电量外文翻译

Power Supply and Distribution SystemThe basic function of the electric power system is to transport the electric power towards customers. The revolution of electric power system has brought a new big round construction, which is pushing the greater revolution of electric power technique along with the application of new technique and advanced equipment. Especially, the combination of the information technique and electric power technique, to great ex- tent, has improved reliability on electric quality and electric supply. The technical development decreases the cost on electric construction and drives innovation of electric network. On the basis of national and internatio- nal advanced electric knowledge, the dissertation introduces the research hotspot for present electric power sy- etem as following.Firstly, this dissertation introduces the building condition of distribution automation(DA, and brings forward two typical construction modes on DA construction, integrative mode and fission mode .It emphasize the DA structure under the condition of the fission mode and presents the system configuration, the main station scheme, the feeder scheme, the optimized communication scheme etc., which is for DA research reference.Secondly, as for the (DA trouble measurement, position, isolation and resume, This dissertation analyzes the changes of pressure and current for line problem, gets math equation by educing phase short circuit and problem position under the condition of single-phase and works out equation and several parameter s U& , s I& and e I& table on problem . It brings out optimized isolation and resume plan, realizes auto isolation and network reconstruction, reduces the power off range and time and improves the reliability of electric power supply through problem self- diagnoses and self-analysis. It also introduces software flow and use for problem judgement and sets a model on network reconstruction and computer flow.Thirdly, electricity system state is estimated to be one of the key techniques in DA realization. The dissertation recommends the resolvent of bad measurement data and structure mistake on the ground of describing state estimate way. It also advances a practical test and judging way on topology mistake in state estimate about bad data test and abnormity in state estimate as well as the problem and effect on bad data from state measure to state estimate .As for real time monitor and control problem, the dissertation introduces a new way to solve them by electricity break and exceptional analysis, and the way has been tested in Weifang DA.Fourthly, about the difficulty for building the model of load forecasting, big parameter scatter limit and something concerned, the dissertation introduces some parameters, eg. weather factor, date type and social environment effect based on analysis of routine load forecasting and means. It presents the way for electricity load forecasting founded on neural network(ANN,which has been tested it's validity by example and made to be good practical effect.Power systemcontrol is very important issue to maintain the normal operation of a system.system voltage levels,frequency,tie-line flows,line currents,and equipment loading must be kept within limits determined to be safe in order to provide satisfactory service to the power system customers.Voltage levels, line currents, and equipment loading may vary from location within a system, and control is on a relatively local basis. For example, generator voltage is determined by the field current of each particular generating unit; however, if the generator voltages are not coordinated,excess var flows result. Similarly, loading on individual generating units is determined by the throttle control on thermal units or the gate controls on hydro-units. each machine will respond individually to the energy input to its prime mover. Transmission line loadings are affected by power input from generating units and theirloadings,the connected loads, parallel paths for power to flow on other lines, and their relative impedances.For satisfactory operation of a power system, the frequency should remain nearly constant. Relatiyely close control of frequency ensures constancy of speed of induction and synchronous motors.Constancy of speed of motor drives is particularly important for satisfactory performance of all the auxiliary drives associated with the fuel, the feed-water and -the combustion air supply system. In a network, considerable drop in frequency could result in high magnetizing currents in induction motors and transformers. The extensive use of electric clocks and the use of frequency for other timing purpose require accurate maintenance of synchronous time which is proportional to integral. A change in active power demand at one point is reflected throughout the system by a change in frequency. Because there are many generators supplying power into system, some means must be provided to allocate change in demand to the generators. A speed governor on each generating unit provides the primmy speed control function, while supplementary control origination at a central control center allocates generation.In an interconnected system with two or more independently controlled areas, in addition to control of frequency, the generation within each area has to be controlled so as to maintain scheduled power interchange. The control of generation and frequency is commonly referred to as load-frequency control (LFC.The control measures of power and frequency include:(1 Regulation of the generator speed governor(2 Underfrequency load shedding(3 Automatic generation control (AGCAGC is an effective means for power frequency control in large-scale power systems. In an Interconnected power system, the primary objectives of AGC are toregulate frequency to the specified nominal value and to maintain the interchange power between control area at the scheduled values by adjust the output of the selected generators. This function is commonly referred to as load-frequency control. A secondary objective is to distribute the required change in generation omong units to minimize operating costs.For efficient and reliable operation of power system, the control of voltage and reactive power should satisfy the following objectives:(1 Voltages at the terminals of all equipment in the system are within acceptable limits. Both utility equipment and customer equipment are designed to operate at a certain voltage rating. Prolonged operation of the equipment at voltages outside the allowable rang could adversely affect their performance and possibly cause them damage.(2 System stability is enhanced to maximize utilization of the transmission system.(3 The reactive power flow is minimzed as to reduce the equipment and the transmission lines losses to a practical minimum. This ensures that the transmission system operates efficiently,i.e. mainly for active power transfer.The problem of maintaining, voltages within the required limits is complicated by the fact that the Power system supplies power to a vast number of loads and is fed from many generating units. As 1oads vary, the reactive power requirements of the transmission system vary. Sincereactive power cannott be transmitted over long distance, voltage control has to be effected by using special devices dispersed throughout the system. This is in contrast to the control of frequency which depends on overall system active power balance. The proper selection and coordination of equipment for controlling reactive power and voltage are among the major challenges of power system engineering.The control of voltage levels is accomplished by controlling the production, absorption, and flow of reactive power at all levels in the system. The generating units provide the basic neans of voltage control; the automatic voltage regulators control field excitation to maintain a scheduled voltage level at the terminals of the generators. Additional means are usually required to control voltage throughout the ststem. The devices used for this purpose may be classified as follows:(1 Sources of reactive power, such as series capars, shunt reactors, synchro-nous condensers, and static var compensators (SVCs.(2 Line reactance compensators, such as series capacitors.(3 Regulating transformers, such as tap-changing tarsformers and boosters.Synchronous condensers and SVCs provide active compensation;the reactive power absorbed/supplied by them is automatically adjust so as to maintain voltages of the buses to which they are connected.供配电系统电力系统的基本功能是向用户输送电能。

