JP5136219B2 - Fuel cell system - Google Patents

Description

  The present invention relates to a fuel cell system including a fuel cell unit and a hot water storage unit, and particularly has a feature in a communication configuration between the fuel cell unit and the hot water storage unit.

  Currently, the fuel cell cogeneration system (cogeneration system) is designed to increase the efficiency of the entire system by generating electricity with a fuel cell and effectively using the heat generated at that time, storing it as hot water, and using it for hot water supply and heating. Development is progressing.

  A fuel cell cogeneration system is generally composed of both a fuel cell unit that generates electricity and a hot water storage unit that stores hot water. The fuel cell unit includes a reformer that produces hydrogen from city gas, a stack that generates electricity by chemically reacting hydrogen and oxygen, etc., and performs complex system control to generate power.

  On the other hand, the heat generated by the chemical reaction is generated at the time of this power generation, and the heat is recovered by a heat exchanger without being wasted in the air and stored as hot water. And in addition to the system controller for storing hot water efficiently and a hot water storage tank for storing hot water, a hot water storage unit is installed in a backup water heater in the event that the fuel cell cogeneration system fails and hot water is no longer supplied. It is configured.

  Since the fuel cell unit and the hot water storage unit are large in volume and heavy, respectively, they are usually installed in a state where they are separated as two units. However, the power generation and hot water storage of the fuel cell cogeneration system (combined heat and power supply system) are related to each other as described above, and the control of the power generation unit and the control of the hot water storage unit need to be comprehensively controlled.

Therefore, exchange of information and exchange of control signals between the two units separated into the power generation unit and the hot water storage unit are performed by inter-unit data communication (see, for example, Patent Document 1).
JP 2003-131730 A

  However, in the conventional configuration, in the fuel cell system composed of the fuel cell unit and the hot water storage unit, when an error occurs during inter-unit communication, an error display means provided on the fuel cell unit side displays an error, Anomaly information is transmitted to a remote office server, but it is determined whether there is a problem on the fuel cell unit side, a problem on the hot water storage unit side, or a unit on the side. It was difficult to cope with this problem.

  An object of the present invention is to provide a fuel cell system that can determine whether a communication unit on the fuel cell unit side is defective or a communication unit on the hot water storage unit side is defective.

In order to solve the above problems, the present invention receives a communication signal from a first microcomputer of a fuel cell unit, a first transmitter for converting a digital signal of the first microcomputer into a communication signal, and a hot water storage unit. A first receiver for converting the digital signal to the first microcomputer; a first signal detector attached to the output side of the first transmitter; and a second signal detector attached to the input side of the first receiver. Fuel cell unit side communication means for inputting output signals of the first signal detection means and the second signal detection means to the first microcomputer, a second microcomputer of the hot water storage unit, and a second thereof a second transmission unit for the digital signal of the second microcomputer converts the communication signals transmitted to the fuel cell unit, and receiving communication signals from the fuel cell unit varying the digital signal to the second microcomputer Second and a hot water storage unit side communication means and a receiving unit, when an error in communication between the fuel cell unit side communication means and the hot water storage unit side communication means has occurred, the first signal detecting means for Based on the output signal from the second signal detection means, the error display means displays an error, and abnormality information is transmitted to the server outside the system using a general communication line.

  The fuel cell system of the present invention has such a configuration, so that when a communication error is displayed on the error display means of the fuel cell unit and abnormality information is transmitted to a remote office server, the office The service person in can know in advance which side of the fuel cell unit or hot water storage unit is defective, can prepare for service parts, etc., and can dispatch the faulty unit at the site Therefore, repair can be started immediately and serviceability can be improved, such as shortening the repair time.

The first of the present invention is the fuel cell system and a fuel cell unit and the hot water storage unit, a first microcomputer in the fuel cell unit, a first transmission section for converting the digital signal of the first microcomputer to the communication signal A first receiving unit that receives a communication signal from the hot water storage unit and converts it into a digital signal to the first microcomputer, a first signal detecting means attached to the output side of the first transmitting unit, and an input of the first receiving unit A fuel cell unit-side communication means for inputting the output signals of the first signal detection means and the second signal detection means to the first microcomputer, and a second hot water storage unit second microcontroller and a second transmission unit that transmits to the digital signal of the second microcomputer converts the communication signal the fuel cell unit, the second microcomputer receives the communication signal from the fuel cell unit And a hot water storage unit side communication means and a second receiver for converting into a digital signal, when an error occurs in the communication between the fuel cell unit side communication means and the hot water storage unit side communication unit, the first signal detection The error display means displays an error based on the output signals from the means and the second signal detection means, and transmits abnormality information to the server outside the system using a general communication line.

