JP4212266B2 - Fuel cell power generation system and control method of fuel cell power generation system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fuel cell power generation system and a control method for a fuel cell power generation system that can ensure safety by detecting this without relying on a gas detector even when a fuel gas leak occurs.
[0002]
[Prior art]
As is well known, a fuel cell power generation system supplies hydrogen generated from raw material fuel by a reformer (reformer) that generates hydrogen-rich gas from raw material fuel and oxygen in the atmosphere to the fuel cell body, This is a system that generates direct-current power by electrochemically reacting these in the fuel cell body.
[0003]
Specifically, a raw fuel gas containing hydrocarbons such as natural gas, LPG (liquefied propane gas), biogas, etc. is sent to a reformer, where the raw fuel gas is reformed with steam to generate hydrogen. Generate. This reforming reaction is a large endothermic reaction, and the heat required for this is supplied by sending the hydrogen surplus in the fuel cell body to a burner provided in the reformer and burning it here. Then, the gas reformed by the reformer in this way is sent to the carbon monoxide converter, and the carbon monoxide contained in the reformed gas is converted into carbon dioxide and hydrogen. Carbon monoxide, which is a poisoning component of the battery catalyst contained in the reformed gas, is removed to obtain a gas having a higher hydrogen concentration.
[0004]
Then, the hydrogen thus obtained and oxygen in the atmosphere are supplied to the fuel cell body, and they are electrochemically reacted in the fuel cell body to generate DC power.
[0005]
The fuel cell body includes a fuel electrode and an oxidant electrode, and electricity can be generated by reacting hydrogen and oxygen.
[0006]
The fuel cell power generation system has such a structure. Conventionally, the reformer, the carbon monoxide transformer, and the fuel cell main body are stored in the package, and the package maintains the safety and the internal temperature. For the purpose of restraining the rise, it has a function (ventilator) for sufficient ventilation. Also, in the unlikely event that an excessive fuel leak occurs, a combustible gas detector is installed near the ventilating air outlet by the ventilator, and if the combustible gas concentration here rises above a certain value, The combustible gas detector and the system control device output an alarm signal or perform an automatic stop operation.
[0007]
FIG. 9 shows a configuration of a conventional fuel cell power generation system. As shown in the figure, in the conventional normal fuel cell power generation system, main devices such as the fuel cell main body FC and the reformer FP are stored in the package P, and the package P has ventilation as described above. And ventilation fan F is installed for the purpose of preventing internal temperature rise. A combustible gas detector GS that detects a combustible gas such as hydrogen and generates a detection output corresponding to the detected amount is provided downstream of the ventilation, and a detection signal from the combustible gas detector GS is supplied to the control device CNT to generate fuel. In the unlikely event that a fuel leak occurs in the system, the control device CNT outputs an alarm from this detection signal, and the control device CNT also performs an automatic stop control operation of the fuel cell power generation system. I try to let them.
[0008]
[Problems to be solved by the invention]
However, since the conventional technology is based on the premise that the combustible gas (fuel gas) leak in the system is monitored by the combustible gas detector, the cost and installation space for that cannot be avoided. Therefore, the fuel cell power generation system as a whole has been a factor in reducing costs and making it more compact.
[0009]
In particular, as the fuel cell power generation system becomes smaller, the installation of such a combustible gas detector does not become ridiculous in terms of cost and the proportion occupied by the exclusive area, which is a major problem in terms of cost reduction and compactness. It was.
[0010]
Accordingly, an object of the present invention is to provide a fuel cell power generation system and a control method for the fuel cell power generation system that can be downsized while maintaining safety. It is another object of the present invention to provide a fuel cell power generation system and a control method for the fuel cell power generation system that can reduce costs while maintaining safety.
[0011]
[Means for Solving the Problems]
In order to achieve the above object, the present invention is configured as follows. That is, the present invention is obtained by (i) a reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons such as natural gas, LPG, biogas, and the like. In the fuel cell power generation system comprising the reformed gas as a fuel gas and a fuel cell main body that generates electric energy by an electrochemical reaction between the fuel gas and an oxidant gas such as air,
[1] First, the present invention provides a fuel cell power generation system having the configuration (i),
Temperature detecting means for detecting the temperature of the reformer;
Means for generating an upper limit value of a flow rate of fuel supplied to the fuel cell body in correspondence with an output current value or load amount of electric energy generated by the fuel cell body;
When the flow rate setting value for instructing the flow rate of the fuel supplied from the reformer to the fuel cell main body reaches the upper limit of the flow rate, the temperature detection means lowers the temperature of the reformer and heats the reformer When there is a misfire of the burner or when the voltage (battery voltage) of the fuel cell main body is lowered, a system control means is provided that performs at least one of alarming or stopping control of the fuel cell power generation system.
[0012]
In the present invention, an upper limit value (upper limit value of the flow rate of the fuel supplied to the fuel cell main body) with respect to the fuel flow rate setting value supplied to the fuel cell is generated, and the flow rate of the supplied fuel (the flow rate of the fuel supplied to the fuel cell main body) Or the flow rate of the raw fuel supplied to the reformer; in any case, the result is the concept of the flow rate of fuel supplied to the fuel cell body). Stop the system automatically.
[0013]
An excessive fuel leak occurs inside the fuel cell power generation system, and when the supplied fuel reaches the upper limit, the fuel in the system becomes insufficient, resulting in a decrease in battery voltage and abnormal combustion of the reformer burner. Therefore, when the above limit value is reached, the battery voltage drop and reformer burner combustion abnormality are detected, and when these abnormalities occur, the operation of the fuel cell power generation system is automatically stopped. By making the protection function of the system function, it becomes possible to ensure the safety of the system against fuel leakage.
[0014]
In addition, according to this configuration, a gas detector is not required for detecting fuel leak, and an inexpensive and compact system can be provided because the gas detector is not required.
[0015]
[2] Second, the present invention relates to a fuel cell power generation system having the configuration (i),
Temperature detecting means for detecting the temperature of the reformer;
Means for generating an upper limit value of a flow rate of fuel supplied to the fuel cell body in correspondence with an output current value or load amount of electric energy generated by the fuel cell body;
When the flow rate setting value for instructing the flow rate of the fuel supplied from the reformer to the fuel cell main body reaches the upper limit of the flow rate, the temperature detection means lowers the temperature of the reformer and heats the reformer A system control that issues a warning when a burner misfires or a voltage (battery voltage) of the fuel cell main body is lowered, and performs a stop control of the fuel cell power generation system when the state of the warning is continued for a predetermined time. And a means provided.
[0016]
In this invention, an upper limit value (upper limit value of the flow rate of fuel supplied to the fuel cell main body) for the fuel flow rate setting value of the fuel gas supplied to the fuel cell main body is generated, and the flow rate of the supplied fuel (supplied to the fuel cell main body). The alarm signal is issued by the alarm function of the system when the flow rate of fuel or the flow rate of raw fuel supplied to the reformer reaches this limit value.
[0017]
When an excessive fuel leak occurs in the fuel cell power generation system and the supplied fuel reaches the upper limit value, the protection monitoring function of the system is activated. As a result of a fuel leak, the fuel in the system becomes insufficient, resulting in a decrease in battery voltage and abnormal combustion of the reformer burner. When the limit value is reached, the decrease in battery voltage or reformer burner occurs. By detecting the occurrence of combustion abnormalities in the system and using a system protection function that issues an alarm when these abnormalities occur, it is possible to promptly notify the operator and operation manager of the occurrence of an abnormal condition called fuel leak. It becomes possible to secure the safety of the system against fuel leakage.
[0018]
In addition, according to this configuration, a gas detector is not required for detecting fuel leak, and an inexpensive and compact system can be provided because the gas detector is not required.
[0019]
[3] Third, the present invention relates to a fuel cell power generation system having the configuration (i) described above.
Temperature detecting means for detecting the temperature of the reformer;
A valve for adjusting the amount of the fuel gas supplied to the fuel cell main body, and a fuel flow rate adjusting valve whose opening degree is adjusted in response to a given opening degree command value;
Means for generating an upper limit value of the fuel flow valve corresponding to an output current value or load amount of electric energy generated by the fuel cell body;
Means for generating the opening command value corresponding to an output current value or load amount of electric energy generated by the fuel cell body;
When the opening degree command value reaches the opening degree upper limit value, a temperature drop of the reformer by the temperature detection means, a misfire of the heating burner of the reformer, or a drop in the voltage (battery voltage) of the fuel cell body. In some cases, the system is provided with system control means for performing at least one of alarming and stopping control of the fuel cell power generation system.
[0020]
In the present invention, an upper limit value (opening upper limit value) for the opening command value of the regulating valve for adjusting the supply amount of the fuel gas supplied to the fuel cell body is generated, and the electric energy generated by the fuel cell body is generated. The opening command value is generated in response to the output current value or the load amount to control the opening of the regulating valve, and when the opening command value reaches the opening upper limit value, the system control means When there is a temperature drop of the reformer by the detection means, a misfire of the heating burner of the reformer or a drop in battery voltage, an alarm is issued or the fuel cell power generation system is stopped.
[0021]
An excessive fuel leak occurs inside the fuel cell power generation system, and the adjustment valve of the supplied fuel is controlled in the direction of increasing the opening to make up for the insufficient fuel, but the opening command value for the opening control When the upper limit value is reached, the system protection monitoring function is activated. As a result of a fuel leak, the fuel in the system becomes insufficient, resulting in a decrease in battery voltage and abnormal combustion of the reformer burner. When the limit value is reached, the decrease in battery voltage or reformer burner occurs. By detecting the occurrence of combustion abnormalities in the system and using a system protection function that issues an alarm when these abnormalities occur, it is possible to promptly notify the operator and operation manager of the occurrence of an abnormal condition called fuel leak. It becomes possible to secure the safety of the system against fuel leakage.
[0022]
In addition, according to this configuration, a gas detector is not required for detecting fuel leak, and an inexpensive and compact system can be provided because the gas detector is not required.
[0023]
[4] Fourth, the present invention relates to a fuel cell power generation system having the configuration (i).
Temperature detecting means for detecting the temperature of the reformer;
A valve for adjusting the amount of the fuel gas supplied to the fuel cell main body, and a fuel flow rate adjusting valve whose opening degree is adjusted in response to a given opening degree command value;
Means for generating an upper limit value of the fuel flow valve corresponding to an output current value or load amount of electric energy generated by the fuel cell body;
Means for generating the opening command value corresponding to an output current value or load amount of electric energy generated by the fuel cell body;
When the opening degree command value reaches the opening degree upper limit value, a temperature drop of the reformer by the temperature detection means, a misfire of the heating burner of the reformer, or a drop in the voltage (battery voltage) of the fuel cell body. A system control means for issuing a warning at a certain time and executing a stop control of the fuel cell power generation system when the status of the warning is continued for a predetermined time;
It is set as the structure which provided.
[0024]
In the present invention, an upper limit value (opening upper limit value) for the opening command value of the regulating valve for adjusting the supply amount of the fuel gas supplied to the fuel cell body is generated, and the electric energy generated by the fuel cell body is generated. The opening command value is generated in response to the output current value or the load amount to control the opening of the regulating valve, and when the opening command value reaches the opening upper limit value, the system control means When there is a temperature drop of the reformer by the detection means, a misfire of the heating burner of the reformer or a drop in battery voltage, an alarm is issued, and when this alarm is triggered for a predetermined time, the fuel cell Stop the power generation system.
[0025]
An excessive fuel leak occurs inside the fuel cell power generation system, and the adjustment valve of the supplied fuel is controlled in the direction of increasing the opening to make up for the insufficient fuel, but the opening command value for the opening control When the upper limit value is reached, the system protection monitoring function is activated. As a result of a fuel leak, the fuel in the system becomes insufficient, resulting in a decrease in battery voltage and abnormal combustion of the reformer burner. When the limit value is reached, the decrease in battery voltage or reformer burner occurs. By detecting the occurrence of combustion abnormalities in the system and using a system protection function that issues an alarm when these abnormalities occur, it is possible to promptly notify the operator and operation manager of the occurrence of an abnormal condition called fuel leak. The system can be forcibly stopped when a predetermined time has elapsed by using the timed function at the alarm notification stage, so that the system can be forcibly stopped when a predetermined time has elapsed. Can be secured.
