JP2017073974A - Distributed power source system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power source system which can perform autonomous power generation without involving an increase in size and cost.SOLUTION: A power generation apparatus control device 19 in the distributed power source system determines, based on a detection signal from a detection device, whether or not power is supplied from a system power (power supply determination unit: step S106), and determines whether or not a communication state between the power generation apparatus control device 19 and an attached device control device is normal (communication state determination unit: step S108). If, in step S108, the communication state between the power generation apparatus control device 19 and the attached device control device is determined to be abnormal and if, in step S106, power is not supplied from the system power, the power generation apparatus control device 19 controls a switchover device to switch power, supplied from the power generation apparatus, to a second load device (switchover control unit: step S110).SELECTED DRAWING: Figure 3

Description

  The present invention relates to a distributed power supply system.

  As one type of distributed power supply system, one disclosed in Patent Document 1 is known. In the distributed power supply system, a voltage detection unit 5 is provided on the further upstream side of the grid connection switching unit 4 for switching connection / disconnection with the system provided on the upstream side of the distribution board 2. When a power failure is detected, the activation control unit 3 that performs activation control of the power generation device brings the grid connection switching unit 4 into a disconnected state and the power generation system is electrically disconnected from the system. Yes. Then, the power generation device is activated using the electric power stored in the storage battery provided in the activation control unit 3 to start the independent power generation.

JP 2009-207325 A

However, in the distributed power system described above, the addition of the voltage detection unit 5 can determine a power failure and start a self-sustaining power generation. However, the system becomes large and the cost increases due to the addition of extra parts. There was a problem.
The present invention has been made to solve the above-described problems, and it is an object of the present invention to be able to reliably perform self-sustained power generation without causing an increase in size and cost in a distributed power supply system.

  In order to solve the above problems, a distributed power supply system according to claim 1 includes a power generation device that generates power and power from the power generation device and power from the system power supply when power transmission from the system power supply is normal. The first load device that can be supplied and the second load that can supply only the power from the power generation device during the self-sustaining power generation operation that supplies only the power from the power generation device when the transmission of the system power supply is stopped The device, the switching device configured to switch the power supply from the power generator to the first load device or the second load device, and the power generator and the first load device are disposed between the power generator and the first load device. A detection device that detects at least one of the voltage and current at the specified position, a power generation device control device that performs at least control of the power generation device, and an associated device that operates accompanying the power generation device, and is supplied from the system power supply An auxiliary device control device that is operated by force and is connected to the power generation device control device so as to be able to communicate with each other. The power generation device control device is supplied with power from a system power source based on a detection signal from the detection device. Communication state determination unit for determining whether or not the communication state between the power supply determination unit and the associated device control device is normal, and the communication state between the communication state determination unit and the associated device control device Switching control for controlling the switching device to switch the power supply from the power generation device to the second load device when it is determined that the power supply is not supplied from the system power supply. And a section.

  According to a second aspect of the present invention, in the distributed power supply system according to the first aspect, the switching device is provided between the power generation device and the first load device to communicate / cut off the power generation device and the first load device. And a second switch that is provided between the power generation device and the second load device and communicates and shuts off the power generation device and the second load device. When the communication state determination unit determines that the communication state with the associated device control device is abnormal and the power supply determination unit determines that power is not supplied from the system power supply, the first switch is opened. At the same time, the second switch is closed.

  The invention according to claim 3 is the distributed power system according to claim 2, wherein the switching control unit determines that the communication state determination unit has an abnormal communication state with the associated device control device, and When the power supply determination unit determines that power is not supplied from the system power supply, the power supply determination unit is supplied with power from the system power supply after the first switch is opened and the second switch is closed. Is determined, the first switch is closed and the second switch is opened.

  According to a fourth aspect of the present invention, in the distributed power system according to any one of the first to third aspects, the circuit further comprises a breaker disposed between the system power source and the switching device. , Between the breaker and the switching device.

  According to a fifth aspect of the present invention, in the distributed power supply system according to any one of the first to fourth aspects, the power generation device includes a fuel cell that generates power using fuel and oxidant gas. Yes.

  In the invention according to claim 1 configured as described above, the associated device control device operates by receiving power supply from the system power supply. Therefore, when an abnormality such as a power failure occurs in the system power supply, Since the associated device control device does not operate, communication with the power generation device control device cannot be performed normally. In this case, the communication state determination unit determines that the communication state with the associated device control device is defective. Further, the power supply determination unit determines that power is not supplied from the system power supply. Therefore, the switching control unit controls the switching device to switch the power supply from the power generation device to the second load device. As a result, it is possible to provide a distributed power supply system that can reliably carry out a self-sustained power generation operation even if the system power supply fails without causing an increase in size and cost.

  In the invention according to claim 2 configured as described above, in the distributed power supply system according to claim 1, the switching device is provided between the power generation device and the first load device, and the power generation device and the first load are provided. A first switch that communicates and blocks the device, and a second switch that is provided between the power generation device and the second load device and communicates and blocks the power generation device and the second load device. The switching control unit determines that the communication state determination unit determines that the communication state with the associated device control apparatus is abnormal, and the power supply determination unit determines that power is not supplied from the system power supply. One switch is opened and the second switch is closed. Thereby, with a simple configuration, it is possible to provide a distributed power supply system that can reliably carry out a self-sustained power generation operation even if the system power supply fails.

  In the invention according to claim 3 configured as described above, in the distributed power supply system according to claim 2, the switching control unit has an abnormal communication state between the communication state determination unit and the associated device controller. And when the power supply determination unit determines that power is not supplied from the system power supply, after the first switch is opened and the second switch is closed, the power supply determination unit is connected to the system. When it is determined that power is supplied from the power source, the first switch is closed and the second switch is opened. Thereby, when the power supply from the system power supply is restored, the power supply from the power generation device can be reliably switched from the first load device to the second load device.