  With this configuration, the service person in the office can know in advance which side of the fuel cell unit or hot water storage unit is defective, can be dispatched with service parts etc. prepared, and is troubled at the site. Since the unit has been identified, repair can be started immediately, and serviceability can be improved, such as shortening the repair time.

  In a second aspect of the present invention, particularly in the first aspect of the present invention, the first signal detecting means is a first light receiving means for detecting a light emitting state of the first light emitting means and the first light emitting means, and the second signal detecting means is The second light emitting means and the second light receiving means for detecting the light emission state of the second light emitting means are used.

  Since the communication line connecting each unit and the first light receiving means and the second light receiving means are electrically insulated, the error display means displays an error based on the output signals from the first light receiving means and the second light receiving means. Therefore, it is possible to prevent malfunction.

Hereinafter, embodiments of the fuel cell system of the present invention will be described with reference to the drawings. However, the present invention is not limited to the embodiments.
(Embodiment 1)
FIG. 1 is a configuration diagram showing the configuration of the fuel cell system according to Embodiment 1 of the present invention.

  Hereinafter, the configuration of the fuel cell system according to Embodiment 1 of the present invention will be described in detail with reference to FIG.

  A fuel cell system is generally composed of both a fuel cell unit for generating electricity and a hot water storage unit for storing hot water. Since the fuel cell unit and the hot water storage unit are large in volume and heavy, respectively, they are installed in a state of being separated into two units.

  However, the control of the power generation unit and the control of the hot water storage unit are not independent of each other but are related to each other and need to be comprehensively controlled. For this reason, information exchange and control signal exchange between two separated units are performed by inter-unit data communication.

  On the fuel cell unit (main station) side, there is a first microcomputer 1 that performs the main control of the fuel cell system, a reformer that produces hydrogen from city gas, and electricity generated by chemically reacting hydrogen and oxygen Controls stacks and many other auxiliary machines.

  The first microcomputer 1 performs communication control with the hot water storage unit, error display control when a system error occurs, and communication control with a remote server. A transmission digital signal from the first microcomputer 1 is input to the first transmission unit 3 of the first transmission / reception circuit 2 and converted into a transmission communication signal, and is transmitted through the first communication line 7 to the second hot water storage unit (slave station) side. The signal is input to the second reception unit 11 of the transmission / reception circuit 10. The second receiving unit 11 converts the received digital signal into an input signal to the second microcomputer 9.

  On the other hand, on the hot water storage unit (slave station) side, there is a second microcomputer 9 that performs main control of the hot water storage system, and controls hot water storage tanks, hot water control, backup hot water heaters, and the like. The second microcomputer 9 also performs communication control with the fuel cell unit side.

  A transmission digital signal from the second microcomputer 9 is input to the second transmission unit 12 of the second transmission / reception circuit 10 and converted into a communication signal, and is transmitted to the first transmission / reception circuit 2 of the fuel cell unit via the second communication line 8. Input to the first receiver 4. Then, it is converted into a digital signal by the first receiver 4 and becomes an input signal to the first microcomputer 1.

  Then, the fuel cell unit and the hot water storage are connected by a communication method in which the hot water storage unit (slave station) receives the transmission from the fuel cell unit (main station) side and the slave station responds to the request from the main station side. A fuel cell system composed of units is comprehensively controlled.

  When communication is performed between the fuel cell unit (main station) side and the hot water storage unit (slave station) side by such a communication method, the transmission from the first microcomputer 1 on the main station side is the same as that on the main station side. When a communication error occurs between the units because reception to one microcomputer 1 is not obtained, an error is displayed on the error display means 13 of the fuel cell unit, and from the communication circuit 14 that receives a signal from the first microcomputer 1 Abnormal information is transmitted to the remote office server 16 using the general communication line 15, but there is a malfunction in the communication unit on the fuel cell unit (main station) side, causing a communication error. I do not know if there is a problem with the communication section on the hot water storage unit (slave station) causing a communication error.

