JP2023092975A - Battery container and battery - Google Patents

Abstract

To provide a battery container and a battery that can be easily filled with high pressure hydrogen gas.SOLUTION: A battery container is used for a battery in which hydrogen gas is sealed and hydrogen is used as an anode active material. The battery container includes an open/close valve for sealing the hydrogen gas within the container. The open/close valve is configured to allow the hydrogen gas to be filled into the container from the outside and to prevent it from escaping from the inside.SELECTED DRAWING: Figure 1

Description

TECHNICAL FIELD The present invention relates to a battery container that can be used for, for example, a nickel-metal hydride battery using hydrogen as a negative electrode active material, and a battery using the same.

Conventionally, a battery described in Patent Document 1, for example, is known as this type of battery using hydrogen as a negative electrode active material. Since hydrogen is enclosed in this battery, the conductive agent made of carbon contained in the positive electrode is not oxidized, and the hydrogen-absorbing alloy in the negative electrode is not oxidized and deteriorated, and has excellent life characteristics. Its configuration is mainly composed of an exterior body (container), a current collecting rod, and an electrode body housed inside the exterior body. and a lid member attached to the opening. The lid member is tightly fitted to the opening of the cylindrical can after the electrode body is accommodated. The lid member is provided with a supply port for supplying the electrolytic solution and hydrogen gas, and a hydrogen gas tank is connected to this supply port so that the interior of the exterior body is filled with hydrogen gas. .

JP 2020-113373 A

However, in the battery described in Patent Document 1, there is only a supply port for filling hydrogen in the cover member, and no specific configuration is described.
An object of the present invention is to provide a battery container and a battery that can be easily filled with high-pressure hydrogen gas.

In order to achieve the above object, the present invention
A battery container for use in a battery in which hydrogen gas is sealed and hydrogen is used as a negative electrode active material,
An opening and closing valve for enclosing the hydrogen gas in the container,
The opening/closing valve is characterized in that the hydrogen gas can be filled into the container from the outside and prevented from flowing out from the inside.
According to the present invention, by using the opening/closing valve, hydrogen gas can be easily filled into the container, and the outflow of the filled hydrogen gas can be reliably prevented by the opening/closing valve.

The present invention can be configured as follows.
1. The opening/closing valve is configured to be opened by pressing from the outside and closed when the pressing is released.
This makes it easier to open and close the valve.
2. A container body having an opening into which an electrode body can be inserted, and a lid closing the opening of the container body are provided, and the lid is provided with the open/close valve.
In this way, it becomes easy to attach the on-off valve to the container.
3. The on-off valve includes a stem movable in a direction protruding to the outside of the lid body and a direction to be retracted into the lid body, a spring biasing the stem in the projecting direction, and a gasket attached to the lid body, wherein the stem is provided with a passage that communicates the outside with the inside of the container, and the passage outlet of the passage on the inside of the container is closed by a gasket when the stem protrudes, and the stem moves toward the retracted position. The passage outlet on the inner side of the container is configured to open.
In this way, it is possible to reliably open and close the stem by moving the stem.
4. The pressure resistance strength of the container is set to 1 MPa or more.
If the pressure resistance is 1 MPa or more, sufficient hydrogen can be filled.

In addition, the battery of the present invention has a configuration in which the electrode assembly is housed in the above-described battery container, and an electrolytic solution and hydrogen are filled therein.

According to the present invention, high-pressure hydrogen gas can be easily filled.

FIG. 1(A) is a schematic cross-sectional view showing a battery in which a battery container according to Embodiment 1 of the present invention is used, and (B) is a partial cross-sectional view showing an exploded view of a container body and a lid in (A). It is a diagram. 2A is a partially enlarged cross-sectional view of a first joint portion of the lid shown in FIG. 1, and FIG. 2B is a partially enlarged cross-sectional view showing a state before joining. 3A is an enlarged cross-sectional view of the on-off valve in FIG. 1 in its closed state, and FIG. 3B is a partially enlarged cross-sectional view in its open state. 4A to 4D are diagrams showing the steps of assembling the battery of FIG. FIG. 5A is an explanatory diagram of the degassing process, and FIG. 5B is an explanatory diagram of the electrolytic solution filling process. FIG. 6 is an explanatory diagram of the hydrogen gas filling process. FIG. 7A is a diagram showing an adapter cap fitted to the inner periphery of the first joint, and FIG. 7B is a diagram showing the adapter cap fitted to the outer periphery of the first joint.

The present invention will be described in detail below based on the illustrated embodiments.
The dimensions, materials, shapes, and relative arrangement of the components described in the following embodiments should be changed as appropriate according to the configuration of the device to which the invention is applied and various conditions, and the scope of the invention is not limited. It is not intended to be limited to the following embodiments.
In the following description, an example in which the battery container of the present invention is applied to a nickel-hydrogen/hydrogen battery will be described. The nickel-metal hydride/hydrogen battery is a battery in which hydrogen gas is sealed in the nickel-metal hydride battery as described in the prior art.

First, with reference to FIG. 1, the overall configuration of a battery using a battery container will be described. FIG. 1A is a schematic cross-sectional view of a battery using a battery container according to Embodiment 1 of the present invention, and FIG. is.
The battery container 100 includes a conductive bottomed cylindrical container main body 10 in which an electrode assembly 50 is housed, and a conductive cover joined to an opening 12 of the container main body 10 via a first joint 41. 20 and an open/close valve 30 provided on the lid body 20 . As materials for the container body 10 and the lid body 20, a conductive metal such as aluminum or steel is used.

In this example, the container body 10 has a cylindrical shape with a bottom, and includes a cylindrical body portion 11, a bottom portion 13 provided at one end of the body portion 11, and a shoulder extending from the other end of the body portion 11 toward the opening portion 12. a portion 15; The container body 10 is divided into three parts, a body part 11, a bottom part 13, and a shoulder part 15. The body part 11 and the shoulder part 15 are joined via a second joint part 42, and the body part 11 and the bottom part 13 are , are joined via a third joint 43 . The diameter of the opening 12 is smaller than that of the body 11, and the diameter of the body is gradually reduced toward the opening 12 via the shoulder 15 (see FIG. 1(B)). A second joint portion 42 where the body portion 11 and the shoulder portion 15 are joined, and a third joint portion 43 where the body portion 11 and the bottom portion 13 are joined are seamed and fixed by double seaming. The second joint portion 42 and the third joint portion 43 are in metal contact, and the trunk portion 11 and the shoulder portion 15 and the trunk portion 11 and the bottom portion 13 are in a conductive state.
Note that the body portion 11 and the shoulder portion 15 may be integrated (a configuration without the second joint portion 42), or the body portion 11 and the bottom portion 13 may be integrated (the third joint portion 43 may be no configuration). Further, the body portion 11, the shoulder portion 15 and the bottom portion 13 may all be integrated (the configuration without the second joint portion 42 and the third joint portion 43). Also, if the diameter of the opening 12 does not need to be reduced, the shoulder 15 is not necessary.

The lid body 20 includes a body portion 21 having a hat-shaped cross section and a joining cylinder portion 24 rising from the outer peripheral edge of the body portion 21 . is joined to The body portion 21 includes a cylindrical central projection portion 22 and a flange portion 23 projecting outward from the base end of the central projection portion 22 . In the illustrated example, the flange portion 23 is inclined downward in a truncated cone shape, but it may be configured to extend horizontally.
In addition, the inner surfaces of the container body 10 and the lid 20 are subjected to a surface treatment that is resistant to the electrolytic solution contained in the container. The surface treatment is a treatment that imparts conductivity, and in this example, the inner surfaces of the container body 10 and the lid 20 are plated with nickel.

Next, the first joint portion 41 will be described with reference to FIG. 2 .
FIG. 2A is a partially enlarged cross-sectional view of a first joint portion, and FIG. 2B is a partially enlarged cross-sectional view showing a state before joining.
As shown in FIG. 2, the first joint portion 41 is fitted to the bead portion 12a provided on the opening edge of the opening portion 12 of the container body 10 and the bead portion 12a provided on the peripheral edge of the lid body 20 and crimped. and an insulator 60 sandwiched between the bead portion 12a and the curl portion 25 to electrically insulate the bead portion 12a and the curl portion 25 from each other.

The bead portion 12a rises from the inner diameter end of the shoulder portion 15 toward the outside of the container and is bent outward to have a circular cross section. The curled portion 25 of the lid body 20 is bent outward from the tip of the joining cylinder portion 24 so as to have an arcuate cross-section. are engaged in The outer periphery of the upper end portion of the joining cylinder portion 24 faces the inner periphery of the bead portion 12a, and is crimped in a direction of expanding radially outward just below a position corresponding to the lower edge of the bead portion 12a. It has a clinch portion 27, and between the clinch portion 27 and the curl portion 25, the outer periphery of the bead portion 12a is gripped from above and below with an insulator 60 interposed therebetween.

