Optimal performance identification of a combined free piston Stirling engine with a permanent magnet linear synchronous machine using dedicated controls

•A Linear Synchronous Machine combined with a Free Piston Stirling Engine.•For the combined system, two different control methods were developed.•Based on the control methods, the performance of the combined system was optimized.•The performance and application of the two control methods were compar...

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Bibliographic Details
Published in:Applied thermal engineering 2023-01, Vol.219, p.119306, Article 119306
Main Authors: Majidniya, Mahdi, Boileau, Thierry, Remy, Benjamin, Pierfederici, Serge, Zandi, Majid
Format: Article
Language:English
Subjects:
Artificial damper
Control
Engineering Sciences
Free Piston Stirling Engine
Optimization
Permanent Magnet Linear Synchronous Machine
Proportional Resonant (PR) controller
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Summary:•A Linear Synchronous Machine combined with a Free Piston Stirling Engine.•For the combined system, two different control methods were developed.•Based on the control methods, the performance of the combined system was optimized.•The performance and application of the two control methods were compared. In the present study, to find the optimal performance of a combined RE-1000 Free Piston Stirling Engine (FPSE) with a three-phase Permanent Magnet Linear Synchronous Machine (PMLSM), two different control methods were developed. To convert the produced mechanical power of the FPSE to the electrical one, generally, it should be coupled with a linear generator. Here, a three-phase PMLSM was chosen to convert the linear movement of the FPSE to electricity. The control of the FPSE system was also done through this generator using velocity control. It is possible to obtain the optimal system behavior based on the identification of the adapted velocity reference value. Based on two different methods, the FPSE-PMLSM optimum working point was determined. In the first method, an open-loop sinusoidal wave was assumed as the reference velocity, and its amplitude and frequency were optimized. In the second method, the reference velocity was identified using closed-loop feedback of the electromagnetic force, and the optimal feedback coefficient was found. The results show that apart from the advantages and disadvantages related to each method, the optimized point was almost identical.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2022.119306