内可逆循环,Endoreversible cycle
1)Endoreversible cycle内可逆循环
2)endoreversible heat engine cycle内可逆热机循环
1.Exergoeconomic performance optimization for universal model ofendoreversible heat engine cycles containing 6 heat engine models;包含6种热机模型的普适内可逆热机循环经济性能优化
2.Universal model ofendoreversible heat engine cycle and its finite time exergoeconomic performance optimization;普适内可逆热机循环模型的经济性能优化
3)endoreversible Carnot cycle内可逆卡诺循环
1.By the use of semiconductor thermopile technique based on the pyroelectric effect,a test equipment which can simulate the performances of real two heat soure heat engines was developed, and some quantitative researches on the characteristics of anendoreversible Carnot cycle of finite time thermodynamics had been made in this paper.利用基于热电效应的半导体热电堆技术,设计了一个可以模拟实际两源热机工作的实验系统,并对有限时间热力学的内可逆卡诺循环特性做了初步的定量分
4)Endoreversible heat pump cycle内可逆热泵循环
英文短句/例句
1.Finite Time Exergoeconomic Performance Optimization for Universal Steady-Flow Endoreversible Heat Pump Model普适定常流内可逆热泵循环模型的有限时间火用经济性能优化
2.Performance Comparison forEndoreversible Carnot and Brayton Heat Pumps Ⅰ. Steady Flow Cycles with Infinite Reservoirs内可逆卡诺和布雷顿热泵循环性能比较
3.Effects of Heat Resistance and Internal Irreversibility on the Performance of Closed Regenerated Brayton Heat Pump Cycles热阻和内不可逆性对闭式回热式布雷顿热泵循环性能的影响
4.OPerformance Comparison for Endoreversible Carnot and Brayton Heat Pumps (Continued) Ⅱ. Steady Flow Cycles with Finite Reservoirs内可逆卡诺和布雷顿热泵循环性能比较(续)Ⅱ定常态流变温热源循环
5.Power density optimization of an endoreversible brayton cycle coupled to variable-temperature heat reservoirs变温热源内可逆布雷顿循环功率密度优化
6.Efficiency optimization of an endoreversible closed intercooled regenerated Brayton cycle内可逆闭式中冷回热布雷顿循环效率优化
7.Power Optimization of a Closed Brayton Cycle with Endo-reversible Intercooling and Regenerative Heating闭式内可逆中冷回热布雷顿循环的功率优化
8.Power and efficiency characteristic for an endoreversible closed intercooled regenerated Brayton cycle内可逆闭式中冷回热布雷顿循环功率效率特性
9.Power Density Optimization of an Endoreversible Closed Intercooled Regenerated Brayton Cycle Coupled to Variable-temperature Heat Reservoirs变温热源内可逆中冷回热布雷顿循环功率密度优化
10.Power Density Analysis of an Endoreversible Closed Intercooled Regenerated Brayton Cycles Coupled to Constant Temperature Heat Reservoirs恒温热源内可逆中冷回热布雷顿循环功率密度分析
11.Power density analysis of an endoreversible closed intercooled regenerated Brayton cycle coupled to variable-temperature heat reservoirs变温热源内可逆中冷回热布雷顿循环功率密度分析
12.Power and Efficiency of an Endoreversible Closed Intercooling Regenerated Brayton Cycle Coupled to Variable-temperature Heat Reservoirs变温热源内可逆闭式中冷回热布雷顿循环的功率和效率