The insulator 60 is a rubber-like elastic resin material that does not conduct electricity. It is interposed in the gap, electrically insulates the container body 10 and the lid 20, and seals them to prevent fluid leakage. By having sealing properties, it is possible to reliably seal the electrolytic solution and filled gas such as hydrogen. Moreover, the insulator 60 is made of a resin material that is resistant to the electrolytic solution contained in the container. Further, the surface of the insulator 60 may be coated with a corrosion inhibitor. By applying a corrosion inhibitor, it is possible to prevent leakage due to corrosion of metal joint surfaces.

Next, the opening/closing valve 30 will be described with reference to FIG.
3A is an enlarged cross-sectional view of the on-off valve in FIG. 1 in a closed state, and FIG. 3B is an enlarged cross-sectional view in an open state.
The opening/closing valve 30 is normally closed and can be opened by an external operation to allow filling of the electrolytic solution or hydrogen gas. The open/close valve 30 includes a valve housing 31 fitted to the inner periphery of the central projection 22 of the lid 20, and an insertion hole provided in the top plate portion 22b of the central projection 22 to protrude into the valve housing 31. A stem 32 that can be inserted, a valve hole 33 provided on the side surface of the stem 32, a gasket 34 that seals the valve hole 33 that is opened and closed by movement of the stem 32, and a biasing force for the stem 32 in the protruding direction. a spring 35;
The valve housing 31 has a bottomed cylindrical shape with a nozzle 36 on the bottom 31d. is sealed by a gasket 34. The nozzle 36 may be omitted, and the bottom portion 31d may simply have a through hole. An annular projection 31c projecting outward is provided on the outer circumference of the valve housing 31 in the vicinity of the open end. In addition, the central protruding portion 22 is locally provided with a caulking recess 22a that engages with the edge portion on the bottom side of the annular protruding portion 31c. 22b so as to be sandwiched in the axial direction.

The stem 32 has a large-diameter stem base portion 32a housed in the valve housing 31, and a stem shaft having a smaller diameter than the stem base portion 32a, which protrudes from a hole in the top plate portion 22b of the central projecting portion 22 to the outside through a gasket 34. and a portion 32b. The stem shaft portion 32b is provided with a channel 32c extending from the tip opening portion in the axial direction by a predetermined length, and a valve hole 33, which is a passage outlet on the inside of the container, opens in the side surface near the boundary with the stem base portion 32a. . The valve hole 33 communicates between the flow path 32c and the inside of the valve housing 31, and together with the flow path 32c constitutes a passage that communicates between the external space and the inside of the container.
The stem 32 is normally urged in the protruding direction by the urging force of the spring 35, is in the valve closing position where the valve hole 33 is closed by the inner circumference of the gasket 34, and is always maintained in the valve closed state.
When the stem 32 is pushed relatively inwardly of the container, the inner edge of the gasket 34 bends inwardly of the container, and the inner peripheral surface of the gasket 34 flexes toward the valve hole 33 as shown in FIG. 3(B). The valve opens away from the edge of the hole.
The cover 20 is provided with an explosion-proof valve 85 that releases pressure when the internal pressure becomes abnormally excessive. The explosion-proof valve 85 is configured by, for example, locally providing a thin portion or a fragile portion such as a score.

Next, the electrode assembly 50 will be described with reference to FIG.
The battery of the present embodiment is a nickel-metal hydride battery (a battery in which a nickel-metal hydride battery is filled with hydrogen gas). An aqueous solution of potassium hydroxide, sodium hydroxide, or the like is used as the nickel electrolyte.
The electrode body 50 exemplifies a laminated type. That is, a plurality of positive electrodes 51 and negative electrodes 52 are accommodated in a stacked state inside the container body 10 with separators 53 interposed therebetween. The positive electrode 51 is electrically connected to the container body 10 via a positive current collector 54 , and the negative electrode 52 is electrically connected to the lid 20 via a negative current collector 55 . The separator 53 is impregnated with the electrolytic solution.

The positive electrode current collector 54 has a bottomed cylindrical shape having a tubular portion 54a and a bottom plate portion 54b. The positive electrode 51 is electrically connected to the body portion 11 of the container body 10 through the cylindrical portion 54a of the positive electrode current collector 54, and through the bottom plate portion 54b. , is electrically connected to the bottom portion 13 of the container body 10 .

