飞利浦学校照明手册

Philips EssentialLED Bulb 3000K/6500K 230VPhilips Essential LED Bulb is a sustainable green light bulb to ensure direct replacement of GLS bulbs in indoor application.With latest LED technology, Essential LED Bulb o ers over 83% energy saving and lasts 10 years (if lit 2.7 hours per day across 365 days) to save your total investment cost.From LED chips chosen to the nal assembly, di erent kinds of professional quality control methods are adopted to guarantee the light quality consistency through product lifetime.The product is professionally designed to endure surge and environmental tests to make sure it can be adapted into di erent indoor application situations.Design highlights• Form factor is designed as a direct retrofit into A60 fixtures • Over 85% energy-saving compared with GLS• Long lifetime of 10 years (if lit 2.7 hours per day across 365 days)• Warm white CCT 3000K and cool daylight CCT 6500K available • Environmental friendly, no Mercury or any other hazardous substances • Low Carbon FootprintApplication areasApplication notes• Operating temperature range is between -20 °C and 45 °C ambient• Only to apply in dry or damp locations and most of open fixtures with E27/B22 lamp- holders that offer sufficient space (10 mm free air space)• Not intended for use with emergency light fixtures or exit lights • Not intended for enclosed luminaires The qualified light makes it suitable for general indoor applications such as:• Elite shops• Corridors / Stairways / Washrooms • Lobby / Reception areas • Hotel rooms / Bars• HomeProduct type Voltage Wattage Cap Bulb CCT Lumen Luminous Lifetime CRI EEIshape e cacy label(V) (W) (K) (Lm) (=lm/W) (hours)ESS LEDBulb 4W E27 3000K 230V A60 TR 220-240V 4.0 E27 A60 3000 300 75 10000 80 A+ ESS LEDBulb 4W E27 6500K 230V A60 TR 220-240V 4.0 E27 A60 6500 310 78 10000 80 A+ ESS LEDBulb 6W E27 3000K 230V A60 TR 220-240V 6.0 E27 A60 3000 490 82 10000 80 A+ ESS LEDBulb 6W E27 6500K 230V A60 TR 220-240V 6.0 E27 A60 6500 510 85 10000 80 A+ ESS LEDBulb 8W E27 3000K 230V A60 TR 220-240V 8.0 E27 A60 3000 610 76 10000 80 A+ ESS LEDBulb 8W E27 6500K 230V A60 TR 220-240V 8.0 E27 A60 6500 640 80 10000 80 A+ ESS LEDBulb 4W E27 3000K 230V A60 UAE 220-240V 4.0 E27 A60 3000 300 75 10000 80 4 star ESS LEDBulb 4W E27 6500K 230V A60 UAE 220-240V 4.0 E27 A60 6500 310 78 10000 80 4 star ESS LEDBulb 6W E27 3000K 230V A60 UAE 220-240V 6.0 E27 A60 3000 490 82 10000 80 4 star ESS LEDBulb 6W E27 6500K 230V A60 UAE 220-240V 6.0 E27 A60 6500 510 85 10000 80 4 star ESS LEDBulb 8W E27 3000K 230V A60 UAE 220-240V 8.0 E27 A60 3000 610 76 10000 80 4 star ESS LEDBulb 8W E27 6500K 230V A60 UAE 220-240V 8.0 E27 A60 6500 640 80 10000 80 4 star ESS LEDBulb 4W B22 3000K 230V A60 UAE 220-240V 4.0 B22 A60 3000 300 75 10000 80 4 star ESS LEDBulb 4W B22 6500K 230V A60 UAE 220-240V 4.0 B22 A60 6500 310 78 10000 80 4 star ESS LEDBulb 6W B22 3000K 230V A60 UAE 220-240V 6.0 B22 A60 3000 490 82 10000 80 4 star ESS LEDBulb 6W B22 6500K 230V A60 UAE 220-240V 6.0 B22 A60 6500 510 85 10000 80 4 star ESS LEDBulb 8W B22 3000K 230V A60 UAE 220-240V 8.0 B22 A60 3000 610 76 10000 80 4 star ESS LEDBulb 8W B22 6500K 230V A60 UAE 220-240V 8.0 B22 A60 6500 640 80 10000 80 4 star ESS LEDBulb 4W E27 3000K 230V A60 SA 220-240V 4.0 E27 A60 3000 300 75 10000 80 C ESS LEDBulb 4W E27 6500K 230V A60 SA 220-240V 4.0 E27 A60 6500 310 78 10000 80 C ESS LEDBulb 6W E27 3000K 230V A60 SA 220-240V 6.0 E27 A60 3000 490 82 10000 80 C ESS LEDBulb 6W E27 6500K 230V A60 SA 220-240V 6.0 E27 A60 6500 510 85 10000 80 C ESS LEDBulb 8W E27 3000K 230V A60 SA 220-240V 8.0 E27 A60 3000 610 76 10000 80 C ESS LEDBulb 8W E27 6500K 230V A60 SA 220-240V 8.0 E27 A60 6500 640 80 10000 80 C ESS LEDBulb 4W B22 3000K 230V A60 SA 220-240V 4.0 B22 A60 3000 300 75 10000 80 C ESS LEDBulb 4W B22 6500K 230V A60 SA 220-240V 4.0 B22 A60 6500 310 78 10000 80 C ESS LEDBulb 6W B22 3000K 230V A60 SA 220-240V 6.0 B22 A60 3000 490 82 10000 80 C ESS LEDBulb 6W B22 6500K 230V A60 SA 220-240V 6.0 B22 A60 6500 510 85 10000 80 C ESS LEDBulb 8W B22 3000K 230V A60 SA 220-240V 8.0 B22 A60 3000 610 76 10000 80 C ESS LEDBulb 8W B22 6500K 230V A60 SA 220-240V 8.0 B22 A60 6500 640 80 10000 80 CLEDbulbB22E27Spectral Power DistributionSpectrum Essential LED Bulb 3000KTemperature300/310lm T c Max: 102 o C 490/510lm T c Max: 90 o C610/640lm T c Max: 105 o CTc pointSpectrum Essential LED Bulb 6500KEssential LEDBulb 4W E27/B22 3000K 230V A601 x 300 lmLight output ratio 1.00Service upward 0.81Service downward 0.19CIE ux code7 26 56 19 100UGRcen (4Hx8H, 0.25H )16Essential LEDBulb 4W E27/B22 6500K 230V A601 x 310 lmLight output ratio 1.00Service upward 0.81Service downward 0.19CIE ux code7 26 56 19 100UGRcen (4Hx8H, 0.25H )16Essential LEDBulb 6W E27/B22 3000K 230V A601 x 490 lmLight output ratio 1.00Service upward 0.81Service downward 0.19CIE ux code7 26 56 19 100UGRcen (4Hx8H, 0.25H )17Light output ratio 1.00Service upward 0.81Service downward 0.19CIE ux code7 26 56 19 100UGRcen (4Hx8H, 0.25H )18Essential LEDBulb 6W E27/B22 6500K 230V A601 x 510 lmLight output ratio 1.00Service upward 0.81Service downward 0.19CIE ux code7 26 56 19 100UGRcen (4Hx8H, 0.25H )18Light output ratio 1.00Service upward 0.81Service downward 0.19CIE ux code7 26 56 19 100UGRcen (4Hx8H, 0.25H )18Essential LEDBulb 8W E27/B22 3000K 230V A601 x 610 lmEssential LEDBulb 8W E27/B22 6500K 230V A601 x 640 lmLifetime + SustainabilityFailure Rate Curve of Essential LED bulb 3000K/6500K50%45%40%35%30%25%20%15%10%5%0%500010000T o t a l F a i l u r e R a t eHoursEssential LED Bulb has a lifetime exceeding 10,000 hours de ned as (F50L70), where:F50L70, meaning 50% in total of whole population of lamps either fail without light output or lumen maintenance lower than 70% of initial value.Lifetime estimation based on the application environment condition: at room temperature (25°C), free air burning,baseup burning position, and at rated voltage.© 2016 Philips LightingAll rights reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner. The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed without notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor imply any license under patent or other industrial or intellectual property rights.。

Interact Pro智能无线照明控制系统IoT无线照明，快速便捷升级绿色健康办公20183目录100812 1604 06你的客户就是你的生意，二者皆需要转型照明在不需要的时候可以自动调暗或关闭，员工可以个性化设置照明环境，企业主对能耗状况、灯具运行一目了然。

InterAct Pro智能无线互联照明系统架构许多大公司已经开始利用智能互联照明技术，但为什么只有大公司可以分享智能互联照明带来的红利？有了Interact Pro 系统，中小企业现在也可以创建更好的工作环境来鼓舞员工，提升生产率。

作为照明方面的专家，有了Interact Pro ，服务商除了提供高质量的照明灯具外，更可以成为智能互联照明专家值得信赖的合作伙伴。

Interact Pro 助力客户实现智能互联照明的各种可能，可以简化工作，处理更多的项目，更快完成项目，有助于建立良好的合作关系。

安装公司管理软件业主管理软件最多可达200传感器业主端安装公司端Interact Pro 功能和特点无线安装，无所顾虑Interact Pro 设计为一个云端智能互联照明系统，系统只需通过移动终端的应用程序即可实现简单的安装步骤，十分简便。

