基于优化的低品位热转换两相热流体振荡器研究

IF 2.35
Yukun Wang, Christos N. Markides, Benoît Chachuat
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引用次数: 2

摘要

非惯性反馈热流体发动机(NIFTE)是一种两相热流体振荡器,能够利用在稳定温度下提供的热量来诱导持续的热流体振荡。NIFTE以其简单性和在小温差下操作的能力而吸引人,据报道,早期原型的温度可低至30°C。但与传统热回收技术相比,NIFTE的效率可能会较低,而传统热回收技术的目标是更高等级的热转换。数学建模可以帮助评估NIFTE技术的全部潜力。我们的分析是基于NIFTE的非线性模型,我们将其扩展到包含不可逆热损失。两种模型都预测NIFTE在特定的设计配置下可能表现出多个循环稳态(CSS),要么稳定,要么不稳定,这是一种从未被假设过的行为。然后对两种模型进行了NIFTE主要设计参数的参数化分析。结果证实,在NIFTE模型中不包括不可逆热损失会严重高估其性能,特别是在扩展参数域上。最后,我们使用不可逆热损失的NIFTE模型,通过进行多目标优化来评估该技术的优化潜力。我们的研究结果表明,大部分的优化潜力是可以通过有针对性地修改三个设计参数来实现的。研究发现,优化后的参数对有效效率和输出功率之间的帕累托边界非常敏感。NIFTE对一系列应用具有实际意义,包括开发太阳能驱动的水泵,以支持发展中国家的小农灌溉。鉴于其较低的资本成本,该技术在效率或功率输出方面的潜在改进超过50%,这对采用该技术具有重要意义。众所周知,传统的热回收技术比这项工作中报道的效率更高,但它们也有更复杂的设计和操作,更高的资本成本,甚至可能不适用于本文所考虑的温差。未来的工作应侧重于通过专门的实验活动来确认基于模型的评估,并研究设计修改以减轻不可逆的热损失。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Optimization-based investigations of a two-phase thermofluidic oscillator for low-grade heat conversion

Optimization-based investigations of a two-phase thermofluidic oscillator for low-grade heat conversion

The non-inertive-feedback thermofluidic engine (NIFTE) is a two-phase thermofluidic oscillator capable of utilizing heat supplied at a steady temperature to induce persistent thermal-fluid oscillations. The NIFTE is appealing in its simplicity and ability to operate across small temperature differences, reported as low as 30 °C in early prototypes. But it is also expected that the NIFTE will exhibit low efficiencies relative to conventional heat recovery technologies that target higher-grade heat conversion. Mathematical modeling can help assess the full potential of the NIFTE technology.

Our analysis is based on a nonlinear model of the NIFTE, which we extend to encompass irreversible thermal losses. Both models predict that a NIFTE may exhibit multiple cyclic steady states (CSS) for certain design configurations, either stable or unstable, a behavior that had never been hypothesized. A parametric analysis of the main design parameters of the NIFTE is then performed for both models. The results confirm that failure to include the irreversible thermal losses in the NIFTE model can grossly overpredict its performance, especially over extended parameter domains. Lastly, we use the NIFTE model with irreversible thermal losses to assess the optimization potential of this technology by conducting a multi-objective optimization. Our results reveal that most of the optimization potential is achievable via targeted modifications of three design parameters only. The Pareto frontier between exergetic efficiency and power output is also found to be highly sensitive to these optimized parameters.

The NIFTE is of practical relevance to a range of applications, including the development of solar-driven pumps to support small-holder irrigation in the developing world. Given its low capital cost, potential improvements greater than 50% in efficiency or power output are significant for the uptake of this technology. Conventional heat recovery technologies are known to have higher efficiencies than those reported in this work, but they also have more complex designs and operations, higher capital costs, and may not even be feasible for the temperature differences considered herein. Future work should focus on confirming this model-based assessment via dedicated experimental campaigns and on investigating design modifications to mitigate irreversible thermal losses.

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