Design, simulation and experimental validation of a Tesla turbine based rotational electromagnetic energy harvester for pipelines
Design, simulation and experimental validation of a Tesla turbine based rotational electromagnetic energy harvester for pipelines
In this paper, a bladeless electromagnetic energy harvester based on Tesla turbine is proposed to harvest fluid’s kinetic energy and monitor the stability of flow inside the pipeline. To figure out the principle of the friction-type turbine, the dynamics and electromagnetism are analyzed theoretically. Meanwhile, two structures of the container, named Structure 1 and Structure 2, are designed and distinguished by their different outlets. Structure 1 has both its inlet and outlet on the same side, while Structure 2 has its inlet and outlet on opposite sides. Simulations based on fluid dynamics (CFD) and electromagnetic induction are carried to analyze the working performance and check with the experimental results. Two main rotors which are 5 and 6 disks have been analyzed via simulations and experiments. Optimizations for the rotor are conducted through changing the magnet array. In summary, the results indicate that although increasing the number of rotors to six can enhance the output torque, it is still insufficient to offset the friction caused by the increased weight and manufacturing issues. However, with 5 disks rotors, significantly improving the performance can be realized by enlarging the size of the magnets and coils. The maximum power can reach 3.11 mW, representing a 438% improvement compared to the 6 disks setup without magnet and coil optimization.
Tesla turbine, energy harvesting, fluid dynamics simulation, electromagnetic simulation, rotor optimization
Lyu, Wenbo
79554032-f797-46aa-bee8-e8d52f598256
Ma, He
a33edb62-fffc-4001-b321-717a324d6d73
Zhou, Hongbin
8d4ed262-322f-4903-b97f-b0f66b06fe37
Zhang, Jiaqin
6fd25eba-7ad3-44bd-9b2d-bdac4a86eafa
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Zhou, Shengxi
1785789b-b88c-43b0-aec6-8bb36af0d684
16 October 2024
Lyu, Wenbo
79554032-f797-46aa-bee8-e8d52f598256
Ma, He
a33edb62-fffc-4001-b321-717a324d6d73
Zhou, Hongbin
8d4ed262-322f-4903-b97f-b0f66b06fe37
Zhang, Jiaqin
6fd25eba-7ad3-44bd-9b2d-bdac4a86eafa
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Zhou, Shengxi
1785789b-b88c-43b0-aec6-8bb36af0d684
Lyu, Wenbo, Ma, He, Zhou, Hongbin, Zhang, Jiaqin, Yurchenko, Daniil and Zhou, Shengxi
(2024)
Design, simulation and experimental validation of a Tesla turbine based rotational electromagnetic energy harvester for pipelines.
Mechanical Systems and Signal Processing, 224, [112034].
(doi:10.1016/j.ymssp.2024.112034).
Abstract
In this paper, a bladeless electromagnetic energy harvester based on Tesla turbine is proposed to harvest fluid’s kinetic energy and monitor the stability of flow inside the pipeline. To figure out the principle of the friction-type turbine, the dynamics and electromagnetism are analyzed theoretically. Meanwhile, two structures of the container, named Structure 1 and Structure 2, are designed and distinguished by their different outlets. Structure 1 has both its inlet and outlet on the same side, while Structure 2 has its inlet and outlet on opposite sides. Simulations based on fluid dynamics (CFD) and electromagnetic induction are carried to analyze the working performance and check with the experimental results. Two main rotors which are 5 and 6 disks have been analyzed via simulations and experiments. Optimizations for the rotor are conducted through changing the magnet array. In summary, the results indicate that although increasing the number of rotors to six can enhance the output torque, it is still insufficient to offset the friction caused by the increased weight and manufacturing issues. However, with 5 disks rotors, significantly improving the performance can be realized by enlarging the size of the magnets and coils. The maximum power can reach 3.11 mW, representing a 438% improvement compared to the 6 disks setup without magnet and coil optimization.
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Accepted/In Press date: 7 October 2024
e-pub ahead of print date: 16 October 2024
Published date: 16 October 2024
Keywords:
Tesla turbine, energy harvesting, fluid dynamics simulation, electromagnetic simulation, rotor optimization
Identifiers
Local EPrints ID: 498200
URI: http://eprints.soton.ac.uk/id/eprint/498200
ISSN: 1096-1216
PURE UUID: 7eb75526-d0e2-4a26-a12d-6688b8318c49
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Date deposited: 12 Feb 2025 17:43
Last modified: 13 Feb 2025 03:06
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Contributors
Author:
Wenbo Lyu
Author:
He Ma
Author:
Hongbin Zhou
Author:
Jiaqin Zhang
Author:
Daniil Yurchenko
Author:
Shengxi Zhou
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