JP6688185B2 - Power supply - Google Patents

Description

  The present invention relates to a power supply device that transforms a power supply input voltage and supplies it to a load.

  Non-Patent Document 1 describes a power supply device that is mounted on an electric vehicle that operates by electric power supplied from an overhead wire and transforms an overhead wire voltage to supply the load to a load. In this power supply device, a serial-parallel continuous chopper (SPCH) is inserted in front of the inverter in order to stabilize the input voltage to the inverter as a measure against a sudden change in the overhead line voltage. .

Yui Mori, Masayuki Nakamura, Shingo Makishima, Keiichi Kamizono "Experimental verification of operation and basic characteristics at unbalanced output in series-parallel continuous switching chopper", 2014 IEEJ Industrial Application Conference, No. 1-22, pp. I-127-I-130, August 2014

  FIG. 11: is a figure which shows the structural example of the power supply device 10a provided with a serial / parallel continuous switching chopper.

  The power supply device 10a illustrated in FIG. 11 includes switching elements 101 to 104, capacitors 107, 111, 112, 121, inductors 108, 109, 110, 119, 120, single-phase inverters 113, 114, a transformer 115, 116, rectifiers 117 and 118, a three-phase inverter 122, and a controller 123. The switching elements 101 to 104, the inductors 109 and 110, and the capacitors 111 and 112 form an SPCH.

  Each of the switching elements 101 to 104 is configured by connecting a switching element such as an IGBT (Insulated Gate Bipolar Transistor) that can be turned on and off and a diode in antiparallel connection.

  The switching element 101 (first switching element) and the switching element 103 (third switching element) are connected in series to form a leg 105 (first leg). The switching element 102 (second switching element) and the switching element 104 (fourth switching element) are directly connected to each other to form a leg 106 (second leg).

  Between the end of the switching element 101 that is not connected to the switching element 103 and the end of the switching element 102 that is not connected to the switching element 104, the capacitor 107 and the series body including the inductor 108 and the DC power supply 20 are connected in parallel. Connected to. When the power supply device 10a is installed in an electric vehicle, the DC power supply 20 corresponds to an overhead line.

  The inductor 109 (first inductor) is connected between the end of the switching element 103 that is not connected to the switching element 101 and the connection point between the switching element 102 and the switching element 104.

  The inductor 110 (second inductor) is connected between the end of the switching element 104 that is not connected to the switching element 102 and the connection point between the switching element 101 and the switching element 103.

  Between the end of the switching element 101 that is not connected to the switching element 103 and the end of the switching element 103 that is not connected to the switching element 101, the capacitor 111 (first capacitor) and the single-phase inverter 113 (first Inverters) are connected in parallel. That is, the capacitor 111 and the single-phase inverter 113 are connected in parallel with the leg 105.

  The single-phase inverter 113 includes switching elements 113a to 113d. The switching element 113a and the switching element 113b are connected in series. The switching element 113c and the switching element 113d are connected in series. The end of the switching element 113a that is not connected to the switching element 113b and the end of the switching element 113c that is not connected to the switching element 113d are connected to one end of the capacitor 111. The end of the switching element 113b that is not connected to the switching element 113a and the end of the switching element 113d that is not connected to the switching element 113c are connected to the other end of the capacitor 111.

  The connection point between the switching element 113a and the switching element 113b is connected to one end of the primary winding of the transformer 115. The connection point between the switching element 113c and the switching element 113d is connected to the other end of the primary winding of the transformer 115.

  According to the single-phase inverter 113 having the above-described configuration, the voltage of the capacitor 111 (DC voltage) can be converted into an AC voltage and output to the transformer 115 by controlling the switching of the switching elements 113a to 113d.

  Between the end of the switching element 102 that is not connected to the switching element 104 and the end of the switching element 104 that is not connected to the switching element 102, the capacitor 112 (second capacitor) and the single-phase inverter 114 (second Inverters) are connected in parallel. That is, the capacitor 112 and the single-phase inverter 114 are connected in parallel with the leg 106.

  The single-phase inverter 114 includes switching elements 114a to 114d. The switching element 114a and the switching element 114b are connected in series. The switching element 114c and the switching element 114d are connected in series. The end of the switching element 114a that is not connected to the switching element 114b and the end of the switching element 114c that is not connected to the switching element 114d are connected to one end of the capacitor 112. The end of the switching element 114b that is not connected to the switching element 114a and the end of the switching element 114d that is not connected to the switching element 114c are connected to the other end of the capacitor 112.

  The connection point between the switching element 114a and the switching element 114b is connected to one end of the primary winding of the transformer 116. The connection point between the switching element 114c and the switching element 114d is connected to the other end of the primary winding of the transformer 116.

  According to the single-phase inverter 114 having the above-described configuration, by controlling the switching of the switching elements 114a to 114d, the voltage (DC voltage) of the capacitor 112 can be converted into an AC voltage and output to the transformer 116.

