JP2021010238A - Power supply system - Google Patents

Abstract

To provide a power supply system which can supply electric power to a load even when long-term power failure is generated.SOLUTION: A power supply system 1 is provided with: a power conditioner 50 connected between a system power supply K and a load; a photovoltaic power generation part 30 which has a plurality of strings 31 to 33 each connected to the power conditioner while being generable in power by utilizing sunlight; a storage battery 40 connected to the power conditioner while being chargeable and dischargeable in electric power; a fuel cell 70 connected to a cable way A10 which connects a first string 31 being at least one of the strings to the power conditioner while being generable in power by supplying fuel thereto; and a cross board 80 which can perform connection between the fuel cell and the power conditioner via the cable way during power failure.SELECTED DRAWING: Figure 4

Description

The present invention relates to a technology of a power supply system capable of supplying power to a load in the event of a power failure.

Conventionally, a technology of a power supply system capable of supplying power to a load in the event of a power failure has been known. For example, as described in Patent Document 1.

The power supply system (photovoltaic power generation system) described in Patent Document 1 includes a plurality of units having a photovoltaic power generation unit (photovoltaic power generation facility), a storage battery (power storage device), and a distribution transformer. The photovoltaic power generation unit and the storage battery are connected to the distribution line via a distribution transformer. The distribution transformer is connected to the load via the distribution line. In such a power supply system, power can be supplied to the load by supplying power from the photovoltaic power generation unit and the storage battery to the distribution line via the distribution transformer in the event of a power failure.

However, in the power supply system described in Patent Document 1, when the generated power of the photovoltaic power generation unit becomes 0 W (for example, at night time), it is necessary to cover the power consumption of the load with a storage battery. In this configuration, if it takes a long time to recover from the power failure (a long-term power failure occurs), the storage battery may run out and power may not be supplied to the load. ..

Japanese Unexamined Patent Publication No. 2012-10536

The present invention has been made in view of the above circumstances, and the problem to be solved is to provide a power supply system capable of supplying power to a load even when a long-term power failure occurs. Is what you do.

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

That is, in claim 1, a power conditioner connected between the system power supply and the load, and a sun having a plurality of strings connected to the power conditioner while being able to generate power using sunlight. A photovoltaic cell, a storage battery capable of charging and discharging electric power and connected to the power conditioner, a first string which is at least one of the plurality of strings and the first string which can be supplied with fuel to generate electric power. It includes a fuel cell connected to an electric circuit connecting the power conditioner, and a connecting portion capable of connecting the fuel cell and the power conditioner via the electric circuit in the event of a power failure.

In claim 2, when the fuel cell and the power conditioner are connected to each other via the electric circuit, the connecting portion disconnects the first string and the power conditioner via the electric circuit. It is something to do.

In claim 3, the power conditioner has a first input unit to which electric power is supplied via the electric circuit, and a second input unit different from the first input unit, and the connection unit is the connection unit. When the fuel cell and the power conditioner are connected via an electric circuit, a second string different from the first string and the first string are connected in series and connected to the second input unit. is there.

In claim 4, the connection portion connects the fuel cell and the power conditioner via the electric circuit from the occurrence of a power failure to the recovery.

In claim 5, the connection portion connects the fuel cell and the power conditioner via the electric circuit in the event of a power failure and when the fuel cell is generating electricity.

In claim 6, the connection portion connects the fuel cell and the power conditioner via the electric circuit when the power generation of the photovoltaic power generation unit is equal to or less than a predetermined first threshold value during a power failure. Is to connect.

In claim 7, the connection portion is connected via the electric circuit when a power failure occurs and the state in which the generated power of the solar power generation unit is equal to or lower than a predetermined first threshold value continues for a predetermined time or longer. It connects the fuel cell and the power conditioner.

In claim 8, the connection portion is predetermined to be in a state where the power generated by the photovoltaic power generation unit is at least a predetermined second threshold value, which is a value larger than the first threshold value, at the time of a power failure. When it lasts for more than an hour, the first string and the power conditioner are connected via the electric path.

As the effect of the present invention, the following effects are exhibited.

According to claim 1, power can be supplied to the load even when a long-term power failure occurs.

In claim 2, the electric power from the fuel cell can be supplied only to the power conditioner.

In claim 3, the electric power from the photovoltaic power generation unit and the fuel cell can be effectively utilized in the event of a power failure.

According to claim 4, power can be stably supplied to the load in the event of a power failure.

In claim 5, the electric power from the fuel cell can be supplied preferentially over the first string in the event of a power failure.

In claim 6, the electric power generated by the photovoltaic power generation unit in the event of a power failure can be effectively utilized.

In claim 7, it is possible to prevent the switching unit from repeatedly operating in a short time.

In claim 8, it is possible to suppress the switching unit from repeatedly operating in a short time.

The block diagram which shows the power supply system which concerns on this embodiment. A block diagram showing a switching board. A flowchart showing the flow of operation of the switching board. A block diagram showing the state of the power supply system during a power outage. A block diagram showing the state of the switching board at the time of a power failure. The block diagram which shows the power supply system which concerns on the 1st modification. A block diagram showing a state in which the fuel cell cannot generate electricity in the event of a power failure. The block diagram which shows the power supply system which concerns on the 2nd modification. A block diagram showing a state in which the photovoltaic power generation unit cannot generate power during a power outage. The block diagram which shows the power supply system which concerns on the 3rd modification. The block diagram which shows the switching board which concerns on the 3rd modification. The block diagram which shows the state of the switching board which concerns on the 3rd modification at the time of a power failure. The block diagram which shows the state of the power supply system which concerns on the 3rd modification at the time of a power failure.

