JP2007059327A - Electronic device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electronic device with operation and a mechanism to stabilize power generation property of a fuel cell and keep pressure in a fuel tank at a predetermined value. <P>SOLUTION: The electronic device 1, equipped with the fuel tank 3 which holds fuel and discharges it by mean of endothermic reaction and the fuel cell 14 with a power generation part 2 generating electric power with fuel supplied from the fuel tank, comprises a channel for letting out gases generated in the power generation part, a channel for letting out the fuel gas changing internal pressure of the fuel tank, and an aperture for discharging the gas and fuel gas passing through the respective channels to the outside. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

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

  Conventionally used batteries include primary batteries called dry batteries, lead-acid batteries used for car batteries, and secondary batteries such as lithium batteries used for mobile devices. The primary battery holds the reactants therein and generates a current due to the chemical reaction of the reactants, but cannot be used when all of the reactants are consumed. In addition, due to the increase in power consumption accompanying the recent increase in performance and functionality of electronic devices, a sufficient amount of energy cannot be supplied.

  A secondary battery has reactants inside and generates a current to reduce the reactants. However, the reverse reaction occurs when charging, and the product is returned to the original reactants so that it can be used repeatedly. I can do it. However, the energy that can be used in one charge is less than that of the primary battery, and external power is required for charging, and a charging time of several tens of minutes to several hours is required for charging.

  On the other hand, in recent years, fuel cells that generate electric power with low pollution to the global environment have attracted attention. Conventionally, fuel cells have been put to practical use in space satellites, and since then they have been developed as drive sources for power generators and automobiles because they are energy-saving and have low environmental pollution.

  In addition, fuel cells can be supplied several times to nearly ten times the amount of energy that can be supplied per volume and weight compared to conventional batteries. Has been done. Furthermore, since it can be used continuously if only the fuel is replaced, it does not take time to charge unlike a secondary battery.

  There are various types of fuel cells, but they are solid for small electric devices, especially those that are carried around and used because they operate in the range from room temperature to 100 ° C and have a short start-up time. Polymer fuel cells are suitable.

  In addition, it is effective to use hydrogen as a fuel for a fuel cell for obtaining a large output. As a method of storing hydrogen which is a gas under normal pressure, the first method is a method of compressing hydrogen and storing it as a high-pressure gas. The second method is a method of storing hydrogen as a liquid at a low temperature. The third method is a method of storing hydrogen using a hydrogen storage alloy. In the fourth method, there is a method in which methanol, gasoline, or the like is loaded on a fuel tank, reformed, converted into hydrogen, and used. Recently, carbon-based materials such as carbon nanotubes, graphite nanofibers, and carbon nanohorns have attracted attention as a fifth method. This is because these carbon-based materials may be able to occlude about 10 wt% of hydrogen per weight.

  On the other hand, power generation of the polymer electrolyte fuel cell is performed as follows. A perfluorosulfonic acid cation exchange resin is often used for the polymer electrolyte membrane. For example, Nafion from DuPont is well known as such a membrane. A pair of porous electrodes carrying a catalyst such as platinum, that is, a membrane electrode assembly sandwiched between a fuel electrode and an oxidizer electrode, serves as a power generation cell. By supplying an oxidant to the oxidant electrode and a fuel to the fuel electrode, protons move through the polymer electrolyte membrane to generate electricity. This power generation reaction is most efficient when performed in a temperature range of about 60 ° C to 100 ° C. In addition, polymer electrolyte membranes are usually used after being moistened, but moisture on the fuel electrode side becomes excessive due to back diffusion that moves from the oxidizer electrode to the fuel electrode side. There is a phenomenon that hinders the diffusion of the battery and lowers the battery characteristics. Therefore, excessive moisture on the fuel electrode side is not preferable. In addition, as a factor that lowers the characteristics of the battery, gas that inhibits chemical reaction that generates power, such as nitrogen gas, permeates from the electrolyte membrane or sealing material that maintains confidentiality, and accumulates on the fuel electrode side to generate power. There is a problem of lowering the performance.

Patent Documents 1 and 2 are conventional examples of an electronic device using a fuel cell including a power generation unit and a fuel unit. In Patent Document 1, a lens barrel is interposed between an electronic chamber and a flash unit, and an opening hole that circulates outside air is formed in an electronic device casing therebetween. Patent Document 1 aims to reduce the concentration of the leaked fuel before it reaches the flash unit when fuel gas leaks from a fuel cell mounted in an electronic chamber inside the electronic device. Patent Document 2 discloses a fuel cell and an electronic device including a filter that adds a mechanism for recovering water generated in the fuel cell itself so that water vapor generated on the air electrode side is released to the outside air but does not allow liquid to permeate. It is disclosed.
JP 2005-017325 A JP 2004-087159 A

  However, the above-mentioned conventional Patent Document 1 is a structure for the fuel gas leaked from the fuel cell, and Patent Document 2 corresponds to water and water vapor generated at the air electrode. For this reason, no consideration has been given to the operation and path for releasing excess moisture on the fuel electrode side, and impure gas that has permeated through the electrolyte membrane and the seal member, particularly nitrogen gas, to the outside air.

  Further, when the entire electronic device is reduced in size, the distance between the fuel tank and the power generation unit is reduced, and heat generated by power generation is easily transmitted to the inside of the fuel tank. However, this is not preferable because it increases the internal pressure in the tank.

  Accordingly, an object of the present invention is to provide an electronic device having an operation and a mechanism capable of stabilizing the power generation characteristics of the fuel cell and maintaining the pressure of the fuel tank below a predetermined value in the electronic device. It is in.

  That is, the present invention provides an electronic device including a fuel tank that holds fuel and releases fuel by an endothermic reaction, and a fuel cell that includes a power generation unit that generates power using the fuel supplied from the fuel tank. An electronic apparatus comprising: a flow path for flowing out the gas generated in the section from the power generation section; and an opening hole for discharging the gas flowing through the flow path to the outside.

It is preferable that a gas discharge operation mechanism that performs an operation of discharging gas from the power generation unit to the flow channel according to a change in electric power of the power generation unit is provided between the power generation unit and the flow channel.
According to another aspect of the present invention, there is provided an electronic apparatus including a fuel tank that holds a fuel and releases the fuel by an endothermic reaction, and a fuel cell that includes a power generation unit that generates power using the fuel supplied from the fuel tank. An electronic apparatus comprising: a flow path through which fuel gas that changes the internal pressure of the tank flows out from the fuel tank; and an opening hole through which the fuel gas flowing through the flow path is discharged to the outside.

Preferably, a fuel discharge operation mechanism is provided between the fuel tank and the flow path for performing an operation of discharging fuel gas from the fuel tank to the flow path in accordance with a change in the internal pressure of the fuel tank.
Furthermore, the present invention provides an electronic apparatus including a fuel tank that holds fuel and releases fuel by an endothermic reaction, and a fuel cell that includes a power generation unit that generates power using the fuel supplied from the fuel tank. A flow path through which the gas generated in the section flows out from the power generation section, a flow path through which the fuel gas that changes the internal pressure of the fuel tank flows out from the fuel tank, and the gas and fuel gas flowing through each flow path to the outside An electronic device having an opening hole for discharging.

  If the electronic device of the present invention is used, when excessive moisture or impure gas permeates on the fuel electrode side, stable power generation can be performed without degrading the power characteristics of the fuel cell by discharging them. In addition, in the fuel tank that transfers heat from the power generation unit, the fuel gas can be released according to the change in the internal pressure due to heat, so that the pressure in the fuel tank can be kept below a predetermined value.

  The present invention provides an electronic device including a fuel tank that holds fuel and releases fuel by an endothermic reaction, and a fuel cell that includes the power generation unit that is supplied with fuel from the fuel tank and generates power. An electronic apparatus comprising a channel and an opening hole through which the released gas flows.

The power generation section includes an operation mechanism section and a relief mechanism as a gas discharge operation mechanism that performs an operation of discharging an internal gas according to a change in power of the power generation section.
Further, the present invention provides an electronic apparatus including a fuel tank that holds fuel and releases fuel by an endothermic reaction, and a fuel cell that includes a power generation unit that generates power by being supplied with fuel from the fuel tank. The electronic device includes a relief mechanism that discharges fuel gas according to a change in internal pressure of the tank, and a check valve that operates in conjunction with the relief mechanism and distributes the fuel gas to the flow path and the opening hole.

  In the present invention, examples of the electronic device include a camera and a mobile device.

Hereinafter, the present invention will be described more specifically with reference to examples.
Example 1
Hereinafter, an electronic device using the fuel cell of the present invention will be described with reference to the drawings.

