JP6584774B2 - Power control system, power control apparatus, and power control method - Google Patents

Description

  The present invention relates to a power control system, a power control apparatus, and a power control method.

  Conventionally, when the power generated by the solar power generation unit can be sold to the grid, the power generated by the gas power generation unit is supplied to the load with priority, and when the power sale is not possible, the solar power generation unit generates power. An energy control system that supplies power to a load with priority is known (for example, Patent Document 1).

International Publication No. 2013/046713 Pamphlet

  If the above-mentioned energy control system includes a storage battery and is connected to the grid, simply adding the storage battery cannot cope with restrictions related to power sales. The power generated by the gas power generation unit cannot be used efficiently.

  An object of the present invention made in view of such circumstances is to provide a power control system, a power control device, and a power control method that can efficiently use power generated by a plurality of power generation devices while using a storage battery. It is in.

In order to solve the above-described problem, a power control system according to an embodiment of the present invention includes:
A storage battery; a load device that receives power supply; a first power generation device that is grid-connected and capable of reverse power flow; a second power generation device that supplies power to at least one of the load device or the storage battery; and the load A power control system comprising: a power control device that controls power supply to the device; and a current sensor that detects a forward power flow from the grid and generates the second power generation device,
The power control device
A control unit;
A first power conversion unit capable of converting DC power output from the first power generator into AC power and backflowing into the system;
A second power conversion unit capable of converting the DC power output by the storage battery into AC power and supplying it to the load device;
A control relay for controlling a connection state between the first power generation device and the storage battery ;
Have
When the control unit detects that the generated power of the first power generation device is flowing backward through the first power conversion unit, the control unit opens the control relay to remove the storage battery from the system. Resshi, when the shortage has occurred in the power generation power of the second power generation apparatus, intends complement at least a portion of the shortfall by discharging the storage battery via the second power conversion unit.

In order to solve the above problem, in the power system according to an embodiment of the present invention,
It is preferable that when the surplus occurs in the generated power of the second power generation device, the control unit causes the storage battery to be charged with the surplus.

In order to solve the above problem, in the power control system according to an embodiment of the present invention,
Preferably, the control unit increases a charging current to the storage battery so as to minimize an increase in current detected by the current sensor.

In order to solve the above problem, in the power control system according to an embodiment of the present invention,
Preferably, the control unit discharges the storage battery so that a current detected by the current sensor is a minimum current for generating power by the second power generation device.

Furthermore, in order to solve the said subject, the power control apparatus which concerns on one Embodiment of this invention is the following.
A first power generator that is connected to the grid and capable of reverse power flow, and a control relay that controls a connection state of the storage battery;
A control unit;
A first power conversion unit capable of converting DC power output from the first power generator into AC power and allowing reverse flow to the system;
A second power conversion unit capable of converting the DC power output by the storage battery into AC power and supplying it to the load device;
Have
When the control unit detects that the generated power of the first power generation device is flowing backward through the first power conversion unit, the control unit opens the control relay to remove the storage battery from the system. When there is a deficiency in the generated power of the second power generator that supplies power to at least one of the load device or the storage battery, the storage battery is discharged via the second power conversion unit. It intends complement at least part of the shortfall.

Furthermore, in order to solve the above-described problem, a power control method according to an embodiment of the present invention includes:
A step of controlling a connection state between the storage battery and the first power generation device capable of systematic interconnection and reverse flow of generated power by a control relay;
When the control unit detects that the generated power of the first power generation device is flowing backward through the first power conversion unit , the control relay is opened to disconnect the storage battery from the system. The first power converter converts the DC power output from the first power generator into AC power and is capable of reverse power flow to the system ;
When there is a deficiency in the generated power of the second power generation device that supplies power to at least one of the load device or the storage battery by the control unit, the storage battery is discharged via the second power conversion unit. And supplementing at least a part of the shortage , wherein the second power generation device can convert the DC power output from the storage battery into AC power and supply it to the load device, and
Have

  According to the power control system, the power control device, and the power control method of the present invention, it is possible to efficiently use the power generated by the plurality of power generation devices while using the storage battery.

