Exergy analysis on ice slurry production system by water spray evaporation in vacuum environment

doi:10.3969/j.issn.0438-1157.2013.08.003

CIESC Journal ›› 2013, Vol. 64 ›› Issue (8): 2724-2729.DOI: 10.3969/j.issn.0438-1157.2013.08.003

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Exergy analysis on ice slurry production system by water spray evaporation in vacuum environment

ZHAO Hongxia, SUN Bingjie, JI Cuilian, HAN Jitian

School of Power and Energy, Shandong University, Jinan 250061, Shandong, China

Received:2012-12-04 Revised:2013-01-29 Online:2013-08-05 Published:2013-08-05
Supported by:
supported by the Ministry of Education of China(2009131120044),the Natural Science Foundation of Shandong Province(2009ZRB01372)and the Innovation Fund of Shandong University(2010TS100).

真空闪蒸制取冰浆系统(火用)分析

赵红霞, 孙冰洁, 冀翠莲, 韩吉田

山东大学能源与动力工程学院, 山东济南 250061

通讯作者: 赵红霞(1977- ),女,副教授。
作者简介:赵红霞(1977- ),女,副教授。
基金资助:
教育部博士点专项科研基金项目(新教师(20090131120044);山东省自然科学基金青年基金项目(2009ZRB01372);山东大学自主创新基金项目(2010TS100);山东省自然科学基金和山东商业集团有限公司联合专项(ZR2010QL05)。

Abstract

Abstract: Based on available formulas for cold exergy and exergy loss,exergy analysis was performed for a laboratory-scale vacuum evaporation system to produce ice slurry.By using EES software,calculations were carried out for the mixing of cold water and icy water in the system,spray and evaporation in the vacuum chamber,vapor condensation in the water trap,and saline coolant production with a chiller.The exergy losses and exergy efficiencies were obtained for the three of them and the whole system.The results show that the spray and evaporation in the vacuum chamber has the highest exergy efficiency and the vapor condensation in the water trap has lower efficiency. The lowest exergy efficiency and largest exergy losses occur in the saline production with a chiller,resulting in lower efficiency of the whole system.In order to improve the exergy efficiency of the system,the saline coolant production with a chiller should be optimized or to be replaced by other means.

Key words: vacuum evaporation, ice slurry, exergy loss, exergy efficiency

摘要： 采用已有的计算冷量以及损失的公式,对实验室用真空闪蒸制取冰浆系统进行了(火用)分析。利用EES软件,对真空闪蒸法冰浆制备系统中的4个关键环节(冷水冰水混合、真空室内喷雾闪蒸、捕水器内蒸汽凝结成霜、制冷机制备低温盐水)进行计算,得出各个环节(火用)损失以及整个系统的(火用)效率。结果表明:实验用真空室内喷雾闪蒸环节的(火用)效率较高,捕水器内蒸汽凝结成霜的(火用)效率较低,制冷机组制备低温盐水(火用)效率最低,(火用)损最大,导致整个系统的效率相对较低。为了改善真空闪蒸制取冰浆系统的能耗,应对低温盐水制备环节进行优化或采用其他方式替代该环节。

关键词: 真空闪蒸, 冰浆, (火用)损失, (火用)效率

CLC Number:

TK02

ZHAO Hongxia, SUN Bingjie, JI Cuilian, HAN Jitian. Exergy analysis on ice slurry production system by water spray evaporation in vacuum environment[J]. CIESC Journal, 2013, 64(8): 2724-2729.

赵红霞, 孙冰洁, 冀翠莲, 韩吉田. 真空闪蒸制取冰浆系统(火用)分析[J]. 化工学报, 2013, 64(8): 2724-2729.

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Exergy analysis on ice slurry production system by water spray evaporation in vacuum environment

真空闪蒸制取冰浆系统(火用)分析

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