The negative electrode current collector 55 is a bottomed cylindrical member having a diameter smaller than that of the positive electrode current collector 54 . The negative electrode current collector 55 passes through holes in the washer-shaped positive electrode 51 , the separator 53 and the negative electrode 52 , and the inner edge of the negative electrode 52 is in close contact with the outer periphery of the negative electrode current collector 55 . The lid-side (open side) end of the negative electrode current collector 55 is in contact with and electrically connected to the flange 23 of the lid 20 . The negative electrode current collector 55 is made of, for example, a porous metal with open cells, and the internal space of the negative electrode current collector 55 communicates with the space in which the positive electrode 51, the negative electrode 52, and the separator 53 are arranged. Even if it is not a porous metal, if the negative electrode current collector 55 is provided with a communication path that communicates the internal space of the negative electrode current collector 55 with the space in which the positive electrode 51, the negative electrode 52, and the separator 53 are arranged. good.
The bottom plate portion 54b of the positive electrode current collector 54 and the bottom portion 55b of the negative electrode current collector 55 are insulated by an insulating member (not shown).
The configuration of the electrode assembly 50 is merely an example. For example, the negative electrode current collector 55 may be brought into contact with the on-off valve 30, and various configurations may be employed.

In this embodiment, the shoulder 15 forming the opening 12 of the container body 10 and the first joint 41 of the lid 20 are electrically insulated via the insulator 60, and the body 11 and the shoulder 15 are electrically insulated. , and the third joint 43 between the trunk portion 11 and the bottom portion 13 are in a conductive state.
The negative electrode 52 is electrically connected to the lid 20 via a negative electrode current collector 55 , and the positive electrode 51 is electrically connected to the body portion 11 and the bottom portion 13 via a positive electrode current collector 54 .
Therefore, the on-off valve 30 and the lid body 20 serve as the negative electrode region N1, and the entire container body 10 including the shoulder portion 15, the trunk portion 11 and the bottom portion 13 serves as the positive electrode region P1. The negative electrode region N1 and the positive electrode region P1 can be used as negative and positive power supply terminals. As the power supply terminal, any position of the negative electrode region N1 and the positive electrode region P1 can be used as a terminal, or a specific region can be used as a terminal by partially covering it with an insulating film or the like.
Further, the heat generated in the electrode body 50 is efficiently dissipated through the trunk portion 11 in contact with the cylindrical portion 54a of the positive electrode current collector 54 and the bottom portion 13 in contact with the bottom plate portion 54b.

Next, an example of a battery assembly process will be described with reference to FIG.
First, the trunk portion 11 and the bottom portion 13 of the container body 10 are joined to form the first preform 10A (see FIGS. 4A and 4B). A third joint 43 between the body portion 11 and the bottom portion 13 is double seamed.
Next, the electrode assembly 50 is housed from the opening of the trunk portion 11 of the first preform 10A, the shoulder portion 15 is joined to the opening of the trunk portion 11, and the container in which the electrode assembly 50 is housed is formed. The main body 10 is molded (see FIGS. 4B and 4C). A second joint portion 42 between the body portion 11 and the shoulder portion 15 is also double seamed.
Next, the lid 20 with the on-off valve 30 pre-assembled is joined to the opening 12 of the shoulder 15 of the container body 10 to complete the assembly of the battery (see FIGS. 4(C) and 4(D)). . The first joint portion 41 between the shoulder portion 15 and the lid body 20 is joined by clinch processing.

After the assembly of the battery is completed, the inside of the container is filled with an electrolytic solution and then filled with hydrogen gas.
5 and 6 schematically show the filling process of the electrolytic solution and hydrogen gas, FIG. 5A is the degassing process, FIG. 5B is the filling process of the electrolytic solution, and FIG. shows the filling process.
First, the inside of the battery is degassed (vacuum) before filling the electrolyte solution.
In this degassing step, as shown in FIG. 5A, the on-off valve 30 is opened and the air inside the battery is sucked by a suction pump (not shown). That is, air in the internal space of the battery is sucked into the inside of the negative electrode current collector 55, as indicated by the dashed arrow in the figure, and the nozzle 36 of the on-off valve 30, the gap between the valve housing 31 and the stem base 32a, and the valve hole 33, it flows out to the outside through the channel 32c of the stem shaft portion 32b.
The negative pressure acting on the container body 10 during vacuuming is retained by the positive electrode current collector 54 of the electrode assembly 50 shown in FIG. 1, and deformation of the container body 10 is prevented.

