中文 1125字 譯文 ： 光伏并網(wǎng)逆變器 最近，人們越來越關注的替代能源，因為化石燃料和核電廠的環(huán)境影響及其穩(wěn)定性（長尾和原田， 1997 年 ; Myrzlk， 2001 年）。在各種替代能源中，太陽能發(fā)電尤為重視，除了因為它是一種清潔的，無限的能源，此外相當多的研究已經(jīng)在這一領域取得了突出的成績。太陽能發(fā)電系統(tǒng)由太陽電池組件，充電電池，和一個逆變器。現(xiàn)在只有逆變電流模式進入主流，原因是光伏逆變是正弦電流進入電網(wǎng)。具體體現(xiàn)在單相并網(wǎng)光伏逆變器中，它具有普遍的拓撲結構，這是標準的全橋電壓源逆變器（電平逆變器），它可以創(chuàng)建一個正弦電網(wǎng)電流（ Kjaer et al., 2005; Kojabadi et al., 2006）。這種拓撲結構有兩個普遍的問題如下。 （ 1 ）電池是 太陽能發(fā)電廠必不可少的儲存電能設備。但電池充電是一個短期和有污染的過程，并且有負面經(jīng)濟的效率。然而，逆變器可以不使用電池可以解決這些問題。在這個過程中，接口電路為逆變環(huán)節(jié)的直流電（ DC ）輸出的太陽能電池陣列的交流電源系統(tǒng)。如果輸出電壓的電流源逆變低于電力系統(tǒng)電壓和在發(fā)生短路負荷或逆變器故障，它沒有電流短路（ Myrzlk， 2001年） 。 （ 2 ）在一般的微處理器作為控制器，以實現(xiàn)良好的特點時，太陽能發(fā)電系統(tǒng)與電流源逆變器的設計。是在控制器以較少的價值，有高質量電感和電波的輸出電流的高開關頻率變頻器 所需要的，但是，受限制的是開關損耗和處理器的采樣頻率。 圖 .1 顯示的結構電流源逆變器用作接口電路連接太陽能電池的實用線（ Mohan et al， 1995年） 。它由五個開關，一個電感器， LC 濾波器，輸出端口。逆變器工作在這兩個開關模式。質量保證開關只執(zhí)行斬波行動，而第一季度，第四季度交換機確定方向的輸出電壓根據(jù)極性的電力系統(tǒng)。因此，與一般全橋 PWM逆變器執(zhí)行完整的一塊，該系統(tǒng)減少了開關損耗。 圖 .2顯示波形的傳統(tǒng)電流源逆變器。它代表了波形的輸出電壓和電流，該電流通過電感，輸入信號，每個開關。 圖 .3顯示了脈沖轉變電流源逆變器電路，用于降低開關頻率和提高效率。當太陽能電池模塊輸出電壓的是高于或低于輸出電壓的轉換器，則合成的電流源轉換，這需要 Buck - Boost變換器運作良好。電路降壓頻率的逆變器是固定的，在60 HZ ，這是電力系統(tǒng)頻率。該過濾器（ LS,CS）在輸出端口的逆變器是一種低成本的能力，以改善波形的輸出電流。如果過濾器的高容量的使用，功率因數(shù)的系統(tǒng)將不統(tǒng)一，因為相位延遲。 圖 .4顯示波形是電流源逆變器。指標代表交換期間的升壓斬波器，這個數(shù)字。國際法協(xié)會， ILF代表波形電感電流 各自的轉換和 IDC代表輸出電流的逆變器。作為一個脈沖波形，輸出波形的六脈沖移轉換代表 6 波形開關頻率 TS.We 采用了數(shù)字信號處理器（ TMS320F2812 ）產(chǎn)生的 PWM 6相移信號電流源逆變本文。由于采用非對稱 PWM模式，波形的輸出電流，這幾乎是逆變器的波形相似，六乘以開關頻率但不完全相同的。 圖 .5 顯示了各自的電感電流和輸出電流的常規(guī)逆變器和逆變器相等的開關頻率。 原文： Grid-connected photovoltaic system using current-source inverter Recently, there has been a growing interest in alternative energy sources because fossil fuel and atomic power plants affect the environment and its stability (Nagao andHarada,1997; Myrzlk, 2001). Among the various alternative source of energy, solar power stands apart as it is a clean and unlimited source of energy moreover, a considerable amount of research has been conducted recently in this field. A solar power systemconsists of a photovoltaic module,a charge battery, and an inverter. Only inverters operating in current-source mode are included in the classification,since one of the aims of the PV inverter is to inject a sinusoidal current into the grid. To embody the operation of a single-phase-grid-connected inverter for photovoltaic module,it has general topology that is a standard full-bridge voltage source inverter (VSI), which can create a sinusoidal grid current (Kjaer et al., 2005; Kojabadi et al., 2006). This topology has two general problem as below. (1) A battery is essential to store the electric energy generated by a solar power plant. But a charge battery has problems on its a short duration and pollution along with economic efficiency. However, transmitting the generated energy directly into the utility line without using a battery can solve these problems. In this process, an interface circuit called an inverter links the direct current (DC) output from the solar cell array to the AC power system. It does not matter if the output voltage of the current-source-inverter is lower than the power system voltage and in case of a shorted load or inverter malfunction, it does not have a surge current from a short-circuit (Myrzlk, 2001). (2) In general a microprocessor is used as the controller to achieve good characteristics when designing solar power systems with the current-source-inverters. In the controller, to reduce the value of the inductance and the ripple of the output current, a high switching frequency is required for the inverter, however, the frequency is restricted bythe switching loss and sampling frequency of a processor. Fig. 1 shows the structure of a current-source PWM inverter used as the interface circuit for linking solar cells to the utility line (Mohan et al., 1995). It consists of fiveswitches, one inductor, and an LC filter at the output port. This inverter operates in two switching modes. The QA switch only performs the chopping action, while the Q1Q4 switches determine the directions of the output voltage according to the polarity ofthe power system. Therefore, compared with general full-bridge PWMinverter that performs complete chopping, this system reduces the switching loss. Fig. 2 shows the waveforms of the conventional current-source PWM inverter. It represents the waveforms of the output voltage and current, the current through the inductor, and the input signals to each switch. Fig. 3 shows the proposed six-pulse-shift current-source PWM inverter circuit that is used to reduce the switching frequency and improve the efficiency. Whenever the output voltage of solar cell module is higher or lower than the output voltage of the converter in compositing the current-source converter, it is required that the buck-boost converter operate well. The proposed circuit has buck-frequency of the inverter is fixed at 60 Hz, which is the value of power system frequency. The filter (LS, CS) at the output port of the inverter is of a low capacity to improve the waveform of the output current. If a high capacity filter were to be used, the power factor of the system would not be unity because of the phase delay. Fig. 4 shows the waveforms of the proposed current source PWM inverter. TS represents the switching period of the buck-boost choppers in this figure. ILAILF represent the waveforms of the inductor currents of the respective converters and IDC represents the output current of the inverter. As a operational waveform, the output waveform of six-pulse-shift the converter represent six waveform in switching frequency TS.We used a DSP (TMS320F2812) to generate a PWM six-phase-shift signal for the current-source inverter in this paper. As a result of using the asymmetricPWM mode, the wa