JPWO2007148628A1 - Electronics - Google Patents

Abstract

The PDA body 1 having the fuel cell unit 5 and the power source unit having the auxiliary power source 7 charged by the output of the fuel cell unit 5 is repeatedly operated by the power key 301 of the input unit 3. At least one stop of the output and the output of the power supply unit to the PDA main body 1 can be selected.

Description

  The present invention relates to an electronic device using a fuel cell as a power source.

  There have been remarkable miniaturizations of electronic devices such as portable audio devices and personal digital assistants (PDAs), and attempts have been made to use fuel cells as power sources along with the miniaturization of these electronic devices. A fuel cell has the advantage that it can generate electricity simply by supplying fuel and an oxidant, and can continuously generate electricity if only the fuel is replaced. Therefore, if miniaturization can be realized, it can be used as a power source for small electronic devices. It is extremely effective.

  Therefore, a direct methanol fuel cell (hereinafter referred to as DMFC) is recently attracting attention as a fuel cell. The DMFC has an electrolyte membrane disposed between an anode electrode and a cathode electrode, and both the anode electrode and the cathode electrode include a current collector and a catalyst layer. An aqueous methanol solution is supplied to the anode electrode as a fuel, and protons (protons) are generated by a catalytic reaction. On the other hand, air is supplied to the cathode electrode (air electrode) from the air intake port. At the cathode electrode, power is generated by protons that have passed through the electrolyte membrane reacting with oxygen contained in the supplied air on the catalyst. In this way, DMFC uses methanol with high energy density as fuel, and can extract current directly from methanol on the electrocatalyst and does not require reforming, so it can be miniaturized, and the handling of fuel compared to hydrogen gas It is promising as a power source for portable electronic devices because of its simplicity.

  On the other hand, in such an electronic device using a fuel cell as a power source, a secondary battery is used as an auxiliary power source for supplying auxiliary power to compensate for a shortage of power output from the fuel cell. This secondary battery is always charged with electric power output from the fuel cell.

  Such a fuel cell is disclosed in, for example, Japanese Patent Application Laid-Open No. 2000-106201, and a fuel cell system disclosed in International Publication No. WO2005 / 043664 is disclosed as a fuel cell system capable of supplying electric power to an electronic device. is there.

  By the way, in many cases, such electronic devices are not used for a long time compared to the time they are actually used. However, even in the state where the electronic device is not used, that is, the state where the load side is not operating at all, the fuel cell continuously supplies fuel and generates an output. For this reason, the secondary battery is charged by the fuel cell in a state where no electronic device is used. That is, the secondary battery is continuously charged by the fuel cell in a very small load where the electronic device is not used. Therefore, the secondary battery is fully charged or close to it for a long time, which causes a problem that the secondary battery is deteriorated.

  An object of the present invention is to provide an electronic device in which a fuel cell is used as a power source capable of stopping power output due to non-use of the device.

  According to the present invention, the electronic device main body, the power generation unit having the fuel cell unit, the auxiliary power source charged by the output of the power generation unit, the power supply unit for supplying power to the electronic device main body, the operation unit, There is provided an electronic device including a control unit that selectively enables the output of the power generation unit to be stopped and the output of the power supply unit to the electronic device main body to be selectively stopped by the operation of the operation unit.

  In the above-described invention, the control unit can select at least one stop of the output of the power generation unit and the output of the power supply unit to the electronic device main body by repeated operation of the operation unit.

  In the above-described invention, the control unit can determine whether or not to stop the output of the power generation unit when the output of the power supply unit to the electronic device main body is stopped based on preset contents.

  In the above-described invention, the electronic device main body further includes a non-use detection unit that detects a non-use state of the electronic device body, and the control unit stops the output of the power generation unit due to non-use detection of the non-use detection unit. .

  In the above-described invention, an external interface can be attached to the electronic device body, and the control unit can stop the output of the power generation unit when the external interface is attached.

  In the above-described invention, the operation unit includes a power key and a specific key, and the control unit makes it possible to determine whether output of the power generation unit can be stopped in a state where the specific key and the power key are operated simultaneously. ing.

  In the above-described invention, the operation unit includes a numeric keypad and a specific key, and the control unit displays various menus correlated with the position of the numeric keypad on the display unit, and the specific key and the numeric keypad are operated simultaneously. In this state, a menu for determining whether or not to stop the output of the power generation unit can be selected corresponding to the numeric keypad.

  In the above-described invention, the operation unit has a specific key, and the control unit enables selection of an index corresponding to various menus displayed on the display unit by operating the specific key. Thus, a menu for determining whether output of the power generation unit can be stopped can be selected.

  In the above-described invention, the specific key can be used for other settings than the determination of whether or not the power generation unit can stop the output.

FIG. 1 is a block diagram showing a schematic configuration of an electronic apparatus according to an embodiment of the present invention. FIG. 2 is a block diagram showing a schematic configuration of a fuel cell system incorporated in the electronic apparatus shown in FIG. FIG. 3 is an operation explanatory diagram showing transition of the operation state of the electronic device for explaining an example of the operation in the electronic device shown in FIG. FIG. 4 is an operation explanatory diagram showing transition of the operation state of the electronic device for explaining the first modification example 1 of the operation shown in FIG. FIG. 5 is an operation explanatory diagram showing transition of the operation state of the electronic device for explaining a second modification 2 of the operation shown in FIG. FIG. 6 is an operation explanatory diagram illustrating transition of the operation state of the electronic device for explaining a third modification 3 of the operation illustrated in FIG. 3. FIG. 7 is an operation explanatory diagram illustrating transition of the operation state of the electronic device for explaining a fourth modification 4 of the operation illustrated in FIG. 3. FIG. 8A is a flowchart showing a detailed operation of the fourth modification shown in FIG. FIG. 8B is a flowchart showing a detailed operation of the fourth modification shown in FIG. FIG. 9 is an operation explanatory diagram showing transition of the operation state of the electronic device for explaining a fifth modification 5 of the operation shown in FIG. FIG. 10 is a flowchart showing a detailed operation of the fourth modification shown in FIG. FIG. 11 is an operation explanatory diagram illustrating transition of the operation state of the electronic device for explaining a sixth modified example 6 of the operation illustrated in FIG. 3. FIG. 12 is a flowchart showing a detailed operation of the sixth modification shown in FIG. FIG. 13A is an explanatory diagram illustrating a display example on the display unit in Modification 6 illustrated in FIG. 11. FIG. 13B is an explanatory diagram illustrating a display example on the display unit in the modified example 6 illustrated in FIG. 11. FIG. 13C is an explanatory diagram illustrating a display example on the display unit in the modified example 6 illustrated in FIG. 11. FIG. 14 is an operation explanatory diagram showing transition of the operation state of the electronic device for explaining an eighth modification 8 of the operation shown in FIG.

  Hereinafter, electronic devices according to embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 shows a schematic configuration of an electronic apparatus according to the first embodiment of the present invention. Note that FIG. 1 shows an example of a portable information terminal (hereinafter referred to as a PDA) as an electronic device.

  In FIG. 1, reference numeral 1 denotes a PDA body, to which a control unit 2 and a display unit 4 are connected. An input unit 3 is connected to the control unit 2 as an operation unit. A liquid crystal display or the like is used for the display unit 4.

  The control unit 2 controls the PDA main body 1 in accordance with data input from the input unit 3. For example, in addition to personal information management functions such as schedule management and reservation management, an electronic dictionary and an Internet connection function Various functions can be realized. The input unit 3 is provided with various keys such as a power key 301, a numeric keypad 302, and a help key 303 as a specific key.

  The control unit 2 has a switch control unit 201. The switch control unit 201 controls on / off of a power generation control switch 41 and a power switch 42 which will be described later according to a program prepared in advance by operating the power key 301 and the help key 303 of the input unit 3. Here, a program for executing each operation described later is prepared.

  In such a power supply chamber (not shown) of the PDA, a fuel cell system 10 is provided as a power supply unit. FIG. 2 shows a schematic configuration of the fuel cell system 10, in which a DMFC unit 5, a control unit 6, an auxiliary power source 7, a liquid fuel tank 8 and an output terminal 9 are provided as fuel cell units.

  The DMFC unit 5 includes a plurality of power generation cells 5a and 5b described later. These power generation cells 5a and 5b are disposed between a cathode electrode composed of a cathode catalyst layer and a cathode gas diffusion layer, an anode electrode composed of an anode catalyst layer and an anode gas diffusion layer, and a cathode catalyst layer and an anode catalyst layer, respectively. A membrane electrode assembly (MEA) having a proton conductive electrolyte membrane is provided. A methanol aqueous solution is supplied to the anode electrode as a fuel, and protons (protons) are generated by a catalytic reaction. On the other hand, air is supplied to the cathode electrode (air electrode) from the air intake port. At the cathode electrode, power is generated by protons that have passed through the electrolyte membrane reacting with oxygen contained in the supplied air on the catalyst. The DMFC unit 5 used here is a passive type unit that supplies both fuel and air using convection, concentration gradient, and the like.

  The liquid fuel tank 8 is filled with pure methanol or an aqueous methanol solution as fuel. This fuel is supplied to the DMFC unit 5 through a supply path (not shown). The liquid fuel tank 8 is provided with an inlet 8a. A fuel cartridge 11 is detachably attached to the injection port 8a, and fuel is injected from the fuel cartridge 11 into the liquid fuel tank 8.

  The liquid fuel stored in the liquid fuel tank 8 is not necessarily limited to methanol fuel. For example, ethanol fuel such as ethanol aqueous solution or pure ethanol, propanol fuel such as propanol aqueous solution or pure propanol, aqueous glycol solution or pure glycol can be used. It may be glycol fuel, dimethyl ether, formic acid, or other liquid fuel. In any case, liquid fuel corresponding to the fuel cell is accommodated.

  In the above description, the structure of the DMFC unit 5 has been described with the structure having the liquid fuel tank 8 as the liquid storage section below the membrane electrode assembly (MEA), but the fuel storage section is configured as a separate body. The membrane electrode assembly may be connected via a flow path and supplied with fuel.

  Further, although the passive type fuel cell has been described as an example of the configuration of the fuel cell main body, the present invention is also applied to a semi-passive type fuel cell in which a pump or the like is partially used for fuel supply or the like. Can be applied. In the semi-passive type fuel cell, the fuel supplied from the fuel storage unit to the MEA is used for a power generation reaction and is not circulated thereafter and returned to the fuel storage unit. The semi-passive type fuel cell is different from the conventional active method because it does not circulate the fuel, and does not impair the downsizing of the device. In addition, the fuel cell uses a pump for supplying fuel, and is different from a pure passive system such as a conventional internal vaporization type. For this reason, the fuel cell is referred to as a semi-passive method as described above. In this semi-passive type fuel cell, a fuel cutoff valve may be arranged in place of the pump as long as fuel is supplied from the fuel storage portion to the MEA. In this configuration, the fuel cutoff valve is provided to control the supply of liquid fuel through the flow path.

  In addition, the liquid fuel vapor supplied to the MEA may be all supplied as a liquid fuel vapor, but the present invention can be applied even when a part of the liquid fuel vapor is supplied in a liquid state.

  The control unit 6 includes a control circuit as described below.

  The DMFC unit 5 includes a plurality of power generation cells 5a and 5b, and generates a predetermined output voltage by connecting the power generation cells 5a and 5b in series. A step-up DC-DC converter 12 is connected to the DMFC unit 5 as an output adjustment unit. The DC-DC converter 12 constitutes a power generation unit 100 as a power generation unit together with the DMFC unit 5. The DC-DC converter 12 includes a converter main body 121, a switching element 122 including a MOSFET, and the like. By operation, the relatively low output voltage of the DMFC unit 5 is boosted to a sufficient voltage and output to the output terminal 9. Reference numeral 123 denotes a Schottky diode for preventing a reverse current flow from the output side of the converter main body 121.

  Here, the standard step-up DC-DC converter 12 is shown, but other circuit systems can be used as long as the step-up operation is possible.

  The DC-DC converter 12 is provided with a switch 124. This switch 124 enables the output of the DC-DC converter 12 to be output to the output terminal 9 side. That is, the switch 124 forcibly turns on and off the output boosted by the converter main body 121 and opens and closes in conjunction with the on / off of the switching element 125. The switching element 125 is controlled to be turned on and off by operating the power generation control switch 41. In this case, when the switching element 125 is turned on by the power generation control switch 41, the switch 124 is turned on to turn on the output from the DC-DC converter 12. Further, when the switching element 125 is turned off by the power generation control switch 41, the switch 124 is turned off and the output of the DC-DC converter 12 is turned off.

  In the above description, the output of the power generation unit 100 is turned off by turning off the output of the DC-DC converter 12 by the switch 124. However, the output of the power generation unit 100 is turned off by the operation of the power generation unit 100 itself. For example, a method of stopping power generation in the DMFC unit 5 by shutting off fuel (or air) supplied from the liquid fuel tank 8 to the DMFC unit 5 in conjunction with the power generation control switch 41 is also included. Therefore, in the following description, it is simply described that “the power generation unit 100 is turned on (or off)”.

  The auxiliary power supply 7 is connected to the output terminal 9. The auxiliary power supply 7 can be charged by the output from the DC-DC converter 12, supplies current to the instantaneous load fluctuation of the PDA main body 1, and enters the fuel depleted state to enter the DMFC unit. 5 is used as a driving power source for the PDA body 1 when power generation is impossible. As the auxiliary power source 7, a chargeable / dischargeable secondary battery (for example, a lithium ion rechargeable battery (LIB)) or an electric double layer capacitor is used.

  The control unit 2 is connected to the output terminal 9, and the PDA main body 1 is connected via a power switch 42. The power switch 42 turns on and off the power supplied from the power generation unit 100 (auxiliary power supply 7) to the PDA body 1.

  Next, the operation of the electronic apparatus according to the embodiment configured as described above will be described.

  By repeating the operation of the power key 301 provided in the input unit 3, the PDA body 1 and the power generation unit 100 are turned on / off, and the operation shown in FIG. 3 is executed.

  First, as shown in step 301, both the PDA main body 1 and the power generation unit 100 are assumed to be in an on state. In this state, the power generation control switch 41 is controlled to be turned on by the switch control unit 201, the switch 124 is turned on by the switching element 125, and the output from the DC-DC converter 12 is turned on, that is, the power generation unit 100 is turned on. Yes. Further, the power switch 42 is also turned on by the switch control unit 201, the output of the power generation unit 100 is supplied to the control unit 2 and the PDA body 1, and the PDA body 1 is also turned on.

  When the power key 301 of the input unit 3 is pressed from this state (step 302), a message “Do you want to stop the power generation unit” is displayed on the display unit 4 as a request to stop the auxiliary power supply 7 (step 303). If the PDA is not in use, a timer (not shown) is operated after a predetermined time has elapsed, the power switch 42 is turned off by the switch control unit 201, and the PDA body 1 is turned off (step 304). At this time, the power generation control switch 41 is on, and the power generation unit 100 remains on. Therefore, the auxiliary power supply 7 continues to be charged by the output of the power generation unit 100. Further, the above message on the display unit 4 is deleted.

  When the display screen of the display unit 4 is closed, the PDA may be determined to be in an unused state, and the power switch 42 may be turned off by the switch control unit 201. Alternatively, the power switch 42 may be turned off in conjunction with a hold key lock (not shown).

  Next, when the power key 301 is pressed and operated (step 305), the process returns to step 301 and both the power generation unit 100 and the PDA main body 1 are turned on.

  On the other hand, when the power key 301 is pressed in step 303 (step 306), the power switch 42 is turned off by the switch control unit 201, the PDA body 1 is turned off, and at the same time, the power generation control switch 41 is turned off. The switch 124 is turned off by the switching element 125, and the output from the DC-DC converter 12 is turned off, that is, the power generation unit 100 is also turned off (step 307). Thereby, charging of the auxiliary power source 7 by the power generation unit 100 and discharging from the auxiliary power source 7 to the PDA main body 1 are also stopped. Further, the above message on the display unit 4 screen is deleted.

  Next, when the power key 301 is pressed and operated (step 308), the power switch 42 is turned on by the switch control unit 201, the output of the auxiliary power supply 7 is supplied to the PDA body 1, and only the PDA body 1 is turned on ( Step 309). In addition, a message “Do you want to activate the power generation unit” is displayed on the display unit 4 screen.

  Next, when the power key 301 is pressed (step 310), the process returns to step 301. In step 301, the power generation control switch 41 is turned on by the switch control unit 201, the switch 124 is turned on by the switching element 125, and the output from the DC-DC converter 12 is turned on, that is, the power generation unit 100 is also turned on.

  In the state of step 309 in which the PDA main body 1 is turned on by the output of the auxiliary power supply 7, the display screen of the display unit 4 is opened and the PDA is used, or other keys than the power key 301 are operated. But this state is maintained.

  Accordingly, by repeating the operation of the power key 301 of the input unit 3 in this way, the on / off state of the PDA body 1 and the power generation unit 100 can be switched in a predetermined order. The PDA main body 1 and the power generation unit 100 can be easily set to the off state only by operating the power key 301. As a result, the fuel consumed by the DMFC unit 5 can be saved as much as possible due to the off state of the power generation unit 100. Also, the auxiliary power source 7 is not charged by the power generation unit 100 being turned off, here, by the output of the DC-DC converter 12, so that the auxiliary power source 7 does not continue to be charged in a very small load where the PDA is not used. Therefore, it is possible to prevent deterioration due to continuous charging in a state close to full charge. At the same time, the discharge from the auxiliary power supply 7 to the PDA main body 1 is cut off when the PDA main body 1 is turned off. Therefore, the auxiliary power supply 7 is excessively discharged by continuing to use the PDA main body 1 with the power generation unit 100 turned off. It is also possible to prevent the battery from being discharged and damaged.

(Modification 1)
In the first modification, the operating condition of the power generation unit 100 is set in advance so that when the power to the PDA body 1 is off, the power generation unit 100 is set to be on or off, and based on this setting, the power generation unit 100 Control on / off of 100. In this control, the operation shown in FIG. 4 is executed.

  First, in step 401, it is assumed that both the PDA main body 1 and the power generation unit 100 are in the on state. That is, the power generation control switch 41 is controlled to be turned on by the switch control unit 201, the switch 124 is turned on by the switching element 125, and the output from the DC-DC converter 12 is turned on, that is, the power generation unit 100 is turned on. In addition, the power switch 42 is also turned on by the switch control unit 201, the output from the power generation unit 100 is supplied to the control unit 2 and the PDA body 1, and the PDA body 1 is also turned on.

  From this state, when the power key 301 of the input unit 3 is pressed, if the power generation unit 100 is set to be turned on when the power to the PDA body 1 is turned off (step 402), the power generation unit is set based on this setting. 100 remains on (step 403). In this state, the auxiliary power supply 7 is charged by the output of the power generation unit 100. Next, when the power key 301 is pressed again (step 404), the process returns to step 401, and both the power generation unit 100 and the PDA main body 1 are turned on.

  On the other hand, when both the power generation unit 100 and the PDA main body 1 in step 401 are turned on, if the power key 301 is pressed on the input unit 3, the power generation unit 100 is also turned off when the power to the PDA main body 1 is turned off. If present (step 405), the power generation unit 100 is also turned off based on this setting (step 406). Next, when the power key 301 is pressed again (step 407), the process returns to step 401, and both the power generation unit 100 and the PDA body 1 are turned on.

  Therefore, if the power supply to the PDA body 1 is turned off in this way, it is determined in advance that the power generation unit 100 is set to be turned on or off. For example, the power supply to the PDA body 1 is turned off. If the power generation unit 100 is also set to be turned off at this time, the PDA main body 1 and the power generation unit 100 can be easily set to the off state only by operating the power key 301 when the PDA is not used. Thereby, the fuel consumed by the DMFC unit 5 by turning off the power generation unit 100 can be saved as much as possible. Also, the auxiliary power source 7 is not charged by the power generation unit 100 being turned off, here, by the output of the DC-DC converter 12, so that the auxiliary power source 7 does not continue to be charged in a very small load where the PDA is not used. Therefore, it is possible to prevent deterioration due to continuous charging in a state close to full charge. At the same time, the discharge from the auxiliary power supply 7 to the PDA main body 1 is cut off when the PDA main body 1 is turned off. Therefore, the auxiliary power supply 7 is excessively discharged by continuing to use the PDA main body 1 with the power generation unit 100 turned off. It is also possible to prevent the battery from being discharged and damaged.

(Modification 2)
In the second modification, the power generation unit 100 can be actively turned off when the PDA is not used. In the second modification, the control unit 2 is provided with a non-use detection unit 202 that detects non-use of the PDA. Then, when the PDA is not used, whether or not to turn off the power generation unit 100 is set in advance, and on / off of the power generation unit 100 is determined based on this setting. In this case, the operation shown in FIG. 5 is executed. In FIG. 5, the same parts as those in FIG. 3 are denoted by the same reference numerals and the description thereof is omitted, and only different parts will be described.

