JP6109108B2 - Power supply system - Google Patents

Description

  The present invention relates to a technology of a power supply system that supplies power from a power generation unit and power from a storage battery to a load.

  Conventionally, a power generation unit capable of generating power using natural energy, a storage battery capable of charging / discharging power from the power generation unit, and a power conditioner capable of supplying power from the power generation unit and power from the storage battery to a load And the technique of the electric power supply system which comprises the control part which controls operation | movement of the said power conditioner is well-known. For example, as described in Patent Document 1.

  The technology described in Patent Document 1 includes a power generation unit (solar cell) capable of generating power using natural energy, a storage battery (battery) capable of charging / discharging power from the power generation unit, power from the power generation unit, and A power conditioner (such as a power storage system) that can supply power from the storage battery to a load; and a control unit that controls the operation of the power conditioner. And the electric power from a power generation part and the electric power from a storage battery can be supplied to load by control of a control part.

  Moreover, in the technique described in Patent Document 1, in order to charge the storage battery with power from the power generation unit and supply the power discharged from the storage battery to the load (that is, to perform simultaneous charge / discharge of the storage battery), the storage battery Are provided. Thus, when two storage batteries are provided, it is inconvenient in that the cost increases.

  Further, in the technique described in Patent Document 1, when simultaneous charging / discharging is performed assuming that one storage battery is provided, a float-type charging method is adopted to temporarily charge the power generated by the power generation unit to the storage battery. Therefore, the storage battery needs to be fully charged at all times. As described above, when the float charging method is adopted, power is lost in the storage battery, which is inefficient, and further disadvantageous in that the storage battery is easily deteriorated.

JP 2012-253849 A

  The present invention has been made in view of the situation as described above, and the problem to be solved is not inefficient even if the storage battery is simultaneously charged and discharged using one storage battery, and the storage battery is deteriorated. It is providing the electric power supply system which can suppress doing.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

That is, in claim 1, a power generation unit capable of generating power using natural energy, a storage battery capable of charging / discharging power from the power generation unit, power from the power generation unit and power from the storage battery to a load A power supply system comprising: a power conditioner that can be supplied; and a control unit that controls an operation of the power conditioner, wherein the power conditioner connects the power generation unit and the load. A first switch arranged in an electric circuit, and an electric circuit connecting the power generation unit and the storage battery, and arranged in a second electric circuit branched from the first electric circuit on the power generation unit side than the first switch A third switch disposed on a third circuit that branches from the first circuit on the load side of the first switch, the second circuit being connected to the storage battery and the load And equipped with A second state, a third state where power is not able to cover the power consumption of the load from the power generating unit, but are alternated, which can power from said power generating portion cover the power consumption of the load In the fourth state, the first switch is opened, the second switch and the third switch are closed, and the storage battery is charged with electric power from the power generation unit and the second switch and the third switch are closed. The power discharged from the storage battery is supplied to the load.

In Claim 2, when the electric power from the said electric power generation part is a 1st state smaller than predetermined electric power, while making said 1st switch into an open state, said 2nd switch and said 3rd switch Is closed, the power from the power generation unit is charged into the storage battery, and the power discharged from the storage battery is supplied to the load.

According to a third aspect of the present invention, in the second state, the first switch and the second switch are closed to supply power from the power generation unit to the load and charge the storage battery. To do .

In the fourth aspect, in the third state, the first switch and the third switch are closed, and the electric power discharged from the storage battery is supplied to the load together with the electric power from the power generation unit. To supply .

In Claim 5, it is further equipped with the power failure detection means which detects that it is at the time of a power failure, and it is detected that it is at the time of the power failure, and when it is the first state, the first switch is opened. In addition, the second switch and the third switch are closed, the power from the power generation unit is charged into the storage battery, and the power discharged from the storage battery is supplied to the load .

In Claim 6, when it is detected that the power outage is in the second state, the first switch and the second switch are closed, and the power from the power generation unit is While supplying to a load, charging the said storage battery, the electric power from the said electric power generation part made to charge the said storage battery is made to increase gradually .

The power generation unit according to claim 7, wherein in the second state, when the voltage of the power from the power generation unit is smaller than the time when charging of the storage battery is started, the power generation unit is caused to charge the storage battery. The power from is gradually reduced .

In Claim 8, it is detected that it is the time of the power failure, and in the third state, the first switch and the third switch are closed, and together with the power from the power generation unit, The power discharged from the storage battery is supplied to the load .

  As effects of the present invention, the following effects can be obtained.

In claim 1, even if simultaneous charging / discharging of a storage battery is performed using one storage battery, it does not become inefficient, and can further suppress deterioration of the storage battery.
Further, a fourth state in which the second state in which the power from the power generation unit can cover the power consumption of the load and the third state in which the power from the power generation unit cannot cover the power consumption of the load are alternately changed. When it is a state, a power generation part and a storage battery can be operated suitably.

In Claim 2, when the electric power from a power generation part is a 1st state smaller than predetermined electric power, a power generation part and a storage battery can be operated suitably.

In Claim 3, when it is a 2nd state, an electric power generation part and a storage battery can be operated suitably.

In Claim 4, when it is a 3rd state, an electric power generation part and a storage battery can be operated suitably.

In Claim 5, when it is detected at the time of a power failure and it is a 1st state, a power generation part and a storage battery can be operated suitably.

In Claim 6, when it is detected at the time of a power failure and it is a 2nd state, a power generation part and a storage battery can be operated suitably.

In Claim 7, when it is a 2nd state, when the voltage of the electric power from a power generation part becomes smaller than the time of starting charge to a storage battery, a power generation part and a storage battery can be operated suitably. .

