JP2011076444A - Power distribution device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power distribution device efficiently extracting power from a solar cell even when distributing DC power from the solar cell. <P>SOLUTION: A potential on the output side of a first converter 55 is regulated (fixed) by a battery 20. Since the potential is regulated, solar cell power Ppv input from the solar cell 3 is determined through the control of an output current Iout of the first converter 55. In the first converter 55, the input power Ppv and the output power Pout are almost equal. Thereby, the first converter 55 can determine the solar cell power Ppv (input power) through output side current control. By changing the solar cell power Ppv, a solar cell voltage Vpv also can be determined. Consequently, the first converter 55 can obtain power from the solar cell 3 at high efficiency by setting the solar cell voltage Vpv to a maximum output voltage through the output side current control. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a power distribution apparatus that supplies power from a power system to a load.

  In recent years, solar power generation systems that generate power using sunlight, which is a kind of renewable energy, are becoming popular. The solar power generation system includes a power distribution device that converts electric power generated by the solar battery into appropriate electric power and supplies the electric power to various loads. Conventionally, for example, a configuration disclosed in Patent Document 1 has been adopted as a photovoltaic power generation system including a power distribution device. That is, as shown in FIG. 7, the system includes a solar cell 101 that converts light energy from the sun into electric energy (DC power), and an inverter 103 that converts DC power generated by the solar cell 101 into AC power. And a commercial power source 108 that supplies AC power to the load 105 in linkage with the inverter 103.

  The inverter 103 is a current control type that can control the output current. Therefore, maximum output operating point tracking control by the inverter 103 (hereinafter, abbreviated as “MPPT (Maximum Power Point Tracking) control”) becomes possible. The MPPT control is control that maximizes the output power of the solar cell 101 by controlling the output current from the inverter 103.

  Specifically, there is a characteristic shown in the graph of FIG. 6 between the solar cell voltage Vpv and the solar cell power Ppv output from the solar cell 101. Here, the solar cell voltage Vpv and the solar cell power Ppv are the input voltage and the input power applied from the solar cell 101 to the inverter 103. In consideration of the above characteristics, high-efficiency solar power generation is possible by supplying the inverter 103 with the solar cell power Ppv that is the maximum output power Pmax that is the maximum value of the solar cell power Ppv, that is, the maximum output voltage Vmp. .

Hereinafter, a control method for setting the solar cell voltage Vpv to the maximum output voltage Vmp will be described.
A voltage Vout is applied to an output power line 109 that supplies power from the inverter 103 to the load 105 and the commercial power supply 108 side. The output voltage Vout from the inverter 103 is determined based on the voltage applied by the commercial power supply 108. Here, the inverter 103 can control the output current i as described above. Therefore, the inverter 103 can control the output power Pout obtained by the product of the output current i and the voltage Vout through the control of the output current i. Here, the solar cell power Ppv corresponding to the input power of the inverter 103 is equal to the output power Pout of the inverter 103 if various power losses due to the inverter 103 and the like are ignored. Therefore, the inverter 103 can change the solar cell power Ppv, in other words, the solar cell voltage Vpv, which is its parameter, through the control of the output current i. Therefore, the maximum output power Pmax can be output from the solar cell 101 by setting the solar cell voltage Vpv to the maximum output voltage Vmp.

JP 2003-284355 A

  By the way, the solar power generation system disclosed in Patent Document 1 supplies AC power to the load 105. However, in recent years, attention has been focused on the system that supplies DC power to the load 105 without converting DC power into AC power from the viewpoint of power supply efficiency and the like.

  In this direct-current power supply type solar power generation system, a converter 106 is provided between the solar cell 101 and the load 105 as shown in FIG. Converter 106 converts the DC voltage from solar cell 101 into DC voltage Vout suitable for operating load 105. Here, the resistance value varies depending on the power usage state of the load 105. Depending on the load resistance value of the load 105, the output current and output voltage of the inverter 103, and hence the output power Pout, are determined. As a result, the solar cell power Ppv and the solar cell voltage Vpv supplied to the inverter 103 are also determined, and thus cannot be controlled. Therefore, the MPPT control in which the solar cell voltage Vpv is set to the maximum output voltage Vmp cannot be performed by the converter 106.

  If the MPPT control is not possible, the following is assumed. For example, as shown in FIG. 6, when the solar cell power Ppv becomes the voltage V1 due to the power usage state of the load 105, when the solar cell 101 outputs the power P1, the maximum possible output of the solar cell 101 is The output power Pmax cannot be output, and only “maximum output power Pmax−power P1” is lost.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a power distribution device that can more efficiently extract power from a solar cell when distributing DC power from the solar cell. is there.

Hereinafter, means for achieving the above-described object and its operation and effects will be described.
According to a first aspect of the present invention, in a power distribution apparatus provided in a DC power system in which DC power is supplied from a solar battery to a DC load via a DC wiring, the power distribution apparatus is provided on the DC wiring and input from the solar battery. Is connected between the first DC-DC converter and the DC load in the DC wiring, and is connected to the DC wiring. A battery that regulates a potential by applying a voltage; and a control unit that outputs a command signal for controlling an output current of the converter to the first DC-DC converter, wherein the first DC-DC converter includes: The gist of the invention is to control the electric power input from the solar cell through the control of the output current based on the command signal from the control unit. .

  According to this configuration, the battery regulates (fixes) the potential on the output side (DC load side) of the first DC-DC converter. Thus, the electric power input from a solar cell is determined through control of the output current of a 1st DC-DC converter because an electric potential is prescribed | regulated. In the first DC-DC converter, the input / output power is substantially equal. Therefore, the first DC-DC converter can determine the input power through current control on the output side based on the command signal from the control unit. Moreover, since the input power is a function of the input voltage, the input voltage can be determined by changing the input power.