  Also in this case, it is assumed in step 301 that both the PDA main body 1 and the power generation unit 100 are in the on state.

  From this state, for example, when the PDA is in a non-use state such as closing the screen of the display unit 4 to enter a standby state. When the non-use detection unit 202 detects this state (step 501), the PDA is not in use beforehand. If the power generation unit 100 is set to be turned off, the process proceeds to step 309. In step 309, the power generation control switch 41 is turned off by the switch control unit 201, the switch 124 is also turned off by the switching element 125, and the output from the DC-DC converter 12 is turned off, that is, the power generation unit 100 is turned off. In addition, a message “Do you want to activate the power generation unit” is displayed on the display unit 4.

  From this state, the screen of the display unit 4 is opened and the PDA returns to the use state. When the non-use detection unit 202 detects this state (step 502), the power generation control switch 41 is turned on again by the switch control unit 201, and the switching is performed. The switch 124 is also turned on by the element 125, the output from the DC-DC converter 12 is turned on, that is, the power generation unit 100 is turned on, and the state of step 301 is restored.

  Therefore, in this way, the power generation unit 100 can be turned on / off according to the use / non-use of the PDA, and in particular, the power generation unit 100 can be actively turned off when the PDA is not used. it can.

(Modification 3)
In the third modification, when an external I / F (interface) (not shown) (USB, AC / DC line, external charger, additional fuel cartridge, etc.) is attached to or removed from the PDA main body 1, Determine on / off. In this case, the operation shown in FIG. 6 is executed. In FIG. 6, the same parts as those in FIG.

  Also in this case, it is assumed in step 301 that both the PDA main body 1 and the power generation unit 100 are in the on state.

  From this state, when an external I / F (not shown) is attached to the PDA main body 1 (step 601), it is asked whether the power generation unit 100 is to be turned off. (Step 602). Here, if it is desired to turn off the power generation unit 100, if YES is operated by a not-shown designation key, the process proceeds to step 309. In step 309, the power generation control switch 41 is turned off by the switch control unit 201, the switch 124 is also turned off by the switching element 125, and the output from the DC-DC converter 12 is turned off, that is, the power generation unit 100 is turned off. On the other hand, if NO is operated by another designation key, the process returns to step 301 and the power generation unit 100 remains on.

  Further, when an external I / F (not shown) is removed from the state of step 309 (step 603), it is asked whether to turn on the power generation unit 100 (step 603). Here, when it is desired to turn on the power generation unit 100, if YES is operated with a designation key (not shown), the process proceeds to step 301. In step 301, the power generation control switch 41 is turned on by the switch control unit 201, the switch 124 is also turned on by the switching element 125, and the output from the DC-DC converter 12 is turned on, that is, the power generation unit 100 is turned on. On the other hand, if NO is operated by another designation key, the process returns to step 309 and the power generation unit 100 remains off.

  Therefore, in this way, since it is possible to determine on / off of the power generation unit 100 according to the attachment / detachment of the external I / F, the power generation unit 100 can be easily configured according to the type of the external I / F. Can be set to off state.

(Modification 4)
In the fourth modification, the power generation unit 100 is turned on / off using the power key 301 and the help key 303 of the input unit 3. In the fourth modification, the operation shown in FIG. 7 is executed. In FIG. 7, the same parts as those in FIG.

  Also in this case, it is assumed in step 301 that both the PDA main body 1 and the power generation unit 100 are in the on state. When the help key 303 is operated from this state (step 701), the mode is switched to the help mode. Here, when the power key 301 and the help key 303 are operated, the power generation unit 100 is switched to the on / off setting mode. When the power generation unit 100 is turned off in the setting mode, the process proceeds to step 309. In step 309, the power generation control switch 41 is turned off by the switch control unit 201, the switch 124 is also turned off by the switching element 125, and the output from the DC-DC converter 12 is turned off, that is, the power generation unit 100 is turned off. When the help key 303 is operated from the state of step 309 (step 701), the mode is switched again to the help mode. Here, when the power key 301 and the help key 303 are operated, the power generation unit 100 is switched to the on / off setting mode. When the power generation unit 100 is turned on in the setting mode, the process returns to step 301. In step 301, the power generation control switch 41 is turned on by the switch control unit 201, the switch 124 is also turned on by the switching element 125, and the output from the DC-DC converter 12 is turned on, that is, the power generation unit 100 is turned on.

  8A and 8B are flowcharts for explaining the operation in detail.

  First, in FIG. 8A, after the help key 303 is operated to switch to the help mode (step 800), the power key 301 is operated while operating the help key 303 in step 801. By this operation, the process proceeds to step 802 and asks whether the power generation unit 100 is to be turned on / off in the on / off setting mode. Here, when it is desired to turn off the power generation unit 100, when an off instruction is given by a not-shown designation key, the power generation control switch 41 is turned off by the switch control unit 201, the switch 124 is also turned off by the switching element 125, and the DC-DC converter The output from 12 is off, that is, the power generation unit 100 is turned off (step 803). Next, the process proceeds to step 804, the icon of the power generation unit (not shown) on the display unit 4 is turned off, and the normal mode is restored by operating a determination key (not shown) in step 805 (step 806). On the other hand, if it is desired to turn on the power generation unit 100 in step 802, when the switch is instructed by another designation key, the power generation control switch 41 is turned on by the switch control unit 201, the switch 124 is also turned on by the switching element 125, and the DC− The output from the DC converter 12 is turned on, that is, the power generation unit 100 is turned on (step 807). Next, the process proceeds to step 808, the icon of the power generation unit (not shown) on the display unit 4 is turned on, and the decision key (not shown) is operated in step 805 to return from the help mode to the normal mode (step 806). .

