Direct liquid cooling in low-power electrical machines: Proof-of-concept

Pia M. Lindh; Ilya Petrov; R. Scott Semken; Markku Niemelä; Juha J. Pyrhonen; Lassi Aarniovuori; Toomas Vaimann; Ants Kallaste

doi:10.1109/TEC.2016.2597059

Direct liquid cooling in low-power electrical machines: Proof-of-concept

Pia M. Lindh^*, Ilya Petrov, R. Scott Semken, Markku Niemelä, Juha J. Pyrhonen, Lassi Aarniovuori, Toomas Vaimann, Ants Kallaste

^*Corresponding author for this work

Department of Electrical Engineering and Automation

Research output: Contribution to journal › Article › Scientific › peer-review

64 Citations (Scopus)

Abstract

This paper evaluates the feasibility of a direct liquid cooling approach in the thermal management of an axial flux permanent-magnet machine. To demonstrate the cooling method, a test motor was fitted with helical tooth coil windings formed from a hybrid conductor comprising a stainless steel coolant conduit tightly wrapped with a stranded Litz wire. The motor is a 100-kW permanent-magnet, axial-flux, double-stator, single-rotor machine. The proof of concept integrated the motor with a closed liquid coolant loop, appropriate instrumentation, and a data acquisition system. The general performance of the motor was examined at various power levels using polyalphaolefin oil as the cooling fluid. The results show the proposed cooling method to be feasible, and furthermore, to provide significant improvements to the machine thermal management.

Original language	English
Article number	7527616
Pages (from-to)	1257-1266
Number of pages	10
Journal	IEEE Transactions on Energy Conversion
Volume	31
Issue number	4
DOIs	https://doi.org/10.1109/TEC.2016.2597059
Publication status	Published - 1 Dec 2016
MoE publication type	A1 Journal article-refereed

Keywords

Electric machines
liquid cooling
permanent-magnet motors
rotating machines
temperature dependence

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10.1109/TEC.2016.2597059

Cite this

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title = "Direct liquid cooling in low-power electrical machines: Proof-of-concept",

abstract = "This paper evaluates the feasibility of a direct liquid cooling approach in the thermal management of an axial flux permanent-magnet machine. To demonstrate the cooling method, a test motor was fitted with helical tooth coil windings formed from a hybrid conductor comprising a stainless steel coolant conduit tightly wrapped with a stranded Litz wire. The motor is a 100-kW permanent-magnet, axial-flux, double-stator, single-rotor machine. The proof of concept integrated the motor with a closed liquid coolant loop, appropriate instrumentation, and a data acquisition system. The general performance of the motor was examined at various power levels using polyalphaolefin oil as the cooling fluid. The results show the proposed cooling method to be feasible, and furthermore, to provide significant improvements to the machine thermal management.",

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AU - Pyrhonen, Juha J.

AU - Aarniovuori, Lassi

AU - Vaimann, Toomas

AU - Kallaste, Ants

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AB - This paper evaluates the feasibility of a direct liquid cooling approach in the thermal management of an axial flux permanent-magnet machine. To demonstrate the cooling method, a test motor was fitted with helical tooth coil windings formed from a hybrid conductor comprising a stainless steel coolant conduit tightly wrapped with a stranded Litz wire. The motor is a 100-kW permanent-magnet, axial-flux, double-stator, single-rotor machine. The proof of concept integrated the motor with a closed liquid coolant loop, appropriate instrumentation, and a data acquisition system. The general performance of the motor was examined at various power levels using polyalphaolefin oil as the cooling fluid. The results show the proposed cooling method to be feasible, and furthermore, to provide significant improvements to the machine thermal management.

KW - Electric machines

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KW - temperature dependence

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Direct liquid cooling in low-power electrical machines: Proof-of-concept

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Keywords

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