JP2002503379A - Container for electrical equipment using metal-air battery - Google Patents

Abstract

SUMMARY OF THE INVENTION The present invention provides a water resistant case (6) for electrical equipment such as an electronic wristwatch that operates on a standard high current zinc-air battery. The small holes (11) formed in the case suppress the flow of water vapor into and out of the case and extend the battery life. This hole further limits the flow of oxygen to the cathode side of the cell, rather than the air inlet of the cell itself. The hydrophobic gas permeable membrane (45) allows air and water vapor to enter the holes but prevents liquid water from entering.

Description

DETAILED DESCRIPTION OF THE INVENTION Container for electrical equipment using metal-air battery Technical field The present invention relates to a container used for an electric device which is driven by a metal-air battery and is suitable for low-current operation (operation), but requires intermittently high current. An example of this type is a case for an electronic watch, for example, in which the case of an electronic watch is equipped with a movement of an electronic watch driven by a zinc-air battery, and a continuously low current for performing a timekeeping operation. However, there is provided a means for illuminating the clock by pressing a push button or operating a wireless receiver included in a paging device or the like. These devices require a relatively high current for a short period of time during operation, and thus require a high current battery. Metal-air cells (metal-air cells) are well known in the art and generally comprise a consumable metal anode, a catalytically non-consumable, oxygen-consuming cathode, and a desired electrolyte. Metal-air batteries are manufactured in the form of small button batteries, and are frequently used for hearing aids, watches, and the like. A typical zinc-air button battery has the following configuration. 1. Cathode can: This cathode can has at least one hole for air inflow and has a gas permeable hydrophobic polymer film, which is pressed with a metal current collector grid and mixed with a hydrophobic binder A non-consumable air cathode structure having a porous catalyst material such as a metal-catalyzed activated carbon. However, in practice, as an independent element of the battery, one or more electrolyte-adsorbing separator layers are arranged on the catalyst layer of the cathode structure to achieve isolation from the anode. 2. Anode can: This is typically bonded to the cathode can by crimping and the zinc anode material is amalgam-type zinc powder (eg, containing 3-8% Hg) or a porous zinc compact, It is saturated with an alkaline electrolyte such as a 40% KOH aqueous solution. 3. An insulator such as polyethylene, polypropylene, or nylon is interposed between the cathode and anode cans to perform an insulating function and to seal an electrolyte. As a method for controlling the inflow of air into the air-consuming electrode, a small hole is formed in a button cell container as disclosed in U.S. Pat. No. 3,897,265 (patented on Jul. 29, 1975). This type of battery is effective as a relatively high current capacity (drain) of, for example, about 10 mA used in hearing aids and the like. Later, a long-life, low-current-capacity zinc-air battery required for electronic wristwatches, such as controlling the flow of oxygen into an air-consuming catalyst by adding a special membrane, was developed. An example of this type of membrane is disclosed in U.S. Pat. No. 4,105,830 (patented Aug. 8, 1978) which is of the oxygen permeable type. Another example is the formation of fine holes or passages in the shield to the cathode, as disclosed in U.S. Pat. No. 4,118,544 (October 3, 1978). In the above configuration, the means for controlling the inflow of oxygen to the cathode side is formed in accordance with each usage mode or the range of the current capacity required by the battery. None of the above configurations can themselves alter battery operation depending on whether the current mode is low or high. According to the prior art, regarding the entry and exit of gas and moisture such as air to and from the zinc-air battery, by restricting the opening of the battery wall that allows the inflow of air, the entry and exit of the gas and the like can be prevented. Speed can be suppressed. Controlling the relative humidity is a very important factor in extending the life of the battery. In the case of a zinc-air battery, it dries in a low humidity environment and overflows under a high humidity condition. Either condition prevents the rated capacity of the battery from being sufficient for a long period of time, which means that if the current capacity is low, for example, in the case where the rated capacity is not exhausted in the next period of 6 weeks or more. Is particularly noticeable. The initial concentration of the battery electrolyte is formed at a relative humidity (RH) inside the battery of approximately 58%. Exposure of an activated battery to ambient relative humidity levels and its vicinity will result in inflow and outflow of water vapor. The inflow and outflow of the lacquer ware can be restricted by reducing the size of the air inlet. However, openings that limit the movement of water vapor also limit the flow of oxygen into the battery. The aperture of the high current battery must be large enough to contain the oxygen needed to limit the maximum discharge value. Metal-air batteries with high current capacity used for hearing aids and the like are not suitable for use in wristwatches without modification. Metal-air batteries have been modified and modified to be used in electrical equipment that requires a high current drain intermittently but typically requires a low average current drain. Examples of such variations are U.S. Pat. No. 4,262,062 (April 14, 1981) and U.S. Pat. No. 5,451,473 (September 19, 1995). In the latter case, the metal-air battery has a limited membrane that controls entry into the internal air reservoir from the air inlet at the bottom of the battery. In this case, the air reservoir provides sufficient oxygen to the cathode assembly within a short period of high current capacity. Another means of matching a battery with an electrical device that receives electrical energy from the battery is disclosed in US Pat. No. 5,191,274 (March 2, 1993). According to this patent, the number of air inlet holes is limited by a seal, and the seal determines the number of holes through which oxygen flows into the battery. In any of the above prior arts, the flow rate of air to the battery is determined by the configuration (design) of the metal-air battery itself. It is also well-known in the related art that an electric device and a metal-air battery that matches the current value required by the electric device are housed in one container. Since the battery requires air for its operation, the container itself cannot be sealed. In the above-mentioned conventional technique, it is possible to take in air into a container so as to satisfy a current condition required by an electric device under all conditions. As described above, the entry of the air accompanied by the water vapor causes the relative humidity in the container to fluctuate greatly. That is, as the air with water vapor enters, as determined by many factors such as fluctuations in the ambient relative humidity outside the container, temperature fluctuations in the container, and depletion of oxygen by the battery, the relative humidity in the container is reduced. It will fluctuate greatly. However, if the electric equipment is used under excessive humidity conditions or operates in water, water as a liquid can enter through the air inlet. In this regard, it is known to use a hydrophobic gas permeable membrane for the walls of the container, which prevents the inflow of water as a liquid while allowing the inflow of air. is there. An example of such a device housing or container is U.S. Pat. No. 4,292,681 (patented September 29, 1981). This patent discloses a container for electric equipment having a lid and a seal, and the seal itself or the hole of the lid, or the housing itself is formed of a hydrophobic, gas-permeable microporous body. Is what you do. In FIG. 1 (prior art) of the accompanying drawings, an example of a conventional container for electrical equipment is disclosed in U.S. Pat. No. 4,292,681, in which the housing comprises parts 1 and 2, which are Are watertightly sealed to each other via a gas-impermeable seal ring 3. The portion 2 has a lid shape and is provided with a gas hole 4, and the gas hole 4 is closed by a microporous hydrophobic member. Air is supplied to the air oxygen elements (electric devices and metal air batteries) housed in the container via this member, and the member can be formed of, for example, unsintered polytetrafluoroethylene. It is also possible to provide several such air permeable holes and close them with a microporous seal body. Illustratively, a zinc-air battery housed in a housing uses approximately 5 microliters of air per hour. When immersed in water, the watch continues to operate by taking in the air contained in the housing. The zinc-air battery shown in the prior art described above is provided with a usable life, and a membrane for limiting the flow rate of air provided in the battery, or the aforementioned U.S. Pat. Nos. 4,292,681 and 5,191,274. No. 5,451,473, should be available, in particular for watches. In U.S. Pat. No. 4,292,681, such hydrophobic, gas permeable materials (usually membrane structures) allow liquid moisture to enter without restricting the inflow of air or other gases containing water vapor. Is adopted for the purpose of restricting Accordingly, one object of the present invention is to provide an improved container for use in electrical equipment operated by a metal-air battery, which will also extend the life of the battery. It is another object of the present invention to provide an improved container that extends the life of a high current capacity metal-air battery that supplies electrical energy to electrical equipment requiring low current capacity. It is yet another object of the present invention to provide an improved container that can