-PR35-30-20W 12V 20W 30º GU4 3000 100 690 4000HAL-PR35-10-35W 12V 35W 10º GU4 3000 100 7000 4000HAL-PR35-30-35W 12V 35W 30º GU4 3000 100 1300 4000





Brilliantline Pro (50mm)HAL-PR50-10-20W 12V 20W 10º GU5.3 3000 100 5000 4000HAL-PR50-24-20W 12V 20W 24º GU5.3 3000 100 1800 4000HAL-PR50-36-20W 12V 20W 36º GU5.3 3000 100 780 4000HAL-PR50-60-20W 12V 20W 60º GU5.3 3000 100 350 4000HAL-PR50-10-35W 12V 35W 10º GU5.3 3000 100 8000 4000HAL-PR50-24-35W 12V 35W 24º GU5.3 3000 100 3100 4000HAL-PR50-36-35W 12V 35W 36º GU5.3 3000 100 1500 4000HAL-PR50-60-35W 12V 35W 60º GU5.3 3000 100 700 4000HAL-PR50-10-50W 12V 50W 10º GU5.3 3000 100 13000 4000HAL-PR50-24-50W 12V 50W 24º GU5.3 3000 100 4400 4000HAL-PR50-36-50W 12V 50W 36º GU5.3 3000 100 2200 4000HAL-PR50-60-50W 12V 50W 60º GU5.3 3000 100 1100 4000

Aluline Pro 111HAL-R111-8-50W 12V 50W 8º G53 3000 100 23000 3000HAL-R111-24-50W 12V 50W 24º G53 3000 100 4000 3000HAL-R111-8-75W 12V 75W 8º G53 3000 100 30000 3000HAL-R111-24-75W 12V 75W 24º G53 3000 100 5300 3000HAL-R111-45-75W 12V 75W 45º G53 3000 100 3000HAL-R111-8-100W 12V 100W 8º G53 3000 100 48000 3000HAL-R111-24-100W 12V 100W 24º G53 3000 100 8500 3000HAL-R111-45-100W 12V 100W 45º G53 3000 100 3000

Aluline Pro (37mm)HAL-R37-6-15W/6V-CL 6V 15W 6º CL BA15d 3000 100 5200 2000HAL-R37-6-20W/12V-CL 12V 20W 6º CL BA15d 3000 100 6400 2000HAL-R37-18-20W/12V-CL 12V 20W 18º CL BA15d 3000 100 1500 2000HAL-R37-18-20W/12V-FR 12V 20W 18º FR BA15d 3000 100 1000 2000HAL-R37-32-20W/12V-CL 12V 20W 32º CL BA15d 3000 100 750 2000HAL-R37-32-20W/12V-FR 12V 20W 32º FR BA15d 3000 100 350 2000HAL-R37-40-35W/12V-FR 12V 35W 40º FR BA15d 3000 100 550 2000

Aluline Pro (56mm)HAL-R56-4-15W/6V-CL 6V 15W 4º CL B15 3000 100 11000 2000HAL-R56-14-15W/6V-CL 6V 15W 14º CL B15 3000 100 1900 2000HAL-R56-6-35W/6V-CL 6V 35W 6º CL B15 3000 100 18000 2000HAL-R56-14-35W/6V-CL 6V 35W 14º CL B15 3000 100 4400 2000HAL-R56-10-50W/12V-CL 12V 50W 10º CL B15 3000 100 12000 2000HAL-R56-22-50W/12V-FR 12V 50W 22º FR B15 3000 100 2000 2000HAL-R56-25-50W/12V-CL 12V 50W 25º CL B15 3000 100 2500 2000

Halogen 12V Dichroic 4 Year (35mm)N/A 12V 20W 10º GU4 3000 100 4800 4000N/A 12V 20W 30º GU4 3000 100 690 4000N/A 12V 35W 30º GU4 3000 100 1300 4000

Halogen 12V Dichroic 4 Year (50mm)N/A 12V 20W 10º GU5.3 3000 100 5000 4000N/A 12V 20W 24º GU5.3 3000 100 1800 4000N/A 12V 20W 36º GU5.3 3000 100 780 4000N/A 12V 35W 36º GU5.3 3000 100 1500 4000N/A 12V 50W 10º GU5.3 3000 100 13000 4000N/A 12V 50W 24º GU5.3 3000 100 4400 4000N/A 12V 50W 36º GU5.3 3000 100 2200 4000

