Cop Enhancement of Vapour Compression Refrigeration System

Indian Journal of Production and Thermal Engineering Pub Date : 2021-06-10 DOI:10.35940/IJPTE.B2004.061221

B. Sairamakrishna, T. G. Rao, N. Krishna

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Abstract

This experimental investigation exemplifies the design and testing of diffuser at compressor inlet and nozzle at condenser outlet in vapour compression refrigeration system with the help of R134a refrigerant. The diffuser with divergence angle of 12°,14° and the nozzle with convergent angle 12°,14° are designed for same inlet and outlet diameters. Initially diffusers are tested at compressor inlet diffuser is used with inlet diameter equal to exit tube diameter of evaporator and outlet tube diameter is equal to suction tube diameter of the compressor. Diffuser helps to increases the pressure of the refrigerant before entering the compressor it will be helps to reduces the compression work and achieve higher performance of the vapour compression refrigeration system. Then nozzles are testing at condenser outlet, whereas nozzle inlet diameter equal to discharging tube diameter of condenser and outlet diameter equal to inlet diameter of expansion valve. Additional pressure drop in the nozzle helped to achieve higher performance of the vapour compression refrigeration system. The system is analyzes using the first and second laws of thermodynamics, to determine the refrigerating effect, the compressor work input, coefficient of performance (COP).

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蒸汽压缩制冷系统的Cop增强

本实验研究举例说明了在R134a制冷剂的辅助下，蒸汽压缩制冷系统中压缩机进口扩压器和冷凝器出口喷嘴的设计和测试。散度角为12°、14°的扩压器和会聚角为12°、14°的喷嘴在相同的进、出口直径下设计。扩压器采用进口直径等于蒸发器出口管径，出口管径等于压缩机吸入管径的扩压器。扩散器有助于提高制冷剂进入压缩机前的压力，这将有助于减少压缩工作，实现更高的蒸汽压缩制冷系统的性能。然后在冷凝器出口测试喷嘴，喷嘴进口直径等于冷凝器排出管直径，出口直径等于膨胀阀进口直径。喷嘴的额外压降有助于实现更高的蒸汽压缩制冷系统性能。利用热力学第一、第二定律对系统进行分析，确定制冷效果、压缩机功输入、性能系数(COP)。

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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Indian Journal of Production and Thermal Engineering

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