It is a functional block diagram at the time of the independent operation of the electric power control system which concerns on one Embodiment of this invention. It is a functional block diagram at the time of charge mode of the electric power control system which concerns on one Embodiment of this invention. It is a functional block diagram at the time of the discharge mode of the electric power control system which concerns on one Embodiment of this invention. It is a figure which shows the operation | movement flow of the power control apparatus of FIG.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

[System configuration]
1 to 3 are functional block diagrams of a power control system 90 according to an embodiment of the present invention during a self-sustained operation, a charge mode, and a discharge mode, respectively. Details will be described later. The power control system 90 includes, for example, a first power generation device 1, a storage battery 22, a power control device 3, a second power generation device 5, a load device 6, and a current sensor 7. 1 to 3, the control line and the information transmission line are indicated by broken lines, and the power line is indicated by a solid line. The information transmission line may be wired or wireless. Moreover, the thick line arrows L1-L7 show the flow of electric power. Although each function of the power control system 90 according to the present invention will be described, it should be noted that the power control system 90 is not intended to exclude other functions.

  The first power generator 1 is a distributed power source that generates electric power based on renewable energy such as sunlight, wind power, or hydropower. The rated output of the 1st electric power generating apparatus 1 is 10 kW, for example. Electricity based on renewable energy can be sold in Japan today. The first power generation device 1 is grid-connected to the grid 80 and can sell power by reversely flowing the generated power. As a restriction on power sale provided in Japan at present, in order for the first power generation apparatus 1 connected to the grid to reversely flow surplus power, the transformer 32c must be stopped. At this time, the storage battery 22 cannot discharge.

  The rated output of the storage battery 22 is 7 kW, for example. The storage battery 22 can be charged and discharged based on control by the power control device 3. The storage battery 22 can charge a surplus of power generated by the second power generation device 5 and can supply the charged power to the load device 6. Details will be described later.

  The power control device 3 includes a control unit 31, a transformation unit 32a, a transformation unit 32b, a transformation unit 32c, a power conversion unit 33a, a power conversion unit 33b, a control relay 34a, an interconnection relay 34b, an independent relay 34c, and a system bypass relay 34d. Have. The power control device 3 controls power supply to a load device 6 to be described later.

  The control unit 31 is a processor that controls the entire power control device 3 including each functional unit of the power control device 3.

  The transformer unit 32a, the transformer unit 32b, and the transformer unit 32c are step-up / step-down circuits that step up or step down the voltage of the input DC power. The transformer 32a is provided between the first power generator 1 and the power converter 33a, transforms the electric power generated by the first power generator 1 into an appropriate voltage, and outputs it to the power converter 33a. The transformation unit 32b is provided between the storage battery 22 and the power conversion unit 33a, converts the output of the storage battery 22 into an appropriate voltage, and outputs the voltage to the power conversion unit 33a. The transformer 32c is provided between the transformer 32b and the power converter 33b, and converts the current flowing between them into an appropriate voltage and outputs it. The transformer 32c can output power bidirectionally.

  The power conversion unit 33 a can convert the DC power output from the first power generation device 1 into AC power and can reversely flow to the grid 80. One end of the power conversion unit 33a is connected to a connection point where outputs of the transformation unit 32a and the transformation unit 32b are collected. A control relay 34a is provided between the power converter 33a and the transformer 32b. The power conversion unit 33a can output power bidirectionally.

  The power converter 33 b converts the DC power output from the storage battery 22 into AC power and outputs the AC power to the distribution board 4. The power conversion unit 33 b can also convert AC power output from the second power generation device 5 into DC power and output it to the storage battery 22. The power converter 33b can output power bidirectionally.

  The control relay 34a is provided between the transformer unit 32a and the transformer unit 32b. When the control relay 34a is opened, the storage battery 22 is disconnected from the first power generation device 1 and disconnected from the system 80. When the control relay 34a is closed, the storage battery 22 is connected to the first power generation device 1. At this time, for example, the power generated by the first power generator 1 is transformed by the transformer 32a and output to the transformer 32b, and the storage battery 22 is connected by the power transformed by the transformer 32b or the power from the system 80. Can be charged. That is, the control relay 34 a controls the connection state between the first power generation device 1 and the system 80 and the storage battery 22 by opening and closing.