  Here, as an output characteristic of the solar cell, there is a maximum output voltage value that outputs maximum power, that is, generates power most efficiently. The output power of the solar cell is the input power of the first DC-DC converter. Therefore, the first DC-DC converter uses the current on the output side based on the command signal from the control unit to set the input voltage of the first DC-DC converter to the maximum output voltage value, so that power can be efficiently obtained from the solar cell. Obtainable.

  According to a second aspect of the present invention, in the power distribution device according to the first aspect of the present invention, the power distribution device includes battery protection means for controlling a current supplied to the battery, and a value of the current supplied to the battery is supplied to the battery. Is detected to be equal to or greater than a threshold value set based on the maximum allowable value, the battery protection means uses the same current so that the value of the current supplied to the battery is less than the threshold value. The gist is to reduce it.

According to this configuration, the battery protection means prevents an excessive current flow that leads to a battery failure. Therefore, a more secure power distribution apparatus can be provided.
According to a third aspect of the present invention, in the power distribution device according to the second aspect, the battery protection unit includes a current measurement unit that detects a current supplied to the battery, and the control unit includes the current measurement unit. When it is determined that the value of the current supplied to the battery is equal to or greater than the threshold value based on the detection result of the above, a command signal for reducing the output current is output to the first DC-DC converter. The gist is to do.

  According to this configuration, the battery current is detected by the current measurement unit, and the detection result is output to the control unit. The control unit outputs a command signal for reducing the output current to the first DC-DC converter when it is determined that the battery is supplied with a current exceeding the threshold value based on the detection result of the current measuring unit. . Therefore, the output current from the first DC-DC converter decreases, and accordingly, the current supplied to the battery becomes less than the threshold value. Therefore, an excessive current flowing into the battery that leads to a failure is prevented.

  According to a fourth aspect of the present invention, in the power distribution apparatus according to any one of the first to third aspects, the direct current system supplies direct current power from a fuel power generation means using depletion energy in addition to the solar cell. The direct current load can be supplied, and the fuel power generation means is connected between the first DC-DC converter and the battery in the DC wiring, and converts the electric power from the fuel power generation means into an appropriate electric power. A second DC-DC converter for supplying a direct current load, wherein the control unit has priority over the first DC-DC converter when it is detected that the value of the current supplied to the battery is greater than or equal to the threshold value; The gist of the invention is to output a command signal for reducing the output current to the second DC-DC converter.

  According to this configuration, the control unit can adjust the amount of power supplied from each of the fuel power generation means and the solar cell to the DC load through command signals to both converters. The control unit outputs a command signal for decreasing the output current to the second DC-DC converter in preference to the first DC-DC converter when the battery is supplied with a current equal to or higher than the threshold value. For this reason, while the electric power from a solar cell is used actively, the electric power from a fuel electric power generation means is suppressed and the consumption of fuel can be suppressed.

  According to a fifth aspect of the present invention, in the power distribution apparatus according to any one of the first to fourth aspects, the DC wiring is supplied with AC power from an AC power source to an AC load via the AC wiring. A system is linked, an AC-DC connection line connecting the DC wiring and the AC wiring, and AC power from the AC wiring provided on the AC-DC connection line to DC power, from the DC wiring The gist of the present invention is to include a bidirectional converter that converts DC power into AC power.

  According to the same configuration, AC power is converted into DC power by transmitting AC power to DC wiring, or DC power is converted into AC power by AC-DC connection line and a bidirectional converter provided in the connection line. Or send electricity to Here, since direct-current power is generated by the solar cell, it can be supplied to the direct-current load without being converted into alternating current. Therefore, power loss related to conversion can be reduced, and power transmission efficiency is good. However, since power generation by solar cells depends on time and weather, it is difficult to supply stable power to a DC load. On the other hand, for AC power, for example, stable power transmission from an electric power company can be expected. In that respect, in the above configuration, when sufficient power generation cannot be performed by the solar battery, AC power can be converted into DC power and supplied to the DC load, and thus power can be stably supplied to the DC load. Conversely, when the amount of power generated by the solar cell exceeds the amount of power used by the DC load, the DC power is converted to AC power and supplied to the AC load or sold to the power company that is the AC supply source. I can do electricity. Thereby, the effective use of surplus electric power is promoted, for example, the electric bill of an electric power company can be reduced.

  According to a sixth aspect of the present invention, in the power distribution device according to any one of the first to fifth aspects, a plurality of the batteries are connected to the DC wiring, and an operation mode of these batteries is changed to a charging mode and a discharging mode. Switching means for switching between, wherein at least one of the plurality of batteries is set to a discharge mode, and at least one of the plurality of batteries is set to a charge mode, the battery in the discharge mode The battery is discharged while prescribing the potential of the DC wiring, and the gist of the battery in the charging mode is charging the surplus power of the power used by the DC load with respect to the supplied power.

  According to this configuration, the potential of the DC wiring on the output side of the first DC-DC converter is defined by the discharge of the battery in the discharge mode. Therefore, as described above, the first DC-DC converter can obtain the maximum output power from the solar cell by performing current control based on the command signal from the control unit. Here, it is assumed that the power generation amount of the solar cell exceeds the usage amount of the DC load. In this case, the battery in the charging mode charges the surplus power that is not used by the DC load. In this way, by connecting a plurality of batteries to the DC wiring, surplus power can be effectively charged and power loss can be reduced.

