Product Data Sheet SAW0LH0A– Acrich MJT 5050 Superior high Flux for High Current System Acrich MJT 5050 SAW0LH0A (Cool) Product Brief Description Features and Benefits • • This White Colored surface-mount LED comes in standard package dimension. Package Size : 5.0x5.0x0.65mm • The MJT series of LEDs are designed for AC & DC(High Voltage) operation and high flux output applications. • It incorporates state of the art SMD design and low thermal resistant material. • • • • • Super high Flux output and high Luminance Designed for high voltage operation SMT solderable Lead Free product RoHS compliant Key Applications • • • • The MJT is ideal light sources for general illumination applications and custom designed solutions. General lighting Architectural lighting LED Bulbs Decorative / Pathway lighting Table 1. Product Selection Table CCT Part Number SAW0LH0A Rev1.0, May 26, 2014 Color Min. Typ. Max. Cool White 4700K 5600K 7000K 1 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Table of Contents Index • Product Brief • Table of Contents • Performance Characteristics • Color Bin Structure • Packaging Information • Product Nomenclature (Labeling Information) • Reflow Soldering Characteristics • Recommended Solder Pad • Handling of Silicone Resin for LEDs • Precaution For Use • Company Information Rev1.0, May 26, 2014 2 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Performance Characteristics Table 2. Characteristics, IF=20mA, Tj=25ºC Value Parameter Symbol Unit Min. Typ. Max. Φv[2] 154 180 - lm CCT 4700 - 7000 K CRI[4] Ra 70 - - - Forward Voltage VF 60 63 68 V Power Dissipation PD - 1.26 - W Viewing Angle 2Θ1/2 - 120 - deg. Thermal resistance (J to S) Rθj-s - 6.0 - K/W ESD Sensitivity(HBM) - 5k - - V Luminous Flux[1] Correlated Color Temperature[3] Table 3. Electro – Optical Characteristics, Tj=25ºC IF [mA] VF [V] Power [W] Φv [lm] lm/W 10 60.3 0.60 92.2 153.7 20 (Typ.) 63.8 1.28 175.2 136.9 30 66.7 2.00 250.7 125.4 40 69.3 2.77 319.7 115.4 50 71.6 3.58 383.2 107.0 60 73.6 4.42 442.6 100.1 Parameter Symbol Value Unit Forward Current IF 60 mA Power Dissipation PD 4.5 W Junction Temperature Tj 125 ºC Operating Temperature Topr -30 ~ + 100 ºC Storage Temperature Tstg -40 ~ + 100 ºC Table 4. Absolute Maximum Ratings Notes : (1) Seoul Semiconductor maintains a tolerance of 7% on flux and power measurements. (2) ФV is the total luminous flux output as measured with an integrating sphere. (3) Correlated Color Temperature is derived from the CIE 1931 Chromaticity diagram. Color coordinate : 0.01, CCT 5% tolerance. (4) Tolerance is 2.0 on CRI measurements. • Calculated performance values are for reference only. • All measurements were made under the standardized environment of Seoul Semiconductor. Rev1.0, May 26, 2014 3 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Relative Spectral Distribution Fig 1. Color Spectrum, Tj=25℃, IF=20mA Relative Spectral Power Distribution [a.u.] 1.2 1.0 0.8 0.6 0.4 0.2 0.0 400 500 600 700 800 Wavelength(nm) Fig 2. Radiant pattern, Tj=25℃, IF=20mA Relative Luminous Flux [a.u.] 1.2 1.0 0.8 0.6 0.4 0.2 0.0 -90 -60 -30 0 30 60 90 Angle [deg.] Rev1.0, May 26, 2014 4 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Forward Current Characteristics Fig 3. Forward Voltage vs. Forward Current , T j=25℃ 70 Forward Current [IF, mA] 60 50 40 30 20 10 0 0 10 20 30 40 50 60 70 80 Forward Voltage [VF, V] Fig 4. Forward Current vs. Relative Luminous Flux, T j=25℃ Relative luminous flux [a.u.] 2.5 2.0 1.5 1.0 0.5 0.0 0 10 20 30 40 50 60 Forward Current [mA] Rev1.0, May 26, 2014 5 www.seoulsemicon.com Preliminary Specification Product Data Sheet SAW0LH0A– Acrich MJT 5050 Forward Current Characteristics Fig 5. Forward Current vs. CIE X, Y Shift , Tj=25℃ 0.370 0.368 10mA 20mA CIE Y 0.366 30mA 40mA 0.364 50mA 0.362 0.360 0.344 60mA 0.346 0.348 0.350 CIE X Rev1.0, May 26, 2014 6 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Junction