天津空港经济区蒸汽供热系统规划与节能研究
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摘要
能源是驱动社会发展和经济增长的最基本动力,随着人口增长、经济快速发展以及城市化进程推进,能源需求日益增长,而资源、环境约束也在强化。提高能源利用率,合理利用能源是关系到国民经济发展、建设节约型社会、实施循环经济的重要内容,而且影响到生态环境和人类的生存。
本文通过对经济区采暖负荷和工业生产负荷的统计,我们将冷、热、电用户数量的发展即可假定为泊松过程,通过建立预测模型,对今后用户数量和负荷进行预测。
结合蒸汽锅炉的热平衡测试数据和实际运行数据,然后求出蒸汽管网的输送效率。综合锅炉热效率、蒸汽输送效率和冷凝水回收效率计算出热能生产方式的能源利用效率。然后进行了热电联产的节能分析、热冷联产的节能评估和冷热电三联产的节能预测。
以热电联产系统为研究对象,并确定生命周期评价边界基础上,通过对热电联产项目基础数据的收集和计算公式的计算,建立了系统全生命周期三个阶段清单。在已建立能耗、资源消耗、环境排放清单基础上,将生命周期影响评价扩展到生命周期能耗评价、生命周期资源消耗评价、生命周期环境影响评价、生命周期成本评价,对系统进行全面的分析。最后全面地对该项目进行节能措施及节能效果分析、社会影响分析、主要风险分析。
根据空港经济区蒸汽管网的现状和管网运行的基础数据,建立了空港经济区蒸汽管网拓扑结构,然后建立了管段动量平衡方程、管段质量平衡方程、管段能量平衡方程、节点质量流量方程等。通过计算得到蒸汽管网的输送效率和理论热损失。最后对蒸汽热用户的用汽规律和实际生产运行过程中蒸汽管网损失,提出了降低蒸汽管网热损失的技术方法和管理方法。
将区间线性规划问题及区间解法的理论应用到在所建立的能源规划模型中,对能源供应、能源转化类型及系统能源利用进行了优化,给出了对相关政策的评价,同时分析了能源供应过程中所产生的污染物对环境的影响,提出了对环境治理政策的建议。
Energy is the most fundamental driving force of the social development andeconomic growth. With the population increase, economic develop rapidly andUrbanization Accelerates, the energy needs is growing besides resources andenvironmental constraints strengthening. Both improving energy efficiency andachieving optimal use of resources are imperative contents which are related tonational economic development, building a conservation-oriented society and theimplementation of circular economy, and they can also affect the ecologicalenvironment and human survival.
In this paper, the development of the number of users of cold, hot, and thepower can be assumed to be Poisson process according to the analysis of the heatingload and the load of industrial production statistics of the economic zone. We canpredict the number of users and load in the future through the establishing theprediction model.
With test data of the heat balance of the steam boiler and the actual operatingdata, we can calculate the transmission efficiency of the steam pipe network.Synthesize boiler thermal efficiency, steam distribution efficiency and condensaterecovery efficiency to calculate the energy efficiency of thermal energy productionmethods. And then carried on energy conservation analysis of the cogeneration,energy assessment of Hot cold co-production and energy-saving forecast of coolingheating and power production.
Having determined the boundary of life cycle assessment, through collection ofcogeneration project-based data and calculation of the formulas, we generated a list ofthree phases of full life cycle cogeneration for the Cogeneration system. Based on theestablished list of energy consumption, resource consumption and environmentalemissions, the life cycle impact assessment is extended to the evaluation of life cycleabout energy consumption, resource consumption, environmental impact andcost.That is to say, we then analyze the system completely. Finally comprehensiveanalysis of the energy-saving measures, energy-saving effect, social impact and themain risk about the project is conducted.
According to the profiles of the steam pipe network and the basic data of pipenetwork running in Airport Economic Zone, we built Airport Industrial Park steampipe network topology,
And then established pipe momentum balance equations, pipe quality balanceequations, pipe energy balance equations, node mass flow equations and so on. Thenwe obtained the transmission efficiency and theoretical heat loss of the steam pipenetwork by calculating. Finally, the loss of steam heat steam law and the actualproduction during the operation of the steam pipe network users. we concluded themethods of technology and management to reduce the heat loss of the steam pipenetwork according to the law of the steam consuming of the users and the loss of thesteam pipe network during the operation in actual production.
In this paper, interval number linear programming problem and the intervalsolution theory are applied to energy planning model we created to optimize theenergy supply, energy conversion type and the Department of Energy use. Weappraised related policies besides analyzed the effect of the pollutants generated in theprocess of energy supply on the environment, and then gave some policyrecommendations about environmental governance.
本文通过对经济区采暖负荷和工业生产负荷的统计,我们将冷、热、电用户数量的发展即可假定为泊松过程,通过建立预测模型,对今后用户数量和负荷进行预测。
结合蒸汽锅炉的热平衡测试数据和实际运行数据,然后求出蒸汽管网的输送效率。综合锅炉热效率、蒸汽输送效率和冷凝水回收效率计算出热能生产方式的能源利用效率。然后进行了热电联产的节能分析、热冷联产的节能评估和冷热电三联产的节能预测。
以热电联产系统为研究对象,并确定生命周期评价边界基础上,通过对热电联产项目基础数据的收集和计算公式的计算,建立了系统全生命周期三个阶段清单。在已建立能耗、资源消耗、环境排放清单基础上,将生命周期影响评价扩展到生命周期能耗评价、生命周期资源消耗评价、生命周期环境影响评价、生命周期成本评价,对系统进行全面的分析。最后全面地对该项目进行节能措施及节能效果分析、社会影响分析、主要风险分析。
根据空港经济区蒸汽管网的现状和管网运行的基础数据,建立了空港经济区蒸汽管网拓扑结构,然后建立了管段动量平衡方程、管段质量平衡方程、管段能量平衡方程、节点质量流量方程等。通过计算得到蒸汽管网的输送效率和理论热损失。最后对蒸汽热用户的用汽规律和实际生产运行过程中蒸汽管网损失,提出了降低蒸汽管网热损失的技术方法和管理方法。
将区间线性规划问题及区间解法的理论应用到在所建立的能源规划模型中,对能源供应、能源转化类型及系统能源利用进行了优化,给出了对相关政策的评价,同时分析了能源供应过程中所产生的污染物对环境的影响,提出了对环境治理政策的建议。
Energy is the most fundamental driving force of the social development andeconomic growth. With the population increase, economic develop rapidly andUrbanization Accelerates, the energy needs is growing besides resources andenvironmental constraints strengthening. Both improving energy efficiency andachieving optimal use of resources are imperative contents which are related tonational economic development, building a conservation-oriented society and theimplementation of circular economy, and they can also affect the ecologicalenvironment and human survival.
In this paper, the development of the number of users of cold, hot, and thepower can be assumed to be Poisson process according to the analysis of the heatingload and the load of industrial production statistics of the economic zone. We canpredict the number of users and load in the future through the establishing theprediction model.
With test data of the heat balance of the steam boiler and the actual operatingdata, we can calculate the transmission efficiency of the steam pipe network.Synthesize boiler thermal efficiency, steam distribution efficiency and condensaterecovery efficiency to calculate the energy efficiency of thermal energy productionmethods. And then carried on energy conservation analysis of the cogeneration,energy assessment of Hot cold co-production and energy-saving forecast of coolingheating and power production.
Having determined the boundary of life cycle assessment, through collection ofcogeneration project-based data and calculation of the formulas, we generated a list ofthree phases of full life cycle cogeneration for the Cogeneration system. Based on theestablished list of energy consumption, resource consumption and environmentalemissions, the life cycle impact assessment is extended to the evaluation of life cycleabout energy consumption, resource consumption, environmental impact andcost.That is to say, we then analyze the system completely. Finally comprehensiveanalysis of the energy-saving measures, energy-saving effect, social impact and themain risk about the project is conducted.
According to the profiles of the steam pipe network and the basic data of pipenetwork running in Airport Economic Zone, we built Airport Industrial Park steampipe network topology,
And then established pipe momentum balance equations, pipe quality balanceequations, pipe energy balance equations, node mass flow equations and so on. Thenwe obtained the transmission efficiency and theoretical heat loss of the steam pipenetwork by calculating. Finally, the loss of steam heat steam law and the actualproduction during the operation of the steam pipe network users. we concluded themethods of technology and management to reduce the heat loss of the steam pipenetwork according to the law of the steam consuming of the users and the loss of thesteam pipe network during the operation in actual production.
In this paper, interval number linear programming problem and the intervalsolution theory are applied to energy planning model we created to optimize theenergy supply, energy conversion type and the Department of Energy use. Weappraised related policies besides analyzed the effect of the pollutants generated in theprocess of energy supply on the environment, and then gave some policyrecommendations about environmental governance.
引文
[1]李崇祥.节能原理与技术[M].西安:西安交通大学出版社,2004,3.
[2]李荫堂.环境保护与节能[M].西安:西安交通大学出版社,2000.
[3]宋徐辉.我国蒸汽系统现状及节能潜力[J].节能与环保,2007,(1):52~54.
[4]卢二坡.中国能源需求预测模型研究,统计与决策,2005,10:1~2.
[5] D.梅多斯等.增长的极限.北京:商务印书馆,1984.
[6]苏泽雄.中国能源需求建模与实证研究[D].福州:福州大学,2002.
[7]于立.能源价格理论研究.辽宁:东北财经大学出版社,1994.
[8] Jorgenson, Dale and Barbara Fraumeni, Relative Prices and Technology changein Modeling and Measuring Natural Resource Substitution. Cambridge, MA:MITPress,1981.
[9] Griffin and Gregory,An Intercountry Translog Model of Energy SubstitutionResponses, American Economics Review, Vol.66,1976,845-857.
[10]ProsserR.D, Demand Elasticity in OECD: Dynamical Aspects. EnergyEconomics January,1985,9-12.
[11]Noel D.Uri. A Note On Energy Demand Estimation. International Journal ofEnergy Research, Vol.17, No.8,1993,747-758.
[12]McFadden, D. and Jeffrey Dubin, Econometric Analysis of Residential ElectricAppliance Holdings and Consumption. Econometrics, Vol.52,1984.
[13]Pindyck, Robert,Gains to Producers from the Certelization of ExhaustibleResources, Review of Economics and Statistics, Vol.60,1978:238-251.
[14]张勇卫.中国能源需求预测及发展战略研究[D],武汉:武汉理工大学,2006.
[15]迟春洁.基于LEAP模型的中国未来能源发展前景研究[J].技术经济与管理研究,2004,5.
[16]Society of environmental toxicology and chemistry (SETAC). Guidelines for lifecycle assessment: A code of p ractice [M]. Brussels: SETAC Europe,1993.
[17]International standard organization. ISO14040-1997environmental managementlife cycle assessment principles and framework[S].
[18]Boustead I; Hancock. G.Handbook of industrial energy analysis [M]. New GillsYork:Harvard,1979.
[19]Steen S; Ryding O.The EPS environ-accounting method[R]. SwedishEnvironmental Research Institute,1992.
[20]杨建新,王如松.生命周期评估的回顾与展望[J].环境科学进展,1998,6(2):21-28.
[21]孙启宏,万年青,范与华.国外生命周期评价(LCA)研究综述[J].世界标准化与质量管理,2000,12:24-26.
[22]Spath PL, Mann MK, Kerr DR. Life cycle assessment of coal-fired powerproduction. National Renewable Energy Laboratory[R], US Department ofEnergy Laboratory,1999.
[23]Cottrell. A, Nunn. J, Urfer. A,et al.Systems assessment of electricity generationusing biomassand coal inCFBC[R]. Australian: BHP Billiton NewcastleTechnology Centre,2003.
[24]Arpad H, Eric M. An Analysis of Measures to Reduce the Life-Cycle EnergyConsumption and Greenhouse Gas Emissions of California’s PersonalComputers[R].UC Energy Institute2547Channing Way Berkeley, California94720-5180,2007.
[25]杨建新,徐成,王如松.产品生命周期评价方法及应用[M].北京:气象出版社,2002.
[26]Pauli M;Raimo P. How to benefit from decision analysis in environmental lifecycle assessment (LCA)[J].Operational Research.1997,102(2):279-294.
[27]S. Ong, T. Koh, A. Nee. Development of a semi-quantitative pre-LCA tool [J].Materials Processing Technology.1999,89:574-582.
[28]Schleisner L. Life cycle assessment of a wind farm and related externalities [J].Renewable Energy.2000,20(3):279-288.
[29]Stig I; Frans M. Life cycle impact assessment and risk assessment ofchemicals a methodological comparison [J].Environmental Impact AssessmentReview.2001,21(4):385-404.
[30]Martin E; Mathias B.Generic LCA methodology applicable for buildings,constructions and operation services today practice and development needs [J].Building and Environment.2003,38(7):919-938.
[31]Matteo C;Andrea C.Life cycle assessment of an integrated biomass gasificationcombined cycle (IBGCC) with CO2removal [J]. Energy Conversion andManagement.2005,46(11):1790-1808.
[32]Francois V; Emmanuelle A, et al. LCA tool for the environmental evaluation ofpotable water production [J]. Desalination.2008,220(1):37-56.
[33]Francesco C; Silvia B, et al. Life cycle assessment of waste managementstrategies:Landfilling, sorting plant and incineration [J].Energy.2009,34(12):2116-2123.
[34]冷如波.产品生命周期3E+S评价与决策分析方法研究[D].上海:上海交通大学,2007.
[35]汪劲松,段广洪,李方义,等.基于产品生命周期的绿色制造技术研究现状与展望[J].计算机集成制造系统,1999,5(4):1-8.
[36]刘飞,曹华军.绿色制造的理论体系框架[J].中国机械工程,2000,11(9):961-964.
[37]黄志甲,张旭.汽车燃料的生命周期评价模型[J].同济大学学报,2003,31(12):1472-1476.
[38]刘光复,刘志峰,李钢.绿色设计与绿色制造[M].北京:机械工业出版社,1999.
[39]曾建春,蔡建国.面向产品生命周期的环境、成本和性能多指标评价[J].中国机械工程,2000,11(9):975-978.
[40]胡志远,张成,浦耿强,等.木薯乙醇汽油生命周期能源、环境及经济性评价[J].内燃机工程,2004,25(1):13-16.
[41]邹治平,马晓茜.风力发电的生命周期分析[J].中国电力,2003,36(9):83-87.
[42]蒋金良,马晓茜.基于生命周期评价的不同电源对环境影响的比较[J].电站系统工程,2004,20(3):26-28.
[43]任玉珑,阳忠明,韩维健,等.低谷电电解制氢的生命周期3E评价[J].工业工程与管理,2006,4:79-82.
[44]林琳,赵黛青,李莉.基于生命周期评价的生物质发电系统环境影响分析[J].太阳能学报,2008,29(5):618-623.
[45]冯超,马晓茜.秸秆直燃发电的生命周期评价[J].太阳能学报,2008,29(6):711-715.
[46]陈胜震,陈铭.中国清洁能源汽车全生命周期的3E分析与评论[J].汽车工程.2008,30(6):465-522.
[47]刘敬尧,钱宇,李秀喜.燃煤及其替代发电方案的生命周期评价[J].煤炭学报,2009,34(1):133-138.
[48]Bujakowski W,Barbacki A.Potential for geothermal development in southernPoland[J].Geothermics,2004,33(3):383~395.
[49]Sahlin J,Knutsson D,Ekvall T.Effects of planned expansion of wasteincineration in the Swedish district heating systems[J].Resources Conservationand Recycling,2004,41(4):279~292.
[50]Silveira JL,Tuna CE.Thermoeconomic analysis method for optimization ofcombined heat and power systems partⅠ[J].Progress in Energy andCombustion Science,2003,29(6):479~485.
[51]Holmgren K, Gebremedhin A.Modelling a district heating system:introductionof waste incineration policy instruments and co-operation with anindustry[J].Energy Policy,2004,32(16):1807~1817.
[52]Bourgeois TG,Hedman B,Zalcman F.Creating markets for combined heat andpower and clean distributed generation in New York State[J].EnvironmentallyPollution,2003,123(3):451~462.
