1·The development of ground source heat pump (GSHP) at home and abroad is briefly introduced.
介绍了地源热泵的工作原理、性能评价指标和基本类型;
2·The result can be used as a reference for the dynamic simulation, optimum design and improvement of GSHP.
计算结果为地源热泵系统的动态模拟、优化设计及改进提供了参考。
3·Along with GSHP running at refrigerate condition the temperatures of the out medium and the wall gradually rise.
随着土壤源热泵在制冷工况下连续运行,埋管出口介质温度和管井壁面温度逐渐升高。
4·This paper introduces heat balance problems of underground soil, effective method of mixed GSHP for solar energy.
介绍了地下土壤的热平衡问题,采用太阳能辅助加热的混合式地源热泵系统是有效的方法。
5·More moisture content and higher soil initial temperature are favorable to the design and operation of GSHP systems.
当土壤含湿量大、土壤初始温度高时,对于系统的设计与运行是有利的。
6·To perfect heat-transfer model for ground heat exchanger is one of key problems about GSHP popularization and application.
提出内热源型埋地换热器理论模型,建立换热器周围土壤热湿传递物理数学模型。
7·GSHP can be subdivided into groundwater heat pump (GWHP), ground-coupled heat pump (GCHP), and surface water heat pump (SWHP).
地源热泵系统包括地下水热泵系统、土壤源热泵系统和地表水热泵系统。
8·Thermal properties of deep ground are important data for designing geothermal heat exchangers in ground source heat pump (GSHP) systems.
地下岩土的热物性参数是地源热泵地热换热器的设计中所需要的很重要的参数。
9·The reasons were analyzed from the points of how efficiently GSHP USES the underground thermal energy and EER comparison of GSHP with the air source heat pump.
通过比较土壤源热泵系统与风冷热泵系统的耗能量和土壤源热泵系统如何有效地利用地表热能两个方面,分析了土壤源热泵系统节能的原因并提出了影响其节能特性的因素。
10·One of the key techniques for GSHP popularization and application is to perfect heat transfer models for the ground heat exchangers to simulate the actual heat exchange process.
推广和应用地源热泵的关键技术之一是完善地下换热埋管的传热模型,使其更好的模拟地下换热埋管的真实传热过程。