LZC-C0SW00-0000

Studio White LED Emitter LZC-00SW00 Key Features  12-die Studio White (5300K) LED  CCT and color rendering matched to HID arc lamp  CRI85 minimum / R9 50 typical  Up to 42 Watt power dissipation on compact 9.0mm x 9.0mm footprint  Industry lowest thermal resistance per package size (0.7°C/W)  Engineered ceramic package with integrated glass lens  JEDEC Level 1 for Moisture Sensitivity Level  Lead (Pb) free and RoHS compliant  Reflow solderable (up to 6 cycles)  Emitter available with several MCPCB options  Full suite of TIR secondary optics family available Typical Applications  Studio Lighting  Photography Lighting  High-end retail Lighting  Showrooms Lighting Description The LZC-00SW00 Studio White LED emitter features CCT and color rendering matched to HID arc lamps used in studio lighting. It delivers a daylight color temperature of 5300K, CRI greater than 85 and R9 red content of 50, resulting in a natural color rendering of skin tones and other colors, which cannot be obtained by standard daylight white LED emitters. The emitter, based on LED Engin’s LuxiGen technology platform, may be driven up to 42W of power in a compact 9.0mmx9.0mm footprint. It has the industry lowest thermal resistance per package size, which allows users to drive the emitter with higher current, while keeping the junction temperature low to ensure long operating life. COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com Part number options Base part number Part number Description LZC-00SW00-xxxx LZC Studio White emitter LZC-70SW00-xxxx LZC Studio White emitter on 1 channel 1x12 Star MCPCB LZC-C0SW00-xxxx LZC Studio White emitter on 2 channel 2x6 Star MCPCB Bin kit option codes SW, Studio-White (5300K) Kit number suffix Min flux Bin Color Bin Ranges Description 0000 Y 2D, 2C, 3A, 3B full distribution flux; full distribution CCT COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 2 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com Studio White Chromaticity Groups 0.40 5630K 0.39 0.38 0.37 0.36 3B 0.35 CIEy Planckian Locus 2C 3A 0.34 2D 0.33 0.32 0.31 0.30 0.29 0.28 0.28 0.29 0.30 0.31 0.32 0.33 0.34 0.35 0.36 0.37 0.38 CIEx Standard Chromaticity Groups plotted on excerpt from the CIE 1931 (2°) x-y Chromaticity Diagram. Coordinates are listed below in the table. Studio White Bin Coordinates Bin code 2D 3A CIEx 0.329 0.3371 0.3366 0.329 0.329 0.3371 0.3451 0.344 0.3366 0.3371 CIEy 0.3417 0.349 0.3369 0.33 0.3417 0.349 0.3554 0.3427 0.3369 0.349 Bin code 2C 3B CIEx 0.329 0.3376 0.3371 0.329 0.329 0.3376 0.3463 0.3451 0.3371 0.3376 CIEy 0.3538 0.3616 0.349 0.3417 0.3538 0.3616 0.3687 0.3554 0.349 0.3616 COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 3 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com Luminous Flux Bins Table 1: Bin Code Minimum Luminous Flux (ΦV) @ IF = 700mA [1,2] (lm) Maximum Luminous Flux (ΦV) @ IF = 700mA [1,2] (lm) Y 1,357 1,696 Z 1,696 2,120 Notes for Table 1: 1. Luminous flux performance guaranteed within published operating conditions. LED Engin maintains a tolerance of ± 10% on flux measurements. 2. Luminous Flux typical value is for all 12 LED dice operating concurrently at rated current. Forward Voltage Bins Table 2: Bin Code Minimum Forward Voltage (VF) @ IF = 700mA [1,2] (V) Maximum Forward Voltage (VF) @ IF = 700mA [1,2] (V) 0 36.0 43.2 Notes for Table 2: 1. LED Engin maintains a tolerance of ± 0.48V for forward voltage measurements. 2. Forward Voltage is binned with 12 LED dice connected in series. The actual LED is configured with two strings of 6 dice in series. COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 4 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com Absolute Maximum Ratings Table 3: Parameter Symbol Value Unit DC Forward Current at Tjmax=130C [1] DC Forward Current at Tjmax=150C [1] Peak Pulsed Forward Current [2] Reverse Voltage Storage Temperature Junction Temperature Soldering Temperature [4] Allowable Reflow Cycles IF IF IFP VR Tstg TJ Tsol 1200 1000 1500 See Note 3 -40 ~ +150 150 260 6 mA mA mA V °C °C °C > 8,000 V HBM Class 3B JESD22-A114-D ESD Sensitivity [5] Notes for Table 3: 1. Maximum DC forward current (per die) is determined by the overall thermal resistance and ambient temperature. Follow the curves in Figure 10 for current derating. 