Diamondline ProHAL-DR50-10-35W 35W 12V 10º GU5.3 4100 100 5400 4000HAL-DR50-24-35W 35W 12V 24º GU5.3 4100 100 1700 4000HAL-DR50-36-35W 35W 12V 36º GU5.3 4100 100 1000 4000HAL-DR50-10-50W 50W 12V 10º GU5.3 4100 100 6400 4000HAL-DR50-24-50W 50W 12V 24º GU5.3 4100 100 2700 4000HAL-DR50-36-50W 50W 12V 36º GU5.3 4100 100 1200 4000

Twistline Pro DichroHAL-TR50-25-GZ10 50W 230V 25º GZ10 2800 98 1000 3000HAL-TR50-50-GZ10 50W 230V 50º GZ10 2800 98 600 3000

Twistline Pro AluHAL-TR50-25-GU10 50W 230V 25º GU10 2800 98 1000 3000HAL-TR50-50-GU10 50W 230V 50º GU10 2800 98 600 3000

MASTER Line TC HAL-TC45W 45W 12V G8.5 3050 100 1100 5000HAL-TC60W 60W 12V G8.5 3050 100 1100 5000





Capsuleline ProHAL-C20W/12V-G4-SI SI 13691 20W G4 12V FR G4 3000 100 315 2000HAL-C10W/12V-G4-SI SI 13692 10W G4 12V FR G4 3000 100 150 2000HAL-C20W/24V-G4-ST ST 13091 20W G4 24V CL G4 3000 100 300 2000HAL-C5W/12V-G4-ST ST 13283 5W G4 12V CL G4 2800 100 60 2000HAL-C20W/12V-G4-SU SU 13078 20W G4 12V CL G4 3000 100 320 2000HAL-C10W/12V-G4-SU SU 13284 10W G4 12V CL G4 2850 100 140 4000HAL-C50W/12V-GY6.35-SI SI 13754 50W GY6.35 12V FR GY6.35 3000 100 860 2000HAL-C35W/12V-GY6.35-SI SI 13755 35W GY6.35 12V FR GY6.35 3000 100 570 2000HAL-C20W/12V-GY6.35-SI SI 13756 20W GY6.35 12V FR GY6.35 3000 100 270 2000HAL-C50W/12V-GY6.35-ST ST 13079 50W GY6.35 12V CL GY6.35 3000 100 935 3000HAL-C100W/12V-GY6.35-ST ST 13083 100W GY6.35 12V CL GY6.35 3000 100 2550 2000HAL-C100W/24V-GY6.35-SU SU 13089 100W GY6.35 24V CL GY6.35 3000 100 2220 2000HAL-C50W/24V-GY6.35-SU SU 13090 50W GY6.35 24V CL GY6.35 3000 100 850 2000HAL-C100W/12V-GY6.35-SU SU 13100 100W GY6.35 12V CL GY6.35 3000 100 2100 2000HAL-C75W/12V-GY6.35-SU SU 13101 75W GY6.35 12V CL GY6.35 3000 100 1450 2000HAL-C50W/12V-GY6.35-SU SU 13102 50W GY6.35 12V CL GY6.35 3000 100 950 2000HAL-C35W/12V-GY6.35-SU SU 13103 35W GY6.35 12V CL GY6.35 3000 100 600 2000HAL-C20W/12V-GY6.35-SU SU 13104 20W GY6.35 12V CL GY6.35 3000 100 300 2000

Capsuleline Pro MV B15d HAL-MC75W-CL 75W 230V CL B15d 2900 100 975 2000HAL-MC75W-FR 75W 230V FR B15d 2900 100 910 2000HAL-MC100W-CL 100W 230V CL B15d 2900 100 1400 2000HAL-MC100W-FR 100W 230V FR B15d 2900 100 1350 2000HAL-MC150W-CL 150W 230V CL B15d 2900 100 2250 2000HAL-MC150W-FR 150W 230V FR B15d 2900 100 2140 2000

Plusline Pro Compact (double ended)HAL-TDC60W 60W 230V R7s 2900 100 828 2000HAL-TDC100W 100W 240V R7s 2900 100 1550 2000HAL-TDC150W 150W 230V R7s 2900 100 2550 2000HAL-TDC200W 200W 230V R7s 2900 100 3200 2000

