JP2021132432A - Power supply device, control device, control method, and program - Google Patents

Abstract

To protect a load side against overcurrent when a short circuit occurs in the load side.SOLUTION: A power supply device includes a bidirectional DC/DC converter having a first end to receive an input of power and a second end to output DC power, and having a capacitor provided between two terminals of the second end, a detection unit that detects a short circuit in an output destination of the DC power supplied from the second end, and a control unit that controls the bidirectional DC/DC converter to send power from the first end side to the second end side when the detection unit has not detected the short circuit, and that controls the bidirectional DC/DC converter to send power from the second end side to the first end side when the detection unit has detected the short circuit.SELECTED DRAWING: Figure 2

Description

The present invention relates to power supplies, control devices, control methods and programs.

Several techniques have been proposed for overcurrent prevention for power supplies. For example, the power supply device (AC / DC converter) described in Patent Document 1 turns off the switching transistor to which the control circuit is connected when an overcurrent is detected in the DC / DC converter inside the power supply device (AC / DC converter). Protects the control circuit from overcurrent.

Japanese Patent No. 6410554

When a short circuit occurs on the load side connected to the power supply device, it is preferable that the load side can be protected from overcurrent.

It is an object of the present disclosure to provide a power supply device, a control device, a control method, and a program capable of protecting the load side from overcurrent in the event of a short circuit on the load side.

The power supply device according to the present disclosure is a bidirectional DC having a first end for receiving a power input and a second end for outputting a DC power, and a capacitor is provided between the two terminals of the second end. A / DC converter, a detection unit that detects a short circuit at the output destination of DC power from the second end, and when the detection unit does not detect the short circuit, from the first end side to the second end side. The bidirectional DC / DC converter is controlled so as to transmit power, and when the detection unit detects the short circuit, the bidirectional DC / DC is transmitted from the second end side to the first end side. It includes a control unit that controls the converter.

The control device according to the present disclosure is a bidirectional DC having a first end that receives power input and a second end that outputs DC power, and a capacitor is provided between the two terminals of the second end. When a short circuit is not detected at the output destination of the DC power from the second end, the / DC converter is controlled to transmit power from the first end side to the second end side, and the short circuit is detected. In this case, a control unit for controlling power transmission from the second end side to the first end side is provided.

The control method according to the present disclosure is a bidirectional DC having a first end that receives power input and a second end that outputs DC power, and a capacitor is provided between the two terminals of the second end. When a short circuit is not detected at the output destination of the DC power from the second end, the / DC converter is controlled to transmit power from the first end side to the second end side, and the short circuit is detected. In this case, it includes controlling the power transmission from the second end side to the first end side.

The program according to the present disclosure has a first end that receives a power input and a second end that outputs a DC power, and a bidirectional DC / DC converter is provided between the two terminals of the second end. If the computer that controls the DC converter does not detect a short circuit at the output destination of the DC power from the second end, the bidirectional DC / This is a program for controlling a DC converter and controlling the bidirectional DC / DC converter so as to transmit power from the second end side to the first end side when the short circuit is detected.

According to the power supply unit, control device, control method and program of the present disclosure, the load side can be protected from overcurrent.

It is a schematic block diagram which shows the structural example of the electric power system which concerns on 1st Embodiment of this disclosure. It is a figure which shows a more specific example of the structure of the power supply circuit which concerns on 1st Embodiment of this disclosure. It is a figure which shows the DAB circuit configuration example which concerns on 1st Embodiment of this disclosure. It is a figure which shows the 1st example of the timing which the control part which concerns on 1st Embodiment of this disclosure turns on and off each of the elements. It is a figure which shows the 2nd example of the timing which the control part which concerns on 1st Embodiment of this disclosure turns on and off each of the elements. It is a block diagram which shows the example of the processing flow by the control part which concerns on 1st Embodiment of this disclosure. It is a figure which shows the structural example of the control part which concerns on 1st Embodiment of this disclosure. It is a flowchart which shows an example of the processing procedure which the control part which concerns on 1st Embodiment of this disclosure controls a power supply circuit. It is a schematic block diagram which shows the structural example of the electric power system which concerns on 2nd Embodiment of this disclosure. It is a schematic block diagram which shows the structure of the computer which concerns on at least one Embodiment.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings. In each figure, the same reference numerals are used for the same or corresponding configurations, and the description thereof will be omitted as appropriate.
<First Embodiment>
(Example of power system configuration)
FIG. 1 is a schematic block diagram showing a configuration example of an electric power system according to the first embodiment of the present disclosure. The electric power system 1 shown in FIG. 1 includes a generator 11, a power supply device 20, a wiring path 51, and a load 52. The power supply device 20 includes a power supply circuit 30 and a control unit 40. The power supply circuit 30 includes a circuit breaker 31, a rectifier circuit 32, a bidirectional DC / DC converter 33, and a detection unit 34.

Further, in FIG. 1, the first end E10 and the second end E20 of the bidirectional DC / DC converter 33 are shown. The first end E10 is an end where the bidirectional DC / DC converter 33 is electrically connected to the rectifier circuit 32. The second end E20 is an end where the bidirectional DC / DC converter 33 is electrically connected to the load 52 via the wiring path 51.

The electric power system 1 is a system that uses electric power. In the electric power system 1, the load 52 consumes the electric power generated by the generator 11.
The generator 11 generates AC power. The AC power output by the generator 11 is input to the power supply device 20.
However, the power supply device 20 may receive an input of DC power, such as receiving power from a storage battery. In this case, the power supply device 20 does not have to include the rectifier circuit 32.