  FIG. 8B shows another example. In this case as well, after the help key 303 is operated to switch to the help mode (step 810), the power key 301 is pressed while operating the help key 303 (step 810). 811). Then, the current state of the power generation unit 100 is forcibly reversed (step 812). For example, if the power generation unit 100 is in an on state, the power generation control switch 41 is turned off by the switch control unit 201, the switch 124 is also turned off by the switching element 125, and the output from the DC-DC converter 12 is turned off. 100 turns off. Conversely, if the power generation unit 100 is in the off state, the power generation control switch 41 is turned on by the switch control unit 201, the switch 124 is also turned on by the switching element 125, and the output from the DC-DC converter 12 is on, that is, power generation Part 100 is turned on. Thereafter, in step 813, the help mode is returned to the normal mode.

  Therefore, if the power key 301 is pressed while operating the help key 303 in this way, the setting of the power generation unit 100 can be switched on / off, so that the power generation unit 100 can be easily operated when the PDA is not used. Can be set to the off state.

(Modification 5)
In this modified example 5, the position of the numeric keypad 302 of the input unit 3 is correlated with the arrangement of icons on the menu screen of the display unit 4, and the setting screen of the power generation unit 100 can be simplified using the numeric keypad 302 and the help key 303. Can be taken out. In this case, the flowchart shown in FIG. 9 is executed. In FIG. 9, the same parts as those in FIG.

  Also in this case, it is assumed in step 301 that both the PDA main body 1 and the power generation unit 100 are in the on state. When the help key 303 is operated from this state (step 901), the mode is switched to the help mode. Here, the setting screen of the power generation unit 100 is taken out by operating the numeric keypad 302 and the help key 303. When the power generation unit 100 is turned off on the setting screen, the process proceeds to step 309. In step 309, the power generation control switch 41 is turned off by the switch control unit 201, the switch 124 is also turned off by the switching element 125, and the output from the DC-DC converter 12 is turned off, that is, the power generation unit 100 is turned off. On the other hand, when the help key 303 is operated from the state of step 309 (step 901), the mode is again switched to the help mode. Here, the setting screen of the power generation unit 100 is taken out by operating the numeric keypad 302 and the help key 303, and when the power generation unit 100 is turned on on the setting screen, the process returns to step 301. In step 301, the power generation control switch 41 is turned on by the switch control unit 201, the switch 124 is also turned on by the switching element 125, and the output from the DC-DC converter 12 is turned on, that is, the power generation unit 100 is turned on.

  FIG. 10 is a flowchart for explaining this operation in more detail.

  In this case, icons corresponding to various menus are displayed on the menu screen of the display unit 4 and when the help key 303 is operated, the mode is switched to the help mode (steps 1001 and 1002). Next, the numeric key 302 is pressed while operating the help key 303. This operation proceeds to step 1004. In step 1004, a menu having a correlation with the position of the pressed numeric keypad 302 is displayed on the display unit 4. Here, it is determined whether the display content is the setting menu of the power generation unit 100 (step 1005). If NO, the numeric key 302 is pressed while operating the help key 303 again (step 1006). Thereafter, when the setting screen of the power generation unit 100 is selected, when the operation of the help key 303 and the numeric keypad 302 is stopped (steps 1007 and 1008), the display unit 4 is switched to the setting screen of the power generation unit 100 (step 1009).

  In this state, it is asked whether the power generation unit 100 is to be turned on / off (step 1010). Here, when it is desired to turn off the power generation unit 100, an instruction to turn it off is given by a designation key (not shown). Then, the power generation control switch 41 is turned off by the switch control unit 201, the switch 124 is also turned off by the switching element 125, and the output from the DC-DC converter 12 is turned off, that is, the power generation unit 100 is turned off (step 1011). Next, the process proceeds to step 1012, the icon of the power generation unit (not shown) on the display unit 4 is turned off, and the normal mode is restored by operating a determination key (not shown) in step 1013 (step 1014). On the other hand, if it is desired to turn on the power generation unit 100 in step 1010, if the switch is instructed by another designation key, the power generation control switch 41 is turned on by the switch control unit 201, the switch 124 is also turned on by the switching element 125, and the DC− The output from the DC converter 12 is turned on, that is, the power generation unit 100 is turned on (step 1015). Next, the process proceeds to step 1016, the power generation unit icon (not shown) on the display unit 4 is turned on, and the decision mode (not shown) is operated in step 1013 to return from the help mode to the normal mode (step 1014). .

  Therefore, by doing this, the position of the numeric keypad 302 is determined by correlating the position of the numeric keypad 302 with the arrangement of the icons on the menu screen of the display unit 4 and pressing the numeric keypad 302 while operating the help key 303. Since the menu having a correlation with is displayed, the setting screen of the power generation unit 100 can be easily taken out. This means that even if you don't know the desired setting screen, you can easily take it out by simply remembering the position of the numeric keypad 302, that is, the number, and when the menu has a hierarchy. By simply learning the combination of numbers, you can easily reach the desired setting screen.