  The transformer 115 (first transformer) is a high-frequency isolation transformer whose primary side and secondary side are insulated. The transformer 115 has a primary winding connected to an output terminal of the single-phase inverter 113 (a connection point between the switching element 113a and the switching element 113b and a connection point between the switching element 113c and the switching element 113d), and a secondary winding. The wire is connected to the rectifier 117. The transformer 115 transforms the AC voltage output from the single-phase inverter 113 with a predetermined transformation ratio and outputs the transformed AC voltage to the rectifier 117.

  The transformer 116 (second transformer) is a high-frequency insulation transformer whose primary side and secondary side are insulated. The transformer 116 has a primary winding connected to an output terminal of the single-phase inverter 114 (a connection point between the switching element 114a and the switching element 114b and a connection point between the switching element 114c and the switching element 114d), and a secondary winding. The wire is connected to the rectifier 118. The transformer 116 transforms the AC voltage output from the single-phase inverter 114 with a predetermined transformation ratio and outputs the transformed AC voltage to the rectifier 118.

  The rectifier 117 (first rectifier) includes diodes 117a to 117d connected in a bridge shape, and rectifies and outputs the AC voltage output from the transformer 115.

  The rectifier 118 (second rectifier) includes diodes 118a to 118d connected in a bridge shape, and rectifies and outputs the AC voltage output from the transformer 116.

  One end of the inductor 119 (third inductor) is connected to the high voltage output terminal of the rectifier 117 (the cathode of the diode 117a and the cathode of the diode 117c).

  One end of the inductor 120 (fourth inductor) is connected to the high voltage output terminal of the rectifier 118 (the cathode of the diode 118a and the cathode of the diode 118c).

  One end of the capacitor 121 (third capacitor) is connected to the other end of the inductor 119 and the other end of the inductor 120, and the other end thereof is a low-voltage output terminal of the rectifier 117 (the anode of the diode 117b and the anode of the diode 117d), and It is connected to the low voltage output terminal of the rectifier 118 (the anode of the diode 118b and the anode of the diode 118d). The capacitor 121 is charged by the outputs of the rectifiers 117 and 118. The outputs of the rectifiers 117 and 118 are smoothed by the capacitor 121.

  The three-phase inverter 122 converts the voltage of the capacitor 121 (DC voltage) into a three-phase AC voltage and outputs it to a load (AC load). Note that FIG. 1 shows an example in which a three-phase inverter 122 is connected to the capacitor 121, the voltage of the capacitor 121 (DC voltage) is converted into an AC voltage by the three-phase inverter 122, and the AC voltage is supplied to a load (AC load). However, the present invention is not limited to this, and a DC load may be connected to the capacitor 121 and the voltage of the capacitor 121 may be supplied to the DC load.

  The three-phase inverter 122 includes switching elements 122a to 122f. The switching element 122a and the switching element 122b are connected in series. The switching element 122c and the switching element 122d are connected in series. The switching element 122e and the switching element 122f are connected in series.

  The end of the switching element 122 a that is not connected to the switching element 122 b, the end of the switching element 122 c that is not connected to the switching element 122 d, and the end that is not connected to the switching element 122 f of the switching element 122 e are one end of the capacitor 121. Connected with. The end of the switching element 122b that is not connected to the switching element 122a, the end of the switching element 122d that is not connected to the switching element 122c, and the end that is not connected to the switching element 122e of the switching element 122f are the capacitors 121 Connected with the end.

  A connection point between the switching element 122a and the switching element 122b, a connection point between the switching element 122c and the switching element 122d, and a connection point between the switching element 122e and the switching element 122f are connected to the load. By controlling the switching of the switching elements 122a to 122f, a three-phase AC voltage is output to the load from these connection points.

The control unit 123 controls the operation of each unit of the power supply device 10a described above. For example, the control unit 123 controls switching of the switching elements 101 to 104. The control unit 123 sets the conduction ratio _{D TR1, D TR2} of the single-phase inverters 113 and 114, depending on the conduction ratio _{D TR1, D TR2} set, switching element single-phase inverters 113 and 114 comprise The switching of 113a to 113d and 114a to 114d is controlled. By doing so, the voltages corresponding to the set _conduction ratios D _TR1 and D _TR2 are output from the single-phase inverters 113 and 114, respectively, and transformed into desired voltages by the transformers 115 and 116.

In the following, the power supply voltage of the DC power supply 20 is E, the voltage of the capacitor 107 is V _Cf , the current flowing in the inductor 109 is I _L1 , the current flowing in the inductor 110 is I _L2, and the voltage of the capacitor 111 is V _C1. , The voltage of the capacitor 112 is V _C2 , the current flowing through the inductor 119 is I _REC1, and the current flowing through the inductor 120 is I _REC2 . Further, the capacitance of the capacitor 107 is C _f , the capacitance of the capacitor 111 is C ₁ , the capacitance of the capacitor 112 is C ₂ , the inductance of the inductor 109 is L ₁ , the inductance of the inductor 110 is L _2, and the capacitance of the inductor 119 is The inductance is L _REC1 and the inductance of the inductor 120 is L _REC2 .

