检索规则说明:AND代表“并且”;OR代表“或者”;NOT代表“不包含”;(注意必须大写,运算符两边需空一格)
检 索 范 例 :范例一: (K=图书馆学 OR K=情报学) AND A=范并思 范例二:J=计算机应用与软件 AND (U=C++ OR U=Basic) NOT M=Visual
名 称:
注 释:
作 者:杨友进[1] 刘向农[1] 吴昊[1] 王铁军[1]
机构地区:[1]合肥工业大学机械与汽车工程学院,合肥230009
出 处:《低温与超导》2014年第12期62-65,共4页Cryogenics and Superconductivity
基 金:安徽省自主创新专项资金(2012XKJH0003)资助项目
摘 要:针对商用空调应用环境,在换热器实验台进行多组平行流冷凝器性能实验,重点研究环境温度和流程分配对平行流冷凝器的流动和传热性能的影响,并与翅片管式换热器进行对比。实验结果表明:平行流冷凝器的换热量及制冷剂流动阻力均随蒸发温度上升而增大;平行流冷凝器的流程分配对制冷剂流动阻力影响显著;同等条件下平行流换热器的传热性能是翅片管式换热器的3~4倍。合理的流程分配可以提高平行流冷凝器的流动和传热性能,拓展其应用范围。For commercial air conditioning applications,some performance experiments of parallel flow condenser in the heat exchanger experiment platform were carried out,what were focused on the flow and heat transfer performance of parallel flow condenser when environmental temperature and flow distribution change,and compared with finned tube heat exchanger. Results of experiments show that the parallel flow condenser's heat transfer and refrigerant flow resistance increase with evaporation temperature rise. Different flow distributions of parallel flow condensers have great influence on refrigerant flow resistance. The heat transfer performance of parallel flow heat exchanger is 3 ~ 4 times of finned tube heat exchanger in same conditions. Appropriate flow distribution can improve the flow and heat transfer performance of parallel flow condenser and augment its range of application.
分 类 号:TK172[动力工程及工程热物理—热能工程]
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在链接到云南高校图书馆文献保障联盟下载...
云南高校图书馆联盟文献共享服务平台 版权所有©
您的IP:216.73.216.15