电力系统外文英语文献资料

unication&control in power system 电力系统通讯与控制2.electric power systems: analysis and control 电力系统: 分析与控制3.Electrical Energy System 电能系统4.embedded generation 嵌入式发电5.fundamentals of power system economics 电力系统经济学基础6.Handbook of Electric Power Calculations 电力系统计算手册7.market operations in electric power systems 电力系统市场运行8.POWER QUALITY 电能质量9.Risk assessment of power systems 电力系统风险评估10.Switching Power Supply Design 开关供电设计11.understanding electric power systems 电力系统学习12.understanding Power Quality problems 电能质量问题学习13.electric energy economic methods 电能经济方法14.FACTS Modelling and Simulation in Power Networks 灵活交流输电: 在电网中的仿真与模拟15.HVDC.and.FACTS.Controllers.Applications.of.Static.Converters.in.Power.Systems 高压直流和灵活交流控制器在电力系统中应用16.LOAD-FLOW ANALYSIS IN POWER SYSTEMS 电力系统潮流分析17.Operation of Market-oriented Power Systems 市场化电力系统运营18.Power Generation Operation and Control 发电运行和控制19.Power system economics 电力系统经济学20.power system harmonics 电力系统谐波21.Power System Operations and Electricity Markets 电力系统运行和电力市场22.Power System Restructuring and Deregulation 电力系统改制和放松管制(即电力市场)23.voltage stability of electric power systems 电力系统电压稳定24.Transients in Power Systems 电力系统(电磁)暂态25.transient stability of power systems电力系统暂态稳定26.Wind Energy Handbook 风电手册27.distrbuted generation-the power paradigmfor the new millennium分布式发电28.electric power distribution handbook 配电手册29.electric power engineering handbook 电力工程手册30.spatial load forecasting(空间)电力负荷预测31.power transer-principles and applications 电力变压器-原理和应用32.electric power transer engineering 电力系统变压器工程33.wind and solar power system 风电和太阳能发电34.Electric Power Distribution Reliability 配电网可靠性35.Aging power delivery infrastrutures 送电结构36.Renewable and Efficient Electric Power Systems 可再生与高效电力系统37.probabilityconcepts in electric power systems 电力系统概率应用38.Short Circuits in Power Systems 电力系统短路39.VOLTAGE STABILITY ASSESSMENT,PROCEDURES AND GUIDES 电压稳定性评估,措施和导则40.electric systems, dynamics and stability with AI application 电力系统动态和稳定性: 人工智能应用41.electric power system application of optimiztion 电力系统优化应用42.protective relaying theory and application 继电保护理论与应用43.vehicular electric power systems 车辆电力系统44.electric power quality control techniques 电能质量控制技术45.reliability assessment of electric power systems using monte carlo methods 利用蒙特卡罗方法进行电力系统可靠性评估petitive Electricity Markets 竞争性电力市场47.power quality enhancement using customer power devices 用户电力设备与电能质量提高48.power system harmonics: computer modelling and analysis 电力系统谐波:计算机仿真与分析49.Analysis of Faulted Power Systems 故障电力系统分析50.Dynamic and control of large power system 大电力系统动态与控制51.Distributed power generation: planning and evaluation分布式发电(规划与评估)52.AC-DC power system analysis 交直流电力系统分析53.FACTS (flexible AC transmission system) 灵活交流输电系统54.Power system in emergencies 紧急状态下的电力系统55.Power system restoration 电力系统恢复56.Electric power system quality 电能质量57.Energy Management Systems (EMS) 能量管理系统58.Automatic learning techniques in power systems 自学习技术在电力系统中的应用59.Power system protection 1-4 电力系统保护1-4册(electricity association 培训教程)60 electrical power system protection 电力系统保护61.elements of power system analysis 电力系统分析基础62.AC power system handbook 交流电力系统手册63. Wind turbine operation in electric power systems: advanced modelling 风力发电(机)在电力系统运行64. Power system control and stability 电力系统控制与稳定性( 不是那本stability and control)65. Analysis of subsynchronous resonance in power system 电力系统次同步谐振分析putationalmethods for large sparse power systems: a object orientedapproach 大稀疏电力系统计算方法: 面向对象的途径67. Power system oscillation 电力系统振荡68. Power system restructuring: engineering and economics 电力系统市场化: 工程和经济69. Distribution system modelling and analysis 配电系统建模与分析70. Electric power engineering 电力工程71. Subsynchronous resonance in power systems 电力系统中的次同步谐振72. Computer modelling of electrical power system 电力系统计算机建模73. High V oltage Direct Current Transmission 高压直流输电74. Electricitydistribution network design (2nd)配电网规划设计75. Industrial power distribution 工业配电76. Protection ofelectricity distribution networks 配电网保护77. Energy function analysis for power system stability 电力系统稳定性的能量函数分析78. Power system commission and maintenance practice电力系统试验(调试)与检修(维护)实践79. Statistical techniques for high-voltage engineering 高电压工程中的统计技术80. Digital protection for power system电力系统数字保护81. Power system protection 电力系统(继电)保护82. V oltage quality in electrical power systems 电力系统电压质量83.Electric power applications of fuzzy systems 模糊系统的电力应用84. Artificial intelligence techniques in power system 电力系统中的人工智能技术85. Insulators in high voltages 高压绝缘体86. Electrical safety供电安全87. High voltageengineering and testing 高电压工程与试验88. Reactive power control in electric systems 电力系统无功(功率)控制89. Electical distribution engineering配电网工程90. Power systemplanning电力系统规划91. Uniquepower system problems 电力系统问题92. Tranmission and Distribution ofElectrical Energy 电力系统输配电93. Electric power system电力系统教程94. Computer-Aided Power systems analysis 计算机辅助电力系统分析95. Electric powertransmission system 输电系统96. Reliability Modelling in Electric power systems电力系统可靠性建模97. High voltage engineering in power system 电力系统高电压工程98. Extra High voltage AC transmission engineering 超高压交流输电工程99. Reliability evaluation of power system 电力系统可靠性评估100. Computation of power system transients 电力系统暂态计算101.Piecewise methods and application to power systems 分段法及其在电力系统中应用103. Analysis and protection of electrical power systems 电力系统分析与保护104. Power systems engineering and mathematicas电力系统工程与数学105. Stability of large power systems 大电力系统稳定性107. Power system reliability evaluation电力系统可靠性评估108.Electric power system dynamics 电力系统动态106. Power system stability handbook 电力系统稳定性手册109. Reliability assessment of large electric power systems 大电力系统可靠性评估110. Power system analysis and planning 电力系统分析与规划111. Electric transmission line fundamental 输电线(工程)基础112. HVDC power transmission systems 高压直流输电系统113. Transient Processes in electrical power systems 电力系统暂态过程114.Discrete Fourier transation and its applications to power system 离散傅立叶变换及其在电力系统中的应用115. Electrical Transients inpower system 电力系统暂态116. Optimal economic operation of electric power system 电力系统优化经济调度运行117.High power switching 大功率开关118. power plant engineering 电厂工程119. power plant system design 电厂系统设计120. power plant evaluation and design reference guide 电厂评估和设计参考导则121. planning engineering, and construction of electric power generationfacilities发电设备的规划和建设工程122. Elements electrical power station design 电站设计基础123.Optimal control applications in electric power systems 电力系统最优控制应用124. applied protected relaying应用继电保护125. power station and substation maintenance 电厂与变电站维修126. Power system operation 电力系统运行127. power system reliability,safety and management 电力系统可靠性,安全与管理128. Electric Machinery and power system fundamentals 电机与电力系统基础(MATLAB辅助)129. Intelligent system applications in power engineering (EP and ANN) 智能系统在电力工程中应用(进化计算和神经网)130. Thyristor-based FACTS controllers for electrical transmission systems 基于晶闸管的灵活交流输电系统控制器131. The economics of power system reliability and planning 电力系统可靠性与规划的经济学132. Computational Intelligence Applications to Power systems 计算智能在电力系统中的应用133. Environmental Impact of Power Generation 发电的环境影响134. Operation and Maintenance of Large Turbo-Generators 大型涡轮发电机组运行与检修135. Power system simulation 电力系统仿真136. Advanced load dispatch for power systems 电力系统高级调度137. The development of electric power transmission 电力传输进展138. Renewable Energy Sources 可再生发电源139. Power system dynamics andstablity 电力系统动态与稳定性140. Practical electrical network automation and communication systems 电力系统自动化与通信系统实践141. Electrical power and controls 电力与控制142. Deregulation of Electric Utilities 电力企业放松管制(市场改革)143. Computational Auction Mechanisms for restructured power industry operation 电力市场运行的(计算)投标机理144. Finanicial and economic evaluation of projects in the electricity supply industry 电力工程项目的金融与经济评价145. Electricity economics and planning 电力经济与规划146. Computational Methods for electric power systems 电力系统计算方法147. Power system relaying 电力系统继电保护148. Computer relaying for power systems 电力系统计算机保护149. Modern power system planning 现代电力系统规划150. High V oltage Engineering (2nd) 高电压工程151. Operation of restructured power systems 市场化电力系统运行152. Transer and Inductor Design Handbook变压器和电感设计手册(04增强版)153. Modern power system analysis (matlab supported) 现代电力系统分析(03年含MATLAB版)154. Power distribution planning reference book 配电规划参考手册155. Understanding FACTS 理解灵活交流输电系统156. Power system analysis :short-circuit load flow and harmonics 电力系统分析: 短路潮流和谐波157. Power systems electromagnetic transients simulation 电力系统电磁暂态仿真158. Power electronic control in electrical systems 电力系统中的电力电子控制159. Protection devices and systems for high-voltage applications保护装置和系统的高压应用160. Small signal analysis of power systems 电力系统小信号分析161. Electrical power cable engineering 电力线缆工程162. Power System State Estimation: Theory and Implementation 电力系统状态估计: 理论和实现163. Dielectrics in Electric Fields 电场中的电介质(绝缘体)164. spacecraft power system 航天器电力系统165. Grid integration of wind energy conversion systems 风能转换系统的电网整合(接入)166. Power loss: the origins of deregulation and restructuring in the American electricutility system网损:美国电力系统放松管制和市场化的根源167. High V oltage Circuit Breakers: Design and Applications 高压断路器:设计与应用168. Power system capacitors 电力系统电容器169. Energy Management Systems & Direct Digitial Control 能量管理系统(EMS)及直接数字控制170. Pricing in Competitive Electricity Market 电力市场电价171. Designing Competitive Electricity Markets 电力市场设计172. Power system dynamics and stability 电力系统动态与稳定性(美国)173. Theory and problems of electric power systems 电力系统的理论和问题174. Insulation coordinationfor power systems 电力系统绝缘配合175. Modal analysis of large interconnected power systems 大互联电力系统的模式分析176. Making competition work in electricity 电力市场竞争177. Power system operation 电力系统运行178. Transmission line reliability and security 输电线路安全可靠性179. Computer analysis of power systems 电力系统计算机分析180. Power system stability and control 电力系统稳定与控制。

Page1.The Production of Electrical Energy（电能生产）1 English texFrom reference 1See also: Wind power, Wind farm, and Wind power in the United StatesAirflows can be used to run wind turbines. Modern wind turbines range from around 600 kW to 5 MW of rated power, although turbines with rated output of 1.5–3 MW have become the most common for commercial use; the power output of a turbine is a function of the cube of the wind speed, so as wind speed increases, power output increases dramatically. Areas where winds are stronger and more constant, such as offshore and high altitude sites, are preferred locations for wind farms. Typical capacity factors are 20-40%, with values at the upper end of the range in particularly favourable sites.Globally, the long-term technical potential of wind energy is believed to be five times total current global energy production, or 40 times current electricity demand. This could require large amounts of land to be used for wind turbines, particularly in areas of higher wind resources. Offshore resources experience mean wind speeds of ~90% greater than that of land, so offshore resources could contribute substantially more energy.Wind power is renewable and produces no greenhouse gases during operation, such as carbon dioxide and methane.Keywords：wind power，wind turinesFrom reference 2See also: Hydroelectricity and HydropowerEnergy in water can be harnessed and used. Since water is about 800 times denser than air, even a slow flowing stream of water, or moderate sea swell, can yield considerable amounts of energy. There are many forms of water energy:∙Hydroelectric energy is a term usually reserved for large-scale hydroelectric dams. Examples are the Grand Coulee Dam in Washington State and theAkosombo Dam in Ghana.∙Micro hydro systems are hydroelectric power installations that typically produce up to 100 kW of power. They are often used in water rich areas as aremote-area power supply (RAPS). There are many of these installationsaround the world, including several delivering around 50 kW in the Solomon Islands.∙Damless hydro systems derive kinetic energy from rivers and oceans without using a dam.∙Ocean energy describes all the technologies to harness energy from the ocean and the sea. This includes marine current power, ocean thermal energyconversion, and tidal power.Keywords: hydropower，the Grand Coulee Dam，the Akosombo DamFrom reference 3See also: Ethanol fuel and BioEthanol for Sustainable TransportSince the 1970s, Brazil has had an ethanol fuel program which has allowed the country to become the world's second largest producer of ethanol (after the UnitedStates) and the world's largest exporter. Brazil’s ethanol fuel program uses modern equipment and cheap sugar cane as feedstock, and the residual cane-waste (bagasse) is used to process heat and power. There are no longer light vehicles in Brazil running on pure gasoline. By the end of 2008 there were 35,000 filling stations throughout Brazil with at least one ethanol pump.Nearly all the gasoline sold in the United States today is mixed with 10 percent ethanol, a mix known as E10, and motor vehicle manufacturers already produce vehicles designed to run on much higher ethanol blends. Ford, DaimlerChrysler, and GM are among the automobile companies that sell “flexible-fuel” cars, trucks, and minivans that can use gasoline and ethanol blends ranging from pure gasoline up to 85% ethanol (E85). By mid-2006, there were approximately six millionE85-compatible vehicles on U.S. roads. The challenge is to expand the market for biofuels beyond the farm states where they have been most popular to date. Flex-fuel vehicles are assisting in this transition because they allow drivers to choose different fuels based on price and availability. The Energy Policy Act of 2005, which calls for 7.5 billion gallons of biofuels to be used annually by 2012, will also help to expand the market.Keyword：ethanol fuel，bioethanol for sustainable transport2 中文翻译及分析出自文献1:通过对风力发电也已increasing.See：在美国风力发电，风电场，风力发电气流可用于运行风力涡轮机。

电力系统继电保护论文中英文资料Relay protection development present situation[Abstract ]reviewed our country electrical power system relay protection technological devil orpiment process，has outlined the microcomputer relay protection technology achievement, pro posed the future relay protection technological development tendency will be: Computerizes, n networked，protects, the control，the survey，the data communication integration and the artificial I intellectualization.[Key word ］relay protection present situation development，relay protections future development1 relay protection development present situationThe electrical power system rapid development to the relay protection proposed unceasingly t he new request，the electronic technology，computer technology and the communication rapid development unceasingly has poured into the new vigor for the relay protection technology de velopment，therefore，the relay protection technology is advantageous, has completed the deve lopment 4 historical stage in more than 40 years time。

电力系统英文书籍Electric power system engineering is an important area of study in the field of electrical engineering. It is concerned with the generation, transmission, and distribution of electrical power from power plants to end-users. Electrical engineers, power system operators, and technicians must have a deep understanding of electric power system engineering to design, operate, and maintain power systems that are safe, reliable, and efficient. In this document, we will explore some of the best electric power system engineering books to help students, engineers, and technicians expand their knowledge of this field.1. “Power System Analysis” by Arthur R. Bergen and Vijay VittalThis textbook is widely regarded as one of the best electric power system engineering books for students and practitioners who want to understand the analysis techniques that are essential for designing and operating power systems. It provides in-depth coverage of such topics as power flow, stability, and control, and covers the latest techniques used in modern power system analysis.2. “Electric Power Systems: A Conceptual Introduction” by Alexandra von MeierThis book offers a comprehensive introduction to electric power systems engineering fundamentals. It is perfect for students who are new to the field and want to get a broad overview of electric power systems. The author provides a clear and concise explanation of basic concepts and principles and their relevance to the design, operation, and management of modern power systems.3. “Power System Protection and Switchgear” by Badriram and VishwakarmaThis book is an excellent guide for engineers, technicians, and students interested in understanding the principles of electric power system protection and switchgear. The authors provide a comprehensive overview of the theory and practice of protection and switchgear, including a detailed discussion of the most important elements of power system protection and security mechanisms.4. “Electric Power Distribution Engineering” by Turan G onenThis book is an excellent resource for students, engineers, and technicians who want to understand the critical concepts and principles of power distribution engineering. It provides a comprehensive overview of the fundamentals of power distribution engineering, including power system planning, design, and operation.5. “Electric Power Transformers” by John WindersThis book provides a comprehensive overview of electric power transformers, which are essential components of power systems. The book covers the principles of transformer design, construction, and operation and provides practical guidance for engineers and technicians in the field.6. “Power System Dynamics: Stability and Control” by K.R. PadiyarThis book provides a thorough introduction to power system dynamics, stability, and control. It covers the most important topics related to power system dynamics and provides a comprehensive overview of the latest techniques used in modeling and control of power systems.7. “Electric Energy Systems: Analysis and Operation” by Antonio Gomez-Exposito, Antonio J. Conejo, and Claudio CanizaresThis book provides a comprehensive overview of the analysis and operation of electric power systems. It covers the latest techniques and methods used in power system analysis and design, and provides practical guidance to engineers, technicians, and students in the field.In conclusion, electric power system engineering is a fascinating field that requires a deep understanding of power generation, transmission, and distribution processes. The books discussed in this document are some of the best electric powersystem engineering books to help students, engineers, and technicians master the fundamentals of this field and excel in their careers.。