When L ₁ = L ₂ = L, C ₁ = C ₂ = C, and L _REC1 = L _REC2 are set, the control unit 123 controls the output voltage command value V _{C1_REF} of the voltage V _{C1 and} the output voltage command value V of the voltage V _{C2. Using C2_REF} , the duty ratio (conduction ratio) D ₁ of the switching element 101 and the duty ratio D ₂ of the switching element 102 are calculated according to the following equations (1) and (2).

The control unit 123 controls the switching of the switching elements 101 to 104 using the calculated duty ratios D ₁ and D ₂ as command values. The control unit 123 sets the conduction ratio _{D TR1, D TR2} of the single-phase inverters 113 and 114, in accordance with the conduction ratio _{D TR1, D TR2,} driving the single-phase inverters 113 and 114.

The flow rate is a value that changes in the range of 0 to 1. When the conduction ratios D ₁ and D ₂ become 0, the switching elements 101 and 102 are turned on and the switching elements 103 and 104 are turned off. In this state, the capacitors 111 and 112 are connected in parallel with the DC power supply 20. Hereinafter, this state is referred to as a parallel mode.

  In the power supply device 10a including the SPCH, in the parallel mode, a voltage difference may occur in the output voltage of the rectifiers 117 and 118 due to an overhead wire voltage drop, an error in the transformation ratio of the transformers 115 and 116, and the like. Due to this voltage difference, a circulating current flows through each inductor (inductors 109, 110, 119, 120), and an insulating rectification circuit including the single-phase inverter 113, the transformer 115, and the rectifier 117, the single-phase inverter 114, and the transformer. The share of the load power is unbalanced between the insulated rectifier circuit including the 116 and the rectifier 118. When such an imbalance in the sharing of load power occurs, adverse effects such as a decrease in efficiency of the power supply device 10a, a failure due to overcurrent, and a reduction in life occur.

  An object of the present invention is to solve the above-mentioned problems, to provide a power supply device capable of suppressing the generation of a circulating current and balancing load power distribution.

  In order to solve the above problems, in a power supply device according to the present invention, a first switching element and a third switching element are connected in series, and the first switching element and the third switching element of the first switching element are connected. A first leg whose end is connected to a DC power source, a second switching element and a fourth switching element are connected in series, and an end of the second switching element which is not connected to the fourth switching element Of a second leg connected to the DC power supply, an end of the third switching element not connected to the first switching element, a second switching element and a fourth switching element. A first inductor connected to a connection point; an end of the fourth switching element that is not connected to the second switching element; A second inductor connected between a switching element and a connection point of the third switching element; a first capacitor and a first inverter connected in parallel with the first leg; A second capacitor and a second inverter connected in parallel with the leg of the first inverter, a first transformer having a primary winding connected to the output terminal of the first inverter, and an output terminal of the second inverter. A second transformer connected to the primary winding, a first rectifier connected to the secondary winding of the first transformer, and a secondary winding connected to the second transformer A second rectifier, a third inductor having one end connected to the high voltage output terminal of the first rectifier, a fourth inductor having one end connected to the high voltage output terminal of the second rectifier, and one end The other end of the third inductor and the fourth A third capacitor connected to the other end of the inductor, the other end of which is connected to the low voltage output terminal of the first rectifier and the low voltage output terminal of the second rectifier, and a current flowing through the third inductor and A current difference from the current flowing through the fourth inductor is detected, and based on the detected current difference, a first voltage command value that commands the voltage of the first capacitor and a voltage of the second capacitor are commanded. A control unit that corrects the second voltage command value and controls switching of the first to fourth switching elements using the corrected first voltage command value and the corrected second voltage command value. , Is provided.

  Further, in order to solve the above-mentioned problems, in the power supply device according to the present invention, the control unit replaces the current difference between the current flowing through the third inductor and the current flowing through the fourth inductor, and replaces the first difference. A current difference between a current flowing through the inductor and a current flowing through the second inductor is detected, the first voltage command value and the second voltage command value are corrected based on the detected current difference, and after correction The switching of the first to fourth switching elements is controlled using the first voltage command value and the second voltage command value after correction.