  According to a seventh aspect of the present invention, in the power distribution apparatus according to any one of the first to sixth aspects, the power distribution device connected to the DC wiring and transmitting power supplied to the DC wiring to a power selling destination. An electric power distribution rule, a battery remaining amount detecting means for detecting the remaining amount of the battery, and a power sale rule that is stored in the control unit and that indicates power supplied to the electric power sale wiring based on the remaining amount of the battery. And the control unit supplies the power determined based on the detection result of the battery remaining amount detection means to the power selling wiring with reference to the power selling rule.

  According to this configuration, the power to be sold is determined based on the remaining battery level with reference to the power sale rule. For example, when the battery is almost fully charged, the power is actively sold, and when the remaining amount of the battery is low, the battery is charged without selling. In this way, by determining the power sale rule corresponding to the remaining battery level, the power can be used more effectively.

  ADVANTAGE OF THE INVENTION According to this invention, when distributing DC power from a solar cell in a power distribution apparatus, electric power can be taken out from a solar cell more efficiently.

The block diagram which shows the structure of the electric power supply system in 1st Embodiment. The block diagram which expanded a part of FIG. 1 in 1st Embodiment. The block diagram which shows the structure of the converter in 1st Embodiment. The flowchart which shows the process sequence of the electric power feeding program in 1st Embodiment. The block diagram which expanded a part of FIG. 1 in 2nd Embodiment. The graph which shows a solar cell voltage-solar cell power characteristic. The block diagram which shows the structure of the solar energy power generation system provided with the conventional alternating current power distribution apparatus. The block diagram which shows the structure of the solar energy power generation system provided with the conventional direct-current power distribution device.

(First embodiment)
Hereinafter, a first embodiment in which a power distribution apparatus according to the present invention is embodied in a power supply system will be described with reference to FIGS. 1 to 6.

  As shown in FIG. 1, a house is provided with a power supply system 1 that supplies power to various devices (such as lighting devices, air conditioners, home appliances, and audiovisual devices) installed in the house. The power supply system 1 includes various devices such as a household commercial AC power source (AC power source) 2, a solar cell 3 power generated by sunlight, and a fuel cell 16 generated by a chemical reaction of substances. To supply. The power supply system 1 also supplies power to an AC device 6 that operates by inputting an AC power supply (AC power supply) in addition to the DC device 5 that operates by inputting a DC power supply (DC power supply).

  The power supply system 1 is provided with a control unit 7 and a DC distribution board (built-in DC breaker) 8 as its distribution board. The power supply system 1 is provided with a control unit 9 and a relay unit 10 as devices for controlling the operation of the DC device 5 in the house.

  An AC distribution board 11 for branching an AC power supply is connected to the control unit 7 via a cross flow connection line 12. The AC power distribution panel 11 is connected to an AC power source 2 and an AC device 6 via an AC power line 23. Note that the AC power line 23 between the AC distribution board 11 and the AC power source 2 corresponds to power sale wiring. A solar cell 3 is connected to the control unit 7 via a DC power line 13 and a fuel cell 16 is connected via a DC power line 15. The control unit 7 takes in AC power from the AC distribution board 11 and DC power from the solar cell 3 and the fuel cell 16 and converts these powers into predetermined DC power as a device power source. Then, the control unit 7 outputs the converted DC power to the DC distribution board 8 via the DC power line 14. The control unit 7 not only takes in AC power, but also converts the power of the solar cell 3 and the fuel cell 16 into AC power and supplies it to the AC distribution board 11. Further, the control unit 7 exchanges data with the DC distribution board 8 via the signal line 17. Further, a battery 20 is connected to the DC power line 14 via a battery connection line 21 in order to regulate the potential of the DC power line 14.

  The DC distribution board 8 is a kind of breaker that supports DC power. The DC distribution board 8 branches the DC power input from the control unit 7 and outputs the branched DC power to the control unit 9 via the DC power line 18 or relays via the DC power line 19. Or output to the unit 10. The DC distribution board 8 exchanges data with the control unit 9 through the signal line 44 and exchanges data with the relay unit 10 through the signal line 45.

  A plurality of DC devices 5 are connected to the control unit 9. These DC devices 5 are connected to the control unit 9 via a DC supply line 22 that can carry both DC power and data by a pair of lines. The DC supply line 22 superimposes a communication signal for transmitting data with a high-frequency carrier wave on a DC voltage serving as a power source for the DC device, so that both power and data are transferred to the DC device 5 through a pair of lines. Transport. The control unit 9 acquires the DC power supply of the DC device 5 via the DC power line 18 and controls which DC device 5 based on the operation command obtained from the DC distribution board 8 via the signal line 44. Know what to do. Then, the control unit 9 controls the operation of the DC device 5 by outputting a DC voltage and an operation command to the instructed DC device 5 via the DC supply line 22.

  A switch 43 that is operated when switching the operation of the DC device 5 in the house is connected to the control unit 9 via the DC supply line 22. In addition, a sensor 24 that detects a radio wave transmitted from an infrared remote controller, for example, is connected to the control unit 9 via a DC supply line 22. Therefore, not only the operation instruction from the DC distribution board 8 but also the operation of the switch 43 and the detection of the sensor 24, a communication signal is sent to the DC supply line 22 to control the DC device 5.

  A plurality of DC devices 5 are connected to the relay unit 10 via individual DC power lines 25, respectively. The relay unit 10 acquires the DC power supply of the DC device 5 via the DC power line 19 and determines which DC device 5 is to be operated based on an operation command obtained from the DC distribution board 8 via the signal line 45. To grasp. The relay unit 10 controls the operation of the DC device 5 by turning on / off the power supply to the DC power line 25 with respect to the instructed DC device 5 using a built-in relay. In addition, a plurality of switches 46 for manually operating the DC device 5 are connected to the relay unit 10. By turning on / off the power supply to the DC system power line 25 by the operation of the switch 46, the DC is performed. The device 5 is controlled.

