Bridgelux Decor SeriesTM Class A LED Array (R) Product Data Sheet DS35 BXRC-30A1001 BXRC-40A1001 | | 30A2001 40A2001 | | 30A4001 40A4001 | | 30A10K1 40A10K1 Vero Introduction Bridgelux(R) Decor SeriesTM Class A products are a revolutionary advancement in lighting designed to match how humans perceive and prefer light. The Class A specification was created by the Lighting Research Center (LRC) behavior studies in conjunction with Bridgelux and other ASSIST members. Based on human factor response testing, the Decor Series Class A products provide vibrant, natural and brilliant looking light, evoking an emotional attraction and response. The Decor Series Class A products were developed for high-end retail, museum, architectural, premium building and hospitality applications. Bridgelux Decor Series Class A products are available on all Vero form factors. The Vero platform has been engineered with advanced connectivity options and can operate over a broad current range, enabling multiple degrees of flexibility in luminaire design optimization. Features Benefits * Light quality is based on human perception of color and light * Broad application coverage for interior and exterior lighting * High gamut area index (GAI) * Flexibility for application driven lighting design requirements * No harmful UV or near IR light in the spectrum * Substantially broader GAI and color spectrum than halogen * High quality true color reproduction * Uniform consistent white light * Radial die pattern enhances optical uniformity * Flexibility in design optimization * Based on Bridgelux Vero COB LED array platform * Enhanced ease of use and manufacturability Contents Product Feature Map 2 Product Nomenclature 2 Product Selection Guide 3 Performance at Commonly Used Drive Currents 5 Electrical Characteristics 7 Absolute Maximum Ratings 8 Performance Curves 9 Typical Radiation Pattern 16 Mechanical Dimensions 17 Packaging 21 Design Resources 24 Precautions 24 Disclaimers 24 About Bridgelux 25 1 Product Feature Map In addition to delivering the performance and light quality required for many lighting applications, Decor Series Class A LED arrays incorporate several features to simplify the design integration and manufacturing process, accelerate time to market and reduce system costs. Thermally isolated solder pads reduce manufacturing cycle time and complexity 2D barcode provides full manufacturing traceability Polarity indication marks simplify manufacturing operator instructions Tc Measurement point Optics location/mounting features Mounting holes Radial die configuration improves lumen density and beam control Zhaga Book 3 compatible mounting locations Solderless connector port enables simplified manufacturing processes, reduced inventory carrying costs and can enable field upgradability Optional Molex Pico-EZmateTM connector harness (sold separately) Product Nomenclature The part number designation for Bridgelux Vero LED arrays is explained as follows: 1 2 3 4 56 7 8 9 10 11 - 12 - 13 14 BXRC - 30 A 1001 - x - 23 Product Family CCT Bin Options 23 = 3 SDCM Nominal CCT 30 = 3,000K 40 = 4,000K Array Configuration Typical GAI GAI >80 Nominal Flux 1001- 1000lm 2001- 2000lm 4001- 4000lm 10K1- 10,000lm 2 Product Selection Guide The following product configurations are available: Table 1: Selection Guide, Pulsed Measurement Data (Tj = Tc = 25C) Product Part Number Nominal CCT1 (K) GAI2 CRI3 Nominal Drive Current4 (mA) Typical Pulsed Flux5,6,7 Tc = 25C (lm) Minimum Pulsed Flux7,8 Tc = 25C (lm) Typical Vf (V) Typical Power (W) Typical Efficacy (lm/W) Decor Class A Vero 10 BXRC-30A1001-B-23 3000 80 93 350 820 750 26.5 9.3 88 Decor Class A Vero 10 BXRC-40A1001-B-23 4000 80 93 350 970 900 26.5 9.3 105 Decor Class A Vero 13 BXRC-30A2001-C-23 3000 80 93 500 1500 1394 32.3 16.2 93 Decor Class A Vero 13 BXRC-40A2001-C-23 4000 80 93 500 1740 1625 32.3 16.2 108 Decor Class A Vero 18 BXRC-30A4001-F-23 3000 80 93 1050 2897 2695 29.5 31.0 94 Decor Class A Vero 18 BXRC-40A4001-F-23 4000 80 93 1050 3385 3157 29.5 31.0 109 Decor Class A Vero 29 