利用冷却管增强离子液体活塞压缩机传热的数值研究

IF 1.7 4区计算机科学 Q3 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Journal of Visualization Pub Date : 2024-09-03 DOI:10.1007/s12650-024-01027-4

Van-Tinh Huynh, Dong Kim

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引用次数: 0

摘要

在一个圆柱形腔体内，使用离子液体 1-ethyl-3-methylimidazolium tetrafluoroborate 将气态氢从 220 巴压缩到 752.3 巴，同时在大约六秒内将其温度从 298.15 K 提高到 394.2 K。建立了三维液体活塞压缩机模型，并根据实验数据进行了验证。使用有限体积法和 ANSYS Fluent 软件中的流体体积模型模拟了两相流动。研究了在液体活塞压缩机内使用冷却管的新型传热增强技术，以实现近等温压缩。考虑到管道数量、横截面形状、直径和管道温度，研究了多种冷却方案，以提高压缩和热性能。通过这种方法，可以更全面地了解工作流体在整个压缩过程中的流动状态和传热行为。为了达到理想的压力比，使用四根圆形管道将氢气温度从 394.2 K 降低到 355 K，热效率提高了 40.8%。此外，压缩性能达到了 95.8%，功率密度为 3221.4 kW-m-3，而在没有冷却的情况下，压缩性能为 90.9%，功率密度为 4550.6 kW-m-3。

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Numerical investigations of heat transfer enhancement in ionic liquid-piston compressor using cooling pipes

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Numerical investigations of heat transfer enhancement in ionic liquid-piston compressor using cooling pipes

In a cylindrical chamber, the ionic liquid 1-ethyl-3-methylimidazolium tetrafluoroborate was used to compress gaseous hydrogen from 220 to 752.3 bar, concurrently raising its temperature from 298.15 to 394.2 K over approximately six seconds. A three-dimensional liquid-piston compressor model was established and validated against the experimental data. Two-phase flow was simulated using the finite volume method and the volume of fluid model in ANSYS Fluent software. A novel heat transfer enhancement technique using cooling pipes was investigated inside a liquid-piston compressor to achieve near-isothermal compression. Multiple cooling scenarios were explored to enhance the compression and thermal performance, considering the number of pipes, cross-sectional shape, diameter, and pipe temperature. This approach provided a more comprehensive understanding of the flow regimes and heat transfer behaviors of working fluids throughout the compression process. To achieve the desired pressure ratio, using four circular pipes reduced the hydrogen temperature from 394.2 to 355 K, marking 40.8% improvement in thermal efficiency. Furthermore, compression performance reached 95.8% with a power density of 3221.4 kW·m⁻³, compared to 90.9% and 4550.6 kW·m⁻³ without cooling.

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来源期刊

Journal of Visualization COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS-IMAGING SCIENCE & PHOTOGRAPHIC TECHNOLOGY

CiteScore

3.40

自引率

5.90%

发文量

审稿时长

>12 weeks

期刊介绍： Visualization is an interdisciplinary imaging science devoted to making the invisible visible through the techniques of experimental visualization and computer-aided visualization. The scope of the Journal is to provide a place to exchange information on the latest visualization technology and its application by the presentation of latest papers of both researchers and technicians.