[53]王东.城市蒸汽采暖系统热力与水利计算的研究[D].山东:山东建筑大学,2007.
[54]刘发启.关于城市集中供热的住宅建筑节能措施研究[J].经济技术协作信息,2009,(29):99-99.
[55]宋徐辉.我国蒸汽系统现状及节能潜力[J].节能与环保,2007,(1):52~54.
[56]刘剑.城市集中供热系统优化研究[D].大连:大连理工大学,2006.
[57]Michael A.Stubblefield,Su-Seng Pang,Vic A.Cundy.Heat loss in insulatedpipe-the influence of thermal contact resistance:a case study,Composites PartB[J].Engineering,1996,27(1):85~93.
[58]刘笑驰,蔡瑞忠,吕崇德.大型蒸汽管网的在线仿真研究[J].系统仿真学报,2002,14(3):397~402.
[59]Atli benonysson,Benny Bohm,Hans F.RANN.Operational optimization in a districtheating system[J].Energy Conversion and Management,1995,36(5):297~314.
[60]The International Association for the Properties of Water and Steam. Release onthe IAPWS Industrial Formulation1997for the Thermodynamic Properties ofWater and Steam[M]. Erl-angen, Germany,1997;
[61]S.P.Mavromatisl, A.C. Kokossis. A logic based model for the analysis andoptimisation of steam turbine networks[J]. Computers in Industry,1998,36:165~179;
[62]Sylvie Lorente, Wishsanuruk Wechsatol, Adrian Bejan. Fundamentals oftree-shaped networks of insulated pipes for hot water and exergy. Exergy, anInternational Journal,2002,2:227~236;
[63]Tian Zhiguang, Meng Xianyao, Zhang Huifen. Design and Realization onDistributed Network System for On-Line Monitoring and Fault Diagnosis in theSteam Turbine Generator Sets [C]. International Conference on ElectronicMeasurement&Instruments(ICEMI'2005) vol.4;
[64]A. Morris, J. Dear, M. Kourmpetis. High Temperature Steam Pipelines-Development of the ARCMAC Creep Monitoring System[J]. Strain,2006,42(3):181~186;
[65]Tveit, TM Fogelholm, CJ. Multi-period steam turbine network optimisation. PartII: Development of a multi-period MINLP model of a utility system[J]. AppliedThermal Engineering,2006,26(15):1730~1736;
[66]V. Rudzinskas, A. V. Valiulis, O. Chernashejus. Operation Reliability of BentElbows of Steam Pipelines[J]. Diffusion and Defect Data. Part B, Solid StateData, Solid State Phenomena,2006,113(3):577~582;
[67]Young-Jong Chung, Soo-Hyong Yang, Hee-Cheol Kim, Sung-Quun Zee.Thermal hydraulic calculation in a passive residual heat removal system of theSMART-P plant for forced and natural convection conditions [J]. NuclearEngineering and Design,2004,232(3):277~288.
[68]Jiang Shizhang,,Yong Qiwei, Jiang Ming, Chen Ming. Experimental Researchand Universal Hydraulic Calculation of Pipe Flow[C]. Asian InternationalConference on Fluid Machinery,2005,8th:957~963;
[69]Helge V. Larsen,Benny Bohm,Michael Wigbels.A comparison of aggregatedmodels for simulation and operational optimisation of districtheating networks[J].Energy Conversion and Management,2004,45(7-8):1119~1139.
[70]Dag Henning,Shahnaz Amiri,Kristina Holmgren.Modelling and optimisation ofelectricity,steam and district heating production for a localSwedish utility[J].European Journal of Operationa Research,2006,175(2):1224~1247.
[71]Irina Gabrielaitiene,Benny Bohm,Bengt Sunden.Modelling temperaturedynamics of a district heating system in Naestved,Denmark-A case Energystudy[J].Conversion and Management,2007,48(1):78~86.
[72]吕泽华,黄志明.蒸汽管道的传递函数及工程应用[J].清华大学学报(自然科学版),1997,37(2):103~107.
[73]赵钦,王志勤,史挺进等.大型蒸汽管网仿真的数学模型研究[J],热能动力工程,1997,12(3):173~175.
[74]李世武.蒸汽管网运行工况模拟计算方法[J].煤气与热力,2001,21(6):552~556.
[75]姜永顺.蒸汽供热管道沿程阻力损失简易计算法[J].暖通空调,2000,30(5):77~79.
[76]姜永顺.蒸汽供热管道局部压力损失计算[J].暖通空调,2003,33(1):73~74.
[77]宋扬,程芳真,蔡瑞忠等.蒸汽供热管道的动态仿真建模[J].清华大学学报,2001,41(10):101~104.
[78]刘笑驰,蔡瑞忠,吕崇德.大型蒸汽管网的在线仿真研究[J].系统仿真学报,2002,14(3):397~402.
[79]刘金平,华贲.考虑蒸汽密度变化的长距离供热蒸汽管道的优化设计[J].中国电机学报,2003,23(1):150~154.
[80]刘金平,华贲,陈志勤.石化企业蒸汽管线的优化设计[J].华南理工大学学报,1997,12:22~27.
[81]李友荣,无双.供热蒸汽管道及其保温层的同步设计法[J].中国电机学报,2003,23(1):150~154.
[82]D.Hennin,5.Arniri,K.Holmgren.ModellingandoPtimisationofeleetrieity,steam anddistrict heating Production for a local Swedish utility[J].EuroPean Journal ofOperational Researeh,2006,175:1224-1247.
[83]S.Iniyan,L.Suganthi and T.R.Jagadeesan.Renewable energy Planning for India in21st century[J].Renewable Energy,1998,14:453-457.
[84]Lehtila A.,PirilaP.Reducing energy related emissions:using an energy systemsOptimization model to support Poliey Planning in Finland[J].Energy Poliey,1996,24:805-819.
[85]G.H.Huang,B.W.Baetz,G.G.party. Trash flow allocation: planning underuncertainly[J].Interfaces,1998,28:36-35.
[86]L.Liu.Development of environmental modeling methodologies for themanagement of regional and industrial pollution control systems
[D].Ph.D.Dissertation,UniversityofRegina,Regina,Saskatchewan,Canada,2001.
[87]Y.P.Li,G.H.Huang,S.L.Nie and X.S.Qin.ITCLP:An inexact two-stage chance-Constrained program for planning waste management systems[J].Resources,Coservation and Recycling,2007,48:284-307.
[88]M.Sadeghi,H.M.Hosseini.Energy supply planning in Iran by using fuzzy linearProgramming approach:regading uncertainties of investment costs[J].EnergyPolicy,2006,34:993-1003.
[89]E.Muela,G.Schweickardt,F.Garces.Fuzzy possibilistic model for medium-termPower generation planning with environmental criteria[J].Energy Policy,2007,35:5643-5655.
[90]Q.G.Lin,G.H.Huang.IPEM;An Tnterval-parameter Energy System PlanningModel[J].Energy Sources,PartA:Recovery,Utilization,and Environmental Effects,2008,30:1382-1399.
[91]咚庆,白泉,刘滨,吕应运.MARKAL模型在北京中远期能源发展研究中的应用[J].中国能源,2004,26(6):36-40.
[92]陈荣,张希良,何建坤,岳立.基于MESSAGE模型的省级可再生能源规划方法[J].清华大学学报(自然科学版),2008,48(9):1525-1528.
[93]刘贞,张希良,高虎,于智为等.区域可再生能源规划基本框架研究[J].中国能源,2010(2):38-41.
[94]李彩,黄国和,蔡宴朋.能源供需优化模型在北京市能源系统的应用.能源工程,2009(4):1-5.
[95]杨静.关于生态城区域建筑能源规划模式的初步研究[D].哈尔滨:哈尔滨工业大学,2010.
[96]牛彦涛.不确定城市能源系统规划模型研究及应用[D].北京:华北电力大学,2011.
[97]陈新华.能源改变命运[M].北京:新华出版社,2008.
[98]谷长利.基于MCS-51单片机的热计量[D].北京:华北电力大学,2006.
[99]中节蓝天投资咨询管理有限责任公司.天津空港加工区475t/h锅炉房热电联产发电改造项目可行性研究报告[R].北京,2009.
[100]南开大学数学科学学院.天保热电营业成本预测报告[R].天津,2009.
