DE112017001765T5 - ELECTRICITY STORAGE DEVICE - Google Patents

Abstract

This power storage device has a housing housing an electrode assembly and an electrolytic solution, and a pressure relief valve provided in a wall of the housing. The electrode assembly has electrodes that have different polarities and are insulated from each other. A shield member is disposed between the inner surface of the wall and the end surface of the electrode assembly. A point located in a center of the housing in a front view of the housing taken in the stacking direction of the electrodes and located at a center of a dimension of the electrode assembly in the stacking direction is referred to as a center, and an area surrounded by a plane connecting the center and a contour of the pressure release valve at a shortest distance is called a three-dimensional area. The shielding member has a shielding portion that completely covers a cross section of the three-dimensional area along the end surface of the electrode assembly.

Description

TECHNICAL AREA

The present invention relates to a power storage device having a pressure relief valve.

STATE OF THE ART

A rechargeable battery, such as a lithium-ion battery, stores as a power storage device that stores power supplied to an electric motor, which is a prime mover, in a vehicle such as an electric vehicle (EV), a plug-in hybrid vehicle (PHV) or the like installed. Patent Document 1 describes an example of a rechargeable battery that houses an electrode assembly and an electrolytic solution in a housing. A pressure relief valve or pressure relief valve is disposed in the wall of the housing to release pressure from the housing.

DOCUMENTS OF THE STATE OF THE ART

Patent Document

PATENT DOCUMENT 1: Japanese Patent No. 4881409

SUMMARY OF THE INVENTION

PROBLEMS TO BE SOLVED BY THE INVENTION

When a nail penetration test, which is a kind of evaluation test, is performed on such a rechargeable battery, a nail breaks a separator, which is located between a positive electrode and a negative electrode. This shorts the positive electrode and the negative electrode in the housing. When such shorting occurs, heat is generated around the shorted part. The heat decomposes the electrolytic solution component and generates gas in the housing. This can raise the pressure in the housing and rupture the pressure relief valve. When the gas is released from the housing by the pressure release valve, parts of the electrodes may be scraped off by the high-pressure gas, and these parts of the electrodes may be led out of the gas and scattered as fragments.

It is an object of the present invention to provide an electrical storage device which prevents scattering of electrode fragments from the open pressure relief valve during the nail penetration test.

MEDIUM TO SOLVE THE PROBLEM

A power storage device solving the above problem has an electrode assembly with a layered structure, an electrolytic solution, a housing housing the electrode assembly and the electrolytic solution, and a pressure relief valve provided in a wall of the housing. The electrode assembly has electrodes that are insulated from each other and have different polarities. The pressure relief valve is configured to be ruptured when a pressure in the housing reaches a relief pressure to release the pressure from the housing. The power storage device includes a shield member located between an inner surface of the wall and an end surface of the electrode assembly facing the inner surface. An axis extending in a stacking direction of the electrodes is referred to as an X axis, an axis orthogonal to the X axis, and parallel to the wall is referred to as a Y axis, a point located in a center of the X axis Housing located in a front view of the housing taken in an X-axis direction and located in a center of a dimension of the electrode assembly in the X-axis direction is referred to as a center point and an area where which is surrounded by a plane connecting the center and a contour of the pressure relief valve in a shortest section is referred to as a three-dimensional area. The shielding member has a shielding portion that completely covers a cross section of the three-dimensional area along the end surface of the electrode assembly.

Therefore, when the nail is pricked through the center of the housing in a front view during the nail penetration test, the nail short-circuits the electrodes of different polarities. When a short circuit occurs, heat is generated in the vicinity of the shorted part. This decomposes the electrolytic solution component and generates gas. The generation of gas raises the pressure in the power storage device. Then, when the internal pressure of the case reaches the relief pressure of the pressure release valve, the pressure release valve is torn open and the gas in the case is discharged from the case.

The high-pressure gas generated at the short-circuited part exits through the three-dimensional region from the midpoint and flows to the opened pressure relief valve. The force of the generated gas breaks up parts of the electrodes and generates fragments. The shielding portion is located between the opened pressure relief valve and the cross section of the three-dimensional area and covers the entire cross-sectional plane. Accordingly, the gas discharged from the electrode assembly from the cross-section of the three-dimensional area strikes against the shielding portion. This changes the direction of the gas flowing to the pressure release valve and extends the gas discharge path extending toward the pressure release valve. As a result, the electrode fragments fall out of the gas. This limits the electrode fragments from being scattered from the housing by the open pressure relief valve.

A power storage device solving the foregoing problem has an electrode assembly with a layered structure, an electrolytic solution, a housing housing the electrode assembly and the electrolytic solution, and a pressure relief valve provided in a wall of the housing. The electrode assembly has electrodes that are insulated from each other and have different polarities. The pressure relief valve is configured to be ruptured when a pressure in the housing reaches a relief pressure to vent the pressure from the housing. The power storage device includes a shield member located between an inner surface of the wall and an end surface of the electrode assembly facing the inner surface. An axis extending in a stacking direction of the electrodes is referred to as an X axis, an axis orthogonal to the X axis, and parallel to the wall is referred to as a Y axis, a plane passing through a center of the housing in a front view of the housing taken in a direction of the X-axis and parallel to the end face of the electrode assembly, is called a hypothetical plane, a line reflecting a straight line, the two ends of the A pressure relief valve in a Y-axis direction at the hypothetical plane, when viewed from an outer surface of the wall, is referred to as a hypothetical line, a plane formed by reflecting the hypothetical line completely across a dimension of the electrode assembly in FIG is formed in the direction of the X-axis is referred to as a ground plane, and an area passing through a plane that is a contour of the Bo The plane and a contour of the pressure relief valve connects in a shortest distance is referred to as a three-dimensional area. The shielding member has a shielding portion covering the entire cross section of the three-dimensional area along the end face of the electrode assembly.

Therefore, when the nail is pricked through the center of the housing in a front view during the nail penetration test, the nail short-circuits the electrodes of different polarities. When a short circuit occurs, heat is generated in the vicinity of the shorted part. This decomposes the electrolytic solution component and generates a gas. The generation of gas raises the pressure in the power storage device. Then, when the internal pressure of the case reaches the relief pressure of the pressure release valve, the pressure release valve is torn open and the gas in the case is discharged from the case.

The high pressure gas generated at the shorted part passes through the three dimensional area from any given location in the ground plane and flows to the opened pressure relief valve. The force of the generated gas scrapes off parts of the electrodes and generates fragments. The shielding portion is located between the opened pressure relief valve and the cross section of the three-dimensional area and covers the entire cross-sectional plane. Accordingly, the gas discharged from the electrode assembly from the cross section of the three-dimensional area strikes against the shielding portion. This changes the direction of the gas flowing to the pressure release valve and extends the gas discharge path extending toward the pressure release valve. As a result, the electrode fragments fall out of the gas. This limits the electrode fragments from being scattered from the housing by the open pressure relief valve.

The shielding member may include a spacer on the shielding portion to contact a portion in the inner surface of the wall surrounding the pressure relief valve to space the shielding portion and the wall apart from each other.

Therefore, if the shielding portion receives the gas pressure generated in the housing, the spacer is in contact with the wall and keeps the shielding portion and the wall in a spaced state. Accordingly, even though the shield member is located between the electrode assembly and the wall, a flow path of gas toward the pressure release valve is obtained and the pressure release valve maintains the function of discharging gas from the housing.

The spacer is a plurality of spacer bars formed to protrude from the shielding portion.

Therefore, the flow path of the gas between the adjacent spacer bars is obtained and the pressure release valve maintains the function of discharging gas from the housing.

The spacer is a rib protruding toward the wall from an edge of the shielding portion extending in a direction of the Y-axis. Therefore, during the nail penetration test, the electrode assembly is expanded in the stacking direction (X-axis direction) and the gas flows to the pressure release valve in the stacking direction. The gas hits the rib and electrode fragments fall out of the gas.

A power storage device solving the above problem has an electrode assembly with a layered structure, an electrolytic solution, a housing housing the electrode assembly and the electrolytic solution, and a pressure relief valve provided in the wall of the housing. The electrode assembly has electrodes that are insulated from each other and have different polarities. The pressure relief valve is configured to be ruptured when a pressure in the housing reaches a relief pressure to vent the pressure from the housing. The power storage device has a shielding member located between an inner surface of the wall and an end surface of the electrode assembly facing the inner surface. An axis extending in a stacking direction of the electrodes is referred to as an X axis, an axis orthogonal to the X axis, and parallel to the wall is referred to as a Y axis, a point located in a center of the X axis Housing is located in a front view of the housing, which is taken in an X-axis direction and is located in a center of a dimension of the electrode assembly in the X-axis direction, is referred to as a center, and a region which is from a Surrounded plane that connects the center and a contour of the pressure relief valve in a shortest distance is referred to as a three-dimensional area. The shielding member has a shielding portion partially covering a cross section of the three-dimensional area along the end face of the electrode assembly. The shield member further includes a rib which contacts a portion in the inner surface of the wall surrounding the pressure relief valve to space the shield portion and the wall apart, the rib projecting toward the wall from an edge of the shield portion which extends extends in a direction of the Y-axis.

Therefore, when the nail is pricked through the center of the housing in a front view during the nail penetration test, the nail short-circuits the electrodes of different polarities. When a short circuit occurs, heat is generated in the vicinity of the shorted part. This decomposes the electrolytic solution component and generates a gas. The generation of gas raises the pressure in the power storage device. Then, when the internal pressure of the housing reaches the discharge pressure of the pressure release valve, the pressure release valve is torn open and the gas in the housing is discharged from the housing.

The high pressure gas generated at the shorted part exits the center through the three-dimensional space and flows to the opened pressure relief valve. The force of the generated gas scrapes or scrapes off parts of the electrodes and generates fragments or fragments. The shielding portion is located between the opened pressure relief valve and the cross section of the three-dimensional area and partially covers the cross section. Accordingly, the gas discharged from the electrode assembly from the cross-section of the three-dimensional area strikes against the shielding portion. This changes the direction of the gas flowing toward the pressure release valve and extends the gas discharge path extending toward the pressure release valve. As a result, the electrode fragments fall out of the gas. This limits the electrode fragments scattered from the housing from the open pressure relief valve.

A power storage device solving the foregoing problem has an electrode assembly with a layered structure, an electrolytic solution, a housing housing the electrode assembly and the electrolytic solution, and a pressure release valve provided in a wall of the housing. The electrode assembly has electrodes that are insulated from each other and have different polarities. The pressure relief valve is configured to be ruptured when a pressure in the housing reaches a relief pressure to vent the pressure from the housing. The power storage device has a shielding member located between an inner surface of the wall and an end surface of the electrode assembly facing the inner surface. An axis extending in a stacking direction of the electrodes is referred to as an X axis, an axis orthogonal to the X axis, and parallel to the wall is referred to as a Y axis, a plane passing through a center of the housing in a front view of the housing, which is taken in a direction of the X-axis and parallel to the End surface of the electrode assembly is called, is referred to as a hypothetical plane, a line that reflects a straight line connecting two ends of the pressure relief valve in a direction of the Y-axis on the hypothetical plane, when from an outer surface of the wall is regarded as a hypothetical line, a plane formed by reflecting the hypothetical line completely over a dimension of the electrode assembly in the direction of the X-axis is referred to as a ground plane and an area derived from is surrounded by a plane connecting a contour of the ground plane and a contour of the pressure relief valve in a shortest distance is referred to as a three-dimensional area. The shielding member has a shielding portion that partially covers a cross section of the three-dimensional area along the end surface of the electrode assembly. The shielding member further includes a rib that contacts a portion in the inner surface of the wall that surrounds the pressure relief valve to space the shielding portion and the wall from each other. The rib protrudes toward the wall from an edge of the shielding portion extending in a direction of the Y-axis.

Therefore, when the nail is pricked through the center of the housing in a front view during the nail penetration test, the nail short-circuits the electrodes of different polarities. When a short circuit occurs, heat is generated in the vicinity of the shorted part. This decomposes the electrolytic solution component and generates a gas. The generation of gas raises the pressure in the power storage device. Then, when the internal pressure of the housing reaches the discharge pressure of the pressure release valve, the pressure release valve is torn open and the gas in the housing is drained from the housing.

The high pressure gas generated at the shorted part exits through the three dimensional area from a given location in the ground plane and flows to the opened pressure relief valve. The force of the generated gas scrapes or scrapes off parts of the electrodes and generates fragments. The shielding portion is located between the opened pressure relief valve and the cross section of the three-dimensional area and partially covers the cross section. Accordingly, the gas discharged from the electrode assembly from the cross-section of the three-dimensional area strikes against the shielding portion. This changes the direction of the gas flowing toward the pressure release valve and extends the gas discharge path extending toward the pressure release valve. As a result, the electrode fragments fall out of the gas. This limits the electrode fragments scattered out of the housing from the open pressure relief valve.

The rib may protrude from each of two edges of the shielding portion extending in the direction of the Y-axis.

Therefore, even if gas flows toward the pressure release valve from the two ends of the electrode assembly in the stacking direction (X-axis direction), the gas hits the ribs and electrode fragments fall out of the gas. This limits the electrode fragments scattered from the housing from the open pressure relief valve.

The shielding member may further include a rib protruding toward the wall from the edge of the shielding portion extending in the X-axis direction.

Therefore, even if gas flows toward the pressure release valve in the Y-axis direction, the gas hits the rib and electrode fragments fall out of the gas. This limits the electrode fragments scattered from the housing by the open pressure relief valve.

The rib protruding from the edge of the shielding portion extending in the direction of the X-axis may have a gas passage hole.

Therefore, when the gas hits the rib, electrode fragments fall out of the gas. The gas passes through the gas passage hole and is discharged from the housing from the opened pressure release valve. That is, the gas passage hole functions to remove electrode fragments that will cause sparks. This limits electrode fragments scattered from the housing with the gas and avoids the generation of sparks.

The power storage device may further include a reinforcing rib connected to the shielding portion and the rib.

Therefore, the reinforcing rib reinforces the shielding portion and the rib and prevents deformation of the shielding member when the gas strikes against the shielding member.

Preferably, when the shield member is viewed from a side of the wall where the electrode assembly is toward the inner surface of the wall, the rib is within a plane defined by a contour of the shield portion.

Therefore, the shielding member is free from a flange shaped to protrude from the outer surface of the rib to fix the shielding member to the wall. Compared with when a flange is used to fix the shield member to the wall, the space between the end face of the electrode assembly and the wall can be widened so that the pressure in the housing does not rise slightly.

The shielding member may be in the form of a box and have a central axis extending in a direction of the Y-axis. The shielding member has a gas inlet provided in an opening at one axial end, a gas outlet open to the pressure release valve in another axial end, and a sheet changing wall extending in a gas path from the one Gas inlet is located to the gas outlet.