  FIG. 1 is a schematic view of an arrangement in which a fuel cell according to the present invention is built in an electronic device, and FIG. 2 is a schematic view of the electronic device of the present invention as viewed obliquely from below. FIG. 5 is a schematic view of the electronic device according to the present invention as viewed obliquely from the bottom when the fuel cell is installed. FIG. 6 is a schematic diagram showing that the fuel gas circulated from the flow path of the power generation unit and the fuel tank leads to a common opening hole in the electronic device of the present invention. The fuel cell 14 of this embodiment is provided in one part of the electronic device 1 as shown in FIG. 1, and the fuel cell 14 includes a fuel tank 3 using a hydrogen storage alloy as a method for storing hydrogen, and a fuel. A power generation unit 2 that generates power using hydrogen derived from the tank 3 is disposed. In the electronic device, there are provided opening holes 4 and 5 which are flow paths for gas and water vapor released by the discharge operation, and an opening hole 16 through which air containing oxygen necessary for power generation flows. Further, as shown in FIG. 5, the fuel cell 14 can be taken in and out of an electronic device by opening and closing the lid 20 and can be replaced.

  FIG. 3 is a cross-sectional view taken along the line AA in FIG. It is sectional drawing of the electric power generation part 2 and the electronic device 1 in the fuel cell of a present Example. The power generation unit 2 includes a mechanism for maintaining confidentiality in the power generation unit 2 by the relief valve 11 that is controlled to the seal position by the sealing material 11a and the spring 11b. In the power generation unit 2, when the power generation characteristic is deteriorated due to excessive moisture or impure gas permeation, the gas discharge operation mechanism unit 10 that detects a change in the current supplied to the actual load and operates using the current change is provided. The electronic device 1 is provided.

  The gas discharge operation mechanism includes an operation mechanism unit 10 provided with the electronic device 1, a check valve 7, and a relief valve 11 provided with the power generation unit 2. The operation mechanism unit 10 is, for example, a device in which a cam-like component is attached to the tip of a motor and a motor shaft. In the power generation unit 2, when the power generation characteristics are deteriorated due to excessive moisture or permeation of impure gas, a change in the current supplied to the actual load is detected and the current change is used to operate, and the relief valve 11 is pushed to open. , Release confidentiality. When the relief valve 11 is opened, impure gas and moisture (mainly water vapor) in the power generation unit 2 pass through the flow path 30 and the relief port 21 in the power generation unit 2 and are suppressed by the spring 7a provided on the electronic device 1 side. The check valve 7 is pushed open. The outflowing gas and moisture (mainly water vapor) are released from the flow path 30 and the relief port 21 of the power generation unit 2 to the outside air through the flow path 6 and the opening holes 4 and 5 of the electronic device 1. In this case, a path that directly contacts the human body is not preferable, so that it is applied to the inner wall of the flow path 6 and an uneven shape is formed in the flow path 6. Moreover, the water | moisture content made into the droplet shape is absorbed by providing the water | moisture-content absorber 13 which absorbs a water | moisture content along the inner wall of the flow path 6, for example, a polymer absorber. When the discharge operation is completed, the check valve 7 is closed by the spring 7a and the relief valve 11 is closed by the spring 11b, so that the confidentiality of the power generation unit 2 can be maintained.

FIG. 4 is a cross-sectional view taken along the line BB in FIG. 1 is a cross-sectional view of a fuel tank 3 and an electronic device 1 in a fuel cell. As a hydrogen storage alloy used inside the fuel tank portion 3, hydrogen release pressure is 0.2 MPa at room temperature. For example, LaNi ₅ is preferable as a material. Table 1 shows the dissociation pressure characteristics of this hydrogen storage alloy.

  As shown in Table 1, the pressure increases as the temperature rises. However, since the pressure resistance of the polymer electrolyte membrane provided in the power generation unit 1 is generally 0.3 to 0.5 MPa or less, It is necessary to use a differential pressure with the outside air pressure within 0.1 MPa.

  When the internal pressure of the fuel tank 3 increases, a fuel release operation mechanism is provided that performs an operation of releasing the fuel gas from the fuel tank to the flow path according to a change in the internal pressure of the fuel tank. The fuel discharge operation mechanism includes a relief valve 9 provided with the fuel tank 3 and a check valve 8 provided with the electronic device 1.

