LZ7-N4MU00-0000

LuxiGen™ Multi-Color Emitter Series LZ7 Flat Lens Emitter RGBW-PC Amber-Cyan-Violet LZ7-04MU00 Key Features  7-color surface mount ceramic LED package with integrated flat glass lens  Red, Green, Blue, Cool White, PC Amber, Cyan and Violet enables richer and wider color combination for more sophisticated color mixing  Compact 3.8mm Light Emitting Surface (LES) and low profile package maximize coupling efficiency into secondary optics  20W max power dissipation in a small 7.0mm x 7.0mm emitter footprint  Thermal resistance of 1.4 °C/W; up to 1.5A maximum drive current for individual die  Electrically neutral thermal path  JEDEC Level 1 for Moisture Sensitivity Level  Lead (Pb) free and RoHS compliant Typical Applications  Stage and Studio Lighting  Effect Lighting  Accent Lighting  Display Lighting  Architectural Lighting Description The LZ7 flat lens emitter contains 7 different colors LED dies closely packed in a low thermal resistance package with integrated glass window. The addition of PC Amber, Cyan and Violet to the traditional RGBW colors enables richer and wider color combination for more sophisticated color mixing. The compact 3.8mm LES, low profile package and glass window, allows maximum coupling efficiency into the zoom optics, mixing rods, light pipes and other secondary optics. The high quality materials used in the package are chosen to maximize light output and minimize stresses which results in monumental reliability and lumen maintenance. Notes This product emits Violet and Blue light, which can be hazardous depending on total system configuration (including, but not limited to optics, drive current and temperature). Do not stare directly into the beam and observe safety precaution given in IEC 62471 when operating this product. COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Part number options Base part number Part number Description LZ7-04MU00-0000 LZ7 RGBW-PC Amber-Cyan-Violet flat lens emitter LZ7-N4MU00-0000 LZ7 RGBW-PC Amber-Cyan-Violet flat lens emitter on 7 channel MCPCB Bin kit option codes MU, Red-Green-Blue-White (6500K)-PC Amber-Cyan-UV Kit number suffix Min flux Bin Color Bin Ranges 0000 07R1 R01 10G1 G2 – G3 09B B03 11W1 1V2U KL PCA 01C C14 01U U56 Description Red, full distribution flux; full distribution wavelength Green, full distribution flux; full distribution wavelength Blue, full distribution flux; full distribution wavelength White full distribution flux and CCT PC Amber, full distribution flux; full distribution wavelength Cyan, full distribution flux; full distribution wavelength Violet, full distribution flux; full distribution wavelength COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Daylight White Chromaticity Group 0.40 5630K 0.39 0.38 0.37 0.36 CIEy 0.35 0.34 1V2U 0.33 0.32 0.31 0.30 Planckian Locus 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 Group plotted on excerpt from the CIE 1931 (2°) x-y Chromaticity Diagram. Coordinates are listed below. Daylight White Bin Coordinates Bin Code 1V2U CIEx CIEy 0.3005 0.3415 0.3290 0.3690 0.3290 0.3180 0.3093 0.2993 0.3005 0.3415 COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 PC Amber Chromaticity Group Standard Chromaticity Group plotted on excerpt from the CIE 1931 (2°) x-y Chromaticity Diagram. Coordinates are listed below. PC Amber Bin Coordinates Bin Code PCA CIEx CIEy 0.5752 0.4242 0.5664 0.4140 0.5955 0.3895 0.6029 0.3965 0.5752 0.4242 COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Flux Bins Table 1: [1] Bin Code Red 07R1 07R2 10G1 10G2 09B Minimum Flux @ IF = 700mA Luminous Radiant (lm) (mW) PC Green Blue White Cyan Violet Amber 60 79 [1] Maximum Flux @ IF = 700mA Luminous Radiant (lm) (mW) PC Green Blue White Cyan Violet Amber Red 79 105 100 128 128 166 13 10B 11W1 11W2 KL 01C 01U 22 22 35 160 200 200 255 75 117 71 130 700 1100 Notes for Table 1: 1. Flux performance is measured at 10ms pulse, TC = 25°C. LED Engin maintains a tolerance of ±10% on flux measurements. Wavelength Bins Table 2: [1,2] Bin Code R01 G2 [1,2] Minimum Wavelength @ IF = 700mA Dominant (λD) Peak (λP) (nm) (nm) Red Green Blue Cyan Violet 617 520 G3 B03 C14 U56 Maximum Wavelength @ IF = 700mA Dominant (λD) Peak (λP) (nm) (nm) Red Green Blue Cyan Violet 630 525 525 530 453 