5W Emitter Led Datasheet

7/27/2019 5W Emitter Led Datasheet

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ProLight PG1N-5LXE5W Power LED

Technical Datasheet

Version: 1.0

Features? High Flux per LED

? Very long operating life(up to 100k hours)

? Available in White, Warm White, Green, Blue, Amber, Red-Orangeand Red

? Lambertian or Collimated Radiation Pattern

? More Energy Efficient than Incandescent and most Halogen lamps

? Low Voltage DC operated

? Cool beam, safe to the touch

? Instant light (less than 100ns)

? No UV

? Superior ESD protection

? Soldering methods: IR reflow soldering and Hand soldering

Typical Applications? Reading lights (car, bus, aircraft)

? Portable (flashlight, bicycle)

? Decorative

? Appliance

? Sign and Channel Letter

? Architectural Detail

? Cove Lighting

? Automotive Exterior (Stop-Tail-Turn, CHMSL, Mirror Side Repeat)

? LCD backlight

1

10 Melfort Avenue | Clydebank, G81 2HX | Tel. 0141 5625627 | Fax 0870 7621832 | www.led-bulbs.com

rolight 5W Emitter


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Mechanical Dimensions

2

Notes:

1. The cathode side of the device is denoted by a

hole in the lead frame.

2. Electrical insulation between the case and the

board is required-slug of device is not electrically

neutral. Do not electrically connect either the

anode or cathode to the slug.

3. Drawing not to scale.4. All dimensions are in millimeters.

5 .All dimendions without tolerances are for

reference only.


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Part Number Matrix

Color Emitter STAR Beam Pattern

White PG1N-5LWE PG1N-5LWS

Lambertian

Warm White PG1N-5LVE PG1N-5LVS

Green PG1N-5LGE PG1N-5LGS

Blue PG1N-5LBE PG1N-5LBS

Amber PG1N-5LAE PG1N-5LAS

Red-Orange PG1N-5LHE PG1N-5LHS

Red PG1N-5LRE PG1N-5LRS

Flux Characteristics at 700mA, Junction Temperature, Tj=25Color Minimum Luminous Flux (lm) Typical Luminous Flux (lm) Beam Pattern

White 67.2 116

Lambertian

Warm White 67.2 108

Green 67.2 120

Blue 18.1 40

Amber - 120

Red-Orange - 144

Red - 120

Optical Characteristics at 700mA, Junction Temperature, Tj=25Dominant Wavelength D Temperature

Peak Wavelength p Spectral Coefficient or

Color Temperature(CCT) Half-width (nm) Dominant Wavelength

Color Min. Typ. Max. 1/2 D/Tj (nm/)

White 4500K 5500K 10000K - -

Warm White 2850K 3300K 3800K - -

Green 520nm 530nm 550nm 35 0.04

Blue 460nm 470nm 490nm 25 0.04Amber 584.5nm 590nm 597nm 20 0.05

Red-Orange 610nm 617nm 620.5nm 20 0.05

Red 620.5nm 625nm 645nm 20 0.05

3


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Optical Characteristics at 700mA, Junction Temperature, Tj=25( Continued)

Total Included Angle Viewing Angle Typical Candela

Color Beam Pattern 0.9v (degree) 21/2 (degree) on Axis (cd)

White

Lambertian

160 140

Warm White 160 140

Green 160 140

Blue 160 140

Amber 160 140

Red-Orange 160 140

Red 160 140

Electr ical Characteristics at 700mA, Junction Temperature, Tj=25Temperature Thermal

Coefficient of Resistance

Forward Voltage Vf(V) Dynamic Vf(mV/) Junction to

Color Min. Typ. Max. Resistance() Vf/Tj Board(/W)

White 5.43 7.10 7.98 1.0 -4 8

Warm White 5.43 7.10 7.98 1.0 -4 8

Green 5.43 7.10 7.98 1.0 -4 8

Blue 5.43 7.10 7.98 1.0 -4 8Amber 3.75 4.40 6.20 2.4 -4 8

Red-Orange 3.75 4.40 6.20 2.4 -4 8

Red 3.75 4.40 6.20 2.4 -4 8

4


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Absolute Maximum RatingsParameter White/Warm White/Green/Blue Amber/Red-Orange/Red

DC Forward Current (mA) 700 770

Peak Pulsed Forward Current (mA) 1000 1100

Average Forward Current (mA) 700 700

ESD Sensitivity 16000V HBM

LED Junction Temperature () 135 120

Aluminum-core PCB Temperature() 105 105

Storage & Operating Temperature() -40 to +105 -40 to +105

Soldering Temperature() 260 for 5 seconds Max.