BXRC-30A10K1-L-23 3000 80 93 2100 7483 7014 38 79.8 94 Decor Class A Vero 29 BXRC-40A10K1-L-23 4000 80 93 2100 8666 8054 38 79.8 109 Table 2: Selection Guide, Stabilized DC Performance (Tc = 70C) 9,10 Product Part Number Nominal CCT1 (K) GAI2 CRI3 Nominal Drive Current4 (mA) Typical DC Flux5,6,7 Tc = 70C (lm) Minimum DC Flux7,11 Tc = 70C (lm) Typical Vf (V) Typical Power (W) Typical Efficacy (lm/W) Decor Class A Vero 10 BXRC-30A1001-B-23 3000 80 93 350 752 688 25.8 9.0 83 Decor Class A Vero 10 BXRC-40A1001-B-23 4000 80 93 350 888 824 25.8 9.0 98 Decor Class A Vero 13 BXRC-30A2001-C-23 3000 80 93 500 1377 1280 31.5 15.8 87 Decor Class A Vero 13 BXRC-40A2001-C-23 4000 80 93 500 1597 1491 31.5 15.8 101 Decor Class A Vero 18 BXRC-30A4001-F-23 3000 80 93 1050 2638 2454 28.7 30.2 87 Decor Class A Vero 18 BXRC-40A4001-F-23 4000 80 93 1050 3120 2910 28.7 30.2 103 Decor Class A Vero 29 BXRC-30A10K1-L-23 3000 80 93 2100 6886 6454 37.2 78.2 88 Decor Class A Vero 29 BXRC-40A10K1-L-23 4000 80 93 2100 7977 7414 37.2 78.2 102 Notes for Tables 1 & 2: 1. Nominal CCT is defined by the Lighting Research Center's Class A definition. The center of the Class A color bin is on the corresponding isothermal line. 2. To help ensure optimal fixture level performance, GAI is measured at the fixture level, on axis, at a case temperature of 70C. GAI may vary depending on fixture design and performance. 3. CRI Values are specified as typical. Typical R9 value for 3000K products is 90. CRI and R Values are measured at 25C pulsed. 4. Drive current is referred to as nominal drive current. 5. Products tested under pulsed condition (10ms pulse width) at nominal test current where Tj (junction temperature) = Tc (case temperature) = 25C. 6. Typical performance values are provided as a reference only and are not a guarantee of performance. 7. Bridgelux maintains a 7% tolerance on flux measurements. 8. Minimum flux values at the nominal test current are guaranteed by 100% test. 9. Typical stabilized DC performance values are provided as reference only and are not a guarantee of performance. 10. Typical performance is estimated based on operation under DC (direct current) with LED array mounted onto a heat sink with thermal interface material and the case temperature maintained at specified temperature. Based on Bridgelux test setup, values may vary depending on the thermal design of the luminaire and/or the exposed environment to which the product is subjected. 11. Minimum flux values at elevated temperatures are provided for reference only and are not guaranteed by 100% production testing. Based on Bridgelux test setup, values may vary depending on the thermal design of the luminaire and/or the exposed environment to which the product is subjected. 3 Product Selection Guide The following product configurations are available: Table 3: Selection Guide, Stabilized DC Performance (Tc = 85C) 9,10 Product Part Number Nominal CCT1 (K) GAI2 CRI3 Nominal Drive Current4 (mA) Typical DC Flux5,6,7 Tc = 85C (lm) Minimum DC Flux7,11 Tc = 85C (lm) Typical Vf (V) Typical Power (W) Typical Efficacy (lm/W) Decor Class A Vero 10 BXRC-30A1001-B-23 3000 80 93 350 728 666 25.5 8.9 81 Decor Class A Vero 10 BXRC-40A1001-B-23 4000 80 93 350 861 799 25.5 8.9 96 Decor Class A Vero 13 BXRC-30A2001-C-23 3000 80 93 500 1332 1238 31.3 15.6 85 Decor Class A Vero 13 BXRC-40A2001-C-23 4000 80 93 500 1545 1443 31.3 15.6 99 Decor Class A Vero 18 BXRC-30A4001-F-23 3000 80 93 1050 2543 2365 28.6 30.0 85 Decor Class A Vero 18 BXRC-40A4001-F-23 4000 80 93 1050 3025 2821 28.6 30.0 101 Decor Class A Vero 29 BXRC-30A10K1-L-23 3000 80 93 2100 6668 6250 36.8 77.3 86 Decor Class A Vero 29 BXRC-40A10K1-L-23 4000 80 93 2100 7718 7173 36.8 77.3 100 Notes for Table: 1. Nominal CCT is defined by the Lighting Research Center's Class A definition. The center of the Class A color bin is on the corresponding isothermal line. 2. To help ensure optimal fixture level performance, GAI is measured at the fixture level, on axis, at a case temperature of 70C. GAI may vary depending on fixture design and performance. 