1 / 30

Why BoldPlay ?

Why BoldPlay ?. Brilliant Design. Intuitive Engineering Innovation + Design = Performance Serious Energy Savings Ideal direct/indirect distribution maximum row spacing Exceptional Ceiling Uniformity Low peak candela angle = close-to-ceiling installation.

axl
Download Presentation

Why BoldPlay ?

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Why BoldPlay? Brilliant Design. Intuitive Engineering Innovation + Design = Performance Serious Energy Savings Ideal direct/indirect distribution maximum row spacing Exceptional Ceiling Uniformity Low peak candela angle = close-to-ceiling installation

  2. Fearless Innovationin Architectural LED Lighting MesoOptics Nanotechnology LED Light Guide Technology High performance LED luminaire

  3. Truly harnessingthe true potential of LED technology 1.67” 9.4”

  4. Serious Performance True D/I performance allows: • Lower power densities • Maximum visual comfort • Wider fixture spacing • Unparalleled uniformity • No direct view of light source Peak candela angle is 112.5° and 3.8:1 Peak-to-zenith. 55° brightness control meets RP1 for intensive spaces. 27.5° peak angle minimizes veiling reflections. 70% up/30% down

  5. Applications

  6. Design for success. LED 4800 lm 48’Lx26’Wx10’H 12’o.c. 39 fc 0.60W/ft2 1.94:1 102 lm/W Light Source Room Size Spacing Light Level Energy Density Ceiling Uniformity Luminaire Efficacy

  7. Make a lasting impression. LED 4800 lm 18’Lx12’Wx9’H 23 fc 0.43W/ft2 102 lm/W Light Source Room Size Light Level Energy Density Luminaire Efficacy

  8. Polished appearance,unrivaled performance. LED 3400 lm 15’Lx12’Wx9’H 7.5’ o.c. 34 fc 0.72W/ft2 1.06:1 106 lm/W Light Source Room Size Spacing Light Level Energy Density Ceiling Uniformity Luminaire Efficacy

  9. In a class of its own. LED 4800 lm 40’Lx24’Wx16’H 12’ o.c. 37 fc 0.78W/ft2 1.07:1 102 lm/W Light Source Room Size Spacing Light Level Energy Density Ceiling Uniformity Luminaire Efficacy

  10. Adding distinction to extraordinaryspaces. LED 4800 lm 60’Lx10’Wx9’H 10’ o.c. 20 fc 0.47W/ft2 3.81:1 102 lm/W Light Source Room Size Spacing Light Level Energy Density Ceiling Uniformity Luminaire Efficacy

  11. Make a bold statement. LED 3400 lm 60’Lx32’Wx12’H 12’ o.c. 37 fc 0.60W/ft2 106 lm/W Light Source Room Size Spacing Light Level Energy Density Luminaire Efficacy

  12. Product options

  13. Flexible Distributions 80% Down Variable Optics Kit 20% Up / 80% Down 100% Down Variable Optics Kit 100% Down

  14. ComplementaryWall Mount 60% Up / 40% Down

  15. Color conscious

  16. Application Guide Lighting power density and illuminance information are average maintained values based on predictive engineering analyses in an open plan area measuring 60'W x 60'L x 9’0"H; with room reflectances of ρc 80/ρw 50/ρf 20; and LLF of 0.85 in all cases. Lumen outputs based on 4ft nominal. Changes to fixture mounting and/or workplane heights affect uniformity and to a lower extent light levels, but have no significant impact on energy performance. Ceiling uniformity values are calculated using a statistical area of exitance values, using as a reference, a plane located between a point on the ceiling above a luminaire's photometric center, and the mid-point between two rows of luminaires. All application results have been calculated using real luminaire photometric test data and OEM published system specifications for Philips Ledalite factory standard components at the time of publication. Modifications to architectural conditions, luminaire components, and calculation parameters will yield different results.

  17. Family of Technologies

  18. Example label. For current U.S. DOE Lighting Facts verified data, please visit ledalite.com/boldplay

  19. Fixture photometry has been conducted by a NVLAP accredited testing laboratory in accordance with IESNA LM-79-08. Lumen maintenance of the LEDs used in this fixture has been tested by the LED manufacturer in accordance with IESNA LM-80-08.

  20. L80 • Lumen maintenance: • TM-21-11: L85 (6K) >36,000 hours* • L80 > 60,000 hours • *IES TM-21-11 only allows lumen maintenance projections up to 6 times the test duration (in hours) of LM-80-08 measured data.

  21. LEDs Driver Fixture

  22. Optional Integrated Technologies

  23. Solar powered occupancy sensor The solar powered occupancy sensor significantly enhances energy savings by automatically dimming down and then turning off when the space is vacant. Intelligent Transceiver As the hub of system intelligence, the Airwave transceiver receives wireless signals from each device and commands the associated light fixtures to turn on, turn off or dim. Solar powered photosensor The solar powered photosensor harnesses energy from natural light via integrated miniature photovoltaic cells and constantly monitors illumination levels. Kinetic energy switch Kinetic handheld remote The wireless and battery-free Airwave wall switch and remote handheld control are powered by the simple motion of pushing the switch; creating just enough kinetic energy to send a wireless signal to the transceiver.

  24. Free. Response Daylight Harvesting Sensors Energy savings of up to 35%

More Related