JP2015164015A - Direct-current feeding system, direct-current power supply device, and feeding control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make effective use of electric power generated by a photovoltaic power generator.SOLUTION: A direct-current feeding system comprises: a direct-current power supply device converting alternating-current power from a commercial power supply system into direct-current power, outputting the obtained direct-current power to a direct-current feeder, and supplying the direct-current power to a load device via the direct-current feeder; a photovoltaic power generator generating direct-current power using sunlight and outputting the direct-current power to the direct-current feeder via a diode; and a detector detecting a current output from the photovoltaic power generator, the direct-current power supply device includes a power supply controller changing an output voltage output to the direct-current feeder and exerting a control to make maximum the output power from the photovoltaic power generator based on the current detected by the detector and the output voltage.

Description

  The present invention relates to a DC power supply system, a DC power supply device, and a power supply control method.

  2. Description of the Related Art In recent years, a DC power supply system that supplies power generated by a solar power generation device to a load device along with power from a commercial power supply system is known. In such a power supply system, for example, the solar power generation device may be connected to a DC supply line via a power conditioner (hereinafter, also referred to as PCS) including a DC / DC converter. In such a case, the DC / DC converter has a function of maximum power point tracking (MPPT) of DC power output from the photovoltaic power generator and a function of stabilizing the DC voltage, and the photovoltaic power generator generates power. The maximum power can be obtained from the power to be transmitted (see, for example, Patent Document 1).

JP 2012-152093 A

  However, in the DC power supply system as described above, the power generated by the photovoltaic power generation apparatus is supplied to the DC supply line via the PCS including the DC / DC converter. In this DC / DC converter, a loss is generated along with the conversion. Therefore, the DC power supply system as described above may not be able to effectively use the power generated by the solar power generation device.

  The present invention has been made to solve the above problems, and an object of the present invention is to provide a DC power supply system, a DC power supply device, and a power supply control method capable of effectively using the power generated by the solar power generation device. There is.

  In order to solve the above-described problem, an aspect of the present invention converts AC power from a commercial power supply system into DC power, outputs the converted DC power to a DC supply line, and loads the load device via the DC supply line. A direct current power supply device that supplies solar power, a solar power generation device that generates direct current power using sunlight, and outputs the generated direct current power to the direct current supply line via a diode; and the solar power generation device A current detection unit that detects a current to be output, wherein the DC power supply device changes an output voltage output to the DC supply line, and the current detection unit detects the current based on the current and the output voltage. A DC power supply system including a power supply control unit that controls the output power of a solar power generation device to become maximum.

  One embodiment of the present invention is the above-described DC power supply system, wherein the power supply control unit changes the output voltage within an operating voltage range of the load device to which the DC power is supplied, Control is performed so that the output power of the apparatus is maximized.

  According to another aspect of the present invention, in the above-described DC power supply system, the first output voltage output from the solar power generation device is adjusted so that the output power of the solar power generation device is maximized. A converter that converts an output voltage of 1 into a predetermined second output voltage, and outputs the converted second output voltage to the DC supply line; an output line of the photovoltaic power generator; and the DC supply A switch unit that is connected to the line and that supplies the DC power output from the photovoltaic power generation apparatus to the DC supply line by bypassing the converter, and a bypass that controls at least the open / closed state of the switch unit A power supply control device having a control unit, wherein the power supply control unit bypasses the converter and supplies the DC power to the DC supply line when the switch unit bypasses the converter. Such that the output power of the location is maximized, and controlling the output voltage.

  Moreover, one aspect of the present invention is the above-described DC power supply system, further comprising a voltage detection unit that detects the first output voltage output from the photovoltaic power generation device, wherein the bypass control unit is controlled by the voltage detection unit. When the detected first output voltage is within a predetermined voltage range, the operation of the converter is stopped, and the DC power output from the photovoltaic power generation device is output to the switch unit. The converter is bypassed and supplied to the DC supply line.

  According to another aspect of the present invention, in the DC power supply system, the predetermined voltage range is a voltage range including the second output voltage, and the DC power is supplied via the DC supply line. A voltage range determined based on an operating voltage range of the load device, wherein the bypass control unit is equal to or higher than a first threshold value in which the first output voltage is higher than a lower limit value of the predetermined voltage range, and , When the second threshold value is lower than the upper limit value of the predetermined voltage range, the operation of the converter is stopped and the switch unit is controlled to bypass the converter, When the first output voltage is less than or equal to the lower limit value or greater than or equal to the upper limit value, the converter is operated and the switch unit is controlled to stop bypassing the converter. And butterflies.

  One embodiment of the present invention includes a power storage device that supplies power to the DC power supply device when the AC power from the commercial power supply system is stopped in the DC power supply system, and the bypass control unit includes: When the AC power from the commercial power supply system stops, the operation of the converter is stopped, and the DC power output from the photovoltaic power generator is bypassed to the converter with respect to the switch unit. The DC power supply device controls the DC power supply line to supply the DC power to the DC power supply based on the power supplied from the power storage device when the AC power from the commercial power supply system stops. It outputs to a supply line, It is characterized by the above-mentioned.

  One embodiment of the present invention is the above-described DC power supply system, including a plurality of the solar power generation devices and a plurality of the current detection units corresponding to the plurality of solar power generation devices, and the power supply control unit. Is characterized in that the output voltage output to the DC supply line is changed so that the total output power from the plurality of photovoltaic power generation devices is maximized.

  According to another aspect of the present invention, a DC power supply apparatus that converts AC power from a commercial power supply system into DC power, outputs the converted DC power to a DC supply line, and supplies the DC power to a load device via the DC supply line. The output voltage to be output to the DC supply line is changed, and the DC power generated using sunlight is supplied to the DC supply line via a diode. A direct current characterized by comprising a power supply control unit for controlling the output voltage so that the output power of the photovoltaic power generation device based on the current detected by the current detection unit to be detected and the output voltage is maximized. It is a power supply device.

  According to another aspect of the present invention, a DC power supply apparatus that converts AC power from a commercial power supply system into DC power, outputs the converted DC power to a DC supply line, and supplies the DC power to a load device via the DC supply line. And a power supply control method in a direct current power supply system comprising a solar power generation device that generates direct current power using sunlight and outputs the generated direct current power to the direct current supply line via a diode, The direct current power supply device changes the output voltage output to the direct current supply line, and the solar based on the current and the output voltage detected by the current detection unit that detects the current output by the solar power generation device A power supply control method characterized by including a power supply control step for controlling the output power of the photovoltaic power generation device to become maximum.

  ADVANTAGE OF THE INVENTION According to this invention, the electric power which a solar power generation device produces | generates can be utilized effectively.

1 is a block diagram illustrating an example of a DC power supply system according to a first embodiment. It is a flowchart which shows an example of operation | movement of the rectifier in 1st Embodiment. It is a block diagram which shows the modification of the DC power supply system by 1st Embodiment. It is a block diagram which shows an example of the DC power supply system by 2nd Embodiment. It is a figure which shows an example of the bypass control in 2nd Embodiment. It is a flowchart which shows an example of the bypass control procedure in 2nd Embodiment. It is a flowchart which shows an example of operation | movement of the rectifier in 2nd Embodiment. It is a block diagram which shows an example of the DC power supply system by 3rd Embodiment. It is a flowchart which shows an example of the bypass control procedure in 3rd Embodiment.

  Hereinafter, a DC power supply system according to an embodiment of the present invention will be described with reference to the drawings.

[First Embodiment]
FIG. 1 is a block diagram illustrating an example of a DC power supply system 1 according to the present embodiment.
In this figure, the DC power supply system 1 includes a rectifier 3, a solar power generator 4, a power supply controller 5, a power storage device 6, a bidirectional DC / DC converter 7, a distribution board 8, and a switch unit 200 (201 to 203). , And a current detection unit 301.

The rectifier 3 (RF: Rectifier) is a DC power supply device that converts AC power from the commercial power supply system 2 that is an AC power source into DC power, and outputs the converted DC power to the DC supply line L1. Here, the DC supply line L1 is, for example, a DC power supply bus of a DC 380V system, and is connected to the load device 90 (for example, the load devices 91 to 93) via the distribution board 8. That is, the rectifier 3 supplies the converted DC power to the load device 90 via the DC supply line L1.
In the example shown in FIG. 1, the DC supply line L <b> 1 is connected to the input side of the distribution board 8, and the rectifier 3 is arranged in the system of the DC supply lines L <b> 2 to L <b> 6 via the distribution board 8. Electric power is supplied to each of the load devices 90 (91 to 93). Note that each of the load devices 91 to 93 is a device that operates with DC power supplied from the rectifier 3, and when indicating any load device included in the DC power supply system 1, or when not particularly distinguished, load The apparatus 90 will be described. The load device 90 is, for example, a DC home appliance, LED lighting, an information device such as a personal computer or a server.
In FIG. 1, the DC supply lines L <b> 1 to L <b> 6 are simply described as one supply line for the sake of explanation, but are constituted by a positive-side power supply line and a negative-side supply line. Further, the solar power generation device 4 and the power storage device 6 are connected to the direct current supply line L <b> 1 via the bidirectional DC / DC converter 7.
The rectifier 3 includes a detection unit 31, a switch unit 32, a DC power supply unit 33, and a power supply control unit 34.