control the change in relative humidity encountered by a metal-air battery in the container. It is another object of the present invention to provide an improved use for operating a watch movement in a waterproof case using a standard zinc-air high capacity battery for hearing aids. Summary of the Invention The present invention has a container for controlling the entrance and exit of air and water vapor to and from a high-current metal-air battery that supplies electrical energy to electrical equipment that requires low current drive and intermittent high current. Both the air battery and the electric equipment are housed in a container, and the metal air battery has an air inflow portion large enough to allow the flow of oxygen to the battery more than necessary, and supplies a low current of the electric equipment. It is something to do. The container includes a metal-air battery including a sealed housing serving as an air reservoir, and the closed housing includes a wall and has a limited flow of communication between the air reservoir and the outside of the housing. The flow passage is defined and the flow passage is sized to allow the inflow of oxygen sufficient to satisfy the low current drive requirements of the electrical equipment. In a preferred form, the housing further comprises a hydrophobic gas permeable membrane between the limited flow passage and the exterior of the housing, and the membrane is adapted to transfer oxygen to the limited flow passage. Although the inflow is permitted, the liquid is prevented from entering the housing. In a preferred embodiment, the restricted flow passage is a micropore having a diameter of about 0.08 mm (0.0032 inch) formed in the container wall, and is a membrane known under the registered trademark “GORE-TEX”. Supplied through covered holes. In addition, various materials can be employed as long as they have hydrophobicity and gas permeability. BRIEF DESCRIPTION OF THE FIGURES Although the structure and implementation method of the present invention, and the objects and effects of the invention will be clearly understood from the description of the embodiments shown in the drawings, in the accompanying drawings showing the embodiments and the like, FIG. It is explanatory drawing which showed the cross section of the container for electrical devices in 1 in simplified form. FIG. 2 is an explanatory view showing a simplified structure of a housing for accommodating an electric device and a battery according to the present invention. FIG. 3 is an explanatory view showing a modification of the present invention. FIG. 4 is an explanatory view showing still another embodiment of the present invention. FIG. 5 is an explanatory view showing still another embodiment of the present invention. FIG. 6 is an explanatory view showing still another embodiment of the present invention. BEST MODE FOR CARRYING OUT THE INVENTION The simplest form of the container of the present invention is as shown in the explanatory view of the simplified configuration in FIG. The housing parts 5 and 6 are connected to each other in a watertight manner via a gas-impermeable sealing ring 7 to form a sealed housing. An electric device 8 is housed and arranged in the housing, and the electric device 8 requires supply of electric energy from a battery 9 electrically connected by a lead wire 10. In the illustrated example, the supporting structure of the electric device 8 or 9 is omitted without illustration because it is illustrated as a simplified explanatory diagram. However, this type of device and member is actually required. Here, as the above-mentioned electric device of reference numeral 8, a movement of an electric clock or a continuous low current for timekeeping in a microampere area (2-250 microamperes) and periodically or intermittently milliampere. It is intended for electrical equipment that requires a high current flow in the area (2-12 mA). An example is an electric page wristwatch, which normally consumes a stable current of 5 microamps to operate the timekeeping function, while requiring a relatively high current of the order of 10 milliamps to operate the pager. It works. This pager is not always activated, but only activated occasionally, so the current capacity for it is low. The energy battery 9 is a standard high-capacity or high-current-supplied zinc-air battery employed in hearing aids and the like, and is, for example, a commercially available battery number 13 or 675, which is described above. In such a manner, the battery is not modified so as to limit the supply of air to the cathode-side structure. Thus, the high-current zinc-air battery 9 is manufactured to have a useful service period in the order of 3 to 6 weeks after the start of operation by removing the cover of the air inflow portion indicated by reference numeral 9a. Is what is being done. All batteries of this type are responsive to changes in relative humidity and other conditions, such as ambient and environmental conditions, which change the battery chemistry, causing battery degradation and non-saturated energy depletion. Will be. Under low humidity environmental conditions, water