  In the invention according to claim 4 configured as described above, in the distributed power supply system according to any one of claims 1 to 3, a breaker disposed between the system power supply and the switching device is provided. Furthermore, the detection device is provided between the breaker and the switching device. Thereby, it is possible to detect a power failure with a simple configuration without adding new parts.

  In the invention according to claim 5 configured as described above, in the distributed power supply system according to any one of claims 1 to 4, the power generation device is a fuel cell that generates power using fuel and oxidant gas. It is comprised including. As a result, even when the power generation device is constituted by a fuel cell, the self-sustained power generation operation can be reliably performed even if the system power supply is interrupted without causing an increase in size and cost.

1 is a schematic diagram showing an embodiment of a distributed power supply system according to the present invention. It is a schematic diagram of the generator shown in FIG. It is a flowchart of operation | movement when the power failure generate | occur | produces in the distributed power supply system by this invention. It is a schematic diagram of the fuel cell in other embodiment of the distributed power supply system by this invention. It is a schematic diagram of the generator in other embodiment of the distributed power supply system by this invention.

  Hereinafter, an example which is one of the embodiments of the distributed power supply system according to the present invention will be described. FIG. 1 is a schematic diagram showing an overview of this distributed power supply system. This distributed power supply system includes a power generation unit 10 and a hot water storage unit 20.

  The power generation unit 10 includes a power generation device 11, a power supply board 13, and a power generation device control device 19. The power generator 11 generates electric power (AC power in the present embodiment), and includes a generator 11a that generates DC power and a power converter 11b. As shown in FIG. 2, the generator 11a includes a fuel cell 11a1, an evaporation unit 11a2, and a reforming unit 11a3.

  The evaporating section 11a2 is heated by a combustion gas, which will be described later, to evaporate the supplied reforming water to generate water vapor and to preheat the supplied reforming raw material. The evaporation section 11a2 mixes the steam generated in this way with the preheated reforming raw material and supplies a mixed gas to the reforming section 11a3. As reforming raw materials, there are gas fuels for reforming such as natural gas and LPG, and liquid fuels for reforming such as kerosene, gasoline and methanol.

  The reforming unit 11a3 is heated by a combustion gas to be described later and supplied with heat necessary for the steam reforming reaction, so that the reformed gas is generated from the mixed gas (reforming raw material and steam) supplied from the evaporation unit 11a2. Is generated and derived. The mixed gas reacts with a catalyst and is reformed to generate hydrogen gas and carbon monoxide gas (so-called steam reforming reaction). At the same time, a so-called carbon monoxide shift reaction occurs in which carbon monoxide and hydrogen produced by the steam reforming reaction react to transform into hydrogen gas and carbon dioxide. These generated gases (so-called reformed gas) are led out to the fuel electrode of the fuel cell 11a1.

  The fuel cell 11a1 generates power using fuel and oxidant gas. The fuel cell 11a1 is configured by laminating a fuel electrode, an air electrode (oxidant electrode), and a plurality of cells 11a1a made of electrolyte interposed between the two electrodes in the left-right direction in FIG. The fuel cell 11a1 of this embodiment is a solid oxide fuel cell, and uses zirconium oxide, which is a kind of solid oxide, as an electrolyte. Hydrogen, carbon monoxide, methane gas, or the like as fuel is supplied to the fuel electrode of the fuel cell 11a1. On the fuel electrode side of the cell 11a1a, a fuel channel 11a1b through which a reformed gas that is a fuel flows is formed. An air flow path 11a1c through which air (cathode air) as an oxidant gas flows is formed on the air electrode side of the cell 11a1a. Cathode air is supplied to the air flow path 11a1c by a cathode air blower 10a (or a cathode air pump).

In the fuel cell 11a1, power generation is performed by the fuel supplied to the fuel electrode and the oxidant gas supplied to the air electrode. That is, the reaction shown in Chemical Formula 1 and Chemical Formula 2 below occurs at the fuel electrode, and the reaction shown in Chemical Formula 3 below occurs at the air electrode. That is, oxide ions (O ²⁻ ) generated at the air electrode pass through the electrolyte and react with hydrogen at the fuel electrode to generate electrical energy.
(Chemical formula 1)
H ₂ + O ²⁻ → H ₂ O + 2e ⁻
(Chemical formula 2)
CO + O ²⁻ → CO ₂ + 2e ⁻
(Chemical formula 3)
1 / 2O ₂ + 2e ⁻ → O ²⁻

  The combustion gas is obtained by burning the reformed gas not used for power generation derived from the fuel flow path 11a1b with the oxidant gas (air) not used for power generation derived from the air flow path 11a1c.

  As shown in FIG. 1, the power conversion device 11 b converts a direct current supplied from the fuel cell 11 a 1 into an alternating current. The power converter 11b has a function of outputting the converted alternating current. One end of the electric wire 14 is connected to the power converter 11b, and the AC power of the power converter 11b is output to the electric wire 14. A first load device 15 is connected to the other end of the electric wire 14. The power output from the power converter 11b is supplied to the first load device 15 via the electric wire 14 as necessary. The first load device 15 is an electric appliance such as an electric lamp, iron, television, washing machine, electric kotatsu, electric carpet, air conditioner, and refrigerator.

  On the electric wire 14, between the power conversion device 11b and the first load device 15, the other end of the power supply line 31 having one end connected to the system power supply 30 is connected to the connection portion 14a. A distribution board 32 is disposed on the power line 31. When the power consumption of the first load device 15 exceeds the power generated by the power generation unit 10, the insufficient power is supplied from the system power supply 30 from the power supply line 31 via the switchboard 32. . As described above, the first load device 15 is supplied with power from the system power supply 30 and power from the power conversion device 11b.