外文资料（一）Current density according to the economic section of the wire researchCurrent density according to the economic section at the wire, according to the following formula :jn A '=c nI J (1-1) Jn=max jn I A '(1-2) where Ic------ design sought by the current calculation, unit A; b----- line with the cost of wire cross-section of relations coefficient;β------ rates Potential for the yuan / (kw • h);τ------ maximum load factor, unit of h;α------ cost factors, according to state regulations, can be found on the manual;Figure 1 wire running costs and the annual cross-section curv ejn A ' standards section is not, By the plan (1), we can see that the curve F so there jn A ' corresponding to the lowest point, because the power loss charges section A with the decrease of the reasons, if not envisaged curve Fs play, Section increasewouldinevitably lead to the increase in operating costs. So admission standards section should not only satisfy the minimum requirements of the power loss, but also reduce running costs less because(1) In general, the establishment of factories or load a development process, the initial value is smaller than the design, gradually in order to achieve the expected A'network is completed by the load considered, This is not consistent value, butjnwith the actual situation, in other words, power loss is not designed so much to the imagination;(2) Design calculations indicate the actual load Ic than big design value;(3) F curve relatively flat bottom.A'smaller than Therefore, the selection criteria section, it should be by choicejnthe cross section, as F curve flat bottom, operating costs of less impact, taking into account the load values, as well as changes in the law, Theoretical calculation of the power loss will be larger than the actual value. with the options to save much of the initial investment and the consumption of non-ferrous metals.In the factory power supply system design using Jn wire cross section, Energy losses are still high volume of large factories into line and the electric network in the short occasions application. Method used Jn wire cross section still in use, but it should be noted that this method has the following problems :(1) 1.2 formula of the b value is not constant, the domestic tariff beta value is not uniform, Operating costs of Europium value in different countries should have the period of change.(2) This method is only from the operating expenses for at least the premise, not the investment, operating costs and the overall efficiency.Therefore, the proposed foreign books "at least expenditure," the wire cross section. Under Ic can elect to meet the heating requirements of the specifications 2-3 lead, their investment costs and operating costs are different. High investment costs of cross-section wire resistance by small and less power loss costs, it will be able to choose one of the best programs. But because the wire cross section Size is notcontinuous, but a broken line, in order to solve the lowest value to be used on the dogleg approximation method for the mathematical model, which is relatively more complicated, it has not been applied to engineering practice.（二）Grounding the researchCircuits are grounded in order to prevent high voltages from building up on the conductors, while equipment grounding aims at preventing enclosures from reaching voltages above ground. Grounding thus improves system protection and reliability and provides safety to people standing by.Grounding every circuit, however, makes the system susceptible to excessive currents should a short circuit develop between a live conductor and ground. Thus, not all neutrals of wye-connected loads (especially large motors) should be grounded. Grounding should then be practiced selectively, especially on the primary distribution system, as shown in Fig. -1. In part (a), disconnection of motors M1 and M3 for maintenance of repair deprives the 2400-volt system of a ground. It is preferable toground the system at the source, that is, at the transformer neutral in Fig.-1 (b).2400V13.8kVM1M2M3M4(a)2400V13.8kVM1M2M3M4(b)Fig.2 Circuit grounding done selectively(a) at a few motor neutrals (load);(b) at the transformer neutral (source)Metal enclosures,raceways,and fixed equipments are normally grounded. However,motor and generators well insulated from ground,and metal enclosurs used to protect cables or equipments from physical damage,may be left ungrounded.Aslo,portable tools and home appliances,such as refrigerators and air conditions,need not be grounded if constructed with double insulation.Some ac circuits are required to be ungrounded as,for instance,in anesthesizing locations in hospital.In fact,line isolation monitors are installed in such cases,capable of sounding warning signals.High-voltage services (>1000V) are not necessarily grounded, but they must be so if they supply portable equipment.Metal underground water pipes are normally used for grounding, If their length is judged inadequate, they may be complemented by other means, such as a building metal frame or some underground pipe of tank.中文译文（一）按照经济电流密度选择导线截面的研究按照经济电流密度选择导线截面时，可根据下式：jn A '=c nI J (1-1) Jn=max jn I A '(1-2) 式中 Ic------设计时求得的计算电流，单位为A ；b-----线路造价与导线截面间的关系系数； β------电价，电位为元/（kw·h）τ------最大负荷损耗系数，单位为h ；α------费用系数，根据国家规定，可在有关手册中查到；图1 导线截面与年运行费的关系曲线jn A '未必是标准截面，那么，由图 1可以看出，曲线F 所以出现对应于jn A '的最低点，是因为电能损耗费随截面A 的增大而减小的缘故，设想如果没有曲线Fs 起作用，截面的增加必然引起运行费用的增加。

An Expert System for Transformer Fault Diagnosis Using Dissolved Gas Analysis1. INTRODUCTIONThe power transformer is a major apparatus in a power system, and its correct functioning its vital to minimize system outages, many devices have evolved to monitor the serviceability of power transformers. These devices, such as, Buchholz relays or differential relays, respond only to a severe power failure requiring immediate removal of the transformer from service, in which case, outages are inevitable. Thus, preventive techniques for early detection faults to avoid outages would be valuable. In this way, analysis of the mixture of the faulty gases dissolved in insulation oil of power transformer has received worldwide recognition as an effective method for the detection of oncipient faults. Many researchers and electrical utilities have reported on their experience and developed interpretative criteria on the basis of DGA. However, criteria tend to vary from utility to utility. Therefore, transformer diagnosis is still in the heuristic stage. For this reason, knowledge-based programming is a suitable approach to implement in such a diagnostic problem.Based on the interpretation of DGA, a prototype of an expert system for diagnosis of suspected transformer faults and their maintenance procedures is proposed. The significant source in this knowledge base is the gas ratio method. Some limitations of this approach are overcome by incorporating the diagnostic procedure and the synthetic expertise method. Furthermore, data bases adopted from TPC'S gas records of transformers are incorporated into the expert system to increase the practical performance. Uncertainty of diagnosis is managed by using fuzzy set concepts. This expert system is constructed with rule based knowledge representation, since it can be expressed by experts. The expert system building tool,knowledge Engineering System(KES), is used in the development of the knowledge system because, it has excellent man-machine interface that provides suggestions. Moreover,its inference strategy is similar to the MYCIN. A famous rule-based expert system used for medical diagnosis. The uncertainty of human qualitative diagnostic expertise, e.g., key gasanalysis, and another quantitative imprecision, such as, norms threshold and gas ratio boundaries etc., are smoothed by appropriate fuzzy models. With the results of such implementation, different certainty factors will be assigned to the corresponding expertise variables. Both event-driven(forward chaining) and goal-driven (backward chaining) inferences are used in the inference engine to improve the inference efficiency. To demonstrate the feasibility of the proposed expert system, around hundreds of TPC historical gas records have been tested. It is found that more appropriate faulty types and maintenance suggestions can support the maintenance personals to increase the performance of transformer diagnosis.2. DEVELOPMENT OF DIAGNOSIS AND INTERPRETATIONLike many diagnostic problems, diagnosis of oil-immersed power transformer is a skilled task. A transformer may function well externally with monitors, while some incipient deterioration may occur internally to cause a fatal problem in the latter development. According to a Japanese experience, nearly 80% of all faults result from incipient deteriorations. Therefore, faults should be identified and avoided at the earliest possible stage by some predictive maintenance technique. DGA is one of the most popular techniques for this problem. Fault gases in transformers are generally produced by oil degradation and other insulating material, e.g., cellulose and paper. Theoretically, if an incipient or active fault is present, the individual dissolved gas concentration, gassing rate, total combustible gas(TCG) and cellulose degradation are all significantly increased. By using gas chromatography to analyse the gas dissolved in a transformer's insulating oil, it becomes feasible to judge the incipient fault types. This study is concerned with the following representative combustible gases; hydrogen(H2), methane(C2H2), ethane(C2H6), ethylene(C2H2) and carbon monoxide(C0).Many interpretative methods based on DGA to the nature of incipient deterioration have been reported. Even under normal transformer operational conditions, some of these gases may be formed inside. Thus, it is necessary to build concentration norms from a sufficiently large sampling to assess the statistics. TPC investigated gas data from power transformers to construct its criteria. The developedknowledge base in this paper is partially based on these data. On the hand, Dornerburg developed a method to judge different faults by rating pairs of concentrations of gases, e.g., CH/H, GH/C3H4, with approximately equal solubility and fusion coefficients. Rogers established mare comprehensive ratio codes to interpret the thermal fault types with theoretical thermodynamic assessments. This gas ratio method was promising because it eliminated the effect of oil volume and simplified the choice of units. Moreover, it systematically classified the diagnosis expertise in a table form. Table 1 displays the ratio method as proposed by Rogers. The dissolved gas may vary with the nature and severity of different faults. By analyzing the energy density of faults, it's possible to distinguish three basic fault processes:overheating(pyrolysis), corona(partial dischatge) and arcing discharge. Corona and arcing arise from electrical faults, while overheating is a thermal fault. Both types of faults my lead to deterioration, while damage from overheating is typically less than that from electrical stress. Infect, different gas trends lead to different faulty types, the key gas method is identified. For example, large amounts of CH and H are produced with minor arcing fault 4 quantities of CH 2aid C2H2 may bea symptom of an arcing fault.3.THE PROPOSED DIAGNOSTIC EXPERT SYSTEMThis study is aimed at developing a rule-based expert system to perform transformer diagnosis similar to a human expert. The details of system processing are described below.3.1 The Proposed Diagnostic MethodDiagnosis is a task that requires experience. It is unwise to determine an approach from only a few investigations. Therefore, this study uses the synthetic expertise method with the experienced procedure to assist the popular gas ratio method and complete practical performance.3.1.1 Experienced Diagnostic ProcedureThe overall procedure of routine maintenance for transformers is listed. The core of this procedure is based on the implementation of the DGA technique. The gas ratio method is the significant knowledge source. Some operational limitations of the gasratio method exist. The ratio table is unable to cover all possible cases. Minimum levels of gases must be present. The solid insulation involving CO and CO are handled separately and the gas ratio codes have been developed mainly from a free-breathing transformer. Other diagnostic expertise should be used to assist this method. Norms, synthetic expertise method and data base records have been incorporated to complete these limitations. The first step of this diagnostic procedure begins by asking DGA for an oil sample to be tested. More important relevant information about the transformer's condition, such as the voltage level, the preservative type, the on-line-tap-changer(OLTC) state, the operating period and degassed time must be known for further inference. Norms(criteria) Set up by TPC power transformers' gas characteristic data are then used to judge the transformers' condition. For the abnormal cases, the gas ratio method is used to diagnose transformer fault type. If different or unknown diagnosis results are found from these ratio methods, a further synthetic expertise method is adopted. After these procedures, different severity degrees are assigned to allow appropriate corresponding maintenance suggestions.3.1.2 Synthetic Expertise MethodThe ratio trend, norms threshold, key gas analysis and some expertise are considered as different evidences to confirm some special fault types. In other words, more significant evidences have been collected for some special fault type, better assessment of the transformer status is obtained.The ratio trend can be seen as a modification of the conventional gas ratio and key gas method.Obviously, the above gas trends should be incorporated with other evidences under the experienced procedure for practical use. Norms threshold, the gassing rate, the quantity of total combustible gas(TCG), the TPC maintenance expertise and the fuzzy set assignment are all important evidences considered in the synthetic diagnosis.Other expertise based on a transformer historical data base is also used to analyse the characteristics of a case transformer. Section 3.4 gives some details of these rules.3.2 Expert System StructureThe proposed diagnostic expert system is composed of components, working memory, a knowledge base, an inference engine and a man-machine interface. Working memory (global data base) contains the current data relevant to solve the present problem. In this study, most of the diagnostic variables stored in the data base are current gas concentration, some are from the user, others are retrieved from the transformer's historical data base. Note that the fuzzy set concept is incorporated to create fuzzy variables on the request of system reasoning. A knowledge relationship, which uses these facts, as the basis for decision making. The production rule used in this system is expressed in IF-THEN forms. A successful expert system depends on a high quality knowledge base. For this transformer diagnostic system, the knowledge base incorporates some popular interpretative methods of DGA, synthetic expertise method and heuristic maintenance rules. Section 3.4 will describe this knowledge base. Another special consideration in the expert system is its inference engine. The inference engine controls the strategies of reasoning and searching for appropriate knowledge. The reasoning strategy employs both forward chaining(data-driven) and backward chaining(goal-driven). Fuzzy rules, norms rules, gas ratio rules, synthetic expertise rules and some of the maintenance rules and some maintenance rules, use forward chaining.As for the searching strategy in KES, the depth first searching and short-circuit evaluation are adopted. The former can improve the search efficiency by properly arranging the location of significant rules in the inference procedures. The latter strategy only searches the key conditional statements in the antecedent that are responsible for establishing whether the entire rule is true or false. Taking the advantages of these two approaches in the building and structuring of a knowledge base improves inference efficiency significantly.As for man-machine interface. KES has an effective interface which is better than typical knowledge programming languages, such as, PROLOG or LISP. With the help of this interface, the capability of tracing, explaining and training in an expert system is greatly simplified.4.IMPLEMENTATION OF THE PROPOSED EXPERT SYSTEMAn expert system is developed based on the proposed interpretative rules and diagnostic procedures of the overall system. To demonstrate the feasibility of this expert system in diagnosis, the gas data supported by MTL of TPC have been tested. In Taiwan, the MTL of TPC performs the DGA and sends the results to all acting divisions relating to power transformers. In return, these acting divisions are requested to collect and supply their transformer oil samples periodically.After analysing oil samples, more than ten years' worthy gas records are collected and classified into three voltage level, 69KV, 16KV and 345KV. Thus, gas records for one transformer are composed of several groups of data. In the process of DGA interpretation, all of these data may be considered, but only the recent data which have significant effects on diagnosis are listed in the later demonstration. In MTL, all gas concentrations are expressed by pm in volume concentration. 100 pm is equal to 0.01 ml(gas)/100ml(oil).From the expertise of diagnosis, the normal state can be confirmed only by inspection of the transformer's norms level. In practice, most of the transformer oil samples are normal, and this can be inferred successfully on the early execution of this expert system. However, the Success of an expert system is mainly dependent on the capability of diagnosis for the transformers in question. In the implementation, many gas records which are in abnormal condition are chosen to test the Justification of this diagnostic system. A total of 101 transformer records have been executed and the results are summarized in Table 5. Among those implemented, three are listed and demonstrated.Shown in Table 5 are the results of 101 units of transformers in three types of remedy: normal, thermal fault and arc fault. After comparing them with the actual state and expert judgement, a summary of results was obtained. As previously stated, one unit of transformer may include many groups of gas data. In evaluation, we depicted some key groups in one unit to justify because some transformers may have different incipient faults during different operational stages. Some mistakes implemented from testing are caused by the remaining oil in the oil sampling container, unstable gas characteristics of the new degassing sample and some obscuregas types. If more information or new techniques support other uncertain membership functions, they can be added into the knowledge has to enlarge the the performance of this prototype expert system. Furthermore, the parameters described in table 2,3 and 4 are suitable for TPC power transformer. Different regions may be modified the maintenance personnel find more suitable system parameters.5.CONCLUSIONSA prototype expert system is developed on a personal computer using KES. It can diagnose the incipient faults of the suspected transformers and suggest proper maintenance actions. Fuzzy set concept is used to handle uncertain norms thresholds, gas ratio boundaries and key gas analysis. The synthetic method and diagnostic procedure are proposed to assist the situation which can not be handled properly by the gas ratio methods. Results from the implementation of the expert system shows that the expert system is a useful tool to assist human expert and maintenance engineers.The knowledge base of this expert system is incorporated within the popular interpretative method of DGA, synthetic expertise and heuristic maintenance rules. The data base supported by TPC MTL for about 10 year collection of transformer inspection data is also used to improve the interpretation of diagnosis. Through the development of the proposed expert system, the expertise of TPC MTL can be reserved. In addition, this work can be continued to expand the knowledge base by adding any new experience, measurement and analysis techniques.。

