TW201519566A - AC-AC power source transformation device and transformation method thereof - Google Patents
AC-AC power source transformation device and transformation method thereof Download PDFInfo
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本發明係與電源轉換有關;特別是指一種交交流電源轉換裝置及其轉換方法。 The invention relates to power conversion; in particular to an AC power conversion device and a conversion method thereof.
按,傳統的交交流電源轉換裝置通常包含有一整流電路與一輸出電容以及一逆變器,藉以將該整流電路將一交流電源轉換成一直流電源,該輸出電容跨接於該整流電路的輸出端,且該逆變器與輸出電容連接後,再連接至一負載。 According to the conventional AC power conversion device, a rectifier circuit and an output capacitor and an inverter are generally included, so that the rectifier circuit converts an AC power source into a DC power source, and the output capacitor is connected across the output end of the rectifier circuit. And the inverter is connected to the output capacitor and then connected to a load.
該交交流電源轉換裝置在作動時,該交流電源的輸入電壓與輸入電流常會處於相位不同的情況,導致功率因數低且電流總諧波失真嚴重。此外,只有在該整流電路輸出之直流電源的電壓高於該輸出電容的電壓時,才會對該輸出電容進行充能,因此造成輸出電容充能時間短縮,導致該整流電路中之二極體導通時間亦隨之縮短,進而導致導通電流的峰值隨之增大,造成輸入電流波形失真及功率因數降低外,更會導致該逆變器之電流響應速度受到影響,使得最後輸出予負載之交流電能嚴重失真。 When the AC power conversion device is activated, the input voltage of the AC power source and the input current are often in a different phase, resulting in a low power factor and a serious current total harmonic distortion. In addition, only when the voltage of the DC power supply outputted by the rectifier circuit is higher than the voltage of the output capacitor, the output capacitor is charged, thereby causing the output capacitor charging time to be shortened, resulting in the diode in the rectifier circuit. The on-time is also shortened, which leads to an increase in the peak value of the on-current, resulting in distortion of the input current waveform and a decrease in the power factor, which in turn causes the current response speed of the inverter to be affected, so that the AC output finally outputs the load. Can be severely distorted.
有鑑於此,本發明之目的用於提供一種交交流電源轉換裝置及其轉換方法,除了具有高功率因數之優點外,可以同時兼顧快速響應與低漣波輸出電壓之目的。 In view of this, the object of the present invention is to provide an AC power conversion device and a conversion method thereof. In addition to the advantages of high power factor, the purpose of both fast response and low chopping output voltage can be simultaneously considered.
緣以達成上述目的,本發明提供有一種交交流 電源轉換裝置用以將一交流電源之電能轉換後供予一負載,且包含一整流電路、一主動式功因校正電路、一自動電荷抽放(auto charge pump)電路以及逆變(Power inverter)電路。其中,該整流電路輸入側與該交流電源連接,用以接收該交流電源之電能後,轉換成直流之電能並自其輸出側輸出;另外,該輸出側具有一正電端以及一負電端。該主動式功因校正電路與該整流電路之輸出端連接,用以接收該整流電路輸出之電能並提升功率因數後輸出,且包含有一第一二極體,其負極與該正電端連接;一第一電容,其一端與該第一二極體之正極連接;一電子開關,其一端與該第一電容另一端連接,而該電子開關另一端則與該負電端連接;一第一電感,其一端與該第一二極體之負極以及該正電端之連接處連接,而該第一電感另一端與該第一電容以及該電子開關的連接處連接;一第二二極體,其正極與該電子開關以及該負電端的連接處連接;一第二電感,其一端與該第一二極體之正極以及該第一電容的連接處連接,另一端則與該第二二極體之負極連接。該自動電荷抽放電路與該主動式功因校正電路連接,係用以接收該主動式功因校正電路輸出之電能後調整輸出者,且包含有一第三二極體,其正極與該第二二極體之負極及該第二電感的連接處連接,而負極則與該第二電感、該第一二極體之正極以及該第一電容之連接處電性連接;一第二電容,其一端連接該第三二極體之負極;一第三電感,其一端連接該第一電容之另一端,而另外一端則電性連接至該第三二極體之負極與該第二電容之連接處;一等效電容,其一端與該第二電容與該第三電感的連接處連接,而另一端則與該第三二極體之正極、該第二二極體之負極及該第二電感的連接處連接;該逆變電路電性連接該自動電荷抽放電路之等效電容,並與該負載連接,用以接收該自動電荷 抽放電路輸出之電能,並轉換成預定頻率之交流電能後,輸出予該負載。 In order to achieve the above object, the present invention provides a communication exchange. The power conversion device is configured to convert the power of an AC power source to a load, and includes a rectifier circuit, an active power factor correction circuit, an automatic charge pump circuit, and a power inverter. Circuit. The input side of the rectifier circuit is connected to the AC power source for receiving the power of the AC power source, and then converted into DC power and outputted from the output side thereof. In addition, the output side has a positive terminal and a negative terminal. The active power factor correction circuit is connected to the output end of the rectifier circuit for receiving the power outputted by the rectifier circuit and outputting the power factor, and includes a first diode, the negative pole of which is connected to the positive terminal; a first capacitor, one end of which is connected to