  On the electric wire 14, between the power converter 11b and the connecting portion 14a, the other end of the electric wire 17 having one end connected to the self-supporting output terminal 16 is connected to the connecting portion 14b. A second load device 18 is detachably connected to the self-supporting output terminal 16.

  When the power supply from the system power supply 30 is stopped (hereinafter referred to as a power failure), the output terminal 16 for self-sustained power generation is performed by the power generation device 11 (fuel cell 11a1) and only the power from the power conversion device 11b is second. It is used only during a power generation operation (hereinafter referred to as a self-sustained power generation operation) supplied to the load device 18. That is, the self-sustained output terminal 16 is configured to output only the electric power generated by the fuel cell 11a1 during the self-sustaining power generation operation in the case of a power failure.

  The second load device 18 is connected to the power conversion device 11b during the self-sustained power generation operation, and only the power from the power conversion device 11b is supplied. The second load device 18 is an electric appliance similar to the first load device 15, but the electric appliance that the user wants to use is connected to the self-sustained output terminal 16 during the self-sustaining power generation operation in the event of a power failure. It is what is done.

  The power converter 11b also has a function of converting AC power from the system power supply 30 supplied via the power line 31 and the electric wire 14 into DC power and outputting the DC power. The DC power output from the power conversion device 11 b is output to the power supply board 13. The power supply board 13 converts the supplied DC power into predetermined DC power and supplies it to the power generator control device 19 and the auxiliary machine 10b. The auxiliary machine 10b is configured to operate with a direct current, which is necessary for operating the power generation unit 10 such as a reforming water pump, a raw material pump, and a temperature sensor of each part (not shown).

  A voltage sensor 31 a is disposed on the power supply line 31 between the system power supply 30 and the switchboard 32. The voltage sensor 31a detects the voltage of the electric power supplied from the system power supply 30 to the power converter 11b. In the present embodiment, the voltage sensor 31a is provided to detect the voltage of the system power supply 30, but a power sensor that detects the power supplied from the system power supply 30 to the power converter 11b is provided. You may make it do.

Furthermore, the power generation unit 10 includes a first switch 14c, a second switch 17a, a sensor 11b1, and a power generation device control device 19.
The first switch 14c is disposed on the electric wire 14 between the connection portion 14a and the connection portion 14b, and electrically disconnects or connects the power converter 11b and the system power supply 30 by opening or closing the circuit. To do. The second switch 17a is disposed between the power conversion device 11b and the second load device 18, and electrically disconnects or connects the power conversion device 11b and the second load device 18 by opening or closing the circuit. Opening and closing device. More specifically, the second switch 17 a is disposed on the electric wire 17 between the connection portion 14 b and the self-supporting output terminal 16.

  The sensor 11b1 is disposed between the power converter 11b and the breaker 14d. More specifically, the sensor 11b1 is disposed between the first switch 14c and the breaker 14d. The sensor 11b1 detects at least one of the voltage and current at the position where the sensor 11b1 is disposed, and detects whether or not the power generation apparatus 11 is supplied with power from the system power supply 30. In the present embodiment, the sensor 11b1 detects the voltage at the disposed position. A voltage detection signal detected by the sensor 11 b 1 is output to the power generation device control device 19. The sensor 11b1 is a detection device that is disposed between the power generation device 11 and the first load device 15 and detects at least one of a voltage and a current at the disposed position.

  A breaker 14d is disposed on the electric wire 14 and between the first switch 14c and the connection portion 14a (that is, between the system power supply 30 and the switching device R). When power is transmitted from the system power supply 30 and an abnormal current (for example, overcurrent) flows through the wire 14 for some reason, the breaker 14d automatically opens the wire 14. ing. As a result, the power generation unit 10 is avoided from being damaged by an abnormal current.

The power generator control device 19 controls at least the power generator 11 (fuel cell 11a1). Specifically, when power is supplied from the system power supply 30, the power generation amount of the fuel cell 11 a 1 is controlled so that the power consumption of the first load device 15 is achieved. At this time, when the power consumption of the first load device 15 exceeds the power generated by the fuel cell 11a1, the insufficient power is received from the system power supply 30 to compensate. In the case of a power failure, control is performed so that the amount of power generated by the fuel cell 11a1 is constant output power (for example, half of the rating (350W)). The power generation amount of the fuel cell 11a1 may be controlled so that the power consumption of the second load device 18 is achieved.
Further, the first switch 14 c and the second switch 17 a are controlled to be opened and closed in accordance with an instruction from the power generator control device 19.

  The power generation device control device 19 is configured to receive a detection signal from the sensor 11b1. The power generation device control device 19 can detect a power failure of the system power supply 30 based on the detection signal of the sensor 11b1. Specifically, when the voltage of the system power supply 30 detected by the sensor 11b1 is equal to or lower than a predetermined voltage (for example, 1/10 or less of the rating), the system power supply 30 is detected as a power failure. The power generation device control device 19 is adapted to receive a detection signal from the voltage sensor 31a.