Plusline Pro Small (double ended) HAL-TDS150W 150W 230V R7s 2900 100 2250 2000HAL-TDS200W 200W 230V R7s 2900 100 3520 2000HAL-TDS300W 300W 230V R7s 2900 100 5600 2000

HalogenA Pro BTT46HAL-B60W-CL 60W 230V CL E27 2900 100 800 4000HAL-B60W-OP 60W 230V OP E27 2900 100 740 4000HAL-B100W-CL 100W 230V CL E27 2900 100 1520 4000HAL-B100W-OP 100W 230V OP E27 2900 100 1400 4000HAL-B150W-CL 150W 230V CL E27 2900 100 2420 4000HAL-B150W-OP 150W 230V OP E27 2900 100 2220 4000

HalogenA T32 ProHAL-T32-60W-CL 60W 230V CL E27 2900 100 840 2000HAL-T32-60W-FR 60W 230V FR E27 2900 100 840 2000HAL-T32-100W-CL 100W 230V CL E27 2900 100 1550 2000HAL-T32-100W-FR 100W 230V FR E27 2900 100 1550 2000HAL-T32-150W-CL 150W 230V CL E27 2900 100 2550 2000HAL-T32-150W-FR 150W 230V FR E27 2900 100 2550 2000

Incandescent lampsSpot NR-shape

NR50-40W NR50 40W 230V 30º FR E14 - 100 400 1000NR63-60W NR63 60W 230V 30º FR E27 - 100 750 1000NR80-75W NR80 75W 230V 25º FR E27 - 100 1600 1000NR80-100W NR80 100W 230V 25º FR E27 - 100 2000 1000

Spotline, crown mirrorPC45-40W-SI-CL 40W 230V E14 - 100 - 1000NR60-40W-SI-CL 40W 230V E27 - 100 - 1000NR60-60W-SI-CL 60W 230V E27 - 100 - 1000A60-B60W-SI-CL 60W 230V E27 - 100 - 1000

A65-B100W-SI-CL 100W 230V E27 - 100 - 1000

PAR38 EconomyPAR38-30-80W PAR38 80W 230V FLOOD 30º E27 - 100 1800 2000PAR38-12-80W PAR38 80W 230V SPOT 12º E27 - 100 4700 2000PAR38-30-120W PAR38 120W 230V FLOOD 30º E27 - 100 3100 2000PAR38-12-120W PAR38 120W 230V SPOT 12º E27 - 100 8200 2000





High-Intensity Discharge lampsMASTER Colour CDM-T

CDM-T35W/830 CDM-T 35W /830 G12 81 3300 12000CDM-T70W/830 CDM-T 70W /830 G12 81 6600 12000CDM-T70W/942 CDM-T 70W /942 G12 92 6600 12000CDM-T150W/830 CDM-T 150W /830 G12 85 14000 12000CDM-T150W/942 CDM-T 150W /942 G12 96 12700 9000

MASTER Colour CDM-TCCDM-TC35W/830 CDM-TC 35W /830 G8.5 3000 81 3300 9000CDM-TC70W/830 CDM-TC 70W /830 G8.5 3000 83 - 6000

MASTER Colour CDM-TPCDM-TP70W/830 CDM-TP 70W /830 PG12-2 3000 83 6000 10000CDM-TP150W/830 CDM-TP 150W /830 PG12-2 3000 85 13000 10000CDM-TP70W/942 CDM-TP 70W /942 PG12-2 4200 90 5800 10000CDM-TP150W/942 CDM-TP 150W /942 PG12-2 4200 95 12000 -

MASTER Colour CDM-TDCDM-TD70W/830 CDM-TD 70W /830 Rx7s 3000 82 6500 15000CDM-TD150W/830 CDM-TD 150W /830 Rx7s 3000 88 13250 15000CDM-TD70W/942 CDM-TD 70W /942 Rx7s 4200 92 6000 15000CDM-TD150W/942 CDM-TD 150W /942 Rx7s 4200 96 14200 15000

MASTER Colour CITY CDM-TTCDM-TT70W CDM-TT 70W/830 E27 3000 83 6300 12000CDM-TT100W CDM-TT 100W/830 E40 3000 83 9000 12000CDM-TT150W CDM-TT 150W/830 E40 3000 83 13500 12000