Hereinafter, the power supply system 1 according to the present embodiment will be described.

The electric power supply system 1 shown in FIG. 1 is provided in a house (for example, a detached house) and supplies electric power to a load of the house (for example, an electric device such as an air conditioner). The load according to this embodiment is connected to the distribution board 10 or the dedicated circuit 60, which will be described later. In the present embodiment, the power supply system 1 includes a distribution board 10, a power purchase meter 20, a photovoltaic power generation unit 30, a storage battery 40, a power conditioner 50, a dedicated circuit 60, a fuel cell 70, and a switching board 80.

The distribution board 10 distributes the power supplied from the power supply source (system power supply K or the like) to the load according to the power consumption of the load. The distribution board 10 is composed of an earth leakage breaker (not shown), a molded case circuit breaker, a control unit, and the like. The distribution board 10 is connected to the system power supply K, the power conditioner 50 described later, and the fuel cell 70. Electric power is appropriately supplied to the distribution board 10 from the system power supply K, the power conditioner 50, and the fuel cell 70.

The power purchase meter 20 is the amount of power flowing from the grid power supply K to the distribution board 10 (the amount of power purchased from the power company) and the amount of power flowing from the distribution board 10 to the grid power supply K (power sold to the power company). Amount) is detected. The power purchase meter 20 is arranged on a distribution line connecting the distribution board 10 and the system power supply K.

The photovoltaic power generation unit 30 is a device that uses sunlight to generate electricity. The photovoltaic power generation unit 30 has a plurality of strings capable of generating electricity by sunlight. In this embodiment, it is assumed that the number of strings is three. Further, in the following, in order to distinguish the three strings, they are referred to as "first string 31", "second string 32" and "third string 33".

The first string 31 is configured by connecting a plurality of solar cell modules (aggregates of solar cells (cells)) to each other. As shown in FIG. 2, the first string 31 has a positive electrode terminal 31a and a negative electrode terminal 31b that can be connected to the power conditioner 50. The second string 32 and the third string 33 shown in FIG. 1 are configured in the same manner as the first string 31.

The storage battery 40 is configured to be able to charge and discharge electric power. The storage battery 40 is composed of, for example, a lithium ion battery. The storage battery 40 is connected to the power conditioner 50.

The power conditioner 50 is a device that appropriately converts electric power (hybrid power conditioner capable of converting DC electric power into AC electric power). The power conditioner 50 has three positive electrode terminals 51 and three negative electrode terminals 52 (see FIG. 2) that can be connected to the three strings 31 to 33, respectively.

The power conditioner 50 is connected to the strings 31 to 33 via electric paths A10 to A30, respectively. The electric circuit A10 shown in FIG. 2 is an electric circuit connecting the first string 31 and the power conditioner 50. The electric line A10 is configured by arranging the first distribution line A11 and the second distribution line A12. The first distribution line A11 connects the positive electrode terminal 31a of the first string 31 and the positive electrode terminal 51 of the power conditioner 50. The second distribution line A12 connects the negative electrode terminal 31b of the first string 31 and the negative electrode terminal 52 of the power conditioner 50. DC power is input to the power conditioner 50 from the first string 31 via such an electric circuit A10. The power conditioner 50 can convert the input DC power into AC power and output it.

The electric circuit A20 shown in FIG. 1 is an electric circuit connecting the second string 32 and the power conditioner 50. The electric circuit A30 is an electric circuit that connects the third string 33 and the power conditioner 50. The electric lines A20 and A30 are configured in the same manner as the electric lines A10.

The power conditioner 50 operates the photovoltaic power generation unit 30 and the storage battery 40 in interconnection with the grid power supply K in a normal state, and operates the photovoltaic power generation unit 30 and the storage battery 40 independently of the grid power supply K in the event of a power failure. It is configured to be feasible to operate independently. The power supply mode in the case of interconnected operation and independent operation will be described in detail later.

The dedicated circuit 60 is a circuit provided for supplying electric power to a load (a load different from the load directly connected to the distribution board 10). The dedicated circuit 60 is connected to the power conditioner 50 and the load. In the following, for convenience of explanation, the load connected to the distribution board 10 will be referred to as a “general load”, and the load connected to the dedicated circuit 60 will be referred to as an “important load”. The dedicated circuit 60 is supplied with electric power via the power conditioner 50 not only in a normal state but also in a power failure. The dedicated circuit 60 can supply the supplied electric power to the critical load. Such important loads include, for example, equipment in which electric power is desirable to be supplied even when a power failure occurs, specifically, lighting and the like.

The fuel cell 70 generates electricity by being supplied with fuel (for example, gas or the like). The fuel cell 70 is composed of a polymer electrolyte fuel cell (PEFC: Polymer Electrolyte Fuel Cell) or the like, and is installed in a house. The fuel cell 70 is configured to be able to supply water, and hot water can be boiled using the heat generated during power generation. The fuel cell 70 is connected to the distribution board 10. Further, as shown in FIG. 2, the fuel cell 70 has a positive electrode terminal 71 and a negative electrode terminal 72 that can be connected to the power conditioner 50, and is connected to the power conditioner 50 via the electric circuits A10 and A40.