The hot water storage unit 20 includes a hot water storage tank 21, a hot water storage tank control device 22, and a power supply substrate 23. The hot water storage unit 20 is an accompanying device that operates accompanying the power generation device 11.
The hot water storage tank 21 stores hot water collected by heat exchange of exhaust heat of the power generation apparatus 11 (fuel cell 11a1). A hot water circulation circuit 24 for circulating hot water (hot water) in the hot water tank 21 is connected to the hot water tank 21. A heat exchanger 25 is disposed on the hot water circulation circuit 24. The heat exchanger 25 is connected to the other end of a flow path 25a, one end of which is connected to the discharge port of the generator 11a from which the exhaust heat of the generator 11a is discharged. The heat exchanger 25 performs heat exchange between the exhaust heat supplied via the flow path 25 a and the hot water circulating in the hot water circulation circuit 24. That is, when hot water circulates in the hot water circulation circuit 24 by driving a pump (not shown) during power generation of the power generation unit 10, the waste heat of the power generation unit 10 from which the hot water has been discharged through the flow path 25a is passed through the heat exchanger 25. By recovering, hot water is heated.
For example, in the case of the power generation unit 10, the exhaust heat from the generator 11a refers to exhaust heat from the fuel cell 11a1 and exhaust heat from the reforming unit 11a3. However, the present invention is not limited to this, and any recoverable exhaust heat such as heat of the power generation unit 10 itself can be used.

  The hot water storage tank 21 is provided with one columnar container, in which hot water is stored in a layered manner, that is, hot water in the upper part is the hottest and becomes lower as it goes down, and the hot water in the lower part is stored at the lowest temperature. It has become so. Hot hot water stored in the hot water tank 21 is led out from the upper part of the columnar container of the hot water tank 21, and water such as tap water (low temperature water) is columnar in the hot water tank 21 so as to replenish the derived amount. It is introduced from the lower part of the container. Such a hot water tank 21 is installed near the power generation unit 10.

  Inside the hot water storage tank 21, a temperature sensor group 21a which is a remaining hot water amount detection sensor is provided. The temperature sensor group 21a is composed of a plurality of (in this embodiment, five) temperature sensors 21a-1, 21a-2,..., 21a-5, and is equally spaced along the vertical direction (vertical direction). It is disposed at a distance of a quarter of the vertical height in the hot water tank 21. The temperature sensor 21 a-1 is disposed at the inner upper surface position of the hot water tank 21. Each temperature sensor 21a-1, 21a-2,..., 21a-5 detects the temperature of the liquid (hot water or water) in the hot water storage tank 21 at that position. Based on the detection result of the hot water temperature at each position by the temperature sensor group 21a, the remaining hot water amount in the hot water storage tank 21 is derived by the hot water tank control device 22 to which the detection result of the temperature sensor group 21a is transmitted. It has become. The amount of remaining hot water represents the amount of heat stored in the hot water storage tank 21.

  A hot water supply pipe 26 is connected to the hot water storage tank 21. The hot water supply pipe 26 is provided with a gas water heater (not shown), a temperature sensor 26a, and a flow rate sensor 26b, which are auxiliary heating devices in order from the upstream. The gas water heater heats hot water from the hot water tank 21 passing through the hot water supply pipe 26 to supply hot water. The temperature sensor 26 a detects the temperature of the hot water after passing through the gas water heater, and the detection signal is transmitted to the hot water tank control device 22. That is, the hot water is heated by the gas water heater so that the temperature of the hot water detected by the temperature sensor 26a becomes the set hot water supply temperature. The flow rate sensor 26 b detects the amount of hot water consumption (hot water supply amount) per unit time supplied from the hot water storage tank 21. The detection signal of the flow sensor 26 b is transmitted to the hot water tank control device 22. Although not shown, tap water is joined to the hot water supply pipe 26 between the outlet of the hot water tank 21 and the temperature sensor 26a. Thereby, the temperature of the hot water from the hot water tank 21 is lowered.

  The hot water supply pipe 26 is connected to a plurality of hot water use devices A2a installed in a hot water use place A2 that uses hot water stored in the hot water tank 21 as hot water supply. Examples of the hot water using equipment include a bathtub, shower, kitchen (kitchen faucet), and washroom (toilet faucet). Further, the hot water supply pipe 26 is connected to a heat utilization device A2b installed in a hot water use place A2 where hot water in the hot water storage tank 21 is used as a heat source. Examples of the heat utilization device include bathroom heating, floor heating, and a hot water bathing mechanism.

  The hot water tank control device 22 controls at least the amount of remaining hot water in the hot water tank 21. The hot water tank control device 22 is an accompanying device control device that is operated by electric power supplied from the system power supply 30 and is connected to the power generation device control device 19 so as to communicate with each other. Based on the detection result of the temperature sensor group 21a, the hot water storage tank control device 22 controls the remaining hot water amount in the hot water storage tank 21 by operating a pump (not shown) to circulate and heat the hot water. Further, the hot water tank control device 22 controls a hot water supply temperature by operating a gas water heater (not shown) based on detection results of the temperature sensor 26a and the flow rate sensor 26b.

  The hot water tank control device 22 operates by receiving power supply from the power supply board 23. The power supply board 23 is supplied with AC power from the system power supply 30 via a distribution board 32 distributed by a switchboard 32. A power switch 34 is disposed on the electric wire 33. The power switch 34 is connected to the self-supporting output terminal 16 via the electric wire 35. The power switch 34 receives a command from the power generator control device 19 and switches power supply from the switchboard 32 or power supply from the independent output terminal 16 to the power supply board 23. The power supply board 23 converts the supplied AC power into predetermined DC power and supplies it to the hot water tank control device 22.

  Further, the hot water storage unit 20 includes a hot water tank control remote controller 27. The hot water tank control remote controller 27 is a remote controller that is connected to the hot water tank control device 22 so as to be communicable with each other, and displays at least the hot water storage status of the hot water tank 21 to remotely operate the hot water tank 21. The remote controller 27 displays the hot water storage status of the hot water storage tank 21 such as the remaining amount of hot water in the hot water storage tank 21, the hot water supply temperature, and the hot water consumption. The remote controller 27 can display the operation status of the power generation unit 10 such as the power generated by the generator 11a and the amount of power used.

