摘要
在传统两级溴化锂吸收式制冷循环的基础上,从增大热源可利用温差考虑,提串了一种由太阳能驱动的新型吸收式制冷循环,分析计算了低压发生器压力(中间压力)和中间溶液浓度变化对系统热力系数COP和热源可利用温差的影响。结果表明,在发生热源温度850C~95℃的范围内,中间压力在1.6KPa(12mmHg)和2.2KPa(16.5mmHg)之间取值新型循环有较高的热力系数和较大的热源可利用温差。
On the basis of the traditional two-level lithium bromide absorption refrigeration cycle, considering that the heat can be increased by the temperature difference, this paper proposes a new absorption refrigeration cycle driven by solar energy to an- alyze and calculate the influence of the system thermal coefficient COP as well as available temperature difference made by the heat source under the low-voltage generator pressure (intermediate pressure) and intermediate solution concentration change. The results show that, within the scope of the occurrence of the heat source temperature of 85℃-95℃, the intermediate pressure be- tween 1.6KPa (12mmHg) and 2.2KPa (16.SmmHg) can obtain the new value which has a higher thermodynamic cycle coeffi- cient and the temperature difference of a larger heat source.
出处
《巢湖学院学报》
2015年第3期40-43,共4页
Journal of Chaohu University
基金
安徽省教育厅科学研究项目(项目编号:KJ2013B158)
关键词
太阳能
吸收式制冷
溴化锂
热源可利用温差
热力系数COP
solar energy
absorption refrigeration
lithium bromide
available temperature difference of heat resource
thermalcoefficient COP