JP5372313B2 - Power supply system having fuel cell device - Google Patents

Description

  The present invention relates to a power supply system having a fuel cell, and more particularly to a power supply system used in connection with a system power supply.

  In recent years, a fuel cell has been deployed as a distributed power supply device at the location of a power consumer (customer), and the power consumer combines the power from the fuel cell with the power from the grid power supply (commercial power) of an electric power company. A distributed power supply system that covers power consumption in the world is attracting attention.

  Fuel cells generate DC power, but it is necessary to superimpose AC power from the system power supply and distribute it to the load in the homes of power consumers, so it is necessary to link the fuel cell, which is a distributed power supply, to the system power supply There is. In order to link the fuel cell to the system power supply, a power conditioner that converts DC power output from the fuel cell into AC power and adapts the frequency and voltage to the power from the system power supply is used.

  FIG. 3 is a block diagram showing a configuration of a power supply system for using a distributed power supply by a fuel cell in conjunction with a system power supply.

  A fuel cell device 81 including a fuel cell and outputting AC power is provided, and the output of the fuel cell device 81 is connected to a distribution board 82. The distribution board 82 is also connected to the system power supply via the reverse power flow prevention device 15, and supplies the AC power from the system power supply and the AC power of the fuel cell device 81 to the load via the same distribution line.

  The fuel cell device 81 is supplied with a reformer 91 that reforms a hydrocarbon fuel, for example, kerosene or LPG (liquefied petroleum gas) to generate hydrogen, and the hydrogen and oxygen (air). And a power conditioner 93 that converts DC power generated by the fuel cell main body 92 into AC power and outputs the AC power. The fuel cell main body 92 includes, as a typical fuel cell, a negative electrode and a positive electrode to which hydrogen and oxygen are supplied, respectively, and an electrolyte membrane that is disposed between the negative electrode and the positive electrode and is permeable to hydrogen ions. The power conditioner 93 converts the direct current power from the fuel cell main body 92 into alternating current power so as to be linked to the alternating current power on the system power source side input via the distribution board 82. In order to operate the reformer 91 and the fuel cell main body 92, it is necessary to raise the temperature of the reformer 91 and the fuel cell main body 92 to a predetermined temperature range by a heater, and to supply fuel to the reformer 91, a pump is used. Need to work. Thus, in order to operate the fuel cell device 81, it is necessary to operate various auxiliary devices such as a heater and a pump, and the electric power for operating the heater and the pump is reformed from the power conditioner 93. Is provided to the container 91 and the fuel cell main body 92. If the fuel cell device 81 enters the steady operation state, a part of the power generated by the fuel cell main body 92 is used as the power for the heater and the pump. However, when the fuel cell device 81 itself is started (started up), the fuel cell main body 92 has not yet started power generation, so the AC power input from the system power supply to the power conditioner 93 via the distribution board 82 is used as a heater. And the power to operate the pump is obtained.

  By the way, when connecting a distributed power supply to a system power supply, the distributed power supply is connected to a distribution line from the system power supply. Therefore, the distributed power source is required not to have an adverse effect on the power system. In particular, strict management is required in an installation situation in which the power generated by the distributed power source exceeds the power consumption at the installation location and a reverse power flow occurs with respect to the system power. In the case of a distributed power source using a fuel cell, the occurrence of reverse power flow is prohibited. Therefore, in the power supply system shown in FIG. 3, the reverse power flow prevention device 15 inserted between the system power supply and the distribution board 82 prevents power from being sent toward the system power supply side.

  The fuel cell is promising as an emergency power source in the event of a disaster because it operates as long as fuel is present regardless of weather conditions. However, a power source system that includes a fuel cell as a distributed power source and is linked to the system power source drives the heaters and pumps necessary for the operation of the fuel cell. Requires supply. Therefore, such a power supply system cannot be started when the system power supply is out of power, such as during a disaster. In other words, a power supply system having a fuel cell connected to a system power supply cannot be used as an emergency power supply device.

  Accordingly, an object of the present invention is a power supply system that has a fuel cell and is linked to a system power supply, and even when the system power supply is out of power, the fuel cell can be started and operated independently. Is to provide a simple power supply system.

The power supply system of the present invention includes a fuel cell main body and a power conditioner including a first connection terminal that converts DC power generated by the fuel cell main body into AC power and is supplied with starting power from the outside. And a power supply system having a fuel cell device linked to the system power supply, the reverse power flow provided between the fuel cell device and the system power supply and having a function of disconnecting the fuel cell device from the system power supply in the event of a power failure of the system power supply A solar power generation device having a prevention device, a solar cell and a second connection terminal for directly outputting DC power from the solar cell, and connected to the system power source, and during a power failure of the system power source in, while disconnecting the photovoltaic device from the system power supply, for starting the DC power from the photovoltaic device by connecting the removable interconnection of the second connection terminal to the first connection terminal Is supplied to the fuel cell device as a force, to start the fuel cell system, characterized in that a self-sustaining operation condition.

