??Inverters have taken a prominent role in the modern technological world due to the sudden rise of electric cars and renewable energy technologies.

 由于電動(dòng)汽車(chē)和可再生能源技術(shù)的突然興起，逆變器在現代技術(shù)世界中扮演了重要角色。

?? Inverters convert DC power to AC power, they are also used uninterrupted power supplies, control all of electrical machines and active power filtering. This video will explain how to get a pure Sinusoidal electric power output from DC power input, in a step by step logical manner.

  逆變器將直流電轉換為交流電，這一過(guò)程可以為電機工作和有功功率的轉換提供不間斷的電源。這個(gè)視頻將逐步講解如何從DC電源輸入中獲得純正弦電源的輸出。

??Alternating current periodically reverses its direction.  For this reason,  the average value of an alternating current over a cycle will be zero.  Before proceeding to sine wave production, let's see how a square wave alternating current is produced.  In fact, the old type inverter is used to produce simple square wave as their output.

 交流電會(huì )周期性地反轉其方向。因此，整個(gè)周期內交流電的平均值為零。在進(jìn)行正弦波介紹之前，讓我們看看如何產(chǎn)生方波交流電。 實(shí)際上，舊式逆變器通過(guò)產(chǎn)生簡(jiǎn)單的方波作為其輸出的。

?? Let's build an interesting circuit as shown with four switches and one input voltage. This circuit is known as full bridge inverter. 

 讓我們構建一個(gè)有趣的電路，如圖所示，其中包含四個(gè)開(kāi)關(guān)和一個(gè)輸入電壓，該電路稱(chēng)為全橋逆變器。

?? The output is drawn between points A and B. To make this circuit analysis easier, let's replace this actual load with a hypothetical load. Just note the current flow when switches S1 and S4 are on, and S2 and S3 are off.  

輸出在點(diǎn)A和點(diǎn)B之間繪制，為了簡(jiǎn)化此電路分析，讓我們用一個(gè)假設負載替換此實(shí)際負載。當開(kāi)關(guān)S1和S4接通，而S2和S3關(guān)斷時(shí)，注意此時(shí)電流流向。

?? Now just do the reverse and observe the current flow. It is clear that the current flow is the opposite in this case, as is the output voltage across the load. This is the basic technique that produces a square wave alternating current.

現在，只需進(jìn)行相反的操作并觀(guān)察電流。顯然，在這種情況下，電流流動(dòng)是相反的，負載兩端的輸出電壓也是如此。以上，就是產(chǎn)生方波交流電的基本原理。

?? We all know that the frequency of the AC supply available in our homes is 60 Hz. This means that we need to turn the switch on and off 120 times in a second, which is not possible when manually or by using mechanical switches. 

 我們都知道，我們家中可用的交流電源的頻率為60 Hz。這意味著(zhù)我們需要在一秒鐘內將開(kāi)關(guān)打開(kāi)和關(guān)閉120次，這在手動(dòng)或使用機械開(kāi)關(guān)時(shí)是不可能的。

?? We introduce semiconductor switches, such as Mosfet for this purpose. They can turn on and turn off thousands of times per second. With the help of control signals, we can turn transistors on or off very easily. 

 為此，我們引入了半導體開(kāi)關(guān)，例如MOSFET。它們每秒可以打開(kāi)和關(guān)閉數千次。借助控制信號，我們可以非常輕松地打開(kāi)或關(guān)閉晶體管。

?? The square wave output is a high approximation of sine wave output. Old inverter is used to produce them. That's why you hear a humming noise when you run your electric fan or other appliances using square wave power. They also heat up electric equipment. 

方波輸出是正弦波輸出的高度近似，而老的控制器一般產(chǎn)生的是方波電流。這就是為什么在使用方波電源運行電風(fēng)扇或其他設備時(shí)聽(tīng)到嗡嗡聲的原因，此外，它們還會(huì )加熱電氣設備。

?? Modern inverters produce pure sinusoidal output. Let's see how they achieve it. 

 然而，現代的逆變器輸出的是正弦電流，下面讓我們看看他們是如何實(shí)現的？

?? A technique called Pulse Width Modulation is used for this purpose. 

 為此，使用了一種稱(chēng)為脈沖寬度調制的技術(shù)。

?? The logic of Pulse Width Modulation is simple. Generate the DC voltage in the form of pulses of different widths. In regions where you need higher amplitude, it will generate pulses of larger width. The pulses for the sine wave look like this.

 脈沖寬度調制的邏輯很簡(jiǎn)單。以不同寬度的脈沖形式產(chǎn)生直流電壓，在需要更高幅度的區域中，它將生成更大寬度的脈沖。正弦波的脈沖看起來(lái)像這樣：

?? Now here is the tricky part, what will happen if you average these pulses in a small time interval.  You will be surprised to see that the shape of the average pulses looks very similar to the sine curve. The finer the pulses used, the better shape the sine curve will be. 

 這里面最有技巧的一部分是：如果在較短的時(shí)間間隔內，對這些脈沖求平均，會(huì )發(fā)生什么？你會(huì )驚訝地發(fā)現平均脈沖的形狀看起來(lái)與正弦曲線(xiàn)非常相似。使用的脈沖越精細。正弦曲線(xiàn)的就形狀越好。

?? Now, the real question is how to make these pulses and how do we average them in a practical way? Let's see how they are implemented in an actual inverter.