(Modification 6)
In this modified example 6, an icon as an index of the power generation unit is prepared on the screen of the display unit 4, and the setting screen of the power generation unit 100 can be easily taken out by directly selecting this icon. In this case, the operation shown in FIG. 11 is executed. In FIG. 11, the same parts as those in FIG.

  Also in this case, it is assumed in step 301 that both the PDA main body 1 and the power generation unit 100 are in the on state. When the help key 303 is operated from this state (step 1101), the mode is switched to the help mode. Here, the icon of the power generation unit 100 on the display unit 4 screen is selected, and the setting screen of the power generation unit 100 is taken out. When the power generation unit 100 is turned off on the setting screen, the process proceeds to step 309. In step 309, the power generation control switch 41 is turned off by the switch control unit 201, the switch 124 is also turned off by the switching element 125, and the output from the DC-DC converter 12 is turned off, that is, the power generation unit 100 is turned off. On the other hand, when the help key 303 is operated from the state of step 309 (step 901), the mode is switched to the help mode. Here, when the setting screen of the power generation unit 100 is taken out again and the power generation unit 100 is turned off on the setting screen, the process returns to step 301. In step 301, the power generation control switch 41 is turned on by the switch control unit 201, the switch 124 is also turned on by the switching element 125, and the output from the DC-DC converter 12 is turned on, that is, the power generation unit 100 is turned on.

  FIG. 12 is a flowchart for explaining this operation in more detail.

  In this case, the display screen of the display unit 4 is provided with an icon display area 402 in which a plurality of icons 402a corresponding to various menus are arranged at both ends of the display area 401 as shown in FIGS. 13A, 13B and 13C. And

  First, when the display screen of the display unit 4 is in the state of FIG. 13A, the help key 303 is operated to switch to the help mode, and then the operation of the help key 303 is stopped (steps 1201 and 1202), as shown in FIG. 13B. The icon color of any of the icons 402a is inverted (or flashes) (step 1203). In the example shown in FIG. 13B, it is assumed that the color of the icon 402a indicated by a black circle is inverted.

  In this state, a menu corresponding to the color-reversed icon 402a is displayed on the display unit 4. Here, it is determined whether the display content is the setting menu of the power generation unit 100 (step 1204). If NO, the power generation unit 100 icon 402a (the hatched icon) is displayed using a cursor not shown in FIG. 13C. Select to reverse (or blink) the color.

  If it is determined from the display content of the display unit 4 that the setting menu of the power generation unit 100 is set (step 1204), when the help key 303 is operated again (step 1206), the display unit 4 switches to the setting screen of the power generation unit 100. .

  In this state, it is asked whether the power generation unit 100 is turned on / off (step 1207). Here, when it is desired to turn off the power generation unit 100, an instruction to turn it off is given by a designation key (not shown). Then, the power generation control switch 41 is turned off by the switch control unit 201, the switch 124 is also turned off by the switching element 125, and the output from the DC-DC converter 12 is turned off, that is, the power generation unit 100 is turned off (step 1208). Next, it progresses to step 1209, the icon of the electric power generation part of the display part 4 is turned off, and it returns to normal mode by operating the help key 303 at step 1210 (step 1211). On the other hand, if it is desired to turn on the power generation unit 100 in step 1207, if an on instruction is given by another designation key, the power generation control switch 41 is turned on by the switch control unit 201, the switch 124 is also turned on by the switching element 125, and the DC− The output from the DC converter 12 is turned on, that is, the power generation unit 100 is turned on (step 1212). Next, it progresses to step 1213, the icon of the electric power generation part of the display part 4 is turned ON, and it returns to normal mode from help mode by operating the help key 303 at step 1210 (step 1211).

  Therefore, in this way, since the icon of the power generation unit is prepared on the screen of the display unit 4 and the help key 303 is operated, the corresponding icon can be selected. Ejection can be performed easily. This means that even if the menu has a hierarchy, it is possible to easily reach the setting screen because only the icon is selected. Thereby, the power generation unit 100 can be easily turned off in the PDA non-use state.

  Depending on how the icons are displayed, the power generation state (fuel state) or the like can be displayed with the power generation unit 100 turned on.

(Modification 7)
The modified example 7 enables the operations described in the modified examples 4, 5, and 6 by using the help key 303 in common, and the operations in the modified examples 4, 5, and 6 are each independently performed. In order to coexist without existing. In this case, each operation described in FIGS. 7 to 12 is selectively executed.

(Modification 8)
In Modification 8, the PDA body 1 (control unit 2) and the power generation unit 100 are both turned on to determine whether the PDA is not used, and the PDA body 1 and the power generation unit 100 are turned on / off. In this case, the operation shown in FIG. 14 is executed. In FIG. 14, the same parts as those in FIG. 3 are denoted by the same reference numerals and description thereof is omitted, and only different parts are described.

  Also in this case, it is assumed in step 301 that both the PDA main body 1 and the power generation unit 100 are in the on state.

