Z-Power LED X10490 Technical Data Sheet RoHS Specification Acrich2 – 8.7W SMJE-2V08W1P3 (120V) SMJE-3V08W1P3 (220V) Rev. 04 April 2013 1 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS Acrich2 - 8.7W Acrich2 Features Description The Acrich2 series of products are designed to be driven directly off of AC • Connects directly to AC line voltage • High Power Efficiency • High Power Factor • Low THD • Long Life Time • Simple BOM • Miniaturization • Lead Free product • RoHS compliant line voltage, therefore they do not need the standard converter essential for conventional general lighting products. The converter or driver found in most general lighting products can limit Applications the overall life of the product, but with the Acrich2 series of products the • Bulb light • Down light • Factory Ceiling light • Industrial Light life of the product can more closely be estimated from the LED itself. This will also allow for a much smaller form factor from an overall fixture design allowing for higher creativity in the fixture. The modules have a high power factor which can contribute to a higher energy savings in the end application. Rev. 04 April 2013 2 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS [ Contents ] 1. Characteristics 2. Thermal Resistance 3. Color spectrum 4. Power characteristics 5. Radiation pattern 6. Binning Structure 7. Marking 8. Part List 9. Outline dimensions 10. Circuit Drawing 11. Packing 12. Cautions for use 13. Handling of silicone resin for LEDs 14. Handling with regards to static electricity 15. Storage before use 16. Guidelines for properly working with Acrich2 Rev. 04 April 2013 3 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS 1. Characteristics 1-1. Electro-Optical characteristics of Acrich2 8.7W Value Parameter Luminous Flux [2] Correlated Color Temperature [4] Symbol ФV [3] CCT CRI Ra Operating Voltage [5] v opt Mark Unit Min Typ Max 8a 590 650 740 8b 740 800 870 8c 870 910 - B 5300 5600 6000 C 4700 5000 5300 E 3700 4000 4200 G 2900 3000 3200 H 2600 2700 2900 80 - - lm K - 120 V[RMS] 220 8.2 8.7 9.1 Power Dissipation PD W Operating Frequency Freq 50 / 60 Hz Power Factor PF Over 0.95 - View Angle 2Θ 1/2 120 deg. Raged Voltage Value Unit 120V 140 220V 264 1-2. Absolute Maximum Ratings Parameter Symbol Max. Voltage v opt V[RMS] Power Dissipation Pd 11.5 W Operating Temperature Topr -30 ~ 85 ºC Storage Temperature Tstg -40 ~ 100 ºC ESD Sensitivity - ±4,000V HBM - Rev. 04 April 2013 4 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS * Notes : [1] At 120V and 220V RMS, Ta=25℃ [2] Acrich2 series maintain the tolerance of 10% on flux and power measurements. [3] ФV is the total luminous flux output measured with an integrated sphere. [4] Correlated Color Temperature is derived from the CIE 1931 Chromaticity diagram. [5] Operating Voltage doesn't indicate the maximum voltage which customers use but means tolerable voltage according to each country’s voltage variation rate. It is recommended that the solder pad temperature should be below 70℃. Rev. 04 April 2013 5 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS 2. Thermal Resistance Part Package Power Dissipation [W] Maximum Junction Temp[℃] Rθj-s [℃/W] Acrich2 LED SAW8KG0B Max 0.5 125 27 Acrich2 IC Max 1.0 125 16.4 The Acrich2 LED has a thermal resistance of 27℃/W from junction of the LED to the LED lead. The maximum junction temperature of the Acrich2 LED package is 125℃, therefore the maximum lead temperature Ts_max is Ts_max = Tj_max - (Rqj-s * PD) = 125℃ - (27℃/W * 0.5W) = 111.5℃ Although this is the maximum lead temperature, it is