  The interconnection relay 34b is provided between the power conversion unit 33a and the system 80, and opens during the self-sustaining operation of FIG. 1, closes during the charging mode of FIG. 2, and closes during the discharging mode of FIG.

  The self-supporting relay 34c is provided between the power conversion unit 33a and the distribution board 4. The self-supporting relay 34c is closed during the self-supporting operation shown in FIG. 1, opened during the charging mode shown in FIG. 2, and opened during the discharging mode shown in FIG.

  The system bypass relay 34d is provided between the system 80 and the distribution board 4 and opens during the self-sustaining operation of FIG. 1, closes during the charging mode of FIG. 2, and closes during the discharging mode of FIG.

  The distribution board 4 supplies the power supplied from at least one of the system 80, the first power generation device 1, the storage battery 22, and the second power generation device 5 to one or more load devices 6. The distribution board 4 can output the power generated by the second power generation device 5 to the storage battery 22.

  The second power generation device 5 is, for example, a distributed power source that cannot reverse flow. For example, the second power generation device 5 generates power that is supplied from the infrastructure, such as power generated by the fuel cell, and that is not allowed to be sold in Japan today. The fuel cell is a power generation device that generates electricity by electrochemical reaction of gases such as hydrogen and oxygen supplied from the outside, and is, for example, an SOFC (Solid Oxide Fuel Cell). At this time, the rated output of the second power generator 5 is, for example, 3 kW or 700 W. When the second power generator 5 generates power while maintaining the rated output, the power generation efficiency is good. As an alternative, the second power generation device 5 may be a gas turbine engine.

  The second power generator 5 may perform the load following operation by an arbitrary method.

  The second power generation device 5 includes an inverter inside. At this time, since the direct current generated by the second power generation device 5 is converted into an alternating current internally, the second power generation device 5 can directly supply power to the load device 6.

  1 to 3, the second power generation device 5 is provided outside the power control device 3, but the second power generation device 5 may be provided inside the power control device 3.

  The load device 6 is a power load that consumes the supplied power, and is, for example, various electric products such as an air conditioner, a microwave oven, a refrigerator, a television, and a router. The load device 6 may be a machine such as an air conditioner or a lighting fixture used in a commercial or industrial facility, a lighting facility, or the like.

  The current sensor 7 is provided between the system 80 and the distribution board 4 and can detect a forward power flow (current in the power purchase direction) or a reverse power flow (current in the power sale direction). When the current sensor 7 detects a forward power flow from the system 80 or a reverse power flow to the system 80, the current sensor 7 outputs the information to the second power generator 5. When the current sensor 7 detects a forward flow of a predetermined amount or more, the second power generation device 5 can generate power.

  Hereinafter, a power control method according to an embodiment of the present invention will be described in detail.

[Details of this embodiment]
In the state where the reverse power flow from the first power generation device 1 is not generated and the control relay 34a is closed, the control unit 31 determines whether or not the first power generation device 1 is reversely flowing the generated power. . The state in which the control relay 34a is closed is, for example, during the self-supporting operation shown in FIG. 1, and the first power generator 1 supplies power to the load device 6 as indicated by the thick arrow L1 and the thick arrow L2, This is when the second power generation device 5 supplies power to the storage battery 22. However, as another example, it may be during grid interconnection operation in which a forward power flow is generated from the grid 80.

  For example, when grid-connected operation is performed, power is supplied from the system 80 to the load device 6 via the distribution board 4 and at the same time the second power generation device 5 supplies generated power to the load device 6. It is. At this time, electric power may be supplied from the system 80 to the storage battery 22 to charge the storage battery 22. At this time, the control relay 34a, the interconnection relay 34b, and the system bypass relay 34d are closed, and the self-supporting relay 34c is open.