  Therefore, first signal detection means 5 for detecting the communication state on the output side of the first transmission unit 3 and the input side of the first reception unit 4 of the first transmission / reception circuit 2 on the fuel cell unit (main station) side, The second signal detection means 6 is attached, and new means for inputting the output signals of the first signal detection means 5 and the second signal detection means 6 to the first microcomputer 1 are provided.

  By providing this new means, when a communication error occurs, it can be determined whether there is a malfunction in the communication section on the fuel cell unit (main station) side or a malfunction in the communication section on the hot water storage unit (substation) side. Become.

  The operation and action will be described below.

  The digital transmission signal sent from the first microcomputer on the fuel cell unit (main station) side is converted into a communication signal by the first transmission unit 3 of the first transmission / reception circuit 2, and the hot water storage unit via the first communication line 7. The signal is transmitted to the second reception unit 11 of the second transmission / reception circuit 10 on the (slave station) side, converted into a digital reception signal by the second reception unit 11, and input to the second microcomputer 9.

  The second microcomputer 9 interprets the received signal, performs some control, sends the information of the result to the second transmitter 12 of the second transmitter / receiver circuit 10 on the hot water storage unit (slave station) side, and passes through the second communication line 8. Then, it is transmitted to the first receiver 4 of the first transmission / reception circuit 2 on the fuel cell unit (main station) side, and input as a digital signal to the first microcomputer 1 on the fuel cell unit (main station) side.

  As described above, when the communication between the fuel cell unit (main station) side and the hot water storage unit (slave station) side is normally performed, the communication signal is detected by the first signal detection means 5 and the second signal detection means 6, and digital A signal is input to the first microcomputer 1. The first microcomputer 1 determines that both the transmission and reception signals are normal and that communication has been performed normally, and does not display a communication error.

  The first microcomputer 1 displays a communication error when the first microcomputer 1 outputs a transmission signal but the reception signal to the first microcomputer 1 is not returned.

  When a communication error is displayed, either on the fuel cell unit (main station) side or on the hot water storage unit (slave station) side based on the presence / absence of the detection signals of the first signal detection means 5 and the second signal detection means 6 It is possible to clarify the relationship of malfunctions.

  The table below summarizes the method for determining defects.

Thus, a communication error is displayed on the error display means 13 provided on the fuel cell unit side (main station), and the communication circuit 14 that receives the signal from the first microcomputer 1 uses the general communication line 15. When abnormality information is transmitted to the remote office server 16, it is possible to determine whether there is a malfunction in the communication unit on the fuel cell unit (main station) side or a malfunction in the communication unit on the hot water storage unit (subordinate station) side. become.
(Embodiment 2)
FIG. 2 is a configuration diagram showing the configuration of the fuel cell system according to Embodiment 2 of the present invention.

  Hereinafter, the configuration of the fuel cell system according to Embodiment 2 of the present invention will be described with reference to FIG.

  In the fuel cell system according to the second embodiment, instead of the first signal detecting means 5 of the first embodiment, the first light receiving means 18 (LED) and the first light receiving means 18 for detecting the light emission state of the first light emitting means 17 are used. In place of the second signal detecting means 6, the second light emitting means 19 (LED) and the second light receiving means 20 (PT) for detecting the light emission state of the second light emitting means 19 are replaced. Is.

  That is, the first light emitting means 17 for displaying the communication states attached to the output side of the first transmission unit 3 and the input side of the first reception unit 4 of the first transmission / reception circuit 2 on the fuel cell unit (main station) side, respectively. The first light receiving means 18 and the second light receiving means 20 for detecting the light emitting states of the second light emitting means 19 and the first light emitting means 17 and the second light emitting means 19 are attached. A new means for inputting the output signal of the light receiving means 20 to the first microcomputer 1 is provided.

  The operation and action will be described below.

  When the communication between the fuel cell unit (main station) side and the hot water storage unit (slave station) side is normally performed, the digital communication is performed during the period in which the first light emitting means 17 and the second light emitting means 19 are both transmitting digital communication signals. It is possible to confirm the state of lighting at a certain brightness by repeating high-frequency blinking as the signal is turned on and off.

