摘要
为探究大规模空分系统中空压机余热利用的可行方法,提出利用压缩余热驱动有机朗肯-蒸汽压缩制冷耦合循环,所得制冷量用于空压机入口空气冷却,从而提高压缩系统效率,实现空压机余热自利用和压缩过程自增效的目的。以6万空分规模中空压系统的余热回收为例,利用MATLAB对该余热自利用系统进行了热力学建模;进一步,以系统经济性最大化为目标,针对典型湿度地区的运行工况采用萤火虫算法对主要蒸发器换热面积进行优化。结果表明,在入口空气相对湿度为70%和30%时,该多级空压余热自利用系统的节能率分别可达到4.6%和4.2%,回收周期分别为4.4年和5.5年,系统显示出较好的节能效果和较高的经济价值。
To explore the feasible method of using the air compression heat in the large-scale air separation unit,it was proposed to use the compression heat to drive the organic Rankine-vapor compression refrigeration coupling cycle.The cooling capacity was used to cool down compressors inlet air,to achieve the purpose of self-utilization of compression heat and self-enhancing of compression process.Taking the compression process in a 60000 m3/h scale air separation unit as an example,MATLAB was used to model the compression heat self-utilization system.Further,with the goal of maximizing the system economy,firefly algorithm was used for the optimization of heat exchange area of the main evaporators in typical humidity area.The result shows that when the relative humidity of the inlet air is 70%and 30%,the energy saving rate of the multi-stage air compression heat self-utilization system can reach 4.4%and 4.6%,respectively,and the payback time is 4.4 a and 5.5 a,respectively.The system shows better energy-saving effect and higher economic value.
作者
荣杨一鸣
吴巧仙
周霞
方松
王凯
邱利民
植晓琴
RONG-YANG Yiming;WU Qiaoxian;ZHOU Xia;FANG Song;WANG Kai;QIU Limin;ZHI Xiaoqin(Institute of Refrigeration and Cryogenics,Zhejiang University,Hangzhou 310027,Zhejiang,China;Key Laboratory of Refrigeration and Cryogenic Technology of Zhejiang Province,Hangzhou 310027,Zhejiang,China;Hangzhou Oxygen Plant Group Co.,Ltd.,Hangzhou 310014,Zhejiang,China)
出处
《化工学报》
EI
CAS
CSCD
北大核心
2021年第3期1654-1666,共13页
CIESC Journal
基金
国家重点研发计划项目(2017YFB0603701)。
关键词
空气压缩机
余热回收
有机朗肯循环
蒸汽压缩制冷
经济
热力学过程
萤火虫算法
air compressor
waste heat recovery
organic Rankine cycle
vapor compression refrigeration
economics
thermodynamics process
firefly algorithm