Interact Pro 实现三大功能：照明控制自动化，员工个性化设置，以及远程诊断功能1.2. 3. 4. 5. 开箱安装 Interact Pro 网关和Interact Ready 照明设备下载 Interact Pro 应用程序用Interact Pro应用程序设置系统配置通过Interact Pro管理软件进行监控和管理无所顾虑的无线安装降低前期成本快速，直观，容易学习通过在线门户网站进行简易轻松的维护简单的调试步骤无线安装优势简单安装步骤Interact Pro appInteract Pro 如何帮助你？Interact Pro 对你的客户来说意味着什么？Interact Pro 主要价值• 快速安装，无需布线• 应用程序极易上手，系统安装简便• 一个具有专业眼光的可信赖的顾问Pro照明更优 员工更舒适数据分析，价值可视化首先，有了Interact Pro, 员工可以自己设置照明，员工可以轻松根据手头的工作调整照明。

Networked ControlsThe Philips Dynalite approach hinges on the belief that notwo lighting systems are the same and that every lighting installation should be tailored to best match the customers needs. Lighting systems can be set up for automatic operation – through the use of clocks and sensors – or for manual operation, or a combination of the two. The Dynalite platform is designed to be easily configured and yet powerful enough for any customized task. When properly set up and configured, the lighting system will respond to the needs of the occupants seamlessly; optimizing lighting for the tasks at hand while ensuring energy is not wasted in unoccupied areas.Envision Manager offers a number of flexible control andmonitoring capabilities for your Dynalite system which: •facilitates two-way communication and control with each lighting system component, including sensors, user interfaces and DALI lighting fixtures.•enables monitoring of all system components, withreal-time failure alerts and reporting of maintenance issues and energy usage.•allows entire floors, buildings or campuses to be controlled remotely, through any authorized web browser-enabled devices, providing an ideal solution for offices, hotels, arenas, stadia, museums, shopping malls, leisure centers, schools, university applications and more.Benefitsof a lighting control systemSystem architecture Philips Dynalite system architecture makes choosing the right control hardware for your project easy with a broad range of load controllers available to match any type of lighting load. The system flexibility where “every product can work with every other product” and its virtually unlimited scalability, means that should you need to change the design as the project evolves, all you need to do is swap out or add on to whathas already been designed.DYNET DALIMULTIMASTER LAN KEY:DYNET DALILED INCANDESCENT FLUORESCENTCURTAINS & BLINDS LIGHTING LOAD CONTROLLER• Able to control any light source • Operates seamlessly with other parts of the system SENSOR • Surface mounted sensor monitors light level and occupancy simultaneously.• Multiple modes can be scheduled to adapt the operation for di erent time of day ENVISION TOUCH • Allows the user control their lightingand HVAC from their mobile device • Enables override of existing light levelsfor speci c tasks• Permits authorized users to rede ne saved levels for lighting scenes ENVISION SWITCH• Desktop virtual control panel gives local control to the lighting over each desk.TO BMS • Shares information with the BMS tosupport the needs of each user• Allows the BMS to control the lighting • Embedded OPC server reports statusof areas, devices, drivers and lampsto the BMS ENVISION MANAGER • Provides full system monitoringand identi es any system issues in real time •O ers a console overview page for instant system status visualization• Provides detailed system oorplans to assist with maintenanceand management ENVISION GATEWAYETHERNET • Connects each network spur tothe Ethernet backbone • Contains a local clock to runscheduled eventsSENSOR• Surface mounted sensor monitorslight level and occupancy simultaneously.•Powered directly from the DALI bus DRIVERS • Supporting individual/group dimming of orescent ttings • Supports lamp status and runtime reporting LED DRIVER • Supporting individual/group dimming of LED ttings • Supports lamp status and runtime reporting EMERGENCY FITTINGS • Supporting individual/group dimming of DALI emergency ttings • Supports lamp status and runtime reporting • Supports DALI emergency testing for functional and duration tests DRY CONTACT INTERFACE • Dry contact interface for third-party connectivity • Powered directly from the DALI bus TOUCHSCREEN • Graphical touchscreen provides a soft keypad for local control of lighting and third-party systems • Custom screens can be tailored to clients exacting speci cations • The screen can be connected directly to the LAN or to the DyNet ER INTERFACE • Attractive keypad for local room controlEnvision Manager overviewSafetyEnvision Manager enables lighting settings to be optimized based on real performance data in each area, enhancing occupant safety. The system’s ability to perform testing on DALI Emergency Lighting further ensures the safety of building occupants during emergency situations.Energy efficiencyEnvision Manager promotes energy efficiency through a number of means. It allows lighting in unoccupied areas to be switched off or dimmed down without compromising occupants’ comfort or safety and facilitates aggressive energy reduction strategies during out-of-hours or non-working periods.In addition to this, Envision Manager supports daylight harvesting schemes to balance artificial lighting with natural daylight.Load Shedding reduces non-essential lighting energy consumption and is often required as part of an energy management strategy. Envision Manager can make this easier by allowing the facility manager to define a load shed statefor each area within the building. These states can be initiated easily either directly from EM or from the building management system (BMS).Aimed specifically for projectswhere it is necessary to controland manage lighting, Envision Manager provides the idealsolution for offices, hotels, arenas, stadiums, museums, shopping malls, leisure centers, schools, university applications and more.The Envision Manager difference•Is compatible with all current Dynalite products/solutions.•Provides live energy performance monitoring display.•Controls the entire lighting system on one screen.•Macro builder allows end-users to tailor the operation of the system to their own needs.•Monitors hardware performance in real time.•Controls scheduling, reports, DALI emergency testing, preset scenes and specific events, such as Earth Hour.•Monitors the performance of all devices, drivers and lamps, with an alert function to send custom notifications.ScalabilityEnvision Manager is inherently scalable, able to handle up to 65,535 different control zones within a building and capable of multiple-site applications.AccessibilityEnvision Manager permits remote access and control of the system via a web-page, which opens up control through any web-enabled device.ComfortOccupancy comfort is supported by Envision Manager’s ability to fine-tune lighting levels to meet the exact needs of each end-user for the tasks in which they are engaged. Moreover, any system or component failures trigger immediate alerts to the facilities manager. As soon as a problem is identified, the facilities manager fix it, minimizing disruption.Envision Manager’s dashboards simplify monitoring current status and operational performance.Operational performance can be viewed by area, showing facilities managers how their lighting system is performing and helping to identify where additional savings may be possible.As well as presenting performance data, Envision Manager is able to highlight a number of additional factors such as: itemsfor attention, pending scheduled activities, the status of each area; and results of emergency lighting testing.Features •Visualizes system energy performance •Provides an analysis tool, Envision Dashboard, to compare the consumption of different areas within the building •Displays performance graphs on a screen or touchpanel to engage occupants Monitor The control aspect of Envision Manager puts the facilitiesmanager firmly in the driving seat. Individual lamps or user-defined groups of lamps can be selected and controlled from the floorplan or overview console. Macros can be created and scheduled to occur at different times of the day or different days of the week. These can be a single action, multiple actionsor reoccurring actions.The system differentiates between working days, weekendsand public holidays, creating lighting scenes that supportcomfort while minimizing energy use. For example, time-outfunctions for unoccupied areas can be set to 30 minutes duringoffice hours but reduced to five minutes during other times.Features•Real time system status•Highly granular control options•Streamlined operationControlSCALABLE CONTROL THROUGHOUTTHE BUILDINGENERGY PERFORMANCE AND OPERATIONAL DATA AT A GLANCESystem maintenance ensures ongoing occupancy safety and comfort. The ‘Lamp Manager’ identifies lamps that are approaching the end of operational life or that have already failed. The system can also identify failed drivers and other faults on the system.The ‘Alerts Overview’ summarizes current alerts on the system with details of the state of each item. This helps the facilities manager prioritize planned maintenance activities and address unplanned outages.Features •Allows staff to manage DALI maintenance, avoiding service call costs •Shows problems on the floorplan •Lamp life reports support efficient maintenance Maintain Envision Manager facilitates a wide range of lighting systemmanagement activities. •The scheduling feature enables pre-defined lighting events to occur automatically at set times or in relation to sunrise/sunset times. •The reporting feature allows system reports to be generatedon hardware status, energy consumption and DALI emergency lighting performance. The report functionalityis particularly important with the growing mandatoryrequirement in different markets for accurate reporting ofenergy usage.•The ‘Emergency Test’ feature enables DALI emergencylighting systems to be tested via the software.Features•Scheduled activities ensure the building operates as designed at all times•DALI emergency tests can be run when the building is unoccupied•Custom schedules can easily be added by the end-user ManageMANAGE PRE-DEFINED LIGHTING EVENTS, GENERATEREPORTS AND TEST SYSTEMSIDENTIFY FAULTS AND FAILURES AND ANTICIPATE THEEND OF OPERATIONAL LIFE FOR LAMPSquestionsIs the Dynalite system designed only for large buildings?What happens when our business grows and we want to expand our control system?I heard that it is very expensive to make changes to the system once it is installed. Is this true?How can I control specific lighting in my office easily without having to add expensive light switches?Why would I not just use the Building Management System (BMS) to manage my lighting?Can the Dynalite system support DALI drivers?We have color changing architectural lighting in our building. Can I control and manage these lights using Envision Manager?I have been hearing about Philips’ range of warm/cool white tuneable fittings. How do they fit in with the Envision Manager offering?。