Therefore, the gas, which is changed in one direction when it strikes against the shielding portion, flows into the shielding member from the gas inlet. In the gas path from the gas inlet to the gas outlet, the gas is changed in a flow direction through the sheet changing wall and hits against the wall surface of the shielding member. Then, the gas flows out of the shielding member from the gas outlet and is discharged from the housing from the depressurizing valve.

Therefore, the arrangement of the web changing wall on the shielding member increases the number of times the gas strikes against the shielding member, so that the electrode fragments fall out of the gas. This limits the electrode fragments that are distributed from the housing with the gas and avoids the generation of sparks.

The electrodes of different polarities are a positive electrode and a negative electrode. The positive electrode and the negative electrode have a positive electrode strip and a negative electrode strip, respectively, and the positive electrode strip is shaped to protrude from the end surface of the electrode assembly. The current storage device further includes a positive electrode conductor member connected to the positive electrode tab and a negative electrode conductor member connected to the negative electrode tab. The positive electrode tab and the positive electrode lead member may have a lower melting point than the negative electrode tab and the negative electrode lead member. The positive electrode lead member and the negative electrode lead member are pulled in a direction of the Y axis. The shield member may include a rib extending in the X-axis direction and being toward the positive electrode lead member from the pressure release valve. A trajectory of gas directed in a planar direction of the wall toward the pressure relief valve from a side on which the positive electrode conduit member is located defines a positive electrode side gas discharge path and a trajectory of the gas in the planar direction of the wall leading to the Pressure relief valve is directed from one side, on which the negative electrode line member is located defines a negative Elektrodenseitengasabgabebahn. A flow path resistance generated with respect to the gas in the positive-electrode side gas discharge path may be larger than a flow path resistance generated with respect to the gas in the negative-electrode side gas delivery path.

During the nail penetration test, when gas strikes between the positive electrode strips and the positive electrode lead member, a part of at least one of the positive electrode tab and the positive electrode lead member may be melted or scraped off by the high-temperature high-pressure gas and suspended in the gas. Even in such a case, the fragments of the positive electrode tab and the positive electrode lead member discharged from the case are limited because the gas strikes against the rib. The flow path resistance of the positive side gas discharge path is large. Therefore, gas flows to the side on which the negative electrode line member is located through the negative side gas discharge path. The flow path resistance of the negative-electrode side gas discharge path is smaller than the flow path resistance of the positive-electrode side gas delivery path. Accordingly, the gas easily flows to the pressure release valve. This limits increases in the pressure of the housing.

The positive electrode side gas discharge path may have a flow path area smaller than that of the negative side gas discharge path. Each gas discharge path is a path connecting the end surface of the electrode assembly and the pressure release valve, and the difference in length between the paths is not large. Accordingly, the difference in the flow path area determines how easily gas flows. The flow path area of the positive electrode side gas delivery path is smaller than the flow path area of the negative side gas discharge path. Accordingly, the gas easily flows to the negative side gas discharge path.

The rib may have a projection end projecting from the shielding portion toward the wall to a position beyond the positive electrode conduction member.

Therefore, during the nail penetration test, when gas passes between the positive electrode strips and strikes the positive electrode lead member, even if the positive electrode lead member is partially melted or scraped off by the high-temperature and high-pressure gas, the gas hits the fin. This limits fragments that are dispensed out of the housing.

The projection end of the rib may be spaced from the inner surface of the wall. Therefore, the gas from the side on which the positive electrode line member is appropriately discharged from the housing from the pressure release valve through the positive Elektrodenseitengasabgabebahn, while the flow path resistance of the positive Elektrodenseitengasabgabebahn is set to be greater than the flow path resistance of the negative Elektrodenseitengasabgabebahn. This limits excessive increases in the pressure increase of the housing.

The power storage device may include a movement restricting member restricting movement of the shielding member in the Y-axis direction between the inner surface of the wall and the end surface of the electrode assembly.

Therefore, the position of the shielding member can be maintained by the movement restricting member, and a state in which the cross section of the three-dimensional area is covered with the shielding portion can be maintained.

The movement restricting member restricting movement of the shielding member toward the positive electrode lead member may be the positive electrode lead member, and the movement restricting member restricting movement of the shielding member toward the negative electrode lead member may be a stripe group formed by collecting the negative electrode strips in the Direction of the X-axis is designed.

Therefore, the movement of the shield member with the component provided in the housing such as the positive electrode lead member and the negative electrode tab group can be restricted.

The movement restricting member restricting movement of the shielding member toward the positive electrode lead member is the positive electrode lead member, and the movement restricting member restricting movement of the shielding member toward the negative electrode lead member is the negative electrode lead member.

Accordingly, the movement of the shield member can be restricted with components provided in the housing, such as the positive electrode lead member and the negative electrode lead member. The positive electrode tab and the negative electrode tab may protrude from the end face of the electrode assembly and may be spaced from each other in the Y-axis direction. The shielding member may include a baffle plate that overlaps the positive electrode tab and the negative electrode tab when viewed from an outer surface of the wall and covers the positive electrode tab and the negative electrode tab along the Y axis.

Therefore, when gas is discharged from between strips adjacent to each other in the stacking direction of the electrodes, the gas strikes against the baffle plate so that electrode fragments fall out of the gas.

One of the positive electrode lead member and the negative electrode lead member may have an overlapping portion overlapping the wall and the shielding portion when viewed from an outer surface of the wall.

Therefore, the gas generated during the nail penetration test is changed in one direction as it strikes against the shielding portion, enters between the two mating surfaces of the overlapping portion of the conductive member from one of the positive electrode lead member and the negative electrode lead member and the shielding portion, and flows the pressure relief valve. As a result, the high temperature gas is less likely to contact the wall due to the overlapping portion.

The one of the piping members has a bent portion that is bent so that the overlapping portion is directed toward the depressurizing valve.

Therefore, the gas generated during the nail penetration test is changed in a direction as it strikes against the shielding portion and enters between the mating surfaces of the overlapping portion of the piping member and the shielding portion toward the pressure release valve. The overlapping portion is formed such that the bent portion extends toward the pressure release valve. Accordingly, the gas flows along the overlapping portion toward the pressure release valve in a preferred manner.

A center position of the pressure release valve in the Y-axis direction may be closer to the negative electrode lead member than a center position between the positive electrode tab and the negative electrode tab in the Y-axis direction.

During the nail penetration test, when gas enters between the positive electrode strips and strikes the positive electrode lead member, at least one of the positive electrode tab and the positive electrode lead member is partially melted or scraped by the high-temperature high-pressure gas and dissolved or suspended in the gas , Even in such a case, fragments of the positive electrode tab and the positive electrode lead member are not discharged from the case because the gas hits the wall. Since the depressurizing valve is closer to the negative electrode line member, the positive side gas discharge pathway is longer than the negative side gas discharge pathway and the positive electrode side gas delivery pathway resistance increases. Accordingly, the gas flows to the side on which the negative electrode lead member is located, and easily flows through the negative electrode side gas discharge path and the negative electrode side gas discharge path, respectively.

A gap may be formed between the positive electrode tab and the rib in the Y-axis direction. In this case, a gas striking member may cover the gap from a side of the wall where the gap is located.

Therefore, during the nail penetration test, the generated gas flows through the gap between the rib of the shielding member and the positive electrode tab. Accordingly, the positive electrode strip resists melting as compared with when the gas flows between the positive electrode strips. Further, since the gas flowing through the gap strikes the gas striking member, fragments of the positive electrode tab and the positive electrode lead member discharged from the case are restricted.

The shielding member may be spaced from an inner surface of the housing.

Therefore, the shield member causes electrode fragments to fall out of the gas without closing the pressure release valve and without hindering the operation of the pressure release valve.

The shielding member may be disposed on the end surface of the electrode assembly.

Accordingly, the gas discharged from the electrode assembly out of the cross-section of the three-dimensional area can strike directly against the shielding portion. The direction of the gas to the pressure relief valve is changed rapidly and the gas discharge path to the pressure release valve can be extended rapidly.

The shielding member may be made of metal. This limits melting of the shielding member that would be caused by the high temperature, high pressure gas generated during the nail penetration test.

The shielding member may be heat resistant. For example, if the shielding member is made of metal, a coating and the like of an insulating resin or ceramics would have to be performed on the surface of the shielding member so that the shielding member is not short-circuited to the housing and the electrodes. In this regard, the heat resistance of the shielding component eliminates the need for coating the insulation.

The inner surface of the shielding member has a flat planar shape. Therefore, the gas generated during the nail penetration test easily flows to the pressure release valve in the shielding member.

A power storage device solving the foregoing problem has an electrode assembly with a layered structure, an electrolytic solution, a housing housing the electrode assembly and the electrolytic solution, and a pressure release valve provided in a wall of the housing. The electrode assembly has electrodes that are insulated from each other and have different polarities. The pressure relief valve is configured to be ruptured when a pressure in the housing reaches a relief pressure to vent the pressure from the housing. The power storage device further includes a shield member that is closer to the electrode assembly than to the pressure relief valve. The shielding member has a shielding portion, which the pressure release valve of a Side of the wall, on which the electrode assembly is located, and has a rib which rises from the shielding portion to the wall and has a surface which intersects a gas path extending along a planar direction of the Abschirmabschnitts.

Therefore, when the nail is pricked through the center of the housing in a front view during the nail penetration test, the nail short-circuits the electrodes of different polarity. When a short circuit occurs, heat is generated in the vicinity of the shorted part. This decomposes the electrolytic solution component and generates a gas. The generation of gas raises the pressure in the power storage device. Then, when the internal pressure of the housing reaches the discharge pressure of the pressure release valve, the pressure release valve is torn open and the gas in the housing is released from the housing.

The high-pressure gas generated at the short-circuited part flows to the opened pressure release valve. The force of the generated gas scrapes or scrapes off parts of the electrodes and generates fragments. The shielding section covers the opened pressure relief valve from the side of the wall on which the electrode assembly is located. Accordingly, the gas discharged from the electrode assembly strikes against the shielding portion. This changes the direction of the gas flowing toward the pressure release valve and extends the gas discharge path extending toward the pressure release valve. Further, the gas delivery path is extended as the gas flows along the rib. As a result, the electrode fragments fall out of the gas. This limits the electrode fragments scattered from the housing by the open pressure relief valve.

A power storage device solving the above problem has an electrode assembly with a layered structure, an electrolytic solution, a housing housing the electrode assembly and the electrolytic solution, and a pressure relief valve provided in a wall of the housing. The electrode assembly has electrodes that are insulated from each other and have different polarities. The pressure relief valve is configured to be ruptured when a pressure in the housing reaches a relief pressure to vent the pressure from the housing. The wall has a shielding member located between an inner surface of the wall and an end surface of the electrode assembly facing the inner surface. An axis extending in a stacking direction of the electrodes is referred to as an X axis, an axis orthogonal to the X axis, and parallel to the wall is referred to as a Y axis, a point located in a center of the X axis Housing in a front view of the housing taken in an X-axis direction and located at a center of a dimension of the electrode assembly in the X-axis direction is referred to as a center and an area surrounded by a plane that connects the center point and a contour of the pressure relief valve at a shortest distance is referred to as a three-dimensional area. The shielding member has a shielding portion that completely covers a cross section of the three-dimensional area along the end surface of the electrode assembly.

Accordingly, when the nail is pricked through the center of the housing in a front view during the nail penetration test, the nail short-circuits the electrodes of different polarities. When a short circuit occurs, heat is generated in the vicinity of the shorted part. This decomposes the electrolytic solution component and generates a gas. The generation of gas increases the pressure in the power storage device. Then, when the internal pressure of the housing reaches the discharge pressure of the pressure release valve, the pressure release valve is torn open and the gas in the housing is drained from the housing.

The high-pressure gas generated at the short-circuited part exits through the three-dimensional area from the center and flows to the opened pressure relief valve. The force of the generated gas scrapes or scrapes off parts of the electrodes and generates fragments or fragments. The shielding portion is located between the opened pressure relief valve and the cross section of the three-dimensional area and completely covers the cross section. Accordingly, the gas discharged from the electrode assembly from the cross-section of the three-dimensional area strikes against the shielding portion. This changes the direction of the gas flowing toward the pressure release valve and extends the gas discharge path extending toward the pressure release valve. As a result, the electrode fragments fall out of the gas. This limits the electrode fragments scattered from the housing by the open pressure relief valve.

The wall has the shielding component. Accordingly, the scattering of electrode fragments out of the housing from the opened pressure relief valve is reduced without increasing the number of components of the power storage device.

A power storage device solving the foregoing problem has an electrode assembly with a layered structure, an electrolytic solution, a housing housing the electrode assembly and the electrolytic solution, and a pressure relief valve provided in a wall of the housing. The electrode assembly has electrodes that are insulated from each other and have different polarities. The pressure relief valve is configured to be ruptured when a pressure in the housing reaches a relief pressure to vent the pressure from the housing. The wall has a shielding member located on an inner surface of the wall and an end surface of the electrode assembly facing the inner surface. An axis extending in a stacking direction of the electrodes is referred to as an X-axis. An axis orthogonal to the X-axis and parallel to the wall is referred to as a Y-axis, a plane passing through a center of the housing in a front view of the housing taken in the X-axis direction and parallel to is the end surface of the electrode assembly is referred to as a hypothetical plane, a line reflecting a straight line connecting two ends of the pressure relief valve in a direction of the Y-axis, on the assumed plane, when from an outer surface of the wall is regarded as a hypothetical line, a plane formed by reflecting the hypothetical line completely over a dimension of the electrode assembly in the direction of the X-axis is referred to as a ground plane, an area surrounded by a plane connecting a contour of the ground plane and a contour of the pressure relief valve in a shortest distance det, is called a three-dimensional area. The shielding member has a shielding portion that completely covers a cross section of the three-dimensional area along the end surface of the electrode assembly.

Therefore, when the nail is pricked through the center of the housing in a front view during the nail penetration test, the nail short-circuits the electrodes of different polarities. When a short circuit occurs, heat is generated in the vicinity of the shorted part. This decomposes the electrolytic solution component and generates a gas. The generation of gas raises the pressure in the power storage device. Then, when the internal pressure of the housing reaches the discharge pressure of the pressure release valve, the pressure release valve is torn open and the gas in the housing is drained from the housing.

The high pressure gas generated at the shorted part passes through the three dimensional area from a given location in the ground plane and flows to the opened pressure relief valve. The force of the generated gas scrapes or scrapes off parts of the electrodes and generates fragments. The shielding portion is located between the opened pressure relief valve and the cross section of the three-dimensional area and partially covers the cross section. Accordingly, the gas discharged from the electrode assembly from the cross-section of the three-dimensional area strikes against the shielding portion. This changes the direction of the gas flowing toward the pressure release valve and extends the gas discharge path extending toward the pressure release valve. As a result, the electrode fragments fall out of the gas. This limits the electrode fragments scattered from the housing by the open pressure relief valve.

