Harnessing waves with folds: a flexible origami-inspired wave energy converter
Harnessing waves with folds: a flexible origami-inspired wave energy converter
Ocean waves offer sustainable power yet the design of efficient and durable wave energy converters (WECs) remains challenging. We focus on a WEC that harvests energy from chamber volume change as two bottom- hinged plates open and close with passing wave troughs and crests, driving a turbine generator. For the first time, we present an origami-inspired enclosed WEC whose plates are linked by rigid pleats and confined membrane regions. Unlike traditional flexible WECs that connect the flaps with elastic membranes that stretch, our design achieves predictable cyclic motion through origami folding mechanisms. Using an analytical design method, we optimize dimensions of the pleats and membranes that keep membrane strain minimal during operation. The analytical design is confirmed by finite element analyses, which indicates negligible membrane strain under normal operation, therefore long fatigue life. Tests on a 1:160 scale prototype achieve a capture width ratio of 0.35 and demonstrate robustness under irregular waves and deliberate misalignment. Our WEC design allows the power take-off (PTO) system to be positioned above sea level, ensuring the PTO system operates in air and remains unaffected even if sealing fails. These results demonstrate the potential of origami- inspired WECs as viable and scalable approaches to wave energy harvesting.
Origami-inspired Design, Folding-dominate volume change, Wave energy converter, Small strain
Yang, Jingyi
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You, Zhong
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Meng, Maozhou
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Tosdevin, Tom
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Borthwick, Alistair G.L.
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Chaplin, John R.
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Chen, Bohan
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Zheng, Siming
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Hann, Martyn
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Cheng, Shanshan
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Wang, Xinya
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Puzhukkil, Krishnendu
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Cox, Malcolm
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Monk, Kieran
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Greaves, Deborah M.
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6 January 2026
Yang, Jingyi
c26908c2-f98e-4dab-91bd-e925ddf74482
You, Zhong
251153f9-b681-4bd3-af60-5a42ac972e1f
Meng, Maozhou
f47d85e2-42e0-40ea-989a-6e6dd06f97b4
Tosdevin, Tom
89dd4167-7c3b-4b26-a8a8-9c94d0d45d53
Borthwick, Alistair G.L.
e49dc647-c505-4684-becc-95e8f75931ba
Chaplin, John R.
d5ed2ba9-df16-4a19-ab9d-32da7883309f
Chen, Bohan
13d80924-ba46-422e-ada1-437f9985e9a9
Zheng, Siming
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Hann, Martyn
422ff09d-2770-403b-842e-77f9985f9d64
Cheng, Shanshan
bb4e7282-35ad-436b-b368-35190520a249
Wang, Xinya
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Puzhukkil, Krishnendu
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Cox, Malcolm
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Monk, Kieran
dacd4900-8b85-4514-a356-a96b9a5f6574
Greaves, Deborah M.
63eca51e-b38f-4f7e-95a2-c7d88a7382db
Yang, Jingyi, You, Zhong, Meng, Maozhou, Tosdevin, Tom, Borthwick, Alistair G.L., Chaplin, John R., Chen, Bohan, Zheng, Siming, Hann, Martyn, Cheng, Shanshan, Wang, Xinya, Puzhukkil, Krishnendu, Cox, Malcolm, Monk, Kieran and Greaves, Deborah M.
(2026)
Harnessing waves with folds: a flexible origami-inspired wave energy converter.
Materials & Design, 262, [115411].
(doi:10.1016/j.matdes.2025.115411).
Abstract
Ocean waves offer sustainable power yet the design of efficient and durable wave energy converters (WECs) remains challenging. We focus on a WEC that harvests energy from chamber volume change as two bottom- hinged plates open and close with passing wave troughs and crests, driving a turbine generator. For the first time, we present an origami-inspired enclosed WEC whose plates are linked by rigid pleats and confined membrane regions. Unlike traditional flexible WECs that connect the flaps with elastic membranes that stretch, our design achieves predictable cyclic motion through origami folding mechanisms. Using an analytical design method, we optimize dimensions of the pleats and membranes that keep membrane strain minimal during operation. The analytical design is confirmed by finite element analyses, which indicates negligible membrane strain under normal operation, therefore long fatigue life. Tests on a 1:160 scale prototype achieve a capture width ratio of 0.35 and demonstrate robustness under irregular waves and deliberate misalignment. Our WEC design allows the power take-off (PTO) system to be positioned above sea level, ensuring the PTO system operates in air and remains unaffected even if sealing fails. These results demonstrate the potential of origami- inspired WECs as viable and scalable approaches to wave energy harvesting.
Text
Manuscript_origami WEC_revised and clean
- Accepted Manuscript
Text
1-s2.0-S0264127525018325-main
- Version of Record
More information
Accepted/In Press date: 29 December 2025
e-pub ahead of print date: 29 December 2025
Published date: 6 January 2026
Keywords:
Origami-inspired Design, Folding-dominate volume change, Wave energy converter, Small strain
Identifiers
Local EPrints ID: 510303
URI: http://eprints.soton.ac.uk/id/eprint/510303
ISSN: 0264-1275
PURE UUID: 2ab1d3fa-ddcd-455b-b9f1-28250c79c189
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Date deposited: 25 Mar 2026 17:32
Last modified: 26 Mar 2026 02:37
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Contributors
Author:
Jingyi Yang
Author:
Zhong You
Author:
Maozhou Meng
Author:
Tom Tosdevin
Author:
Alistair G.L. Borthwick
Author:
Bohan Chen
Author:
Siming Zheng
Author:
Martyn Hann
Author:
Shanshan Cheng
Author:
Xinya Wang
Author:
Krishnendu Puzhukkil
Author:
Malcolm Cox
Author:
Kieran Monk
Author:
Deborah M. Greaves
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