In Claim 8, when it is detected at the time of a power failure and it is a 3rd state, a power generation part and a storage battery can be operated suitably.

The block diagram which showed the structure of the electric power supply system which concerns on one Embodiment of this invention. Similarly, the block diagram which showed the structure of the power conditioner. Similarly, the flowchart which showed the process at the normal time by a control part. Similarly, the flowchart which showed the process at the time of the power failure by a control part. Similarly, the figure which showed a mode that the electric power generated in the electric power generation part was supplied to load (distribution panel) in normal time. Similarly, the figure which showed a mode that the electric power generated in the electric power generation part was supplied to a load (distribution panel) and a storage battery was charged in normal time. Similarly, the figure which showed a mode that the electric power generated by the electric power generation part and the electric power discharged from the storage battery were supplied to load (distribution panel) in normal time. Similarly, the figure which showed a mode that the electric power generated by the electric power generation part was charged to a storage battery, and the electric power discharged from the storage battery was supplied to a load (distribution panel) at the normal time (a storage battery is charged / discharged simultaneously). Similarly, the figure which showed a mode that the electric power generated in the power generation part was supplied to load (dedicated circuit) at the time of a power failure. Similarly, the figure which showed a mode that the storage battery was charged while supplying the electric power generated in the power generation part to a load (dedicated circuit) at the time of a power failure. Similarly, the figure which showed a mode that the electric power generated by the power generation part and the electric power discharged from the storage battery were supplied to load (dedicated circuit) at the time of a power failure. Similarly, the figure which showed a mode that the electric power generated by the electric power generation part was charged to a storage battery at the time of a power failure, and the electric power discharged from the storage battery was supplied to a load (dedicated circuit) (a storage battery is charged and discharged simultaneously). The block diagram which showed the structure of the electric power supply system which concerns on another embodiment which concerns on this invention.

  Below, the structure of the electric power supply system 1 which is one Embodiment of the "electric power supply system" concerning this invention is demonstrated using FIG.

  The power supply system 1 is provided in a building (in the present embodiment, a house) and supplies power from the commercial power supply 30, the fuel cell 4, the storage battery 5, and the like to a load (not shown). The power supply system 1 is mainly composed of a distribution board 2, a power path 3, a fuel cell 4, a storage battery 5, a solar power generation unit 6, a sensor unit 7, a power conditioner (hereinafter simply referred to as “power control”) 8, and a dedicated power supply system 1. A circuit 9 is provided.

  The distribution board 2 distributes the supplied power to the load. The distribution board 2 is connected to the commercial power supply 30 via the power path 3. The distribution board 2 is provided with an unillustrated earth leakage breaker, wiring breaker, control unit and the like. The distribution board 2 is connected to a load (not shown).

  In the present embodiment, the “load” is a circuit to which an appliance that consumes electric power in a house is connected. The load is provided, for example, for each room or for each outlet dedicated to a device that consumes a large amount of power. In the following, for convenience of explanation, it is assumed that distribution board 2 is included in the load.

  The power path 3 is a path through which power can be distributed. The power path 3 is constituted by a single-phase three-wire wiring. The power path 3 has one end (upstream end) connected to the commercial power supply 30 and the other end (downstream end) connected to the distribution board 2.

  The fuel cell 4 is a device that generates power using a fuel such as hydrogen. The fuel cell 4 is connected to the middle part of the power path 3. The fuel cell 4 includes a hot water storage unit (not shown) and can boil hot water in the hot water storage unit using heat generated during power generation. The fuel cell 4 is configured to be capable of load following operation that generates electric power as necessary.

  The storage battery 5 is an embodiment of a “storage battery” according to the present invention. The storage battery 5 is configured to be able to charge electric power. The storage battery 5 is composed of a lithium ion battery. The storage battery 5 is connected to the power conditioner 8.

  The solar power generation unit 6 is an embodiment of the “power generation unit” according to the present invention. The solar power generation unit 6 is a device that generates power using sunlight. The solar power generation unit 6 is connected to the power conditioner 8. The solar power generation unit 6 is configured by a solar cell panel or the like (not shown). The solar power generation unit 6 is installed in a sunny place such as on the roof of a house.

  The sensor unit 7 is an embodiment of the “power failure detection means” according to the present invention. The sensor unit 7 acquires information regarding the power in the power supply system 1. The sensor unit 7 can detect the occurrence of a power failure based on the acquired information. The sensor unit 7 includes a first sensor 7a and a second sensor 7b.

  The first sensor 7 a is connected between the solar power generation unit 6 and the power conditioner 8. The first sensor 7 a detects the voltage and current (power generation voltage and power generation current) of the power generated by the solar power generation unit 6. The first sensor 7a is configured to output a detection result.

  The second sensor 7 b is connected to the downstream side of the commercial power supply 30 in the power path 3. The second sensor 7b detects the voltage and current (supply voltage and supply current) of power from the commercial power supply 30. The second sensor 7b is configured to output a detection result.

The power conditioner 8 is an embodiment of a “power conditioner” according to the present invention. The power conditioner 8 is a hybrid power conditioner. The power conditioner 8 is configured to be able to output the electric power generated by the solar power generation unit 6 and the electric power discharged from the storage battery 5 to the distribution board 2 and output the electric power from the commercial power supply 30 to the storage battery 5. . The power conditioner 8 is connected between the middle part of the power path 3 (upstream side of the fuel cell 4), the storage battery 5, and the solar power generation unit 6. Thus, the storage battery 5 and the photovoltaic power generation unit 6 are connected to the distribution board 2 via the power conditioner 8 and the power path 3.
A detailed description of the configuration of the power conditioner 8 will be given later.

