A novel pyroelectric generator utilising naturally driven temperature fluctuations from oscillating heat pipes for waste heat recovery and thermal energy harvesting
A novel pyroelectric generator utilising naturally driven temperature fluctuations from oscillating heat pipes for waste heat recovery and thermal energy harvesting
Low temperature thermal to electrical energy converters have the potential to provide a route for recovering waste energy. In this paper, we propose a new configuration of a thermal harvester that uses a naturally driven thermal oscillator free of mechanical motion and operates between a hot heat source and a cold heat sink. The system exploits a heat induced liquid-vapour transition of a working fluid as a primary driver for a pyroelectric generator. The two-phase instability of a fluid in a closed looped capillary channel of an oscillating heat pipe (OHP) creates pressure differences which lead to local high frequency temperature oscillations in the range of 0.1–5 K. Such temperature changes are suitable for pyroelectric thermal to electrical energy conversion, where the pyroelectric generator is attached to the adiabatic wall of the OHP, thereby absorbing thermal energy from the passing fluid. This new pyroelectric-oscillating heat pipe (POHP) assembly of a low temperature generator continuously operates across a spatial heat source temperature of 55 °C and a heat sink temperature of 25 °C, and enables waste heat recovery and thermal energy harvesting from small temperature gradients at low temperatures. Our electrical measurements with lead zirconate titanate (PZT) show an open circuit voltage of 0.4 V (AC) and with lead magnesium niobate–lead titanate (PMN-PT) an open circuit voltage of 0.8 V (AC) at a frequency of 0.45 Hz, with an energy density of 95 pJ cm−3 for PMN-PT. Our novel POHP device therefore has the capability to convert small quantities of thermal energy into more desirable electricity in the nW to mW range and provides an alternative to currently used batteries or centralised energy generation.
Zabek, D.
7281d29f-829d-4f54-89a2-ee4f48a357af
Taylor, J.
f3a9f1ba-4735-4aa4-9767-20c0ce90f9ca
Ayel, V.
a0b72d59-a388-41fb-bcf3-a43ba5e98b47
Bertin, Y.
22ad991f-f79e-4ae3-9d7d-59843011da68
Romestant, C.
6c06606c-3b06-4395-8d7b-cd757ff4ada6
Bowen, C.R.
35919b53-5085-4cea-a4d1-13858b2c55a0
14 July 2016
Zabek, D.
7281d29f-829d-4f54-89a2-ee4f48a357af
Taylor, J.
f3a9f1ba-4735-4aa4-9767-20c0ce90f9ca
Ayel, V.
a0b72d59-a388-41fb-bcf3-a43ba5e98b47
Bertin, Y.
22ad991f-f79e-4ae3-9d7d-59843011da68
Romestant, C.
6c06606c-3b06-4395-8d7b-cd757ff4ada6
Bowen, C.R.
35919b53-5085-4cea-a4d1-13858b2c55a0
Zabek, D., Taylor, J., Ayel, V., Bertin, Y., Romestant, C. and Bowen, C.R.
(2016)
A novel pyroelectric generator utilising naturally driven temperature fluctuations from oscillating heat pipes for waste heat recovery and thermal energy harvesting.
Journal of Applied Physics, 120, [024505].
(doi:10.1063/1.4958338).
Abstract
Low temperature thermal to electrical energy converters have the potential to provide a route for recovering waste energy. In this paper, we propose a new configuration of a thermal harvester that uses a naturally driven thermal oscillator free of mechanical motion and operates between a hot heat source and a cold heat sink. The system exploits a heat induced liquid-vapour transition of a working fluid as a primary driver for a pyroelectric generator. The two-phase instability of a fluid in a closed looped capillary channel of an oscillating heat pipe (OHP) creates pressure differences which lead to local high frequency temperature oscillations in the range of 0.1–5 K. Such temperature changes are suitable for pyroelectric thermal to electrical energy conversion, where the pyroelectric generator is attached to the adiabatic wall of the OHP, thereby absorbing thermal energy from the passing fluid. This new pyroelectric-oscillating heat pipe (POHP) assembly of a low temperature generator continuously operates across a spatial heat source temperature of 55 °C and a heat sink temperature of 25 °C, and enables waste heat recovery and thermal energy harvesting from small temperature gradients at low temperatures. Our electrical measurements with lead zirconate titanate (PZT) show an open circuit voltage of 0.4 V (AC) and with lead magnesium niobate–lead titanate (PMN-PT) an open circuit voltage of 0.8 V (AC) at a frequency of 0.45 Hz, with an energy density of 95 pJ cm−3 for PMN-PT. Our novel POHP device therefore has the capability to convert small quantities of thermal energy into more desirable electricity in the nW to mW range and provides an alternative to currently used batteries or centralised energy generation.
This record has no associated files available for download.
More information
Accepted/In Press date: 28 June 2016
Published date: 14 July 2016
Identifiers
Local EPrints ID: 496750
URI: http://eprints.soton.ac.uk/id/eprint/496750
ISSN: 0021-8979
PURE UUID: fd74894a-bbb8-406a-88a7-541d2fc90325
Catalogue record
Date deposited: 07 Jan 2025 23:14
Last modified: 11 Jan 2025 03:14
Export record
Altmetrics
Contributors
Author:
D. Zabek
Author:
J. Taylor
Author:
V. Ayel
Author:
Y. Bertin
Author:
C. Romestant
Author:
C.R. Bowen
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics