变电站设计外文翻译 毕业设计

General Requirements to Construction of SubstationSubstations are a vital element in a power supply system of industrial enterprises．They serve to receive ，convert and distribute electric energy .Depending on power and purpose ,the substations are divided into central distribution substations for a voltage of 110-500kV;main step-down substations for110-220/6-10-35kV;deep entrance substations for 110-330/6-10Kv;distribution substations for 6-10Kv;shop transformer substations for 6-10/0.38-0.66kV.At the main step-down substations, the energy received from the power source is transformed from 110-220kV usually to 6-10kV(sometimes 35kV) which is distributed among substations of the enterprise and is fed to high-voltage services.Central distribution substations receive energy from power systems and distribute it (without or with partial transformation) via aerial and cable lines of deep entrances at a voltage of 110-220kV over the enterprise territory .Central distribution substation differs from the main distribution substation in a higher power and in that bulk of its power is at a voltage of 110-220kV;it features simplified switching circuits at primary voltage; it is fed from the power to an individual object or region .Low-and medium-power shop substations transform energy from 6-10kV to a secondary voltage of 380/220 or 660/380.Step-up transformer substations are used at power plants for transformation of energy produced by the generators to a higher voltage which decreases losses at a long-distance transmission .Converter substations are intended to convert AC to DC (sometimes vice versa) and to convert energy of one frequency to another .Converter substations with semiconductor rectifiers are convert energy of one frequency to another .Converter substations with semiconductor rectifiers are most economic. Distribution substations for 6-10kV are fed primarily from main distribution substations (sometimes from central distribution substations).With a system of dividing substations for 110-220kV, the functions of a switch-gear are accomplishedby switch-gears for 6-10kV at deep entrance substations.Depending on location of substations their switch-gear may be outdoor or indoor. The feed and output lines at 6-10kV substations are mainly of the cable type .at 35-220kV substations of the aerial type .When erecting and wiring the substations ,major attention is given to reliable and economic power supply of a given production.Substations are erected by industrial methods with the use of large blocks and assemblies prepared at the site shops of electric engineering organizations and factories of electrical engineering industry .Substations are usually designed for operation without continuous attendance of the duty personnel but with the use of elementary automatic and signaling devices.When constructing the structural part of a substation .it is advisable to use light-weight industrial structures and elements (panels ,floors ,etc.) made of bent sections .These elements are pre-made outside the erection zone and are only assembled at site .This considerably cuts the terms and cost of construction.Basic circuitry concepts of substations are chosen when designing a powersupply system of the enterprise .Substations feature primary voltage entrances .transformers and output cable lines or current conductors of secondary voltage .Substations are mounted from equipment and elements described below .The number of possible combinations of equipment and elements is very great .Whenelaborating a substation circuitry ,it is necessary to strive for maximum simplification and minimizing the number of switching devices .Such substations are more reliable and economic .Circuitry is simplified by using automatic reclosure or automatic change over to reserve facility which allows rapid and faultless redundancy of individual elements and using equipment.When designing transformer substations of industrial enterprises for all voltages , the following basic considerations are taken into account:1. Preferable employment of a single-bus system with using two-bus systems only to ensure a reliable and economic power supply;2. Wide use of unitized constructions and busless substations;3.Substantiated employment of automatics and telemetry ;if the substation design does not envisage the use of automatics or telemetry ,the circuitry is so arranged as to allow for adding such equipment in future without excessive investments and re-work.e of simple and cheap devices-isolating switches ,short-circuiting switches ,load-breaking isolators ,fuses ,with due regard for their switching capacity may drastically cut the need for expensive and critical oil ,vacuum ,solenoid and air switches .Substation and switch-gear circuitries are so made that using the equipment of each production line is fed from individual transformers ,assemblies ,the lines to allow their disconnection simultaneously with mechanisms without disrupting operation of adjacent production flows.When elaborating circuitry of a substation, the most vital task is to properly choose and arrange switching devices(switches ,isolators ,current limiters ,arresters ,high-voltage fuses).The decision depends on the purpose ,power and significance of the substation.Many years ago, scientists had very vague ideas about electricity. Many of them thought of it as a sort of fluid that flowed through wires as water flows through pipes, but they could not understand what made it flow. Many of them felt that electricity was made up of tiny particles of some kind ,but trying to separate electricity into individual particles baffled them.Then, the great American scientist Millikan, in 1909,astounded the scientific world by actually weighing a single particle of electricity and calculating its electric charge. This was probably one of the most delicate weighing jobs ever done by man,for a single electric particle weighs only about half of a millionth of a pound. To make up a pound it would take more of those particles than there are drops of water in the Atlantic Ocean.They are no strangers to us, these electric particles, for we know them as electrons. When large numbers of electrons break away from their atoms and move through a wire,we describe this action by saying that electricity is flowing through the wire.Yes,the electrical fluid that early scientists talked about is nothing more than electrical flowing along a wire.But how can individual electrons be made to break away from atoms? And how can these free electrons be made to along a wire? The answer to the first question lies in the structure of the atoms themselves. Some atoms are so constructed that they lose electrons easily. An atom of copper, for example ,is continually losing an electron, regaining it(or another electron),and losing it again. A copper atom normally has 29 electrons, arranged in four different orbits about its nucleus. The inside orbit has 2 electrons. The next larger orbit has 8.The third orbit is packed with 18 electrons . And the outside orbit has only one electron.It is this outside electron that the copper atom is continually losing, for it is not very closely tied to the atom. It wanders off, is replaced by another free-roving electron, and then this second electron also wanders away.Consequently,in a copper wire free electrons are floating around in all directions among the copper atoms.Thus, even through the copper wire looks quite motionless to your ordinary eye, there is a great deal of activity going on inside it. If the wire were carrying electricity to an electric light or to some other electrical device, the electrons would not be moving around at random. Instead, many of them would be rushing in the same direction-from one end of the wire to the other.This brings us to the second question .How can free electrons be made to move along a wire? Well ,men have found several ways to do that .One way is chemical. V olta,s voltaic pile,or battery, is a chemical device that makes electricity(or electrons)flow in wires. Another way is magnetic. Faraday and Henry discovered how magnets could be used to make electricity flow in a wire.MagnetsAlmost everyone has seen horseshoe magnets-so called because they are shaped like horseshoes. Probably you have experimented with a magnet, and noticed how it will pick up tacks and nails, or other small iron objects. Men have known about magnets for thousands of years.Several thousand years ago, according to legend, a shepherd named Magnes lived on the island of Crete, in the Mediterranean Sea .He had a shepherds crook tipped with iron. One day he found an oddly shaped black stone that stuck to this ironter, when many other such stones were found, they were called magnets(after Magnets).These were natural magnets.In recent times men have learned how to make magnets out of iron. More important still, they have discovered how to use magnets to push electrons through wires-that is, how to make electricity flow. Before we discuss this, there arecertain characteristics of magnets that we should know about.If a piece of glass is laid on top of a horse- shoes magnet, and if iron filings are then sprink ledon the glass, the filings will arrange themselves into lines. If this same thing is trid with a bar magnet(a horseshoe magnet straightened out),the lines can be seen more easily. These experiments demonstrate what scientists call magnetic lines of force. Magnets, they explain, work through lines of force that ext- end between the two ends of the magnet. But electrons seem to have magnetic lines of force around them, too.This can be proved by sticking a wire through a piece ofcard board, sprinkling iron filings on the cardboard, and connecting a battery to the wire. The filings will tend to form rings around the wire,as a result of the magnetism of the moving electrons(or electricity).So we can see that there is arelationship between moving electrons and magnetism, Magnetism results from the movement of electrons.Of course, electrons are not really flowing in the bar magnet, but they are in motion, circling the nuclei of the iron atoms. However, in the magnet, circling thelined up in such a way that their electrons are circling in the same direction. Perhaps a good comparison might be a great number of boys whirling balls onstrings in a clockwise direction around their heads.。

毕业设计（论文）外文文献翻译文献、资料中文题目：变电站建设的一般要求文献、资料英文题目：General Requirements to Construction of Substation文献、资料来源：文献、资料发表（出版）日期：院（部）：专业：班级：姓名：学号：指导教师：翻译日期： 2017.02.14毕业设计（论文）外文资料翻译外文出处International journal ofelectrical power and energy systemsGeneral Requirements to Construction of SubstationCarpentier J; Optimal Power Flows2011《International journal of electrical power and energy systems》FebSubstations are a vital element in a power supply system of industrial enterprises．They serve to receive ，convert and distribute electric energy .Depending on power and purpose ,the substations are divided into central distribution substations for a voltage of 110-500kV;main step-down substations for110-220/6-10-35kV;deep entrance substations for 110-330/6-10kV;distribution substations for 6-10kV;shop transformer substations for 6-10/0.38-0.66kV.At the main step-down substations, the energy received from the power source is transformed from 110-220kV usually to 6-10kV(sometimes 35kV) which is distributed among substations of the enterprise and is fed to high-voltage services.Central distribution substations receive energy from power systems and distribute it (without or with partial transformation) via aerial and cable lines of deep entrances at a voltage of 110-220kV over the enterprise territory .Central distribution substation differs from the main distribution substation in a higher power and in that bulk of its power is at a voltage of 110-220kV;it features simplified switching circuits at primary voltage; it is fed from the power to an individual object or region .Low-and medium-power shop substations transform energy from 6-10kV to a secondary voltage of 380/220 or 660/380.Step-up transformer substations are used at power plants for transformation of energy produced by the generators to a higher voltage which decreases losses at a long-distance transmission .Converter substations are intended to convert AC to DC (sometimes vice versa) and to convert energy of one frequency to another .Converter substations with semiconductor rectifiers are convert energy of one frequency to another .Converter substations with semiconductor rectifiers are most economic. Distribution substations for 6-10kV are fed primarily from main distribution substations (sometimes from central distribution substations).With a system of dividing substations for 110-220kV, the functions of a switch-gear are accomplished by switch-gears for 6-10kV at deep entrance substations.Depending on location of substations their switch-gear may be outdoor or indoor. The feed and output lines at 6-10kV substations are mainly of the cable type .at 35-220kV substations of the aerial type .When erecting and wiring the substations, major attention is given to reliable and economic power supply of a given production.Substations are erected by industrial methods with the use of large blocks and assemblies prepared at the site shops of electric engineering organizations and factories of electrical engineering industry .Substations are usually designed for operation without continuous attendance of the duty personnel but with the use of elementary automatic and signaling devices.When constructing the structural part of a substation .it is advisable to use light-weight industrial structures and elements (panels ,floors ,etc.) made of bent sections .These elements are pre-made outside the erection zone and are only assembled at site .This considerably cuts the terms and cost of construction.Basic circuitry concepts of substations are chosen when designing a powersupply system of the enterprise .Substations feature primary voltage entrances .transformers and output cable lines or current conductors of secondary voltage .Substations are mounted from equipment and elements described below .The number of possible combinations of equipment and elements is very great .When elaborating a substation circuitry ,it is necessary to strive for maximum simplification and minimizing the number of switching devices .Such substations are more reliable and economic .Circuitry is simplified by using automatic enclosure or automatic change over to reserve facility which allows rapid and faultless redundancy of individual elements and using equipment.When designing transformer substations of industrial enterprises for all voltages, the following basic considerations are taken into account:1. Preferable employment of a single-bus system with using two-bus systems only to ensure a reliable and economic power supply;2. Wide use of unitized constructions and bustles substations;3.Substantiated employment of automatics and telemetry ;if the substation design does not envisage the use of automatics or telemetry ,the circuitry is so arranged as to allow for adding such equipment in future without excessive investments and re-work.e of simple and cheap devices-isolating switches ,short-circuiting switches ,load-breaking isolators ,fuses ,with due regard for their switching capacity may drastically cut the need for expensive and critical oil ,vacuum ,solenoid and air switches .Substation and switch-gear circuitries are so made that using the equipment of each production line is fed from individual transformers ,assemblies ,the lines to allow their disconnection simultaneously with mechanisms without disrupting operation of adjacent production flows.When elaborating circuitry of a substation, the most vital task is to properly choose and arrange switching devices (switches, isolators, current limiters, arresters, high-voltage fuses).The decision depends on the purpose, power and significance of the substation.Power System Substation is an important and indispensable component of the power it assumed the task of conversion and distribution of grid security and the economy play a decisive role in running is to contact the user’s power plants and intermediate links. With economic development, expanding grid capacity, reliability of operation of the power grid is getting higher and higher requirements. Developmentof science and technology, intelligent switches, photoelectric current and voltage transformer, a run-line state detection, training simulation Substation Operation matures, such as high-tech, as well as fiber-optic technology, computer high-speed network system in the development of real-time applications, bound to the existing substation automation technology have a profound impact, all-digital substation automation system development trend.Power system is operated by the production, transmission, distribution and consumption of a variety of power linked to the composition of electrical equipment. As a result of a large number of powers can not be stored, we must ensure that the production of electricity and energy balance. With the scientific and technological advances in the technological development of our country has reached a certain level. Intelligent switches, photoelectric current and voltage transformer, a run-line state detection, training simulation Substation Operation matures, such as high-tech, as well as fiber-optic technology, computer high-speed network system in the development of real-time applications, significantly increase the transformation degree of automation.Design of our substation cable programs tend to be simple, many of the recent domestic new 220 k V substation and 110kV voltage levels of wiring without the use of dual-bus bypass bus. The use of GIS, the priority sub-bus single wire. Terminal Substation, the line as far as possible, such as transformer unit wiring. A large number of the introduction of new technology, transformer substation rising level of electrical equipment, power distribution devices from the traditional form of moving toward oil-free, vacuum switches, SF6 switches and mechanical, electrical equipment combination of the development of small-scale integration. In recent years the world famous high-voltage electrical equipment companies have been developing, the development of the various types of 145-550 kV outdoor high-pressure and ultrahigh-pressure combination of electrical appliances, some high-voltage switchgear plant has also started production of 145 k V compact outdoor portfolio electrical appliances. Smart plug-in type outdoor switchgear is a more complete high-pressure and ultrahigh-pressure switch system, which includes electrical first and second equipment, as well as the associated fiber optic cable, such as plug-type compound. The entire distributed substation automation system; the introduction of advanced network technology; substation and the construction area covers an area of reducedsubstation program to simplify wiring, switchgear, bus and steel pipes, such as the use of stents to substation layout is more simple, the abolition of the former station area and optimize the layout to make a substantial decline in an area substation.With technological advances, the traditional relay protection devices are gradually being replaced by microprocessor-based protection. Microprocessor-based protection is referred to as the protection of PC computer, a digital relay protection, is based on the programmable digital circuit technology and real-time digital signal processing technology of the Power System Protection. At present, both at home and abroad have been developed to 32-bit digital signal processor for hardware-based protection, control, measurement, and data communications integration of microprocessor-based protection control devices, and artificial intelligence technology into a number of relay protection, such as artificial neural networks, fuzzy theory to determine the realization of fault type, fault location, the direction of protection, the main equipment and other new methods of protection. By means of wavelet analysis of the theory of digital signal failure of the entire frequency band information and to achieve fault detection. These artificial intelligence technologies to improve the accuracy of failure to provide a means of identification, but also some single-frequency signal based on the traditional method difficult to identify the problems to be resolved. At present, the microprocessor-based relay protection is along the microprocessor-based protection network, and intelligent, adaptive and protection, control, measurement, signal, data communications integration direction.The most basic request that charged barbed wire net in the city circulates is safe and stable. The core problem of charged barbed wire net safety in the city stability wants to build up to be a with the city mutually accommodative of, reasonable of charged barbed wire net structure. This text passes and programs to the charged barbed wire net with electric power and designs the technique principle of the aspect analysis. Elaborated the standard concerning electric voltage grade, power supply credibility, power supply ability and charged barbed wire net safe power supply requests etc. some problems that should notice in the charged barbed wire net safety; And have already aimed at sex's elaborating request to the concrete design principle opposite charged barbed wire net safe power supply of the 220 kV transformer substation and 110kV transformer substation.How to promise power supply credibility1) Satisfy charged barbed wire net power supply safe standard. The power supply。

AC 500 kV Substation Design in ChinaAbstract: Some brief informations about AC 500kV substations in China, historical data of their design and essential design principles are presented in this paper. Some technical and engineering problems of AC500 kV substation design and construction are discussed. It is emphasized to introduce the 500 kV substation scales, main electrical connections, selection of equipment and apparatus, insulation coordination, distribution switchyard, control and protection etc.. here we also discuss the policy of project cost control at present time and a prospective view of China AC substations in future.1. IntroductionThe research and design of 500 kV substations in China were started in 1977,and the first substation was put into operation in 1981. From that time, because of the rapid development of electricity demand in China, design and construction of 500 kV substations have a great development. Especially in recent years, due to the increase of capital investment for power system construction from the State Government, 500 kV power system has developed even faster. Till 1998 about 55 substations (500 kV) were already put into operation, in which 217 transformers were installed, and the total capacity reached 60410 MVA. At present, there are 30 substations under construction. In addition, it has been planned to construct/extend 30 substations in accordance with the power delivery from Three Gorges Power Plant.A complete design system of AC 500 kV substation in China has been gradually established based on the past design and construction experiences and the use of new technologies. This system includes design procedure, design standards, rules and regulations, design management and so on.The essential design principles are safe and reliable ,technically advanced ,economical and reasonable, and good quality.2. Size of SubstationsChina is a developing country with broad territory. The economic development is very different from one region to another. In accordance with this fact, the 500 kV substation size is different at different time and for different regions.Generally there are several classes of transformer capacity in substation according to different stages of construction:Initial stage, MVA Final stage, MVAI 1 X500(750) 2 >500(2 >750)II 1X750 3X750川 1 X750(2 X50) 4 750(1000,1500)The numbers of 500 kV and 220 kV outgoing lines from substation differ from time to time. Usually there are 1-4 circuits of 500 kV lines and 6-8 circuits of 220 kV lines in the first stage of construction, and finally the number reaches 6-10 circuits of 500 kV and12-14 circuits of 220 kV lines.Whether install or not the high voltage reactor is decided by systematical investigation in overvoltage level and line length. Reactive compensation facilities at low voltage side ofmain transformer are also designed in accordance with the system conditions and the principle of “ compensationon the spot according to the condition of each voltage level and region . Usua”lly in first stage of construction only low voltage shunt reactors are installed, reserving the possibility to install shunt capacitors. But some times, especially in recent projects, shunt reactors and capacitors may be installed simultaneously in first stage of construction.3. Electrical Design Features3.1 Main Electrical ConnectionsIt is very important to select main electrical connection for safe and reliable operation and project cost control. The most popular 500 kV electrical connection is one-and-half circuit breaker connection, which are flexible, reliable, relatively and less landused. Double sectionalized bus with transfer bus connection also being employed in some early projects. In the 1 1/2 CB connection configuration, source and load circuits are usually arranged in pair and in series, with same title circuits arranged in different series. It is permitted to connect the same title circuits to the same bus, 2 transformer groups into series separately and the other 2 groups to bus separately. 3 current transformer groups are installed in every series and single phase capacitive voltage transformers(CVT) are installed at line and transformer sides. Special calculations are required to decide if bus arresters to be installed. At initial construction stage outgoing lines and transformer groups use 1-2 breakers. For 1 1/2 Cb connection, if number of series is equal to or more than 3 at initial stage, outgoing isolating switches are not installed for the line and transformer. If there are only 2 series in the initial stage, they should be installed.In most cases double bus (single or double sectionalized bus connection) with transfer bus scheme are used in 220 kV main electrical connections. In some projects 1 1/2 CB connection is employed, but in several projects double bus without transfer facilities is also used. In case of double bus connections three phase CVT are installed on every bus section, single phase CVT being installed in line side.Single-bus connection is used at main transformer low voltage side without outgoing line circuits, only reactive compensation and auxiliary power system circuits being connected. There are three cases for the general breaker at 35 kV side: not installed, reserve installation position and installed. Likewise, there are two cases for breaker in branch reactor circuits: installed at bus side or at reactor neutral point. As well, in auxiliary power system circuit breakers or limiting-current reactors with fuses may be employed.Typical main electrical connection diagrams are shown in Fig.1.3.2 Equipment SelectionThe short circuit current level is usually computed in accordance with the system development plan within 10-15 year after substation commissioning. In general cases it is selected as 50 kA,50 kA,40or50 kA(31.1 kA)for 500 kV, 220 kV, 35 kV(66kV)bus-bar respectively. At present time short circuit current level for 500 kV side reaches 62 kA in some substations. The problem, that short circuit current level for 220kV side in some substations may reach 63 kA in future, will be solved by employing control measures inthe system, for example, to divide the power supply area into parts.Usually single-phase auto-transformers with forced oil and air cooling are equipped. Special system voltage regulation computation is needed for employing on-load tap-changer transformer. Because of the quality improvement of domestic made transformer, spare transformer is usually not installed in recent years. In some cases, in accordance with transformer manufacture conditions, a spare transformer is necessary for substations in the whole region. In some projects three-phase transformers are used after economical and technical comparison in transformer including its transportation conditions.500 kV circuit breakers are usually ceramic pole type or tank type. In some special cases, for example, high altitude, severe atmospheric pollution regions and limited site area, SF metal enclosed gas insulated switchgear(GIS)may also be used. Circuit breakers usually have 4-3 breaks in one phase, or 2 in recent years. 500 kV isolating switches are usually single-or double-pole horizontal swatch-and-draw type, which occupies relatively less land area. 500 kV current transformers are oil or SF insulated. 35(or66)kV shunt reactors are oil immersed type or aircrew dry type.In order to reduce switching over voltage, 500 kV insulation level and air gaps, high quality SF circuit breakers and good protection performance metal oxide arresters are employed. In case of relatively long line it may be necessary to equip closing resistors in circuit breakers according to computation study.The external insulation level of electrical equipment is selected according to the regional atmospheric pollution conditions. Usually the selected pollution class is not lower thann ,that is, the unit leakage distanee is not less than 20 mm/kV for 500 kV and 220 kV apparatus. The external insulation level for neutral ungrounded low voltage side should be strengthened to one elass higher. The general leakage distanee is ealeulated by using maximum operating voltage.3.3 Insulation CoordinationInsulation eoordination is determined in aeeordanee with the prineiples stated in China Power Industry Standard DL/T62 0- 1997“Ove rl a rg e Proteetion and Insulation Coordination for AC Eleetrieal Installations. ”Power frequeney overvoltage: 1.3Uxg for substation side of line breaker, 1.4Uxg for line side. Here Uxg is the maximum operating phase voltage.The eoordination faetor between nominal lightning impulse withstand voltage of eleetrieal installations and residue voltage of substation arresters under nominal diseharge eurrent is adopted as 1.4.Coordination faetor between nominal phase-to-earth switehing impulse withstand voltage of eleetrieal installation internal insulation and proteetion level of arrester under switehing overvoltage should not be less than 1.15.3.4 SwitchyardUsually the following busbar types are used in 500 kV switehyard: double bundle diameter-extended soft buses, supported thiek aluminum tube buses, or suspended aluminum tube buses by V type insulator strings. The switehyard may be arranged in one, two or three outgoing line directions types. Two outgoing directions type is usuallyused, and breakers are arranged in three columns with medium height type. The transformers are connected in series with low frame crossing type, each bay width being 28 m. There are service paths between phases for repairing the switchgear.For 220 kV switchyard, supported or suspended aluminum tube buses are used. Circus breakers are arranged in medium height type in single or two lines, each bay width being 13 or 13.5 m. There are service paths between circuit breakers and current transformers.3.5 Grounding SystemThe service life of grounding systems is the same as the designed service life of ground project. In case of high soil resistivity and great short circuit current the ground potential may exceed the value limited by regulation even if measures to reduce grounding resistance are adopted. In these cases potential equalization and electrical insulation measures should be used according to the regulations. The typical methods to reduce grounding resistanceinclude deep burying grounding poles and extending grounding. 3.6 Control SystemIn general three types of control systems are employed: electronic one-to-one control, electronic transfer to power one-to-one direct control and 220 V power one-to-one direct control. Mosaic control panel and computer monitoring systems are used. Accordingly, conventional control systems should be adequately simplified, for example, the measuring systems and lighted-letter signals can be simplified or even canceled, and partial or all their functions can be realized by computer systems. At present time in some substations computer monitoring-and-control systems are used, at the same time the conventional monitoring-and-control systems are not used. In case of distributed computer monitoring-and-control systems, small relay rooms near switchgear are set up, in which relays and computer subsystemsare installed. Basic manual operation functions are reserved in relay cabinets.Computer monitoring-and-control systems are distributed, open circuit mode. Hardware and software should be designed to cater for the substation future extension. AC data acquisition system is used. Computer monitoring-and-control system and RTU system should use common data acquisition system. Relay protection should be installed separately, and their operation signals and other informations should be entered into the computer system.The computer system should fulfill the requirement of substation monitoring-and-control, synchronizing, and prevention from mal-operation. Computer systems should have good anti-interference performance.3.7 General Layout of SubstationGeneral layout of 500kV substation is composed of the following four parts: 500kV outdoor switchyard, 220kV outdoor switchyard, main transformer with reactive compensation installation, main and auxiliary buildings.The layout is arranged in accordance with the general planning and engineering requirements, taking into account the substation natural conditions and special characteristics of projects, fully satisfying requirement in safe and reliableoperation/maintenance of the substation. With these preconditions the following principles are also considered: less land used, compact layout, reduced cost andconvenient for future extension. In recent years the territory area within substation boundary walls is usually limited to be about 7-9 ha, and the administration area in front of substation to be about 0.5 ha.The typical layout is shown in Fig.2.3.8 Civil EngineeringThe ground elevation of the substation site shall be higher than the high flood level of 1% frequency. In case the elevation is lower, the substation area shall be surrounded by flood-prevention dike or other reliable flood-prevention facilities.The general building area in substation designed and/or constructed in recent years is as follows: 2700-2900 in case of centralized relay protection, and 2100-2300 if protection apparatus are distributed in vicinity of switchyard.Steel tube frameworks are used for the outdoor switchyard installation with advantage of its relatively low steel consumption, but angle iron structure can also be employed. Water sprayer fire extinguishers are employed for main transformers.4. Prospect of 500 kV Substation DesignthChina will come into “ The10th Five-year Plan ”atthe beginning of 21 century, and competitive bidding system will be widely used in procurement.An upsurge of 500 kV substation construction in accordance with power delivery for the three Gorges Power Plant will be seen in the neat future. Generally domestic made equipments will be employed in these substations, but is is not exclusive to imported ones.In addition to assuring safety and reliability, 500 kV substation of next century should be designed in accordance with the following principles: economization of land-use, employment of computer monitoring and control systems, unmanned or only a few on duty in substation, etc., So more and more high and new technologies and hi-tech products will be used.翻译：AC 500 千伏变电站的设计摘要：关于在中国的AC 500kV 分站的一些简要的信息，他们的设计历史数据和根本设计原则在本文被提出。

变电站建设外文文献翻译(文档含中英文对照即英文原文和中文翻译)General Requirements to Construction of SubstationSubstations are a vital element in a power supply system of industrial enterprises．They serve to receive ，convert and distribute electric energy .Depending on power and purpose ,the substations are divided into central distribution substations for a voltage of 110-500kV;main step-down substations for110-220/6-10-35kV;deep entrance substations for 110-330/6-10Kv;distribution substations for 6-10Kv;shop transformer substations for 6-10/0.38-0.66kV.At the main step-down substations, the energy received from the power source is transformed from 110-220kV usually to 6-10kV(sometimes 35kV) which is distributed among substations of the enterpriseand is fed to high-voltage services.Central distribution substations receive energy from power systems and distribute it (without or with partial transformation) via aerial and cable lines of deep entrances at a voltage of 110-220kV over the enterprise territory .Central distribution substation differs from the main distribution substation in a higher power and in that bulk of its power is at a voltage of 110-220kV;it features simplified switching circuits at primary voltage; it is fed from the power to an individual object or region .Low-and medium-power shop substations transform energy from 6-10kV to a secondary voltage of 380/220 or 660/380.Step-up transformer substations are used at power plants for transformation of energy produced by the generators to a higher voltage which decreases losses at a long-distance transmission .Converter substations are intended to convert AC to DC (sometimes vice versa) and to convert energy of one frequency to another .Converter substations with semiconductor rectifiers are convert energy of one frequency to another .Converter substations with semiconductor rectifiers are most economic. Distribution substations for 6-10kV are fed primarily from main distribution substations (sometimes from central distribution substations).With a system of dividing substations for 110-220kV, the functions of a switch-gear are accomplished by switch-gears for 6-10kV at deep entrance substations.Depending on location of substations their switch-gear may be outdoor or indoor. The feed and output lines at 6-10kV substations are mainly of the cable type .at 35-220kV substations of the aerial type .When erecting and wiring thesubstations ,major attention is given to reliable and economic power supply of a given production.Substations are erected by industrial methods with the use of large blocks and assemblies prepared at the site shops of electric engineering organizations and factories of electrical engineering industry .Substations are usually designed for operation without continuous attendance of the duty personnel but with the use of elementary automatic and signaling devices.When constructing the structural part of a substation .it is advisable to use light-weight industrial structures and elements (panels ,floors ,etc.) made of bent sections .These elements are pre-made outside the erection zone and are only assembled at site .This considerably cuts the terms and cost of construction.Basic circuitry concepts of substations are chosen when designing a powersupply system of the enterprise .Substations feature primary voltage entrances .transformers and output cable lines or current conductors of secondary voltage .Substations are mounted from equipment and elements described below .The number of possible combinations of equipment and elements is very great .Whenelaborating a substation circuitry ,it is necessary to strive for maximum simplification and minimizing the number of switching devices .Such substations are more reliable and economic .Circuitry is simplified by using automatic reclosure or automatic change over to reserve facility which allows rapid and faultless redundancy of individual elements and using equipment.When designing transformer substations of industrial enterprises for all voltages ,the following basic considerations are taken into account:1. Preferable employment of a single-bus system with using two-bus systems only to ensure a reliable and economic power supply;2. Wide use of unitized constructions and busless substations;3.Substantiated employment of automatics and telemetry ;if the substation design does not envisage the use of automatics or telemetry ,the circuitry is so arranged as to allow for adding such equipment in future without excessive investments and re-work.e of simple and cheap devices-isolating switches ,short-circuiting switches ,load-breaking isolators ,fuses ,with due regard for their switching capacity may drastically cut the need for expensive and critical oil ,vacuum ,solenoid and air switches .Substation and switch-gear circuitries are so made that using the equipment of each production line is fed from individual transformers ,assemblies ,the lines to allow their disconnection simultaneously with mechanisms without disrupting operation of adjacent production flows.When elaborating circuitry of a substation, the most vital task is to properly choose and arrange switching devices(switches ,isolators ,current limiters ,arresters ,high-voltage fuses).The decision depends on the purpose ,power and significance of the substation.Many years ago, scientists had very vague ideas about electricity. Many of them thought of it as a sort of fluid that flowed through wires as water flows through pipes, but they could not understand what made it flow. Many of them felt that electricity was made up of tiny particles of some kind ,but trying to separate electricity intoindividual particles baffled them.Then, the great American scientist Millikan, in 1909,astounded the scientific world by actually weighing a single particle of electricity and calculating its electric charge. This was probably one of the most delicate weighing jobs ever done by man,for a single electric particle weighs only about half of a millionth of a pound. To make up a pound it would take more of those particles than there are drops of water in the Atlantic Ocean.They are no strangers to us, these electric particles, for we know them as electrons. When large numbers of electrons break away from their atoms and move through a wire,we describe this action by saying that electricity is flowing through the wire.Yes,the electrical fluid that early scientists talked about is nothing more than electrical flowing along a wire.But how can individual electrons be made to break away from atoms? And how can these free electrons be made to along a wire? The answer to the first question lies in the structure of the atoms themselves. Some atoms are so constructed that they lose electrons easily. An atom of copper, for example ,is continually losing an electron, regaining it(or another electron),and losing it again. A copper atom normally has 29 electrons, arranged in four different orbits about its nucleus. The inside orbit has 2 electrons. The next larger orbit has 8.The third orbit is packed with 18 electrons . And the outside orbit has only one electron.It is this outside electron that the copper atom is continually losing, for it is not very closely tied to the atom. It wanders off, is replaced by another free-roving electron, and then this second electron also wandersaway.Consequently,in a copper wire free electrons are floating around in all directions among the copper atoms.Thus, even through the copper wire looks quite motionless to your ordinary eye, there is a great deal of activity going on inside it. If the wire were carrying electricity to an electric light or to some other electrical device, the electrons would not be moving around at random. Instead, many of them would be rushing in the same direction-from one end of the wire to the other.This brings us to the second question .How can free electrons be made to move along a wire? Well ,men have found several ways to do that .One way is chemical. V olta,s voltaic pile,or battery, is a chemical device that makes electricity(or electrons)flow in wires. Another way is magnetic. Faraday and Henry discovered how magnets could be used to make electricity flow in a wire.MagnetsAlmost everyone has seen horseshoe magnets-so called because they are shaped like horseshoes. Probably you have experimented with a magnet, and noticed how it will pick up tacks and nails, or other small iron objects. Men have known about magnets for thousands of years.Several thousand years ago, according to legend, a shepherd named Magnes lived on the island of Crete, in the Mediterranean Sea .He had a shepherds crook tipped with iron. One day he found an oddly shaped black stone that stuck to this iron ter, when many other such stones were found, they were called magnets(after Magnets).These were natural magnets.In recent times men have learned how to make magnets out of iron. More important still, they have discovered how to use magnets to push electrons through wires-that is, how to make electricity flow. Before we discuss this, there arecertain characteristics of magnets that we should know about.If a piece of glass is laid on top of a horse- shoes magnet, and if iron filings are then sprink ledon the glass, the filings will arrange themselves into lines. If this same thing is trid with a bar magnet(a horseshoe magnet straightened out),the lines can be seen more easily. These experiments demonstrate what scientists call magnetic lines of force. Magnets, they explain, work through lines of force that ext- end between the two ends of the magnet. But electrons seem to have magnetic lines of force around them, too.This can be proved by sticking a wire through a piece ofcard board, sprinkling iron filings on the cardboard, and connecting a battery to the wire. The filings will tend to form rings around the wire,as a result of the magnetism of the moving electrons(or electricity).So we can see that there is arelationship between moving electrons and magnetism, Magnetism results from the movement of electrons.Of course, electrons are not really flowing in the bar magnet, but they are in motion, circling the nuclei of the iron atoms. However, in the magnet, circling thelined up in such a way that their electrons are circling in the same direction. Perhaps a good comparison might be a great number of boys whirling balls onstrings in a clockwise direction around their heads.翻译：变电站建设的一般要求变电站(所)在电源系统的工业企业是一个至关重要的因素。

附录附录A外文资料Design of Mv/Lv Substation TransformerAbstract：A substation is a part of an electrical generation, transmission, and distribution system. Substations generally have switching, protection and control equipment, and transformers. The low voltage distribution networks are supplied from MV/LV substation transformer that represent the last step of bringing transformation to the low voltage and ensuring the protection and monitoring of the network. There are three types of MV/LV substation: pole-mounted transformer substation, the substation in an envelope and substation in masonry. This paper presents a general description for different MV/LV substation and a methodology to design the various elements making up the public distribution substation (choice of the emplacement, engineering, power transformer, choice of MV cells, circuit breakers, fuses, disconnect switch, conductors,...etc).Keywords:Substation transformer MV cells Substation in masonryPole-mounted transformer substation1. IntroductionA substation is a part of an electrical generation, trans-mission, and distribution system. Substations transform voltage from high to low, or the reverse, or perform any of several other important functions. Electric power may flow through several substations between generating plant and consumer, and its voltage may change in several steps. Substations generally have switching, protection and control equipment, and transformers. Distribution circuits are fed from a transformer located in an electrical substation, where the voltage is reduced from the high values used for power transmission.Distribution networks are typically of two types, radial or interconnected. A radial network leaves the station and passes through the network area with no normal connection to any other supply. This is typical of long rural lines with isolated load areas. An interconnected network is generally found in more urban areas and will have multiple connections to other points of supply. These points of connection arenormally open but allow various con-figurations by the operating utility by closing and opening switches. Operation of these switches may be by re-mote control from a control center or by a lineman. The benefit of the interconnected model is that in the event of a fault or required maintenance a small area of network can be isolated and the remainder kept on supply.The MV/LV substations are a node of a network, which includes a set of equipment designed to protect and facilitate the operation of the electrical energy . The MV/LV substations provide the interface between the distribution MV and LV. The MV / LV adapts to all modes of operation and why should fulfill the following functions:● Distribute the power and protect the LV departures;● Is olate the MV/LV substation in case of default;● Manage the MV network in case of default and the position by remote control.MV/LV substation transformer has two purposes:- The interconnection between the lines of the same voltage level, it helps to distribute the power of the different lines from substations.- The transformation of electrical power, processors can switch between voltage levels to another.So, we can classify the MV/LV substations over the networks on which they are used as well as the functions they perform. The realization of MV/LV substations needs prior knowledge:● Standards of reference and statutory instruments (voltage, quality of supply, short-circuit power, ..., etc);● Needs to be performing (power plant availability, op eration);● Specific needs-related uses (voltage variations tolerated, compensation of reactive power, immunity to interference receivers, regulations related to facility security);● Constraints, installation and environment .This paper presents the different MV/LV substation transformer and a methodology to design the various elements making up the public distribution substation.2. The Birth of MV/LV Substation TransformerThe decision of a MV or LV supply will depend on local circumstances and considerations such as those mentioned above, and will generally be imposed by the utility for the district concerned. When a decision to supply power at MV has been made, there are two widely-followedmethods of proceeding:● The power-supplier constructs a st andard substation close to the consumer’s premises, but the MV/LV transformer is located in transformer chamber inside the premises, close to the load centre.● The consumer constructs and equips his own substation on his own premises, to which the power supplier makes the MV connection .2.1. Project StudiesThe consumer must provide certain data to the utility at the earliest stage of the project. the power-supplier must indicate:● The type of power supply proposed, and define the kind of power-supply system: over headline or under-ground-cable network, the service connection details: single-line service, ring-main installation, or parallel feeders, and the power (kVA) limit and fault current.● The nominal voltage and rated voltage (Highest volt- age for equipment)● Metering details which define: The cost of connection to the power network and tariff details (consumption and standing charges).2.2. ImplementationBefore any installation work is started, the official agreement of the power-supplier must be obtained. The request for approval must include the following information, largely based on the preliminary exchanges noted above:● Location of the proposed substation;● Single-line diagram of power circuits and connections, together with earthing-circuit proposals;● Full details of electrical equipment to be installed, including performance characteristics;● Layout of equipment and provision for metering components;● Arrangements for power-factor improvement if required;● Arrangements provided for emergency standby power plant (MV or LV) if eventually required.●Prefabricated substations.3. Classification of Mv/Lv Substation Transformer BirthSubstations transformer may be classified according to metering arrangements(Mv or Lv) and type of supply(overhead line or underground cable),Substations transformer are classified into three types:● Substation in masonry: Installed in a dedicated enclosure prefabricated or not, with indoor equipment (switchgear and transformer) ;● Pole mounted(S ≤ 160kVA)with dedicated outdoor equipment (switchgear and transformer);● Prefabricated substations.3.1. Pole Mounted SubstationsThese substations are mainly used to supply isolated rural consumers from MV overhead line distribution systems. In this type of substation, most often, the MV transformer protection is provided by fuses.The kinds of outdoor substation are common in some countries, based on weatherproof equipment exposed to the elements. The pole mounted substation is the easiest, it is used in cases where the power transformer is less than or equal to 160 KVA.3.2. Prefabricated SubstationsPrefabricated substations provide a particularly simple, rapid and competitive choice. The MV/ LV prefabricated are made using: MV cells, transform er …etc, grouped in an envelope whose role is the protection of internal equipment against external influences and to ensure a degree of protection against the public. The prefabricated substations are manufactured, wired and tested at the manufacturer, bringing the transformer, the LV and MV switchgear, connections and auxiliary equipment limit the study time and achievement. The transformer and switchgear are assembled in a metal case, the start is done by airline or underground, these substations are very compact and their implementation is very fast, one of the best-known benefits:● Simplified civil engineering (platform only);● Immediate availability;● Limited space and time.● The prefabricated substation is transported by truck. It is placed on a concrete slab.3.3. Masonry SubstationOperating a distribution network sometimes requires switching points in addition to the HV/MV substations, in order to limit the effect of a fault on the network. Distribution substations in masonry may be classified into three types:● Public Distribution substations (DP);● Distribution substations with LV metering (S ≤ 630 kVA);● Distribution substations with MV metering called specific substations (a transformer whose power S> 630 kVA or several transformers).4. Design of Public Distrubution SubstationPublic distribution substations with prefabricated cells metal is done with cells each fulfilling a function. The public distribution substation includes:● 02 incoming panels,● Fuse-switch combination or fused switch;● Fault detector for MV underground;● LV circuit breaker (Table of public distribution);● Power Transformer 100,160, 250, 400.630 KVA;● Cell power transformer (closing metal);● Safety equipment;● Boxes of deflector;● Boxes end external and internal;● MV cable and lugs;● Spare fuses;5. ConclusionIn this paper, we presented a synthesis of the various MV/LV substation transformer, we have explained below the various documents constituting technical study, a detailed study of the public distribution substations Operating a distribution network requires switching points in addition to the MV/LV substations, in order to limit the effect of a fault on the network. To build a MV/LV substation transformer, it is necessary to size a number of parameters to achieve the appropriate wiring diagram. The development of these components must meet certain conditions dictated by the dual concern for the safety of operation and lower operating costs. These construction conditions can be classified into conditions related to tension, conditions relating to the thermal effects of the current, and conditions relating to the safety of operating personnel.From: 2013.51b004 Published Online January 2013 ()中压/低压变电站变压器的设计摘要:变电站是电力系统中的发电、输电、和配电的一部分。

学校代码：11517学号：2HENAN INSTITUTE OF ENGINEERING 文献翻译题目 110kv变电站设计学生姓名褚帅峰专业班级电气工程及其自动化1021班学号 2系（部）电气信息工程系指导教师(职称) 任鹏飞完成时间 2012年 2月 18日一种实用的输配电系统的维护优化计划Sohrab Asgarpoor Mohamad DoghmanDepartment of Electrical Engineering Principal Research EngineerUniversity of Nebraska-Lincoln Omaha Public Power Distric摘要：今天，维护和/或提高系统的可靠性和降低运营和维护（O＆M）成本是电力的首要任务。

由于系统设备继续老化，并逐渐恶化，由于组件故障增加的服务中断的概率。

一个有效的维护策略是在提供安全可靠的电力客户经济所必需的。

本文的目的是提供一个预测，条件为基础的框架，且成本有效的维护，输电和配电系统的优化方案。

引言原则上，提高系统的可靠性和降低运营和维护（O＆M）成本是电力的重中之重。

在竞争日益激烈的电力输送环境，电力公司被迫申请实用资产管理更加积极主动的方法。

的电力交货资产管理的主要组成部分之一，是资本预算和现有设施的O＆M。

由于在许多情况下，建设和设备采购的成本是固定的，澳＆M的支出为削减成本和潜在的储蓄的主要候选人。

由于系统设备继续老化，并逐渐恶化，由于组件故障增加的服务中断的概率。

电力公司都面临着许多挑战，在这种竞争的新时代：上升的O＆M成本，系统上的需求不断增长，保持高可靠性和电能质量水平和管理设备老化。

因此，健康的设备是由设备条件的影响，因为收入行业至关重要。

当需求高和设备的工作秩序，丰厚的收入可以实现的。

相反，不健康的设备可能会导致服务中断，顾客不满，善意的损失，并最终失去客户。

提供安全可靠的电力客户经济有效的维护策略是必不可少的。

毕业论文中英文翻译-变电站翻译本科毕业设计（论文）中英文对照翻译院（系部）___专业名称___________________ 年级班级_______________学生姓名___________________ 指导老师英文文献Second substation equipment over-voltage protection on electronic information system for the protection of core equipment fur the construction of a protected both pressure and other potential system, and through all levels of over-voltaj»c surge protectors of the current step by step into the land ， Substation secondary safety equipment and reliable operation.1second over-voltage substation protectionJn recent years, the substation communicadon!；, communications systems, protection systems, background management module frequent over-voltage damage, the main reason for this is weak and its related systems products over-voltage protection level is or no guard against over-vol(agt 1 ^chnical measures, the consequences for the safe operation of power grids bring about a greater negative impact. With integrated automation systems and automation systems such as communication systems in the substation weak secondary by the wider use of sitch electronic systems (equipment) components of the integrated more and more, the growing volume of information storage^ speed and accuracy of the Increased and operates only a few volts, current information only microiiinp level, thus extremely sensitive to outside interference, especially the lightning and electrumagnetic pulse, such as over-voltage tolerance is low・ When thunder and lightnings such as over-voltage and accompanied by the electromagnetic fields reach a certain threshold^ ranging from system failure caused, resulted in heavy equipment or permanent damage to its components. Despite the thunder and lightning viewpoint of electronic systems (equipment) is unlikely, but lightning strike near the land, building communication and air supply line directly l^eiyun discharge form, or because of electrostatic induction nnd the impact of electromagnetic induction formation of over-voltage, There might be connected to the power lines, signal lines or grounding system, through various interfaces to transfer, coupling, radiation and other forms of invasive electronic system (equipment) und lead to serious disturbances or incidents. Therefore, strengthening and improving the electronic system (equipment) protectioru to minimize the impact of interierence by lightning and other damage caused direct losses and indirect losses, has become the urgent need to solve the prublenL2over-voltage protection design】EC (International Electrotechnical Com miss ion) TC/81 mine technical committee will be divided into internal and external mine mint in two parts, the external mine is lightning rod (or with lightning, lightning network), Vin Xiaxian and grounding system, Objects to be protected from direct lightning ^trikes^mine is to prevent internal lightning and other internal over-voltage damage caused by invasive equipment. A comprehensive mine and over-voltage protection systems must be integrated use of discharge (segregation), both pressure (and other potential), shielding (isolation), grounded, limit pressure (clamp) protection, and other technology, in accordance with the external mine And the principle of internal mine, in accordance with the targets of protective features, flexible application to take concrete measures, constitute a complete protection system. Over-voltage substation in the form are: Lightning over-voltage, the resonant frequency over-voltage and over-voltage, over-voltage operation, these over-voltage transmission or electromagnetic induction to the way the lines and equipment on a dangerous over-voltage, in particular, Lightning over-voltage, lightning substation, in the low-voltage power supply system and weak system to produce a strong over-voltage sensor, while the substation to potential rise (for example: the substation grounding resistance to 1 Q, lightning current 10 kA, while the potential for 10 kV), due to the increased potential of the counter lines and equipment damaged lines and equipment and the events have occurred, therefore, despite the substation outside the mine system (lightning rod. Yin Xiaxian And grounding devices) in line with national standards and the requirements of Buban, and the integrated automation and communications automation systems, such as weak secondary have been taken, such as shielding, grounding, isolation, filtering, and other measures, but it can not completely avoid over-voltage powerful lightning And voltage of the system counter the disruption caused damage and, therefore, the second weak system substation and a mine-voltage must also take the appropriate protective measures, in accordance with the IEC within the mine area EMP, the device's power cord, signal Lines, data lines, and the installation of lightning protection and internal over-voltage devices to prevent lightning sensors, channeling people along the lightning current, voltage counterattack, such as transient voltage surge too transient over-voltage caused by a fault and damaged electronic equipment. Over-voltage surge protection in accordance with its connection mode is divided into two series and parallel, the use of over-voltage surge protection tandem with, there may exist because of signal transmission does not match the causes of transmission of the signal interference, in particular data Communication Interface in the series were over-voltage surge protection in place, will have the normal data communications. Therefore, the data communications access I: I in the series were over-voltage surge protection in place, the transmission of data must be carried out conscientiously check if the data are not normal transmission, it maybe due to the reasons do not match the transmission signal Interference, should be replaced to match the over-voltage surge protection for. If the use of over-voltage surge protection for use of parallel, the situation is basically non-existent, but the connection mode of over-voltage surge protection for higher technical requirements.3 secondary system over-voltage substation protection 3.1points over-voltage electricity system protectionSubstation installed in the communications dispatch automation systems are used AC power or a DC power supply equipment for the rectification of its links are generally larger capacity filter capacitance, the transient over-voltage shock absorption of a certain extent, the station Low-voltage transformer side go to feed between the screen using a shielded cable and equipment have a good grounding, the use of modern technology to analyze mine, we must increase the circuit's segregation measures, because its grounding, protection and other electrical grounding all Grounding devices using the same equipment, and equipment are in a LPZOB, the relative strength of strong electromagnetic pulse, the station changed to prevent low-pressure side although there are lines intrusive wave arrester, but the residual pressure high, in the substation of lightning, through the line Coupling and the potential rise caused by over-voltage counterattack still exist, and high-pressure side of the residual pressure as high as several thousand volts, it is necessary to these scheduling automation equipmentfor the power supply over-voltage circuit protection. Lightning Protection in accordance with the principle of regional division, substation equipment in the secondary power supply system over-voltage sensors lightning protection may be two (B, C level) for the protection of segregation. B-mine use is generally greater flow capacity of the mine installations, the Lightning could be more casual Liuxie people, to achieve the objective of current limit, over-voltage at the same time will reduce to a certain extent, c-mine use With lower residual pressure of the mine installations, you can loop in the remaining scattered lightning Liuxie people, to limit the purpose of over-voltage, over-voltage equipment can be reduced to the level of tolerance. The main power supply system is inhibited lightning protection and operation of the power back to the road and over-voltage surge. According to the substation status of the substation of the second mine-sensing system and the operation and use of two over-voltage protection. As build more substations in the region more open, relatively strong electromagnetic strength, power lines and communication cables are very vulnerable to lightning attacks sensors, sensors along the over-voltage power lines and communication lines into one device, which will damage equipment, Therefore, the exchange of first-class bus to install the power protection (B level) is to ensure the safety of the entire control room, and 80 percent of the over-voltage China, scattered to the earth, play a primary role in the protection, but are still in the exchange of feeder Some of the B-level power supply voltage and mine the residual pressure increases on-line and must therefore be important in the exchange of feeder lines (DC charging screen, UPS, etc.) c-level power protection, which would curb over-voltage electrical equipment to back-end To the level of tolerance.Protective location: It is 1 EC1312 (LEMP protection "in the region of lightning protection principles. Arrester installation should be in different locations at the junction of protected areas, this network, the first-class protection should be located in the bus exchange. In Two on the bus with the installation of a B-class models of a three-phase power supply voltage surge protector.Install Location: AC bus (cabinet).For the more important feeder lines on the exchange of equipment, here for the DC charge screen, the installation of c-level three-phase power arrester. As DC charging screen is two-way exchange of electricity supply, so the screen in the DC charge with the installation of two models of c-level three-phase power supply over-voltage surge protector. Installation location should choose the DC charge screen open exchange of air power Commissioner Office.3.2integrated automation system over-voltage protectionProtective position: Computer-based integrated automation system's ability to bear a very low voltage, several hundred volts of over-voltage is enough to damage the equipment, so must the high side arrester the residual pressure (thousands of volts) to further curb to meet equipment Insulation level of need, and because of the potential rise to power and the induction loop is also over-voltage line up on KV, to be used in the exchange of integrated automation system to the exchange on the c-level single-phase installation of a surge Voltage protection. Location should choose to install automated-ping in the Composite Air switch the AC power.3.3did not ask off power supplies (UPS) over-voltage protectionProtection here: because of the internal computer systems, hubs, monitoring equipment, electric energy billing systems and so on through the UPS power supply protection, in order to protect the safety of these micro-electronics equipment, the UPS power supply device in front of the installation of a c-Surge Voltage protection. Optional models: The (UPS for single-phase power input) C-class single-phase power surge or over-voltage protection (UPS for the three-phase power input) of c-level three-phase power supply over-voltage surge protector. Installation should choose the location of UPS into the front line.3.4communication interface over-voltage protectionCommunication Interface over-voltage protection compared with the grid supply system, this over-voltage circuit on the degree of sensitivity is much higher, and these are over-voltage equipment in the circumstances itis very fragile. Equipment insulation tolerance level is very low. With the equipment connected to a signal line, data lines, measurement and control lines, and these are basically in line LPZOB region, but also through the LVZOA region, on the lines of sensors over-voltage relatively strong, according to the IEC test, when the electromagnetic field Strength increased to 0.07 GS, will have a micro-computer equipment malfunction, loss of data. And the safety of these circuits is directly related to a system of safety equipment, so important to be on the interface circuit over-voltage protection.3.4.1remote computer interface devices over-voltage protectionProtective position: As substation computer remote installations scattered distribution structure. From remote modules, intelligent telemetry module, intelligent remote control module, intelligent remote-module. The modules are installed in different automated-ping, through the RS232 interface between the modules or field bus communication. These interfaces are in the indoor circuit, equipment interface circuits shorter the distance, so there will be no more sensors to the over-voltage, but the automation equipment and other secondary equipment (measurement unit, computer, etc.) have electrical connections, when Other secondary equipment sensors to a strong over-voltage sensors, will be counter to these automation equipment, communications interface, so that damage to equipment interface circuits, it is necessary in these devices RS232 interfaces on the installation of a surge Voltage protection. Installation location should choose the remote computer interface devices, communications lines.3.4.2electric energy billing system signals over-voltage protectionA protective position: a multi-functional electronic power substationtable, energy acquisition, the electronic power meter to bear a very low voltage levels. As Meter and remote computer stations in the communications equipment used RS232 interfaces, the communication line is longer, and in LVZOB region, near the substation or by direct lightning strike at the substation, proximity to the high voltage sensors, In order to prevent damage to equipment. E-Meter in and around the RS232 port RS232installation of the over-voltage surge protector. Location should choose to install electronic power meter in and around the port, RS232.The location of protection: electronic power meter through the acquisition of information on the collector's MODEM (modem) from telephone lines to send data to a remote, since the introduction of telephone lines from the outside, thelines on the sensor to sensor lightning current relatively strong, easy to Modem interface equipment damage, it is necessary in the telephone line modem interface, the installation of an interface over-voltage surge protector. Location should choose to install telephone Chuxian inside and outside phone lines-the-line people.变电站的过电压保护是以电子信息系统为保护核心，为被保护设备构建一个均压等电位系统，并通过各级过电压浪涌保护器逐级把电流泄放入大地，使变电站设备安全和可靠地运行。

毕业设计外文资料翻译题目智能变电站技术的研究学院自动化与电气工程学院专业电气工程及其自动化班级电控0903学生徐浩军学号20090321264指导教师李毅二〇一三年四月二十三日Energy Procedia 12 (2011) 113 – 119Research on Technologies in Smart SubstationHongwei Li*, Lixin WangTechnology College, State Grid Corporation of China , Jinan, China摘要：一个强大的智能电网是未来发展的方向，同时也建立了中国电网未来的目标。

智能变电站是智能电网的重要技术基础，对智能变电站的核心技术的研究在近年来已经吸引了越来越多的关注，在本文中我们演示了概念，策略和国家电网在智能变电站方面的目标，同时我们提出了在智能变电站最新的研究技术。

关键词：智能电网，智能变电站，智能设备，智能组件，智能电子设备，电子仪器。

1.介绍智能电网是一个现代电网，具有信息化、自动化和互动特征。

为了实现数字化变电站信息、网络通信平台和标准信息共享，智能变电站使用先进、可靠性能力、集成、低碳和环保的智能设备，从而实现信息采集，测量、控制、保护、计量、监测与其他基本功能,支持一系列的先进的功能,如顺序控制、智能报警和分析、故障信息综合分析、智能操作票系统,源——终端维护、变电站区域控制,等等。

作为一个具有六个环节的智能电网，智能变电站的发展目标是通过收集宽区域的的整个电网运行实时信息数据，实现智能灵活集群和自我适应地区控制保护变电站,支持安全的和稳定的合作，每个层次的电网和设备确保了信息的综合交流.与传统变电站年代相比,智能变电站基于先进的传感器技术点的信息数据分析方法取得了智能管理变电站设备的优点。

集成的一次和二次设备是采用的是通过智能改革的主要设备和电子仪器，变压器和条件的监测技术。

AC 500 kV Substation Design in ChinaAbstract: Some brief informations about AC 500kV substations in China, historical data of their design and essential design principles are presented in this paper. Some technical and engineering problems of AC500 kV substation design and construction are discussed. It is emphasized to introduce the 500 kV substation scales, main electrical connections, selection of equipment and apparatus, insulation coordination, distribution switchyard, control and protection etc.. here we also discuss the policy of project cost control at present time and a prospective view of China AC substations in future.1. IntroductionThe research and design of 500 kV substations in China were started in 1977,and the first substation was put into operation in 1981. From that time, because of the rapid development of electricity demand in China, design and construction of 500 kV substations have a great development. Especially in recent years, due to the increase of capital investment for power system construction from the State Government, 500 kV power system has developed even faster. Till 1998 about 55 substations (500 kV) were already put into operation, in which 217 transformers were installed, and the total capacity reached 60410 MVA. At present, there are 30 substations under construction. In addition, it has been planned to construct/extend 30 substations in accordance with the power delivery from Three Gorges Power Plant.A complete design system of AC 500 kV substation in China has been gradually established based on the past design and construction experiences and the use of new technologies. This system includes design procedure, design standards, rules and regulations, design management and so on.The essential design principles are safe and reliable ,technically advanced ,economical and reasonable, and good quality.2. Size of SubstationsChina is a developing country with broad territory. The economic development is very different from one region to another. In accordance with this fact, the 500 kV substation size is different at different time and for different regions.Generally there are several classes of transformer capacity in substation according to different stages of construction:Initial stage, MVA Final stage, MVAI 1 X500(750) 2 >500(2 >750)II 1X750 3X750川 1 X750(2 X50) 4 750(1000,1500)The numbers of 500 kV and 220 kV outgoing lines from substation differ from time to time. Usually there are 1-4 circuits of 500 kV lines and 6-8 circuits of 220 kV lines in the first stage of construction, and finally the number reaches 6-10 circuits of 500 kV and12-14 circuits of 220 kV lines.Whether install or not the high voltage reactor is decided by systematical investigation in overvoltage level and line length. Reactive compensation facilities at low voltage side ofmain transformer are also designed in accordance with the system conditions and the principle of “ compensationon the spot according to the condition of each voltage level and region . Usua”lly in first stage of construction only low voltage shunt reactors are installed, reserving the possibility to install shunt capacitors. But some times, especially in recent projects, shunt reactors and capacitors may be installed simultaneously in first stage of construction.3. Electrical Design Features3.1 Main Electrical ConnectionsIt is very important to select main electrical connection for safe and reliable operation and project cost control. The most popular 500 kV electrical connection is one-and-half circuit breaker connection, which are flexible, reliable, relatively and less landused. Double sectionalized bus with transfer bus connection also being employed in some early projects. In the 1 1/2 CB connection configuration, source and load circuits are usually arranged in pair and in series, with same title circuits arranged in different series. It is permitted to connect the same title circuits to the same bus, 2 transformer groups into series separately and the other 2 groups to bus separately. 3 current transformer groups are installed in every series and single phase capacitive voltage transformers(CVT) are installed at line and transformer sides. Special calculations are required to decide if bus arresters to be installed. At initial construction stage outgoing lines and transformer groups use 1-2 breakers. For 1 1/2 Cb connection, if number of series is equal to or more than 3 at initial stage, outgoing isolating switches are not installed for the line and transformer. If there are only 2 series in the initial stage, they should be installed.In most cases double bus (single or double sectionalized bus connection) with transfer bus scheme are used in 220 kV main electrical connections. In some projects 1 1/2 CB connection is employed, but in several projects double bus without transfer facilities is also used. In case of double bus connections three phase CVT are installed on every bus section, single phase CVT being installed in line side.Single-bus connection is used at main transformer low voltage side without outgoing line circuits, only reactive compensation and auxiliary power system circuits being connected. There are three cases for the general breaker at 35 kV side: not installed, reserve installation position and installed. Likewise, there are two cases for breaker in branch reactor circuits: installed at bus side or at reactor neutral point. As well, in auxiliary power system circuit breakers or limiting-current reactors with fuses may be employed.Typical main electrical connection diagrams are shown in Fig.1.3.2 Equipment SelectionThe short circuit current level is usually computed in accordance with the system development plan within 10-15 year after substation commissioning. In general cases it is selected as 50 kA,50 kA,40or50 kA(31.1 kA)for 500 kV, 220 kV, 35 kV(66kV)bus-bar respectively. At present time short circuit current level for 500 kV side reaches 62 kA in some substations. The problem, that short circuit current level for 220kV side in some substations may reach 63 kA in future, will be solved by employing control measures inthe system, for example, to divide the power supply area into parts.Usually single-phase auto-transformers with forced oil and air cooling are equipped. Special system voltage regulation computation is needed for employing on-load tap-changer transformer. Because of the quality improvement of domestic made transformer, spare transformer is usually not installed in recent years. In some cases, in accordance with transformer manufacture conditions, a spare transformer is necessary for substations in the whole region. In some projects three-phase transformers are used after economical and technical comparison in transformer including its transportation conditions.500 kV circuit breakers are usually ceramic pole type or tank type. In some special cases, for example, high altitude, severe atmospheric pollution regions and limited site area, SF metal enclosed gas insulated switchgear(GIS)may also be used. Circuit breakers usually have 4-3 breaks in one phase, or 2 in recent years. 500 kV isolating switches are usually single-or double-pole horizontal swatch-and-draw type, which occupies relatively less land area. 500 kV current transformers are oil or SF insulated. 35(or66)kV shunt reactors are oil immersed type or aircrew dry type.In order to reduce switching over voltage, 500 kV insulation level and air gaps, high quality SF circuit breakers and good protection performance metal oxide arresters are employed. In case of relatively long line it may be necessary to equip closing resistors in circuit breakers according to computation study.The external insulation level of electrical equipment is selected according to the regional atmospheric pollution conditions. Usually the selected pollution class is not lower thann ,that is, the unit leakage distanee is not less than 20 mm/kV for 500 kV and 220 kV apparatus. The external insulation level for neutral ungrounded low voltage side should be strengthened to one elass higher. The general leakage distanee is ealeulated by using maximum operating voltage.3.3 Insulation CoordinationInsulation eoordination is determined in aeeordanee with the prineiples stated in China Power Industry Standard DL/T62 0- 1997“Ove rl a rg e Proteetion and Insulation Coordination for AC Eleetrieal Installations. ”Power frequeney overvoltage: 1.3Uxg for substation side of line breaker, 1.4Uxg for line side. Here Uxg is the maximum operating phase voltage.The eoordination faetor between nominal lightning impulse withstand voltage of eleetrieal installations and residue voltage of substation arresters under nominal diseharge eurrent is adopted as 1.4.Coordination faetor between nominal phase-to-earth switehing impulse withstand voltage of eleetrieal installation internal insulation and proteetion level of arrester under switehing overvoltage should not be less than 1.15.3.4 SwitchyardUsually the following busbar types are used in 500 kV switehyard: double bundle diameter-extended soft buses, supported thiek aluminum tube buses, or suspended aluminum tube buses by V type insulator strings. The switehyard may be arranged in one, two or three outgoing line directions types. Two outgoing directions type is usuallyused, and breakers are arranged in three columns with medium height type. The transformers are connected in series with low frame crossing type, each bay width being 28 m. There are service paths between phases for repairing the switchgear.For 220 kV switchyard, supported or suspended aluminum tube buses are used. Circus breakers are arranged in medium height type in single or two lines, each bay width being 13 or 13.5 m. There are service paths between circuit breakers and current transformers.3.5 Grounding SystemThe service life of grounding systems is the same as the designed service life of ground project. In case of high soil resistivity and great short circuit current the ground potential may exceed the value limited by regulation even if measures to reduce grounding resistance are adopted. In these cases potential equalization and electrical insulation measures should be used according to the regulations. The typical methods to reduce grounding resistanceinclude deep burying grounding poles and extending grounding. 3.6 Control SystemIn general three types of control systems are employed: electronic one-to-one control, electronic transfer to power one-to-one direct control and 220 V power one-to-one direct control. Mosaic control panel and computer monitoring systems are used. Accordingly, conventional control systems should be adequately simplified, for example, the measuring systems and lighted-letter signals can be simplified or even canceled, and partial or all their functions can be realized by computer systems. At present time in some substations computer monitoring-and-control systems are used, at the same time the conventional monitoring-and-control systems are not used. In case of distributed computer monitoring-and-control systems, small relay rooms near switchgear are set up, in which relays and computer subsystemsare installed. Basic manual operation functions are reserved in relay cabinets.Computer monitoring-and-control systems are distributed, open circuit mode. Hardware and software should be designed to cater for the substation future extension. AC data acquisition system is used. Computer monitoring-and-control system and RTU system should use common data acquisition system. Relay protection should be installed separately, and their operation signals and other informations should be entered into the computer system.The computer system should fulfill the requirement of substation monitoring-and-control, synchronizing, and prevention from mal-operation. Computer systems should have good anti-interference performance.3.7 General Layout of SubstationGeneral layout of 500kV substation is composed of the following four parts: 500kV outdoor switchyard, 220kV outdoor switchyard, main transformer with reactive compensation installation, main and auxiliary buildings.The layout is arranged in accordance with the general planning and engineering requirements, taking into account the substation natural conditions and special characteristics of projects, fully satisfying requirement in safe and reliableoperation/maintenance of the substation. With these preconditions the following principles are also considered: less land used, compact layout, reduced cost andconvenient for future extension. In recent years the territory area within substation boundary walls is usually limited to be about 7-9 ha, and the administration area in front of substation to be about 0.5 ha.The typical layout is shown in Fig.2.3.8 Civil EngineeringThe ground elevation of the substation site shall be higher than the high flood level of 1% frequency. In case the elevation is lower, the substation area shall be surrounded by flood-prevention dike or other reliable flood-prevention facilities.The general building area in substation designed and/or constructed in recent years is as follows: 2700-2900 in case of centralized relay protection, and 2100-2300 if protection apparatus are distributed in vicinity of switchyard.Steel tube frameworks are used for the outdoor switchyard installation with advantage of its relatively low steel consumption, but angle iron structure can also be employed. Water sprayer fire extinguishers are employed for main transformers.4. Prospect of 500 kV Substation DesignthChina will come into “ The10th Five-year Plan ”atthe beginning of 21 century, and competitive bidding system will be widely used in procurement.An upsurge of 500 kV substation construction in accordance with power delivery for the three Gorges Power Plant will be seen in the neat future. Generally domestic made equipments will be employed in these substations, but is is not exclusive to imported ones.In addition to assuring safety and reliability, 500 kV substation of next century should be designed in accordance with the following principles: economization of land-use, employment of computer monitoring and control systems, unmanned or only a few on duty in substation, etc., So more and more high and new technologies and hi-tech products will be used.翻译：AC 500 千伏变电站的设计摘要：关于在中国的AC 500kV 分站的一些简要的信息，他们的设计历史数据和根本设计原则在本文被提出。

附录Ⅲ英文翻译A comprehensive overview of substationsAlong with the economic development and the modern industry developments ofquick rising, the design of the power supply system become more and more completelyand system. Because the quickly increase electricity of factories, it also increases seriously to the dependable index of the economic condition, power supply in quantity. Therefore they need the higher and more perfect request to the power supply. Whether Design reasonable, not only affect directly the base investment and circulate the expenses with have the metal depletion in colour metal, but also will reflect the dependable in power supply and the safe in many facts. In a word, it is close with the economic performance and the safety of the people. The substation is an importancepart of the electric power system, it is consisted of the electric appliances equipmentsand the Transmission and the Distribution. It obtains the electric power from theelectric power system, through its function of transformation and assign, transport and safety. Then transport the power to every place with safe, dependable, and economical.As an important part of power’s transport and control, the transformer substation must change the mode of the traditional design and control, then can adapt to the modernelectric power system, the development of modern industry and the of trend of thesociety life.Electric power industry is one of the foundations of national industry andnational economic development to industry, it is a coal, oil, natural gas, hydropower,nuclear power, wind power and other energy conversion into electrical energy of the secondary energy industry, it for the other departments of the national economy fastand stable development of the provision of adequate power, and its level of development is a reflection of the country's economic development an important indicator of the level. As the power in the industry and the importance of the national economy, electricity transmission and distribution of electric energy used in these areasis an indispensable component.。

变电所毕业设计外文翻译英文文献附录1：外文资料翻译A1.2原文TRANSFORMER1. INTRODUCTIONThe high-voltage transmission was need for the case electrical power is to be provided at considerable distance from a generating station. At some point this high voltage must be reduced, because ultimately is must supply a load. The transformer makes it possible for various parts of a power system to operate at different voltage levels. In this paper we discuss power transformer principles and applications.2. TOW-WINDING TRANSFORMERSA transformer in its simplest form consists of two stationary coils coupled by a mutual magnetic flux. The coils are said to be mutually coupled because they link a common flux.In power applications, laminated steel core transformers (to which this paper is restricted) are used. Transformers are efficient because the rotational losses normally associated with rotating machine are absent, so relatively little power is lost when transforming power from one voltage level to another. Typical efficiencies are in the range 92 to 99%, the higher values applying to the larger power transformers.The current flowing in the coil connected to the ac source is called the primary winding or simply the primary. It sets up the flux φ in the c ore, which varies periodically both in magnitude and direction. The flux links the second coil, called the secondary winding or simply secondary. The flux is changing; therefore, it induces a voltage in the secondary by electromagnetic induction in accordance with Lenz’s law. Thus the primary receives its power from the source while the secondary supplies this power to the load. This action is known as transformer action.3. TRANSFORMER PRINCIPLESWhen a sinusoidal voltage V p is applied to the primary with the secondary open-circuited, there will be no energy transfer. The impressed voltage causes a small current Iθto flow in the primary winding. This no-load current has twofunctions: (1) it produces the magnetic flux in the core, which varies sinusoidally between zero and ± φm , where φm is the maximum value of the core flux; and (2) it provides a component to account for the hysteresis and eddy current losses in the core. There combined losses are normally referred to as the core losses.The no-load current I θ is usually few percent of the rated full-load current of the transformer (about 2 to 5%). Since at no-load the primary winding acts as a large reactance due to the iron core, the no-load current will lag the primary voltage by nearly 90º. It is readily seen that the current component I m = I 0sinθ0, called the magnetizing current, is 90º in phase behind the primary voltage V P . It is this component that sets up the flux in the core; φ is therefore in phase with I m .The second component, I e =I 0sinθ0, is in phase with the primary voltage. It is the current component that supplies the core losses. The phasor sum of these two components represents the no-load current, orI 0 = I m + I eIt should be noted that the no-load current is distortes and nonsinusoidal. This is the result of the nonlinear behavior of the core material.If it is assumed that there are no other losses in the transformer, the induced voltage In the primary, E p and that in the secondary, E s can be shown. Since the magnetic flux set up by the primary winding ，there will be an induced EMF E in the secondary winding in accordance with Faraday’s law, namely, E=NΔφ/Δt. This same flux also links the primary itself, inducing in it an EMF, E p . As discussed earlier, the induced voltage must lag the flux by 90º, therefore, they are 180º out of phase with the applied voltage. Since no current flows in the secondary winding, E s =V s . The no-load primary current I 0 is small, a few percent of full-load current. Thus the voltage in the primary is small and V p is nearly equal to E p . The primary voltage and the resulting flux are sinusoidal; thus the induced quantities E p and E s vary as a sine function. The average value of the induced voltage given byE avg = turns× change in flux in a given time given timewhich is Faraday’s law applied to a finite time interval. It follows thatE avg = N 21/(2)m f ϕ = 4fNφm which N is the number of turns on the winding. Form ac circuit theory, the effective or root-mean-square (rms) voltage for a sine wave is 1.11 times the average voltage; thusE = 4.44fNφmSince the same flux links with the primary and secondary windings, the voltage per turn in each winding is the same. HenceE p = 4.44fN p φmandE s = 4.44fN s φmwhere E p and Es are the number of turn on the primary and secondary windings, respectively. The ratio of primary to secondary induced voltage is called the transformation ratio. Denoting this ratio by a, it is seen that a = p sE E = p s N N Assume that the output power of a transformer equals its input power, not a bad sumption in practice considering the high efficiencies. What we really are saying is that we are dealing with an ideal transformer; that is, it has no losses. ThusP m = P outorV p I p × primary PF = V s I s × secondary PFwhere PF is the power factor. For the above-stated assumption it means that the power factor on primary and secondary sides are equal; thereforeV p I p = V s I s from which is obtainedp s V V = p s I I ≌ p sE E ≌ a It shows that as an approximation the terminal voltage ratio equals the turns ratio. The primary and secondary current, on the other hand, are inversely related to the turns ratio. The turns ratio gives a measure of how much the secondary voltage is raised or lowered in relation to the primary voltage. To calculate the voltage regulation, we need more information.The ratio of the terminal voltage varies somewhat depending on the load and its power factor. In practice, the transformation ratio is obtained from the nameplate data, which list the primary and secondary voltage under full-load condition.When the secondary voltage V s is reduced compared to the primary voltage, the transformation is said to be a step-down transformer: conversely, if this voltageis raised, it is called a step-up transformer. In a step-down transformer the transformation ratio a is greater than unity (a>1.0), while for a step-up transformer it is smaller than unity (a<1.0). In the event that a=1, the transformer secondary voltage equals the primary voltage. This is a special type of transformer used in instances where electrical isolation is required between the primary and secondary circuit while maintaining the same voltage level. Therefore, this transformer is generally knows as an isolation transformer.As is apparent, it is the magnetic flux in the core that forms the connecting link between primary and secondary circuit. In section 4 it is shown how the primary winding current adjusts itself to the secondary load current when the transformer supplies a load.Looking into the transformer terminals from the source, an impedance is seen which by definition equals V p / I p . From p s V V = p s I I ≌ p sE E ≌ a , we have V p = aV s and I p = I s /a.In terms of V s and I s the ratio of V p to I p isp p V I = /s s aV I a= 2s s a V I But V s / I s is the load impedance Z L thus we can say thatZ m (primary) = a 2Z LThis equation tells us that when an impedance is connected to the secondary side, it appears from the source as an impedance having a magnitude that is a 2 times its actual value. We say that the load impedance is reflected or referred to the primary. It is this property of transformers that is used in impedance-matching applications.4. TRANSFORMERS UNDER LOADThe primary and secondary voltages shown have similar polarities, as indicated by the “dot-making ” convention. The dots near the upper ends of the windings have the same meaning as in circuit theory; the marked terminals have the same polarity. Thus when a load is connected to the secondary, the instantaneous load current is in the direction shown. In other words, the polarity markings signify that when positive current enters both windings at the marked terminals, the MMFs of the two windings add.Since the secondary voltage depends on the core flux φ0, it must be clear that the flux should not change appreciably if E s is to remain essentially constant under normal loading conditions. With the load connected, a current I s will flow in thesecondary circuit, because the induced EMF E s will act as a voltage source. The secondary current produces an MMF N s I s that creates a flux. This flux has such a direction that at any instant in time it opposes the main flux that created it in the first place. Of course, this is Lenz’s law in action. Thus the MMF represented by N s I s tends to reduce the core flux φ0. This means that the flux linking the primary winding reduces and consequently the primary induced voltage E p, This reduction in induced voltage causes a greater difference between the impressed voltage and the counter induced EMF, thereby allowing more current to flow in the primary. The fact that primary current I p increases means that the two conditions stated earlier are fulfilled: (1) the power input increases to match the power output, and (2) the primary MMF increases to offset the tendency of the secondary MMF to reduce the flux.In general, it will be found that the transformer reacts almost instantaneously to keep the resultant core flux essentially constant. Moreover, the core flux φ0 drops very slightly between n o load and full load (about 1 to 3%), a necessary condition if E p is to fall sufficiently to allow an increase in I p.On the primary side, I p’ is the current that flows in the primary to balance the demagnetizing effect of I s. Its MMF N p I p’ sets up a flux linking the primary only. Since the core flux φ0 remains constant. I0 must be the same current that energizes the transformer at no load. The primary current I p is therefore the sum of the current I p’ and I0.Because the no-load current is relatively small, it is correct to assume that the primary ampere-turns equal the secondary ampere-turns, since it is under this condition that the core flux is essentially constant. Thus we will assume that I0 is negligible, as it is only a small component of the full-load current.When a current flows in the secondary winding, the resulting MMF (N s I s) creates a separate flux, apart from the flux φ0produced by I0, which links the secondary winding only. This flux does no link with the primary winding and is therefore not a mutual flux.In addition, the load current that flows through the primary winding creates a flux that links with the primary winding only; it is called the primary leakage flux. The secondary- leakage flux gives rise to an induced voltage that is not counter balanced by an equivalent induced voltage in the primary. Similarly, the voltage induced in the primary is not counterbalanced in the secondary winding. Consequently, these two induced voltages behave like voltage drops, generallycalled leakage reactance voltage drops. Furthermore, each winding has some resistance, which produces a resistive voltage drop. When taken into account, these additional voltage drops would complete the equivalent circuit diagram of a practical transformer. Note that the magnetizing branch is shown in this circuit, which for our purposes will be disregarded. This follows our earlier assumption that the no-load current is assumed negligible in our calculations. This is further justified in that it is rarely necessary to predict transformer performance to such accuracies. Since the voltage drops are all directly proportional to the load current, it means that at no-load conditions there will be no voltage drops in either winding.A1.1译文变压器1. 介绍要从远端发电厂送出电能，必须应用高压输电。

本科毕业设计（论文）外文参考文献译文及原文学院自动化学院专业电气工程及其自动化（电力系统自动化方向）年级班别2011级3班学号学生姓名指导教师2015年3月10日通过对磁场的分析改进超高压变电站扩展连接器的设计Joan Hernández-Guiteras a, Jordi-Roger Riba a,⇑, LuísRomeral ba UniversitatPolitècnica de Catalunya, Electrical Engineering Department, 08222 Terrassa, Spainb UniversitatPolitècnica de Catalunya, Electronic Engineering Department, 08222 Terrassa, Spain摘要：在世界上很多的国家，电力需求的增长比输电容量的发展更快。

由于环境的限制、社会的担忧以及经济上的投入，建设新的输电线路是一项严峻的挑战。

除此以外，输电网经常要承担接近额定容量的负载。

因此，提高输电系统的效率和可靠性受到了关注。

这项研究主要针对一个400KV，3000A，50Hz的超高压变电站扩展连接器，用于连接两个母线直径均为150mm的变电站。

该变电站连接器是一个四线制的铝导线，为母线之间的相互电能传输提供了路径。

前期的初步试验显示：电流在输电线路中的不平衡分布，主要是受到了距离的影响。

应用一个三维的有限元素法，可以改进设计，以及对改进前后两个版本的连接器的电磁性能和热性能进行评估比较。

这份报告中将提出：在实验室条件下的检验已经验证了仿真方法的准确性。

这也许将会是促进变电站连接器设计进程的一个很有价值的工具。

因此，将不仅仅提高其热性能，还将提高其可靠性。

关键词：变电站连接器、超高压、电力传输系统、有限单元法、数值模拟、临近效应、热学分析1.引入全球能源需求的频繁增长，连同分散的和可再生能源份额的增长促进超高压和特高压电力传输系统[1]的建设和研究。

山东理工大学毕业设计（外文翻译材料）学院：专业：学生姓名：指导教师：电气与电子工程学院电气工程及其自动化韦柳军孟繁玉Reliability modelling and analysis for SheffieldSubstation 220 kV upgrade projectCaroline Lee Transend, Networks Pty Ltd , TasmaniaDr Sudhir Agarwal,San Diego, California, USAABSTRACTThis paper describes the application of a defensible probabilistic process in reliability evaluation for Sheffield 220 kV Substation redevelopment project. Sheffield Substation is a hub of 220 kV transmission system in the North and North-West regions of Tasmania. It provides connection to West Coast and Mersey Forth hydro power stations and facilitates power transfers from these power stations to major industrial customers in George Town area and retail andindustrial loads in the North and North-West regions of Tasmania. Therefore, it is important that integrity of Sheffield Substation is protected as much as possible and consequences of unplanned outages minimised to prevent possible widespread system disturbances.Together with General Reliability from San Diego,California, Transend undertook the reliability evaluation of four redevelopment options for Sheffield Substation using SUBREL, substation reliability and TRANSREL, transmission system reliability programs.1.INTRODUCTIONTransend, as a Transmission Service Provider and Transmission Network Operator in Tasmania is responsible for providing reliable electricity supply and providing cost effective development solutions- 1 -of the transmission network. Transend has identified a need for a comprehensive and more objective process in justification of development projects from its capital works program. The need to combine customer reliability targets and economics to achieve cost effective development solutions has been long recognised. A hierarchical framework for overall power system reliability evaluation is presented in [1].Different design, planning and operating principles and techniques have been developed in different countries over many decades in an attempt to find balance between reliability targets and economic constraints [2].Following the reliability concept and principles, differentutilities applied different reliability criteria to justify projects from their capital works program. Reliability criteria can be viewed as conditions that should be satisfied by electricity generation, transmission and distribution systems in order to achieve requiredreliability targets. Reliability criteria usually fall into two categories: established numerical target levels of reliability (eg level of expected energy not supplied) and performance test criteria (eg N-1, N-2 incidents that the system has to withstand). An attempt to combine these two categories into one set of reliability criteria is currently underway in Tasmania [3]. The use of reliability criteria from the first category is the core of probabilistic reliability evaluation approach. The second category is a deterministic reliability evaluation approach. The usefulness of deterministic criteria and security standards in justification of projects from capital works program is challenged in [4]. Instead, an approach involving customers in decision making and simulating a realistic system operation and failure is commended. The basic steps suggested in proper reliability evaluations are based on complete understanding of the equipment and system behaviour including:• Understanding the way the equipment and system operate;- 2 -• Identify the situations in which equipment can fail;• Understand consequences of the failures;• Incorporate these events into the reliability model;•Use the available evaluation techniques tocalculate reliability indices and costs.With this understanding of the system behaviour probability theory is then only seen as a tool to transform this understanding into the likely system future behaviour.2. SELECTION OF EVALUATION TECHNIQUE AND SOFTWARE TOOLS There are two main categories of evaluation techniques[5]: analytical (stateenumeration) and Monte Carlo simulation. The advantages and disadvantages of both methods are discussed in [1].Analytical technique was chosen by Transend because of its usefulness in comparing different development options for network development projects. This approach was presented also in the Electricity Supply Association of Australia Guidelines for Reliability Assessment Planning [6]. Consequently, decision was made to acquire SUBREL, and TRANSREL, substation reliability and transmission system reliability programs from General Reliability,USA.2.1. SUBREL - SUBSTATION RELIABILITYPROGRAMSUBREL is a computer program which calculates reliability indices for an electricity utility substation and generating station switchyard [7]. The methodology used to analyse impact of substation generated outages on overall system reliability performances has been described in [8]. The program models the following outage events, including all required subsequent automatic and manual switching operations:1. Forced outage of any substation component:- 3 -• Breaker• Transformer• Bus Section• Disconnector2. Forced outage of an incoming line.3. Forced outage overlapping a maintenance outage for substation equipment or an incoming line.4. Stuck breaker (failure to open when needed to clear the fault). SUBREL calculates the following load point indices:• Frequency of Interruption (per year)• Number of Circuits Interruptions (per year)• Outage Duration (minutes per outage)• Annual Total Outage Duration (minutes per year)• Customer Minutes of Interruption CMI (per year)• Expected Unsupplied Energy (EUE) (kWh per year)• Expected Outage Cost ($ per year)SUBREL also calculates the following substation or totalsystem indices:• SAIFI, System Average Interruption Frequency Index• SAIDI, System Average Interruption Duration Index• CAIDI, Customer Average Interruption Duration Index• ASAI, Average Service Availability Index• EUE, Expected Unsupplied Energy (kWh per year)- 4 -• Expected Outage Cost ($ per year)SUBREL generates a list of substation generated outages that can be used further by TRANSREL to analyse impact on overall system reliability performance.2.2. TRANSREL – TRANSMISSION SYSTEM RELIABILITY PROGRAMTRANSREL uses contingency enumeration of transmission contingencies to evaluate power network reliability. It is designed to aid electric utility system planners for reliability assessment of bulk power systems. The process involves specifying contingencies (outages of transmission lines and station originated outages) and performing load flow analysis to determine system problems such as circuit overloads, low/high bus voltages, bus separation or islanding. Using the probability, frequency and duration of the contingencies evaluated, indices of system problems as measures of system unreliability are calculated. Both post contingency and post remedial action indices can be calculated. If no remedial actions are taken to alleviate a problem, the post contingency indices may provide a pessimistic assessment of system reliability. If remedial actions such as generation redispatch, switching of facilities, curtailment of load alleviates some of the system problems, the post remedial action reliability indices provide a more realistic measure of system performance. The amount of load shedding is used as an indicator of contingency severity or system capability to withstand contingencies. Using probabilities of contingencies, expected load curtailment at buses can be calculated as reliability indices. TRANSREL was used with load flow program, PTI PSS/E to examine the impact of an outage on system performance. The types of failures identified for checking the impact of a contingency on system performance are: Transmission circuit overloads - by comparing flows based on the load flow solution with user- 5 -selected circuit ratings; Bus voltage violations - by checking bus voltages against high and low voltage limits, or maximum allowable voltage deviation from the base case; Load curtailment - by tabulating the amount of load curtailed as a result of system failure;Load flow divergence - by tabulating the bus mismatches above a predefined tolerance. TRANSREL computes reliability indices using a contingency enumeration approach, which involves selection and evaluation of contingencies, classification of each contingency according to specified failure criteria, and computation of reliability indices. Reliability indices include frequency, duration and severity (overloads, voltage violations, load curtailed, and energy curtailed). Both system and bus indices are calculated.3.SUBREL AND TRANSREL APPLICATION FOR SHEFFIELD 220 KV SUBSTATION Sheffield Substation is a hub of 220 kV transmission system in the North and North-West regions of Tasmania. As shown on Figure 1, it provides connections from the West Coast and Mersey Forth hydro power stations to the rest of the system. In addition, it supplies Aurora Energy customers in North and North-West regions and major industrial customers in the George Town area.During winter months, from May to September, the amount of energy supplied through and transferred from Sheffield Substation can reach more than 50% of the energy supplied to the rest of the system as shown in Figure 2.As such, Sheffield Substation has been recognized as a vulnerable point in the Tasmanian power system. The total loss of Sheffield Substation during times of large power transfer from West Coast of Tasmania to the rest of the system could possibly lead to a large system disturbance in Tasmania. With the present Sheffield Substation 220 kV layout, the total loss of Sheffield Substation can be caused by a single element failure.- 6 -3.1. DEVELOPMENT OPTIONS ANALYSEDThe need to redesign the existing substation 220 kV layout has been recognised long time ago. The following three options have been selected for detailed modeling and analysis:Option 1: Triple busbar arrangementOption 2: Full breaker and a half and double breaker arrangement Option 3: Partial breaker and half and double breaker arrangement These options were compared against the existing 220 kV busbar design (Do Nothing option).A brief description of each of these options is as follows:3.1.1. DO NOTHING OPTION- 7 -The “Do nothing option” represents the existing 220 kV busbar arrangement at Sheffield Substation. The existing 220 kV Sheffield Substation has had some major changes since substation commissioning and installation of two autotransformers for the North and North-West regions of Tasmania supply in 1967. The substation 220 kV busbar arrangement is double, strung busbar arrangement with one bus coupler. In normal system configuration main bus coupler A752 is closed, 220 kV“S” by pass bus and second bus coupler S752 are not in service. The schematic diagram of this option is shown below. Total number of circuits connected at Sheffield Substation is 12. Total number of circuit breakers is 14 (12 plus 2 bus couplers). Sheffield Substation is a main supply point to the North-West Region of Tasmania. Total load in the region is around 260 MVA. The fault on bus coupler A752 will result in the loss of both busbar A and B and therefore loss of more than 50% of supply in Tasmania during winter season leading to a blackout in the North-West region.West Coast region will loose synchronism with the rest of the system, experience over frequency and will be islanded. The rest of the system will experience.Under frequency and significant amount of load must be shed to prevent total blackout. In the case of 220 kV busbar A fault at Sheffield Substation, two elements supplying the North-West region which are the Sheffield–Burnie 220 kV line and autotransformer T1, would be lost. During high winter load the remaining autotransformer T2 will be overloaded and tripped on overload conditions. This will lead to total blackout in the North-West region of Tasmania. In the case of 220 kV busbar B fault, two elements supplying George Town which are the Sheffield–George Town No 1 transmission line and Sheffield–Palmerston transmission line will be lost. During high winter loads the remaining Sheffield–George Town No 2 line will tripped on overload.- 8 -This will cause significant change in network impedance with requirement to shed load at major industrial customers at George Town. Consequently, this will produce excessive generation connected at Farrell and Sheffield, which can move the system towards unstable operation and cascade of events with possible blackout in the North and North West regions of Tasmania.3.1.2. OPTION 1-TRIPLE BUSBAR ARRANGEMENTThe schematic diagram of this option is shown below In comparison with “do nothing option” this option proposes to use the spare S752 circuit breaker and upgrade a nd energise “S” bypass bus to full size. The existing 12 circuits will be spread across the three busbars. Only one additional 220 kV circuit breaker is required in this option. The total number of circuit breakers in this option is 15.3.1.3. OPTION 2 - FULL BREAKER AND A HALF AND DOUBLE BREAKER ARRANGEMENT The schematic diagram of this option is shown below. This option includes- 9 -creating double breaker and breaker and half arrangements. Breaker and a half arrangement is proposed between Hydro Tasmania’s C ethana power station and autotransformer T1; and Lemonthyme power station and autotransformer T2. The total number of circuit breakers in this option is 19.3.1.4. OPTION 3 - PARTIAL BREAKER AND A HALF AND DOUBLE BREAKER ARRANGEMENTThe schematic diagram of this option is shown below. The main difference in comparison with option 2 is thatthere is no breaker and half arrangements between Hydro Tasmania’s Cethana power station and autotransformer T1; and Lemonthyme power station and autotransformer T2. The establishment of breaker and a half arrangements between these circuits could have as a consequence increase in connection charges for Hydro Tasmania for middle breakers, which needs to be discussed and agreed with this customer. Total number of circuit breakers in this option is 17.3.2. RESULTSIn this study, the following outages are examined:• n-1 forced outage of a station component including transmission lines and transformers• n-1 maintenance overlapping n-1 forced outages•breaker stuck condition following a fault. For a fault on line, transformer, bus or a breaker, only those breakers will be considered for being in a stuck condition that are supposed to trip to clear the fault. In this case back up protection will clear the fault.Apart from the above outages examined, higher order of outages can also be considered and simulated in the programs, however the probability and frequency of- 10 -their occurrence is quite low. Based on the Transend outage data, it was decided that the above settings should capture most of the credible outage events. The number of events for each of the options is given in the following table. These events are generated by the program to study their impact on substation performance. For each event, the program calculates the probability, frequency and duration. Using the connectivity model, it also computes the amount of loss of load and energy for a load point and for the overall substation. Using a linear flow method it checks if the load can be supplied without violating the ratings of any component. The number of outage events enumerated and examined by the SUBREL program depends on the number of components in a station and the program settings. If more components are added to a station, their exposure to failures also increases. To select an optimal design, a balance between the redundancy provided by adding a component (breaker or a busbar) and the increased exposure should be kept in mind. As seen from the tables above, the number of outage events for options 1,2 and 3 is higher than for the existing configuration since these options have more breakers and buses in their suggested configurations. There is no event that causes the complete loss of load in the area (including Burnie, Sheffield and George Town substations in the model) in any of the options. However there are events in each option that will cause partial loss of load. Option 2 has the lowest number of events causing loss of load while the existing configuration has the highest number of events causing loss of load. Reliability indices computed by SUBREL program for each of the option is given in the table below. These indices are computed using the load Probability Density Function (PDF) as unity. PDF of unity means that the load is same throughout the year. The widely used reliability indices such as SAIFI, SAIDI, CAIDI, ASAI,and EUE are computed by the program.Outage costs are calculated based on calculated expected- 11 -unsupplied energy (EUE) and value of lost load applied to particular customer groups. A comprehensive analysis of value of lost load for different customer groups has been undertaken by Monash University for Victorian utilities [9]. Based on the table above it is clear that option 1 – triple busbar arrangement, has lowest outage costs. Based on the list of substation originated outages generated by SUBREL, TRANSREL program was used to indicated consequences on the overall system performances. The voltage violations were encountered only for option2 in 9 simulation events. There were few contingencies for which solution did not converge. For these contingencies, a potential exists that the system will face major problems including a collapse. The system stress and its response will, of course, depend on the system conditions present at the time outages. There are four events for Option 1 that result in non-convergence of the power flow. The probability of these non-convergence cases for Option 1 is 0.0026 which means that there is a potential that exists that the system may collapse once every 400 years. This is a very low likely event and during this time the system is likely to go through several changes. It should also be noted that in this analysis no remedial actions are included. With remedial actions, operators may be able to avoid such a situation.4. CONCLUSIONSThe implementation and application of a probabilistic based planning for selecting a substation configuration provides quite useful information to an engineer in deciding the best option. The use of both SUBREL and TRANSREL programs for Sheffield Substation study has sufficiently demonstrated that it is important to examine all credible outage scenarios that are not possible to do manually. Quantitative indices computed by these programs provide an objective assessment of various- 12 -options considered. For transmission substations it is important that only SUBREL analysis may not provide the complete information. Without performing a TRANSREL analysis,it is likely that the risk posed by a configuration may not be correctly assessed from the overall system point of view. For the Sheffield Substation the triple busbar arrangement (Option 1) is the cheapest option, easy to implement, and reliability indices for Sheffield Substation are the best in this option. The low probabilities divergent cases can be resolved with appropriate remedial actions in place, including, generation rescheduling, voltage support and load shedding.REFERENCES[1] Billinton, R. and Allan, R.N.,:”Power-system reliability in perspective”, IEE Electronic and Power, pp. 231-236, March 1984.[2] “Power System Reliability Analysis. Application Guide,” CIGRE WG03 of SC 38,Edited by Lesley Kelley-Regnier, 1987.[3] “Transmission Network Security and Planning Criteria-draft”, Office of Tasmanian Energy Regulator, August 2005.[4] Al lan, R.N., and Billinton, R.:”Probabilistic methods applied to electric power systems-are they worth it?”,Power Engineering Journal, pp.121-129, May 1992.[5] Billinton, R. and Allan, R.N.,:” Reliability Evaluation of Power Systems”, Pitmans Books, New Yor k and London, 2nd edition, 1996. [6] “ESAA Guidelines for Reliability Assessment Planning,”, November 1997.[7] “Subrel-Substation Reliability Program User Manual”, General Reliability, San Diego, CA, 2002.- 13 -[8] Agarwal, S.K., and Anderson, P.M..: “Effect o f Station Originated Outages on Bulk Power System Reliability, ”, Cigre Symposium, S 38- 91, Montreal, 1991.[9] Monash University,:” Study of the Value of Lost Load” , Study conducted for the Victorian Power Exchange (VPX) company,Melbourne,2000.- 14 -谢菲尔德变电站220千伏升级项目的可靠性建模与分析创见网络私人有限公司，塔斯马尼亚阿加瓦尔博士，美国加利福尼亚州圣迭戈摘要本文介绍了在可靠性评估中的应用一个可防御概率过程谢菲尔德220千伏变电站重建项目。

General Requirements to Construction of SubstationSubstations are a vital element in a power supply system of industrial enterprises．They serve to receive ，convert and distribute electric energy .Depending on power and purpose ,the substations are divided into central distribution substations for a voltage of 110-500kV;main step-down substations for110-220/6-10-35kV;deep entrance substations for 110-330/6-10Kv;distribution substations for 6-10Kv;shop transformer substations for 6-10/0.38-0.66kV.At the main step-down substations, the energy received from the power source is transformed from 110-220kV usually to 6-10kV(sometimes 35kV) which is distributed among substations of the enterprise and is fed to high-voltage services.Central distribution substations receive energy from power systems and distribute it (without or with partial transformation) via aerial and cable lines of deep entrances at a voltage of 110-220kV over the enterprise territory .Central distribution substation differs from the main distribution substation in a higher power and in that bulk of its power is at a voltage of 110-220kV;it features simplified switching circuits at primary voltage; it is fed from the power to an individual object or region .Low-and medium-power shop substations transform energy from 6-10kV to a secondary voltage of 380/220 or 660/380.Step-up transformer substations are used at power plants for transformation of energy produced by the generators to a higher voltage which decreases losses at a long-distance transmission .Converter substations are intended to convert AC to DC (sometimes vice versa) and to convert energy of one frequency to another .Converter substations with semiconductor rectifiers are convert energy of one frequency to another .Converter substations with semiconductor rectifiers are most economic. Distribution substations for 6-10kV are fed primarily from main distribution substations (sometimes from central distribution substations).With a system of dividing substations for 110-220kV, the functions of a switch-gear are accomplishedby switch-gears for 6-10kV at deep entrance substations.Depending on location of substations their switch-gear may be outdoor or indoor. The feed and output lines at 6-10kV substations are mainly of the cable type .at 35-220kV substations of the aerial type .When erecting and wiring the substations ,major attention is given to reliable and economic power supply of a given production.Substations are erected by industrial methods with the use of large blocks and assemblies prepared at the site shops of electric engineering organizations and factories of electrical engineering industry .Substations are usually designed for operation without continuous attendance of the duty personnel but with the use of elementary automatic and signaling devices.When constructing the structural part of a substation .it is advisable to use light-weight industrial structures and elements (panels ,floors ,etc.) made of bent sections .These elements are pre-made outside the erection zone and are only assembled at site .This considerably cuts the terms and cost of construction.Basic circuitry concepts of substations are chosen when designing a powersupply system of the enterprise .Substations feature primary voltage entrances .transformers and output cable lines or current conductors of secondary voltage .Substations are mounted from equipment and elements described below .The number of possible combinations of equipment and elements is very great .Whenelaborating a substation circuitry ,it is necessary to strive for maximum simplification and minimizing the number of switching devices .Such substations are more reliable and economic .Circuitry is simplified by using automatic reclosure or automatic change over to reserve facility which allows rapid and faultless redundancy of individual elements and using equipment.When designing transformer substations of industrial enterprises for all voltages , the following basic considerations are taken into account:1. Preferable employment of a single-bus system with using two-bus systems only to ensure a reliable and economic power supply;2. Wide use of unitized constructions and busless substations;3.Substantiated employment of automatics and telemetry ;if the substation design does not envisage the use of automatics or telemetry ,the circuitry is so arranged as to allow for adding such equipment in future without excessive investments and re-work.e of simple and cheap devices-isolating switches ,short-circuiting switches ,load-breaking isolators ,fuses ,with due regard for their switching capacity may drastically cut the need for expensive and critical oil ,vacuum ,solenoid and air switches .Substation and switch-gear circuitries are so made that using the equipment of each production line is fed from individual transformers ,assemblies ,the lines to allow their disconnection simultaneously with mechanisms without disrupting operation of adjacent production flows.When elaborating circuitry of a substation, the most vital task is to properly choose and arrange switching devices(switches ,isolators ,current limiters ,arresters ,high-voltage fuses).The decision depends on the purpose ,power and significance of the substation.Many years ago, scientists had very vague ideas about electricity. Many of them thought of it as a sort of fluid that flowed through wires as water flows through pipes, but they could not understand what made it flow. Many of them felt that electricity was made up of tiny particles of some kind ,but trying to separate electricity into individual particles baffled them.Then, the great American scientist Millikan, in 1909,astounded the scientific world by actually weighing a single particle of electricity and calculating its electric charge. This was probably one of the most delicate weighing jobs ever done by man,for a single electric particle weighs only about half of a millionth of a pound. To make up a pound it would take more of those particles than there are drops of water in the Atlantic Ocean.They are no strangers to us, these electric particles, for we know them as electrons. When large numbers of electrons break away from their atoms and move through a wire,we describe this action by saying that electricity is flowing through the wire.Yes,the electrical fluid that early scientists talked about is nothing more than electrical flowing along a wire.But how can individual electrons be made to break away from atoms? And how can these free electrons be made to along a wire? The answer to the first question lies in the structure of the atoms themselves. Some atoms are so constructed that they lose electrons easily. An atom of copper, for example ,is continually losing an electron, regaining it(or another electron),and losing it again. A copper atom normally has 29 electrons, arranged in four different orbits about its nucleus. The inside orbit has 2 electrons. The next larger orbit has 8.The third orbit is packed with 18 electrons . And the outside orbit has only one electron.It is this outside electron that the copper atom is continually losing, for it is not very closely tied to the atom. It wanders off, is replaced by another free-roving electron, and then this second electron also wanders away.Consequently,in a copper wire free electrons are floating around in all directions among the copper atoms.Thus, even through the copper wire looks quite motionless to your ordinary eye, there is a great deal of activity going on inside it. If the wire were carrying electricity to an electric light or to some other electrical device, the electrons would not be moving around at random. Instead, many of them would be rushing in the same direction-from one end of the wire to the other.This brings us to the second question .How can free electrons be made to move along a wire? Well ,men have found several ways to do that .One way is chemical. V olta,s voltaic pile,or battery, is a chemical device that makes electricity(or electrons)flow in wires. Another way is magnetic. Faraday and Henry discovered how magnets could be used to make electricity flow in a wire.MagnetsAlmost everyone has seen horseshoe magnets-so called because they are shaped like horseshoes. Probably you have experimented with a magnet, and noticed how it will pick up tacks and nails, or other small iron objects. Men have known about magnets for thousands of years.Several thousand years ago, according to legend, a shepherd named Magnes lived on the island of Crete, in the Mediterranean Sea .He had a shepherds crook tipped with iron. One day he found an oddly shaped black stone that stuck to this ironter, when many other such stones were found, they were called magnets(after Magnets).These were natural magnets.In recent times men have learned how to make magnets out of iron. More important still, they have discovered how to use magnets to push electrons through wires-that is, how to make electricity flow. Before we discuss this, there arecertain characteristics of magnets that we should know about.If a piece of glass is laid on top of a horse- shoes magnet, and if iron filings are then sprink ledon the glass, the filings will arrange themselves into lines. If this same thing is trid with a bar magnet(a horseshoe magnet straightened out),the lines can be seen more easily. These experiments demonstrate what scientists call magnetic lines of force. Magnets, they explain, work through lines of force that ext- end between the two ends of the magnet. But electrons seem to have magnetic lines of force around them, too.This can be proved by sticking a wire through a piece ofcard board, sprinkling iron filings on the cardboard, and connecting a battery to the wire. The filings will tend to form rings around the wire,as a result of the magnetism of the moving electrons(or electricity).So we can see that there is arelationship between moving electrons and magnetism, Magnetism results from the movement of electrons.Of course, electrons are not really flowing in the bar magnet, but they are in motion, circling the nuclei of the iron atoms. However, in the magnet, circling thelined up in such a way that their electrons are circling in the same direction. Perhaps a good comparison might be a great number of boys whirling balls onstrings in a clockwise direction around their heads.。

变电站外文翻译外文文献英文文献变电站的综合概述Introduction:2. Circuit Breakers: Circuit breakers are protective devices used to interrupt or break an electrical circuit during abnormal conditions. They prevent excessive damage to equipment and maintain system stability by isolating faulty parts from therest of the system.3. Switchgear: Switchgear refers to a collection ofelectrical disconnect switches, fuses, or circuit breakers used to control and protect electrical equipment within the substation. It allows operators to isolate faulty sections of the electrical network for maintenance or repair without affecting the rest of the system.5. Lightning Arresters: Lightning arresters are protective devices installed on substation equipment to safeguard against high voltage surges caused by lightning strikes. They divert the excess electrical energy away from the equipment and prevent damage to the substation.Types of Substations:2. Transmission Substations: Transmission substations receive electricity from power generating stations and transform the voltage to a suitable level for long-distance transmissionover high voltage transmission lines. They are often located at the interconnection points between different transmission lines.3. Switching Substations: Switching substations provide switching, control, and protection functions in the electrical power system. They allow for the rerouting of power flows and enable system operators to isolate faulty equipment or sectionsof the system while still maintaining power supply to consumers.4. Converter Substations: Converter substations are specific to systems using high voltage direct current (HVDC) transmission technology. They convert alternating current (AC) from the power grid to direct current (DC) for transmission over long distances, and then convert it back to AC at the receiving end.Conclusion:。

变电站中英文资料对照外文翻译文献综述XXXns are an essential part of electrical power systems。

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n ns。

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英文翻译A comprehensive overview of substationsAlong with the economic development and the modern industry developments of quick rising, the design of the power supply system become more and more completely and system. Because the quickly increase electricity of factories, it also increases seriously to the dependable index of the economic condition, power supply in quantity. Therefore they need the higher and more perfect request to the power supply. Whether Design reasonable, not only affect directly the base investment and circulate the expenses with have the metal depletion in colour metal, but also will reflect the dependable in power supply and the safe in many facts. In a word, it is close with the economic performance and the safety of the people. The substation is an importance part of the electric power system, it is consisted of the electric appliances equipments and the Transmission and the Distribution. It obtains the electric power from the electric power system, through its function of transformation and assign, transport and safety. Then transport the power to every place with safe, dependable, and economical. As an important part of power’s transport and control, the transformer substation must change the mode of the traditional design and control, then can adapt to the modern electric power system, the development of modern industry and the of trend of the society life.Electric power industry is one of the foundations of national industry and national economic development to industry, it is a coal, oil, natural gas, hydropower, nuclear power, wind power and other energy conversion into electrical energy of the secondary energy industry, it for the other departments of the national economy fast and stable development of the provision of adequate power, and its level of development is a reflection of the country's economic development an important indicator of the level. As the power in the industry and the importance of the national economy, electricity transmission and distribution of electric energy used in these areas is an indispensable component.。