  The dedicated circuit 9 is a circuit for taking out the electric power generated by the solar power generation unit 6 and the electric power discharged by the storage battery 5 at the time of a power failure. The dedicated circuit 9 is connected to the power conditioner 8. In the following, for convenience of explanation, it is assumed that the dedicated circuit 9 is included in the load.

  Below, the structure of the power conditioner 8 is demonstrated in detail using FIG.

  As shown in FIG. 2, the power conditioner 8 mainly includes an inverter 11, a first converter 12, a second converter 13, a first electric circuit 21, a second electric circuit 22, a third electric circuit 23, a first relay 14, a second relay 15, A third relay 16, a fourth relay 17, and a control unit 18 are provided.

  When the DC power is input, the inverter 11 appropriately converts the DC power into AC power and outputs the AC power. Further, when AC power is input, the inverter 11 appropriately converts the AC power into DC power and outputs it. The inverter 11 is connected to the distribution board 2 via the power path 3. Further, the inverter 11 is connected to the second converter 13. The inverter 11 is connected to the dedicated circuit 9.

  The first converter 12 appropriately converts the DC power generated by the solar power generation unit 6 into a predetermined voltage and outputs it. The first converter 12 is connected to the solar power generation unit 6. The first converter 12 is connected to the second converter 13. The first converter 12 is connected to the storage battery 5.

  The second converter 13 appropriately converts the input DC power into a predetermined voltage and outputs it. Second converter 13 is connected to inverter 11. The second converter 13 is connected to the storage battery 5. The second converter 13 is connected to the first converter 12.

  The first electric circuit 21 is an embodiment of the “first electric circuit” according to the present invention. The first electric circuit 21 is an electric circuit that connects the photovoltaic power generation unit 6 and a load.

  The second electric circuit 22 is an embodiment of the “second electric circuit” according to the present invention. The second electric circuit 22 is an electric circuit that connects the solar power generation unit 6 and the storage battery 5. The second electric circuit 22 branches off from the first electric circuit 21 on the photovoltaic power generation unit 6 side with respect to the first relay 14 described later.

  The third electric circuit 23 is an embodiment of the “third electric circuit” according to the present invention. The third electric circuit 23 is an electric circuit that connects the storage battery 5 and the load. The third electric circuit 23 branches from the first electric circuit 21 on the load side with respect to the first relay 14 described later.

  The first converter 12 and the second converter 13 are connected via the first electric circuit 21. Specifically, the first converter 12 is connected to one side of the first electric circuit 21, and the second converter 13 is connected to the other side of the first electric circuit 21.

  The first converter 12 and the storage battery 5 are connected via the first electric circuit 21 and the second electric circuit 22. Specifically, the storage battery 5 is connected to one side of the second electric circuit 22, and a middle part of the first electric circuit 21 (hereinafter referred to as “first intermediate part 21 a”) is connected to the other side of the second electric circuit 22. Is done.

  The second converter 13 and the storage battery 5 are connected via the first electric circuit 21 and the third electric circuit 23. Specifically, the storage battery 5 is connected to one side of the third electric circuit 23, and the middle part of the first electric circuit 21 (hereinafter referred to as “second intermediate part 21 b”) is connected to the other side of the third electric circuit 23. Is done.

  The first relay 14 is an embodiment of a “first switch” according to the present invention. The first relay 14 is for connecting the first converter 12 and the second converter 13 and releasing the connection (switching between open and closed states). Specifically, when the first relay 14 is closed, the first converter 12 and the second converter 13 are connected. On the other hand, when the first relay 14 is opened, the connection between the first converter 12 and the second converter 13 is released. The first relay 14 is disposed between the first midway part 21 a and the second midway part 21 b in the first electric path 21.

  The second relay 15 is an embodiment of the “second switch” according to the present invention. The second relay 15 performs connection between the first converter 12 and the storage battery 5 and release of the connection (switching of the open / close state). Specifically, when the second relay 15 is closed, the first converter 12 and the storage battery 5 are connected. On the other hand, when the second relay 15 is opened, the connection between the first converter 12 and the storage battery 5 is released. The second relay 15 is disposed on the second electric path 22.

  The third relay 16 is an embodiment of a “third switch” according to the present invention. The third relay 16 performs connection between the second converter 13 and the storage battery 5 and release of the connection (switching of the open / close state). Specifically, when the third relay 16 is closed, the second converter 13 and the storage battery 5 are connected. On the other hand, when the third relay 16 is opened, the connection between the second converter 13 and the storage battery 5 is released. The third relay 16 is disposed on the third electric circuit 23.

  The fourth relay 17 connects and disconnects the inverter 11 and the dedicated circuit 9 (switches the open / close state). Specifically, when the fourth relay 17 is closed, the inverter 11 and the dedicated circuit 9 are connected. On the other hand, when the fourth relay 17 is opened, the connection between the inverter 11 and the dedicated circuit 9 is released. The fourth relay 17 is disposed between the inverter 11 and the dedicated circuit 9 in the first electric circuit 21.

  The control unit 18 is an embodiment of the “control unit” according to the present invention. The control unit 18 manages information in the power conditioner 8 and controls the operation of the power conditioner 8. The control unit 18 includes a storage unit such as a RAM and a ROM, an arithmetic processing unit such as a CPU, and the like. The storage unit of the control unit 18 stores in advance information related to a power supply mode (a normal process or a process during a power failure described later).