3. CRI Values are specified as typical. Typical R9 value for 3000K products is 90. CRI and R Values are measured at 25C pulsed. 4. Drive current is referred to as nominal drive current. 5. Products tested under pulsed condition (10ms pulse width) at nominal test current where Tj (junction temperature) = Tc (case temperature) = 25C. 6. Typical performance values are provided as a reference only and are not a guarantee of performance. 7. Bridgelux maintains a 7% tolerance on flux measurements. 8. Minimum flux values at the nominal test current are guaranteed by 100% test. 9. Typical stabilized DC performance values are provided as reference only and are not a guarantee of performance. 10. Typical performance is estimated based on operation under DC (direct current) with LED array mounted onto a heat sink with thermal interface material and the case temperature maintained at specified temperature. Based on Bridgelux test setup, values may vary depending on the thermal design of the luminaire and/or the exposed environment to which the product is subjected. 11. Minimum flux values at elevated temperatures are provided for reference only and are not guaranteed by 100% production testing. Based on Bridgelux test setup, values may vary depending on the thermal design of the luminaire and/or the exposed environment to which the product is subjected. 4 Performance at Commonly Used Drive Currents Vero LED arrays are tested to the specifications shown using the nominal drive currents in Table 1. Vero may also be driven at other drive currents dependent on specific application design requirements. The performance at any drive current can be derived from the current vs. voltage characteristics shown in Figure 3-6 and the flux vs. current characteristics shown in Figures 7-10. The performance at commonly used drive currents is summarized in Table 4. Table 4: Product Performance at Commonly Used Drive Currents Product Decor Class A Vero 10 Decor Class A Vero 10 Decor Class A Vero 13 Decor Class A Vero 13 Decor Class A Vero 18 Part Number BXRC-30A1001-B-23 BXRC-40A1001-B-23 BXRC-30A2001-C-23 BXRC-40A2001-C-23 BXRC-30A4001-F-23 GAI 80 80 80 80 80 CRI Drive Current1 (mA) Typical Vf Tc = 25C (V) Typical Power Tj = 25C (W) Typical Flux2 Tc = 25C (lm) Typical DC Flux3 Tc = 85C (lm) Typical Efficacy Tj = 25C (lm/W) 175 24.9 4.4 435 386 100 350 26.5 9.3 820 728 88 500 27.6 13.8 1116 991 81 700 29.0 20.3 1454 1292 72 93 93 93 93 93 175 24.9 4.4 514 457 118 350 26.5 9.3 970 861 105 500 27.6 13.8 1321 1172 96 700 29.0 20.3 1720 1527 85 175 30.2 5.3 572 508 108 350 31.4 11.0 1095 972 100 500 32.3 16.2 1500 1332 93 700 33.4 23.4 1995 1772 85 1050 35.1 36.9 2702 2400 73 175 30.2 5.3 663 589 125 350 31.4 11.0 1270 1127 116 500 32.3 16.2 1740 1545 108 700 33.4 23.4 2314 2055 99 1050 35.1 36.9 3134 2783 85 500 28.1 14.1 1483 1301 106 700 28.7 20.1 2025 1777 101 1050 29.5 31.0 2897 2543 94 1400 30.2 42.3 3692 3241 87 2100 31.6 66.4 5003 4391 75 Notes for Table 4: 1. Alternate drive currents in Table 4 are provided for reference only and are not a guarantee of performance. 2. Bridgelux maintains a 7% tolerance on flux measurements. 3. Typical stabilized DC performance values are provided as reference only and are not a guarantee of performance. 5 Performance at Commonly Used Drive Currents Table 4: Product Performance at Commonly Used Drive Currents Product Decor Class A Vero 18 Decor Class A Vero 29 Decor Class A Vero 29 Part Number BXRC-40A4001-F-23 BXRC-30A10K1-L-23 BXRC-40A10K1-L-23 GAI 80 80 80 CRI Drive Current1 (mA) Typical Vf Tc = 25C (V) Typical Power Tj = 25C (W) Typical Flux2 Tc = 25C (lm) Typical DC Flux3 Tc = 85C (lm) Typical Efficacy Tj = 25C (lm/W) 500 28.1 14.1 1732 1548 123 700 28.7 20.1 2366 2114 118 1050 29.5 31.0 3385 3025 109 1400 30.2 42.3 4314 3855 102 2100 31.6 66.4 5846 5224 88 500 35.1 17.6 1964 1750 112 700 35.6 24.9 2717 2421 109 1050 36.4 38.2 3991 3556 104 2100 38.0 79.8 7483 6668 94 2800 39.0 109.2 9506 8470 87 3150 39.5 124.4 10438 9301 84 4200 40.4 169.7 12895 11490 76 500 35.1 17.6 2275 2026 129 700 35.6 24.9 3147 2803 126 1050 36.4 38.2 4622 4116 121 2100 38.0 79.8 8666 7718 109 2800 39.0 109.2 11009 9805 101 3150 39.5 124.4 12089 10767 97 4200 40.4 169.7 14933 13300 88 93 93 93 Notes for Table 4: 1. Alternate drive currents in Table 4 are provided for reference only and are not a guarantee of performance. 