The electric circuit A40 is an electric circuit used when the fuel cell 70 operates independently. The electric circuit A40 connects the fuel cell 70 and the electric circuit A10. The electric line A40 is configured by arranging the first distribution line A41 and the second distribution line A42. The first distribution line A41 connects the positive electrode terminal 71 of the fuel cell 70 and the middle part of the first distribution line A11 of the electric circuit A10. The second distribution line A42 connects the negative electrode terminal 72 of the fuel cell 70 and the middle part of the second distribution line A12 of the electric circuit A10. In the following, the connection portion of the first distribution lines A11 and A41 will be referred to as a "first connection point P1". Further, in the following, the connection portion of the second distribution lines A12 and A42 will be referred to as a "second connection point P2".

The fuel cell 70 is configured to be able to execute an interconnection operation in which AC power is output in connection with the grid power supply K in a normal state and an independent operation in which DC power is output independently of the grid power supply K in the event of a power failure. Will be done. The power supply mode in the case of interconnected operation and independent operation will be described in detail later.

The switching board 80 shown in FIGS. 1 and 2 switches between connecting and disconnecting the first string 31 and the power conditioner 50 and connecting and disconnecting the fuel cell 70 and the power conditioner 50. The switching board 80 includes a first relay 81 and a second relay 82.

The first relay 81 shown in FIG. 2 is for connecting and disconnecting the first string 31 and the power conditioner 50. The first relay 81 is provided in the electric circuit A10. The first relay 81 is arranged between the first connection point P1 and the second connection point P2 and the positive electrode terminal 31a and the negative electrode terminal 31b of the first string 31.

The first relay 81 configured in this way operates according to the power from the system power supply K. Specifically, the first relay 81 is configured to be on (closed state) during normal operation and off (open state) during a power failure. When the first relay 81 is turned on, the first string 31 and the power conditioner 50 can be connected to each other. Further, when the first relay 81 is turned off, the connection between the first string 31 and the power conditioner 50 can be released.

The second relay 82 is for connecting and disconnecting the fuel cell 70 and the power conditioner 50. The second relay 82 is provided in the electric circuit A40.

The second relay 82 operates according to the electric power output from the storage battery 40 during the self-sustaining operation of the power conditioner 50. Specifically, the second relay 82 is configured to be turned off during normal operation and turned on during a power failure. When the second relay 82 is turned on, the fuel cell 70 and the power conditioner 50 can be connected to each other. Further, when the second relay 82 is turned off, the connection between the fuel cell 70 and the power conditioner 50 can be released.

Hereinafter, the operation flow of the switching board 80 will be described with reference to FIG.

For convenience of explanation, it is assumed that the state shown in FIG. 2 is the initial state of the operation of the switching board 80. That is, in the initial state of the switching board 80, it is assumed that the first relay 81 is on and the second relay 82 is off (see FIG. 2). Further, the operation of the switching panel 80 is not performed by controlling the first relay 81 or the like by a predetermined control device (for example, the power conditioner 50 or the like), but the power from the system power supply K or the like (whether or not there is a power failure). By opening and closing the first relay 81 and the like according to the above), the switching board 80 voluntarily performs the operation. Further, when the flow shown in FIG. 3 is completed, the switching board 80 repeats the flow from the beginning.

When a power failure occurs (step S10: Yes), the power supply from the system power supply K is cut off, and the first relay 81 is turned off (step S20).

On the other hand, when no power failure has occurred (step S10: No), the initial state (state in which the first relay 81 is on and the second relay 82 is off) is maintained, and the flow shown in FIG. 3 ends.

In the switching board 80 in which the first relay 81 is turned off in step S20, the second relay 82 is turned on when the storage battery 40 is outputting power by the self-sustaining operation of the power conditioner 50 (step S30: Yes). Step S40).

On the other hand, when the storage battery 40 does not output electric power due to the independent operation of the power conditioner 50 (step S30: No), the flow shown in FIG. 3 ends.

In the switching board 80 in which the second relay 82 is turned on in step S40, when the power failure is restored (power failure is restored) (step S50: Yes), the power supply from the system power supply K is restarted and the first relay 81 is turned on. When it is turned on, the power conditioner 50 ends the self-sustaining operation and the second relay 82 is turned off (step S60). In this way, the flow shown in FIG. 3 ends.

On the other hand, when the power failure is not restored (step S50: No), the flow shown in FIG. 3 ends.

Hereinafter, the operation of the switching board 80 and the power supply mode of the power conditioner 50 and the fuel cell 70 will be specifically described. First, with reference to FIGS. 1 and 2, the operation of the switching board 80 and the power supply mode in the normal state will be described.

In the normal state, power is supplied from the system power supply K to the distribution board 10. The electric power is supplied to a general load connected to the distribution board 10. Further, the electric power supplied to the distribution board 10 is supplied to the dedicated circuit 60 via the power conditioner 50. As a result, the power from the system power supply K is also supplied to the important load connected to the dedicated circuit 60.

In such a normal time (step S10: No), the initial state in which the first relay 81 is on and the second relay 82 is off is maintained. In this way, the switching board 80 connects the power conditioner 50 and the first string 31 in a normal state.