the anode of the first diode; an electronic switch, one end of which is connected to the other end of the first capacitor, and the other end of the electronic switch is connected to the negative terminal; a first inductor One end of the first diode is connected to the cathode of the first diode and the positive terminal, and the other end of the first inductor is connected to the connection of the first capacitor and the electronic switch; a second diode, The positive pole is connected to the connection between the electronic switch and the negative terminal; a second inductor is connected at one end to the junction of the anode of the first diode and the first capacitor, and the other end is connected to the second diode The negative electrode is connected. The automatic charge pumping circuit is connected to the active power factor correction circuit, and is configured to receive the power output by the active power factor correction circuit and adjust the output, and includes a third diode, the positive pole and the second a cathode of the diode is connected to the junction of the second inductor, and a cathode is electrically connected to the junction of the second inductor, the anode of the first diode, and the first capacitor; a second capacitor One end is connected to the negative electrode of the third diode; a third inductor is connected at one end to the other end of the first capacitor, and the other end is electrically connected to the connection between the negative electrode of the third diode and the second capacitor An equivalent capacitor having one end connected to the junction of the second capacitor and the third inductor, and the other end being opposite to the anode of the third diode, the cathode of the second diode, and the second The connection of the inductor is connected; the inverter circuit is electrically connected to the equivalent capacitance of the automatic charge pumping circuit, and is connected to the load for receiving the automatic charge The power outputted by the circuit is discharged and converted into AC power of a predetermined frequency, and then output to the load.
依據上述構思,該交交流電源轉換裝置的電源轉換方法,包含有下列步驟:A.導通該電子開關,使該整流電路輸出之直流電對該第一電感器充能,且該第一電容之儲能對該第二電感器充能,而該第二電容與該第三電感之儲能對該等效電容充能,使該等效電容之儲能通過該逆變電路對該負載釋能;B.斷開該電子開關以阻斷該整流電路輸出之直流電,使該第一電感之儲能對該第一電容充能,並使該第二電感之儲能對該第三電感、該第二電容與該等效電容充能,使該等效電容之儲能持續通過該逆變電路對該負載釋能;C.該第二電感停止釋能,使該第三二極體截止,以使該第三電感之儲能對該第二電容充能,而使該第二電容之跨壓極性反轉,且該等效電容之儲能持續通過該逆變電路對該負載釋能;D.導通該第三二極體,使該第二電容與該第三電感產生與前一步驟反向之電壓,並對該等效電容充能,使該第二電容持續通過該逆變電路對該負載釋能。 According to the above concept, the power conversion method of the AC power conversion device includes the following steps: A. turning on the electronic switch, causing the DC power output by the rectifier circuit to charge the first inductor, and storing the first capacitor The second inductor can be charged, and the storage of the second capacitor and the third inductor charges the equivalent capacitor, so that the stored energy of the equivalent capacitor is discharged to the load through the inverter circuit; B. Disconnecting the electronic switch to block the direct current outputted by the rectifier circuit, causing the energy storage of the first inductor to charge the first capacitor, and storing the energy of the second inductor to the third inductor, the first The second capacitor and the equivalent capacitor are charged, so that the stored energy of the equivalent capacitor continues to be released to the load through the inverter circuit; C. the second inductor stops releasing energy, and the third diode is turned off to The energy storage of the third inductor charges the second capacitor, and the polarity of the voltage across the second capacitor is reversed, and the energy storage of the equivalent capacitor continues to release the load through the inverter circuit; Turning on the third diode to generate the second capacitor and the third inductor The sudden reverse voltage, and the equivalent capacitance can be charged, so that the second capacitor of the inverter circuit by continuously discharging the load.