Product guideThe first intelligent ‘plug and play’ road luminaireIridium gen3Outdoor lightingContentsThe Iridium gen3 family 3 The first intelligent ‘plug and play’ road luminaire 3 Family range 4 Lighting performance 5 Light distribution 5 Appli ations 6 Application examples 7 Luminaire features 8 Tilt adjustments 8 Spigot arrangement 8 Easy ‘plug and play’ installation in just three steps 9 Iridium gen3 in control 10 CityTouch Ready 10 Starsense Wireless with RF antenna 11 LumiStep 11 DynaDimmer 11 Iridium gen3 in perspective 12 Iridium gen3 complete sets 13 Féroé bracket 13 Mayotte bracket 13 KC bracket 14 Aloa/Accante pole 14 Main specifications 16 Specification table 17The Iridium gen3 familyThe first intelligent ‘plug and play’ road luminaireIridium gen3 is the first intelligent luminaire designed for seamless connectivity. No hassle in commissioning – just install the luminaireand control it directly from a distance through CityTouch lighting management platform. Remote light management made easy!The new ‘plug and play’ concept has been designed to ensure safe and easy installation in just three steps:1. Install the spigot2. Plug in the mains3. Tilt and close the luminaireThe luminaire’s high efficiency at system level ensures significant energy savings compared to existing conventional installations, offering afast payback. Thanks to its wide choice of lumen packages, optics and color temperatures, Iridium gen3 fits most applications on roads andin residential areas. The luminaire’s neo-classical design guarantees a consistent look and feel for your surroundings.Seamless connection from luminaire to CityTouch software without commissioning: CityTouch Ready‘Plug and play’ installation in just three stepsHigh efficiency, ensuring fast payback and low Total Cost of OwnershipFamily rangeThe neo-classical design of the new Iridium gen3 family ensures smooth integration of the luminaire in residential areas as well as on main roads. Inspired by the round shape of Iridium, the new Iridium gen3 provides the best of new LED technology while still echoing the legacy designs.Iridium gen3 Mini Iridium gen3 Medium Iridium gen3 LargeCE and S class for street and path lighting CE and S class for street and path lightingMEW class for road lightingApplicationsThe Iridium gen3 family's neo-classical round design, together with its wide range of optics and lumen packages, makes it the perfect luminaire to light residential areas, urban roads as well as provincial roads and highways.Iridium gen3 is part of our functional lighting solutions portfolio andincorporate primarily traffic functions that offer guidance and orientation, in a way that traffic safety for all participants is secured, mainly by having perfect glare control, white color rendering and uniformity quality up to all relevant standards. At the same time maximization of pole spacings is targeted by designing high performance optics, to match various lightingclasses and road geometries for traffic routes in and around cities.Traffic routeroadand Avenueroadaccess roadareaFoothpathstreetand AvenueFoothpathtransport areaTransportationtransportstationarea Road lightinglighting and Road lightingSpigot arrangementOne common spigot is used in the three sizes of the Iridium gen3 family.Tilt adjustmentsThe Iridium gen3 new and innovative separated spigot makesit possible to have post-top mounting in three positions -0°, +5°, +10°, while with side-entry the spigot provides negative tilt to fit existing brackets -0°, -5°, -10°.Luminaire featuresPost-top: 0, +5, +10°Side-entry: 0, -5, -10°Easy tilt settingPost-top Ø 60/76 mm Side-entry Ø 42/60 mmLuminaire featuresInstall spigot on the pole (post-top or side-entry)Position the luminaire on the spigotConnect the connector to the luminaire, close and tiltOptimized side-entry installation with bubble level indicatorNo segment controller No routerNo outdoor luminaire controllerNo cabinetEasy ‘plug and play’ installation in just three stepsCityTouch ReadyAutomatic connection Automatic locationAutomatic commissioningAutomatic asset data import into CityTouchlighting management platformIridium gen3 in controlPhilips offers you a complete connected public lighting system to help you overcome all the challenges you face in terms of an evolving urban environment, the movement of traffic, etc., as well as the need for flexible lighting and reduced costs.CityTouch ReadyIridium can be seamlessly connected with CityTouch via integration of all the intelligence into the luminaire without any additional hardware needed. The communication runs directly via the public mobile network. As a positive side effect, no own maintenance effort is required. Inaddition, the whole connectivity management is part of our service which keeps any hassle away from you as a customer. Once connected to the power supply a light point automatically appears on the CityTouch map at the right location – with all lighting assets imported into the system and ready to be remotely controlled by CityTouch LightWave.CityTouch LightWave is an intelligent, interactive remote management solution for your street lighting. It brings your city lighting to life and provides you with flexibility, knowledge and accuracy.Flexibility means that you will be easily able to act or react according to expected and unexpected situations by dimming or brightening all areas within your city to ensure safety and well-being. Knowledge implies that you are always informed about the current status of every single luminaire– for better maintenance and faster repairs. Accuracy stands for precise energy metering which gives you a perfect overview on real non-estimated energy consumption.Fault detection & notification A quicker and better knowledge of the current status of the lighting infrastructure enables you to manage faster maintenance and improve the maintenance service level.Control of each individual light pointYou get the flexibility to adapt every single luminaire to changing situations or demands of the city at any time. To adjust calendars to the individual needs you are free to change the “switching points” of every dimming profile simply via drag and drop.Accurate energy metering With accurate energy metering down to the level of each single luminaire it is possible to verify your energy bills and identify newpotential savings.CityTouch LightWave key featuresPhilips offers you a complete range of lighting controls to maximize yourenergy consumption by dimming and reduced light nuisance.Dimming regimesLumiStepAn integrated stand-alone control system which lowers the flux of thelight source and power consumed over a period of 6, 8 or 10 hours (3pre-programmed versions). The potential energy savings (on power system) is up to 25%, depending on the luminaires and light source used.DDF2 regime DDF1 regime DDF3 regimeDynaDimmerAn integrated stand-alone control system included in each light point- operated on electronic equipment and can be integrated into theluminaire. It can apply 5 levels of power, (re)definable on the level andduration, per chosen light point. For example, an average energy savingof approximately 50% per year can be realized.Starsense Wireless with RF antennaA system to control and monitor remotely light points, that worksindependently with practically any light source. It is not limited inavailable power scenarios. Starsense allows to have feedback from theinstallation, which supports easy maintenance. This solution can generateup to 70% energy savings and 40% on maintenance costs.Iridium gen3 in controlIridium gen3 in perspectiveThe Iridium gen3 range has been designed to offer perfect solutions, including in terms of the proportion of the luminaire to its mounting height or a specific environment.• I ridium gen3 Mini is suitable for mounting heights from 3 to 6 m,for instance on residential streets.• I ridium gen3 Medium is suitable for mounting heights from 6 to 12 m, for instance on main residential streets or urban traffic roads.