  Next, an example of a basic operation when power is transmitted from the system power supply 30 of the distributed power supply system described above will be described. The power generation device control device 19 starts the startup operation when the start switch (not shown) is pressed to start the operation or when the operation is started according to the planned operation. Here, when power is supplied from the system power supply 30, the first switch 14 c is controlled by the power generator control device 19 so that the first switch 14 c is closed and the second switch 17 a is opened. Thus, when the power supply from the grid power supply 30 is normal, that is, when the generator 11a is grid-connected to the grid power supply 30, the generation of power by the generator 11a is referred to as grid-connected power generation.

  When the start-up operation is started, the power generation device control device 19 operates an auxiliary device 10b such as a motor-driven pump (not shown), and starts supplying fuel and reformed water to the evaporation section 11a2 of the generator 11a. As described above, a mixed gas is generated in the evaporation unit 11a2, and the mixed gas is supplied to the reforming unit 11a3. In the reforming unit 11a3, a reformed gas is generated from the supplied mixed gas, and the reformed gas is supplied to the fuel cell 11a1. If the reforming unit 11a3 is equal to or higher than the predetermined temperature, the start-up operation is finished and the steady operation (power generation operation) is started.

  During the power generation operation, the power generator control device 19 controls the auxiliary machine 10b so that the power generated by the generator 11a becomes the power of the first load device 15 calculated based on the detection signal from the sensor 11b1. Then, the reformed gas and the cathode air are supplied to the generator 11a. As described above, when the electric power of the first load device 15 exceeds the electric power generated by the generator 11a, the insufficient electric power is received from the system power supply 30 and compensated.

  During such a power generation operation, when a stop switch (not shown) is pressed to stop the power generation operation, or when the operation is stopped according to the operation plan, the power generation device control device 19 is connected to the distributed power supply system. Perform stop operation (stop process).

  The power generator control device 19 stops the supply of the fuel and water to the evaporation unit 11a2, and stops the supply of the reformed gas and air to the fuel cell 11a1. At this time, when the generator 11a is generating electricity with the remaining fuel, the output power is supplied to the auxiliary machine 10b and consumed. When the power generation of the generator 11a with the remaining fuel is finished, the stop operation is finished.

  When such a stop operation ends, the distributed power supply system enters a standby state (standby state). The standby state is the power generation stop state of the distributed power supply system (that is, the start operation, the power generation operation, or the stop operation is not in progress) and waits for a power generation instruction (such as turning on the start switch). It is a state of being. That is, the state at the end of the stop operation state is maintained.

Next, an example of the operation of the distributed power supply system when the system power supply 30 fails will be described with reference to the flowchart shown in FIG.
In step S102, the power generation device control device 19 determines whether or not the power generation unit 10 of the distributed power supply system is performing the grid-connected power generation described above. In this case, the power generation device control device 19 can determine from the operating state of the power generation unit 10 whether it is grid-connected power generation. For example, when the power supply from the system power supply 30 is normal, that is, when the first switch 14 c is closed and the second switch 17 a is opened, and the generator 11 a is connected to the system power supply 30. Is determined to be grid-connected power generation. On the other hand, when the power supply from the system power supply 30 is abnormal (for example, a power failure), that is, the first switch 14 c is opened, the second switch 17 a is closed, and the generator 11 a is connected to the second load device 18. When the power generation unit 10 is connected to the power generation unit 10, it is determined that the power generation unit 10 is not grid-connected power generation.

  In step S104, the power generation device control device 19 determines whether or not the communication state with the hot water tank control device 22 is normal. When the system power supply 30 is not supplied with power to the power line 31 due to an abnormality such as a power failure, the hot water tank control device 22 does not operate (stops) because the hot water tank control device 22 is not supplied with power. The device control device 19 cannot communicate with the hot water tank control device 22. In this case, the power generation device control device 19 determines that the communication state with the hot water tank control device 22 is abnormal (determined as “NO” in step S104), and advances the program to step S116.

  In addition, when the generator 11a is generating electric power (self-sustaining power generation), electric power is supplied to the electric power generation apparatus control apparatus 19 from the electric power generation apparatus 11 (generator 11a). For this reason, even if the power supply unit 10 is not supplied with power from the system power supply 30 due to an abnormality in the system power supply 30, the power generation device control device 19 operates, and the power generation device control device 19 is connected to the hot water tank control device 22. It is possible to determine whether or not the communication state between the two is abnormal.

  On the other hand, in a state where the system power supply 30 is normal and power is supplied to the power supply line 31, since the hot water tank control device 22 is supplied with electric power, the hot water tank control device 22 operates, and the power generation device control device. 19 is in a state where it can communicate with the hot water tank control device 22. In this case, the power generation device control device 19 determines that the communication state with the hot water tank control device 22 is normal (determined as “YES” in step S104), and advances the program to step S106.

  In step S106, the power generation device control device 19 determines whether or not power is being supplied from the system power supply 30 based on the detection signal input from the sensor 11b1 (power supply determination unit). Specifically, in the power generation device control device 19, the voltage from the system power supply 30 detected by the sensor 11b1 (the voltage on the power conversion device 11b side with respect to the breaker 14d) is equal to or lower than a predetermined voltage (for example, 1/10 of the rating). Or less). When determining that the voltage from the system power supply 30 is equal to or lower than the predetermined voltage, the power generation device control device 19 determines that the power is not supplied from the system power supply 30.

  When the power generation device control device 19 determines that power is not supplied from the system power supply 30 (determined as “NO” in step S106), the program proceeds to step S108. On the other hand, when the power generation device control device 19 determines that the power is supplied from the system power supply 30 (determined as “YES” in step S106), the program is returned to the processing in step S102.