藉此,透過上述之設計,便可以在電源轉換時提高功率因數,更同時兼顧有快速響應與低漣波輸出電壓外之優點。 Therefore, through the above design, the power factor can be improved during power conversion, and the advantages of fast response and low chopping output voltage are also taken into consideration.
10‧‧‧整流電路 10‧‧‧Rectifier circuit
12‧‧‧正電端 12‧‧‧ Positive terminal
14‧‧‧負電端 14‧‧‧Negative terminal
20‧‧‧主動式功因校正電路 20‧‧‧Active power factor correction circuit
30‧‧‧自動電荷抽放電路 30‧‧‧Automatic charge pumping circuit
40、50‧‧‧逆變電路 40, 50‧‧‧ inverter circuit
100‧‧‧交流電源 100‧‧‧AC power supply
200‧‧‧負載 200‧‧‧load
C1~C5‧‧‧電容 C1~C5‧‧‧ capacitor
L1~L3‧‧‧電感 L1~L3‧‧‧Inductance
D1~D5‧‧‧二極體 D1~D5‧‧‧ diode
SW‧‧‧電子開關 SW‧‧‧Electronic switch
S1~S6‧‧‧切換開關 S1~S6‧‧‧Toggle switch
圖1為本發明較佳實施例之交交流電源轉換裝置的電路圖;圖2A、B至圖5A、B為各步驟之等效電路圖;圖6為本發明另一較佳實施例之交交流電源轉換裝置的電路圖; 1 is a circuit diagram of an AC power conversion device according to a preferred embodiment of the present invention; FIGS. 2A, B to 5A, and B are equivalent circuit diagrams of respective steps; and FIG. 6 is an AC power supply according to another preferred embodiment of the present invention. a circuit diagram of the conversion device;
為能更清楚地說明本發明,茲舉較佳實施例並配合圖示詳細說明如後。請參圖1所示,本發明一較佳實施例之交交流電源轉換裝置用以將一交流電源100之電能轉換後,輸出供予一負載200。該交交流電源轉換裝置包含一整流電路10、一主動式功因校正電路20、一自動電荷抽放(auto charge pump)電路30以及一逆變(Power inverter)電路40。其中:該整流電路10於本實施例中為一橋式整流器,且輸入側與該交流電源100連接,用以接收該交流電源100之電能後,轉換成直流之電能並自其輸出側輸出。另外,該輸出側依據供電之極性而區分有一正電端12以及一負電端14。 In order that the present invention may be more clearly described, the preferred embodiments are illustrated in the accompanying drawings. Referring to FIG. 1 , an AC power conversion device according to a preferred embodiment of the present invention converts the power of an AC power source 100 and outputs it to a load 200. The AC power conversion device includes a rectifier circuit 10, an active power factor correction circuit 20, an automatic charge pump circuit 30, and a power inverter circuit 40. The rectifier circuit 10 is a bridge rectifier in the embodiment, and the input side is connected to the AC power source 100, and is configured to receive the power of the AC power source 100, convert it into DC power, and output it from the output side. In addition, the output side distinguishes between a positive terminal 12 and a negative terminal 14 depending on the polarity of the power supply.
該主動式功因校正電路20與該整流電路10之輸出端連接,用以接收該整流電路10輸出之電能並提升功率因數後輸出,且包含有二個二極體(第一二極體D1以及第二二極體D2)、一個電容(第一電容C1)、二個電感(第一電感L1以及第二電感L2)以及一電子開關SW。該等元件之連接關係如下所述:該第一二極體D1之負極與該正電端12連接。 The active power factor correction circuit 20 is connected to the output end of the rectifier circuit 10 for receiving the power output by the rectifier circuit 10 and outputting the power factor, and includes two diodes (the first diode D1) And a second diode D2), a capacitor (first capacitor C1), two inductors (first inductor L1 and second inductor L2), and an electronic switch SW. The connection relationship of the components is as follows: the negative electrode of the first diode D1 is connected to the positive terminal 12.
該第一電容C1一端與該第一二極體D1之正極連接。 One end of the first capacitor C1 is connected to the anode of the first diode D1.