[0026]
In addition, according to this configuration, a gas detector is unnecessary, and an inexpensive and compact system can be provided because the gas detector is unnecessary.
[0027]
[5] Fifthly, in the fuel cell power generation system having the above-described configuration (i), the present invention includes a detecting means for detecting a flow rate of the fuel gas supplied to the fuel cell main body,
Means for providing an abnormality detection reference value of the fuel flow rate corresponding to an output current value or load amount of electric energy generated by the fuel cell body;
Comparison means for comparing the detected flow rate of the fuel gas using the abnormality detection reference value as a comparison reference, and generating a signal (fuel leak signal) when the detected flow rate of the fuel gas exceeds the comparison reference;
System control means for performing stop control of the fuel cell power generation system based on a signal (fuel leak signal) from the comparison means is provided.
[0028]
The present invention includes means (function generator) for giving a predetermined upper limit value of the fuel supply flow rate or its set value in accordance with the battery current and the battery load, and the fuel flow rate (or its set value) Compared with the upper limit value, the fuel cell power generation system is automatically stopped when this value is exceeded.
[0029]
Therefore, excessive operation or fuel leakage occurs inside the fuel cell power generation system, and as a result, the supply fuel is controlled to increase and the operation is automatically stopped when the supply fuel exceeds the allowable upper limit value. The system can be secured against fuel leaks.
[0030]
In addition, according to this configuration, a gas detector is not required for detecting fuel leak, and an inexpensive and compact system can be provided because the gas detector is not required.
[0031]
[6] Sixth, the present invention relates to a fuel cell power generation system having the configuration (i),
Detecting means for detecting a flow rate of the fuel gas supplied to the fuel cell body;
Means for providing an abnormality detection reference value of the fuel flow rate corresponding to an output current value or load amount of electric energy generated by the fuel cell body;
Comparison means for comparing the detected flow rate of the fuel gas using the abnormality detection reference value as a comparison reference, and generating a signal (fuel leak signal) when the detected flow rate of the fuel gas exceeds the comparison reference;
System control means for issuing an alarm signal by a signal (fuel leak signal) from the comparison means is provided.
[0032]
The present invention includes means (function generator) for giving a predetermined upper limit value of the fuel supply flow rate or its set value in accordance with the battery current and the battery load, and the fuel flow rate (or its set value) Compared with the upper limit value, an alarm signal is issued when this value is exceeded.
[0033]
Therefore, excessive fuel leakage occurs in the fuel cell power generation system, and as a result, the supply fuel is controlled to increase, and when the supply fuel exceeds the allowable upper limit value, an alarm signal is issued, Since the operator and the operation manager can be notified promptly, the safety of the system can be ensured against the fuel leak.
[0034]
In addition, according to this configuration, a gas detector is not required for detecting fuel leak, and an inexpensive and compact system can be provided because the gas detector is not required.
[0035]
[7] Seventh, the present invention provides a fuel cell power generation system having the configuration (i),
Detecting means for detecting an opening of an adjusting valve for adjusting a flow rate of the fuel gas supplied to the fuel cell main body by valve opening control or a rotation speed of a blower for sending the fuel gas; and electric energy generated by the fuel cell main body Means for providing an abnormality detection reference value for the opening of the regulating valve or the rotational speed of the blower in response to the output current value or load amount of
Comparison means for comparing the detected value of the opening of the regulating valve or the rotation speed of the blower with the abnormality detection reference value as a comparison reference, and generating a signal (fuel leak signal) when the detected value exceeds the comparison reference;
System control means for performing stop control of the fuel cell power generation system based on a signal (fuel leak signal) from the comparison means is provided.
[0036]
In the present invention, a means (function generator) for giving a permissible upper limit value for a fuel supply flow rate control valve opening degree (or a set value thereof) or a blower speed (or a set value thereof) determined in accordance with a battery current or a load The fuel flow control valve opening degree (or its set value) or the rotation speed of the blower (or its set value) is compared with the allowable upper limit value, and when this is exceeded, the fuel cell power generation system is automatically stopped. .
[0037]
Therefore, an excessive fuel leak occurs inside the fuel cell power generation system. As a result, the opening of the fuel supply valve increases or the rotation speed of the blower increases, which exceeds the allowable upper limit value. By automatically stopping the operation at the stage, it is possible to maintain the safety of the system even when a fuel leak occurs.
[0038]
In addition, according to this configuration, a gas detector is not required for detecting fuel leak, and an inexpensive and compact system can be provided because the gas detector is not required.
[0039]
[8] Eighthly, in the fuel cell power generation system configured as described in (i) above, the present invention relates to an opening of an adjustment valve that adjusts a flow rate of the fuel gas supplied to the fuel cell body by valve opening control or Detecting means for detecting the rotational speed of the blower for sending out the fuel gas;
Means for providing an abnormality detection reference value for the opening degree of the regulating valve or the rotational speed of the blower in response to an output current value or load amount of electric energy generated by the fuel cell body;
Comparing means for comparing the detected value of the opening of the regulating valve or the rotational speed of the blower with the abnormality detection reference value as a comparison reference, and generating a signal when the detected value exceeds the comparison reference;
System control means for issuing an alarm by a signal from the comparison means;
It is set as the structure which provided.
[0040]
In the present invention, means (function generator) for giving an allowable upper limit value for an adjustment valve opening (or a set value thereof) of a predetermined fuel supply flow rate according to a battery current or a load or a rotation speed (or a set value thereof) of a blower ), And the fuel flow control valve opening (or its set value) or the rotation speed of the blower (or its set value) is compared with the allowable upper limit value, and an alarm is issued when this value is exceeded.
[0041]
Therefore, an excessive fuel leak occurs inside the fuel cell power generation system. As a result, the opening degree of the adjustment valve for the fuel supply flow rate or the rotation speed of the blower increases, which is the allowable upper limit value. When the value exceeds the value, an alarm is issued, so that it is possible to promptly notify an operator or an operation manager of the occurrence of an abnormal condition called fuel leak, and the safety of the system can be ensured.
[0042]
In addition, according to this configuration, a gas detector is unnecessary, and an inexpensive and compact system can be provided because the gas detector is unnecessary.
[0043]
(Ii) Next, the present invention provides a reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons such as natural gas, LPG, and biogas, and the reformer. The reformed gas is used as a fuel gas, and is composed of a fuel cell body that generates electric energy by an electrochemical reaction between the fuel gas and an oxidant gas such as air, and detects the temperature of the reformer. It is intended for a fuel cell power generation system having an adjustment function for adjusting and controlling to reduce the amount of oxidant gas supplied to a heating burner of the reformer when the temperature of the reformer falls below a set temperature. ,
[9] Ninth, detection means for detecting the flow rate of the oxidant gas supplied to the heating burner of the reformer;
Means for providing an abnormality detection reference value for the amount of oxidant gas supplied to the heating burner of the reformer in response to an output current value or load amount of electric energy generated by the fuel cell body;
A comparison means for comparing the detected flow rate of the oxidant gas with the abnormality detection reference value as a comparison reference, and generating a signal (fuel leak signal) when the detected flow rate reaches the comparison reference, and a signal ( And a system control means for performing stop control of the fuel cell power generation system by a fuel leak signal).
[0044]
According to the present invention, there is provided means (function generator) for giving an allowable lower limit value of a reformer burner combustion air flow rate (or a set value thereof) determined in advance according to the battery current and load, and for reformer burner combustion. When the air flow rate (or its set value) exceeds the allowable upper limit value, the fuel cell power generation system is automatically stopped.
[0045]
Therefore, if an excessive fuel leak occurs inside the fuel cell power generation system, the temperature of the reformer drops, and the amount of combustion air supplied to the reformer burner is reduced accordingly. System safety can be ensured by automatically stopping the operation when the condition falls below the lower limit.
[0046]
In addition, according to this configuration, a gas detector is not required for detecting fuel leak, and an inexpensive and compact system can be provided because the gas detector is not required.
[0047]
[10] Tenthly, the present invention relates to a fuel cell power generation system configured as described in (ii) above.
Detecting means for detecting the flow rate of the oxidant gas supplied to the heating burner of the reformer;
Means for providing an abnormality detection reference value for the amount of oxidant gas supplied to the heating burner of the reformer in response to an output current value or load amount of electric energy generated by the fuel cell body;
A comparison means for comparing the detected flow rate of the oxidant gas with the abnormality detection reference value as a comparison reference, and generating a signal (fuel leak signal) when the detected flow rate reaches the comparison reference, and a signal ( System control means for issuing an alarm by a fuel leak signal) is provided.
[0048]
According to the present invention, there is provided means (function generator) for giving an allowable lower limit value of a reformer burner combustion air flow rate (or a set value thereof) determined in advance according to the battery current and load, and for reformer burner combustion. When the air flow rate (or its set value) exceeds the allowable upper limit value, an alarm is issued.
[0049]
Therefore, if an excessive fuel leak occurs inside the fuel cell power generation system, the temperature of the reformer drops, and the amount of combustion air supplied to the reformer burner is reduced accordingly. By issuing an alarm when the condition falls below the lower limit, it will be possible to promptly notify the operator and operation manager of the occurrence of an abnormal condition called fuel leak, thus ensuring the safety of the system. become.
[0050]
In addition, according to this configuration, a gas detector is not required for detecting fuel leak, and an inexpensive and compact system can be provided because the gas detector is not required.
[0051]
[11] Eleventhly, the present invention provides a fuel cell power generation system configured as described in (ii) above,
Detecting means for detecting the opening of an adjusting valve for adjusting the flow rate of the oxidant gas supplied to the heating burner of the reformer by the valve opening degree control or the rotational speed of the blower for sending the oxidant gas;
Means for providing an abnormality detection reference value for the opening degree of the regulating valve or the rotational speed of the blower in response to an output current value or load amount of electric energy generated by the fuel cell body;
A comparison means for comparing the detected flow rate of the oxidant gas with the abnormality detection reference value as a comparison reference, and generating a signal (fuel leak signal) when the detected flow rate reaches the comparison reference, and a signal ( And a system control means for performing stop control of the fuel cell power generation system by a fuel leak signal).
[0052]
The present invention comprises means (function generator) for providing an allowable lower limit value of the air flow rate control valve opening for reforming device burner combustion (or its set value) that is predetermined according to the battery current and load. The apparatus burner combustion air flow rate (or its set value) is compared with the allowable lower limit value, and if it falls below this, the fuel cell power generation system is automatically stopped.
[0053]
Therefore, when the reformer temperature decreases as a result of excessive fuel leakage inside the fuel cell power generation system and the burner air is throttled accordingly, the condition of the burner air flow control valve falls below the lower limit value. At this stage, the system can be secured by automatically stopping the operation.
[0054]
In addition, according to this configuration, a gas detector is not required for detecting fuel leak, and an inexpensive and compact system can be provided because the gas detector is not required.
[0055]
[12] Twelfth, the present invention relates to a fuel cell power generation system having the configuration (ii),
Detecting means for detecting the opening of an adjusting valve for adjusting the flow rate of the oxidant gas supplied to the heating burner of the reformer by the valve opening degree control or the rotational speed of the blower for sending the oxidant gas;
Means for providing an abnormality detection reference value for the opening degree of the regulating valve or the rotational speed of the blower in response to an output current value or load amount of electric energy generated by the fuel cell body;
A comparison means for comparing the detected flow rate of the oxidant gas with the abnormality detection reference value as a comparison reference, and generating a signal (fuel leak signal) when the detected flow rate reaches the comparison reference, and a signal ( System control means for issuing an alarm by a fuel leak signal) is provided.
[0056]
The present invention includes means (function generator) for providing an allowable upper limit value of a reformer burner combustion air flow control valve opening degree (or a set value thereof) that is predetermined according to battery current and load. The apparatus burner combustion air flow rate (or its set value) is compared with the allowable lower limit value, and an alarm signal is issued when the air flow rate is below the allowable lower limit value.
[0057]
Therefore, as a result of excessive fuel leak inside the fuel cell power generation system, the condition of the burner air flow control valve falls below the lower limit when the temperature of the reformer decreases and the burner air is throttled accordingly. At this stage, it is possible to output the abnormal state in the form of an alarm and promptly notify the operator or operation manager, thereby maintaining the safety of the system.
