Experimental Study on Performance of Dual-serial-throat Nozzle Ejector and Two-phase Ejector Refrigeration Cycle System

Ren Liqian; Guo Xianmin; Li Tianlong

doi:10.3969/j.issn.0253-4339.2014.04.021

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Experimental Study on Performance of Dual-serial-throat Nozzle Ejector and Two-phase Ejector Refrigeration Cycle System

更新时间：2024-07-18

- Experimental Study on Performance of Dual-serial-throat Nozzle Ejector and Two-phase Ejector Refrigeration Cycle System
- Journal of Refrigeration Vol. 35, Issue 4, (2014)
- 作者机构：
  
  天津商业大学天津市制冷技术重点实验室
- 作者简介：
- 基金信息：
- DOI：10.3969/j.issn.0253-4339.2014.04.021
  CLC：
- Published：2014
- 稿件说明：
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Ren Liqian, Guo Xianmin, Li Tianlong. Experimental Study on Performance of Dual-serial-throat Nozzle Ejector and Two-phase Ejector Refrigeration Cycle System[J]. Journal of refrigeration, 2014, 35(4).
DOI：

Ren Liqian, Guo Xianmin, Li Tianlong. Experimental Study on Performance of Dual-serial-throat Nozzle Ejector and Two-phase Ejector Refrigeration Cycle System[J]. Journal of refrigeration, 2014, 35(4). DOI： 10.3969/j.issn.0253-4339.2014.04.021.

摘要

对采用两段式喷嘴引射器的两相流引射制冷系统进行了实验研究，并将两段式喷嘴的引射比及其系统COP分别与拉法尔喷嘴引射器的引射比及其系统COP进行了比较。实验结果表明：在冷凝/蒸发温度为45 ℃/1 ℃工况下，使用不同几何尺寸两段式喷嘴引射器的引射比均大于拉法尔喷嘴引射器的引射比，最大提高了约18%；使用两段式喷嘴引射器的制冷系统COP大于使用拉法尔喷嘴引射器的制冷系统COP，最大提高了约12%；在蒸发温度为1 ℃条件下，两段式喷嘴引射器及拉法尔喷嘴引射器的引射比均在冷凝温度为45 ℃时达到最大值，而在冷凝温度为50 ℃条件下，两种引射器的引射比均在蒸发温度为3 ℃时达到最大值。

Abstract

The two-phase ejector refrigeration cycle (TPERC) system with a dual-serial-throat nozzle ejector was investigated experimentally

and the entrainment ratio of the ejector and the COP of the system were compared with those of the ejector with Laval nozzle and the TPERC system respectively. The experimental results indicate that the entrainment ratios of the dual-serial-throat nozzle ejectors with different geometric size are greater than those of the Laval nozzle ejectors under the working condition of the evaporating/condensing temperatures 1 ℃/45 ℃

the maximum increment of the entrainment ratio is about 18%; and the COP of the TPERC system with dual-serial-throat nozzle ejector is greater than that of the TPERC system with Laval nozzle ejector

the maximum increment of the COP is about 12%. Under the condition of the fixed evaporating temperature 1 ℃

the entrainment ratios of both the dual-serial-throat nozzle ejector and the Laval nozzle ejector achieve the maximum values as the condensing temperature is about 45 ℃. Under the condition of the fixed condensing temperature 50 ℃

the entrainment ratios of the two types of ejectors achieve the maximum values as the evaporating temperature is about 3 ℃.

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