該電子開關SW一端與該第一電容C1另一端連接,而另一端則與該負電端14連接。 One end of the electronic switch SW is connected to the other end of the first capacitor C1, and the other end is connected to the negative end 14 .
該第一電感L1一端與該第一二極體D1之負極以及該正電端12之連接處連接,而該第一電感L1另一端與該第一電容C1以及該電子開關SW的連接處連接。 One end of the first inductor L1 is connected to the junction of the cathode of the first diode D1 and the positive terminal 12, and the other end of the first inductor L1 is connected to the junction of the first capacitor C1 and the electronic switch SW. .
該第二二極體D2正極與該電子開關SW以及該負電端14的連接處連接。 The positive electrode of the second diode D2 is connected to the connection of the electronic switch SW and the negative terminal 14.
該第二電感L2一端與該第一二極體D1之正極以及該第一電容C1的連接處連接,另一端則與該第二二極體D2之負極連接。 One end of the second inductor L2 is connected to the junction of the anode of the first diode D1 and the first capacitor C1, and the other end is connected to the cathode of the second diode D2.
該自動電荷抽放電路30與該主動式功因校正電路20連接,係用以接收該主動式功因校正電路20輸出之電能後調整輸出,且包含有三個二極體(第三二極體D3、第四二極體D4以及第五二極體D5)、三個電容(第二電容C2、第三電容C3以及第四電容C4)以及一個電感(第三電感L3)。該等元件之連接關係如下所述:該第五二極體D5之正極連接至該第二電感L2、該第一二極體D1之正極以及該第一電容C1之連接處。 The automatic charge pumping circuit 30 is connected to the active power factor correction circuit 20 for receiving the power output of the active power factor correction circuit 20 and adjusting the output, and includes three diodes (third diode) D3, fourth diode D4 and fifth diode D5), three capacitors (second capacitor C2, third capacitor C3, and fourth capacitor C4) and one inductor (third inductor L3). The connection relationship of the components is as follows: the anode of the fifth diode D5 is connected to the second inductor L2, the anode of the first diode D1, and the junction of the first capacitor C1.
該第三二極體D3之正極與該第二二極體D2之負極及該第二電感L2的連接處連接,而負極則與該第五二極體D2之負極連接以透過該第五二極體D5與該第一二極體D1之正極、該第二電感L2以及該第一電容C1之連接處電性連接。 The anode of the third diode D3 is connected to the junction of the cathode of the second diode D2 and the second inductor L2, and the cathode is connected to the cathode of the fifth diode D2 to transmit the fifth The pole body D5 is electrically connected to the junction of the anode of the first diode D1, the second inductor L2, and the first capacitor C1.
該第二電容C2一端則與該第三二極體D3之負極及該第五二極體D5之負極的連接處連接。 One end of the second capacitor C2 is connected to the junction of the negative electrode of the third diode D3 and the negative electrode of the fifth diode D5.
該第四二極體D4之正極與該第三二極體D3 之負極、該第五二極體D5之負極及該第二電容C2之連接處連接。 a positive electrode of the fourth diode D4 and the third diode D3 The negative electrode, the negative electrode of the fifth diode D5, and the junction of the second capacitor C2 are connected.
該第三電感L3一端連接該第一電容C1之另一端,另外一端則與該第四二極體D4之負極連接,而透過該第四二極體D4電性連接至該第三二極體D3之負極、該第五二極體D5之負極及該第二電容C2之連接處。 One end of the third inductor L3 is connected to the other end of the first capacitor C1, and the other end is connected to the cathode of the fourth diode D4, and is electrically connected to the third diode through the fourth diode D4. The junction of the negative electrode of D3, the negative electrode of the fifth diode D5, and the second capacitor C2.
該第三電容C3與該第四電容C4的一端相連接,且該第三電容C3之另一端與該第二電容C2與該第三電感L3的連接處連接,而該第四電容C4之另一端與該第三二極體D3之正極、該第二二極體D2之負極及該第二電感L2的連接處連接。 The third capacitor C3 is connected to one end of the fourth capacitor C4, and the other end of the third capacitor C3 is connected to the junction of the second capacitor C2 and the third inductor L3, and the fourth capacitor C4 is connected to another One end is connected to a junction of the anode of the third diode D3, the cathode of the second diode D2, and the second inductor L2.