  Further, the control unit 18 includes each unit (specifically, the inverter 11, the first converter 12, the second converter 13, the first relay 14, the second relay 15, the third relay 16, and the fourth included in the power conditioner 8. Connected to a relay 17 or the like (not shown), and can control the operation of each part. Moreover, the control part 18 controls the operation | movement of the 1st converter 12, the 2nd converter 13, the inverter 11, etc., and the output of the electric power generated by the solar power generation part 6, the charging / discharging of the storage battery 5 is carried out. Can be controlled.

  The control unit 18 is connected to the sensor unit 7 (first sensor 7a and second sensor 7b). The control unit 18 can acquire the detection result of the sensor unit 7.

  Below, the outline of the supply mode of the electric power in the electric power supply system 1 is demonstrated.

  Electric power from the commercial power supply 30 is supplied to the distribution board 2 through the electric power path 3. Further, the power generated by the photovoltaic power generation unit 6 and the power discharged by the storage battery 5 are also supplied from the power conditioner 8 to the distribution board 2 via the power path 3. The electric power generated by the fuel cell 4 is also supplied to the distribution board 2 via the electric power path 3. As described above, the electric power from the commercial power source 30, the electric power generated by the solar power generation unit 6 and the fuel cell 4, and the electric power discharged from the storage battery 5 are supplied to the distribution board 2 through the electric power path 3.

  In addition, the power supplied to the distribution board 2 is distributed to the load by the distribution board 2. Thereby, the resident of the house can turn on the lighting or use a cooking appliance or an air conditioner.

  Thus, in the power supply system 1, the power consumption of the load (power distributed by the distribution board 2) is generated not only by the power from the commercial power supply 30 but also by the solar power generation unit 6 and the fuel cell 4. Can be covered by using the electric power discharged or the electric power discharged by the storage battery 5. As a result, the power (purchasing power) supplied from the commercial power supply 30 to the distribution board 2 can be reduced, and the power charge can be saved.

  In addition, the power consumption of the load can be covered by power other than the power from the commercial power source 30 (that is, power generated by the fuel cell 4), and surplus power is generated in the power generated by the solar power generation unit 6. In such a case, the surplus power can be sold by causing the commercial power source 30 to reversely flow. As a result, it is possible to save power charges and obtain an economic benefit. Further, the surplus power (generated by the solar power generation unit 6) and the power from the commercial power source 30 can be charged to the storage battery 5.

  Below, the electric power supply aspect in the electric power supply system 1 is demonstrated in detail.

In this supply mode, by controlling each part provided in the power conditioner 8, the output of the electric power generated by the solar power generation unit 6 and the charging / discharging of the storage battery 5 at the normal time (non-power failure) and at the time of power failure. Can be suitably controlled.
In this supply mode, normal processing and power failure processing are sequentially performed by the control unit 18 of the power conditioner 8. This process is repeatedly performed at approximately one minute intervals.

  First, normal processing by the control unit 18 will be described in detail with reference to the flowchart of FIG. 3 and FIGS. 2 and 5 to 8.

  Note that the processing of the control unit 18 includes control of the operation of each relay. Here, normally, since the electric power generated by the solar power generation unit 6 and the electric power discharged by the storage battery 5 are supplied to the distribution board 2, the dedicated circuit 9 is not used. Therefore, at the normal time, the fourth relay 17 arranged between the inverter 11 and the dedicated circuit 9 is always opened, and the connection between the inverter 11 and the dedicated circuit 9 is continuously released. Hereinafter, description of the operation control of the fourth relay 17 is omitted.

  At the start of normal processing, the first relay 14 is closed as shown in FIG. Moreover, the 2nd relay 15 and the 3rd relay 16 will be in an open state. That is, the first converter 12 and the second converter 13 are connected. Further, the connection between the first converter 12 and the second converter 13 and the storage battery 5 is released.

In step S101, the control unit 18 determines whether the supply current of the commercial power supply 30 is smaller than 0 A (ampere) based on the detection result of the sensor unit 7 (second sensor 7b).
If the control unit 18 determines that the supply current of the commercial power supply 30 is smaller than 0 A (ampere), the control unit 18 proceeds to step S102.
When the control unit 18 determines that the supply current of the commercial power supply 30 is not smaller than 0 A (ampere), the control unit 18 proceeds to step S104.

  In addition, when the supply current of the commercial power supply 30 is smaller than 0 A (ampere), power is flowing backward to the commercial power supply 30 (power is sold). On the other hand, when the supply current of the commercial power supply 30 is larger than 0 A (ampere), power is supplied from the commercial power supply 30 (purchased).

In step S <b> 102, the control unit 18 closes the second relay 15. That is, as shown in FIG. 6, the first converter 12 and the storage battery 5 are connected.
After the process of step S102, the control unit 18 proceeds to step S103.

In step S <b> 103, the control unit 18 charges the storage battery 5 with the amount of power sold to the commercial power supply 30. That is, when the power generated by the solar power generation unit 6 is supplied to the distribution board 2 and surplus occurs, the surplus power is not sold by reverse flow, but as shown in FIG. Then, the storage battery 5 is charged.
After the process of step S103, the control unit 18 proceeds to step S106.

In step S <b> 104, the control unit 18 closes the third relay 16. That is, as shown in FIG. 7, the second converter 13 and the storage battery 5 are connected.
After the process of step S104, the control unit 18 proceeds to step S105.

In step S <b> 105, the control unit 18 discharges the amount of power purchased from the commercial power supply 30 from the storage battery 5. That is, when the power generated by the solar power generation unit 6 is supplied to the distribution board 2 and a shortage occurs, the shortage power is not purchased from the commercial power source 30 but as shown in FIG. Then, the storage battery 5 is discharged.
After the process of step S105, the control unit 18 proceeds to step S106.