  When the control unit 31 detects that the first power generation device 1 is reversely flowing the generated power, the control unit 31 determines a mode that the power control device 3 should adopt. There are three modes to be adopted. The first mode is a charging mode, in which the power consumed by the load device 6 is smaller than the power generated by the second power generator 5, and the storage battery 22 is charged with the surplus power generated by the second power generator 5. Mode. The second mode is a discharge mode, in which the power consumed by the load device 6 is larger than the power generated by the second power generator 5 and compensates for at least a part of the shortage of power generated by the second power generator 5. Therefore, the storage battery 22 is discharged in this mode. The third mode is a non-charge / discharge mode, in which the power consumed by the load device 6 is equal to the power generated by the second power generation device 5 and the storage battery 22 does not charge / discharge.

  When it is determined that the mode to be adopted is the charging mode, as shown in FIG. 2, the control unit 31 opens the control relay 34a and the self-supporting relay 34c, closes the interconnection relay 34b and the system bypass relay 34d, and the thick line arrow L4. As shown, the charging of the storage battery 22 is started. At this time, power is also supplied from the second power generation device 5 to the load device 6. As indicated by a thick arrow L3, the first power generator 1 supplies the generated power to the load device 6 and at the same time causes the generated power to flow backward through the system 80. At this time, the storage battery 22 is disconnected from the system 80, and only the generated power of the first power generator 1 flows backward to the system 80.

  After the start of charging, the control unit 31 controls the power conversion unit 33b so as to reduce the charging current little by little (by a predetermined value) so as to suppress the increase in current detected by the current sensor 7 to a minimum (within a predetermined value). )increase. Specifically, by increasing the charging current little by little, it is determined whether or not the current flowing in the forward direction of the current sensor 7 (forward power flow) has increased. Does not increase. That is, an increase in current detected by the current sensor 7 can be minimized.

  On the other hand, when the current flowing through the current sensor 7 does not increase, the control unit 31 further increases the charging current and determines again whether the current flowing through the current sensor 7 has increased.

  Moreover, when it determines with the mode which should be employ | adopted being discharge mode, as shown in FIG. 3, the control part 31 opens the control relay 34a and the self-supporting relay 34c, and closes the interconnection relay 34b and the system | strain bypass relay 34d. Moreover, the control part 31 starts supply to the load apparatus 6 from the storage battery 22 as shown to the thick line arrow L6. Thereby, the shortage of the generated power of the second power generation device 5 indicated by the thick line arrow L7 is compensated. As indicated by a thick arrow L5, the first power generator 1 supplies the generated power to the load device 6 and at the same time causes the generated power to flow backward through the system 80. At this time, the storage battery 22 is disconnected from the system 80, and only the generated power of the first power generator 1 flows backward to the system 80.

  After the start of the discharge, the control unit 31 determines the current flowing through the current sensor 7 at the minimum (within a predetermined value) that the second power generator 5 determines that the current is flowing in the forward direction (the direction of the forward power flow). The electric power is supplied from the storage battery 22 to the load device 6 so as to suppress the current to a certain amount. At this time, the control unit 31 compensates the load device 6 with the priority of the power from the second power generation device 5, the power from the storage battery 22, and the power from the first power generation device 1. Also good.

[Operation flow]
FIG. 4 is a diagram showing an operation flow executed by the power control device 3 of FIG. 2 or 3 while the control relay 34a is closed.

  The power control device 3 determines whether a reverse power flow is detected (step S1). When No in step S1, the power control device 3 repeats step S1. When Yes in step S1, the power control device 3 determines a mode to be adopted (step S2). When the mode to be adopted is the non-charge / discharge mode, the power control device 3 ends the flow. In the non-charge / discharge mode, the control relay 34a remains closed.

  When the mode to be adopted in step S2 is the charging mode, the power control device 3 opens the control relay 34a (step S3), and starts charging the storage battery 22 from the second power generation device 5 (step S4). Next, the power control device 3 increases the charging current (step S5). At this time, the power control device 3 determines whether or not the current flowing through the current sensor 7 has increased (step S6). When the result is No in step S6, the power control device 3 executes step S5 again.

