Passive pre-tensioning of buoyancy engines for fail-safe and energy efficient depth control
Passive pre-tensioning of buoyancy engines for fail-safe and energy efficient depth control
This paper describes the development and testing of a novel pre-tensioned variable buoyancy engine (VBE) that has two major advantages over traditional VBEs, i) fail safe behaviour, where the device expands to achieve maximum buoyancy in the event of power loss, and ii) reduced energy consumption when varying buoyancy at high hydrostatic pressure. The system achieves these properties by using a set of springs to push out a piston that varies the device's displacement. This paper develops the theory to size these springs for fail-safe and energy efficient operation at different depths. Practical experiments are carried out under simulated hydrostatic pressures using a prototype pre-tensioned VBE designed according to the developed theory. We compare two methods of sealing the piston. Both methods demonstrated fail-safe response when power is lost, and achieved a maximum energy reduction of 25% compared to VBEs with no pre-tension under our experimental conditions. We discuss the implications of our results for different types of autonomous submersible mission profiles and make suggestions for future work.
Redfern, Harry
a09822ef-9756-4348-b6f6-9ccc4855ec5f
Denton, Guy
0056bde3-4a66-45b0-8611-037b92c16d8d
Massot-Campos, Miquel
a55d7b32-c097-4adf-9483-16bbf07f9120
Thornton, Blair
8293beb5-c083-47e3-b5f0-d9c3cee14be9
19 December 2022
Redfern, Harry
a09822ef-9756-4348-b6f6-9ccc4855ec5f
Denton, Guy
0056bde3-4a66-45b0-8611-037b92c16d8d
Massot-Campos, Miquel
a55d7b32-c097-4adf-9483-16bbf07f9120
Thornton, Blair
8293beb5-c083-47e3-b5f0-d9c3cee14be9
Redfern, Harry, Denton, Guy, Massot-Campos, Miquel and Thornton, Blair
(2022)
Passive pre-tensioning of buoyancy engines for fail-safe and energy efficient depth control.
In OCEANS 2022 Hampton Roads.
vol. 2022-October,
IEEE.
7 pp
.
(doi:10.1109/OCEANS47191.2022.9977114).
Record type:
Conference or Workshop Item
(Paper)
Abstract
This paper describes the development and testing of a novel pre-tensioned variable buoyancy engine (VBE) that has two major advantages over traditional VBEs, i) fail safe behaviour, where the device expands to achieve maximum buoyancy in the event of power loss, and ii) reduced energy consumption when varying buoyancy at high hydrostatic pressure. The system achieves these properties by using a set of springs to push out a piston that varies the device's displacement. This paper develops the theory to size these springs for fail-safe and energy efficient operation at different depths. Practical experiments are carried out under simulated hydrostatic pressures using a prototype pre-tensioned VBE designed according to the developed theory. We compare two methods of sealing the piston. Both methods demonstrated fail-safe response when power is lost, and achieved a maximum energy reduction of 25% compared to VBEs with no pre-tension under our experimental conditions. We discuss the implications of our results for different types of autonomous submersible mission profiles and make suggestions for future work.
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Published date: 19 December 2022
Venue - Dates:
2022 OCEANS Hampton Roads, OCEANS 2022, , Hampton Roads, United States, 2022-10-17 - 2022-10-20
Identifiers
Local EPrints ID: 470375
URI: http://eprints.soton.ac.uk/id/eprint/470375
ISSN: 0197-7385
PURE UUID: 780ef910-fcad-4e68-84bf-33dec157cd06
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Date deposited: 07 Oct 2022 16:34
Last modified: 08 Jun 2024 01:58
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Author:
Harry Redfern
Author:
Guy Denton
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