Temperature Characteristics Fig 6. Relative Light Output vs. Junction Temperature , I F=20mA Relative Light Output [a.u.] 1.2 1.0 0.8 0.6 0.4 0.2 0.0 0 25 50 75 100 o Junction Temperature [ C] 125 150 Fig 7. Relative Forward Voltage vs. Junction Temperature , IF=20mA Relative Forward Voltage [a.u.] 1.2 1.0 0.8 0.6 0.4 0.2 0.0 0 25 50 75 100 125 150 o Junction Temperature [ C] Rev1.0, May 26, 2014 7 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Junction Temperature Characteristics Fig 8. Junction Temp. vs. CIE X, Y Shift, IF=20mA 0.000 CIE X CIE Y -0.002 -0.004 CIE X,Y Shift -0.006 -0.008 -0.010 -0.012 -0.014 -0.016 -0.018 -0.020 0 25 50 75 100 125 150 o Junction Temperature [ C] Rev1.0, May 26, 2014 8 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Ambient Temperature Characteristics Fig 9. Maximum Forward Current vs. Ambient Temperature, T j(max.)=125℃, IF=60mA 0.07 Forward Current (A) 0.06 0.05 0.04 0.03 0.02 Rth(J-a) = 15 'C/W Rth(J-a) = 20 'C/W Rth(J-a) = 25 'C/W 0.01 0.00 0 25 50 75 100 125 O Ambient Temperature ( C) Rev1.0, May 26, 2014 9 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Color Bin Structure Bin Code description 1. Luminous Flux Bins - Luminous flux bin structure for cool white · Example BIN CODE : W2C0A Bin Code Luminous Flux [lm] W1 154.0~177.0 W2 177.0~200.0 X1 200.0~230.0 Available ranks Not yet available ranks 2. Cool White CIE Cool white product tested and binned by x,y coordinates and CCT · Example BIN CODE : W2C0A Color bin 3. Voltage Bins · Example BIN CODE : W2C0A Voltage bin Bin Code Voltage [V] A 60.0 - 63.0 B 63.0 – 65.0 C 65.0 – 68.0 Rev1.0, May 26, 2014 10 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Color Bin Structure Binning structure graphical representation < IF= 20mA, Tj=25℃ > 0.38 4700K 5000K C1 5300K CIE Y 0.36 C0 5600K B1 C2 B0 B3 C4 A1 B2 B5 A3 B4 6000K 6500K 0.34 7000K A0 A2 0.32 C3 C5 A5 A4 0.30 0.30 0.32 0.34 0.36 CIE X A0 CIE X 0.3028 0.3041 0.3126 0.3115 A1 CIE Y 0.3304 0.3240 0.3324 0.3393 CIE X 0.3115 0.3126 0.3210 0.3205 CIE Y 0.3324 0.3256 0.3334 0.3408 CIE X 0.3055 0.3068 0.3146 0.3136 CIE Y 0.3462 0.3389 0.3461 0.3539 CIE X 0.3292 0.3293 0.3373 0.3376 CIE Y 0.3461 0.3384 0.3451 0.3534 CIE X 0.3217 0.3222 0.3294 0.3293 CIE Y 0.3616 0.3534 0.3601 0.3687 CIE X 0.3463 0.3456 0.3539 0.3552 CIE Y 0.3601 0.3514 0.3578 0.3669 CIE X 0.3369 0.3366 0.344 0.3448 A3 CIE X 0.3126 0.3136 0.3216 0.3210 Rev1.0, May 26, 2014 CIE Y 0.3539 0.3461 0.3534 0.3616 CIE X 0.3212 0.3217 0.3293 0.3293 CIE Y 0.3316 0.3243 0.3306 0.3384 CIE X 0.3293 0.3294 0.3366 0.3369 CIE Y 0.3687 0.3601 0.3669 0.376 CIE X 0.3373 0.3369 0.3448 0.3456 CIE Y 0.3451 0.3369 0.3428 0.3514 CIE X 0.3448 0.344 0.3514 0.3526 CIE Y 0.3256 0.3187 0.3261 0.3334 B2 CIE Y 0.3389 0.3316 0.3384 0.3461 B5 CIE Y 0.3384 0.3306 0.3369 0.3451 C2 C4 11 CIE Y 0.3240 0.3177 0.3256 0.3324 A5 C1 C3 CIE X 0.3456 0.3448 0.3526 0.3539 CIE X 0.3136 0.3146 0.3221 0.3216 B4 C0 CIE X 0.3376 0.3373 0.3456 0.3463 CIE Y 0.3177 0.3113 0.3187 0.3256 B1 B3 CIE X 0.3293 0.3293 0.3369 0.3373 CIE X 0.3041 0.3055 0.3136 0.3126 A4 B0 CIE X 0.3207 0.3212 0.3293 0.3292 A2 CIE Y 0.3393 0.3324 0.3408 0.3481 CIE Y 0.3534 0.3451 0.3514 0.3601 C5 CIE Y 0.3514 0.3428 0.3487 0.3578 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Mechanical Dimensions < Top View > < Bottom View > < Side view> Cathode Anode < Inner Circuit Diagram> Cathode Anode ESD Protection Device Notes : (1) (2) (3) (4) All dimensions are in millimeters. Scale : none Undefined tolerance is ±0.1mm The appearance and specifications of the product may be changed for improvement without notice. Rev1.0, May 26, 2014 12 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Emitter Tape & Reel Packaging Notes : (1) Quantity : 7 inch reel type ( 1,000 pcs / Reel ) (2) Cumulative Tolerance : Cumulative Tolerance/10 pitches to be ±0.2mm (3) Adhesion Strength