• I ridium gen3 Large is suitable for mounting heights from 6 to 16 m, for instance on main urban traffic roads or highways.Mayotte bracket8 m7 m6 m5 m4 m3 m2 mIridium gen3 + Mayotte bracket9 m8 m7 m6 m5 m4 m3 mIridium gen3 + Féroé bracketFéroé bracket1. I ridium gen3 Large + Féroé bracket + Aloa/Accante pole + Féroé rear bracket +Iridium gen3 Mini2,4. Iridium gen3 Medium + Féroé bracket + Aloa/Accante pole3,6. Iridium gen3 Large + Féroé bracket + Aloa/Accante pole5,7. Iridium gen3 Mini + Féroé bracket + Aloa/Accante pole1,4. Iridium gen3 Large + Mayotte bracket + Aloa/Accante pole2,3. Iridium gen3 Mini + Mayotte bracket + Aloa/Accante pole5,6. I ridium gen3 Medium + Mayotte bracket + Aloa/Accante pole7. I ridium gen3 Large + Mayotte bracket + Aloa/Accante pole + Mayotte rear bracket +Iridium gen3 MiniIridium gen3 + Aloa/Accante pole10 m9 m8 m7 m6 m5 m4 m3 m10 m9 m8 m7 m6 m5 m4 m3 mIridium gen3 + KC bracketKC bracket1,7,12. Iridium gen3 Large + KC bracket + Aloa/Accante pole2,5,8,10,11. Iridium gen3 Medium + KC bracket + Aloa/Accante pole3,4,6,9. Iridium gen3 Mini + KC bracket + Aloa/Accante poleAloa/Accante pole1. Iridium gen3 Mini + Aloa/Accante pole2. Iridium gen3 Medium + Aloa/Accante pole3. Iridium gen3 Large + Aloa/Accante poleProduct features Iridium gen3 Mini Iridium gen3 Medium Iridium gen3 Large Type BGP381BGP382BGP383Light source Integral LED-module Integral LED-module Integral LED-moduleColor temperature• 3000 K (warm white)• 4000 K (neutral white) • 3000 K (warm white)• 4000 K (neutral white)• 3000 K (warm white)• 4000 K (neutral white)Color Rendering Index • ≥ 80 (warm white)• ≥ 70 (neutral white) • ≥ 80 (warm white)• ≥ 70 (neutral white)• ≥ 80 (warm white)• ≥ 70 (neutral white)Luminous flux 1,021 to 4,024 lm4,616 to 9,951 lm 7,372 to 15,553 lmPower 9 to 36 W depending on LED configuration38 to 86 W depending on LED configuration60 to 138 W depending on LED configuration Luminaire efficacy 100 to 126 lm/W105 to 129 lm/W103 to 131 lm/WLumen maintenance100,000 hours at L80F10100,000 hours at L80F10100,000 hours at L80F10Optic• Medium street optic (MSO)• Wide Street Optic (WSO)• D istribution Medium for wet roadconditions (DK)• Distribution Asymmetrical (DA)• Distribution Medium (DM)• Distribution Wide (DW)• Distribution Medium for comfort (DC)• D istribution Medium for wet roadconditions (DK)• Distribution Asymmetrical (DA)• Distribution Medium (DM)• Distribution Wide (DW)• Distribution Medium for comfort (DC)• D istribution Medium for wet roadconditions (DK)Installation• Post-top: 60 or 76 mm• Side-entry: 42 or 60 mm• Recommended mounting height: 4 m• Standard tilt angle post-top: 0, 5 and 10°• Adjustable tilt angle: 0, -5 and -10° • Post-top: 60 or 76 mm• Side-entry: 42 or 60 mm• Recommended mounting height: 8 m• Standard tilt angle post-top: 0, 5 and 10°• Adjustable tilt angle: 0, -5 and -10°• Post-top: 60 or 76 mm• Side-entry: 42 or 60 mm• Recommended mounting height: 10 m• Standard tilt angle post-top: 0, 5 and 10°• Adjustable tilt angle: 0, -5 and -10°Driver Built-in (self ballasted LED-module)Built-in (self ballasted LED-module)Built-in (self ballasted LED-module) Inrust current driver27 A / 150 µs80 A / 150 µs105 A / 150 µsMains voltage220-240 V / 50-60 Hz220-240 V / 50-60 Hz220-240 V / 50-60 HzMaterial• Housing: high pressure die-cast aluminum• Cover: polycarbonate, flat • Housing: high pressure die-cast aluminum• Cover: polycarbonate, flat• Housing: high pressure die-cast aluminum• Cover: polycarbonate, flatColor• Aluminum or grey• O ther RAL or AKZO colors available onrequest • Aluminum or grey• O ther RAL or AKZO colors available onrequest• Aluminum or grey• O ther RAL or AKZO colors available onrequestIP IP66IP66IP66IK IK09IK09IK09Weight6,5 kg10,5 kg14,2 kgElectrical connection Push-in connector with 3 to 5 poles Push-in connector with 3 to 5 poles Push-in connector with 3 to 5 poles Operating temperature range-30 to +35 °C-30 to +35 °C-30 to +35 °COptions• Nema socket• Photocell: mini cell 35, 55, 75 Lux• Fuse• Cable: 3, 4, 5, 6 m • Nema socket• Photocell: mini cell 35, 55, 75 Lux• Fuse• Cable: 6, 8, 9, 10, 11, 12 m• Nema socket• Photocell: mini cell 35, 55, 75 Lux• Fuse• Cable: 6, 8, 9, 10, 11, 12, 16 mDimming• LumiStep 6, 8 or 10 hours • DynaDimmer• Constant Light Output (CLO) • SDU • 1-10 V• D ALI • RF regulation • Controls systemoutput • CityTouch Ready • LumiStep 6, 8 or 10 hours • DynaDimmer• Constant Light Output (CLO) • SDU • 1-10 V• D ALI • RF regulation • Controls systemoutput • CityTouch Ready• LumiStep 6, 8 or 10 hours • DynaDimmer• Constant Light Output (CLO) • SDU • 1-10 V• D ALI • RF regulation • Controls systemoutput • CityTouch ReadyMaintenance Can be opened via screw to replace driverand LED module Can be opened via screw to replace driverand LED moduleCan be opened via screw to replace driverand LED moduleDimensions530 x 270 x 147 mm643 x 328 x 157 mm748 x 354 x 154 mmSurge protection 4 kV standard(Optional: 10 kV)4 kV standard(Optional: 10 kV)4 kV standard(Optional: 10 kV)Effective Projective Area SCx 0,024 M2 max SCx 0,031 M2 max SCx 0,039 M2 max Iridium gen3Luminaire version Product familycodeLine Color System flux(lm)System power(W)System efficacy(lm/W)Iridium gen3 MiniIridium gen3 Mini BGP381GRN11/740NW1,0219115 Iridium gen3 Mini BGP381GRN13/740NW1,21411115 Iridium gen3 Mini BGP381GRN15/740NW1,40413112 Iridium gen3 Mini BGP381GRN17/740NW1,59114112 Iridium gen3 Mini BGP381GRN19/740NW1,81514126 Iridium gen3 Mini BGP381GRN20/740NW1,85917110 Iridium gen3 Mini BGP381GRN22/740NW2,02916124 Iridium gen3 Mini BGP381GRN25/740NW2,29519123 Iridium gen3 Mini BGP381GRN30/740NW2,76523119 Iridium gen3 Mini BGP381GRN35/740NW3,17627117 Iridium gen3 Mini BGP381GRN40/740NW3,63032114 Iridium gen3 Mini BGP381GRN45/740NW4,02436113 Iridium gen3 Mini BGP381GRN11/830WW1,02510104 Iridium gen3 Mini BGP381GRN13/830WW1,21512105 Iridium gen3 Mini BGP381GRN15/830WW1,38413103 Iridium gen3 Mini BGP381GRN17/830WW1,56816101 Iridium gen3 Mini BGP381GRN19/830WW1,76516114 Iridium gen3 Mini BGP381GRN20/830WW1,84619100 Iridium gen3 Mini BGP381GRN22/830WW2,03518113 Iridium gen3 Mini BGP381GRN25/830WW2,29621111 Iridium gen3 Mini BGP381GRN30/830WW2,72425108 Iridium gen3 Mini BGP381GRN35/830WW3,18830106 Iridium gen3 Mini BGP381GRN40/830WW3,59435103Iridium gen3 MediumIridium gen3 Medium BGP382GRN55/740NW5,02738132 Iridium gen3 Medium BGP382GRN65/740NW5,93646129 Iridium gen3 Medium BGP382GRN75/740NW6,82755125 Iridium gen3 Medium BGP382GRN85/740NW7,63763122 Iridium gen3 Medium BGP382GRN95/740NW8,42971119 Iridium gen3 Medium BGP382GRN105/740NW9,25979117 Iridium gen3 Medium BGP382GRN115/740NW9,95186115 Iridium gen3 Medium BGP382GRN50/830WW4,61638122 Iridium gen3 Medium BGP382GRN60/830WW5,44546118 Iridium gen3 Medium BGP382GRN70/830WW6,37356114 Iridium gen3 Medium BGP382GRN80/830WW7,16565111 Iridium gen3 Medium BGP382GRN90/830WW7,93773109 Iridium gen3 Medium BGP382GRN100/830WW8,79383106Luminaire version Product familycodeLine Color System flux(lm)System power(W)System efficacy(lm/W)Iridium gen3 LargeIridium gen3 Large BGP383GRN96/740NW8,66666131 Iridium gen3 Large BGP383GRN106/740NW9,57375128 Iridium gen3 Large BGP383GRN116/740NW10,36682126 Iridium gen3 Large BGP383GRN125/740NW11,14790124 Iridium gen3 Large BGP383GRN135/740NW11,91598122 Iridium gen3 Large BGP383GRN145/740NW12,669106120 Iridium gen3 Large BGP383GRN155/740NW13,500115118 Iridium gen3 Large BGP383GRN165/740NW14,222123116 Iridium gen3 Large BGP383GRN175/740NW14,928131114 Iridium gen3 Large BGP383GRN185/740NW15,533138113 Iridium gen3 Large BGP383GRN81/830WW7,37261122 Iridium gen3 Large BGP383GRN91/830WW8,19969119 Iridium gen3 Large BGP383GRN101/830WW9,01278116 Iridium gen3 Large BGP383GRN110/830WW9,72185114 Iridium gen3 Large BGP383GRN120/830WW10,58995112 Iridium gen3 Large BGP383GRN130/830WW11,352104110 Iridium gen3 Large BGP383GRN140/830WW12,096113107 Iridium gen3 Large BGP383GRN150/830WW12,820122105 Iridium gen3 Large BGP383GRN160/830WW13,524131103Iridium gen3 MiniIridium gen3 MediumIridium gen3 Large。

