降低冷却水进口温度和提高其质量流量不仅有利于提高制冷性能系数,而且能降低最佳高压侧压力。
Reducing the inlet temperature of cooling water and increasing its mass flow are favorable to increase refrigerant performance coefficient, and can decrease optimal pressure at high pressure side.
以制冷系数为目标函数,对制冷循环系统的性能进行优化分析。
The coefficient of performance is taken as an objective function. The performance of the refrigeration system is optimized.
并讨论了循环的发生温度、蒸发温度、吸收温度对循环性能系数、循环倍率和制冷量的影响。
The influences of generation temperature, evaporation temperature, absorption temperature to the coefficient of performance, circular ratio and cooling capacity were also studied.
再生温度和环境空气含湿量对系统制冷量和性能系数的影响较大,而环境空气温度的影响较小;
The regenerating temperature and the humidity ratios of ambient air are two main factors affecting system performance, while the temperature of ambient air functions less.
吸收式制冷的优势在于可用低势热源驱动并以环保无公害流体作为工作介质,缺点是性能系数(COP)较低。
Absorption refrigeration can use low thermal potential energy as its power and environment friendly fluids as its working substance.
制冷量与制冷系数变化趋势的交叉点处为压缩机发挥最佳制冷性能的控制点;
Refrigerator oil having viscosity corresponded to the cross point of refrigerating capacity curve and refrigerating coefficient curve was the optimum product to obtain optimal refrigeration effect.
制冷量与制冷系数变化趋势的交叉点处为压缩机发挥最佳制冷性能的控制点;
Refrigerator oil having viscosity corresponded to the cross point of refrigerating capacity curve and refrigerating coefficient curve was the optimum product to obtain optimal refrigeration effect.
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