2. Bridgelux maintains a 7% tolerance on flux measurements. 3. Typical stabilized DC performance values are provided as reference only and are not a guarantee of performance. 6 Electrical Characteristics Table 5: Electrical Characteristics Part Number Forward Voltage Pulsed, Tc = 25C (V) 1, 2,3 Typical Coefficient of Forward Voltage4 Vf/TC (mV/C) Typical Thermal Resistance Junction to Case5,6 Rj-c (C/W) Nominal Drive Current 1 (mA) Minimum Typical Maximum 350 24.5 26.5 29.0 -16 700 26.5 29.0 31.2 500 29.9 32.3 1050 32.0 1050 Driver Selection Voltages7 (V) Vf Min. Hot Tc = 105C (V) Vf Max. Cold4 Tc = -40C (V) 0.47 23.2 29.5 -16 0.59 25.2 32.2 34.7 -17 0.22 28.5 35.8 35.1 37.9 -17 0.28 30.6 39.0 27.3 29.5 31.7 -15 0.13 26.1 32.7 2100 29.2 31.6 34.2 -15 0.17 28.0 35.2 2100 35.2 38.0 40.9 -20 0.06 33.6 42.2 4200 37.3 40.4 44.0 -20 0.07 35.7 45.3 BXRC-xxA1001-B-23 BXRC-xxA2001-C-23 BXRC-xxA4001-F-23 BXRC-xxA10K1-L-23 Notes for Table 5: 1. Parts are tested in pulsed conditions, Tc = 25C. Pulse width is 10ms. 2. Voltage minimum and maximum are provided for reference only and are not a guarantee of performance. 3. Bridgelux maintains a tester tolerance of O.10V on forward voltage measurements. 4. Typical coefficient of forward voltage tolerance is O.1mV for nominal current. 5. Thermal resistance values are based from test data of a 3000K 80 CRI product. 6. Thermal resistance value was calculated using total electrical input power; optical power was not subtracted from input power. 7. Vf min hot and max cold values are provided as reference only and are not guaranteed by test. These values are provided to aid in driver design and selection over the operating range of the product. 7 Absolute Maximum Ratings Table 6: Maximum Ratings Parameter Maximum Rating LED Junction Temperature 150C Storage Temperature -40C to +105C Operating Case Temperature1,2 105C Soldering Temperature3 350C or lower for a maximum of 10 seconds BXRC-xxA1001-B-23 BXRC-xxA2001-C-23 BXRC-xxA4001-F-23 BXRC-xxA10K1-L-23 Maximum Drive Current1 700 mA 1050 mA 2100 mA 4200 mA Maximum Peak Pulsed Drive Current4 1500 mA 1500 mA 3000 mA 6000 mA Maximum Reverse Voltage5 -45V -55 V -55 V -65 V Notes for Table 6: 1. Please refer to Figures 1 and 2 for drive current derating curve for Vero 10 and Vero 29. Vero 13 and Vero 18 may be driven at 2 times nominal current upto 105C. 2. For IEC 62717 requirement, please contact Bridgelux Sales Support. 3. See Bridgelux Application Note AN31, Assembly Considerations for Vero LED arrays, for more information. 4. Bridgelux recommends a maximum duty cycle of 10% and pulse width of 20ms when operating LED Arrays at the maximum peak pulsed current specified. Maximum peak pulsed current indicate values where the LED array can be driven without catastrophic failures. 5. Light emitting diodes are not designed to be driven in reverse voltage and will not produce light under this condition. Maximum rating provided for reference only. 8 Performance Curves The maximum allowable drive current for the Vero 10 and Vero 29 product families is dependent on the operating case temperature. Please refer to the Product Feature Map (page 2) for the location of the Tc Point. Figure 1: Vero 10 Drive Current Derating Curve Notes for Figure 1: 1. In order to meet LM-80 lifetime projections Vero 10 may be driven up to 700mA at case temperatures up to 90C. Operating conditions above case temperatures of 90C driving conditions must follow the Vero 10 Drive Current Derating Curve. 2. Lumen maintenance (L70) and lifetime predictions are valid for drive current and case temperature conditions used for LM-80 testing as included in the applicable LM-80 test report for these products. Contact your Bridgelux sales representative for LM-80 report. 9 Performance Curves Figure 2: Vero 29 Drive Current Derating Curve Notes for Figure 2: 1. LM-80 Max Drive Current must not be exceeded in order to meet LM-80 lifetime projections. 2. Lumen maintenance (L70) and lifetime predictions are valid for drive current and case temperature conditions used for LM-80 testing as included in the applicable LM-80 test report for these products. Contact your Bridgelux sales representative for LM-80 report. 10 Performance Curves Figure 3: Vero 10 Drive Current vs. Forward Voltage (Tj=Tc=25C) Figure 4: Vero 13 Drive Current vs. Forward Voltage (Tj=Tc=25C) Figure 5: Vero 18 Drive Current vs. Forward Voltage (Tj=Tc=25C) Figure 6: Vero 29 Drive Current vs. Forward Voltage (Tj=Tc=25C) 11 Performance Curves Figure 7: Vero 10 Typical Relative Luminous Flux vs. Drive Current Figure 8: Vero 13 Typical Relative Luminous Flux vs. Drive Current Figure 9: Vero 18 Typical Relative Luminous Flux vs. Drive Current Figure 10: Vero 29Typical Relative Luminous Flux vs. Drive Current 12 Performance Curves Figure 11: Vero 10 Typical Relative Luminous Flux vs. Case Temperature Figure 12: Vero 13 Typical Relative Luminous Flux vs. Case Temperature Figure 13: Vero 18 Typical Relative Luminous Flux vs. Case Temperature Figure 14: Vero 29 Typical Relative Luminous Flux vs. Case Temperature Note for Figures 11-14: Flux measurements taken under DC conditions. 13 Performance Curves Figure 15: Vero 10 Typical ccx Shift vs. Case Temperature Figure 16: Vero 10 Typical ccy Shift vs. Case Temperature Figure 17: Vero 13 Typical ccx Shift vs. Case Temperature Figure 18: Vero 13 Typical ccy Shift vs. Case Temperature Note for Figures 15-18: Flux measurements taken under DC conditions. 14 Performance Curves Figure 19: Vero 18 Typical ccx Shift vs. Case Temperature Figure 20: Vero 18 Typical ccy Shift vs. Case Temperature Figure 21: Vero 29 Typical ccx Shift vs. Case Temperature Figure 22: Vero 29 Typical ccy Shift vs. Case Temperature Note for Figures 19-22: Flux measurements taken under DC conditions. 15 Typical Radiation Pattern Figure 23: Typical Spatial Radiation Pattern Notes for Figure 23: 1. Typical viewing angle is 120. 2. The viewing angle is defined as the off axis angle from the centerline where Iv is 1/2 of the peak value. Figure 24: Typical Polar Radiation Pattern 16 Mechanical Dimensions Figure 25: Drawing for Vero 10 LED Array Notes for Figure 25: 1. Drawings are not to scale. 2. Drawing dimensions are in millimeters. 3. Unless otherwise specified, tolerances are 0.01mm. 4. Mounting slots (2X) are for M2.5 screws. 5. Bridgelux recommends two tapped holes for mounting screws with 19.0 0.10mm center-to-center spacing. 6. Screws with flat shoulders (pan, dome, button, round, truss, mushroom) provide optimal torque control. Do NOT use flat, countersink, or raised head screws. 7. Solder pads and connector port are labeled "+" and "-" to denote positive and negative, respectively. 8. It is not necessary to provide electrical connections to both the solder pads and the connector port. Either set may be used depending on application specific design requirements. 9. Refer to Application Notes AN30 and AN31 for product handling, mounting and heat sink recommendations. 10. The optical center of the LED Array is nominally defined by the mechanical center of the array to a tolerance of 0.2mm. 11. Bridgelux maintains a flatness of 0.10mm across the mounting surface of the array. 17 Mechanical Dimensions Figure 26: Drawing for Vero 13 LED Array Notes for Figure 26: 1. Drawings are not to scale. 2. Drawing dimensions are in millimeters. 3. Unless otherwise specified, tolerances are 0.01mm. 4. Mounting holes (2X) are for M2.5 screws. 5. Bridgelux recommends two tapped holes for mounting screws with 31.4 0.10mm center-to-center spacing. 6. Screws with flat shoulders (pan, dome, button, round, truss, mushroom) provide optimal torque control. Do NOT use flat, countersink, or raised head screws. 7. Solder pads and connector port are labeled "+" and "-" to denote positive and negative, respectively. 