of Cover Tape : Adhesion strength to be 0.1-0.7N when the cover tape is turned off from the carrier tape at the angle of 10º to the carrier tape (4) Package : P/N, Manufacturing data Code No. and quantity to be indicated on a damp proof Package. Rev1.0, May 26, 2014 13 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Emitter Tape & Reel Packaging Reel Aluminum Bag Outer Box Rev1.0, May 26, 2014 14 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Product Nomenclature Part Number Form : X1X2X3X4X5X6X7X8 – X9X10X11X12X13 Part Number Code Description Part Number Value X1 Company S SSC X2 Package series A X3 W Color White X4 0 X5 Series number L X6 Voltage H X7 PCB type 0 Emitter X8 Revision No. A Rev0 X9X10 Luminous flux - - X11X12 Color bin - - X13 Voltage - - LF W1 L series Color bin 154.0~177.0 Voltage A 60.0 ~ 63.0 B 63.0 ~ 65.0 C 65.0 ~ 68.0 A0~A5 W2 177.0~200.0 X1 200.0~230.0 Rev1.0, May 26, 2014 B0~B5 C0~C5 15 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Recommended Solder Pad Notes : (1) (2) (3) (4) All dimensions are in millimeters. Scale : none This drawing without tolerances are for reference only Undefined tolerance is ±0.1mm Rev1.0, May 26, 2014 16 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Reflow Soldering Characteristics IPC/JEDEC J-STD-020 Table 5. Profile Feature Sn-Pb Eutectic Assembly Pb-Free Assembly Average ramp-up rate (Tsmax to Tp) 3° C/second max. 3° C/second max. Preheat - Temperature Min (Tsmin) - Temperature Max (Tsmax) - Time (Tsmin to Tsmax) 100 °C 150 °C 60-120 seconds 150 °C 200 °C 60-180 seconds Time maintained above: - Temperature (TL) - Time (tL) 183 °C 60-150 seconds 217 °C 60-150 seconds Peak Temperature (Tp) 215℃ 260℃ Time(tp) within 5°C of actual Peak Temperature 10-30 seconds 20-40 seconds Ramp-down Rate 6 °C/second max. 6 °C/second max. Time 25°C to Peak Temperature 6 minutes max. 8 minutes max. Caution (1) Reflow soldering is recommended not to be done more than two times. In the case of more than 24 hours passed soldering after first, LEDs will be damaged. (2) Repairs should not be done after the LEDs have been soldered. When repair is unavoidable, suitable tools must be used. (3) Die slug is to be soldered. (4) When soldering, do not put stress on the LEDs during heating. (5) After soldering, do not warp the circuit board. Rev1.0, May 26, 2014 17 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Handling of Silicone Resin for LEDs (1) During processing, mechanical stress on the surface should be minimized as much as possible. Sharp objects of all types should not be used to pierce the sealing compound. (2) In general, LEDs should only be handled from the side. By the way, this also applies to LEDs without a silicone sealant, since the surface can also become scratched. (3) When populating boards in SMT production, there are basically no restrictions regarding the form of the pick and place nozzle, except that mechanical pressure on the surface of the resin must be prevented. This is assured by choosing a pick and place nozzle which is larger than the LED’s reflector area. (4) Silicone differs from materials conventionally used for the manufacturing of LEDs. These conditions must be considered during the handling of such devices. Compared to standard encapsulants, silicone is generally softer, and the surface is more likely to attract dust. As mentioned previously, the increased sensitivity to dust requires special care during processing. In cases where a minimal level of dirt and dust particles cannot be guaranteed, a suitable cleaning solution must be applied to the surface after the soldering of components. (5) SSC suggests using isopropyl alcohol for cleaning. In case other solvents are used, it must be assured that these solvents do not dissolve the package or resin. Ultrasonic cleaning is not recommended. Ultrasonic cleaning may cause damage to the