Photometric Luminous Flux Bin StructureBin Code Minimum Photometric Flux (lm) Maximum Photometric Flux (lm)

L 10.7 13.9

M 13.9 18.1

N 18.1 23.5P 23.5 30.6

Q 30.6 39.8

R 39.8 51.7

S 51.7 67.2

T 67.2 87.4

U 87.4 113.6

V 113.6 147.7

W 147.7 192.0

Tolerance on each Luminous Flux bin is 15%

Color Bins for AmberBin Code Minimum Dominant Wavelength (nm) Maximum Dominant Wavelength (nm)

1 584.5 587.0

2 587.0 589.5

4 589.5 592.0

6 592.0 594.5

7 594.5 597.0

Tolerance on each Color bin is 1nm

Color Bins for Red-OrangeBin Code Minimum Dominant Wavelength (nm) Maximum Dominant Wavelength (nm)

1 610.0 613.5

2 613.5 620.5


5


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Color Bins for Red

Bin Code Minimum Dominant Wavelength (nm) Maximum Dominant Wavelength (nm)

2 613.5 620.5

4 620.5 631.0

5 631.0 645.0


Color Bins for Blue


1 460 465

2 465 470

3 470 475

4 475 480

5 480 485

6 485 490


Color Bins for Green


1 520 525

2 525 530

3 530 535

4 535 540

5 540 545

6 545 550


Color Bins for White

Bin Code X YTyp. CCT

(K)Bin Code X Y

Typ. CCT

(K)

V0

0.346 0.359

5350 X0

0.316 0.333

67000.344 0.344 0.317 0.32

0.329 0.331 0.308 0.311

0.329 0.345 0.305 0.322

V1

0.367 0.4

5500 X1

0.329 0.369

63000.362 0.372 0.329 0.345

0.329 0.345 0.305 0.322

0.329 0.369 0.301 0.342

W0

0.329 0.345

6050 YA

0.308 0.311

80000.329 0.331 0.311 0.293

0.317 0.32 0.29 0.27

0.316 0.333 0.283 0.284

WA

0.329 0.331

6300 Y0

0.303 0.333

80000.33 0.31 0.308 0.311

0.311 0.293 0.283 0.284

0.308 0.311 0.274 0.301

Tolerance on each Color bin (x , y) is 0.01

6


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Color Bins for White

Color Bins for Warm White

Bin Code X YTyp. CCT

(K)Bin Code X Y

Typ. CCT

(K)

N0

0.438 0.412

2950 Q0

0.409 0.4

3370

0.429 0.394 0.402 0.382

0.444 0.399 0.416 0.3890.453 0.416 0.424 0.406

0.438 0.412 0.409 0.4

N1

0.454 0.446

2950 R0

0.392 0.391

3640

0.438 0.412 0.387 0.374

0.453 0.416 0.402 0.382

0.471 0.451 0.409 0.4

0.454 0.446 0.392 0.391

P0

0.424 0.406

3150 R1

0.402 0.423

3500

0.416 0.389 0.392 0.391

0.429 0.394 0.424 0.406

0.438 0.412 0.438 0.44

0.424 0.406 0.402 0.423

P1

0.438 0.44

3150 RA

0.387 0.374

3500

0.424 0.406 0.383 0.36

0.438 0.412 0.41 0.374

0.454 0.446 0.416 0.389

0.438 0.44 0.387 0.374

Tolerance on each Color bin (x , y) is 0.01

7

0.25

0.27

0.29

0.31

0.33

0.35

0.37

0.39

0.41

0.25 0.3 0.35 0.4

X

Y

Y0

V1

V0

YA

WA

X1

X0

W0

CCT 4500KCCT 5000KCCT 5500K

CCT 6000K

CCT 7000K

CCT 8000K


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Color Bins for Warm White

8

0.34

0.36

0.38

0.4

0.42

0.44

0.46

0.36 0.4 0.44 0.48

X

Y

R1

CCT 3250KCCT 3490K

CCT 3800K

CCT 3050K CCT 2850K

R0

N1

N0

RA

P1

Q0P0


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Wavelength Characterist ics, Tj=25

White Color Spectrum

Warm White Color Spectrum

9

0.0

0.2

0.4

0.6

0.8

1.0

400 450 500 550 600 650 700

Wavelength(nm)

RelativeSpectralPowe

rDistribution

Blue RedGreen

0

0.2

0.4

0.6

0.8

1

350 400 450 500 550 600 650 700 750 800 850

Wavelength(nm)

RelativeSpectralPower

Distribution

Figure 1a. Relative Intensity vs. Wavelength

Figure 1b. White Color Spectrum of Typical 5500K Part.

Red-

Orange

0

0.2

0.4

0.6

0.8

1

350 400 450 500 550 600 650 700 750 800 850

Wavelength(nm)

RelativeSpectral

Power

Distribution

Figure 1c. Warm White Color Spectrum of Typical 3300K

Part.

Amber


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Light Output Characteristics

10

50

60

70

80

90

100

110120

130

140

150

1 2 3 4 5 6 7 8

Junction Temperature ( )

RelativeLightOutp

ut(%)

.

Green Photometric

White Photometric

Blue Photometric

Figure 2a. Relative Light Output vs. Junction

Temperature

0

20

40

60

80

100

120140

160

180

200

1 2 3 4 5 6 7 8

Junction Temperature()

RelativeLightoutput(%

)

.