Since the wall has the shielding member, there is no increase in the number of components of the power storage device, and the scattering of electrode fragments out of the housing from the opened pressure relief valve is reduced.

A power storage device solving the foregoing problem has an electrode assembly with a layered structure, an electrolytic solution, a housing housing the electrode assembly and the electrolytic solution, and a pressure relief valve provided in a wall of the housing. The electrode assembly has electrodes that are insulated from each other and have different polarities. The pressure relief valve is configured to be ruptured when a pressure in the housing reaches the discharge pressure to release the pressure from the housing. The power storage device has a shielding member located between an inner surface of the wall and an end surface of the electrode assembly facing the inner surface. An axis extending in a stacking direction of the electrodes is referred to as an X axis, an axis orthogonal to the X axis, and parallel to the wall is referred to as a Y axis, a line passing through a center of the housing in a front view of the housing taken in the X-axis direction and extending in a direction of the X-axis is referred to as a center line, an area surrounded by a plane which is a moving point or movement point located at a given position on the center line and connecting a contour of the pressure release valve at a shortest distance is referred to as a three-dimensional area and an entire area in which the three-dimensional area moves when the movement point over the entire dimension of the electrode assembly in the direction of the X- Axis is moved along the center line is referred to as an entire three-dimensional area. The shielding member has a shielding portion that completely covers a cross section of the entire three-dimensional area along the end surface of the electrode assembly.

list of figures

• 1 FIG. 13 is an exploded perspective view showing a rechargeable battery of a first embodiment. FIG.
• 2 is a perspective view of the outside of the rechargeable battery of 1 shows.
• 3 FIG. 13 is an exploded perspective view showing elements of an electrode assembly in the rechargeable battery of FIG 1 shows.
• 4 is a plan view showing the rechargeable battery of 1 shows.
• 5 is a partial cross-sectional view showing an internal structure of the rechargeable battery of 1 shows.
• 6 is a partially cutaway front view showing the rechargeable battery of 1 during the nail penetration test.
• 7 FIG. 12 is a perspective view showing a rechargeable battery of a second embodiment. FIG.
• 8th is a plan view showing the rechargeable battery of 7 shows.
• 9 Fig. 16 is a partial cross-sectional view showing another example of a shielding member.
• 10 FIG. 14 is a partial cross-sectional view showing the rechargeable battery of another example. FIG.
• 11 Fig. 10 is a plan view showing the rechargeable battery of another example.
• 12 FIG. 14 is a partial cross-sectional view showing the rechargeable battery of another example. FIG.
• 13 FIG. 14 is a partial cross-sectional view showing the rechargeable battery of another example. FIG.
• 14 Fig. 16 is a perspective view showing another example of the shielding member.
• 15 Fig. 16 is a perspective view showing another example of the shielding member.
• 16 is a partial perspective view of the rechargeable battery with the shielding of 15 shows.
• 17 is a partial cross-sectional view showing the internal structure of the rechargeable battery of 16 shows.
• 18 FIG. 15 is a perspective view showing a shielding member in which a gas passage hole is provided in the second rib. FIG.
• 19 is a cross-sectional view showing the shielding of 18 shows.
• 20A and 20B FIG. 15 is perspective views each showing the shielding member having a reinforcing rib. FIG.
• 21 FIG. 15 is a partial cross-sectional view showing a negative electrode lead member having an overlapping portion. FIG.
• 22 FIG. 10 is a partial cross-sectional view showing a negative electrode lead member having an overlapping portion and a bent portion. FIG.
• 23 FIG. 10 is a plan view showing a shield member having a first rib of another example. FIG.
• 24 FIG. 10 is a plan view showing a shield member supported by the negative electrode lead member. FIG.
• 25 FIG. 16 is a partial cross-sectional view showing a rechargeable battery having the shielding member of FIG 24 shows.
• 26A FIG. 12 is a cross-sectional view showing a shielding member having a sheet changing wall; and FIG 26B FIG. 15 is a perspective view showing a shielding member of another example. FIG.
• 27 FIG. 10 is a partial cross-sectional view showing a shield member manufactured by pressing a lid body. FIG.
• 28 Fig. 10 is a partial cross-sectional view showing a shield member having a round shielding portion.
• 29 Fig. 16 is a perspective view showing a rechargeable battery having a case rib.
• 30 FIG. 10 is a partial cross-sectional view showing a rechargeable battery in which the pressure release valve is offset toward the negative electrode lead member. FIG.
• 31 FIG. 10 is a cross-sectional view showing a cylindrical rechargeable battery. FIG.
• 32 is a partial cross-sectional view showing a shield member having a second rib in contact with the inner surface of the lid body.

EMBODIMENTS OF THE INVENTION

First embodiment

A first embodiment embodying a power storage device in a rechargeable battery will now be described with reference to FIG 1 to 6 described.

As in 1 and 2 shows has a rechargeable battery 10 serving as the power storage device, a housing 11 on. The rechargeable battery 10 has an electrode assembly 12 and an electrolytic solution contained in the housing 11 are housed. The housing 11 has a housing main body 13 with an opening 13a and a lid body 14 on, the opening 13a of the housing main body 13 closes.

The case main body 13 and the lid body 14 Both are made of aluminum. The case main body 13 has a rectangular plate-shaped bottom wall 13b , a short sidewall 13c that is shaped to from a short side of the bottom wall 13b protrude, and a long sidewall 13d on which is shaped to from a long side of the bottom wall 13b protrude. The housing 11 has a cuboid or cuboid shape and the electrode assembly 12 also has a cuboid or cuboid shape in conformity with the housing 11 , The rechargeable battery 10 is a prismatic lithium-ion battery.

As in 3 is shown, the electrode assembly 12 a variety of positive electrodes 21 with a rectangular track shape and a plurality of negative electrodes 31 with a rectangular track shape. The positive electrode 21 and the negative electrode 31 are electrodes of different polarity. The positive electrode 21 has a positive electrode metal foil (aluminum foil in the present embodiment) 21a and a positive electrode active material layer 21b on top of both surfaces of the positive electrode metal foil 21a is available. The negative electrode 31 has a negative electrode metal foil (copper foil in the present embodiment) 31a and a negative electrode active material layer 31b on top of both surfaces of the negative electrode metal foil 31a is available. The electrode assembly 12 is a stacked type in which a separator or a separator 24 between the plurality of positive electrodes 21 and the plurality of negative electrodes 31 located to get a layered structure. The separator 24 isolates the positive electrode 21 and the negative electrode 31 , The stacking direction of the electrodes 21 . 31 in the electrode assembly 12 is a short-side direction or a short side direction of the lid body 14 in the case 11 , An axis extending in the stacking direction of the electrodes 21 . 31 is referred to as an X-axis and an axis orthogonal to the X-axis and parallel to the lid body 14 (In particular outer surface and inner surface of the lid body 14 ) is referred to as a Y-axis. Accordingly, the short side direction and the short side direction of the lid body 14 a direction of the X-axis and the longitudinal direction of the lid body 14 is a direction of the Y axis.

The positive electrode 21 has a strip 25 which is shaped to from a part of a positive electrode side 21 to stand out. The negative electrode 31 has a strip 35 which is shaped to be from a part of a side of the negative electrode 31 protrude. The positive electrode strips 25 overlap the negative electrode strips 35 not in a state where the positive electrodes 21 and the negative electrodes 31 are stacked. The electrode assembly 12 has a strip-side end surface 12b on. The Stripes 25 . 35 are shaped to from the strip-side end face 12b protrude. That's why the strip 25 the positive electrode 21 a part of the positive electrode metal foil 21a and the strip 35 the negative electrode 31 is a part of the negative electrode metal foil 31a , Further, the positive electrode metal foil has 21a a lower melting point than the negative electrode metal foil 31a ,

As in 1 shows the rechargeable battery 10 the positive electrode strip group 26 which is shaped to from the strip-side end surface 12b protrude. The positive electrode strip group 26 is by collecting and stacking all the positive electrode strips 25 on one end side in the stacking direction of the electrode assembly 12 designed. The rechargeable battery 10 has a negative electrode tab group 36 which is shaped to from the strip-side end surface 12b protrude. The negative electrode strip group 36 is by putting together and stacking all the negative electrode strips 35 on one end side in the stacking direction of the electrode assembly 12 designed.

The rechargeable battery 10 has a positive electrode lead component 41 on. The positive electrode lead component 41 is made of a material equal to the positive electrode metal foil 21a is and is made of aluminum in the present embodiment. The positive electrode lead component 41 has a rectangular plate shape in which a long side is in the longitudinal direction of the lid body 14 extends. The positive electrode strip group 26 is with a longitudinal end of the positive electrode line component 41 connected. The positive electrode connection 42 is with the other longitudinal end of the positive electrode lead member 41 connected.

The rechargeable battery 10 has a negative electrode lead component 51 on. The negative electrode lead component 51 is made of a material equal to the negative electrode metal foil 31a and is made of copper in the present embodiment. Accordingly, the positive electrode lead member has 41 a lower melting point than the negative electrode line component 51 , The negative electrode lead component 51 has a rectangular plate shape in which a long side is in the longitudinal direction of the lid body 14 extends. The negative electrode strip group 36 is with a longitudinal end of the negative electrode lead component 51 connected. The negative electrode connection 52 is with the other longitudinal end of the negative electrode lead component 51 connected. The positive electrode lead component 41 and the negative electrode lead member 51 are located between an inner surface 14a of the lid body 14 and the strip-side end surface 12b the electrode assembly 12 that the inner surface 14a is facing.

The positive electrode lead component 41 and the negative electrode lead member 51 are mutually in the longitudinal direction of the lid body 14 spaced. The positive electrode connection 42 and the negative electrode terminal 52 extend through the lid body 14 through and are partially to the outside of the housing 11 exposed. Further, an annular insulating member or element 17a for isolation from the housing 11 at the positive electrode terminal 42 and the negative electrode terminal 52 appropriate.

The rechargeable battery 10 has the pressure relief valve or pressure relief valve 18 on the lid body 14 which serves as a wall. The pressure relief valve 18 is torn open when the pressure in the housing 11 reaches a discharge pressure which is a predetermined pressure. When the pressure relief valve 18 is torn open, the pressure in the housing 11 out of the case 11 drained.

The discharge pressure of the pressure relief valve 18 is set to a pressure at which the pressure relief valve is ruptured before the housing 11 or a connecting portion of the housing main body 13 and the lid body 14 Cracks gets or breaks. The pressure relief valve 18 has a thin plate-shaped valve body 19 on, thinner than the lid body 14 is. The valve body 19 is located at the bottom of a depression 20 that in a recessed way in the outer surface 14b of the lid body 14 from the surfaces of the lid body 14 is provided, and is integral with the lid body 14 molded or poured.

The pressure relief valve 18 is closer to the positive electrode terminal 42 as a longitudinal middle part of the lid body 14 , The pressure relief valve 18 is located at the middle in the short side direction of the lid body 14 , As in 5 is shown, there is a center position C1 the pressure relief valve 18 closer to the positive electrode line component 41 as a middle position C2 between the strip 25 (Strip group 26 ) of the positive electrode 21 and the strip 35 (Strip group 36 ) of the negative electrode 31 in the longitudinal direction of the lid body 14 , The pressure relief valve 18 has the shape of an elongated hole in a view taken from the outside surface 14b of the lid body 14 is seen.

As in 1 . 4 or 5 shows the rechargeable battery 10 a shielding component 60 on. The shielding component 60 is located between the positive electrode line component 41 and the negative electrode lead member 51 in the longitudinal direction of the lid body 14 , Furthermore, the shielding is located 60 between the inner surface 14a of the lid body 14 and the strip-side end surface 12b and is at the strip-side end surface 12b mounted or attached. The shielding component 60 is not on the inside surface 14a of the lid body 14 and the strip-side end surface 12b fixed and is slightly movable between the lid body 14 and the electrode assembly 12 , The shielding component 60 is made of synthetic resin and is preferably made of, for example, a heat-resistant resin such as polyimide. Accordingly, the shielding member closes 60 the components of the positive electrode potential and the components of the negative electrode potential in the housing 11 not short.

The shielding component 60 has a rectangular plate-shaped shielding section 61 on. The long side of the shielding section 61 extends in the longitudinal direction of the lid body 14 , The shielding component 60 has first ribs 62 formed to be from a pair of long edges of the shielding portion 61 to the lid body 14 to stand out. Every first rib 62 is shaped such that the long side is in the longitudinal direction of the lid body 14 extends. The shielding component 60 has a second rib 63 on. The second rib 63 is shaped to move from a short edge closer to the positive electrode lead member 41 from a pair of short edges of the shielding portion 61 to the lid body 14 to stand out. The pair of first ribs 62 is with the second rib 63 coupled.

An outer surface of the second rib 63 contacts a longitudinal end surface of the positive electrode lead member 41 , An end surface of the shielding portion 61 is in contact with a side surface of the negative electrode tab group 36 , The shielding component 60 immediately touches the positive electrode lead component 41 or the negative electrode tab group 36 if it is slightly in the longitudinal direction of the lid body 14 is moved. Accordingly, the shielding member restricts 60 a movement of the lid body 14 in the longitudinal direction. Therefore, the positive electrode lead member functions 41 and the negative electrode tab group 36 as a movement restricting member that controls the movement of the shielding member 60 in the longitudinal direction of the lid body 14 limited.

The outer surface of a first rib 62 is in contact with the inner surface of a long sidewall 13d of the housing main body 13 and the outer surface of the other first rib 62 is in contact with the inner surface of the other long sidewall 13d , The shielding component 60 is from the inside surface of every long sidewall 13d spaced, which the inner surface of the housing 11 is. However, if slightly in the short side direction or short side direction of the lid body 14 moves, touches the shielding 60 immediately one of the long side walls 13d , Accordingly, the shielding member restricts 60 a movement of the lid body 14 in the short side direction. Therefore, the shielding member restricts 60 also a movement in both directions along the strip-side end face 12b ,

The shielding component 60 exists between the positive electrode lead member 41 and the negative electrode lead member 51 in the longitudinal direction of the lid body 14 , A portion having a central portion in the longitudinal direction of the strip-side end surface 12b is and of the positive electrode line component 41 , the negative electrode lead component 51 and the pair of long sidewalls 13d is designated as a coverage area H. The coverage area H is from the shielding component 60 covered. A direction of extension of a straight line, the inner surface 14a of the lid body 14 and the bottom surface of the case main body 13 connecting in a shortest distance is called a height direction. In the shielding component 60 becomes an area attached to the strip-side end face 12b in the shielding section 61 is attached as an outer surface 61a and an area that is the inner surface 14a of the lid body 14 is facing, is called an inner surface 61e designated.