CK系列ColorFuse Powercore eColor Fuse PowercoreeW Fuse PowercoreiW Fuse PowercoreiColor Cove MX Powercore iW Cove MX Powercore eColor Cove MX Powercore eW Cove MX Powercore iColor Cove QLX尺寸小巧，安装简便，控制精准，色温一致，可以产生缤纷变幻的照明效果，营造出动静皆宜的氛围，从而满足设计师对照明设计的各种需求。

当这些灯光的颜色、强度和速度产生变化的动态效果时，就如同赋予被照物体以新的生命，就象在灯光中呼吸、表演、炫耀。

灯光，尽情随心而变。

特别紧凑能轻松实现动态颜色变化的掠射灯具ColorFuse Powercore 是一款高质量特别紧凑的线形支架灯具，能产生优异的动态色彩变化效果，具有窄和中两种配光选择，可作为掠射，洗墙或重点照明应用。

特别紧凑的外观适合有限的照明空间，不仅能替代传统的掠射照明而且也能提供相似的照明水平和光线分布。

ColorFuse Powercore主要应用掠射洗墙重点照明容，如Light System Manager ，iPlayer ®3和ColorDial Pro ， 同时也兼容第三方控制器。

容易安装－直接连接主电压，不仅能减少外置直流电源的数量，而且也能免除特殊的控制配线方 式，同时允许灯具长距离运行。

灵活的安装方式－电源和数据电缆采用整体注模雌雄连接器，可180°转动，紧凑的305mm 长灯具 容易安装在有限制的安装环境。

同时可选择0.305m 和1.5m 连接线以适应不同的安装要求。

轨道安装 方式满足垂直或吸顶安装要求。

* 光通量测试符合IES LM-79-08标准； † L70/L50=70%/50%光通维持率(当环境温度在额定情况下，如25°C 或50°C ，光输出衰减到初始光通量的70%/50%时)测试流程符合IES LM-80-08标准； ‡ 这些数据仅提供一种参考性的指导，因为改变配置，将影响灯具的运行长度或灯具数量最新信息请查询: LED 主电压紧凑型彩色支架灯具产品特点高光通输出－具有高流明输出，总光通量大于380lm每305mm 。

本资料所列数据仅供参考，具体产品数据以产品说明书为准，如有更改恕不另行通知昕诺飞控股版权所有，未经许可，禁止全部及部分复制https:///zh-cn 2022年 印刷于上海产品目录2022年飞利浦专业经销渠道LED 照明产品系列专业经销*本手册所有数据来源于昕诺飞实验室。

目录ContentLED Lamp Series P01 LED光源系列LED Linear LightSeriesP23LED线性灯系列LED Downlight &SpotlightSeriesP49LED筒射灯系列Integrated CeilingSeriesP39集成吊顶系列LED CeilingSeriesP75LED吸顶灯系列Module DrivenSeriesP107模组驱动系列LED WholesaleLuminaireSeriesP113批发专业灯具系列SwitchSeriesP137开关系列恒亮型LED 小球泡真彩版娇小玲珑 自然真色彩• 更舒适：舒视光技术，无可视频闪，远离蓝光危害，营造舒适的照明环境，确保用眼健康 穹顶光学设计，光线照射角度相比一般球泡增加50度，有效提升光线均匀度并降低40% 眩光，提高视觉舒适度• 更真实：显色指数90以上，完美展现物体如同在阳光下真实而自然的色彩• 更小巧：小巧精致，完美契合各种类型的灯具，小空间、大亮度• 更长寿：15000小时长寿命，出色的流明维持率恒亮型LED小球泡真彩版02恒亮型小球泡真彩版恒亮型球泡真彩版商用LED PAR30L 恒亮型LED 飞碟灯经济型MR16恒亮型LED 灯泡上的交错光学网点有助于提升光线均匀分布及降低眩光• 光线较上一代飞利浦LED 球泡更均匀分布10%• 光线投射角度可增加50度并降低眩光40%穹顶透射光学设计恒亮型LED *舒适优选 怡目设计。

访问/eyecomfort 了解关于闪烁、频闪和其他标准以及产品信息恒亮型LED 小球泡真彩版 3W E27 3000K 220V 恒亮型LED 小球泡真彩版 3W E27 6500K 220V恒亮型LED 小球泡真彩版 3.5W E27 3000K 220V 恒亮型LED 小球泡真彩版 3.5W E27 6500K 220V 恒亮型LED 小球泡真彩版 5W E27 3000K 220V 恒亮型LED 小球泡真彩版 5W E27 6500K 220V 恒亮型LED 小球泡真彩版 6.5W E27 3000K 220V恒亮型LED 小球泡真彩版 6.5W E27 6500K 220V 恒亮型LED 小球泡真彩版 8W E27 3000K 220V 恒亮型LED 小球泡真彩版 8W E27 6500K 220V 恒亮型LED 小球泡真彩版 3.5W E14 3000K 220V 恒亮型LED 小球泡真彩版 3.5W E14 6500K 220V 恒亮型LED 小球泡真彩版 6.5W E14 3000K 220V恒亮型LED 小球泡真彩版 6.5W E14 6500K 220V白色白色白色白色白色白色白色白色白色白色白色白色白色白色30006500300065003000650030006500300065003000650030006500220-240220-240220-240220-240220-240220-240220-240220-240220-240220-240220-240220-240220-240220-24025025035035045045055055075075035035055055015000150001500015000150001500015000150001500015000150001500015000150009290029736099290029737099290029740099290029741099290029742099290029743099290029744099290029745099290029746299290029747299290029750099290029751099290029754099290029755093W/E273W/E273.5W/E273.5W/E275W/E275W/E276.5W/E276.5W/E278W/E278W/E273.5W/E143.5W/E146.5W/E146.5W/E149090909090909090909090909090经济型GU10恒亮型Globe 经济型LED恒亮型LED 柱泡全幅大广角 柔光更明亮• 更明亮：柱型设计使发光角度扩大10%，涡型导光设计使出光面增加15%，结合高亮度设计令亮度 提升18%，打造更明亮的空间；长时间使用，亮度依旧• 更舒适：涡型导光设计使光更加均匀，舒视光技术无可视频闪，远离蓝光危害，保护用眼健康• 更真实：展现环境和物体在太阳下的真实色彩• 更长寿：15000小时寿命，使用时间是节能灯的2倍• 更省电：达到相同亮度时比节能灯省电43%，节约电费护目低眩光 生活真色彩更舒适：舒视光技术，无可视频闪，远离蓝光危害，营造舒适的照明环境，确保用眼健康50度，有效提升光线均匀度并降低以上，完美展现物体如同在阳光下真实而自然的色彩级标准，与白炽灯相比节能高达80%**以上恒亮型LED 柱泡04*舒适优选 怡目设计。