LED. (6) Please do not mold this product into another resin (epoxy, urethane, etc) and do not handle this product with acid or sulfur material in sealed space. (7) Avoid leaving fingerprints on silicone resin parts. Rev1.0, May 26, 2014 18 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Precaution for Use (1) Storage To avoid the moisture penetration, we recommend store in a dry box with a desiccant . The recommended storage temperature range is 5℃ to 30℃ and a maximum humidity of RH50%. (2) Use Precaution after Opening the Packaging Use proper SMD techniques when the LED is to be soldered dipped as separation of the lens may affect the light output efficiency. Pay attention to the following: a. Recommend conditions after opening the package - Sealing / Temperature : 5 ~ 40℃ Humidity : less than RH30% b. If the package has been opened more than 4 week(MSL_2a) or the color of the desiccant changes, components should be dried for 10-12hr at 60±5℃ (3) Do not apply mechanical force or excess vibration during the cooling process to normal temperature after soldering. (4) Do not rapidly cool device after soldering. (5) Components should not be mounted on warped (non coplanar) portion of PCB. (6) Radioactive exposure is not considered for the products listed here in. (7) Gallium arsenide is used in some of the products listed in this publication. These products are dangerous if they are burned or shredded in the process of disposal. It is also dangerous to drink the liquid or inhale the gas generated by such products when chemically disposed of. (8) This device should not be used in any type of fluid such as water, oil, organic solvent and etc. When washing is required, IPA (Isopropyl Alcohol) should be used. (9) When the LEDs are in operation the maximum current should be decided after measuring the package temperature. (10) LEDs must be stored properly to maintain the device. If the LEDs are stored for 3 months or more after being shipped from Seoul Semiconductor. A sealed container with a nitrogen atmosphere should be used for storage. (11) The appearance and specifications of the product may be modified for improvement without notice. (12) Long time exposure of sunlight or occasional UV exposure will cause lens discoloration. Rev1.0, May 26, 2014 19 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Precaution for Use (13) VOCs (Volatile organic compounds) emitted from materials used in the construction of fixtures can penetrate silicone encapsulants of LEDs and discolor when exposed to heat and photonic energy. The result can be a significant loss of light output from the fixture. Knowledge of the properties of the materials selected to be used in the construction of fixtures can help prevent these issues. (14) The slug is electrically isolated. (15) Attaching LEDs, do not use adhesives that outgas organic vapor. (16) The driving circuit must be designed to allow forward voltage only when it is ON or OFF. If the reverse voltage is applied to LED, migration can be generated resulting in LED damage. (17) LEDs are sensitive to Electro-Static Discharge (ESD) and Electrical Over Stress (EOS). Below is a list of suggestions that Seoul Semiconductor purposes to minimize these effects. a. ESD (Electro Static Discharge) Electrostatic discharge (ESD) is the defined as the release of static electricity when two objects come into contact. While most ESD events are considered harmless, it can be an expensive problem in many industrial environments during production and storage. The damage from ESD to an LEDs may cause the product to demonstrate unusual characteristics such as: - Increase in reverse leakage current lowered turn-on voltage - Abnormal emissions from the LED at low current The following recommendations are suggested to help minimize the potential for an ESD event. One or more recommended work area suggestions: - Ionizing fan