The power conditioner 50 and the fuel cell 70 are connected to each other in such a state. As a result, the power conditioner 50 can supply the electric power from all the strings 31 to 33 and the electric power from the storage battery 40 to the distribution board 10. The electric power supplied to the distribution board 10 is supplied to the general load connected to the distribution board 10. Further, the electric power supplied to the distribution board 10 is supplied to the dedicated circuit 60 via the power conditioner 50. As a result, electric power is also supplied to the important load connected to the dedicated circuit 60. In this way, the power conditioner 50 can supply electric power to the general load and the important load in connection with the grid power supply K in the normal state, and can operate the electric equipment of the house by the electric power from the photovoltaic power generation unit 30 and the storage battery 40. ..

Further, the fuel cell 70 performs interconnection operation in a normal state. Specifically, the fuel cell 70 supplies the generated electric power to the distribution board 10. The electric power is supplied to the general load and is also supplied to the critical load via the power conditioner 50 and the dedicated circuit 60. In this way, the fuel cell 70 normally supplies power to the general load and the critical load in connection with the system power supply K.

As described above, in the normal state, not only the electric power from the system power supply K but also the electric power from the photovoltaic power generation unit 30, the storage battery 40 and the fuel cell 70 can be appropriately supplied to the distribution board 10. As a result, the owner of the house can reduce the amount of electricity from the grid power supply K to the distribution board 10 (the amount of electricity purchased from the electric power company) to save the electricity bill.

Hereinafter, the operation of the switching panel 80 and the power supply mode in the event of a power failure will be described with reference to FIGS. 4 and 5.

When a power failure occurs, the power supply from the system power supply K to the distribution board 10 is cut off. Further, the first relay 81 of the switching board 80 is turned off when a power failure occurs (step S10: Yes, step S20). As a result, the connection between the first string 31 and the power conditioner 50 is released.

Further, the power conditioner 50 starts independent operation when a power failure occurs. As a result, the second relay 82 is turned on (step S30: Yes, step S40). As a result, the fuel cell 70 and the power conditioner 50 are connected. In this way, in the event of a power failure, the power supply source of the power conditioner 50 is switched from the first string 31 to the fuel cell 70, and is connected to the second string 32, the third string 33, the storage battery 40, and the fuel cell 70. Will be done.

Further, the fuel cell 70 starts self-sustaining operation when a power failure occurs. As a result, the fuel cell 70 outputs the generated electric power to the electric circuit A40. The electric power is supplied to the power conditioner 50 via the electric path A10.

As a result, in the present embodiment, in the event of a power failure, electric power from the fuel cell 70 can be supplied to the power conditioner 50 in addition to the second string 32, the third string 33, and the storage battery 40. The power conditioner 50 directly supplies the electric power supplied to itself to the dedicated circuit 60 without supplying it to the distribution board 10. As a result, the power conditioner 50 can supply electric power to the critical load even during a power failure.

Further, the fuel cell 70 can stably generate electricity for a long period of time if fuel and water are supplied. By supplying the electric power from the fuel cell 70 to the dedicated circuit 60, even if it takes time to recover from the power failure (a long-term power failure occurs), the electric power is stably supplied to the important load. can do. Further, by supplying the electric power from the fuel cell 70 to the dedicated circuit 60 to which the electric power is supplied even in the normal state, the convenience is improved as compared with the case where the electric power is supplied to the independent outlet that can be used only in the event of a power failure. Can be made to.

Further, the fuel cell 70 according to the present embodiment can output DC power during independent operation. According to this, the DC power output from the fuel cell 70 during the self-sustaining operation can be input to the input units (positive electrode terminal 51 and negative electrode terminal 52) from the strings 31 to 33 to the power conditioner 50. As a result, in the event of a power failure, the power from the fuel cell 70 can be supplied to the dedicated circuit 60 by using the input unit.

Further, the power conditioner 50 can charge the storage battery 40 not only the electric power from the second string 32 and the third string 33 but also the electric power from the fuel cell 70 in the event of a power failure. As a result, the storage battery 40 can be charged even when the generated power of the photovoltaic power generation unit 30 is 0 W (for example, at night time) or when the generated power is small at the time of a power failure, and the remaining amount of the storage battery 40 is secured. It can be made easier.

Further, when the generated power of the photovoltaic power generation unit 30 is 0 W at the time of a power failure, not only the storage battery 40 can cover the power consumption of the important load, but also the fuel cell 70 can cover the power consumption of the important load. As a result, the amount of discharge of the storage battery 40 at the time of a power failure can be reduced.

In this way, by facilitating the securing of the remaining amount of the storage battery 40 and reducing the discharge amount of the storage battery 40, it is possible to maintain the state in which the storage battery 40 can be discharged for a long period of time even during a power failure. As a result, even if it takes time to recover from the power failure, it is possible to prevent the power supply from the storage battery 40 from being interrupted.

As described above, the power supply system 1 according to the present embodiment can generate power by using the power conditioner 50 (power conditioner) connected between the system power supply K and the load, and the power conditioner 50. A photovoltaic power generation unit 30 having a plurality of strings 31 to 33 connected to each of the above, a storage battery 40 capable of charging and discharging power and connected to the power conditioner 50, and fuel being supplied to generate power. A fuel cell 70 connected to an electric circuit A10 connecting the first string 31 which is at least one of the plurality of strings 31 to 33 and the power conditioner 50, and the fuel cell 70 via the electric circuit A10 in the event of a power failure. It is provided with a switching board 80 (connecting portion) to which the power conditioner 50 can be connected.