[101]张红玉.天津空港加工区蒸汽管网仿真[D].天津:天津大学,2010
[102]天津市发展和改革委员会.天津市临空产业区供热规划(2007-2020年)[R].天津,2007.
[103]王凤雨.随机过程[M].北京:北京师范大学出版社,2009.
[104]魏艳华,王丙参,宋立新.复合泊松过程性质及其应用[J].宜宾学院学报,2009,9(12):45-48.
[105]孙天晴.基于复合泊松过程战略石油储备天数的概率模型及其应用[J].数理统计与管理,2007,26(5):12-14.
[106]蒲俊,吉家锋.Matlab工程数学解题指导[M].上海:浦东电子出版社,2001.
[107]贺平,孙刚.供热工程[M].北京:中国建筑工业出版社,1993,第三版.
[108]法利咨询(上海)有限公司.能源状况评估报告[R].上海,2009.
[109]于建国.浅论以热定电.化工技术经济[J].1998vol.16(6):14-16.
[110]中华人民共和国国务院.中华人民共和国节约能源法[S].北京,1998.
[111]陈光明,夏中明.一个新型的吸收制冷循环研究[J].制冷学报,1996(3):26-36.
[112]吴进发.溴化锂吸收制冷的发展和应用[J].工厂动力,1993(1):4-14.
[113]周贵斌,刘志清,段永红,邓宝军.高效蒸汽型溴化锂吸收式制冷机组的研究[J].制冷与空调,2007vol.7(5):13-16.
[114]冯俊凯,沈幼庭,杨瑞昌.锅炉原理及计算[M].北京:科学出版社,2003.
[115]周亮亮.清洁燃煤发电技术全生命周期评价[D].重庆:重庆大学,2011.
[116]Hammers R. Ethanol’s energy retum on investment: A survey of the literature1990[J].Environmental Seienee&Teehoology,2006,40(6):1744-1750.
[117]Jean F, Sylvain L,et al. Estimation of the environmental impact of apetrochemical process using coupled LCA and exergy analysis [J]. Resources,Conservation and Recycling,2010,54(5):291-298.
[118]郑彬,赵绪新,马晓茜等.生命周期评价方法及其应用[J].中国资源综合利用,2004,3:9-12.
[119]Krozer J,Vis C.How to get LCA in the right direction [J]. Cleaner Production,1998.6(1):53-61.
[120]惠世恩,庄正宁,周屈兰,等.煤的清洁利用与污染防治[M].北京:中国电力出版社,2008.
[121]岳光溪.循环流化床技术发展与应用[J].研究与探讨,2003,(12):3-4.
[122]俞珠峰.洁净煤技术发展及应用[M].北京:化学工业出版社,2004.
[123]Hiroki H.Life cycle GHG emission analysis of power generation systems:Japanese case [J].Energy,2005,30:2042-2056.
[124]中华人民共和国国家统计局.中国统计年鉴2008[M].北京:中国统计出版社,2009.
[125]刘顺妮,林宗寿,张小伟.硅酸盐水泥的生命周期评价方法初探[J].中国环境科学,1998,18(4):328-332.
[126]Spath PL, Mann MK, Kerr DR. Life cycle assessment of coal-fired powerproduction. National Renewable Energy Laboratory[R], US Department ofEnergy Laboratory,1999.
[127]Cottrell.A,Nunn. J,Urfer. A,et al.Systems assessment of electricity generationusing biomass and coal in CFBC[R].Australian: BHP Billiton NewcastleTechnology Centre,2003.
[128]Dones R,Gantner U,Hirschberg S.Environmental inventories for futureelectricity supply systems for Switzerland[R]. Switzerland: Paul ScherrerInstitute,1996.
[129]Daniele F, Lidia L. Integrated gasifier combined cycle plant with integratedCO2-H2S removal: performance analysis, lifecycle assessment and exergetic lifecycle assessment[J]. Applied Thermodynamics,2002,5(1):13-24.
[130]李君,吴少华,李振中.超超临界燃煤发电技术是我国目前发展洁净煤发电技术的优先选择[J].中国电力,2004,37(9):13-17.
[131]袁宝荣,聂祚仁,狄向华,等.中国化石能源生产的生命周期清单(1)-能源消耗与直接排放[J].现代化工,2006,26(3):59-64.
[132]国家统计局、国家环境保护总局编.中国环境统计年鉴2006[M].中国统计出版社,2007.
[133]吕伟业,汤蕴琳,方正.中国火电结构优化和技术升级研究概论[J].电力建设,2002,23(11):9-22.
[134]王大中.21世纪中国能源科技发展展望[M].北京:清华大学出版社,2007.
[135]R.Kannan,C.P.Tso, et al. LCA-LCCA of oil fired steam turbine power plant inSingapore[J].Energy Conversion and Management,2004,(45):3093-3107.
[136]电力规划设计总院编.火电工程限额设计参考造价指标[M].北京:中国电力出版社,2007.
[137]Luc G,Camille B,Yohji U.Life-cycle assessment of electricity generationoptions:the status of research in year2001[J]. Energy Policy,2002,30(14):1267-1278.
[138]Zhihui Z, Xing W, Xiaomin Y, et al. BEPAS a life cycle buildingenvironmental performance assessment model[J]. Building and environment,2006,41(5):669-675.
[139]Francesco Di Maria. Design and off design pipe network geothermal powerplant analysis with power pipe simulator [J].Energy Conversion andManagement,2000,41(12):1223~1225.
[140]李世武.蒸汽管网运行工况模拟计算方法[J].煤气与热力,2001,6(21):552~556.
[141]付祥钊.流体输配管网[M].北京:中国建筑工业出版社,2005.
[142]C.A.博布罗夫斯基等.天然气管路输送(陈祖泽)[M].北京:中国建筑工业出版社,1996.
[143]Ryszard A. Bialecki,Tadeusz Kruczek. Frictional,diathermal flow of steam in apipeline[J]. Chemical Engineering science,1996,51(19):4369~4378.
[144]高鲁峰.蒸汽管网水力热力耦合计算方法的研究及软件开发[D].山东:山东建筑大学,2009.
[145]段常贵.燃气输配(第三版)[M].北京:中国建筑工业出版社,2001.
[146]段常贵等.燃气输配[M].北京:中国建筑出版社,2001.
[147]张昌煜.工业蒸汽的有效利用[M].上海:上海科学技术出版社,1984.
[148]李世武.蒸汽管网运行工况模拟计算方法[J].煤气与热力,2001,21(6):552~556.
[149]刘笑驰,蔡瑞忠,吕崇德.大型蒸汽管网的在线仿真研究[J].系统仿真学报,2002,14(3):397~402.
[150]Michael A.Stubblefield,Su-Seng Pang,Vic A.Cundy.Heat loss in insulatedpipe-the influence of thermal contact resistance:a case study,Composites PartB[J].Engineering,1996,27(1):85~93.
[151]邹平华.借鉴俄罗斯经验积极发展我国集中供热事业[J].暖通空调,2000,30(4):33~37.
[152]杨冶金.丹麦的集中供热[J].区域供热,2000,1(6):27~30.
[153]J.R.威尔特,C.E.威尔斯,R.E.威尔逊等.动量,热量和质量传递原理第四版(马紫峰,吴卫生)[M].北京:化学工业出版社,2005.
[154]陆耀庆.实用供热空调设计手册[M].北京:中国建筑工业出版社,2007.
[155]杨世铭,陶文铨.传热学(第四版)[M].北京:高等教育出版社,2006.
[156]安娜-玛丽娅比安什,伊夫福泰勒,雅克琳娜埃黛.传热学(王晓东)[M].大连:大连理工大学出版社,2008.
[157]宋永军,吕君.蒸汽直埋复合保温管的热工计算[J].电站系统工程,2003,19(3):21~22.
[158]G.H.Huang,R.D.Moore.Grey linear programming,its solving approach,and itsapplication[J].International Journal of Systems Science,1993,24:159-172.
[159]J.M.Wanger,U,Shamir and D.H.Marks,Containing groundwatercontamination:Planning models using stochastic programming withrecourse[J].European Journal of Operational Research,1994,77:1-26.
