JP2008059813A - Fuel cell unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To carry out appropriate processing by effectively measuring temperature of a cell. <P>SOLUTION: A DMFC stack 42 has a plurality of MEA201 which are equivalent to cells stacked with a separator 202 in-between. A substrate 210 is attached to this DMFC stack 42. A contact 214 is provided on a bottom side of the substrate 210, and a plurality of elastic bodies with the plurality of separators 202 are provided as arranged to be facing each other. A circuit 212 is provided on a top side surface of the substrate 210 and voltage value is measured for each cell obtained through the contact 214. The substrate 210 is implemented with a thermistor 300. The thermistor 300 is implemented on the same surface that the contact 214 for the substrate 210 is implemented. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a direct methanol fuel cell unit, for example.

  There are various types of fuel cells, and a direct methanol fuel cell (DMFC) is suitable as an information processing apparatus. A cell stack in which a plurality of cells are stacked via separators is applied to this type of fuel cell. In the cell stack, when the balance of fuel supply is lost, the voltage of a specific cell may be lower than the voltages of other cells. In this case, if the power generation is continued, the cell may be destroyed. Therefore, it is necessary to devise an abnormal cell in advance so that the system does not fail. Furthermore, it is known that the output characteristics of the fuel cell are greatly influenced by the temperature of the cell, and it is important to detect the temperature of this cell stack efficiently.

As a technique for measuring the voltages of a plurality of cells constituting a cell stack, for example, Patent Document 1 can be cited. This document discloses that a measurement substrate having a plurality of voltage measurement terminals for press-contacting to the side surfaces of a plurality of separators using an elastic member is attached to a cell stack and the voltage of each cell is measured. .
JP 2006-107789 A

  However, the technique of the above document discloses that the voltage of each cell is efficiently measured, but does not disclose a specific attack on the temperature detection of the cell stack.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a fuel cell unit capable of efficiently detecting the temperature of a cell stack.

  A fuel cell unit according to the present invention includes a cell stack in which a plurality of cells are stacked via separators, and a substrate attached to the cell stack, and the substrate is a cell when the substrate is attached to the cell stack. A terminal having a plurality of elastic bodies arranged so as to be in contact with a plurality of separators in the stack; a resistance member whose resistance value varies depending on the temperature of the cell stack; and a plurality of terminals when the substrate is attached to the cell stack. And a circuit for measuring the temperature of the cell stack based on the obtained voltage value of each cell and the resistance value of the resistance member.

  According to the present invention, the temperature of the cell stack can be detected efficiently.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is an external view showing a fuel cell unit according to an embodiment of the present invention. As shown in FIG. 1, the fuel cell unit 10 includes an information processing apparatus, for example, a placement unit 11 for placing a rear part of a notebook personal computer, and a fuel cell unit body 12. The fuel cell unit main body 12 incorporates a DMFC stack that generates power by an electrochemical reaction, and auxiliary equipment (pumps, valves, etc.) for injecting and circulating methanol and air as fuel to the DMFC stack. .

  In addition, a removable fuel cartridge (not shown) is built in, for example, the left end of the unit case 12a of the fuel cell unit main body 12, and the cover 12b can be removed so that the fuel cartridge can be replaced. ing.

  An information processing apparatus is placed on the placement unit 11. A docking connector 14 is provided on the upper surface of the mounting portion 11 as a connection portion for connecting to the information processing apparatus. On the other hand, a docking connector 21 (not shown) is provided as a connecting portion for connecting to the fuel cell unit 10 at the bottom rear portion of the information processing apparatus, for example, and mechanically connected to the docking connector 14 of the fuel cell unit 10. Electrically connected. In addition, three positioning projections 15 and hooks 16 are provided on the mounting portion 11, and the positioning projections 15 and the hooks 16 are inserted into three holes in the rear portion of the bottom surface of the corresponding information processing apparatus. Is done.

  When removing the information processing apparatus from the fuel cell unit 10, the lock mechanism (not shown) is released by pushing the eject button 17 of the fuel cell unit 10 shown in FIG. Can do.

  In addition, a power generation setting switch 112 and a fuel cell operation switch 116 are provided on the right side of the fuel cell unit main body 12, for example.

  The power generation setting switch 112 is a switch for a user to set in advance in order to permit or prohibit power generation in the fuel cell unit 10, and is configured by, for example, a slide type switch.

  For example, when the information processing device 18 is operating with the power generated by the fuel cell unit 10, the fuel cell operation switch 116 stops only the power generation in the fuel cell unit 10 while the operation of the information processing device 18 continues. It is used for such cases. In this case, the information processing apparatus 18 continues to operate using the power of the built-in secondary battery. The fuel cell operation switch 116 is configured by, for example, a push switch.

  FIG. 2 is a diagram showing an external appearance when the information processing apparatus 18 (for example, a notebook personal computer) is placed on and connected to the placement unit 11 of the fuel cell unit 10.

  Various shapes are conceivable for the shape and size of the fuel cell unit 10 shown in FIGS. 1 and 2 or the shape and position of the docking connector 14.

  FIG. 3 shows a system diagram of the fuel cell unit 10, and particularly shows a detailed system of the DMFC stack and auxiliary equipment provided in the periphery thereof.

  The fuel cell unit 10 includes a power generation unit 40 and a fuel cell control unit 41 that is a control unit of the fuel cell unit 10. In addition to controlling the power generation unit 40, the fuel cell control unit 41 has a function as a communication control unit that communicates with the information processing device 18.

  The power generation unit 40 includes a DMFC stack 42 serving as a center for generating power, and a fuel cartridge 43 that stores methanol as a fuel. The fuel cartridge 43 is sealed with high-concentration methanol. The fuel cartridge 43 is detachable so that it can be easily replaced when the fuel is consumed.

  In general, in a direct methanol fuel cell, it is necessary to reduce the crossover phenomenon in order to increase power generation efficiency. For this purpose, it is effective to dilute high-concentration methanol to lower the concentration and inject it into the fuel electrode 47. In order to realize this, the fuel cell unit 10 employs a dilution circulation system 62, and an auxiliary device 63 necessary for realizing the dilution circulation system 62 is provided in the power generation unit 40.

  There are auxiliary machines 63 provided in the liquid flow path and those provided in the gas flow path.

  The auxiliary machine 63 provided in the liquid flow path is connected to the fuel supply pump 44 by piping from the output part of the fuel cell cartridge 43 and further connected to the mixing tank 45 from the output part of the fuel supply pump 44. Further, the output portion of the mixing tank 45 is connected to the liquid feed pump 46, and the output portion of the liquid feed pump 46 is connected to the fuel electrode 47 of the DMFC stack 42. The output portion of the fuel electrode 47 is connected to the mixing tank 45 by piping. The output portion of the water recovery tank 55 is connected to a water recovery pump 56 by piping, and the water recovery pump 56 is connected to the mixing tank 45.

  On the other hand, in the gas flow path, the air pump 50 is connected to the air electrode 52 of the DMFC stack 42 via the air valve 51. The output part of the air electrode 52 is connected to the condenser 53. The mixing tank 45 is also connected to the condenser 53 via the mixing tank valve 48. The condenser 53 is connected to an exhaust port 58 via an exhaust valve 57. The condenser 53 is provided with fins that effectively condense water vapor. The cooling fan 54 is disposed in the vicinity of the condenser 53.

  Next, the power generation mechanism of the power generation unit 40 of the fuel cell unit 10 will be described along the flow of fuel and air (oxygen).

  First, the high-concentration methanol in the fuel cartridge 43 flows into the mixing tank 45 by the fuel supply pump 44. Inside the mixing tank 45, the high-concentration methanol is mixed with diluted water, low-concentration methanol (remaining power generation reaction) from the fuel electrode 47, and the like, and diluted to produce low-concentration methanol. The concentration of the low-concentration methanol is controlled so as to maintain a high concentration (for example, 3 to 6%) with high power generation efficiency. This concentration control is realized, for example, by controlling the amount of high concentration methanol supplied to the mixing tank 45 by the fuel supply pump 44 based on the detection result of the concentration sensor 60. Alternatively, it can be realized by controlling the amount of water circulating in the mixing tank 45 by the water recovery pump 56 or the like.

  Further, the mixing tank 45 is provided with a liquid amount sensor 61 for detecting the amount of the methanol aqueous solution in the mixing tank 45 and a temperature sensor 64 for detecting the temperature, and these detection results are based on the fuel cell control unit 41. To be used for controlling the power generation unit 40 and the like.