  In this power supply system, the fuel cell device includes, for example, a fuel cell using hydrocarbon as fuel. The rated output of the photovoltaic power generator is preferably 1 kW or more and less than 10 kW per 1 kW of the rated output of the fuel cell device.

  Also in this power supply system, the fuel cell device has, for example, a fuel cell using hydrocarbon as fuel. The rated capacity of the power storage device is preferably 100 W · h or more and less than 300 W · h per 1 kW of the rated output of the fuel cell.

  In the present invention, when the fuel cell device is in a steady operation state after the fuel cell device is started, it is preferable to stop the supply of starting power to the fuel cell device. The fuel cell using hydrocarbon as fuel used in the present invention uses, for example, kerosene, LPG (liquefied petroleum gas), natural gas, methane or the like as fuel. In a fuel cell using hydrocarbon as a fuel, a reformer for reforming the fuel is generally provided. Therefore, for example, the starting power is increased to at least a predetermined temperature of the reformer, It is used to raise the electrode part and the electrolyte membrane of the fuel cell device to a predetermined temperature.

  In the present invention, as the starting power used for starting the fuel cell device, the power output from the photovoltaic power generation device or the power output from the power storage device can be used. Even in a case where the system power supply is interrupted in the power supply system connected to the system power supply, the fuel cell apparatus can be started, and the electric power generated from the fuel cell apparatus can be supplied to the load. Therefore, the power supply system of the present invention is linked to the system power supply in normal times, and can be independently operated as an emergency power supply in an emergency such as a disaster, and is useful in both normal times and emergency times.

  Next, a preferred embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 shows a power supply system according to an embodiment of the present invention. This power supply system is connected to a system power supply, and includes a fuel cell device 11 that outputs AC power and a solar power generation device 12 that outputs AC power as a distributed power source.

  The output of the fuel cell device 11 is connected to the distribution board 14, and the output of the solar power generation device 12 is connected to the distribution board 16. The distribution board 14 is connected to the distribution board 16 via the reverse power flow prevention device 15 and also connected to a distribution line for supplying power to the load. The distribution board 16 is further connected to a system power supply. The reverse power flow prevention device 15 prevents the power generated by the fuel cell device 11 from being supplied to the system power supply side, and electrically connects the distribution board 16 and the distribution board 14 particularly when the system power supply is interrupted. It has a function to disconnect. In this power supply system, AC power from the system power supply, AC power from the fuel cell device 11, and AC power from the solar power generation device 12 are supplied to the load via the distribution board 14 and the same distribution line. Supplied.

  The fuel cell device 11 is generated by the reformer 21 that reforms the fuel to generate hydrogen, the fuel cell main body 22 that generates power by supplying the hydrogen and oxygen (air), and the fuel cell main body 92. And a power conditioner 23 that converts DC power into AC power and outputs the power. As fuel, kerosene, LPG (liquefied petroleum gas) or natural gas is used. Therefore, the fuel cell device 11 has a fuel cell using hydrocarbon as fuel. As the power conditioner 23, the same one as the power conditioner 93 used in the conventional power supply system shown in FIG. 3 is used. However, the power conditioner 23 in the system shown in FIG. 3 is different from that shown in FIG. 3 in that a connection terminal 24 for supplying electric power for starting, that is, starting power from the outside is provided. That is, since the power conditioner 23 needs to be connected to the grid, in normal times, the power for starting is supplied via the distribution board 14, but when the grid power supply is stopped. In order to enable the fuel cell device 21 to operate independently, starting power can be supplied from a power source different from the system power source via the connection terminal 24. The starting power supplied to the connection terminal 24 is, for example, DC power.

  As the reformer 21 and the fuel cell main body 22, those similar to the reformer 91 and the fuel cell main body 92 in the conventional system shown in FIG. 3 are used.

  The solar power generation device 12 includes a solar cell 31 and a power conditioner 32 that converts the DC power generated by the solar cell 31 into AC power and connects the solar power generation device 12 to the system power supply. When the solar power generation device 12 is used in conjunction with the system power supply, a reverse power flow is permitted, and therefore no reverse power flow prevention device is provided between the solar power generation device 12 and the system power supply. . However, since power should not be supplied from the photovoltaic power generation device 12 to the system power supply side due to reverse power flow at the time of a power failure on the system power supply side, the power conditioner 32 detects a stop (power failure) of the system power supply and A function of disconnecting the photovoltaic power generation device 12 from the system power supply is provided. Specifically, the power conditioner 32 includes an inverter circuit that converts DC power from the solar battery 31 to AC power, but is configured to stop the operation of the inverter circuit when a power failure occurs in the system power supply. . Even if the inverter circuit is stopped, the solar cell 31 can generate power as long as it is exposed to light. Therefore, the power conditioner 32 includes a connection terminal 33 for directly outputting DC power from the solar cell 31. . The connection terminal 24 on the fuel cell device 11 side and the connection terminal 33 on the solar power generation device 12 side can be detachably connected by the emergency wiring 13. In normal times, the connection terminals 24 and 33 are not connected.

  Next, the operation of this power supply system will be described.