With this configuration, it is possible to supply the power conditioner 50 with electric power from the fuel cell 70, which can generate electricity stably for a long period of time even during a power failure. As a result, electric power can be supplied to the load even when a long-term power failure occurs. In particular, in the present embodiment, the power consumption of the load at the time of power failure can be reduced by supplying power to only a part of the load (important load) at the time of power failure. This makes it easier to secure the remaining amount of the storage battery 40 and reduces the amount of discharge of the storage battery 40. Therefore, even if a power failure occurs for a long period of time, the power supply from the storage battery 40 can be effectively cut off. It can be suppressed.

Further, when the fuel cell 70 and the power conditioner 50 are connected via the electric circuit A10 (step S10: Yes), the switching board 80 connects the power conditioner 50 and the first string 31 via the electric circuit A10. The connection with is released (step S20).

With this configuration, the electric power from the fuel cell 70 can be supplied only to the power conditioner 50.

Further, the switching board 80 connects the fuel cell 70 and the power conditioner 50 via the electric circuit A10 from the occurrence of the power failure to the recovery (step S10: Yes, step S20, step S30: Yes, step S40, step S50: Yes).

With this configuration, electric power from the fuel cell 70, which can generate electricity stably even during a power failure, can be supplied to the load until the power failure is restored. As a result, power can be stably supplied to the load in the event of a power failure. Further, if the switching board 80 is configured to operate according to the electric power from the system power supply K and the storage battery 40 as in the present embodiment, the switching board 80 can be operated without using a sensor or the like. As a result, the configuration can be simplified.

The power conditioner 50 according to the present embodiment is an embodiment of the power conditioner according to the present invention.
Further, the switching board 80 according to the present embodiment is an embodiment of the connecting portion according to the present invention.

Next, a modified example of the power supply system 1 according to the present embodiment will be described.

The power supply system 101 according to the first modification shown in FIG. 6 differs from the power supply system 1 according to the present embodiment in the operation of the switching board 180. In the following, the differences will be mainly described.

The switching board 180 according to the first modification does not maintain the disconnection between the power conditioner 150 and the first string 31 from the time of power failure to the time of recovery, but is predetermined even during a power failure. It differs from the switching board 80 according to the present embodiment in that the power conditioner 150 and the first string 31 are connected when the conditions are satisfied.

The power supply system 101 according to the first modification includes a sensor 190 that detects a voltage applied to the electric circuit A40. The power conditioner 150 is configured to be able to acquire the detection result of the sensor 190.

The switching board 180 according to the first modification includes a first relay 81 and a second relay 82 arranged in the same manner as in the present embodiment (see FIG. 2). Unlike the present embodiment, the first relay 81 and the second relay 82 do not open and close according to the electric power from the system power supply K or the like, but open and close according to the signal from the power conditioner 150.

The power conditioner 150 according to the first modification turns off the first relay 81 and turns on the second relay 82 when the sensor 190 detects a voltage (see FIG. 5). As a result, the switching board 180 connects the power conditioner 150 and the fuel cell 70 at the time of a power failure and when the fuel cell 70 is generating power (fuel and water are supplied and the generated power is larger than 0 W). To do.

FIG. 7 shows a state in which the fuel cell 70 is not generating power (a state in which power generation becomes impossible and the generated power becomes 0 W) at the time of a power failure. In FIG. 7, such a fuel cell 70 that does not generate electricity is shown by a broken line. If the fuel cell 70 is not generating electricity, the sensor 190 will not detect the voltage. In this case, the power conditioner 150 turns on the first relay 81 and turns off the second relay 82 (see FIG. 2). As a result, the switching board 180 connects the first string 31 and the power conditioner 50 in the event of a power failure and when the fuel cell 70 is not generating power, and supplies the power from the photovoltaic power generation unit 30 to the dedicated circuit 60. To do.

According to this, when the first string 31 and the fuel cell 70 can generate electricity, the electric power from the fuel cell 70 capable of generating electricity stably is supplied with priority over the first string 31. Power can be stably supplied to the dedicated circuit 60 in the event of a power failure. Further, the first string 31 and the power conditioner 150 can be connected according to the state of the fuel cell 70 at the time of a power failure. As a result, the electric power from the first string 31 can be used while supplying the electric power from the fuel cell 70 capable of generating electricity stably in the event of a power failure to the dedicated circuit 60.

When the power failure is restored, the fuel cell 70 is switched from independent operation to interconnection operation. As a result, electric power is not output from the fuel cell 70 to the electric circuit A40, so that the sensor 190 does not detect the voltage. Therefore, the power conditioner 150 opens and closes the first relay 81 and the like in the same manner as when the fuel cell 70 does not generate electricity at the time of a power failure. As a result, the switching board 180 connects the first string 31 and the power conditioner 150 (see FIG. 6).

As described above, in the power supply system 101 according to the first modification, the switching board 180 connects the fuel cell and the fuel cell 180 via the electric circuit A10 during a power failure and when the fuel cell 70 is generating power. It connects to the power conditioner 150.

With this configuration, the electric power from the fuel cell 70 can be preferentially supplied over the first string 31 in the event of a power failure. Further, the electric power from the first string 31 can be used while preferentially supplying the electric power from the fuel cell 70 in the event of a power failure.