該逆變電路40電性連接該自動電荷抽放電路30並與該負載200連接,用以接收該自動電荷抽放電路30輸出之電能,並轉換成預定頻率之交流電能後輸出予該負載200。於本實施例中,該逆變電路40係呈半橋是架構而包含有一第一切換開關S1及一第二切換開關S2,且該第一切換開關S1與該第二切換開關S2的一端相連接。另外,該第一切換開關S1之另一端與該第二電容C2、該第三電容C3與該第三電感L3的連接處連接,而該第二切換開關S2之另一端則與該第四電容C4、該第三二極體D3之正極、該第二二極體D2之負極及該第二電感L2的連接處連接。 The inverter circuit 40 is electrically connected to the automatic charge pumping circuit 30 and connected to the load 200 for receiving the power output by the automatic charge pumping circuit 30, and converting it into AC power of a predetermined frequency and outputting the power to the load 200. . In the embodiment, the inverter circuit 40 is a half bridge, and includes a first switch S1 and a second switch S2, and the first switch S1 and the second switch S2 are opposite to each other. connection. In addition, the other end of the first switch S1 is connected to the connection of the second capacitor C2, the third capacitor C3 and the third inductor L3, and the other end of the second switch S2 is connected to the fourth capacitor. C4, the anode of the third diode D3, the cathode of the second diode D2, and the junction of the second inductor L2 are connected.
於本實施例中,該等電容C1~C4、該等電感L1~L3、輸入電壓、該電子開關SW以及該等切換開關S1、S2之切換頻率以及該負載200之規格如下表所示:
藉此,透過上述結構設計與規格,使用時便將該負載200之一端連接至該第三電容C3及該第四電容C4的連接處,而負載200之另外一端則連接至該第一切換開關S1及該第二切換開關S2的連接處,再利用下述之電源轉換方法,便可達到提高功率因數,同時兼顧快速響應與低漣波輸出電壓之效果,而該方法包含有下列步驟: Therefore, through the above structural design and specifications, one end of the load 200 is connected to the connection of the third capacitor C3 and the fourth capacitor C4, and the other end of the load 200 is connected to the first switch. The connection between S1 and the second switch S2 can be improved by using the power conversion method described below, and the effect of fast response and low chopping output voltage can be achieved, and the method includes the following steps:
A.請參閱圖2A及圖2B,導通該電子開關SW,使該整流電路10輸出之直流電對該第一電感器L1充能,且該第一電容C1之儲能對該第二電感器L2充能,而該第二電容C2與該第三電感L3之儲能對該第三電容C3與該第四電容C4充能,使該第三電容C3與該第四電容C4之儲能通過該逆變電路40對該負載釋能。另外,若交交流電源轉換裝置動作於正半波導通狀態,則第二切換開關S2導通,此時第四電容器C4對該負載200釋能,其等效電路如圖2A所示。若交交流電源轉換裝置動作於負半波導通狀 態,則第一切換開關S1導通,此時則為該第三電容器C3對該負載200釋能,其等效電路如圖2B所示。 A. Referring to FIG. 2A and FIG. 2B, the electronic switch SW is turned on, and the DC power outputted by the rectifier circuit 10 charges the first inductor L1, and the energy stored by the first capacitor C1 is applied to the second inductor L2. Charging, and the storage of the second capacitor C2 and the third inductor L3 charges the third capacitor C3 and the fourth capacitor C4, so that the energy storage of the third capacitor C3 and the fourth capacitor C4 Inverter circuit 40 releases the load. Further, if the AC power conversion device operates in the positive half-wave-on state, the second change-over switch S2 is turned on, and at this time, the fourth capacitor C4 discharges the load 200, and the equivalent circuit thereof is as shown in FIG. 2A. If the AC power conversion device operates in the negative half-waveguide Then, the first switch S1 is turned on, and at this time, the third capacitor C3 is discharged to the load 200, and the equivalent circuit is as shown in FIG. 2B.