  Further, in order to solve the above-mentioned problems, in a power supply device according to the present invention, a first switching element and a third switching element are connected in series, and the first switching element and the third switching element are connected. A first leg having an unconnected end connected to a DC power source, a second switching element and a fourth switching element are connected in series, and the second leg is connected to the fourth switching element of the second switching element. A second leg having an end that is not connected to the DC power supply, an end that is not connected to the first switching element of the third switching element, the second switching element and the fourth switching element A first inductor connected between the second switching element and a first inductor connected between the first inductor and a second switching element; A second inductor connected between a connection point between the first switching element and the third switching element, a first capacitor and a first inverter connected in parallel with the first leg, A second capacitor and a second inverter connected in parallel with the second leg; a first transformer having a primary winding connected to an output terminal of the first inverter; and a second inverter of the second inverter. A second transformer having a primary winding connected to the output terminal, a first rectifier connected to the secondary winding of the first transformer, and a secondary winding of the second transformer. A connected second rectifier, a third inductor having one end connected to the high voltage output terminal of the first rectifier, and a fourth inductor having one end connected to the high voltage output terminal of the second rectifier , One end of the third inductor and the other end of the third inductor A third capacitor connected to the other end of the inductor No. 4 and having the other end connected to the low voltage output terminal of the first rectifier and the low voltage output terminal of the second rectifier; and a current flowing through the third inductor. A current difference between the current flowing through the fourth inductor and the current flowing through the fourth inductor, and based on the detected current difference, a first current flow rate that is a current flow rate of the first inverter and a current flow rate of the second inverter. A second flow rate, which is a flow rate, is corrected, and the corrected first flow rate and the corrected second flow rate are used to control the first inverter and the second inverter. And a control unit for controlling.

  Further, in order to solve the above-mentioned problems, in the power supply device according to the present invention, the control unit uses the first difference instead of the current difference between the current flowing through the third inductor and the current flowing through the fourth inductor. Current difference between the current flowing through the inductor and the current flowing through the second inductor is detected, and the first conduction ratio and the second conduction ratio are corrected based on the detected current difference, The first inverter and the second inverter are controlled using the subsequent first conduction ratio and the corrected second conduction ratio.

  Further, in order to solve the above-mentioned problems, in the power supply device according to the present invention, the control unit calculates a current difference between a current flowing through the third inductor and a current flowing through the fourth inductor as the third inductor. It is desirable to perform detection using a detection result of a current sensor that detects a current flowing through the current sensor and a current sensor that detects a current flowing through the fourth inductor, or to perform detection using one current sensor.

  Further, in order to solve the above-mentioned problems, in the power supply device according to the present invention, the control unit calculates a current difference between a current flowing through the first inductor and a current flowing through the second inductor as the first inductor. It is desirable to perform detection using a detection result of a current sensor that detects a current flowing through the second inductor and a detection result of a current sensor that detects a current flowing through the second inductor, or to detect using a single current sensor.

  According to the power supply device of the present invention, it is possible to suppress the generation of the circulating current and balance the sharing of the load power.

It is a figure which shows the structural example of the power supply device which concerns on the 1st Embodiment of this invention. It is a figure which shows the structural example of the control part shown in FIG. It is a figure which shows the structural example of the control part which concerns on the 2nd Embodiment of this invention. It is a figure which shows the structural example of the control part which concerns on the 3rd Embodiment of this invention. It is a figure which shows the waveform example of the output voltage of the single phase inverter which concerns on the 3rd Embodiment of this invention. It is a figure which shows the structural example of the control part which concerns on the 4th Embodiment of this invention. Is a diagram showing an example of the waveform of the current I _L1, I _L2 when not applying the present invention. Is a diagram showing an example of the waveform of the current _{I REC1, I REC2} when not applying the present invention. It is a figure which shows the waveform example of electric current _IL1 and _IL2 at the time of applying this invention. Is a diagram showing an example of the waveform of the current _{I REC1, I REC2} in the case of applying the present invention. It is a figure which shows the structural example of the power supply device provided with SPCH.

  Hereinafter, embodiments of the present invention will be described.

(First embodiment)
FIG. 1 is a diagram showing a configuration example of a power supply device 10 according to the first embodiment of the present invention. In FIG. 1, the same components as those in FIG. 11 are designated by the same reference numerals and the description thereof will be omitted.

  The power supply device 10 shown in FIG. 1 is different from the power supply device 10a shown in FIG. 11 in that the control unit 123 is changed to the control unit 200.

The control unit 200 controls the overall operation of the power supply device 10. For example, the control unit 200 detects a current difference between the current I _REC1 flowing through the inductor 119 and the current I _REC2 flowing through the inductor 120. Control unit 200, based on the detected current difference, the output voltage command value _{V C1_REF} voltage _{V C1} (first voltage command value) and the output voltage command value _{V C2_REF} voltage _{V C2} (second voltage command value) The correction is _performed , and the switching of the switching elements 101 to 104 is controlled according to the corrected output voltage command value V ′ _{C1_REF} and the corrected output voltage command value V ′ _{C2_REF} . The control unit 200 also controls the switching of the switching elements 113a to 113d and 114a to 114d of the single-phase inverters 113 and 114.

  FIG. 2 is a diagram showing a configuration example of the control unit 200.