[160]S.O.Russell,P.F.Campbell.Reservoir operating rules with fuzzyprogramming[J].Journal of Water Resources Planning andManagement,1997,123:312-321.
[161]N.B.Chang and W.C.Chen.Fuzzy controller design for municipal incineratorswith the aid of genetic algorithms and genetic programming techniques[J].WasteManagement&Research,ISWA,2000,18:429-443.
[162]A.Haurie and F.Moresino.A stochastic programming approach to manufacturingflow control [J].HE Transactions,2000,32:907-920.
[163]H.C.Guo,L.Liu,G.H.Huang,R.Zao and Y.Y.Yin.A system dynamics approach forregional environmental planning and management:A study for the Lake ErhaiBasin[J].Journal of Environmental Management,2001,61:93-112.
[164]G.H.Huang.Grey mathematical programming and its application to municipalsolid waste management planning[D].PH.D.Dissertation,Department of CivilEngineering,McMaster University,Ontario,Canada,1994.
[165]D.P.Loucks,J.R.Stedinger,D.A.Haith.Water.resource.systems.planning.and.analysis[M].Homewood Cliffs,N.J.,USA:Prentice-Hall.,1981.
[166]F.S.Budnick,D.Mcleavey,R.Mojena.Principles of Operations Research forMangement[M].Homewood,Illinois,USA:Richard D.Irwin,Inc.,1988.
[167]L.Liu.Development of environmental modeling methodologies for themanagement of regional and industrial pollution contral systems[D]. PH.D.Dissertation,University of Regina,Saskatchewan,Canada,2011.
[168]S.Sen.Sub gradient decomposition and differentiability of the recourse functionof a two stage stochastic linear program[J].Operations Research Letters,1993,13:143-148.
[169]S.Sen and J.L.Higle.An introductory tutorial on stochastic linear programmingmodels[J].Interfaces,1999,29:33-61.
[170]Y.Yoshitomi,H.Ikenoue,T.Takeba and S.Tomita.Genetic algorithm in uncertainenvironments for solving stochastic programming problem[J].Journal of theOperations Reacharch Society of Japan,2000,43:266-290.
[171]R.Slowinski,J.Teghem.Stochastic versus fuzzy approaches to multiobjectivemathematical programming underuncertainty [M]. Inuiguchi,M.,Ichihashi,H.I.,Tanaka,H. Fuzzy programming:a sury of recent development. Norwell,Massachusetts,USA:Kluwer Academic Publishers.
[172]G.H.Huang,B.W.Baetz and G.G.Patry.Grey dynamic programming forwaste-management planning under uncertainty[J].Journal of Urban Planning andDevelopment,1994,120:132-156.
[173]G.H.Huang.A hybrid inexact-stochastic water management model[J].EuropeanJournal of Operational Research,1998,107:137-158.
[174]G.H.Huang.IPWM:An interval parameter water quality managementmode[J].Engineering Operational Research,1996,26:79-103.
[175]I.Maqsood,G.H.Huang,J.S.Yeomans.An interval-parameter fuzzy two-stagestochastic program for water resources management underuncertainty[J].European Journal of Operational Research,2005,167:208-225.
[176]Y.P.Li.G.H.Huang.Interval-parameter two-stage stochsstic nonlinearprogramming for water resources management under uncertainty[J].WaterResources Management,2008,22:681-698.
[177]G.H.Huang,B.W.Baetz,G.G.Party.Grey integer programming:an application towaste management planning under uncertainty[J].European Journal ofOperational Research,1995,83:594-620.
[178]G.H.Huang,B.W.Baetz,G.G.Patry and V.Terluk.Capacity planning for anintegrated waste management system under uncertainty:a North American casestudy[J].Waste Management&Research,1997,15:523-546.
[179]Q.G.Lin,G.H.Huang.IPEM:An Interval-parameter Energy Systems PlanningModel[J].Energy Sources,Part A:Recovery,Utilization,and EnvironmentalEffects,2008,30:1382-1399.
[180]G.H.Huang.B.W.Baetz,G.G.Patry.A grey linear programming approach formunicipal solid waste management planning under uncertainty[J].CivilEngineering Systems,1992,9:319-335.
[181]S.Tong.Interval number and fuzzy number linear programming[J].Fuzzy Setsand Systems,1994,66:301-306.
[182]达庆利,刘新旺.区间数线性规划及其满意解[J].系统工程理论与实践,1999,19(4):3-7.
[183]王志文,蔡文彬.改善天津市大气环境质量的研究[J].城市环境与城市生态,2002,02.
[2]李荫堂.环境保护与节能[M].西安:西安交通大学出版社,2000.
[3]宋徐辉.我国蒸汽系统现状及节能潜力[J].节能与环保,2007,(1):52~54.
[4]卢二坡.中国能源需求预测模型研究,统计与决策,2005,10:1~2.
[5] D.梅多斯等.增长的极限.北京:商务印书馆,1984.
[6]苏泽雄.中国能源需求建模与实证研究[D].福州:福州大学,2002.
[7]于立.能源价格理论研究.辽宁:东北财经大学出版社,1994.
[8] Jorgenson, Dale and Barbara Fraumeni, Relative Prices and Technology changein Modeling and Measuring Natural Resource Substitution. Cambridge, MA:MITPress,1981.
[9] Griffin and Gregory,An Intercountry Translog Model of Energy SubstitutionResponses, American Economics Review, Vol.66,1976,845-857.
[10]ProsserR.D, Demand Elasticity in OECD: Dynamical Aspects. EnergyEconomics January,1985,9-12.
[11]Noel D.Uri. A Note On Energy Demand Estimation. International Journal ofEnergy Research, Vol.17, No.8,1993,747-758.
[12]McFadden, D. and Jeffrey Dubin, Econometric Analysis of Residential ElectricAppliance Holdings and Consumption. Econometrics, Vol.52,1984.
[13]Pindyck, Robert,Gains to Producers from the Certelization of ExhaustibleResources, Review of Economics and Statistics, Vol.60,1978:238-251.
[14]张勇卫.中国能源需求预测及发展战略研究[D],武汉:武汉理工大学,2006.
[15]迟春洁.基于LEAP模型的中国未来能源发展前景研究[J].技术经济与管理研究,2004,5.
[16]Society of environmental toxicology and chemistry (SETAC). Guidelines for lifecycle assessment: A code of p ractice [M]. Brussels: SETAC Europe,1993.
[17]International standard organization. ISO14040-1997environmental managementlife cycle assessment principles and framework[S].
[18]Boustead I; Hancock. G.Handbook of industrial energy analysis [M]. New GillsYork:Harvard,1979.
[19]Steen S; Ryding O.The EPS environ-accounting method[R]. SwedishEnvironmental Research Institute,1992.
[20]杨建新,王如松.生命周期评估的回顾与展望[J].环境科学进展,1998,6(2):21-28.
[21]孙启宏,万年青,范与华.国外生命周期评价(LCA)研究综述[J].世界标准化与质量管理,2000,12:24-26.
[22]Spath PL, Mann MK, Kerr DR. Life cycle assessment of coal-fired powerproduction. National Renewable Energy Laboratory[R], US Department ofEnergy Laboratory,1999.
[23]Cottrell. A, Nunn. J, Urfer. A,et al.Systems assessment of electricity generationusing biomassand coal inCFBC[R]. Australian: BHP Billiton NewcastleTechnology Centre,2003.
[24]Arpad H, Eric M. An Analysis of Measures to Reduce the Life-Cycle EnergyConsumption and Greenhouse Gas Emissions of California’s PersonalComputers[R].UC Energy Institute2547Channing Way Berkeley, California94720-5180,2007.
[25]杨建新,徐成,王如松.产品生命周期评价方法及应用[M].北京:气象出版社,2002.
[26]Pauli M;Raimo P. How to benefit from decision analysis in environmental lifecycle assessment (LCA)[J].Operational Research.1997,102(2):279-294.
[27]S. Ong, T. Koh, A. Nee. Development of a semi-quantitative pre-LCA tool [J].Materials Processing Technology.1999,89:574-582.
[28]Schleisner L. Life cycle assessment of a wind farm and related externalities [J].Renewable Energy.2000,20(3):279-288.