  The DC distribution board 8 is connected to a DC outlet 27 built in a house in the form of a wall outlet or a floor outlet, for example, via a DC power line 28. If a plug (not shown) of a DC device is inserted into the DC outlet 27, DC power can be directly supplied to the device.

  Further, between the AC distribution board 11 and the AC power supply 2, a power meter 29 capable of remotely measuring the amount of use of the AC power supply 2 is connected. The power meter 29 is equipped with not only a function of remote meter reading of the amount of commercial power used, but also a function of power line carrier communication and wireless communication, for example. The power meter 29 transmits the meter reading result to an electric power company or the like via power line carrier communication or wireless communication.

  The power supply system 1 is provided with a network system 30 that enables various devices in the home to be controlled by network communication. The network system 30 is provided with a home server 31 as a control unit of the system 30. The home server 31 is connected to a management server 32 outside the home via a network N such as the Internet, and is connected to a home device 34 via a signal line 33. The in-home server 31 operates with DC power acquired from the DC distribution board 8 via the DC wiring 35 as a power source.

  A control box 36 that manages operation control of various devices in the home by network communication is connected to the home server 31 via a signal line 37. The control box 36 is connected to the control unit 7 and the DC distribution board 8 via the signal line 17 and can directly control the DC device 5 via the DC supply line 38. For example, a gas / water meter 39 that can remotely measure the amount of gas used or the amount of water used is connected to the control box 36, and an operation panel 40 of the network system 30 is connected to the control box 36. The operation panel 40 is connected to a monitoring device 41 including, for example, a door phone slave, a sensor, and a camera.

  When the in-home server 31 inputs an operation command for various devices in the home via the network N, the home server 31 notifies the control box 36 of the instruction, and operates the control box 36 so that the various devices operate in accordance with the operation command. . The in-home server 31 can provide various information acquired from the gas / water meter 39 through the control box 36 to the management server 32 through the network N, and operates that the monitoring device 41 has detected an abnormality. When accepted from the panel 40, this is also provided to the management server 32 through the network N.

Next, a specific configuration of the control unit 7 will be described.
As shown in FIG. 2, the control unit 7 includes a control unit 51, a current / voltage measurement unit 52, a first DC-DC converter (hereinafter referred to as “first converter”) 55, and a bidirectional converter 58. .

  The first converter 55 converts a direct current input from the solar cell 3 side into a predetermined direct current and outputs the DC current to the DC distribution board 8 side. That is, the first converter 55 is a current control type converter that can control its output current.

  Specifically, as shown in FIG. 3, the first converter 55 includes an input voltage detection circuit 61 that detects a voltage on the solar cell 3 side, and an output voltage detection circuit 62 that detects a voltage value on the DC distribution board 8 side. And an output current detection circuit 63 that detects a current value on the DC distribution board 8 side, a power circuit 64 for power conversion, and a CPU 65 that controls the power circuit 64.

  The power circuit 64 outputs the current supplied from the solar cell 3 to the DC distribution board 8 side as a predetermined current value based on the control signal from the CPU 65. At this time, the input voltage detection circuit 61 detects the input voltage, and the output voltage detection circuit 62 and the output current detection circuit 63 detect the output voltage and the output current. Thereby, the CPU 65 determines whether or not the input power is appropriately converted into the output power. The power circuit 64 includes a plurality of switch elements. Further, the CPU 65 outputs the detection result of the output current detection circuit 63 to the control unit 51 and inputs a command signal related to the output current from the control unit 51. The CPU 65 controls the power circuit 64 based on this command signal.

  As shown in FIG. 2, the current / voltage measuring unit 52 detects current and voltage at a measurement point 53 provided on the battery connection line 21. The current / voltage measuring unit 52 outputs the detection result to the control unit 51.

  The control unit 51 includes a non-volatile memory 51a, in which a power sale rule, a threshold value, a power supply program, and the like are stored. The control unit 51 recognizes the voltage Vb of the battery connection line 21 based on the detection result of the current / voltage measurement unit 52 and compares the voltage Vb with a reference voltage that is a voltage value when the battery 20 is fully charged. 20 remaining amount is determined.

  The controller 51 outputs a command signal to the first converter 55 and the second converter 56 based on the power supply program stored in the memory 51a. The specific control contents of the converters 55 and 56 by the control unit 51 will be described in detail later.

  The bidirectional converter 58 is provided in the cross flow connection line 12. Bidirectional converter 58 converts the electric power from DC power lines 13 to 15 into alternating current and also converts the electric power from AC power line 23 into direct current. Thus, by providing the bidirectional converter 58 in the cross-flow connection line 12, AC power is converted into DC power and transmitted to the DC power lines 13 to 15, or DC power is converted into AC power and the AC system is converted. It is possible to transmit power to the power line 23. Here, since direct-current power is generated by the solar cell 3, it can be supplied to the DC device 5 without being converted into alternating current. Therefore, power loss related to power conversion can be reduced, and power transmission efficiency is good. However, since power generation by the solar cell 3 depends on time and weather, it is difficult to supply stable power to the DC device 5. On the other hand, for AC power, for example, stable power transmission from an AC power source 2 generated by an electric power company can be expected. Therefore, when sufficient power generation by the solar cell 3 cannot be performed, AC power from the AC power source 2 can be converted to DC power and supplied to the DC device 5, so that power can be stably supplied to the DC device 5. Conversely, when it is determined that the amount of power generated by the solar cell 3 exceeds the amount of power used by the DC device 5, the DC power of the solar cell 3 is converted to AC power and supplied to the AC device 6, The power can be sold by causing the AC power source 2, that is, the power company, to reversely flow power (surplus power). Thereby, the electricity bill of an electric power company can be reduced.