In step S106, the control unit 18 determines whether or not the power generation current of the solar power generation unit 6 is smaller than 1 A (ampere) based on the detection result of the sensor unit 7 (first sensor 7a).
When the control unit 18 determines that the generated current of the solar power generation unit 6 is smaller than 1 A (ampere), the control unit 18 proceeds to step S108.
When the control unit 18 determines that the generated current of the solar power generation unit 6 is not smaller than 1 A (ampere), the control unit 18 proceeds to step S107.

  In addition, in this embodiment, when the electric power generation current of the solar power generation unit 6 is smaller than 1A (ampere), the solar power generation unit 6 is an environment in which it is difficult to generate power stably (for example, the weather is rainy). Assumes that.

  In the present embodiment, “1A (ampere)” is a value serving as a reference for determining whether or not the solar power generation unit 6 is an environment in which it is difficult to generate power stably (for example, the weather is rainy). The reference value is not limited to “1A (ampere)”, and can be arbitrarily set according to the power generation performance of the solar power generation unit 6 or the like. The “1A (ampere)” is an embodiment of “predetermined power” according to the present invention.

In step S107, the control unit 18 determines whether charging and discharging of the storage battery 5 are switched three times or more in 5 minutes.
When it is determined that the charging and discharging of the storage battery 5 are switched three times or more in 5 minutes, the control unit 18 proceeds to step S108.
When it is determined that the charging and discharging of the storage battery 5 are not switched three times or more in 5 minutes, the control unit 18 ends the normal processing and shifts to the power failure processing.

  In the present embodiment, when the storage battery 5 is switched between charging and discharging three times or more in 5 minutes, the solar power generation unit 6 is difficult to generate power stably (for example, the weather is cloudy). Assume that there is. Specifically, for example, when the weather is cloudy, the sun is blocked by the clouds or the sun is exposed from the clouds alternately, and it becomes difficult for the solar power generation unit 6 to generate power stably. That is, when the weather is cloudy, the storage battery 5 may be repeatedly charged and discharged alternately (so-called chattering).

  In the present embodiment, “whether or not the charging and discharging of the storage battery 5 can be switched three times or more in 5 minutes” is an environment in which it is difficult to generate power stably in the solar power generation unit 6 (for example, the weather is cloudy) It is a criterion of whether or not. The reference is not limited to “whether the charging and discharging of the storage battery 5 can be switched three times or more in 5 minutes”, but can be arbitrarily set according to the power generation performance of the solar power generation unit 6 or the like. it can.

In step S <b> 108, the control unit 18 opens the first relay 14 and closes the second relay 15 and the third relay 16. That is, as shown in FIG. 8, the connection between the first converter 12 and the second converter 13 is released. Further, the first converter 12 and the second converter 13 and the storage battery 5 are connected.
After the process of step S108, the control unit 18 proceeds to step S109.

In step S <b> 109, the control unit 18 charges the storage battery 5 with the power generated by the solar power generation unit 6, and supplies the power discharged from the storage battery 5 to the distribution board 2. That is, as shown in FIG. 8, charging and discharging are simultaneously performed in the storage battery 5 in an environment where it is difficult to generate power stably by the solar power generation unit 6 (weather is rainy or cloudy).
Control part 18 shifts to Step S110 after Step S109 processing.

In step S110, the control part 18 determines whether the electric power generation current of the solar power generation part 6 is larger than 5A (ampere) by the detection result of the sensor part 7 (first sensor 7a).
When the control unit 18 determines that the generated current of the solar power generation unit 6 is larger than 5A (ampere), the control unit 18 proceeds to step S111.
When the control unit 18 determines that the generated current of the solar power generation unit 6 is not larger than 5 A (ampere), the control unit 18 proceeds to step S109 again.

  In addition, in this embodiment, when the electric power generation current of the solar power generation part 6 is larger than 5A (ampere), it is an environment (for example, the weather is sunny) where the solar power generation part 6 can easily generate power stably. It is assumed that Specifically, for example, when the weather is fine (the sky is not covered with clouds), the sun is not blocked by the clouds, and the solar power generation unit 6 generates power stably. .

  In the present embodiment, the “5A (ampere)” is a value that serves as a reference for whether or not the environment (for example, the weather is sunny) in which the photovoltaic power generation unit 6 can easily generate power stably. The reference value is not limited to “5 A (ampere)”, and can be arbitrarily set according to the power generation performance of the solar power generation unit 6.

In step S111, the control unit 18 closes the first relay 14 and opens the second relay 15 and the third relay 16. That is, as shown in FIG. 5, the first converter 12 and the second converter 13 are connected. Further, the connection between the first converter 12 and the second converter 13 and the storage battery 5 is released. Thus, the control unit 18 supplies the power generated by the solar power generation unit 6 to the distribution board 2.
After the process of step S108, the control unit 18 ends the normal process and proceeds to the process at the time of power failure.

  Next, the processing at the time of a power failure by the control unit 18 will be described in detail using the flowchart of FIG. 4 and FIGS. 9 to 12.

In step S201, the control unit 18 determines whether a power failure is detected. Specifically, the control unit 18 determines whether the supply voltage of the commercial power supply 30 is detected based on the detection result of the sensor unit 7 (second sensor 7b).
When the control unit 18 determines that the supply voltage of the commercial power supply 30 is detected (no power failure), the control unit 18 ends the process at the time of the power failure and shifts to the normal process.
If the control unit 18 determines that the supply voltage of the commercial power supply 30 has not been detected (power failure has occurred), the control unit 18 proceeds to step S202.