[29]Stig I; Frans M. Life cycle impact assessment and risk assessment ofchemicals a methodological comparison [J].Environmental Impact AssessmentReview.2001,21(4):385-404.
[30]Martin E; Mathias B.Generic LCA methodology applicable for buildings,constructions and operation services today practice and development needs [J].Building and Environment.2003,38(7):919-938.
[31]Matteo C;Andrea C.Life cycle assessment of an integrated biomass gasificationcombined cycle (IBGCC) with CO2removal [J]. Energy Conversion andManagement.2005,46(11):1790-1808.
[32]Francois V; Emmanuelle A, et al. LCA tool for the environmental evaluation ofpotable water production [J]. Desalination.2008,220(1):37-56.
[33]Francesco C; Silvia B, et al. Life cycle assessment of waste managementstrategies:Landfilling, sorting plant and incineration [J].Energy.2009,34(12):2116-2123.
[34]冷如波.产品生命周期3E+S评价与决策分析方法研究[D].上海:上海交通大学,2007.
[35]汪劲松,段广洪,李方义,等.基于产品生命周期的绿色制造技术研究现状与展望[J].计算机集成制造系统,1999,5(4):1-8.
[36]刘飞,曹华军.绿色制造的理论体系框架[J].中国机械工程,2000,11(9):961-964.
[37]黄志甲,张旭.汽车燃料的生命周期评价模型[J].同济大学学报,2003,31(12):1472-1476.
[38]刘光复,刘志峰,李钢.绿色设计与绿色制造[M].北京:机械工业出版社,1999.
[39]曾建春,蔡建国.面向产品生命周期的环境、成本和性能多指标评价[J].中国机械工程,2000,11(9):975-978.
[40]胡志远,张成,浦耿强,等.木薯乙醇汽油生命周期能源、环境及经济性评价[J].内燃机工程,2004,25(1):13-16.
[41]邹治平,马晓茜.风力发电的生命周期分析[J].中国电力,2003,36(9):83-87.
[42]蒋金良,马晓茜.基于生命周期评价的不同电源对环境影响的比较[J].电站系统工程,2004,20(3):26-28.
[43]任玉珑,阳忠明,韩维健,等.低谷电电解制氢的生命周期3E评价[J].工业工程与管理,2006,4:79-82.
[44]林琳,赵黛青,李莉.基于生命周期评价的生物质发电系统环境影响分析[J].太阳能学报,2008,29(5):618-623.
[45]冯超,马晓茜.秸秆直燃发电的生命周期评价[J].太阳能学报,2008,29(6):711-715.
[46]陈胜震,陈铭.中国清洁能源汽车全生命周期的3E分析与评论[J].汽车工程.2008,30(6):465-522.
[47]刘敬尧,钱宇,李秀喜.燃煤及其替代发电方案的生命周期评价[J].煤炭学报,2009,34(1):133-138.
[48]Bujakowski W,Barbacki A.Potential for geothermal development in southernPoland[J].Geothermics,2004,33(3):383~395.
[49]Sahlin J,Knutsson D,Ekvall T.Effects of planned expansion of wasteincineration in the Swedish district heating systems[J].Resources Conservationand Recycling,2004,41(4):279~292.
[50]Silveira JL,Tuna CE.Thermoeconomic analysis method for optimization ofcombined heat and power systems partⅠ[J].Progress in Energy andCombustion Science,2003,29(6):479~485.
[51]Holmgren K, Gebremedhin A.Modelling a district heating system:introductionof waste incineration policy instruments and co-operation with anindustry[J].Energy Policy,2004,32(16):1807~1817.
[52]Bourgeois TG,Hedman B,Zalcman F.Creating markets for combined heat andpower and clean distributed generation in New York State[J].EnvironmentallyPollution,2003,123(3):451~462.
[53]王东.城市蒸汽采暖系统热力与水利计算的研究[D].山东:山东建筑大学,2007.
[54]刘发启.关于城市集中供热的住宅建筑节能措施研究[J].经济技术协作信息,2009,(29):99-99.
[55]宋徐辉.我国蒸汽系统现状及节能潜力[J].节能与环保,2007,(1):52~54.
[56]刘剑.城市集中供热系统优化研究[D].大连:大连理工大学,2006.
[57]Michael A.Stubblefield,Su-Seng Pang,Vic A.Cundy.Heat loss in insulatedpipe-the influence of thermal contact resistance:a case study,Composites PartB[J].Engineering,1996,27(1):85~93.
[58]刘笑驰,蔡瑞忠,吕崇德.大型蒸汽管网的在线仿真研究[J].系统仿真学报,2002,14(3):397~402.
[59]Atli benonysson,Benny Bohm,Hans F.RANN.Operational optimization in a districtheating system[J].Energy Conversion and Management,1995,36(5):297~314.
[60]The International Association for the Properties of Water and Steam. Release onthe IAPWS Industrial Formulation1997for the Thermodynamic Properties ofWater and Steam[M]. Erl-angen, Germany,1997;
[61]S.P.Mavromatisl, A.C. Kokossis. A logic based model for the analysis andoptimisation of steam turbine networks[J]. Computers in Industry,1998,36:165~179;
[62]Sylvie Lorente, Wishsanuruk Wechsatol, Adrian Bejan. Fundamentals oftree-shaped networks of insulated pipes for hot water and exergy. Exergy, anInternational Journal,2002,2:227~236;
[63]Tian Zhiguang, Meng Xianyao, Zhang Huifen. Design and Realization onDistributed Network System for On-Line Monitoring and Fault Diagnosis in theSteam Turbine Generator Sets [C]. International Conference on ElectronicMeasurement&Instruments(ICEMI'2005) vol.4;
[64]A. Morris, J. Dear, M. Kourmpetis. High Temperature Steam Pipelines-Development of the ARCMAC Creep Monitoring System[J]. Strain,2006,42(3):181~186;
[65]Tveit, TM Fogelholm, CJ. Multi-period steam turbine network optimisation. PartII: Development of a multi-period MINLP model of a utility system[J]. AppliedThermal Engineering,2006,26(15):1730~1736;
[66]V. Rudzinskas, A. V. Valiulis, O. Chernashejus. Operation Reliability of BentElbows of Steam Pipelines[J]. Diffusion and Defect Data. Part B, Solid StateData, Solid State Phenomena,2006,113(3):577~582;
[67]Young-Jong Chung, Soo-Hyong Yang, Hee-Cheol Kim, Sung-Quun Zee.Thermal hydraulic calculation in a passive residual heat removal system of theSMART-P plant for forced and natural convection conditions [J]. NuclearEngineering and Design,2004,232(3):277~288.
[68]Jiang Shizhang,,Yong Qiwei, Jiang Ming, Chen Ming. Experimental Researchand Universal Hydraulic Calculation of Pipe Flow[C]. Asian InternationalConference on Fluid Machinery,2005,8th:957~963;
[69]Helge V. Larsen,Benny Bohm,Michael Wigbels.A comparison of aggregatedmodels for simulation and operational optimisation of districtheating networks[J].Energy Conversion and Management,2004,45(7-8):1119~1139.
[70]Dag Henning,Shahnaz Amiri,Kristina Holmgren.Modelling and optimisation ofelectricity,steam and district heating production for a localSwedish utility[J].European Journal of Operationa Research,2006,175(2):1224~1247.
[71]Irina Gabrielaitiene,Benny Bohm,Bengt Sunden.Modelling temperaturedynamics of a district heating system in Naestved,Denmark-A case Energystudy[J].Conversion and Management,2007,48(1):78~86.
[72]吕泽华,黄志明.蒸汽管道的传递函数及工程应用[J].清华大学学报(自然科学版),1997,37(2):103~107.
[73]赵钦,王志勤,史挺进等.大型蒸汽管网仿真的数学模型研究[J],热能动力工程,1997,12(3):173~175.
[74]李世武.蒸汽管网运行工况模拟计算方法[J].煤气与热力,2001,21(6):552~556.
[75]姜永顺.蒸汽供热管道沿程阻力损失简易计算法[J].暖通空调,2000,30(5):77~79.
[76]姜永顺.蒸汽供热管道局部压力损失计算[J].暖通空调,2003,33(1):73~74.