B.請參閱圖3A及圖3B,斷開該電子開關SW以阻斷該整流電路10輸出之直流電,使該第一電感L1之儲能對該第一電容C1充能,並使該第二電感L2之儲能對該第三電感L3以及該第二電容C2充能,並透過該第二電容C2與該第三電感L3形成之共振電路,將該第二電感L2之儲能傳導至該第三電容C3與該第四電容C4,使該第三電容C3與該第四電容C4之儲能持續依據正半波或負半波導通狀態通過該逆變電路40對該負載200釋能。 B. Referring to FIG. 3A and FIG. 3B, the electronic switch SW is disconnected to block the direct current output from the rectifier circuit 10, so that the energy storage of the first inductor L1 charges the first capacitor C1, and the second The storage of the inductor L2 charges the third inductor L3 and the second capacitor C2, and transmits a resonant circuit formed by the second capacitor C2 and the third inductor L3, and the stored energy of the second inductor L2 is transmitted to the The third capacitor C3 and the fourth capacitor C4 enable the energy storage of the third capacitor C3 and the fourth capacitor C4 to continue to be discharged to the load 200 through the inverter circuit 40 according to the positive half wave or the negative half waveguide pass state.
C.請參閱圖4A及圖4B,該第一電感L1停止釋能後,該第一二極體D1截止,而該第二電感L2停止釋能後,該第五二極體D5截止。此時,該第二電容C2與該第三電感L3形成共振電路,以使該第三電感L3之儲能對該第二電容C2充能,而使該第二電容C2之跨壓極性反轉,而該第三電容C3與該第四電容C4之儲能持續依據正半波或負半波導通狀態通過該逆變電路40對該負載200釋能。 C. Referring to FIG. 4A and FIG. 4B , after the first inductor L1 stops releasing energy, the first diode D1 is turned off, and after the second inductor L2 stops releasing energy, the fifth diode D5 is turned off. At this time, the second capacitor C2 forms a resonant circuit with the third inductor L3, so that the energy storage of the third inductor L3 charges the second capacitor C2, and the polarity of the second capacitor C2 is reversed. The energy storage of the third capacitor C3 and the fourth capacitor C4 is continuously discharged to the load 200 through the inverter circuit 40 according to the positive half wave or the negative half waveguide pass state.
D.當該第三電感C3之跨壓大於該第三電容C3與該第四電容C4之總跨壓時,該第三二極體D3導通,使該第二電容C2與該第三電感L3產生與步驟C反向之電壓,並對該第三電容C3與該第四電容C4充能,使該第三電容C3與該第四電容C4之儲能持續依據正半波或負半波導通狀態通過該逆變電路40對該負載200釋能。 D. When the voltage across the third inductor C3 is greater than the total voltage across the third capacitor C3 and the fourth capacitor C4, the third diode D3 is turned on, so that the second capacitor C2 and the third inductor L3 Generating a voltage opposite to the step C, and charging the third capacitor C3 and the fourth capacitor C4, so that the energy storage of the third capacitor C3 and the fourth capacitor C4 continues according to the positive half wave or the negative half waveguide The state releases the load 200 through the inverter circuit 40.
另外,每執行一次步驟A至步驟D後,則表示完成一次週期之作動。是以,在該交交流電源轉換裝置持續作動之情況下,於步驟D後,便繼續重複執行步驟A至步驟D,直至該交交流電源轉換裝置停止作動。 In addition, after each step A to step D is performed, it indicates that the operation of one cycle is completed. Therefore, in the case where the AC power conversion device is continuously operated, after step D, the steps A to D are repeatedly performed until the AC power conversion device stops operating.
藉此,透過上述之該自動電荷抽放電路30之設計,於每次作動週期中,該第二電容C2的跨壓可自動地提供負電位,而導通該第三二極體D3,以使該第三二極體D3導通前後之整體電路結構改變,而可達到快速響應與低漣波輸出電壓之目的,同時可透過該電子開關SW之切換達到提升功率因數之目的。 Thereby, through the design of the automatic charge and discharge circuit 30 described above, the voltage across the second capacitor C2 can automatically provide a negative potential during each actuation cycle, and the third diode D3 is turned on, so that The overall circuit structure of the third diode D3 is changed before and after the conduction, and the purpose of fast response and low chopping output voltage can be achieved, and the switching of the electronic switch SW can achieve the purpose of improving the power factor.