  Here, at the time of a power failure, the electric power generated by the solar power generation unit 6 or the electric power discharged by the storage battery 5 is not supplied to the distribution board 2 and the dedicated circuit 9 is used. Therefore, when it is determined in step S201 that a power failure has occurred, the fourth relay 17 disposed between the inverter 11 and the dedicated circuit 9 is always closed, and the connection between the inverter 11 and the dedicated circuit 9 is established. Continued. Hereinafter, description of the operation control of the fourth relay 17 is omitted.

  Moreover, when it determines with the control part 18 having failed in step S201, the 1st relay 14, the 2nd relay 15, and the 3rd relay 16 are once made into an open state. That is, the connection between the first converter 12 and the second converter 13 is released. Further, the connection between the first converter 12 and the storage battery 5 is released. Further, the connection between the second converter 13 and the storage battery 5 is released.

In step S202, the control unit 18 closes the first relay 14. That is, as shown in FIG. 9, the first converter 12 and the second converter 13 are connected.
After the process of step S202, the control unit 18 proceeds to step S203.

In step S203, the control unit 18 determines whether or not the power generation current of the solar power generation unit 6 is greater than 1A (ampere) based on the detection result of the sensor unit 7 (first sensor 7a).
When the control unit 18 determines that the generated current of the solar power generation unit 6 is larger than 1 A (ampere), the control unit 18 proceeds to step S207.
When the control unit 18 determines that the generated current of the solar power generation unit 6 is not larger than 1 A (ampere), the control unit 18 proceeds to step S204.

  In the present embodiment, when the power generation current of the solar power generation unit 6 is smaller than 1 A (ampere), as described above, the environment in which the solar power generation unit 6 cannot stably generate power (for example, weather) Is assumed to be rainy).

In step S <b> 207, the control unit 18 determines whether or not the power generation voltage of the solar power generation unit 6 is greater than the optimum voltage of the solar power generation unit 6.
When the control unit 18 determines that the power generation voltage of the solar power generation unit 6 is larger than the optimum voltage of the solar power generation unit 6, the control unit 18 proceeds to step S208.
When the control unit 18 determines that the power generation voltage of the solar power generation unit 6 is not greater than the optimum voltage of the solar power generation unit 6, the control unit 18 proceeds to step S210.

  In addition, when the power generation voltage of the solar power generation unit 6 is larger than the optimum voltage of the solar power generation unit 6, the power required by the dedicated circuit 9 is covered only by the power generated by the solar power generation unit 6. (Or surplus power, that is, power that can be charged in the storage battery 5 is generated). On the other hand, when the power generation voltage of the solar power generation unit 6 is not larger than the optimum voltage of the solar power generation unit 6, that is, when the power generation voltage of the solar power generation unit 6 is equal to or lower than the optimal voltage of the solar power generation unit 6. The power required by the dedicated circuit 9 is insufficient with only the power generated by the solar power generation unit 6.

In step S208, the control unit 18 closes the second relay 15. That is, as shown in FIG. 10, the first converter 12 and the storage battery 5 are connected.
After the process of step S208, the control unit 18 proceeds to step S209.

  In step S <b> 209, the control unit 18 charges the storage battery 5 with a part of the power generated by the solar power generation unit 6 supplied to the dedicated circuit 9 (that is, surplus power).

Moreover, when the process at the time of normal and the process at the time of a power failure are repeatedly performed at intervals of 1 minute, the charging current to the storage battery 5 is changed to 1A ( Increase in amperes (increase gradually). Moreover, when the supply voltage of the solar power generation unit 6 becomes smaller than the time when charging of the storage battery 5 is started, the charging current to the storage battery 5 is decreased by 1 A (ampere) (gradually decreased). By such control, it is possible to charge the storage battery 5 to the maximum extent with the surplus power in the dedicated circuit 9.
The control unit 18 proceeds to step S206 after the process of step S209.

In step S210, the control unit 18 closes the third relay 16. That is, as shown in FIG. 11, the second converter 13 and the storage battery 5 are connected.
After the process of step S210, the control unit 18 proceeds to step S211.

In step S <b> 211, the control unit 18 discharges the power charged in the storage battery 5. That is, as shown in FIG. 11, not only the power generated by the solar power generation unit 6 but also the power discharged from the storage battery 5 is supplied to the dedicated circuit 9.
After the process of step S211, the control unit 18 proceeds to step S206.

In step S204 transferred from step S203, the control unit 18 turns the first relay 14 into an open state and closes the second relay 15 and the third relay 16 into a closed state. That is, as shown in FIG. 12, the connection between the first converter 12 and the second converter 13 is released. Further, the first converter 12 and the second converter 13 and the storage battery 5 are connected.
After the process of step S204, the control unit 18 proceeds to step S205.

In step S <b> 205, the control unit 18 charges the storage battery 5 with the power generated by the solar power generation unit 6, and supplies the power discharged from the storage battery 5 to the distribution board 2. That is, as shown in FIG. 12, in an environment where it is difficult to generate power stably by the solar power generation unit 6 (for example, when the weather is rainy), the storage battery 5 is charged and discharged simultaneously.
After the process in step S205, the control unit 18 proceeds to step S206.

  Thus, in the present embodiment, in the normal processing, for example, when the weather is assumed to be rainy or cloudy, the storage battery 5 is charged and discharged at the same time. When the weather is assumed to be rainy, the storage battery 5 is charged and discharged simultaneously. In this way, the power required by the dedicated circuit 9 is configured to be as short as possible during a power failure.

In step S206, the control unit 18 determines whether or not the power failure has been canceled (the power failure has been recovered). Specifically, the control unit 18 determines whether the supply voltage of the commercial power supply 30 is detected based on the detection result of the sensor unit 7 (second sensor 7b).
If the control unit 18 determines that the supply voltage of the commercial power supply 30 has been detected (the power failure has been canceled), the control unit 18 ends the process at the time of the power failure and shifts to a normal process.
If the control unit 18 determines that the supply voltage of the commercial power supply 30 has not been detected (the power failure has not been canceled), the control unit 18 proceeds to step S203.