The detection unit 31 detects, for example, a voltage or current supplied from the commercial power supply system 2 to detect whether the commercial power supply system 2 is in a power failure state.
The switch unit 32 is a switch connected between the supply line from the commercial power supply system 2 and the input side (primary side) of the DC power supply unit 33.

  The DC power supply unit 33 converts AC power from the commercial power supply system 2 into DC power (for example, DC 380V system), and outputs the converted DC power to the DC supply line L1. The output voltage output from the DC power supply unit 33 is controlled by a power supply control unit 34 described later.

The power supply control unit 34 controls the direct current power supply unit 33 and disconnects the rectifier 3 from the commercial power supply system 2 by opening the switch unit 32 when the detection unit 31 detects a power failure of the commercial power supply system 2. Let Moreover, the power supply control part 34 outputs the signal Spf which shows whether the commercial power supply system 2 is a power failure state.
Moreover, the power supply control part 34 performs the maximum power point tracking control which changes the output voltage output to the DC supply line L1, and controls so that the output power of the solar power generation device 4 mentioned later becomes the maximum. Details of the maximum power point tracking control will be described later. The power supply control unit 34 changes the output voltage output to the DC supply line L1 by outputting the set voltage information for setting the output voltage of the DC power supply unit 33 to the DC power supply unit 33. Further, the power supply control unit 34 can acquire the output voltage of the DC power supply unit 33 (rectifier 3) by acquiring the set voltage information set in the DC power supply unit 33.

The switch parts 201 to 203 are switches for opening and closing the electric circuit in the DC supply lines L2 to L6. The switch units 201 to 203 select the load device 90 (for example, the load devices 91 to 93) and supply power when, for example, a power failure occurs in the commercial power supply system 2 or when it is desired to save power due to a power saving request or the like. It is possible to do.
Note that the switch units 201 to 203 will be described as the switch unit 200 when an arbitrary switch unit included in the DC power supply system 1 is shown or when there is no particular distinction.

Here, the DC supply after the distribution board 8 will be described in more detail. The DC supply line L1 is connected to the input side of the distribution board 8, and an overcurrent breaker (not shown) in the distribution board 8 is provided. Are branched into a DC supply line L2 and a DC supply line L5. The DC supply line L2 is connected to the DC supply line L3 via the switch unit 201, and the load device 91 is connected to the DC supply line L3. Further, the DC supply line L4 is branched from the DC supply line L3 via the switch unit 202, and the load device 92 is connected to the DC supply line L4.
On the other hand, the DC supply line L5 branched from the distribution board 8 is branched to the DC supply line L6 via the switch unit 203, and a load device 93 is connected to the DC supply line L6.

  In addition, the above-described switch units 201 to 203 have a power failure in the rectifying device 3, and thereafter, the electric charge accumulated in the backup power storage device 6 is insufficient or depleted. When it becomes impossible to supply the battery, it is assumed to be in an open (off) state once. For example, when power is supplied from the solar power generation device 4, the power supply range can be sequentially expanded by controlling the open / closed state of the switch units 201 to 203 by the power supply control device 5 described later. I have to.

The solar power generation device 4 generates power using sunlight, which is natural energy, and outputs the generated power as DC power. The solar power generation device 4 includes a solar cell array 41 (solar cell) and a diode 42. The solar power generation device 4 outputs DC power generated by converting sunlight into electricity by the solar cell array 41 to the DC supply line L <b> 1 via the diode 42. Here, the diode 42 prevents backflow of output power.
The current detection unit 301 detects an output current output from the solar power generation device 4. The current detection unit 301 outputs the detected output current of the solar power generation device 4 to the rectifying device 3.

The power supply control device 5 performs control such as charge / discharge control of the power storage device 6, control for setting various setting information for operating the rectifying device 3, and control of the open / close state of the switch units 201 to 203. In addition, the power supply control device 5 includes a power supply control unit 51.
The power supply control unit 51 controls the open / close state of the switch unit 200 (201 to 203) by the control signal CNT, and controls charging / discharging of the power storage device 6 by the bidirectional DC / DC converter 7. The power supply control unit 51 controls the power supply range by controlling the power supply source (the solar power generation device 4, the rectifying device 3, or the power storage device 6) of the DC supply line L1, and controlling the switch units 201 to 203. To do.

  The power storage device 6 is, for example, a storage battery that charges and discharges electric power, such as a lead storage battery or a lithium ion battery. The power storage device 6 is charged (charged) with the power from the rectifier 3 via the bidirectional DC / DC converter 7 during normal times when power is supplied from the rectifier 3 to the DC supply line L1. The power storage device 6 supplies the stored power to the DC supply line L <b> 1 via the bidirectional DC / DC converter 7 during a power failure when the commercial power supply system 2 is in a power failure state.

A bidirectional DC / DC converter 7 (an example of a bidirectional converter) is connected to the DC supply line L1, charges the power storage device 6 with power supplied from the DC supply line L1, and also connects the power supply device 6 to the DC supply line. A bidirectional converter that causes L1 to discharge power.
The bidirectional DC / DC converter 7 performs charge / discharge control of the power storage device 6 for the purpose of peak cut of electric power used in normal times. Bidirectional DC / DC converter 7 includes a switch (not shown) for disconnecting (disconnecting) DC supply line L1 and power storage device 6, and based on control by power supply control device 5 described later, Charging / discharging of the power storage device 6 and disconnection of the power storage device 6 are controlled.

Next, the operation of the DC power supply system 1 in the present embodiment will be described with reference to the drawings.
FIG. 2 is a flowchart showing an example of the operation of the rectifier 3 in the present embodiment.
Here, operation | movement of the power supply control part 34 of the DC power supply system 1 (rectifier 3) is demonstrated with reference to FIG.
The power supply control unit 34 of the rectifier 3 changes the output voltage output from the DC power supply unit 33 to the DC supply line L <b> 1, and is based on the current detected by the current detection unit 301 and the output voltage of the DC power supply unit 33. Control is performed so that the output power of the photovoltaic power generation device 4 is maximized. For example, the power supply control unit 34 changes the output voltage of the DC power supply unit 33 within the operating voltage range of the load device 90 to which DC power is supplied so that the output power of the solar power generation device 4 is maximized. To do. Here, the operating voltage range of the load device 90 is, for example, a DC voltage range of 380V ± 20V (a voltage range of 360V to 400V). The power supply control unit 34 outputs the set voltage information for setting the output voltage of the DC power supply unit 33 to the DC power supply unit 33, for example, in a voltage range of 360 V (lower limit value) to 400 V (upper limit value). The output voltage output to the line L1 is changed. Note that the DC power supply unit 33 cannot set, for example, an output voltage lower than 360 V (lower limit value) and an output voltage higher than 400 V (upper limit value).

  In FIG. 2, first, the power supply controller 34 of the rectifier 3 acquires the output voltage of the rectifier 3 (the voltage of the DC supply line L1) as a start voltage (step S101). The power supply control unit 34 acquires the set voltage information set in the DC power supply unit 33, thereby acquiring the current output voltage of the rectifier 3 as the start voltage.

  Next, the power supply control unit 34 determines whether or not the start voltage is a lower limit value (eg, 360 V) of the operating voltage range (step S102). When the start voltage is the lower limit value of the operating voltage range (step S102: YES), the power supply controller 34 advances the process to step S111. Moreover, the power supply control part 34 advances a process to step S103, when a start voltage is not the lower limit of an operating voltage range (step S102: NO).

  In step S103, the power supply control unit 34 determines whether or not the output voltage of the rectifier 3 is a lower limit value. That is, the power supply control unit 34 acquires the set voltage information from the DC power supply unit 33, thereby acquiring the currently set output voltage of the rectifying device 3, and the acquired output voltage of the rectifying device 3 is within the operating voltage range. It is determined whether it is a lower limit value. The power supply control part 34 complete | finishes a process, when the output voltage of the rectifier 3 is a lower limit (step S103: YES). That is, the power supply control unit 34 determines that the output voltage of the rectifying device 3 that maximizes the output power of the solar power generation device 4 is the lower limit value of the operating voltage range, and ends the process. Moreover, the power supply control part 34 advances a process to step S104, when the output voltage of the rectifier 3 is not a lower limit (step S103: NO).

  In step S104, the power supply controller 34 reduces the output voltage of the rectifier 3 by a voltage ΔV that is a predetermined voltage. That is, the power supply control unit 34 outputs the set voltage information obtained by reducing the currently set output voltage of the rectifying device 3 by the voltage ΔV to the DC power supply unit 33 and reduces the output voltage of the rectifying device 3 by the voltage ΔV. Let Here, the voltage ΔV is a predetermined voltage.