After the vacuum is finished, the electrolyte is filled.
As shown in FIG. 5B, the electrolytic solution is filled with a predetermined amount of electrolytic solution from an electrolytic solution supply line (not shown) while the on-off valve 30 is open. The electrolyte is supplied by a supply pump (not shown). Contrary to degassing, the electrolyte flows through the flow path 32c of the stem shaft portion 32b, the valve hole 33, the gap between the valve housing 31 and the stem base portion 32a, and the bottom portion of the valve housing 31, as indicated by solid arrows in the drawing. It flows into the negative electrode current collector 55 through the nozzle 36 . The electrolytic solution that has flowed into the inside of the negative electrode current collector 55 passes through the wall surface of the negative electrode current collector 55 and flows into the internal space of the container, and is held in a state of being impregnated in the separator 53 shown in FIG.

When the filling of the electrolytic solution is completed, the process proceeds to the degassing step before filling the hydrogen gas.
In the degassing step, as shown in FIG. 5A, the air inside the battery, ie, oxygen and nitrogen, is degassed again with the on-off valve 30 open. In this embodiment, the separator 53 is impregnated with the electrolytic solution, but if the electrolytic solution is retained, it is air in the head space excluding the electrolytic solution.

After the degassing process is completed, hydrogen gas is filled.
In the hydrogen gas filling step, as shown in FIG. 6, hydrogen gas is supplied from a hydrogen gas supply source (not shown) while the on-off valve 30 is open. Hydrogen gas passes through the flow path 32c of the stem shaft portion 32b, the valve hole 33, the gap between the valve housing 31 and the stem base portion 32a of the stem 32, and the nozzle 36 at the bottom of the valve housing 31, as indicated by the dashed arrows in the drawing. It flows into the internal space of the negative electrode current collector 55 . The hydrogen gas that has flowed into the negative electrode current collector 55 flows into the inner space of the container through the wall surface of the negative electrode current collector 55, and the inside of the container is filled with hydrogen.

The pressure of the hydrogen gas to be enclosed is preferably at least 1 MPa, and preferably at least 1 MPa. The pressure resistance of the container is set to 1 MPa or higher, which is higher than the gas pressure of hydrogen gas. The compressive strength of a container is the pressure at which buckling does not occur due to the internal pressure of the container. The buckling is a deformation in which the corners of the flange portion 23 and the joining cylinder portion 34 of the lid body 20 are turned outward, for example, as indicated by a two-dot chain line in FIG. 3(A). The operating pressure of the explosion-proof valve 85 is greater than the pressure resistance, and when the internal pressure exceeds the pressure resistance, buckling occurs in the lid body 20. When the internal pressure further increases and exceeds a predetermined pressure, the explosion-proof valve 85 operates, causing the container to break. Material leakage is prevented. If the pressure of hydrogen gas is about 1 MPa, the pressure at which the explosion-proof valve 85 operates is set to about 1.2-1.5 MPa.
Even if the gas pressure acts, the first joint 41 between the lid 20 and the container body 10 has a curled portion 25 that is fitted into the bead portion 12a and crimped to secure high joint strength. High pressure resistance can be maintained. Furthermore, by sandwiching the insulator 60 between the bead portion 12a and the curled portion 25, the insulator 60 can be securely fixed, and the reliability of the insulation can be improved.

The hydrogen gas filled in the container is absorbed by the hydrogen absorbing alloy of the negative electrode 52, and the negative electrode 52 reaches a fully charged state. 20, gaps between the positive electrode 51, the negative electrode 52, and the separator 53, gaps between the negative electrode current collector 55 and the separator 53, the positive electrode 51, gaps between the positive electrode current collector 54, the separator 53, and the negative electrode 52. state.
When charging is performed in this state, hydrogen gas is generated from the negative electrode 52 . Since the on-off valve 30 is in a closed state, the hydrogen gas concentration inside the battery increases as charging progresses, the potential of the negative electrode 52 decreases, and as a result, the terminal voltage increases. At this time, oxygen generated at the positive electrode is combined with hydrogen to form water due to the hydrogen gas held in the gaps in the container, and the oxidation of the conductive agent of the positive electrode 51 and the oxidation of the hydrogen storage alloy of the negative electrode 52 are prevented. be.