  In step S108, the power generation device control device 19 determines whether or not the communication state with the hot water tank control device 22 is normal (communication state determination unit). Similarly to step S104, the power generator control device 19 is in an abnormal communication state with the hot water tank control device 22 in a state where the power source 30 is not supplied with power due to an abnormality such as a power failure. It determines with it being in a state (it determines with "NO" at step S108), and advances a program to step S110. On the other hand, when the system power supply 30 is normal and power is supplied to the power supply line 31, the power generation device control device 19 determines that the communication state with the hot water tank control device 22 is normal (" If “YES” is determined), the program proceeds to step S116.

In step S <b> 110, the power generation device control device 19 self-supports the output power of the power generation device 11 from the system line (power supply line 31: an electric wire that connects the power generation device 11 (or the first load device 15) to the system power supply 30). Switch to the line (electric wire 17: electric wire connecting the power generator 11 to the second load device 18). Specifically, the power generation device control device 19 disconnects the power generation device 11 from the system power supply 30 (disconnects) and opens the power generation device 11 by opening the first switch 14c and closing the second switch 17a. Connect to the second load device 18. At this time, the power generation apparatus 11 performs power generation independently (self-sustaining power generation).
Moreover, it is preferable that the electric power generating apparatus control apparatus 19 switches the power supply switch 34 so that the output terminal 16 for self-supporting and the power supply board 23 may be connected in step S110. When the grid connection is established, the power generation device control device 19 switches the power switch 34 so that the switchboard 32 and the power supply board 23 are connected.

In step S112, the power generation device control device 19 determines whether or not the abnormality of the system power supply 30 has been resolved.
Specifically, in the power generation device control device 19, the voltage from the system power supply 30 is equal to or lower than the predetermined voltage based on the detection signal input from the sensor 11b1, as in step S106 described above. Is determined, it is determined that the power is not supplied from the system power supply 30. When the system power supply 30 recovers normally and the supply of power from the system power supply 30 to the electric wire 14 is recovered, the power generation device control device 19 determines that the power is supplied from the system power supply 30, that is, Then, it is determined that the abnormality of the system power supply 30 has been resolved (determined as “YES” in step S112), and the program proceeds to step S114.

  On the other hand, when the system power supply 30 has not recovered normally, the power generator control device 19 determines that power is not supplied from the system power supply 30, that is, the abnormality of the system power supply 30 has not been resolved. ("NO" is determined in step S112), and the process of step S112 is repeated. In step S112, whether or not the abnormality of the system power supply 30 has been resolved by determining whether the power generation apparatus control device 19 is supplied with power from the system power supply 30 based on the detection signal from the voltage sensor 31a. May be determined.

In step S114, the power generation device control device 19 switches the output power of the power generation device 11 from the self-supporting line (electric wire 17) to the system line (power supply line 31). Specifically, the power generator control device 19 closes the first switch 14c and opens the second switch 17a, thereby disconnecting the power generator 11 from the second load device 18 and connecting the power generator 11 to the system power supply. Reconnect to 30. Thereafter, the power generator control device 19 returns the program to step S102.
In addition, it is preferable that the electric power generating apparatus control apparatus 19 switches the power supply switch 34 so that the switchboard 32 and the power supply board 23 may be connected in step S114.

  In step S116, the power generation device control device 19 stops the power generation operation of the power generation device 11 (the generator 11a), and ends the flowchart shown in FIG. Specifically, the power generator control device 19 outputs a command to the auxiliary machine 10b, stops the supply of fuel and the like, and stops the generator 11a.

  If it is determined in step S106 that the system power supply voltage is abnormal and it is determined in step S108 that the power generation device control device 19 and the hot water tank control device 22 are in a communicable state, the power generation device control is performed. The device 19 determines that the breaker 14d is activated and the electric wire 14 is cut off. That is, the fact that the power generation device control device 19 and the hot water tank control device 22 are in a communicable state is that, as described above, the hot water tank control device 22 is supplied with electric power from the system power supply 30. In this state, the reason why the power conversion device 11b is not supplied with power from the system power supply 30 is that the breaker 14d is activated and the electric wire 14 is cut off. The cause of the operation of the breaker 14d includes a case where an overcurrent flows through the electric wire 14 due to an abnormality such as a short circuit or leakage in a heater (for example, a fuel cell ignition heater) or the power generation unit 10 (not shown).

  The first switch 14c and the second switch 17a are used to switch the power supply from the power generation device 11 to the first load device 15 or the second load device 18 as described in the claims (with the power generation device 11 and A switching device R configured to switch the connection with the first load device 15 or the connection between the power generation device 11 and the second load device 18 is configured. In addition, the switching device R may be configured to provide one switching device having one input contact and two output contacts at the connection point 14b. In this case, the input contacts may be connected to the power generator 11 and the first load device 15 and the second load device 18 may be connected to the output contacts, respectively.

  According to the present embodiment, the hot water tank control device 22 (accompanying device control device) operates by receiving power supply from the system power supply 30, and therefore, when an abnormality such as a power failure occurs in the system power supply 30. Since the hot water tank control device 22 does not operate, communication with the power generator control device 19 cannot be performed normally. In this case, the power generation device control device 19 (communication state determination unit: step S108) determines that the communication state with the hot water tank control device 22 is defective. Furthermore, the power generation device control device 19 (power supply determination unit: step S106) determines that power is not supplied from the system power supply 30. Accordingly, the power generation device control device 19 (switching control unit: step S110) controls the switching device R to switch the power supply from the power generation device 11 to the second load device 18. As a result, it is possible to provide a distributed power supply system that can reliably carry out a self-sustained power generation operation even when the system power supply 30 is powered down without causing an increase in size and cost. In addition, during the self-sustaining power generation operation, the power supply from the power generation device 11 to the second load device 18 can be reliably performed.

