TY - JOUR
T1 - Low-cost cascade thermoacoustic electric generator for energy harvesting
AU - Dhuchakallaya, Isares
AU - Saechan, Patcharin
AU - Hamood, Ahmed
AU - Jaworski, Artur J.
N1 - Funding Information:
The authors gratefully acknowledge the following sponsors and funding sources: Isares Dhuchakallaya acknowledges support from the Thailand Science Research and Innovation (TSRI) Fundamental Fund, fiscal year 2024, Thammasat University (grant TUFF 35/2567). Patcharin Saechan acknowledges support from the National Science, Research and Innovation Fund (NSRF) and King Mongkut's University of Technology North Bangkok (Contract no. KMUTNB-FF-66-23). Artur J. Jaworski acknowledges the Royal Society Industry Fellowship (grant IF110094). Both Artur J. Jaworski and Ahmed Hamood would like to acknowledge EPSRC funding under grant EP/R023328, and the financial support from Huawei Technologies Sweden AB under agreement number YBN2019095134.
Publisher Copyright:
© 2024 The Authors
PY - 2024/11/1
Y1 - 2024/11/1
N2 - The cascade thermoacoustic heat engine has garnered significant attention for its ability to convert various heat sources into acoustic power without the challenges of acoustic streaming. By integrating it with a commercial loudspeaker, it can be further developed into a novel, low-cost thermoacoustic electric generator. This study aims to design and evaluate a thermoacoustic electric generator capable of producing several watts of electricity. The system consists of a cascade thermoacoustic engine, comprising a standing-wave and a traveling-wave unit, coupled with a B&C 6PS38 loudspeaker in a linear configuration. Atmospheric air is used as the working fluid, and standard market components, such as PVC and steel pipes, are proposed to minimize costs. Unlike traditional thermoacoustic generators, this system uses commercially available loudspeakers and a linear configuration, offering a cost-effective solution for low-wattage power generation, free from the issue of acoustic streaming. This makes it suitable for small-scale, distributed energy systems. The numerical simulation tool DeltaEC is employed to design and assess the system's performance. The optimal configuration is 4 m long, with the standing-wave and traveling-wave units centrally positioned. Operating at a frequency of 74.56 Hz, the system generates 90.18 W of electrical power with a total heat input of 1046.74 W and an external load resistance of 19.77 ohms. This corresponds to a heat-to-acoustic efficiency of 18.41 %, an acoustic-to-electric efficiency of 68.98 %, and an overall heat-to-electric efficiency of 8.62 %. The study also emphasizes the importance of operating conditions and impedance matching between the cascade engine and the loudspeaker. These findings represent progress toward developing an affordable thermoacoustic generator for energy recovery and other applications.
AB - The cascade thermoacoustic heat engine has garnered significant attention for its ability to convert various heat sources into acoustic power without the challenges of acoustic streaming. By integrating it with a commercial loudspeaker, it can be further developed into a novel, low-cost thermoacoustic electric generator. This study aims to design and evaluate a thermoacoustic electric generator capable of producing several watts of electricity. The system consists of a cascade thermoacoustic engine, comprising a standing-wave and a traveling-wave unit, coupled with a B&C 6PS38 loudspeaker in a linear configuration. Atmospheric air is used as the working fluid, and standard market components, such as PVC and steel pipes, are proposed to minimize costs. Unlike traditional thermoacoustic generators, this system uses commercially available loudspeakers and a linear configuration, offering a cost-effective solution for low-wattage power generation, free from the issue of acoustic streaming. This makes it suitable for small-scale, distributed energy systems. The numerical simulation tool DeltaEC is employed to design and assess the system's performance. The optimal configuration is 4 m long, with the standing-wave and traveling-wave units centrally positioned. Operating at a frequency of 74.56 Hz, the system generates 90.18 W of electrical power with a total heat input of 1046.74 W and an external load resistance of 19.77 ohms. This corresponds to a heat-to-acoustic efficiency of 18.41 %, an acoustic-to-electric efficiency of 68.98 %, and an overall heat-to-electric efficiency of 8.62 %. The study also emphasizes the importance of operating conditions and impedance matching between the cascade engine and the loudspeaker. These findings represent progress toward developing an affordable thermoacoustic generator for energy recovery and other applications.
KW - Cascade
KW - Electricity generator
KW - Loudspeaker
KW - Low cost
KW - hermoacoustic engine
UR - http://www.scopus.com/inward/record.url?scp=85208486864&partnerID=8YFLogxK
U2 - 10.1016/j.ijft.2024.100954
DO - 10.1016/j.ijft.2024.100954
M3 - Article
VL - 24
JO - International Journal of Thermofluids
JF - International Journal of Thermofluids
SN - 2666-2027
M1 - 100954
ER -