will evaporate from the electrolyte and escape from the battery, reducing the volume of the electrolyte and eventually causing a dry condition. Conversely, at high humidity, the battery takes in moisture and dilutes the electrolyte, thereby overflowing the battery. In this case, the branch line separating the "high" humidity from the "low" humidity is the equilibrium value of the relative humidity that the battery uses and maintains at about 58% relative humidity due to the chemicals inside it. When the relative humidity exceeds 58%, the battery takes up moisture, and when it is less than 58%, the battery loses moisture. Such gain and loss as moisture is made possible by the uptake and release of water vapor divergence performed via the air inlet 9a in the cell wall. The inside of the air battery 9 enters through the air inflow portion 9a serving as an air intake portion, and reacts with water to consume oxygen and form hydroxide ions. The following is an example of the number and size of typical air intakes (air inflows) formed in a typical high current zinc-air battery for a hearing aid that is commercially available. The flow of oxygen that can be taken from the air inflow is substantially greater than what is allowed in the microampere range to supply the low average current required by the electrical equipment, Is sufficient for the intermittent supply of high currents, of the order of a few milliamperes, as required. According to the present invention, the inflow and outflow of water vapor and the inflow of air (oxygen) for low current operation required by the electric equipment are controlled by the restricted flow passage 11. The flow passage 11 communicates between the air reservoir 12 in the housing and the atmosphere outside the housing. In the embodiment shown in FIG. 2, the limited flow passage is formed by a small hole formed in the metal plate 13 mechanically or by a laser beam. The metal plate 13 is held or sealed in a hole 14 formed in the wall of the housing 6. A suitable size for the limited flow passage 11 that holds a 2 milliamp low average current drain is a single 0.08 mm (0.0032 inch) diameter hole or 0.005 mm. ^Two (0.000008in ^Two ). A useful range of the diameter of the restricted flow passage 11 is in the range of 0.05 to 0.1 mm, depending on the expected low current capacity (drain). This diameter can be determined empirically. The air flow flowing through the hole of this size to the air storage portion 12 sufficiently satisfies the low current capacity required by the electric device 8. However, the inventor has found that the holes hinder and delay the escape of water vapor into and out of the air reservoir 12 and extend the usable life of the metal-air battery. . When the hole is closed or when the electric device 8 requires a high current capacity, the air reservoir 12 temporarily supplies the battery 9 as needed. In the other embodiment of FIG. 3, the same reference numerals as in FIG. 2 denote the same parts. However, in this embodiment, the metal plate 13 provided with the restricted or limited type flow passage 11 is disposed inside the hole 14, and the outside of the hole 14 is made of hydrophobic gas. It is closed by a film body 15 which is a transmission type member. The film body 15 is preferably an unsintered polytetrafluoroethylene foil. A preferred commercially available membrane 15 is GORE-TEX, which is a commercially available membrane that allows the passage of air and water vapor but prevents the passage of liquid water. The membrane 15 covers the hole 14 and is held and sealed around an end formed on the wall of the container. An empty space or chamber 6a provided on the wall of the housing part 6 is formed between the hole 11 and the membrane 15, and collects air and water vapor and passes through the porosity of the membrane 15. The membrane 15 is not formed to clearly restrict the flow of air into the air reservoir 12, and this function itself is achieved by the restricted flow passage 11. The size of the holes is selected such that the air flow through the membrane 15 is sufficient and meets the low current carrying requirements of the electrical equipment. However, the film body 15 ensures that a sufficient amount of air flows into the air storage portion 6a while preventing the inflow of liquid moisture, and thus the continuous operation of the electric device 8 is severe. It is formed so that it can be maintained and maintained under If the housing is completely immersed in water, the battery 9 is supplied with air from the air reservoir 12 for a long period of time under low current drain requirements. When a temporary high current is required, the air is similarly supplied from the air storage unit 12 to the battery 9 for a short time. Since the water vapor is gaseous, it also passes through the membrane 15. In this case, the inflow or outflow due to divergence is greatly suppressed by the cooperation of the membrane body 15 and the flow passage 11. In FIG. 4, the housing section 16 includes the lid 5 and the seal ring 7 as in the above embodiment. The inside of the housing is a battery chamber wall 17 which forms