Conjugate heat transfer analysis of an energy conversion device with an updated numerical model obtained through inverse identification

•Conjugate heat transfer analysis of an electric machine.•Inverse identification method for estimating the model parameters.•Experimentally determined thermal properties and electromagnetic losses.•Coupling of inverse identification method with a numerical model.•Improved modeling accuracy through i...

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Bibliographic Details
Published in:Energy conversion and management 2015-04, Vol.94, p.198-209
Main Authors: Hey, Jonathan, Malloy, Adam C., Martinez-Botas, Ricardo, Lamperth, Michael
Format: Article
Language:English
Subjects:
Conjugate heat transfer
Devices
Direct power generation
Electric machine
Energy conversion
Estimates
Heat transfer
Inverse
Inverse identification
Mathematical models
Permanent magnets
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Summary:•Conjugate heat transfer analysis of an electric machine.•Inverse identification method for estimating the model parameters.•Experimentally determined thermal properties and electromagnetic losses.•Coupling of inverse identification method with a numerical model.•Improved modeling accuracy through introduction of interface material. Energy conversion devices undergo thermal loading during their operation as a result of inefficiencies in the energy conversion process. This will eventually lead to degradation and possible failure of the device if the heat generated is not properly managed. The ability to accurately predict the thermal behavior of such a device during the initial developmental stage is an important requirement. However, accurate predictions of critical temperature is challenging due to the variation of heat transfer parameters from one device to another. The ability to determine the model parameters is key to accurately representing the heat transfer in such a device. This paper presents the use of an inverse identification technique to estimate the model parameters of an energy conversion device designed for vehicular applications. To simulate the imperfect contact and the presence of insulating materials in the permanent magnet electric machine, thin material are introduced at the component interface of the numerical model. The proposed inverse identification method is used to estimate the equivalent thermal conductance of the thin material. In addition, the electromagnetic losses generated in the permanent magnet is also derived indirectly from the temperature measurement using the same method. With the thermal properties and input parameters of the numerical model obtained from the inverse identification method, the critical temperature of the device can be predicted more accurately. The deviation between the maximum measured and predicted winding temperature is less than 2.4%.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2015.01.065