  As shown in FIG. 2, the DC power line 15 from the fuel cell 16 to the control unit 7 is provided with a second DC-DC converter (hereinafter referred to as “second converter”) 56. The second converter 56 is configured in the same manner as the first converter 55, converts the direct current input from the fuel cell 16 side into a predetermined direct current, and outputs it to the control unit 7 side.

  The control unit 51 determines whether to sell power and the power to sell based on the power sale rules stored in the memory 51a. In the power sale rule, power sale power is set according to the remaining amount of the battery 20. Hereinafter, the power sale rules will be described with specific examples.

  For example, when the remaining amount of the battery 20 is 80 to 100%, the control unit 51 sells all surplus power for the DC device 5. When the remaining amount of the battery 20 is 40 to 80%, the control unit 51 sells half of the surplus power and spends the other half for charging the battery 20. When the remaining battery level is 0 to 40%, the control unit 51 spends all the surplus power for charging the battery 20. Thus, by changing the distribution of surplus power according to the remaining amount of the battery 20, the power can be used more effectively.

Also in this example, the maximum output operating point tracking control (MPPT control) is executed as in the background art. Hereinafter, the MPPT control executed by the control unit 51 will be described.
The battery 20 regulates (fixes) the potential of the DC power line 14 and thus the output voltages of the converters 55 and 56 to a constant value. Here, the power is obtained by the product of current and voltage. Therefore, when the voltage becomes constant, both converters 55 and 56 can control output power Pout from both converters 55 and 56 through control of output current Iout. Here, the output power Pout is equal to the power supplied to the converters 55 and 56 via the DC power lines 13 and 15 if power loss associated with the power conversion of the converters 55 and 56 is ignored. That is, the solar cell power Ppv is equal to the output power Pout from the first converter 55. Therefore, the first converter 55 can change the solar cell power Ppv, in other words, the solar cell voltage Vpv, which is the parameter, through the control of the output current Iout.

  As described above, since the output voltage Vout of the first converter 55 is defined, the MPPT control described in the above background art that maximizes the output from the solar cell 3 can be performed. In the MPPT control, as shown in FIG. 6, the output current Iout of the first converter 55 is controlled so that the solar cell voltage Vpv becomes the maximum output voltage Vmp. Thereby, the maximum output power Pmax can be output from the solar cell 3. As described above, even in a configuration in which direct current power is supplied from the solar cell 3 to the DC device 5, MPPT control is possible, and power can be obtained from the solar cell 3 with high efficiency.

  Next, the power supply control processing procedure executed by the control unit 51 will be described with reference to the flowchart of FIG. This flow is executed according to the power supply program stored in the memory 51a. The power supply program is created from the viewpoint of battery protection and effective power use.

  The controller 51 constantly monitors whether or not the current Ia supplied to the battery 20 is abnormal. That is, the control unit 51 recognizes the current Ia supplied to the battery connection line 21 through the current / voltage measurement unit 52. Then, the control unit 51 compares the current Ia with the threshold value Ib stored in its own memory 51a (S101). The threshold value Ib is set to be less than the maximum charging current (overcurrent) at which the battery 20 is expected to malfunction when supplied to the battery 20. That is, in this example, the threshold value Ib is set based on the rated charging current. When current Ia is less than threshold value Ib (NO in S101), battery 20 is in a state of being charged with current Ia equal to or lower than the rated charging current.

  When current Ia is equal to or greater than threshold value Ib (YES in S101), control unit 51 performs control to reduce current Ia, assuming that current Ia may reach an overcurrent level where a malfunction of battery 20 is assumed. I do. Specifically, first, the control unit 51 determines whether or not the output current Iout of the second converter 56 is an approximate value of zero (output current Iout≈0) (S102). Here, even if no power is supplied from the fuel cell 16, the second converter 56 is connected to various electronic devices, and therefore, it is conceivable that the output current Iout does not become completely zero. That is, the approximate value of zero is set to include a minute current that is not electric power from the fuel cell 16. In this example, the approximate value of zero is a concept including zero (output current Iout = 0).

  When the output current Iout from the second converter 56 does not approximate zero (NO in S102), the power from the fuel cell 16 is being supplied to the second converter 56. In this state, the control unit 51 outputs a command signal for reducing the output current Iout to the second converter 56 (S103). As shown in FIG. 3, the CPU 65 that has received the command signal performs control to reduce the output current Iout from the power circuit 64. Here, as shown in FIG. 2, the current Ia supplied to the battery connection line 21 is based on the output current Iout from both the converters 55 and 56. Therefore, the current Ia decreases as the output current Iout from the second converter 56 decreases.

  On the other hand, as shown in FIG. 4, when the output current Iout from the second converter 56 approximates zero (YES in S102), the power from the fuel cell 16 is not supplied. That is, the current Ia supplied to the battery connection line 21 in this state is derived from the electric power from the solar cell 3. In this case, the control unit 51 outputs a command signal for decreasing the output current Iout to the first converter 55 (S104). Similar to the second converter 56, the first converter 55 receives the command signal and lowers the output current Iout. Thereby, the current Ia supplied to the battery connection line 21 decreases.