  On the other hand, when Yes in step S6, the power control device 3 maintains the charging current without increasing it (step S7).

  Moreover, when the mode which should be employ | adopted in step S2 is discharge mode, the electric power control apparatus 3 opens the control relay 34a (step S8). Next, the power control device 3 starts discharging from the storage battery 22 to the load device 6 (step S9). In addition, the power control device 3 increases the discharge current (step S10), and whether the current flowing through the current sensor 7 is the minimum amount of current that the second power generation device 5 determines that power is flowing in the forward direction. It is determined whether or not (step S11), and when step S11 is No, step S11 is executed again.

  When Yes in step S10, the power control device 3 maintains the discharge current without increasing it (step S12).

  After step S7 or step S12, the power control device 3 determines whether or not the detection of the reverse power flow is finished (step S13). When No in step S13, the power control apparatus 3 returns to the mode determination in step S2, and repeats steps S2 to S13. On the other hand, when Yes in step S13, the power control device 3 ends the charge mode or the discharge mode, and the power control device 3 closes the control relay 34a (step S14). Thereafter, the operation flow ends.

  According to the power control system 90 according to the above-described embodiment, the power control device 3 includes the control relay 34 a that controls the connection state between the first power generation device 1 and the storage battery 22, and the generated power of the first power generation device 1. The control unit 31 opens the control relay 34a and disconnects the storage battery 22 from the system 80 when it is detected that the reverse current is flowing. For this reason, for example, when reverse power flow is occurring, the storage battery 22 is disconnected from the system 80 so that the storage battery 22 and the second power generation device 5 can be used, and the plurality of transformers 32c are stopped without stopping. It is possible to efficiently use the power generated by the power generation device.

  According to the power control system 90 according to the above embodiment, the control unit 31 causes the storage battery 22 to charge the surplus when the surplus occurs in the generated power of the second power generation device 5. For this reason, it is possible to efficiently use the power generated by the second power generation device 5 using the storage battery 22 not only during the self-sustained operation but also when a reverse power flow occurs. Moreover, since a surplus can be stored in the storage battery 22 and can be used when there is much electric power demand, the peak shift effect can be acquired.

  According to the power control system 90 according to the above embodiment, the control unit 31 increases the charging current to the storage battery 22 so that the increase in current detected by the current sensor 7 is minimized. That is, when the increase in current detected by the current sensor 7 is minimized, the current flowing from the first power generator 1 to the load device 6 is minimized, so the first power generator 1 generates the generated power, Power can be sold with maximum reverse power flow. Therefore, the merit of the economic incentive by power sale can be received.

  According to the power control system 90 according to the above embodiment, the control unit 31 compensates for the shortage by discharging the storage battery 22 when the shortage is generated in the generated power of the second power generation device 5. For this reason, when it is possible to discharge the storage battery 22, it is not necessary to use all of the generated power of the first power generation device 1 for the shortage, so that it is possible to increase the power flowing backward from the first power generation device 1. . Therefore, the merit of the economic incentive by power sale can be received.

  According to the power control system 90 according to the above-described embodiment, the control unit 31 discharges the storage battery 22 so that the current detected by the current sensor 7 is the minimum current that the second power generation device 5 generates. . For this reason, while driving the 2nd electric power generating apparatus 5 and ensuring the supply electric power to the load apparatus 6, electric power sales amount can be increased and the merit of the economic incentive by electric power sale can be received.

  According to the power control system 90 according to the above-described embodiment, the control unit 31 calculates the shortage of the power from the second power generation device 5, the power from the storage battery 22, and the power from the first power generation device 1. Make up with priority. For this reason, since the electric power supplied to the load apparatus 6 from the 1st electric power generating apparatus 1 becomes the minimum, and much electric power sales electric power can be ensured, the economic incentive by electric power sales can be maximized.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and corrections based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention. For example, functions included in each member, each part, each step, and the like can be rearranged so as not to be logically contradictory. Also, when the present invention is implemented as a method invention, it is possible to combine or divide a plurality of parts or steps into one.