  When the system power supply is functioning normally, AC power from the system power supply, AC power from the fuel cell device 11, and AC power from the solar power generation device 12 are supplied to the load via the distribution board 14. Supplied. Even if the fuel cell device 11 needs to be started, the starting power is supplied from the system power source to the power conditioner 23.

  Assume that the system power supply is stopped, that is, a power failure occurs. At this time, the solar power generation device 12 is disconnected from the system power supply, and the distribution board 14 and the distribution board 16 are electrically disconnected by the reverse power flow prevention device 15. In order to start the fuel cell device 11 in this state, the emergency wiring 13 is provided between the connection terminal 33 of the power conditioner 32 of the solar power generation device 12 and the connection terminal 24 of the power conditioner 23 of the fuel cell device 11. And the DC power generated by the solar cell 31 may be supplied to the power conditioner 23 of the fuel cell device 11. As a result, electric power for driving a heater, a pump, and the like is supplied from the power conditioner 23 to the reformer 21 and the fuel cell main body 22, and the fuel cell device 11 can be started. When the fuel cell device 11 is started and reaches a steady operation state, the emergency wiring 13 may be removed and the heater and the pump may be operated with a part of the power generated by the fuel cell main body 22. In this way, in this embodiment, even when the system power supply is stopped, the fuel cell device 11 can be started to be in a self-sustaining operation state, and the AC power generated in the fuel cell device 11 is It can be supplied to the load via the distribution board 14.

  In the present embodiment, it is preferable that the rated output of the solar power generation device 12 be 1 kW or more and less than 10 kW per rated output of 1 kW of the fuel cell device 11 so that the fuel cell device 11 can be reliably started.

  Next, a power supply system according to another embodiment of the present invention will be described with reference to FIG.

  The power supply system shown in FIG. 2 is obtained by removing the photovoltaic power generation device 12 and the distribution board 16 from the power supply system shown in FIG. 1 and connecting the reverse power flow prevention device 15 directly to the system power supply. By removing the solar power generation device 12, the power for starting the fuel cell device 11 cannot be obtained in the event of a power failure of the system power supply. However, in the power supply system shown in FIG. By connecting the device 17 to the power conditioner 23 and supplying DC power stored in the power storage device 17 to the power conditioner 23, the fuel cell device 11 can be started even in the event of a power failure of the system power supply. After the fuel cell device 11 is started and reaches a steady operation state, the power storage device 17 is removed or the power supply from the power storage device 17 is cut off. The operation of this power supply system is the same as that of the power supply system shown in FIG. 1 except that AC power from the solar power generation device does not flow to the load and starting power is supplied from the power storage device 17. It is.

  As the power storage device 17, one having a capacity of 100 W · h or more and less than 300 W · h per 1 kW of the rated output of the fuel cell device 11 is preferably used. The power storage device 17 is charged in advance when the system power supply is functioning normally in order to prepare for a power failure of the system power supply. The power storage device 17 is configured by a secondary battery such as a lead storage battery, a nickel-metal hydride battery, or a lithium ion battery, for example.

It is a block diagram which shows the structure of the power supply system of one Embodiment of this invention. It is a block diagram which shows the structure of the power supply system of another embodiment of this invention. It is a block diagram which shows the structure of the conventional power supply system.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11,81 Fuel cell apparatus 12 Photovoltaic power generation apparatus 13 Emergency wiring 14, 16, 82 Distribution board 15, 83 Reverse power flow prevention apparatus 17 Power storage apparatus 21, 91 Reformer 11, 92 Fuel cell main body 23, 32, 93 Power conditioner 24, 33 Connection terminal 31 Solar cell

Claims (5)

A fuel cell main body, and a power conditioner including a first connection terminal that converts the DC power generated by the fuel cell main body into AC power and is supplied with starting power from the outside. A power supply system having a fuel cell device,
A reverse power flow prevention device provided between the fuel cell device and the system power source, and having a function of disconnecting the fuel cell device from the system power source in the event of a power failure of the system power source ;
A solar power generation device having a solar cell and a second connection terminal for directly outputting DC power from the solar cell, and connected to the system power supply;
Have
At the time of a power failure of the system power supply, the photovoltaic power generation apparatus is disconnected from the system power supply, and the solar power generation is performed by connecting the second connection terminal to the first connection terminal by a removable wiring. the DC power from the device is supplied to the fuel cell system as the starting power, characterized by a self-sustaining operation condition by starting the fuel cell system, the power supply system.   The power supply system according to claim 1, wherein the fuel cell device includes a fuel cell using hydrocarbon as a fuel.   The power supply system according to claim 2, wherein the rated output of the solar power generation device is 1 kW or more and less than 10 kW per rated output of 1 kW of the fuel cell device. 2. The power supply system according to claim 1, wherein after starting the fuel cell device, when the fuel cell device is in a steady operation state, supply of the starting power to the fuel cell device is stopped. The fuel cell device includes a reformer, and the starting power is used to raise at least the reformer to a predetermined temperature and to raise the electrode part and the electrolyte membrane of the fuel cell device to a predetermined temperature. The power supply system according to claim 2 used.

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