[77]宋扬,程芳真,蔡瑞忠等.蒸汽供热管道的动态仿真建模[J].清华大学学报,2001,41(10):101~104.
[78]刘笑驰,蔡瑞忠,吕崇德.大型蒸汽管网的在线仿真研究[J].系统仿真学报,2002,14(3):397~402.
[79]刘金平,华贲.考虑蒸汽密度变化的长距离供热蒸汽管道的优化设计[J].中国电机学报,2003,23(1):150~154.
[80]刘金平,华贲,陈志勤.石化企业蒸汽管线的优化设计[J].华南理工大学学报,1997,12:22~27.
[81]李友荣,无双.供热蒸汽管道及其保温层的同步设计法[J].中国电机学报,2003,23(1):150~154.
[82]D.Hennin,5.Arniri,K.Holmgren.ModellingandoPtimisationofeleetrieity,steam anddistrict heating Production for a local Swedish utility[J].EuroPean Journal ofOperational Researeh,2006,175:1224-1247.
[83]S.Iniyan,L.Suganthi and T.R.Jagadeesan.Renewable energy Planning for India in21st century[J].Renewable Energy,1998,14:453-457.
[84]Lehtila A.,PirilaP.Reducing energy related emissions:using an energy systemsOptimization model to support Poliey Planning in Finland[J].Energy Poliey,1996,24:805-819.
[85]G.H.Huang,B.W.Baetz,G.G.party. Trash flow allocation: planning underuncertainly[J].Interfaces,1998,28:36-35.
[86]L.Liu.Development of environmental modeling methodologies for themanagement of regional and industrial pollution control systems
[D].Ph.D.Dissertation,UniversityofRegina,Regina,Saskatchewan,Canada,2001.
[87]Y.P.Li,G.H.Huang,S.L.Nie and X.S.Qin.ITCLP:An inexact two-stage chance-Constrained program for planning waste management systems[J].Resources,Coservation and Recycling,2007,48:284-307.
[88]M.Sadeghi,H.M.Hosseini.Energy supply planning in Iran by using fuzzy linearProgramming approach:regading uncertainties of investment costs[J].EnergyPolicy,2006,34:993-1003.
[89]E.Muela,G.Schweickardt,F.Garces.Fuzzy possibilistic model for medium-termPower generation planning with environmental criteria[J].Energy Policy,2007,35:5643-5655.
[90]Q.G.Lin,G.H.Huang.IPEM;An Tnterval-parameter Energy System PlanningModel[J].Energy Sources,PartA:Recovery,Utilization,and Environmental Effects,2008,30:1382-1399.
[91]咚庆,白泉,刘滨,吕应运.MARKAL模型在北京中远期能源发展研究中的应用[J].中国能源,2004,26(6):36-40.
[92]陈荣,张希良,何建坤,岳立.基于MESSAGE模型的省级可再生能源规划方法[J].清华大学学报(自然科学版),2008,48(9):1525-1528.
[93]刘贞,张希良,高虎,于智为等.区域可再生能源规划基本框架研究[J].中国能源,2010(2):38-41.
[94]李彩,黄国和,蔡宴朋.能源供需优化模型在北京市能源系统的应用.能源工程,2009(4):1-5.
[95]杨静.关于生态城区域建筑能源规划模式的初步研究[D].哈尔滨:哈尔滨工业大学,2010.
[96]牛彦涛.不确定城市能源系统规划模型研究及应用[D].北京:华北电力大学,2011.
[97]陈新华.能源改变命运[M].北京:新华出版社,2008.
[98]谷长利.基于MCS-51单片机的热计量[D].北京:华北电力大学,2006.
[99]中节蓝天投资咨询管理有限责任公司.天津空港加工区475t/h锅炉房热电联产发电改造项目可行性研究报告[R].北京,2009.
[100]南开大学数学科学学院.天保热电营业成本预测报告[R].天津,2009.
[101]张红玉.天津空港加工区蒸汽管网仿真[D].天津:天津大学,2010
[102]天津市发展和改革委员会.天津市临空产业区供热规划(2007-2020年)[R].天津,2007.
[103]王凤雨.随机过程[M].北京:北京师范大学出版社,2009.
[104]魏艳华,王丙参,宋立新.复合泊松过程性质及其应用[J].宜宾学院学报,2009,9(12):45-48.
[105]孙天晴.基于复合泊松过程战略石油储备天数的概率模型及其应用[J].数理统计与管理,2007,26(5):12-14.
[106]蒲俊,吉家锋.Matlab工程数学解题指导[M].上海:浦东电子出版社,2001.
[107]贺平,孙刚.供热工程[M].北京:中国建筑工业出版社,1993,第三版.
[108]法利咨询(上海)有限公司.能源状况评估报告[R].上海,2009.
[109]于建国.浅论以热定电.化工技术经济[J].1998vol.16(6):14-16.
[110]中华人民共和国国务院.中华人民共和国节约能源法[S].北京,1998.
[111]陈光明,夏中明.一个新型的吸收制冷循环研究[J].制冷学报,1996(3):26-36.
[112]吴进发.溴化锂吸收制冷的发展和应用[J].工厂动力,1993(1):4-14.
[113]周贵斌,刘志清,段永红,邓宝军.高效蒸汽型溴化锂吸收式制冷机组的研究[J].制冷与空调,2007vol.7(5):13-16.
[114]冯俊凯,沈幼庭,杨瑞昌.锅炉原理及计算[M].北京:科学出版社,2003.
[115]周亮亮.清洁燃煤发电技术全生命周期评价[D].重庆:重庆大学,2011.
[116]Hammers R. Ethanol’s energy retum on investment: A survey of the literature1990[J].Environmental Seienee&Teehoology,2006,40(6):1744-1750.
[117]Jean F, Sylvain L,et al. Estimation of the environmental impact of apetrochemical process using coupled LCA and exergy analysis [J]. Resources,Conservation and Recycling,2010,54(5):291-298.
[118]郑彬,赵绪新,马晓茜等.生命周期评价方法及其应用[J].中国资源综合利用,2004,3:9-12.
[119]Krozer J,Vis C.How to get LCA in the right direction [J]. Cleaner Production,1998.6(1):53-61.
[120]惠世恩,庄正宁,周屈兰,等.煤的清洁利用与污染防治[M].北京:中国电力出版社,2008.
[121]岳光溪.循环流化床技术发展与应用[J].研究与探讨,2003,(12):3-4.
[122]俞珠峰.洁净煤技术发展及应用[M].北京:化学工业出版社,2004.
[123]Hiroki H.Life cycle GHG emission analysis of power generation systems:Japanese case [J].Energy,2005,30:2042-2056.
[124]中华人民共和国国家统计局.中国统计年鉴2008[M].北京:中国统计出版社,2009.
[125]刘顺妮,林宗寿,张小伟.硅酸盐水泥的生命周期评价方法初探[J].中国环境科学,1998,18(4):328-332.
[126]Spath PL, Mann MK, Kerr DR. Life cycle assessment of coal-fired powerproduction. National Renewable Energy Laboratory[R], US Department ofEnergy Laboratory,1999.
[127]Cottrell.A,Nunn. J,Urfer. A,et al.Systems assessment of electricity generationusing biomass and coal in CFBC[R].Australian: BHP Billiton NewcastleTechnology Centre,2003.
[128]Dones R,Gantner U,Hirschberg S.Environmental inventories for futureelectricity supply systems for Switzerland[R]. Switzerland: Paul ScherrerInstitute,1996.
[129]Daniele F, Lidia L. Integrated gasifier combined cycle plant with integratedCO2-H2S removal: performance analysis, lifecycle assessment and exergetic lifecycle assessment[J]. Applied Thermodynamics,2002,5(1):13-24.
[130]李君,吴少华,李振中.超超临界燃煤发电技术是我国目前发展洁净煤发电技术的优先选择[J].中国电力,2004,37(9):13-17.
[131]袁宝荣,聂祚仁,狄向华,等.中国化石能源生产的生命周期清单(1)-能源消耗与直接排放[J].现代化工,2006,26(3):59-64.
[132]国家统计局、国家环境保护总局编.中国环境统计年鉴2006[M].中国统计出版社,2007.
[133]吕伟业,汤蕴琳,方正.中国火电结构优化和技术升级研究概论[J].电力建设,2002,23(11):9-22.