460 490 510 390 400 Notes for Table 2: 1. Wavelength is measured at 10ms pulse, TC = 25oC. 2. LED Engin maintains a tolerance of ± 1.0nm on dominant wavelength measurements and ± 2.0nm on peak wavelength measurements. Forward Voltage Bin Table 3: Bin Code 0 Red Green 2.1 3.2 Minimum Forward Voltage (VF) @ IF = 700mA [1] (V) PC Blue White Cyan Amber 2.8 2.8 2.8 2.9 Violet Red Green 3.2 2.9 4.2 Maximum Forward Voltage (VF) @ IF = 700mA [1] (V) PC Blue White Cyan Amber 3.8 3.8 3.8 4.0 Violet 4.2 Notes for Table 3: 1. Forward voltage is measured at 10ms pulse, TC = 25oC. LED Engin maintains a tolerance of ± 0.04V for forward voltage measurements. COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Absolute Maximum Ratings Table 4: Symbol Value Unit DC Forward Current (@TJ = 125 C) – R, G, B, or W single die on o DC Forward Current (@TJ = 125 C) – PC-A, C or V single die on o DC Forward Current (@TJ = 125 C) – all 7 die on[1] Parameter IF(MAX) IF(MAX) IF(MAX) 1500 1000 850 mA mA mA Peak Pulsed Forward Current [2] IFP 2000 mA Power Dissipation Reverse Voltage Storage Temperature Junction Temperature Soldering Temperature [4] Pd VR Tstd 20 See Note 3 -40 ~ +150 125 260 W V °C °C °C o TJ(MAX) Tsol Notes for Table 4: 1. Maximum DC forward current is determined by the overall thermal resistance and ambient temperature. Follow the curves in Figure 11 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 3. 5. LED Engin recommends taking reasonable precautions towards possible ESD damages and handling the emitter 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 5: Parameter Symbol Luminous Flux (@ IF = 700mA) Luminous Flux (@ IF = 1000mA) Luminous Flux (@ IF = 1500mA) Radiant Flux (@ IF = 700mA) Radiant Flux (@ IF = 1000mA) Dominant Wavelength Peak Wavelength ΦV ΦV ΦV Φ Φ λD λP Correlated Color Temperature Color Rendering Index (CRI) Viewing Angle [3] Total Included Angle [4] CCT Ra 2Θ½ Θ0.9 Red 80 110 160 Green 140 180 220 Blue [1] 33 45 60 Typical White PC Amber 200 100 270 130 350 Cyan 95 120 Violet [2] 0.80 1.10 623 523 457 592 500 395 6500 75 120 160 Unit lm lm lm W W nm nm K Degrees Degrees Notes for Table 5: 1. When operating the Blue LED, observe IEC 62471 Risk Group 2 rating. Do not stare into the beam. 2. When operating the UV LED, observe IEC 62471 Risk Group 3 rating. Do not stare into the beam. 3. Viewing Angle is the off axis angle from emitter centerline where the luminous intensity is ½ of the peak value. 4. Total Included Angle is the total angle that includes 90% of the total luminous flux. Electrical Characteristics @TC = 25°C Table 6: Typical Unit Parameter Symbol Red Green Blue Cyan Violet Forward Voltage (@ IF = 700mA) Temperature Coefficient of Forward Voltage Thermal Resistance (Junction to Case) VF 2.5 3.6 3.2 3.2 3.2 3.6 3.7 V ΔVF/ΔTJ -1.9 -2.9 -2.0 -2.0 -2.0 -2.6 -2.2 mV/°C RΘJ-C White PC Amber 1.4 COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. °C/W LZ7-04MU00 (1.1 - 03/10/16) 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 IPC/JEDEC Moisture Sensitivity Level Table 7 - IPC/JEDEC J-STD-20D.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 7: 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. COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Mechanical Dimensions (mm) Pin Out Pin Die Color Polarity 2 B Red + 3 A Green + 5 C Blue + 6 F PC Amber + 8 E Cool White + 9 G Cyan - 11 D Violet + 14 D Violet - 15 G Cyan + 17 E Cool White - 20 F PC Amber - 21 C Blue - 23 A Green - 24 B Red - NC pins: 1, 4, 7, 10, 12, 13, 16, 18, 19, 22 DNC pins: none Note: NC = Not Internally Connected (Electrically Isolated) DNC = Do Not Connect (Electrically Non Isolated) Figure 1: Package Outline Drawing Notes for Figure 1: 1. Unless otherwise noted, the tolerance = ± 0.20 mm. 2. Thermal contact, Pad 25, is electrically neutral. 3. Temperature measurement point: side ceramic closest to the Ts point Recommended Solder Pad Layout (mm) Non-pedestal MCPCB Design Pedestal MCPCB Design Figure 2a: Recommended solder pad layout for anode, cathode, and thermal pad for non-pedestal and pedestal design Note for Figure 2a: 1. Unless otherwise noted, the tolerance = ± 0.20 mm. 2. Pedestal MCPCB allows the emitter thermal slug to be soldered directly to the metal core of the MCPCB. Such MCPCB eliminate the high thermal resistance dielectric layer that standard MCPCB technologies use in between the emitter thermal slug and the metal core of the MCPCB, thus lowering the overall system thermal resistance. 