[0058]
In addition, according to this configuration, a gas detector is not required for detecting fuel leak, and an inexpensive and compact system can be provided because the gas detector is not required.
[0059]
DETAILED DESCRIPTION OF THE INVENTION
In order to reduce the size and cost of the fuel cell power generation system, the present invention knows the abnormal state of the state quantity in the system without using a combustible gas detector, and determines the existence of an excessive fuel leak. In the following, embodiments of a fuel cell power generation system according to the present invention will be described in detail with reference to the drawings.
[0060]
(First embodiment)
This embodiment corresponds to the inventions of the items [1] and [2] in the above [Means for Solving the Problems], and the example shown in the first embodiment is applied to a fuel cell. An upper limit value for the fuel flow rate setting value to be supplied and a means for automatically stopping the fuel cell power generation system by the system protection function when the supplied fuel reaches this limit value, and the fuel flow rate to be supplied to the fuel cell An improvement is made by providing means for issuing an alarm signal by an alarm function of the system when the upper limit value for the set value and the supplied fuel reach this limit value. The details will be described below.
[0061]
A first embodiment is shown in FIG. In the figure, 1 is a reformer, 2 is a burner, 3 is a thermometer, 4 is a temperature setter, 5 is a temperature controller, 6 is a burner fuel regulating valve, 7 is a carbon monoxide converter, and 8 is fuel cell fuel. An adjuster, 9 is a fuel cell main body, and 10 is a fuel cell output current detector. Further, 11 is a function unit, 12 is a controller, 13 is a multiplier, 14 is a K multiplier, 15 is a low-value selector, and 20 is a system controller.
[0062]
Among these, the reformer 1 receives supply of raw fuel gas containing hydrocarbons such as natural gas, LPG, biogas, etc., and reforms the raw fuel gas with steam to generate hydrogen, The generated reformed gas is supplied to the carbon monoxide converter 7, and the burner 2 generates heat necessary for the reforming in the reformer 1. It becomes a heat source. The burner 2 burns hydrogen gas to generate heat. The burner 2 is provided with a combustion detector 2a that detects a fire state optically, mechanically, or electrically in order to monitor misfire / combustion.
[0063]
The thermometer 3 is for detecting the temperature in the reformer 1, and generates an output (temperature detection signal) corresponding to the detected temperature. The temperature setter 4 is for setting the temperature in the reformer 1, and the temperature controller 5 sets the temperature detection signal value output from the thermometer 3 based on the set temperature value of the temperature setter 4. In comparison, a control output is generated so that the temperature of the reformer 1 is maintained at a set value, and the burner fuel adjustment valve 6 has a valve opening degree corresponding to the control output from the temperature controller 5. It is a flow rate adjustment valve that adjusts and automatically adjusts the amount of hydrogen gas supplied to the burner 2.
[0064]
The fuel cell fuel regulator 8 is constituted by a flow rate regulating valve, a fuel flow rate regulating blower, or the like, and the raw fuel supplied to the reformer 1 is converted into a valve opening degree or the like corresponding to the control output from the low value selector 15. It is an adjuster that automatically adjusts the supply amount by adjusting the rotational speed of the fuel flow rate adjusting blower.
[0065]
The carbon monoxide converter 7 converts the carbon monoxide component contained in the gas from the reformed gas that has been reformed and sent out by the reformer 1 into carbon dioxide and hydrogen, and supplies the fuel cell body 9 with the carbon monoxide. This is to supply carbon monoxide, which is a poisoning component of the battery catalyst contained in the reformed gas, and to obtain a gas having a higher hydrogen concentration.
[0066]
The fuel cell main body 9 generates direct-current power by causing an electrochemical reaction between oxygen in the atmosphere and hydrogen supplied from the carbon monoxide transformer 7. The surplus hydrogen in the fuel cell main body 9 is supplied to the burner 2 via the burner fuel adjustment valve 6 and is used as fuel in the burner 2.
[0067]
The fuel cell output current detector 10 detects a current value generated and output by the fuel cell main body 9 and outputs it as a current detection signal corresponding to the value.
[0068]
The function unit 11 obtains an output value corresponding to the input value in accordance with a function of a predetermined characteristic set in advance. The function unit 11 is a reference for the raw fuel corresponding to the current detection signal output from the fuel cell output current detector 10. A function for setting the set flow rate is set, and a reference set flow rate corresponding to the current detection signal is generated.
[0069]
The controller 12 is configured to set the reference flow rate of raw fuel given by the function unit 11, the detected temperature of the reformer 1 (reformer temperature 18) output from the thermometer 3, and the temperature setting of the reformer 1 A correction coefficient for correcting the reference set flow rate is obtained from the deviation from the set value 19 from the temperature setter 4 that gives the value.
[0070]
The multiplier 13 multiplies the reference set flow rate by a correction coefficient from the controller 12, and the K multiplier 14 is a multiplier that multiplies the reference set flow rate output from the function unit 11 by K. The low value selector 15 selects the lower one of the output of the K multiplier 14 and the output of the multiplier 13 and outputs it as the fuel flow rate setting value 17 to control the valve opening degree of the fuel cell fuel regulator 8. This is used for controlling the rotational speed of the fuel flow rate adjusting blower.
[0071]
The fuel cell fuel regulator 8 automatically adjusts the supply amount of the raw fuel supplied to the reformer 1 according to the fuel flow rate setting value 17. It plays a role as one of adjustment elements for the amount of fuel supplied to the fuel cell main body 9 via the carbon monoxide transformer 7.
[0072]
The system controller 20 controls the center of control from the operation to the stop of the fuel cell power generation system. In addition to normal control, the system controller 20 lowers the reformer temperature 18, misfires the reformer burner 2, It has a function of monitoring a decrease in battery voltage, etc., performing control necessary for protection against these occurrences, issuing an alarm, and automatically stopping the fuel cell power generation system.
[0073]
This system having such a configuration sends raw fuel gas containing hydrocarbons such as natural gas, LPG (liquefied propane gas), biogas and the like to the reformer 1 through the fuel cell fuel regulator 8, In the reformer 1, the raw fuel gas is reformed with steam to generate hydrogen. This reforming reaction is a large endothermic reaction, and the heat required for this is sent to the burner 2 provided in the reformer 1 for surplus hydrogen (unreacted hydrogen) in the fuel cell main body and burned here. Supplied by The gas reformed by the reformer 1 is sent to the carbon monoxide converter 7 to convert the carbon monoxide contained in the reformed gas into carbon dioxide and hydrogen.
[0074]
Then, hydrogen obtained through the carbon monoxide transformer 7 and oxygen in the atmosphere are supplied to the fuel cell main body 9 to cause an electrochemical reaction to generate DC power.
[0075]
Here, the reformer 1 reforms the raw fuel gas with steam using the heat generated by the combustion of the burner 2, but the reformer 1 has a temperature detector 3 for temperature control. The detected temperature of the mass device 1 (reformer temperature 18) is obtained. The temperature controller 5 compares the temperature detection signal value output from the thermometer 3 with reference to the temperature setting value 19 from the temperature setting device 4 that gives the temperature setting value of the reformer 1, and the temperature of the reformer 1. A control output is generated so that is maintained at the set value 19. This control output is given to the burner fuel adjustment valve 6, and the burner fuel adjustment valve 6 adjusts the opening of the valve corresponding to the control output from the temperature controller 5 to supply the amount of hydrogen gas supplied to the burner 2. As a result of the automatic adjustment, the reformer 1 is kept at the set temperature.
[0076]
On the other hand, a difference between the reformer temperature 18 and the temperature setting value 19 of the reformer 1 is given to the controller 12. Then, the controller 12 obtains a correction coefficient corresponding to the difference, and gives the obtained correction coefficient to the multiplier 13. Further, the current value of the fuel cell main body 9 is detected by the fuel cell output current detector 10 and given to the function unit 11, and the function unit 11 generates the reference set flow rate of the raw fuel corresponding to the detected current value. Then, the reference set flow rate of the raw fuel is supplied to the multiplier 13.
[0077]
The multiplier 13 multiplies the reference set flow rate of raw fuel by the correction coefficient from the controller 12 to generate a corrected reference set flow rate. That is, the control is performed so as to correspond to the deviation between the reformer temperature 18 and the temperature set value 19 of the reformer 1 with respect to the reference set flow rate of the raw fuel obtained from the function unit 11 corresponding to the output current value of the fuel cell body 9. Correction is performed by the multiplier 13 using the correction coefficient obtained by the unit 12 to obtain a corrected reference set flow rate. Then, this is given to the low value selector 15.
[0078]
Further, a value obtained by multiplying the reference set flow rate of the raw fuel given by the function unit 11 by K by the K multiplier 14 is given to the low value selector 15. Then, the low value selector 15 selects the lower one of the output of the K multiplier 14 and the output of the multiplier 13 and outputs it as the fuel flow rate set value 17 to be used for the control of the fuel cell fuel regulator 8.
[0079]
The fuel cell fuel regulator 8 adjusts the opening degree of the valve or the rotational speed of the fuel flow rate adjusting blower in response to the fuel flow rate setting value 17 so that the amount of raw fuel supplied to the reformer 1 corresponds to the set value 17. It will be automatically adjusted. By setting the value of K appropriately large, the low value selector 15 selects the corrected reference set flow rate corrected by the multiplier 13 when operating in a normal state where there is no fuel gas leak or the like. Since the fuel flow rate setting value 17 is output, the fuel cell fuel regulator 8 automatically adjusts the raw fuel supply amount to the reformer 1 in correspondence with the fuel flow rate setting value 17. Accordingly, hydrogen is supplied to the fuel cell main body 9 in correspondence with the output current value of the fuel cell main body 9 and the reformer temperature, so that normal operation is performed in a normal state where there is no fuel leakage in the case of the fuel cell power generation system. Will be implemented.
[0080]
On the other hand, when a fuel leak (fuel gas leak) occurs in the case of the fuel cell power generation system due to some failure or failure, unreacted hydrogen flowing from the fuel cell body 9 to the burner 2 via the valve 6. Since (surplus hydrogen) decreases, the amount of hydrogen supplied to the burner 2 decreases, the combustion temperature decreases, and the reformer temperature 18 decreases. On the other hand, the controller 12 increases the output correction coefficient in order to keep the reformer temperature 18 at the set speed, and supplies this correction coefficient to the multiplier 13. The multiplier 13 corrects the raw fuel reference set flow rate corresponding to the battery current 16 output from the function unit 11 by the correction coefficient. As a result, the fuel flow rate set value 17 also increases.
[0081]
However, the lower value selector 15 selects the smaller one of the output of the multiplier 13 and the output of the K multiplier 14 to obtain the fuel flow rate set value 17, and the fuel cell output current detector 10 outputs the result. Since this configuration has an upper limit value obtained by multiplying the reference set flow rate according to the battery current detection value 16 by K times, an increase in fuel supply is suppressed by this upper limit value when excessive fuel or hydrogen leak occurs. Is done.
[0082]
When this state occurs, it is used as a trigger for determining that there is fuel leakage up to a level where there is a safety problem, that is, as a trigger for starting the determination processing in the system control device 20, The criterion for determination is that the reformer burner 2 using the output of the combustion detector 2a for detecting the one-sided reformer temperature 18 (abnormally lowering the detection output of the temperature detector 3) or misfire is detected. It is determined taking into consideration that a phenomenon such as a misfire or a decrease in battery voltage (a decrease in the detection value of the fuel cell output current detector 10) occurs in the system in competition.
[0083]
That is, when the system controller 20 knows that a decrease in the reformer temperature 18, a misfire of the reformer burner 2, or a decrease in the battery voltage has occurred based on these detection information, to decide. By carrying out necessary protective measures against these abnormalities and issuing warnings, the fuel cell power generation system is automatically and automatically stopped, or an emergency situation is notified to the operator by automatic warnings before the stoppage. When necessary measures are not taken, safety is ensured by performing an emergency stop after that.
