OVTL09LG3WD Optek, OVTL09LG3WD Datasheet - Page 13
OVTL09LG3WD
Manufacturer Part Number
OVTL09LG3WD
Description
LED High Power (> 0.5 Watts) Daylight White 5200K 275lm 1050mA
Manufacturer
Optek
Datasheet
1.OVTL09LG3WD.pdf
(14 pages)
Specifications of OVTL09LG3WD
Illumination Color
Daylight White
Wavelength/color Temperature
5800 K
Luminous Flux
522 lm
Viewing Angle
120 deg
Power Rating
10 W
Operating Voltage
10.2 V
Operating Current
1050 mA
Minimum Operating Temperature
- 50 C
Maximum Operating Temperature
+ 85 C
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Lednium Series Optimal X
OVTL09LG3x Series
200mw, the adjusted value of δT is 2.29K. The calculation now assumes that all of the dissipation, 800mw of heat,
is conducted along the thermal path, thereby ignoring any conduction and subsequent radiation that is not direction-
ally normal to the surfaces considered, ie: conduction through the encapsulant material vertically away from the
board, and conduction horizontally away from the heat source. The calculation also assumes that there is no contri-
bution to thermal resistance at the boundaries between material layers. In practice it is improbable that perfect
transfer will occur at these transition regions, even though the bonding between layers in this example are of high
quality. In general, the calculation indicates that the measurements below are of the order of magnitude that can be
expected.
self to a simple theoretical calculation similar to that shown above. There are multiple incident heat sources, parallel
heat conduction paths, and significantly larger surface area for stray radiation, eg. Cup above has a surface area
available for stray radiation of approximately, 25mm
mately 92.5mm
Measurements
perature (Tj). Since the die itself is, and must be, encapsulated during testing, and the junction is contained within
the structure of the die, direct measurement of the junction temperature by normal means is not possible.
Two methods of non-contact thermography are available, both of which rely on emitted infrared detection.
small value of δT is expected which makes accurate estimation of the actual temperature gradient difficult using col-
orimetry.
tainty in the calculation algorithm, which sometimes gives results considered unacceptably inaccurate. In this in-
stance absolute accuracy is of secondary importance because the value to be determined is a temperature differ-
ence (δT) which requires only relative values – any error in a first reading will also be present in subsequent read-
ings that are about the same value. The difference between readings is accurate.
which the measurement is made. This poses a difficulty for small assemblies like an LED cup, and in particular the
added complication that the calculated temperature is an average value for the area being interrogated further com-
plicates the issue. Another concern is sometimes raised about the ability of this type of instrument to detect a
heated surface beyond the closest transparent radiating surface. This is a significant issue for far field measure-
ments; however, it is simple to demonstrate that this does not hold true for the near field, and particularly when the
incident beam has a known focal length.
OPTEK Technology Inc. — 1645 Wallace Drive, Carrollton, Texas 75006
Phone: (972) 323-2200 or (800) 341-4747 FAX: (972) 323-2396 visibleLED@optekinc.com www.optekinc.com
Power input is 1 watt; however, some power is converted into light energy. Assuming this is of the order of
The alternate matrix product range is of a much more complicated thermal design, which does not lend it-
The key to an accurate measurement of thermal resistance is to obtain a reliable value for the junction tem-
Infrared imagery by calibrated radiograph is a possibility; however, in the instance of a cup product only a
The alternative measurement type is digital infrared thermography. This means there is an inherent uncer-
The other significant drawback to infrared thermometers is a limitation to minimizing the spot size over
OPTEK reserves the right to make changes at any time in order to improve design and to supply the best product possible.
2
of exposed surface per input watt.
2
per watt of input power. A 10-watt matrix product has approxi-
Issue B.2 07/08
Page 13 of 14
Related parts for OVTL09LG3WD
Image
Part Number
Description
Manufacturer
Datasheet
Request
R
Part Number:
Description:
OPB606REFLECTIVE OBJECT SENSORS
Manufacturer:
OPTEK OPTEK Technologies
Datasheet:
Part Number:
Description:
Infrared Emitters High Intensity 890nm
Manufacturer:
Optek
Datasheet:
Part Number:
Description:
Infrared Emitters Infrared 890nm
Manufacturer:
Optek
Datasheet:
Part Number:
Description:
Infrared Emitters VCSEL
Manufacturer:
Optek
Datasheet:
Part Number:
Description:
Infrared Emitters SMD Gull
Manufacturer:
Optek
Datasheet:
Part Number:
Description:
Infrared Emitters SMD Axial
Manufacturer:
Optek
Datasheet:
Part Number:
Description:
Infrared Emitters SMD Flat Lens
Manufacturer:
Optek
Datasheet:
Part Number:
Description:
Infrared Emitters IR EMITTING DIODE
Manufacturer:
Optek
Datasheet:
Part Number:
Description:
Photointerruptors .2in SLOT INFRARED
Manufacturer:
Optek
Datasheet:
Part Number:
Description:
Photointerruptors .16in SLOT INFRARED
Manufacturer:
Optek
Datasheet:
Part Number:
Description:
OPB606REFLECTIVE OBJECT SENSORS
Manufacturer:
OPTEK OPTEK Technologies
Datasheet:
Part Number:
Description:
TRANSISTOR PNP GP HERMETIC SMD
Manufacturer:
TT Electronics/Optek Technology
Datasheet:
Part Number:
Description:
TRANSISTOR PNP GP HERMETIC SMD
Manufacturer:
TT Electronics/Optek Technology
Datasheet:
Part Number:
Description:
TRANSISTOR NPN GP HERMETIC SMD
Manufacturer:
TT Electronics/Optek Technology
Datasheet:
Part Number:
Description:
LED IR 880NM FLAT LENS 0805 SMD
Manufacturer:
TT Electronics/Optek Technology
Datasheet: