電力系統(tǒng)自動(dòng)化畢業(yè)論文中英文資料外文翻譯

1、畢業(yè)設(shè)計(jì)(論文)外文資料翻譯專 業(yè) 名 稱： 電力系統(tǒng)自動(dòng)化 英文資料：induction motor starting methodsabstract - many methods can be used to start large ac induction motors. choices such as full voltage, reduced voltage either by autotransformer or wyes - delta, a soft starter, or usage of an adjustable speed drive can all have pote

2、ntial advantages and trade offs. reduced voltage starting can lower the starting torque and help prevent damage to the load. additionally, power factor correction capacitors can be used to reduce the current, but care must be taken to size them properly. usage of the wrong capacitors can lead to sig

3、nificant damage. choosing the proper starting method for a motor will include an analysis of the power system as well as the starting load to ensure that the motor is designed to deliver the needed performance while minimizing its cost. this paper will examine the most common starting methods and th

4、eir recommended applications.i. introductionthere are several general methods of starting induction motors: full voltage, reduced voltage, wyes-delta, and part winding types. the reduced voltage type can include solid state starters, adjustable frequency drives, and autotransformers. these, along wi

5、th the full voltage, or across the line starting, give the purchaser a large variety of automotives when it comes to specifying the motor to be used in a given application. each method has its own benefits, as well as performance trade offs. proper selection will involve a thorough investigation of

6、any power system constraints, the load to be accelerated and the overall cost of the equipment.in order for the load to be accelerated, the motor must generate greater torque than the load requirement. in general there are three points of interest on the motor's speed-torque curve. the first is

7、locked-rotor torque (lrt) which is the minimum torque which the motor will develop at rest for all angular positions of the rotor. the second is pull-up torque (put) which is defined as the minimum torque developed by the motor during the period of acceleration from rest to the speed at which breakd

8、own torque occurs. the last is the breakdown torque (bdt) which is defined as the maximum torque which the motor will develop. if any of these points are below the required load curve, then the motor will not start. the time it takes for the motor to accelerate the load is dependent on the inertia o

9、f the load and the margin between the torque of the motor and the load curve, sometimes called accelerating torque. in general, the longer the time it takes for the motor to accelerate the load, the more heat that will be generated in the rotor bars, shorting ring and the stator winding. this heat l

10、eads to additional stresses in these parts and can have an impaction motor life. ii. full voltagethe full voltage starting method, also known as across the line starting, is the easiest method to employ, has the lowest equipment costs, and is the most reliable. this method utilizes a control to clos

11、e a contactor and apply full line voltage to the motor terminals. this method will allow the motor to generate its highest starting torque and provide the shortest acceleration times.this method also puts the highest strain on the power system due to the high starting currents that can be typically

12、six to seven times the normal full load current of the motor. if the motor is on a weak power system, the sudden high power draw can cause a temporary voltage drop, not only at the motor terminals, but the entire power bus feeding the starting motor. this voltage drop will cause a drop in the starti

13、ng torque of the motor, and a drop in the torque of any other motor running on the power bus. the torque developed by an induction motor varies roughly as the square of the applied voltage. therefore, depending on the amount of voltage drop, motors running on this weak power bus could stall. in addi

14、tion, many control systems monitor under voltage conditions, a second potential problem that could take a running motor offline during a full voltage start. besides electrical variation of the power bus, a potential physical disadvantage of an across the line starting is the sudden loading seen by t

15、he driven equipment. this shock loading due to transient torques which can exceed 600% of the locked rotor torque can increase the wear on the equipment, or even cause a catastrophic failure if the load can not handle the torques generated by the motor during staring.a. capacitors and startinginduct

16、ion motors typically have very low power factor during starting and as a result have very large reactive power draw. see fig. 2. this effect on the system can be reduced by adding capacitors to the motor during starting.the large reactive currents required by the motor lag the applied voltage by 90

17、electrical degrees. this reactive power doesn't create any measurable output, but is rather the energy required for the motor to function. the product of the applied system voltage and this reactive power component can be measured in vars (volt-ampere reactive). the capacitors act to supply a cu

18、rrent that leads the applied voltage by 90 electrical degrees. the leading currents supplied by the capacitors cancel the lagging current demanded by the motor, reducing the amount of reactive power required to be drawn from the power system.to avoid over voltage and motor damage, great care should

19、be used to make sure that the capacitors are removed as the motor reaches rated speed, or in the event of a loss of power so that the motor will not go into a generator mode with the magnetizing currents provided from the capacitors. this will be expanded on in the next section and in the appendix.b

20、. power factor correctioncapacitors can also be left permanently connected to raise the full load power factor. when used in this manner they are called power factor correction capacitors. the capacitors should never be sized larger than the magnetizing current of the motor unless they can be discon

21、nected from the motor in the event of a power loss.the addition of capacitors will change the effective open circuit time constant of the motor. the time constant indicates the time required for remaining voltage in the motor to decay to 36.8% of rated voltage after the loss of power. this is typica