2: Pulse forward current conditions: Pulse Width ≤ 10msec and Duty cycle ≤ 10%. 3. LEDs are not designed to be reverse biased. 4. Solder conditions per JEDEC 020D. See Reflow Soldering Profile Figure 5. 5. LED Engin recommends taking reasonable precautions towards possible ESD damages and handling the LZ4-00SW00 in an electrostatic protected area (EPA). An EPA may be adequately protected by ESD controls as outlined in ANSI/ESD S6.1. Optical Characteristics @ TC = 25°C Table 4: Parameter Symbol Typical Unit Luminous Flux (@ IF = 700mA) [1] Luminous Flux (@ IF = 1000mA) [1] Luminous Efficacy (@ IF = 350mA) Correlated Color Temperature Color Rendering Index (CRI) Viewing Angle [2] ΦV ΦV 1900 2450 89 5300 88 110 lm lm lm/W K CCT Ra 2Θ1/2 Degrees Notes for Table 4: 1. Luminous flux typical value is for all 12 LED dice operating concurrently at rated current. 2. Viewing Angle is the off-axis angle from emitter centerline where the luminous intensity is ½ of the peak value. Electrical Characteristics @ TC = 25°C Table 5: Parameter Symbol Typical Unit Forward Voltage (@ IF = 700mA) Forward Voltage (@ IF = 1000mA) [1] VF VF 38.8 40.0 V V Temperature Coefficient of Forward Voltage [1] ΔVF/ΔTJ -24.0 mV/°C Thermal Resistance (Junction to Case) RΘJ-C 0.7 °C/W [1] Notes for Table 5: 1. Forward Voltage is binned with 12 LED dice connected in series. The actual LED is configured with two strings of 6 dice in series. COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 5 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com IPC/JEDEC Moisture Sensitivity Level Table 6 - IPC/JEDEC J-STD-20.1 MSL Classification: Soak Requirements Floor Life Standard Accelerated Level Time Conditions Time (hrs) Conditions Time (hrs) Conditions 1 unlimited ≤ 30°C/ 85% RH 168 +5/-0 85°C/ 85% RH n/a n/a Notes for Table 6: 1. The standard soak time includes a default value of 24 hours for semiconductor manufacturer’s exposure time (MET) between bake and bag and includes the maximum time allowed out of the bag at the distributor’s facility. Average Lumen Maintenance Projections Lumen maintenance generally describes the ability of a lamp to retain its output over time. The useful lifetime for solid state lighting devices (Power LEDs) is also defined as Lumen Maintenance, with the percentage of the original light output remaining at a defined time period. Based on long-term WHTOL testing, LED Engin projects that the LZC Series will deliver, on average, 70% Lumen Maintenance at 70,000 hours of operation at a forward current of 700 mA per die. This projection is based on constant current operation with junction temperature maintained at or below 110°C. COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 6 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com Mechanical Dimensions (mm) Pin Out Pad Channel Function 2 1 Anode 3 1 Anode 5 2 Anode 6 2 Anode 14 2 Cathode 15 2 Cathode 17 1 Cathode 18 1 Cathode Figure 1: Package outline drawing. Notes for Figure 1: 1. LZC-00SW00 is compatible with MCPCB designed for other LZC White emitters (i.e. LZC-00xW00) when emitter is rotated 180 degree with respect to the LZCxW00 position on the MCPCB. 2. Index mark, Tc indicates case temperature measurement point. 3. Unless otherwise noted, the tolerance = ± 0.20 mm. 4. Thermal contact pad is electrically neutral. Recommended Solder Pad Layout (mm) Figure 2a: Recommended solder pad layout for anode, cathode, and thermal pad. Note for Figure 2a: 1. Unless otherwise noted, the tolerance = ± 0.20 mm. COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 7 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com Recommended 8mil Stencil Apertures Layout (mm) Figure 2b: Recommended solder mask opening for anode, cathode, and thermal pad. Note for Figure 2b: 1. Unless otherwise noted, the tolerance = ± 0.20 mm. Reflow Soldering Profile Figure 3: Reflow soldering profile for lead free soldering. COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 