Assessing the Performance of Design Variations of a Thermoacoustic Stirling Engine Combining Laboratory Tests and Model Results

The equations governing energy conversion in traveling wave thermoacoustic machines are affected by their multiphysics nature. Their theoretical study is complicated and, in order to obtain real results, it is necessary to resort to prototypes and experimental tests. This work presents the theoretic...

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Bibliographic Details
Published inMachines (Basel) Vol. 10; no. 10; p. 958
Main Authors Iniesta, Carmen, Olazagoitia, José Luis, Vinolas, Jordi, Gros, Jaime
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.10.2022
Subjects
acoustic network improvement
Acoustics
Analysis
Compliance
early-stage design
Energy
Energy conversion
Engines
Gases
Generators
Heat exchangers
Laboratories
Laboratory tests
Model testing
Power flow
reactive acoustic power
Stirling engines
thermoacoustic Stirling engine
Thermoacoustics
Thermodynamics
Traveling waves
Vehicles
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Summary:The equations governing energy conversion in traveling wave thermoacoustic machines are affected by their multiphysics nature. Their theoretical study is complicated and, in order to obtain real results, it is necessary to resort to prototypes and experimental tests. This work presents the theoretical–experimental study of a thermoacoustic Stirling engine in which, by altering some of its critical parts and analysing the experimental result, it is possible to improve its performance. The methodology used is based on the study and modelling of the active and reactive acoustic power flow for the improvement of the output power of the thermoacoustic engine. The work and analysis are illustrated through the instrumentation of a thermoacoustic Stirling engine with three different feedbacks. The present work presents the experimental results obtained in all cases, including their parameters, experimental data and analysis. The results are compared with the virtual computational models, allowing us to quantify the theoretical/experimental correlation and the performance improvement obtained that allows us to significantly increase the energy provided by the thermoacoustic machine. In conclusion, it is shown that the proposed methodology is a useful design tool that allows using a simplified and practical approach in the study of the power flow of thermoacoustic machines.
ISSN:2075-1702
2075-1702
DOI:10.3390/machines10100958