求中文翻译(电气工程专业英语),在线等!!!!!
Inverters derived from voltage source(VSI) are ideally suited for supplying power to a resistive and inductive load and the applications that require constant torque operation of AC motors.Current Source Inverters(CSI) are ideally suited for supplying power to largely capacitive loads andAC voltage buses.Inverters can be further classified on the basis of the mode of the output variable: voltage or current.
Inverter control in practice concerns three aspects:fundamental frequency,amplitude,harmonic profile.
Fundamental frequency is either equal to the switching frequency of the inverter(square-wave and PWM inverter)or ist simple fraction(1/3,1/5,and so) such as in Multiple PWM or sine PWM inverters.
Power electronic applications require the amplitude control of output voltage or output current,called Voltage-Mode control and Current-Mode control respectively.An example of Voltage-Mode control is the adjustable speed drives of induction and synchronous motors.An example of Current-Mode control is a a constant torque drive for induction motors.Output amplitude in both modes can be controlled by varying the DC source voltage or by varying the pulse-width(pulse-width modulation,PWM).The inverters based on the controlled of DC source voltage are also termed DC-Link Inverters.These inverters use an AC to controlled DC converter on the input side. The inverter is square-wave controlled.This arrangement is expensive but exhibits a faster response time than PWM inverters.The control circuitry is also simpler.
Harmonic profiling is an extra feature added over the amplitude control.The objective of harmonic profiling is to bolster the amplitude of the fundamental component of the output voltage and the elimination or reduction of high order harmonics.One of technique involves the ootching or adding step pulses to a base pulse.The other technique involves multiple pulses percycle of the fundamental,each pulse-width modulated to achieve desired wave-shaping of the output waveform(Sine-PWM).
翻译要尽量准确,语句通顺才给分哦!!! 不专业勿来!!
来自电压电源换流器(VSI)特别适于向电阻与电感负载和需要交流电发电机持续的扭力运转应用的供电。电流型换流器(CSI) 特别适于向大量的电容性负载和交流电压总线供电。在输出变量模式的基础上,换流器可以进一步分为电压换流器和电流换流器。
实践中,换流器控制涉及到三个方面:基频、振幅、谐波剖面。
功率电子应用需要输出电压或输出电流的幅值控制,分别称为电压型控制和电流型控制。电压型控制的实例之一是感应和同步发电机的变速传动。电流控制的实例之一是持续扭力传动。两种形式的输出幅度可以通过改变直流电源电压或通过改变脉冲宽度(脉宽调制PWM)来控制。基于受控直流电源电压的换流器也可以叫做直流连接换流器。这些换流器使用在输入一边接通到可控直流换流器的交流电。这种换流器是矩形波控制。这种装配是昂贵的但却比脉宽调制换流器显示了更加快速的反应时间,控制电路也很简单。
谐波造型是另一个附加在振幅控制上的特殊特征。谐波造型的目的是支持输出电压和高序谐波消失或衰减的基波分量的振幅。技术方法之一包括把阶跃脉冲感应到或者增加基础脉冲,令种方法包括基本的复式脉冲周期,每个脉宽被调整到需要的输出波形的波形(正弦脉宽调制)。
(文中有拼写错的词汇,有的猜不透意思,只好按译者的理解选择了一个拼写近似的词取代,如认可本译文,请考虑更正。)
在实践关注逆变器控制三方面:基本频率、幅值、谐波的轮廓。
基本频率是逆变器(PWM逆变器)在相等的开关频率,或者方波是简单的分数(1 / 3,因此,1 / 5),如在多个PWM脉宽调制逆变器或正弦量。
电力电子应用需要的是振幅控制输出电压或电流输出电压型控制,称为分别控制,一个例子是电动机在电压型控制调速驱动的诱导下与其同步. 一个例子是恒定电流型控制感应电动机驱动…输出幅度都能被不同模式的直流电压源或通过PWM脉宽,脉宽调制在逆变器的基础上,对直流电压源的控制也称为DC-Link。. 这些变频器控制使用交流电,直流变流器输入。用方波逆变器控制,这样安排很昂贵,但展品更快的反应时间比PWM逆变器控制电路更简单。
额外的特征是谐波剖面的增加振幅控制,这个目标是为了加强谐波剖面的幅度的基本组成部分的输出电压和消除或减少高次谐波ootching技术涉及的步骤,最基本的是增加一个基地脉冲脉与其他技术涉及的多个脉冲percycle,每个脉宽调制达到预期的wave-shaping输出波形(Sine-PWM)。
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