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Issue B.2 07/08 �
� Page 13 of 14 �
� OPTEK reserves the right to make changes at any time in order to improve design and to supply the best product possible. �
� 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 �
� 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. �
� The alternate matrix product range is of a much mo�
� re complicated thermal design, which does not lend it-�
� 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, 25mm2�
� per watt of input power. A 10-watt matrix product has approxi-�
� mately 92.5mm2�
� of exposed surface per input watt. �
� Measurements �
� The key to an accurate measurement of thermal resist�
� ance is to obtain a reliable value for the junction tem-�
� 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. �
� Infrared imagery by calibrated radiograph is a possibi�
� lity; however, in the instance of a cup product only a �
� small value of δT is expected which makes accurate estimation of the actual temperature gradient difficult using col-�
� orimetry. �
� The alternative measurement type is digital infrared th�
� ermography. This means there is an inherent uncer-�
� 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. �
� The other significant drawback to infrared thermometers is a limitation to minimizing the spot size over �
� 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. �
� Lednium Series Optimal X �
� OVTL09LG3x Series �
� 
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相关代理商/技术参数
OVTL09LG3WW
功能描述:大功率LED - 白色 Warm White 3200K 230lm 1050mA RoHS:否 制造商:Cree, Inc. 照明颜色:Cool White 颜色温度:5000 K 光通量:280 lm 显示角:125 deg 正向电流:700 mA 正向电压:2.9 V 安装风格:SMD/SMT 系列:XMLBWW 封装:Reel
OVTL09LGAA
功能描述:大功率LED - 单色 Power Array Amber 595nm
RoHS:否 制造商:Cree, Inc. 照明颜色:Blue 波长:465 nm 光强度: 光通量/辐射通量:500 mW 正向电流:350 mA 正向电压:3.1 V 安装风格:SMD/SMT 功率额定值: 系列:XB-D 封装:Reel
OVTL09LGAA
制造商:TT Electronics / OPTEK Technology 功能描述:LED LAMP COLOR:AMBER
OVTL09LGAB
功能描述:大功率LED - 单色 Power Array Blue 467nm
RoHS:否 制造商:Cree, Inc. 照明颜色:Blue 波长:465 nm 光强度: 光通量/辐射通量:500 mW 正向电流:350 mA 正向电压:3.1 V 安装风格:SMD/SMT 功率额定值: 系列:XB-D 封装:Reel
OVTL09LGAB
制造商:TT Electronics / OPTEK Technology 功能描述:LED LAMP COLOR:BLuE
OVTL09LGAG
功能描述:大功率LED - 单色 Power Array Green 524nm
RoHS:否 制造商:Cree, Inc. 照明颜色:Blue 波长:465 nm 光强度: 光通量/辐射通量:500 mW 正向电流:350 mA 正向电压:3.1 V 安装风格:SMD/SMT 功率额定值: 系列:XB-D 封装:Reel
OVTL09LGAG
制造商:TT Electronics / OPTEK Technology 功能描述:LED LAMP COLOR:GREEN
OVTL09LGAM
功能描述:大功率LED - 多色 Power Array RGB Full Color
RoHS:否 制造商:Cree, Inc. 照明颜色:RGB, Cool White 波长/色温: 光强度: 系列: 封装:Reel