JP6023985B2 - Fuel cell system - Google Patents

Description

  The present invention relates to a fuel cell system.

  Conventionally, fuel cell systems using solid polymer and phosphoric acid fuel cells are mainly used in systems, etc., and effectively use energy by recovering heat generated simultaneously with power generation as hot water. It is attracting attention as a highly efficient distributed power source.

  This fuel cell system generally generates electricity using a gas meter equipped with a microcomputer from a gas supplier, that is, a city gas supplied via a so-called microcomputer meter. This microcomputer meter shuts off the flow of gas when the flow rate of gas within the predetermined shutoff target fluctuation range flows continuously for a predetermined monitoring time, but the fuel cell system normally uses a certain amount of gas during power generation. Therefore, the fluctuation range of the gas flow rate is expected to be within a certain range. That is, if the fuel cell system continues the power generation state for a certain time, the microcomputer meter shut-off condition is satisfied, and as a result, the gas supply may be shut off. To avoid this, the fuel cell system burns the gas within a predetermined time during power generation and temporarily changes the output of the combustor that generates heat, thereby blocking the flow rate of city gas passing through the microcomputer meter. The flow rate is not temporarily included, and the microcomputer meter is prevented from being interrupted (see, for example, Patent Document 1).

  The fuel cell system of Patent Document 1 includes a gas meter having a shut-off function for shutting off a flow of a city gas when a city gas having a flow rate within a predetermined shut-off target range flows continuously over a predetermined monitoring time, and a gas meter The generator is configured to be supplied with city gas through a power source, generate power at a rated output, an auxiliary heat source that generates heat by burning fuel gas, and a controller that controls the output of the auxiliary heat source and the generator.

JP 2009-243736 A

  In the conventional configuration, when the power generation state continues, the control unit temporarily changes the output of at least one of the auxiliary heat source or the generator that consumes the city gas at least once within the monitoring time. Thus, the flow rate of the city gas passing through the microcomputer meter is temporarily changed to a flow rate that is not included in the cutoff target range. However, in the conventional configuration, the path for returning hot water generated by power generation to the hot water storage tank and the path for returning hot water generated by burning city gas with an auxiliary heat source such as a gas water heater to the hot water storage tank by joining the microcomputer meter is avoided. In the case of this configuration, the present inventors have revealed that the following problems occur.

  In other words, when the flow rate of hot water that returns hot water generated by power generation to the hot water storage tank is smaller than the flow rate of hot water that is returned to the hot water storage tank by hot water generated by burning city gas with an auxiliary heat source by avoiding shutoff of the microcomputer meter, The flow of hot water having a small flow rate stops at the portion where the hot water is generated, so that the hot water generated by the power generation cannot be returned to the hot water storage tank and stays in the pipe, and the temperature of the hot water may rise excessively. At this time, when the hot water in the pipe reaches a certain temperature or more, power generation cannot be continued.

  The present invention takes into account problems such as those in the past, and before the microcomputer meter shuts off avoidance, by increasing the flow rate of hot water that returns hot water generated by power generation to the hot water storage tank, An object of the present invention is to provide a fuel cell system capable of reliably returning hot water generated by power generation to a hot water storage tank even when hot water generated by burning gas with an auxiliary heat source is returned to the hot water storage tank.

In order to solve the conventional problems, the fuel cell system of the present invention includes:
A fuel cell stack that generates electricity by reacting fuel and oxidant gas; and
A heat recovery path configured such that water flowing out of the hot water storage tank storing water absorbs heat of the fuel cell stack and returns to the hot water storage tank;
A first circulator disposed in the heat recovery path;
A combustor that burns combustible gas to heat water;
A branch path configured to branch from the heat recovery path upstream of the fuel cell stack and return to the heat recovery path downstream of the fuel cell stack via the combustor;
The combustor is arranged downstream of the second circulator and the second circulator in the branch path,
Increasing the amount of combustible gas burned in the combustor when performing a cut-off avoidance operation that fluctuates the amount of combustible gas burned in the combustor to avoid shutting off the microcomputer meter that detects the flow of combustible gas And a controller for controlling the operation amount of the first circulator to be greater than or equal to the first predetermined operation amount , and increasing the operation amount of the second circulator.
A fuel cell system comprising:
Control is performed so that the operation amount of the first circulator is greater than or equal to the first predetermined operation amount in order to make the flow rate of hot water that returns hot water generated by power generation back to the hot water storage tank when the microcomputer meter shuts off is avoided. Do.