As in 5 is shown in the shielding 60 under the dimensions in the protruding direction of the first rib 62 from the shielding section 61 a dimension of the first rib 62 from the outside surface 61a the shielding section 61 as a protrusion distance and a protrusion distance, respectively H1 designated. In the shielding component 60 becomes smaller than the dimensions in the protruding direction of the second rib 63 from the shielding section 61 a dimension of the outer surface 61a the shielding section 61 as a protrusion distance and a protrusion distance, respectively H2 designated. The projection distance H2 the second rib 63 is shorter than the projection distance H1 the first rib 62 , Accordingly, a projection end is located from the shielding portion 61 the first rib 62 at a position that is essentially the inner surface 14a of the lid body 14 touched. A projection end of the shielding portion 61 the second rib 63 is from the inner surface 14a of the lid body 14 spaced. This is so as to obtain a flow path so that the gas generated during the nail penetration test performed on the rechargeable battery goes to the pressure release valve 18 flows from a side on which the positive electrode line component 41 located. The projection end of the shielding portion 61 the second rib 63 is located at a position closer to the lid body 14 as the positive electrode lead component 41 , That is, the position of the protrusion end of the second rib 63 is located above the positive electrode line component 41 away to the lid body 14 out.

As in 4 can be shown with respect to the Abschirmbauteils 60 , on or on the strip-side end face 12b is mounted, in the short side direction of the lid body 14 from the point of the pressure relief valve 18 in the inner surface 14a of the lid body 14 surrounds the pair of first ribs 62 the outside of the pressure relief valve 18 touch. The second rib 63 is located on the outside closer to the positive electrode line component 41 as the pressure relief valve 18 in the longitudinal direction of the lid body 14 , Accordingly, the first rib 62 and the second rib 63 at positions that the pressure relief valve 18 in a view of the lid body 14 do not overlap that from the outside surface 14b is taken out. If the rechargeable battery 10 vibrates and the electrode assembly 12 to the lid body 14 is moved, is also the shielding 60 to the lid body 14 moved out and the first rib 62 is in contact with the inner surface 14a of the lid body 14 , The shielding section 61 and the lid body 14 are separated by the contact. Accordingly, in the present embodiment, the first rib forms 62 a spacer of the shielding member 60 ,

When the shielding component 60 from the side of the lid body 14 from which the electrode assembly is viewed 12 to the inner surface 14a There are the first ribs 62 and the second rib 63 within a plane defined by a contour of the shielding section 61 is defined. That is, the shielding member 60 has no flange that is shaped to from the outside surface of each rib 62 . 63 protrude to the shielding component 60 on the lid body 14 to fix, and the outer surface of each rib 62 . 63 has a flat planar shape.

As in 2 and 6 is shown in the front view of the housing 11 the position where two diagonal lines intersect each other as a center of the housing 11 in front view. A point located at the center of the case 11 located in the front view and at the center of the electrode assembly 12 in the stacking direction of the electrodes 21 . 31 is located as a midpoint P designated. An area surrounded by a plane that is the center P and the contour of the valve body 19 in the pressure relief valve 18 in a shortest distance, is referred to as a three-dimensional area R.

The three-dimensional area R is an area of the center P , the area of the valve body 19 in the pressure relief valve 18 and the level is the center of attention P and the area of the valve body 19 combines. The three-dimensional area R is shaped to stand out from the pressure relief valve 18 to the center P to narrow down and gives a cone or cone. The pressure relief valve 18 is closer to the positive electrode connection or positive pole 42 in the longitudinal direction of the lid body 14 , Accordingly, the three-dimensional area R shaped to connect to the positive electrode terminal 42 in the longitudinal direction of the lid body 14 to tilt.

As in 4 and 6 is shown, a cross-section along the strip-side end face 12b as a cross section Ra in the three-dimensional area R designated. In the cross section Ra is a dimension in the longitudinal direction of the lid body 14 slightly smaller than the valve body 19 , The cross section Ra of the three-dimensional area R lies in the coverage area or coverage area H the strip-side end surface 12b , The cross section Ra standing on the strip-side end face 12b is present, is completely from the outer surface 61a the shielding section 61 covered, the at the strip-side end face 12b is mounted.

Operation of the rechargeable battery 10 will now be described.

As in 6 shown is when a nail passes through the middle of the case 11 in a front view of the rechargeable battery 10 is introduced to perform the nail penetration test, the nail extends through the electrode assembly 12 through in the stacking direction. The separator 24 between the positive electrode 21 and the negative electrode 31 is accordingly broken or melted by the nail and the positive electrode 21 and the negative electrode 31 be in the case 11 shorted.

If a short circuit in the electrode assembly 12 occurs, heat is generated in the vicinity of the short-circuited portion. This decomposes the electrolytic solution component and generates a gas. The generation of gas raises the pressure in the rechargeable battery 10 at. When the internal pressure of the case 11 the discharge pressure or discharge pressure of the pressure relief valve 18 reached, the valve body 19 the pressure relief valve 18 Torn open and the gas in the housing 11 gets out of the case 11 discharged or discharged.

The high-pressure gas that is at the center P of the short-circuited part passes through the three-dimensional area R to the opened pressure relief valve 18 down and up, as if by an arrow Y is shown. A part of each of the electrodes 21 . 31 and each of the metal foils 21a . 31a is fragmented by the force of the generated gas. The gas flows to the pressure release valve 18 and gets out of the electrode assembly 12 from the cross section Ra of the three-dimensional area R of the coverage area H the strip-side end surface 12b issued. The gas then hits against the outside surface 61a the shielding section 61 that the cross section Ra of the three-dimensional area R covers, and is in a direction along the outer surface 61a changed.

The gas that is changed in one direction when it is against the shielding section 61 beats, climbs along the first rib 62 and the second rib 63 and enters through a gap between the distal end surface of each rib 62 . 63 and the inner surface 14a of the lid body 14 to the pressure relief valve 18 out. Further, the gas flowing between the strips flows 25 the positive electrode strip group 26 happens on the inside surface 61e the shielding section 61 from the side on which the positive electrode lead component 41 located to the pressure relief valve 18 to reach. The gas happens between the strips 35 the negative electrode tab group 36 and flows on the inner surface 61e the shielding section 61 from the side on which the negative electrode lead component 51 located to the pressure relief valve 18 to reach. Accordingly, the gas flows in from any given location the vicinity of the pressure relief valve 18 to the pressure relief valve 18 towards the inside of the shielding member 60 , Therefore, the gas path also lies at any given position along the inner surface 61e the shielding section 61 in front. In the present embodiment, the outer surface of each of the first ribs 62 a surface orthogonal to the gas path to the pressure relief valve 18 along the short side direction of the lid body 18 and the outer surface of the second rib 63 is a surface orthogonal to the gas path to the pressure relief valve 18 in the longitudinal direction of the lid body 14 ,

A direction in which the gas to the pressure relief valve 18 in the longitudinal direction and the planar direction of the lid body 14 is referred to as a gas discharge direction. The gas generated during the nail penetration test flows through the positive side gas discharge path to the pressure relief valve 18 over the second rib 63 out on the side on which the positive electrode line component 41 located. The gas flows through a negative side gas exhaust passage to the pressure relief valve 18 from the side on which the negative electrode lead component 51 located.

In this case, the gas flowing through the positive-electrode side gas discharge path passes through a flow path coming from the pair of first fins 62 , the second rib 63 and the lid body 14 is surrounded, and flows to the pressure relief valve 18 from the side on which the positive electrode lead component 41 located.

The gas flowing through the negative electrode side gas discharge path passes through a flow path coming from the pair of first ribs 62 , the shielding section 61 and the lid body 14 is surrounded, and flows to the pressure relief valve 18 from the side on which the negative electrode lead component 51 located. Then the gas gets out of the case 11 from the opened pressure relief valve 18 issued. The flow path resistance of the positive electrode side gas delivery path in which the second rib 63 proximal to the positive electrode lead component 41 is greater than the flow path resistance of the negative electrode side gas delivery path in which the second rib 63 not available. That is, a flow path sectional area of the positive-electrode side gas discharge path is smaller than a flow path sectional area of the negative-electrode side gas delivery path. Therefore, in the two gas discharge paths, the gas flows even more easily through the positive side gas discharge passageway than through the negative side exhaust gas discharge pathway.

