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实验测试 Flotherm对热电偶测量的分析

Modeling Thermocouples with FLOTHERM


Figure 1 -FLOTHERM Model: Front View


Did you ever wonder what effect a thermocouple has on your experimental data? Can you trust the measured temperature or is there a hidden source of error you have not considered? Dr. Cathy Biber, Senior Thermal Engineer with Wakefield Engineering and FLOTHERM user, recently addressed this topic. She began by building a model of a Wakefield series 275 heat sink attached to a TO-220 power semiconductor dissipating 3 watts in a natural convection environment. Two thermocouples were added to the model, one on the heat sink and one on the device tab as shown below.
Dr. Biber's method for modeling a thermocouple (TC) consists of three parts: the bead, the wire and the contact resistance between the bead and the surface whose temperature is being measured. The bead and wire should be modeled as solve-in-solid cuboid blocks, with appropriate thermal conductivity to account for the type of TC being used in the experiment. Remember to calculate an equivalent thermal conductivity for the bimetallic wire. As an example, Dr. Biber used a T type (copper-constantan) thermocouple which worked out to have an equivalent thermal conductivity of 100 W/mK.


Figure 2 - FLOTHERM Model: Rear View


Finally, an internal plate is used to model the contact resistance between the bead and the surface. The thickness and thermal conductivity of the plate are critical in obtaining agreement with test results. Cathy Biber used the conductivity of air (0.026 W/mK) and a thickness of 1.5 microns to represent the contact resistance in her model. However, it is important to model the effects of thermal grease or adhesives if used. The routing of the TC wire in your model should match that of the experimental set-up.


Results Experimental results were compared to FLOTHERM model predictions with and without the presence of thermocouples. In the model without thermocouples, the temperature was taken from a cell within the device tab and within the heat sink. In the model with thermocouples, the temperature was taken from the cells representing the TC beads. The following table presents the results.


Measured
FLOTHERM Model (C)

(C)
No TC's
With TC's

TO-220
Device Tab108.1 114.0108.4
Heat Sink89.8103.0 90.6
Max. Temp in Modeln/a119.3 118.5
Table 1 - Results
As you can see, the model containing thermocouples has excellent agreement with the experimental data. This model was correlated to one set of experimental results and then tested against several other sets of data, all with similar agreement. However, in the model without TC's, the results showed temperature differences of 6C on the device and 13C on the heat sink!

Figure 3 - Results on the Centerline Plane
ConclusionsTwo points are clear as a result of this exercise:

Author: Dr. Catharina Biber, Wakefield Engineering







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大神点评5

我不会 2011-5-1 09:32:06 显示全部楼层

贴在这比较合适。

delta 2011-5-1 09:32:06 显示全部楼层

不知道有谁试过这个方法没有!!


散热小菜 2011-5-1 09:32:06 显示全部楼层

感觉热电偶也起了散热作用!!

Blossom 2011-5-1 09:32:06 显示全部楼层

是的,所以热电偶的选择、粘帖还是挺有讲究的。

xlt 2011-5-1 09:32:06 显示全部楼层



超版能否给大家介绍下热电偶的选择、粘贴都应该注意那些问题。如何避免这些问题。
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