MASTER Colour CDM-RCDM-R20-10-35W/830 CDM-R 35W /830 PAR20 10º E27 3000 81 23000 7500CDM-R20-30-35W/830 CDM-R 35W /830 PAR20 30º E27 3000 81 5000 7500CDM-R30-10-35W/830 CDM-R 35W /830 PAR30L 10º E27 3000 81 44000 7500CDM-R30-30-35W/830 CDM-R 35W /830 PAR30L 30º E27 3000 81 7400 7500CDM-R30-10-70W/830 CDM-R 70W /830 PAR30L 10º E27 3000 83 68000 9000CDM-R30-40-70W/830 CDM-R 70W /830 PAR30L 40º E27 3000 83 10000 9000

MASTER Colour CDM-R111 CDM-R111-10-35W/830 CDM-R111 35W /830 10º GX8.5 3000 81 1400 7500CDM-R111-24-35W/830 CDM-R111 35W /830 24º GX8.5 3000 81 1600 7500CDM-R111-45-35W/830 CDM-R111 35W /830 45º GX8.5 3000 81 1800 7500

Low-wattage metal halideMHN-TD70W MHN-TD Pro 70W /842 RX7s 4200 80 5700 9000MHN-TD150W MHN-TD Pro 150W /842 RX7s 4200 85 12900 9000MHN-TD250W MHN-TD Pro 250W /842 FC2 4200 85 20000 9000MHW-TD70W MHW-TD Pro 70W /730 RX7s 3000 75 6200 9000MHW-TD150W MHW-TD Pro 150W /730 RX7s 3000 75 13800 9000

MASTER MHN-LAMHN-LA1000W 220-240V MHN-LA 1000/842 230V X528/cable 4200 80 100000 4000MHN-LA1000W 220-240V MHN-LA 1000/956 230V X528/cable 5600 90 90000 4000MHN-LA2000W 380-415V MHN-LA 2000/842 400V X528/cable 4200 80 220000 4000MHN-LA2000W 380-415V MHN-LA 2000/956 400V X528/cable 5600 90 190000 4000

MASTER MHN-SAMHN-SA1800W 220-240V MHN-SA 1800W/956 230V (P)SFC 5600 90 155000 4000MHN-SA1800W 220-240V MHN-SA 1800W/956 230V X830 ROD 5600 90 155000 4000MHN-SA1800W 380-415V MHN-SA 1800W/956 400V (P)SFC 5600 90 160000 4000MHN-SA2000W 380-415V MHN-SA 2000W/856 400V X830 ROD 5600 85 200000 4000MHN-SA2000W 380-415V MHN-SA 2000W/956 400V X830 ROD 5600 90 180000 4000

High-Intensity Discharge lampsMASTER HPI Plus on HPI gear

HPI-P250W-BU MASTER HPI Plus 250W /743 BU E40 4300 69 18000 20000HPI-P250W-BU-P MASTER HPI Plus 250W /743 BU-P E40 4300 69 18000 20000HPI-P400W-BU MASTER HPI Plus 400W /743 BU E40 4300 69 32500 20000HPI-P400W-BU-P MASTER HPI Plus 400W /743 BU-P E40 4300 69 32500 20000HPI-P400W-BUS MASTER HPI Plus 400W /743 BUS E40 4300 69 32500 20000HPI-P400W-BUS-P MASTER HPI Plus 400W /743 BUS-P E40 4300 69 32500 20000

MASTER HPI Plus on SON gearHP-P-400W-BU HPI Plus 400W BU E40 3800 69 42500 20000HP-P-400W-BU-P HPI Plus 400W BU-P E40 3800 69 42500 20000

MASTER HPI-T Plus on HPL gearHPI-T-P250W MASTER HPI-T Plus 250W E40 4500 65 19000 20000HPI-T-P400W MASTER HPI-T Plus 400W E40 4500 65 35000 20000





MASTER HPI-T Plus on SON gearHPI-T-P250W MASTER HPI-T Plus 250W E40 4000 65 23000 20000HPI-T-P400W MASTER HPI-T Plus 400W E40 4000 65 38000 20000

HPI-T ProHPI-T1000W HPI-T Pro 1000W/643 230V E40 4300 65 86000 10000HPI-T2000W HPI-T Pro 2000W/642 400V HO E40 4200 65 200000 10000HPI-T2000W HPI-T Pro 2000W/646 230V E40 4600 65 192000 10000HPI-T2000W HPI-T Pro 2000W/646 400V E40 4600 65 190000 10000

High-pressure sodium SONMASTER SON

SON-P70W MASTER SON PIA Plus 70W E27 1900 20 5900 28000SON-P100W MASTER SON PIA Plus 100W E40 2000 25 10200 32000SON-P150W MASTER SON PIA Plus 150W E40 2000 25 17000 32000SON-P250W MASTER SON PIA Plus 250W E40 2000 25 31100 32000SON-P400W MASTER SON PIA Plus 400W E40 2000 25 55500 32000

MASTER SON-T PIA PlusSON-T-P50W MASTER SON-T PIA Plus 50W E27 1950 23 4400 28000SON-T-P70W MASTER SON-T PIA Plus 70W E27 1950 23 6600 32000SON-T-P100W MASTER SON-T PIA Plus 100W E40 1950 23 10500 32000SON-T-P150W MASTER SON-T PIA Plus 150W E40 1950 23 16500 32000SON-T-P250W MASTER SON-T PIA Plus 250W E40 1950 23 32000 32000SON-T-P400W MASTER SON-T PIA Plus 400W E40 1950 23 55000 32000SON-T-P600W MASTER SON-T PIA Plus 600W E40 1950 23 90000 32000

SON ComfortSON-C150W SON Comfort Pro 150W E40 2150 65 12500 20000SON-C250W SON Comfort Pro 250W E40 2150 65 22000 20000SON-C400W SON Comfort Pro 400W E40 2150 65 37000 20000

MASTER SON-T ComfortSON-T-C150W MASTER SON-T Comfort 150W E40 2150 65 13000 20000SON-T-C250W MASTER SON-T Comfort 250W E40 2150 65 23000 20000SON-T-C400W MASTER SON-T Comfort 400W E40 2150 65 38000 20000

SON ProSON150W SON Pro 150W E40 2000 25 14500 28000SON250W SON Pro 250W E40 2000 25 27000 28000SON400W SON Pro 400W E40 2000 25 48000 28000

SON-T ProSON-T70W SON-T Pro 70W E27 2000 25 6000 28000SON-T150W SON-T Pro 150W E40 2000 25 15000 28000SON-T250W SON-T Pro 250W E40 2000 25 28000 28000SON-T400W SON-T Pro 400W E40 2000 25 48000 28000SON-T1000W SON-T Pro 1000W E40 2000 25 130000 18000

MASTER SDW-T White SONSDW-T35W MASTER SDW-T 35W /825 PG12-1 2500 83 1300 10000SDW-T50W MASTER SDW-T 50W /825 PG12-1 2500 83 2300 10000SDW-T100W MASTER SDW-T 100W /825 PG12-1 2550 83 5000 10000

MASTER SDW-TG Mini White SONSDW-TG50W MASTER SDW-TG 50W /825 GX12-1 2550 81 2400 10000SDW-TG100W MASTER SDW-TG 100W /825 GX12-1 2550 83 4900 10000

High-pressure mercury HPLHPL-C250W HPL Comfort 250W E40 3300 51 14200 16000HPL-C400W HPL Comfort 400W E40 3500 47 24200 20000HPL-N250W HPL-N 250W E40 4100 45 12700 16000HPL-N400W HPL-N 400W E40 3900 45 22000 16000

Low-pressure sodium SONMASTER SOX-E

SOX-E18W MASTER SOX-E 18W BY22d 1770SOX-E26W MASTER SOX-E 26W BY22d 3700SOX-E36W MASTER SOX-E 36W BY22d 6100SOX-E66W MASTER SOX-E 66W BY22d 10700SOX-E91W MASTER SOX-E 91W BY22d 17000SOX-E131W MASTER SOX-E 131W BY22d 26000

SOX ProSOX35W SOX Pro 35W BY22d 4300SOX55W SOX Pro 55W BY22d 7700SOX90W SOX Pro 90W BY22d 13100SOX135W SOX Pro 135W BY22d 21700SOX180W SOX Pro 180W BY22d 32000