  The methanol aqueous solution diluted in the mixing tank 45 is pressurized by the liquid feed pump 46 and injected into the fuel electrode (negative electrode) 47 of the DMFC stack 42. In the fuel electrode 47, electrons are generated by the oxidation reaction of methanol. Hydrogen ions (H +) generated by the oxidation reaction pass through the solid polymer electrolyte membrane 422 in the DMFC stack 42 and reach the air electrode (positive electrode) 52.

  On the other hand, the carbon dioxide produced by the oxidation reaction performed at the fuel electrode 47 is recirculated to the mixing tank 45 together with the methanol aqueous solution not subjected to the reaction. The carbon dioxide is vaporized in the mixing tank 45, travels to the condenser 53 through the mixing tank valve 48, and is finally exhausted to the outside through the exhaust valve 57 through the exhaust valve 57.

  On the other hand, the flow of air (oxygen) is taken from the intake port 49, pressurized by the air supply pump 50, and injected into the air electrode (positive electrode) 52 through the air supply valve 51. At the air electrode 52, the reduction reaction of oxygen (O2) proceeds, electrons (e−) from an external load, hydrogen ions (H +) from the fuel electrode 47, and oxygen (O2) to water (H2O). Is produced as water vapor. This water vapor is discharged from the air electrode 52 and enters the condenser 53. In the condenser 53, the water vapor is cooled by the cooling fan 54 to become water (liquid), and is temporarily accumulated in the water recovery tank 55. The recovered water is circulated to the mixing tank 45 by the water recovery pump 56 to constitute a dilution circulation system 62 for diluting the high-concentration methanol.

  As can be seen from the power generation mechanism of the fuel cell unit 10 by the dilution circulation system 62, in order to extract power from the DMFC stack 42, that is, to start power generation, the pumps 44, 46, 50, 56 and valves 48, 51 of each part are started. , 57 or the auxiliary machine 63 such as the cooling fan 54 is driven. As a result, an aqueous methanol solution and air (oxygen) are injected into the DMFC stack 42, and an electrochemical reaction proceeds there to generate electric power. On the other hand, to stop the power generation, the driving of these auxiliary machines 63 is stopped.

  FIG. 4 shows a system configuration of the information processing apparatus 18 to which the fuel cell unit 10 according to the present invention is connected.

  The information processing apparatus 18 includes a CPU 65, a main memory 66, a display controller 67, a display 68, an HDD (Hard Disk Drive) 69, a keyboard controller 70, a pointer device 71, a keyboard 72, an FDD 73, and a bus for transmitting signals between these components. 74, a device called a north bridge 75 for converting a signal transmitted through the bus 74, a device called a south bridge 76, and the like. In addition, a power supply unit 79 is provided inside the information processing apparatus 18, and a lithium ion battery, for example, is held as the secondary battery 80 therein. The power supply unit 79 is controlled by a control unit 77 (hereinafter referred to as a power supply control unit 77).

  As an electrical interface between the fuel cell unit 10 and the information processing apparatus 18, a control system interface and a power system interface are provided. The control system interface is an interface provided for communication between the power supply control unit 77 of the information processing apparatus 18 and the control unit 41 of the fuel cell unit 10. Communication performed between the information processing apparatus 18 and the fuel cell unit 10 via the control system interface is performed via a serial bus such as an I2C bus 78, for example.

  The power supply system interface is an interface provided for power transfer between the fuel cell unit 10 and the information processing device 18. For example, the power generated by the DMFC stack 42 of the power generation unit 40 is supplied to the information processing apparatus 18 via the control unit 41 (hereinafter referred to as the fuel cell control unit 41) and the docking connectors 14 and 21. The power supply system interface also includes a power supply 83 from the power supply unit 79 of the information processing apparatus 18 to the auxiliary machine 63 and the like in the fuel cell unit 10.

  Note that a DC power source that is AC / DC converted is supplied to the power source unit 79 of the information processing device 18 via the AC adapter connector 81, whereby the operation of the information processing device 18, the secondary battery (lithium ion battery). 80 charging is possible.

  FIG. 5 is a configuration example showing a connection relationship between the fuel cell control unit 41 of the fuel cell unit 10 and the power supply unit 79 of the information processing apparatus 18.