8 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com Typical Radiation Pattern Figure 4: Typical representative spatial radiation pattern. Typical Relative Spectral Power Distribution 1.00 0.90 Relative Spectral Power 0.80 0.70 0.60 0.50 0.40 0.30 0.20 0.10 0.00 350 400 450 500 550 600 650 700 750 800 Wavelength (nm) Figure 5: Typical relative spectral power vs. wavelength @ TC = 25°C. COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 9 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com Typical Chromaticity Coordinate Shift over Temperature 0.02 0.015 Cx 0.01 Cy Cx, Cy 0.005 3E-17 -0.005 -0.01 -0.015 -0.02 0 10 20 30 40 50 60 70 80 90 100 Case Temperature (°C) Figure 6: Typical chromaticity coordinate shift vs. Case temperature. Typical Relative Light Output 160% 140% Relatiive Light Output 120% 100% 80% 60% 40% 20% 0% 0 200 400 600 800 1000 1200 IF - Forward Current (mA) Figure 7: Typical relative light output vs. forward current @ TC = 25°C. Notes for Figure 7: 1. Luminous Flux typical value is for all 12 LED dice operating concurrently at rated current. COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 10 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com Typical Relative Light Output over Temperature Relatiive Light Output (%) 110 100 90 80 70 60 0 10 20 30 40 50 60 70 80 90 100 Case Temperature (°C) Figure 8: Typical relative light output vs. case temperature. Notes for Figure 8: 1. Luminous Flux typical value is for all 12 LED dice operating concurrently at rated current. Typical Forward Current Characteristics 1200 IF - Forward Current (mA) 1000 800 600 400 200 0 31.0 33.0 35.0 37.0 39.0 41.0 43.0 VF - Forward Voltage (V) Figure 9: Typical forward current vs. forward voltage @ TC = at 25°C. Note for Figure 9: 1. Forward Voltage assumes 12 LED dice connected in series. The actual LED is configured with two strings of 6 dice in series. COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 11 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com Current De-rating IF - Maximum Current (mA) 1200 1000 800 700 (Rated) 600 400 RΘJ-A = 2.0°C/W RΘJ-A = 3.0°C/W RΘJ-A = 4.0°C/W 200 0 0 25 50 75 100 125 150 Maximum Ambient Temperature (°C) Figure 10: Maximum forward current vs. ambient temperature based on T J(MAX) = 150°C. Notes for Figure 10: 1. Maximum current assumes that all LED dice are operating concurrently at the same current. 2. RΘJ-C [Junction to Case Thermal Resistance] for the LZC-00xx00 is typically 0.7°C/W. 3. RΘJ-A [Junction to Ambient Thermal Resistance] = RΘJ-C + RΘC-A [Case to Ambient Thermal Resistance]. COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 12 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com Emitter Tape and Reel Specifications (mm) Figure 11: Emitter carrier tape specifications (mm). Figure 12: Emitter Reel specifications (mm). COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 13 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com LZC MCPCB Family Emitter + MCPCB Typical Vf Typical If Thermal Resistance (V) (mA) (oC/W) Part number Type of MCPCB Diameter (mm) LZC-7xxxxx 1-channel 28.3 0.7 + 0.6 = 1.3 38.8 700 LZC-Cxxxxx 2-channel 28.3 0.7 + 0.6 = 1.3 19.4 2 x 700 Mechanical Mounting of MCPCB   MCPCB bending should be avoided as it will cause mechanical stress on the emitter, which could lead to substrate cracking and subsequently LED dies cracking. To avoid MCPCB bending: o Special attention needs to be paid to the flatness of the heat sink surface and the torque on the screws. o Care must be taken when securing the board to the heat sink. This can be done by tightening three M3 screws (or #4-40) in steps and not all the way through at once. Using fewer than three screws will increase the likelihood of board bending. o It is recommended to always use plastics washers in combinations with the three screws. o If non-taped holes are used with self-tapping screws, it is advised to back out the screws slightly after tightening (with controlled torque) and then re-tighten the screws again. Thermal interface material    To properly transfer