Information Index

TYPE PAGE TYPE PAGE TYPE PAGE TYPE PAGE

60800.2 Series 5.28

AAdante diffuse 2.68Adante uplighter 2.66Amazon 13.24Annecy 12.7ArenaVision 14.4

BBasic fixed 4.57Ber lin 12.8Bilbao 12.5Bodeaux 12.10Brussels 12.11

CCambridge 12.9Carpe Diem 2.4, 3.4CBX500 4.65CDM606Y 13.6CDS501 12.11CDS502 12.11CDS503 12.12CDS504 12.12CDS505 12.13CDS506 12.13CDS530 12.4CDS531 12.4CDS540 12.5CDS541 12.5CDS550 12.6CDS560 12.7CDS560 12.8CDS580 12.9CDS590 12.10Cityvision 12.22CityZEN 12.27Comfor tVision 15.4CPS400 12.22CPS401 12.23CPS402 12.23CPS403 12.23CPS409 12.23CRX100 18.12CRX202 18.6CRX203 18.6CRX204 18.6CRX206 18.6CWH100 2.72CWH101 2.72

DDBC270 13.26DBC271 13.26DBP300 16.6DBS103 4.51DBS201 4.58

DBS202 4.58DBS203 4.58DBS205 4.58DCP300 16.8Decoflood 13.4Decovision 12.25DGP300 16.10DGP333 17.2Dueta 100 4.43Dueta 200 4.45DVF605Y 13.4DVF606Y 13.5DVP333 17.4DWP333 17.6DWP603 13.16DWP604 13.16

EEGP140Y 12.29EGP440Y 12.5Europa 2 4,38Executive 2.18

FFBF502 13.21FBF503 13.21FBH011 4.41FBH146 4.31FBH147 4.29FBH246 4.26FBR600Y 4.24FBS105 3.47FBS120 4.38FBS122 4.38FBS231 3.18FBS261 4.8FBS263 4.8FBS270 4.10FBS271 4.10FBS273 4.10FBS280 4.13FBS435 3.32FBS633 3.17FCG620 2.68FCH146 4.35FCW196 9.12FGC110 15.21FGC113Y 15.19FGC120 15.21FGS223 11.18FGS224 11.19Fibre Optics 6.8Fiorenza 5.4Fiorenza Twin 5.9FPK630Y 2.70FRC090 11.20Fugato 4.6FWC110 15.20

FWC120 15.20FWC121 15.20FWG200 2.74FWG210 2.75FWG220 2.75FWG230 2.75FWG240 2.75FWG620 2.67

GGBS011 4.42GBS120 4.39GBS122 4.39GBS146 4.37GBS246 4.28GBS261 4.21GBS271 4.21GBS280 4.21GCV100 6.23GCV200 6.24GCW216 9.9GDK090 8.5GGP091 12.25GGP092 12.25GGP141Y 12.29GGP143Y 12.29GGP148Y 12.29GGP441 12.15GGP442 12.15GGP443 12.15GGS900GGX450 7.30GGX451 7.28GGX452 7.29GGX453 7.29GGX454 7.29GGX555 7.13GGX556 7.15GMS023 7.47GMW065 9.15, 9.16GMX430 7.23GMX450 7.25GMX465 7.33GMX466 7.34GMX467 7.35GMX470 7.35GMX555 TL5 7.11GMX565 7.16GMX566 7.16GMX567 7.17GMX570 7.17Gondola 2.74GPX200 2.79GTX150 7.45

HHCP170 12.34HCP171 12.3

HDK090 8.2HDK09 IP65 8.3Helios 12.16HGC136 12.30HGC137 12.30HGC138 12.30HGP140Y 12.28HGP141Y 12.29HGP142Y 12.29HGP143Y 12.29HGP375 12.18HGP376 12.18HGP443Y 12.14HGS101Y 11.14HGS102Y 11.14HGS104Y 11.17HPP090 12.25HPS100 12.27HPS900 12.16

IIr idum 11.6IRT7090/00 2.8, 2.11

KKIT7091 2.8, 2.11

LLBS250 4.15LBS254 4.15LBS260 4.17LBS262 4.17LBS264 4.17LCS612 5.23LCS700 5.8LCV100 Kit 6.14LEDline 6.2Lightcolumn 12.14Lighting Control Systems 10.2LRG701 5.34LRG702 5.34LRG703 5.34LRG704 5.34LRG711 5.35LRG712 5.35LRG713 5.35LRG721 5.35LRG722 5.35LRG723 5.35LRG724 5.35LRM8117/00 7.43LRS612 5.23LRS700 5.6LRS703 5.10