  The fuel cell unit 10 and the information processing apparatus 18 are mechanically and electrically connected by docking connectors 14 and 21. From the first power supply terminal (output power supply terminal) 91 for supplying the power generated by the DMFC stack 42 of the fuel cell unit 10 to the information processing device 18 and the information processing device 18, A second power supply terminal (auxiliary input power supply terminal) for supplying power to the microcomputer 95 of the fuel cell unit 10 via the regulator 94 and supplying power to the auxiliary power supply circuit 97 via the switch 101 ) 92. Further, a third power supply terminal 92 a for supplying power from the information processing device 18 to the EEPROM 99 is provided.

  Further, the docking connectors 14 and 21 are communication for performing communication between the power control unit 77 of the information processing device 18 and the microcomputer 95 of the fuel cell unit 10 and communication with a writable nonvolatile memory (EEPROM) 99. The input / output terminal 93 is provided.

  Next, using the connection diagram shown in FIG. 5 and the state transition diagram of the fuel cell unit 10 shown in FIG. 6, the DMFC stack provided in the fuel cell unit 10 from the fuel cell unit 10 to the information processing device 18. A basic processing flow until 42 power is supplied will be described.

  It is assumed that the secondary battery (lithium ion battery) 80 of the information processing apparatus 18 is charged with predetermined power. Also assume that all the switches in FIG. 5 are open.

  First, the information processing apparatus 18 recognizes that the information processing apparatus 18 and the fuel cell unit 10 are mechanically and electrically connected based on a signal output from the connector connection detection unit 111. This recognition is performed by detecting that the connector connection detection unit 111 is grounded inside the fuel cell unit 10 by the connection of the docking connectors 14 and 21 based on a signal input to the connector connection detection unit 111, for example. Is called.

  Further, the power control unit 77 of the information processing apparatus 18 recognizes whether the setting of the power generation setting switch 112 of the fuel cell unit 10 is a power generation permission setting or a power generation prohibition setting. For example, based on a signal input to the power generation setting switch detection unit 113, the power generation setting switch detection unit 113 detects whether the power generation setting switch 112 is in a grounded state or a released state according to the setting state of the power generation setting switch 112. . When the power generation setting switch 112 is in the released state, the power control unit 77 recognizes the power generation prohibition setting.

  The state in which the power generation setting switch 112 is in the power generation prohibition setting is a state corresponding to “stop state (0)” ST10 in the state transition diagram of FIG.

  When the information processing device 18 and the fuel cell unit 10 are mechanically connected via the docking connectors 14 and 21, the storage unit of the fuel cell control unit 41 is connected from the information processing device 18 side via the third power supply terminal 92a. The non-volatile memory (EEPROM) 99 is supplied with power. In the EEPROM 99, identification information of the fuel cell unit 10 and the like are stored in advance. For example, information such as a part code, a manufacturing serial number, or a rated output of the fuel cell unit can be included in the identification information. The EEPROM 99 is connected to a serial bus such as an I2C bus 93, for example, and data stored in the EEPROM 99 can be read while power is supplied to the EEPROM 99. In the configuration of FIG. 5, the power supply control unit 77 can read information from the EEPROM 99 via the communication input / output terminal 93.

  In this state, the fuel cell unit 10 is not generating power, and the internal state of the fuel cell unit 10 is a state in which no power is supplied except for the power source of the EEPROM 99.

  Here, when the user sets the power generation setting switch 112 to the power generation permission setting (in FIG. 5, the power generation setting switch is set to the ground state side), the power control unit 77 provided in the information processing apparatus 18 Thus, the identification information stored in the EEPROM 99 provided in 10 can be read out. This state is the state of “stop state (1)” ST11 in FIG.

  In other words, unless the user sets the power generation setting switch 112 to the power generation permission setting, that is, as long as the power generation prohibition setting is set, the state is the “stop state (0)” ST10 and power generation in the fuel cell unit 10 is prohibited. It is possible.

  The power generation setting switch is preferably a switch that can maintain the open or closed state in one of the states, such as a slide switch.

  Reading of the identification information by the power supply control unit 77 is performed by reading the identification information of the fuel cell unit 10 stored in the EEPROM 99 provided in the fuel cell unit 10 via a serial bus such as the I 2 C bus 78.