[0084]
Here, the value of K used in the K multiplier 14 is determined as follows, for example. Now 1 [m^Three/ H] raw fuel methane (CH_Four) Is supplied to the system. Considering the ideal state, 1 [m^Three/ H] from methane 4 [m^Three/ H] hydrogen (H₂)But
CH_Four+ 2H₂O → 4H₂+ CO₂
It is produced according to the chemical formula of
[0085]
In addition, the ventilation in the system is, for example, 40 [m^Three/ H], 0.8 [m generated from 20% of the raw fuel^Three/ H], when the hydrogen leak occurs, the hydrogen concentration in the system reaches 2 [%] (corresponding to a level of 50 [%], which is half of the lower hydrogen explosion limit of 4 [%]) . Therefore, for example, when it is assumed that the protection level is determined with the hydrogen concentration of 2%, the value of K may be set to “1.2”.
[0086]
In the above embodiment, the function unit 11 is configured to generate the reference set flow rate of the raw fuel corresponding to the cell current detection value output from the fuel cell output current detector 10, but the fuel cell output current detector 10 Instead of this, a measuring device that measures the load of the fuel cell power generation system may be used to generate the reference set flow rate of the raw fuel corresponding to the measured load. In this case, it is assumed that the load is used instead of the detected battery current value as the monitoring target in the system control device 20.
[0087]
As described above, in this embodiment, the upper limit value is set for the flow rate of fuel supplied to the fuel cell, and the means for automatically stopping the fuel cell power generation system by the system protection function when the supplied fuel reaches the upper limit value. The configuration is provided. Therefore, an excessive fuel leak occurs inside the fuel cell power generation system, and when the supplied fuel reaches the limit value, the fuel in the system becomes insufficient, resulting in a decrease in cell voltage and abnormal combustion of the reformer burner. Since abnormal phenomena that serve as the operating conditions for the protective function appear in combination, by detecting these abnormalities through these monitoring, the automatic operation can be stopped by the protective function, thus ensuring safe operation of the system. It becomes possible to do. Moreover, it can be realized without using a combustible gas detector, which has been a bottleneck in cost and space saving.
[0088]
In addition, by providing a function to detect an abnormality in the system that occurs when the upper limit value for the fuel flow rate supplied to the fuel cell and the supplied fuel reach this limit value, and to issue an alarm by this detection, A fuel leak can be reported without using a combustible gas detector, and a safe operation of the system can be secured.
[0089]
Therefore, according to this embodiment, when excessive fuel or hydrogen leak occurs in the fuel cell power generation system, this can be detected by the reformer temperature or the like, so that the fuel can be detected without having a combustible gas detector. Therefore, it is possible to quickly and surely detect the leakage of the system and to automatically stop the system, so that the safety of the system can be maintained. As a result, an inexpensive and compact system can be provided by reducing the number of detectors.
[0090]
In the above embodiment, excessive fuel leakage occurs inside the fuel cell power generation system, and when the supplied fuel reaches the limit value, the fuel in the system becomes insufficient, the battery voltage decreases, the reformer burner Abnormal phenomena that serve as the operating conditions for the protective function, such as the occurrence of combustion abnormalities, appear in combination, so this was a method for detecting abnormalities by monitoring these, but the amount of fuel supplied to the fuel cell body and the output of the fuel cell A fuel leak abnormality can be detected from the relationship. Therefore, an example thereof will be described next as a second embodiment.
[0091]
(Second Embodiment)
This embodiment corresponds to the inventions of the items [3] and [4] in the above [Means for Solving the Problems], and in the second embodiment, shown in FIG. As described above, the fuel flow meter 25 is provided in the fuel supply path between the fuel cell fuel regulator 8 and the reformer 1. The fuel flow meter 25 generates a fuel flow signal 26 corresponding to the fuel flow rate. 2 is basically the same as the configuration of the first embodiment described in FIG. 1. Therefore, the same parts as those in FIG. I will omit it. However, in the configuration of FIG. 2, the fuel flow rate set value 17 is obtained by an element including the function unit 11, the controller 12, and the multiplier 13.
[0092]
That is, the function unit 11 obtains an output value corresponding to the input value in accordance with a function of a predetermined characteristic set in advance, and the reference of the raw fuel corresponding to the current detection signal output from the fuel cell output current detector 10 is obtained. A function for setting the set flow rate is set, and a reference set flow rate corresponding to the current detection signal is generated. The controller 12 determines the reference set flow rate of the raw fuel given by the function unit 11 and the thermometer 3. The reference set flow rate is corrected based on the deviation between the detected temperature of the reformer 1 (reformer temperature 18) and the set value 19 from the temperature setter 4 that gives the temperature set value of the reformer 1. The multiplier 13 obtains a correction coefficient, and the multiplier 13 multiplies the reference set flow rate by the correction coefficient from the controller 12. The one corrected by the multiplier 13 is used as the fuel flow set value 17. Use it.
[0093]
In addition, as shown in FIG. 2, the fuel cell power generation system uses a difference between the fuel flow rate 26 and the fuel flow rate setting value 17 that is the set value, such as the fuel valve opening degree or the fuel flow rate adjusting blower rotational speed. A fuel controller 22 that provides fuel control information 24, a cell current (or a load) 16 detected by the current detector 10, and an adjustment valve opening or fuel flow rate adjustment blower in the fuel cell fuel regulator 8 according to A function unit 21 that gives an upper limit value of the fuel control information 24 such as the number of revolutions, the fuel control information 24 output from the function unit 21 and the fuel control information 24 output from the fuel controller 22 is selected and output. The low-value selector 23 is provided.
[0094]
In this system having such a configuration, the raw fuel gas containing hydrocarbons is sent to the reformer 1 via the fuel cell fuel regulator 8, and the raw fuel gas is reformed with steam to generate hydrogen. . The heat necessary for the reforming reaction is supplied by sending surplus hydrogen (unreacted hydrogen) in the fuel cell main body 9 to the burner 2 provided in the reformer 1 for combustion. Then, the gas reformed by the reformer 1 is sent to the carbon monoxide converter 7 to convert the carbon monoxide contained in the reformed gas into carbon dioxide and hydrogen.
[0095]
Hydrogen obtained through the carbon monoxide transformer 7 and oxygen in the atmosphere are supplied to the fuel cell main body 9 to cause an electrochemical reaction to generate DC power.
[0096]
Here, the reformer 1 reforms the raw fuel gas with steam using the heat generated by the combustion of the burner 2, but the reformer 1 has a temperature detector 3 for temperature control. The detected temperature of the mass device 1 (reformer temperature 18) is obtained. The temperature controller 5 compares the temperature detection signal value output from the thermometer 3 with reference to the temperature setting value 19 from the temperature setting device 4 that gives the temperature setting value of the reformer 1, and the temperature of the reformer 1. A control output is generated so that is maintained at the set value 19. This control output is given to the burner fuel adjustment valve 6, and the burner fuel adjustment valve 6 adjusts the opening of the valve in response to the control output from the temperature controller 5 to supply the amount of hydrogen gas supplied to the burner 2. As a result of the automatic adjustment, the reformer 1 is kept at the set temperature.
[0097]
On the other hand, a difference between the reformer temperature 18 and the temperature setting value 19 of the reformer 1 is given to the controller 12. Then, the controller 12 obtains a correction coefficient corresponding to the difference, and gives the obtained correction coefficient to the multiplier 13. Further, the current value of the fuel cell main body 9 is detected by the fuel cell output current detector 10 and given to the function unit 11, and the function unit 11 generates the reference set flow rate of the raw fuel corresponding to the detected current value. Then, the reference set flow rate of the raw fuel is supplied to the multiplier 13.
[0098]
The multiplier 13 multiplies the reference set flow rate of raw fuel by the correction coefficient from the controller 12 to generate a corrected reference set flow rate. That is, the control is performed so as to correspond to the deviation between the reformer temperature 18 and the temperature set value 19 of the reformer 1 with respect to the reference set flow rate of the raw fuel obtained from the function unit 11 corresponding to the output current value of the fuel cell body 9. The multiplier 13 performs correction using the correction coefficient obtained by the unit 12 to obtain a corrected reference set flow rate, which is output as the fuel flow rate set value 17.
[0099]
A fuel flow meter 25 is provided in the raw fuel supply path to the reformer 1, and the fuel flow meter 25 generates a fuel flow signal 26 corresponding to the flow rate of the fuel. Deviations between the fuel flow rate signal 26 and the fuel flow rate set value 17 are given to the fuel controller 22, and the fuel controller 22 obtains fuel control information 24 such as an adjustment valve opening degree or a fuel flow rate adjustment blower rotational speed from the deviation. . Then, this fuel control information 24 is given to the low value selector 23.
[0100]
Further, a battery current value (or a load) 16 detected by the current detector 10 is given to a function unit 21, and the function unit 21 corresponds to the fuel cell fuel regulator corresponding to the battery current value 16. 8 generates an upper limit value of the fuel control information 24 such as the fuel flow rate adjustment valve opening degree or the rotational speed of the fuel flow rate adjustment blower. Then, this is given to the low value selector 23.
[0101]
The low value selector 23 selects the lower one of the fuel control information 24 output from the function unit 21 and the fuel control information 24 output from the fuel controller 22 and outputs it as the fuel control information 24. This is given to the battery fuel regulator 8. The fuel cell fuel regulator 8 automatically adjusts the opening of the regulating valve or the rotational speed of the fuel flow rate adjusting blower corresponding to the fuel control information 24 in correspondence with the fuel control information 24. As a result, since the amount of raw fuel supplied to the reformer 1 is adjusted, the amount of hydrogen supplied from the reformer 1 to the fuel cell main body 9 via the carbon monoxide converter 7 is the cell current value. (Or load) is automatically controlled to an amount corresponding to 16. However, although the upper limit value corresponding to the battery current value (or load) 16 given by the function unit 21 is restricted, a situation that reaches such an upper limit value does not occur in the normal state.
[0102]
Accordingly, since hydrogen is supplied to the fuel cell body 9 in response to the output current value of the fuel cell body 9, normal operation is performed in a normal state where there is no fuel leakage in the case of the fuel cell power generation system. become. The above is the control operation in the normal state.
[0103]
On the other hand, when fuel leakage occurs in the case of the fuel cell power generation system due to some failure or failure, unreacted hydrogen (surplus hydrogen) that flows from the fuel cell body 9 to the burner 2 via the valve 6 Therefore, the amount of hydrogen supplied to the burner 2 is reduced, the combustion temperature is lowered, and the reformer temperature 18 is lowered.
[0104]
On the other hand, in order to keep the reformer temperature appropriately as described above, the fuel flow rate set value 17 increases, and the fuel controller 22 adjusts the fuel flow rate based on the deviation between this value and the fuel flow rate 26. Fuel control information 24 such as the valve opening degree or the fuel flow rate adjusting blower rotation speed is obtained. Then, this fuel control information 24 is given to the low value selector 23.
[0105]
Further, the battery current value (or load) 16 detected by the current detector 10 is given to the function unit 21, and this function unit 21 corresponds to the battery current value 16 in the fuel cell fuel regulator 8. An upper limit value of the fuel control information 24 such as a fuel flow rate adjustment valve opening or a fuel flow rate adjustment blower rotation speed is generated. Then, this is given to the low value selector 23.
[0106]
The low value selector 23 selects the lower one of the fuel control information 24 output from the function unit 21 and the fuel control information 24 output from the fuel controller 22 and outputs it as the fuel control information 24. This is given to the battery fuel regulator 8. The fuel cell fuel regulator 8 automatically adjusts the opening of the regulating valve or the rotational speed of the fuel flow rate adjusting blower corresponding to the fuel control information 24 in response to the fuel control information 24. The amount of hydrogen supplied from the reformer 1 to the fuel cell body 9 via the carbon monoxide converter 7 is determined by the battery current value (or load) 16 and the reformer. The amount is automatically controlled according to the temperature. However, when the fuel leakage is large, the upper limit value given by the function unit 21 and corresponding to the battery current value (or load) 16 is reached, so the fuel control information 24 sticks to the limit value.
[0107]
By setting this upper limit value to a level that requires caution when hydrogen leaks occur, an increase in fuel supply is suppressed at an upper limit value that falls before the leak amount at which the risk of explosion is imminent. In this case, since the upper limit value has been reached, it is necessary to determine that there is a leakage of fuel to a level where there is a safety problem and to deal with it.