setup - ESD table/shelf mat made of conductive materials - ESD safe storage containers One or more personnel suggestion options: - Antistatic wrist-strap - Antistatic material shoes - Antistatic clothes Environmental controls: - Humidity control (ESD gets worse in a dry environment) Rev1.0, May 26, 2014 20 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Precaution for Use b. EOS (Electrical Over Stress) Electrical Over-Stress (EOS) is defined as damage that may occur when an electronic device is subjected to a current or voltage that is beyond the maximum specification limits of the device. The effects from an EOS event can be noticed through product performance like: - Changes to the performance of the LED package (If the damage is around the bond pad area and since the package is completely encapsulated the package may turn on but flicker show severe performance degradation.) - Changes to the light output of the luminaire from component failure - Components on the board not operating at determined drive power Failure of performance from entire fixture due to changes in circuit voltage and current across total circuit causing trickle down failures. It is impossible to predict the failure mode of every LED exposed to electrical overstress as the failure modes have been investigated to vary, but there are some common signs that will indicate an EOS event has occurred: - Damaged may be noticed to the bond wires (appearing similar to a blown fuse) - Damage to the bond pads located on the emission surface of the LED package (shadowing can be noticed around the bond pads while viewing through a microscope) - Anomalies noticed in the encapsulation and phosphor around the bond wires. - This damage usually appears due to the thermal stress produced during the EOS event. c. To help minimize the damage from an EOS event Seoul Semiconductor recommends utilizing: - A surge protection circuit - An appropriately rated over voltage protection device - A current limiting device Rev1.0, May 26, 2014 21 www.seoulsemicon.com Product Data Sheet SAW0LH0A– Acrich MJT 5050 Company Information Published by Seoul Semiconductor © 2013 All Rights Reserved. Company Information Seoul Semiconductor (SeoulSemicon.com) manufacturers and packages a wide selection of light emitting diodes (LEDs) for the automotive, general illumination/lighting, appliance, signage and back lighting markets. The company is the world’s fifth largest LED supplier, holding more than 10,000 patents globally, while offering a wide range of LED technology and production capacity in areas such as “nPola”, deep UV LEDs, "Acrich", the world’s first commercially produced AC LED, and "Acrich MJT - Multi-Junction Technology" a proprietary family of high-voltage LEDs. The company’s broad product portfolio includes a wide array of package and device choices such as Acrich, high-brightness LEDs, mid-power LEDs, side-view LEDs, through-hole type LED lamps, custom displays, and sensors. The company is vertically integrated from epitaxial growth and chip manufacture in it’s fully owned subsidiary, Seoul Viosys, through packaged LEDs and LED modules in three Seoul Semiconductor manufacturing facilities. Seoul Viosys also manufactures a wide range of unique deep-UV wavelength devices. Legal Disclaimer Information in this document is provided in connection with Seoul Semiconductor products. With respect to any examples or hints given herein, any typical values stated herein and/or any information regarding the application of the device, Seoul Semiconductor hereby disclaims any and all warranties and liabilities of any kind, including without limitation, warranties of non-infringement of intellectual property rights of any third party. The appearance and specifications of the product can be changed to improve the quality and/or performance without notice. Rev1.0, May 26, 2014 22 www.seoulsemicon.com