  Further, when the control unit 31 of the power control device 3 according to the present invention is configured by a computer, a program describing processing contents for realizing each function is stored in a storage unit inside or outside the computer, and This can be realized by reading and executing this program by a central processing unit (CPU) of the computer. In addition, such a program can be distributed by selling, transferring, or lending a portable recording medium such as a DVD or a CD-ROM, and such a program is stored in a storage unit of a server on a network, for example. And the program can be distributed by transferring the program from the server to another computer via the network. In addition, a computer that executes such a program can temporarily store, for example, a program recorded on a portable recording medium or a program transferred from a server in its own storage unit. As another embodiment of the program, the computer may directly read the program from a portable recording medium and execute processing according to the program, and each time the program is transferred from the server to the computer. In addition, the processing according to the received program may be executed sequentially.

DESCRIPTION OF SYMBOLS 1 1st electric power generating apparatus 22 Storage battery 3 Electric power control apparatus 31 Control part 32a Transformer part (converter)
32b Transformer (converter)
32c Transformer (converter)
33a Power converter (inverter)
33b Power converter (inverter)
34a Control relay 34b Interconnection relay 34c Independent relay 34d System bypass relay 4 Distribution board 5 Second power generator 6 Load device 7 Current sensor 80 System (commercial system)
90 Power control system

Claims (6)

A storage battery; a load device that receives power supply; a first power generation device that is grid-connected and capable of reverse power flow; a second power generation device that supplies power to at least one of the load device or the storage battery; and the load A power control system comprising: a power control device that controls power supply to the device; and a current sensor that detects a forward power flow from the grid and generates the second power generation device,
The power control device
A control unit;
A first power conversion unit capable of converting DC power output from the first power generator into AC power and backflowing into the system;
A second power conversion unit capable of converting the DC power output by the storage battery into AC power and supplying it to the load device;
A control relay for controlling a connection state between the first power generation device and the storage battery ;
Have
When the control unit detects that the generated power of the first power generation device is flowing backward through the first power conversion unit, the control unit opens the control relay to remove the storage battery from the system. Resshi, when the shortage has occurred in the power generation power of the second power generation apparatus, cormorants complement at least a portion of the shortfall by discharging the storage battery via the second power conversion unit,
Power control system. The power control system according to claim 1,
The said control part is an electric power control system which makes the said storage battery charge the said surplus part when the surplus part has arisen in the generated electric power of a said 2nd electric power generating apparatus. The power control system according to claim 2, wherein
The said control part is an electric power control system which increases the charging current to the said storage battery so that the increment of the electric current which the said current sensor detects may be suppressed to the minimum. The power control system according to claim 1,
The said control part is an electric power control system which discharges the said storage battery so that the electric current which the said current sensor detects may turn into the minimum electric current which a said 2nd electric power generating apparatus produces. A first power generator that is connected to the grid and capable of reverse power flow, and a control relay that controls a connection state of the storage battery;
A control unit;
A first power conversion unit capable of converting DC power output from the first power generator into AC power and allowing reverse flow to the system;
A second power conversion unit capable of converting the DC power output by the storage battery into AC power and supplying it to the load device;
Have
When the control unit detects that the generated power of the first power generation device is flowing backward through the first power conversion unit, the control unit opens the control relay to remove the storage battery from the system. When there is a deficiency in the generated power of the second power generator that supplies power to at least one of the load device or the storage battery, the storage battery is discharged via the second power conversion unit. cormorant complement at least part of the shortfall,
Power control device. A step of controlling a connection state between the storage battery and the first power generation device capable of systematic interconnection and reverse flow of generated power by a control relay;
When the control unit detects that the generated power of the first power generation device is flowing backward through the first power conversion unit , the control relay is opened to disconnect the storage battery from the system. The first power converter converts the DC power output from the first power generator into AC power and is capable of reverse power flow to the system ;
When there is a deficiency in the generated power of the second power generation device that supplies power to at least one of the load device or the storage battery by the control unit, the storage battery is discharged via the second power conversion unit. And supplementing at least a part of the shortage , wherein the second power generation device can convert the DC power output from the storage battery into AC power and supply it to the load device, and
A power control method.

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