[0108]
Therefore, in this case, when the upper limit value is reached, it is used as a trigger for causing the system control device 20 to start the determination process. The criterion for the determination is a one-sided decrease in the reformer temperature 18 (temperature detector). 3 (abnormal decrease in detection output 3), misfire of the reformer burner 2 using the output of the combustion detector 2a for misfire detection, or a decrease in battery voltage (of the detection value of the fuel cell output current detector 10). This is determined taking into consideration that a phenomenon such as (decrease) occurs by competing in the system.
[0109]
In the present system, the determination is made as the occurrence of an abnormality due to the unilateral reformer temperature 18 decrease, the misfire detection of the reformer burner 2, or the battery voltage decrease. The system controller 20 knows that a reduction in the reformer temperature 18, a misfire in the reformer burner 2, or a drop in the battery voltage has occurred based on these detection information. By performing necessary protective actions and warnings, the fuel cell power generation system is automatically stopped immediately, or an emergency situation is notified to the operator by automatic warnings before the stoppage, and necessary actions are taken. If this is not possible, the safety is ensured by performing an emergency stop after that.
[0110]
As described above, when the fuel leaks, unreacted hydrogen flowing out from the fuel cell main body 9 decreases, so the reformer temperature decreases. On the other hand, as described in the first embodiment, The fuel flow rate set value 17 is increased so as to keep the reformer temperature appropriately, and as a result, the fuel valve opening degree or the fuel flow rate adjusting blower rotational speed 11 is controlled to increase. Since the battery has an upper limit value corresponding to the battery current value (or load) 16, an increase in fuel supply is suppressed by this upper limit value when excessive fuel or hydrogen leak occurs. In this case, the reformer temperature unilaterally decreases, the reformer burner 2 misfires, or the battery voltage decreases in the system. Therefore, as in the first embodiment, these information are used. By causing the system controller 20 to determine that there is a fuel leak to a level that causes a safety problem, and causing the system controller 20 to issue these protective actions or alarms, the fuel cell power generation system is It is now possible to notify the user of the occurrence of a fuel leak failure by automatically stopping or automatically issuing an alarm before the automatic stop.
[0111]
Therefore, according to this embodiment, when excessive fuel or hydrogen leak occurs in the fuel cell power generation system, this is detected by the reformer temperature or the like, and measures such as automatic stop of the fuel cell power generation system are taken. Therefore, even without a combustible gas detector, it is possible to quickly and reliably detect fuel leakage and maintain safety. As a result, an inexpensive and compact system can be provided by reducing the number of detectors.
[0112]
As described above, the fuel supply control is performed based on the relationship between the fuel flow rate of the hydrogen fuel supplied to the fuel cell body and the fuel cell output, and the unilateral reformer temperature drop, burner misfire or battery voltage Since the decrease occurs in the system in competition, an abnormal fuel leak is detected to ensure safety. Since there is a configuration that can be detected more simply if only fuel leak detection is performed, an embodiment thereof will be described next.
[0113]
(Third embodiment)
This embodiment corresponds to the inventions of the items [5] and [6] in the above [Means for Solving the Problems], and this third embodiment is shown in FIG. Further, a function unit 32 that gives an abnormality detection reference value of the fuel flow rate 26 according to the battery current value (or load) 16 of the fuel cell power generation system, and a fuel flow meter 25 based on the output from the function unit 32 as a comparison reference. A leak detector is configured by a comparator 31 that compares the values of the fuel flow rates 26 and generates a fuel leak signal when the fuel flow rate 26 exceeds the comparison reference. The leak detector is applied to a fuel cell power generation system as shown in FIG.
[0114]
The fuel cell power generation system of FIG. 5 basically follows the configuration of FIG. 2, but the output of the multiplier 13 is given to the fuel cell fuel regulator 8 as a fuel flow rate setting value 17 to adjust the fuel supply. It is the composition which does.
[0115]
The multiplier 13 multiplies the reference set flow rate of raw fuel by the correction coefficient from the controller 12 to generate a corrected reference set flow rate. That is, the control is performed so as to correspond to the deviation between the reformer temperature 18 and the temperature set value 19 of the reformer 1 with respect to the reference set flow rate of the raw fuel obtained from the function unit 11 corresponding to the output current value of the fuel cell body 9. Correction is performed by the multiplier 13 using the correction coefficient obtained by the unit 12 to obtain a corrected reference set flow rate, which is output as the fuel flow rate set value 17.
[0116]
Further, a system control device 20A is provided, and this system control device 20A has a fuel leak signal monitoring function. When the generation of the fuel leak signal continues for a predetermined time or more, the protection operation of the fuel cell operation is performed. Alternatively, by issuing an alarm, the fuel cell power generation system can be automatically stopped, or a user can be informed of the occurrence of a fuel leak failure due to the automatic alarm issuing before the automatic stop.
[0117]
This system having such a configuration sends raw fuel gas containing hydrocarbons to the reformer 1, where the raw fuel gas is reformed with steam to generate hydrogen. The heat necessary for the reforming reaction is supplied by sending surplus hydrogen (unreacted hydrogen) in the fuel cell main body 9 to the burner 2 provided in the reformer 1 for combustion. Then, the gas reformed by the reformer 1 is sent to the carbon monoxide converter 7 to convert the carbon monoxide contained in the reformed gas into carbon dioxide and hydrogen.
[0118]
Hydrogen obtained through the carbon monoxide transformer 7 and oxygen in the atmosphere are supplied to the fuel cell main body 9 to cause an electrochemical reaction to generate DC power.
[0119]
Here, the reformer 1 reforms the raw fuel gas with steam using the heat generated by the combustion of the burner 2, but the reformer 1 has a temperature detector 3 for temperature control. The detected temperature of the mass device 1 (reformer temperature 18) is obtained. The temperature controller 5 compares the temperature detection signal value output from the thermometer 3 with reference to the temperature setting value 19 from the temperature setting device 4 that gives the temperature setting value of the reformer 1, and the temperature of the reformer 1. A control output is generated so that is maintained at the set value 19. This control output is given to the burner fuel adjustment valve 6, and the burner fuel adjustment valve 6 adjusts the opening of the valve corresponding to the control output from the temperature controller 5 to supply the amount of hydrogen gas supplied to the burner 2. As a result of the automatic adjustment, the reformer 1 is kept at the set temperature.
[0120]
On the other hand, a difference between the reformer temperature 18 and the temperature setting value 19 of the reformer 1 is given to the controller 12. Then, the controller 12 obtains a correction coefficient corresponding to the difference, and gives the obtained correction coefficient to the multiplier 13. Further, the current value of the fuel cell main body 9 is detected by the fuel cell output current detector 10 and given to the function unit 11, and the function unit 11 generates the reference set flow rate of the raw fuel corresponding to the detected current value. Then, the reference set flow rate of the raw fuel is supplied to the multiplier 13.
[0121]
The multiplier 13 multiplies the reference set flow rate of raw fuel by the correction coefficient from the controller 12 to generate a corrected reference set flow rate. That is, the control is performed so as to correspond to the deviation between the reformer temperature 18 and the temperature set value 19 of the reformer 1 with respect to the reference set flow rate of the raw fuel obtained from the function unit 11 corresponding to the output current value of the fuel cell body 9. The multiplier 13 performs correction using the correction coefficient obtained by the unit 12 to obtain a corrected reference set flow rate, which is output as the fuel flow rate set value 17.
[0122]
Then, this is supplied to the fuel cell fuel regulator 8. The fuel cell fuel regulator 8 automatically adjusts the opening degree of the fuel flow rate adjustment valve or the rotational speed of the fuel flow rate adjustment blower, which is a component of the fuel cell fuel regulator 8 corresponding to the fuel flow rate set value 17. As a result, the amount of raw fuel supplied to the reformer 1 is automatically controlled to an amount corresponding to the battery current value 16 and the reformer temperature. A fuel cell load may be used instead of the battery current value.
[0123]
As a result of adjusting the amount of raw fuel to the reformer 1 to an amount corresponding to the cell current value 16 and the reformer temperature, the reformer 1 is supplied from the reformer 1 to the fuel cell body 9 via the carbon monoxide converter 7. Since the amount of hydrogen is automatically controlled according to the output current value of the fuel cell main body 9 and the reformer temperature, normal operation is performed in a normal state where there is no fuel leakage in the case of the fuel cell power generation system. .
[0124]
Further, at this time, in the leak detector shown in FIG. 3, the function unit 32 which is a component of the leak detector gives an abnormality detection reference value of the fuel flow rate 26 according to the battery current value (or load) 16. The comparator 31 compares the value of the fuel flow rate 26 from the fuel flow meter 25 with the output from the fuel flow meter 25 as a comparison criterion. However, since the fuel cell power generation system is in a normal state, the fuel flow rate 26 does not exceed the comparison criterion. . Therefore, no fuel leak signal is generated from the leak detector.
[0125]
On the other hand, when fuel leakage occurs in the case of the fuel cell power generation system due to some failure or failure, unreacted hydrogen (surplus hydrogen) flowing from the fuel cell main body 9 to the burner 2 via the valve 6 decreases. Therefore, the amount of hydrogen supplied to the burner 2 is reduced, the combustion temperature is lowered, and the reformer temperature 18 is lowered.
[0126]
On the other hand, in order to keep the reformer temperature appropriately as described above, the fuel flow rate set value 17 increases, the adjustment valve opening in the fuel cell fuel regulator 8 or the rotation speed of the fuel flow rate adjustment blower, etc. The fuel supply control is performed.
[0127]
Further, at this time, in the leak detector shown in FIG. 3, the function unit 32 which is a component of the leak detector gives an abnormality detection reference value of the fuel flow rate 26 according to the battery current value (or load) 16. The comparator 31 compares the value of the fuel flow rate 26 from the fuel flow meter 25 with the output from. In this case, since the fuel cell power generation system is in an abnormal fuel leak state, the fuel flow rate 26 eventually exceeds the comparison standard. Then, when the fuel flow rate 26 exceeds the comparison reference, the leak detector shown in FIG. 3 generates a fuel leak signal. As a result, the fuel leak signal indicates that the fuel cell power generation system in operation is in an abnormal state of fuel leak.
[0128]
Therefore, by providing the system control device 20A with a fuel leak signal monitoring function and when the generation of the fuel leak signal continues for a predetermined time or more, a fuel cell operation protection operation or an alarm is issued. The fuel cell power generation system can be automatically stopped, or the user can be informed of the occurrence of a fuel leak failure due to an automatic warning before the automatic stop.
[0129]
As described above, when the fuel leaks, unreacted hydrogen flowing out from the fuel cell main body decreases, so that the reformer temperature decreases. In contrast, in the first and second embodiments, As explained, in order to keep the reformer temperature properly, control is made to increase the fuel flow rate, but since a function unit that provides an upper limit value according to the battery current or load is provided, excessive fuel or hydrogen leak occurs In this case, a fuel leak signal will be output according to this upper limit value, and in order to add a time limit element to this fuel leak signal for safety management, the system control device has a protection and alarm function, When an abnormal fuel leak occurs, the fuel cell power generation system can be automatically stopped, and an alarm can be automatically issued at the preceding stage to notify the user.
[0130]
Therefore, according to the third embodiment, when an excessive fuel or hydrogen leak occurs in the fuel cell power generation system, this is detected by a function that gives an upper limit value corresponding to the cell current or the load, and the fuel cell power generation Since it is possible to take measures such as automatically stopping the system, it is possible to quickly and reliably detect fuel leakage and maintain safety without having a combustible gas detector. As a result, an inexpensive and compact system can be provided by reducing the number of detectors.
[0131]
The above is a leak detector that detects the leakage of fuel by comparing the hydrogen fuel supplied to the fuel cell body based on the upper limit of the fuel flow rate determined for battery current or load, and generating a leak if the reference value is exceeded Was used. The occurrence of an abnormal fuel leak can also be detected by detecting that the fuel valve opening degree or the fuel flow rate adjusting blower rotational speed has reached the upper limit value. An example thereof will now be described as a fourth embodiment.
