exergy loss

㶲损失,有效能损失

化学



双语例句

  1. Some irreversible factors for exergy loss are analyzed, and the approaches to reducing exergy loss are presented.
    分析了各种不可逆因素对损的影响,指出了降低损的技术措施,为节能降耗指明了技术路径。
  2. Based on the exergy loss coefficient analysis, we can find that exergy loss mainly occurred in the three-stage thermostatic biogas system and gas engine power generation subsystem.
    可以采用对沼渣进行回热回质,减小三级恒温生物质发酵子系统的火用损;
  3. The exergy loss number is used in this paper as the objective function to indicate the irreversibility of the thermodynamic process.
    以损失数作为目标函数来表征该热力学过程的不可逆程度,分析了管道内对流换热过程中的损。
  4. An Analysis of Exergy Loss Power for a Cooling-heating-power Cogeneration System
    冷热电三联供燃气机热泵系统的火用损功率分析
  5. Analysis of Exergy Loss in Pressure Reducing Process of Superheated Steam and Reasonable Utilization of the Exergy
    过热蒸汽减压过程的?损分析及合理利用方向
  6. Based on thermodynamic principles, entropy generation and exergy loss of BFG ( Blast Furnace Gas) and COG ( Coke Oven Gas) during mixing were studied.
    从热力学原理出发,研究了高、焦炉煤气混合过程的熵增加和损失。
  7. After energy-saving modification and operation optimization, the exergy loss has been reduced, and as a result, a decrease of air separation unit's energy consumption has been realized.
    通过节能改造和优化操作,提高了有效能的利用率,从而达到降低空分设备能耗的目的。
  8. The relation between exergy loss rate and refrigeration coefficient of a Carnot Refrigerator
    卡诺制冷机的火用损率与制冷系数间的关系
  9. The Exergy loss of the cycle is mainly due to the energy conversion and irreversible heat exchange.
    循环Exergy损失主要原因是能量形式的转换和不可逆换热。
  10. The exergy analysis of refrigeration and heat process of air-source gas engine-driven heat pump is carried out. The exergy efficiency and exergy loss of the different equipments and the total thermal efficiency of the system are obtained, and the flow chart of exergy is established.
    对空气源燃气机热泵的制冷过程、制热过程进行了火用分析,得出了各设备的火用效率、火用损及系统总热效率,建立了火用流图。
  11. Heat exergy loss and exergy efficiency of heat exchangers are analyzed.
    对换热器的热量(火用)损失和(火用)效率进行了分析。
  12. The main locations and reasons of exergy loss are illustrated by energy-flow framework diagram. The effects of energy conservation is discussed.
    采用能流结构图直观地分析了甲苯吸收乙烯分离工艺,揭示了系统火用损失发生的主要部位和原因,说明了系统的节能效果。
  13. Compare exergy loss efficiency of multi-product system with heat electricity co-product system.
    并比较三联产系统和热电联产系统的(火用)损率。
  14. Through the thermodynamics analysis on the irreversible exergy loss of radiator caused by temperature differences and viscous friction resistance, the calculation formula of exergy efficiency is derived.
    通过对汽车散热器因传热温差以及粘性流动阻力引起的不可逆火用损失进行热力学分析,推导得出了汽车散热器的火用效率计算公式。
  15. Equations of rate of exergy loss for shell and tube exchanger are derived.
    导出了管壳式换热器的火用损率计算公式,对影响功火用损的因素进行了分析。
  16. The characteristics of use of energy in the refrigeration processes and the optimal performances related to the rate of exergy loss ard further revealed.
    进一步揭示了制冷机用能过程的特点以及与火用损率有关的各种优化性能。
  17. Taking engineering for example, exergy analysis of a groundwater source heat pump system is conducted, and the exergy loss of the compressor per unit time is maximum.
    结合工程实例,对某地下水源热泵系统进行了火用分析,压缩机的单位时间火用损最大。
  18. Results of the energy and exergy balance analysis of the system show that the overall fuel utilization efficiency of the proposed cogeneration system is more than 86%, and the largest exergy loss is generated in the fuel cell.
    该系统的能量和平衡分析结果表明系统总的燃料利用率可达86%以上,损失最大值发生在燃料电池子系统。
  19. The Exergy loss distribution and Exergy loss ratio of each sub-process were quantified and compared with the results of energy analysis.
    给出了各个部件的输入和产出Exergy公式,计算了Exergy损失分布,并与按照传统分析方法获得的分析结果进行了比较。
  20. This paper researches the exergy analysis of ice-storage air-condition system, discovering the distribution and causes of exergy loss in the system to point out a way for system energy economization.
    本文对冰蓄冷系统进行了(火用)分析研究,揭示了系统中(火用)损失的大小分布与成因,为系统节能指明了方向。
  21. The exergy loss of primary steam after temperature and pressure reduction is calculated.
    计算了一次蒸汽经减温减压后的火用损失。
  22. Based on the analysis of flow and convective heat transfer in a pipe for working pair, water/ diglycol, of high-temperature absorption heat pump, the mathematical models describing energy and exergy loss are established in this paper.
    本文研究分析了水/二甘醇热泵工质对在管内流动及换热过程,建立了描述能量损失与火用损失的数学模型。
  23. The calculation equation of exergy transfer efficiency is derived for heat exchanger considering pressure exergy loss.
    在考虑压力火用损失的情况下,给出了换热器传火用有效度的计算式。
  24. The exergy analysis of groundwater source heat pump system as well as the evaporator, compressor, condenser and throttle valve in the system is carried out, and the calculation formula for exergy efficiencies, exergy loss per unit time and exergy loss coefficient is given.
    对地下水源热泵系统中蒸发器、压缩机、冷凝器、节流阀及系统进行了火用分析,给出火用效率、单位时间火用损、火用损系数的计算公式。
  25. After an analysis of the non equivalence of exergy the authors put forward a series of concepts, such as exergy elastic factor, primary exergy loss rate, etc.
    分析了火用的不等价性,在此基础上提出了火用弹性系数、初始火用损耗率等概念。
  26. It also points out the method of decreasing of exergy loss and energy saving.
    分析了减少火用损失的途径,节约能源。
  27. And according to model of the test-bed, the system of exergy loss power and thermo-economic analysis were researched.
    以实验台为原型,对其进行火用损功率分析和热经济学分析。
  28. So reduction the range of temperature-difference is a main way to save exergy loss. 2.
    因此,降低过大的温差,是降低火用损的主要途径。
  29. Calculation of the cooling water system, refrigerator, air treatment systems, air-conditioning at the end of the exergy losses, exergy efficiency, product, and exergy unit cost of exergy loss.
    计算了冷却水系统、制冷机系统、空气处理系统、空调末端的(?)损失、火用效率、产品(?)单价以及(?)损成本。