  When the power supply control unit 77 determines that the fuel cell unit 10 connected to the information processing device 18 is a fuel cell unit suitable for the information processing device 18 based on the read identification information, the state of FIG. Transit from “stop state (1)” ST11 to “standby state” ST20.

  Specifically, the power supply control unit 77 provided in the information processing device 18 closes the switch 100 provided in the information processing device 18, thereby supplying the electric power of the secondary battery 80 via the first power supply terminal 92 to the fuel cell. Power is supplied to the unit 10, and power is supplied to the microcomputer 95 via the regulator 94.

  In the “standby state” ST20, the switch 101 provided in the fuel cell unit 10 is open, and power is not supplied to the auxiliary power supply circuit 97. Accordingly, the auxiliary machine 63 is not operating in this state.

  However, the microcomputer 95 has started its operation and is in a state where various control commands can be received via the I 2 C bus 78 from the power supply control unit 77 provided in the information processing apparatus 18. Further, the microcomputer 95 is in a state where the power supply information of the fuel cell unit 10 can be transmitted to the information processing apparatus 18 via the I2C bus.

  FIG. 7 is a diagram illustrating an example of a control command sent from the power supply control unit 77 provided in the information processing apparatus 18 to the microcomputer 95 provided in the fuel cell control unit 41.

  FIG. 8 is a diagram showing an example of power supply information sent from the microcomputer 95 provided in the fuel cell control unit 41 to the power supply control unit 77 provided in the information processing apparatus 18.

  The power supply control unit 77 provided in the information processing device 18 reads the “DMFC operation state” (number 1 in FIG. 8) in the power supply information in FIG. 8, thereby confirming that the fuel cell unit 10 is in the “standby state” ST20. recognize.

  When the power supply control unit 77 sends a “DMFC operation ON request” command (power generation start command) to the fuel cell control unit 41 among the control commands shown in FIG. 7 in the “standby state” ST20 state, The received fuel cell control unit 41 shifts the state of the fuel cell unit 10 to the “warm-up state” ST30.

  Specifically, the switch 101 provided in the fuel cell control unit 41 is closed under the control of the microcomputer 95 to supply power from the information processing device 18 to the auxiliary power supply circuit 97. In addition, the auxiliary machine 63 provided in the power generation unit 40 by the auxiliary machine control signal transmitted from the microcomputer 95, that is, the pumps 44, 46, 50, 56 and valves 48, 51, 57 shown in FIG. Then, the cooling fan 54 and the like are driven. Further, the microcomputer 95 closes the switch 102 provided in the fuel cell control unit 41.

  As a result, a methanol aqueous solution or air is injected into the DMFC stack 42 provided in the power generation unit 40, and power generation is started. Further, the power generated by the DMFC stack 42 is started to be supplied to the information processing apparatus 18. However, since the power generation output does not instantaneously reach the rated value, the state until the rated value is reached is called “warm-up state” ST30.

  The microcomputer 95 provided in the fuel cell control unit 41 monitors the output voltage of the DMFC stack 42 and the temperature of the DMFC stack 42 by a measurement board 210 to be described later attached to the DMFC stack 42, so that the output of the DMFC stack 42 is rated. When it is determined that the value has been reached, the switch 101 provided in the fuel cell unit 10 is opened, and the power supply source to the auxiliary machine 63 is switched from the information processing device 18 to the DMFC stack 42. This state is the “on state” ST40.

  The above is the outline of the processing flow from the “stop state” ST10 to the “on state” ST40.

  Hereinafter, a method for effectively measuring the voltage of each cell in the DMFC stack 42 (see FIG. 5) and performing appropriate processing will be described.

  When the fuel supply is balanced, the output of each cell in the DMFC stack 42 is also equal. However, if the balance of fuel supply is disrupted for some reason, the output balance of each cell may also be disrupted. In addition, the output balance of each cell may be lost due to factors such as temperature distribution.

  FIG. 9 is a diagram showing the current-voltage characteristics of the cell when the fuel supply is reduced.