[0132]
(Fourth embodiment)
This embodiment corresponds to the inventions of the items [7] and [8] in the above [Means for Solving the Problems], and the fourth embodiment is shown in FIG. In addition, an upper limit value (a value serving as a criterion for abnormality) serving as a reference for the opening degree of the regulating valve or the rotational speed of the fuel flow rate adjusting blower, which is a constituent element of the fuel cell fuel regulator 8, is set as the battery current value (or load) 16 A function unit 32 given in accordance with the output of the function unit 32, and the output from the function unit 32 is compared with a detected value of the opening of the adjustment valve of the fuel cell fuel regulator 8 or the rotational speed of the fuel flow rate adjustment blower. When the opening degree or the fuel flow rate adjusting blower rotational speed exceeds the comparison reference, a comparator 31 that generates a fuel leak signal constitutes a leak detector. The leak detector is applied to a fuel cell power generation system as shown in FIG.
[0133]
In the fuel cell power generation system of FIG. 5, the adjustment valve of the fuel cell fuel regulator 8 can detect the opening degree, or the fuel flow rate adjustment blower can also detect the rotation speed. And it is the structure which gives the detected value to the leak detector of FIG.
[0134]
Further, the system control device 20A is provided with a fuel leak signal monitoring function, and when the generation of the fuel leak signal continues for a preset predetermined time or more, a protection operation of the fuel cell operation or an alarm is issued. Thus, the fuel cell power generation system can be automatically stopped, or the user can be informed of the occurrence of a fuel leak failure due to the automatic alarm generation before the automatic stop.
[0135]
In this system having such a configuration, when there is no fuel leakage in the case of the fuel cell power generation system, hydrogen supply to the fuel cell body 9 is performed in accordance with the output current value of the fuel cell body 9 and the reformer temperature. Since the automatic control is performed as described above, normal operation is performed in a normal state where there is no fuel leakage in the case of the fuel cell power generation system.
[0136]
On the other hand, when fuel leakage occurs in the case of the fuel cell power generation system due to some failure or failure, unreacted hydrogen (surplus hydrogen) flowing from the fuel cell main body 9 to the burner 2 via the valve 6 decreases. Therefore, the amount of hydrogen supplied to the burner 2 is reduced, the combustion temperature is lowered, and the reformer temperature 18 is lowered.
[0137]
On the other hand, in order to keep the reformer temperature appropriately as described above, the fuel flow rate set value 17 increases, and the fuel cell fuel adjustment provided on the inlet side of the reformer 1 for raw fuel adjustment. The fuel supply control such as the adjustment valve opening degree or the rotational speed of the fuel flow rate adjusting blower in the vessel 8 is performed.
[0138]
Therefore, the fuel cell body 9 is automatically controlled so as to supply hydrogen to the fuel cell body 9 according to the output current value of the fuel cell body 9 and the reformer temperature, so that the fuel supply to the fuel cell body 9 is increased. Control will work on the
In addition, at this time, the leak detector shown in FIG. 4 is configured such that the function unit 32 which is a component of the leak detector according to the battery current value (or load) 16 has the opening degree of the adjustment valve or the fuel of the fuel cell fuel regulator 8. An upper limit value serving as a criterion for abnormality determination with respect to the rotational speed of the flow rate adjusting blower is given, and the upper limit value output from the function unit 32 is used as a comparison reference, and the comparator 31 is used for the adjustment valve of the fuel cell fuel regulator 8. The detected value of the opening degree or the rotation speed of the fuel flow rate adjusting blower is compared. In this case, since the fuel cell power generation system is in an abnormal state of fuel leak, the detected value eventually exceeds the comparison standard. Then, when the detected value exceeds the comparison reference, the leak detector shown in FIG. 3 generates a fuel leak signal. As a result, the fuel leak signal indicates that the fuel cell power generation system in operation is in an abnormal state of fuel leak.
[0139]
Therefore, when the fuel leakage signal generation function is provided to the system controller 20A and the generation of the fuel leakage signal continues for a predetermined time or more, the fuel cell power generation is performed by causing the protection operation of the fuel cell operation or issuing an alarm. The system can be automatically stopped, or the user can be informed of the occurrence of a fuel leak failure by the automatic alarming before the automatic stop.
[0140]
As described above, the fuel cell power generation system according to the fourth embodiment includes a function unit that gives an upper limit value of the fuel flow rate adjustment valve opening or the fuel flow rate adjustment blower speed according to the battery current or the battery load. Compared to the upper limit value, the actual fuel valve opening or the rotation speed of the fuel flow rate adjustment blower is compared, and if this exceeds the upper limit value, the detector is composed of a comparator that generates a leak signal. is there.
[0141]
In the fuel cell power generation system, when the supplied fuel leaks in the system, unreacted hydrogen sent from the fuel cell main body to the reformer burner decreases, so that the reformer temperature decreases. On the other hand, as described in the first to third embodiments, in order to keep the reformer temperature appropriately, the opening degree of the adjustment valve of the fuel cell fuel regulator 8 or the rotational speed of the fuel flow rate adjustment blower. Will increase. However, since a function unit that provides an upper limit value according to the battery current or the load is provided, when an excessive fuel or hydrogen leak occurs, the upper limit value is reached and a fuel leak signal is generated. Therefore, the fuel leak signal is managed by a timed element, and when the fuel leak signal is generated, if the signal continues for a predetermined time, the fuel cell operation protection operation or alarm is issued. Therefore, the fuel cell power generation system can be automatically stopped, or the user can be notified of the occurrence of a fuel leak failure due to the automatic warning before the automatic stop.
[0142]
Therefore, according to this embodiment, even when excessive fuel or hydrogen leak occurs in the fuel cell power generation system, this abnormality is detected by a function that gives an upper limit value according to the cell current or the load, and the fuel cell power generation Since it is possible to cope with automatic stop of the system, alarm warning, etc., it becomes possible to quickly and surely detect fuel leakage and maintain safety without having a combustible gas detector. As a result, an inexpensive and compact system can be provided by reducing the number of detectors.
[0143]
The above is the hydrogen fuel supply state (fuel flow rate, fuel valve opening or fuel flow rate adjustment) that is supplied to the fuel cell body based on the upper limit value of fuel supply related information determined for battery current or load. The information on the number of rotations of the blower was compared, and a leak detector was used to generate a leak when the reference value was exceeded. This is monitored not by the fuel supply related information (information on the fuel flow rate, fuel valve opening or fuel flow adjustment blower rotation speed), but by the reformer burner air supply related information, and the reformer burner air supply related information is detected. The occurrence of an abnormal fuel leak can also be detected by detecting that the value has reached the upper limit value. An example thereof will be described next as a fifth embodiment.
[0144]
(Fifth embodiment)
This embodiment corresponds to the inventions of the items [9] and [10] in the above [Means for Solving the Problems], and the fuel cell power generation system of this embodiment includes a reformer burner. It is intended for a system having a function of controlling the air flow rate corresponding to the reformer temperature. This is a system having a function of reducing the amount of air supplied to the burner 2 when the reformer temperature decreases.
[0145]
That is, as shown in FIG. 6, an air flow meter 27 and an air supply amount regulator 28 are provided in the air supply path to the burner 2 of the reformer 1. The air flow meter 27 has a function of measuring an air flow rate and outputting a flow rate-corresponding flow rate signal. The air supply amount regulator 28 includes an adjustment valve, a blower for air blowing, and the like. In this configuration, the amount of outside air supplied to the burner 2 of the reformer 1 can be controlled by adjusting the opening degree or controlling the rotational speed of the air blower.
[0146]
Here, the reformer 1 reforms the raw fuel gas with steam using the heat generated by the combustion of the burner 2, but the reformer 1 has a temperature detector 3 for temperature control. The detected temperature of the mass device 1 (reformer temperature 18) is obtained. The temperature controller 5 compares the temperature detection signal value output from the thermometer 3 with reference to the temperature setting value 19 from the temperature setting device 4 that gives the temperature setting value of the reformer 1, and the temperature of the reformer 1. Is generated at a set value 19, and this control output is applied to the burner fuel adjustment valve 6 so that the burner fuel adjustment valve 6 is opened in response to the control output from the temperature controller 5. The amount of hydrogen gas supplied to the burner 2 is automatically adjusted. Further, the temperature controller 5 controls the number of revolutions of a regulating valve and a blower for air blowing, which are components of the air supply amount regulator 28, corresponding to the temperature detected by the temperature detector 3 (reformer temperature 18). Outputs are generated and controlled to adjust the amount of air to the reformer burner.
[0147]
The configuration of FIG. 6 is basically the same as the configuration of the embodiment described with reference to FIG. 1 and FIG. 5, and therefore, the same parts as those in FIG. 1 and FIG. Are omitted here.
[0148]
The fuel cell power generation system according to the fifth embodiment is the other. A fuel leak detector as shown in FIG. 7 is provided. In the configuration of FIG. 7, a function unit 32 that gives a lower limit value (a value that becomes an abnormality determination criterion) that is a lower limit reference value of the detected flow rate value of the air flow meter 27 according to the battery current value (or load) 16, and The output from the function unit 32 is compared with the detected flow rate value of the air flow meter 27 based on the comparison reference. When the detected flow rate exceeds (below) the comparison reference, the comparator 31 generates a fuel leak signal. Configure. The leak detector is applied to a fuel cell power generation system as shown in FIG.
[0149]
Further, the system control device 20A is provided with a fuel leak signal monitoring function, and when the generation of the fuel leak signal continues for a preset predetermined time or more, a protection operation of the fuel cell operation or an alarm is issued. Thus, the fuel cell power generation system can be automatically stopped, or the user can be informed of the occurrence of a fuel leak failure due to the automatic alarm generation before the automatic stop.
[0150]
In this system having such a configuration, when there is no fuel leakage in the case of the fuel cell power generation system, hydrogen supply to the fuel cell body 9 is performed in accordance with the output current value of the fuel cell body 9 and the reformer temperature. Since the automatic control is performed as described above, normal operation is performed in a normal state where there is no fuel leakage in the case of the fuel cell power generation system.
[0151]
On the other hand, when fuel leakage occurs in the case of the fuel cell power generation system due to some failure or failure, unreacted hydrogen (surplus hydrogen) flowing from the fuel cell main body 9 to the burner 2 via the valve 6 decreases. Therefore, the amount of hydrogen supplied to the burner 2 is reduced, the combustion temperature is lowered, and the reformer temperature 18 is lowered.
[0152]
On the other hand, in order to keep the reformer temperature appropriately as described above, the fuel flow rate set value 17 increases, the adjustment valve opening in the fuel cell fuel regulator 8 or the rotation speed of the fuel flow rate adjustment blower, etc. The fuel supply control is performed.
[0153]
Therefore, the fuel cell body 9 is automatically controlled so as to supply hydrogen to the fuel cell body 9 according to the output current value of the fuel cell body 9 and the reformer temperature, so that the fuel supply to the fuel cell body 9 is increased. Control will work.
[0154]
In addition, since the present system is a system having a function of reducing the reformer burner air flow rate 14 in order to keep the reformer temperature appropriately, the function of the temperature controller 5 is used at this time. The air supply amount adjuster 28 is controlled to reduce the amount of outside air supplied to the burner 2 of the reformer 1 by controlling the opening degree of the adjusting valve and the blower rotation speed for air blowing. The burner air flow rate will decrease.
[0155]
Here, the reformer burner air flow rate is detected by the air flow meter 27.
[0156]
In the leak detector shown in FIG. 7, the function unit 32 which is a component of the leak detector gives a lower limit value serving as a criterion for abnormality determination of the reformer burner air amount according to the battery current value (or load) 16. The comparator 31 compares the air flow rate detection value from the air flow meter 27 with the upper limit value output from the device 32 as a reference for comparison.
[0157]
In this case, since the fuel cell power generation system is in an abnormal fuel leak state, the air flow rate of the reformer burner is reduced, and as a result, the air amount detection value eventually breaks the comparison standard. The leak detector shown in FIG. 7 generates a fuel leak signal when the detected value divides the comparison reference. As a result, the fuel leak signal indicates that the fuel cell power generation system in operation is in an abnormal state of fuel leak.
[0158]
Therefore, by providing the system control device 20A with a fuel leak signal monitoring function and when the generation of the fuel leak signal continues for a predetermined time or more, a fuel cell operation protection operation or an alarm is issued. The fuel cell power generation system can be automatically stopped, or the user can be informed of the occurrence of a fuel leak failure due to an automatic warning before the automatic stop.