The power supply device 20 performs AC / DC conversion and transformation on the AC power input from the generator 11. The DC power output by the power supply device 20 is supplied to the load 52 via the wiring path 51.
Further, when the power supply device 20 detects a short circuit at the output destination of the DC power from the power supply device 20, the power supply device 20 operates so as to take in the power (particularly the current). In the example of FIG. 1, the wiring path 51 and the load 52 correspond to the example of the output destination of the DC power from the power supply device 20. The output destination of DC power from the power supply device 20 is also referred to as a load side.

When a short circuit on the load side is detected, the power supply device 20 takes in a current, so that it is possible to reduce the possibility that an overcurrent flows on the load side and damages the wiring, equipment, or the like.
The power supply device 20 can be applied to various applications involving connection to a DC system, such as a ship to which a DC system is applied and a system interconnection such as a DC interconnection offshore wind turbine system.

The power supply circuit 30 performs AC / DC conversion and transformation under the control of the control unit 40.
Further, when the power supply circuit 30 detects a short circuit on the load side, the power supply circuit 30 operates so as to take in electric power according to the control of the control unit 40.
The circuit breaker 31 cuts off the input of electric power from the generator 11 to the power supply circuit 30 when an abnormality occurs. In particular, the circuit breaker 31 cuts off the input of electric power from the generator 11 to the power supply circuit 30 when a short circuit on the load side is detected. The circuit breaker 31 may be configured as a part of the power supply circuit 30, or may be configured outside the power supply circuit 30.
In the following, a case where the circuit breaker 31 operates under the control of the control unit 40 will be described as an example. However, the circuit breaker 31 may be operated autonomously.

The rectifier circuit 32 converts AC power from the generator 11 into DC power. In the following, a case where the rectifier circuit 32 is an active rectifier circuit and operates under the control of the control unit 40 will be described as an example. However, the rectifier circuit 32 is not limited to a specific type of rectifier circuit. For example, a passive rectifier circuit may be used as the rectifier circuit 32.

The bidirectional DC / DC converter 33 transforms DC power according to the control of the control unit 40. Further, the bidirectional DC / DC converter 33 switches the power transmission direction according to the control of the control unit 40. The power transmission of the bidirectional DC / DC converter 33 referred to here is by receiving an input of electric power from one end of the first end E10 and the second end E20 and outputting the electric power from the other end. be.

Normally, the bidirectional DC / DC converter 33 transforms the DC power from the rectifier circuit 32 according to the control of the control unit 40. The DC power transformed by the bidirectional DC / DC converter 33 is supplied to the load 52 as output power from the power supply device 20. Therefore, normally, the bidirectional DC / DC converter 33 transmits power from the first end E10 side to the second end E20 side.
On the other hand, when a short circuit on the load side is detected, the bidirectional DC / DC converter 33 switches the power transmission direction according to the control of the control unit 40. At the time of short circuit detection, the bidirectional DC / DC converter 33 transmits power from the second end E20 side to the first end E10 side.
The normal time referred to here is when a short circuit on the load side has not been detected. The short circuit detection here is when a short circuit on the load side is detected.

In the power supply device 20, power transmission is normally performed in one direction from the first end E10 side to the second end E20 side, but by using a bidirectional DC / DC converter as the bidirectional DC / DC converter 33, a load is obtained. When a short circuit occurs on the side, power can be transmitted from the second end E20 side to the first end E10 side, contrary to the normal case. The bidirectional DC / DC converter 33 transmitting power from the second end E20 side to the first end E10 side corresponds to the power supply device 20 taking in electric power (particularly current), and as described above, to the load side. It is possible to reduce the possibility that an overcurrent will flow and damage the wiring or equipment.

The detection unit 34 detects a short circuit on the load side (the output destination of the DC power from the second end E20). The detection unit 34 notifies the control unit 40 of whether or not a short circuit has been detected. For example, when the detection unit 34 measures the output current from the power supply device 20 to the wiring path 51 and determines that the current value exceeds a predetermined threshold value, it determines that a short circuit has occurred on the load side. It may be. Then, when the detection unit 34 detects a short circuit on the load side, a signal indicating that the short circuit has been detected may be output to the control unit 40.
The detection unit 34 may be configured as a part of the power supply circuit 30, or may be configured outside the power supply circuit 30.

The control unit 40 controls each unit of the power supply circuit 30. In particular, the control unit 40 normally controls the rectifier circuit 32 to convert AC power into DC power. Further, the control unit 40 controls the bidirectional DC / DC converter 33 during normal operation (when the detection unit 34 does not detect a short circuit on the load side, from the first end E10 side to the second end E20 side. DC power is transformed and transmitted.

When the detection unit 34 detects a short circuit on the load side, the control unit 40 opens (turns off) the circuit breaker 31 to cut off the DC power from the generator 11 to the power supply device 20. When the detection unit 34 detects a short circuit on the load side, the control unit 40 controls the bidirectional DC / DC converter 33 to transform the DC power from the second end E20 side to the first end E10 side. Send power.

The power supply device 20 including the control unit 40 corresponds to an example of the control device. Alternatively, the control unit 40 may be configured as a control device separate from the power supply circuit 30.

The wiring path 51 electrically connects the bidirectional DC / DC converter 33 and the load 52, and transmits the DC power output by the bidirectional DC / DC converter 33 to the load 52. The wiring path 51 is configured by using, for example, an electric wire.
The load 52 consumes power from the power supply device 20. The configuration of the load 52 is not limited to a specific configuration. For example, various devices that consume DC power can be used as the load 52. Further, the load 52 may be configured to include only one device that consumes DC power, or may be configured to include a plurality of devices.