recommended to keep the lead temperature under 70℃ The Acrich2 IC has a 16.4℃/W thermal resistance from junction to the top surface. The maximum junction temperature (Tt_max) of the IC is 125℃, therefore the maximum temperature of the top of the IC is Tt_max = Tj_max - (yj-t * PD) = 125℃ - (16.4℃/W * 1.0W) = 108.6℃ Rev. 04 April 2013 6 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS 3. Color spectrum Relative Spectral Distribution vs. Wavelength Characteristic – G, H 1.2 Relative Spectral Power Distribution 1 0.8 0.6 0.4 0.2 0 300 400 500 600 700 800 Wavelength[nm] Relative Spectral Distribution vs. Wavelength Characteristic - E 1.2 Relative Spectral Power Distribution 1 0.8 0.6 0.4 0.2 0 300 400 500 600 700 800 Wavelength[nm] Rev. 04 April 2013 7 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS Relative Spectral Distribution vs. Wavelength Characteristic – B, C 1.2 Relative Spectral Power Distribution 1 0.8 0.6 0.4 0.2 0 300 400 500 600 700 800 Wavelength[nm] Rev. 04 April 2013 8 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS 4. Power characteristic Relative Power Distribution vs. Voltage at Ta=25℃ 1.6 1.4 Relative Power 1.2 1.0 0.8 0.6 0.4 0.2 0.0 100 110 120 130 140 150 160 240 250 260 Voltage[RMS,V] 1.4 Relative Power 1.2 1.0 0.8 0.6 0.4 0.2 0.0 200 210 220 230 Voltage[RMS,V] Rev. 04 April 2013 9 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS Relative Luminous Flux [a.u.] Relative Luminous flux vs. Voltage at Ta=25℃ 1.6 1.4 1.2 1 0.8 0.6 100 110 120 130 140 150 160 240 250 260 Relative Luminous Flux [a.u.] Voltage[RMS,V] 1.6 1.4 1.2 1 0.8 0.6 200 210 220 230 Voltage[RMS,V] Rev. 04 April 2013 10 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS 5. Radiation Pattern Rev. 04 April 2013 11 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS 6. Binning Structure 0.46 0.44 2700K 2600K 2900K 3000K 3200K 0.42 G0 3700K 0.40 4000K 4200K CIE Y 4700K E2 5000K C1 5300K 0.36 5600K 6000K B0 G G5 H4 H H3 H5 G4 E0 0.38 G2 E1 H2 G3 H1 H0 G1 E E3 E5 E4 C0 C3 B1 C2C C5 B3 C4 B2 BB5 0.34 B4 0.32 McAdam 4 step 0.30 0.28 0.28 0.30 0.32 0.34 0.36 0.38 0.40 0.42 0.44 0.46 0.48 0.50 Bin code X Y 0.3778 0.3815 0.3753 0.3714 0.3874 0.3788 0.3906 0.3895 CIE X Bin code B G X Y 0.3253 0.3425 0.3255 0.3350 0.3331 0.3418 0.3333 Bin code X Y 0.3415 0.3568 0.3409 0.3483 0.3487 0.3546 0.3498 0.3498 0.3635 0.4311 0.4071 0.4560 0.4152 0.4258 0.3952 0.4494 0.4029 0.4377 0.3994 0.4609 0.4056 0.4437 0.4116 0.4680 0.4180 C H E Rev. 04 April 2013 12 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS 7. Marking • 12 Digits(including Blank) 130109 8a G 2 3 ① 130109 8aG23 SMT Date(6 Digits) – ex)130109 Flux(2 Digits) CCT(1 Digit) CCT Combination No.(1 Digit) Vf Combination No.(1 Digit) ③ CCT ② Flux Marking ① ② ③ ④ ⑤ ② ③④ ⑤ Flux[lm] Marking Min Typ Max 8a 590 650 740 8b 740 800 870 8c 870 910 - ④ CCT Combination No. CCT[K] Min Typ Max B 5300 5600 6000 C 4700 5000 5300 E 3700 4000 4200 G 2900 3000 3200 H 2600 2700 2900 ⑤ Vf Combination No. Marking Bin 1 Bin 2 Marking Bin 1 Bin 2 1 0 5 1 A A 2 5 0 2 A B 3 1 4 3 B A 4 4 1 4 A C 5 2 3 5 C A 6 3 2 6 B B 7 B C 8 C B 9 C C Rev. 04 April 2013 13 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS 8. Part List No. Part Silk Specification Q'ty 1 PCB - Metal(Al) Φ46 1.6T 1 2 LED - SAW8KG0B 21 3 IC U1 MAH3082(120V) MAH3080(220V) 1 9. Outline dimensions * Notes : [1] All dimensions are in millimeters. (Tolerance : ±0.2) [2] Scale : none Rev. 04 April 2013 14 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS 10. Circuit Drawing SMJE-2V08W1P3 (120V) SMJE-3V08W1P3 (220V) Rev. 04 April 2013 15 