Red Photometric

Red-Orange Photometric

Figure 2b. Relative Light Output vs. Junction Temperature

-20 0 20 40 60 80 100 120

-20 0 20 40 60 80 100 120


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Forward Current Characterist ics, Tj=25

11

0

100

200

300

400500

600

700

800

0 0.5 1 1.5 2 2.5 3 3.5 4

VF-Forward Voltage(V)

IF-AverageForwardC

urrent(mA)

0

100

200

300

400500

600

700

800

0 0.5 1 1.5 2 2.5 3 3.5 4

VF-Forward Voltage(V)

IF-AverageForwardC

urrent(mA)

Fig 3a. Forward Current vs.

Forward Voltage for White, Warm

White, Blue and Green.

Fig 3b. Forward Current vs.

Forward Voltage for Amber, Red-

Orange and Red.

0

0.2

0.4

0.6

0.8

1

1.2

0 200 400 600 800

IF-Average Forward Current(mA)

Normalize

dRelativeLuminous

Flux

.

0

0.2

0.4

0.6

0.8

1

1.2

0 200 400 600 800

IF-Average Forward Current(mA)

NormalizedRelativeLuminous

Flux

.

Fig 4a. Relative Luminous Flux vs.

Forward Current for White, Warm

White, Blue and Green at Tj=25

maintained.

Fig 4b. Relative Luminous Flux

vs. Forward Current for Amber,

Red-Orange, Red at Tj=25

maintained.


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Current Derating Curves

12

0

100

200

300

400

500

600

700

800

0 25 50 75 100 125 150

Ta-Ambient Temperature ( )

IF-ForwardCurre

nt(mA)

0

100

200

300

400

500

600

700

800

0 25 50 75 100 125 150

Ta-Ambient Temperature ( )

IF-ForwardCu

rrent(mA)

Fig 5a. Maximum Forward Current vs.

Ambient Temperature. Derating based on

TjMAX=135 for White, Warm White, Blue

and Green.

RJ-A=20/W

RJ-A=20/W

RJ-A=15/W

RJ-A=10/W

RJ-A=10/W

RJ-A=15/W

Fig 5b. Maximum Forward Current vs. Ambient

Temperature. Derating based on TjMAX=120

forAmber, Red-Orange and Red.


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Typical Representative Spatial Radiation PatternLambertian Radiation Pattern

Recommended Soldering Pads

13

0

10

20

30

40

50

6070

80

90

100

-100 -80 -60 -40 -20 0 20 40 60 80 100

Angular Displacement(Degree)

RelativeIntensity(%)

Fig 6. Typical Representative Spatial Radiation Pattern for

White, Warm White, Blue, Green, Amber, Red-Orange andRed.

Fig 7. Recommended Solder pads dimension. Solder mask

is

also recommended to advoid short circuit while


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n

Recommend IR Reflow Condition

Reflow Soldering

Lead Solder Lead-free Solder

Pre-heat 120~150 180~200

Pre-heat time 120 sec. Max. 120 sec. Max.

Peak temperature 240 Max. 260 Max.Soldering time 10 sec. Max. 10 sec. Max.

Conditionrefer to temperature-

profile (A)

refer to temperature-

profile (B) (N2 reflow is

recommended.)

After reflow soldering rapid cooling should be avoided.

Temperature-prof ile ( Surface of MCPCB)

Occasionally there is a brightness decrease caused by the influence of heat or ambient

during air reflow. It is recommended that the User use the nitrogen reflow method.

Repairing should not be done after the LEDs have been soldered. When repairing is

double-head soldering iron should be used. It should be confirmed beforehand whether the

characteristics of the LEDs will or will not be damaged by repairing.

Reflow soldering should not be done more than two times.

When soldering, do not put stress on the LEDs during heating.

After soldering, do not warp the circuit board.

Manual Hand Soldering

For Prototype builds or small series production runs it possible to place and solder the emitters

It is recommended to hand solder the leads and slug with a solder tip temperature of 230'C for l

10 seconds. This profile maintains a junction temperature below the maximum of 120'C, avoidi

to the emitter or to the MCPCB dielectric layer. Damage to the epoxy layer can cause a short ci

the array.

14

2.5~5/sec.

2.5~5/sec.

Pre-heating

120~150

120sec.Max

60sec.Max.

Above 200

240Max.

10sec.Max.

60sec.Max.

Above 220

1~5/sec.

1~5/sec.

Pre-heating

180~200

120sec.Max.

260Max.

10sec.Max.

Figure 8a. Lead Solder Temperature Profile

Figure 8b. Lead-free Solder Temperature Profile


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Emitter Reel Packaging

15

Notes:

1. The emitters should be picked up by the body

(not the lens) during placement. The inner diameterof the pick-up collet should be greater than or

equal to 6.5 mm.

2. Drawing not to scale.

3. All dimensions are in millimeters.

4 .All dimendions without tolerances are for

reference only.

5W Emitter Led Datasheet

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