a battery chamber 18 and functions as an air storage section surrounding the battery 9. The removable battery cap 19 allows access to the battery compartment 18. The cap 19 has a sealing gasket or O-ring 20 and is attached by a bayonet lock or screw or other suitable technique. Cap 19 defines a hole 21. A plate or washer 22 is hermetically provided in the inner hole 21 facing the battery chamber. The washer 22 has a limited flow passage 23 similar to the above-described limited flow passage 23. Covering the hole 21 facing the outside air is a film 24 made of a gas-permeable and hydrophobic substance, which is the same as that of the reference numeral 15 described in the embodiment of FIG. Is fine. The water vapor that has passed through the membrane 24 is collected by the chamber 19a. The configuration in FIG. 4 is a general configuration in an electric timepiece, and electric devices are stored in a compartment separated from a battery. In this case, the battery is detachable via a separation hole by a detachable cap as shown by reference numeral 19. The lead wire 25 connects the battery 9 and the electric device 9 via the sealing body 26 of the wall 17. The configuration of FIG. 4 is more realistic and practical in actual use. This is because the cap 19 is removable and the battery can be replaced, and the flow passage 23 and the membrane 24 can be easily inspected. FIG. 5 is a modification of the configuration of FIG. 3, but is the same as the configuration of FIG. 3 except that the lower part of the housing indicated by reference numeral 27 is made of plastic such as polycarbonate. A hole 28 formed on the outer surface of the housing portion 27 is connected to a limited flow passage 29 located on the inner surface of the housing 27. The preferred diameter of this hole 28 is 1.75 mm (0.069 inch). As mentioned above, the desired diameter of the limited flow passage 29 formed in the wall during the manufacturing process is 0.08 mm (0.0032 inches). The drawings are not drawn to scale, but are exaggerated for convenience of explanation. The membrane 15 made of a hydrophobic gas-permeable substance covers the hole 28 and is held and sealed by the outer wall of the housing 27. The intermediate chamber 30 collects the gas that has passed through the group of micropores in the membrane body 15 as in the case described above. FIG. 6 shows still another modification, in which an electric wristwatch having a plastic case or housing 31 is shown as a specific example. Of course, in this embodiment, a configuration for an electric wristwatch is shown, but the present invention is not limited to this, and other general electricity (such as those shown in FIGS. It is needless to say that the present invention can be applied to an (electronic) device or device. Now, in this embodiment, the housing 31 has a battery chamber wall 32 forming a battery chamber 33. In the chamber 33, two metal air batteries 34a and 34b connected in series are arranged. The cap 36 for accessing the battery is provided with the O-ring 20 serving as a seal gasket, and is attached to the housing 31 by a stopper or a screw of an insertion die. A hole 37 formed in the outer surface of the wall of the housing 31 narrows a limited type (restricted) flow passage 38 formed in the inner wall inside the battery chamber 33. The dimensions of the hole 37 and the limited flow passage 38 are the same as in the previous embodiment described with reference to FIG. The film body 15 closing the hole 37 is the same as in the case of FIG. The film body 15 is configured to allow the gas to flow into the chamber 39 but prevent the flow of the liquid from the chamber 39, and the chamber 39 supplies the battery chamber 33. The series-connected zinc-air batteries 34, 35 supply electrical energy to the movement 40 of the watch via a lead 41 passing through the battery compartment wall 32. The watch movement 40 itself may be conventional and has a push button and means for illuminating the watch face by pressing the push button (not shown). A preferred example of a movement is disclosed in U.S. Pat. No. 5,265,071, which is hereby incorporated by reference herein. The operation of the push button requires a short period of high current of about 6 mA. The battery compartment 33 provides an air reservoir, which can be predetermined to the volume required to intermittently supply the high current required by the lighting device of the movement 40 at a given time. The limited flow passage 38 is large enough to supply the low current capacity required for the timepiece movement 8. Calculation of such numerical values is within the purview of those skilled in the art. The air storage section 33 shown in FIG. 6 is formed in a size sufficient to operate the timepiece movement with a predetermined current capacity at a predetermined time when the passage of air is blocked. For example, if two batteries are connected in series and the air in the air reservoir consists of a normal ratio of 21% oxygen, one cubic centimeter of air reservoir (more than the amount occupied by the battery itself) Provides only about 1/2 mA · h (milliamp · hour). Thus, if the