  Next, the power supply control part 34 acquires the output current of the solar power generation device 4 (step S105). That is, the power supply control unit 34 acquires the output current of the solar power generation device 4 detected by the current detection unit 301.

  Next, the power supply control part 34 calculates the output electric power of the solar power generation device 4 (step S106). That is, for example, the power supply control unit 34 integrates the output current value of the solar power generation device 4 acquired from the current detection unit 301 and the output voltage of the rectifying device 3 set in the DC power supply unit 33, The output power of the power generator 4 is calculated.

  Next, the power supply control part 34 determines whether the output electric power of the solar power generation device 4 fell (step S107). That is, the power supply control unit 34 determines whether or not the output power of the solar power generation device 4 calculated this time has decreased from the output power of the solar power generation device 4 calculated last time. The power supply control part 34 advances a process to step S108, when the output electric power of the solar power generation device 4 falls (step S107: YES). Moreover, the power supply control part 34 returns a process to step S103, when the output electric power of the solar power generation device 4 is not falling (it is increasing or there is no change) (step S107: NO). That is, the power supply control unit 34 repeats the processing from step S103 to step S107 until the output power of the solar power generation device 4 decreases. That is, the power supply control unit 34 decreases the output voltage of the solar power generation device 4 by the voltage ΔV until the output power of the solar power generation device 4 decreases.

In step S108, the power supply control unit 34 determines whether or not the output voltage of the rectifying device 3 is (start voltage−voltage ΔV). When the output voltage of the rectifier 3 is (start voltage−voltage ΔV) (step S108: YES), the power supply controller 34 advances the process to step S110. That is, when the output power of the solar power generation device 4 is reduced when the output voltage of the rectifying device 3 is reduced by the voltage ΔV for the first time, the power supply control unit 34 advances the process to step S110 and rectifies The process of increasing the output voltage of the device 3 and detecting the output voltage of the rectifier 3 that maximizes the output power of the photovoltaic power generator 4 is executed. Moreover, the power supply control part 34 advances a process to step S109, when the output voltage of the rectifier 3 is not (start voltage-voltage (DELTA) V) (step S108: NO).
Thus, in the processing from step S103 to step S108, the power supply control unit 34 detects the operating point at which the output power of the solar power generation device 4 is maximized by reducing the output voltage output to the DC supply line L1. .

  In step S109, the power supply controller 34 increases the output voltage of the rectifier 3 by the voltage Δ. That is, in step S107, the power control unit 34 determines that the output voltage of the previous rectifier 3 is the maximum power because the output power of the solar power generator 4 has decreased, and the current output of the rectifier 3 The voltage is increased from the voltage by the voltage ΔV, and the process is terminated. Thereby, the output voltage of the rectifier 3 is set to an output voltage at which the output power of the solar power generator 4 is maximized.

  Moreover, in step S110, the power supply control part 34 determines whether the output voltage of the rectifier 3 is an upper limit. That is, the power supply control unit 34 acquires the set voltage information from the DC power supply unit 33, thereby acquiring the currently set output voltage of the rectifying device 3, and the acquired output voltage of the rectifying device 3 is within the operating voltage range. It is determined whether or not the upper limit value is reached. The power supply control part 34 complete | finishes a process, when the output voltage of the rectifier 3 is an upper limit (step S110: YES). That is, the power supply control unit 34 determines that the output voltage of the rectifying device 3 that maximizes the output power of the solar power generation device 4 is the upper limit value of the operating voltage range, and ends the process. Moreover, the power supply control part 34 advances a process to step S111, when the output voltage of the rectifier 3 is not an upper limit (step S110: NO).

  In step S111, the power supply control unit 34 increases the output voltage of the rectifier 3 by a voltage ΔV that is a predetermined voltage. That is, the power supply control unit 34 outputs the set voltage information that is increased by the voltage ΔV from the currently set output voltage of the rectifying device 3 to the DC power supply unit 33 and increases the output voltage of the rectifying device 3 by the voltage ΔV. Let

  Next, the power supply control part 34 acquires the output current of the solar power generation device 4 (step S112). That is, the power supply control unit 34 acquires the output current of the solar power generation device 4 detected by the current detection unit 301.

  Next, the power supply control part 34 calculates the output electric power of the solar power generation device 4 (step S113). That is, for example, the power supply control unit 34 integrates the output current value of the solar power generation device 4 acquired from the current detection unit 301 and the output voltage of the rectifying device 3 set in the DC power supply unit 33, The output power of the power generator 4 is calculated.

Next, the power supply control part 34 determines whether the output electric power of the solar power generation device 4 fell (step S114). That is, the power supply control unit 34 determines whether or not the output power of the solar power generation device 4 calculated this time has decreased from the output power of the solar power generation device 4 calculated last time. The power supply control part 34 advances a process to step S115, when the output electric power of the solar power generation device 4 falls (step S114: YES). Moreover, the power supply control part 34 returns a process to step S110, when the output electric power of the solar power generation device 4 is not falling (it is increasing or there is no change) (step S114: NO). That is, the power supply control unit 34 repeats the processing from step S110 to step S114 until the output power of the solar power generation device 4 decreases. That is, the power supply control unit 34 increases the output voltage of the solar power generation device 4 by the voltage ΔV until the output power of the solar power generation device 4 decreases.
Thus, in the processing from step S110 to step S114, the power supply control unit 34 increases the output voltage output to the DC supply line L1, and detects the operating point at which the output power of the solar power generation device 4 is maximized. .

  In step S115, the power supply control unit 34 reduces the output voltage of the rectifier 3 by the voltage Δ. That is, the power supply control unit 34 determines that the output voltage of the previous rectifying device 3 is the maximum power because the output power of the photovoltaic power generation device 4 has decreased in step S <b> 115, and the current output of the rectifying device 3. The voltage is decreased from the voltage by a voltage ΔV, and the process is terminated. Thereby, the output voltage of the rectifier 3 is set to an output voltage at which the output power of the solar power generator 4 is maximized.

In step S102, when the start voltage is the lower limit value, the power supply control unit 34 performs the processing from step S110 to step S114 to increase the output voltage, so that the output power of the photovoltaic power generator 4 is increased. Detect the maximum operating point.
Moreover, the power supply control part 34 performs the process from above-mentioned step S101 to step S115 regularly for every predetermined time interval.

  As described above, the DC power supply system 1 includes the rectifying device 3 (an example of a DC power supply device), the solar power generation device 4, and the current detection unit 301. The rectifier 3 converts AC power from the commercial power supply system 2 into DC power, outputs the converted DC power to the DC supply line L1, and supplies it to the load device 90 via the DC supply line L1. The solar power generation device 4 generates direct-current power using sunlight, and outputs the generated direct-current power to the direct-current supply line L <b> 1 via the diode 42. The current detection unit 301 detects the current output from the solar power generation device 4. And the rectifier 3 is provided with the power supply control part 34, and the power supply control part 34 changes the output voltage output to DC supply line L1, and sunlight based on the electric current and output voltage which the current detection part 301 detected Control is performed so that the output power of the power generation device 4 is maximized.

  Thereby, the output of the solar power generation device 4 is supplied to the DC supply line L1 without going through the DC / DC converter, and the DC power supply system 1 according to the present embodiment does not include the DC / DC converter, Control is performed so that the output power of the device 4 is maximized. Therefore, the DC power supply system 1 in the present embodiment can appropriately supply power to the DC supply line L1 without causing loss due to conversion of the DC / DC converter. That is, the DC power supply system 1 according to the present embodiment can reduce the power loss due to the conversion of the DC / DC converter. Therefore, the DC power supply system 1 in the present embodiment can effectively use the power generated by the solar power generation device 4. In addition, since the DC power supply system 1 in the present embodiment does not need to include a DC / DC converter that converts the power of the solar power generation device 4, the configuration can be simplified and the facility cost can be reduced. it can.

Moreover, in this embodiment, the power supply control part 34 changes an output voltage within the operating voltage range (for example, DC 360V-400V) of the load apparatus 90 to which direct-current power is supplied, and the output of the solar power generation device 4 is changed. Control to maximize power.
Thereby, within the operating voltage range of the load device 90, the DC power feeding system 1 in the present embodiment can appropriately supply power to the DC supply line L1 without causing loss due to conversion of the DC / DC converter.

In the above example, the case where the DC power supply system 1 includes one solar power generation device 4 has been described. However, as illustrated in FIG. 3, a plurality of solar power generation devices 4 may be included.
FIG. 3 is a block diagram showing a modification of the DC power supply system 1 according to the present embodiment.
In FIG. 3, the DC power supply system 1a includes a rectifying device 3, a solar power generation device 4 (4-1, 4-2,...), A power supply control device 5, a power storage device 6, a bidirectional DC / DC converter 7, A distribution board 8 switch unit 200 (201 to 203) and a current detection unit 301 (301-1, 301-2, ...) are provided. In this figure, the same components as those shown in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted.