  As described above, when the fuel cell 16 is used, when the current Ia is decreased, the power (exactly, current) from the fuel cell 16 that is depleting energy is decreased. Thereby, consumption of fuel in the fuel cell 16 can be suppressed.

  Then, the control unit 51 compares the current Ia and the threshold value Ib again (S105). If current Ia is equal to or greater than threshold value Ib (YES in S105), control unit 51 returns to the process of step S102 and determines whether or not output current Iout of second converter 56 is close to zero. . When the output current Iout approximates to zero (YES in S102), a command signal for decreasing the output current Iout is output to the first converter, and when the output current Iout does not approximate zero (NO in S102). ), A command signal for reducing the output current Iout is output to the second converter. Thus, the above process is repeated until the current Ia becomes less than the threshold value Ib. If the current Ia is less than the threshold value Ib (NO in S105), the battery 20 ends the processing of the power supply program on the assumption that the battery 20 is charged below the rated charging current.

  Thus, since the output current Iout from both the converters 55 and 56 is lowered until the current Ia becomes less than the threshold value Ib, it is possible to suppress the occurrence of a malfunction in the battery 20 due to overcurrent. Further, for example, it is not necessary to newly provide overcurrent protection means such as a converter in the battery connection line 21, and the power supply system 1 can be configured more simply.

  The battery 20 can also be used as an emergency power source. For example, when power transmission from the AC power source 2, the solar cell 3, and the fuel cell 16 is stopped due to a disaster, failure, or the like, the battery 20 can supply stored power to the DC device 5 and the AC device 6.

As described above, according to the embodiment described above, the following effects can be obtained.
(1) The potential of the output side (DC distribution board 8 side) of the first converter 55 is defined (fixed) by the battery 20. Thus, the solar cell electric power Ppv input from the solar cell 3 is determined through control of the output current Iout of the first converter 55 by defining the potential. In the first converter 55, the input / output powers Ppv and Pout are substantially equal. Therefore, the first converter 55 can determine the solar cell power Ppv (input power) through output-side current control based on the command signal from the control unit 51. Further, since the solar cell power Ppv is a function of the solar cell voltage Vpv (input voltage), the solar cell voltage Vpv can be determined by changing the solar cell power Ppv.

  Here, as an output characteristic of the solar cell 3, there is a maximum output voltage Vmp that outputs maximum power, that is, generates power most efficiently. The solar cell power Ppv is the input power of the first converter 55. Therefore, the first converter 55 can obtain power from the solar cell 3 with high efficiency by setting the solar cell voltage Vpv to the maximum output voltage Vmp through current control on the output side based on the command signal from the control unit 51. it can.

  (2) The battery protection means including the control unit 51, the current / voltage measurement unit 52, and both the converters 55 and 56 prevents an inflow of an excessive current that leads to a failure of the battery 20. Therefore, a more secure power distribution apparatus can be provided.

  (3) The current Ia supplied to the battery 20 is detected by the current / voltage measuring unit 52, and the detection result is output to the control unit 51. When the control unit 51 determines that the battery 20 is supplied with a current equal to or higher than the threshold value Ib based on the detection result of the current-voltage measurement unit 52, the control unit 51 causes the first converter 55 to reduce the output current Iout. A command signal is output. Accordingly, the output current Iout from the first converter 55 is reduced, and accordingly, the current supplied to the battery 20 is less than the threshold value Ib. Therefore, an excessive current inflow to the battery 20 leading to a failure is prevented.

  (4) The control unit 51 can adjust the amount of electric power supplied from each of the fuel cell 16 and the solar cell 3 to the DC device 5 through command signals to both the converters 55 and 56. When the control unit 51 detects that the battery 20 is supplied with a current equal to or higher than the threshold value Ib, the control unit 51 outputs a command signal to the second converter 56 to reduce the output current Iout in preference to the first converter 55. To do. For this reason, while the electric power from the solar cell 3 is actively utilized, the electric power from the fuel cell 16 is suppressed, and the consumption of fuel can be suppressed.

  (5) AC power is converted into DC power by the bidirectional converter 58 provided in the cross flow connection line 12 and transmitted to the DC system power lines 13 to 15, or DC power is converted into AC power to the AC system power line 23. And can transmit power. Here, since direct-current power is generated by the solar cell 3, it can be supplied to the DC device 5 without being converted into alternating current. Therefore, power loss related to conversion can be reduced, and power transmission efficiency is good. However, since power generation by the solar cell 3 depends on time and weather, it is difficult to supply stable power to the DC device 5. On the other hand, for AC power, for example, stable power transmission from an electric power company can be expected. In that respect, when the solar cell 3 cannot generate enough power, AC power can be converted into DC power and supplied to the DC device 5, so that power can be stably supplied to the DC device 5. Conversely, when the amount of power generated by the solar cell 3 exceeds the amount of power used by the DC device 5, the direct current power is converted into alternating current power and supplied to the alternating current load or sold to an electric power company. it can. Thereby, the effective use of surplus electric power is promoted, for example, the electric bill of an electric power company can be reduced.

  (6) With reference to the power sale rules stored in the memory 51a, the power to be sold is determined based on the remaining amount of the battery 20. For example, when the battery 20 is almost fully charged, the power is actively sold, and when the remaining amount of the battery 20 is low, the battery 20 is charged without selling power. Thus, by determining a power sale rule corresponding to the remaining amount of the battery 20, the power can be used more effectively.