  Comparing the case where the fuel supply is reduced and the case where the fuel supply is not generated, it can be seen that the output current value is reduced when the fuel supply is reduced. That is, the output power is reduced. In the case of a stack structure in which cells are connected in series, the current value of each cell constituting the stack is the same. However, when the output balance is lost, the output voltage value is different for each cell. At this time, the efficiency of the cell whose output has dropped decreases and the heat generation also increases. Although the load on other cells is lightened in some cases, the efficiency of the entire stack is reduced and heat generation is increased. Furthermore, when power generation is continued in a low output state, the cell may be destroyed due to inversion. The failed cell cannot generate electricity and enters a high resistance state. For this reason, the output of the stack does not increase, and in the worst case, the stack may become unusable.

  In the present embodiment, such a problem can be prevented beforehand by the method described below.

  A plurality of cells in the DMFC stack 42 are connected in series. When the balance of fuel supply is kept constant, the voltage of each cell becomes the same as shown in FIG. 10, and power can be supplied efficiently. On the other hand, if the balance of fuel supply is greatly disrupted, the voltage of a specific cell may decrease as shown in FIG. 11, and if power generation is continued in this case, the efficiency of power supply deteriorates and the amount of heat generation increases, Eventually, the cell may be destroyed.

  In order to prevent this from happening, it is preferable to detect the occurrence of a low-voltage cell and perform appropriate control based on the detected content.

  FIG. 12 is a top view of the DMCF stack 42 to which the measurement substrate is attached. FIG. 13 is a side view of the DMCF stack 42 to which the measurement substrate is attached. FIG. 14 is a perspective view showing the back surface of the measurement substrate 210 on which the contacts 202 are mounted. FIG. 15 is a side view of the contact 202 shown in FIG. 14 viewed from the side.

  The DMFC stack 42 has a laminated structure of an MEA (Membrane Electrode Assembly) 201 as a power generation unit corresponding to a cell and a separator 202 serving as a fuel flow path. End plates 203 are joined to both ends of the laminated structure.

  A measurement substrate (substrate unit) 210 is attached to the upper part of the DMFC stack 42. The measurement substrate 210 is fixed to the end plate 203 through the opening 210 </ b> A by a mounting screw 211.

  A plurality of contacts 214 arranged to face the plurality of separators 202 are mounted on the lower surface of the measurement substrate 210 (the surface facing the DMFC stack 42). The plurality of contacts 214 are terminals for electrical connection with the plurality of separators 202, and are in pressure contact with the opposing separators 202, respectively.

  Similarly, the thermistor 300 is mounted on the lower surface of the measurement substrate 210 (the surface facing the DMFC stack 42). The thermistor 300 is a resistance member whose resistance value changes depending on the temperature of the DMFC stack 42.

  A circuit 212 and a connector 213 made of LSI or the like are mounted on the upper surface of the measurement substrate 210. The circuit 212 measures the voltage value of each cell obtained through the plurality of contacts 214, and also measures the temperature of the DMFC stack 42 based on the resistance value of the thermistor 300, and the fuel cell control unit 10 side shown in FIG. A process of generating data (measured temperature value, output voltage value) to be notified to the microcomputer 95 is performed. The connector 213 connects a signal line for transmitting and receiving signals between the measurement board 210 and the microcomputer 95.

  As shown in FIGS. 14 and 15, the plurality of contacts 202 are, for example, shield finger type contacts. The shield finger type contact 214 includes an elastic body portion 214A that is pressed against the separator 202 and a fixed portion that is grounded to the substrate. The elastic body portion 214A is a portion that is pressed against the separator 202. In addition, each connector 214 is electrically connected to the above-described circuit 212 through wiring 215 on the substrate. Similarly, the thermistor 300 is electrically connected to the circuit 212 via the wiring 301.

  As shown in FIG. 13, the thermistor 300 is thermally connected to a separator 202 located in the center among a plurality of separators 202 via a heat transfer member such as grease or a heat transfer sheet. Since the temperature of the plurality of cells constituting the DMFC stack 42 is substantially the same temperature, it is of course possible to electrically connect to a separator 202 other than the separator 202 located in the center. Although the thermistor 300 may measure the temperature of the separator 202 through the gap even without the heat transfer member 301, it is preferable to detect the temperature of the DMFC stack 42 through the heat transfer member 301 as accurately as possible. Temperature can be detected.