In the modification shown in this figure, the DC power supply system 1a includes a plurality of solar power generation devices 4 (4-1, 4-2,...) And a plurality of current detection units 301 (301-1, 301-2). ,... Are the same as those of the first embodiment except for the point provided with. Here, the solar power generation devices (4-1, 4-2,...) Have the same configuration, and indicate any solar power generation device included in the DC power feeding system 1a, or when not particularly distinguished. Is described as a solar power generation device 4. Moreover, the solar power generation device 4-1 includes a solar cell array 41-1 and a diode 42-1, and the solar power generation device 4-2 includes a solar cell array 41-2 and a diode 42-2.
In addition, a solar cell array (41-1, 41-2, ...) is demonstrated as the solar cell array 41, when showing the arbitrary solar cell arrays with which DC power supply system 1a is provided, or when not distinguishing in particular. . Further, the diodes (42-1, 42-2,...) Are described as the diodes 42 in the case where any diodes included in the DC power supply system 1a are indicated or when they are not particularly distinguished.

  In addition, the current detection units (301-1, 301-2, ...) have the same configuration, and in the case where any current detection unit included in the DC power supply system 1a is indicated or not particularly distinguished, The detection unit 301 will be described.

  In the case where a plurality of solar power generation devices 4 are provided as in this modification, the power supply control unit 34 changes the output voltage output to the DC supply line L1, and the output power from the plurality of solar power generation devices 4 Control the total of the maximum. That is, the power supply control unit 34 sums the output currents of the respective solar power generation devices 4 detected by the current detection units 301 (301-1, 301-2,...) Control the sum to maximize.

  Specifically, in the flowchart shown in FIG. 2, the power supply control unit 34 responds by changing the processing in step S <b> 106 and step S <b> 113 to processing for summing output power by the plurality of solar power generation devices 4.

As described above, the DC power supply system 1 a includes the plurality of photovoltaic power generation devices 4 and the plurality of current detection units 301 corresponding to the plurality of photovoltaic power generation devices 4. And the power supply control part 34 changes the output voltage output to DC supply line L1, and controls so that the sum total of the output electric power by the some solar power generation device 4 becomes the maximum. In addition, by performing such control, the electric power generated by each of the plurality of solar power generation devices 4 is supplied to the DC supply line L1 by an appropriate distribution according to the respective power generation amounts of the solar power generation devices 4. The
Thereby, even if it is a case where DC power supply system 1a is provided with a plurality of photovoltaic power generation devices 4, it can supply electric power appropriately to DC supply line L1 without generating loss by conversion of a DC / DC converter. . Therefore, the DC power supply system 1a in the present embodiment can effectively use the power generated by the plurality of solar power generation devices 4.

According to the present embodiment, the rectifier 3 (an example of a DC power supply device) converts AC power from the commercial power supply system 2 into DC power, and outputs the converted DC power to the DC supply line L1. It supplies to the load apparatus 90 via the supply line L1. And the rectifier 3 is provided with the power supply control part 34, and the power supply control part 34 changes the output voltage output to DC supply line L1, and changes the output voltage output using sunlight, a solar power generation device The output voltage of the rectifying device 3 is set so that the output power of the photovoltaic power generation device 4 based on the current detected by the current detection unit 301 that detects the current output by the output voltage 4 and the output voltage of the rectifying device 3 is maximized. Control.
Thereby, the rectifier 3 can appropriately supply the power output from the solar power generator 4 to the DC supply line L1 without any loss due to the conversion of the DC / DC converter. Therefore, the rectifier 3 in the present embodiment can effectively use the power generated by the solar power generator 4.

In addition, according to the present embodiment, the power supply control method according to the present embodiment includes a rectifier 3 and a solar power generator 4 that outputs generated DC power to the DC supply line L <b> 1 via the diode 42. It is the electric power feeding control method in an electric power feeding system. And the electric power feeding control method by this embodiment was detected by the electric current detection part 301 which detects the electric current which the rectifier 3 changes the output voltage output to the DC supply line L1, and outputs the solar power generation device 4. A power supply control step for controlling the output power of the photovoltaic power generation apparatus 4 based on the current and the output voltage to become maximum is included.
Thereby, since the electric power feeding control method by this embodiment can supply the electric power which the solar power generation device 4 outputs appropriately to DC supply line L1, without the loss by conversion of a DC / DC converter occurring, The electric power generated by the solar power generation device 4 can be used effectively.

Next, a second embodiment will be described with reference to the drawings.
[Second Embodiment]
In the first embodiment, the case where the power output from the solar power generation device 4 is supplied to the DC supply line L1 without the DC / DC converter has been described. However, in the present embodiment, the DC / DC converter is provided. An example of bypassing the DC / DC converter will be described.

FIG. 4 is a block diagram illustrating an example of the DC power supply system 1b according to the present embodiment.
In this figure, the DC power supply system 1b includes a rectifier 3, a solar power generation device 4, a power supply control device 5a, a power storage device 6, a bidirectional DC / DC converter 7, a distribution board 8, and a switch unit 200 (201 to 203). , A current detection unit 301, a voltage detection unit 302, a PCS (power conditioner) 10, and a bypass switch unit 12.

The present embodiment differs from the first embodiment in that the voltage detection unit 302, the PCS 10, and the bypass switch unit 12 are provided, and the power supply control device 5a is provided instead of the power supply control device 5. A configuration different from those of the first embodiment will be described.
In this figure, the same components as those shown in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted.

The PCS 10 (power conditioner) converts the output voltage (first voltage) output from the solar power generation device 4 into a predetermined output voltage (second output voltage) that is determined in advance to the DC supply line L1. Output. The predetermined output voltage (second output voltage) set in advance is, for example, a DC 380 V system voltage output from the rectifier 3. The PCS 10 supplies the power generated by the solar power generation device 4 to the DC supply line L1 during normal times when the rectifier 3 supplies the DC power to the DC supply line L1, and the rectifier 3 supplies the DC supply line L1 to the DC supply line L1. Reduce the amount of power supplied.
The PCS 10 includes a DC / DC converter 11.

  The DC / DC converter 11 (an example of a converter) adjusts the direct current voltage (first output voltage) output from the solar power generation device 4 so that the output power of the solar power generation device 4 is maximized. In addition, the DC / DC converter 11 converts the direct-current voltage (first output voltage) output from the solar power generation device 4 into the predetermined output voltage (second output voltage) described above and converts the direct-current voltage (first output voltage). The DC voltage (second output voltage) is stabilized and output to the DC supply line L1. The DC / DC converter 11 is, for example, a boost converter (converter) for boosting the output voltage of the solar power generation device 4 and supplying power to the DC supply line L1. As described above, the DC / DC converter 11 has a function of maximum power point tracking (MPPT) of DC power output from the solar power generation device 4 and a function of stabilizing DC voltage.

The bypass switch unit 12 (switch unit) is connected between the output line of the solar power generation device 4 (input side of the DC / DC converter 11) and the DC supply line L1, and the direct current power output from the solar power generation device 4 Is supplied to the DC supply line L1 by bypassing the DC / DC converter 11.
The bypass switch unit 12 includes, for example, a semiconductor switch using a semiconductor switching element such as a thyristor or IGBT (Insulated Gate Bipolar Transistor), and the open / close state is controlled based on a control signal output from the power supply control device 5a. .
The voltage detection unit 302 detects the output voltage (first output voltage) output from the solar power generation device 4. Here, the first output voltage is a voltage on the input side (primary side) of the DC / DC converter 11. The voltage detection unit 302 outputs the detected output voltage (first output voltage) of the solar power generation device 4 to the power supply control device 5a.

The power supply control device 5 a is configured to control charging / discharging of the power storage device 6, control to set various setting information for operating the rectifying device 3, control of opening / closing states of the switch units 201 to 203, and the bypass switch unit 12. Control the open / close state of. The power supply control device 5 a outputs information indicating whether the bypass switch unit 12 is open or closed (information indicating whether the DC / DC converter 11 is bypassed) to the rectifier 3.
The power supply control device 5 a includes a power supply control unit 51 and a bypass control unit 52.

  When the output voltage (first output voltage) of the photovoltaic power generation device 4 detected by the voltage detection unit 302 is within a predetermined voltage range, the bypass control unit 52 The DC power output from the photovoltaic device 4 is controlled to bypass the DC / DC converter 11 and be supplied to the DC supply line L1. Here, the predetermined voltage range is a voltage range including the second output voltage, and is a voltage range determined based on an operating voltage range of the load device 90 to which DC power is supplied via the DC supply line L1. For example, it is a voltage range of DC 380V ± 20V (voltage range of 360V to 400V) which is a voltage in the operating voltage range of the load device 90. The bypass control unit 52 bypasses the DC / DC converter 11 to supply the DC power (voltage of 360V to 400V) output from the solar power generation device 4 to the DC supply line L1. In this case, since the predetermined voltage range is a voltage within the operating voltage range of the load device 90, the DC power supply system 1b can operate the load device 90 normally.