container is immersed in water and the movement requires a continuous 2 mA · h current supply, the two batteries will operate the movement for approximately 15 minutes. Experimental example Experiments were performed using a 675 type hearing aid battery in a sealed container with electrical equipment set at 500 mAh for over 4 months. The container has one hole with a diameter of 0.08 mm (0.0032 inches). The relative humidity outside the container was kept constant during three experiments over a period of more than four months, of which one was 10% relative humidity and one was 90% relative humidity, and the third experiment was relative humidity. Although the humidity was set to 58%, this value (58%) is a value held by the electrolyte of the battery. In each case, the batteries worked normally for 4 months. The same relative humidity conditions were maintained in the bare battery control test without the container. In both cases where the relative humidity was 10% and 90%, the operation of the battery stopped after one week. On the other hand, at a relative humidity of 58%, the battery functioned normally during the entire test. As described above, an improved housing for electrical equipment can extend the life of a standard high current zinc-air battery. The housing itself controls the ingress and egress of water vapor, which mitigates changes in relative humidity which can shorten battery life. In addition, the housing controls the rate of supply of oxygen to the air reservoir so that the battery can better meet the requirements of electrical equipment. As a variant, the housing has the advantages described above, but the membrane is liquid-resistant to prevent the inflow of water. The membrane assures airflow through the restricted flow passage to regulate the use of the battery in the housing, while cooperating with the restricted flow passage to limit the entry and exit of water vapor. By suppressing the water vapor from escaping into and out of the air storage unit in which the battery is disposed, the battery life can be significantly increased. The preferred embodiment of the present invention has been described above. However, the present invention is not limited to this, and various changes can be made within the scope of the claims.

[Procedure of Amendment] Article 184-8, Paragraph 1 of the Patent Act [Submission date] November 10, 1998 (November 10, 1998) [Correction contents] 4. The closed housing further includes a hydrophobic, gas permeable member. The hydrophobic gas permeable member is provided between the limited flow passage and the outside of the closed housing. A chamber is formed between the chambers, and liquid is prevented from flowing into the chamber. In addition, a predetermined amount of oxygen sufficient to satisfy the demand for the low current capacity of the electric device is increased. The container of claim 1 adapted to be delivered to said solute. 5. Removable housing with metal air battery accessible The container according to claim 1, further comprising a cap, wherein the wall is formed on the cap. 6. The sealed housing includes a first housing for housing the metal-air battery and the electrical device. A second chamber is formed, and a detachable chamber for accessing the first chamber is provided. An air reservoir, wherein the air reservoir is disposed in the first chamber. The container of claim 1. 7. Connected to electrical equipment that requires intermittent high current and low current capacity, A container for providing flow capacity and extending the life of a metal-air battery, And the electrical equipment are all housed in the container, and the metal-air battery is Sized to allow sufficient airflow to meet high current capacity requirements It has an air inlet,   The container has a sealed housing forming an air storage section and a chamber for accommodating the metal-air battery. Equipped with a housing,   The closed housing communicates the air reservoir with the outside of the closed housing. Having a wall with a limited type of flow passage,   The limited type flow path is used for the low current capacity requirement of the electrical equipment. In order to satisfy the condition, the air reservoir is formed in a size that allows a predetermined amount of air to flow. And,   By suppressing the movement of water vapor between the air storage section and the outside of the battery, the air storage The operating life of the metal-air battery can be extended by adjusting the humidity inside the To be able to   Furthermore, when the volume of the air reservoir is limited, the limited type flow passage is opened. Metal air that is predetermined to satisfy a predetermined current capacity for a predetermined time Container for electrical equipment that uses batteries. 8. 8. The limited flow passage having at least one hole formed in the wall. Container. 