(Example of power supply circuit configuration)
FIG. 2 is a diagram showing a more specific example of the configuration of the power supply circuit 30. FIG. 2 shows the generator 11, the power supply circuit 30, the control unit 40, the wiring path 51, and the load 52 of the power system 1. Further, in FIG. 2, the circuit breaker 31, the rectifier circuit 32, the bidirectional DC / DC converter 33, and the detection unit 34 of the power supply circuit 30 are shown.
Further, FIG. 2 shows an example in which three-phase AC power is input from the generator 11 to the power supply device 20 and the rectifier circuit 32 performs AC / DC conversion in an active bridge circuit.

However, neither the type of the generator 11 nor the rectifier circuit 32 is limited to a specific type. For example, the number of phases of AC power output by the generator 11 is not limited to three phases, and may be two phases or four or more phases. Further, the rectifier circuit 32 may be one that corresponds to the ratings of the number of phases, the current, the voltage, and the like of the output power of the generator 11.
Further, as described above, the power supply device 20 may be supplied with DC power. In that case, the power supply device 20 does not have to include the rectifier circuit 32.

Further, FIG. 2 shows an example in which the bidirectional DC / DC converter 33 is configured by using a DAB (Dual Active Bridge) type bidirectional DC / DC converter. The bidirectional DC / DC converter 33 in this case is referred to as a DAB circuit 33a. Each part of the DAB circuit 33a will be described later with reference to FIG. As the DAB circuit 33a, a DAB circuit having a known configuration can be used.

Further, in FIG. 2, terminals constituting the end portion of the DAB circuit 33a are shown. Specifically, the first terminal T11 and the second terminal T12 form the first end E10. The third terminal T21 and the fourth terminal T22 form the second end E20. The first terminal T11 and the third terminal T21 are positive terminals, respectively. The second terminal T12 and the fourth terminal T22 are terminals on the minus side (earth side or ground side), respectively.

The positive output terminal of the rectifier circuit 32 and the first terminal T11 are electrically connected, and the negative output terminal of the rectifier circuit 32 and the second terminal T12 are electrically connected. Further, the electric wires of the wiring path 51 are connected to each of the third terminal T21 and the fourth terminal T22, and each electric wire is connected to the load 52. When the load 52 has a positive side and a negative side, the third terminal T21 and the positive side of the load 52 are electrically connected by the wiring path 51, and the fourth terminal T22 and the negative side of the load 52 are connected to each other. , Electrically connected by a wiring path 51.

Further, FIG. 2 shows an example in which the detection unit 34 is configured by using the overcurrent detection sensor. The detection unit 34 in this case is referred to as an overcurrent detection sensor 34a.
In the example of FIG. 2, the overcurrent detection sensor 34a includes a current transformer provided at the position of the third terminal T21 of the DAB circuit 33a, and measures the output current from the DAB circuit 33a. The output current from the DAB circuit 33a corresponds to an example of the output current from the power supply device 20 to the wiring path 51.

The overcurrent detection sensor 34a compares the measured current value with a predetermined threshold value, and when it is determined that the current value exceeds the threshold value, it determines that a short circuit has occurred on the load side. For example, when a short circuit on the load side is detected, the 34a outputs a signal indicating that the short circuit has been detected to the control unit 40.
Further, in FIG. 2, the resistance 14R of the wiring path 51 and the inductance 14L are schematically shown.

(Example of DAB circuit configuration)
FIG. 3 is a diagram showing a configuration example of the DAB circuit 33a. The DAB circuit 33a shown in FIG. 3 includes a first capacitor 111, a first bridge circuit 112, a transformer 113, a second bridge circuit 114, and a second capacitor 115. The first bridge circuit 112 and the second bridge circuit 114 are each composed of four elements 120.
The side of the transformer 113 connected to the first bridge circuit 112 is referred to as the primary side of the transformer 113. The side of the transformer 113 connected to the second bridge circuit 114 is referred to as the secondary side of the transformer 113.

Each of the elements 120 is configured by connecting a switch by a transistor, a diode, and a capacitor in parallel. When the switch is off (OFF, open), the element 120 conducts current only in the direction of the diode. On the other hand, when the switch is ON (ON, closed), the element 120 conducts current in any direction. The four elements 120 included in the first bridge circuit 112 are referred to as a first element 121, a second element 122, a third element 123, and a fourth element 124. The four elements 120 included in the second bridge circuit 114 are referred to as a fifth element 125, a sixth element 126, a seventh element 127, and an eighth element 128.

The control unit 40 controls the on and off of the switch of the element 120 of the first bridge circuit 112 and the second bridge circuit 114, so that the DAB circuit 33a has the first end E10 side to the second end E20 side, or the first. Power is transmitted in any one direction from the two-end E20 side to the first end E10 side. Turning on or off the switch of the element 120 is also referred to as turning on or off the element 120. Controlling the on / off of the element 120 is also referred to as controlling the switching of the element 120.

Normally, the DAB circuit 33a transmits power from the first end E10 side to the second end E20 side. In this case, a current flows from the first bridge circuit 112 to the primary side of the transformer 113 due to the voltage applied between the first terminal T11 and the second terminal T12. When the current flowing to the primary side of the transformer 113 changes due to the switching of the element 120 by the control unit 40, the current flows from the secondary side of the transformer 113 to the second bridge circuit 114 and is stored in the second capacitor 115. A voltage is generated between the third terminal T21 and the fourth terminal T22 by storing electricity in the second capacitor 115, and electric power is output from the DAB circuit 33a.