MMalaga 11.14


Information Index

TYPE PAGE TYPE PAGE TYPE PAGE TYPE PAGE

Malmö 12.6MBF504 13.19MBF505 13.19MBN110Y 4.4MBS100 4.43MBS146 4.43MBS200 4.45MBS250 4.15MBS254 4.15MBS260 4.17MBS262 4.17MBS264 4.17MBX500 4.65MBX510 4.65, 4.67MBX512 4.67MCN690 5.12MCN810MCS410 5.31MCS420 5.33MCS430 5.33MCS440 5.31MCS450 5.31MCS610 5.20MCS612 5.23MCS703 5.10MCS520 6.16MCV524 6.16MCV528 6.17MCV535 6.18MCV536 6.19MDK090 8.2MDK090 IP65 8.3Metronomis 12.4Metronomis-2 12.11Midi Musa 5.23Milewide 15.20Mini 300 16.4Mini Decoflood 13.16Mini Musa 5.26MNF300Y 15.7MNN210Y 4.5Modella 2.60Monza 5.31MPF111 16.2MPF112 16.2MPK630Y 2.70MPP090 12.26MRN690 5.12MRN810 5.28MRS410 5.31MRS420 5.33MRS430 5.33MRS440 5.31MRS450 5.31MRS610 5.20MRS612 5.23MRS700 5.6MRS702 5.8

MRS703 5.9Musa 5.18MVF024 14.8MVF401 14.6MVF403 14.4MVF415 15.6MVF607 13.9MVF616 13.11MVF617 13.13MVP507 14.12MWF130 15.10MWF230 15.12MWF330 15.14MWG620 2.67

NNBS101 4.51NBS102 4.51NBS121 4.51

OOptiVision 14.10Oslo 12.13Ovalita-2 2.76

PPCV740 6.20PCV745 6.20PGV099 6.22Pompei 13.19Por to 12.12PowerVision 14.8

QQBD561 4.49QBD563 4.49QBD564 4.49QBD565 4.49QBD567 4.49QBD570 4.49QBN110Y 4.4QBS100 4.43QBS200 4.45QBS250 4.15QBS254 4.15QBS260 4.17QBS262 4.17QBS264 4.17QBS560 4.56QBS568 4.53QBS569 4.53QBS570 4.56QBS609 4.57QBX500 4.69QBX502 4.69QCN690 5.15QCS400 5.33QCS614 5.26

QCV310 6.12QCV310 Kit 6.14QCV311 6.13QCV311 Kit 6.15QCV330 6.12QCV331 6.13QCX500 4.73QPX500 4.71QPX501 4.71QRN690 5.15QRS400 5.33QRS614 5.26QRS701 5.8QVF415 15.17QVF416 15.17QVF417 15.17QWG200 2.74QWG210 2.75QWG620 2.66

RRCS700 5.43RCS750 5.47Rotaris 2.12, 3.7

SSBN210Y 4.5SBS100 4.43SBS200 4.45SBX500 4.65Scenio 10.10SCN690 5.12SCN810Scrabble recessed 4.63Scrabble recessed compact4.67Scrabble surface mounted 4.72Scrabble supsended 4.70SDK090 8.2SDK090 IP65 8.3SGS101Y 11.14SGS102Y 11.14SGS103Y 11.16SGS104Y 11.16SGS252 11.8SGS253 11.10SGS254 11.12SGS305 11.4SGS306Y 11.4SGS452 11.8SGS453 11.10SGS454 11.12SNF11 15.4SNF210 15.8SNF300Y 15.6Soprrano 5.12SRN690 5.12SRN810 5.28SRS419 12.20

SRS421 12.20SRS427 12.20Stealth 17.2SVF606Y 13.6SWF130 15.10SWF230 15.12SWF330 15.14

TTBH320 3.20TBS280 3.15TBS300 3.21TBS300Y 3.16TBS315 3.23TBS318 3.26TBS330 3.29TBS410Y 3.19TBS631 3.12TBS633 3.14TBS740 3.7TBS741 3.9TBX780 3.4TBX790 3.4TCG620 2.68TCS125 2.60TCS214 2.57TCS398 195mm 2.49TCS398 311mm 2.51TCS298 light-line 2.53TCS631 2.41TCS740 2.16TCW210 9.7TCW215 9.10TCW216 9.8TCW596 9.4TCX780 2.9TCX790 2.9Tempo 1 15.10Tempo 2 15.12Tempo 3 15.14Tetrix 7.44TMS023 7.46TMW065 9.14TMX400 TL5 7.8TMX TL-D 7.22TMX403 7.36TMX405 7.36TMX407 7.36Torino 12.4TPH672Y 2.38TPS498 2.46TPS670 2.39TPS672 2.39TPS673 2.39TPS740 2.14TPS745 2.14TPX200 2.77TPX701 2.20