  Further, when a failure occurs in the circuit 212 or the like mounted on the measurement board 210, there is an advantage that only the measurement board 210 needs to be replaced. The substrate can be easily replaced by simply removing the mounting screw 211.

  In addition, since the circuit 212 on the measurement substrate 210 is mounted on a surface different from the surface on which the contact 214 is mounted, wiring can be reduced, the circuit configuration can be simplified, The difficulty is reduced. In addition, it is easy to perform inspections and maintenance.

  Further, since a small space on the DMFC stack 42 is effectively used for the arrangement of the measurement substrate 210, it can be said that an extremely compact configuration is realized.

  Next, the voltage monitoring operation will be described with reference to the flowchart of FIG.

  First, the power generation operation by the DMFC stack 42 is started in a no-load state (step S1). Thereby, the state of the fuel cell unit 10 is changed from, for example, “stop state (0)” ST10 described in FIG. 6 to “stop state (1)” ST11, “standby state” ST20, “warm-up state” ST30, Transition to “on-state” ST40 sequentially.

  The microcomputer 95 (see FIG. 5) obtains the voltage value of the DMFC stack 42 and determines whether or not the voltage value is equal to or greater than a specified value (step S2). Here, when the voltage value of the DMFC stack 42 is less than the specified value, it is regarded as abnormal, and the power generation operation by the DMFC stack 42 is stopped (step S3). At this time, the state of the fuel cell unit 10 transitions to, for example, “stop state (0)” ST10. On the other hand, when the voltage value of the DMFC stack 42 is equal to or higher than the specified value, it is regarded as normal, and the microcomputer 95 starts voltage monitoring of each cell using the measurement substrate 210 (step S4).

  The microcomputer 95 performs OCV monitoring through the circuit 212 on the measurement board 210, and determines whether or not each cell in the no-load state is equal to or greater than a specified value (step S5). Here, if there is a cell whose voltage value is less than the specified value, it is regarded as abnormal, and the power generation operation by the DMFC stack 42 is stopped (step S3). At this time, the state of the fuel cell unit 10 transitions to, for example, “stop state (0)” ST10. On the other hand, when the voltage value of the DMFC stack 42 is equal to or higher than the specified value, it is regarded as normal, and the microcomputer 95 starts voltage monitoring of each cell in a state where the load is electrically connected (step S6).

  Here, if all the cells are equal to or greater than the specified value, power generation is continued (step S8). On the other hand, when there is a cell whose voltage value is less than the specified value, the load is electrically disconnected (step S9).

  After disconnecting the load, the microcomputer 95 determines how many times the voltage value has become less than the specified value in voltage monitoring (hereinafter referred to as NG times) (step S10). If the number of NG is less than the specified number, in order to restore the corresponding cell to normal, for example, refresh processing is performed such as refreshing with a flow rate higher than normal in a no-load state (step S11). At this time, the state of the fuel cell unit 10 transitions to, for example, the “refresh state” ST60. After completing the refresh process, the process proceeds to step S5. At this time, the state of the fuel cell unit 10 transitions to, for example, “on state” ST40. On the other hand, when the number of NG times is equal to or greater than the specified number, it is regarded as abnormal and the power generation operation by the DMFC stack 42 is stopped (step S3). At this time, the state of the fuel cell unit 10 transitions to, for example, “stop state (0)” ST10.

  Next, the temperature monitoring operation will be described with reference to the flowchart of FIG. Specifically, the operation of determining that the output of the DMFC stack has reached the rated value by monitoring the temperature of the DMFC stack 42 and shifting from the “warm-up state” to the “on state” will be described.

  First, the power generation operation by the DMFC stack 42 is started in a no-load state. Thereby, the state of the fuel cell unit 10 is changed from, for example, “stop state (0)” ST10 described in FIG. 6 to “stop state (1)” ST11, “standby state” ST20, “warm-up state” ST30. Transition sequentially. (Step S21)

  The microcomputer 95 obtains the temperature of the DMFC stack 42 and determines whether the temperature is equal to or higher than a specified value. (Step S22)

  Here, when the temperature of the DMFC stack 42 is lower than the specified value, it is determined that the output of the DMFC stack 42 has not reached the rated value. Further, it is determined whether the elapsed time from the start of power generation is equal to or greater than a specified value. If the elapsed time is less than the specified value, the temperature of the DMFC stack 42 is continuously monitored (step S23). Stop power generation in the DMFC stack. (Step S24)