On the other hand, when the overcurrent detection sensor 34a detects a short circuit on the load side, the DAB circuit 33a transmits power from the second end E20 side to the first end E10 side. In this case, at least a part of the current discharged by the second capacitor 115 flows from the second bridge circuit 114 to the secondary side of the transformer 113. Due to the change in the current, a current flows from the primary side of the transformer 113 to the first bridge circuit 112, and is stored in, for example, the first capacitor 111. As a result, the amount of the current discharged by the second capacitor 115 flowing to the load side can be reduced.

The DAB bidirectional DC / DC converter can handle a relatively high voltage, and can be applied to applications such as connecting a plurality of DAB bidirectional DC / DC converters in multiple stages to obtain a larger output voltage.
On the other hand, the DAB bidirectional DC / DC converter has a configuration in which a capacitor is arranged at the output end like the second capacitor 115, and when a short circuit occurs on the load side, the capacitor is discharged to the short circuit point and the load side. Wiring or equipment may be damaged by overcurrent. Therefore, when a short circuit occurs on the load side, the DAB circuit 33a takes in electric power. As a result, the amount of current flowing to the load side can be reduced as described above, and the possibility that the wiring or equipment on the load side is damaged by the overcurrent can be reduced.

(Control of DAB circuit by control unit)
The control unit 40 periodically repeats turning on and off of each of the elements 120.
FIG. 4 is a diagram showing a first example of timing at which the control unit 40 turns each of the elements 120 on and off. The horizontal axis of FIG. 4 indicates the time.
FIG. 4 shows an example of the on and off timing of each of the elements 120 when the DAB circuit 33a transmits power from the first end E10 side to the second end E20 side.

In the example of FIG. 4, the control unit 40 turns on the first element 121 for a predetermined time T1 and then turns it off for the same time T1. The control unit 40 repeats the on and off of the first element 121 with each on and off once as one cycle.
The time width of this one cycle (time width of T1 × 2) is represented by 360 °. The time width in which the first element 121 is on and the time width in which the first element 121 is turned off are both T1 time widths and are represented by 180 °.

The control unit 40 also turns on the fourth element 124 at the timing when the first element 121 is turned on, and turns it off at the timing when the first element 121 is turned off.
Regarding the on / off of the second element 122 and the third element 123, the control unit 40 inverts the on / off of the first element 121 and the fourth element 124. That is, the control unit 40 turns off each of the second element 122 and the third element 123 at the timing when the first element 121 is turned on. Then, the control unit 40 turns on each of the second element 122 and the third element 123 at the timing when the first element 121 is turned off.

Regarding the fifth element 125, the control unit 40 repeats on and off with the same time width as the on and off time widths of the first element 121, behind the on and off timings of the first element 121. Let me. Specifically, the control unit 40 delays the phase difference φ from the timing at which the first element 121 is turned on, and turns on the fifth element 125. Further, the control unit 40 delays the timing of turning off the first element 121 by the phase difference φ to turn off the fifth element 125.

The on / off timing relationship of the fifth element 125, the sixth element 126, the seventh element 127, and the eighth element 128 is such that the first element 121, the second element 122, the third element 123, and the fourth element 124 are turned on. , Same as the off timing relationship.
That is, the control unit 40 turns on the eighth element 128 at the timing of turning on the fifth element 125, and turns off the eighth element 128 at the timing of turning off the fifth element 125.
Further, the control unit 40 turns off each of the sixth element 126 and the seventh element 127 at the timing when the fifth element 125 is turned on. Then, the control unit 40 turns on each of the sixth element 126 and the seventh element 127 at the timing when the fifth element 125 is turned off.

When the phase difference φ is within the range of 0 ° <φ ≦ 90 °, the DAB circuit 33a transmits power from the first end E10 side to the second end E20 side. Further, the larger the value of φ within the range of 0 ° <φ ≦ 90 °, the larger the power transmitted from the first end E10 side to the second end E20 side. When φ = 0 °, the transmitted power is 0, and when φ = 90 °, the transmitted power is maximum.
Therefore, the control unit 40 can control the magnitude of the output power of the power supply device 20 by adjusting the magnitude of the phase difference φ.

FIG. 5 is a diagram showing a second example of the timing at which the control unit 40 turns each of the elements 120 on and off. The horizontal axis of FIG. 5 indicates the time.
FIG. 5 shows an example of the on and off timing of each of the elements 120 when the DAB circuit 33a transmits power from the second end E20 side to the first end E10 side.

In the example of FIG. 5, the on / off timing relationship of the first element 121, the second element 122, the third element 123, and the fourth element 124 is the same as in the case of FIG.
That is, the control unit 40 turns on the fourth element 124 at the timing when the first element 121 is turned on, and turns off the fourth element 124 at the timing when the first element 121 is turned off.
Further, the control unit 40 turns off each of the second element 122 and the third element 123 at the timing when the first element 121 is turned on. Then, the control unit 40 turns on each of the second element 122 and the third element 123 at the timing when the first element 121 is turned off.

On the other hand, in FIG. 4, the control unit 40 turns the fifth element on and off later than the on / off timing of the first element 121, whereas in FIG. 5, the control unit 40 turns on and off the first element 121. The fifth element is turned on and off before the timing of turning on and off. Specifically, the control unit 40 advances the phase difference φ from the timing at which the first element 121 is turned on, and turns on the fifth element 125. Further, the control unit 40 advances the first element 121 by the phase difference φ from the timing of turning it off, and turns off the fifth element 125.
The fact that the phase of the on / off period of the fifth element 125 is ahead of the phase of the on / off period of the first element 121 is based on the on / off period of the first element 121. It is shown by making the value of the phase difference φ negative.