OEM Design GuidePhilips MasterColor ®CDM Elite MW Lighting SystemOEM Design Guide Philips MasterColor®CDM Elite MW Lighting SystemContents1.General Introduction of PhilipsMasterColor®CDM Elite MW System (3)2.Ordering Information (4)3.Dimension and Mechanical Design (4)4.T emperature Behavior (5)5.Wiring (5)6.Electromagnetic Interference(EMI) (5)7.Factory Handling (6)8.Installation/Mounting (7)9.Operating in Abnormal Conditions (7)10.Specifications (8)11.Frequently Asked Questions (11)Product descriptionMasterColor ®CDM Elite MW is a medium wattage lighting solution based on Philips unique CDM technology.This new system consists of a specially developed lamp,ballast and socket,which provides high quality and high efficient white light in combination with long life.The MasterColor ®Elite product offering will include two wattages (lumen packages)and two color temperatures:•4200K available 2009•Protected designs are under evaluation and may become an option in the futureOne of the key features of this lamp/ballast system is the system efficacy (>100LPW)and the high Lumen Maintenance.MasterColor CDM Elite Spectral Power DistributionGeneral Introduction of Philips MasterColor ®CDM Elite MW System23-24210W3000K Non-protected 210W/3K 4200KNon-protected 210W/4K 36–37315W 3000K Non-protected 315W/3K 4200KNon-protected315W/4KLamp EfficacyLumen Maintenance1.OEM Design Guide Philips MasterColor CDM Elite MW Lighting System 31)Rated average life is the life obtained,on the average,from large representative groups of lamps in laboratory tests under controlled conditions at 10or more operating hours per start.It is based on survival of at least 50%of the lamps and allows for individual lamps or groups of lamps to vary considerably from the average.Ballast DimensionsDimensions of Metal housing (excluding grommets)is 188x 124x 57mm,see drawings below.Socket DimensionsOrdering InformationPacking will be Mid-pack,12pieces in one box for each lamp and ballast.Dimensions and2.3.Lamp DimensionsLamp dimensions for both the MasterColor ®CDM Elite 315W and 210W are the same and can be found below.4OEM Design Guide Philips MasterColor CDM Elite MW Lighting SystemT emperature Behavior Following temperature limits have to be taken into account for the MasterColor CDM Elite315W and210W:T emperatures are measured on burning lamps.Exceeding the maximum temperature will not guarantee optimal performance (lifetime,lumen maintenance).Application tips for optimal thermal performance:•Ensure good thermal contact on the side with the mounting feet •Minimize air gaps for maximum heat transfer•Shield lamp heat Lifetime and temperatureThe temperature is the most important parameter for lifetime and reliability.In the design of the lamp and ballast,everything is done to keep the temperature as low as possible.But the luminaire can affect that.Therefore,the design of the luminaire and its ability to guide the heat out of the luminaire is very important.WiringConnectionLamp:Blue and red wireInput:Black(line200-277V),White(Neutral)and Green(Earth Ground)Dimming Leads:Violet and GreyAll lead lengths are18.0"+/-1.0".Red lead must be connected to center terminal of lamp in case of a screw base.Do not connect red or blue wire to neutral or line. The maximum distance between lamp and ballast is30feet(1nF of lamp load)Electromagnetic Interference(EMI)The ballast is tested and approved according to FCC regulations;however,when mounted in a luminaire,different behavior can be found.T o assist in the reduction of radiated EMI,the ballast should be grounded by either mounting feet or green ground wire.5.6.4.OEM Design Guide Philips MasterColor CDM Elite MW Lighting System5Factory HandlingFixation in luminaireMounting feet can be bent over if mp Date Code System:0to 9:Representing last number of the calendar year.A to M (excluding I):Representing January to December.Note:During odd numbered decades,the first character designates the year of manufacture;the second character designates the month of manufacture.During even numbered decades,the first character designates the month of manufacture;the second character designates the year of manufacture.Designations are listed below and example shown to the right:Ballast Date Code System:For tracking purposes,every ballast will be marked with a date-code after the final testing.The code consists of productionY ear and Day of theY ear .Last two (2)digits of year:2000=00,2006=06,2099=99.Day of Y ear:Sequential Julian date,January 1=001,December 31non-leap years =365,December 31leap year =366.IBM Code:Code from Identification of Ballast Model Data Base.For those units not having an assigned IBM Code,the placeholders XXX shall be inserted to maintain the 2x 8character integrity.Plant Code:F =PLEM TijuanaSAP Work Order Number:Manufacturing lot work order as assigned by the SAP system7.Note:The decade 2000to 2009is considered even.6OEM Design Guide Philips MasterColor CDM Elite MW Lighting SystemInstallation/MountingLamps that can be driven by the ballastMasterColor®CDM Elite MW210W or315W can be driven with the Advance e-Vision ballast.Suitable application for the Advance e-Vision ballast Input voltage:200V-277VOperating in Abnormal ConditionsThermo-switch behaviorIf the ballast is used at too high temperatures,a so-called thermo-switch will switch off the ballast to protect it against damage.The ballast will automatically turn off at a case temperature of90ºC±5ºCInput voltageThe ballast is designed to operate within an input tolerance of ±10%.In this range,the lamp power is regulated within±3%of its nominal power.Because the ballast will regulate the lamp to a constant power,the input current will increase when the input voltage is lower.This will ultimately influence the power losses,so the worst-case temperature should therefore be measured at lowest mains voltage.Over voltageThe ballast has a limited protection against over voltage and the ballast will switch off at mains voltage above330V;this will however negatively influence the lifetime and reliability.It is advised to prevent higher mains voltages than+10%.The ballast will attempt to reignite the lamp once input voltage goes back down below310V.OvercurrentProtection against surges are built in the ballast.(6KV ring wave(diff.Mode),Common mode2KV)EOL lamp protectionThe ballast has a protection against End Of Life Lamps.The ballast will detect these lamps and switch off.Mains needs to be cycled (>2seconds)to reset ballast.9.8.OEM Design Guide Philips MasterColor CDM Elite MW Lighting System7Note:For Enclosed fixtures only.For horizontal operation,the lamps are not recommended to rotate over 90°in sockets after operation.When turning an operating lamp orientation over 90°,or turning a non-operating lamp over 90°then switching it on,there is a risk for arc tube to rupture.This holds during operation as well as after a cooling period after switching off the lamp.If one wishes to rotate the lamp over more than 90°around the lamp axis,one should do so in steps of less than 90°and let the lamp burn for at least 2hours between steps.1)Measured at 100hours of life in a horizontal operating position.2)Approximate lumen output at 40%of lamp rated average life.3)Rated average life is the length of operation (in hours)at which point an average of 50%of the lamps will still be operational and 50%will not.Lamp T echnicalSpecifications for the MasterColor ®CDM Elite MW 315W lamp at 100hoursApprox.Initial Lumens 1Lm 37,800Approx.Design Lumens 2Lm 34,000Lumen Maintenance %80@20khrs Efficacy Lm/W 120Lamp Voltage V 100Lamp power W 315W Color T emperature K 3000Color Rendering CRI 90R9>45Operating position Universal Lamp base PGZ18Rated Average Life 3K 20,000hrs.Specifications for the MasterColor ®CDM Elite MW 210W lamp at 100hoursApprox.Initial Lumens 1Lm 24,150Approx.Design Lumens 2Lm 21,700Lumen Maintenance %80@20khrs Efficacy Lm/W 115Lamp Voltage V 100Lamp power W 210W Color T emperature K 3000Color RenderingCRI 90R9>40Operating position Universal Lamp base PGZ18Rated Average Life 3K20,000hrs.Specifications10.8OEM Design Guide Philips MasterColor CDM Elite MW Lighting SystemBallast T echnical InputMains voltage V mains Operational performance 180277305V Operational safety 4160330V Mains frequency f mains Operational performance 47.563Hz Operational safety 4566Hz Mains power P mains P la =210W233W Mains current I mains At P la_nom ,V mains =200V TBD A At P la_max ,V mains =180V TBD APower factor Within oper.performance mains and at P la_nom 0.90.95DistortionTHD15%Within oper.performance mains and at P la_nomInrush current I mains_pk V mains =200V ,Z mains =0.4Ω+0.8mH<TBD AEMIFCC,Title 47.Part 18.Subpart CNon-consumer (Class “A”)InputMains voltage V mains Operational performance 180277305V Operational guideline 4160330V Mains frequency f mains Operational performance 47.563Hz Operational guideline 4566Hz Mains power P mains P la =315W353W Mains current I mains At P la_nom ,V mains =200V TBD A At P la_max ,V mains =180V TBD APower factor Within oper.performance mains and at P la_nom 0.90.95DistortionTHD15%Within oper.performance mains and at P la_nomInrush current I mains_pk V mains =200V ,Z mains =0.4Ω+0.8mH<TBD AEMIFCC,Title 47.Part 18.Subpart CNon-consumer (Class “A”)4)The input of the driver is protected against transients and over voltage.These typically occur at below or above V,beyond which point the driver will fail (not repairable by the end user).Output (lamp side)Lamp power P la V mains ±10%(P la_nom )210W Ignition voltage V ignC load <1nF53.03.54.0kV pkOutput (lamp side)Lamp power P la V mains ±10%(P la_nom )315W Ignition voltage V ignC load <1nF53.03.54.0kV pk5)Typical cable capacity 100pF/3'Dimming•Ballast will not dim when it is set to210W setting•Ballast is designed to be able to dim the lamp using a 0-10V interface•Ballast will wait for10min at full power before it can start dimming•Lowest dim level:50%of ballast power •Dimming rate:TBD•Dimming Curve:Following graph shows the Nominal dimming curve120100806040200.0 1.0 2.0 3.0 4.0 5.0 6.07.08.09.010.0Dim VolPower(%)Dim Vol vs.PowerIgnition TimingT0<1sT130sT260sT360sT40.5sTMAX30minN4Specifications(continued)OEM Design Guide Philips MasterColor CDM Elite MW Lighting System9Rated Average Life 1:60,000hrs @T c =80°C Failure Rate:<0.25%/1,000hrs @T c =80°CProtections:Against lamp end of life,against overheating(when Tc exceeds 90°C),against not connected lamp,against short circuited lampImmunity:T ransient protection to comply with 6kV ring wave (diff.Mode),common mode 2.0kVIEC1547;surge test levels phase to phase or phase to neutral:1kV .Any phase to ground:2kV .Mains dips:according IEC1547Approbation:UL,CSA Standards:UL935,UL1029Vibration:IEC 68-2-6-Fc (Frequency 10…150Hz,acceleration 2G or amplitude 0.15mm.Frequency change 1oct/min,3directions,5sweeps/direction)Bumps:IEC 68-2-29-Eb (Acceleration 10G/16ms,1000bumps/direction)ULN-D 1672(Acceleration 30G,2per direction)Drop test:UND 1400T emperature shock:IEC 68-2-14-Na (5cycles –25…+80°C,30min.,2chamber method)T emperature cycle:IEC 68-2-14-Nb (400cycles –20…+100°C)T emperature:-30°C <T amb <45°C (Depending on luminaire)Humidity:Ballast to be built into a sealed enclosure (IP63),relative humidity <85%(under all operating conditions)Storage:–30°C <T amb <80°C relative humidity <95%(non condensing)Hum and Noise:<30dBA at nominal operating conditionsSpecifications(continued)10.10OEM Design Guide Philips MasterColor CDM Elite MW Lighting System1)Rated average life is the life obtained,on the average,from large representative groups of lamps in laboratory tests under controlled conditions at 10or more operating hours per start.It is based on survival of at least 50%of the lamps and allows for individual lamps or groups of lamps to vary considerably from the average.Frequently Asked Questions11.Q1:Can the Advance e-Vision ballast be used with all ceramicmetal halide lamps?A1:No,the Advance e-Vision ballast has been designed to becompatible only with Philips MasterColor®CDM EliteMedium Wattage Lamps.Q2:Is this product also available in347-480V version?A2:Not at this time,other input voltage ranges are underconsideration.Q3:Is there a protected lamp version?A3:Not at this time.A protected lamp version may be availablesometime in the future.OEM Design Guide Philips MasterColor CDM Elite MW Lighting System11Philips Lighting Company200Franklin Square DriveP.O.Box6800Somerset,NJ08875-68001-800-555-0050A Division of Philips Electronics North America CorporationPhilips Lighting281Hillmount RoadMarkham,OntarioCanada L6C2S31-800-555-0050A Division of Philips Electronics Ltd.10275West Higgins RoadRosemont,IL60018-56031-800-322-2086A Division of Philips Electronics North America Corporation©2008Philips Lighting Company,A Division of Philips Electronics North America CorporationAll rights reserved.Reproduction in whole or part is prohibited without the prior written consent of the copyright owner.The informationpresented in this document does not form part of any quotation or contract,is believed to be accurate and reliable and may be changedwithout notice.No liability will be accepted by the publisher for any consequence of its use.Publication thereof does not convey nor imply anylicense under patent or other industrial or intellectual property rights.This guide is for OEM use only.Data subject to change without notice.05/08P-5963。