About Adapter Cap FIG. 7 shows an adapter cap that is applied to the first joint portion 41 of the battery container of the above-described embodiment. FIG. 7A shows an adapter cap of a first example that fits on the inner periphery of the first joint portion 41, and FIG. 7B shows an adapter cap of a second example that fits on the outer periphery of the first joint portion. be.
First, the adapter cap 81 of the first example will be described with reference to FIG. 7(A).
The adapter cap 81 is made of metal and has a hat-shaped cross section. and a locking tube portion 81c that hangs down at a right angle from the outer edge. An engaging protrusion 81d that protrudes outward is provided on the lower edge of the locking tubular portion 81c. The outer periphery of the locking cylinder portion 81c is fitted to the inner periphery of the first joint portion 41, and the engaging protrusion 81d is clinched with the collar portion 81b in contact with the end surface of the central projecting portion 22 of the lid body 20. It engages with the inner circumference of the portion 27 and is fixed vertically.

Next, a second example of the adapter cap 82 will be described with reference to FIG. 7(B).
The adapter cap 82 is also made of metal and has a hat-shaped cross section. and a locking tube portion 82c that hangs down at a right angle from the outer edge. An engaging protrusion 82d that protrudes inward is provided on the lower edge of the locking tube portion 82c. The inner periphery of the locking cylinder portion 82c is fitted to the outer periphery of the first joint portion 41, and the engagement protrusion 82d is engaged with the first joint portion 41 with the collar portion 82b in contact with the upper end of the curled portion 25 of the first joint portion 41. It engages with the lower end of the curled portion 25 of the 1 joint portion 41 and is fixed in the vertical direction.
These adapter caps 81, 82 protect the stem 32 and prevent the stem 32 from being pushed inadvertently. Since the adapter caps 81 and 82 are in contact with the lid 20, they are electrically connected to the lid 20 and also function as battery terminals.

In addition, although the nickel-metal hydride battery has been described in the above embodiment, the positive electrode may be a metal oxide such as manganese dioxide, and is not limited to the nickel-metal hydride battery. INDUSTRIAL APPLICABILITY The present invention is applicable to secondary batteries in which the negative electrode active material is hydrogen and hydrogen gas is enclosed.

REFERENCE SIGNS LIST 10 container body 10A first preform 11 body 12 opening 12a bead 13 bottom 15 shoulder 20 lid 21 main body 22 central protrusion 22a recess 22b top plate 23 collar Part 24 Joint Cylinder Part 25 Curl Part 27 Clinch Part 30 Opening/Closing Valve 31 Valve Housing 31a Opening End 31c Annular Convex Part 31d Bottom Part 36 Nozzle 32 Stem 32a Stem Base Part 32b Stem Shaft Part 32c Flow Path 33 Valve hole,
34 Gasket 35 Spring 41 First joint 42 Second joint 43 Third joint 50 Electrode assembly 51 Positive electrode 52 Negative electrode 53 Separator 54 Positive electrode current collector 54a Cylindrical portion 54b Bottom plate portion 55 Negative electrode current collector Body 55a Small-diameter tubular portion 55b Bottom portion 60 Insulator 81 Adapter cap 81a Central protrusion 81b Collar 81c Locking cylinder 81d Engagement protrusion 82 Adapter cap 82a Central protrusion 82b Collar 82c Engagement Stop cylinder portion 82d Engagement protrusion 85 Explosion-proof valve 100 Battery container N1 Negative electrode region P1 Positive electrode region

Claims (6)

A battery container for use in a battery in which hydrogen gas is sealed and hydrogen is used as a negative electrode active material,
An opening and closing valve for enclosing the hydrogen gas in the container,
The battery container, wherein the opening/closing valve is configured to allow the hydrogen gas to be filled from the outside into the container and to prevent the hydrogen gas from flowing out from the inside. 2. The battery container according to claim 1, wherein said on-off valve is opened by pressing from the outside and closed when the pressing is released. 3. The apparatus according to claim 1, further comprising a container body having an opening into which an electrode body can be inserted, and a lid closing said opening of said container body, said lid being provided with said open/close valve. battery container. The open/close valve includes a stem that can move in a direction of projecting to the outside of the lid and a direction of retracting into the lid, a spring that biases the stem in the projecting direction, and a gasket that is attached to the lid. The stem is provided with a passage that communicates the outside with the inside of the container, and the passage outlet of the passage on the inside of the container is closed by the gasket when the stem protrudes and is closed on the stem retracted position side. 4. The battery container according to claim 3, wherein the movement of the stem to the inside of the container opens the passage outlet. 5. The battery container according to any one of claims 1 to 4, wherein the pressure resistance is set to 1 MPa or more. 6. A battery comprising an electrode body housed in the battery container according to any one of claims 1 to 5 and filled with an electrolytic solution and hydrogen.

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