  The control unit 200 illustrated in FIG. 2 includes subtractors 201, 203 and 206, a low pass filter (LPF), a PI (Proportional Integral) control unit 204, an adder 205, and limiters 207 and 208. And a duty ratio calculation unit 209.

The subtractor 201 detects the current difference between the current I _REC1 flowing through the inductor 119 and the current I _REC2 flowing through the inductor 120, and outputs the detected current difference to the LPF 202. As a method of detecting the current difference between the current I _REC1 and the current I _REC2 , a method of detecting the current I _REC1 and the current I _REC2 by using different current sensors and detecting the current difference from the detection result. There is. Further, as another method, there is a method of detecting the current difference with one current sensor. For example, the connection line of the inductor 119 and the connection line of the inductor 120 are arranged close to each other so that a current flows in the opposite direction, and these wirings are penetrated through a magnetic ring having a gap to be interposed in the gap of the magnetic ring. There is a method of detecting a current difference by a magnetic semiconductor current sensor.

The LPF 202 removes a high frequency component of the current difference output from the subtractor 201 to generate a current difference I _ERR and outputs the current difference I _ERR to the subtractor 203.

The subtractor 203 receives zero as a command value, and outputs the difference between the command value and the current difference I _ERR output from the LPF 202 to the PI control unit 204.

The PI control unit 204 sets the output voltage so that the difference (difference between the command value (zero) and the current difference I _ERR ) output from the subtractor 203 becomes zero, that is, the current difference I _ERR is canceled. The circulating current suppressing voltage signal ΔV for correcting the command values V _{C1_REF} and V _{C2_REF} is generated and output to the adder 205 and the subtractor 206.

The adder 205 adds the output voltage command value V _{C1_REF} and the circulating current suppressing voltage signal ΔV output from the PI control unit 204, and outputs the result to the limiter 207.

The subtractor 206 subtracts the circulating current suppressing voltage signal ΔV output from the PI control unit 204 from the output voltage command value V _{C2_REF} and outputs the subtracted voltage signal ΔV to the limiter 208.

The limiter 207 _limits the output (V _{C1_REF} + ΔV) of the adder 205 with a predetermined upper limit value and a lower limit value, and outputs the corrected output voltage command value V ′ _{C1_REF} to the duty ratio calculation unit 209.

The limiter 208 _limits the output ( _{VC2_REF-ΔV} ) of the subtractor 206 with a predetermined upper limit value and a predetermined lower limit value, and outputs it as a corrected output voltage command value _{V'C2_REF} to the duty ratio calculation unit 209.

By _limiting the upper limit value and the lower limit value of the output voltage command values V ′ _{C1_REF} and V ′ _{C2_REF} by the limiters 207 and 208, stable control becomes possible.

Duty ratio calculation unit 209, based on the _{C2_REF} 'output voltage command value V of the corrected output from _{C1_REF} and limiter 208' the output voltage command value V of the corrected output from the limiter 207, the duty of the switching elements 101 and 102 Ratios (flow rate) D ′ ₁ and D ′ ₂ are calculated. Specifically, the duty ratio calculation unit 209 calculates the conduction ratios D ′ ₁ and D ′ ₂ according to the following equations (3) and (4).

By controlling the switching of the switching elements 101 to 104 according to the calculated conduction ratios D ′ ₁ and D ′ ₂ , the circulation current suppression generated so that the voltage V _C1 and the voltage V _C2 cancel the current difference I _ERR. The value takes the working voltage signal ΔV into consideration. As a result, the currents output through the conversion into AC voltage by the single-phase inverters 113, 114, the transformation by the transformers 115, 116 and the rectification by the rectifiers 117, 118 become equal, so that the generation of circulating current is prevented and the single-phase current is prevented. The insulation rectification circuit configured by the inverter 113, the transformer 115, and the rectifier 117 and the insulation rectification circuit configured by the single-phase inverter 114, the transformer 116, and the rectifier 118 can balance load power sharing. it can.

As described above, according to the present embodiment, the power supply device 10 detects the current difference I _ERR between the current I _REC1 flowing through the inductor 119 and the current I _REC2 flowing through the inductor 120, and based on the detected current difference I _ERR , the capacitor the 111 output voltage command value _{V C2_REF} of the output voltage command value _{V C1_REF} and capacitor 112 corrects the control unit 200 for controlling the switching of the switching elements 101 to 104 after correction of the output voltage command value V _{'C1_REF,} V' according _{C2_REF} Equipped with.

Based on the current difference I _ERR between the current I _REC1 and the current I _REC2 , the output voltage command values V _{C1_REF} and V _{C2_REF} are corrected so that the circulating current is not generated, and the corrected output voltage command values V ′ _{C1_REF} and V ′ _{C2_REF.} By controlling the switching of the switching elements 101 to 104 in accordance with the above, it is possible to prevent the generation of the circulating current and balance the sharing of the load power.