  In addition, when the process at the time of a power failure is complete | finished and it transfers to the process at the normal time, the 4th relay 17 arrange | positioned between the inverter 11 and the exclusive circuit 9 will always be in an open state. Further, the first relay 14 is closed. Moreover, the 2nd relay 15 and the 3rd relay 16 will be in an open state. That is, the operation of each relay is in the state shown in FIG.

As described above, the power supply system 1 as an embodiment of the “power supply system” according to the present invention is as follows.
A solar power generation unit 6 (power generation unit) capable of generating power using natural energy,
A storage battery 5 capable of charging and discharging electric power from the solar power generation unit 6 (power generation unit);
A power conditioner 8 (power conditioner) capable of supplying power from the solar power generation unit 6 (power generation unit) and power from the storage battery 5 to a load;
A control unit 18 for controlling the operation of the power conditioner 8;
A power supply system comprising:
The power conditioner 8 is
A first relay 14 (first switch) disposed on a first electric circuit 21 connecting the photovoltaic power generation unit 6 (power generation unit) and the load;
An electric circuit connecting the solar power generation unit 6 (power generation unit) and the storage battery 5, and the first power generation unit 6 (power generation unit) side of the first relay 14 (first switch). A second relay 15 (second switch) disposed in a second electric circuit 22 branched from the electric circuit 21;
A third relay disposed on a third electrical path 23 that branches from the first electrical path 21 on the load side of the first relay 14 (first switch), the electrical path connecting the storage battery 5 and the load. 16 (third switch),
It comprises.

  With such a configuration, by switching the open / closed state of each relay, the storage battery 5 can be charged and discharged simultaneously without adopting the float charging method. (Specifically, when performing simultaneous charging / discharging of the storage battery 5, the first relay 14 is opened and the second relay 15 and the third relay 16 are closed. Simultaneous charging / discharging of the storage battery 5 is also performed. In the case of this embodiment, at least the first relay 14 is closed.) Therefore, in the present embodiment, the storage battery 5 is always charged by temporarily charging the storage battery 5 with the power generated by the solar power generation unit 6. Since it is not necessary to be in a fully charged state, power loss in the storage battery 5 can be reduced (not inefficient), and further deterioration of the storage battery 5 can be suppressed.

In the power supply system 1,
When the power from the solar power generation unit 6 (power generation unit) is in the first state smaller than the predetermined power,
The first relay 14 (first switch) is opened and the second relay 15 (second switch) and the third relay 16 (third switch) are closed. The power from the (power generation unit) is charged in the storage battery 5 and the power discharged from the storage battery 5 is supplied to the load.

  With such a configuration, as shown in steps S106; YES, S108, S109, etc., solar power generation when the power from the solar power generation unit 6 (power generation unit) is in the first state smaller than the predetermined power. The part 6 and the storage battery 5 can be operated suitably.

In the power supply system 1,
A second state in which the power from the solar power generation unit 6 (power generation unit) can cover the power consumption of the load, and the power from the solar power generation unit 6 (power generation unit) covers the power consumption of the load. If the third state that can not be and the fourth state that is alternately changed,
The first relay 14 (first switch) is opened and the second relay 15 (second switch) and the third relay 16 (third switch) are closed. The power from the (power generation unit) is charged in the storage battery 5 and the power discharged from the storage battery 5 is supplied to the load.

  With such a configuration, as shown in steps S107; YES, S108, S109, etc., the second state in which the power from the solar power generation unit 6 (power generation unit) can cover the power consumption of the load, and the solar power generation When the third state in which the power from the unit 6 (power generation unit) cannot cover the power consumption of the load is the fourth state that is alternately changed, the solar power generation unit 6 and the storage battery 5 are preferably operated. Can be made.

In the power supply system 1,
In the second state,
The first relay 14 (first switch) and the second relay 15 (second switch) are closed to supply power from the solar power generation unit 6 (power generation unit) to the load and the storage battery. 5 is charged.

  With such a configuration, as shown in steps S101; YES, S102, S103, etc., the solar power generation unit 6 and the storage battery 5 can be suitably operated in the second state.

In the power supply system 1,
In the third state,
The first relay 14 (first switch) and the third relay 16 (third switch) are closed, and the power discharged from the storage battery 5 together with the power from the solar power generation unit 6 (power generation unit) is It supplies to the load.

  With such a configuration, as shown in steps S101; N0, S104, S105 and the like, the solar power generation unit 6 and the storage battery 5 can be suitably operated in the third state.

In the power supply system 1,
It further comprises a sensor unit 7 (power failure detection means) for detecting that there is a power failure,
If it is detected that the power is out and is in the first state,
The first relay 14 (first switch) is opened and the second relay 15 (second switch) and the third relay 16 (third switch) are closed. The power from the (power generation unit) is charged in the storage battery 5 and the power discharged from the storage battery 5 is supplied to the load.

  With such a configuration, as shown in Steps S203; NO, S204, S205, etc., it is detected that a power failure has occurred, and when it is in the first state, the solar power generation unit 6 and the storage battery 5 are preferably operated. be able to.

In the power supply system 1,
When it is detected that the power is out, and in the second state,
The first relay 14 (first switch) and the second relay 15 (second switch) are closed to supply power from the solar power generation unit 6 (power generation unit) to the load and the storage battery. 5 to charge
The electric power from the solar power generation unit 6 (power generation unit) to be charged in the storage battery 5 is gradually increased.