  In addition, the switching device R is provided between the power generation device 11 and the first load device 15, and communicates and blocks the power generation device 11 and the first load device 15. And a second switch 17a provided between the two load devices 18 and communicating and blocking between the power generation device 11 and the second load device 18, and includes a power generation device control device 19 (switching control unit: step). S110), when the communication state determination unit determines that the communication state with the hot water tank control device 22 is abnormal, and the power supply determination unit determines that power is not supplied from the system power supply 30, The first switch 14c is opened and the second switch 17a is closed. Thereby, with a simple configuration, it is possible to provide a distributed power supply system that can reliably carry out a self-sustaining power generation operation even when the system power supply 30 fails.

  Further, the switching control unit determines that the communication state determination unit is in an abnormal communication state with the hot water tank control device 22 and determines that the power supply determination unit is not supplied with power from the system power supply 30. In this case, after the first switch 14c is opened and the second switch 17a is closed, the power supply determination unit (step S112) determines that power is supplied from the system power supply 30 (recovery). In this case, the first switch 14c is closed and the second switch 17a is opened. Thereby, when the power supply from the system power supply 30 is restored, the power supply from the power generation device 11 can be reliably switched from the first load device 15 to the second load device 18.

  Further, a breaker 14d disposed between the system power supply 30 and the switching device R is further provided, and the detection device is disposed between the breaker 14d and the switching device R. Thereby, it is possible to detect a power failure with a simple configuration without adding new parts.

  The power generator 11 includes a fuel cell 11a1 that generates power using fuel and oxidant gas. As a result, even when the power generation device 11 is configured by the fuel cell 11a1, the self-sustained power generation operation can be reliably performed even if the system power supply is interrupted without causing an increase in size and cost.

  Although the fuel cell 11a1 in the above-described embodiment is a solid oxide fuel cell, the present invention may be applied to a polymer electrolyte fuel cell. In this case, as shown in FIG. 4, the generator 11a is mainly composed of a fuel cell 51a and a reformer 51b.

  The fuel cell 51a is supplied with a fuel gas (hydrogen gas) and an oxidant gas (air containing oxygen), generates power by a chemical reaction between hydrogen and oxygen, and outputs a direct current (for example, 40V).

  The reformer 51b steam-reforms the fuel (reforming fuel) and supplies the hydrogen-rich reformed gas to the fuel cell 51a. The reformer 51b burner (combustion unit) 51b1, reforming unit 51b2, and monoxide It comprises a carbon shift reaction part (hereinafter referred to as CO shift part) 51b3 and a carbon monoxide selective oxidation reaction part (hereinafter referred to as CO selective oxidation part) 51b4. Examples of the fuel include natural gas, LPG, kerosene, gasoline, and methanol.

  The burner 51b1 is supplied with combustion fuel and combustion air from the outside during start-up operation, or anode off-gas (reformed gas discharged without being supplied to the fuel cell 51a) from the fuel electrode of the fuel cell 51a during steady operation. The supplied combustible gas is combusted and the combustion gas is led out to the reforming part 51b2.

  The reforming unit 51b2 reforms a mixed gas obtained by mixing the fuel supplied from the outside with the water vapor (reformed water) from the evaporator by using a catalyst charged in the reforming unit 51b2, and hydrogen gas and carbon monoxide gas. (So-called steam reforming reaction). At the same time, carbon monoxide and steam generated by the steam reforming reaction are converted into hydrogen gas and carbon dioxide (so-called carbon monoxide shift reaction). These generated gases (so-called reformed gas) are led to the CO shift unit 51b3.

  The CO shift unit 51b3 is converted into hydrogen gas and carbon dioxide by reacting carbon monoxide and water vapor contained in the reformed gas with a catalyst filled therein. Thus, the reformed gas is led to the CO selective oxidation unit 51b4 with the carbon monoxide concentration reduced.

  The CO selective oxidation unit 51b4 generates carbon dioxide by reacting carbon monoxide remaining in the reformed gas with CO purification air further supplied from the outside using a catalyst filled therein. . As a result, the reformed gas is further reduced in carbon monoxide concentration (10 ppm or less) and is led to the fuel electrode of the fuel cell 51a.

  Further, in the above-described embodiment, the generator 11a is not a fuel cell generator that generates power using fuel such as natural gas, LPG, kerosene, gasoline, or methanol, but an engine generator or the like or natural energy. A solar power generator, a wind power generator, or the like, or a combination thereof is included.

  The configuration when the generator 11a is an engine generator will be described with reference to FIG. The engine generator converts the thermal energy generated by combustion of fuel and air supplied from a fuel supply device (not shown) into rotational energy (kinetic energy), and generates electric current as electric energy from the rotational energy. A generator main body 52b is provided. The engine 52a includes internal combustion engines such as gas turbine engines and reciprocating engines, and external combustion engines such as steam turbine engines.

  In the above-described embodiment, the distributed power supply system of the present invention has been described by taking the hot water storage unit 20 as an example of an accompanying device that operates accompanying the power generation device 11. However, the accompanying device is not limited to the hot water storage unit 20, and has an accompanying device control device that operates with the power supplied from the system power supply 30, and the accompanying device control device communicates with the power generation device control device 19. The technical idea of the present invention can be applied to any distributed power supply system having such an accompanying device.

Furthermore, as another embodiment of the distributed power supply system according to the present invention, an embodiment in which the self-supporting output terminal 16 is omitted is also conceivable. In this case, the second load device 18 is always directly connected to the second switch 17a even when there is power transmission from the system power supply 30 or a power failure. When there is power transmission from the system power supply 30, the second switch 17 a is opened, so that no power is supplied to the second load device 18. On the other hand, since the second switch 17a is closed during the self-sustaining power generation operation in the case of a power failure, only the power from the generator 11a is automatically supplied to the second load device 18 regardless of the user. It will be.
Furthermore, in the above-described embodiment, power is supplied to the power supply board 23 via the power switch 34, but may be directly supplied from the distribution board 32 without using the power switch 34.