(Second Embodiment)
Hereinafter, a second embodiment in which the power distribution apparatus according to the present invention is embodied in a power supply system will be described with reference to FIG. The power supply system 1 of the present embodiment has a configuration substantially similar to that of the power supply system of the first embodiment shown in FIG. The power supply system of this embodiment is different from the first embodiment in that a plurality of batteries are provided. Hereinafter, a description will be given focusing on differences from the first embodiment.

As shown in FIG. 5, a first battery 75 and a second battery 76 are connected to the DC power line 14 via a switching device 70, respectively.
The switching device 70 includes a battery side DC-DC converter (hereinafter referred to as “battery side converter”) 71 and a series circuit of a diode 73 and a switching element 72 connected in parallel.

  The battery side converter 71 raises and lowers the input voltage to a predetermined voltage value based on the command signal from the control unit 51 and outputs it. The battery side converter 71 has a backflow prevention function for preventing the flow of current from the batteries 75 and 76 to the DC power line 14 side. Based on a command signal from the control unit 51, the switching element 72 switches between energization and non-energization states of the connection line provided with the switching element 72. The diode 73 is an element that allows current to flow from both the batteries 75 and 76 only in the direction of the DC power line 14.

  Both the batteries 75 and 76 are switched to either the charge mode or the discharge mode by the switching device 70. Here, a case where the first battery 75 is in the charging mode and the second battery 76 is in the discharging mode will be described.

  When the operation mode of the first battery 75 is set to the charging mode, the control unit 51 outputs an operation command signal to the battery-side converter 71 and outputs a command signal indicating that the switching element 72 is not energized. To do. As a result, the power supplied to the DC power line 14 is converted into a predetermined voltage by the battery side converter 71 and supplied to the first battery 75. At this time, the charging power to the first battery 75 can be adjusted by controlling the output voltage of the battery-side converter 71. The same applies when the operation mode of the second battery 76 is set to the charging mode.

  When the operation mode of the second battery 76 is set to the discharge mode, the control unit 51 outputs a command signal to the effect that the switching element 72 is energized. In this case, since the battery side converter 71 is provided with the above-described backflow prevention function, power is not supplied to the DC system power line 14 via the battery side converter 71, and the DC system is connected from the second battery 76 through the diode 73. Supplied to the power line 14. Therefore, the power of the second battery 76 is supplied to the DC device 5 and defines the potential of the DC power line 14. Thereby, as explained in the first embodiment, the control unit 51 can execute MPPT control. The same applies when the operation mode of the first battery 75 is set to the discharge mode.

  In both the batteries 75 and 76, the operation mode is switched at any time between the charge mode and the discharge mode. For example, when the first battery 75 that has been in the charging mode becomes fully charged, or when the remaining amount of power stored in the second battery 76 that has been in the discharging mode has decreased, the control unit 51 controls the first battery 75. Is switched to the discharge mode, and the second battery 76 is switched to the charge mode.

  Thereby, even if the power generation amount of the solar cell 3 exceeds the usage amount of the DC device 5, the batteries 75 and 76 in the charging mode can be charged with surplus power that has not been used by the DC device 5. When there is no power generation by the solar cell 3 at night or the like, the control unit 51 uses the surplus power charged in the batteries 75 and 76 while securing electric power for regulating the potential. Therefore, surplus power can be effectively charged and power loss can be reduced.

As mentioned above, according to embodiment described, in addition to the effect of (1)-(6) of 1st Embodiment, there can exist the following effects.
(7) The potential of the DC power line 14 on the output side of the first converter 55 is defined by the discharge of the batteries 75 and 76 in the discharge mode. Therefore, as described above, the first converter 55 can obtain the maximum output power Pmax from the solar cell 3 by controlling the output current Iout based on the command signal from the control unit 51. Here, it is assumed that the power generation amount of the solar cell 3 exceeds the usage amount of the DC device 5. In this case, the first battery 75 in the charging mode charges surplus power that is not used by the DC device 5. For example, when the battery 75 in the charging mode is fully charged due to the charging of the surplus power, the switching device 70 switches the charging mode to the discharging mode. At this time, similarly, the second battery 76 in the discharge mode is switched to the charge mode by the switching device 70. Thus, by connecting the plurality of batteries 75 and 76 to the DC power line 14, the surplus power can be effectively charged and the loss of power can be reduced.

  Moreover, both the batteries 75 and 76 are switched and used. Therefore, the lifetime of the batteries 75 and 76 can be extended compared with a single battery, and the labor for battery replacement can be reduced.

In addition, the said embodiment can be implemented with the following forms which changed this suitably.
In the first and second embodiments, the distribution of surplus power according to the remaining amount of the battery 20 (75, 76), that is, the power consumed for charging and selling is determined by the power sale rule. However, according to the power sale rules, not only the power consumed for charging and selling, but also the charging speed may be determined. For example, rapid charging is performed when the remaining amount of the battery 20 is small, and low-speed charging is performed when the remaining amount of the battery 20 is large. In this case, the charging speed is controlled through the control of the converters 55 and 56 and the DC distribution board 8 by the control unit 7.

In the first and second embodiments, the second converter 56 is provided separately from the control unit 7, but may be provided in the control unit 7.
-In 2nd Embodiment, although the control part 51 performed operation control of the battery side converter 71 and the switching element 72, for example, the switching apparatus 70 is provided with a new control part, and the new control part is Operation control of the battery side converter 71 and the switching element 72 may be performed. In this case, the control unit 51 and the new control unit can exchange information via a communication line or the like.

  -In 2nd Embodiment, although the switching apparatus 70 was provided with the battery side converter 71, the diode 73, and the switching element 72, if switching of charging / discharging of the batteries 75 and 76 is possible, it will be limited to the said structure. Not.

  In the second embodiment, two batteries 75 and 76 are provided, but the number of batteries may be three or more. In this case, since the total capacity of all the batteries is increased, it becomes possible to define the potential and supply power more stably.

  In the first embodiment, the control unit 51 determines whether or not to sell power and the power to sell based on the power sale rules stored in the memory 51a, but omits the power sale rules. May be. In this case, all the surplus power is spent for charging until the battery 20 is fully charged.

  In the first and second embodiments, the power supply system 1 can transfer power through the cross-flow connection line 12 between the DC power lines 13 to 15 and the AC power line 23. However, the AC power supply 2, the AC distribution board 11, the AC power line 23, the AC device 6, and the like may be omitted to configure an independent DC power supply system.

  In the first and second embodiments, when the control unit 51 reduces the current Ia supplied to the battery 20 (75, 76), the electric power (accurately) from the fuel cell 16 that is depleting energy In this case, the current was preferentially reduced. However, for example, the output current Iout from both the converters 55 and 56 may be reduced to the same extent without performing the processing.

  -In 1st and 2nd embodiment, the control part 51 is protecting the battery 20 (75, 76) from overcurrent through control of both converters 55 and 56 based on the detection result of the current-voltage measurement part 52. It was. However, this battery protection means, specifically, the process according to the flowchart of FIG. 4 may be omitted. In this case, the current / voltage measuring unit 52 is omitted, and for example, a protective means such as a new converter is provided on the battery connection line 21 to control the current supplied to the battery 20. 20 is protected.

  DESCRIPTION OF SYMBOLS 1 ... Power supply system, 2 ... AC power supply (alternating current power source), 3 ... Solar cell, 7 ... Control unit, 12 ... Cross flow connection line (AC-DC connection line), 13-15 ... DC system power line (DC wiring) ), 16 ... Fuel cell (fuel power generation means), 18, 19 ... DC power line, 20 ... Battery, 21 ... Battery connection line, 51 ... Control unit, 51a ... Memory, 52 ... Current voltage measurement unit (Current measurement unit, Remaining battery level detection means) 53... Measuring point 55. First converter 56. Second converter 58. Bidirectional converter 61. Input voltage detection circuit 62 62 Output voltage detection circuit 63 Output current detection circuit , 64 ... Power circuit, 65 ... CPU, 70 ... Switching device (switching means), 71 ... Battery side converter, 72 ... Switching element, 73 ... Diode, 75 ... First battery, 76 ... Second battery

Claims (7)

In a power distribution device provided in a DC power system in which DC power is supplied from a solar cell to a DC load via a DC wiring,
A first DC-DC converter that is provided on the DC wiring and that is input from the solar cell, supplies current to the DC load as output power by controlling current;
A battery connected between the first DC-DC converter and the DC load in the DC wiring and defining a potential by applying a voltage to the DC wiring;
A controller that outputs a command signal to control the output current of the first DC-DC converter;
The first DC-DC converter controls electric power input from the solar cell through control of an output current based on the command signal from the control unit. The power distribution device according to claim 1,
Battery protection means for controlling the current supplied to the battery,
When it is detected that the value of the current supplied to the battery is greater than or equal to a threshold set based on the maximum value allowed to be supplied to the battery,
The battery protection means is a power distribution device that reduces the current supplied to the battery so that the value of the current supplied to the battery is less than the threshold value. The power distribution device according to claim 2,
The battery protection means includes
A current measuring unit for detecting a current supplied to the battery;
When the control unit determines that the value of the current supplied to the battery is greater than or equal to the threshold value based on the detection result of the current measurement unit, the control unit outputs an output current to the first DC-DC converter. Distribution device that outputs a command signal to reduce the power. In the power distribution apparatus as described in any one of Claims 1-3,
In addition to the solar cell, the DC system can supply DC power from the fuel power generation means using depletion energy to the DC load,
The fuel power generation means is connected between the first DC-DC converter and the battery in the DC wiring,
A second DC-DC converter that converts electric power from the fuel power generation means into appropriate electric power and supplies the electric power to the DC load;
The control unit reduces the output current to the second DC-DC converter in preference to the first DC-DC converter when it is detected that the value of the current supplied to the battery is greater than or equal to the threshold value. A power distribution device that outputs a command signal to the effect. In the power distribution apparatus as described in any one of Claims 1-4,
The DC wiring is linked with an AC power system in which AC power is supplied from an AC power source to the AC load via the AC wiring.
An AC-DC connection line connecting the DC wiring and the AC wiring;
A bi-directional converter that converts AC power from the AC wiring provided on the AC-DC connection line into DC power, and a bidirectional converter that converts DC power from the DC wiring into AC power. In the power distribution apparatus as described in any one of Claims 1-5,
A plurality of the batteries are connected to the DC wiring, and switching means for switching the operation mode of these batteries between the charging mode and the discharging mode is provided,
At least one of the plurality of batteries is set to a discharge mode, and at least one of the plurality of batteries is set to a charge mode.
The battery in the discharge mode is discharged while defining the potential of the DC wiring;
The battery in the charging mode is a power distribution device that charges surplus power of power used by the DC load with respect to supplied power. In the power distribution apparatus as described in any one of Claims 1-6,
Power selling wiring connected to the DC wiring and transmitting power supplied to the DC wiring to a power selling destination;
Battery remaining amount detecting means for detecting the remaining amount of the battery;
A power sale rule that is stored in the control unit and that indicates the power supplied to the power sale wiring based on the remaining amount of the battery,
The control unit refers to the power sale rule, and supplies the power determined based on the detection result of the battery remaining amount detection means to the power sale wiring.

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