  In addition, when the bypass control unit 52 causes the bypass switch unit 12 to supply the DC power output from the photovoltaic power generation device 4 to the DC supply line L1 by bypassing the DC / DC converter 11, the DC / DC The converter 11 stops outputting a predetermined output voltage (second output voltage). In the following description, the control process for controlling whether to bypass the DC / DC converter 11 by controlling the open / close state of the bypass switch unit 12 may be referred to as “bypass control”.

  In addition, the power supply control part 34 of the rectifier 3 in this embodiment is a solar power generation device, when the bypass switch part 12 bypasses the DC / DC converter 11 and supplies DC power to the DC supply line L1. The output voltage is controlled so that the output power of 4 is maximized.

Here, specific control by the bypass control unit 52 will be described with reference to FIG.
FIG. 5 is a diagram illustrating an example of bypass control in the present embodiment.
In this figure, the graph shows the voltage on the input side of the DC / DC converter 11 (output voltage of the photovoltaic power generation apparatus 4) by the bypass control in this embodiment and the voltage on the output side of the DC / DC converter 11 (DC supply line). L1 voltage).
In this graph, the horizontal axis indicates the voltage on the input side of the DC / DC converter 11 (unit: [V]), and the vertical axis indicates the voltage on the output side of the DC / DC converter 11 (unit: [V]). Show.

  Further, in this figure, the voltage range R2 (the range from the voltage Vmin to the voltage Vmax) on the input side of the DC / DC converter 11 indicates the above-described predetermined voltage range, and the voltage range R1 and the voltage range R3 are the predetermined range. Indicates out of voltage range. A waveform W1 indicated by a solid line indicates a voltage waveform on the output side of the DC / DC converter 11 when the voltage on the input side of the DC / DC converter 11 is increasing, and a waveform W2 indicated by a broken line indicates a DC The voltage waveform on the output side of the DC / DC converter 11 when the voltage on the input side of the / DC converter 11 is decreasing (decreasing) is shown. In the example shown in this figure, the predetermined output voltage output from the DC / DC converter 11 is 380V.

As shown in FIG. 5, the bypass control unit 52 has a first threshold value (Vmin) in which the voltage (first output voltage) on the input side of the DC / DC converter 11 is higher than the lower limit value (Vmin) of the predetermined voltage range R2. Control that causes the bypass switch unit 12 to bypass the DC / DC converter 11 when Vth1) is equal to or higher than the second threshold value (Vth2) lower than the upper limit value (Vmax) of the predetermined voltage range R2. I do. In addition, the bypass control unit 52 has a bypass switch unit when the voltage (first output voltage) on the input side of the DC / DC converter 11 becomes lower than the lower limit (Vmin) or higher than the upper limit (Vmax). 12 is controlled to stop the bypass of the DC / DC converter 11.
The lower limit value (Vmin) and upper limit value (Vmax) of the predetermined voltage range R2, the first threshold value (Vth1), and the second threshold value (Vth2) are stored in a storage unit (not shown) as setting information. Assume that it is stored in advance.

  Specifically, for example, when the output voltage of the solar power generation device 4 increases and reaches the first threshold value (Vth1), the bypass control unit 52 controls the DC / DC converter 11 with respect to the bypass switch unit 12. To bypass. Further, the bypass control unit 52 causes the bypass switch unit 12 to stop bypassing the DC / DC converter 11 when the output voltage of the solar power generation device 4 further increases and reaches the upper limit value (Vmax). . Therefore, a predetermined output voltage (380 V) converted by the DC / DC converter 11 in the voltage range R1 and the voltage range R3 is output to the DC supply line L1 in the voltage range R1 and the voltage range R3, and the first threshold ( In the voltage range R22 from Vth1) to the upper limit value (Vmax), the output voltage of the solar power generation device 4 is output.

  Further, for example, the bypass control unit 52 bypasses the DC / DC converter 11 with respect to the bypass switch unit 12 when the output voltage of the photovoltaic power generation device 4 decreases and reaches the second threshold value (Vth2). Let Moreover, the bypass control part 52 stops the bypass of the DC / DC converter 11 with respect to the bypass switch part 12, when the output voltage of the solar power generation device 4 further falls and reaches a lower limit (Vmin). . Therefore, a predetermined output voltage (380 V) converted by the DC / DC converter 11 is output to the DC supply line L1 in the voltage range R1 and the voltage range R3 as shown in the waveform W2, and the lower limit value (Vmin) To the second threshold value (Vth2), the output voltage of the solar power generation device 4 is output.

  Thus, in the bypass control in the present embodiment, the bypass is stopped between the first threshold value (Vth1) to be bypassed and the lower limit value (Vmin) to stop the bypass, or the second threshold value (Vth2) to be bypassed. A predetermined voltage difference is provided between the upper limit value (Vmax) to be set. The predetermined voltage difference is determined in consideration of robustness against external factors such as noise. Thereby, the bypass control part 52 can improve the robustness with respect to external factors, such as a noise.

Next, the operation of the DC power supply system 1b in the present embodiment will be described with reference to the drawings.
Here, first, a bypass control procedure of the DC power supply system 1b (power supply control device 5a) will be described with reference to FIG.

FIG. 6 is a flowchart illustrating an example of a bypass control procedure in the present embodiment.
In FIG. 6, first, the bypass control unit 52 of the power supply control device 5a acquires the output voltage V1 of the solar power generation device 4 (step S201). That is, the bypass control unit 52 acquires the output voltage V1 (first output voltage) of the solar power generation device 4 detected by the voltage detection unit 302.

  Next, the bypass control part 52 performs a branch process based on the acquired value of the output voltage V1 of the solar power generation device 4 (step S202). That is, the bypass control unit 52 sets the acquired output voltage V1 and setting information (the above-described “lower limit value (Vmin), upper limit value (Vmax), first threshold value (Vth1), and second threshold value (Vth2)”). ) And a branch process is executed. For example, when the output voltage V1 is equal to or lower than the lower limit value (Vmin) (V1 ≦ lower limit value), the bypass control unit 52 advances the process to step S203 to release the bypass by the bypass switch unit 12 (stops the bypass). ). That is, the bypass control unit 52 opens the bypass switch unit 12 (off state) and stops the bypass of the DC / DC converter 11.

Further, the bypass control unit 52, for example, when the output voltage V1 is equal to or higher than the first threshold (Vth1) and equal to or lower than the second threshold (Vth2) (first threshold ≦ V1 ≦ second threshold). Then, the process proceeds to step S204, and the bypass switch unit 12 is bypassed. That is, the bypass control unit 52 closes the bypass switch unit 12 (on state) and bypasses the DC / DC converter 11.
For example, when the output voltage V1 is equal to or higher than the upper limit value (Vmax) (upper limit value ≦ V1), the bypass control unit 52 advances the process to step S205 and cancels the bypass by the bypass switch unit 12 (bypass Stop). That is, the bypass control unit 52 opens the bypass switch unit 12 (off state) and stops the bypass of the DC / DC converter 11.

For example, the bypass control unit 52 returns the process to step S201 in other cases where the output voltage V1 does not correspond to any of the above-described conditions.
Further, the bypass control unit 52 returns to step S201 after executing any one of steps S203 to S205.

In this way, the bypass control unit 52 performs the bypass control as shown in FIG. 5 by executing the processing shown in FIG.
In the above-described embodiment, the bypass control unit 52 acquires the output voltage V1 of the solar power generation device 4 at predetermined time intervals. The bypass controller 52 immediately determines (V1 ≦ lower limit value), (first threshold ≦ V1 ≦ second threshold), and (upper limit ≦ V1) based on the acquired output voltage V1. However, when these conditions are satisfied a predetermined number of times or for a predetermined period, control corresponding to each condition may be performed. By doing so, the bypass control unit 52 can further improve the robustness against external factors such as noise.

Next, operation | movement of the power supply control part 34 of the DC power supply system 1b (rectifier 3) in this embodiment is demonstrated with reference to FIG.
FIG. 7 is a flowchart showing an example of the operation of the rectifier 3 in the present embodiment.

  In FIG. 7, first, the power supply control unit 34 of the rectifier 3 determines whether or not the bypass switch unit 12 is in a closed state (step S301). That is, the power supply control unit 34 determines whether or not the DC / DC converter 11 is bypassed by the bypass switch unit 12 from the power supply control device 5a. The power supply control unit 34 is based on information indicating whether the bypass switch unit 12 is opened or closed (information indicating whether the DC / DC converter 11 is bypassed) output from the power supply control device 5a. It is determined whether 11 is bypassed. When the bypass switch unit 12 is in the closed state (bypassed) (step S301: YES), the power supply control unit 34 advances the process to step S302. Moreover, the power supply control part 34 advances a process to step S317, when the bypass switch part 12 is not a closed state (it is not bypassed) (step S301: NO).