現在真正的問(wèn)題是：如何產(chǎn)生這些脈沖，以及如何以將其在實(shí)際中應用? 讓我們看看如何在實(shí)際的逆變器中實(shí)現它們。

?? Two comparators are used for this purpose. Comparators compare a sine wave with triangular waves.  One comparator uses a normal sine wave,  and the other comparator uses an invertion sine wave.  

為此使用了兩個(gè)比較器。比較器將正弦波與三角波進(jìn)行比較。一個(gè)比較器使用正常的正弦波；另一個(gè)比較器使用反向正弦波。

?? The first comparator controls S1 and S2 switches. And the secondcomparator controls S3 and S4.  

第一比較器控制S1和S2開(kāi)關(guān)，第二比較器控制S3和S4。

?? S1 and S2 switches determined voltage level at point A and the other two switches determined voltage level at point B. 

S1和S2的切換，決定了A點(diǎn)的電壓電平；其他兩個(gè)的切換決定了B點(diǎn)的電壓電平。

?? You can see that the one branch of comparative output is fitted with a logic not gate.  This will make sure that when S1 is on S2 will be off . This also means that we can never turn on S1 and S2 at the same time, which will cause the DC circuit to short circuit. 

可以看到比較器輸出的一個(gè)分支裝有邏輯非門(mén)。這將確保當S1打開(kāi)時(shí)S2將關(guān)閉，這也意味著(zhù)我們永遠不能同時(shí)打開(kāi)S1和S2，這將導致DC電路短路。

?? The switching logic of PWM is simple. When the sine way value is more than the triangular wave, comparator produces 1 signal, otherwise zero signal. 

PWM的開(kāi)關(guān)邏輯很簡(jiǎn)單：當正弦波值大于三角波時(shí)，比較器將置1，否則置0。

?? Now observe voltage variation at first comparator according to this logic. 

現在，根據此邏輯在第一個(gè)比較器處觀(guān)察電壓變化：

?? Control signal of 1 turns on the MOSFET. The voltage pulse is produced at point A are shown. 

MOSFET上控制信號置1，A點(diǎn)處產(chǎn)生的電壓脈沖如下圖：

?? Apply the same switching logic and observe the voltage pulses generated at point B. 

采用相同的開(kāi)關(guān)邏輯，觀(guān)察B點(diǎn)處的電壓脈沖如下圖：

?? Since we are drawing output voltage between point A and B, the net voltage will be the difference between A and B. This is the exact pulse train we need to create the sine wave. The finer the triangular wave, the more accurate the pulse train will be.

由此，我們可以在點(diǎn)A和點(diǎn)B之間繪制輸出電壓，因此凈電壓將是點(diǎn)A和點(diǎn)B之間的差，這正是我們需要產(chǎn)生正弦波的確切脈沖序列。三角波越精細，脈沖序列將越精確。

?? Now the next question is how do we practically implement the averaging. 

 現在，下一個(gè)問(wèn)題是我們如何實(shí)際中實(shí)現平均化。

?? To make it exactly sinusoidal, energy storage elements such as inductors and capacitors are used to smoother power flow. They are called passive filters. Inductors are used to smoothen the current. And capacitors are used to smooth in the voltage.

 為了使其精確地呈正弦形，使用了諸如電感和電容之類(lèi)的能量存儲元件來(lái)平滑功率流。它們稱(chēng)為無(wú)源濾波器。電感用于平滑電流。電容用來(lái)平滑電壓。

??  All in all, with an inverter bridge, a good PWM technique, and a passive filter, you can generate sinusoidal voltage and operate all of your appliances without any fuss. 

 總而言之，借助逆變器電橋、良好的PWM技術(shù)和無(wú)源濾波器，您可以產(chǎn)生正弦電壓，并且可以輕松操作所有設備。

??  The inverter technology we have explained so far has only two levels of voltage.  What if we introduce one more voltage level. This will give better approximation of the sine wave and can reduce instantaneous error.

 到目前為止，我們解釋的逆變器技術(shù)只有兩個(gè)電壓電平，如果再引入一個(gè)電壓電平該怎么辦。這樣可以更好地近似正弦波，并可以減少瞬時(shí)誤差。

?? Such Multilevel Inverter Technology is used in high precision applications like wind turbines and electric cars.

 這種多電平逆變器技術(shù)用于風(fēng)力渦輪機和電動(dòng)汽車(chē)等高精度應用中。

??  Inverters are used in the electric cars have intelligent frequency and amplitude control. In fact, frequency controls the speed of an electric car and amplitude controls the power of it. This way inverters act as the brain of electric cars by producing electric power ideal for driving conditions.

 電動(dòng)汽車(chē)中使用的逆變器具有智能的頻率和幅度控制。實(shí)際上，頻率控制電動(dòng)汽車(chē)的速度，振幅控制電動(dòng)汽車(chē)的功率。通過(guò)這種方式，逆變器通過(guò)產(chǎn)生理想的駕駛條件電力來(lái)充當電動(dòng)汽車(chē)的大腦。

總結

以上就是關(guān)于逆變器工作原理的介紹，三句話(huà)簡(jiǎn)單總結下：

1). 通過(guò)MOSFET開(kāi)關(guān)，我們在全橋逆變電路上產(chǎn)生高頻變化的方波

2). 通過(guò)比較器的應用，產(chǎn)生正弦波所需要的脈沖序列

3). 通過(guò)電容、電感等儲能元件，獲得精確的交流電，實(shí)現電機的控制和功率的轉換。