Correspondence Course Lighting ApplicationLighting Design andEngineering Centre History of Light and LightingContentsIntroduction3 1. The role of lighting in modern32. History of light sources5 2.1 Before the advent of the lamp5 2.2 The oldest lamps5 2.3 Gaslight8 2.4 Electric lighting before the incandescent lamp11 2.5 The incandescent lamp14 2.6 Discharge lamps212.7 History of electricity production and distribution253. History of light in science28 3.1 Greek and Mediaeval times28 3.2 The seventeenth and eighteenth centuries29 3.3 The nineteenth century303.4 The present century304. History of lighting technology32 4.1 History of photometry32 4.2 Lighting societies33 4.3 Modern lighting technology34 Conclusion35(c)Philips Lighting B.V. 1984 All rights reserved. No part of this publication may be reproduced, stored in a retrieval system or transmitted in any form or by any means, electronic, mechanical, photocopying recordingor otherwise without the prior permission of Philips Lighting B.V.Printed in The NetherlandsIntroductionThe story of the history of light and lighting is a fascinating one, going backalmost as far as the history of mankind. It started when man learned tocontrol fire, and for thousands of years afterwards the simple flameremained the only source of artificial light available. Subsequent attempts torefine the process of light generation and separate it from heat productioncan be roughly divided into four stages:Four important stages in the development of light sourcesStage 1 was marked by the wish to produce a constant flame, which couldbe left relatively unattended for a longer period. This resulted, still in thestone age, in the first bowl-type lamps, burning animal or vegetable oil andfitted with a wick, and later - probably in Roman times - to the invention ofthe candle. The lamp and the candle, like the torch, made light ‘portable’.The next big stride in the development of light sources took place just twocenturies ago, when the first successful steps were taken to increase thelight output of the flame. The physicist Ami Argand it was who gave hisname to the tubular burner, which launched the era of lighting technology.The third stage began a little over a century ago, when the flame as a lightsource was abandoned in favour of an incandescent solid body. Theincandescent electric lamp and the gas mantle were the two importantinventions during this period of development.Finally, in the second decade of the present century, it became possible toproduce light without wasting energy on its traditional byproduct - heat, fordischarge lamps in various forms went into commercial production.Development of these lamps is still in full swing today.Parallel to the development of light sources, came the increase in ourknowledge of the nature and behaviour of light. Commonplace though itmight have been, the controversy among philosophers and scientists aboutthe exact nature of light raged for centuries, and was not finally settled untilcomparatively recently.Lighting technology Scientific investigation into the proper application of light - LightingTechnology - started comparatively late, as was the case with most multi-disciplinary sciences. National lighting societies sprang up in Europe and theUnited States in the first decade of the present century. Their activities wereput on an international footing by the foundation of the ‘Commissionlnternationale de l’Eclairage’ (CIE) or ‘International Lighting Commission’, inwhich experts from all parts of the world and from all provinces of science,technology and design contribute to the expansion of our knowledgesurrounding lighting and lighting application.1. The role of lighting in modern societyIt is difficult to overestimate the importance of artificial light in our present-day society. Without it, commercial, social and cultural life would come to avirtual stand-still with the onset of darkness. And yet task lighting - designedto allow work to continue after dark, rather than facilitating basic orientation -like so many other achievements is a by-product of the Industrial Revolution.3Fig. 1 A simple oil-flame - in addition to the light from the open fire - was theonly source of light available in an average household before the nineteenthcentury. The man entering from outside carries a portable lightThe influence of the Industrial RevolutionThis started at the beginning of the eighteenth century, and would in a fewhundred years change the face of the earth as never before in the history ofmankind. It was more than just a technical revolution, it was an economicaland social one too, that brought with it industrial mass production andmechanized transport.It also meant the end of a way of life that was dictated by the daily passageof the sun and the change of seasons, a way of life that had changed verylittle over thousands of years. Daylight and weather still continued to governagricultural activity, and with it the associated crafts and trades. Although oillamps and candles existed, the costs of the fuel they burned was so high asto make it uneconomical to continue most types of economic activity afterdarkness, and for the poorer classes of the population - the great majority -the open domestic fire remained the only source of light (Fig. 1).More and cheaper light All this changed dramatically with the advent of planned production and theorganised long-distance transport of people and goods. Contemporarylighting was both inadequate and expensive, and so seriously hamperedexpansion of these activities. Consequently inventors were pressed to turnto alternative light sources, and at the same time reduce the costs of fuel.The success of their efforts is clearly demonstrated by the followingexample. Compared with the most advanced light source currently availablefor domestic use, the SL* lamp, candles producing the same amount of lightwould be approximately 2000 times more expensive in terms of energyconsumption, a staggering figure indeed!We are reminded of the almost mystical role that artificial light played in thepast by the fact that in many cultures the lamp is still seen as a symbol,associated with truth, inspiration, progress, hope and wealth (Alladin!).Indeed, it is safe to state that our present-day society would beunrecognizable without artificial lighting.42.History of light sources2.1Before the advent of the lampThe harnessing of fire Artificial light entered into the history of mankind with the harnessing of fire.This, along with the introduction of the first primitive tools, must have beenone of man’s earliest achievements. Needless to say, in those early daysfire was certainly not primarily used as a light source, but rather for itswarmth, as a protection against animals, and to prepare food. And yet itcould not have been long before the first portable light source was‘invented’, in the form of primitive torches made from the branches ofresiniferous trees.2.2The oldest lamps2.2.1Primitive oil lampsOil lamps were used all over the worldThe oldest known artifacts made especially for lighting purposes date from atleast 20 000 years ago. They take the form of primitive oil lamps; made of ahollowed-out stone (Fig. 2 left). The same basic design of lamp has beenused all over the world, remaining principally unchanged until well into theeighteenth century. It consisted basically of a fuel reservoir and a wick,sometimes completed by a pedestal or suspension device and a collector forspilled oil.Vegetable or animal oil or fat was burned in these lamps. During the latercenturies in Europe either olive or colza oil was generally used, as it burnedwith a steady, smoke-free flame. The wick would be made of bark, moss orplant fibres, and was either free-floating, supported by a spike, or laid in asloping groove or lip in the rim of the reservoir (Fig. 2 centre). With latertypes of oil lamp the wick was usually led through a spout (Fig. 2 right).2.2.2CandIes and torchesToday’s candles differ considerably from those before 1800Compared with the oil lamp the candle is relatively recent, and is said tohave been invented by the Romans soon after the birth of Christ. The firstcandles were made either of hard animal fat (tallow) or beeswax. The latterwere of superior quality, but also far more expensive.Fig. 2 Oil-lamps, made of a hollowed-out stone (left), of earthenware in theform of a shell (centre), and of brass with a spout (right).5Fig. 3 A bog-deal torch foruse indoors.At the end of the eighteenth century an urgent need arose for a candlematerial of better quality than tallow, but less costly than beeswax. Fromabout 1830 on, stearine became popular, a product obtained by chemicaltreatment of animal or vegetable fat or oil. Finally, in the second half of thenineteenth century, paraffin became available for candle-making. This is adistillation product of mineral oil or pitch, but can also be obtained from theresidues of coal-gas production. These new materials, together with thebraided cotton wick, which was introduced around 1800, resulted in thedomestic candle as we know it today.