8. It is not necessary to provide electrical connections to both the solder pads and the connector port. Either set may be used depending on application specific design requirements. 9. Refer to Application Notes AN30 and AN31 for product handling, mounting and heat sink recommendations. 10. The optical center of the LED Array is nominally defined by the mechanical center of the array to a tolerance of 0.2mm. 11. Bridgelux maintains a flatness of 0.10mm across the mounting surface of the array. 18 Mechanical Dimensions Figure 27: Drawing for Vero 18 LED Array Notes for Figure 27: 1. Drawings are not to scale. 2. Drawing dimensions are in millimeters. 3. Unless otherwise specified, tolerances are 0.01mm. 4. Mounting holes (2X) are for M2.5 screws. 5. Bridgelux recommends two tapped holes for mounting screws with 31.4 0.10mm center-to-center spacing. 6. Screws with flat shoulders (pan, dome, button, round, truss, mushroom) provide optimal torque control. Do NOT use flat, countersink, or raised head screws. 7. Solder pads and connector port are labeled "+" and "-" to denote positive and negative, respectively. 8. It is not necessary to provide electrical connections to both the solder pads and the connector port. Either set may be used depending on application specific design requirements. 9. Refer to Application Notes AN30 and AN31 for product handling, mounting and heat sink recommendations. 10. The optical center of the LED Array is nominally defined by the mechanical center of the array to a tolerance of 0.2mm. 11. Bridgelux maintains a flatness of 0.10mm across the mounting surface of the array. 19 Mechanical Dimensions Figure 28: Drawing for Vero 29 LED Array Notes for Figure 28: 1. Drawings are not to scale. 2. Drawing dimensions are in millimeters. 3. Unless otherwise specified, tolerances are 0.01mm. 4. Mounting holes (2X) are for M2.5 screws. 5. Bridgelux recommends two tapped holes for mounting screws with 31.4 0.10mm center-to-center spacing. 6. Screws with flat shoulders (pan, dome, button, round, truss, mushroom) provide optimal torque control. Do NOT use flat, countersink, or raised head screws. 7. Solder pads and connector port are labeled "+" and "-" to denote positive and negative, respectively. 8. It is not necessary to provide electrical connections to both the solder pads and the connector port. Either set may be used depending on application specific design requirements. 9. Refer to Application Notes AN30 and AN31 for product handling, mounting and heat sink recommendations. 10. The optical center of the LED Array is nominally defined by the mechanical center of the array to a tolerance of 0.2mm. 11. Bridgelux maintains a flatness of 0.10mm across the mounting surface of the array. 20 Packaging Figure 29: Drawing for Vero 10 Packaging Tray Notes for Figure 29: 1. Dimensions are in millimeters 2. Tolerances: X.X = 0.1, X.XX = 0.05, Angles = 1 3. Trays are stackable without interference and will not stick together during unstacking operation. 4. Each tray holds 40 LEDs. Figure 30: Drawing for Vero 13 Packaging Tray Notes for Figure 30: 1. Dimensions are in millimeters 2. Tolerances: X.X = 0.1, X.XX = 0.05, Angles = 1 3. Trays are stackable without interference and will not stick together during unstacking operation. 4. Each tray holds 20 LEDs. 21 Packaging Figure 31: Drawing for Vero 18 Packaging Tray Notes for Figure 31: 1. Dimensions are in millimeters 2. Tolerances: X.X = 0.1, X.XX = 0.05, Angles = 1 3. Trays are stackable without interference and will not stick together during unstacking operation 4. Each tray holds 20 LEDs. Figure 32: Drawing for Vero 29 Packaging Tray Notes for Figure 32: 1. Dimensions are in millimeters 2. Tolerances: X.X = 0.1, X.XX = 0.05, Angles = 1 3. Trays are stackable without interference and will not stick together during unstacking operation 4. Each tray holds 10 LEDs. 22 Packaging Figure 33: Vero Series Packaging and Labeling Notes for Figure 33: 1. 