  From this state, in step 1401, the operation status of the PDA is checked by a timer (not shown) (step 1402). Here, when key input at the input unit 3 or vibration due to PDA handling by the user is detected (step 1403), both the PDA main body 1 and the power generation unit 100 in step 301 are held in the on state. On the other hand, when the timer operates after a predetermined time has elapsed, it is determined that no operation is performed on the PDA (step 1404), and the process proceeds to step 307. In step 307, the power switch 42 is turned off by the switch control unit 201, the PDA body 1 is turned off, at the same time, the power generation control switch 41 is turned off, the switch 124 is turned off by the switching element 125, and the DC-DC converter. The output from 12 is off, that is, the power generation unit 100 is also turned off.

  Therefore, in this way, the operation of the input unit 3 by the operator is not continuously performed for a certain time set in advance in the timer from the normal operation state in which both the PDA main body 1 and the power generation unit 100 are on. If there is, the PDA is determined not to be used, and the PDA main body 1 and the power generation unit 100 can be forcibly turned off. Therefore, the power generation unit 100 can be easily turned off without using the PDA.

  In addition, this invention is not limited to the said embodiment, In the implementation stage, it can change variously in the range which does not change the summary. For example, in the above-described embodiment, the case of a PDA as an electronic device has been described, but application to other small electronic devices such as a personal computer, a mobile phone, a PHS, and a smart phone is also possible.

  ADVANTAGE OF THE INVENTION According to this invention, the electronic device with which a fuel cell is used as a power supply which can stop a power supply output by non-use of an apparatus etc. can be provided.

Claims (19)

An electronic device body,
A power generation unit having a fuel cell unit and an auxiliary power source charged by the output of the power generation unit, and a power supply unit for supplying power to the electronic device body;
An operation unit;
An electronic device comprising: a control unit that selectively enables the output of the power generation unit to be stopped and the output of the power supply unit to the electronic device main body to be selectively stopped by an operation on the operation unit.     The electronic device according to claim 1, wherein the control unit enables selection of at least one of the output of the power generation unit and the output of the power supply unit to the electronic device main body by repeated operation of the operation unit.     The electronic device according to claim 1, wherein the control unit can determine whether output of the power generation unit can be stopped when the output of the power supply unit to the electronic device main body is stopped based on preset contents. Furthermore, it has a non-use detection unit that detects a non-use state of the electronic device body,
The electronic device according to claim 1, wherein the control unit stops the output of the power generation unit when the non-use detection unit detects the non-use. Furthermore, it has a non-use detection unit that detects a non-use state of the electronic device body,
The electronic device according to claim 2, wherein the control unit stops the output of the power generation unit when the non-use detection unit detects the non-use. The electronic device body can be attached with an external interface,
The electronic device according to claim 1, wherein the control unit can stop the output of the power generation unit when the external interface is attached. The electronic device body can be attached with an external interface,
The electronic device according to claim 2, wherein the control unit can stop the output of the power generation unit when the external interface is attached. The operation unit has a power key and a specific key,
The electronic device according to claim 1, wherein the control unit can determine whether output of the power generation unit can be stopped in a state where the specific key and the power key are simultaneously operated. The operation unit has a power key and a specific key,
The electronic device according to claim 2, wherein the control unit is configured to determine whether output of the power generation unit can be stopped in a state where the specific key and the power key are simultaneously operated. The operation unit has a numeric keypad and a specific key,
The control unit displays various menus correlated with the position of the numeric keypad on the display unit, and whether the output of the power generation unit can be stopped corresponding to the numeric keypad when the specific key and the numeric keypad are operated simultaneously. The electronic device according to claim 1, wherein a menu for determining the selection can be selected. The operation unit has a numeric keypad and a specific key,
The control unit displays various menus correlated with the position of the numeric keypad on the display unit, and whether the output of the power generation unit can be stopped corresponding to the numeric keypad when the specific key and the numeric keypad are operated simultaneously. The electronic device according to claim 2, wherein a menu for determining the selection can be selected. The operation unit has a numeric keypad and a specific key,
The control unit displays various menus correlated with the position of the numeric keypad on the display unit, and whether the output of the power generation unit can be stopped corresponding to the numeric keypad when the specific key and the numeric keypad are operated simultaneously. The electronic device according to claim 9, wherein a menu for determining the selection can be selected. The operation unit has a specific key,
The control unit enables selection of indexes corresponding to various menus displayed on the display unit by operating the specific key, and a menu for determining whether output of the power generation unit can be stopped by selecting the index. The electronic device according to claim 1, wherein the electronic device can be selected. The operation unit has a specific key,
The control unit enables selection of indexes corresponding to various menus displayed on the display unit by operating the specific key, and a menu for determining whether output of the power generation unit can be stopped by selecting the index. The electronic device according to claim 2, wherein the electronic device can be selected. The operation unit has a specific key,
The control unit enables selection of indexes corresponding to various menus displayed on the display unit by operating the specific key, and a menu for determining whether output of the power generation unit can be stopped by selecting the index. 10. The electronic device according to claim 9, wherein the electronic device can be selected. The operation unit has a specific key,
The control unit enables selection of indexes corresponding to various menus displayed on the display unit by operating the specific key, and a menu for determining whether output of the power generation unit can be stopped by selecting the index. The electronic device according to claim 12, wherein the electronic device can be selected.     The electronic device according to claim 9, wherein the specific key can be used for a setting other than the determination of whether or not to stop the output of the power generation unit.     The electronic device according to claim 12, wherein the specific key can be used for other settings than the determination of whether or not the output of the power generation unit can be stopped.     The electronic device according to claim 16, wherein the specific key can be used for other settings than the determination of whether or not the power generation unit can stop the output.

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