The relationship between the on and off timings of the sixth element 126, the seventh element 127, and the eighth element 128 is the same as in the case of FIG.
That is, the control unit 40 turns on the eighth element 128 at the timing of turning on the fifth element 125, and turns off the eighth element 128 at the timing of turning off the fifth element 125.
Further, the control unit 40 turns off each of the sixth element 126 and the seventh element 127 at the timing when the fifth element 125 is turned on. Then, the control unit 40 turns on each of the sixth element 126 and the seventh element 127 at the timing when the fifth element 125 is turned off.

When the phase difference φ is within the range of −90 ° ≦ φ <0 °, the DAB circuit 33a transmits power from the second end E20 side to the first end E10 side. Further, the smaller the value of φ within the range of −90 ° ≦ φ <0 ° (the larger the absolute value of φ), the larger the power transmitted from the second end E20 side to the first end E10 side. When φ = 0 °, the transmitted power is 0, and when φ = −90 °, the transmitted power is maximum.

When a short circuit occurs on the load side, the control unit 40 controls the switching of each element 120 so that the value of the phase difference φ becomes negative, so that the power on the second end E20 side (particularly, the second capacitor). (Discharge power from 115) can be transmitted to the first end E10 side.
At that time, by controlling the switching of the element 120 so that the transmitted power becomes the maximum φ = −90 °, a relatively large amount of power can be transmitted from the second end E20 side to the first end E10 side. It is possible to reduce the possibility that overcurrent will flow to the load side and damage the wiring or equipment.

The switching of the first element 121, the second element 122, the third element 123, and the fourth element 124 is generically referred to as the switching of the first bridge circuit 112. The switching of the fifth element 125, the sixth element 126, the seventh element 127, and the eighth element 128 is collectively referred to as the switching of the second bridge circuit 114.
The phase difference between the switching of the first element 121 and the switching of the fifth element 125 can be said to be the phase difference between the switching of the first bridge circuit 112 and the switching of the second bridge circuit 114.

FIG. 6 is a block diagram showing an example of a processing flow by the control unit 40.
In the example of FIG. 6, element F11 indicates a subtractor that subtracts a measured value from a target value of the output voltage (output voltage to the wiring path 51) of the power supply circuit 30. V _o ^* indicates a target value of the output voltage of the power supply circuit 30. V _o indicates the measurement value of the output voltage of the power supply circuit 30.
Element F12 represents PI control (Proportional-Integral Control). Element F12 indicates feedback control in which the control unit 40 normally controls the output voltage of the power supply circuit 30. However, the control method performed by the control unit 40 is not limited to PI control and may be various methods.

Element F13 indicates switching of control between the normal time and the short circuit detection time. Normally, the control unit 40 calculates the value of the phase difference φ by the feedback control indicated by the element F12. As described with reference to FIGS. 4 and 5, the phase difference φ represents the phase difference of the on / off period of the fifth element 125 with respect to the on / off period of the first element 121.
On the other hand, when the overcurrent detection sensor 34a detects a short circuit on the load side, the control unit 40 sets the value of the phase difference φ to −90 °, which maximizes the power transmitted from the second end E20 to the first end E10. Set.

Element F14 indicates that the control unit 40 controls each switching of the element 120 based on the phase difference φ. I _o indicates a measured value (actual value) of the current to the second capacitor 115.
Element F15 indicates storage by the second capacitor 115. The second capacitor 115 stores electricity according to the input current, and a voltage corresponding to the amount of stored power appears across the second capacitor 115. “1 / S” of the element F15 _{indicates that the voltage (V o} ) of the second capacitor 115 is first-order delayed with _{respect to the current (I o) input to the second capacitor 115.}

(Configuration example of control unit 40)
FIG. 7 is a diagram showing a configuration example of the control unit 40. The control unit 40 shown in FIG. 7 includes a control signal output unit 41, a switching unit 42, and a switching control unit 43.

The control signal output unit 41 corresponds to the combination of the element F11 and the element F12 of FIG. The control signal output unit 41 calculates a voltage difference obtained by subtracting a measured value from a target value of the output voltage (output voltage to the wiring path 51) of the power supply circuit 30, and performs a feedback control calculation using the calculated voltage difference. Therefore, the control unit 40 calculates the phase difference φ for controlling the output voltage of the power supply circuit 30 at normal times. The control signal output unit 41 outputs the calculated phase difference φ as a control signal to the switching unit 42.
The output voltage of the power supply circuit 30 can be equated with the voltage at the second end E20.

The switching unit 42 corresponds to the element F13. When the detection unit 34 does not detect a short circuit, the switching unit 42 outputs the control signal output by the control signal output unit 41 to the switching control unit 43. When the detection unit 34 detects a short circuit, the switching unit 42 has a switching phase of the bridge circuit (first bridge circuit 112) on the first end E10 side of the bridge circuit (second bridge) on the second end E20 side. A control signal (for example, φ = −90 °) indicating a phase difference φ that is behind the switching phase of the circuit 114) is output to the switching control unit 43.

The switching control unit 43 corresponds to the element F14. The switching control unit 43 switches the bridge circuit on the first end E10 side (first bridge circuit 112) and the bridge circuit on the second end E20 side (second bridge circuit 114) based on the control signal output by the switching unit 42. ) Is controlled.

FIG. 8 is a flowchart showing an example of a processing procedure in which the control unit 40 controls the power supply circuit 30.
In the process of FIG. 8, the control unit 40 confirms the sensor signal from the detection unit 34 of FIG. 1 (in the case of FIG. 2, the overcurrent detection sensor 34a) (step S11), and a short circuit occurs on the load side. Whether or not it is determined (step S12).