[0159]
As described above, the fuel cell power generation system according to the fifth embodiment includes a function unit that gives a lower limit value of the reformer burner air flow rate according to the battery current or load of the fuel cell, and reforming based on this lower limit value. And a comparator for generating a fuel leak signal for notifying the fuel leak when the reformer burner air flow rate reaches the lower limit value.
[0160]
When the fuel leaks, unreacted hydrogen flowing out from the fuel cell main body decreases, so that the reformer temperature decreases. On the other hand, in order to keep the reformer temperature appropriately, some fuel cell power generation systems have a function of reducing the reformer burner air flow rate. The flow rate decreases.
[0161]
According to the fifth embodiment, there is provided a function unit that gives a lower limit value of the reformer burner air flow rate corresponding to the battery current or the load 6, and this is compared with the actual reformer burner air flow rate to actually A comparator that generates a fuel leak signal when the air flow rate of the reformer burner reaches the lower limit value is provided. Therefore, if excessive fuel or hydrogen leak occurs in the fuel cell power generation system, the fuel leak signal is determined by the lower limit value. By adding a time limit element to this signal and managing and controlling it with the control device, if the generation of the fuel leak signal continues for a predetermined time, an alarm is issued or the fuel cell power generation system is operated. It is possible to automatically stop the system and to ensure safety.
[0162]
Therefore, according to this embodiment, when excessive fuel or hydrogen leak occurs in the fuel cell power generation system, this is actually changed by a function that gives a lower limit value of the reformer burner air flow rate according to the cell current or load. Since it can be detected by comparing the flow rate of the gasifier burner, it is possible to quickly and surely detect fuel leaks without using a combustible gas detector, thus ensuring safety, thus eliminating the need for a combustible gas detector. As a result, an inexpensive and compact system can be provided.
[0163]
The above is intended for a system having a function of controlling the reformer burner air flow rate according to the reformer temperature. If the reformer temperature decreases, the amount of air supplied to the reformer burner is also reduced. Focusing on the fact that the supply status of fuel and hydrogen gas can be monitored and monitored by the amount of air in the reformer burner, the detection of fuel leaks is defined as battery current or load correspondence. Based on the limit amount, the occurrence of abnormal fuel leak is detected by detecting that the flow rate of the burner supply air as the reformer burner air supply related information detection value has reached the above limit value (lower limit value). It is a thing. However, as information related to the reformer burner air supply, in addition to the air flow rate, the degree of reformer burner air valve opening or the number of revolutions of the air blower can be used. Next, an example in which this is detected will be described next as a sixth embodiment.
[0164]
(Sixth embodiment)
This embodiment corresponds to the inventions of the items [11] and [12] in the above [Means for Solving the Problems], and the fuel cell power generation system of this embodiment is the fifth embodiment. Similarly to the embodiment, the system is intended for a system having a function of controlling the reformer burner air flow rate in accordance with the reformer temperature. 6 is a system as shown in FIG. 6 having a function of reducing the amount of air supplied to the burner 2 when the reformer temperature decreases.
[0165]
In addition, the fuel cell power generation system according to the sixth embodiment includes a fuel leak detector as shown in FIG. 8 instead of the leak detector having the configuration shown in FIG. In the configuration of FIG. 8, a lower limit value (a value serving as a criterion for abnormality) serving as a reference for the opening degree of a valve or the rotational speed of the air blower that is a component of the air supply amount regulator 28 is a battery current value (or load). 16 is compared with the detected value of the valve opening of the air supply amount regulator 28 or the rotational speed of the fuel air blower, using the output from the function unit 32 as a reference for comparison. Alternatively, when the fuel flow rate adjusting blower rotational speed reaches the comparison reference, the leak detector is configured by the comparator 31 that generates a fuel leak signal while the fuel flow adjustment blower rotational speed falls below the comparison reference. The leak detector is applied to a fuel cell power generation system as shown in FIG.
[0166]
Further, the system control device 20A is provided with a fuel leak signal monitoring function, and when the generation of the fuel leak signal continues for a preset predetermined time or more, a protection operation of the fuel cell operation or an alarm is issued. Thus, the fuel cell power generation system can be automatically stopped, or the user can be informed of the occurrence of a fuel leak failure due to the automatic alarm generation before the automatic stop.
[0167]
In the leak detector shown in FIG. 8, the function unit 32 which is a component of the leak detector has a criterion for determining an abnormality with respect to the opening degree of the reformer burner air valve or the rotation speed of the air blower according to the battery current value (or load) 16. Based on the lower limit value output from the function unit 32 as a comparison reference, the comparator 31 detects the opening degree of the air valve or the rotation speed of the air blower of the air supply amount regulator 28 for the reformer. Compare values. In this case, since the fuel cell power generation system is in an abnormal state of fuel leak, the detected value eventually exceeds the comparison standard. Then, when the detected value reaches the comparison reference, the leak detector generates a fuel leak signal. Then, while the detected value falls below the comparison reference, that is, until the detected value returns from the lower limit value, the leak detector continues to generate the fuel leak signal.
As a result, the fuel leak signal indicates that the fuel cell power generation system in operation is in an abnormal state of fuel leak.
[0168]
Therefore, by providing the system control device 20A with a fuel leak signal monitoring function and when the generation of the fuel leak signal continues for a predetermined time or more, a fuel cell operation protection operation or an alarm is issued. The fuel cell power generation system can be automatically stopped, or the user can be informed of the occurrence of a fuel leak failure due to an automatic warning before the automatic stop.
[0169]
As described above, the fuel cell power generation system according to the sixth embodiment provides a function that gives the lower limit value of the reformer burner air valve opening or the reformer burner air blower speed according to the battery current or load of the fuel cell. Compare the actual reformer burner air valve opening or reformer burner air blower rotation speed with a comparator based on the lower limit value obtained by this function unit and the actual reformer burner. When the air valve opening degree or the reformer burner air blower rotational speed reaches the lower limit value which is a reference value, a leak detector is provided that generates a fuel leak signal until the lower limit value is removed.
[0170]
When the fuel leaks, unreacted hydrogen flowing out from the fuel cell main body decreases, so that the reformer temperature decreases. On the other hand, in order to keep the reformer temperature appropriately, some fuel cell power generation systems have a function of reducing the reformer burner air flow rate. The flow rate decreases.
[0171]
In the case of the fuel cell power generation system that is the subject of the sixth embodiment, when the fuel or hydrogen leaks and the reformer temperature decreases, the reformer burner air valve opening or the reformer burner air The blower speed will be reduced.
[0172]
However, since a lower limit value according to the battery current or load is given by the function unit, if excessive fuel or hydrogen leak occurs, a fuel leak signal is output by this lower limit value, and a time limit element is added to this signal. Management control by the control device will ensure that safety will be issued when a fuel leak signal continues for a specified time, and an alarm can be issued or the operation of the fuel cell power generation system can be automatically stopped. be able to.
[0173]
Therefore, according to this embodiment, when an excessive fuel or hydrogen leak occurs in the fuel cell power generation system, it can be detected and dealt with by a function that gives a lower limit value corresponding to the battery current or the load. Therefore, without using a combustible gas detector, it is possible to quickly and reliably detect fuel leakage and ensure safety. As a result, an inexpensive and compact system can be provided because no combustible gas detector is required.
[0174]
Note that the present invention is not limited to the above-described embodiment, and can be appropriately modified and implemented without departing from the scope of the invention. For example, the leak detector in the above embodiment can be realized by software in addition to the hardware configuration, and when realized by software, the function is executed by causing the system control device 20A to execute the software. Various modifications are possible, such as a configuration to be realized.
[0175]
In the present invention, the above embodiment includes inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements. For example, even if some constituent elements are deleted from all the constituent elements shown in the embodiment, at least one of the problems described in the column of the problem to be solved by the invention can be solved, and is described in the column of the effect of the invention. When at least one of the effects is obtained, a configuration in which this configuration requirement is deleted can be extracted as an invention.
[0176]
【The invention's effect】
As described above, according to the present invention, without using a combustible gas detector, it is possible to detect an abnormal state of the state quantity in the system and quickly determine the presence of an excessive fuel leak. Alarm output and automatic stop operation can be performed.
[0177]
Accordingly, it is possible to provide a fuel cell power generation system and a control method for the fuel cell power generation system that can be configured at low cost while maintaining safety. Further, it is possible to provide a fuel cell power generation system that is a compact system and a control method for the fuel cell power generation system.
[Brief description of the drawings]
FIG. 1 is a diagram for explaining the present invention, and is a block diagram showing a first embodiment of the present invention as an example;
FIG. 2 is a block diagram showing a second embodiment of the present invention as an example for explaining the present invention;
FIG. 3 is a block diagram showing a configuration example of a leak detector of the present invention used in the third embodiment of the present invention.
FIG. 4 is a block configuration diagram showing a configuration example of a leak detector of the present invention used in the fourth embodiment of the present invention.
FIG. 5 is a diagram for explaining the present invention, and is a block configuration diagram showing a configuration example of a fuel cell power generation system as an example to which the leak detector according to the third and fourth embodiments of the present invention is applied; It is.
FIG. 6 is a block configuration diagram showing a configuration example of a fuel cell power generation system as an example to which the leak detector according to the fifth and sixth embodiments of the present invention is applied.
FIG. 7 is a block configuration diagram showing a configuration example of a leak detector used in the fifth embodiment of the present invention.
FIG. 8 is a block diagram showing a configuration example of a leak detector used in the sixth embodiment of the present invention.
FIG. 9 is a configuration diagram showing a conventional fuel cell.
[Explanation of symbols]
1 ... reformer
2 ... Burner
2a ... Combustion detector
3 ... Thermometer
4 ... Temperature setter
5 ... Temperature controller
6 ... Burner fuel adjustment valve
7 ... Carbon monoxide transformer
8. Fuel cell fuel regulator
9. Fuel cell body
10 ... Fuel cell output current detector
11 ... Function unit
12 ... Controller
13 ... Multiplier
14 ... K multiplier
15 ... Low value selector
16 ... Battery current detection value
17 ... Fuel flow rate setting value
18 ... reformer temperature
19 ... Temperature set value
20, 20A ... System control device
21 ... Functional unit
22 ... Fuel controller
23 ... Low value selector
24 ... Fuel control information
25 ... Fuel flow meter
26: Fuel flow signal 26
27 ... Air flow meter
28 ... Air supply regulator
31 ... Comparator
32 ... Functional unit
FC ... Fuel cell body
FP ... reformer
P ... Package
GS ... Combustible gas detector
CNT: Control device.