In step S302, the power supply controller 34 acquires the output voltage of the rectifier 3 (the voltage of the DC supply line L1) as the start voltage. The power supply control unit 34 acquires the set voltage information set in the DC power supply unit 33, thereby acquiring the current output voltage of the rectifier 3 as the start voltage.
Note that the processing from step S302 to step S316 is the same as the processing from step S101 to step S115 shown in FIG. Thus, in this embodiment, the power supply control part 34 is the solar power generation device 4 when the bypass switch part 12 bypasses the DC / DC converter 11 and supplies DC power to the DC supply line L1. The process of controlling the output voltage of the rectifier 3 (the process from step S302 to step S316) is executed so that the output power of the current becomes maximum. After the process of step S316, the power supply control unit 34 ends the process.

In step S317, the power supply controller 34 sets the output voltage of the rectifier 3 to a predetermined voltage. That is, in the process of step S317, since the bypass switch unit 12 does not bypass the DC / DC converter 11, the output voltage of the rectifier 3 is set to a predetermined voltage (for example, a fixed voltage of 380 V). That is, in this case, since the bypass switch unit 12 does not bypass the DC / DC converter 11, the DC / DC converter 11 executes the process of maximizing the output power of the solar power generation device 4. Therefore, the power supply control unit 34 sets the output voltage of the rectifier 3 to a predetermined voltage.
In addition, after the process of step S316, the power supply control part 34 complete | finishes a process.
Moreover, the power supply control part 34 performs the process from above-mentioned step S301 to step S316 regularly for every predetermined time interval.

  As described above, the DC power supply system 1b according to the present embodiment further includes the DC / DC converter 11 (an example of a converter), the bypass switch unit 12 (an example of a switch unit), and the open / close state of the bypass switch unit 12. And a power supply control device 5 having a bypass control unit 52 that controls at least the above. The DC / DC converter 11 adjusts the output voltage (first output voltage) output from the solar power generation device 4 so that the output power of the solar power generation device 4 becomes maximum, and the output of the solar power generation device 4 The voltage is converted into a predetermined output voltage (second output voltage), and the converted output voltage is output to the DC supply line L1. The bypass switch unit 12 is connected between the output line of the solar power generation device 4 and the DC supply line L1, and bypasses the DC power output by the solar power generation device 4 from the DC / DC converter 11 to provide a DC supply line. To L1. The power supply control unit 34 maximizes the output power of the solar power generation device 4 when the bypass switch unit 12 bypasses the DC / DC converter 11 and supplies DC power to the DC supply line L1. In this way, the output voltage is controlled.

  Thus, in the DC power supply system 1b according to the present embodiment, when the DC / DC converter 11 is not bypassed, the DC / DC converter 11 adjusts the photovoltaic power generation device 4 to the maximum power, and the DC / DC converter 11 Is bypassed, the power supply controller 34 of the rectifier 3 adjusts the photovoltaic power generator 4 to the maximum power. Therefore, when the DC / DC converter 11 is bypassed, the DC power supply system 1b in the present embodiment appropriately supplies power to the DC supply line L1 without causing loss due to conversion of the DC / DC converter 11. Can do. Therefore, the DC power supply system 1b in the present embodiment can effectively use the power generated by the solar power generation device 4.

In the present embodiment, the DC power supply system 1b includes a voltage detection unit 302 that detects an output voltage (first output voltage) output from the solar power generation device 4. The bypass control unit 52 stops the operation of the DC / DC converter 11 when the output voltage detected by the voltage detection unit 302 is within a predetermined voltage range (for example, a range of 360 V to 400 V). The bypass control unit 52 causes the bypass switch unit 12 to supply the DC power output from the solar power generation device 4 to the DC supply line L1 by bypassing the DC / DC converter 11.
Thereby, within the predetermined voltage range of the output of the solar power generation device 4, the output of the solar power generation device 4 is supplied to the DC supply line L1 without going through the DC / DC converter 11. Therefore, the DC power supply system 1b according to the present embodiment can supply power to the DC supply line L1 within the predetermined voltage range described above without causing a loss due to the conversion of the DC / DC converter 11.

In the present embodiment, the predetermined voltage range (for example, voltage range R2) is a voltage range including the DC / DC converter 11 (second output voltage), and DC power is supplied via the DC supply line L1. The voltage range is determined based on the operating voltage range of the load device 90 to be supplied. The voltage range determined based on the operating voltage range of the load device 90 is, for example, a voltage range (for example, 360 V to 400 V) within the operating voltage range of the load device 90. The bypass control unit 52 has a predetermined voltage range in which the output voltage (first output voltage) of the photovoltaic power generation device 4 is equal to or higher than a first threshold value (Vth1) higher than the lower limit value (Vmin) of the predetermined voltage range. When the voltage is equal to or lower than the second threshold value (Vth2) lower than the upper limit value (Vmax), the bypass switch unit 12 is controlled to bypass the DC / DC converter 11. Further, the bypass control unit 52 sets the bypass switch unit 12 to the bypass switch unit 12 when the output voltage (first output voltage) of the solar power generation device 4 is lower than the lower limit (Vmin) or higher than the upper limit (Vmax). On the other hand, control for stopping the bypass of the DC / DC converter 11 is performed.
The predetermined voltage range described above is a voltage range lower than the predetermined voltage range among the voltage ranges that can be output from the solar power generation device 4, and the voltage range that does not bypass the DC / DC converter 11 (FIG. 5). Voltage range R1) and a voltage range higher than a predetermined voltage range and not bypassing the DC / DC converter 11 (voltage range R3 in FIG. 5).

Thereby, the photovoltaic power generation in which the DC / DC converter 11 is bypassed in a predetermined voltage range (for example, 360 V to 400 V within the operating voltage range of the load device 90) determined based on the operating voltage range of the load device 90. The output voltage (first output voltage) of the device 4 is output to the DC supply line L1. Then, outside the predetermined voltage range, the output voltage (second output voltage) of the DC / DC converter 11 is output to the DC supply line L1. Therefore, the power from the solar power generation device 4 is supplied to the DC supply line L <b> 1 by a voltage within the operating voltage range of the load device 90. Therefore, the DC power supply system 1b in the present embodiment can reduce the power loss due to the conversion of the DC / DC converter 11 while operating the load device 90 normally.
Further, the threshold values for bypassing (for example, the first threshold value (Vth1) and the second threshold value (Vth2)) and the threshold values for stopping bypassing (for example, the lower limit value (Vmin) and the upper limit value (Vmax)) are made different. Thus, the DC power supply system 1b in the present embodiment can improve the robustness against external factors such as noise in the bypass control.

Next, a third embodiment will be described with reference to the drawings.
[Third Embodiment]
In the second embodiment, an example in which the DC / DC converter 11 is bypassed has been described. In the present embodiment, another example in which the DC / DC converter 11 is bypassed will be described. That is, in the second embodiment, the DC / DC converter 11 is bypassed when the output voltage of the photovoltaic power generation device 4 is in a predetermined voltage range. However, in this embodiment, the AC from the commercial power supply system 2 is bypassed. When power is stopped, the DC / DC converter 11 is bypassed. In this case, the power control unit 34a of the rectifying device 3a adjusts the solar power generation device 4 to the maximum power.

FIG. 8 is a block diagram illustrating an example of the DC power supply system 1c according to the present embodiment.
In this figure, the DC power supply system 1c includes a rectifier 3a, a solar power generation device 4 (4-1, 4-2,...), A power supply control device 5b, a power storage device (6, 30), a bidirectional DC / DC converter 7, distribution board 8, switch unit 200 (201 to 203), current detection unit 301 (301-1, 301-2, ...), voltage detection unit 302, PCS10 (10-1, 10-2) ,..., And a bypass switch unit 12 (12-1, 12-2,...). In this figure, the same components as those shown in FIGS. 3 and 4 are denoted by the same reference numerals, and the description thereof is omitted.

In the present embodiment, an example in which the DC power feeding system 1c includes a plurality of solar power generation devices 4 will be described.
The PCS (10-1, 10-2,...) Has the same configuration as the PCS 10 shown in FIG. 4. If any PCS included in the DC power supply system 1c is indicated or not particularly distinguished, the PCS 10 Will be described. Similarly, the DC / DC converters (11-1, 11-2,...) Have the same configuration as the DC / DC converter 11 shown in FIG. When a DC converter is shown or not particularly distinguished, the DC / DC converter 11 will be described.
In addition, the bypass switch units (12-1, 12-2,...) Have the same configuration as the bypass switch unit 12 shown in FIG. 4, and indicate any bypass switch unit provided in the DC power supply system 1c. Or when not distinguished in particular, it will be described as the bypass switch unit 12.

  In the example illustrated in FIG. 8, the output power of the solar power generation device 4-1 is supplied to the DC supply line L <b> 1 via the PCS 10-1 or the bypass switch unit 12-1 and the output of the solar power generation device 4-2. The electric power is supplied to the DC supply line L1 via the PCS 10-2 or the bypass switch unit 12-2.

The power supply control device 5b includes charge / discharge control of the power storage device 6, control for setting various setting information for operating the rectifier 3a, control such as control of the open / close state of the switch units 201 to 203, and the bypass switch unit 12. Control the open / close state of. The power supply control device 5b outputs information indicating whether the bypass switch unit 12 is open or closed (information indicating whether the DC / DC converter 11 is bypassed) to the rectifying device 3a.
The power supply control device 5a includes a power supply control unit 51 and a bypass control unit 52a.