[134]王大中.21世纪中国能源科技发展展望[M].北京:清华大学出版社,2007.
[135]R.Kannan,C.P.Tso, et al. LCA-LCCA of oil fired steam turbine power plant inSingapore[J].Energy Conversion and Management,2004,(45):3093-3107.
[136]电力规划设计总院编.火电工程限额设计参考造价指标[M].北京:中国电力出版社,2007.
[137]Luc G,Camille B,Yohji U.Life-cycle assessment of electricity generationoptions:the status of research in year2001[J]. Energy Policy,2002,30(14):1267-1278.
[138]Zhihui Z, Xing W, Xiaomin Y, et al. BEPAS a life cycle buildingenvironmental performance assessment model[J]. Building and environment,2006,41(5):669-675.
[139]Francesco Di Maria. Design and off design pipe network geothermal powerplant analysis with power pipe simulator [J].Energy Conversion andManagement,2000,41(12):1223~1225.
[140]李世武.蒸汽管网运行工况模拟计算方法[J].煤气与热力,2001,6(21):552~556.
[141]付祥钊.流体输配管网[M].北京:中国建筑工业出版社,2005.
[142]C.A.博布罗夫斯基等.天然气管路输送(陈祖泽)[M].北京:中国建筑工业出版社,1996.
[143]Ryszard A. Bialecki,Tadeusz Kruczek. Frictional,diathermal flow of steam in apipeline[J]. Chemical Engineering science,1996,51(19):4369~4378.
[144]高鲁峰.蒸汽管网水力热力耦合计算方法的研究及软件开发[D].山东:山东建筑大学,2009.
[145]段常贵.燃气输配(第三版)[M].北京:中国建筑工业出版社,2001.
[146]段常贵等.燃气输配[M].北京:中国建筑出版社,2001.
[147]张昌煜.工业蒸汽的有效利用[M].上海:上海科学技术出版社,1984.
[148]李世武.蒸汽管网运行工况模拟计算方法[J].煤气与热力,2001,21(6):552~556.
[149]刘笑驰,蔡瑞忠,吕崇德.大型蒸汽管网的在线仿真研究[J].系统仿真学报,2002,14(3):397~402.
[150]Michael A.Stubblefield,Su-Seng Pang,Vic A.Cundy.Heat loss in insulatedpipe-the influence of thermal contact resistance:a case study,Composites PartB[J].Engineering,1996,27(1):85~93.
[151]邹平华.借鉴俄罗斯经验积极发展我国集中供热事业[J].暖通空调,2000,30(4):33~37.
[152]杨冶金.丹麦的集中供热[J].区域供热,2000,1(6):27~30.
[153]J.R.威尔特,C.E.威尔斯,R.E.威尔逊等.动量,热量和质量传递原理第四版(马紫峰,吴卫生)[M].北京:化学工业出版社,2005.
[154]陆耀庆.实用供热空调设计手册[M].北京:中国建筑工业出版社,2007.
[155]杨世铭,陶文铨.传热学(第四版)[M].北京:高等教育出版社,2006.
[156]安娜-玛丽娅比安什,伊夫福泰勒,雅克琳娜埃黛.传热学(王晓东)[M].大连:大连理工大学出版社,2008.
[157]宋永军,吕君.蒸汽直埋复合保温管的热工计算[J].电站系统工程,2003,19(3):21~22.
[158]G.H.Huang,R.D.Moore.Grey linear programming,its solving approach,and itsapplication[J].International Journal of Systems Science,1993,24:159-172.
[159]J.M.Wanger,U,Shamir and D.H.Marks,Containing groundwatercontamination:Planning models using stochastic programming withrecourse[J].European Journal of Operational Research,1994,77:1-26.
[160]S.O.Russell,P.F.Campbell.Reservoir operating rules with fuzzyprogramming[J].Journal of Water Resources Planning andManagement,1997,123:312-321.
[161]N.B.Chang and W.C.Chen.Fuzzy controller design for municipal incineratorswith the aid of genetic algorithms and genetic programming techniques[J].WasteManagement&Research,ISWA,2000,18:429-443.
[162]A.Haurie and F.Moresino.A stochastic programming approach to manufacturingflow control [J].HE Transactions,2000,32:907-920.
[163]H.C.Guo,L.Liu,G.H.Huang,R.Zao and Y.Y.Yin.A system dynamics approach forregional environmental planning and management:A study for the Lake ErhaiBasin[J].Journal of Environmental Management,2001,61:93-112.
[164]G.H.Huang.Grey mathematical programming and its application to municipalsolid waste management planning[D].PH.D.Dissertation,Department of CivilEngineering,McMaster University,Ontario,Canada,1994.
[165]D.P.Loucks,J.R.Stedinger,D.A.Haith.Water.resource.systems.planning.and.analysis[M].Homewood Cliffs,N.J.,USA:Prentice-Hall.,1981.
[166]F.S.Budnick,D.Mcleavey,R.Mojena.Principles of Operations Research forMangement[M].Homewood,Illinois,USA:Richard D.Irwin,Inc.,1988.
[167]L.Liu.Development of environmental modeling methodologies for themanagement of regional and industrial pollution contral systems[D]. PH.D.Dissertation,University of Regina,Saskatchewan,Canada,2011.
[168]S.Sen.Sub gradient decomposition and differentiability of the recourse functionof a two stage stochastic linear program[J].Operations Research Letters,1993,13:143-148.
[169]S.Sen and J.L.Higle.An introductory tutorial on stochastic linear programmingmodels[J].Interfaces,1999,29:33-61.
[170]Y.Yoshitomi,H.Ikenoue,T.Takeba and S.Tomita.Genetic algorithm in uncertainenvironments for solving stochastic programming problem[J].Journal of theOperations Reacharch Society of Japan,2000,43:266-290.
[171]R.Slowinski,J.Teghem.Stochastic versus fuzzy approaches to multiobjectivemathematical programming underuncertainty [M]. Inuiguchi,M.,Ichihashi,H.I.,Tanaka,H. Fuzzy programming:a sury of recent development. Norwell,Massachusetts,USA:Kluwer Academic Publishers.
[172]G.H.Huang,B.W.Baetz and G.G.Patry.Grey dynamic programming forwaste-management planning under uncertainty[J].Journal of Urban Planning andDevelopment,1994,120:132-156.
[173]G.H.Huang.A hybrid inexact-stochastic water management model[J].EuropeanJournal of Operational Research,1998,107:137-158.
[174]G.H.Huang.IPWM:An interval parameter water quality managementmode[J].Engineering Operational Research,1996,26:79-103.
[175]I.Maqsood,G.H.Huang,J.S.Yeomans.An interval-parameter fuzzy two-stagestochastic program for water resources management underuncertainty[J].European Journal of Operational Research,2005,167:208-225.
[176]Y.P.Li.G.H.Huang.Interval-parameter two-stage stochsstic nonlinearprogramming for water resources management under uncertainty[J].WaterResources Management,2008,22:681-698.
[177]G.H.Huang,B.W.Baetz,G.G.Party.Grey integer programming:an application towaste management planning under uncertainty[J].European Journal ofOperational Research,1995,83:594-620.
[178]G.H.Huang,B.W.Baetz,G.G.Patry and V.Terluk.Capacity planning for anintegrated waste management system under uncertainty:a North American casestudy[J].Waste Management&Research,1997,15:523-546.
[179]Q.G.Lin,G.H.Huang.IPEM:An Interval-parameter Energy Systems PlanningModel[J].Energy Sources,Part A:Recovery,Utilization,and EnvironmentalEffects,2008,30:1382-1399.
[180]G.H.Huang.B.W.Baetz,G.G.Patry.A grey linear programming approach formunicipal solid waste management planning under uncertainty[J].CivilEngineering Systems,1992,9:319-335.
[181]S.Tong.Interval number and fuzzy number linear programming[J].Fuzzy Setsand Systems,1994,66:301-306.
[182]达庆利,刘新旺.区间数线性规划及其满意解[J].系统工程理论与实践,1999,19(4):3-7.
[183]王志文,蔡文彬.改善天津市大气环境质量的研究[J].城市环境与城市生态,2002,02.