广义传热规律下的斯特林热机的Z函数优化

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英文篇名：Z-function optimization of Stirling heat engine under generalized heat transfer law 作者：云慧敏 ; 章超明 ; 吴锋 ; 李蒙 ; 殷勇 英文作者：YUN Huimin;ZHANG Chaoming;WU Feng;LI Meng;YIN Yong;School of Optoelectronic Information and Energy Engineering,Wuhan Institute of Technology;School of Mechanical and Electrical Engineering,Wuhan Institute of Technology; 关键词：斯特林热机 ; 广义传热规律 ; Z函数 英文关键词：stirling heat engine;;generalized heat transfer law;;Z-function 中文刊名：HDZK 英文刊名：Journal of Hubei University(Natural Science) 机构：武汉工程大学光电信息与能源工程学院;武汉工程大学机电工程学院; 出版日期：2019-01-05 出版单位：湖北大学学报(自然科学版) 年：2019 期：v.41;No.153 基金：国家自然科学基金(51176143)资助 语种：中文; 页：HDZK201901013 页数：7 CN：01 ISSN：42-1212/N 分类号：72-77+93

摘要

基于广义传热规律Q∝(ΔT)m,建立不可逆斯特林热机模型,并考虑热阻、热漏和回热损失对热机的影响.以Z函数为目标实现功率与效率之间的协调优化,对比研究Z函数与效率、功率与效率,功率与效率的关系曲线,讨论漏热率、回热器效率、回热时间等参数对斯特林热机性能的影响.结果表明:漏热率越小,回热时间越短;回热器效率越大,斯特林机性能越好.
        Based on the generalized heat transfer law Q ∝( ΔT)m,an irreversible Stirling heat engine model was established and the effects of thermal resistance,heat leakage and heat recovery losses on the heat engine were considered. The Z-function is used as the goal to achieve the coordination and optimization between power and exergy efficiency. The relationship between the Z-function and exergy efficiency,power and exergy efficiency,power and efficiency is studied and compared. The influence of parameters such as heat-recovery rate,regenerator efficiency and reheating time on the performance of Stirling heat engine is discussed. In addition,the smaller the heat loss rate,the shorter the regenerative time,and the greater the efficiency of the regenerator,the better the performance of the Stirling machine.

引文

[1]吴锋.斯特林机的有限时间热力学优化[M].北京:化学工业出版社,2008.
    [2]姜昱祥,张营,冯允茹.斯特林热机的可行性分析与展望[J].山东工业技术,2013(15):226-227.
    [3]周雨青.理想斯特林热机循环原理及其效率的计算和实际工作效率的简单讨论[J].物理与工程,2015,25(1):49-52.
    [4]陈丽璇,严子浚.有限时间热力学---现代热力学理论的一个新分支[J].自然杂志,1987(11):27-31.
    [5]叶兴梅,刘静宜.两有限热源间的不可逆斯特林热机的优化性能[J].黑龙江八一农垦大学学报,2009,21(5):76-78.
    [6]Lanzetta F,Vaudrey A,Baucour P.A new method to optimize finite dimensions thermodynamic models:application to an irreversible stirling engine[J].International Journal of Ambient Energy,2018,39(4):392-405.
    [7]Ahmadi M H,Hosseinzade H,Sayyaadi H,et al.Application of the multi-objective optimization method for designing a powered Stirling heat engine:design with maximized power,thermal efficiency and minimized pressure loss[J].Renewable Energy,2013,60(4):313-322.
    [8]李亚奇,何雅玲,王巍巍.碟式集热器驱动斯特林热机系统炯效率分析[J].工程热物理学报,2009,30(6):911-914.
    [9]眭永兴.Q∝(ΔT)n时广义不可逆卡诺热机的生态学性能优化[J].扬州大学学报(自然科学版),2004,7(4):43-46.
    [10]林比宏.一类不可逆斯特林热机的生态学准则优化[J].泉州师范学院学报,1999(4):3-6.
    [11]李亚奇,许行,李海伟,等.不同优化准则下斯特林发动机的性能分析[J].热科学与技术,2011,10(1):63-67.
    [12]贾小权,王海军,李德远,等.具有热阻、热漏和回热损失的不可逆斯特林循环生态学性能系数优化分析研究[J].节能,2011,30(22):60-63.
    [13]Chaitou H,Nika P.Exergetic optimization of a thermoacoustic engine using the particle swarm optimization method[J].Energy Conversion&Management,2012,55(6):71-80.