另外,該第四二極體D4以及該第五二極體D5之設計更可有效地分別防止電路產生回流影響該主動式功因校正電路20以及該自動電荷抽放電路30之作動,進而使得整體電路更加地穩定,藉以提升該交交流電源轉換裝置能源轉換與抑制漣波之效果。當然,在實際實施上,即使不使用該第四二極體D4以及該第五二極體D5仍可達到增進電源轉換效率以及抑制漣波之目的。 In addition, the design of the fourth diode D4 and the fifth diode D5 can effectively prevent the circuit from generating reflow to affect the actuation of the active power correction circuit 20 and the automatic charge extraction circuit 30, thereby enabling The overall circuit is more stable, thereby improving the energy conversion and suppressing the chopping effect of the AC power conversion device. Of course, in actual implementation, even if the fourth diode D4 and the fifth diode D5 are not used, the purpose of improving power conversion efficiency and suppressing chopping can be achieved.
再者,本發明之交交流電源轉換裝置除適用於半橋式之逆變電路40外,亦適用於如圖6所示之全橋式之逆變電路50,而與前述不同之處在於全橋式之逆變電路50具有第一切換開關S3至第四切換開關S6,而第三電容C3與第四電容C4則視為一等效電容C5,而連接關係如下:該第一切換開關S3與該第三切換開關S5之一端相連接,而該第二切換開關S4與該第四切換開關S6的一端相連接。另外,該第一切換開關S3以及該第二切換開關S4之另一端與該等效電容C5、該第二電容C2與該第三電感L3的連接處連接,而該第三切換開關S5以及該第四切換開關S6之另一端則與該等效電容C5、該第三二極體D3之正極、該第二二極體D2之負極及該第二電感L2的連接處連接。 Furthermore, the AC power conversion device of the present invention is applicable to the full-bridge inverter circuit 50 as shown in FIG. 6 except for the half-bridge inverter circuit 40, and the difference is that The bridge type inverter circuit 50 has a first switch S3 to a fourth switch S6, and the third capacitor C3 and the fourth capacitor C4 are regarded as an equivalent capacitor C5, and the connection relationship is as follows: the first switch S3 Connected to one end of the third switch S5, and the second switch S4 is connected to one end of the fourth switch S6. In addition, the other end of the first switch S3 and the second switch S4 are connected to the connection of the equivalent capacitor C5, the second capacitor C2 and the third inductor L3, and the third switch S5 and the The other end of the fourth switch S6 is connected to the junction of the equivalent capacitor C5, the anode of the third diode D3, the cathode of the second diode D2, and the second inductor L2.
藉此,透過上述之結構設計,使用時便將該負載200之一端連接至該第一切換開關S3與該第三切換開關 S5的連接處,而另外一端則連接至該第二切換開關S4與該第四切換開關S6的連接處,並利用前述之電源切換方法,同樣能達到高功率因數、快速響應與低漣波輸出電壓之目的。 Thereby, through the above structural design, one end of the load 200 is connected to the first switch S3 and the third switch when in use. The connection of S5, and the other end is connected to the connection of the second switch S4 and the fourth switch S6, and the same power switching method can also achieve high power factor, fast response and low chopping output. The purpose of the voltage.
以上所述僅為本發明較佳可行實施例而已,且在電氣特性以及電路動作原理相同之情況下,前述各電路元件之設置位置以及數量、以及舉凡應用本發明說明書及申請專利範圍所為之等效電路變化,理應包含在本發明之專利範圍內。 The above description is only a preferred embodiment of the present invention, and in the case where the electrical characteristics and the circuit operation principle are the same, the position and the number of the above-mentioned circuit components are set, and the scope of the present invention and the scope of the patent application are applied. The effect of the circuit change is intended to be included in the scope of the patent of the present invention.
10‧‧‧整流電路 10‧‧‧Rectifier circuit
12‧‧‧正電端 12‧‧‧ Positive terminal
14‧‧‧負電端 14‧‧‧Negative terminal
20‧‧‧主動式功因校正電路 20‧‧‧Active power factor correction circuit
30‧‧‧自動電荷抽放電路 30‧‧‧Automatic charge pumping circuit
40‧‧‧逆變電路 40‧‧‧Inverter circuit
100‧‧‧交流電源 100‧‧‧AC power supply
200‧‧‧負載 200‧‧‧load
C1~C4‧‧‧電容 C1~C4‧‧‧ capacitor
L1~L3‧‧‧電感 L1~L3‧‧‧Inductance
D1~D5‧‧‧二極體 D1~D5‧‧‧ diode
SW‧‧‧電子開關 SW‧‧‧Electronic switch
S1、S2‧‧‧切換開關 S1, S2‧‧‧ switch
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