3. LED Engin recommends x-ray sample monitoring for solder voids underneath the emitter thermal slug. The total area covered by solder voids should be less than 20% of the total emitter thermal slug area. Excessive solder voids will increase the emitter to MCPCB thermal resistance and may lead to higher failure rates due to thermal over stress. COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Recommended Solder Mask Layout (mm) Non-pedestal MCPCB Design Pedestal MCPCB Design Figure 2b: Recommended solder mask opening for anode, cathode, and thermal pad for non-pedestal and pedestal design Note for Figure 2b: 1. Unless otherwise noted, the tolerance = ± 0.20 mm. Recommended 8 mil Stencil Apertures Layout (mm) Non-pedestal MCPCB Design Pedestal MCPCB Design Figure 2c: Recommended 8mil stencil apertures layout for anode, cathode, and thermal pad for non-pedestal and pedestal design Note for Figure 2c: 1. Unless otherwise noted, the tolerance = ± 0.20 mm. COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Reflow Soldering Profile Figure 3: Reflow soldering profile for lead free soldering Typical Radiation Pattern 100% 90% 80% Relatiive Intensity 70% 60% 50% 40% 30% 20% 10% 0% -90 -80 -70 -60 -50 -40 -30 -20 -10 0 10 20 30 40 50 60 70 80 90 Angular Displacement (Degrees) Figure 4: Typical representative spatial radiation pattern – all dies on COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Spectral Power Distribution 1.00 0.90 0.80 Relative Spectral Power Red 0.70 Green 0.60 Blue White 0.50 PC Amber 0.40 Cyan Violet 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. Typical Forward Current Characteristics 1,600 IF - Forward Current (mA) 1,400 1,200 1,000 800 600 Red Green 400 Blue/PC Amber/White Cyan 200 Violet 0 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 VF - Forward Voltage (V) Figure 6: Typical forward current vs. forward voltage @ TC = 25°C COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Typical Relative Flux over Current 200 180 160 Relative Flux (%) 140 120 Red 100 Green 80 Blue 60 White 40 20 0 0 200 400 600 800 1000 1200 1400 1600 IF - Forward Current (mA) Figure 7a: Typical relative luminous (radiant for Violet) flux vs. forward current @ TC = 25°C – R, G, B, W 160 140 Relative Flux (%) 120 100 80 PC Amber 60 Cyan 40 Violet * 20 * Radiant Flux 0 0 200 400 600 800 1000 1200 IF - Forward Current (mA) Figure 7b: Typical relative luminous (radiant for Violet) flux vs. forward current @ T C = 25°C – PC-A, C, V COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Typical Relative Flux over Temperature 140 120 Relative Flux (%) 100 80 Red Green 60 Blue White 40 20 0 0 20 40 60 80 100 120 100 120 TC - Case Temperature (°C) Figure 8a: Typical relative luminous flux vs. case temperature – R, G, B, W 120 Relative Flux (%) 100 80 60 PC Amber Cyan 40 Violet * * Radiant Flux 20 0 0 20 40 60 80 TC - Case Temperature (°C) Figure 8b: Typical relative luminous (radiant for Violet) flux vs. case temperature – PC-A, C, V COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Typical Wavelength Shift over Current 15.0 Red Wavelength Shift (nm) 10.0 Green Blue 5.0 0.0 -5.0 -10.0 -15.0 0 200 400 600 800 1000 1200 1400 1600 IF - Forward Current (mA) Figure 9a: Typical dominant wavelength shift vs. forward current @ TC = 25°C – R, G, B 15.0 Wavelength Shift (nm) 10.0 Cyan Violet * 5.0 * Peak Wavelength 0.0 -5.0 -10.0 -15.0 0 200 400 600 800 1000 1200 IF - Forward Current (mA) Figure 9b: Typical dominant (peak for Violet) wavelength shift vs. forward current @ T C = 25°C – C, V COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Typical Chromaticity Coordinate Shift over Current 0.010 0.008 0.006 Delta_Cx, Delta_Cy PC Amber - Delta Cx 0.004 PC Amber - Delta_Cy 0.002 0.000 -0.002 -0.004 -0.006 -0.008 -0.010 0 200 400 600 800 1000 1200 1400 1600 IF - Forward Current (mA) Figure 9c: Typical chromaticity coordinate shift vs. forward current @ TC = 25°C – PC Amber 0.0100 0.0080 0.0060 Delta_Cx, Delta_Cy White - Delta_Cx 0.0040 White - Delta_Cy 0.0020 