‘Poor-man’s’ versions of the candle - mainly used in Northern Europe - werethe rushlight, a piece of stripped rush dipped in molten tallow, and the bog-deal torch, a splinter of long-burning pine wood found in peat bogs (Fig. 3).Outdoor lighting usually took the form of torches or flambeaux, which weresticks topped off with rope or tow and dipped in resin, fat or pitch. They wereused to illuminate outdoor festivities, and were carried by runners to light theway for the carriages and sedan chairs of the rich.2.2.3Further development of the oil lampThe economic and social pressure for more, better and cheaper lighting,brought about by the Industrial Revolution, led, from about 1780 on, to aflood of inventions, aimed either at improving existing light sources(especially the oil lamp) or at the development of completely new methods oflight production - for example gas lighting, and later on electric lighting.The tubular oil burner A first step toward improving the light output of the oil flame was made in1784, when the Swiss physicist Ami Argand invented a round burner with atubular wick, which was named after him (Fig. 4). As air is drawn up insidethe wick, combustion is improved, resulting in an increase in light output fromthe flame and less risk of smoke. The upward air draught was considerablyincreased by the subsequent invention, by Argand’s partner Quinquet, of theglass chimney.Vegetable oil was used exclusively in these improved lamps. As this issomewhat sticky by nature, much thought was given to finding methods toensure a constant supply to the burner without overflowing. From 1836 on,the ‘Moderator lamp was introduced. This was fitted with a spring-loadedpiston to pressure-feed the burner (Fig. 5).6Fig. 4 A typical Argand burner, fitted with a Fig. 5 A ‘Moderator’ lamp for colza oil, withflame spreader.pressure-feed to the burner.Mineral oil replaces vegetable oilBecause of the relatively high price of vegetable oil and its tendency to clog theburner, making frequent cleaning necessary, a fuel that could be used as asubstitute was eagerly sought after. In 1847 the Scotsman James Youngdiscovered a refining process for mineral oil, and thus produced the first paraffinoil. It proved to be an ideal fuel for oil lamps, rapidly replacing vegetable oil after itbecame cheaply available around 1860.In less than a century the oil lamp had evolved from a rather primitive lightsource into one that was highly effective. The largest single-f lame types, asused in churches, schools and public rooms, had a light output of some 2500lumens. Furthermore, availability of cheap fuel helped its proliferation at all levelsof Victorian society, and even the most modest of house-holds had at least adozen lamps at their disposal.Apart from differences in size and decoration, a host of specially adapted lampscame about, for portable, industrial and marine use, as well as for street andvehicle lighting. Perhaps the most famous among these special versions is theminer’s safety lamp, invented in 1813 almost simultaneously by GeorgeStephenson and Sir Humphry Davy. It is still used today in coal mines, althoughno longer for general lighting purposes (Fig. 6).Oil lamps for street lightingStreet lighting on any scale was unheard of before the middle of the seventeenthcentury -people going out after dark carried their own lights. The invention of anoil lantern specially suited to street lighting is usually attributed to the DutchmanJan van der Heyden, who first used it to light the streets of his home townAmsterdam in 1669. The all-enclosed lantern housed a shouted oil lamp, fittedwith a special reservoir that maintained a constant oil level on the wick (Fig. 7).In the following fifty years most of the major cities of the old world received streetlighting, be it on a very limited scale by present-day standards. From 1810 on,gas lighting quickly gained ground in towns, it being both cheaper on fuel andmaintenance, but in rural areas the oil lantern lasted well into the presentcentury.By 1870, development of the oil lamp had almost come to an end. The onlysignificant improvement made after that date was in around 1895 when Auer vonWelsbach’s gas mantle (q.v.) was adapted for use with oil lamps. In some casesthe oil reservoir was also pressurised to improve combustion (Fig. 8).7Fig. 6 A ‘Davy’ miner’s safety Fig. 7 Oil-burning street lantern Fig. 8 Modern pressurizedlamp with a flat wick for of the type introduced in paraffin oil-lamp, fitted with anparaffin oil.Amsterdam in 1669 by Jan van incandescent mantle.der Heyden.2.3Gaslight2.3.1Early historyThe existence of flammable gas was known for ages, but it was not until theeighteenth century that man attempted to use it to his benefit. The earliestexperiments using gas for lighting purposes were carried out by threescientists, independently of each other. They were the Dutchman JanMinckelers, who in 1783 produced coal gas to light his lecture room at theuniversity of Louvain, the Englishman George Dixon, and the FrenchmanPhilippe Lebon.The first to exploit coal gas commercially must have been William Murdock, aScot. In 1803 he successfully lighted the Soho works of the Boulton and WattCompany, where he was employed. The following year he sold a lightinginstallation with fifty lights to a cotton spinning mill in Salford, nearManchester. Over the following years the capacity was extended to cover thewhole premises, the owner claiming that, compared with tallow candles,annual lighting costs had dropped to a fifth.Gas was first used for street lightingThe idea of centralising gas production and distributing it over the townthrough a network of pipes came from a German working in London, oneFriedrich Albert Winzer, or Winsor as he called himself in England. He wasneither an engineer, nor a scientist, but a businessman of considerableenterprise who was able to interest political and financial circles in his plan.In 1807, after a successful demonstration in London, he formed the NationalLight and Heat Company which, after being renamed to the Gas Light andCoke Company in 1812, would grow to be the largest gas company in theworld. Yet, in those early days, gas lighting was far from ideal. Supply waserratic and the pressure in the mains would drop to almost zero during peakloads. The smell of the insufficiently purified gas restricted its use indoors,and the price was still high. Nevertheless, because of the low maintenancecosts of the lamps, it was strongly favoured for street lighting. Heavycompetition - in 1823 there were in London alone already three rival gascompanies meant that the quality of the gas and the reliability of its supplyquickly improved, while the price dropped steeply during the same period.82.3.2Gas productionCoal gas is produced by heating bituminous coal in cast-iron retorts, in theabsence of air. The methane liberated during this process is cleaned ofundesirable admixtures before being stored in the gasometer, today still awell-known landmark in many towns. From there it is pressure-fed into themains, either by pumping or by the weight of the movable upper part of thegasometer. What is left in the retorts is highly carboniferous coal, calledcokes, which is used for the production of iron from its ore in blast furnaces,or for heating purposes.2.3.3Gaslight burnersFlat-flame and Argand burnersThe first gaslight burners were nothing more than narrow apertures at Theends of pipes. The number and configuration of the openings gave theflame(s) a specific shape, and thus names like ‘rat-tail’, ‘cockspur’ and‘cockscomb’ burner evolved.As with oil lamps, attemps were made to increase the light output of the gasflame. This resulted in the introduction of flat-flame burners, named ‘bats-wing’ or ‘fish-tail’ burners after the shape of the flame. In 1809, SamuelClegg managed to adapt the Argand burner for use with gas, which - fittedwith a glass chimney - would remain the most popular type until theintroduction of the gas mantle (Fig. 9). A further improvement, aimed atincreasing the efficiency of the lamp, was introduced in 1886, whereby theincoming air needed for combustion was preheated by the flue gases. Thisresulted in the so-called regenerative lamp (Fig. 10).2.3.4 The gas-mantleA dramatic step foreward was made in 1887. Following numerous attemptsby a host of inventors - even including Thomas Alva Edison - over a periodof twenty-five years, to improve the luminosity of the gas flame by bringingsolid material in it to incandescence, it was at last the Austrian physicist CarlAuer von Welsbach who met with success.The story of the origin of the incandescent gas lamp is not unlike that of theelectric incandescent lamp, invented some ten years earlier. It was not somuch a problem to find a material that could be brought to brilliantincandescence, but rather to find one that would last long enough to becomepracticable. MostCarl Auer von Welsbach experimenters tried platinum gauze, coated with various oxides, ormagnesia, but these materials were prone to prematureFig. 9 Gas chandelier, fittedwith two Argand burners.9Fig. 10 Regenerative gas-lamp Fig. 11 Early upright ‘Auer’ gas-Fig. 12 Acetylene lantern forfor use in factories, fitted with e on bicycles.an inverted incandescentmantle.disintegration.Auer von Welsbach used a tube of fabric, impregnated with amixture of thorium and cerium salts. The fabric would burn away leaving abrittle, but heat-resistant structure consisting of the oxides of the afore-mentioned metals - the so-called gas-mantle (Fig. 11). Its brilliant light isattributable to the phenomenon of candoluminescence -fluorescencestimulated by heat.The battle of gas versus electricityThe gas-mantle lamp came in the nick of time to provide the mighty gascompanies with an adequate answer to the electric incandescent lamp. Andso successful was it that the proliferation of electric lighting was seriously setback by it for many years. In many parts of the world it was only after the1940-1945 war that electricity took a definite lead in lighting.Over the years the gas-mantle lamp underwent a number of improvements,the most important being the introduction of the inverted burner, in 1897.This had two advantages over the upright one: the downward light was nolonger intercepted by the burner, and the heat of the flame stayed inside themantle, thus increasing the efficiency of the burner.Acetylene gas for lighting Gas was also used for lighting vehicles, ranging from bicycles to railwaycarriages. This was accomplished using acetylene gas, which was producedby adding water to calcium carbide dropwise in a special reservoir (Fig. 12).Owners of isolated houses and mansions could buy their own ‘gasworks’based upon the same principle for lighting the premises. Nowadays,propane gas in pressurized containers is sometimes used to the same end.An almost forgotten form of gas lighting, except in the metaphorical sense, isthe ‘limelight’, reputedly invented by Drummond in 1804. By heating acylinder of quicklime to incandescence in an oxyhydrogen flame, a compact,extremely intense light source was obtained, which was used for projectionor theatre lighting.Although in the home since long superseded by electricity, gas is stillextensively used for street lighting in some countries. The city of West-Berlin, for example, still uses some 40 000 gas lanterns, mostly of a moderndesign (Fig. 13).10。