DESCRIPTION OF SYMBOLS 10 ... Power generation unit, 11 ... Power generation device, 11a ... Generator, 11a1 ... Fuel cell, 11b ... Power converter, 11b1 ... Sensor, 14 ... Electric wire, 14c ... First switch, 15 ... First load device, 17 ... Electric wire, 17a ... second switch, 18 ... second load device, 19 ... power generation device control device (power supply determination unit, communication state determination unit, switching control unit), 20 ... hot water storage unit, 21 ... hot water storage tank, 22 ... hot water storage Tank control device (accompanying device control device), 24 ... hot water circulation circuit, 25 ... heat exchanger, 25a ... flow path, 27 ... hot water tank control remote control, 27a ... display unit, 30 ... system power supply, 31 ... power line, 31a ... Voltage sensor, R ... Switching device.

Next, an example of the operation of the distributed power supply system when the system power supply 30 fails will be described with reference to the flowchart shown in FIG .

When the power generation device control device 19 determines that power is not supplied from the system power supply 30 (determined as “NO” in step S106), the program proceeds to step S108. On the other hand, when the power generation device control device 19 determines that the power is supplied from the system power supply 30 (determined as “YES” in step S106 ), the determination processing in step S106 is performed.

In step S108, the power generation device control device 19 determines whether or not the communication state with the hot water tank control device 22 is normal (communication state determination unit) . The system integrated power supply 30 is a power failure or the like abnormality in the state in which the power supply line 31 is not supplied, since the power in the hot water storage tank control device 22 is not supplied, the hot water storage tank control device 22 does not operate (stop), The power generation device control device 19 cannot communicate with the hot water tank control device 22. In this case, the power generation device control device 19 determines that the communication state with the hot water tank control device 22 is abnormal (determined as “NO” in step S108), and advances the program to step S110. In addition, when the generator 11a is generating electric power (self-sustaining power generation), electric power is supplied to the electric power generation apparatus control apparatus 19 from the electric power generation apparatus 11 (generator 11a). For this reason, even if the power supply unit 10 is not supplied with power from the system power supply 30 due to an abnormality in the system power supply 30, the power generation device control device 19 operates, and the power generation device control device 19 is connected to the hot water tank control device 22. It is possible to determine whether or not the communication state between the two is abnormal.
On the other hand, if the system power supply voltage is determined to be abnormal at step S106, and a power generator control device 19 and the hot water storage tank control device 22 is determined to be ready for communication at step S108 (step S 106 , 108 determine “NO” and “YES” respectively ), and the power generation device control device 19 advances the program to step S116.

In step S114, the power generation device control device 19 switches the output power of the power generation device 11 from the self-supporting line (electric wire 17) to the system line (power supply line 31). Specifically, the power generator control device 19 closes the first switch 14c and opens the second switch 17a, thereby disconnecting the power generator 11 from the second load device 18 and connecting the power generator 11 to the system power supply. Reconnect to 30. Thereafter, the power generation device control device 19 returns the program to step S106 .
In addition, it is preferable that the electric power generating apparatus control apparatus 19 switches the power supply switch 34 so that the switchboard 32 and the power supply board 23 may be connected in step S114.

Claims (5)

A power generator for generating electric power;
A first load device capable of supplying power from the power generation device and power from the system power supply when transmission of the system power supply is normal;
A second load device capable of supplying only the power from the power generation device during the self-sustaining power generation operation for supplying only the power from the power generation device when power transmission of the system power supply is stopped;
A switching device configured to switch the power supply from the power generation device to the first load device or the second load device;
A detection device disposed between the power generation device and the first load device to detect at least one of a voltage and a current at the disposed position;
A power generator control device that at least controls the power generator;
An auxiliary device that controls the auxiliary device that operates in association with the power generation device, operates with the power supplied from the system power supply, and is connected to the power generation device control device so as to be communicable with each other.
The power generator control device is:
Based on a detection signal from the detection device, a power supply determination unit that determines whether power is supplied from the system power supply,
A communication state determination unit that determines whether or not the communication state with the accompanying device control device is normal;
When the communication state determination unit determines that the communication state with the associated device control device is abnormal, and the power supply determination unit determines that power is not supplied from the system power supply, the switching device is And a switching control unit that controls the power supply from the power generation device to switch to the second load device. The switching device includes a first switch provided between the power generation device and the first load device to communicate and block the power generation device and the first load device, the power generation device, and the second load. A second switch that is provided between the power generator and the second load device to communicate with and shut off the power generation device,
The switching control unit determines that the communication state determination unit determines that the communication state with the associated device control apparatus is abnormal and determines that the power supply determination unit is not supplied with power from the system power supply. The distributed power supply system according to claim 1, wherein the first switch is opened and the second switch is closed.   The switching control unit determines that the communication state determination unit determines that the communication state with the associated device control apparatus is abnormal and determines that the power supply determination unit is not supplied with power from the system power supply. In addition, when the first switch is opened and the second switch is closed, and the power supply determination unit determines that power is supplied from the system power supply, the first switch The distributed power supply system according to claim 2, wherein the second switch is opened and the second switch is opened. A breaker disposed between the system power supply and the switching device;
The distributed power supply system according to any one of claims 1 to 3, wherein the detection device is disposed between the breaker and the switching device.   The distributed power supply system according to any one of claims 1 to 4, wherein the power generation device includes a fuel cell that generates power using fuel and an oxidant gas.

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