22、lly one to three seconds without capacitors.with capacitors connected to the leads of the motor, the capacitors can continue to supply magnetizing current after the power to the motor has been disconnected. this is indicated by a longer time constant for the system. if the motor is driving a high in

23、ertia load, the motor can change over to generator action with the magnetizingcurrent from the capacitors and the shaft driven by the load. this can result in the voltage at the motor terminals actually rising to nearly 50% of rated voltage in some cases. if the power is reconnected before this volt

24、age decays severe transients can be created which can cause significant switching currents and torques that can severely damage the motor and the driven equipment. an example of this phenomenon is outlined in the appendix. reduced voltageeach of the reduced voltage methods are intended to reduce the

25、 impact of motor starting current on the power system by controlling the voltage that the motor sees at the terminals. it is very important to know the characteristics of the load to be started when considering any form of reduced voltage starting. the motor manufacturer will need to have the speed

26、torque curve and the inertia of the driven equipment when they validate their design. the curve can be built from an initial, or break away torque, as few as four other data points through the speed range, and the full speed torque for the starting condition. a centrifugal or square curve can be ass

27、umed in many cases, but there are some applications where this would be problematic. an example would be screw compressors which have a much higher torque requirement at lower speeds than the more common centrifugal or fan load. see fig. 3. by understanding the details of the load to be started the

28、manufacturer can make sure that the motor will be able to generate sufficient torque to start the load, with the starting method that is chosen.a. autotransformerthe motor leads are connected to the lower voltage side of the transformer. the most common taps that are used are 80%, 65%, and 50%. at 5

29、0% voltage the current on the primary is 25% of the full voltage locked rotor amps. the motor is started with this reduced voltage, and then after a pre-set condition is reached the connection is switched to line voltage. this condition could be a preset time, current level, bus volts, or motor spee

30、d. the change over can be done in either a closed circuit transition, or an open circuit transition method. in the open circuit method the connection to the voltage is severed as it is changed from the reduced voltage to the line level. care should be used to make sure that there will not be problem

31、s from transients due to the switching. this potential problem can be eliminated by using the closed circuit transition. with the closed circuit method there is a continuousvoltage applied to the motor. another benefit with the autotransformer starting is in possible lower vibration and noise levels

32、 during starting. since the torque generated by the motor will vary as the square of the applied voltage, great care should be taken to make sure that there will be sufficient accelerating torque available from the motor. a speed torque curve for the driven equipment along with the inertia should be

33、 used to verify the design of the motor. a good rule of thumb is to have a minimum of 10% of the rated full load torque of the motor as a margin at all points of the curve.additionally, the acceleration time should be evaluated to make sure that the motor has sufficient thermal capacity to handle th

34、e heat generated due to the longer acceleration time.b. solid state or soft startingthese devices utilize silicon controlled rectifiers or scars. by controlling the firing angle of the scr the voltage that the device produces can be controlled during the starting of the motor by limiting the flow of

35、 power for only part of the duration of the sine wave. the most widely used type of soft starter is the current limiting type. a current limit of 175% to 500% of full load current is programmed in to the device. it then will ramp up the voltage applied to the motor until it reaches the limit value,

36、and will then hold that current as the motor accelerates.tachometers can be used with solid state starters to control acceleration time. voltage output is adjusted as required by the starter controller to provide a constant rate of acceleration.the same precautions in regards to starting torque shou

37、ld be followed for the soft starters as with the other reduced voltage starting methods. another problem due to the firing angle of the scr is that the motor could experience harmonic oscillating torques. depending on the driven equipment, this could lead to exciting the natural frequency of the sys

38、tem.c. adjustable frequency drivesthis type of device gives the greatest overall control and flexibility in starting induction motors giving the most torque for an amount of current. it is also the most costly.the drive varies not only the voltage level, but also the frequency, to allow the motor to

39、 operate on a constant volt per hertz level. this allows the motor to generate full load torque throughout a large speed range, up to 10:1. during starting, 150% of rated current is typical.this allows a significant reduction in the power required to start a load and reduces the heat generated in th

40、e motor, all of which add up to greater efficiency. usage of the afd also can allow a smaller motor to be applied due to the significant increase of torque available lower in the speed range. the motor should still be sized larger than the required horsepower of the load to be driven. the afd allows

41、 a great degree of control in the acceleration of the load that is not as readily available with the other types of reduced voltage starting methods.the greatest drawback of the afd is in the cost relative to the other methods. drives are the most costly to employ and may also require specific motor

42、 designs to be used. based on the output signal of the drive, filtered or unfiltered, the motor could require additional construction features. these construction features include insulated bearings, shaft grounding brushes, and insulated couplings due to potential shaft current from common mode vol

43、tage. without these features, shaft currents, which circulate through the shaft to the bearing, through the motor frame and back, create arcing in the bearings that lead to premature bearing failure, this potential for arcing needs to be considered when applying a motor/drive package in a hazardous

44、environment, division2/zone2.an additional construction feature of a motor used on an afd may require is an upgraded insulation system on the motor windings. an unfiltered output signal from a drive can create harmonic voltage spikes in the motor, stressing the insulation of the motor windings.it is