  With this configuration, even when hot water generated by burning gas with an auxiliary heat source when the microcomputer meter is shut off is returned to the hot water storage tank, a flow rate at which hot water generated by power generation does not stay in the pipe is ensured. Furthermore, even if microcomputer meter shut-off avoidance is implemented, hot water generated by power generation will remain in the piping even when hot water generated by burning gas with an auxiliary heat source is returned to the hot water storage tank in order to avoid shut-off of the micrometer. There is no, and power generation can be continued.

  In the fuel cell system of the present invention, hot water generated by power generation does not stay in the pipes and power generation can be continued even if the fuel cell unit avoids shutting off the microcomputer meter during power generation.

1 is a block diagram schematically showing the configuration of a fuel cell system according to Embodiment 1 of the present invention. The flowchart which shows the operation control of the fuel cell system in Embodiment 1 of this invention.

The first invention is
A fuel cell stack that generates electricity by reacting fuel and oxidant gas; and
A heat recovery path configured such that water flowing out of the hot water storage tank storing water absorbs heat of the fuel cell stack and returns to the hot water storage tank;
A first circulator disposed in the heat recovery path;
A combustor that burns combustible gas to heat water;
A branch path configured to branch from the heat recovery path upstream of the fuel cell stack and return to the heat recovery path downstream of the fuel cell stack via the combustor;
Increasing the amount of combustible gas burned in the combustor when performing a cut-off avoidance operation that fluctuates the amount of combustible gas burned in the combustor to avoid shutting off the microcomputer meter that detects the flow of combustible gas And a controller for controlling the operation amount of the first circulator to be greater than or equal to the first predetermined operation amount , and increasing the operation amount of the second circulator.
This is a fuel cell system.

  With this configuration, even when the fuel cell unit avoids shutting off the microcomputer meter during power generation, the operation amount of the first circulator is set to be equal to or greater than the first predetermined operation amount, so that hot water generated by the power generation is generated in the pipe. Power generation can be continued without stagnation.

  According to a second aspect of the invention, particularly in the first aspect of the invention, the controller sets the power generation amount of the fuel cell stack to be equal to or greater than the first predetermined power generation amount and performs the operation amount of the first circulator when performing the shut-off avoiding operation. The fuel cell system has a first predetermined operation amount or more.

  With this configuration, even when the fuel cell unit avoids shutting off the microcomputer meter during power generation, the operation amount of the first circulator is set to be equal to or greater than the first predetermined operation amount, so that hot water generated by the power generation is generated in the pipe. Power generation can be continued without stagnation.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 is a block diagram schematically showing the configuration of the fuel cell system according to the first embodiment of the present invention.

  In FIG. 1, the fuel cell system 1 according to Embodiment 1 includes a fuel cell stack 10 that generates power by reacting a fuel and an oxidant gas, and water flowing out of a hot water storage tank 5 that stores water. And a heat recovery path 13 configured to absorb the heat of the fuel cell stack 10 and return to the hot water storage tank 5.

  In addition, the fuel cell system 1 includes a first circulator 14 disposed in the heat recovery path 13, a combustor 6 that burns combustible gas to heat water, and heat recovery on the upstream side of the fuel cell stack 10. And a branch path 7 configured to branch from the path 13 and return to the heat recovery path 13 on the downstream side of the fuel cell stack 10 via the combustor 6. A heat exchanger 16 is disposed in the heat recovery path 13 to absorb the heat of the fuel cell stack 10.

  The fuel cell system 1 also includes a first circulator when the combustor 6 performs a shut-off avoiding operation for changing the combustion amount of the combustible gas in order to avoid shut-off of the microcomputer meter that detects the flow rate of the combustible gas. 14 is provided with a controller 12 that controls the operation amount 14 to be greater than or equal to the first predetermined operation amount and controls the power generation amount of the stack to be greater than or equal to the predetermined amount.

  The branch path 7 includes a second circulator 8 and a combustor 6 disposed downstream from the second circulator 8.

  The operation and action of the microcomputer meter of the fuel cell system configured as described above will be described with reference to FIG.

  FIG. 2 is a flowchart showing shut-off avoidance of the microcomputer meter of the fuel cell system according to Embodiment 1 of the present invention.

The controller 12 of the fuel cell system 1 instructs the fuel cell stack 10 to generate a predetermined power generation amount (S101). The controller 12 determines whether the power generation amount of the fuel cell stack 10 is equal to or greater than a predetermined value (S102). If the power generation amount of the fuel cell stack 10 is not equal to or greater than the predetermined power generation amount, the fuel cell stack 10 is instructed to generate the predetermined power generation amount (S101).