heat from LED emitter to heat sink, a thermally conductive material is required when mounting the MCPCB on to the heat sink. There are several varieties of such material: thermal paste, thermal pads, phase change materials and thermal epoxies. An example of such material is Electrolube EHTC. It is critical to verify the material’s thermal resistance to be sufficient for the selected emitter and its operating conditions. Wire soldering   To ease soldering wire to MCPCB process, it is advised to preheat the MCPCB on a hot plate of 125-150oC. Subsequently, apply the solder and additional heat from the solder iron will initiate a good solder reflow. It is recommended to use a solder iron of more than 60W. It is advised to use lead-free, no-clean solder. For example: SN-96.5 AG-3.0 CU 0.5 #58/275 from Kester (pn: 24-7068-7601) COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 14 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com LZC-7xxxxx 1-Channel MCPCB Mechanical Dimensions (mm) Tc Notes: • Unless otherwise noted, the tolerance = ± 0.2 mm. • Slots in MCPCB are for M3 or #4-40 mounting screws. • LED Engin recommends plastic washers to electrically insulate screws from solder pads and electrical traces. • Electrical connection pads on MCPCB are labeled “+” for Anode and “-” for Cathode. • LED Engin recommends using thermal interface material when attaching the MCPCB to a heatsink. • The thermal resistance of the MCPCB is: RΘC-B 0.6°C/W Components used MCPCB: ESD chips: HT04503 BZX585-C51 (Bergquist) (NPX, for 12 LED dies in series) Pad layout Ch. 1 MCPCB Pad + - String/die Function 1/BCEFGHJ KLMPQ Anode + Cathode - COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 15 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com LZC-Cxxxxx 2 channel, Star MCPCB (2x6) Dimensions (mm) Tc Notes: • Unless otherwise noted, the tolerance = ± 0.2 mm. • Slots in MCPCB are for M3 or #4-40 mounting screws. • LED Engin recommends plastic washers to electrically insulate screws from solder pads and electrical traces. • Electrical connection pads on MCPCB are labeled “+” for Anode and “-” for Cathode. • LED Engin recommends thermal interface material when attaching the MCPCB to a heatsink. • The thermal resistance of the MCPCB is: RΘC-B 0.6°C/W Components used MCPCB: ESD chips: HT04503 BZT52C36LP (Bergquist) (NPX, for 6 LED dies in series) Pad layout Ch. 1 2 MCPCB Pad 1+ 12+ 2- String/die 1/JKLMPQ 2/BCEFGH Function Anode + Cathode Anode + Cathode - COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 16 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com Company Information LED Engin, based in California’s Silicon Valley, develops, manufactures, and sells advanced LED emitters, optics and light engines to create uncompromised lighting experiences for a wide range of entertainment, architectural, general lighting and specialty applications. LuxiGen™ multi-die emitter and secondary lens combinations reliably deliver industry-leading flux density, upwards of 5000 quality lumens to a target, in a wide spectrum of colors including whites, tunable whites, multi-color and UV LEDs in a unique patented compact ceramic package. Our LuxiTuneTM series of tunable white lighting modules leverage our LuxiGen emitters and lenses to deliver quality, control, freedom and high density tunable white light solutions for a broad range of new recessed and downlighting applications. The small size, yet remarkably powerful beam output and superior in-source color mixing, allows for a previously unobtainable freedom of design wherever high-flux density, directional light is required. LED Engin is committed to providing products that conserve natural resources and reduce greenhouse emissions. LED Engin reserves the right to make changes to improve performance without notice. Please contact sales@ledengin.com or (408) 922-7200 for more information. COPYRIGHT © 2014 LED ENGIN. ALL RIGHTS RESERVED. LZC-00SW00 (1.2-08/23/14) 17 LED Engin | 651 River Oaks Parkway | San Jose, CA 95134 USA | ph +1 408 922 7200 | fax +1 408 922 0158 | em sales@ledengin.com | www.ledengin.com