45、 important to note that the features described pertain to motors which will be started and run on an afd. if the drive is only used for starting the motor, these features may not be necessary. consult with the motor manufacturer for application specific requirements.d. primary resistor or reactor st

46、artingthis method uses either a series resistor or reactor bank to be placed in the circuit with the motor. resistor starting is more frequently used for smaller motors.when the motor is started, the resistor bank limits the flow of inrush current and provides for a voltage drop at the motor termina

47、ls. the resistors can be selected to provide voltage reductions up to 50%. as the motor comes up to speed, it develops a counter emf (electro-magnetic field) that opposes the voltage applied to the motor. this further limits the inrush currents. as the inrush current diminishes, so does t>e volta

48、ge drop across the resistor bank allowing the torque generated by the motor to increase. at a predetermined time a device will short across the resistors and open the starting contactor effectively removing the resistor bank from the circuit. this provides for a closed transition and eliminates the

49、concerns due to switching transients.reactors will tend to oppose any sudden changes in current and therefore act to limit the current during starting. they will remain shorted after starting and provide a closed transition to line voltage.e .star delta startingthis approach started with the inducti

50、on motor, the structure of each phase of the terminal are placed in the motor terminal box. this allows the motor star connection in the initial startup, and then re-connected into a triangle run. the initial start time when the voltage is reduced to the original star connection, the starting curren

51、t and starting torque by 2 / 3. depending on the application, the motor switch to the triangle in the rotational speed of between 50% and the maximum speed. must be noted that the same problems, including the previously mentioned switch method, if the open circuit method, the transition may be a tra

52、nsient problem. this method is often used in less than 600v motor, the rated voltage 2.3kv and higher are not suitable for star delta motor start method. increment typethe first starting types that we have discussed have deal with the way the energy is applied to the motor. the next type deals with

53、different ways the motor can be physically changed to deal with starting issues.part windingwith this method the stator of the motor is designed in such a way that it is made up of two separate windings. the most common method is known as the half winding method. as the name suggests, the stator is

54、made up of two identical balanced windings. a special starter is configured so that full voltage can be applied to one half of the winding, and then after a short delay, to the second half. this method can reduce the starting current by 50 to 60%, but also the starting torque. one drawback to this m

55、ethod is that the motor heating on the first step of the operation is greater than that normally encountered on across-the-line start. therefore the elapsed time on the first step of the part winding start should be minimized. this method also increases the magnetic noise of the motor during the fir

56、st step.iv .conclusion there are many ways asynchronous motor starting, according to the constraints of power systems, equipment costs, load the boot device to select the best method. from the device point of view, was the first full-pressure launch the cheapest way, but it may increase the cost eff

57、iciency in the use of, or the power supply system in the region can not meet their needs. effective way to alleviate the buck starts the power supply system, but at the expense of the cost of starting torque. these methods may also lead to increased motor sizes have led to produce the required load

58、torque. inverter can be eliminated by the above two shortcomings, but requires an additional increase in equipment costs. understand the limitations of the application, and drives the starting torque and speed, allowing you for your application to determine the best overall configuration.朗讀顯示對(duì)應(yīng)的拉丁字符

59、的拼音朗讀顯示對(duì)應(yīng)的拉丁字符的拼音英文資料翻譯：異步電動(dòng)機(jī)起動(dòng)的方法摘要：大容量的交流異步電動(dòng)機(jī)有多種啟動(dòng)方法。可選擇的如全壓?jiǎn)?dòng)、降壓?jiǎn)?dòng)、自耦變壓器啟動(dòng)、星三角轉(zhuǎn)換啟動(dòng)、軟啟動(dòng)、或者使用可調(diào)速驅(qū)動(dòng)器，都有潛在優(yōu)勢(shì)和選擇。降壓?jiǎn)?dòng)可以減小啟動(dòng)轉(zhuǎn)矩，可以防止損壞負(fù)載。此外，功率因數(shù)校正電容器可以用來(lái)減小電流，但選擇的型號(hào)必須合適，否則將會(huì)造成電容器的嚴(yán)重?fù)p壞 。為電動(dòng)機(jī)選擇一個(gè)合適的啟動(dòng)方法，需要分析電力系統(tǒng)和啟動(dòng)負(fù)載以確保電機(jī)達(dá)到所需性能且成本最少。本文將探討最常見的幾種啟動(dòng)方法。.引言異步電動(dòng)機(jī)有多種啟動(dòng)方法：全壓?jiǎn)?dòng)、降壓?jiǎn)?dòng)、星三角轉(zhuǎn)換啟動(dòng)和部分繞組等類型。降壓?jiǎn)?dòng)包括固態(tài)啟動(dòng)器、變頻啟動(dòng)和自耦變壓器啟動(dòng)。這些連同全壓或者直接啟動(dòng)，當(dāng)電動(dòng)機(jī)的應(yīng)用場(chǎng)合被確定后可以給購(gòu)買者大量類