9. The limited flow passage is a hole formed in the wall, and has a diameter of 0.05 8. The container of claim 7, wherein the range is from 0.1 mm to 0.1 mm. 10. The closed housing further includes a hydrophobic gas permeable member. The hydrophobic and gas permeable member of the above-mentioned limited flow passage and the outside of the tightly closed housing While forming a chamber between, the liquid is prevented from flowing into the chamber, Further, a predetermined amount of oxygen sufficient to satisfy the requirement of the low current capacity of the electric device is used. 8. The container of claim 7, adapted to be sent to said chamber. 11. Removable housing with access to metal air battery The container according to claim 7, further comprising a cap, wherein the wall is formed on the cap. . 12. The sealed housing is a second housing for housing the metal-air battery and the eleventh electrical device. The first and second chambers are formed respectively, An air reservoir having a removable cap accessible to the first chamber; The container according to claim 7, wherein the container is disposed in the first chamber. Performs clocking operation in the 13.2-250 mA range and provides high current. Temporarily supplies a current in the range of 2 to 12 mA from the supplied zinc-air battery As a result, an electronic watch movement that requires a large Water resistant watch case,   The water-resistant watch case has an air storage section and a chamber for accommodating zinc / air batteries. Equipped with a sealed housing,   The tightly closed housing communicates the air reservoir with the outside of the closed housing. Having a wall with a perforated hole,   A hydrophobic gas-permeable membrane covering the pores is provided,   The pores and the hydrophobic gas-permeable membrane are provided in the air storage portion with the zinc / air electrode. A sufficient amount of oxygen is supplied so that the pond can be continuously operated at the low current capacity. ,   The holes slow the movement of water vapor between the air reservoir and the outside of the battery, By adjusting the humidity in the air storage to a predetermined level, the above zinc / air battery can be used. A water-resistant watch case that can extend the lifespan of a watch. 14． The hole is a hole formed in the wall, and has a diameter of 0.08 mm. 13. A water-resistant watch case. 15. The hole has a diameter of 1.75 mm, and the membrane of the hydrophobic gas permeable wall is a trade name. 14. The container of claim 13, wherein the container is a GORE-TEX fitting. 16. The pores and the hydrophobic gas permeable membrane are as low as 2 milliamps. 14. The container of claim 13, wherein the container is selected to retain a current carrying capacity. 17． Connected to electrical equipment that requires low current capacity and provides high current capacity A container for transferring water vapor into and out of the metal-air battery. Both the metal air battery and the electric device are housed in the container, and the metal The gas battery has an oxygen inlet for taking in oxygen,   The container has an air reservoir and a sealed chamber forming the metal-air battery. Has a closed housing,   The closed housing communicates the air reservoir with the outside of the closed housing. And a predetermined space sufficient to satisfy the requirement of the low current capacity of the electrical equipment. Adjusting means for taking air into the air reservoir,   Suppressing the movement of water vapor between the air reservoir and the outside of the closed housing, By maintaining the humidity in the air reservoir at a predetermined level, the use of the metal air battery can be improved. A container for electrical equipment that uses a metal-air battery that can be used for a longer period of time. [Procedure of Amendment] Article 184-8, Paragraph 1 of the Patent Act [Submission date] April 16, 1999 (1999.16.16) [Correction contents]                           Claims (after amendment) 1. Metal air powered to provide high current capacity connected to electrical equipment requiring low current capacity A container provided with means for suppressing the entry and exit of water vapor inside and outside the pond, Both the metal air battery and the electric equipment are housed in the container, and the metal air The battery has an air inlet for allowing oxygen to flow,   The container has a sealed housing forming an air storage section and a chamber for accommodating the metal-air battery. Equipped with a housing,   The closed housing communicates the air reservoir with the outside of the closed housing. Having a wall with a limited type of flow passage,   The limited flow passage may satisfy the low current capacity requirement of the electric device. Is formed in a size such that a predetermined amount of air flows through the air storage portion, ,   By delaying the movement of water vapor between the air storage section and the outside of the battery, the air storage The operating life of the metal-air battery can be extended by adjusting the humidity inside the A container for electrical equipment that uses a metal-air battery. 2. The limited flow passage having at least one hole formed in the wall. 1 container. 3. The limited flow passage is a hole formed in the wall of the housing, 2. The container of claim 1, wherein the diameter is in the range of 0.05 mm to 0.1 mm.