1. (1) Der Abschirmabschnitt 61 des Abschirmbauteils 60 deckt vollständig den Querschnitt Ra ab, der sich auf der streifenseitigen Endfläche 12b des dreidimensionalen Bereichs R befindet, der den Mittelpunkt P, der in dem kurzgeschlossenen Teil vorhanden ist, und das Druckablassventil 18 verbindet. Dementsprechend strömt während des Nagelpenetrationstests das Gas zu dem Druckablassventil 18 hin und schlägt gegen die Außenfläche 61a des Abschirmabschnitts 61 und die Strömungsrichtung des Gases wird von der Bahn, die sich gerade zu dem Druckablassventil 18 hin erstreckt, abgelenkt, um die Gasabgabebahn zu dem Druckablassventil 18 hin zu verlängern. Als ein Ergebnis fallen die Fragmente der Elektroden 21, 31 und der Metallfolien 21a, 31a aus dem Gas heraus in das Gehäuse 11. Dies reduziert die Fragmente, die aus dem Gehäuse 11 durch das Gas verstreut werden und begrenzt die Erzeugung von Funken.
2. (2) Die ersten Rippen 62 des Abschirmbauteils 60 sind in Kontakt mit der Innenfläche 14a des Deckelkörpers 14, um den Abschirmabschnitt 61 und den Deckelkörper 14 voneinander beabstandet zu halten und einen Abstand zwischen den zwei Flächen beizubehalten. Dementsprechend, selbst obwohl das Abschirmbauteil 60 an der streifenseitigen Endfläche 12b montiert bzw. befestigt ist, wird eine Strömungsbahn des Gases gewährleistet und die Funktion des Druckablassventils 18 zum Abgeben von Gas aus dem Gehäuse 11 wird beibehalten.
3. (3) Das Paar von ersten Rippen 62 des Abschirmbauteils 60 berührt die Außenseite des Druckablassventils 18 in der Kurzseitenrichtung der Innenfläche 14a des Deckelkörpers 14. Dementsprechend blockiert die erste Rippe 62 nicht das Druckablassventil 18.
4. (4) Die erste Rippe 62 des Abschirmbauteils 60 befindet sich auf der Außenseite des Druckablassventils 18 in der Kurzseitenrichtung des Deckelkörpers 14. Während des Nagelpenetrationstests wird die Elektrodenbaugruppe 12 in der Stapelrichtung ausgedehnt, wenn die Temperatur steigt, und das Gas strömt zu dem Druckablassventil 18 hin von den zwei Seiten in der Stapelrichtung der Elektrodenbaugruppe 12. Solch ein Gas schlägt gegen die erste Rippe 62 und Fragmente von jeder von den Elektroden 21, 31 und jeder von den Metallfolien 21a, 31a fallen aus dem Gas heraus.
5. (5) Das Abschirmbauteil 60 weist die zweite Rippe 63 auf, die sich in der Kurzseitenrichtung des Deckelkörpers 14 erstreckt. Dementsprechend, selbst wenn das Gas zu dem Abschirmbauteil 60 von der Seite aus strömt, auf der sich das positive Elektrodenleitungsbauteil 41 befindet, schlägt das Gas gegen die zweite Rippe 63 derart, dass die Fragmente von jeder von den Elektroden 21, 31 und jeder von den Metallfolien 21a, 31a herausfallen.
6. (6) Die zweite Rippe 63 befindet sich zu dem positiven Elektrodenleitungsbauteil 41 hin von dem Druckablassventil 18 aus in dem Abschirmbauteil 60. Dementsprechend werden Teile des positiven Elektrodenleitungsbauteils 41 und des Streifens 25, die aus Aluminium hergestellt sind, geschmolzen und durch das Hochtemperatur-Hochdruck-Gas abgeschabt bzw. abgeschrammt, das gegen die zweite Rippe 63 schlägt, welche nicht von dem Gehäuse 11 abgegeben werden.
7. (7) Das Abschirmbauteil 60 ist an bzw. auf der streifenseitigen Endfläche 12b montiert mit der Außenfläche von jeder ersten Rippe 62, die von der Innenfläche der langen Seitenwand 13b beabstandet ist. Dementsprechend blockiert das Abschirmbauteil 60 nicht das Druckablassventil 18, während Fragmente von jeder von den Elektroden 21, 31 und jeder von den Metallfolien 21a, 31a veranlasst werden, aus dem Gas in das Gehäuse 11 zu fallen, ohne den Betrieb des Druckablassventils 18 zu behindern.
8. (8) Das Abschirmbauteil 60 ist an bzw. auf der streifenseitigen Endfläche 12b montiert bzw. befestigt. Dementsprechend schlägt das Gas, das aus der Elektrodenbaugruppe 12 von dem Querschnitt Ra der streifenseitigen Endfläche 12b abgebeben wird, unmittelbar gegen den Abschirmabschnitt 61. Folglich wird die Richtung des Gases, das zu dem Druckablassventil 18 hin strömt, rasch geändert und die Gasabgabebahn zu dem Druckablassventil 18 hin wird rasch verlängert.
9. (9) Das Abschirmbauteil 60 ist aus einem hitzebeständigen Harz hergestellt. Dementsprechend wird das Abschirmbauteil 60 nicht durch das Hochtemperaturgas geschmolzen, das während des Nagelpenetrationstests erzeugt wird.
10. (10) Das Abschirmbauteil 60 weist ein Paar von ersten Rippen 62 auf, die sich von dem Abschirmabschnitt 61 aus erheben. Dementsprechend, selbst wenn die wiederaufladbare Batterie 10 vibriert wird und die Elektrodenbaugruppe 12 zu dem Deckelkörper 14 hin bewegt wird, bewegt sich das Abschirmbauteil 60 zu dem Deckelkörper 14 hin, so dass die ersten Rippen 62 in Kontakt mit dem Deckelkörper 14 gelangen. Dementsprechend trifft die Elektrodenbaugruppe 12 nicht den Deckelkörper 14 und ein Schaden der Elektrodenbaugruppe 12 wird vermieden.
11. (11) Das Abschirmbauteil 60 weist die zweiten Rippen 63 auf. Dementsprechend, selbst wenn Teile des Streifens 25, der aus Aluminium hergestellt ist, oder Teile des positiven Elektrodenleitungsbauteils 41 geschmolzen werden oder durch das Hochtemperatur-Hochdruck-Gas abgeschrammt werden, wenn das Gas, das gegen den Abdeckungsabschnitt 55 schlägt, zwischen Streifengruppen 26 auf der positiven Elektrodenseite tritt, oder wenn das Gas entlang dem positiven Elektrodenleitungsbauteil 41 strömt, schlagen solche Teile gegen die zweite Rippe 63 und werden nicht aus dem Gehäuse 11 abgegeben während des Nagelpenetrationstests. Der Strömungsbahnwiderstand der positiven Elektrodenseitengasabgabebahn bzw. der Gasabgabebahn auf der positiven Elektrodenseite proximal zu dem positiven Elektrodenleitungsbauteil 41 ist größer als der Strömungsbahnwiderstand der negativen Elektrodenseitengasabgabebahn bzw. der Gasabgabebahn auf der negativen Elektrodenseite proximal zu dem negativen Elektrodenleitungsbauteil 51, aufgrund der Anordnung der zweiten Rippe 63. Mit anderen Worten ist ein Strömungsbahnquerschnittsbereich der positiven Elektrodenseitengasabgabebahn kleiner als ein Strömungsbahnquerschnittsbereich der negativen Elektrodenseitengasabgabebahn. Dementsprechend, da der Strömungsbahnwiderstand der positiven Elektrodenseitengasabgabebahn größer ist (Strömungsbahnquerschnittsbereich ist kleiner), strömt Gas leicht zu der Seite, auf der sich das negative Elektrodenleitungsbauteil 51 befindet. Ferner, da der Strömungsbahnquerschnittsbereich der negativen Elektrodenseitengasabgabebahn größer ist als der Strömungsbahnquerschnittsbereich der positiven Elektrodenseitengasabgabebahn, strömt Gas leicht von der negativen Elektrodenseitengasabgabebahn zu dem Druckablassventil 18 hin und der Druck in dem Gehäuse 11 steigt nicht.
12. (12) Das Vorsprungsende von dem Abschirmabschnitt 61 der zweiten Rippe 63 befindet sich an einer Position näher an dem Deckelkörper 14 als das positive Elektrodenleitungsbauteil 41. Dementsprechend, selbst wenn das Gas zwischen den Streifengruppen 26 auf der positiven Elektrodenseite tritt und gegen das positive Elektrodenleitungsbauteil 41 schlägt, und selbst wenn ein Teil von dem positiven Elektrodenleitungsbauteil 41, der aus Aluminium hergestellt ist, geschmolzen und durch das Hochtemperatur-Hochdruck-Gas abgeschrammt wird, schlägt das Gas gegen die zweite Rippe 63 und Fragmente des positiven Elektrodenleitungsbauteils 41 werden nicht aus dem Gehäuse 11 durch die zweite Rippe 63 abgegeben während des Nagelpenetrationstests. Das Vorsprungsende von dem Abschirmabschnitt 61 der zweiten Rippe 63 ist von der Innenfläche 14a des Deckelkörpers 14 beabstandet. Dementsprechend ist die Bahn des Gases, das zu dem Druckablassventil 18 entlang dem positiven Elektrodenleitungsbauteil 41 strömt, gewährleistet und das Gas von der Seite, auf der sich das positive Elektrodenleitungsbauteil 41 befindet, wird aus dem Gehäuse 11 von dem Druckablassventil 18 abgegeben. Dies begrenzt übermäßige Druckanstiege in dem Gehäuse 11.
13. (13) Das Abschirmbauteil 60 ist aus einem hitzebeständigen Harz hergestellt. Zum Beispiel, falls das Abschirmbauteil 60 aus Metall hergestellt ist, muss die Oberfläche des Abschirmbauteils 60 mit einem isolierenden Harz oder einer Keramik beschichtet werden. Jedoch eliminiert das Abschirmbauteil, das aus einem hitzebeständigem Harz hergestellt ist, die Notwendigkeit für solch eine Beschichtung.
14. (14) Der Streifen 25 der positiven Elektrode 21 ist ein Teil der positiven Elektrodenmetallfolie 21a und der Streifen 35 der negativen Elektrode 31 ist ein Teil der negativen Elektrodenmetallfolie 31a. Daher, wenn die positive Elektrode 21 und die negative Elektrode 31 gestapelt werden, wird ein Raum zum Anordnen des Abschirmbauteils 60 zwischen der Streifengruppe 26, in der die Streifen 25 der positiven Elektroden 21 gestapelt sind, und der Streifengruppe 36 erlangt, in der die Streifen 35 der negativen Elektrode 31 gestapelt sind. Zum Beispiel, wenn die Streifen von jeder von den Elektroden 21, 31 getrennt sind, wird sich der Raum zwischen den Streifen in einer Größe ändern und die Anordnung des Abschirmbauteils 60 nicht ermöglichen.
15. (15) Die erste Rippe 62 des Abschirmbauteils 60A weist kein Loch auf, das sich in der Dickenrichtung erstreckt. Dementsprechend, verglichen dazu, wenn ein Loch enthalten ist, wird die Steifigkeit der ersten Rippe 62 erhöht. Selbst wenn das Abschirmbauteil 60 zu dem Deckelkörper 14 durch das Gas bewegt wird, das während des Nagelpenetrationstests erzeugt wird, und die erste Rippe 62 den Deckelkörper 14 trifft bzw. darauf schlägt, wird eine Deformation der ersten Rippe 62 begrenzt.
16. (16) Wenn das Abschirmbauteil 60 von der Seite aus betrachtet wird, auf der sich die Elektrodenbaugruppe 12 befindet, zu der Innenseite 14a des Deckelkörpers 14 hin, liegt die erste Rippe 62 und die zweite Rippe 63 innerhalb einer Ebene vor, die durch die Kontur des Abschirmabschnitts 61 definiert ist. Dementsprechend hat das Abschirmbauteil 60 keinen Flansch, der geformt ist, um von der Außenfläche von jeder Rippe 62, 63 vorzuragen, um das Abschirmbauteil 60 an dem Deckelkörper 14 zu fixieren. Deshalb kann der Raum zwischen der streifenseitigen Endfläche 12b und dem Deckelkörper 14 aufgeweitet werden verglichen mit einem Fall, in dem ein Flansch vorgesehen ist, um das Abschirmbauteil 60 an dem Deckelkörper 14 zu fixieren.
17. (17) Die Außenfläche der zweiten Rippe 63 kann eine Längsendfläche des positiven Elektrodenleitungsbauteils 41 berühren. Die Endfläche des Abschirmabschnitts 61 kann die Seitenfläche der negativen Elektrodenstreifengruppe 36 in dem gefalteten Zustand berühren. Dementsprechend wird die Bewegung des Abschirmbauteils 60 in der Längsrichtung des Deckelkörpers 14 durch das positive Elektrodenleitungsbauteil 41 und die negative Elektrodenstreifengruppe 36 beschränkt. Dies behält einen Zustand bei, in dem der Querschnitt Ra, der sich auf der Streifenseitenendfläche 12b befindet, vollständig von dem Abschirmbauteil 60 abgedeckt ist.
18. (18) Die Innenfläche 61e des Abschirmbauteils 60 hat eine flache Ebene bzw. planare Form. Dementsprechend strömt das Gas, das während des Nagelpenetrationstests erzeugt wird, leicht zu dem Druckablassventil 18 innerhalb des Abschirmbauteils 60.

The embodiment described above has the following advantages.

1. (1) The shielding section 61 the shielding component 60 completely covers the cross section Ra starting on the strip-side end face 12b of the three-dimensional area R is the center P which is present in the short-circuited part, and the pressure release valve 18 combines. Accordingly, during the nail penetration test, the gas flows to the pressure release valve 18 down and beats against the outside surface 61a the shielding section 61 and the flow direction of the gas is from the web, which is just to the pressure relief valve 18 out, deflected to the gas delivery path to the pressure relief valve 18 to extend. As a result, the fragments of the electrodes fall 21 . 31 and the metal foils 21a . 31a out of the gas into the housing 11 , This reduces the fragments coming out of the case 11 be scattered by the gas and limits the generation of sparks.
2. (2) The first ribs 62 the shielding component 60 are in contact with the inner surface 14a of the lid body 14 to the shielding section 61 and the lid body 14 Keep spaced apart and maintain a distance between the two surfaces. Accordingly, even though the shielding member 60 at the strip-side end surface 12b is mounted or secured, a flow path of the gas is ensured and the function of the pressure relief valve 18 for discharging gas from the housing 11 will be maintained.
3. (3) The pair of first ribs 62 the shielding component 60 touches the outside of the pressure relief valve 18 in the short side direction of the inner surface 14a of the lid body 14 , Accordingly, the first rib blocks 62 not the pressure relief valve 18 ,
4. (4) The first rib 62 the shielding component 60 is located on the outside of the pressure relief valve 18 in the short side direction of the lid body 14 , During the nail penetration test, the electrode assembly becomes 12 expanded in the stacking direction when the temperature rises, and the gas flows to the pressure release valve 18 from the two sides in the stacking direction of the electrode assembly 12 , Such a gas hits the first rib 62 and fragments of each of the electrodes 21 . 31 and each of the metal foils 21a . 31a fall out of the gas.
5. (5) The shielding member 60 has the second rib 63 on, located in the short side direction of the lid body 14 extends. Accordingly, even if the gas to the shielding member 60 flows from the side on which the positive electrode line component 41 the gas hits the second rib 63 such that the fragments from each of the electrodes 21 . 31 and each of the metal foils 21a . 31a fall out.
6. (6) The second rib 63 is located to the positive electrode line component 41 out from the pressure relief valve 18 out in the shielding component 60 , Accordingly, parts of the positive electrode lead member become 41 and the strip 25 , which are made of aluminum, melted and scraped off by the high-temperature high-pressure gas, that against the second rib 63 which does not hit the case 11 be delivered.
7. (7) The shielding member 60 is on or on the strip-side end surface 12b mounted with the outer surface of each first rib 62 coming from the inner surface of the long side wall 13b is spaced. Accordingly, the shielding member blocks 60 not the pressure relief valve 18 while fragments of each of the electrodes 21 . 31 and each of the metal foils 21a . 31a be induced from the gas into the housing 11 to fall without the operation of the pressure relief valve 18 to hinder.
8. (8) The shielding member 60 is on or on the strip-side end surface 12b mounted or attached. Accordingly, the gas that blows out of the electrode assembly strikes 12 from the cross section Ra the strip-side end surface 12b is discharged, directly against the shielding section 61 , Consequently, the direction of the gas going to the pressure release valve becomes 18 flows rapidly changed and the gas delivery path to the pressure relief valve 18 It will be extended quickly.
9. (9) The shielding member 60 is made of a heat-resistant resin. Accordingly, the shielding member becomes 60 not melted by the high temperature gas generated during the nail penetration test.
10. (10) The shielding member 60 has a pair of first ribs 62 on, extending from the shielding section 61 from elevate. Accordingly, even if the rechargeable battery 10 vibrates and the electrode assembly 12 to the lid body 14 is moved, the shielding moves 60 to the lid body 14 out, so the first ribs 62 in contact with the lid body 14 reach. Accordingly, the electrode assembly hits 12 not the lid body 14 and damage to the electrode assembly 12 is avoided.
11. (11) The shielding member 60 has the second ribs 63 on. Accordingly, even if parts of the strip 25 , which is made of aluminum, or parts of the positive electrode line component 41 be melted or be scrapped by the high-temperature high-pressure gas, if the gas, which is against the cover section 55 beats, between stripe groups 26 occurs on the positive electrode side, or if the gas along the positive electrode line component 41 flows, beat such parts against the second rib 63 and will not be out of the case 11 delivered during the nail penetration test. The flow path resistance of the positive electrode side gas delivery path and the gas discharge path on the positive electrode side proximal to the positive electrode line component 41 is greater than the flow path resistance of the negative electrode side gas delivery path or the negative electrode side gas discharge path proximal to the negative electrode line component 51 , due to the arrangement of the second rib 63 , In other words, a flow path sectional area of the positive-electrode side gas discharge path is smaller than a flow path sectional area of the negative-electrode side gas delivery path. Accordingly, since the flow path resistance of the positive-electrode side gas discharge path is larger (flow path sectional area is smaller), gas easily flows to the side on which the negative-electrode-line component 51 located. Further, since the flow path sectional area of the negative-electrode side gas discharge path is larger than the flow path sectional area of the positive-electrode side gas discharge path, gas easily flows from the negative-electrode side gas discharge path to the pressure-discharge valve 18 back and the pressure in the housing 11 does not rise.
12. (12) The projection end of the shielding portion 61 the second rib 63 is located at a position closer to the lid body 14 as the positive electrode lead component 41 , Accordingly, even if the gas is between the strip groups 26 on the positive electrode side and against the positive electrode line component 41 beats, and even if a part of the positive electrode line component 41 Made of aluminum, melted and scarified by the high temperature high pressure gas, the gas hits the second rib 63 and fragments of the positive electrode lead member 41 will not be out of the case 11 through the second rib 63 delivered during the nail penetration test. The projection end of the shielding portion 61 the second rib 63 is from the inner surface 14a of the lid body 14 spaced. Accordingly, the path of the gas that is to the pressure relief valve 18 along the positive electrode lead member 41 flows, ensures and the gas from the side on which the positive electrode line component 41 is removed from the housing 11 from the pressure relief valve 18 issued. This limits excessive pressure increases in the housing 11 ,
13. (13) The shielding member 60 is made of a heat-resistant resin. For example, if the shielding component 60 Made of metal, the surface of the shielding component must 60 be coated with an insulating resin or a ceramic. However, the shielding member made of a heat-resistant resin eliminates the need for such a coating.
14. (14) The strip 25 the positive electrode 21 is a part of the positive electrode metal foil 21a and the strip 35 the negative electrode 31 is a part of the negative electrode metal foil 31a , Therefore, if the positive electrode 21 and the negative electrode 31 is stacked, a space for arranging the Abschirmbauteils 60 between the strip group 26 in which the stripes 25 the positive electrodes 21 stacked, and the strip group 36 attained in which the stripes 35 the negative electrode 31 are stacked. For example, if the strips of each of the electrodes 21 . 31 are separated, the space between the strips will change in size and the arrangement of the Abschirmbauteils 60 not allow.
15. (15) The first rib 62 the shielding component 60A does not have a hole extending in the thickness direction. Accordingly, as compared with when a hole is included, the rigidity of the first rib becomes 62 elevated. Even if the shielding component 60 to the lid body 14 is moved by the gas generated during the nail penetration test and the first rib 62 the lid body 14 meets or strikes, becomes a deformation of the first rib 62 limited.
16. (16) When the shielding member 60 viewed from the side on which the electrode assembly 12 is located, to the inside 14a of the lid body 14 there is the first rib 62 and the second rib 63 within a plane defined by the contour of the shielding section 61 is defined. Accordingly, the shielding member 60 no flange that is shaped to from the outer surface of each rib 62 . 63 protrude to the shielding component 60 on the lid body 14 to fix. Therefore, the space between the strip-side end surface 12b and the lid body 14 be expanded compared to a case in which a flange is provided to the shielding member 60 on the lid body 14 to fix.
17. (17) The outer surface of the second rib 63 may be a longitudinal end surface of the positive electrode lead member 41 touch. The end surface of the shielding portion 61 may be the side surface of the negative electrode tab group 36 in the folded state. Accordingly, the movement of the shielding member becomes 60 in the longitudinal direction of the lid body 14 through the positive electrode lead component 41 and the negative electrode tab group 36 limited. This maintains a condition in which the cross section Ra Standing on the strip side end surface 12b located completely off the shielding member 60 is covered.
18. (18) The inner surface 61e the shielding component 60 has a flat plane or planar shape. Accordingly, the gas generated during the nail penetration test easily flows to the pressure release valve 18 within the shielding component 60 ,

Second embodiment

A second embodiment embodying a power storage device in a rechargeable battery will now be described with reference to FIG 7 and 8th described. In the second embodiment, components that are the same as in the first embodiment will not be described in detail.