The bypass control unit 52a stops the operation of the DC / DC converter 11 when the AC power from the commercial power supply system 2 is stopped, and the DC power output from the solar power generation device 4 to the bypass switch unit 12 Is controlled to bypass the DC / DC converter 11 and to be supplied to the DC supply line L1. That is, when the AC power from the commercial power supply system 2 is stopped, the bypass control unit 52a causes the bypass switch unit 12 (12-1, 12-2, ...) to be in a closed state (on state), The DC / DC converter 11 (11-1, 11-2, ...) is bypassed. The bypass control unit 52a determines whether or not the AC power from the commercial power supply system 2 is stopped based on the signal Spf output from the rectifier 3a.
Moreover, the power feeding control unit 51 causes the bidirectional converter 7 to maintain the charging mode.

  The power storage device 30 is, for example, a storage battery that charges and discharges electric power, such as a lead storage battery or a lithium ion battery. The power storage device 30 is charged (accumulated) with electric power from the commercial power supply system 2 via the bidirectional DC / AC converter 35 during normal times when AC power from the commercial power supply system 2 is supplied. The power storage device 30 supplies the stored power to the DC power supply unit 33 via the bidirectional DC / AC converter 35 when the commercial power supply system 2 is in a power failure state. That is, the power storage device 30 supplies power to the rectifying device 3a when the AC power from the commercial power supply system 2 is stopped.

The rectifier 3a is a DC power supply that converts AC power from the commercial power supply system 2 that is an AC power source into DC power, and outputs the converted DC power to the DC supply line L1. The rectifier 3a outputs DC power to the DC supply line L1 based on the power supplied from the power storage device 30 when the AC power from the commercial power supply system 2 is stopped. A detection unit 31, a switch unit 32, a DC power supply unit 33, a power supply control unit 34a, and a bidirectional DC / AC converter 35 are provided.

  The DC power supply unit 33 converts AC power from the commercial power supply system 2 or the bidirectional DC / AC converter 35 into DC power (for example, DC 380V system), and outputs the converted DC power to the DC supply line L1. The output voltage output from the DC power supply unit 33 is controlled by the power supply control unit 34a.

  Bidirectional DC / AC converter 35 converts AC power of commercial power supply system 2 into DC power based on the control of power supply control unit 34 a and charges power storage device 30 with power. Bidirectional DC / AC converter 35 converts DC power output from power storage device 30 into AC power based on the control of power supply control unit 34a when AC power from commercial power supply system 2 is stopped. Then, the converted AC power is supplied to the DC power supply unit 33.

The power supply control unit 34a controls the DC power supply unit 33 and the bidirectional DC / AC converter 35, and when the detection unit 31 detects a power failure in the commercial power supply system 2, the switch unit 32 is opened and the commercial power supply system is turned on. 2, the rectifier 3a is disconnected. In addition, when the power supply control unit 34 a detects a power failure of the commercial power supply system 2 by the detection unit 31, the power supply unit 34 a supplies the power stored (charged) in the power storage device 30 via the bidirectional DC / AC converter 35. To supply. Moreover, the power supply control part 34a outputs the signal Spf which shows whether the commercial power supply system 2 is a power failure state.
Moreover, the power supply control part 34a changes the output voltage output to DC supply line L1, and performs the maximum power point tracking control which controls so that the output power of the solar power generation device 4 may become the maximum. The details of this maximum power point tracking control are the same as in the second embodiment.

Next, the operation of the DC power supply system 1c in the present embodiment will be described with reference to the drawings.
Here, first, a bypass control procedure of the DC power supply system 1c (power supply control device 5b) will be described with reference to FIG.

FIG. 9 is a flowchart showing an example of a bypass control procedure in the present embodiment.
In FIG. 9, first, the bypass control unit 52a of the power supply control device 5b determines whether or not the commercial power supply system 2 is in a power failure state (step S401). That is, the bypass control unit 52a determines whether or not the AC power from the commercial power supply system 2 is stopped based on the signal Spf output from the rectifier 3a. If the commercial power supply system 2 is in a power failure state (step S401: YES), the bypass control unit 52a advances the process to step S402. Further, when the commercial power supply system 2 is not in a power failure state (step S401: NO), the bypass control unit 52a advances the process to step S403.

  In step S402, the bypass control unit 52a causes the bypass switch unit 12 to bypass. That is, the bypass control unit 52a closes the bypass switch unit 12 (12-1, 12-2,...) (On state), and the DC / DC converter 11 (11-2, 11-2,. ...) is bypassed. Further, the bypass control unit 52a stops the operation of the DC / DC converter 11 (11-2, 11-2,...). After the process of step S402, the bypass control unit 52a returns the process to step S401.

  In step S403, the bypass control unit 52a releases the bypass by the bypass switch unit 12 (stops the bypass). That is, the bypass control unit 52a opens the bypass switch unit 12 (12-1, 12-2,...) (Off state) and the DC / DC converter 11 (11-2, 11-2,. ...) Bypass is stopped. Further, the bypass control unit 52a starts the operation of the DC / DC converter 11 (11-2, 11-2,...). After the process of step S403, the bypass control unit 52a returns the process to step S401.

  As described above, the DC power supply system 1c (power supply control device 5b) in the present embodiment has the DC / DC converter 11 (11-2, 11-2,...) When the commercial power supply system 2 is in a power failure state. Bypass control to bypass

Next, operation | movement of the power supply control part 34a of the DC power supply system 1c (rectifier 3a) in this embodiment is demonstrated.
Since the maximum power point follow-up control for controlling the output power of the photovoltaic power generation device 4 by the power supply control unit 34a to be maximized is the same as in the second embodiment shown in FIG. Description is omitted.
The power controller 34 a of the rectifier 3 a uses the power stored (charged) in the power storage device 30 via the bidirectional DC / AC converter 35 when the detection unit 31 detects a power failure in the commercial power system 2. The DC power supply unit 33 is supplied. Thereby, rectifier 3a outputs DC power to DC supply line L1 based on the electric power supplied from power storage device 30.

As described above, the DC power supply system 1c according to the present embodiment includes the power storage device 30 that supplies power to the rectifier 3a when the AC power from the commercial power supply system 2 is stopped. And the bypass control part 52a stops the operation | movement of the DC / DC converter 11, and the solar power generation device 4 outputs with respect to the bypass switch part 12, when the alternating current power from the commercial power supply system 2 stops. Control is performed so that the DC power is supplied to the DC supply line L1 by bypassing the DC / DC converter 11. The rectifier 3a outputs DC power to the DC supply line L1 based on the power supplied from the power storage device 30 when AC power from the commercial power supply system 2 is stopped, and the second embodiment. The same maximum power point tracking control is performed.
Thereby, the DC power supply system 1c in the present embodiment can reduce the power loss due to the conversion of the DC / DC converter 11 at the time of a power failure of the commercial power supply system 2, for example. Can be adjusted to maximum power. Therefore, the DC power supply system 1c in the present embodiment can effectively use the power generated by the solar power generation device 4 at the time of a power failure of the commercial power supply system 2, for example.

The present invention is not limited to the above embodiments, and can be modified without departing from the spirit of the present invention.
For example, although each of the above embodiments has been described with respect to a case where the above embodiments are implemented independently, the above embodiments may be combined. For example, the DC power supply system 1b according to the second embodiment includes a plurality of photovoltaic power generation apparatuses 4, a plurality of current detection units 301, a plurality of voltage detection units 302, a plurality of PCBs 10, and a plurality of bypass switch units 12. It may be.
Further, for example, in the third embodiment, the DC power supply system 1c performs the bypass control according to the second embodiment and the maximum power point tracking control by the power storage device 30 at the normal time when the commercial power supply system 2 is not interrupted. May be.

  Further, in each of the embodiments described above, the power supply control unit 34 (34a) has been described with respect to an example in which the maximum power point tracking control is periodically performed at predetermined time intervals. However, the present invention is not limited to this. For example, the power supply control unit 34 (34 a) may execute the maximum power point tracking control when the output power of the solar power generation device 4 changes or when the power consumption of the load device 90 changes. Further, the power supply controller 34 (34a) constantly changes the output voltage of the rectifier 3 (3a) by a voltage ΔV in the direction in which the output power of the photovoltaic power generator 4 increases in the operating voltage range of the load device 90. The maximum power point tracking control may be executed.

In each of the above embodiments, the DC power supply system 1 (1a, 1b, 1c) has been described with respect to the configuration including the power storage device 6 and the bidirectional DC / DC converter 7. However, the power storage device 6 and the bidirectional DC / DC are described. A configuration without the converter 7 may also be used. Further, although the bidirectional DC / DC converter 7 has been described as a configuration that includes a switch inside and can disconnect (disconnect) the DC supply line L1 and the power storage device 6, the bidirectional DC / DC converter 7 is bidirectional with the DC supply line L1. The switch unit 200 may be provided between the DC / DC converter 7 and the DC / DC converter 7.
Further, the DC power supply system 1 (1a, 1b, 1c) includes a switch unit 200 between the solar power generation device 4 and the DC power supply line L1, and selectively selects the solar power generation device 4 from the DC power supply line L1. You may make it the structure which can be disconnected.