When it is determined that a short circuit has not occurred (step S12: NO), the control unit 40 controls the power supply circuit 30 by normal control (step S21). In the case of the example of FIG. 6, the control unit 40 controls when the switch of the element F13 is connected to the side of the element F12.
After step S21, the process returns to step S11.

On the other hand, when it is determined in step S12 that a short circuit has occurred (step S12: YES), the control unit 40 controls the bidirectional DC / DC converter 33 of FIG. 1 (DAB circuit 33a in the case of FIG. 3). Is switched from the normal control for transmitting power from the first end E10 side to the second end E20 side to the control at the time of short-circuit detection for transmitting power from the second end E20 side to the first end E10 side (step S31). In the case of the example of FIG. 6, the control unit 40 switches the setting of the phase difference φ indicated by the element F13 from the setting by PI control of the element F12 to the setting of the maximum negative value phase difference (φ = −90 °).

Further, the control unit 40 shuts off the circuit breaker 31 (step S32). That is, the control unit 40 controls the circuit breaker 31 to bring it into the open (OFF) state. The order of processing in step S31 and step S32 is arbitrary. The control unit 40 may perform the process of step S32 before the process of step S31.
After step S31, the control unit 40 ends the process of FIG.

<Second embodiment>
In the configuration illustrated in FIG. 2, when the inductance 14L of the wiring path 51 is small, even if the control unit 40 switches the control of the DAB circuit 33a when a short circuit occurs, the leakage inductance of the transformer 113 (FIG. 3) causes the second There is a possibility that the power supply device 20 cannot sufficiently take in the discharge power of the capacitor 115. That is, there is a possibility that the DAB circuit 33a cannot sufficiently transmit power from the second end E20 side to the first end E10 side.
Therefore, in the second embodiment, a reactor may be provided in the output path from the power supply circuit 30 to increase the inductance when the power supply circuit 30 outputs power to the wiring path 51 and the load 52. In the second embodiment, this point will be described.

FIG. 9 is a schematic block diagram showing a configuration example of the electric power system according to the second embodiment of the present disclosure. The example of FIG. 9 is different from the case of FIG. 2 in that the power supply circuit 30 includes a reactor 35 provided between the third terminal T21 and the wiring path 51. Other than that, the electric power system 1 according to the second embodiment is the same as the electric power system 1 according to the first embodiment.

Since the reactor 35 is provided in the path where the discharge current of the second capacitor 115 reaches the load 52 when a short circuit occurs, the wiring path 51 and the load 52 when a short circuit occurs even when the inductance 14L of the wiring path 51 is relatively small. There is a delay in the current flowing through. As a result, when a short circuit occurs, the power supply device 20 can take in more discharge power (particularly, discharge current) of the second capacitor 115, and it is expected that the current flowing through the wiring path 51 and the load 52 becomes smaller. ..

(Other embodiments)
Although the embodiment of the present disclosure has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment and includes design changes and the like within a range not deviating from the gist of the present disclosure. Is done. For example, the bidirectional DC / DC converter 33 of FIG. 1 is not limited to the DAB circuit 33a (Dual Active Bridge system bidirectional DC / DC converter) exemplified in FIG. 2, and is between two terminals serving as output terminals. Any bidirectional DC / DC converter provided with a capacitor may be used.

(Computer configuration)
FIG. 10 is a schematic block diagram showing a configuration of a computer according to at least one embodiment. In the configuration shown in FIG. 10, the computer 700 includes a CPU (Central Processing Unit) 710, a main storage device 720, an auxiliary storage device 730, and an interface 740.

The control unit 40 may be mounted on the computer 700. In that case, the operation of each of the above-mentioned processing units is stored in the auxiliary storage device 730 in the form of a program. The CPU 710 reads the program from the auxiliary storage device 730, expands it to the main storage device 720, and executes the above processing according to the program. Further, the CPU 710 secures a storage area corresponding to each of the above-mentioned storage units in the main storage device 720 according to the program. Communication between each device and other devices is executed by having the interface 740 have a communication function and performing communication according to the control of the CPU 710. The auxiliary storage device 730 is, for example, a non-transitory recording medium such as a CDC (Compact Disc) or a DVD (digital versatile disc).

When the control unit 40 is mounted on the computer 700, the operations of the control signal output unit 41, the switching unit 42, and the switching control unit 43 are stored in the auxiliary storage device 730 in the form of a program. The CPU 710 reads the program from the auxiliary storage device 730, expands it to the main storage device 720, and executes the above processing according to the program.
Further, the CPU 710 secures a storage area used by the control unit 40 in the main storage device 720 according to the program. The input / output of the signal performed by the control unit 40 is executed by the interface 740.

By recording a program for executing all or part of the processing performed by the control unit 40 on a computer-readable recording medium, and causing the computer system to read and execute the program recorded on the recording medium. Each part may be processed. The term "computer system" as used herein includes hardware such as an OS (Operating System) and peripheral devices.
The "computer-readable recording medium" is a portable medium such as a flexible disk, a magneto-optical disk, a ROM (Read Only Memory), a CD-ROM (Compact Disc Read Only Memory), or a hard disk built in a computer system. It refers to a storage device such as. Further, the above-mentioned program may be a program for realizing a part of the above-mentioned functions, and may be a program for realizing the above-mentioned functions in combination with a program already recorded in the computer system.

<Additional notes>
The power supply device, control device, control method and program described in each embodiment are grasped as follows, for example.