(Second embodiment)
FIG. 3 is a diagram showing a configuration example of the control unit 200A according to the second embodiment of the present invention. In FIG. 3, the same components as those in FIG. 2 are designated by the same reference numerals and the description thereof will be omitted. Note that the power supply device according to the present embodiment is different from the power supply device 10 according to the first embodiment in that the control unit 200 is changed to a control unit 200A, and other configurations are the same, so description will be made. Is omitted.

  The control unit 200A shown in FIG. 3 is different from the control unit 200 shown in FIG. 2 in that the subtractor 201 is changed to a subtractor 201A.

The subtractor 201A detects the current difference between the current I _L1 flowing through the inductor 109 and the current I _L2 flowing through the inductor 110, and outputs the detected current difference to the LPF 202. Note that the current difference between the current I _L1 and the current I _L2 may be detected by using two different current sensors as in the case of the current difference between the current I _REC1 and the current I _REC2 , or one current sensor. May be used for detection.

Hereinafter, similar to the first embodiment, the circulating current suppressing voltage signal ΔV is generated so that the current difference between the current I _L1 and the current I _L2 becomes zero. Then, the output voltage command values V _{C1_REF} and V _{C2_REF} are corrected based on the circulating current suppression voltage signal ΔV, and the switching of the switching elements 101 to 104 is controlled according to the corrected output voltage command values V ′ _{C1_REF} and V ′ _{C2_REF.} It

In this way, by detecting the current difference between the current I _L1 and the current I _L2 , it is possible to prevent the generation of the circulating current and balance the distribution of the load power, as in the first embodiment. .

(Third Embodiment)
FIG. 4 is a diagram showing a configuration example of the control unit 200B according to the third embodiment of the present invention. 4, the same components as those in FIG. 2 are designated by the same reference numerals, and the description thereof will be omitted. It should be noted that the power supply device according to the present embodiment is different from the power supply device 10 according to the first embodiment in that the control unit 200 is changed to the control unit 200B, and other configurations are the same, so the description will be made. Is omitted.

  The control unit 200B illustrated in FIG. 4 includes a PI control unit 204, an adder 205, a subtractor 206, and limiters 207 and 208, respectively, as compared with the control unit 200 illustrated in FIG. The difference is that the subtractor 206B and the limiters 207B and 208B are changed, and the duty ratio calculation unit 209 is deleted.

The PI control unit 204B sets the single phase so that the difference (difference between the command value (zero) and the current difference I _ERR ) output from the subtractor 203 becomes zero, that is, the current difference I _ERR is canceled. The circulating current suppressing duty factor signal ΔD for correcting the _duty factor D _TR1 (first duty factor) of the inverter 113 and the duty factor D _TR2 (second duty factor) of the single-phase inverter 114 is used. It is generated and output to the adder 205B and the subtractor 206B. In the following, D _TR1 = D _TR2 = D _TR .

The adder 205B adds the conduction ratio D _TR and the circulation current suppressing conduction ratio signal ΔD output from the PI control unit 204B, and outputs the result to the limiter 207B.

The subtractor 206B subtracts the circulating current suppressing conduction ratio signal ΔD output from the PI control unit 204B from the conduction ratio D _TR , and outputs it to the limiter 208B.

The limiter 207B limits the output (D _TR + ΔV) of the adder 205 with a predetermined upper limit value and a lower limit value, and outputs it as the corrected _conduction ratio D ′ _TR1 of the single-phase inverter 113.

The limiter 208B limits the output (D _TR −ΔV) of the subtractor 206 to a predetermined upper limit value and a lower limit value, and outputs it as the corrected _conduction ratio D ′ _TR2 of the single-phase inverter 114.

By limiting the upper limit value and the lower limit value of the _conduction ratios D ′ _TR1 and D ′ _TR2 of the single-phase inverters 113 and 114 by the limiters 207B and 208B, stable control becomes possible.

The operations of the single-phase inverters 113 and 114 are controlled according to the corrected _conduction ratios D ′ _TR1 and D ′ _TR2 . Specifically, as shown in FIG. 5, the output voltage of the single-phase inverter 113 has a predetermined voltage value during the period corresponding to the _conduction ratio D ′ _TR1 in the predetermined control period T, and the other period. Becomes zero. Further, the output voltage of the single-phase inverter 114 has a predetermined voltage value in a period corresponding to the _conduction ratio D ′ _TR2 in the predetermined control period T, and becomes zero in other periods. Then, the output voltages of the single-phase inverters 113 and 114 are respectively transformed by the transformers 115 and 116 at a predetermined transformation ratio, so that the output voltages of the transformers 115 and 116 are made coincident with each other and the generation of the circulating current is prevented. You can

As described above, in the present embodiment, the conduction ratios D _TR1 and D _TR2 of the single-phase inverters 113 and 114 are corrected and corrected so that the current difference I _ERR between the current I _REC1 and the current I _REC2 becomes zero. The single-phase inverters 113 and 114 are controlled according to the subsequent _conduction ratios D ′ _TR1 and D ′ _TR2 . As a result, the currents output through the transformers 115 and 116 and the rectifiers 117 and 118 are equalized, so that the circulating current is prevented from being generated and the load power is balanced as in the first embodiment. Can be realized.