────────────────────────────────────────────────── ─── Continuation of front page    (72) Inventor Couple, William             06762, Connecticut, United States,             Middlebury, Breakneck Hill             552 (72) Inventor Bennett, Leonard             United States, Florida 33317, Pula             Station, South West Fif             Ti Sixth Avenue 1641

Claims (1)

[Claims] 1. In and out of high current capacity metal-air batteries connected to electrical equipment requiring low average current A container for suppressing entry and exit of water vapor, wherein the metal-air battery and the electric machine are provided. The container is housed in the container, and the metal-air battery allows the inflow of oxygen. Air inflow portion,   The container is a sealed housing forming an air reservoir having the metal-air battery. Wherein the closed housing communicates the air reservoir with the outside of the housing. And the air storage so as to satisfy the low average current requirement of the electric device. Forming a limited-type flow passage sized to allow a predetermined amount of air to flow therethrough A container for electric equipment employing a metal-air battery and having a wall. 2. The limited flow passage having at least one hole formed in the wall. 1 container. 3. The limited flow passage is a hole formed in the wall of the housing, 2. The container of claim 1, wherein the diameter is in the range of 0.05 mm to 0.1 mm. 4. The housing further includes a hydrophobic, gas permeable member. The gas permeable member is provided between the limited flow passage and the outside of the housing. And form the above Preventing the liquid from flowing into the room, and further comprising the low average current of A predetermined amount of oxygen sufficient to satisfy the request can be sent to the solute, The container of claim 1. 5. Removable housing with metal air battery accessible The container according to claim 1, further comprising a cap, wherein the wall is formed on the cap. 6. The housing includes first and second housings for housing the metal-air battery and the electric device. Of each of the first and second compartments can be removed and can access the first compartment. An air reservoir, wherein the air reservoir is disposed in the first chamber. Item 6. The container according to Item 1. 7. High current connected to low average current demand type electrical equipment requiring intermittent high current A container for extending the life of a metal-air battery. Each of the containers is housed in the container, and the metal-air battery Having an air inlet portion sized to allow sufficient air flow to satisfy;   The container is a sealed housing that defines an air reservoir for containing the metal-air battery. Have   The closed housing is in communication with the air reservoir and the outside of the housing. Then, a predetermined air amount sufficient to satisfy the low average current requirement of the electrical equipment is increased. Flow into the air reservoir It has a wall that forms a limited type flow passage sized to be able to The volume of the air reservoir is limited to a predetermined time when the limited flow passage is closed. Use a metal-air battery that is predetermined to satisfy a predetermined average current drain. For electrical equipment used. 8. 8. The limited flow passage having at least one hole formed in the wall. Container. 9. The limited flow passage is a hole formed in the wall of the housing, 8. The container according to claim 7, wherein the diameter is in the range of 0.05 mm to 0.1 mm. 10. The housing further includes a hydrophobic, gas permeable member. The water-based, gas permeable member is located between the limited flow passage and the outside of the housing. A chamber is formed, and liquid is prevented from flowing into the chamber. A predetermined amount of oxygen sufficient to satisfy the low average current requirement of the electric device is added to the solute. The container of claim 7, adapted to be delivered. 11. Removable housing with access to metal air battery The container according to claim 7, further comprising a cap, wherein the wall is formed on the cap. . 12. The housing connects the metal air battery and the electric device. First and second chambers for accommodating are respectively formed, and the first chamber is accessed. A removable cap which can be fitted in the first chamber. The container of claim 7, wherein the container is placed. 13. Perform a timing operation in the range of 2 to 250 mA, and at least One zinc-air high-current battery provides a temporary supply of 2 to 12 mA Electronic watch that requires a current drain to supply a low average current drain A water-resistant watch case housing the movement,   The watch case is hermetically sealed by forming an air reservoir for accommodating zinc-air batteries. With a housing,   The housing has a wall having a hole formed therein, and is hydrophobic for covering the hole. Equipped with a gas-permeable membrane,   The wall forms a limited flow passage communicating the hole and the air reservoir. Yes,   The limited flow passage connects the battery to the air reservoir with the low average current drain. It is designed to deliver a sufficient amount of oxygen that can be operated continuously,   The membrane has a predetermined volume sufficient to operate the battery at the low average current drain. A water-resistant wristwatch case that has oxygen so that oxygen can be sent Source. 14． The limited flow passage is a hole formed in the wall, and has a diameter of 0.08 mm. 14. The container of claim 13, comprising: 15. The hole has a diameter of 1.75 mm, and the membrane is manufactured by GORE-TEX. 14. The container of claim 13, wherein the container is an article. 16. The limited flow passage and the membrane are provided with a low average current dose of the order of 2 mA. 14. The container of claim 13, wherein the container is selected to hold a len.