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS 11. Packing ๏ 1Box : 50 PCS per tray x Max 10 layer = Max 500 PCS (about 5.85kg) ๏ Box size( L x W x H ) = 590 x 330 x 260 Rev. 04 April 2013 16 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS 12. Cautions for use • Please review the Acrich2 Application Note for proper protective circuitry usage • Please note, Acrich2 products run off of high voltage, therefore caution should be taken when working near Acrich2 products. • DO NOT touch any of the circuit board, components or terminals with body or metal while circuit is active. • Please do not add or change wires while Acrich2 circuit is active • Long time exposure to sunlight or UV can cause the lens to discolor. • Please do not use adhesives to attach the LED that outgas organic vapor. • Please do not use together with the materials containing Sulfur. • Please do not assemble in conditions of high moisture and/or oxidizing gas such as Cl, H2S,NH3,SO2,NOX,etc. • Please do not make any modification on module. • Please be cautious when soldering to board so as not to create a short between different trace patterns. 13. Handling of silicone resin for LEDs • • • • • • Acrich2 series is encapsulated with silicone resin for high optical efficiency. Please do not touch the silicone resin area with sharp objects such as pincette(tweezers). Finger prints on silicone resin area may affect the performance. Please store LEDs in covered containers to prevent dust accumulation as this may affect performance. Excessive force more than 3000gf to the silicone lens can result in fatal or permanent damage with LEDs. Please do not cover the silicone resin area with any other resins such as epoxy, urethane, etc. Rev. 04 April 2013 17 www.Acrich.com Z-Power LED X10490 Technical Data Sheet RoHS 14. Handling with regards to static electricity • The Acrich2 products use an integrated circuit (IC) which can be damaged when exposed to static electricity. Please handle using equipment that prevents static electricity. Do not touch unless ESD protection is used. • The Acrich2 product should also not be installed in end equipment without ESD protection. 15. Storage before use • Do not impact or place pressure on this product because even a small amount of pressure can damage the product. The product should also not be placed in high temperatures, high humidity or direct sunlight since the device is sensitive to these conditions. • When storing devices for a long period of time before usage, please following these guidelines: * The devices should be stored in the anti-static bag that it was shipped in from Seoul-Semiconductor with opening. * If the anti-static bag has been opened, re-seal preventing air and moisture from being present in the bag. 16. Guidelines for properly working with Acrich2 • Discharge the lighting system a minimum of 2-3 times prior to working with the module. • Use only properly rated test equipment and tools for the rated voltage and current of the product being tested. • It is strongly suggested to wear rubber insulated gloves and rubber bottom shoes. • Do not wear any conductive items (such as jewelry) which could accidentally contact electric circuits. • Perform several tests with power off and the lighting system unplugged. • Faults, lightning, or switching transients can cause voltage surges in excess of the normal ratings. • Internal component failure can cause excessive voltages. • Stored or residual electricity in long wire could be hazardous. • Make sure proper discharge prior to starting work. Rev. 04 April 2013 18 www.Acrich.com