  On the other hand, when the temperature of the DMFC stack 42 is equal to or higher than the specified value, it is determined that the output of the DMFC stack 42 has reached the rated value, the switch provided in the fuel cell unit 10 is opened, and the power supply source to the auxiliary machine 63 is determined. The processing apparatus 18 is switched to the DMFC stack 42 and shifts to the “on state”. (Step S25)

  According to such an operation, when an abnormality occurs in the cell, the fact can be reliably detected through the measurement substrate 210, and the microcomputer 95 performs appropriate processing (power generation stoppage and return processing). Problems such as cell destruction can be prevented in advance.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

1 is an external view showing a fuel cell unit according to an embodiment of the present invention. The external view which shows the state which connected the information processing apparatus to the said fuel cell unit. The system diagram which mainly shows the structure of the electric power generation part of the said fuel cell unit. The system diagram which shows the state which connected the said information processing apparatus to the said fuel cell unit. The system diagram which shows the structure of the said fuel cell unit and the said information processing apparatus. The state transition diagram of the fuel cell unit and the information processing apparatus. The figure which shows the main commands for control with respect to the said fuel cell unit. The figure which shows the main power supply information of the said fuel cell unit. The figure which shows the electric current-voltage characteristic of a cell when fuel supply reduces. The figure for demonstrating the case where the balance of each cell in the serial structure and voltage balance of a cell of a fuel cell is perfect. The figure for demonstrating the case where the balance of the specific cell in the serial structure and voltage balance of a cell of a fuel cell is extremely bad. The figure which looked at the DMCF stack with which the measurement board | substrate was attached from the top. The figure which looked at the DMCF stack with which the measurement board | substrate was attached from the side. The perspective view which shows the back surface of the measurement board | substrate with which a contact is mounted. The side view which shows an example of the contact mounted in the back surface of a measurement board | substrate. The flowchart which shows the operation | movement of voltage monitoring. The flowchart which shows operation | movement of temperature monitoring.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Fuel cell unit, 11 ... Mounting part, 12 ... Fuel cell unit main body, 14 ... Docking connector, 40 ... Power generation part, 41 ... Fuel cell control part, 42 ... DMFC stack, 43 ... Fuel cartridge, 44 ... Fuel supply Pump, 45 ... mixing tank, 46 ... liquid feeding pump, 47 ... fuel electrode (negative electrode), 48 ... mixing tank valve, 50 ... air feeding pump, 51 ... air feeding pump, 52 ... air electrode (positive electrode), 53 ... condensation 54 ... Cooling fan, 55 ... Water recovery tank, 56 ... Water recovery pump, 57 ... Exhaust valve, 58 ... Exhaust port, 60 ... Concentration sensor, 61 ... Liquid quantity sensor, 62 ... Dilution circulation system, 63 ... Auxiliary machine , 64 ... Temperature sensor, 201 ... MEA, 202 ... Separator, 203 ... End plate, 210 ... Voltage monitoring base, 211 ... Mounting screw, 212 ... Circuit, 213 ... Connector 214, 216 ... contact, 300 ... thermistor.

Claims (5)

A cell stack in which a plurality of cells are stacked via separators, and
A substrate attached to the cell stack,
The substrate is
A terminal having a plurality of elastic bodies arranged so as to come into contact with the plurality of separators in the cell stack when the substrate is attached to the cell stack;
A resistance member whose resistance value varies depending on the temperature of the cell stack;
A circuit for measuring a temperature of the cell stack based on a voltage value of each cell obtained through the plurality of terminals and a resistance value of the resistance member when the substrate is attached to the cell stack. Fuel cell unit. The terminal and the resistance member are provided on a first surface of the substrate,
The fuel cell unit according to claim 1, wherein the circuit is provided on a second surface different from the first surface of the substrate.   The fuel cell unit according to claim 1, wherein the resistance member is thermally connected to at least one of the plurality of cells.   The fuel cell unit according to claim 1, wherein the resistance member is thermally connected to a cell located substantially in the center of the plurality of cells. The fuel cell unit according to claim 3 or 4, wherein the resistance member is thermally connected to the cell via a heat transfer member.

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