  With such a configuration, as shown in S203; YES, S207; YES, S208, S209, etc., it is detected that there is a power outage, and in the second state, the photovoltaic power generation unit 6 and the storage battery 5 are suitable. Can be operated.

In the power supply system 1,
In the second state,
When the voltage of the electric power from the solar power generation unit 6 (power generation unit) becomes smaller than the time when charging of the storage battery 5 is started,
The electric power from the solar power generation unit 6 (power generation unit) to be charged in the storage battery 5 is gradually reduced.

  With such a configuration, when the voltage of power from the solar power generation unit 6 (power generation unit) becomes smaller than the time when charging of the storage battery 5 is started, the solar power generation unit 6 and the storage battery 5 are preferably operated. Can be made.

Moreover, in the power supply system 1, when it is detected that the power failure occurs, and in the third state,
The first relay 14 (first switch) and the third relay 16 (third switch) are closed, and the power discharged from the storage battery 5 together with the power from the solar power generation unit 6 (power generation unit) is It supplies to the load.

  With such a configuration, as shown in S203; YES, S207; NO, S210, S211, etc., it is detected that there is a power outage, and in the third state, the solar power generation unit 6 and the storage battery 5 are suitable. Can be operated.

  In this embodiment, the power supply system 1 is provided in a house. However, the “power supply system” according to the present invention is used not only in a house but also in various buildings such as a store, an office building, and an apartment. be able to.

  FIG. 13 illustrates a power supply system 101 which is another embodiment of the “power supply system” according to the present invention. As shown in FIG. 13, the storage battery 5, the solar power generation unit 6, the power conditioner 8, and the dedicated circuit 9 may be arranged on the downstream side of the distribution board 2.

  Further, the “power generation unit” according to the present invention is configured to use sunlight as natural energy, but is not limited thereto. The natural energy used in the “power generation unit” according to the present invention may be, for example, hydraulic power, wind power, tidal power, or the like.

  In addition, the configuration of the “control unit” according to the present invention is not limited to the configuration of the control unit 18 and may not be included in the power conditioner 8. For example, the “control unit” according to the present invention may be configured by a control unit such as a home server (not shown), a switch unit, a control unit of the storage battery 5, a control unit of the fuel cell 4, or the like.

  In the present embodiment, the power generated by the photovoltaic power generation unit 6 and the power discharged by the storage battery 5 are not supplied to the distribution board 2 but supplied to the dedicated circuit 9 at the time of a power failure. However, the present invention is not limited to this. That is, even in the event of a power failure, the power generated by the solar power generation unit 6 or the power discharged by the storage battery 5 may be supplied to the distribution board 2.

DESCRIPTION OF SYMBOLS 1 Electric power supply system 5 Storage battery 6 Solar power generation part 8 Power conditioner 14 1st relay 15 2nd relay 16 3rd relay 18 Control part 21 1st electric circuit 22 2nd electric circuit 23 3rd electric circuit

Claims (8)

A power generation unit capable of generating power using natural energy;
A storage battery capable of charging and discharging power from the power generation unit;
A power conditioner capable of supplying power from the power generation unit and power from the storage battery to a load;
A control unit for controlling the operation of the inverter;
A power supply system comprising:
The inverter is
A first switch disposed in a first electrical path connecting the power generation unit and the load;
A second switch disposed in a second electrical circuit that branches from the first electrical circuit on the power generation unit side relative to the first switch, the electrical circuit connecting the power generation unit and the storage battery;
A third switch disposed in a third electrical circuit that branches from the first electrical circuit on the load side of the first switch, the electrical circuit connecting the storage battery and the load;
Comprising
The second state in which the power from the power generation unit can cover the power consumption of the load and the third state in which the power from the power generation unit cannot cover the power consumption of the load are alternately changed. In the fourth state,
The first switch is opened, the second switch and the third switch are closed, the power from the power generation unit is charged in the storage battery, and the power discharged from the storage battery is supplied to the load. And supply,
Power supply system. In the first state where the power from the power generation unit is smaller than the predetermined power,
The first switch is opened, the second switch and the third switch are closed, the power from the power generation unit is charged in the storage battery, and the power discharged from the storage battery is supplied to the load. And supply,
The power supply system according to claim 1. In the second state,
Closing the first switch and the second switch, supplying power from the power generation unit to the load and charging the storage battery;
Power supply system according to claim 1 or claim 2, characterized in that. In the third state,
The first switch and the third switch are closed, and the power discharged from the storage battery is supplied to the load together with the power from the power generation unit,
The power supply system according to claim 1 , wherein the power supply system is a power supply system. Further comprising a power failure detection means for detecting that a power failure has occurred,
If it is detected that the power is out and is in the first state,
The first switch is opened, the second switch and the third switch are closed, the power from the power generation unit is charged in the storage battery, and the power discharged from the storage battery is supplied to the load. And supply,
Power supply system as claimed in any one of claims 1 to 4, characterized in that. When it is detected that the power is out, and in the second state,
Close the first switch and the second switch, supply power from the power generation unit to the load and charge the storage battery,
Gradually increasing the power from the power generation unit to charge the storage battery,
The power supply system according to claim 5. In the second state,
When the voltage of power from the power generation unit becomes smaller than the time when charging of the storage battery is started,
Gradually reducing the electric power from the power generation unit to charge the storage battery,
The power supply system according to claim 6. When it is detected that the power is out, and in the third state,
The first switch and the third switch are closed, and the power discharged from the storage battery is supplied to the load together with the power from the power generation unit,
The power supply system according to any one of claims 5 to 7, wherein

Images