(1) The power supply device 20 according to the first aspect has a first end E10 that receives an input of power and a second end E20 that outputs DC power, and has two terminals (third) of the second end E20. A bidirectional DC / DC converter 33 (for example, DAB circuit 33a) in which a second capacitor 115 is provided between the terminal T21 and the fourth terminal T22) and an output destination of DC power from the second end E20 (for example, for example). The detection unit 34 (for example, the overcurrent detection sensor 34a) that detects a short circuit in the wiring path 51 and the load 52), and when the detection unit 34 does not detect a short circuit, from the first end E10 side to the second end E20 side. The bidirectional DC / DC converter 33 is controlled so as to transmit power, and when the detection unit 34 detects a short circuit, the bidirectional DC / DC converter 33 transmits power from the second end E20 side to the first end E10 side. A control unit 40 for controlling the above is provided.
According to the first aspect, when a short circuit occurs on the load side, the electric power released by the second capacitor 115 can be taken into the power supply device 20. As a result, it is possible to reduce the possibility that an overcurrent will flow to the load side (wiring path 51 and load 52 in the example of FIG. 1) and damage the wiring or equipment.

(2) The power supply device 20 according to the second aspect is the power supply device of (1), and the bidirectional DC / DC converter 33 is a bidirectional DC / DC using a Dual Active Bridge circuit (DAB circuit 33a). The control unit 40 is a converter, and when the detection unit 34 does not detect a short circuit, the switching phase of the bridge circuit (first bridge circuit 112) on the first end E10 side in the Dual Active Bridge circuit (DAB circuit 33a). However, switching is controlled so as to advance with respect to the switching phase of the bridge circuit (second bridge circuit 114) on the second end E20 side, and when the detection unit 34 detects a short circuit, the first end Switching control is performed so that the switching phase of the bridge circuit (first bridge circuit 112) on the E10 side is delayed with respect to the switching phase of the bridge circuit (second bridge circuit 114) on the second end E20 side. ..
According to the second aspect, the control unit 40 switches the direction of power transmission of the DAB circuit 33a by a relatively simple process of switching the phase difference between the switching of the first bridge circuit 112 and the switching of the second bridge circuit 114. be able to. According to the power supply device 20, at this point, it is expected that the direction of power transmission of the DAB circuit 33a can be quickly switched to reduce the possibility of damage to the wiring or equipment on the load side.

(3) The power supply device 20 according to the third aspect is the power supply device of (2), and the control unit 40 has a target value of the voltage at the second end E20 and a measured value of the voltage at the second end E20. When the control signal output unit 41 that outputs the phase difference control signal and the detection unit 34 do not detect a short circuit, the control signal output unit 41 outputs the control signal and the detection unit 34 short-circuits. Is detected, the switching phase of the bridge circuit (first bridge circuit 112) on the first end E10 side is relative to the switching phase of the bridge circuit (second bridge circuit 114) on the second end E20 side. Switching and the second end of the bridge circuit (first bridge circuit 112) on the first end E10 side based on the switching unit 42 that outputs the control signal indicating the delayed phase difference and the control signal output by the switching unit 42. A switching control unit 43 that controls switching of the bridge circuit (second bridge circuit 114) on the E20 side is provided.
According to the third aspect, in a relatively simple process in which the switching unit 42 switches the control signal, the output voltage of the power supply device 20 is controlled by the feedback control in the normal state, and the power generated by the power supply device 20 when the short circuit is detected. You can switch between importing and importing. According to the power supply device 20, at this point, it is expected that the direction of power transmission of the DAB circuit 33a can be quickly switched to reduce the possibility of damage to the wiring or equipment on the load side.

(4) The power supply device according to the fourth aspect is any of the power supply devices (1) to (3), and further includes a reactor 35 provided on the second end E20 side.
According to the fourth aspect, even when the inductance 14L of the wiring path 51 is relatively small, the reactor 35 causes a delay in the current flowing through the wiring path 51 and the load 52 when a short circuit occurs. As a result, when a short circuit occurs, the power supply device 20 can take in more discharge power (particularly, discharge current) of the second capacitor 115, and it is expected that the current flowing through the wiring path 51 and the load 52 becomes smaller. ..

(5) The power supply device according to the fifth aspect is the power supply device of (2) or (3), which is provided on the second end E20 side and is the first end E10 of the Dual Active Bridge circuit (DAB circuit 33a). A reactor 35 having an inductance larger than the leakage inductance of the transformer 113 between the bridge circuit on the side (first bridge circuit 112) and the bridge circuit on the second end E20 side (second bridge circuit 114) is further provided.
According to the fifth aspect, the power supply device 20 can more reliably take in the discharge power (particularly, the discharge current) of the second capacitor 115 in that the inductance of the reactor 35 is larger than the leakage inductance of the transformer 113. It is expected that the current flowing through the wiring path 51 and the load 52 will be smaller.

(6) The control device (power supply device 20 or control unit 40) according to the sixth aspect has a first end E10 that receives an input of power and a second end E20 that outputs DC power, and the second end E20. A bidirectional DC / DC converter 33 (for example, DAB circuit 33a) in which a second capacitor 115 is provided between the two terminals (the third terminal T21 and the fourth terminal T22) is connected to a direct current from the second end E20. If a short circuit is not detected at the power output destination, power is controlled to be transmitted from the first end E10 side to the second end E20 side, and if a short circuit is detected, the first end E20 side is used to transmit power. A control unit 40 for controlling power transmission to the end E10 side is provided.
According to the sixth aspect, when a short circuit occurs on the load side, the electric power released by the second capacitor 115 can be taken into the power supply device 20. As a result, it is possible to reduce the possibility that an overcurrent will flow to the load side (wiring path 51 and load 52 in the example of FIG. 1) and damage the wiring or equipment.