(Fourth Embodiment)
FIG. 6 is a diagram showing a configuration example of a control unit 200C according to the fourth embodiment of the present invention. 6, the same components as those in FIG. 4 are designated by the same reference numerals, and the description thereof will be omitted. Note that the power supply device according to the present embodiment is different from the power supply device according to the third embodiment in that the control unit 200B is changed to the control unit 200C, and the other configurations are the same, so the description will be made. Omit it.

  The control unit 200C shown in FIG. 6 is different from the control unit 200B shown in FIG. 4 in that the subtractor 201 is replaced with a subtractor 201C.

The subtractor 201C detects the current difference between the current I _L1 flowing through the inductor 109 and the current I _L2 flowing through the inductor 110, and outputs the detected current difference to the LPF 202. Note that the current difference between the current I _L1 and the current I _L2 may be detected by using two different current sensors as in the case of the current difference between the current I _REC1 and the current I _REC2 , or one current sensor. May be used for detection.

Hereinafter, similarly to the third embodiment, the circulating current suppressing conduction ratio signal ΔD is generated so that the current difference between the current I _L1 and the current I _L2 becomes zero. Then, the conduction ratios D _TR1 and D _{TR2 of} the single-phase inverters 113 and 114 are corrected based on the generated circulation current suppression conduction ratio signal ΔD, and the corrected _conduction ratios D ′ _TR1 and D ′ _{TR2 are obtained.} , The single-phase inverters 113 and 114 are controlled.

In this way, the current difference between the current I _L1 and the current I _L2 is detected, and the conduction ratios D _TR1 and D _TR2 of the single-phase inverters 113 and 114 are corrected based on the detected current difference. As in the above embodiment, it is possible to prevent the generation of a circulating current and balance the sharing of load power.

The effects of the present invention will be described below by taking specific values as examples. In the following, E = V _Cf = 220V, L ₁ = L ₂ = 0.003H, C ₁ = C ₂ = 0.001F, C _f = 0.001F, L _f = 0.003H, L _REC1 = L _REC2 = It is set to 0.003H. Further, it is _assumed that D _TR = 1, V _{C1_REF} = V _{C2_REF} = 220V, the transformation ratio of the transformers 115 and 116 is 1, and the power of the three-phase inverter is 2 kW.

In order to simulate an error in a circuit wire or a transformer, a circuit equivalent resistance of 0.1Ω or 0.2Ω is inserted in each of the inductors 119 and 120. Due to this different resistance, as shown in FIG. 7, the current I _L1 and the current I _L2 flowing through both inductors (inductors 109 and 110) in the SPCH are different. Further, as shown in FIG. 8, the current I _REC1 and the current I _REC2 flowing through both inductors (inductors 119 and 120) connected to the rectifiers 117 and 118 are different. The current difference between the current I _L1 and the current I _L2 and the current difference between the current I _REC1 and the current I _REC2 correspond to the circulating current.

FIG. 9 is a diagram showing a current I _L1 and a current I _L2 obtained by controlling switching of the switching elements 101 to 104 by the control unit 200 according to the first embodiment of the present invention. Further, FIG. 10 is a diagram showing a current I _REC1 and a current I _REC2 obtained by controlling switching of the switching elements 101 to 104 by the control unit 200.

As shown in FIG. 9, according to the present invention, the current I _L1 and the current I _L2 are equal. Further, as shown in FIG. 10, according to the present invention, the current I _REC1 and the current I _REC2 are equal. Therefore, it can be seen that the circulating current is suppressed. Even when the second to fourth embodiments described above were used, the circulating current could be suppressed as in the first embodiment.

  Although the present invention has been described based on the drawings and the embodiments, it should be noted that those skilled in the art can easily make various variations or modifications based on the present disclosure. Therefore, it should be noted that these variations or modifications are included in the scope of the present invention. For example, the functions included in each block can be rearranged so as not to logically contradict each other, and a plurality of blocks can be combined into one or divided.