Moreover, in each said embodiment, although the rectifier 3 (3a) demonstrated the case where alternating current power was directly supplied from the commercial power system 2, the rectifier 3 (3a) is a power receiving installation including a transformer. AC power may be supplied through the power supply.
Further, in each of the embodiments described above, the case where power is supplied to the load device 90 via the distribution board 8 and the switch unit 200 has been described. However, the load is not provided via the distribution board 8 and / or the switch unit 200. Electric power may be supplied to the device 90.
Further, in each of the above embodiments, the case where the bypass switch unit 12 and the power supply control device 5 (5a, 5b) are provided outside the PCS 10 has been described. However, the bypass switch unit 12 and / or the power supply control device 5 (5a) are provided. 5b) may be included in the PCS 10.

  Moreover, in 3rd Embodiment, the rectifier 3a is provided with the bidirectional | two-way DC / AC converter 35, and the rectifier 3a is a power storage device via the bidirectional DC / AC converter 35 at the time of a power failure of the commercial power supply system 2. Although the case where the maximum power point tracking control is performed based on the power of 30 has been described, the present invention is not limited to this. For example, the rectifier 3 a supplies the DC power of the power storage device 30 to a DC power output unit (for example, a DC / DC converter unit not shown) inside the DC power supply unit 33, and based on the power of the power storage device 30. Thus, the maximum power point tracking control may be performed.

Further, in each of the above embodiments, the case where the rectifier 3 (3a) performs the maximum power point tracking control has been described. However, when the bidirectional DC / DC converter 7 is in the power failure of the commercial power system 2, the maximum power point is determined. The form which performs tracking control may be sufficient.
In each of the above embodiments, the case where the rectifier 3 (3a) that converts AC power from the commercial power supply system 2 to DC power is used as an example of the DC power supply device has been described. Other power supply devices may be used as long as they can output DC power and change the output voltage.

Note that a program for realizing the functions of each component included in the DC power feeding system 1 (1a, 1b, 1c) in the present invention is recorded on a computer-readable recording medium, and the program recorded on the recording medium is stored in the computer. You may perform the process in each structure with which direct-current electric power feeding system 1 (1a, 1b, 1c) mentioned above is provided by making a system read and run. Here, “loading and executing a program recorded on a recording medium into a computer system” includes installing the program in the computer system. The “computer system” here includes an OS and hardware such as peripheral devices.
Further, the “computer system” may include a plurality of computer devices connected via a network including a communication line such as the Internet, WAN, LAN, and dedicated line. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. As described above, the recording medium storing the program may be a non-transitory recording medium such as a CD-ROM.

  The recording medium also includes a recording medium provided inside or outside that is accessible from the distribution server in order to distribute the program. A distribution server that divides a program into a plurality of parts and downloads them at different timings and combines them with each component included in the DC power supply system 1 (1a, 1b, 1c) or a distribution server that distributes each of the divided programs. May be different. Furthermore, the “computer-readable recording medium” holds a program for a certain period of time, such as a volatile memory (RAM) inside a computer system that becomes a server or a client when the program is transmitted via a network. Including things. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.

  Moreover, you may implement | achieve part or all of the function mentioned above as integrated circuits, such as LSI (Large Scale Integration). Each function described above may be individually made into a processor, or a part or all of them may be integrated into a processor. Further, the method of circuit integration is not limited to LSI, and may be realized by a dedicated circuit or a general-purpose processor. In addition, when an integrated circuit technology that replaces LSI appears due to the advancement of semiconductor technology, an integrated circuit based on the technology may be used.

DESCRIPTION OF SYMBOLS 1, 1a, 1b, 1c DC power supply system 2 Commercial power supply system 3 Rectifier 4 4-1 4-2 Photovoltaic power generator 5, 5a, 5b Power supply control device 6, 30 Power storage device 7 Bidirectional DC / DC converter 8 Distribution board 10, 10-1, 10-2 Power conditioner (PCS)
11, 11-1, 11-2 DC / DC converter 12, 12-1, 12-2 Bypass switch part 31 Detection part 32, 200, 201, 202, 203 Switch part 33 DC power supply part 34, 34a Power supply control part 35 Bidirectional DC / AC converters 41, 41-1, 41-2 Solar cell array 42, 42-1, 42-2 Diode 51 Power supply control unit 52, 52a Bypass control unit 90, 91, 92, 93 Load devices 301, 301 -1, 301-2 Current detection unit 302 Voltage detection unit

Claims (9)

AC power from a commercial power system is converted to DC power, the converted DC power is output to a DC supply line, and the DC power supply is supplied to the load device via the DC supply line;
A solar power generation device that generates direct-current power using sunlight and outputs the generated direct-current power to the direct-current supply line via a diode;
A current detection unit for detecting a current output from the solar power generation device,
The DC power supply is
A power supply control unit that changes an output voltage to be output to the DC supply line and controls the output power of the photovoltaic power generation device based on the current detected by the current detection unit and the output voltage to be maximized; A direct current power supply system comprising: The power control unit
The control is performed so that the output power of the photovoltaic power generator is maximized by changing the output voltage within an operating voltage range of the load device to which the DC power is supplied. DC power supply system. The first output voltage output from the photovoltaic power generator is adjusted so that the output power of the photovoltaic power generator is maximized, and the first output voltage is converted to a predetermined second output voltage. A converter that outputs the converted second output voltage to the DC supply line;
A switch unit connected between an output line of the solar power generation device and the DC supply line, and supplying the DC power output from the solar power generation device to the DC supply line by bypassing the converter; ,
A power supply control device having a bypass control unit that controls at least an open / close state of the switch unit,
The power control unit
When the switch unit bypasses the converter and supplies the DC power to the DC supply line, the output voltage is controlled so that the output power of the photovoltaic power generator is maximized. The DC power supply system according to claim 1 or 2, wherein A voltage detection unit for detecting the first output voltage output by the solar power generation device;
The bypass control unit
When the first output voltage detected by the voltage detection unit is within a predetermined voltage range, the operation of the converter is stopped and the photovoltaic power generation device outputs to the switch unit. The DC power supply system according to claim 3, wherein the DC power to be supplied is supplied to the DC supply line by bypassing the converter. The predetermined voltage range is a voltage range including the second output voltage, and is a voltage range determined based on an operating voltage range of the load device to which the DC power is supplied via the DC supply line. And
The bypass control unit
The conversion is performed when the first output voltage is equal to or higher than a first threshold value that is higher than the lower limit value of the predetermined voltage range and lower than or equal to a second threshold value that is lower than the upper limit value of the predetermined voltage range. Stop the operation of the device and perform control to bypass the converter to the switch unit,
When the first output voltage is equal to or lower than the lower limit value or equal to or higher than the upper limit value, the converter is operated and the switch unit is controlled to stop bypassing the converter. The DC power feeding system according to claim 4, wherein: When AC power from the commercial power supply system is stopped, a power storage device that supplies power to the DC power supply device,
The bypass control unit
When the AC power from the commercial power supply system stops, the operation of the converter is stopped, and the DC power output from the photovoltaic power generator is bypassed to the converter with respect to the switch unit. Control to supply to the DC supply line,
The DC power supply is
6. The DC power is output to the DC supply line based on the power supplied from the power storage device when AC power from the commercial power supply system is stopped. The DC power supply system according to any one of the above. A plurality of the solar power generation devices, and a plurality of the current detection units corresponding to each of the plurality of solar power generation devices,
The power control unit
The output voltage output to the DC supply line is changed, and control is performed so that the sum of the output powers of the plurality of the solar power generation devices becomes maximum. 7. The direct current power supply system according to item. A DC power supply that converts AC power from a commercial power supply system to DC power, outputs the converted DC power to a DC supply line, and supplies the DC power to a load device via the DC supply line,
Current detection for detecting the current output from the photovoltaic power generation apparatus that outputs the DC power generated using sunlight by changing the output voltage output to the DC supply line to the DC supply line via a diode A direct-current power supply device comprising: a power supply control unit that controls the output voltage so that the output power of the photovoltaic power generation device based on the current detected by the unit and the output voltage is maximized. AC power from a commercial power system is converted into DC power, the converted DC power is output to a DC supply line, and supplied to the load device via the DC supply line; A power supply control method in a DC power supply system including a photovoltaic power generation device that generates electric power and outputs the generated DC power to the DC supply line via a diode,
The direct current power supply device changes the output voltage output to the direct current supply line, and the solar based on the current and the output voltage detected by the current detection unit that detects the current output by the solar power generation device A power supply control method comprising: a power supply control step for controlling the output power of the photovoltaic power generation device to become maximum.

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