The three-dimensional space R is set as described below. As in 7 Shown is a plane passing through the center of the case 11 in a front view of the housing 11 in the stacking direction of the electrode assembly 12 is taken, and parallel to the strip-side end surface 12b the electrode assembly 12 is designated as a hypothetical plane K.

A straight line, both ends of the pressure relief valve 18 in the longitudinal direction of the lid body 14 connects is called a hypothetical or assumed line T designated. A page (line) in which the hypothetical line T at the hypothetical level K reflected or reflected when viewed from the outside surface 14b of the lid body 14 regarded as a hypothetical or assumed side (hypothetical line) G designated. A plane created by reflecting the hypothetical side G over the entire dimension of the electrode assembly 12 formed in the stacking direction is called a ground plane S1 designated. The ground level S1 has a rectangular or rectangular shape including a side, through the hypothetical side G is defined, and another page passing through an end of the hypothetical page G passes and extends in the stacking direction.

The three-dimensional area R is an area that is surrounded by a plane that is the contour of the ground level S1 and the contour of the valve body 19 the pressure relief valve 18 connects in a shortest distance. The three-dimensional area R The second embodiment is an area that is from the ground level S1 , the area of the valve body 19 in the pressure relief valve 18 and the levels surrounding the ground level S1 and the area of the valve body 19 connect. The three-dimensional area R The second embodiment has the shape of a quadrangular truncated cone. In the three-dimensional area R the dimension increases along the short side direction of the lid body 14 gradually from the valve body 19 to the floor area S1 at.

As in 8th is shown, the three-dimensional area R the cross section Ra on that along the strip-side end face 12b lies. In the cross section Ra is a dimension of the lid body 14 in the short side direction greater than that of the valve body 19 , Further, the cross section Ra of the three-dimensional area R completely from the outside surface 61a the shielding section 61 the shielding component 60 covered, that at the strip-side end face 12b is mounted.

Therefore, the second embodiment has the following advantage in addition to the advantages of the first embodiment.

(19) In the second embodiment, even if gas from any point in the ground plane S1 is generated during the nail penetration test, the gas passes through the three-dimensional space or area R to the pressure relief valve 18 out. The shielding component 60 is located at a position that covers the entire cross section Ra of the three-dimensional area R covers. Accordingly, the gas that hits the pressure relief valve strikes 18 towards the outer surface during the nail penetration test 61a the shielding section 61 and the flow direction of the gas is from the delivery path, which is just to the pressure relief valve 18 is directed, deflected and extended the gas delivery path, which is to the pressure relief valve 18 extends. As a result, the fragments of the electrodes fall 21 . 31 and the metal foils 21a . 31a out of the gas into the housing 11 and the fragments will not come out of the case 11 scattered with the gas. This avoids the generation of sparks.

The foregoing embodiments may be modified as described below.

In the first embodiment, the area of the shielding member 60 is set, as described below. That is, in the front view of the housing 11 For example, the position where two diagonal lines intersect becomes the center of the housing 11 in a front view. A line passing through the middle of the case 11 in a front view and in the stacking direction of the electrodes 21 . 31 extends is referred to as the centerline. An area surrounded by a plane containing a point of movement or a moving point at a given position on the center line and the contour of the valve body 19 in the pressure relief valve 18 connecting at the shortest distance is referred to as the three-dimensional area. An entire area in which the three-dimensional area moves when the moving point is over the entire dimension of the electrode assembly 12 in the stacking direction of the electrodes 21 . 31 is moved along the center line is referred to as an entire three-dimensional area. In other words, the entire three-dimensional area is the entire area occupied by a moving trajectory of the three-dimensional area obtained when the moving point is over the entire dimension of the electrode assembly 12 in the stacking direction of the electrodes 21 . 31 moved along the center line. A cross section of the entire three-dimensional area along the strip-side end face 12b the electrode assembly 12 lies in the coverage area H before and is completely from the shielding 60 covered.

As in 9 is shown, in any embodiment and any shape, the shielding 60 have a shape in which the second rib 63 at both short edges of the shielding section 61 is arranged. When designed in such a way, the gas that blows to the pressure relief valve will strike 18 out flows from the side on which the negative electrode line component 51 located, so against the second rib 63 that the fragments of the electrodes 21 . 31 and the metal foils 21a . 31a fall out of the gas. In the second rib 63 on the side on which the negative electrode lead component 51 is the projection distance or the projection distance H2 that the dimension of the outer surface 61a the shielding section 61 is, preferably smaller (lower or lower) than the projection distance and the projection distance H2 the second rib 63 on the side on which the positive electrode line component 41 located. As a result, the flow path resistance is the positive one The electrode side gas discharge path is larger than the flow path resistance of the negative side gas discharge path, that is, the flow path area of the positive side gas discharge path is smaller than the flow path area of the negative side gas discharge path.

As in 10 is shown, in each embodiment and each form the center position C1 the pressure relief valve 18 closer to the negative electrode lead component 51 as the middle position C2 between the strip 25 (Strip group 26 ) of the positive electrode 21 and the strip 35 (Strip group 36 ) of the negative electrode 31 in the longitudinal direction of the lid body 14 are located.

When designed in such a way, for example, when the shielding member 60 the second rib 63 at each of the short edges of the shielding portion 61 is arranged, and when the projection distance H2 from both second rib 63 is the same, the positive-electrode side gas discharge path is longer than the negative-electrode side gas discharge path, and the flow path resistance of the positive-electrode side gas delivery path is larger than the flow path resistance of the negative-electrode side gas delivery path.

During the nail penetration test, the gas that is between the strips 25 and the positive electrode side passes against the positive electrode lead member 41 beat and at least one of the strip 25 the positive electrode 21 or the positive electrode lead component 41 may partially melt or be scrapped by the high temperature high pressure gas and suspended in the gas. In this case, the gas strikes against the lid body 14 before leaving the case 11 from the pressure relief valve 18 is delivered. As a result, fragments of the strip become 25 and the positive electrode line component 41 not out of the case 11 from the pressure relief valve 18 issued.

The stripe 25 (Strip group 26 ) of the positive electrode 21 and the strip 35 (Strip group 36 ) of the negative electrode 31 can be modified as in 11 and 12 in the rechargeable battery 10 is shown, in which the projection distance H2 from both second ribs 63 the same is.

A gap S can be between the side surface of the strip group 26 on the positive electrode side and the side surface of the second rib 63 be provided, that of the strip group 26 in the longitudinal direction of the lid body 14 is facing. Similarly, a gap S between the side surface of the strip group 36 on the negative electrode side and the side surface of the second rib 63 be provided, that of the strip group 36 in the longitudinal direction of the lid body 14 is facing. The distal end of the positive electrode lead member 41 can be arranged to the gap S from the side of the gap S from cover on which the lid body 14 located, and the positive electrode line component 41 can be used as a gas shock component. Likewise, the distal end of the negative electrode lead member may 51 be arranged to the gap S from the side of the gap S from cover on which the lid body 14 located, and the negative electrode line component 51 can be used as a gas shock component.

When designed in such a manner, the generated gas flows through the room during the nail penetration test S between the second rib 63 and the shielding member 60 and the strip 25 the positive electrode 21 , and accordingly the strip resists 25 a melt compared with it when the gas between the strips 25 the positive electrode 21 flows. If the gas that passes through the gap S flows, against the positive electrode line component 41 beats, the fragments of the strip fall 25 and the positive electrode line component 41 out of the gas and the fragments will not come out of the case 11 from the pressure relief valve 18 issued.

On the negative electrode side, the gas also flows through the room S between the second rib 63 the shielding component 60 and the strip 35 the negative electrode 31 and the strip 35 resists melting when compared to the gas between the strips 35 the negative electrode 31 flows. Further, if the gas passing through the gap S flows, against the negative electrode line component 51 beats, the fragments of the strip fall 35 and the negative electrode line component 51 out of the gas and the fragments are not from the pressure relief valve 18 out of the case 11 handed out.

As in 13 is shown, the gas striking component, the gap S from the side of the gap S covering out, on which the lid body 14 is located by a projection 63b be formed, to each strip 25 . 35 from the second rib 63 the shielding component 60 protrudes, or, although not shown in the drawings, through the distal ends of both conduit components 41 . 51 and the lead 63b the second rib 63 ,

In the form that is in 11 to 13 is shown, the center position can be C1 the pressure relief valve 18 closer to the positive electrode line component 41 as the center position C2 between the strip 25 (Strip group 26 ) of the positive electrode 21 and the strip 35 (Strip group 36 ) of the negative electrode 31 in the longitudinal direction of the case main body 13 are located. The projection distance H2 can be between the two second ribs 63 differ.

The shielding component 60 spaced the inner surface 14a the lid component or the lid body 14 from the shielding section 61 ,

Furthermore, the gas hammer component does not have to cover the entire gap S cover and a very small through hole may be in the distal end of each conduit component 41 . 51 and the lead 63b the second rib 63 be educated.

The shielding component 60 can be shaped to the second rib 63 at the short edge on the side on which the negative electrode lead component 51 instead of on the side on which the positive electrode lead component is located 41 located.

The shielding component 60 that from the inside surface 14a of the lid body 14 is spaced, and the shielding section 61 need the pressure relief valve 18 do not block. Accordingly, the shielding member 60 a spacer bar 64 which serves as the spacer instead of the first rib 62 and the second rib 63 ,

As in 14 is shown, the distance rod protrudes 64 from each of the four corners of the shielding section 61 in front. A distal end surface in the protrusion direction of the spacer bar 64 touches four digits that the pressure relief valve 18 the inner surface 14a of the lid body 14 surround.

When designed in such a way, even if the gas to the pressure relief valve 18 rises and the gas against the outer surface 61a the shielding section 61 strikes, touches the distance bar 64 the inner surface 14a of the lid body 14 and maintains a state in which the shielding portion 61 and the inner surface 14a spaced apart from each other. This avoids a situation where the pressure relief valve 18 through the shielding section 61 is closed.

There is also a flow path between the adjacent spacer bars 64 trained and gas leading to the pressure relief valve 18 flows, is not blocked.

The distance bar 64 can be thicker than 14 is shown. When designed in such a way, the spacer bar becomes 64 not damaged by the gas generated during the nail penetration test and a condition in which the pressure release valve 18 from the shielding section 61 covered from the side on which the electrode assembly 12 can be retained.

In any embodiment and any shape, the thickness of the first rib 62 and the second rib 63 be increased to improve or increase the stiffness. When designed in such a way, become the first rib 62 and the second rib 63 not damaged by the gas generated during the nail penetration test. As a result, a state in which the pressure release valve 18 with the shielding section 61 covered from the side on which the electrode assembly 12 located, through the first rib 62 and further, the flow path resistance of the positive-electrode side gas discharge path is larger than the flow path resistance of the negative-electrode side gas discharge path, and the negative-electrode side gas discharge path having a larger flow path sectional area than the positive-electrode side gas discharge path can pass through the second rib 63 be guaranteed.

In any embodiment and any shape, the thickness of the shielding portion 61 be increased to the rigidity of the Abschirmabschnitts 61 to increase. When designed in such a manner, the shielding portion becomes 61 not damaged by the gas generated during the nail penetration test and a condition in which the pressure release valve 18 with the shielding section 61 covered from the side on which the electrode assembly 12 can be retained.

As in 15 is shown, in any embodiment and any shape, the shielding 60 be formed to have a baffle plate 65 in the longitudinal direction of the Abschirmabschnitts 61 from both short sides of the shielding section 61 protrudes beyond. The baffle 65 has a flat plate shape.

As in 16 and 17 is shown overlaps each baffle 65 each one of the strips 25 . 35 if from the outside surface 14b of the lid body 14 from, and each of the strips 25 . 35 is in the longitudinal direction of the lid body 14 from the side of the stripes 25 . 35 covered on which the electrode assembly 12 located.

When designed in such a way as with an arrow Y shown in each of the strip groups 26 . 36 if gas from between the strips 25 . 35 is discharged from, which are adjacent in the stacking direction, the gas strikes against the baffle 65 , This distracts the Direction of flow of the gas from the delivery path from which straight to the pressure relief valve 18 directed and accordingly extends the gas delivery path leading to the pressure relief valve 18 directed, which can be extended. As a result, the fragments of the electrodes fall 21 . 31 and the metal foils 21a . 31a out of the gas into the housing 11 , This reduces the fragments coming out of the case 11 be scattered with the gas, and avoid the generation of sparks.

As in 18 and 19 shown when the second rib 63 at the short edges of the shielding section 61 is provided, the shielding 60 be shaped to a variety of gas through holes 63a to be shown through the second rib 63 extend on the side on which the negative electrode line component 51 located in the thickness direction. When designed in such a way, beat the fragments of the electrodes 21 . 31 and the metal foils 21a . 31a , which are suspended in the gas, against the second rib 63 and fall out of the gas. The gas can pass through the gas through hole 63a pass through and out of the case 11 through the pressure relief valve 18 be discharged through. The gas passage hole 63a works to the fragments of the electrodes 21 . 31 and the metal foils 21a . 31a that would cause sparks to remove. This reduces fragments coming out of the case 11 scattered with the gas, which prevents the generation of sparks. Preferably, the hole diameter of the gas passage hole becomes 63a in accordance with the size of the fragments of each of the electrodes 21 . 31 and each of the metal foils 21a . 31a changed, which are suspended in the gas. Preferably, the hole diameter of the gas passage hole 63a in order to maintain the state where the flow path resistance of the negative-electrode side gas discharge path is smaller than the flow path resistance of the positive-electrode side gas discharge path; in other words, the state in which the flow path sectional area of the negative-electrode side gas discharge path is larger than the flow path sectional area of the positive-electrode side gas supply path. The gas passage hole 63a can in the second rib 63 be formed on the side on which the positive electrode line component 41 located, and the Abschirmbauteil 60 can the gas passage hole 63a in both second ribs 63 exhibit.

In each embodiment and each form, as in 20A is shown, the Abschirmbauteil 60 a reinforcing rib 64 having, with the shielding 61 and the first rib 62 is connected and in the short side direction of the Abschirmabschnitts 61 is formed extending.