0.0000 -0.0020 -0.0040 -0.0060 -0.0080 -0.0100 0 200 400 600 800 1000 1200 1400 1600 IF - Forward Current (mA) Figure 9d: Typical chromaticity coordinate shift vs. forward current @ T C = 25°C - White COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Typical Wavelength Shift over Temperature 10.0 8.0 Wavelength Shift (nm) 6.0 4.0 2.0 0.0 Red -2.0 Green -4.0 Blue -6.0 -8.0 -10.0 0 20 40 60 80 100 120 TC - Case Temperature (°C) Figure 10a: Typical dominant wavelength shift vs. case temperature – R, G, B 10.0 8.0 Wavelength Shift (nm) 6.0 4.0 2.0 0.0 Cyan -2.0 Violet * -4.0 * Peak Wavelength -6.0 -8.0 -10.0 0 20 40 60 80 100 120 TC - Case Temperature (°C) Figure 10b: Typical dominant (peak for Violet) wavelength shift vs. case temperature – C, V COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Typical Chromaticity Coordinate Shift over Temperature 0.010 Δ Cx, Δ Cy Chromaticity Coordinate Shift 0.008 PC Amber - Delta_Cx 0.006 PC Amber - Delta_Cy 0.004 0.002 0.000 -0.002 -0.004 -0.006 -0.008 -0.010 0 20 40 60 80 100 120 TC - Case Temperature (oC) Figure 10c: Typical chromaticity coordinate shift vs. case temperature – PC Amber Δ Cx, Δ Cy Chromaticity Coordinate Shift 0.020 0.015 0.010 White - Delta_Cx 0.005 White - Delta_Cy 0.000 -0.005 -0.010 -0.015 -0.020 0 20 40 60 TC - Case Temperature 80 100 120 (oC) Figure 10d: Typical chromaticity coordinate shift vs. case temperature - White COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 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 Current De-rating 900 850 800 700 IF - Forward Current (mA) (Rated) 600 500 RΘJA = 2°C/W 400 RΘJA = 3°C/W RΘJA = 4°C/W 300 200 100 0 0 25 50 75 100 125 TA - Ambient Temperature (°C) Figure 11: Maximum forward current vs. ambient temperature Notes for Figure 11: 1. Maximum current assumes that all 7 LED die are operating concurrently at the same current. 2. RΘJ-C [Junction to Case Thermal Resistance] for LZ7-04MU00 is 1.4°C/W. 3. RΘJ-A [Junction to Ambient Thermal Resistance] = RΘJ-C + RΘC-A [Case to Ambient Thermal Resistance]. COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 18 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 12: Emitter carrier tape specifications (mm). Ø 178mm (SMALL REEL) Ø 330mm (LARGE REEL) Figure 13: Emitter reel specifications (mm). Notes for Figure 13: 1. Small reel quantity: up to 250 emitters 2. Large reel quantity: 250-1200 emitters. 3. Single flux bin and single wavelength bin per reel. COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 19 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 LZ7 MCPCB Family Part number LZ7-Nxxxxx Type of MCPCB 7-channel Dimension (mm) 38.3 x 31.2 COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. Emitter + MCPCB Thermal Resistance (oC/W) Typical Vf (V) Typical If (mA) 1.4 + 0.1 = 1.5 Red: 2.5V Green: 3.6V Blue: 3.2V White: 3.2V PC-A: 3.2V Cyan: 3.6V Violet: 3.7V 700 LZ7-04MU00 (1.1 - 03/10/16) 20 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 LZ7-Nxxxxx 7 channel, MCPCB (7x1) Dimensions (mm) Notes:  Unless otherwise noted, the tolerance = ± 0.2 mm.  Standard screw refers to M3 or #4-40 screw.  The thermal resistance of the MCPCB is: RΘC-B 0.1°C/W Components used MCPCB: Thermistor: MHE-301 copper NCP15XH103F03RC (Rayben) (Murata) Pad layout Ch. 1 2 3 4 5 6 7 T MCPCB Pad 1 14 2 13 3 12 4 11 5 10 6 9 7 8 1-RT 2-RT Die/ Color B/ Red A/ Green C/ Blue F/ PC Amber E/ CW G/ Cyan D/ UV NTC Function Anode + Cathode Anode + Cathode Anode + Cathode Anode + Cathode Anode + Cathode Cathode Anode + Anode + Cathode 10kOhm NTC COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 21 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 Application Guidelines MCPCB Assembly Recommendations A good thermal design requires an efficient heat transfer from the MCPCB to the heat sink. In order to minimize air gaps in between the MCPCB and the heat sink, it is common practice to use thermal interface materials such as thermal pastes, thermal pads, phase change materials and thermal epoxies. Each material has its pros and cons depending on the design. Thermal interface materials are most efficient when the mating surfaces of the MCPCB and the heat sink are flat and smooth. Rough and uneven surfaces may cause gaps with higher thermal