13.Power optimization of an endo-reversible inter-cooling regeneration Brayton cycle coupled to variable-temperature heat reservoirs变温热源条件下内可逆闭式中冷回热布雷顿循环的功率优化
14.OPTIMAL RELATIONS OF ENDOREVERSIBLE TWO-HEAT-RESERVOIR DIRECT AND INVERSE CYCLES WITH COMPLEX HEAT TRANSFER LAW内可逆正反向两热源循环复杂传热规律下的优化关系
15.Power Density Performance of an Irreversible Brayton Cycle Coupled to Constant-temperature Heat Reservoirs恒温热源条件下内不可逆布雷顿循环的功率密度特性
16.Power Density Performance of Endoreversible Brayton Cycle Coupling to Variable-temperature Heat Reservoirs变温热源条件下内可逆布雷顿循环的功率密度特性
17.An Ecological Optimization of Irreversible Braysson Heat Engine Cycle;不可逆布雷森热机循环的生态学优化
18.The Heat-Work Conversion Analysis of Irreversible Carnot Cycle;不可逆卡诺循环的热功转换特点分析
相关短句/例句
endoreversible heat engine cycle内可逆热机循环
1.Exergoeconomic performance optimization for universal model ofendoreversible heat engine cycles containing 6 heat engine models;包含6种热机模型的普适内可逆热机循环经济性能优化
2.Universal model ofendoreversible heat engine cycle and its finite time exergoeconomic performance optimization;普适内可逆热机循环模型的经济性能优化
3)endoreversible Carnot cycle内可逆卡诺循环
1.By the use of semiconductor thermopile technique based on the pyroelectric effect,a test equipment which can simulate the performances of real two heat soure heat engines was developed, and some quantitative researches on the characteristics of anendoreversible Carnot cycle of finite time thermodynamics had been made in this paper.利用基于热电效应的半导体热电堆技术,设计了一个可以模拟实际两源热机工作的实验系统,并对有限时间热力学的内可逆卡诺循环特性做了初步的定量分
4)Endoreversible heat pump cycle内可逆热泵循环
5)reversible cycle可逆循环
1.It is pointed out that in many textbooks, the derivation of the theorem that the ratio of heat to temperature amounts to zero in anyreversible cycle is insufficiently exact and too excessively brief.关于任一可逆循环热温比之和为零的推导,许多教材上的阐述存在着不够准确和过于简单的问题,本文提出一种比较严格的推导方法。
6)endoreversible Brayton cycle内可逆布雷顿循环
延伸阅读
可逆与不可逆一切客观过程、特别是基本物理化学过程变化的顺序性。前者是指过程的可反演性,后者是指过程的不可反演性。严格的物理学意义上的可逆性是指时间反演,即过程按相反的顺序进行。在经典力学的运动方程中,把时间参量 t换成-t,就意味着过程按相反的顺序历经原来的一切状态,最后回到初始状态。但实际上,机械运动过程总是受到各种复杂的随机因素的作用,因此完全的可逆性是不存在的。严格的物理学意义上的不可逆性概念最初是由经典热力学提出的。它把热的过程区分为可逆的和不可逆的两种,并指出在一个封闭系统的热过程中,热量总是自发地从较热物体传输给较冷物体。热力学第二定律用熵的增加来描述这种不可逆过程。这个定律的统计解释表明,不可逆过程就是封闭的分子系统从有序状态趋向于无序状态。20世纪40年代以来,系统论、控制论等学科的发展表明,任何开放系统即任何现实存在的系统不仅可以增熵,也可以从外界输入负熵而导致减熵。因此,决不能把时间的方向性唯一地同熵增对应起来,因为事实上也存在着熵减的不可逆过程。非平衡态热力学等新兴学科的发展又进一步表明,任何开放系统,包括我们所观察到的宇宙系统,都可以在远离平衡态的条件下形成某种有序的耗散结构(见耗散结构理论),从而阻止或延缓熵增过程。而且,一个非平衡态的开放系统在一定条件下既可能从无序到有序,也可能从有序到混乱。所以,不可逆过程是复杂的,既可以是熵增过程,也可以是熵减过程,即既可以是退化,也可以是进化。自然界发展中的进化和退化是不可逆过程的两种形式。虽然自然界中的不可逆过程是绝对的,但有些过程在一定的条件下却表现出相对的可逆性,因此,人类可以创造条件,利用这种近似的可逆性。