Next, the power supply system 201 according to the second modification will be described.

The power supply system 201 according to the second modification shown in FIG. 8 supplies power according to the present embodiment in that power from the first string 31 is preferentially supplied to the dedicated circuit 60 over the fuel cell 70 in the event of a power failure. It is different from system 1. In the following, the differences will be mainly described.

The power conditioner 250 according to the second modification is configured to be able to acquire the value of the generated power of the photovoltaic power generation unit 30. Further, the power conditioner 250 has a timer function and is configured to be able to measure the time.

The switching board 280 according to the second modification includes the first relay 81 and the second relay 82 arranged in the same manner as in the present embodiment (see FIG. 2). Unlike the present embodiment, the first relay 81 and the second relay 82 do not open and close according to the electric power from the system power supply K or the like, but open and close according to the signal from the power conditioner 250.

In the second modification, the power conditioner 250 does not open and close the first relay 81 and the second relay 82 when a power failure occurs, and maintains the normal state. Therefore, in the second modification, at the time of the power failure, the first string 31 and the power conditioner 250 are connected even if the fuel cell 70 starts power generation.

FIG. 9 shows a state in which the generated power of the photovoltaic power generation unit 30 (from the first string 31 to the third string 33) becomes 0 W at the time of a power failure. In FIG. 9, the first string 31 to the third string 33 of the photovoltaic power generation unit 30 are shown by broken lines.

The power conditioner 250 starts measuring the time when the generated power of the photovoltaic power generation unit 30 becomes equal to or less than a predetermined first threshold value at the time of a power failure. In the second modification, the first threshold value is 0 W. In this case, as shown in FIG. 9, when the generated power of the photovoltaic power generation unit 30 becomes 0 W, the value becomes equal to or less than the first threshold value, and the time measurement by the power conditioner 250 is started. Then, when the generated power is below the first threshold value for a predetermined time (for example, 5 minutes), the power conditioner 250 opens and closes the first relay 81 and the like to connect the first string 31 and the power conditioner 250. At the same time as releasing it, the fuel cell 70 and the power conditioner 250 are connected.

Further, the power conditioner 250 starts measuring the time when the generated power of the photovoltaic power generation unit 30 becomes equal to or higher than a predetermined second threshold value at the time of a power failure. The second threshold value is a value larger than the first threshold value (0 W). In the second modification, the second threshold value is 500 W. When the generated power continues to be equal to or higher than the second threshold value for a predetermined time (for example, 5 minutes), the power conditioner 250 opens and closes the first relay 81 and the like to disconnect the fuel cell 70 and the power conditioner 250. , The first string 31 and the power conditioner 250 are connected (see FIG. 8). In this way, the power supply source of the power conditioner 250 is switched from the fuel cell 70 to the first string 31, and is connected to all the strings 31 to 33 and the storage battery 40.

According to such a configuration, the electric power from the first string 31 can be supplied preferentially to the fuel cell 70 in the event of a power failure. As a result, the electric power generated by the first string 31 can be supplied to the power conditioner 50 as much as possible.

As described above, in the power supply system 201 according to the second modification, the switching board 280 is predetermined to be in a state where the power generated by the photovoltaic power generation unit 30 is equal to or less than a predetermined first threshold value during a power failure. When it continues for more than an hour, the fuel cell 70 and the power conditioner 250 are connected via the electric circuit A10.

With this configuration, it is possible to prevent the switching board 280 from repeatedly operating in a short time when the power generation of the photovoltaic power generation unit 30 is unstable due to the influence of the weather.

Further, the switching board 280 is in a state where the power generated by the photovoltaic power generation unit 30 is at least a predetermined second threshold value or more, which is a value larger than the first threshold value, during a power failure for a predetermined time or longer. In the subsequent case, the first string 31 and the power conditioner 250 are connected via the electric circuit A10.

With this configuration, it is possible to prevent the switching board 280 from repeatedly operating in a short time when the power generation of the photovoltaic power generation unit 30 is unstable due to the influence of the weather.

In the second modification, the first threshold value is set to 0 W, but the present invention is not limited to this, and a value larger than 0 W may be set. Further, the second threshold value is assumed to be 500 W, but the value is not limited to this as long as it is a value larger than the first threshold value.

Further, in the second modification, the power conditioner 250 does not necessarily have to measure the time at the time of a power failure, and the switching board 280 may be operated according to the generated power of the photovoltaic power generation unit 30. In this case, the power conditioner 250 connects the fuel cell 70 and the power conditioner 250 when, for example, the generated power of the photovoltaic power generation unit 30 is equal to or less than the first threshold value (for example, 0 W), and the generated power is the second. When it is equal to or more than a threshold value (for example, 500 W), the first string 31 and the power conditioner 250 may be connected.

As described above, in the second modification, when the switching board 280 has a power failure and the generated power of the photovoltaic power generation unit 30 is equal to or less than a predetermined first threshold value, the fuel cell passes through the electric circuit A10. It connects the battery 70 and the power conditioner 250.

With this configuration, the electric power generated by the photovoltaic power generation unit 30 in the event of a power failure can be effectively utilized.

Next, the power supply system 301 according to the third modification will be described.

The power supply system 301 according to the third modification shown in FIG. 10 differs from the power supply system 1 according to the present embodiment in the configuration of the switching board 380. In the following, the differences will be mainly described.