  When the power generation amount of the fuel cell stack 10 is equal to or greater than the predetermined power generation amount, the controller 12 instructs the first circulator to have an operation amount equal to or greater than the predetermined amount (S103). The controller 12 determines whether or not the operation amount of the first circulator 14 is greater than or equal to a predetermined value (S104). Note that whether or not the operation amount of the first circulator 14 is equal to or greater than a predetermined value may be determined by the number of rotations of the first circulator 14. Whether or not the operation amount of the first circulator 14 is greater than or equal to a predetermined value may be determined by whether or not the flow rate of the heat recovery path 13 is greater than or equal to a predetermined value. In addition, when the power generation amount of the fuel cell stack 10 is equal to or greater than the predetermined power generation amount, when the operation amount of the first circulator 14 is equal to or greater than the predetermined amount, The operation amount of the first circulator 14 may be determined to be a value greater than or equal to a predetermined value.

  If the operation amount of the first circulator 14 is not greater than or equal to a predetermined value, the controller 12 controls the first circulator 14 with an operation amount greater than or equal to a predetermined amount when the power generation amount of the fuel cell stack 10 is greater than or equal to the predetermined power generation amount. (S103).

  When the operation amount of the first circulator 14 is equal to or greater than a predetermined value, the controller 12 determines whether or not a certain time has elapsed since the operation amount of the first circulator 14 became equal to or greater than the predetermined value (S105). When the controller 12 determines that a certain time has elapsed since the operation amount of the first circulator 14 becomes equal to or greater than a predetermined amount, the controller 12 avoids shutting off the microcomputer meter (S106). Specifically, the amount of city gas burned in the combustor 6 is increased, and the amount of operation of the second circulator 8 is increased so that the heat generated in the combustor 6 is transferred to the heat recovery path 13, the branch path 7, It is made to return to the hot water storage tank 5 through the junction 15 and the heat recovery path 13.

  As a result, even when the fuel cell unit performs power generation avoidance of shutoff of the microcomputer meter, the operation amount of the first circulator is predetermined so that hot water generated by power generation does not stay in the piping of the heat recovery path. By setting it to the above value, power generation can be continued without the temperature of hot water in the heat recovery path rising above a specified level. That is, when the water discharged from the hot water storage tank 5 is supplied to the junction 15 via the heat recovery path 13 and the heat exchanger 16, the water does not flow in the junction 15 during the operation of the microcomputer meter in the cut-off beach. Can be suppressed.

  According to the fuel cell system of the present invention, hot water generated by power generation does not stay in the pipe even if the fuel cell unit performs power generation to avoid shutting off the microcomputer meter, and power generation can be continued. A fuel cell unit having a self-sustaining power generation function that operates by supplying power from the fuel cell stack when the commercial power source is out of power; This is useful in a solid polymer type or solid oxide type fuel cell system having a hot water storage unit that operates with electric power supplied from a commercial power source.

DESCRIPTION OF SYMBOLS 1 Fuel cell system 5 Hot water storage tank 6 Combustor 7 Branch path 8 2nd circulator 10 Fuel cell stack 12 Controller 13 Heat recovery path 14 1st circulator

Claims (2)

A fuel cell stack that generates electricity by reacting fuel and oxidant gas; and
A heat recovery path configured such that water flowing out of a hot water storage tank storing water absorbs heat of the fuel cell stack and returns to the hot water storage tank;
A first circulator disposed in the heat recovery path;
A combustor that burns combustible gas to heat water;
A branch path configured to branch from the heat recovery path upstream of the fuel cell stack and to return to the heat recovery path downstream of the fuel cell stack via the combustor;
A second circulator is disposed in the branch path, and the combustor is disposed downstream of the second circulator.
Combustion amount of combustible gas in the combustor when performing a shut-off avoiding operation in which the combustion amount of the combustible gas is varied in the combustor in order to avoid shutoff of the microcomputer meter that detects the flow rate of the combustible gas And a controller for controlling an operation amount of the first circulator to be equal to or greater than a first predetermined operation amount , and increasing an operation amount of the second circulator.
A fuel cell system. The controller makes the power generation amount of the fuel cell stack equal to or greater than a first predetermined power generation amount and the operation amount of the first circulator to be equal to or greater than the first predetermined operation amount when executing the shut-off avoiding operation. ,
The fuel cell system according to claim 1.

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