10 power supply device 20 DC power supply 101-104, 131a-131d, 141a-141d, 122a-122f switching element 105,106 leg 107,111,112,121 capacitor 108,109,110,119,120 inductor 113,114 single phase Inverter 115,116 Transformer 117,118 Rectifier 117a-117d, 118a-118d Diode 122 Three-phase inverter 200,200A, 200B, 200C Control part 201,201A, 201C, 203,206,206B Subtractor 202 Low-pass filter 204 , 204B PI control unit 205, 205B Adder 207, 208, 207B, 208B Limiter 209 Duty ratio calculation unit

Claims (6)

A first leg in which a first switching element and a third switching element are connected in series, and an end of the first switching element that is not connected to the third switching element is connected to a DC power supply;
A second leg in which a second switching element and a fourth switching element are connected in series, and an end of the second switching element that is not connected to the fourth switching element is connected to the DC power supply;
A first inductor connected between an end of the third switching element that is not connected to the first switching element and a connection point between the second switching element and the fourth switching element; ,
A second inductor connected between an end of the fourth switching element that is not connected to the second switching element and a connection point between the first switching element and the third switching element; ,
A first capacitor and a first inverter connected in parallel with the first leg;
A second capacitor and a second inverter connected in parallel with the second leg;
A first transformer having a primary winding connected to an output terminal of the first inverter;
A second transformer having a primary winding connected to the output terminal of the second inverter;
A first rectifier connected to the secondary winding of the first transformer;
A second rectifier connected to the secondary winding of the second transformer;
A third inductor whose one end is connected to the high voltage output terminal of the first rectifier;
A fourth inductor, one end of which is connected to the high voltage output terminal of the second rectifier,
One end connected to the other end of the third inductor and the other end of the fourth inductor, and the other end connected to the low-voltage output terminal of the first rectifier and the low-voltage output terminal of the second rectifier; 3 capacitors,
A first voltage command value that detects a current difference between a current flowing through the third inductor and a current flowing through the fourth inductor, and commands a voltage of the first capacitor based on the detected current difference, and The second voltage command value that commands the voltage of the second capacitor is corrected, and the first voltage command value after correction and the second voltage command value after correction are used, and the first to fourth values are corrected. A power supply device comprising: a control unit that controls switching of a switching element. The power supply device according to claim 1,
The control unit replaces the current difference between the current flowing through the third inductor and the current flowing through the fourth inductor with the difference between the current flowing through the first inductor and the current flowing through the second inductor. Is detected, the first voltage command value and the second voltage command value are corrected based on the detected current difference, and the corrected first voltage command value and the corrected second voltage command value are detected. Is used to control switching of the first to fourth switching elements. A first leg in which a first switching element and a third switching element are connected in series, and an end of the first switching element that is not connected to the third switching element is connected to a DC power supply;
A second leg in which a second switching element and a fourth switching element are connected in series, and an end of the second switching element that is not connected to the fourth switching element is connected to the DC power supply;
A first inductor connected between an end of the third switching element that is not connected to the first switching element and a connection point between the second switching element and the fourth switching element; ,
A second inductor connected between an end of the fourth switching element that is not connected to the second switching element and a connection point between the first switching element and the third switching element; ,
A first capacitor and a first inverter connected in parallel with the first leg;
A second capacitor and a second inverter connected in parallel with the second leg;
A first transformer having a primary winding connected to an output terminal of the first inverter;
A second transformer having a primary winding connected to the output terminal of the second inverter;
A first rectifier connected to the secondary winding of the first transformer;
A second rectifier connected to the secondary winding of the second transformer;
A third inductor whose one end is connected to the high voltage output terminal of the first rectifier;
A fourth inductor, one end of which is connected to the high voltage output terminal of the second rectifier,
One end connected to the other end of the third inductor and the other end of the fourth inductor, and the other end connected to the low-voltage output terminal of the first rectifier and the low-voltage output terminal of the second rectifier; 3 capacitors,
A current difference between a current flowing through the third inductor and a current flowing through the fourth inductor is detected, and based on the detected current difference, a first current flow rate that is a current flow rate of the first inverter. And a second conduction ratio, which is a conduction ratio of the second inverter, is corrected, and the corrected first conduction ratio and the corrected second conduction ratio are used to calculate the first inverter. And a control unit that controls the second inverter. The power supply device according to claim 3,
The control unit, instead of the current difference between the current flowing through the third inductor and the current flowing through the fourth inductor, the current flowing between the current flowing through the first inductor and the current flowing through the second inductor. It detects the difference, based on the current difference the detected second passage before Symbol a first duty ratio and the second duty ratio is corrected, after the first duty ratio after the correction and the correction A power supply device, wherein the first inverter and the second inverter are controlled using a flow rate. The power supply device according to claim 1 or 3,
The control unit detects a current difference between a current flowing through the third inductor and a current flowing through the fourth inductor, a current sensor for detecting a current flowing through the third inductor, and a fourth inductor. A power supply device characterized by detecting using a detection result of a current sensor that detects a flowing current, or by using one current sensor. The power supply device according to claim 2 or 4,
The control unit detects a current difference between a current flowing through the first inductor and a current flowing through the second inductor, a current sensor that detects a current flowing through the first inductor, and the second inductor. A power supply device characterized by detecting using a detection result of a current sensor that detects a flowing current, or by using one current sensor.

Images