The switching board 380 according to the third modification is configured so that the connection of the second string 32 can be appropriately switched in addition to the connection between the first string 31 and the fuel cell 70 and the power conditioner 50. In the explanation of the switching board 380, the connection of the first string 31, the second string 32, the fuel cell 70, and the power conditioner 50 will be described.

The power conditioner 50 shown in FIG. 11 has a first positive electrode terminal 51a and a first negative electrode terminal 51b that can be connected to the first string 31 and the fuel cell 70, and a second positive electrode terminal that can be connected to the first string 31 and the second string 32. It has a 52a and a second negative electrode terminal 52b.

The first string 31 is connected to the power conditioner 50 (first positive electrode terminal 51a and first negative electrode terminal 51b) via the electric circuit A10. The fuel cell 70 is connected to the electric circuit A10 via the electric circuit A40.

The second string 32 is connected to the power conditioner 50 via the electric path A20. The electric line A20 is configured by arranging the first distribution line A21 and the second distribution line A22. The first distribution line A21 is connected to the positive electrode terminal 32a of the second string 32 and the second positive electrode terminal 52a of the power conditioner 50. The second distribution line A22 is connected to the negative electrode terminal 32b of the second string 32 and the second negative electrode terminal 52b of the power conditioner 50. The second distribution line A22 is formed so as to branch at a third relay 383, which will be described later.

Next, the configuration of the switching board 380 will be described. The switching board 380 includes the first relay 381 to the fourth relay 384.

The first relay 381 and the second relay 382 are configured in the same manner as the first relay 81 and the second relay 82 according to the present embodiment. Specifically, the first relay 381 is provided in the electric circuit A10. The second relay 82 is provided in the electric circuit A40.

The third relay 383 is for connecting and disconnecting the first string 31 and the second string 32 connected in series and the power conditioner 50. The third relay 383 is provided in the electric circuit A20. The second distribution line A22 of the electric circuit A20 is formed so as to branch at a contact on the second string 32 (negative electrode terminal 32b) side of the third relay 383. The branched second distribution line A22 is connected to the second negative electrode terminal 52b of the power conditioner 50 without going through the third relay 383. In this way, the electric circuit A20 is configured to always connect the negative electrode terminal 32b of the second string 32 and the second negative electrode terminal 52b of the power conditioner 50 regardless of the open / closed state of the third relay 383.

The third relay 383 operates according to the power from the system power supply K. Specifically, the third relay 383 is configured to be turned on during normal operation and turned off during a power failure.

The fourth relay 384 is for connecting and disconnecting the first string 31 and the second string 32 connected in series and the power conditioner 50. The fourth relay 384 is provided in the electric circuit A51 connecting the first relay 381 and the second positive electrode terminal 52a of the power conditioner 50, and in the electric circuit A52 connecting the first relay 381 and the third relay 383.

The electric circuit A51 connects the contact P31 on the first string 31 (positive electrode terminal 31a) side of the first relay 381 and the second positive electrode terminal 52a of the power conditioner 50. The electric circuit A52 connects the contact P32 on the first string 31 (negative electrode terminal 31b) side of the first relay 381 and the contact P33 on the second string 32 (positive electrode terminal 32a) side of the third relay 383.

The fourth relay 384 operates according to the electric power output from the storage battery 40 during the self-sustaining operation of the power conditioner 50. Specifically, the fourth relay 384 is configured to be turned off during normal operation and turned on during a power failure.

In the switching board 380 configured in this way, the first relay 381 and the third relay 383 are turned on based on the power from the system power supply K in the normal state. On the other hand, the second relay 382 and the fourth relay 384 are turned off. As a result, the switching board 380 connects the first string 31 and the second string 32 and the power conditioner 50 in the normal state. As a result, power is supplied to the power conditioner 50 (first positive electrode terminal 51a and first negative electrode terminal 51b) from the first string 31 via the electric circuit A10. Further, power is supplied to the power conditioner 50 (second positive electrode terminal 52a and second negative electrode terminal 52b) from the second string 32 via the electric circuit A20.

Further, as shown in FIG. 12, when a power failure occurs in the switching board 380, the power supply from the system power supply K is cut off and the first relay 381 and the third relay 383 are turned off. On the other hand, the second relay 382 and the fourth relay 384 are turned on based on the electric power output from the storage battery 40.

As a result, the fuel cell 70 is connected to the power conditioner 50 (first positive electrode terminal 51a and first negative electrode terminal 51b). Further, the first string 31 and the second string 32 are connected in series and are connected to the power conditioner 50 (second positive electrode terminal 52a and second negative electrode terminal 52b).

According to such a configuration, as shown in FIG. 13, all the strings 31 to 33 can be connected to the power conditioner 50 while the fuel cell 70 is connected to the power conditioner 50 in the event of a power failure. As a result, the electric power from the photovoltaic power generation unit 30 (first string 31) can be used without wasting it. Further, since more electric power can be supplied to the dedicated circuit 60, convenience can be improved.

Further, when the power failure is restored, the switching board 380 operates the first relay 381 and the like to return to the normal state (see FIGS. 10 and 11). In this way, in the third modification, the first string 31, the second string 32, the fuel cell 70, and the power conditioner 50 are connected from the occurrence of the power failure to the recovery.