5 trays are stacked and one empty tray placed on top to cover the top tray. 2. Stacked trays are to contain only 1 part number and be vacuum sealed in an anti-static bag and placed in own box. 3. Each bag and box is to be labeled as shown above. 23 Design Resources Application Notes 3D CAD Models Bridgelux has developed a comprehensive set of application notes and design resources to assist customers in successfully designing with the Vero product family of LED array products. For a list of of resources under development, visit www.bridgelux.com. Three dimensional CAD models depicting the product outline of all Bridgelux Vero LED arrays are available in both SAT and STEP formats. Please contact your Bridgelux sales representative for assistance. Optical Source Models Optical source models and ray set files are available for all Bridgelux products. For a list of available formats, visit www.bridgelux.com. Precautions CAUTION: CHEMICAL EXPOSURE HAZARD Exposure to some chemicals commonly used in luminaire manufacturing and assembly can cause damage to the LED array. Please consult Bridgelux Application Note AN31 for additional information. CAUTION: EYE SAFETY Eye safety classification for the use of Bridgelux Vero LED arrays is in accordance with IEC specification EN62471: Photobiological Safety of Lamps and Lamp Systems. Vero LED arrays are classified as Risk Group 1 (Low Risk) when operated at or below the maximum drive current. Please use appropriate precautions. It is important that employees working with LEDs are trained to use them safely. CAUTION CONTACT WITH LIGHT EMITTING SURFACE (LES) Avoid any contact with the LES. Do not touch the LES of the LED array or apply stress to the LES (yellow phosphor resin area). Contact may cause damage to the LED array. Optics and reflectors must not be mounted in contact with the LES (yellow phosphor resin area). Optical devices may be mounted on the top surface of the plastic housing of the Vero LED array. Use the mechanical features of the LED array housing, edges and/or mounting holes to locate and secure optical devices as needed. CAUTION: RISK OF BURN Do not touch the Vero LED array or yellow resin area during operation. Allow the array to cool for a sufficient period of time before handling. The Vero LED array may reach elevated temperatures such that could burn skin when touched. Disclaimers MINOR PRODUCT CHANGE POLICY STANDARD TEST CONDITIONS The rigorous qualification testing on products offered by Bridgelux provides performance assurance. Slight cosmetic changes that do not affect form, fit, or function may occur as Bridgelux continues product optimization. Unless otherwise stated, array testing is performed at the nominal drive current. 24 About Bridgelux Bridgelux is a leading developer and manufacturer of technologies and solutions transforming the $40 billion global lighting industry into a $100 billion market opportunity. Based in Livermore, California, Bridgelux is a pioneer in solid state lighting (SSL), expanding the market for light emitting diode (LED) technologies by driving down the cost of LED lighting systems. Bridgelux's patented light source technology replaces traditional technologies (such as incandescent, halogen, fluorescent and high intensity discharge lighting) with integrated, solid state lighting solutions that enable lamp and luminaire manufacturers to provide high performance and energy efficient white light for the rapidly growing interior and exterior lighting markets, including street lights, commercial lighting and consumer applications. For more information about the company, please visit bridgelux.com. 101 Portola Avenue Livermore, CA 94551 Tel (925) 583-8400 Fax (925) 583-8410 www.bridgelux.com (c) 2015 Bridgelux, Inc. All rights reserved 2014. Product specifications are subject to change without notice. Bridgelux, the Bridgelux stylized logo design and Vero are registered trademarks, and Decor Series is a trademark of Bridgelux, Inc. All other trademarks are the property of their respective owners. Bridgelux Vero Decor Series Product Data Sheet DS35 Rev. A (03/2015) 25