Enhancing solar thermoelectric power generation with supercritical CO2 cooling: Hydraulic, thermal, and exergy analysis

IF 5.1 3区 工程技术 Q2 ENERGY & FUELS
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引用次数: 0

Abstract

This research investigates the dynamic behavior and impact of various factors on the hydraulic, thermal, and exergetic characteristics of a solar-based thermoelectric device using a pin–fin heatsink cooled by supercritical CO2. A comprehensive numerical model analyzes the heat dissipation and performance of the power generator, integrating a thermoelectric generator and a pin–fin heatsink with various pin shapes. Key geometric and operational parameters, such as the height of PN (P-type and N-type semiconductor) legs of the TEG, the number of thermocouples, operating pressure, Reynolds number, and CO2 temperature, are examined for a comprehensive performance assessment. The study highlights the superior performance of CO2 coolant over traditional water-cooling system. Near the critical temperature of CO2, enhanced heat transfer significantly boosts power output, conversion efficiency, and exergetic efficiency. For example, at 8 MPa, the TEG’s (thermoelectric generator) power output increases from 1.31 mW at 295 K to 2.35 mW at 310 K. Comparisons reveal that while water coolant lowers the cold side temperature more effectively, it results in reduced power output due to decreased temperature differentials and increased pressure loss. Conversely, CO2 coolant maintains higher cold side temperatures while having advantages in power output. At 315 K, the cold side temperature with water is 315.7 K compared to 346.7 K with CO2. Increasing the number of thermocouples from 18 to 32 for a leg height of 1 mm leads to an approximate 102.3 % increase in voltage. Raising the PN leg height from 1 mm to 2 mm for an NTC of 50 results in a nearly 99.8 % increase in voltage. Lozenge-shaped fin produces a peak power output of 2.73 mW, while square fin generates 2.62 mW. This research underscores CO2’s potential as a high-performance coolant in solar thermoelectric applications, offering insights into optimizing system design for maximum efficiency.

利用超临界二氧化碳冷却增强太阳能热发电:水力、热力和放能分析
本研究探讨了使用超临界二氧化碳冷却的针形鳍片散热器的太阳能热电装置的动态行为以及各种因素对其水力、热力和发电特性的影响。综合数值模型分析了热电发电机的散热和性能,该模型集成了热电发电机和具有不同针形的针形鳍片散热器。为进行全面的性能评估,对关键的几何和运行参数进行了研究,如 TEG 的 PN(P 型和 N 型半导体)脚高度、热电偶数量、工作压力、雷诺数和二氧化碳温度。研究结果表明,二氧化碳冷却剂的性能优于传统的水冷系统。在接近二氧化碳临界温度时,增强的热传递可显著提高功率输出、转换效率和能效。例如,在 8 兆帕时,TEG(热电发生器)的功率输出从 295 K 时的 1.31 mW 增加到 310 K 时的 2.35 mW。比较发现,虽然水冷却液能更有效地降低冷端温度,但由于温差减小和压力损失增加,导致功率输出降低。相反,二氧化碳冷却剂能保持较高的冷侧温度,同时在功率输出方面具有优势。在 315 K 时,水的冷侧温度为 315.7 K,而二氧化碳的冷侧温度为 346.7 K。将热电偶的数量从 18 个增加到 32 个,脚高为 1 毫米,可使电压增加约 102.3%。在 NTC 为 50 的情况下,将 PN 脚高度从 1 毫米增加到 2 毫米,可使电压增加近 99.8%。菱形鳍片产生的峰值功率输出为 2.73 mW,而方形鳍片则为 2.62 mW。这项研究强调了二氧化碳在太阳能热电应用中作为高性能冷却剂的潜力,为优化系统设计以实现最高效率提供了启示。
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来源期刊
Thermal Science and Engineering Progress
Thermal Science and Engineering Progress Chemical Engineering-Fluid Flow and Transfer Processes
CiteScore
7.20
自引率
10.40%
发文量
327
审稿时长
41 days
期刊介绍: Thermal Science and Engineering Progress (TSEP) publishes original, high-quality research articles that span activities ranging from fundamental scientific research and discussion of the more controversial thermodynamic theories, to developments in thermal engineering that are in many instances examples of the way scientists and engineers are addressing the challenges facing a growing population – smart cities and global warming – maximising thermodynamic efficiencies and minimising all heat losses. It is intended that these will be of current relevance and interest to industry, academia and other practitioners. It is evident that many specialised journals in thermal and, to some extent, in fluid disciplines tend to focus on topics that can be classified as fundamental in nature, or are ‘applied’ and near-market. Thermal Science and Engineering Progress will bridge the gap between these two areas, allowing authors to make an easy choice, should they or a journal editor feel that their papers are ‘out of scope’ when considering other journals. The range of topics covered by Thermal Science and Engineering Progress addresses the rapid rate of development being made in thermal transfer processes as they affect traditional fields, and important growth in the topical research areas of aerospace, thermal biological and medical systems, electronics and nano-technologies, renewable energy systems, food production (including agriculture), and the need to minimise man-made thermal impacts on climate change. Review articles on appropriate topics for TSEP are encouraged, although until TSEP is fully established, these will be limited in number. Before submitting such articles, please contact one of the Editors, or a member of the Editorial Advisory Board with an outline of your proposal and your expertise in the area of your review.
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