As described above, in the power supply system 301 according to the third modification, the power controller 50 has the first positive electrode terminal 51a and the first negative electrode terminal 51b (first input unit) to which power is supplied via the electric circuit A10. Further, the switching board 380 has a second positive electrode terminal 52a and a second negative electrode terminal 52b (second input unit) different from the first positive electrode terminal 51a and the first negative electrode terminal 51b, and the switching board 380 is described via the electric path A10. When the fuel cell 70 and the power controller 50 are connected, the second string 32 different from the first string 31 and the first string 31 are connected in series to the second positive electrode terminal 52a and the second negative electrode terminal 52b. It connects to.

With this configuration, power from all strings 31 to 33 and the fuel cell 70 can be supplied to the load in the event of a power failure. As a result, the electric power from the photovoltaic power generation unit 30 and the fuel cell 70 can be effectively utilized in the event of a power failure. Further, the fuel cell 70 different from the strings 31 and 32 can be connected to the power conditioner 50 by using the input units (first positive electrode terminal 51a and first negative electrode terminal 51b) for the strings 31 and 32. As a result, the electric power from the fuel cell 70 can be supplied to the load without increasing the number of input units.

The first positive electrode terminal 51a and the first negative electrode terminal 51b according to the third modification are one embodiment of the first input unit according to the present invention.
Further, the second positive electrode terminal 52a and the second negative electrode terminal 52b according to the third modification are one embodiment of the second input unit according to the present invention.

As in the present embodiment, the switching board 380 according to the third modification has the first string 31, the second string 32, the fuel cell 70, and the power conditioner 50 during the period from the occurrence of the power failure to the recovery. Although it is assumed that they are connected, the operation of the switching board 380 is not limited to this. The switching board 380 may connect the first string 31, the second string 32, the fuel cell 70, and the power conditioner 50, for example, at the time of a power failure and when the fuel cell 70 is generating power.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above configuration, and various modifications can be made within the scope of the invention described in the claims.

For example, the power supply systems 1, 101, 201, and 301 are applied to houses, but are not limited to these, and may be applied to offices and the like.

Further, in the present embodiment, the number of the solar power generation unit 30, the storage battery 40, and the fuel cell 70 is all set to one, but the number is not limited to this, and any number of two or more is used. be able to.

Further, the number of strings of the photovoltaic power generation unit 30 is assumed to be three, but the number is not limited to this, and any number of two or more can be used.

The fuel cell 70 is not limited to the polymer electrolyte fuel cell (PEFC), and various types of fuel cells such as a solid oxide fuel cell (SOFC: Solid Oxide Fuel Cell) can be used. It is possible.

Further, the fuel cell 70 may be configured so that the maximum generated power during independent operation is larger than the maximum generated power of the first string 31. This makes it possible to supply more electric power from the fuel cell 70 to the dedicated circuit 60 in the event of a power failure. As a result, it is possible to easily operate a device having a large power consumption (for example, a microwave oven) even during a power failure, so that convenience can be improved.

1 Power supply system 30 Photovoltaic power generation unit 31 First string 32 Second string (string)
33 Third string (string)
40 Storage battery 50 Power conditioner (power conditioner)
70 Fuel cell 80 Switching board (connection part)
A10 grid K system power supply

Claims (8)

A power conditioner connected between the grid power supply and the load,
A photovoltaic power generation unit that can generate electricity using sunlight and has a plurality of strings connected to the power conditioner, respectively.
A storage battery that can charge and discharge electric power and is connected to the power conditioner,
A fuel cell that is supplied with fuel and can generate electricity, and is connected to an electric circuit connecting at least one of the plurality of strings, the first string, and the power conditioner.
A connection portion capable of connecting the fuel cell and the power conditioner via the electric circuit in the event of a power failure.
Equipped with
Power supply system. The connection part
When connecting the fuel cell and the power conditioner via the electric circuit, the connection between the first string and the power conditioner via the electric circuit is released.
The power supply system according to claim 1. The power conditioner is
It has a first input unit to which electric power is supplied via the electric circuit, and a second input unit different from the first input unit.
The connection part
When the fuel cell and the power conditioner are connected via the electric circuit, a second string different from the first string and the first string are connected in series and connected to the second input unit.
The power supply system according to claim 2. The connection part
The fuel cell and the power conditioner are connected to each other via the electric circuit from the occurrence of the power failure to the recovery.
The power supply system according to any one of claims 1 to 3. The connection part
When there is a power failure and the fuel cell is generating electricity, the fuel cell and the power conditioner are connected via the electric circuit.
The power supply system according to any one of claims 1 to 3. The connection part
When there is a power failure and the generated power of the photovoltaic power generation unit is equal to or less than a predetermined first threshold value, the fuel cell and the power conditioner are connected via the electric circuit.
The power supply system according to any one of claims 1 to 3. The connection part
The fuel cell and the power conditioner are connected via the electric circuit when a power failure occurs and the power generated by the photovoltaic power generation unit remains below a predetermined first threshold value for a predetermined time or longer. To do,
The power supply system according to any one of claims 1 to 3. The connection part
During a power outage, and when the state in which the generated power of the photovoltaic power generation unit is at least a predetermined second threshold value, which is a value larger than the first threshold value, continues for a predetermined time or longer, the power is passed through the electric circuit. To connect the first string and the power conditioner,
The power supply system according to claim 6 or 7.

Images