  The high-frequency blinking is detected by the first light receiving means 18 and the second light receiving means 20 and input to the first microcomputer as a digital signal. The first microcomputer determines that both the transmission and reception signals are normal and the communication is normally performed, and does not display a communication error.

  The first microcomputer 1 displays a communication error when the first microcomputer 1 outputs a transmission signal but the reception signal to the first microcomputer 1 is not returned.

  When a communication error is displayed, the relationship between the combination of the state of the first light emitting means 17 and the second light emitting means 19 and whether the malfunction occurs on the fuel cell unit (main station) side or the hot water storage unit (subordinate station) side is clarified. Can be.

  The table below summarizes the method for determining defects.

  Thus, a communication error is displayed on the error display means 13 provided on the fuel cell unit side (main station), and the communication circuit 14 that receives the signal from the first microcomputer 1 uses the general communication line 15. When abnormality information is transmitted to the remote office server 16, it is possible to determine whether there is a malfunction in the communication unit on the fuel cell unit (main station) side or a malfunction in the communication unit on the hot water storage unit (subordinate station) side. become.

  In the case of the second embodiment shown in FIG. 2, the first light receiving means 18 and the second light receiving means 20 are electrically insulated from the first communication line 7 and the second communication line 8, respectively. It is possible to prevent a malfunction from occurring in the error display by the error display means 13 based on the output signals from the first light receiving means 18 and the second light receiving means 20.

  As described in the first and second embodiments, by providing the new means, a communication error is displayed on the error display means of the fuel cell unit, and the abnormality information is transmitted to the remote office server. In this case, a service person in the office can know in advance which side of the fuel cell unit or hot water storage unit is defective, can prepare for service parts, and can be dispatched. Therefore, there is an effect that serviceability can be improved such that repair can be started immediately and repair time can be shortened.

  The present invention can be used in a fuel cell system including a fuel cell unit and a hot water storage unit, and particularly facilitates handling when a communication error occurs between the fuel cell unit and the hot water storage unit.

1 is a configuration diagram of a fuel cell system according to Embodiment 1 of the present invention. Configuration diagram of a fuel cell system according to Embodiment 2 of the present invention

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 1st microcomputer 2 1st transmission / reception circuit 3 1st transmission part 4 1st reception part 5 1st signal detection means 6 2nd signal detection means 7 1st communication line 8 2nd communication line 9 2nd microcomputer 10 2nd transmission / reception circuit DESCRIPTION OF SYMBOLS 11 2nd receiving part 12 2nd transmission part 13 Error display means 14 Communication circuit 15 General communication line 16 Remote location office server 17 1st light emission means 18 1st light reception means 19 2nd light emission means 20 2nd light reception means

Claims (2)

In a fuel cell system comprising a fuel cell unit and a hot water storage unit,
A first microcomputer of the fuel cell unit, a first transmitter for converting a digital signal of the first microcomputer into a communication signal, and a communication signal from the hot water storage unit are received and converted into a digital signal to the first microcomputer. A first receiving unit; a first signal detecting unit attached to the output side of the first transmitting unit; and a second signal detecting unit attached to the input side of the first receiving unit. And a fuel cell unit side communication unit configured to input an output signal of the second signal detection unit to the first microcomputer,
Said second microcomputer hot water storage unit, a second transmission unit that transmits converts the digital signal of the second microcomputer in communication signal to the fuel cell unit, and receiving communication signals from the fuel cell unit and the second microcomputer A hot water storage unit side communication means comprising a second receiver for converting the digital signal to
With
When an error occurs in communication between the fuel cell unit side communication means and the hot water storage unit side communication means, an error display means is based on output signals from the first signal detection means and the second signal detection means. A fuel cell system that displays error information and transmits abnormality information to a server outside the system using a general communication line. The first signal detecting means is a first light receiving means for detecting the light emitting state of the first light emitting means and the first light emitting means, and the second signal detecting means is the light emission of the second light emitting means and the second light emitting means. The fuel cell system according to claim 1, wherein the second light receiving means for detecting a state is used.