  For this reason, the relief valve 9 maintains the confidentiality of the fuel tank 3 by the spring 9b and the sealing material 9a at a predetermined pressure. When the internal pressure of the fuel tank 3 is increased, the pressure applied to the relief valve 9 is increased, so that the tension of the spring 9b is overcome, and the relief valve 9 moves toward the flow path 6 so that the fuel tank 3 Release confidentiality. At the same time, by pushing open the check valve 8 held by the spring 8a, the fuel gas in the fuel tank 3 passes through the flow path 31 and the relief port 22 and flows through the flow path 6 of the electronic device 1. Flows out. The fuel gas that has flowed out is released to the outside air through the flow path 6 and the opening holes 4 and 5, but is not preferable in a path that directly contacts the human body. An uneven shape is formed. When the internal pressure of the fuel tank 3 decreases due to the release of the internal fuel gas, the reverse support valve 8 can be maintained by the spring 8a and the relief valve 9 can be maintained by the spring 9b to maintain the confidentiality of the fuel tank 3.

  The electronic device of the present invention has an operation and mechanism capable of stabilizing the power generation characteristics of the fuel cell and keeping the pressure of the fuel tank below a predetermined value, so that it can be used for a camera or a mobile device. it can.

It is the arrangement | positioning schematic diagram which incorporated the fuel cell by this invention in the electronic device. It is the schematic which looked at the electronic device of this invention from diagonally downward. 2 is a cross-sectional view taken along the line AA in the electronic apparatus of FIG. FIG. 3 is a cross-sectional view taken along the line BB in the electronic apparatus of FIG. 1. It is the schematic which looked at the state which takes in a fuel cell to an electronic device from diagonally lower. It is a schematic diagram of the flow-path system in the electronic device of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Electronic device 1a Electronic device housing 2 Power generation part 3 Fuel tank 4 Opening hole 5 Opening hole 6 Flow path 7 Check valve
7a Spring 8 Check valve
8a Spring 9 Relief valve 9a Sealing material 9b Spring 10 Operation mechanism 11 Relief valve 11a Sealing material 11b Spring 13 Moisture absorbing material 14 Fuel cell 16 Open hole 20 Lid 21 Relief port 22 Relief port 30 Channel 31 Channel

Claims (7)

  In an electronic device equipped with a fuel tank that holds fuel and releases fuel by an endothermic reaction, and a power generation unit that generates power using the fuel supplied from the fuel tank, the gas generated in the power generation unit An electronic apparatus comprising: a flow path that flows out from a power generation unit; and an opening hole that discharges a gas flowing through the flow path to the outside.   The electronic apparatus according to claim 1, further comprising a gas discharge operation mechanism that performs an operation of discharging gas from the power generation unit to the flow channel in accordance with a change in power of the power generation unit between the power generation unit and the flow channel.   In an electronic device including a fuel tank that holds fuel and releases fuel by an endothermic reaction and a power generation unit that generates power using the fuel supplied from the fuel tank, the internal pressure of the fuel tank is changed. An electronic apparatus comprising: a flow path through which fuel gas flows out from a fuel tank; and an opening hole through which the fuel gas flowing through the flow path is discharged to the outside.   4. The electronic apparatus according to claim 3, further comprising a fuel discharge operation mechanism that performs an operation of releasing fuel gas from the fuel tank to the flow path according to a change in internal pressure of the fuel tank between the fuel tank and the flow path. .   In an electronic device equipped with a fuel tank that holds fuel and releases fuel by an endothermic reaction, and a power generation unit that generates power using the fuel supplied from the fuel tank, the gas generated in the power generation unit A flow path that flows out from the power generation unit, a flow path that flows out the fuel gas that changes the internal pressure of the fuel tank from the fuel tank, and an opening hole that discharges the gas and fuel gas flowing through each flow path to the outside An electronic device characterized by that.   The electronic apparatus according to claim 5, further comprising a gas discharge operation mechanism that performs an operation of discharging gas from the power generation unit to the flow channel according to a change in electric power of the power generation unit between the power generation unit and the flow channel.   6. The electronic apparatus according to claim 5, further comprising a fuel discharge operation mechanism that performs an operation of discharging fuel gas from the fuel tank to the flow path in accordance with a change in internal pressure of the fuel tank between the fuel tank and the flow path. .

Images