Influence of Condensation on the Outer Surface of Polymer Hollow Fiber Heat Exchangers During Heat Transfer

ASME 2018 16th International Conference on Nanochannels, Microchannels, and Minichannels Pub Date : 2018-06-10 DOI:10.1115/ICNMM2018-7728

T. Brozova, E. Bartuli

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引用次数: 6

Abstract

Condensation during heat transfer processes can be very beneficially used due to the large amount of energy contained in phase change (vapor to liquid). This contribution focuses on the possible use of polymer hollow fiber heat exchangers (PHFHEs) in air conditioning. PHFHEs consist of hundreds or thousands of polymer hollow fibers with an outer diameter of around 1 mm. The wall thickness is approximately 10% of the outer diameter. PHFHEs are heat exchangers with such benefits as low weight, easy shaping, corrosion resistance, and resistance to many chemical solutions. In comparison with metal heat exchangers (made of copper, aluminum, or stainless steel) the plastic wall of PHFHEs has low thermal conductivity (between 0.1 and 0.4 Wm-1K-1). This seems to be their key disadvantage. However, due to the extremely small thickness of the fiber’s wall this disadvantage is negligible. PHFHEs are compact heat exchangers with a large heat transfer area with respect to their volume. This paper shows the results of condensation tests for PHFHEs that consist of 6 equivalent layers of polypropylene fibers with a length of 190 mm. The total number of fibers is 798. The air humidity was set to 50% with an air temperature of 27°C, which are the typical conditions for such tests in air conditioning technology. Another important parameter was the velocity of the air. Testing velocities were chosen as 3 m s−1 and 1 m s−1. The influence of gravity was studied by putting the PHFHEs in three different positions. The fibers were placed in horizontal and vertical positions, and in a position where fibers form an angle of 45° with the ground. The study showed the ineffectiveness of placing the PHFHE in a horizontal position and suggests that it is better to have a larger distance between the layers of fibers.

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聚合物中空纤维换热器换热过程中外表面结露的影响

由于相变(蒸汽到液体)中含有大量的能量，因此在传热过程中可以非常有益地使用冷凝。这篇文章的重点是聚合物中空纤维热交换器(PHFHEs)在空调中的可能应用。PHFHEs由数百或数千个外径约为1毫米的聚合物中空纤维组成。壁厚约为外径的10%。PHFHEs是一种热交换器，具有重量轻、易于成型、耐腐蚀和耐多种化学溶液等优点。与金属热交换器(由铜、铝或不锈钢制成)相比，PHFHEs的塑料壁导热系数低(在0.1至0.4 Wm-1K-1之间)。这似乎是他们的主要缺点。然而，由于纤维壁的厚度非常小，这个缺点可以忽略不计。PHFHEs是紧凑的热交换器，相对于其体积具有较大的传热面积。本文给出了由6层等长190 mm聚丙烯纤维组成的PHFHEs的凝结试验结果。光纤总数为798根。空气湿度为50%，温度为27°C，这是空调技术中此类测试的典型条件。另一个重要的参数是空气的速度。试验速度分别为3 m s - 1和1 m s - 1。通过将PHFHEs放置在三个不同的位置，研究了重力的影响。光纤的布放位置为水平和垂直，布放位置为光纤与地面成45°角。研究表明，PHFHE在水平位置放置是无效的，并建议在纤维层之间有更大的距离。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ASME 2018 16th International Conference on Nanochannels, Microchannels, and Minichannels

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