Information Index

TYPE PAGE TYPE PAGE TYPE PAGE

TPX702 2.23TPX703 2.26TPX704 2.28TPX705 2.30TPX706 2.32TPX707 2.34TPX708 2.36TPX780 2.6TPX785 2.7TPX790 2.6TPX795 2.7Traffic Vision 11.4Trios 1.5TTX150 7.44TTX400 7.4TTX400 TL5 7.6TTX400/410 TL-D 7.18TTX403 7.36TTX405 7.36TTX407 7.36TU Combi 18.12Tunlite 18.6

VVBD010 6.27VBD20 6.30VBD30 6.30VBD50 6.30VCG010 6.27VCG230 6.29VCG240 6.29VCG250 6.29VCG660 6.29VCG670 6.29VCG730 6.28VCG740 6.28VCN810 6.35VCN910 6.38VCV020 6.21VCV500 6.22, 6.23VCV700 6.22Verona 12.28VFG510 6.33VFG540 6.33VFG610 6.41VFG620 6.41VFG630 6.41Vivara 12.30Vivara ZON 12.32VPV050 6.31VSV070 6.31VXG720 6.27VZG540 6.34VZN060 6.32VZN210 6.32VZN260 6.32VZN060 6.32VZV290 6.25

VZV340 6.25VZV470 6.25VZV510 6.34VZV540 6.34VZV810 6.36VZV910 6.39

XXGC113Y 15.19XRC090 11.20X-tendolight 2.44XWC120 15.20XWC121 15.20

ZZadora adjustable 4.47Zadora deco 4.52Zadora fixed 4.54Zadora mini 4.50ZBF503 13.22ZBF505 13.20ZBS120 4.39ZBS122 4.39ZBS203 4.58ZBS205 4.58ZBS250 4.21ZBS254 4.21ZBS260 4.21ZBS262 4.21ZBS264 4.21ZBS270 4.23ZBS280 4.23ZBS300 3.6, 3.25, 3.28, 3.31ZBS740 2.15, 2.17, 3.8ZCS398 2.48, 2.56ZCS400 5.33ZCS440 5.33ZCS700 5.38, 5.39ZCS700 5.44, 5.45ZCS750 5.38, 5.39ZCS750 5.52ZCS800 5.36, 5.40ZCW216 9.6ZCW596 9.6ZDK090 8.5ZGP440 12.15ZMW065 9.15, 9.16ZNV920 4.66, 4.69ZNX500 4.66, 4.69ZPH301 2.40, 2.48, 2.55ZPH401 2.48, 2.55ZPH501 2.48, 2.55ZPP090 12.26ZPS400 12.24ZPS498 2.48ZPS670 2.40ZPS700 5.53ZPX100 2.80

ZPX100 2.39, 5.40ZPX200 2.79ZPX300 2.80ZPX700 2.22, 2.25, 2.27, 2.31ZRC090 11.20ZRS700 5.45ZRS704 5.11ZRS750 5.49ZRS800 5.36ZTX150 7.45ZTX400 7.37, 7.39ZTX400 9.6ZTX400 TL5 7.9ZTX400 TL-D 7.22ZVF024 14.9ZVF320 14.14ZVF403 14.7ZVF605 13.8ZVF606 13.8ZVF607 13.10ZVF616 13.15ZVF617 13.10, 13.15ZVP508 14.13ZWF230 15.13ZWF330 15.15ZWP600 13.18ZZG146 4.37ZZG147 4.30ZZG185 5.25, 5.27ZZG210 5.22ZZG246 4.28ZZN145 5.22, 5.30ZZN200 4.46ZZN610 5.22ZZN612 5.25, 5.27ZZN690 5.14, 5.17ZZN860 5.22, 5.30ZZV703 6.22ZZX005 5.38ZZX010 5.38ZZX020 5.38ZZX114 5.40ZZX310 5.40ZZX312 5.40ZZX313 5.41ZZX314 5.41ZZX800 5.36

Date post:	22-Mar-2023
Category:	Documents
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