resistances, increasing the overall thermal resistance of this interface. It is critical that the thermal resistance of the interface is low, allowing for an efficient heat transfer to the heat sink and keeping MCPCB temperatures low. When optimizing the thermal performance, attention must also be paid to the amount of stress that is applied on the MCPCB. Too much stress can cause the ceramic emitter to crack. To relax some of the stress, it is advisable to use plastic washers between the screw head and the MCPCB and to follow the torque range listed below. For o applications where the heat sink temperature can be above 50 C, it is recommended to use high temperature and rigid plastic washers, such as polycarbonate or glass-filled nylon. LED Engin recommends the use of the following thermal interface materials: 1. Bergquist’s Gap Pad 5000S35, 0.020in thick  Part Number: Gap Pad® 5000S35 0.020in/0.508mm  Thickness: 0.020in/0.508mm  Thermal conductivity: 5 W/m-K  Continuous use max temperature: 200°C  Using M3 Screw (or #4 screw), with polycarbonate or glass-filled nylon washer (#4) the recommended torque range is: 50 to 60 in-oz (3.13 to 3.75 in-lbs or 0.35 to 0.42 N-m) 2. 3M’s Acrylic Interface Pad 5590H  Part number: 5590H @ 0.5mm  Thickness: 0.020in/0.508mm  Thermal conductivity: 3 W/m-K  Continuous use max temperature: 100°C  Using M3 Screw (or #4 screw), with polycarbonate or glass-filled nylon washer (#4) the recommended torque range is: 50 to 60 in-oz (3.13 to 3.75 in-lbs or 0.35 to 0.42 N-m) Mechanical Mounting Considerations The mounting of MCPCB assembly is a critical process step. Excessive mechanical stress build up in the MCPCB can cause the MCPCB to warp which can lead to emitter substrate cracking and subsequent cracking of the LED dies LED Engin recommends the following steps to avoid mechanical stress build up in the MCPCB: o Inspect MCPCB and heat sink for flatness and smoothness. o Select appropriate torque for mounting screws. Screw torque depends on the MCPCB mounting method (thermal interface materials, screws, and washer). o Always use three M3 or #4-40 screws with #4 washers. o When fastening the three screws, it is recommended to tighten the screws in multiple small steps. This method avoids building stress by tilting the MCPCB when one screw is tightened in a single step. o Always use plastic washers in combinations with the three screws. This avoids high point contact stress on the screw head to MCPCB interface, in case the screw is not seated perpendicular. o In designs with non-tapped holes using self-tapping screws, it is common practice to follow a method of three turns tapping a hole clockwise, followed by half a turn anti-clockwise, until the appropriate torque is reached. COPYRIGHT © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 22 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 Wire Soldering   o To ease soldering wire to MCPCB process, it is advised to preheat the MCPCB on a hot plate of 125-150 C. 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 © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 23 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, Inc., based in California’s Silicon Valley, specializes in ultra-bright, ultra compact solid state lighting solutions allowing lighting designers & engineers the freedom to create uncompromised yet energy efficient lighting experiences. The LuxiGen™ Platform — an emitter and lens combination or integrated module solution, delivers superior flexibility in light output, ranging from 3W to 90W, a wide spectrum of available colors, including whites, multi-color and UV, and the ability to deliver upwards of 5,000 high quality lumens to a target. The small size combined with powerful output allows for a previously unobtainable freedom of design wherever high-flux density, directional light is required. LED Engin’s packaging technologies lead the industry with products that feature lowest thermal resistance, highest flux density and consummate reliability, enabling compact and efficient solid state lighting solutions. 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 © 2016 LED ENGIN. ALL RIGHTS RESERVED. LZ7-04MU00 (1.1 - 03/10/16) 24 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