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Parametric analysis of fatigue-resistant elastocaloric regenerators : tensile vs. compressive loading
ID
Ahčin, Žiga
(
Author
),
ID
Tušek, Jaka
(
Author
)
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https://www.sciencedirect.com/science/article/pii/S1359431123010256
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Abstract
Elastocaloric cooling has recently shown high potential as an environmentally friendly alternative to vapor-compression technology. Here, we have studied and analyzed the geometric characteristics of two active elastocaloric regenerators (AeCRs) that were proved to have high application potential, i.e., a shell-and-tube AeCR loaded in compression and a parallel-plate AeCR loaded in tension, with the goal of maximizing their cooling performance. For this purpose, a previously developed and experimentally verified 1D numerical model was used. We focused only on the geometries and operating conditions that allow for durable, i.e., buckling-free operation in compression and fatigue-resistant operation in tension. The results show that although the applied strain of the parallel-plate AeCR loaded in tension needs to be limited (below 2%) to ensure fatigue-resistant operation, it outperforms (in terms of cooling power and COP at 15 K of temperature span) the shell-and-tube AeCR, which due to buckling issues suffers from a poorer heat-transfer geometry, but can withstand higher strains due to compressive loading. At the maximum strain of 2%, the optimum parallel-plate AeCR can generate a maximum cooling power of 1825 W (corresponding to 7075 W kg$^{−1}$ of elastocaloric material) and a COP of 9.15 at a zero-temperature span. On the other hand, due to a higher applied strain (3%) the optimum shell-and-tube AeCR can generate a higher maximum temperature span at zero cooling power (up to 50 K) but has limited cooling performance at lower temperature spans. In addition, the layering of the shell-and-tube AeCR was investigated for the first time to improve its performance. This study shows the crucial impact of the heat-transfer geometry (heat-transfer area and hydraulic diameter), which needs to be further improved in compression-loaded AeCRs to improve their efficiencies (without compromising the buckling stability). The study also shows the importance of the applied strain, which needs to be at least 2% or more to achieve a high cooling performance of the AeCR. The obtained results should serve as guidelines for designing powerful and efficient AeCRs in the future.
Language:
English
Keywords:
elastocaloric effect
,
caloric cooling
,
Ni-Ti
,
regenerators
,
parametric analysis
Work type:
Article
Typology:
1.01 - Original Scientific Article
Organization:
FS - Faculty of Mechanical Engineering
Publication status:
Published
Publication version:
Version of Record
Year:
2023
Number of pages:
13 str.
Numbering:
Vol. 231, art. 120996
PID:
20.500.12556/RUL-147390
UDC:
519.876.5:621.57
ISSN on article:
1359-4311
DOI:
10.1016/j.applthermaleng.2023.120996
COBISS.SI-ID:
157626371
Publication date in RUL:
04.07.2023
Views:
480
Downloads:
79
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Record is a part of a journal
Title:
Applied thermal engineering
Shortened title:
Appl. therm. eng.
Publisher:
Elsevier Science
ISSN:
1359-4311
COBISS.SI-ID:
1861910
Licences
License:
CC BY-NC-ND 4.0, Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International
Link:
http://creativecommons.org/licenses/by-nc-nd/4.0/
Description:
The most restrictive Creative Commons license. This only allows people to download and share the work for no commercial gain and for no other purposes.
Secondary language
Language:
Slovenian
Keywords:
elastokalorični učinek
,
kalorično hlajenje
,
Ni-Ti
,
regeneratorji
,
parametrična analiza
Projects
Funder:
EC - European Commission
Funding programme:
H2020
Project number:
803669
Name:
Superelastic Porous Structures for Efficient Elastocaloric Cooling
Acronym:
SUPERCOOL
Funder:
ARRS - Slovenian Research Agency
Project number:
P2-0422
Name:
Funkcionalne tekočine za napredne energetske sisteme
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