可编辑修改精选全文完整版电力系统电力系统介绍随着电力工业的增加，与用于生成和处置现今大规模电能消费的电力生产、传输、分派系统相关的经济、工程问题也随之增多。

这些系统组成了一个完整的电力系统。

应该着重提到的是生成电能的工业，它不同凡响的地方在于其产品应按顾客要求即需即用。

生成电的能源以煤、石油，或水库和湖泊中水的形式贮存起来，以备以后所有需。

但这并非会降低用户对发电机容量的需求。

显然，对电力系统而言服务的持续性相当重要。

没有哪一种服务能完全幸免可能显现的失误，而系统的本钱明显依托于其稳固性。

因此，必需在稳固性与本钱之间找到平稳点，而最终的选择应是负载大小、特点、可能显现中断的缘故、用户要求等的综合表现。

但是，网络靠得住性的增加是通过应用必然数量的生成单元和在发电站港湾各分区间和在国内、国际电网传输线路中利用自动断路器得以实现的。

事实上大型系统包括众多的发电站和由高容量传输线路连接的负载。

如此，在不中断整体服务的前提下能够停止单个发电单元或一套输电线路的运作。

现此生成和传输电力最普遍的系统是三相系统。

相关于其他交流系统而言，它具有简便、节能的优势。

尤其是在特定导体间电压、传输功率、传输距离和线耗的情形下，三相系统所需铜或铝仅为单相系统的75%。

三相系统另一个重要优势是三相电机比单相电机效率更高。

大规模电力生产的能源有：1.从常规燃料（煤、石油或天然气）、城市废料燃烧或核燃料应用中取得的蒸汽；2.水；3.石油中的柴油动力。

其他可能的能源有太阳能、风能、潮汐能等，但没有一种超越了试点发电站时期。

在大型蒸汽发电站中，蒸汽中的热能通过涡轮轮转换为功。

涡轮必需包括安装在轴承上并封锁于汽缸中的轴或转子。

转子由汽缸周围喷嘴喷射出的蒸汽流带动而平稳地转动。

蒸汽流撞击轴上的叶片。

中央电站采纳冷凝涡轮，即蒸汽在离开涡轮后会通过一冷凝器。

冷凝器通过其导管中大量冷水的循环来达到冷凝的成效，从而提高蒸汽的膨胀率、后继效率及涡轮的输出功率。

中英文对照外文翻译(文档含英文原文和中文翻译)always adopts mechanical tinplate to measure. There are some shortcomings that the measurement precision falls with machine abrasion, single time period setting and strong manpower [2]. In this paper, we propose a novel multi-rate three-phase watt-hour meter based on AT89LV52. This multi-rate three-phase watt-hour meter adoptsAD7752 for measurement. It has the characteristics which are time-sharing measurement, accurate measurement, LCD display, automatic meter reading, flexible time period setting, timely emendation, low cost and novel design. II. STRUCTURE AND WORKING PRINCIPLEThe novel multi-rate three-phase watt-hour meter proposed in this paper is based upon AT89LV52 singlechip [3]. AT89LV52 has the flash memorizer with 8k bytes, cryptographical program memorizer with third class, RAM with 256 bytes, 32 programmable I/O lines, three time/ counter with 16 bits and a two class halt with six vectors. The interface circuit adopts I2C bus unit which is a 8 bits singlechipwith good performance and suitable price. The system structure diagram is shown in figure 1.Figure 1. System structure diagramThe principle of this multi-rate watt-hour meter is reading in themulti-rate time segments using RS485 bus and noting in X25045 then take over correctional clock with RS485 bus and write in clock CMOS chip S3530A. Thethree-phase AC voltage and electric current pass through potentiometer and mutual inductance instrument respectively so as to produce small signal which is sent toAD7752 to complete measurement. The clock CMOS chip S3530A gives clockinformation per second in the course of automatic move and analyze this clock belongs to which period of time according to advance periods of time set in X25045 then save the electrical energy in RAM memorizeraccording to corresponding period of time. We write it to corresponding address ofX25045 when the electrical energy achieves one degree in order to make the multi-rate measurement come true. This watt-hour meter hasfunctions of clear LCD display, missing phase detection, burthen control, halt electricity check and storage, automatic meter reading and so on.III. THE DESIGH OF HARDWARE CIRCUITA． Electrical energy measurementThe three-phase electrical energy measurement is realized by the low consume CMOS chip AD7752 of ADI company. The inside of AD7752 adopts digital circuit besides ADC, filter and multiplication circuit which can eliminate noises effectively. The sampling course of voltage and electric current in three-phase AC power supply loop is shown in figure 2 in which IA stands for voltage sampling of A phase. The sampling circuits of B phase and C phase are similar to A phase. The power after integral is transformed to electrical pulse for output. The pulse of fan-out CF enters into interregnum INT0 of AT89LV52 through photoelectricity insulation 4N25. CPU measures the electrical energy [4]. We adjust the pulse number of CF by combining the state of S1 and S2. The connection of electrical energy and pulse is W = M C . In which, W is the electrical energy with the unit of kilowatt-hour, M is the total pulse number,C is the pulse number of ammeter. We choose C equals to 3000 that is to say every kilowatt-hour is 3000pulses.Figure 2. Circuit schematic diagramof watt-hour meterB． LCD displayThe LCD display [6] adopts HT1621 CMOS chip of HOLTEK Company toachieve twelve bits digital display. HT1621 is the LCD drivers with 128 segments (32×4) inner memorizer. The interior of HT1621 consists ofcontrol and time circuits, RAM, LCD drive and watch timer. It hasthe merits of small volume and low cost so that it is suit to watt-hour meter. We use serial interface which only has four lines between HT1621 and AT89LV52. The detailed connection is shown in figure 3. P20, P21, P22 and P23 of AT89LV52 connect to CS, RD, WR and DATA respectively with the use to refurbish the display of RAM. HT1621 drive CMOS chip has 48 nodes in which COM0, COM1, COM2, COM3 connect to the communal end and drive output of LCD and SG0, SG1, SG2, SG3 connect to drive output of every segment respectively. In addition, an adjustable resistance of 20kΩ is put between VDD and VLCD to adjust the display contrast of LCD. Experiment shows that the contrast is better with VDD=5V and VLCD=4V. C． Serial memorizerSerial memorizer adopts low power consumption chip X25045 of XICORcompany .It has three functions which are watchdog timer WTD, voltage supervision and serial memorizer E2PROM with 512 bytes. WTD can be set 200ms, 600ms and 1400ms time intervals. The software program is read into X25045. During the normal running of program, WTD receives the trigger signal in time intervals in order to ensure the normal running of program. X25045 will output a high potential through RESET line if WTD does not receive trigger signal in time intervals. The trigger watt-hour meter reset in order to prevent program flying away. As the serial memorizer chip, 512 bytes of X25045 are used to storage the watt-hour meter code, multi-rate periods of time, the apex electricity, smooth electricity, vale electricity and total electricity of last month and this month. Storage can be divided into two same areas. One is used as data storage. The other is used for backup. The number of storagecan be revised 100,000 times. Data can be stored for 100 years. It is connected withAT89LV52 by SPI agreement bus. The connection is shown in figure 3.D． Clock circuitThe clock circuit is completed by S3530A chip. It is a low powerconsumption clock chip that supports I2C Bus. It sets the clock and calendar according to the data received by CUP communicating with RS485. At the same time, it continues to walk time by its own oscillation. The crystaloscillator of 32.768 kHz is put between Xin and Xout of S3530A which is connected with CPU through latching. SDA foot and SCL foot connect to P1.6 and P1.7 ofAT89LV52 respectively. There are two interrupt alarming foots can be set as second output or minute output synchronizing pulse which supply interrupt signal toAT89LV52 with one second period. Single-chip system will readout the current time through I2C communication interface according to this signal and calculate the period of time that this moment belongs to so as to realize the electrical energy measurement in different periods of time [5]. This clock circuit has spare lithium battery. The powersupply VCC supply power in normal wiring and electrified for lithium battery of 3.6V. When there is power off, the system will automatically convert lithium battery to clock circuit for power supply. The clock will still running accurately even the power is off.Figure 3. Partial circuit figure of watt-hour meterE． RS485 CommunicationMAX485 chip can implement RS485 communication control ofmulti-rate watt-hour meter. MAX485 chip has RS485 communication protocol. It can take 128 hypogenous computers. Its transmission distance is greater than 1km and its transfer rate is up to 250kb per second. The watt-hour meter connects with the unit controller through the RS485 bus. Each unit has a cell controller can manage 128 multi-rate watt-hour meter. The cell controller connects to power management computer.Each watt-hour meter has one and only meter number with eight bits of hex. The electrician should write the user’s information and meter number and then import to the power management computer for initial installation so ad to complete the connection of user and management computer. Management computer sends setting of period of time and clock information with the manner of broadcast communication without address information. PC uploads information by the way of calling address. F． Lack Phase detection and relay controlIt can achieve relay control [7] with P27 of AT89LV52. P27 cancontrol relays using 4N25 photoelectricity isolator so as to complete powersupply and power control. Lack Phase detection gets the signal from fan-out of the relay and connects to 1 foot of photoelectricity isolator after passing a 75K resistance, the diode half-wave rectifier and capacitive filtering respectively. We detect the 4 foot of isolator to determine whether there is the lack of phase. If there is lack of phase, we detect again after 2 seconds overtime. We break off the power immediately if there is lack of power after the twice confirmation. In power protection circuit, it uses the INT1 interrupt foot of AT89LV52 to detect signal.When there is a sudden power off, INT1 jumps into a low voltage and the INT1 interrupt enters to the power protection program relying on the energy storage capacitor to save data. In the system, pulse output of AD7752, relay control port and the inputs of lack phase detection all use photoelectric isolator 4N25. It sends electrical signal by light coupling which can enhance the ability of anti-jamming. IV. THE DESIGN OF SOFTWAREA．The distribution of resourceThe software program includes main program, X25045 read and write program, RS485 serial communication program, interrupt serve program, timer handling program,HT1621 display control program, electrical energy measurement in different period of time and power down protection program, and system self-checking andanti-interference handling program. Interrupt resource distribution of system is: INT0 interrupt is used as AD7752 pulse measurement, INT1 as synchronization detecting, timer T0 as 100 ms timing, T1 as 1ms timing, and T2 as baud rate generator for serial communication program. RS485 asynchronous communication is set to receive interrupt and check information for sending.B． Module desighThe flow chart of main program is shown in figure 4. The watt-hourmeter should be able to initialize at each power up time. The initializing program includes setting working mode of timers, serial stomata and interrupts for AT89LV52,writing control word into X25045, S3530A and HT1621. This system sets three periods of time. The singlechip reads clock value from S3530A per second then analyze this clock belongs to which period of time according to advance periods of time set inX25045 then save the electrical energy in RAM memorizer according to corresponding period of time. We write it to corresponding address of X25045 when the electrical energy achieves one degree. The LCD display with 16 bits shows period of time and electrical energy information in turn. Figure 4. Flow chart of main program V. TESTING RESULTError measurement and running test have been made in Zibo Billion Electron Co., Ltd. The epigenous computer completes the setting of time management. There arethree-rate period of time. The first period of time is vale electricity from 00 point 00 minute to 06 point 30 minutes. The second period of time is apex electricity from 06 point 30 minutes to 22 point 30 minutes. The third period of time is smooth electricity from 22 point 30 minutes to 24 point 00 minute. The setting of rate period of time is sent to computer management system by electric power company according to national policy and saved in X25045. The apex electricity, smooth electricity, vale electricity and total electricity per month read saved in electrical energy meter and sent to epigenous computer through cell controller. The communication baud rate is 9600 bits per second. The checkout platform of 0.1 grade standard electronic power meter is used as standard meter and the multi-rate watt-hour meter is the tested meter. Billion Electron Company has carried out testing according to different load running. The measured data is shown in table 1 with the burthen of 30kW.TABLE I. COMPARE OF NORMAL METER AND TESTING METERThe testing result indicates that the error of this multi-ratewatt-hour meter is less than 1%, belongs to 1.0 grade. The return reading of electrical energy is precision and the emendation of time is timely and right. By testing, the method of decreasing errors for electricity metering can be obtained. Firstly, adjust the sampling resistance of AD7752 to accurate value. Secondly, the value of this resistance is needed less varying with temperature. Thirdly, during electricity metering progress, when mantissa portion of electricity is less than0.01, the remaining pulse should be accessed together, thus cumulative error caused by lack of 0.01degree energy loss could be avoided.VI. CONCLUSION AND EXPECTATIONThe multi-rate watt-hour meter achieves electrical energycomputation in different time according to different time setting. It adopts RS485 for serial communication and realizes automatic meter reading and real-time emendation. The results of production in Billion Electron Company showthat the multi-rate three-phase watt-hour meter proposed in this paper has the characteristics of novel design technique, accurate measurement, and flexible time period setting. Various technical indexes achieve the technique standard for national intelligent card watt-hour meter. Therefore, it has wide application. REFERENCES [1] Bu Zhengl iang, Yin Xianggen, Tu Guangyu. “Development of HV Watt-hour meter.” Automation of Electric Power Systems, 2006, 30(19): 89-93.[2] Kosukegawa M., Sakumoto Y. “Traceability system of electric energy standard and tendency in static watthour meter developmen t in Japan.” Sixth International Conference on Metering Apparatus and Tariffs for Electricity Supply, 1990,4: 259-263.[3] Xuehai Li. Applied tutorial of singlechip. Electronic industry publishing company, 2003.[4] Al-Khateeb Tarik, Blundel Martin. “An el ectronic meter for measuring the saving in electrical power.” The Ninth Arab International Conference on Solar Energy (AICSE-9), Kingdom of Bahrain, 2007,4 (209):328-333.[5] Liu Ying, Liu Qingyu. “Development of a self-calibration precision electricalmea suring meter.” Proceedings of the 1998 Conference Precision Electromagnetic Measurements, 1998,7:276.。

电力专业英语阅读与翻译第一课一、Summary of glossary 术语1.电力系统(electric) power systempower generation 发电transmission system(network) 输电系统(网络)distribution system 配电系统2.发电power generationpower plant 发电厂powerhouse 发电站hydropower plant 水力发电厂nuclear plant 核电厂thermal plant 热电厂fossil-power plant火电厂3.负荷分类load classificationindustrial loads 工业负荷residential loads 居民负荷commercial loads 商业负荷4.拓扑结构system topologyradial system 辐射状系统loop system 环状系统network system 网状系统二、Wording-buildingGeneral Introduction 专业英语词汇和构词方法简介专业词汇的形成主要有三种情况：1.借用日常英语词汇或其他学科的专业词汇，但是词义和词性可能发生了明显的变化。

例如：在日常英语中表示“力量、权力”和在机械专业表示“动力”的power，数学上表示“幂”，在电力专业领域可以仍作为名词，表示“电力、功率、电能”；也可以作为动词，表示“供以电能”。

在日常英语中表示“植物”的plant，在电力专业领域中用来表示“电厂”等。

2.由日常英语词汇或其他学科的专业词汇，直接合成新的词汇。

例如：over和head组合成overhead，表示“架空（输电线）”；super和conductor合成superconductor，表示“超导体”等。

3.由基本词根和前缀或后缀组成新的词汇。

大部分专业词汇属于这种情况。

A decrease in the field current gives rise to lagging (inductive) current in the stator; and increase in the field current that overexcites the motor causes a leading (capacitive) current to appear in the stator.励磁电流减小时，定子电流感性增强；励磁电流增加使电机过励时将在定子中产生容性电流。

An induction machine is an AC two-winding unit in which only one (primary, usually the stator) winding is supplied with an alternating current at a constant frequency ω1 from an external source.感应电机是一种具有双绕组的交流电气设备，它只有一个绕组（一次侧，通常是定子）通过外电源输入固定频率为ω1的交变电流。

Current transformers for protection are essentially similar to those used for the operation of ammeters, watthourmeters and other instruments.保护用电流互感器基本上同操作用的电流表、电能表和其他仪器类似。

DG planning also involves arranging for connection of the renewable power generator with the local grid, and for support of any local electric load when the renewable source is not available.分布式发电规划还包括安排可再生能源发电机与地方电网相连接，这样当可再生能源不可用时，本地电力负荷仍能得到支持。

10月8日《水利水电工程技术术语标准》（二）由WESTBANK根据中华人民共和国水利部能源部联合发布的《水利水电工程技术术语标准》整理，鉴于篇幅空间限制，删除了定义部分和重复部分床面形态 Bed form床沙质(造床质) bed material load垂线观测坐标仪（垂线观测仪） coordinatograph for plummet observation垂线平均流速 mean velocity at a vertical垂直度 perpendicularity垂直度盘指标差（指标差，竖盘指标差） index error of vertical circle垂直升船机 vertical ship lift垂直收缩系数 vena-contracta coefficient垂直位移工作点 operative mark of vertical displacement垂直位移观测（沉陷观测，沉降观测） vertical displacement observation垂直位移基点 datum mark of vertical displacement磁法勘探 magnetic prospecting磁方位角 magnetic azimuth磁极 fieid pole磁子午线 magnetic meridian次固结(次压缩) secondary consolidation(secondary compression)次固结沉降 secondary consolidation settlement次生曲流 submeander次生盐碱化 secondary salinization次要建筑物 secondary structure凑合节 adjuster of steel pipe粗骨料 coarse aggregate粗碎 primary crushing粗制螺栓 bolt,rough bolt错缝 staggered joint搭接 lap joint达西渗流定律Darcy′s law of seepage大坝变形观测 dam deformation observation大坝水泥 dam cement大暴雨 large rainstorm大潮(朔望潮) spring tide大地构造 geotectonics大地控制点（大地点） geodetic control point大地水准面 geoid大地原点（大地基准点） geodetic datum大气窗口 atmospheric window大气折光差 atmospheric refraction error大体积混凝土 mass concrete大头坝 massive-head dam (massive-buttress dam)大修理费 overhauling cost代表性露点 representative dew point带喉管的圆筒式调压室 throttled surge chamber带舌瓣闸门 gate with flap带速饱和变流器差动保护 longitudinal differential protection employing quickly-saturable transformer带状间作 strip cropping带状淤积 belt deposit贷款偿还年限 pay back period of loan单层布置 single storey layout单调节调速器 single-regulation governor单回线 single-circuit line单机调节 independent regulation单级单吸悬臂式离心泵 single-stageend-suction centrifugal pump单级双吸式离心泵 single-stagedouble-suction centrifugal pump单极高压直流系统 monopolar/unipolar HVDC system单价合同(固定单价合同) unit-price contract单价和总价混合合同 lump-sum and unit-price combined contract单列布置 single row layout单母线接线 single-bus connection单曲拱坝 single curvature arch dam单位弹性抗力系数 coefficient of unit elastic resistance单位电能投资 cost per kilowatt-hour单位工程 unit project单位耗药量 powder factor单位容量投资(单位千瓦投资) cost per kilowatt单位水力矩 unit hydraulic torque单位水推力 unithydraulic thrust单位线(单位过程线) unit hydrograph单位线(时段单位线) unit hydrograph单位转速[流量][出力] unit speed[discharge][power]单吸式离心泵 single-suction pump单相变压器 single-phase transformer单相重合闸 one-phase ARC单向变形 one directional deformation单向波 one-direction wave单斜岩层 monocline单因子试验 experiment of single factor单元接线(发电机—变压器组接线) generator-transformer unit connection弹簧常数 spring constant弹性 elasticity弹性极限 limit of elasticity弹性抗力系数 coefficient of elastic resistance弹性模量(弹性系数,杨氏模数) modulus of elasticity弹性屈曲 elastic buckling弹性释水系数(弹性给水度) elastic storavity弹性支承 elastic support当地加速度(时变加速度) local acceleration挡潮闸(防潮闸) tide barrage挡水建筑物 water retaining structure挡水面板 water retaining deck挡水墙 head wall挡土墙 retaining wall导爆索(传爆索) primacord (detonatin fuse)导洞掘进法 heading and cut method导航建筑物(导航架) guide structure (approachtrestle) 导火索 safety fuse导流 River diversion导流堤取水 intake with diversion dike导流方案 diversion scheme导流方式(导流方法) diversion procedure导流孔(洞)封堵 plugging of the diversion opening导流流量标准(导流标准) diversion discharge frequency 导流时段 diversion period导流隧洞 diversion tunnel导沙槽 sand-guide channel导沙坎(拦沙坎,挡沙坎) sand-guide sill导水机构 gate operating mechanism导水系数 coefficient of transmissivity导水锥 hydrocone导线测量 traverse survey导线点 traverse point导线网 traverse network导线网平差 adjustment of traverse network导向坡度 guide slope导向装置 guiding device导叶分布圆 gate circle,wicket gate circle导叶高度 guide vane height导叶开口 guide vane opening导叶限位块 gate stop导轴承 guide bearing导轴瓦间隙 guide bearing clearance倒锤线观测（倒锤法） inverse plumb line observation倒虹吸管 inverted siphon稻田适宜水深 suitable water depth in paddy field灯泡式水轮发电机 bulb hydraulic generator灯泡式水轮机 bulb turbine等高耕作(横坡耕作) contour tillage等高截流 contour interception等高距（等高线间隔） contour interval等高线 contour等径流深图 runoff isopleth map等流时线 isochrone等密图 contour diagram等面积定则 equal-area criterion等容粒径 volume equivalent diameter等水位线图 water table contour map等速流 homogeneous flow等效网络 equivalent network等压面 equi-pressure surface等雨量线图 isohyetal map等值线图 isoline map低坝 low dam低电压保护 under voltage protection低电压闭锁(起动)过电流保护 under voltage-started over current protection 低流态混凝土 low-slump concrete低频起动 low frequency starting低型布置 low-type layout低压(低电压) low voltage (L.V.)低压配电屏 low voltage distribution panel/board低压配电装置 Low voltage switchgear installation低压配电装置 low voltage switchgear installation低扬程泵站 low-head pumping station堤 dike (embankment,levee)堤后式泵房 pump house at levee-toe堤身式泵房 water retaining pump house滴灌 drip irrigation滴灌系统 system of drip irrigation底环 bottom ring底槛 embedded sill (ground sill)底孔导流 bottom outlet diversion底栏栅式取水 bottom-grating intake底流消能(水跃消能) energy dissipation by hydraulic jump底枢 bottom pintle底缘 bottom edge抵偿年限 payment period抵偿年限法 payment period method地表径流 surface runoff地基沉降 ground settlement地基处理 Foundation treatment地基处理 Treatment of foundation地基稳定分析 Stability analysis of foundation地脚螺栓 foundation bolt地壳 earth crust地壳形变观测（大坝库区地壳形变观测） observation of earth crust deformation 地幔 earth mantle地貌 geomorphy地貌综合 cartographic generalization of relief地面分辨力 ground resolution地面灌溉系统 Surface irrigation system地面立体摄影测量 terrestrial stereo photogrammetry地面露点 dew point at earth surface地面排水系统 Surface drainage system地球弯曲差 error due to curvature of earth地球物理勘探(物探) geophysical prospection地图 map地图编绘 Map Compilation地图编绘（原图编绘） map compilation地图编绘与制印 Map Compilation and Reproduction地图分幅 Sheet line system地图复照 map photography地图清绘 map fair drawing地图投影 map projection地图投影变换 map projection transfromation地图投影变形 distortion of map projection地图图号（图号） map numbering地图图式（图式） cartographic symbol地图印刷 map printing地图整饰 map appearance地图制版 map printing plate making地图制印 map reproduction地图制印与仪器 Map reproduction and instrument地物 planimetric feature地物和地貌的表示 representation of planimetric feature and geomorphy地下暗管灌溉 irrigation by buried pipes地下工程施工 Under ground works construction地下浸润灌溉 subsurface irrigation by groundwater地下径流 groundwater runoff地下轮廓线 underground configuration地下埋管 underground penstock地下排水 subsurface drainage地下排水系统 Subsurface drainage system地下热水 hot groundwater地下式厂房 underground power house地下式水电站 underground hydroelectric station地下水侧向补给 recharge by ground water地下水超量开采 excessive mining of ground water地下水动态 ground water regime地下水降深 drawdown of groundwater地下水开采 Ground water mining地下水矿化度 mineralization of ground water地下水利用量 ground water supplement to the crop root zone地下水临界深度 critical depth of ground water地下水平衡(地下水均衡) ground water balance地下水人工补给(人工回灌) artificial recharge of ground water地下水水文地质特性 Hydro geological characteristics of groundwater 地下水下降漏斗 depression cone of ground water地下水越层补给 recharge through weak permeable layer地下水资源 Ground water resources地下水资源开发利用 Development of ground water resources地形 landform地形测量 topographic survey地形图 topographic map地性线（地貌结构线，地貌特征线） orographic character line地震 earthquake地震动水压力 earthquake hydrodynamic pressure地震惯性力 earthquake inertia force地震勘探 seismic prospecting地震烈度 earthquake intensity地震前兆 premonitory symptom地震区划 seismic zoning地震水波 water wave by earthquake地震震级 earthquake magnitude地质编录 geological record地质点 geological observation point地质点测量 geololgical point survey地质构造 geologic structure地质基础 Basicgeology地质勘探 geological exploration地质雷达 geological radar地质力学 geomechanics地质剖面 geological section地质素描 geological sketch典型暴雨 typical rainstorm点法测量 point wise点荷载强度 point load strength点位中误差 mean square error of position点污染源 point-source of pollution点雨量 point precipitation(point rainfall)电测探法 electrical sounding电磁波测距误差 error in electromagnetic wave distance measurement电磁波测距仪 Electromagnetic wave distance measuring instrument（EDMI）电磁波测距仪（物理测距仪） electromagnetic wave distance measuring instrument（EDMI）电动发电机组 motor-generator set电动机 Motor电动机的额定转矩 rated load torque of motor电动机的起动转矩 starting torque of motor电动潜水泵 submersible motor pump电法勘探 electrical prospecting电机 Electrical machine电价 electricity price电抗器 Reactor电抗器 reactor (shunt reactor)电缆夹层 cable interlayer电雷管 electric blasting cap电力不足时间期望值 loss of load expectation (LOLE)电力弹性系数(电力超前系统) elastic coefficient of electric energy电力电缆 power cable电力负荷 Electric power load电力负荷(电力负载) electric power load电力负荷图 electric load diagram电力工程二次部分 Electrotechnical Secondary Circuit电力工程一次部分 Electrotechnical Primary Circuit电力系统 Electrical power system电力系统的集中控制 centralized control of power system电力系统调度 Power system dispatch电力系统计算 Calculation of electric power system电力系统可靠性 Reliability of electric power system电力系统容量 Installed capacity of electric system电力系统运行 Operation of electric power system电力系统状态估计 state estimation in power system电力线载波通信 power line carrier communication电量不足期望值 expected energy not served (EENS)电流差动保护 current differential protection电流互感器 current transformer (CT)电流互感器的精确等级 accurate degree of current transformer电流密度 current density电流平衡保护 current balance protection电路图 circuit diagram电气缓冲单元 electric damper电气设备选择 Electric equipment selection电气液压式调速器 electro-hydraulic governor电气制动 braking resistance (BR)电气主接线 main electrical connection电容式电压互感器 capacitor voltage transformer电视测井 television logging电压变化率保护 voltage change rate protection电压调整率 voltage regulationrate电压互感器 potential transformer (PT) (voltage transformer)电压互感器的精确等级 accurate degree of potential transformer电压降 voltage drop (potential drop)电压控制母线(PV母线) voltage control busbar电压偏移 voltage deviation电液转换器(电液伺服阀) electro-hydraulic transducer,electro-hydraulic servo-valve电液转换器失灵 maladjustment of electro-hydraulic transducer电源 Power source电站气蚀系数 plant cavitation factor电制动 electromagnetic braking电子速测仪（全站式电子速测仪，自动电子速测仪） electronic tacheometer电子印像机 electronic printer电阻率剖面法(电剖面法) resistivity profiling凋萎系数 wilting coefficient, withering coefficient吊车轨道 crane rail吊车梁 crane runway girder吊耳 hoist eye (hook eye)吊杆 hanger (gate stem)吊罐 bucket吊距 centre distance between two hoist eyes调度端 control end (dispatching end)调度通信 dispatching communication调洪库容 flood control storage调绘像片 identified photograph调节流量 regulated flow调节年度 regulation year调节容积 adjustable volume调节系数 regulation coefficient调节周期 period of regulation调速器结构与部件 Components of governor调速器静特性试验 static characteristic test of governor调速器类型 Types of governor调速器失灵 maladjustment of governor调速系统 governing system调速系统静态特性(永态转差系数图) static characteristics of governing system (speed droop graph)调相容量 compensator capacity (condensator capacity)调相压水 bear on water for phase modulation (bear on water for condenser operation) 调蓄容积 storage capacity调压阀(空放阀) pressure regulator调压阀关闭时间 closing time for pressure regulator调压阀开启时间 opening time for pressure regulator调压阀滞后时间 dead time for pressure regulator调压井 surge shaft调压室 surge chamber调压塔 surge tank跌水 drop叠梁闸门 stoplog丁坝 spur dike (groin)顶盖 top cover (head cover)顶盖排水 head cover drainage顶管法 pipe jacking method顶枢 upper gudgeon (top pintle)定床河流模型(定床河工模型) fixed bed model定点定面关系 precipitation relationship between fixed point and fixed area定电流控制(定电流调节) constant current control/regulation定电压控制(定电压调节) constant voltage control定功率控制 constant power control定量评价 quantitative evaluation定轮闸门 fixed roller gate (fixed wheel gate)定期保养 periodical maintenance, regular maintenance定倾半径 metacentric radius定倾中心 metacenter定时限电流保护 definite time-lag current protection定向爆破 directional throw blasting定向取心 directional coring定性评价 qualitative evaluation定裕度角控制(定裕度角调节) constant margin angle control定子 stator定子短路时间常数 stator short-circuit time constant定子接地保护 earthing fault protection for generator stator定子匝间短路保护 stator inter-turn fault protection冬、雨季施工增加费 additional cost in winter-rainy season动床河流模型(动床河工模型) movable bed model动点动面关系(暴雨中心点面关系) precipitation relationship between center point and variable area动断触点(常闭接点) break contact (normally-closed contact)动合触点(常开接点) make contact (normally-open contact)动荷载 dynamic load动静弹模比 ratio of static-dynamic moduli动库容 dynamical storage动力触探试验 dynamic cone penetration test动力弹性模量 dynamic modulus of elasticity动力控制箱 power control box动力配电箱 power distributing box动力系数 dynamic factor动力相似 dynamic similarity动力粘滞系数 dynamic viscosity coefficient动力装备率(动力装备系数) powered equipment rate动量改正系数 momentum coefficient动量损失厚度 momentum loss thickness动能改正系数 kinetic energy coefficient动平床 moving flat bed动平衡 dynamic balancing动水压强 hydrodynamic pressure动态经济分析 dynamic economic analysis动态稳定 dynamic-state stability动态相似(运动相似) kinematic similarity冻结基面 stationary datum冻胀力 frost heave pressure冻胀量 frost-heave capacity洞蚀 cave and hole erosion洞室爆破 coyote blasting陡槽(泄槽) chute陡槽式溢洪道 chute spillway陡坡 chute陡坡 steep slope独立坐标系 independent coordinate system渡槽 aqueduct (flume)渡槽导流 aqueduct flume diversion端电池 end cell端面承压应力 bearing stress端子(接线端子,引出端子) terminal端子接线图 terminal connection diagram短管 short pipe短路 short circuit短路比 short-circuit ratio (SCR)短路电流 short circuit current短路电流非周期分量 aperiodic component of short circuit current 短路电流周期分量 periodic component of short circuit current短路计算 Short circuit calculation短路容量 short-circuit capacity短路校验计算 short-circuit check calculation短期水文预报 short date hydrologic forecasting断层 fault断层擦痕 slicken side断层角砾岩 fault breccia断层泥 fault gouge断层破碎带 shatterred fault zone断层破碎带处理 treatment of fault and fracture zone断层破碎带处理 treatment of fault-fracture zone断层上盘 hanging wall断层下盘 heading wall断口 fracture断裂韧性 toughness of fracture断流围堰导流(拦断河床导流,全断面导流) full river by-pass diversion断路器 circuit breaker断路器失灵保护(后备接线保护) breaker failure protection断面比力 specific force断面比能 specific energy断面测量 section survey断面模型 sectional model断面平均流速 average velocity of cros ssection断面平均流速 mean velocity at across-section(over all mean velocity)断水保护 water supply cut-off protection堆焊 pad welding堆积阶地 construction alter race堆石 rock filling堆石坝 rock fill dam对称电压 symmetric voltage对接 butt joint对流层散射通信 tropospheric scatter communication对数螺线形拱坝 logarithmic spiral arch dam对外交通 site access盾构法 shielding method多波段扫描仪（多光谱扫描仪） multi band scanner多端高压直流输电系统 multi-terminal HVDC transmission system多阀单元 multiplevalve unit多级泵 multi-stage pump多级泵站 multistage pumping station多级船闸 multi-stage lock (flight locks)多年调节 over year regulation(carry over regulation)多年平均年发电量 average annual energy output多年平均年径流量 mean annual runoff多首制取水 multi-head water intake多线船闸 multi-line lock (multiple lock)多相流 multi-phase flow多油式断路器 bulk oil circuit breaker额定变比 rated transformation ratio额定电流 rated current额定电压 rated voltage额定动稳定电流(额定极限通过电流) rated dynamic current (rated limit through-current)额定工况 rated condition额定工况(满载工况) rated condition额定关合电流 rated making current额定开断电流 rated breaking current额定频率 rated frequency额定容量 rated capacity额定水头 rated head额定油压 rated oil pressure额定值 rated value额定值 rated value (rating)额定转速 rated speed二[三]段式电流保护 two[three]-step current protection二倍照准差互差（2c互差，2c较差） discrepancy between twice collimation errors二次电流[电压] secondary current[voltage]二次回路 secondary circuit二次接线图 secondary connection diagram二次筛分(最终筛分) finish screening二端高压直流输电系统 two-terminal HVDC transimission system二期冷却 second stage cooling二维流(二元流) two-dimensional flow发包设计 bid design发电电动机 generator-motor发电机-变压器组保护 protection for generator-transformer unit发电机[电力变压器、调相机、电动机、母线、电抗器]保护 protection of synchronous generator [power transformer,condenser,motor,bus-bar,reactor]。

附件2：外文原文Battery Fuel Gauges: Accurately Measuring Charge LevelAbstract: Battery fuel gauges determine the amount of charge remaining in a secondary battery and how much longer (under specific operating conditions) the battery can continue providing power. This application note discusses the challenges presented in measuring the charge remaining in a lithium-ion battery and the different methods of implementing a fuel gauge to address these challenges.IntroductionSince the advent of the mobile phone, chargeable batteries and their associated fuel-gauge indicators have become an integral part of our information and communication society. They are just as important to us now as automotive fuel gauges have been for the past 100 years. Yet, while drivers do not tolerate inaccurate fuel gauges, mobile-phone users are often expected to live with highly inaccurate, low-resolution indicators. This article discusses the various impediments to accurately measuring charge levels and describes how designers can implement accurate fuel gauging in their battery-powered applications.Lithium-Ion BatteriesLithium-ion batteries have only been in mass production since about 1997, following the resolution of various technical problems during their development.Because they offer the highest energy density with respect to volume and weight (Figure 1), they are used in systems ranging from mobile phones to electric cars.Figure 1. The energy densities of various battery types.Lithium cells also have specific characteristics that are important for determining their charge level. A lithium battery pack must include various safety mechanisms to prevent the battery from being overcharged, deeply discharged, or reverse connected. Because the highly reactive lithium can pose an explosion hazard, lithium batteries must not be exposed to high temperatures.The anode of an Li-ion battery is made from a graphite compound, and the cathode is made of metal oxides with lithium added in a way that minimizes disruption of the lattice structure. This process is calledintercalation. Because lithium reacts strongly with water, lithium batteries are constructed with non-liquid electrolytes of organic lithium salts. When charging a lithium battery, the lithium atoms are ionized in the cathode and transported through the electrolyte to the anode.Battery CapacityThe most important characteristic of a battery (apart from its voltage) is its capacity (C), specified in mA-hours and defined as the maximum amount of charge the battery can deliver. Capacity is specified by the manufacturer for a particular set of conditions, but it changes constantly after the battery is manufactured.Figure 2. The influence of temperature on battery capacity.As Figure 2 illustrates, capacity is proportional to battery temperature. The upper curve shows an Li-ion battery charged with a constant-I, constant-V process at different temperatures. Note that the battery can take approximately 20% more charge at high temperatures than it can at -20°C.As shown by the lower curves in Figure 2, temperature has an even greater influence on the available charge while a battery is being discharged. The graph shows a fully charged battery discharged with two different currents down to a cut-off point of 2.5V. Both curves show a strong dependence on temperature as well as discharge current. At a given temperature and discharge rate, the capacity of a lithium cell is given by the difference between the upper and lower curves. Thus, Li-cell capacity is greatly reduced at low temperatures or by a large discharge current or by both. After discharge at high current and low temperature, a battery still has significant residual charge, which can then be discharged at a low current at the same temperature.Self-DischargeBatteries lose their charge through unwanted chemical reactions as well as impurities in the electrolyte. Typical self-discharge rates at room temperature for common battery types are shown in Table 1.Table 1. The Self-Discharge Rates of Common Battery TypesChemical reactions are thermally driven, so self-discharge is highly temperature-dependent (Figure 3). Self-discharge can be modelled for different battery types using a parallel resistance for leakage currents.Figure 3. Self-discharge of Li-ion batteries.AgingBattery capacity declines as the number of charge and discharge cycles increases (Figure 4). This decline is quantified by the term service life, defined as the number of charge/discharge cycles a battery can provide before its capacity falls to 80% of the initial value. The service life of a typical lithium battery is between 300 and 500 charge/discharge cycles.Lithium batteries also suffer from time-related aging, which causes their capacity to fall from the moment the battery leaves the factory, regardless of usage. This effect can cause a fully charged Li-ion battery to lose 20% of its capacity per year at 25°C, and 35% at 40°C. For partially charged batteries theaging process is more gradual: for a battery with a 40% residual charge, the loss is about 4% of its capacity per year at 25°C.Figure 4. Battery aging.Discharge CurvesThe characteristic discharge curve for a battery is specified in its data sheet for specific conditions. One factor affecting battery voltage is the load current (Figure 5). Load current cannot, unfortunately, be simulated in the model by a simple source resistance, because that resistance depends on other parameters such as the battery's age and charge level.Figure 5. Battery-discharge curve.Secondary lithium cells exhibit relatively flat discharge curves in comparison with primary cells. System developers like this behaviour because the available voltage is relatively constant. However, gradual discharge makes the battery voltage independent of the battery's residual-charge level. Accurately Measuring Charge LevelTo determine the available charge in a battery, simple monitoring methods are preferred. They should consume little energy and should (ideally) allow one to deduce the charge level from battery voltage. Such a voltage-only method can produce unreliable outcomes, however, because no clear correlation exists between voltage and the available charge (Figure 5). Batteryvoltage also depends on temperature, and dynamic relaxation effects can cause a slow increase in the terminal voltage after a reduction in load current. Thus, purely voltage-based monitoring is unlikely to provide charge-level accuracies better than 25%.The relative charge level, often called the state of charge (SOC), is defined as the ratio of residual charge to the battery's charge capacity. Hence charge flow must be measured and monitored through a procedure called "coulomb counting." In practice, coulomb counting is accomplished by integrating the currents flowing into and out of the cell. To measure these currents with a high-resolution ADC, one typically connects a small resistor in series with the anode.Fuel-Gauge LearningThe functional relationship between battery SOC and the parameters mentioned above cannot be related analytically, so cell capacity and charge must be determined empirically. No extensive analytical models are available for calculating (with sufficient accuracy) the capacity of a battery under practical operating conditions such as temperature, number of charge cycles, current, age, etc. Theoretical models apply only to certain "local" conditions. For determining relative charge levels, they are applied locally and calibrated globally.To achieve sufficient accuracy while a battery is in use, the model parameters must be calibrated constantly through a process calledfuel-gauge "learning." In conjunction with coulomb counting, that approach yields fuel gauges accurate to within a few percent.Fuel-Gauge SelectionModern integrated circuits can determine the SOC for all types of secondary cells, cell configurations, and applications. Despite their low supply current (about 60µA in active mode and 1µA in sleep mode), these ICs achieve a high degree of accuracy. Fuel-gauge ICs fall into three categories (Table 2). Because lithium-based batteries are preferred for many applications, the examples shown are based on Li-ion and Li-polymer batteries.Table 2. Fuel-Gauge Circuits.Coulomb counters, sometimes known as battery monitors, are ICs that measure, count, and convert the battery's parameters mentioned above, including charge, temperature, voltage, load cycles, and time. Because coulomb counters do not process the measured variables, they are not intelligent. One such device, the DS2762, already includes an integrated, highly accurate 25m resistor for measuring current. It monitors temperature, battery voltage, and current, and it features a 1-Wire® bus that allows all readings to be read by a microcontroller residing in the battery pack or host system. It also offers the requisite safety circuit essential for secondary Li cells. The result is a flexible, cost-effective system that requires considerable knowledge and development effort (although costs are offset by the software, models, and support provided by the IC vendor).An alternative approach to the coulomb counter is provided by fuel gauges. These all-in-one devices perform fuel-gauging routines with a learning algorithm, and they perform all necessary measurements on their own. Fuel gauges are typically deployed in intelligent, autonomous batteries called smart batteries. Because development effort is considerably less with integrated fuel gauges, this approach is well suited for applications that demand a quick time to market. One such fuel gauge, the DS2780, allows the host to read the SOC using the 1-Wire bus.Another option is provided by programmable fuel gauges, which include integrated microcontrollers that provide considerable flexibility. The MAX1781, for example, includes an integrated RISC core, EEPROM, and RAM. This device enables developers to implement battery models, fuel-gauging routines, and measurements as required. Integrated LED drivers support simple but accurate SOC indication.SummaryFuel gauging of chargeable battery cells is a complex task due to the many interdependent parameters that influence cell capacity. Simple methods of measurement, therefore, deliver inaccurate results that are adequate only for non-critical applications. By utilizing off-the-shelf fuel-gauge ICs, however, one can implement highly accurate and reliable fuel gauges.燃料电池,准确测量负载水平文摘:电池燃料仪检测电荷残留在废旧电池和多少时间(在特定的操作条件)电池可以继续提供电力。

空调节能技术中英文对照外文翻译文献(文档含英文原文和中文翻译)中英文对照资文翻译空调节能技术的研究1、引言节能可以说是楼宇自动控制系统的出发点和归宿。

众所周知，在智能建筑中HV AC (采暖、通风和空调)系统所耗费的能量要占到大楼消耗的总能量的极大部分比例，大致在50%~60%左右。

特别是冷冻机织、冷却塔、循环水泵和空调机组、新风机组，都是耗能大户。

所以实有必要发展一种有效的空调系统节能方法，尤其用是在改善现有大楼空调系统自动化上方面。

DDC(Dircctdigitalcontrol)直接数字化控制，是一项构造简单操作容易的控制设备，它可借由接口转接设各随负荷变化作系统控制，如空调冷水循环系统、空调箱变频自动风量调整及冷却水塔散热风扇的变频操控等，可以让空调系统更有效率的运转，这样不仅为物业管理带来很大的经济效益，而且还可使系统在较佳的工况下运行，从而延长设备的使用寿命以及达到提供舒适的空调环境和节能之目的。

一般大楼常用的空调系统有CA V、V A V、VWV等，各有不同操控方式，都可以用DDC控制。

（1）定风量系统(CA V)定风量系统(ConstantAirV olume，简称CA V)定风量系统为空调机吹出的风量一定，以提供空调区域所需要的冷(暖)气。

当空调区域负荷变动时，则以改变送风温度应付室内负荷，并达到维持室内温度度于舒适区的要求。

常用的中央空调系统为AHU(空调机)与冷水管系统(FCU系统)。

这两者一般均以定风量(CA V)来供应空调区，为了应付室内部分负荷的变动，在AHU定风量系统以空调机的变温送风来处理，在一般FCU系统则以冷水阀ON/OFF控制来调节送风温度。

（2）变风量系统(V A V)变风量系统(VarlableAirV olume，简称V A V)即是空调机(AHU或FCU)可以调变风量。

常用的中央空调系统为AHU(空调机)与冷水管系统FCL系统。

这两者一般均以定风量(CA V)来供应空调区，为了应付室内部分负荷的变动，在AHU定风量系统以空调机的变温送风来处理，在一般FCU系统则以冷水阀ON/OFF控制来调节送风温度。

Alkaline batteries ：碱性电池Capacitor batteries：电容电池Carbon zinc batteries ：碳锌电池Lead acid batteries：铅酸电池Lead calcium batteries：铅钙电池Lithium batteries ：锂电池Lithium ion batteries ：锂离子电池Lithium polymer batteries：锂聚合物电池Nickel cadmium batteries ：镍镉电池Nickel iron batteries ：镍铁电池Nickel metal hydride batteries ：金属氧化物镍氢电池/镍氢电池Nickel zinc batteries：镍锌电池Primary batteries ：原电池Rechargeable batteries ：充电电池Sealed lead acid batteries：密封铅酸电池Silver cadmium batteries ：银钙电池Silver oxide batteries ：银氧化物电池Silver zinc batteries：银锌电池Zinc chloride batteries：银氯化物电池Zinc air batteries：锌空电池Environmental Protection batteries:环保电池Lithium batteries ：锂电池Lithium ion batteries ：锂离子电池Lithium polymer batteries：锂聚合物电池铅酸蓄电池 Lead-acid battery起动铅酸电池 Lead-acid starter batteries摩托车用铅酸电池 Lead-acid batteries for motorcycles内燃机车用铅酸电池 Lead-acid batteries for disel locomotive电动道路车辆用铅酸电池 Lead-acid batteries for electric road vehicles小型阀控密封式铅酸电池 small-sized valve-regulated lead-acid batteries航空用铅酸电池 Aircraft lead-acid batteries固定型阀控密封式铅酸蓄电池 Lead-acid batteries for stationary valve-regulated铅酸电池用极板 plate for lead-acid battery铅锭 lead ingots牵引用铅酸电池 Lead-acid traction batteies电解液激活蓄电池 electrolyte activated battery更多电池资讯：电池产品认证指导网站：valve 排气阀filling device for pleral cells 电池组填充装置negative electrode 负电极negative plate 负极板addition reagent for negative plate 负极板添加剂indicator 指示器top cover 上盖vent plug 液孔塞expanded grid 扩展式板栅specific gravity indicator 比重指示器electrolyte level control pipe 电解液液面控制管electrolyte level indicator 电解液液面指示器electrolyte level sensor 电解液液面传感器hard rubber container 硬橡胶槽envelope separator 包状隔板woven cloth tube 纺布管spongy lead 海绵状铅partition 隔壁over the partition type 越过隔壁型through the partition type 贯通隔壁贯通型separator 隔板(1)battery rack(2)battery stand(3)battery stillage 蓄电池架/蓄电池底垫active material 活性物质glass fiber separator 玻璃纤维隔板glass mat 玻璃纤维绵glass mat tube 玻璃纤维绵管spacing washer 间隔垫圈reinforced fiber separator 强化纤维隔板polarity mark plate 极性标记板pole 极柱pole insulator 极柱绝缘子pole nut 极柱螺母plate 极板plate foot 极板足plate supporter 极板支撑件element 极板群/极群组pole bolt 极柱螺栓plate lug 极板耳dilute sulfuric acid 稀硫酸steel can 金属罐steel container 金属蓄电池槽(1)madribs(2)element rest 鞍子/极群组座tubular plate 管状极板gelled electrolyte 胶体电解液更多电池资讯：电池产品认证指导网站：板栅caution label 警告标签synthetic resin separator 合成树脂隔板plastics container 塑料蓄电池槽synthetic fiber separator 合成纤维隔板connector sunken type 沉没型连接器connetor exposed type 露出型连接器safety valve test 安全阀测试ampere-hour efficency 安时效率one charge distance range 一次充电行程gas recombination on negative electrode typecut-off discharge 终止放电/截止放电阴极气体再化合型/阴极气体复合型(1）specific characteristic (2)energy density (1)比特性（2）能量密度recovering charge 恢复充电(1)open circuit voltage(2)off-load voltage 开路电压/空载电压overcharge 过充电gassing 析气overcharge life test 过充电寿命试验accelerated life test 加速寿命试验active material utilization 活性物质利用率theoretical capacity of active material 活性物质的理论容量over discharge 过放电intermittent discharge 间歇放电full charge 完全充电full discharge 完全放电reverse charge 反充电/反向充电quick charge 快速放电allowable minimum voltage 允许最小电压equalizing charge 均衡充电creeping 蠕变group voltage 组电压shallow cycle endurance 轻负荷寿命/轻负荷循环寿命characteristic of electrolyte decrease 电解液减少特性nominal voltage 标称电压high rate discharge 高率放电high rate discharge characteristic 高率放电特性5 second voltage at discharge 放电 5 秒电压（1）cold cranking ampere（2）cold cranking performance（1）冷启动电流（2）冷启动性能cycle life test 循环寿命测试maximum voltage at discharge 最大放电电压30 second voltage at discharge 放电 30 秒电压residual capacity 残存容量(1)hour rate(2) discharge rate （1）小时率（2）放电率更多电池资讯：电池产品认证指导网站：self discharge (2) local action （1）自放电（2）局部自放电(1) self discharge rate(2) local action rate （1）自放电率（2）局部自放电率actual capacity 实际容量(1)starting capability(2)cranking ability 启动能力cranking current 启动电流battery clamp test 电池夹钳测试power density 功率密度momentary discharge 瞬间放电modified constant voltage charge 修正恒定电压充电initial capacity 初始容量gas recombination by catalyser type 触媒气体复合式initialcharge 初始充电viberation test 振动试验predetermined voltage 预定电压total voltage 总电压activation test for dry charged battery 干式荷电蓄电池活化试验salting 盐析earthquake-proof characteristics 防震性能dielectric voltage withstand test 电介质耐压试验short time discharge 短时间放电escaped acid mist test 酸雾逸出测试terminal voltage 端子电压cell voltage 单电池电压step charge阶段充电short-circuit current 短路电流storage test 保存测试high rate discharge at low temperature 低温高率放电rated voltage 额定电压rated capacity 额定容量fixed resistance discharge 定阻抗放电constant voltage charge 恒压充电constant voltage life test 恒压寿命测试constant current charge 恒流充电constant voltage constant current charge 恒流恒压充电constant current discharge 恒流放电constant watt discharge 恒功率放电low rate discharge characteristics 低率放电特征trickle charge 涓流充电trickle charge current 涓流充电电流trickle charge life test 涓流充电寿命测试thermal runaway 热失控driving pattern test 运行测试capacity in driving pattern test 运行测试更多电池资讯：电池产品认证指导网站：charge急充电floating charge浮充电floating charge voltage 浮充电电压floating charge current 浮充电电流(1)mean voltage (2)average voltage 平均电压on-load voltage 负载电压discharge duration time 放电持续时间(1)final voltage(2)cut-off voltage(3)end voltagedepth of discharge 放电深度discharge voltage 放电电压discharge current 放电电流discharge current density 放电电流密度discharge watt-hour 放电瓦时discharge characteristics 放电特性discharged ampere-hour 放电安时explosion proof test 防爆测试auxiliary charge 补充电maintenance factor 维护率storage characteristics 保存特性终止电压/截止电压gas recombinating efficiencycharge 充电气体复合效率/气体再化合效率charge acceptance test 充电可接受性试验start-of-charge current 充电开始电流charge efficiency 充电效率end-of-charge voltage 充电结束电压specific gravity of electrolyte at the end of charge充电结束时电解液比重charge voltage 充电电压charge current 充电电流charged watt-hour 充电瓦时charge characteristic 充电特性charge ampere-hour 充电安时deep cycle endurance 重负荷循环寿命/重复合寿命weight engergy density 重量能量密度rubber pad 橡胶垫lower level line 下液面线side terminal 侧端子collective exhaust unit 公共的排放单元sintered plaque 烧结极板sintered separator 烧结隔板sintered plate 烧结极板catalyst plug 催化塞spine 芯骨strap 带更多电池资讯：电池产品认证指导网站：隔离物insulating tube绝缘管intercell connector连接线/连接条connector cover连接管盖float mounted plug 浮动安装的栓(1)pasted plate (2)grid type plate 涂膏式极板braidd tube 编织管(1)flame-arrester vent plug (2)flam-retardant vent plug 安全塞explosion and splash proof construction 防爆防溅结构baffle 保护板pocket type plate 袋式极板bottom hole-down 底孔向下（固定）bolt fastening terminal 螺栓连接端子male blade 阳片monoblock container 整体槽positive electrode 正极positive plate 正极板leading wire terminal 引线端子retainer mat 止动垫片ribbed separator 肋隔板(1)jumping wire (2)inter low wire 跳线end plate 端板filling plug 注液塞plante plate 形成式极板/普朗特极板tubular plate 管式极板low electric resistance separator 低电阻隔板tapered terminal post 锥形接线柱electrolyte 电解液container 蓄电池槽/蓄电池壳set of container 成套蓄电池槽level-scope mounted plug 透视塞/透视栓handle 手柄jug 取液管(1)connector;(2)plug concent (1)连接器；(2)插座式连接器connector wire 连接线connecting bar 连杆connecting bar cover 连杆帽lead 引线/连接线edge insulator 绝缘卡side frame 侧框架battery cubicle 蓄电池箱perforated separator 多孔隔板burning rod (铅)焊条terminal 端子更多电池资讯：电池产品认证指导网站：connector 端子连接条terminal cover 端子盖terminal base 端子座tab 接线片lead bushing 铅套corrugated separator 波形隔板(1)lead dioxide;(2)lead peroxide (1)二氧化铅；(2)过氧化铅(1)woven separator;(2)nonwoven separator (1)织物隔板；(2)非织物隔板vent hole 通气孔exhaust tube 排气管antipolar mass 反极性物质output cable 输出电缆microporous rubber separator 微孔像胶隔板specific gravity indicator 比重计leaf separator 叶片式隔板lid sealing compound 密封剂/封口剂sealing gasket 密封衬垫/垫圈lid 蓄电池盖set of lid 系列的盖方通盖板cover board底板solepiece钢珠steel ball压钢珠press steel ball防爆阀valve preventing explosion大电流(倍率)放电discharge in high rate current 标称电压Normal voltage标称容量normal capacity放电容量discharge capacity充电上限电压limited voltage in charge 放电下限电压更多电池资讯：电池产品认证指导网站：voltage in discharge恒流充电constant current charge恒压充电constant voltage charge恒流放电constant current discharge 放电曲线discharge curve充电曲线charge curve放电平台discharge voltage plateau 容量衰减capacity attenuation起始容量initial discharge capacity 流水线pipelining传送带carrying tape焊极耳welding the current collector卷绕wind叠片layer贴胶带stick tape点焊spot welding超声焊ultrasonic weldingThe terminating voltage in discharge of the battery is volt. The limited voltage in charge of the battery is volt.三元素Nickle-Cobalt-Manganese Lithium Oxidethree elements materials钴酸锂Cobalt Lithium Oxide锰酸锂Manganese Lithium Oxide石墨graphite更多电池资讯：电池产品认证指导网站：烘箱oven真空烘箱vacuum oven搅拌机mixing devicevacuum mixing device涂布机coating equipment裁纸刀paper knife ,,,,,,cutting knife分条机equipment for cutting big piece to much pieces 辊压机roll press equipment电阻点焊机spot welding machine超声点焊机ultrasonic spot welding machine 卷绕机winder自动叠片机auto laminating machine激光焊机laser welding machine注液机infusing machine真空注液机vacuum infusion machine预充柜pre-charge equipment化成柜formation systems分容柜grading systems测试柜testing systems内阻仪battery inner resistance tester 万用表multimeter转盘式真空封口机turntable type vacuum sealing machine更多电池资讯：电池产品认证指导网站：自动冲膜机automatic aluminum membrane shaper序号首字母英文中文1 A aging 老化2 B battery charger3 black-fleck 黑斑4 C cap 盖板充电器5 capacity density 能量密度6 capacity grading 分容7 cathode tab welding 极耳超焊8 cell 电芯9 charge(capacity) retention 荷电（容量）保持10 checking code 检码11 concave spot 凹点12 constant current charge 恒流充电13 constant current discharge 恒流放电14 constant voltage charge 恒压充电15 corrective measures 纠正措施16 crack 裂纹17 cut-off voltage 终止电压18 cycle life 循环寿命19 D dark trace 暗痕20 degrade 降级21 dent 凹痕22 discharge depth 放电深度23 distortion 变形24 drape 打折25 E Electrical and MechanicalServices Department 机电部26 electrolyte 电解，电解液27 empaistic 压纹28 end-off voltage 放电截止电压29 environmentally friendly 对环境友好30 equipment first inspection 设备首检31 erode 腐蚀32 explosion-proof line 防爆线33 F first inspection 首检34 formation 化成35 fracture 断裂36 I inspection 检验37 insulate 绝缘38 internal resistance 内阻更多电池资讯：电池产品认证指导网站：J jellyroll 卷芯40 joint 接缝，结合点41 L laser deflecting 偏光42 laser reticle 激光刻线43 laser welding-flatwise weld 激光焊接-平焊laser welding-standing weld 激光焊接-立焊44 leakage 漏液45 leak-checking 测漏46 leaving out of welding 漏焊47 limited charge voltage 充电限制电压48 local action 自放电49 M margin turnly 翘边50 measuring the dimension of cells 电芯卡尺寸51 meet requirement 达到要求52 memory effects 记忆效应53 N nick 划痕54 nominal voltage 标称电压55 notice-board confirmation 看板确认56 nugget 硬块57 O obverse 正面58 open circuit voltage 开路电压59 over charge 过充60 over discharge 过放61 over the thickness 超厚62 P particle 颗粒63 PE membrane PE 膜64 pit 坑点65 placing cells into the box 电芯装盒66 point inspection 点检67 preventive measures 预防措施68 pricking the tapes 扎孔69 process inspection 制程检验70 put the battery piled up 将电芯叠放在一起71 Q qualified products 合格品72 quality assurance 质量保证73 quality control 质量控制74 quality improvement 质量改进75 quality match 品质配对76 quality planning 质量策划77 R rated capacity 额定容量78 recharge 再充电79 refitting the can of cell 电芯壳口整形80 requirment 要求81 reverse 背面，反面更多电池资讯：电池产品认证指导网站：rework 返工83 ringing cells into pyrocondensation films84 S safety vent 安全阀85 sand aperture 砂眼86 scar 疤痕87 secondary battery 二次电池88 select appearance 选外观sharp-set 批锋89 short circuit checking 测短路90 smudginess 污物91 spot welding by laser 激光点焊92 spot welding place 点焊位置93 spraying the code 喷码94 spur 毛刺95 sticking the PVC cover boards 贴面垫96 storing 陈化97 storing with high voltage 高压储存98 T tabs deflection 极耳歪斜99 tabs excursion 极耳错位100 technics requiment 工艺要求101 U ultrasonic welding 超声波焊接102 ultrasonic welding strength 超焊强度103 unqualified products 不合格品104 W wave 波浪105 working procedure 工序套热缩膜Voltage：Units of measuring electrical current, all batteries are rated in volts DC.(DirectCurrent). This determines how much energy is needed to power your equipment.Voltage plateau:（电压平台）A slow decrease in voltage over a long period of time. As a rule, the plateauextendsfrom the first voltage drop at the start of the discharge to the bend of thecurveafter which the voltage drops rapidly at the end.Nominal Voltage（标称电压）The voltage of a battery, as specified by the manufacturer, discharging at aspecified rate and temperature.Working voltage（工作电压）The working voltage of a cell or battery begins at its electrical connections assoon as an electrical consumer is connected to it.Discharging voltage, average voltage (放电电压)更多电池资讯：电池产品认证指导网站：average discharging voltage is the average value of the dischargingvoltageduring the entire discharging process with a related discharging current.Open circuit voltage (OCV 开路电压)The voltage of a battery when there is no current flowing.Closed-Circuit Voltage (CCV 闭路电压)The potential or voltage of a battery when it is discharging or charging. State of charge:The rate of charge capacity vs. whole capacity.Initial voltage（起始电压）A battery＇s initial voltage is the working voltage when discharging begins. End-point voltage (End voltage, Cutoff voltage, Final voltage)截止电压Specified closed circuit voltage at which a service output test is terminated. End-of-discharge voltageThe battery voltage when discharge is terminated.End-of-charge voltageThe battery voltage when charge is terminated.Cutoff voltage (V)The battery voltage at which charge or discharge is terminated.Definition: Capacity(容量）The capacity of a cell is defined as how manymilli-amp-hours (mAh) of current the cell canstore and subsequently deliver.One milli-amp (mA) is 1/1000th of an Amp. Somelarger cell capacities are expressed in Amp-hours(Ah).“Rated capacity” is varies with discharge rate,temperature, and cutoff voltage.Rated capacity is different from power or energyExample:If a cell is rated at 1000 mAh, then it can deliverthe following:1000 mA of current for 1 hour500 mA of current for 2 hours200 mA of current for 5 hours2000 mA of current for 1/2 hourDefinition: Energy Density(能量密度，包括体积比能量和质量比能量）The energy density of a cell is a measure of howmuch energy can be stored in the cell per unitvolume or per unit weight.E (watt-hours) = cell voltage x capacity rating更多电池资讯：电池产品认证指导网站：Energy density per unit volumeis called the“volumetric energy density” and is expressed interms of watt-hours/liter (wh/l).Energy density per unit weight is called the“gravimetric energy density” and is expressedin terms of watt-hours/kilogram (wh/kg).These measurements are useful when you aretrying to determine which cell has the mostcapacity per unit volume or weight.Discharge自放电of the Li-ion Batteriesstrap 钢带vent 防爆阀 port 注液孔锂离子电池的一致性wound type cylindrical wound type箔圆柱形prismatic design 方形叠片式设计Ageing （老化）-Permanent loss of capacity with frequent use orthe passage of time due to unwanted irreversible chemical reactions in the cell.Anode（阳极） - The electrode in an electrochemical cell where oxidation takes place,releasing electrons.During discharge the negative electrode of the cell is the anode.During charge the situation reverses and the positive electrode of the cell is the anode.Cathode（阴极） - The electrode in an electrochemical cell where reduction takesplace, gaining electrons.During discharge the positive electrode of the cell is the cathode. During chargethe situation reverses andthe negative electrode of the cell is the cathode.Cycle （循环）- A single charge and discharge of a battery.Depth of discharge DOD （放电深度）- The ratio of the quantity of electricity orcharge removed from a cell on discharge to its rated capacity.Internal impedance（交流内阻） - Resistance to the flow of AC current within a cell.It takes into account the capacitive effect of the plates forming the electrodes.Internal resistance（直流内阻）- Resistance to the flow of DC electric current withina cell,causing a voltage drop across the cell in closed circuit proportional to the currentdrain from the cell.A low internal impedance is usually required for a high rate cell.更多电池资讯：电池产品认证指导网站：锂离子电池的内阻英语概念到底用哪个概念，是Internal resistance还是Internalimpedance，一些电池说明书内阻用 Internal resistance，也有的用 Internal impedance，我认为 Internal impedance 较好些，因为国内测的电池内阻基本都是交流内阻，而外文也有这样定义的（我在别的帖子也粘贴过）：Internal impedance（交流内阻） - Resistance to the flow of AC current within a cell.It takes into account the capacitive effect of the plates forming the electrodes.Internal resistance（直流内阻）- Resistance to the flow of DC electric current withina cell,causing a voltage drop across the cell in closed circuit proportional to the currentdrain from the cell.A low internal impedance is usually required for a high rate cell.在 IEC6196002 中，只定义为 Internal resistance，而用交流的方法测得的内阻，叫Internal. resistance（交流内阻）用直流的方法测得的内阻，叫 Internal . resistance（直流内阻），其实 Internal.resistance 测得就是阻抗，这样看来不如用 Internal impedance（交流内阻）和 Internal resistance （直流内阻）这两个概念把它们进行分清，以免混淆。

学号： 08438222 常州大学毕业论文外文翻译（2012届）外文题目Decolorization of Reactive Dye Solutions byElectrocoagulation Using Aluminum Electrodes译文题目铝电极电絮凝处理染料废水外文出处industrial. Engineering. Chemistry. Research. 2003, 42：3391-3396学生税勇学院环境与安全工程学院专业班级环工082 校内指导教师李英柳专业技术职务讲师校外指导老师无专业技术职务无二○一二年一月常州大学本科生毕业设计（论文）外文翻译铝电极电絮凝脱色活性染料O. T. Can, M. Bayramoglu, and M. Kobya*Engineering Faculty, Department of Environmental Engineering, Gebze Institute of Technology,41400 Gebze, Turkey.摘要：最近几年，电絮凝法去除化工废料中的污染物已经变成了一个引人注目的方法。

这篇文章讲述了用铝电极作为阳极电极在水介质中用电絮凝处理活性纺织染料中含有的雷马素RB133。

本文旨在研究废水电导率，初始pH值，电流密度，搅拌速率，染料浓度和处理时间对脱色效率和能源消耗的影响。

在早期操作过程中形成的铝羟基化合物可以有效地去除沉淀的染料分子；在接下来的过程中，Al(OH)3捕获到胶体沉淀，并且在浮选阶段中，使得固液分离更加容易。

在整个电絮凝操作阶段中，必须优化设计经济可行的的操作过程。

1 前言近年来，在纺织行业中，由染整工艺带来的染料流失和废水排放引起的污染已经变成了一个严重的环境问题。

染料在废水中进行生物和化学反应，消耗水体中的溶解氧并且因为他们的毒性危害水生生物。

因此，在向受纳水体排放纺织染料废水前进行处理是非常有必要的。

The Basics of Solar Power for Producing Electricity Using solar power to produce electricity is not the same as using solar to produce heat. Solar thermal principles are applied to produce hot fluids or air. Photovoltaic principles are used to produce electricity. A solar panel is made of the natural element, silicon, which becomes charged electrically when subjected to sun light.Solar panels are directed at solar south in the northern hemisphere and solar north in the southern hemisphere (these are slightly different than magnetic compass north-south directions) at an angle dictated by the geographic location and latitude of where they are to be installed. Typically, the angle of the solar array is set within a range of between site-latitude-plus 15 degrees and site-latitude-minus 15 degrees, depending on whether a slight winter or summer bias is desirable in the system. Many solar arrays are placed at an angle equal to the site latitude with no bias for seasonal periods.The intensity of the Sun's radiation changes with the hour of the day, time of the year and weather conditions. To be able to make calculations in planning a system, the total amount of solar radiation energy is expressed in hours of full sunlight perm, or Peak Sun Hours. This term, Peak Sun Hours, represents the average amount of sun available per day throughout the year.It is presumed that at "peak sun", 1000 W/m of power reaches the surface of the earth. One hour of full sun provides 1000 Wh perm = 1 kWh/m - representing the solar energy received in one hour on a cloudless summer day on a one-square meter surface directed towards the sun. To put this in some other perspective, the United States Department of Energy indicates the amount of solar energy that hits the surface of the earth every +/- hour is greater than the total amount of energy that the entire human population requires in a year. Another perspective is that roughly 100 square miles of solar panels placed in the southwestern . could power the country.The daily average of Peak Sun Hours, based on either full year statistics, or average worst month of the year statistics, for example, is used for calculation purposes in the design of the system. To see the average Peak Sun Hours for your area in the United States, Choose the area closest to your location for a good indication of your average Peak Sun Hours.For a view of global solar isolation values (peak sun-hours) use this link: , then, you can use [back] or [previous] on your browser to return right here if you want to.So it can be concluded that the power of a system varies, depending on the intended geographical location. Folks in the northeastern . will need more solar panels in their system to produce the same overall power as those living in Arizona. We can advise you on this if you have any doubts about your area.The four primary components for producing electricity using solar power, which provides common 120 volt AC power for daily use are: Solar panels, charge controller, battery and inverter. Solar panels charge the battery, and the charge regulator insures proper charging of the battery. The battery provides DC voltage to the inverter, and the inverter converts the DC voltage to normal AC voltage. If 240 volts AC is needed, then either a transformer is added or two identical inverters are series-stacked to produce the 240 volts.The output of a solar panel is usually stated in watts, and the wattage is determined by multiplying the rated voltage by the rated amperage. The formula for wattage is VOLTS times AMPS equals WATTS. So for example, a 12 volt 60 watt solar panel measuring about 20 ×44 inches has a rated voltage of and a rated amperage.V × A = Wvolts times amps equals 60 wattsIf an average of 6 hours of peak sun per day is available in an area, then the above solar panel can produce an average 360 watt hours of power per day; 60w times 6 hrs= 360 watt-hours. Since the intensity of sunlight contacting the solar panel varies throughout the day, we use the term "peak sun hours" as a method to smooth out the variations into a daily average. Early morning and late-in-the-day sunlight produces less power than the mid-day sun. Naturally, cloudy days will produce less power than bright sunny days as well. When planning a system your geographical area is rated in average peak sun hours per day based on yearly sun data. Average peak sun hours for various geographical areas is listed in the above section.Solar panels can be wired in series or in parallel to increase voltage or amperage respectively, and they can be wired both in series and in parallel to increase both volts and amps. Series wiring refers to connecting the positive terminal of one panel to the negative terminal of another. The resulting outer positive and negative terminals will produce voltage the sum of the two panels, but the amperage stays the same as one panel. So two 12 volt/ amp panels wired in series produces 24 volts at amps. Four of these wired in series would produce 48 volts at amps. Parallel wiring refers to connecting positive terminals to positive terminals and negative to negative. Theresult is that voltage stays the same, but amperage becomes the sum of the number of panels. So two 12 volt/ amp panels wired in parallel would produce 12 volts at 7 amps. Four panels would produce 12 volts at 14 amps.A charge controller monitors the battery's state-of-charge to insure that when the battery needs charge-current it gets it, and also insures the battery isn't over-charged. Connecting a solar panel to a battery without a regulator seriously risks damaging the battery and potentially causing a safety concern.Charge controllers (or often called charge regulator) are rated based on the amount of amperage they can process from a solar array. If a controller is rated at 20 amps it means that you can connect up to 20 amps of solar panel output current to this one controller. The most advanced charge controllers utilize a charging principal referred to as Pulse-Width-Modulation (PWM) - which insures the most efficient battery charging and extends the life of the battery. Even more advanced controllers also include Maximum Power Point Tracking (MPPT) which maximizes the amount of current going into the battery from the solar array by lowering the panel's output voltage, which increases the charging amps to the battery - because if a panel can produce 60 watts with volts and amps, then if the voltage is lowered to say 14 volts then the amperage increases to (14v ×amps = 60 watts) resulting in a 19% increase in charging amps for this example.Many charge controllers also offer Low Voltage Disconnect (LVD) and Battery Temperature Compensation (BTC) as an optional feature. The LVD feature permits connecting loads to the LVD terminals which are then voltage sensitive. If the battery voltage drops too far the loads are disconnected - preventing potential damage to both the battery and the loads. BTC adjusts the charge rate based on the temperature of the battery since batteries are sensitive to temperature variations above and below about 75F degrees.The Deep Cycle batteries used are designed to be discharged and then re-charged hundreds or thousands of times. These batteries are rated in Amp Hours (ah) - usually at 20 hours and 100 hours. Simply stated, amp hours refers to the amount of current - in amps - which can be supplied by the battery over the period of hours. For example, a 350ah battery could supply continuous amps over 20 hours or 35 continuous amps for 10 hours. To quickly express the total watts potentially available in a 6 volt 360ah battery; 360ah times the nominal 6 volts equals 2160 watts or (kilowatt-hours). Like solar panels, batteries are wired in series and/or parallel to increase voltage to the desired level and increase amp hours.The battery should have sufficient amp hour capacity to supply needed power during the longest expected period "no sun" or extremely cloudy conditions. A lead-acid battery should be sized at least 20% larger than this amount. If there is a source of back-up power, such as a standby generator along with a battery charger, the battery bank does not have to be sized for worst case weather conditions.The size of the battery bank required will depend on the storage capacity required, the maximum discharge rate, the maximum charge rate, and the minimum temperature at which the batteries will be used. During planning, all of these factors are looked at, and the one requiring the largest capacity will dictate the battery size.One of the biggest mistakes made by those just starting out does not understand the relationship between amps and amp-hour requirements of 120 volt AC items versus the effects on their DC low voltage batteries. For example, say you have a 24 volt nominal system and an inverter powering a load of 3 amps, 120VAC, which has a duty cycle of 4 hours per day. You would have a 12 amp hour load (3A × 4 hrs=12 ah). However, in order to determine the true drain on your batteries you have to divide your nominal battery voltage (24v) into the voltage of the load (120v), which is 5, and then multiply this times your 120vac amp hours (5 × 12 ah). So in this case the calculation would be 60 amp hours drained from your batteries - not the 12 ah. Another simple way is to take the total watt-hours of your 120VAC device and divide by nominal system voltage. Using the above example; 3 amps × 120 volts × 4 hours = 1440 watt-hours divided by 24 DC volts = 60 amp hours.Lead-acid batteries are the most common in PV systems because their initial cost is lower and because they are readily available nearly everywhere in the world. There are many different sizes and designs of lead-acid batteries, but the most important designation is that they are deep cycle batteries. Lead-acid batteries are available in both wet-cell (requires maintenance) and sealed no-maintenance versions. AGM and Gel-cell deep-cycle batteries are also popular because they are maintenance free and they last a lot longer.太阳能发电的基础太阳能发电板由天然成分的硅制成，受太阳光控制的电池板。

毕业设计论文外文资料翻译学院：建筑工程学院专业：建筑环境与设备工程姓名：学号：外文出处：Cooling Towers 附件： 1.外文资料翻译译文；2.外文原文。

指导教师评语：签名：年月日冷却塔如果冷却塔设备被用来向建筑空调提供冷却水，在这个过程中冷却水吸收的热能必须释放掉。

释放蒸汽压缩过程产生的热能的两个最常用的方法是直接用空气冷却和用冷却塔。

在冷却塔内，水在被不断循环蒸发中与周围空气进行热量交换。

这种冷却水能够被用来吸收释放冷却设备冷凝器的热能。

暖通空调应用中使用最广的冷却塔是机械通风。

机械通风塔用一个或多个风机推动空气在塔内的流动，用一个冷却塔（如图4.2.13）换热器或填料层使循环水与空气充分接触，用一个水箱来收集物质循环水，和一个配水系统来确保水分散在塔的填料层中。

图 4.2.14 表示循环水和空气在逆流式冷却塔内相互作用的关系。

蒸发冷却过程即水和空气充分接触，包括了同时进行的热质的交换。

理想状态下，水通过配水系统形成飞溅或分裂成较小的水滴，增加了热交换中水的换热面积。

通常用湿球来表示塔的大小和工作情况。

它被定义为出塔冷却水和进塔空气湿球温度之间的差值。

理论上，水在塔内循环可以到达湿球温度，但在实际工作中是不可能实现的。

制冷设备与冷却塔组成的工作范围是由冷凝器热负荷和冷却水流程决定的，而并不是由冷却塔的容量决定的。

冷却塔的工作范围用进出冷却塔的水温差表示。

冷却塔的运行动力是其周围的湿球温度。

平均湿球温度越低，冷却截越容易达到其设计运行参数。

暖通空调应用的典型温度为６℃１０℉。

因此，要相同的热负荷条件下，炎热干燥气候中的冷却塔要比炎热潮湿环境中的冷却塔小得多。

正是因为冷却塔可以通过多种途径释放热量，这就允许设计者不考虑一些通常的问题，因而被广泛采用。

机械通风冷却塔的主要优点是能把水冷却到周围３－６℃（５－１０℉）的湿球温度，这就意谓着冷却塔能提供较低温度的冷凝水，改善（降低）了工作压头，从而提高制冷设备的工作效率。

III. THE DESIGH OF HARDWARE CIRCUITA.Electrical en ergy measureme ntThe three-phase electrical en ergy measureme nt is realized by the low con sume CMOS chipAD7752 of ADI compa ny. The in side of AD7752 adopts digital circuit besides ADC, filter and multiplication circuit which can eliminate noises effectively. The sampli ng course of voltage and electric curre nt in three-phase AC power supply loop is shown in figure 2 in which IA stands for voltage sampling of A phase. The sampling circuits of B phase and C phase are similar to A phase. The power after in tegral is transformed to electrical pulse for output. The pulse of fan-out CF enters into in terreg num INT0 of AT89LV52 through photoelectricity in sulation 4N25. CPU measures the electrical en ergy [4]. We adjust the pulse nu mber of CF by comb ining the state of S1 and S2. The conn ecti on of electrical en ergy and pulse is W = M C .In which, W is the electrical energy with the unit of kilowatt-hour, M is the total pulse number,in consumption clock chip that supports I2C Bus. It sets the clock and calendar to the data received byCUP com muni cat ing with RS485. At the same time, i to walk time by its own oscillation. The crystaloscillator of 32.768 kHz is put between Xin and Xout of S3530A which is connected with CPUthrough latching. SDA foot and SCL foot connect to P1.6 and P1.7 of AT89LV52 respectively. Thereare two in terrupt alarmi ng foots can be set as sec ondoutput or minute output synchronizing pulse which supply in terrupt sig nal to AT89LV52 with onesec ond period. Sin gle-chip system will readout the curre nt time through I2C com muni catio n interface accord ing to this sig nal and calculate the period of time that this moment belongs to so asto realize the electrical energy measuremer different periods of time [5]. This clock circuit has sparelithium battery. The powersupply VCC supply power in normal wiring and electrified for lithiumbattery of 3.6V. When there is power off, the system will automatically con vert lithium battery toclock circuit for power supply. The clock will still running accurately even the power is off.MAX485 chip can impleme nt RS485 com muni cati on con trol of multi-rate watt-hour meter. MAX485 chip has RS485 com muni cati on protocol. It can take 128 hypogenous computers. Its transmission distance is greater than 1km and its tran sfer rate is up to 250kb per sec ond. The watt-hour meter conn ects with the unit con troller through the RS485 bus. Each unit has a cell con troller can man age 128 rate watt-hour meter. The cell con troller conn ects to power man ageme nt computeEach watt-hour meter has one and on ly meter nu mber with eight bits of hex. The electrician should write the user ' s information and meter number and then import to the power man ageme nt computer for in itial in stallati on so ad to complete the connection of user and manageme nt computer. Man ageme nt computer sends sett ing of period of time and clock in formati on with the T — V5S \ n : M.LT-Figure 3. Partial circuit figure of watt-hour meter E . RS485 Com mun icatio n8 nr" II ：6 PIO 1 vex p\ 1 PW> Pi2 Ryl PIJ P(-2 Pld 1帕 P ：5 P(U P b POS PI T 帰 RXD LXD 叹 IXTO P2 ]\TI P22 TO [ 'VT: Pi 5 恵 X2 叩 XS , RtSi t L AIIPT\. vi» Al ?*9LV52 b 6 rs su SI US J SCK zt 14 4 二 j vcc 26 9l 屮 wa D41Amanner of broadcast com muni cati on without address information. PC uploads information by the way of calling address. F Lack Phase detect ion and relay con trolIt ca n achieve relay con trol [7] with P27 of AT89LV52. P27 cancon trol relays using 4N25 photoelectricity isolator so as to complete powersupply and power con trol. Lack Phase detect ion gets the sig nal from fan-out of the relay and conn ects to 1 foot of photoelectricity isolator after pass ing a 75K resista nee, the diode half-wave rectifier and capacitive filteri ng respectively. We detect the 4 foot of isolator to determ ine whether there is the lack of phase. If there is lack of phase, we detect aga in after 2 sec onds overtime. We break off the power immediately if there is lack of power after the twice confirmation. In power protection circuit, it uses the INT1 interrupt foot of AT89LV52 to detect sig nal.When there is a sudden power off, INT1 jumps into a low voltage and the INT1 in terrupt en ters to the power protectio n program relyi ng on the en ergy storage capacitor to save data. In the system, pulse output ofAD7752, relay con trol port and the in puts of lack phase detecti on all use photoelectric isolator 4N25. It sends electrical sig nal by light coupli ng which can enhance the ability of an ti-jam min g. IV. THE DESIGN OF SOFTWAREA.The distribution of resourceThe software program in cludes main program, X25045 read and write program, RS485 serial com muni cati on program, in terrupt serve program, timer han dli ng program, HT1621 display con trol program, electrical en ergy measureme nt in differe nt period of time and power dow n protect ion program, and system self-check ing and an ti-i nterfere nee han dli ng program .In terrupt resource distributi on of system is: INTO in terrupt is used as AD7752 pulse measureme nt, INT1 as synchroni zati on detecting, timer TO as 100 ms timing, T1 as 1ms timing, and T2 as baud rate generator for serial com muni cati on program. RS485 asynchronous com muni cati on is set to receive in terrupt and check in formati on for sending.B.Module desighThe flow chart of main program is shown in figure 4. The watt-hour meter should be able to initialize at each power up time. The initializing program in cludes sett ing work ing mode of timers, serial stomata and inItem Nonual metei Tested merer Error (%) cleciTKii^r 3 000 2996 0.13% Cslm ele-c XKit}? 3 WO 工洱5 0.17% VaJ 霁 3.0P0 2,997 0,10% Torsi el^ctricin" 9.000 S 988 013% 0(5.09 103 06 09 10:3 00.00.000 111口 E 0;fll 0;01 O.WTABLE I. COMPARE OF NORMAL METER AND TESTING METERThe testi ng result in dicates that the error of this multi-rate watt-hour meter is less than 1%, belongs to 1.0 grade. The return reading of electrical energy is precision and the emendation of time is timely and right. By testing, the method of decreas ing errors for electricity meteri ng can be obta in ed. Firstly,adjust the sampli ng resista nee of AD7752 to accurate value. Secon dly, the value of this resista nee is needed less varying with temperature. Thirdly, during electricity metering progress, when mantissa portion of electricity is less than0.01, the remaining pulse should be accessed together, thus cumulative error caused by lack of Tj] 'Jf 1、 ■ RwdS^JOA Mrawiic c Icctnc on MFI - A C LJimimiic J I L Ser id chuRrfLtfbi%FOWH 15电处。

国际电气工程教育46/4虚拟发电厂英国曼彻斯特大学电气与电子工程学院：盖.纽曼和马泰尔.约瑟夫电子邮件：g.newman-3@ 摘要：依靠各种新能源和可再生技术的小型发电机正在得到越来越普遍的应用，这是由于这种发电机能够减少温室气体的排放量，而这些温室气体正是导致气候变化的首要原因。

随着分布式要素的增加，中央式结构逐渐被取代，也就需要我们越来越多的了解分布式发电设备的复合运行方式，这种设备也被称为虚拟电厂。

本文介绍了一种在数学建模基础上进行虚拟电厂开发的一种用户友好型工具，它可以用来作为一个电力系统工程教具，来辅助演示虚拟电厂的特点。

关键词:分布式发电；微型热电联产；太阳能；虚拟电厂；风力发电社会环保意识的增强促使电力行业需要去发展新的业务，以减少二氧化碳的排放，而二氧化碳的释放正是气候变化的首要因素。

这就导致需要通过新的途径来发电，其中一些方法就是确立现有的绿色技术并且推广它们，例如新型海上风力场，还有一些方法就需要更新的技术，例如燃料电池。

这种转变由一系列因素引起，从由于化石燃料发电所引起的气候变化而增强的环保意识，到对长期石油供应安全的担忧。

当然，小规模的传统化石燃料发电，也可以安装备份。

如光伏、风能和微热电联产这样的环保的绿色科技，就正在像高标准看齐，它们减少了来自电网的压力，这样就减少了传统发电导致的二氧化碳的释放。

如果设备量够大，那么通过这些技术，年度生产的电能就可以达到甚至超过每年建设所用的电量。

如果一项建筑安装了足够数量的分布式发电厂，又能够长期的运用这些技术，那么这一地区的电网就可以被完全移除而自给自足。

但是，光伏阵列在晚上处于休眠状态，而风涡轮机的运行性能取决于风速，微热电联产受现场供暖的要求的局限。

要真正成为离网时需安装的储能设备，费用是昂贵的，所以很多地方只有在产大于出的时候才将能量馈入电网，当入不敷出时就只能从电网中取电。

因此，依靠化石燃料燃烧发电还将持续一段时间。

用这种分布式发电厂建模电网就假设了这些分布式发电厂可以作为负载的抵消，这种假设可以成为一个接受点，然而，如果小规模的发电不敷负载，或者减少了网路的可控性，这种假设就不能成立。

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电量的英文缩写
【原创版】
目录
1.电量英文缩写的概念
2.常用电量英文缩写及其含义
3.电量英文缩写的使用场景
4.注意事项
正文
电量的英文缩写通常用来表示电池的剩余电量或者电能的总量。

在英语中，电量的缩写通常为"电量"，其英文为"Electricity"或者"Power"。

在实际应用中，我们常常会用到一些常用的电量英文缩写。

例如，“kWh”表示千瓦时，它是电能的计量单位，常用于电费计算。

另外，“Wh”表示
瓦时，也是电能的计量单位，但通常用于电池容量的表示。

再比如，“VAh”表示伏安时，它是电池容量的单位，常用于蓄电池的标注。

还有“mAh”
表示毫安时，也是电池容量的单位，常用于便携式电子设备的电池容量标注。

在使用电量英文缩写时，我们需要注意一些事项。

首先，我们需要清楚地知道各种电量英文缩写的含义，避免混淆。

其次，我们需要根据实际情景选择合适的电量英文缩写，例如在描述电池容量时，我们应该使用“mAh”而不是“kWh”。

最后，我们需要注意单位的转换，例如 1kWh 等
于 1000Wh，1Wh 等于 1000mWh。

第1页共1页。

Intelligent Power Supply英文With the rapid development of electronic technology, application field of electronic system is more and more extensive, electronic equipment, there are more and more people work with electronic equipment, life is increasingly close relationship. Any electronic equipment are inseparable from reliable power supply for power requirements, they more and more is also high. Electronic equipment miniaturized and low cost in the power of light and thin,small and efficient for development direction. The traditional transistors series adjustment manostat is continuous control linear manostat. This traditional manostat technology more mature, and there has been a large number of integrated linear manostat module, has the stable performance is good, output ripple voltage small, reliable operation, etc. But usually need are bulky and heavy industrial frequency transformer and bulk and weight are big filter.In the 1950s, NASA to miniaturization, light weight as the goal, for a rocket carrying the switch power development. In almost half a century of development process, switch power because of is small volume, light weight, high efficiency, wide range, voltage advantages in electric, control, computer, and many other areas of electronic equipment has been widely used. In the 1980s, a computer is made up of all of switch power supply, the first complete computer power generation. Throughout the 1990s, switching power supply in electronics,electrical equipment, into the rapid development. In addition, large scale integrated circuit technology, and the rapid development ofswitch power supply with a qualitative leap, raised high frequency power products of, miniaturization, modular tide.Power switch tube, PWM controller and high-frequency transformer is an indispensable part of the switch power supply. The traditional switch power supply is normally made by using high frequency power switch tube division and the pins, such as using PWM integrated controller UC3842 + MOSFET is domestic small power switch power supply, the design method of a more popularity.Since the 1970s, emerged in many function complete integrated control circuit, switch power supply circuit increasingly simplified, working frequency enhances unceasingly, improving efficiency, and for power miniaturization provides the broad prospect. Three end off-line pulse width modulation monolithic integrated circuit TOP (Three switch Line) will Terminal Off with power switch MOSFET PWM controller one package together, has become the mainstream of switch power lC development. Adopt TOP switch lC design switch power, can make the circuitsimplified,volume further narrowing, cost also is decreased obviousiy.Monolithic switching power supply has the monolithic integrated, the minimalist peripheral circuit, best performance index, no work frequency transformer can constitute a significant advantage switching power supply, etc. American Pl (with) company in Power in the mid 1990s first launched the new high frequency switching Power supply chip, known as the "top switch Power", with low cost, simple circuit, higher efficiency. The first generation of products launched in 1994 represented TOP100/200 series, the second generation product is the TOPSwitch - debuted in 1997 П .The above productsonce appeared showed strong vitality and he greatly simplifies the design of 150W following switching power supply and the development of new products for the new job, also, high efficiency and low cost switch power supply promotion and popularization created good condition, which can be widely used in instrumentation, notebook computers, mobile phones, TV, VCD and DVD, perturbation VCR, mobile phone battery chargers, power amplifier and other fields, and form various miniaturization, density, on price can compete with the linear manostat AC/DC power transformation module.Switching power supply to integrated direction of future development will be the main trend, power density will more and more big, to process requirements will increasingly high. In semiconductor devices and magnetic materials, no new breakthrough technology progress before major might find it hard to achieve, technology innovation will focus on how to improve the efficiency and focus on reducing weight. Therefore, craft level will be in the position of power supply manufacturing higher in. In addition, the application of digital control IC is the future direction of the development of a switch power. This trust in DSP for speed and anti-interference technology unceasing enhancement. As for advanced control method, now the individual feels haven't seen practicability of the method appears particularly strong, perhaps with the popularity of digital control, and there are some new control theory into switching power supply.(1) The technology: with high frequency switching frequencies increase, switch converter volume also decrease,power density has also been boosted, dynamic responseimproved. Small power DC - DC converter switch frequency will rise to MHz. But as the switch frequency unceasing enhancement, switch components and passive components loss increases, high-frequency parasitic parameters and high-frequency EMI and so on the new issues will also be caused．(2) Soft switching technologies: in order to improve the efficiency of non-linearity of various soft switch, commutation technical application and hygiene, representative of soft switch technology is passive and active soft switch technology, mainly including zero voltage switch/zero current switch (ZVS/ZCS) resonance, quasi resonant, zero voltage/zero current pulse width modulation technology (ZVS/ZCS - PWM) and zero voltage transition/zero current transition pulse width modulation (PWM) ZVT/ZCT - technical, etc. By means of soft switch technology can effectively reduce switch loss and switch stress, help converter transformation efficiency.(3) Power factor correction technology (IC simplifies PFC). At present mainly divided into IC simplifies PFC technology passive and active IC simplifies PFC technology using IC simplifies PFC technology two kinds big, IG simplifies PFC technology can improve AC - DC change device input power factor, reduce the harmonic pollution of power grid.(4) Modular technology. Modular technology can meet the needs of the distributed power system, enhance the system reliability.(5) Low output voltage technology. With the continuous development of semiconductor manufacturing technology, microprocessor and portable electronic devices work more and more low, this requires future DC - DG converter can providelow output voltage to adapt microprocessor and power supply requirement of portable electronic devicesPeople in switching power supply technical fields are edge developing related power electronics device, the side of frequency conversion technology, development of switch between mutual promotion push switch power supply with more than two year growth toward light, digital small, thin, low noise and high reliability, anti-interference direction. Switching power supply can be divided into the AC/DC and DC/DC two kinds big, also have AC/AC DC/AC as inverter DC/DC converter is now realize modular, and design technology and production process at home and abroad, are mature and standardization, and has approved by users, but the AC/DC modular, because of its own characteristics in the process of making modular, meet more complex technology and craft manufacture problems. The following two types of switch power supply respectively on the structure and properties of this.Switching power supply is the development direction of high frequency, high reliability, low consumption, low noise, anti-jamming and modular. Because light switch power, small, thin key techniques are changed, so high overseas each big switch power supply manufacturer are devoted to the development of new high intelligent synchronous rectifier, especially the improvement of secondary devices of the device, and power loss of Zn ferrite (Mn) material? By increasing scientific and technological innovation, to enhance in high frequency and larger magnetic flux density (Bs) can get high magnetic under the miniaturization of, and capacitor is a key technology. SMT technology application makes switching power supply has made considerable progress,both sides in the circuit board to ensure that decorate components of switch power supply light, small, thin. The high frequency switching power supply of the traditional PWM must innovate switch technology, to realize the ZCS ZVS, soft switch technology has become the mainstream of switch power supply technical, and greatly improve the efficiency of switch power. For high reliability index, America's switch power producers, reduce by lowering operating current measures such as junction temperature of the device, in order to reduce stress the reliability of products made greatly increased．Modularity is of the general development of switch power supply trend can be modular power component distributed power system, can be designed to N + 1 redundant system, and realize the capacity expansion parallel. According to switch power running large noise this one defect, if separate the pursuit of high frequency noise will increase its with the partial resonance, and transform circuit technology, high frequency can be realized in theory and can reduce the noise, but part of the practical application of resonant conversion technology still have a technical problem, so in this area still need to carry out a lot of work, in order to make the technology to practional utilization.Power electronic technology unceasing innovation, switch power supply industry has broad prospects for development. To speed up the development of switch power industry in China, we must walk speed of technological innovation road, combination with Chinese characteristics in the joint development path, for the high-speed development of national economy to make the contribution.中文智能开关电源随着电子技术的高速进展，电子系统的应用领域愈来愈普遍，电子设备的种类也愈来愈多，电子设备与人们的工作、生活的关系口益紧密。

汽车防盗报警器中外文翻译XXX: Car Anti-theft Alarm SystemCurrently。

XXX 60 n cars are sold worldwide every year。

with a total of over 400 n in use。

As the number of vehicles increases。

so do the number of traffic accidents and car thefts。

resulting in personal injury and economic loss。

People have XXX has XXX issue。

In order to ce car accidents and give car owners a sense of security。

it is of great XXX a safety system that is easy to operate。

automatically detects the safety status of each part of the car。

and alerts the driver with an alarm in case of XXX.Cars are of high value。

and with the increasing number of cars。

they have e the primary target of XXX。

us anti-XXX。

thieves can easily open the doors and drive away the car with a XXX。

the problem of car theft has not been XXX。

there are several ways to prevent car theft:1.Mechanical anti-theft: XXX is to lock a certain part of the car with a lock。

电池：又称化学电源，是一种将物质的化学能通过电化学氧化还原反应直接转化成电能，通过放电对外做功的装置或系统。

容量：电池在一定的放电条件下所能释放出的电量称为电池的容量理论容量（C0）：假设电极活性物质全部参加电池的成流反应所能提供的电量。

实际容量：指电池在一定的放电条件下实际放出的电量。

它等于放电电流与放电时间的乘积，实际容量的计算方法如下：C=It额定容量：指设计和制造电池时，按照国家或相关部门颁布的标准，保证电池在一定的放电条件下能够放出的最低限度的电量。

标称容量：用来鉴别电池适当的近似容量，一般指0.2C放电时的放电容量比容量：单位质量或单位体积的电池所能够给出的电量。

相应称为质量比容量和体积比容量。

电池的能量：指在一定放电制度下，电池所能输出的电能，通常用瓦时（W·h）表示。

理论能量：假设电池在放电过程中始终处于平衡状态，其放电电压保持电动势（E）的数值，活性物质的利用率为100%，此条件下电池所输出的能量为理论能量W0。

实际容量：在电池放电时实际输出的能量。

在数值上等于电池实际容量（C）与电池平均工作电压（V平）的乘积W=C·V平比能量：单位质量或单位体积电池所能输出的能量。

功率：电池在一定放电制度下，单位时间内输出的能量，单位为瓦（W）或千瓦（kW）比功率：单位质量或单位体积电池输出的功率。

比功率的大小表征电池所能承受的工作电流的大小，一个电池的比功率大，表示它可以承受大电流放电。

电动势：电池的两个电极的平衡电势之差。

开路电压：指在开路状态下（几乎没有电流通过时），电池两极之间的电势差。

工作电压：指电池在接通负荷后的放电过程中，两极显示的电压。

额定电压：指某电池开路电压的最低值。

或者说是在规定条件下电池工作的标准电压。

放电终止电压：也称放电截止电压。

充电电压：指二次电池在充电式，外电源加在电池两端的电压。

放电电流：通常用放电率表示，放电率是指放电时的速率，通常有“时率”和“倍率”两种表示方法。