unication&control in power system 电力系统通讯与控制2.electric power systems: analysis and control 电力系统: 分析与控制3.Electrical Energy System 电能系统4.embedded generation 嵌入式发电5.fundamentals of power system economics 电力系统经济学基础6.Handbook of Electric Power Calculations 电力系统计算手册7.market operations in electric power systems 电力系统市场运行8.POWER QUALITY 电能质量9.Risk assessment of power systems 电力系统风险评估10.Switching Power Supply Design 开关供电设计11.understanding electric power systems 电力系统学习12.understanding Power Quality problems 电能质量问题学习13.electric energy economic methods 电能经济方法14.FACTS Modelling and Simulation in Power Networks 灵活交流输电: 在电网中的仿真与模拟15.HVDC.and.FACTS.Controllers.Applications.of.Static.Converters.in.Power.Systems 高压直流和灵活交流控制器在电力系统中应用16.LOAD-FLOW ANALYSIS IN POWER SYSTEMS 电力系统潮流分析17.Operation of Market-oriented Power Systems 市场化电力系统运营18.Power Generation Operation and Control 发电运行和控制19.Power system economics 电力系统经济学20.power system harmonics 电力系统谐波21.Power System Operations and Electricity Markets 电力系统运行和电力市场22.Power System Restructuring and Deregulation 电力系统改制和放松管制(即电力市场)23.voltage stability of electric power systems 电力系统电压稳定24.Transients in Power Systems 电力系统(电磁)暂态25.transient stability of power systems电力系统暂态稳定26.Wind Energy Handbook 风电手册27.distrbuted generation-the power paradigmfor the new millennium分布式发电28.electric power distribution handbook 配电手册29.electric power engineering handbook 电力工程手册30.spatial load forecasting(空间)电力负荷预测31.power transer-principles and applications 电力变压器-原理和应用32.electric power transer engineering 电力系统变压器工程33.wind and solar power system 风电和太阳能发电34.Electric Power Distribution Reliability 配电网可靠性35.Aging power delivery infrastrutures 送电结构36.Renewable and Efficient Electric Power Systems 可再生与高效电力系统37.probabilityconcepts in electric power systems 电力系统概率应用38.Short Circuits in Power Systems 电力系统短路39.VOLTAGE STABILITY ASSESSMENT,PROCEDURES AND GUIDES 电压稳定性评估,措施和导则40.electric systems, dynamics and stability with AI application 电力系统动态和稳定性: 人工智能应用41.electric power system application of optimiztion 电力系统优化应用42.protective relaying theory and application 继电保护理论与应用43.vehicular electric power systems 车辆电力系统44.electric power quality control techniques 电能质量控制技术45.reliability assessment of electric power systems using monte carlo methods 利用蒙特卡罗方法进行电力系统可靠性评估petitive Electricity Markets 竞争性电力市场47.power quality enhancement using customer power devices 用户电力设备与电能质量提高48.power system harmonics: computer modelling and analysis 电力系统谐波:计算机仿真与分析49.Analysis of Faulted Power Systems 故障电力系统分析50.Dynamic and control of large power system 大电力系统动态与控制51.Distributed power generation: planning and evaluation分布式发电(规划与评估)52.AC-DC power system analysis 交直流电力系统分析53.FACTS (flexible AC transmission system) 灵活交流输电系统54.Power system in emergencies 紧急状态下的电力系统55.Power system restoration 电力系统恢复56.Electric power system quality 电能质量57.Energy Management Systems (EMS) 能量管理系统58.Automatic learning techniques in power systems 自学习技术在电力系统中的应用59.Power system protection 1-4 电力系统保护1-4册(electricity association 培训教程)60 electrical power system protection 电力系统保护61.elements of power system analysis 电力系统分析基础62.AC power system handbook 交流电力系统手册63. Wind turbine operation in electric power systems: advanced modelling 风力发电(机)在电力系统运行64. Power system control and stability 电力系统控制与稳定性( 不是那本stability and control)65. Analysis of subsynchronous resonance in power system 电力系统次同步谐振分析putationalmethods for large sparse power systems: a object orientedapproach 大稀疏电力系统计算方法: 面向对象的途径67. Power system oscillation 电力系统振荡68. Power system restructuring: engineering and economics 电力系统市场化: 工程和经济69. Distribution system modelling and analysis 配电系统建模与分析70. Electric power engineering 电力工程71. Subsynchronous resonance in power systems 电力系统中的次同步谐振72. Computer modelling of electrical power system 电力系统计算机建模73. High V oltage Direct Current Transmission 高压直流输电74. Electricitydistribution network design (2nd)配电网规划设计75. Industrial power distribution 工业配电76. Protection ofelectricity distribution networks 配电网保护77. Energy function analysis for power system stability 电力系统稳定性的能量函数分析78. Power system commission and maintenance practice电力系统试验(调试)与检修(维护)实践79. Statistical techniques for high-voltage engineering 高电压工程中的统计技术80. Digital protection for power system电力系统数字保护81. Power system protection 电力系统(继电)保护82. V oltage quality in electrical power systems 电力系统电压质量83.Electric power applications of fuzzy systems 模糊系统的电力应用84. Artificial intelligence techniques in power system 电力系统中的人工智能技术85. Insulators in high voltages 高压绝缘体86. Electrical safety供电安全87. High voltageengineering and testing 高电压工程与试验88. Reactive power control in electric systems 电力系统无功(功率)控制89. Electical distribution engineering配电网工程90. Power systemplanning电力系统规划91. Uniquepower system problems 电力系统问题92. Tranmission and Distribution ofElectrical Energy 电力系统输配电93. Electric power system电力系统教程94. Computer-Aided Power systems analysis 计算机辅助电力系统分析95. Electric powertransmission system 输电系统96. Reliability Modelling in Electric power systems电力系统可靠性建模97. High voltage engineering in power system 电力系统高电压工程98. Extra High voltage AC transmission engineering 超高压交流输电工程99. Reliability evaluation of power system 电力系统可靠性评估100. Computation of power system transients 电力系统暂态计算101.Piecewise methods and application to power systems 分段法及其在电力系统中应用103. Analysis and protection of electrical power systems 电力系统分析与保护104. Power systems engineering and mathematicas电力系统工程与数学105. Stability of large power systems 大电力系统稳定性107. Power system reliability evaluation电力系统可靠性评估108.Electric power system dynamics 电力系统动态106. Power system stability handbook 电力系统稳定性手册109. Reliability assessment of large electric power systems 大电力系统可靠性评估110. Power system analysis and planning 电力系统分析与规划111. Electric transmission line fundamental 输电线(工程)基础112. HVDC power transmission systems 高压直流输电系统113. Transient Processes in electrical power systems 电力系统暂态过程114.Discrete Fourier transation and its applications to power system 离散傅立叶变换及其在电力系统中的应用115. Electrical Transients inpower system 电力系统暂态116. Optimal economic operation of electric power system 电力系统优化经济调度运行117.High power switching 大功率开关118. power plant engineering 电厂工程119. power plant system design 电厂系统设计120. power plant evaluation and design reference guide 电厂评估和设计参考导则121. planning engineering, and construction of electric power generationfacilities发电设备的规划和建设工程122. Elements electrical power station design 电站设计基础123.Optimal control applications in electric power systems 电力系统最优控制应用124. applied protected relaying应用继电保护125. power station and substation maintenance 电厂与变电站维修126. Power system operation 电力系统运行127. power system reliability,safety and management 电力系统可靠性,安全与管理128. Electric Machinery and power system fundamentals 电机与电力系统基础(MATLAB辅助)129. Intelligent system applications in power engineering (EP and ANN) 智能系统在电力工程中应用(进化计算和神经网)130. Thyristor-based FACTS controllers for electrical transmission systems 基于晶闸管的灵活交流输电系统控制器131. The economics of power system reliability and planning 电力系统可靠性与规划的经济学132. Computational Intelligence Applications to Power systems 计算智能在电力系统中的应用133. Environmental Impact of Power Generation 发电的环境影响134. Operation and Maintenance of Large Turbo-Generators 大型涡轮发电机组运行与检修135. Power system simulation 电力系统仿真136. Advanced load dispatch for power systems 电力系统高级调度137. The development of electric power transmission 电力传输进展138. Renewable Energy Sources 可再生发电源139. Power system dynamics andstablity 电力系统动态与稳定性140. Practical electrical network automation and communication systems 电力系统自动化与通信系统实践141. Electrical power and controls 电力与控制142. Deregulation of Electric Utilities 电力企业放松管制(市场改革)143. Computational Auction Mechanisms for restructured power industry operation 电力市场运行的(计算)投标机理144. Finanicial and economic evaluation of projects in the electricity supply industry 电力工程项目的金融与经济评价145. Electricity economics and planning 电力经济与规划146. Computational Methods for electric power systems 电力系统计算方法147. Power system relaying 电力系统继电保护148. Computer relaying for power systems 电力系统计算机保护149. Modern power system planning 现代电力系统规划150. High V oltage Engineering (2nd) 高电压工程151. Operation of restructured power systems 市场化电力系统运行152. Transer and Inductor Design Handbook变压器和电感设计手册(04增强版)153. Modern power system analysis (matlab supported) 现代电力系统分析(03年含MATLAB版)154. Power distribution planning reference book 配电规划参考手册155. Understanding FACTS 理解灵活交流输电系统156. Power system analysis :short-circuit load flow and harmonics 电力系统分析: 短路潮流和谐波157. Power systems electromagnetic transients simulation 电力系统电磁暂态仿真158. Power electronic control in electrical systems 电力系统中的电力电子控制159. Protection devices and systems for high-voltage applications保护装置和系统的高压应用160. Small signal analysis of power systems 电力系统小信号分析161. Electrical power cable engineering 电力线缆工程162. Power System State Estimation: Theory and Implementation 电力系统状态估计: 理论和实现163. Dielectrics in Electric Fields 电场中的电介质(绝缘体)164. spacecraft power system 航天器电力系统165. Grid integration of wind energy conversion systems 风能转换系统的电网整合(接入)166. Power loss: the origins of deregulation and restructuring in the American electricutility system网损:美国电力系统放松管制和市场化的根源167. High V oltage Circuit Breakers: Design and Applications 高压断路器:设计与应用168. Power system capacitors 电力系统电容器169. Energy Management Systems & Direct Digitial Control 能量管理系统(EMS)及直接数字控制170. Pricing in Competitive Electricity Market 电力市场电价171. Designing Competitive Electricity Markets 电力市场设计172. Power system dynamics and stability 电力系统动态与稳定性(美国)173. Theory and problems of electric power systems 电力系统的理论和问题174. Insulation coordinationfor power systems 电力系统绝缘配合175. Modal analysis of large interconnected power systems 大互联电力系统的模式分析176. Making competition work in electricity 电力市场竞争177. Power system operation 电力系统运行178. Transmission line reliability and security 输电线路安全可靠性179. Computer analysis of power systems 电力系统计算机分析180. Power system stability and control 电力系统稳定与控制。

电气工程的外文文献(及翻译)文献一：Electric power consumption prediction model based on grey theory optimized by genetic algorithms本文介绍了一种基于混合灰色理论与遗传算法优化的电力消耗预测模型。

该模型使用时间序列数据来建立模型，并使用灰色理论来解决数据的不确定性问题。

通过遗传算法的优化，模型能够更好地预测电力消耗，并取得了优异的预测结果。

此模型可以在大规模电力网络中使用，并具有较高的可行性和可靠性。

文献二：Intelligent control for energy-efficient operation of electric motors本文研究了一种智能控制方法，用于电动机的节能运行。

该方法提供了一种更高效的控制策略，使电动机能够在不同负载条件下以较低的功率运行。

该智能控制使用模糊逻辑方法来确定最佳的控制参数，并使用遗传算法来优化参数。

实验结果表明，该智能控制方法可以显著降低电动机的能耗，节省电能。

文献三：Fault diagnosis system for power transformers based on dissolved gas analysis本文介绍了一种基于溶解气体分析的电力变压器故障诊断系统。

通过对变压器油中的气体样品进行分析，可以检测和诊断变压器内部存在的故障类型。

该系统使用人工神经网络模型来对气体分析数据进行处理和分类。

实验结果表明，该系统可以准确地检测和诊断变压器的故障，并有助于实现有效的维护和管理。

文献四：Power quality improvement using series active filter based on iterative learning control technique本文研究了一种基于迭代研究控制技术的串联有源滤波器用于电能质量改善的方法。

毕业设计(论文)外文资料翻译专业名称：电力系统自动化英文资料：INDUCTION MOTOR STARTING METHODSAbstract -Many methods can be used to start large AC induction motors. Choices such as full voltage, reduced voltage either by autotransformer or Wyes - Delta, a soft starter, or usage of an adjustable speed drive can all have potential advantages and trade offs. Reduced voltage starting can lower the starting torque and help prevent damage to the load. Additionally, power factor correction capacitors can be used to reduce the current, but care must be taken to size them properly. Usage of the wrong capacitors can lead to significant damage. Choosing the proper starting method for a motor will include an analysis of the power system as well as the starting load to ensure that the motor is designed to deliver the needed performance while minimizing its cost. This paper will examine the most common starting methods and their recommended applications.I. INTRODUCTIONThere are several general methods of starting induction motors: full voltage, reduced voltage, wyes-delta, and part winding types. The reduced voltage type can include solid state starters, adjustable frequency drives, and autotransformers. These, along with the full voltage, or across the line starting, give the purchaser a large variety of automotives when it comes to specifying the motor to be used in a given application. Each method has its own benefits, as well as performance trade offs. Proper selection will involve a thorough investigation of any power system constraints, the load to be accelerated and the overall cost of the equipment.In order for the load to be accelerated, the motor must generate greater torque than the load requirement. In general there are three points of interest on the motor's speed-torque curve. The first is locked-rotor torque (LRT) which is the minimum torque which the motor will develop at rest for all angular positions of the rotor. The second is pull-up torque (PUT) which is defined as the minimum torque developed by the motor during the period of acceleration from rest to the speed at which breakdown torque occurs. The last is the breakdown torque (BDT) which is defined as the maximum torque which the motor will develop. If any of these points are below the required load curve, then the motor will not start.The time it takes for the motor to accelerate the load is dependent on the inertia of the load and the margin between the torque of the motor and the load curve, sometimes called accelerating torque. In general, the longer the time it takes for the motor to accelerate the load, the more heat that will be generated in the rotor bars, shorting ring and the stator winding. This heat leads to additional stresses in these parts and can have an impaction motor life.II. FULL VOLTAGEThe full voltage starting method, also known as across the line starting, is the easiest method to employ, has the lowest equipment costs, and is the most reliable. This method utilizes a control to close a contactor and apply full line voltage to the motor terminals. This method will allow the motor to generate its highest starting torque and provide the shortest acceleration times.This method also puts the highest strain on the power system due to the high starting currents that can be typically six to seven times the normal full load current of the motor. If the motor is on a weak power system, the sudden high power draw can cause a temporary voltage drop, not only at the motor terminals, but the entire power bus feeding the starting motor. This voltage drop will cause a drop in the starting torque of the motor, and a drop in the torque of any other motor running on the power bus. The torque developed by an induction motor varies roughly as the square of the applied voltage. Therefore, depending on the amount of voltage drop, motors running on this weak power bus could stall. In addition, many control systems monitor under voltage conditions, a second potential problem that could take a running motor offline during a full voltage start. Besides electrical variation of the power bus, a potential physical disadvantage of an across the line starting is the sudden loading seen by the driven equipment. This shock loading due to transient torques which can exceed 600% of the locked rotor torque can increase the wear on the equipment, or even cause a catastrophic failure if the load can not handle the torques generated by the motor during staring.A. Capacitors and StartingInduction motors typically have very low power factor during starting and as a result have very large reactive power draw. See Fig. 2. This effect on the system can be reduced by adding capacitors to the motor during starting.The large reactive currents required by the motor lag the applied voltage by 90 electrical degrees. This reactive power doesn't create any measurable output, but is rather the energy required for the motor to function. The product of the applied system voltage and this reactive power component can be measured in V ARS (volt-ampere reactive). The capacitors act to supply a current that leads the applied voltage by 90 electrical degrees. The leading currents supplied by the capacitors cancel the laggingcurrent demanded by the motor, reducing the amount of reactive power required to be drawn from the power system.To avoid over voltage and motor damage, great care should be used to make sure that the capacitors are removed as the motor reaches rated speed, or in the event of a loss of power so that the motor will not go into a generator mode with the magnetizing currents provided from the capacitors. This will be expanded on in the next section and in the appendix.B. Power Factor CorrectionCapacitors can also be left permanently connected to raise the full load power factor. When used in this manner they are called power factor correction capacitors. The capacitors should never be sized larger than the magnetizing current of the motor unless they can be disconnected from the motor in the event of a power loss.The addition of capacitors will change the effective open circuit time constant of the motor. The time constant indicates the time required for remaining voltage in the motor to decay to 36.8% of rated voltage after the loss of power. This is typically one to three seconds without capacitors.With capacitors connected to the leads of the motor, the capacitors can continue to supply magnetizing current after the power to the motor has been disconnected. This is indicated by a longer time constant for the system. If the motor is driving a high inertia load, the motor can change over to generator action with the magnetizingCurrent from the capacitors and the shaft driven by the load. This can result in the voltage at the motor terminals actually rising to nearly 50% of rated voltage in some cases. If the power is reconnected before this voltage decays severe transients can be created which can cause significant switching currents and torques that can severely damage the motor and the driven equipment. An example of this phenomenon is outlined in the appendix.Ⅲ. REDUCED VOLTAGEEach of the reduced voltage methods are intended to reduce the impact of motor starting current on the power system by controlling the voltage that the motor sees atthe terminals. It is very important to know the characteristics of the load to be started when considering any form of reduced voltage starting. The motor manufacturer will need to have the speed torque curve and the inertia of the driven equipment when they validate their design. The curve can be built from an initial, or break away torque, as few as four other data points through the speed range, and the full speed torque for the starting condition. A centrifugal or square curve can be assumed in many cases, but there are some applications where this would be problematic. An example would be screw compressors which have a much higher torque requirement at lower speeds than the more common centrifugal or fan load. See Fig. 3. By understanding the details of the load to be started the manufacturer can make sure that the motor will be able to generate sufficient torque to start the load, with the starting method that is chosen.A. AutotransformerThe motor leads are connected to the lower voltage side of the transformer. The most common taps that are used are 80%, 65%, and 50%. At 50% voltage the current on the primary is 25% of the full voltage locked rotor amps. The motor is started with this reduced voltage, and then after a pre-set condition is reached the connection is switched to line voltage. This condition could be a preset time, current level, bus volts, or motor speed. The change over can be done in either a closed circuit transition, or an open circuit transition method. In the open circuit method the connection to the voltage is severed as it is changed from the reduced voltage to the line level. Care should be used to make sure that there will not be problems from transients due to the switching. This potential problem can be eliminated by using the closed circuit transition. With the closed circuit method there is a continuousVoltage applied to the motor. Another benefit with the autotransformer starting is in possible lower vibration and noise levels during starting.Since the torque generated by the motor will vary as the square of the applied voltage, great care should be taken to make sure that there will be sufficient accelerating torque available from the motor. A speed torque curve for the driven equipment along with the inertia should be used to verify the design of the motor. A good rule of thumb is to have a minimum of 10% of the rated full load torque of the motor as a margin at all points of the curve.Additionally, the acceleration time should be evaluated to make sure that the motor has sufficient thermal capacity to handle the heat generated due to the longeracceleration time.B. Solid State or Soft StartingThese devices utilize silicon controlled rectifiers or Scars. By controlling the firing angle of the SCR the voltage that the device produces can be controlled during the starting of the motor by limiting the flow of power for only part of the duration of the sine wave.The most widely used type of soft starter is the current limiting type. A current limit of 175% to 500% of full load current is programmed in to the device. It then will ramp up the voltage applied to the motor until it reaches the limit value, and will then hold that current as the motor accelerates.Tachometers can be used with solid state starters to control acceleration time. Voltage output is adjusted as required by the starter controller to provide a constant rate of acceleration.The same precautions in regards to starting torque should be followed for the soft starters as with the other reduced voltage starting methods. Another problem due to the firing angle of the SCR is that the motor could experience harmonic oscillating torques. Depending on the driven equipment, this could lead to exciting the natural frequency of the system.C. Adjustable Frequency DrivesThis type of device gives the greatest overall control and flexibility in starting induction motors giving the most torque for an amount of current. It is also the most costly.The drive varies not only the voltage level, but also the frequency, to allow the motor to operate on a constant volt per hertz level. This allows the motor to generate full load torque throughout a large speed range, up to 10:1. During starting, 150% of rated current is typical.This allows a significant reduction in the power required to start a load and reduces the heat generated in the motor, all of which add up to greater efficiency. Usage of the AFD also can allow a smaller motor to be applied due to the significant increase of torque available lower in the speed range. The motor should still be sizedlarger than the required horsepower of the load to be driven. The AFD allows a great degree of control in the acceleration of the load that is not as readily available with the other types of reduced voltage starting methods.The greatest drawback of the AFD is in the cost relative to the other methods. Drives are the most costly to employ and may also require specific motor designs to be used. Based on the output signal of the drive, filtered or unfiltered, the motor could require additional construction features. These construction features include insulated bearings, shaft grounding brushes, and insulated couplings due to potential shaft current from common mode voltage. Without these features, shaft currents, which circulate through the shaft to the bearing, through the motor frame and back, create arcing in the bearings that lead to premature bearing failure, this potential for arcing needs to be considered when applying a motor/drive package in a hazardous environment, Division2/Zone2.An additional construction feature of a motor used on an AFD may require is an upgraded insulation system on the motor windings. An unfiltered output signal from a drive can create harmonic voltage spikes in the motor, stressing the insulation of the motor windings.It is important to note that the features described pertain to motors which will be started and run on an AFD. If the drive is only used for starting the motor, these features may not be necessary. Consult with the motor manufacturer for application specific requirements.D. Primary Resistor or Reactor StartingThis method uses either a series resistor or reactor bank to be placed in the circuit with the motor. Resistor starting is more frequently used for smaller motors.When the motor is started, the resistor bank limits the flow of inrush current and provides for a voltage drop at the motor terminals. The resistors can be selected to provide voltage reductions up to 50%. As the motor comes up to speed, it develops a counter EMF (electro-magnetic field) that opposes the voltage applied to the motor. This further limits the inrush currents. As the inrush current diminishes, so does t>e voltage drop across the resistor bank allowing the torque generated by the motor to increase. At a predetermined time a device will short across the resistors and open the starting contactor effectively removing the resistor bank from the circuit. This provides for a closed transition and eliminates the concerns due to switchingtransients.Reactors will tend to oppose any sudden changes in current and therefore act to limit the current during starting. They will remain shorted after starting and provide a closed transition to line voltage.E .Star delta StartingThis approach started with the induction motor, the structure of each phase of the terminal are placed in the motor terminal box. This allows the motor star connection in the initial startup, and then re-connected into a triangle run. The initial start time when the voltage is reduced to the original star connection, the starting current and starting torque by 2 / 3. Depending on the application, the motor switch to the triangle in the rotational speed of between 50% and the maximum speed. Must be noted that the same problems, including the previously mentioned switch method, if the open circuit method, the transition may be a transient problem. This method is often used in less than 600V motor, the rated voltage 2.3kV and higher are not suitable for star delta motor start method.Ⅴ. INCREMENT TYPEThe first starting types that we have discussed have deal with the way the energy is applied to the motor. The next type deals with different ways the motor can be physically changed to deal with starting issues.Part WindingWith this method the stator of the motor is designed in such a way that it is made up of two separate windings. The most common method is known as the half winding method. As the name suggests, the stator is made up of two identical balanced windings. A special starter is configured so that full voltage can be applied to one half of the winding, and then after a short delay, to the second half. This method can reduce the starting current by 50 to 60%, but also the starting torque. One drawback to this method is that the motor heating on the first step of the operation is greater than that normally encountered on across-the-line start. Therefore the elapsed time on the first step of the part winding start should be minimized. This method also increases the magnetic noise of the motor during the first step.IV .ConclusionThere are many ways asynchronous motor starting, according to the constraints of power systems, equipment costs, load the boot device to select the best method. From the device point of view, was the first full-pressure launch the cheapest way, but it may increase the cost efficiency in the use of, or the power supply system in the region can not meet their needs. Effective way to alleviate the buck starts the power supply system, but at the expense of the cost of starting torque.These methods may also lead to increased motor sizes have led to produce the required load torque. Inverter can be eliminated by the above two shortcomings, but requires an additional increase in equipment costs. Understand the limitations of the application, and drives the starting torque and speed, allowing you for your application to determine the best overall configuration.英文资料翻译：异步电动机起动的方法摘要：大容量的交流异步电动机有多种启动方法。

Electric Power SystemElectrical power system refers to remove power and electric parts of the part,It includes substation, power station and distribution. The role of the power grid is connected power plants and users and with the minimum transmission and distribution network disturbance through transport power, with the highest efficiency and possibility will voltage and frequency of the power transmission to the user fixed .Grid can be divided into several levels based on the operating voltage transmission system, substructure, transmission system and distribution system, the highest level of voltage transmission system is ZhuWangJia or considered the high power grids. From the two aspects of function and operation, power can be roughly divided into two parts, the transmission system and substation. The farthest from the maximum output power and the power of the highest voltage grade usually through line to load. Secondary transmission usually refers to the transmission and distribution system is that part of the middle. If a plant is located in or near the load, it might have no power. It will be direct access to secondary transmission and distribution system. Secondary transmission system voltage grade transmission and distribution system between voltage level. Some systems only single second transmission voltage, but usually more than one. Distribution system is part of the power system and its retail service to users, commercial users and residents of some small industrial users. It is to maintain and in the correct voltage power to users responsible. In most of the system, Distribution system accounts for 35% of the total investment system President to 45%, and total loss of system of the half .More than 220kv voltage are usually referred to as Ultra high pressure, over 800kv called high pressure, ultra high voltage and high pressure have important advantages, For example, each route high capacity, reduce the power needed for the number of transmission. In as high voltage to transmission in order to save a conductor material seem desirable, however, must be aware that high voltage transmission can lead to transformer, switch equipment and other instruments of spending increases, so, for the voltage transmission to have certain restriction, allows it to specific circumstances in economic use. Although at present, power transmission most is through the exchange of HVDC transmission, and the growing interest in, mercury arc rectifier and brake flow pipe into the ac power generation and distribution that change for the high voltage dc transmission possible.Compared with the high-voltage dc high-voltage ac transmission has the following some advantages: (1) the communication with high energy; (2) substation of simple maintenance and communication cost is low; (3) ac voltage can easily and effectively raise or lower, it makes the power transmission and high pressure With safety voltage distributionHVDC transmission and high-voltage ac transmission has the following advantages: (1) it only need two phase conductors and ac transmission to three-phase conductors; (2) in the dc transmission impedance, no RongKang, phase shift and impact overvoltage; (3) due to the same load impedance, no dc voltage, and transfer of the transmission line voltage drop less communication lines, and for this reason dc transmission line voltage regulator has better properties; (4) in dc system without skin effect. Therefore, the entire section of route conductors are using; (5) for the same work, dc voltage potential stress than insulation. Therefore dc Wire need less insulation; (6) dc transmission line loss, corona to little interference lines of communication; (7) HVDC transmission without loss of dielectric, especially in cable transmission; (8) in dc system without stability and synchronization of trouble.A transmission and the second transmission lines terminated in substation or distribution substations, the substation and distribution substations, the equipment including power and instrument transformer and lightning arrester, with circuit breaker, isolating switch, capacitor set, bus and a substation control equipment, with relays for the control room of the equipment. Some of the equipment may include more transformer substations and some less, depending on their role in the operation. Some of the substation is manual and other is automatic. Power distribution system through the distribution substations. Some of them by many large capacity transformer feeders, large area to other minor power transformer capacity, only a near load control, sometimes only a doubly-fed wire feeders (single single variable substation)Now for economic concerns, three-phase three-wire type communication network is widely used, however, the power distribution, four lines using three-phase ac networks.Coal-fired power means of main power generating drive generators, if coal energy is used to produce is pushing the impeller, then generate steam force is called the fire. Use coal produces steam to promote the rotating impeller machine plant called coal-fired power plants. In the combustion process, the energy stored in the coal to heat released,then the energy can be transformed into the form within vapor. Steam into the impeller machine work transformed into electrical energy.Coal-fired power plants could fuel coal, oil and natural gas is. In coal-fired power plant, coal and coal into small pieces first through the break fast, and then put out. The coal conveyer from coal unloader point to crush, then break from coal, coal room to pile and thence to power. In most installations, according to the needs of coal is, Smash the coal storage place, no coal is through the adjustable coal to supply coal, the broken pieces of coal is according to the load changes to control needs. Through the broken into the chamber, the coal dust was in the second wind need enough air to ensure coal burning.In function, impeller machine is used to high temperature and high pressure steam energy into kinetic energy through the rotation, spin and convert electricity generator. Steam through and through a series of impeller machine parts, each of which consists of a set of stable blade, called the pipe mouth parts, even in the rotor blades of mobile Li called. In the mouth parts (channel by tube nozzle, the steam is accelerating formation) to high speed, and the fight in Li kinetic energy is transformed into the shaft. In fact, most of the steam generator is used for air is, there is spread into depression, steam turbine of low-pressure steam from the coagulation turbine, steam into the condenses into water, and finally the condensate water is to implement and circulation.In order to continuous cycle, these must be uninterrupted supply: (1) fuel; (2) the air (oxygen) to the fuel gas burning in the configuration is a must; (3) and condenser, condensed from the condensed water supply, sea and river to lake. Common cooling tower; (4) since water vapour in some places in circulation, will damage process of plenty Clean the supply.The steam power plant auxiliary system is running. For a thermal power plant, the main auxiliary system including water system, burning gas and exhaust systems, condensation system and fuel system. The main auxiliary system running in the water pump, condensation and booster pump, coal-fired power plants in the mill equipment. Other power plant auxiliary equipment including air compressors, water and cooling water system, lighting and heating systems, coal processing system. Auxiliary equipment operation is driven by motor, use some big output by mechanical drive pump and some of the impeller blades, machine drive out from the main use of water vaporimpeller machine. In coal-fired power plant auxiliary equipment, water supply pump and induced draft fan is the biggest need horsepower.Most of the auxiliary power generating unit volume increased significantly in recent years, the reason is required to reduce environment pollution equipment. Air quality control equipment, such as electrostatic precipitator, dust collection of flue gas desulfurization, often used in dust in the new coal-fired power plants, and in many already built in power plant, the natural drive or mechanical drive, fountain, cooling tower in a lake or cooling canal has been applied in coal-fired power plants and plants, where the heat release need to assist cooling system.In coal-fired power stations, some device is used to increase the thermal energy, they are (1) economizer and air preheater, they can reduce the heat loss; (2) water heater, he can increase the temperature of water into boiling water heaters; (3) they can increase and filter the thermal impeller.Coal-fired power plants usually requires a lot of coal and coal reservoirs, however the fuel system in power plant fuel handling equipment is very simple, and almost no fuel oil plants.The gas turbine power plants use gas turbine, where work is burning gas fluid. Although the gas turbine must burn more expensive oil or gas, but their low cost and time is short, and can quickly start, they are very applicable load power plant. The gas turbine burn gas can achieve 538 degrees Celsius in the condensing turbine, however, the temperature is lower, if gas turbine and condenser machine, can produce high thermal efficiency. In gas turbine turbine a combined cycle power plant. The gas through a gas turbine, steam generator heat recovery in there were used to generate vapor heat consumption. Water vapor and then through a heated turbine. Usually a steam turbine, and one to four gas turbine power plant, it must be rated output power.。

Faults on Power SystemsEach year new design of power equipment bring about increased reliability of operation. Nevertheless, equipment failures and interference by outside sources occasionally result in faults on electric power systems. On the occurrence of a fault , current an voltage conditions become abnormal, the delivery of power from the generating station to the loads may be unsatisfactory over a considerable area, and if the faulted equipment is not promptly disconnected from the remainder of the system, damage may result to other pieces of operating equipment.A faulty is the unintentional or intentional connecting together of two or more conductors which ordinarily operate with a difference of potential between them. The connection between the conductors may be by physical metallic contact or it may be through an arc. At the fault, the voltage between the two parts is reduced to zero in the case of metal-to-metal contacts, or to a very low value in case the connection is through an arc. Currents of abnormally high magnitude flow through the network to the point of fault. These short-circuit currents will usually be much greater than the designed thermal ability of the condition in the lines or machines feeding the fault . The resultant rise in temperature may cause damage by the annealing of conductors and by the charring of insulation. In the period during which the fault is permitted to exist, the voltage on the system in the near vicinity of the fault will be so low that utilization equipment will be inoperative. It is apparent that the late conditions that exist during a fault, and provide equipment properly adjusted to open the switches necessary to disconnect the faulted equipment from the remanding of the system. Ordinarily it is desirable that no other switches on the system are opened, as such behavior would result in unnecessary modification the system circuits.A distinction must be made between and an overload. An overload implies only that loads greater than the designed values have been imposed on system. Under such a circumstance the voltage at the overload point may be low, but not zero. This undervoltage condition may extend for some distance beyond the overload point into the remainder of the system. The current in the overload equipment are high and may exceed the thermal design limits. Nevertheless, such currents are substantially lower than in the case of a fault. Service frequently may be maintained, but at below-standard voltage.Overloads are rather common occurrences in homes. For example, a housewife might plug five waffle irons into the kitchen circuit during a neighborhood part. Such an overload, if permitted to continue, would cause heating of the wires from the power center and might eventually start a fire. To prevent such trouble, residential circuits are protected by fuses or circuit breakers which open quickly when currents above specified values persist. Distribution transformers are sometimes overloads as customers install more and more appliances. The continuous monitoring of distribution circuits is necessary to be certain that transformers sizes are increased as load grows.Faults of many types and causes may appear on electric power systems. Many of us in our homes have seen frayed lamp cords which permitted the two conductors of the cord to come in contact with each other. When this occurs, there is a resulting flash, and if breaker or fuse equipment functions properly, the circuit is opened.Overhead lines, for the most part, are constructed of bare conductors. There are sometimes accidentally brought together by action of wind, sleets, trees, cranes, airplanes, or damage to supporting structures. Overvoltages due to lighting or switching nay cause flashover of supporting or from conductor to conductor. Contamination on insulators sometimes results in flashover even during normal voltage conditions.The conductors of underground cables are separated from each and from ground by solid insulation, which nay be oil-impregnated paper or a plastic such polyethylene. These materials undergo somedeterioration with age, particularly if overloads on the cables have resulted in their operation at elevated temperature. Any small void present in the body of the insulating material will results in ionization of the gas contained therein, the products of which react unfavorably with the insulation. Deterioration of the insulation may result in failure of the material to retain its insulating properties, and short circuits will develop between the cable conductors. The possibility of cable failure is increased if lightening or switching produces transient voltage of abnormally high values between the conductors.Transformer failures may be the result of insulation deterioration combined with overvoltage due to lightning or switching transients. Short circuit due to insulation failure between adjacent turns of the same winding may result from suddenly applied overvoltage. Major insulation may fail, permitting arcs to be established between primary and secondary windings or between winding and grounded metal parts such as the core or tank.Generators may fail due to breakdown of the insulation between adjacent turns in the same slot, resulting in a short circuit in a single turn of the generator. Insulation breakdown may also occur between one of the winding and the grounded steel structure in which the coils are embedded. Breakdown between different windings lying in the same slot results in short-circuiting extensive section of machine.Balanced three-phase faults, like balanced three-phase loads, may be handled on a lineto-neutral basis or on an equivalent single-phase basis. Problems may be solved either in terms of volts, amperes, and ohms. The handing of faults on single-phase lines is of course identical to the method of handing three-phase faults on an equivalent single-phase basis.Faults may be classified as permanent or temporary. Permanent faults are those in which insulation failure or structure failure produces damage that makes operation of the equipment impossible and requires repairs to be made. Temporary faults are those which may be removed by deenergizing the equipment for a short period of time, short circuits on overhead lines frequently are of this nature. High winds may cause two or more conductions to swing together momentarily. During the short period of contact. An arc is formed which may continue as long as line remains energized. However, if automatic equipment can be brought into operation to service as soon as the are is extinguished. Arcs across insulators due to overvoltages from lighting or switching transients usually can be cleared by automatic circuit-breaker operation before significant structure damage occurs.Because of this characteristic of faults on lines, many companies operate following a procedure known as high-speed reclosing. On the occurrence of a fault, the line is promptly deenergized by opening the circuit breakers at each end of the line. The breakers remain open long enough for the arc to clear, and then reclose automatically. In many instances service is restored in a fraction of a second. Of course, if structure damage has occurred and the fault persists, it is necessary for the breakers to reopen and lock open.电力系统故障每年新设计的电力设备都使系统的可靠性不断提高，然而，设备的使用不当以及一些偶然遇到的外在因素均会导致系统故障的发生。

A realistic approach for reduction of energy losses in low voltage distribution networkabstractThis paper proposes reduction of energy losses in low voltage distribution network using Lab VIEW as simulation tool. It suggests a methodology for balancing load in all three phases by predicting and controlling current unbalance in three phase distribution systems by node reconfiguration solution for typical Indian scenario. A fuzzy logic based load balancing technique along with optimization oriented expert system for implementing the load changing decision is proposed. The input is the total phase current for each of the three phases. The average unbalance per phase is calculated and checked against threshold value. If the average unbalance per phase is below threshold value, the system is balanced. Otherwise, it goes for the fuzzy logic based load balancing. The output from the fuzzy logic based load balancing is the value of load to be changed for each phase. A negative value indicates that the specific phase is less loaded and should receive the load, while a positive value indicates that the specific phase is surplus load and should release that amount of load. The load change configuration is the input to the expert system which suggests optimal shifting of the specific number of load points, i.e., the consumers.1. IntroductionAmong three functional areas of electrical utility namely, generation, transmission and distribution, the distribution sector needs more attention as it is very difficult to standardize due to its complexity. Transmission and distribution losses in India have been consistently on the higher side in the range of 21–23%. Out of these losses, 19% is at distribution level in which 14% is contributed by technical losses. This is due to inadequate investments for system improvement work. To reduce technical losses, the important parameters are inadequate reactive compensation, unbalance of current and voltage drops in the system. There are two main distribution network lines namely, primary distribution lines (33 kV/22 kV/11 kV) and secondary distribution lines (415 V line voltage). Primary distribution lines are feeding HT consumers and are regularized by insisting the consumers to maintain power factor of 0.9 and above and their loads in all three phases is mostly balanced. The energy loss control becomes a critical task in secondary distribution network due to the very complex nature of the network.Distribution Transformer caters to the needs of varying consumers namely Domestic, Commercial, Industrial, Public lighting, Agricultural, etc. Nature of load also varies as single phase load and three phase load. The system is dynamic and ever expanding. It requires fast response to changes in load demand, component failures and supply outages. Successful analysis of load data at the distribution level requiresprocedures different from those typically in use at the transmission system level. Several researchers have proposed methods for node reconfiguration in primary distribution network [1–11]. Two types of switches used in primary distribution systems are normally closed switches (sectionalizing switches) and normally open switches (tie switches). Those two types of switches are designed for both protection and configuration management and by altering the open/ closed status of switches loss reduction and optimization of primary distribution network can be achieved. Siti et al. [12] discussed reconfiguration algorithms in secondary distribution network with load connections done via a switching matrix with triacs and hence costly alternative for developing countries. Much work needs to be done in the secondary distribution network where lack of information is an inherent characteristic. For example in most of the developing countries (India, China, Brazil, etc.) the utilities charge the consumers based on their monthly electric energy consumption. It does not reflect the day behaviour of energy consumption and such data are insufficient for distribution system analysis.Conventionally, to reduce the unbalance current in a feeder the load connections are changed manually after field measurement and software analysis. Although this process can improve the phase current unbalance, this strategy is more time consuming and erroneous. The more scientific process of node reconfiguration of LV network which involves thearrangement of loads or transfer of load from heavily loaded area to the less loaded area is needed. This paper focuses on this objective. In the first stage, the energy meter reading from secondary of Distribution Transformer is downloaded and is applied as input to Lab-VIEW based distribution simulation package to study the effects of daily load patterns of a typical low voltage network (secondary distribution network). The next stage is to develop an intelligent model capable of estimating the load unbalance on a low voltage network in any hour of day and suggesting node reconfiguration to balance the currents in all three phases.Objectives are to:Study the daily load pattern of low voltage network of Distribution Transformer by using Lab VIEW.Study the unbalance of current in all three phases and power factor compensation in individual phases.Develop distribution simulation package.The distribution simulation package contains fuzzy logic based load balancing technique and fuzzy expert system to shift the number of consumers from over loaded phase to under loaded phase.2. Existing systemIn the existing system of distribution network, the energymeters are provided for energy accounting, but there is no means of sensingunbalance currents, voltage unbalance and power factor correction requirement for continuous 24 h in three phases of LT feeder. In other words, instantaneous load curves, voltage curves, energy curves and power factor curves for individual three phases are not available for monitoring, analyzing and controlling the LV network. The individual phase of Distribution Transformer could be monitored only by taking reading whenever required and if there is unequal distribution of load in three phases, the consumer loads are shifted from overloaded phase to under loaded phase of distribution LT feeder by the field staff in charge of the Distribution Transformer. There is no scientific methodology at present.3. Proposed systemIn the proposed system, Lab VIEW is used as software simulation tool [13]. In the existing system of distribution network, the Distribution Transformers are fixed with energy meters in the Secondary of the Distribution Transformer and energy meter readings can be downloaded with Common Meter Reading Instrument (CMRI instrument). The energy meter reading includes VI profile and it can be used for the power measurement.4. Monitoring parametersThe phase voltages and the line currents of all three phases are available every half an hour and the voltage curve and load curve are obtained fromthese values. The active, the reactive and the apparent power are computed from these quantities after the phase angle is determined. The following parameters are plotted:1. Individual phase voltage.2. Individual phase current.3. Individual phase active power.4. Individual phase reactive power.5. Individual phase apparent power.6. Individual phase power factor.With the above concepts, the front panel and block diagram are developed for unbalanced three phase loads by downloading the VI profile from energy meter installed in the Distribution Transformer and simulating the setup using practical values. From the actual values obtained load unbalance is predicted using fuzzy logic and node reconfiguration is suggested using expert system.The Lab VIEW front panel displays the VI profile on a particular date with power and energy measurement as in Table 1. The Lab VIEW reads the VI profile and computes the real power, reactive power, apparent power and energy, kWh.4.1. Prediction of current unbalanceThe maximum current consumption in each phase is IRmax, IYmax, and IBmax. The optimum current (Iopt) is given in the following equation:()3max max max B Y R opt I I I I ++=The difference between opt I and m ax R I is then determined. Similarly thedifference between opt I and max Y I , opt I and max B I is computed. If thedifference is positive then that phase is considered as overloaded and if the difference is negative then that phase is considered to be under loaded. If the difference is within the threshold value, then that load is perfectly balanced.To balance the current in three phases, if the difference between opt I and m ax R I is less than threshold value then that phase is left as such.Otherwise, if the difference is greater than threshold value, some of the consumers are suggested reconfiguration from overloaded phase to under loaded phase using expert system.5. Fuzzy based load balancingA fuzzy logic based load balancing technique is proposed along with combinatorial optimization oriented expert system for implementing the load changing decision. The flowchart of the proposed system is shown in Fig. 1. Here the input is the total phase current for each of the three phases. Typical loads on low voltage networks are stochastic by nature. However it has been ensured that there is similarity in stochastic nature throughout the day as seen from load graph of Distribution Transformer as shown in Fig. 6. It has been verified that if R phase is overloaded followed by Y phase and thenB phase the same load pattern continuesthroughout the day.The average unbalance per phase is calculated as (IRmax _ Iopt) for R phase, (IYmax _ Iopt) for Y phase and (IBmax _ Iopt) for B phase and is checked against a threshold value (allowed unbalance current) of 10 A. If the average unbalance per phase is below 10 A, it can be assumed that the system is more or less balanced and discard any further load balancing. Otherwise, it goes for the fuzzy logic based load balancing. The output from the fuzzy logic based load-balancing step is the load change values for each phase.This load change configuration is the input to the expert system, which tries to optimally suggest shifting of specific number of load points. However, sometimes the expert system may not be able to execute the exact amount of load change as directed by the fuzzy step. This is because the actual load points for any phase might not result in a combination which sums up to the exact change value indicated by the fuzzy controller however optimization is achieved because of balancing attempted during peak hours of the day of the load graph.5.1. Fuzzy controller: input and outputTo design the fuzzy controller, at first the input and output variables are to be designed. For the load balancing purpose, the inputs selected are ‘phase current’ i.e., the individual phase current for each of the three phases and optimum current required and the output as ‘change’, i.e., thechange of load (positive or negative) to be made for each phase. For the input variable, Table 2 and Fig. 2 show the fuzzy nomenclature and the triangular fuzzy membership functions. And for the output variable, Table 3 shows the fuzzy nomenclature and Fig. 3 the corresponding triangular fuzzy membership functions.The IF-THEN fuzzy rule set governing the input and output variable is described in Table 4.5.2. Fuzzy expert systemA fuzzy expert system is an expert system that uses a collection of fuzzy membership functions and rules, instead of Boolean logic, to reason out data. The rules in a fuzzy expert system are usually of a form similar to the following:If x is low and y is high then z = mediumwhere x and y are input variables (names for known data values), z is an output variable (a name for a data value to be computed), low is a membership function (fuzzy subset) defined on x, high is a membership function defined on y, and medium is a membership function defined on z .The antecedent (the rule’s premise) describes to what degree the rule applies, while the conclusion (the rule’s consequent) assigns a membership function to each of one or more output variables. Most tools for working with fuzzy expert systems allow more than one conclusion per rule. The set of rules in a fuzzy expert system is known as the rulebase or knowledge base.The load change configuration is the input to the expert system which tries to optimally shift the specific number of load points. The following are the objectives of the expert system:_ Minimum switching._ Minimum losses._ Satisfying the voltage and current constraints.Fg. 4 shows the block diagram of the expert system. The inputs to the expert system are the value added or subtracted to that particular phase from the fuzzy controller and the current consumption of the individual consumers on that particular phase. The expert system should display which of the consumers are to be shifted from the overloaded phase to under loaded phase and also displays the message NO CHANGE if that phase is balanced.6. Simulation resultsTable 1 shows the display of output of Lab-VIEW based power and energy measurement [14]. It asks for the Distribution Transformer secondary reading, date, tolerance value (threshold value), and fuzzy conditioner of three phases for load balancing. It then displays the date, time, voltage, current, power factor, real power, reactive power, apparent power.Fig. 5 shows the line voltage curve for R, Y and B phases. It alsoindicates the voltage drop during peak hours of the day. The current curve for R, Y and B phases is shown in Fig. 6. It indicates the current unbalance in the existing supply network. The load graph from typical Distribution Transformer for entire day indicates interesting similarity in load patterns of consumers. Hence load balancing attempted during peak load band yielded fruitful result for the entire day.Fig. 7 displays the results of fuzzy logic based load balancing technique. Fuzzy toolkit in Lab VIEW is used for simulation. Mamdani fuzzy inference technique is applied and centroid based defuzzication technique is employed in the load balancing system. The output from the fuzzy controller is the value that is to be subtracted or added to a particular phase. The positive value indicates that the specific phase is overloaded and it should release the amount of load. The negative value indicates that the specific phase is under loaded and it should receive the amount of load. The value less than 10 A indicate that phase is perfectly loaded. Fig. 8 show the expert system output for all three phases. It gives the Service connection number (SC No.) and current consumption of individual consumer. The output of the fuzzy controller is applied as the input to the expert system. If the output of the fuzzy controller is a positive value then the expert system should inform which of the consumers are to be shifted from that phase.From Fig. 8, the R phase is overloaded, so the expert system informs thatthe SC No.’s 56 and 23 should be shifted. The output of the fuzzy controller for the Y phase is less than threshold value 10 A so that phase is perfectly loaded. The output of the fuzzy controller for B phase is a negative value; hence it receives the load from R-phase. There is no shifting of consumer in Y phase and B phase therefore the entries are indicated by zero values. There is no switching arrangement in secondary low voltage distribution network in Indian scenario and hence shifting to be done manually.The suggested approach has been tested practically on 70 nodes (70 consumers) low voltage distribution network and results are as shown in Fig. 9 (before balancing) and Fig. 10 (after balancing). Single phase customers physically reconfigured from overloaded phase into under loaded phase and then test results studied. Unbalancing has been observed for 10 days and then balancing attempted. Balanced network was studied and then results obtained. There is a percentage reduction in Energy loss from 9.695% to 8.82% though there is increase in cumulative kWh from 1058.95 to 1065.9. This Distribution Transformer belongs to urban area of a typical Indian city and has 41 single phase consumers and 29 three-phase consumers and three-phase consumers have balanced loads. In rural areas where number of single phase consumers are predominant and scattered around lengthy distribution lines this balancing technique will be much more beneficial than the tested study indicates.This research is significant to the Indian scenario considering the fact that there are 180,763 Distribution Transformers (www.tneb.in) and 2,07,00,000 consumers and length of secondary distribution network 5,17,604 km in one state, Tamil Nadu alone, 1% saving in energy loss per transformer per day will save few crores of rupees for a month to electrical utility.7. ConclusionIn this paper, the complete online monitoring of low voltage distribution network is done by using Lab VIEW and the fuzzy logic based load balancing technique is presented. With the results obtained from Lab VIEW, currents in individual phases are predicted and unbalance pattern is studied without actually measuring instantaneous values from consumer premise.A fuzzy logic based load balancing is implemented to balance the current in three phases and expert system to reconfigure some of the consumers from over loaded phase to under loaded phase. The input to the fuzzy controller is the individual phase current. The output of the fuzzy controller is the load change value, negative value for load receiving and positive value for load releasing. Expert system performs the optimal interchanging of the load points between the releasing and receiving phases.The proposed phase balancing system using fuzzy logic and expertsystem is effective for reducing the phase unbalance in the low voltage secondary distribution network. The energy losses are reduced and efficiency of the distribution network is improved and has been practically studied in typical Distribution Transformer of electrical utility.图一图2图3 图4图5图6图7图8图9图10。

电力专业英语英文文献翻译报告Page 1.The Production of Electrical Energy(电能生产)1 English textFrom reference 1Should the generation be not adequate to balance the load demand, it is imperative that one of following alternatives be considered for keeping the system in operating condition:1. Staring fast peaking units,2. Load shedding for unimportant loads,3. generation rescheduling.It is apparent from the above that since the voltage specifications are not stringent, load frequency control is by far the most important in power system control.In order to understand the frequency control, consider a small step-increase in load. The initial distribution of the load increment is determined by the system simpedance; and the sistantaneous relative generator rotor positions. The energy required to supply the load increment is drawn from the kinetic energy of rotating machines. As a result, the system frequency drops. The distribution of load during this period among the various machines is determined by the inertias of the rotors of the generators partaking in process. This problem is stability analysis of the system.After the speed or frequency fall due to reduction in stored energy in the rotors has taken place, the drop is sensed by the governors and they divide the load increment between the machines as determined by the droops of the respective governor characterstics. Subsequently, secondary control restores the system frequency to its normal value by readjustingthe governor characteristics. Keywords：load frequency control From reference 2Modern power systems are so large that it is impossible to design a single central control system that would handle the overall control job. It is extremely useful take into account the weak links in the system and then apply control through decomposition. The demarcation of load frequency control and Mavar voltage control characteristics is one such decomposition. Geographical and functional decomposition are successfully applied to power systems and this leads to the concept of area control.A modern power system can be divided into several areas for load frequency control. Each control area fulfils the following:1.The area is a geographically contious portion of a large interconnected area, which adjusts its own generation to accommodate load changes within its precincts.2.Under normal conditions of operation, it changes bulk power with neighboring areas.3.Under abnormal conditions of operation, it may deviate from predetermined schedules and provide assistance to any neighboring control area in the system.4.It is expected, in addition, to partake with the other areas in the system in a suitable manner in the system frequency regulation.The rotors of all generators in a control area swing together for load change. Thus, a coherent group of generators within a geographical region may constitute a control area which is connected to other similar areas by weak tie lines.Keywords：areas load frequency controlFrom reference 3For plant loading schedules in thermal systems, load prediction up to two hours in advance is necessary while for unit commitment schedules prediction up to 24 hours is sufficient. Also, at all sations and control centers, short-time prediction is needed for storage and display of advance information. Based on this information, predictive security assessment of the system is made. This also helps to contain the rates of change of generator outputs within their permissible limits.For the implementation of economic scheduling of generation using digital computers, detailed estimates of the future load demands are essential in order to allow sufficient time for the calculation and implementation of the generator schedules. Whatever method is envisaged for the calculation of such economic schedules consistent with the security and spare requirements of the system, the schedules should be calculated every 15 or 30 minutes and each economic schedule should be a predictive one ,for at least about 30 minutes ahead of event. It is then obvious that the predictions are to be revised frequently in the light of any fresh information so as to minimize the estimation errors.Peak load demand forecasts are useful in determining the investment required for additional generating and transmission capacities required. Forecasts for planning require data extending over several previous years. Meaningful forecasts can be obtained with lead time of 3 to 5 years.Keywords：load predictionFrom reference 4In this method, the load is separated into two main components. The first component is a base load which is of fixed value and the second a variable component which is a functionof the weather conditions.Estimates can be made 24 hours ahead, using the weather forecast. The temperature base for weighting the effect of the predicated temperature on the load is the normal, mean temperature of the month. The normal, mean temperature of the month has zero weight. Similarly the change in consumers demand due to cloudy weather may be assumed to vary in direct proportion to the degree of cloudiness. This in turn may be expressed by an illumination index with fair, clear sky corresponding to zero weight.The base load is determined from past records. Proper weighting of the elements of the weather will be attained only after several trials. The method of prediction stabilizes after this trial period. It may be noted that the base loads for week days and weekend will generally be different for any hour.Using these base loads, a load estimate based on the best available weather forecast can be made using proper weighting of meteorological factors like temperature, cloudiness, wind velocity, etc.Keywords：proper weighting of the elements of the weather2 中文翻译及分析出自文献1：万一发电量不足以平衡负荷需求，要使电力系统处于运行状态，必须考虑采取以下选择方法中的一种：1、启动快速峰荷机组2、对不重要的用户实行拉闸断电3、重新制定发电计划从上述情况来看，电压技术的要求并不严格，目前为止负荷频率控制是电力系统控制中最重要的手段。

（完整版）电力系统外文英语文献资料Electric Power SystemElectrical power system refers to remove power and electric parts of the part,It includes substation, power station and distribution. The role of the power grid is connected power plants and users and with the minimum transmission and distribution network disturbance through transport power, with the highest efficiency and possibility will voltage and frequency of the power transmission to the user fixed .Grid can be divided into several levels based on the operating voltage transmission system, substructure, transmission system and distribution system, the highest level of voltage transmission system is ZhuWangJia or considered the high power grids. From the two aspects of function and operation, power can be roughly divided into two parts, the transmission system and substation. The farthest from the maximum output power and the power of the highest voltage grade usually through line to load. Secondary transmission usually refers to the transmission and distribution system is that part of the middle. If a plant is located in or near the load, it might have no power. It will be direct access to secondary transmission and distribution system. Secondary transmission system voltage grade transmission and distribution system between voltage level. Some systems only single second transmission voltage, but usually more than one. Distribution system is part of the power system and its retail service to users, commercial users and residents of some small industrial users. It is to maintain and in the correct voltage power to users responsible. In most of the system, Distribution system accounts for 35% of the total investment system President to 45%, andtotal loss of system of the half .More than 220kv voltage are usually referred to as Ultra high pressure, over 800kv called high pressure, ultra high voltage and high pressure have important advantages, For example, each route high capacity, reduce the power needed for the number of transmission. In as high voltage to transmission in order to save a conductor material seem desirable, however, must be aware that high voltage transmission can lead to transformer, switch equipment and other instruments of spending increases, so, for the voltage transmission to have certain restriction, allows it to specific circumstances in economic use. Although at present, power transmission most is through the exchange of HVDC transmission, and the growing interest in, mercury arc rectifier and brake flow pipe into the ac power generation and distribution that change for the high voltage dc transmission possible.Compared with the high-voltage dc high-voltage ac transmission has the following some advantages: (1) the communication with high energy; (2) substation of simple maintenance and communication cost is low; (3) ac voltage can easily and effectively raise or lower, it makes the power transmission and high pressure With safety voltage distribution HVDC transmission and high-voltage ac transmission has the following advantages: (1) it only need two phase conductors and ac transmission to three-phase conductors; (2) in the dc transmission impedance, no RongKang, phase shift and impact overvoltage; (3) due to the same load impedance, no dc voltage, and transfer of the transmission line voltage drop less communication lines, and for this reason dc transmission line voltage regulator has better properties; (4) in dc system withoutskin effect. Therefore, the entire section of route conductors are using; (5) for the same work, dc voltage potential stress than insulation. Therefore dc Wire need less insulation; (6) dc transmission line loss, corona to little interference lines of communication; (7) HVDC transmission without loss of dielectric, especially in cable transmission; (8) in dc system without stability and synchronization of trouble.A transmission and the second transmission lines terminated in substation or distribution substations, the substation and distribution substations, the equipment including power and instrument transformer and lightning arrester, with circuit breaker, isolating switch, capacitor set, bus and a substation control equipment, with relays for the control room of the equipment. Some of the equipment may include more transformer substations and some less, depending on their role in the operation. Some of the substation is manual and other is automatic. Power distribution system through the distribution substations. Some of them by many large capacity transformer feeders, large area to other minor power transformer capacity, only a near load control, sometimes only a doubly-fed wire feeders (single single variable substation)Now for economic concerns, three-phase three-wire type communication network is widely used, however, the power distribution, four lines using three-phase ac networks.Coal-fired power means of main power generating drive generators, if coal energy is used to produce is pushing the impeller, then generate steam force is called the fire. Use coal produces steam to promote the rotating impeller machine plant called coal-fired power plants. In the combustion process, the energy stored in the coal to heat released,then the energy can be transformed into the form within vapor. Steam into the impeller machine work transformed into electrical energy.Coal-fired power plants could fuel coal, oil and natural gas is. In coal-fired power plant, coal and coal into small pieces first through the break fast, and then put out. The coal conveyer from coal unloader point to crush, then break from coal, coal room to pile and thence to power. In most installations, according to the needs of coal is, Smash the coal storage place, no coal is through the adjustable coal to supply coal, the broken pieces of coal is according to the load changes to control needs. Through the broken into the chamber, the coal dust was in the second wind need enough air to ensure coal burning.In function, impeller machine is used to high temperature and high pressure steam energy into kinetic energy through the rotation, spin and convert electricity generator. Steam through and through a series of impeller machine parts, each of which consists of a set of stable blade, called the pipe mouth parts, even in the rotor blades of mobile Li called. In the mouth parts (channel by tube nozzle, the steam is accelerating formation) to high speed, and the fight in Li kinetic energy is transformed into the shaft. In fact, most of the steam generator is used for air is, there is spread into depression, steam turbine of low-pressure steam from the coagulation turbine, steam into the condenses into water, and finally the condensate water is to implement and circulation.In order to continuous cycle, these must be uninterrupted supply: (1) fuel; (2) the air (oxygen) to the fuel gas burning in the configuration is a must; (3) and condenser, condensed from the condensed water supply, sea and river to lake. Common coolingtower; (4) since water vapour in some places in circulation, will damage process of plenty Clean the supply.The steam power plant auxiliary system is running. For a thermal power plant, the main auxiliary system including water system, burning gas and exhaust systems, condensation system and fuel system. The main auxiliary system running in the water pump, condensation and booster pump, coal-fired power plants in the mill equipment. Other power plant auxiliary equipment including air compressors, water and cooling water system, lighting and heating systems, coal processing system. Auxiliary equipment operation is driven by motor, use some big output by mechanical drive pump and some of the impeller blades, machine drive out from the main use of water vaporimpeller machine. In coal-fired power plant auxiliary equipment, water supply pump and induced draft fan is the biggest need horsepower.Most of the auxiliary power generating unit volume increased significantly in recent years, the reason is required to reduce environment pollution equipment. Air quality control equipment, such as electrostatic precipitator, dust collection of flue gas desulfurization, often used in dust in the new coal-fired power plants, and in many already built in power plant, the natural drive or mechanical drive, fountain, cooling tower in a lake or cooling canal has been applied in coal-fired power plants and plants, where the heat release need to assist cooling system.In coal-fired power stations, some device is used to increase the thermal energy, they are (1) economizer and air preheater, they can reduce the heat loss; (2) water heater, he can increase the temperature of water into boiling water heaters; (3) they can increase and filter the thermal impeller.Coal-fired power plants usually requires a lot of coal and coal reservoirs, however the fuel system in power plant fuel handling equipment is very simple, and almost no fuel oil plants.The gas turbine power plants use gas turbine, where work is burning gas fluid. Although the gas turbine must burn more expensive oil or gas, but their low cost and time is short, and can quickly start, they are very applicable load power plant. The gas turbine burn gas can achieve 538 degrees Celsius in the condensing turbine, however, the temperature is lower, if gas turbine and condenser machine, can produce high thermal efficiency. In gas turbine turbine a combined cycle power plant. The gas through a gas turbine, steam generator heat recovery in there were used to generate vapor heat consumption. Water vapor and then through a heated turbine. Usually a steam turbine, and one to four gas turbine power plant, it must be rated output power.。

Brief Introduction to The Electric Power SystemPart 1 Minimum electric power systemA minimum electric power system is shown in Fig.1-1, the system consists of an energy source, a prime mover, a generator, and a load.The energy source may be coal, gas, or oil burned in a furnace to heat water and generate steam in a boiler; it may be fissionable material which, in a nuclear reactor, will heat water to produce steam; it may be water in a pond at an elevation above the generating station; or it may be oil or gas burned in an internal combustion engine.The prime mover may be a steam-driven turbine, a hydraulic turbine or water wheel, or an internal combustion engine. Each one of these prime movers has the ability to convert energy in the form of heat, falling water, or fuel into rotation of a shaft, which in turn will drive the generator.The electrical load on the generator may be lights, motors, heaters, or other devices, alone or in combination. Probably the load will vary from minute to minute as different demands occur.The control system functions （are）to keep the speed of the machines substantially constant and the voltage within prescribed limits, even though the load may change. To meet these load conditions, it is necessary for fuel input to change, for the prime mover input to vary, and for torque on the shaft from the prime mover to change in order that the generator may be kept at constant speed. In addition, the field current to the generator must be adjusted to maintain constant output voltage. Thecontrol system may include a man stationed in the power plant who watches a set of meters on the generator output terminals and makes the necessary adjustments manually. In a modern station, the control system is a servomechanism that senses generator-output conditions and automatically makes the necessary changes in energy input and field current to hold the electrical output within certain specifications..Part 2 More Complicated SystemsIn most situations the load is not directly connected to the generator terminals. More commonly the load is some distance from the generator, requiring a power line connecting them. It is desirable to keep the electric power supply at the load within specifications. However, the controls are near the generator, which may be in another building, perhaps several miles away.If the distance from the generator to the load is considerable, it may be desirable to install transformers at the generator and at the load end, and to transmit the power over a high-voltage line (Fig.1-2). For the same power, the higher-voltage line carries less current, has lower losses for the same wire size, and provides more stable voltage.In some cases an overhead line may be unacceptable. Instead it may be advantageous to use an underground cable. With the power systems talked above, the power supply to the load must be interrupted if, for any reason, any component of the system must be moved from service for maintenance or repair. Additional system load may require more power than the generator can supply. Another generator with its associated transformers and high-voltage line might be added.It can be shown that there are some advantages in making ties between the generators (1) and at the end of the high-voltage lines (2 and 3), as shown in Fig.1-3. This system will operate satisfactorily as long as no trouble develops or no equipmentneeds to be taken out of service.The above system may be vastly improved by the introduction of circuit breakers, which may be opened and closed as needed. Circuit breakers added to the system, Fig.1-4, permit selected piece of equipment to switch out of service without disturbing the remainder of system. With this arrangement any element of the system may be deenergized for maintenance or repair by operation of circuit breakers.Of course, if any piece of equipment is taken out of service, then the total load must be carried by the remaining equipment. Attention must be given to avoid overloads during such circumstances. If possible, outages of equipment are scheduled at times when load requirements are below normal.Fig.1-5 shows a system in which three generators and three loads are tied together by three transmission lines. No circuit breakers are shown in this diagram, although many would be required in such a system.Part 3 Typical System LayoutThe generators, lines, and other equipment which form an electric system are arranged depending on the manner in which load grows in the area and may be rearranged from time to time.However, there are certain plans into which a particular system design may be classified. Three types are illustrated: the radial system, the loop system, and the network system. All of these are shown without the necessary circuit breakers. In each of these systems, a single generator serves four loads.The radial system is shown in Fig.1-6. Here the lines form a “tree” spreading out from the generator. Opening any line results in interruption of power to one or more of the loads.The loop system is illustrated in Fig.1-7. With this arrangement all loads may be served even though one line section is removed from service. In some instances during normal operation, the loop may be open at some point, such as A. In case a line section is to be taken out, the loop is first closed at A and then the line section removed. In this manner no service interruptions occur.Fig.1-8 shows the same loads being served by a network. With this arrangement each load has two or more circuits over which it is fed.Distribution circuits are commonly designed so that they may be classified as radial or loop circuits. The high-voltage transmission lines of most power systems are arranged as network. The interconnection of major power system results in networks made up by many line sections.Part 4 Auxiliary EquipmentCircuit breakers are necessary to deenergize equipment either for normal operation or on the occurrence of short circuits. Circuit breakers must be designed to carry normal-load currents continuously, to withstand the extremely high currents that occur during faults, and to separate contacts and clear a circuit in the presence of fault. Circuit breakers are rated in terms of these duties.When a circuit breaker opens to deenergize a piece of equipment, one side of the circuit breaker usually remains energized, as it is connected to operating equipment. Since it is sometimes necessary to work on the circuit breaker itself, it is also necessary to have means by which the circuit breaker may be completely disconnected from other energized equipment. For this purpose disconnect switches are placed in series with the circuit breakers. By opening these disconnectors, thecircuit breaker may be completely deenergized, permitting work to be carried on in safety.Various instruments are necessary to monitor the operation of the electric power system. Usually each generator, each transformer bank, and each line has its own set of instruments, frequently consisting of voltmeters, ammeters, wattmeters, and varmeters.When a fault occurs on a system, conditions on the system undergo a sudden change. V oltages usually drop and currents increase. These changes are most noticeable in the immediate vicinity of fault. On-line analog computers, commonly called relays, monitor these changes of conditions, make a determination of which breaker should be opened to clear the fault, and energize the trip circuits of those appropriate breakers. With modern equipment, the relay action and breaker opening causes removal of fault within three or four cycles after its initiation.The instruments that show circuit conditions and the relays that protect the circuits are not mounted directly on the power lines but are placed on switchboards in a control house. Instrument transformers are installed on the high-voltage equipment, by means of which it is possible to pass on to the meters and relays representative samples of the conditions on the operating equipment. The primary of a potential transformer is connected directly to the high-voltage equipment. The secondary provides for the instruments and relays a voltage which is a constant fraction of voltage on the operating equipment and is in phase with it；similarly, a current transformer is connected with its primary in the high-current circuit. The secondary winding provides a current that is a known fraction of the power-equipment current and is in phase with it.Bushing potential devices and capacitor potential devices serve the same purpose as potential transformers but usually with less accuracy in regard to ratio and phase angle.中文翻译：电力系统的简介第一部分：最小电力系统一个最小电力系统如图1-1所示，系统包含动力源，原动机，发电机和负载。

中英文对照外文翻译文献(文档含英文原文和中文翻译)POWER SUPPLY AND DISTRIBUTION SYSTEMABSTRACTThe basic function of the electric power system is to transport the electric power towards customers. The l0kV electric distribution net is a key point that connects the power supply with the electricity using on the industry, business and daily-life. For the electric power, allcostumers expect to pay the lowest price for the highest reliability, but don't consider that it's self-contradictory in the co-existence of economy and reliable.To improve the reliability of the power supply network, we must increase the investment cost of the network construction But, if the cost that improve the reliability of the network construction, but the investment on this kind of construction would be worthless if the reducing loss is on the power-off is less than the increasing investment on improving the reliability .Thus we find out a balancepoint to make the most economic,between the investment and the loss by calculating the investment on power net and the loss brought from power-off.KEYWARDS：power supply and distribution,power distribution reliability，reactive compensation,load distributionTEXTThe revolution of electric power system has brought a new big round construction,which is pushing the greater revolution of electric power technique along with the application of new technique and advanced equipment. Especially, the combination of the information technique and electric power technique, to great ex- tent, has improved reliability on electric quality and electric supply. The technical development decreases the cost on electric construction and drives innovation of electric network. On the basis of national and internatio- nal advanced electric knowledge, the dissertation introduces the research hotspot for present electric power sy- etem as following.Firstly, This dissertation introduces the building condition of distribution automation(DA), and brings forward two typical construction modes on DA construction, integrative mode and fission mode .It emphasize the DA structure under the condition of the fission mode and presents the system configuration, the main station scheme, the feeder scheme, the optimized communication scheme etc., which is for DA research reference.Secondly, as for the (DA) trouble measurement, position, isolation and resume, This dissertation analyzes the changes of pressure and current for line problem, gets math equation by educing phase short circuit and problem position under the condition of single-phase and works out equation and several parameter s U& , s I& and e I& table on problem . It brings out optimized isolation and resume plan, realizes auto isolation and network reconstruction, reduces the power off range and time and improves the reliability of electric power supply through problem self- diagnoses and self-analysis. It also introduces software flow and use for problem judgement and sets a model on network reconstruction and computer flow.Thirdly, electricity system state is estimated to be one of the key techniques in DA realization. The dissertation recommends the resolvent of bad measurement data and structure mistake on the ground of describing state estimate way. It also advances a practical test and judging way on topology mistake in state estimate about bad data test and abnormity in state estimate as well as the problem and effect on bad data from state measure to state estimate .As for real time monitor and control problem, the dissertation introduces a new way to solve them by electricity break and exceptional analysis, and the way has been tested in Weifang DA.Fourthly, about the difficulty for building the model of load forecasting, big parameter scatter limit and something concerned, the dissertation introduces some parameters, eg. weather factor, date type and social environment effect based on analysis of routine load forecasting and means. It presents the way for electricity load forecasting founded on neural network(ANN),which has been tested it’s validity by examp le and made to be good practical effect.Fifthly, concerning the lack of concordant wave on preve nting concordant wave and non-power compensation and non-continuity on compensation, there is a topology structure of PWM main circuit and nonpower theory on active filter the waves technique and builds flat proof on the ground of Saber Designer and proves to be practical. Meanwhile, it analyzes and designs the way of non-power need of electric network tre- nds and decreasing line loss combined with DA, which have been tested its objective economic benefit throu- gh counting example.Sixthly, not only do the dissertation design a way founded on the magrginal electric price fitted to our present national electric power market with regards to future trends of electric power market in China and fair trade under the government surveillance, that is group competitio n in short-term trade under the way of grouped price and quantityharmony, but also puts forward combination arithmetic, math model of trading plan and safty economical restriction. It can solve the original contradiction between medium and long term contract price and short term competitive price with improvement on competitive percentage and cut down the unfair income difference of electric factory, at the same time, it can optimize the electric limit for all electric factories and reduce the total purchase charge of electric power from burthen curve of whole electric market network.The distribution network is an important link among the power system. Its neutral grounding mode and operation connects security and stability of the power system directly. At the same time, the problem about neutral grounding is associated with national conditions, natural environment, device fabrication and operation. For example, the activity situation of the thunder and lightning, insulating structure and the peripheral interference will influence the choice of neutral grounding mode Conversely, neutral grounding mode affects design, operation, debugs and developing. Generally in the system higher in grade in the voltage, the insulating expenses account for more sizable proportion at the total price of the equipment. It is very remarkable to bring the economic benefits by reducing the insulating level. Usually such system adopt the neutral directly grounding and adopt the autoreclosing to guarantee power supply reliability. On the contrary, the system which is lower in the voltage adopts neutral none grounding to raise power supply reliability. So it is an important subject to make use of new- type earth device to apply to the distribution network under considering the situation in such factors of various fields as power supply reliability, safety factor, over-voltage factor, the choice of relay protection, investment cost, etc.The main work of this paper is to research and choice the neutral grounding mode of the l0kV distribution network. The neutral grounding mode of the l0kV network mainly adopts none grounding, grounding by arc suppressing coil, grounding by reactance grounding and directly grounding. The best grounding mode is confirmed through the technology comparison. It can help the network run in safety and limit the earth electric arc by using auto-tracking compensate device and using the line protection with the detection of the sensitive small ground current. The paper introduces and analyzes the characteristic of all kind of grounding modes about l0kV network at first. With the comparison with technological and economy, the conclusion is drawn that the improved arc suppressing coil grounding mode shows a very big development potential.Then, this paper researches and introduces some operation characteristics of the arc suppressing coil grounding mode of the l0kV distribution network. And then the paper putemphasis on how to extinguish the earth electric arc effectively by utilizing the resonance principle. This paper combines the development of domestic and international technology and innovative achievement, and introduces the computer earth protection and autotracking compensate device. It proves that the improved arc suppressing coil grounding mode have better operation characteristics in power supply reliability, personal security, security of equipment and interference of communication. The application of the arc suppressing coil grounding mode is also researched in this paper.Finally, the paper summarizes this topic research. As a result of the domination of the arc suppressing coil grounding mode, it should be more popularized and applied in the distribution network in the future.The way of thinking, project and conclusions in this thesis have effect on the research to choose the neutral grounding mode not only in I0kV distribution network but also in other power system..The basic function of the electric power system is to transport the electric power towards customers. The l0kV electric distribution net is a key point that connects the power supply with the electricity using on the industry, business and daily-life. For the electric power, all costumers expect to pay the lowest price for the highest reliability, but don't consider that it's self-contradictory in the co-existence of economy and reliable. To improve the reliability of the power supply network, we must increase the investment cost of the network con- struction But, if the cost that improve the reliability of the network construction, but the investment on this kind of construction would be worthless if the reducing loss is on the power-off is less than the increasing investment on improving the reliability .Thus we find out a balance point to make the most economic, between the investment and the loss by calculating the investment on power net and the loss brought from power-off. The thesis analyses on the economic and the reliable of the various line modes, according to the characteristics various line modes existed in the electric distribution net in foshan..First, the thesis introduces as the different line modes in the l0kV electric distribution net and in some foreign countries. Making it clear tow to conduct analyzing on the line mode of the electric distribution net, and telling us how important and necessary that analyses are.Second, it turns to the necessity of calculating the number of optimization subsection, elaborating how it influences on the economy and reliability. Then by building up the calculation mode of the number of optimization subsection it introduces different power supply projects on the different line modes in brief. Third, it carries on the calculation andanalyses towards the reliability and economy of the different line modes of electric distribution net, describing drafts according by the calculation. Then it makes analysis and discussion on the number of optimization subsection.At last, the article make conclusion on the economy and reliability of different line modes, as well as, its application situation. Accordion to the actual circumstance, the thesis puts forward the beneficial suggestion on the programming and construction of the l0kV electric distribution net in all areas in foshan. Providing the basic theories and beneficial guideline for the programming design of the lOkV electric distribution net and building up a solid net, reasonable layout, qualified safe and efficiently-worked electric distribution net.References[1] Wencheng Su. Factories power supply [M]. Machinery Industry Publishing House. 1999.9[2] Jiecai Liu. Factories power supply design guidance [M]. Machinery Industry Publishing House.1999.12[3] Power supply and distribution system design specifications[S].China plans Press. 1996[4] Low-voltage distribution design specifications [S].China plans Press. 1996.6供配电系统摘要电力系统的基本功能是向用户输送电能。

供配电系统设计英文文献以下是一些供配电系统设计的英文文献:1. "Power System Design" by James A. Reedy, published in 2012 by John Wiley & Sons.2. "Power System Stabilization" by R. W. Knapp and H. W. Zacharias, published in 1963 by John Wiley & Sons.3. "Power System Protection" by E. H. Elser, published in 1968 by John Wiley & Sons.4. "Transmission System Design" by William A. Crothers, published in 1973 by John Wiley & Sons.5. "Power System Control" by T. W. Anderson and R. B. Francis, published in 1968 by John Wiley & Sons.6. "Power System Engineering" by W. J. Lathrop, published in 1976 by John Wiley & Sons.7. "Power Distribution System Design" by R. C. Davis, published in 1970 by John Wiley & Sons.8. "Electric Power Systems Analysis and Design" by R. C. Davis and H. A. Thomas, published in 1975 by John Wiley & Sons.9. "Power System Stability and Control" by P. M. S. Black, published in 1962 by John Wiley & Sons.10. "Electric Power System Security" by G. A. Czarnecki and T. J. Mclaughlin, published in 2000 by John Wiley & Sons.这些文献涵盖了供配电系统设计的各个方面，包括电力系统设计、电力系统稳定控制、电力系统保护和控制、输电系统设计、配电系统设计等。

Academic essay reading appreciation Reading Task: To learn the main structure of an academic essayQuestion 1: How many parts are there in this easy?Question 2.How does the automatic transfer switch work? Question 3.What is the Grounding System？Power System Equipment Maintenance and Long-Term Servicing Requirements for Data CentersKen Agent, PE, Square D/Schneider Electric Engineering Services SummarySummary (2)Abstract (3)Introduction (3)Electrical Preventive Maintenance Program (EPM) (3)Typical Data Center Power Distribution Equipment (5)Design (12)Conclusion (14)References (14)AbstractNo engineered system can run indefinitely without the need for maintenance, and the electric power equipment found in data centers is no exception to this rule. This paper discusses how equipment servicing and maintenance is crucial to the long-term operation of a data center power system, typical maintenance intervals and servicing activities for different types of equipment and how the consideration of maintenance in the initial design of a data center enhances reliability in the long-term.IntroductionAn effective electrical preventive maintenance (EPM) program is critical to any power system. Without such a program, those with a vested interest in the operation of the facility may be unaware of potential problems and cannot prevent them. In addition, the risk of failures greatly decreases with the frequency and quality of an EPM program.Each individual program should be tailored to the types of equipment in the facility, the availability of downtimes, and the critical nature of the loads. Hostile environments, overloads, and severe duty cycles can increase the need for regular maintenance. In addition, if equipment feeds critical loads, it should be maintained regularly to decrease the likelihood of failure.The ideal first step in an electrical preventive maintenance program is a good design. Dual feeds, draw-out equipment, standardized equipment, etc. can all make maintenance much more realistic during the normal operation of a facility. Otherwise, the necessary downtimes will increase and maintenance will either be delayed or eliminated. In addition, if the equipment is excessively complex or extremely unique, repairs can be overly expensive.Electrical Preventive Maintenance Program (EPM)The three parts of an EPM program are inspection, testing, and repair. Each part is vital to the program’s overall success. It is vital to tailor each part around the operations and critical nature ofthe facility.Before an inspection can begin, up to date drawings and diagrams must be obtained, along with applicable manufacturers’ operation and maintenance manuals for the equipment; otherwise the inspection could be incomplete, inaccurate, or unsafe. This information will help determine where to prioritize maintenance and how to implement lock-out/tag-out before testing begins.In a facility where down time is a premium, running inspections are vital. However, these should only be performed by qualified personnel who have been properly trained on the potential hazards. An example of a running inspection would be infrared scanning. These types of inspections can increase the effectiveness of a complete inspection once a shut-down is scheduled.Only once the equipment has been shut-down, all of the energy sources have been locked-out/tagged-out, equipment has been verified “dead,” and proper grounds have been applied (if applicable), can a complete inspection begin. This type of inspection should be planned in detail before the shut-down so time is not wasted. The areas of interest for inspection will be unique for each type of equipment in the facility, and the equipment manufacturers’ operation and maintenance manuals should be consulted for guidance as to key areas upon which to concentrate. Both age and environment should be considered during planning and implementation. In addition, all personnel involved should be properly trained so the inspection is both effective and safe and time is not wasted during the process.As with inspection, testing will be unique for each type of equipment and the equipment manufacturers’ operation and maintenance manuals should be consulted. The proper testing equipment should be available before the shut-down begins. This equipment should be tested in advance to both determine its accuracy and insure that it will work as planned during the shut-down. In addition, if the equipment needs an external source of power, it should be part of the plan to make such power available.A vital outcome from inspection and testing should be accurate and complete records. Without them, planning for repairs can become extremely difficult. In addition, future trouble shooting will be much more effective with good records.Based on the outcome of the inspection and testing, repairs should be scheduled. Repairs should first be targeted at equipment that is either close to failure or vital to a critical load.Typical Data Center Power Distribution EquipmentMedium-voltage transformers are some of the most critical components in a power system. They can cause drastic service interruptions and can take weeks or months to replace if they fail. In addition, they are also one of the most expensive components in a power system.A typical data center will contain either liquid-filled or dry-type (including cast-coil) substation transformers.Medium-voltage Liquid-filled TransformersNewer liquid-filled transformers can contain mineral oil, seed oil (less flammable) or silicone fluid. However, some older transformers could contain askarel, which contains PCBs. These fluids should never be mixed.The designer should work with the insurance underwriter to specify clearances and necessary containment means to contain the fluid, in case of a leak or spill.Like all other components in an electrical power system, the frequency of maintenance depends on the operating conditions. Clean and dry conditions could require annual maintenance, while a hot, dirty environment will require more frequent maintenance. However, major maintenance is recommended at least every three to six years.A visual inspection should be part of routine maintenance. This will consist of monitoring the load current, voltage, liquid level, liquid temperature, winding temperature, ambient temperature and any fluid leaks. In addition, the transformer fluid should be sampled at regular intervals and dissolved gas analysis performed. Fluid should never be sampled while energized, unless an external sampling valve is present. Most of these inspections should be able to take place with the transformer in service. However, the transformer must be equipped with all of the necessary gauges and monitors for this to take place while energized. The results of these tests are best utilized by tracking the results of multiple tests as trends over time.During a shut-down, more testing should take place. These tests would include insulation tests such as power-factor testing and insulation-resistance testing. The transformer instrumentation and protection, such as gauges, sudden-pressure relays, etc., should be checked as well. Diagnostic tests such as turns-ratio testing and exciting-current testing should also occur. Any readings outside of the manufactures specifications should be investigated. Any fans, relays, control power, control power wiring, etc. should be inspected along with the general condition ofthe enclosure. Bushing and surge arrestor should be cleaned and loose connections should be tightened. The transformer should also be checked for pressure and bushing leaks.Medium-voltage Dry-type TransformersVentilated and cast-coil dry-type ANSI/IEEE C57.12.01 medium-voltage transformers are another option to liquid-filled. Clean and dry conditions could require maintenance at least every three to six years, while a hot, dirty environment will require more frequent maintenance.During the shut-down, dirt and debris should be removed from the core, coil and insulators. Special care should be made to insure air flow is not impeded. Loose connections should be tightened. Insulation-resistance testing, turns-ratio testing, and core Megger tests should also take place. Any readings outside of the manufactures specifications should be investigated.Medium-voltage Metal-clad SwitchgearANSI/IEEE C37.20.2 metal-clad switchgear in a power system distributes power and contains circuit breakers and overcurrent protection, usually in addition to other types of, protection. The construction of this switchgear can vary widely based on manufacturer and age, so accurate drawings and documentation is essential for use and maintenance.Like all other components in an electrical power system, the frequency of maintenance depends on the operating conditions. Moisture combined with dirt will deteriorate the insulation in the equipment at a highly accelerated rate. Major maintenance is recommended at least every three to six years.During a shut-down the busbars, supports and insulating barriers should be inspected and cleaned. The busbars should be tightened to manufacturer’s specifications. The interior should be thoroughly vacuumed and adequate ventilation verified. All parts should be inspected for signs of corona, tracking or thermal damage. All cable terminations should be inspected for indication of insulation deterioration. If space heaters are present, they should be tested.It is vital to also inspect the circuit breaker compartments. Once the circuit breaker(s) have been withdrawn,all of the moving mechanisms in the compartment should be inspected. The shutters should also beinspected and tightened. In addition, the primary contacts should be inspected for signs of loose hardware or poor contact with the circuit breaker contacts. All contacts and joints should be lubricated per the manufacturer’s specifications.It is also important to service the VT and CPT compartments. Parts should be inspected,cleaned, tightened and lubricated per the manufacturer’s specifications.In addition, all surge arrestors, interlocks, and battery systems should be checked and maintained per the manufacturer’s specif ications.Medium-voltage Circuit BreakersThe ANSI/IEEE C37.04 and C37.06 circuit breakers within the medium-voltage switchgear are controlled by external protective relays to provide overcurrent, and probably other types of, protection. In addition, they can be used to switch between various sources of power.There are basically four types of medium-voltage circuit breakers: vacuum, gas, air and oil. However, most new installations will have vacuum circuit breakers.Like all other components in an electrical power system, the frequency of maintenance depends on the operating conditions. However, one manufacturer recommends inspection ever year, or every 1,000 operations.Inspection and maintenance should take place after any fault operations.Circuit breakers should be completely withdrawn from their cubicles before being maintained. They should be inspected for signs of overheating, and excessive dirt or moisture. Check for loose parts or connections. The operating mechanisms should be snug and friction free. Both the insulators and the vacuum interrupters should be cleaned. The drawout primary contact clusters should be checked for signs of wear or damage.Contact erosion, hi-pot (dielectric), and resistance measurement tests should take place to check the vacuum interrupters against the manufacturer’s specifications. In addition, it is highly recommended to have spares of each amperage size and manufacturer available, in case of failure. Protective RelaysProtective relays utilize inputs from CTs and PTs, along with their characteristic curves and settings, to provide protection to cables, transformer, motors, and other equipment within the power system. Relays will shunt trip their associated medium-voltage circuit breaker if they detect an over current, or other anomaly, that falls within their settings.There are basically two types of protective relays: Electronic and electro-mechanical. While some owners still specify electromechanical, electronic relays are much more common in new installations.Electronic relays are designed to be maintenance-free. However, like all other components inan electrical power system, harsh operating conditions could dramatically reduce the lifespan of the device. In general, once an electronic relay has been commissioned, it should be maintenance free, unless settings changes are needed in the future.Electromechanical relays should be tested on a regular basis. One manufacturer, for example, recommends every six months. In addition to testing the calibration, the unit should be inspected for damage and the contacts should be cleaned.Medium-voltage Metal-enclosed SwitchgearIn most cases, ANSI/IEEE C37.20.3 medium-voltage metal-enclosed switchgear is located at the primary side of unit substations in data centers. However, it also can be used as the main switchgear to distribute power downstream. It generally consists of load interrupter switches, either fused or non-fused, that are infrequently used for load interruption. Their primary task is to protect the downstream load, if fusible, and to provide a disconnect for lock-out/tag-out.Like all other components in an electrical power system, the frequency of maintenance depends on the operating conditions. For example, one manufacturer recommends inspection every one to five years, or every 100 operations. Inspection and maintenance should take place after any fault downstream.During the shut-down, a hi-pot (dielectric) test should take place to measure insulation integrity along with general cleaning and tightening of the insulators, busing , and mechanical parts. The contacts and operating mechanism should be cleaned and lubricated per the manufacturer’s specifications.Low-voltage SwitchgearLike medium-voltage switchgear, ANSI C37.20.1 low-voltage switchgear distributes power and contains circuit breakers with over current protection. Some facilities might choose UL 891 low-voltage switchboards, which can be almost identical to switchgear.Like all other components in an electrical power system, the frequency of maintenance depends on the operating conditions. Moisture combined with dirt will deteriorate the insulation in the equipment at a highly accelerated rate.Maintenance on low-voltage switchgear is very similar to maintenance on medium-voltage switchgear. Construction can vary widely based on manufacturer and age, so accurate drawings and documentation is essential for use and maintenance. The equipment should be cleaned,lubricated and exercised on a regular basis. One manufacturer, for example, recommends inspection every year as a maximum. However, under ideal circumstances, maintenance could only be required every five years.Like with other equipment, an inspection should take place after a short circuit involving the switchgear in the path of current flow. In particular, Insulation and conductors should be inspected for damage.Low-voltage Circuit BreakersThere are essentially two classes of low-voltage circuit breakers that can be applied in a power system: Power circuit breakers (ANSI C37.13) or molded and insulated case circuit breakers (UL 489). Power breakers are used in draw-out switchgear while molded and insulated case circuit breakers are used in switchboards, panel boards and other applications.Like medium-voltage circuit breakers, low-voltage power breakers should be completely withdrawn from their cubicles before being maintained. The primary drawout contact clusters should be checked for signs of wear or damage. Insulation should be checked using dielectric tests (hi-pot or insulation resistance).Unlike medium-voltage breakers, low-voltage breakers usually have an integral trip unit. There are usually two ways to test the trip unit: primary and secondary injection. Primary injection is recommended since it tests the complete system, including the current sensors, while secondary injection only tests the trip unit itself. It is important to note that primary injection requires a large test set that could need single-phase 480V for operation. Planning for this power is necessary prior to any shut-down.Insulated case circuit breakers can sometimes be maintained similar to power circuit breakers. However, in many cases, their maintenance is similar to a molded case breaker. Manufa cturer’s literature should be consulted for recommended practices.Molded case circuit breakers require a minimal amount of maintenance. In fact, opening the case will void the manufacture warranty. Maintenance is limited to inspection and good operating conditions, and in some cases primary injection testing with the circuit breaker removed from the enclosure. They should be manually operated annually. In addition, the “push to trip” button should be utilized to exercise the tripping mechanism.Switchboards and Panel boardsSwitchboards and panel boards are built per UL 489. They are for low-voltage applications and contain either molded-case circuit breakers or fusible switches. Both are typically found downstream of the switchgear in a data center.Maintenance is mostly limited to insuring good electrical and mechanical connections plus good housekeeping. Regular infrared scanning and cleaning is recommended to insure dependable operation.Low-voltage Motor Control Centers (MCCs)One of the most versatile components in a power system are the UL 845 low-voltage motor control centers (MCCs). These are designed to contain starters for motors, located within buckets, or control units, in the enclosure. The buckets can also contain drives, or simply molded case circuit breakers or fusible switches.Maintenance on the enclosure and busbars of MCCs is very similar to switchgear, the major difference being the maintenance of the drawout buckets. The buckets should be removed from the MCC before maintenance. Once removed, the primary contact stabs should be examined for signs of arcing or overheating. If a stab is badly pitted, it may be necessary to replace the vertical bus within the MCC. Within the bucket, any circuit breakers, switches, starters, control devices and wiring should be examined.Low-voltage TransformersNEMA low-voltage dry-type transformers are typically used for lighting applications within data centers. The frequency of inspection is based upon the operating conditions. Clean and dry conditions require less maintenance, while dusty, hot environments will require more frequent inspections. During maintenance, connections should be checked for looseness. In addition, any dust that restricts air flow or lies on insulating surfaces should be removed. A visual inspection for overheating, tracking and overall enclosure condition should also take place.Automatic Transfer Switches (ATSs)Automatic transfer switches (ATSs) are critical in data center power systems. They switch their downstream loads between power sources in the event of source failure.There are basically two types of ATSs: standard and bypass-isolation. Either can be open- or closed-transition. Bypass-isolation ATSs allow the switch to be racked out for inspection, testing and maintenance without any interruption of power to the load.The controller/switch combination should be checked often. One manufacturer recommendsa once a month test. Any test should verify the proper electrical operation of the controller and switch per the manufacturer’s specifications.One manufacturer recommends annual maintenance of the switch itself. The maintenance should include general cleaning of the enclosure, inspection of the contacts, lubrication and inspection of all cable connections.Uninterruptible Power Supply (UPS) SystemsUninterruptible Power Supply (UPS) systems provide the final safety net for a data center power system. They also can remove the momentary power interruption during open transition switching between utility and generator sources.There are basically two types of UPS systems: static (or battery) and rotary (or flywheel). There are advantages to both systems. However, a detailed description is outside of the scope of this paper.Due to the unique and technical nature of a UPS system, most manufacturers recommend that their service personnel perform any major maintenance and system tests. In addition, since a UPS is designed and applied to provide constant power to its loads, extreme caution should be used to not interrupt power. As a result of the need to not lose power, the system should be design so that switching can occur to allow the UPS (or each module of a multi-module UPS) to be isolated while maintaining power to critical loads. This furthers the need for qualified and trained personnel.However, some less-complex routine maintenance can take place. It is important to keep the room clean and cool. In addition, the air filters should be replaced and the battery system inspected on a regular basis. Also, depending on the UPS size and manufacturer, it is possible individual components of the system (molded case circuit breakers, etc.) can be maintained, as detailed in other parts of this paper.Bus wayWhile not every data center has bus way, it is becoming more common in this environment. NEMA low-voltage Bus way is typically found downstream of the PDUs, feeding critical loads. However, ANSI medium-voltage metal-enclosed bus way can be found at the service level. Bus way is designed to be low-maintenance equipment. However, a regular visual inspection and IR scan are recommended to look for exterior damage and loose connections. An inspection shouldbe made if a short-circuit or ground fault has taken place downstream of the bus way. Connections should be torqued and insulation resistance should be tested also.In addition to the bus way itself, plug-in bus way will have “plugs” that contain either fusible switches or molded case circuit breakers. These switches and breakers should also be inspected and maintained as recommended above.Grounding SystemThe grounding system is vital to both the operation of the over current devices in the system and personnel safety. Grounding and bonding within the system should be inspected on a regular basis. The electrical connection to earth should be measured. In addition, voltage should be measured between the equipment grounding conductor and the grounded conductor at multiple locations. Also, current should be measured on the grounded conductor. If any of these readings are outside of standard levels, their cause should be immediately found and corrected.DesignIn an ideal world, the initial design of a power system should account for both the loads being serviced in the facility and the ease of maintenance. However, many owners are left to deal with systems that have been value-engineered where maintenance is extremely difficult to schedule and implement. There are several design opportunities that can make both scheduling and implementing maintenance much more realistic.Tie breakers allow power from alternate sources to feed downstream loads, while a main breaker, and possibly another tie breaker, is opened. This allows maintenance on some of the upstream distribution system. In addition, depending on the system, trip unit settings can be applied to the tie breaker to allow another level of selectivity in the protection system.ATSs and UPSs are vital to a data center. ATSs quickly switch between various power sources during a voltage interruption, sag, loss of phase, etc. ATSs can be applied as closed-transition, if the downstream equipment has the proper AIC and WCR ratings. Regardless, the use of ATSs with downstream UPSs provide maximum reliability to the system. If all available power sources go down, the UPSs will provide power for a certain amount of time,depending on the model. In addition, the UPS will provide continuous power during open-transition switching of upstream ATSs or circuit breakers. The use of ATSs and UPSs will also allow upstream maintenance without critical load interruption. As mentioned above, high-reliability systems should be designed with appropriate switching to allow each UPS (or each module of a multi-module UPS) to be isolated individually while maintaining power to the critical load.Draw-out equipment provides an advantage during both maintenance and system failures. Draw-out equipment can be quickly removed from service for testing, while fixed-mounted equipment usually requires an extended shut-down for removal from the equipment. Also, if spares are available, they can be utilized while other equipment is tested. In addition, if a draw-out device fails, it can be replaced with a spare much quicker than fixed mounted equipment.Standardized equipment is also recommended as part of the initial design and any expansions. If draw-out equipment is used, they can be taken between different parts of the building during maintenance and failure if such a standard is employed. However, if multiple types and manufactures are utilized, the equipment will not be as versatile.In a data center, down time for maintenance is a critical commodity. Grouping of equipment can speed up this process. If all of the personnel and test equipment can be staged and located in one part of the facility, the process should become smoother and quicker.Part of the initial design should insure the proper operating environment for the power system equipment. This will reduce the amount of necessary maintenance and probability of failure. Equipment rooms should have clean, filtered air with very low levels of vibration. Also, while the exact conditions will vary between equipment and manufacturer, ambient conditions between 60 degrees to 85 degrees F and 40–70% humidity are generally recommended.An extremely useful tool for both detecting potential problems and trouble shooting is a robust power monitoring system. This system will allow the owner to detect potential power quality issues before they cause a major problem in the system. In addition, it will provide the necessary data for planning for expansions and the installation of new equipment.Several equipment features can allow easy inspection during operation, which could extend time between necessary downtimes for maintenance. Infrared (IR) windows, hinged doors and barriers between sections all provide an added level of safety for running inspections.Both acceptance testing and inspection before shipment are recommended for the more vital components in a power system. This will allow the owner to find problems before the equipment is energized and utilized and will provide the necessary data points when preventative maintenance takes place in the future.ConclusionNo critical power system should be without an effective electrical preventive maintenance (EPM) program. Potential failures cannot be detected without such a system in place. Failures within the system will decrease with the frequency and quality of the EPM.The EPM should be tailored to each individual system. Details such as types of equipment, availability of downtimes, operating conditions, and the nature of the loads must be considered. Two systems with identical designs could have different EPMs if they are operated in a different manner.The first step to an effective EPM is the design. The system can be designed to allow shutdowns of a small portion of the system to allow for maintenance. Such a design can all for decreased time periods between maintenance. In addition, the specified equipment should be easily repairer or replaced, if a failure does occur.ReferencesNFPA 70B., Recommended Practice for Electrical Equipment Maintenance, Quincy, MA: NFPA。