Alternatively, as in 20B is shown, the Abschirmbauteil 60 a reinforcing rib 75 having, with the shielding 61 and the second rib 63 is connected and in the short side direction of the Abschirmabschnitts 61 is formed extending.

When designed in such a manner, the shielding member may 60 through the reinforcing ribs 74 . 75 be strengthened and a deformation of the shielding 60 is limited when gas hits against it.

In each embodiment and each form, as in 21 is shown, the negative electrode line component 51 an overlapping section 51a have, which is closer to the positive electrode line component 41 as the strip group 36 located. The overlapping section 51a overlaps the lid body 14 and the shielding section 61 if from the outside surface 14b of the lid body 14 out of view. A distal end surface of the overlapping portion 51a , which is a longitudinal end surface of the negative electrode conductive member 51 is, overlaps the edge of the pressure relief valve 18 when the lid body 14 from the outside surface 14b is considered from, and the overlapping section 51a covers the pressure relief valve 18 not from the side of the lid body 14 starting on which the electrode assembly 12 located. The overlapping section 51a can on or on the positive electrode line component 41 be arranged.

When designed in such a manner, the gas whose direction changes when it strikes the shielding section 61 beats, and flows to the side on which the negative electrode line component 41 located between the mating surfaces of the overlapping section 51a and the shielding section 61 to the pressure relief valve 18 by. As a result, the overlapping section reduces 51a a contact of the high-temperature gas with the lid body 14 , In particular, since the negative electrode line component 51 Made of copper and has a high thermal resistance, the overlapping section 51a not melted by the gas and the overlapping section 51a limits melting of the lid body 14 ,

In each embodiment and each form, as in 22 is shown, the negative electrode line component 51 the overlapping section 51a have, which is closer to the positive electrode line component 41 as the strip group 36 located. The negative electrode lead component 51 can have a curved section 51b that to the lid body 14 is bent such that the distal end of the overlapping portion 51a the pressure relief valve 18 approaches. The curved one section 51b may be at any position as long as it is closer to the positive electrode lead component 41 as a welded section of the strip group 36 and the negative electrode lead member 51 located. The overlapping section 51a covers the pressure relief valve 18 not from the side on which the electrode assembly 12 located. The overlapping section 51a and the bent section 51b can on or on the positive electrode line component 41 be arranged.

When designed in such a manner, the gas whose direction changes when it strikes the shielding section 61 beats, and that flows to the side on which the negative electrode line component 51 located between the mating surfaces of the overlapping section 51a and the shielding section 61 to the pressure relief valve 18 along the surface of the overlapping section 51a , A distal end surface of the overlapping portion 51a is arranged to the edge of the pressure relief valve 18 to be facing. Accordingly, gas flows along the overlapping portion 51a to the pressure relief valve 18 out. As a result, the gas does not strike against the vicinity of the pressure relief valve 18 in the lid body 14 and the vicinity of the pressure relief valve 18 in the lid body 14 does not melt.

In each embodiment and each form, the pair of first ribs 62 the shielding component 60 not from every long edge of the shielding section 61 protrude. For example, as in 23 can be shown in the shielding section 61 the first ribs 62 project from a position close to each other in the short side direction. If from the outside surface 14b of the lid body 14 From the first ribs can 62 close to each other in the longitudinal direction of the lid body 14 between the positive electrode lead component 41 and the negative electrode lead member 51 are located.

When configured in such a manner, a longitudinal end surface of each of the two first ribs contacts 62 the distal end surface extending from a longitudinal end surface of the positive electrode lead member 41 is defined. The other longitudinal end face of each of the two first ribs 62 contacts the distal end surface of a longitudinal end surface of the negative electrode lead member 51 is defined. The shielding component 60 immediately contacts the distal end surface of the positive electrode lead member 41 or the negative electrode lead component 51 if it is slightly in the longitudinal direction of the lid body 14 is moved. Accordingly, the shielding member restricts 60 a movement of the lid body 14 in the longitudinal direction. Therefore, the positive electrode lead member serve 41 and the negative electrode lead member 51 as movement restricting members, which is a movement of the shielding member 60 in the longitudinal direction of the lid body 14 restrict.

In any embodiment and any shape, as the movement of the shielding member 60 in the longitudinal direction of the lid body 14 is limited, the second rib 63 the side surface of the strip group 26 touch on the positive electrode side and may be the first rib 62 the side surface of the strip group 36 on the negative electrode side.

In any embodiment and any shape, as the movement of the shielding member 60 in the longitudinal direction of the lid body 14 is limited, the second rib 63 the side surface of the strip group 26 touch on the positive electrode side and may be the first rib 62 the end face of the negative electrode lead member 51 touch.

In each embodiment and each form, as in 24 and 25 is shown when the lid body 14 from the outside surface 14b is considered, the pressure relief valve 18 be disposed at a position that the negative electrode line component 51 overlaps, and may be the Abschirmbauteil 60 on the negative electrode line component 51 be mounted or attached.
In this case, the shielding 60 or can not completely cross section Ra cover, located at the strip-side end face 12b of the three-dimensional area R is the center P which is present at the shorted part in the nail penetration test, and the pressure release valve 18 combines. It is only necessary that the shielding 60 a rib having a surface that intersects the gas flow path. The first rib 62 and the second rib 63 have an outer surface facing the lid body 14 from the shielding section 61 rises and the gas path along the inner surface 61e the shielding section 61 cuts.

When configured in such a manner, the gas generated during the nail penetration test flows to a location closer to the lid body 14 is as the negative electrode lead component 51 or the positive electrode lead component 41 , and then flows along the gas path, which extends along the inner surface 61e the shielding section 61 extends. The remaining gas hits the first rib 62 and the second rib 63 , rises along the first and second ribs 62 . 63 and enters through a gap between the distal end surface of each rib 62 . 63 and the inner surface 14a of the lid body 14 to the pressure relief valve 18 to reach.

Accordingly, the fragments of the electrodes fall 21 . 31 and the metal foils 21a . 31a out of the gas into the housing 11 if they are against the first rib 62 and the second rib 63 beat. This reduces fragments coming out of the case 11 are scattered out with the gas, and limits the generation of sparks. Although not shown in the drawings, when the lid body 14 from the outside surface 14b is considered, the pressure relief valve 18 disposed at a position that the positive electrode lead member 41 overlaps, and may be on the positive electrode lead component 41 be mounted.

As in 26A is shown, a Abschirmbauteil 66 have the shape of a square box and the shielding member 66 may be at the strip-side end face 12b be mounted such that a central axis M of the shielding 66 in the longitudinal direction of the lid body 14 extends. The shielding component 66 has a shielding section 67 at a bottom portion of the strip-side end surface 12b the electrode assembly 12 is supported. The shielding component 66 has a gas inlet 66a on an end side in the axial direction (side on which the negative electrode lead member 51 is located). The shielding component 66 has a gas outlet 66b on going to the pressure relief valve 18 is open at the other end side in the axial direction in a top plate and a top plate, respectively 68 that the lid body 14 is facing. In addition, the shielding accommodates 66 a railway change wall 66c , The railway change wall 66c is plate-shaped and protrudes to the shielding section 67 from the inner surface of the upper plate 68 from before and has a gap between the projection end of the web change wall 66c and the shielding section 67 , The railway change wall 66c is shaped such that the long side is in the short side direction of the lid body 14 extends.
When designed in such a manner, the gas generated during the nail penetration test is changed in one direction when it is against the shielding portion 67 suggests. After it has flowed to the side on which the negative electrode lead component 51 is located, the gas flows into the shielding member 66 from the gas inlet 66a out, like an arrow Y is shown. Although the gas to the gas outlet 66b flows to the pressure relief valve 18 is opened, the gas path is changed and to the shielding section 67 through the railway change wall 66c Directed after the gas against the top plate 68 the shielding component 66 suggests. Then the gas flows between the web change wall 66c and the shielding section 67 and from the shielding member 66 from the gas outlet 66b out. The gas is then removed from the housing 11 from the pressure relief valve 18 issued.

That's why the gas hits the top plate 68 and the shielding section 67 in the shielding member 66 due to the arrangement of the web change wall 66c , As a result, the fragments of the electrodes fall 21 . 31 and the metal foils 21a . 31a out of the gas into the housing 11 when the gas is against the shielding section 67 and the top plate 68 beats, and the fragments will not come out of the case 11 out with the gas scattered. This limits the generation of sparks. The force of the gas is reduced as the gas strikes against the shielding section 67 and the top plate 68 so that the fragments fall out of the gas.

As in 26b is shown, the path change wall protrudes 66c from the inner surface of the shielding portion 67 instead of the top plate 68 and a gap between the projection end of the web change wall 66c and the top plate 68 and between the railway change wall 66c and the first rib 62 formed on the two sides. When designed in such a way, the gas that strikes the shielding component strikes 66 from the gas inlet 66a flowed out, even against the first rib 62 that with the shielding section 67 and the top plate 68 connected, in addition to the top plate 68 and the shielding section 67 ,

As in 27 can be shown in each embodiment and each form of the lid body 14 pressed or pressed to a Abschirmbauteil 69 to provide that with the lid body 14 is integrated, and the Abschirmbauteil 69 can be arranged to the positive electrode 21 and the negative electrode 31 between the inner surface 14a of the lid body 14 and the strip-side end surface 12b the electrode assembly 12 not short circuit. The surface of the shielding component 69 is covered with a coating of an insulating resin or ceramic to short-circuit the positive electrode 21 and the negative electrode 31 to prevent that by the shielding component 69 would be caused.

A hole in the lid body 14 can with a web-like valve body 77 be covered by forming the Abschirmbauteils 69 in the lid body 14 and a pressure relief valve 78 can the valve body 77 exhibit. The discharge pressure of the pressure relief valve 78 is set to a pressure at which the pressure relief valve ruptures before the housing 11 or a connecting portion of the housing main body 13 and the lid body 14 gets a crack or breaks.

When designed in such a way, covers a shielding section 69a the shielding component 69 completely the cross section Ra starting at the strip-side end face 12b of three-dimensional area R is the center P which is present in the short-circuited part, and the pressure release valve 78 combines. Accordingly, gas strikes the pressure release valve during the nail penetration test 78 flows against the outer surface of the shielding 69a and the flow direction of the gas is from the web, which straight to the pressure relief valve 78 directed, deflected to extend the gas delivery path, which is to the pressure relief valve 78 extends. As a result, the fragments of the electrodes fall 21 . 31 and the metal foils 21a . 31a out of the gas into the housing 11 and the fragments will not come out of the case 11 out with the gas scattered. This limits the generation of sparks.

As in 28 is shown, in each embodiment and each shape of the shielding 61 have a round shape, gradually moving outward to the strip-side end face 12b bulges outward from the peripheral edge towards the central part. In this case, the shielding member restricts 60 a movement between the inner surface 14a of the lid body 14 and the strip-side end surface 12b the electrode assembly 12 by the first rib 62 the inner surface 14a of the lid body 14 touched. The round shape is not limited to the shape used in 24 is shown, and may be a shape, which is to the strip-side end face 12b completely from the peripheral edge to the middle part of the shielding portion 61 arching out.

When designed in such a manner, during the nail penetration test, the gas coming to the pressure release valve beats 18 flows towards, against the outer surface 61a the shielding section 61 , However, the shielding section is 61 round. This reduces deformation of the shielding portion 61 that would be caused by gas.

In each embodiment and each form, as in 29 shown is the rechargeable battery 10 a housing rib 73 on the long side wall 13d of the housing main body 13 exhibit. The shell rib 73 has a rectangular plate shape in which the long side is in the longitudinal direction of the long side wall 13d extends, and there is more than one shell rib 73 in the short side direction of the long sidewall 13d are arranged. Further, when the lid body 14 from the outside surface 14b is considered, is the housing rib 73 along the first rib 62 the shielding component 60 arranged.

When designed in such a manner, the electrode assembly expands during the nail penetration test 12 in the stacking direction, when the temperature rises, and the case 11 is deformed and expands in the stacking direction by the expansion of the electrode assembly 12 on. However, the deformation of the housing 11 in the stacking direction through the housing rib 73 be reduced. As a result, the gap between the outer surface of the first rib widens 62 the shielding component 60 and the inner surface of the long side wall 13d not up. This limits passage of the gas through the gap.

In each embodiment, as in 30 is shown, the pressure relief valve 18 closer to the negative electrode lead component 51 be arranged as the embodiment. When designed in such a way, the gas whose direction is changed when it is against the shielding section 61 beats and flows to the side on which the negative electrode line component 51 located at the end edge of the Abschirmabschnitts 61 to the pressure relief valve 18 distracted. In this case, because the pressure relief valve 18 closer to the negative electrode lead component 51 is the gas that hits the pressure relief valve 18 from the shielding section 61 is deflected, not against the lid body 14 and the lid body 14 is not melted by the heat of the gas.

As in 31 shown is the rechargeable battery 80 be of a cylindrical nature. The rechargeable battery 80 has an electrode assembly 85 a winding on, in which a band-shaped positive electrode 82 and a band-shaped negative electrode 83 stacked and through the separator 84 in a hollow, circular, columnar housing 81 are wound. The housing 81 is made of metal and has a shape in which one end is closed in the axial direction and the other end is open. The housing 81 is filled with an electrolytic solution and the separator 84 is impregnated in the electrolytic solution. The rechargeable battery 80 has an insulating plate 86 at both ends in the axial direction of the electrode assembly 85 on.

The rechargeable battery 80 has a lid body 87 on, acting as a wall at the open end of the case 81 serves, and a pressure relief valve 88 on the inside of the lid body 87 is arranged. The pressure relief valve 88 is electrically connected to the lid body 87 connected and a disc plate 88a the pressure relief valve 88 is torn open to the pressure in the housing 81 out of the case 81 during the nail penetration test, when the pressure in the housing 81 reached the discharge pressure by an internal short circuit. The rechargeable battery 80 has a center pin 90 on that at the center of the electrode assembly 85 is arranged. A positive electrode lead 91 is with the positive electrode 82 the electrode assembly 85 connected and a negative electrode line 92 is with the negative electrode 83 connected. The positive electrode line 91 has an end, that at the positive electrode 82 is fixed, and another end connected to the pressure relief valve 88 is welded to electrically with the lid body 87 to be connected. The negative electrode lead 92 has an end, that at the negative electrode 83 is fixed, and another end attached to the housing 81 welded to the electrical connection.

The rechargeable battery 80 has a shielding component 94 on, that the pressure relief valve 88 from the side of the lid body 14 from covering on which the electrode assembly 85 located. In the front view of the housing 81 that is, when the case 81 in the radial direction, the center becomes in the axial direction and the radial direction of the housing 81 as the middle of the case 81 in a front view. In the cylindrical rechargeable battery 80 is the radial direction of the housing 81 the stacking direction (X-axis direction) of the electrodes 82 . 83 , A point located at the center of the case 81 located in the front view and at the center of the electrode assembly 85 in the stacking direction is called the center point P designated. An area surrounded by a plane that is the center P and a contour of the pressure relief valve 88 connecting at a shortest distance is called a three-dimensional area R designated. In the electrode assembly 85 lies a cross section Ra of the three-dimensional area R on the end face on the side in front, on which the pressure relief valve 88 located in the axial direction. The cross section Ra becomes completely from a plate-shaped shielding section 95 the shielding component 94 covered.