(7) The method according to the seventh aspect has a first end E10 for receiving power input and a second end E20 for outputting DC power, and has two terminals (third terminal T21) of the second end E20. A short circuit has not been detected in the bidirectional DC / DC converter (for example, DAB circuit 33a) provided with the second capacitor 115 between the fourth terminal T22 and the output destination of the DC power from the second end E20. In this case, it is controlled to transmit power from the first end E10 side to the second end E20 side, and when a short circuit is detected, control is performed to transmit power from the second end E20 side to the first end E10 side. include.
According to the seventh aspect, when a short circuit occurs on the load side, the electric power released by the second capacitor 115 can be taken into the power supply device 20. As a result, it is possible to reduce the possibility that an overcurrent will flow to the load side (wiring path 51 and load 52 in the example of FIG. 1) and damage the wiring or equipment.

(8) The program according to the eighth aspect has a first end E10 for receiving power input and a second end E20 for outputting DC power, and has two terminals (third terminal T21) of the second end E20. A short circuit at the output destination of DC power from the second end E20 to a computer that controls a bidirectional DC / DC converter 33 (for example, DAB circuit 33a) provided with a second capacitor 115 between the fourth terminal T22). If is not detected, the bidirectional DC / DC converter 33 is controlled so as to transmit power from the first end E10 side to the second end E20 side, and if a short circuit is detected, the first from the second end E20 side. This is a program for controlling the bidirectional DC / DC converter 33 so as to transmit power to the end E10 side.
According to the eighth aspect, when a short circuit occurs on the load side, the electric power released by the second capacitor 115 can be taken into the power supply device 20. As a result, it is possible to reduce the possibility that an overcurrent will flow to the load side (wiring path 51 and load 52 in the example of FIG. 1) and damage the wiring or equipment.

1 Power system 11 Generator 20 Power supply device 30 Power supply circuit 31 Breaker 32 Rectifier circuit 33 Bidirectional DC / DC converter 33a DAB circuit 34 Detection unit 34a Overcurrent detection sensor 40 Control unit 41 Control signal output unit 42 Switching unit 43 Switching control Part 51 Wiring path 52 Load 33a DAB circuit 34a Overcurrent detection sensor E10 1st end E20 2nd end 111 1st capacitor 112 1st bridge circuit 113 Transformer 114 2nd bridge circuit 115 2nd capacitor 120 elements

Claims (8)

A bidirectional DC / DC converter having a first end that receives power input and a second end that outputs DC power, and a capacitor is provided between the two terminals of the second end.
A detector that detects a short circuit at the output destination of DC power from the second end,
When the detection unit did not detect the short circuit, the bidirectional DC / DC converter was controlled so as to transmit power from the first end side to the second end side, and the detection unit detected the short circuit. In this case, a control unit that controls the bidirectional DC / DC converter so as to transmit power from the second end side to the first end side.
A power supply unit. The bidirectional DC / DC converter is a bidirectional DC / DC converter using a Dual Active Bridge circuit.
When the detection unit does not detect the short circuit, the control unit determines that the switching phase of the bridge circuit on the first end side of the Dual Active Bridge circuit is the switching phase of the bridge circuit on the second end side. When the switching is controlled so as to advance with respect to the above and the detection unit detects the short circuit, the switching phase of the bridge circuit on the first end side is the bridge circuit on the second end side. Control the switching so that it lags behind the switching phase.
The power supply device according to claim 1. The control unit
A control signal output unit that outputs a phase difference control signal based on the target value of the voltage at the second end and the measured value of the voltage at the second end.
When the detection unit does not detect the short circuit, the control signal output unit outputs the control signal, and when the detection unit detects the short circuit, the bridge circuit on the first end side A switching unit that outputs a control signal indicating a phase difference in which the switching phase is delayed with respect to the switching phase of the bridge circuit on the second end side.
A switching control unit that controls switching of the bridge circuit on the first end side and switching of the bridge circuit on the second end side based on the control signal output by the switching unit.
2. The power supply device according to claim 2. Further provided with a reactor provided on the second end side,
The power supply device according to any one of claims 1 to 3. A reactor provided on the second end side and having an inductance larger than the leakage inductance of the transformer between the bridge circuit on the first end side of the Dual Active Bridge circuit and the bridge circuit on the second end side is further provided. Prepare, prepare
The power supply device according to claim 2 or 3. The second is a bidirectional DC / DC converter having a first end that receives power input and a second end that outputs DC power, and a capacitor is provided between the two terminals of the second end. When a short circuit at the output destination of DC power from the end is not detected, power is controlled to be transmitted from the first end side to the second end side, and when the short circuit is detected, the second end side is detected. A control device including a control unit that controls power transmission from the first end side to the first end side. The second is a bidirectional DC / DC converter having a first end that receives power input and a second end that outputs DC power, and a capacitor is provided between the two terminals of the second end. When a short circuit at the output destination of DC power from the end is not detected, power is controlled to be transmitted from the first end side to the second end side, and when the short circuit is detected, the second end side is detected. A control method including controlling the power transmission from the first end side to the first end side. A computer that controls a bidirectional DC / DC converter that has a first end that receives power input and a second end that outputs DC power, and a capacitor is provided between the two terminals at the second end. ,
When a short circuit at the output destination of the DC power from the second end is not detected, the bidirectional DC / DC converter is controlled so as to transmit power from the first end side to the second end side, and the short circuit is performed. Is detected, a program for controlling the bidirectional DC / DC converter so as to transmit power from the second end side to the first end side.

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