Claims (16)

A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and using the reformed gas obtained by the reformer as a fuel gas, oxidizing the fuel gas and air, etc. In a fuel cell power generation system composed of a fuel cell main body that generates electrical energy by an electrochemical reaction with the agent gas,
Temperature detecting means for detecting the temperature of the reformer;
Means for generating an upper limit value of the flow rate of fuel supplied to the fuel cell main body corresponding to an output current value or load amount of electric energy generated by the fuel cell main body;
When the flow rate setting value for instructing the flow rate of the fuel supplied from the reformer to the fuel cell main body reaches the upper limit value of the flow rate, the temperature detection means lowers the temperature of the reformer and the heating of the reformer And a fuel cell power generation system comprising: system control means for performing at least one of alarming and stop control of the fuel cell power generation system when there is a burner misfire or a voltage drop of the fuel cell main body. system. A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and using the reformed gas obtained by the reformer as a fuel gas, oxidizing the fuel gas and air, etc. In a fuel cell power generation system composed of a fuel cell main body that generates electrical energy by an electrochemical reaction with the agent gas,
Temperature detecting means for detecting the temperature of the reformer;
Means for generating an upper limit value of the flow rate of fuel supplied to the fuel cell main body corresponding to an output current value or load amount of electric energy generated by the fuel cell main body;
When the flow rate setting value for instructing the flow rate of the fuel supplied from the reformer to the fuel cell main body reaches the upper limit of the flow rate, the temperature detection means lowers the temperature of the reformer and heats the reformer System control means for performing stop control of the fuel cell power generation system when there is a burner misfire or a voltage drop of the fuel cell main body, and the alarm issuance status continues for a predetermined time;
A fuel cell power generation system comprising: A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and using the reformed gas obtained by the reformer as a fuel gas, oxidizing the fuel gas and air, etc. In a fuel cell power generation system composed of a fuel cell main body that generates electrical energy by an electrochemical reaction with the agent gas,
Temperature detecting means for detecting the temperature of the reformer;
A valve for adjusting the amount of the fuel gas supplied to the fuel cell main body, and a fuel flow rate adjustment valve whose opening degree is adjusted in response to a given opening degree command value;
Means for generating an opening upper limit value of the fuel flow valve corresponding to an output current value or load amount of electric energy generated by the fuel cell body;
Means for generating the opening command value corresponding to an output current value or load amount of electric energy generated by the fuel cell body;
When the opening degree command value reaches the opening degree upper limit value , a warning is given when there is a temperature drop of the reformer by the temperature detection means, a misfire of the heating burner of the reformer or a voltage drop of the fuel cell body System control means for performing at least one of alarming or stopping control of the fuel cell power generation system;
A fuel cell power generation system comprising: A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and using the reformed gas obtained by the reformer as a fuel gas, oxidizing the fuel gas and air, etc. In a fuel cell power generation system composed of a fuel cell main body that generates electrical energy by an electrochemical reaction with the agent gas,
Temperature detecting means for detecting the temperature of the reformer;
A valve for adjusting the amount of the fuel gas supplied to the fuel cell main body, and a fuel flow rate adjusting valve whose opening degree is adjusted in response to a given opening degree command value;
Means for generating an upper limit value of the fuel flow valve corresponding to an output current value or load amount of electric energy generated by the fuel cell body;
Means for generating the opening command value corresponding to an output current value or load amount of electric energy generated by the fuel cell body;
When the opening degree command value reaches the opening degree upper limit value , an alarm is given when there is a temperature drop of the reformer by the temperature detecting means, a misfire of a heating burner of the reformer or a voltage drop of the fuel cell body System control means for performing a stop control of the fuel cell power generation system when a warning is issued and the alarm is being issued for a predetermined time; and
A fuel cell power generation system comprising: A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and using the reformed gas obtained by the reformer as a fuel gas, oxidizing the fuel gas and air, etc. In a fuel cell power generation system composed of a fuel cell main body that generates electrical energy by an electrochemical reaction with the agent gas,
Detecting means for detecting a flow rate of the fuel gas supplied to the fuel cell body;
A means for giving an abnormality detection reference value of a fuel flow rate corresponding to an output current value or load amount of electric energy generated by the fuel cell body;
Comparing means for comparing the detected flow rate of the fuel gas using the abnormality detection reference value as a comparison reference, and generating a signal when the detected flow rate of the fuel gas exceeds the comparison reference;
System control means for performing at least one of alarming or stopping control of the fuel cell power generation system based on a signal from the comparison means;
A fuel cell power generation system comprising: A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and using the reformed gas obtained by the reformer as a fuel gas, oxidizing the fuel gas and air, etc. In a fuel cell power generation system composed of a fuel cell main body that generates electrical energy by an electrochemical reaction with the agent gas,
Detecting means for detecting an opening of an adjusting valve for adjusting a flow rate of fuel gas supplied to the fuel cell main body by valve opening control or a rotation speed of a blower for sending out fuel gas;
Means for providing an abnormality detection reference value for the opening degree of the regulating valve or the rotational speed of the blower in response to an output current value or load amount of electric energy generated by the fuel cell body;
Comparing means for comparing the detected value of the opening of the regulating valve or the rotational speed of the blower with the abnormality detection reference value as a comparison reference, and generating a signal when the detected value exceeds the comparison reference;
A fuel cell power generation system, comprising: system control means for performing at least one of alarm generation and stop control of the fuel cell power generation system by a signal from the comparison means. A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and using the reformed gas obtained by the reformer as a fuel gas, oxidizing the fuel gas and air, etc. A fuel cell main body that generates electric energy by an electrochemical reaction with the agent gas, and when the temperature of the reforming device is detected and the temperature of the reforming device falls below a set temperature, In a fuel cell power generation system having an adjustment function of adjusting and controlling to reduce the amount of oxidant gas supplied to a heating burner,
Detecting means for detecting the flow rate of the oxidant gas supplied to the heating burner of the reformer;
Means for providing an abnormality detection reference value for the amount of oxidant gas supplied to the heating burner of the reformer in response to an output current value or load amount of electrical energy generated by the fuel cell body;
Comparing means for comparing the detected flow rate of the oxidant gas with the abnormal value detection reference value as a comparison reference, and generating a signal when the detected flow rate reaches the comparison reference;
Fuel cell power generation system characterized by comprising a system control means for performing at least one of the stop control alarm onset report or fuel cell power generation system by a signal from the comparison means. A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and using the reformed gas obtained by the reformer as a fuel gas, oxidizing the fuel gas and air, etc. A fuel cell main body that generates electric energy by an electrochemical reaction with the agent gas, and when the temperature of the reforming device is detected and the temperature of the reforming device falls below a set temperature, In a fuel cell power generation system having an adjustment function of adjusting and controlling to reduce the amount of oxidant gas supplied to a heating burner,
Detecting means for detecting the opening of an adjusting valve for adjusting the flow rate of the oxidant gas supplied to the heating burner of the reformer by the valve opening degree control or the rotational speed of the blower for sending the oxidant gas;
Means for providing an abnormality detection reference value of the opening of the regulating valve or the rotational speed of the blower in response to an output current value or load amount of electric energy generated by the fuel cell body;
Comparing means for comparing the detected flow rate of the oxidant gas with the abnormality detection reference value as a comparison reference, and generating a signal when the detected flow rate reaches the comparison reference;
A fuel cell power generation system, comprising: system control means for performing at least one of alarm generation and stop control of the fuel cell power generation system by a signal from the comparison means. A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and using the reformed gas obtained by the reformer as a fuel gas, oxidizing the fuel gas and air, etc. In a control method of a fuel cell power generation system composed of a fuel cell main body that generates electric energy by an electrochemical reaction with an agent gas ,
Detecting the temperature of the reformer,
In addition, the fuel cell main body generates an upper limit value of the flow rate of the fuel supplied to the fuel cell main body corresponding to the output current value or load amount of the electric energy generated by the fuel cell main body,
When the flow rate setting value indicating the flow rate of the fuel supplied from the reformer to the fuel cell main body reaches the flow rate upper limit value, the temperature of the reformer decreases and the burner for heating of the reformer misfires or A control method for a fuel cell power generation system, wherein the fuel cell power generation system is controlled to stop when there is a voltage drop in the fuel cell main body in the fuel cell main body. A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and using the reformed gas obtained by the reformer as a fuel gas, oxidizing the fuel gas and air, etc. In a control method of a fuel cell power generation system composed of a fuel cell main body that generates electric energy by an electrochemical reaction with an agent gas ,
Detecting the temperature of the reformer,
The fuel cell main body generates an upper limit value of the flow rate of the fuel supplied to the fuel cell main body corresponding to the output current value or load amount of electric energy generated by the fuel cell main body, and the fuel supplied from the reformer to the fuel cell main body When the flow rate setting value for instructing the flow rate reaches the upper limit value of the flow rate, there is a temperature drop of the reformer, a misfire of the heating burner of the reformer, or a battery voltage drop from the detected value of the reformer A control method for a fuel cell power generation system, characterized in that an alarm is issued or the fuel cell power generation system is stopped. A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and an electrochemical reaction between the reformed gas obtained by the reformer and an oxidant gas such as air. In a control method of a fuel cell power generation system comprising a fuel cell main body that generates energy ,
A valve for adjusting the amount of the fuel gas supplied to the fuel cell main body, wherein a fuel flow rate adjustment valve is provided that adjusts the opening in response to a given opening command value, and the fuel cell main body An opening upper limit value of the fuel flow valve is generated corresponding to the output current value or load amount of the electric energy generated, and the opening command value corresponding to the output current value or load amount of the electric energy generated by the fuel cell body Is generated,
When the opening degree command value reaches the opening degree upper limit value, an alarm is generated when there is a temperature drop of the reformer by the temperature detecting means, a misfire of the heating burner of the reformer or a drop in the battery voltage. Or a control method of a fuel cell power generation system, wherein at least one of stop control of the fuel cell power generation system is performed. A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and an electrochemical reaction between the reformed gas obtained by the reformer and an oxidant gas such as air. In a control method of a fuel cell power generation system comprising a fuel cell main body that generates energy ,
A valve for adjusting the amount of the fuel gas supplied to the fuel cell main body, wherein a fuel flow rate adjustment valve is provided that adjusts the opening in response to a given opening command value, and the fuel cell main body An output upper limit value of the fuel flow valve corresponding to the output current value or load amount of the electric energy generated by
Generating the opening command value corresponding to the output current value or load amount of the electric energy generated by the fuel cell body,
When the opening degree command value reaches the opening degree upper limit value, when there is a temperature drop of the reformer and a misfire of a heating burner of the reformer or a voltage drop of the fuel cell body, an alarm is issued. A control method for a fuel cell power generation system, characterized in that a stop control of the fuel cell power generation system is carried out when the alarm issuance status continues for a predetermined time. A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and an electrochemical reaction between the reformed gas obtained by the reformer and an oxidant gas such as air. In a control method of a fuel cell power generation system comprising a fuel cell main body that generates energy ,
An allowable upper limit value for the fuel cell main body supplied fuel flow rate or its set value is given according to the battery current and load, and the actual fuel flow rate to the fuel cell main body or The set value is compared, and when the actual fuel flow rate to the fuel cell body or the set value exceeds the reference value, an alarm signal is issued or the fuel cell power generation system is automatically stopped. Control method of fuel cell power generation system. A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and an electrochemical reaction between the reformed gas obtained by the reformer and an oxidant gas such as air. In a control method of a fuel cell power generation system comprising a fuel cell main body that generates energy ,
An adjustment valve for adjusting the flow rate of the fuel gas supplied to the fuel cell main body by valve opening control or a blower for sending the fuel gas to the fuel cell main body is provided, and the opening of the adjustment valve or the rotation of the blower for sending the fuel gas is provided. The detection value is obtained by detecting the number, and a predetermined upper limit value for the fuel supply flow rate control valve opening or its set value or the rotation speed of the blower according to the battery current or load is given. The fuel is characterized in that the detected value is compared based on the upper limit value, and as a result, if the detected value exceeds the reference value, an alarm signal is issued or the fuel cell power generation system is controlled to stop. Control method of battery power generation system. A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and an electrochemical reaction between the reformed gas obtained by the reformer and an oxidant gas such as air. An oxidant gas supplied to the heating burner of the reformer when the temperature of the reformer is detected and the temperature of the reformer decreases to a set temperature. In a control method of a fuel cell power generation system having an adjustment function of adjusting and controlling to reduce the amount ,
Predetermined reformer burner combustion air flow or provide an acceptable lower limit for the set value, the reformer air amount or setting the burner combusting the given allowable lower limit value to the reference corresponding to the battery current and the load comparing a value, the fuel cell power generation, characterized by automatically stopping the or fuel cell power generation system to alarm an alarm signal when the reformer burner combustion air amount or setting value that is below the reference How to control the system. A reformer for generating a hydrogen-rich reformed gas from a raw fuel gas containing hydrocarbons, and using the reformed gas obtained by the reformer as a fuel gas, oxidizing the fuel gas and air, etc. A fuel cell main body that generates electrical energy by an electrochemical reaction between the oxidant gas and the oxidant gas, and when the temperature of the reformer is detected and the temperature of the reformer falls below a set temperature In the control method of the fuel cell power generation system having an adjustment function of adjusting and controlling to reduce the amount of oxidant gas supplied to the heating burner of the reformer ,
An adjusting valve for adjusting the flow rate of the oxidant gas supplied to the heating burner of the reformer by valve opening degree control or a blower for sending out the oxidant gas is provided to detect the opening degree of the adjusting valve or the rotation speed of the blower. To obtain the detected value,
A predetermined reformer burner combustion air flow rate control valve opening or its set value or an allowable lower limit value of the rotation speed of the blower is given according to the battery current or load, and this allowable lower limit value is compared with the detected value. A control method for a fuel cell power generation system, wherein an alarm signal is issued or the fuel cell power generation system is automatically stopped when a detected value falls below an allowable lower limit value.

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