In the cylindrical rechargeable battery 80 may be the area of the shielding section 95 may be set in the same manner as in the second embodiment or another modified example. For example, if the three-dimensional area R is set according to the second embodiment, the X-axis extends along the radial direction of the housing 81 (Stacking direction of the electrodes 82 . 83 ) and the Y-axis is orthogonal to the X-axis and parallel to the lid body 87 , A plane passing through the middle of the case 81 in the front view leads, in which the housing 81 in the direction of the X-axis, and parallel to the end face of the electrode assembly 85 is called a hypothetical plane. A line in which a straight line, both ends of the pressure relief valve 88 along the direction of the Y-axis connects, is reflected on the hypothetical plane, that of the outer surface of the lid body 87 from is considered a hypothetical line. A plane created by reflecting the hypothetical line over the entire dimension of the electrode assembly 85 is formed in the direction of the X-axis is referred to as a ground plane. An area surrounded by a plane containing the contour of the ground plane and the contour of the pressure relief valve 88 connecting at a shortest distance is called the three-dimensional area R designated.

The shielding component 60 can be made of metal. When the shielding component 60 is made of metal, is an insulating member between a component of the positive electrode potential (positive electrode line component 41 and positive electrode 21 ) and a negative electrode potential component (negative electrode line component 51 and negative electrode 31 ). The insulating member may be provided with one or both of a component charged with potentials and the shield member 60 be integrated. The insulating member may be a coating of insulating resin or ceramics.

Alternatively, when the shielding member 60 is made of metal, is the Abschirmbauteil 60 not arranged to connect one of the components of the positive electrode potential (positive electrode line component 41 and positive electrode 21 ) or the component of the negative electrode potential (negative electrode line component 51 and negative electrode 31 ) when touching the other component.

When designed in such a manner, the shielding member resists 60 easily a melting, which would be caused by the high-temperature high-pressure gas.

When made of metal, the shielding component can 60 on the lid body 14 , every conductive component 41 . 51 or other components are welded and fixed. When designed in such a manner, a heat-resistant coating is preferably carried out at the welded location.

The stripe 35 the negative electrode 31 is shaped to from an end face of the electrode assembly 12 protrude, extending from the strip-side end face 12b different. In this case, the negative electrode tab group lies 36 also at an end face extending from the strip-side end face 12b differs, and has the negative electrode line component 51 also a shape that protrudes from the protruding end face of the strip 35 to the strip-side end surface 12b bent at which the positive electrode strip 25 projects.

In the first embodiment, the shielding portion covers 61 the shielding component 60 the entire cross section Ra of the three-dimensional area R but the shielding section can 61 only part of the cross section Ra cover.

When designed in such a manner, during the nail penetration test, some of the gas going to the pressure relief valve will strike 18 flows towards, against the outer surface 61a the shielding section 61 so that the flow direction of the gas is diverted from the delivery path, straight to the pressure relief valve 18 directed, and the gas delivery path to the pressure relief valve 18 can be extended. As a result, the fragments of the electrodes fall 21 . 31 and the metal foils 21a . 31a out of the gas into the housing 11 and the fragments will not come out of the case 11 scattered with the gas. This limits the generation of sparks.

Further, during the nail penetration test, some of the generated gas flows in the stacking direction of the electrode assembly 12 along the outer surface 61a the shielding section 61 , The gas that is not against the shielding section 61 also flows in the stacking direction of the electrode assembly 12 , The electrode assembly 12 is expanded in the stacking direction when the temperature rises, and the gas flows to the pressure release valve 18 from both sides in the stacking direction of the electrode assembly 12 , The gas hits the first rib 62 and the fragments of the electrodes 21 . 31 and the metal foils 21a . 31a fall out of the gas.

In the second embodiment, the shielding portion covers 61 the shielding component 60 the entire cross section Ra of the three-dimensional area R but the shielding section can 61 only part of the cross section Ra cover. When designed in such a manner, during the nail penetration test, some of the gas going to the pressure relief valve will strike 18 flows towards, against the outer surface 61a the shielding section 61 such that the direction of flow of the gas is diverted from the delivery path straight to the pressure relief valve 18 is aligned, and the gas delivery path to the pressure relief valve 18 can be extended. As a result, the fragments of the electrodes fall 21 . 31 and the metal foils 21a . 31a out of the gas into the housing 11 and the fragments can be suppressed therein, to the outside of the housing 11 to fly off with the gas, whereby the generation of sparks is suppressed or suppressed.

Further, during the nail penetration test, a part of the generated gas becomes in the stacking direction of the electrode assembly 12 along the outer surface 61a the shielding section 61 flowed. The gas that is not against the shielding section 61 flows, also flows in the stacking direction of the electrode assembly 12 , The electrode assembly 12 is expanded in the stacking direction by the temperature rise and the gas flows to the pressure release valve 18 from both sides in the stacking direction of the electrode assembly 12 , Such gas hits the first rib 62 and the fragments of the electrodes 21 . 31 and the metal foils 21a . 31a fall out of the gas.

In the shielding component 60 may be the first rib 62 only from the long edges of the shielding section 61 protrude.

In the shielding component 60 can the second rib 63 can be omitted and may be the first rib 62 be omitted.

In each embodiment and each form, as in 32 is shown, the projection end of the shielding portion 61 the second rib 63 the inner surface 14a of the lid body 14 touch. When designed in such a manner, even if the shielding member 60 is moved in the longitudinal direction of the lid body 14 during the Nagelpenetrationstests when the gas pressure is absorbed, as long as the second rib 63 in contact with the lid body 14 is the gas that hits the pressure relief valve 18 flows towards the second rib 63 and the fragments of the electrodes 21 . 31 and the metal foils 21a . 31a fall out of the gas.

The shielding component 60 that is made of resin is not on the strip-side end surface 12b attached and can with the inner surface 14a of the lid body 14 or another component by a bond, a weld and the like.

In every embodiment and every form, the shielding section needs 61 the shielding component 60 not completely the coverage area H in the strip-side end surface 12b cover. The shielding section 61 can be the same size as the cross section Ra have or may be larger than the cross section Ra be, as long as the cross section Ra at the strip-side end surface 12b is completely covered.

The separator 24 does not have to be of a type in which a separator is between each positive electrode 21 and the adjacent negative electrode 31 and may be, for example, a bag-shaped separator containing the positive electrode 21 houses.

Alternatively, the separator may be an elongated type and in a zig-zag manner between the positive electrodes 21 , and the negative electrodes 31 be bent.

The electrode assembly may be of a winding type in which a band-shaped positive electrode and a band-shaped negative electrode are insulated by a separator and wound around a winding axis.

The power storage device may be of a different type of power storage device, such as an electric double layer capacitor.

In each embodiment and each form is the rechargeable battery 10 a rechargeable lithium-ion battery, however, may instead be a different type of rechargeable battery, such as a nickel-metal hybrid battery. It is only required that the rechargeable battery move ions and exchange charges between the positive electrode active material layer and the negative electrode active material layer.

LIST OF REFERENCE NUMBERS

C1, C2) center position; M) central axis; K) hypothetical level; P) center; R) three-dimensional area; Ra) cross section; S) gap; S1) ground level; 10) a rechargeable battery serving as a power storage device; 11) housing; 12) electrode assembly; 12b a strip side end surface serving as an end surface; 14) lid body serving as a wall; 14a) inner surface; 14b, 61a) outer surface; 18) pressure relief valve; 21) positive electrode serving as an electrode; 25, 35) strips; 26) strip group functioning as a movement restricting member; 31) negative electrode serving as an electrode; 36) strip group functioning as a movement restricting member; 41) positive electrode lead member functioning as a movement restricting member; 51) negative electrode lead member functioning as a movement restricting member; 51a) overlapping portion; 51b) bent portion; 60, 66) shielding component; 61) shielding section; 62) first rib serving as a rib forming a spacer; 63) second rib; 63a) gas passage hole; 63b) projection serving as an impact member; 64) spacer bar; 65) baffle plate; 66a) gas inlet; 66b) gas outlet; 66c) track changing wall; 74) Reinforcing rib

This power storage device has a housing housing an electrode assembly and an electrolytic solution, and a pressure relief valve provided in a wall of the housing. The electrode assembly has electrodes that have different polarities and are insulated from each other. A shield member is disposed between the inner surface of the wall and the end surface of the electrode assembly. A point located in a center of the housing in a front view of the housing taken in the stacking direction of the electrodes and located at a center of a dimension of the electrode assembly in the stacking direction is referred to as a center, and an area surrounded by a plane connecting the center and a contour of the pressure release valve at a shortest distance is called a three-dimensional area. The shielding member has a shielding portion that completely covers a cross section of the three-dimensional area along the end surface of the electrode assembly.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP4881409 [0003]

Claims (34)

An electricity storage device, comprising: an electrode assembly having a layered structure and having electrodes which are insulated from each other and have different polarities; an electrolytic solution; a housing housing the electrode assembly and the electrolytic solution; a pressure relief valve provided in a wall of the housing and configured to be torn open when a pressure in the housing reaches a relief pressure to release the pressure from the housing; and a shielding member located between an inner surface of the wall and an end surface of the electrode assembly facing the inner surface, wherein an axis extending in a stacking direction of the electrodes is referred to as an X-axis, an axis orthogonal to the X-axis and parallel to the wall is referred to as a Y-axis, a point located at a center of the housing in a front view of the housing taken in an X-axis direction and located at a center of a dimension of the electrode assembly in the X-axis direction as a center becomes, an area surrounded by a plane connecting the center and a contour of the pressure relief valve at a shortest distance, referred to as a three-dimensional area, and the shielding member has a shielding portion that completely covers a cross section of the three-dimensional area along the end surface of the electrode assembly. An electricity storage device, comprising: an electrode assembly having a layered structure and having electrodes which are insulated from each other and have different polarities; an electrolytic solution; a housing housing the electrode assembly and the electrolytic solution; a pressure relief valve provided in a wall of the housing and configured to be torn open when a pressure in the housing reaches a relief pressure to release the pressure from the housing; and a shielding member located between an inner surface of the wall and an end surface of the electrode assembly facing the inner surface, wherein an axis extending in a stacking direction of the electrodes is referred to as an X-axis, an axis orthogonal to the X-axis and parallel to the wall is referred to as a Y-axis, a plane passing through a center of the housing in a front view of the housing taken in the X-axis direction and parallel to the end surface of the electrode assembly is called a hypothetical plane, a line reflecting a straight line connecting two ends of the pressure relief valve in a direction of the Y-axis on the hypothetical plane when viewed from an outer surface of the wall is called a hypothetical line; a plane formed by reflecting the hypothetical line completely across a dimension of the electrode assembly in the direction of the X-axis is referred to as a ground plane, an area surrounded by a plane connecting a contour of the ground plane and a contour of the pressure release valve at a shortest distance, referred to as a three-dimensional area, and the shielding member has a shielding portion covering the entire cross section of the three-dimensional area along the end surface of the electrode assembly. Electricity storage device according to Claim 1 or 2 wherein the shielding member has a spacer on the shielding portion to contact a portion in the inner surface of the wall surrounding the pressure relief valve to space the shielding portion and the wall. Electricity storage device according to Claim 3 wherein the spacer is a plurality of spacer bars that are shaped to protrude from the shielding portion. Electricity storage device according to Claim 3 wherein the spacer is a rib projecting toward the wall from an edge of the shielding portion extending in a direction of the Y-axis. A power storage device comprising: an electrode assembly having a layered structure and having electrodes insulated from each other and having different polarities; an electrolytic solution; a housing housing the electrode assembly and the electrolytic solution; a pressure relief valve provided in a wall of the housing and configured to be torn open when a pressure in the housing reaches a relief pressure to release the pressure from the housing; and a shielding member located between an inner surface of the wall and an end surface of the electrode assembly facing the inner surface, wherein an axis extending in a stacking direction of the electrodes is referred to as an X-axis, an axis orthogonal to the X-axis and parallel to the wall is referred to as a Y-axis, a point located in a center of the Housing is located in a front view of the housing, which is taken in a direction of the X-axis and is located in a center of a dimension of the electrode assembly in the direction of the X-axis, referred to as a center, and a region of a Level, which connects the center and a contour of the pressure relief valve at a shortest distance, is referred to as a three-dimensional area, the shielding member comprising: a shielding portion partially covering a cross section of the three-dimensional area along the end surface of the electrode assembly, and a Rib contacting a portion in the inner surface of the wall surrounding the pressure relief valve to the Abschirmabs and the wall from each other, the rib projecting toward the wall from an edge of the shielding portion extending in a direction of the Y-axis. An electricity storage device, comprising: an electrode assembly having a layered structure and having electrodes which are insulated from each other and have different polarities; an electrolytic solution; a housing housing the electrode assembly and the electrolytic solution; a pressure relief valve provided in a wall of the housing and configured to be torn open when a pressure in the housing reaches a relief pressure to release the pressure from the housing; and a shielding member located between an inner surface of the wall and an end surface of the electrode assembly facing the inner surface, wherein an axis extending in a stacking direction of the electrodes is referred to as an X-axis, an axis orthogonal to the X-axis and parallel to the wall is referred to as a Y-axis, a plane passing through a center of the housing in a front view of the housing taken in an X-axis direction and parallel to the end surface of the electrode assembly is called a hypothetical plane, a line that reflects a straight line connecting two ends of the pressure relief valve in a direction of the Y-axis, on the hypothetical plane, when viewed from an outer surface of the wall, is called a hypothetical line, a plane formed by reflecting the hypothetical line completely over a dimension of the electrode assembly in the direction of the X-axis is referred to as a ground plane, an area surrounded by a plane connecting a contour of the ground plane and a contour of the pressure relief valve at a shortest distance, referred to as a three-dimensional area, the shielding component comprises a shielding portion partially covering a cross section of the three-dimensional area along the end face of the electrode assembly, and a rib contacting a portion in the inner surface of the wall surrounding the pressure relief valve to space the shield portion and the wall apart, the rib projecting toward the wall from an edge of the shield member which is in a Y-axis direction projects. Electricity storage device according to one of Claims 5 to 7 wherein the rib protrudes from each of two edges of the shielding portion extending in the direction of the Y-axis. Electricity storage device according to one of Claims 5 to 8th wherein the shielding member further comprises a rib projecting toward the wall from the edge of the shielding portion extending in the direction of the X-axis. Electricity storage device according to Claim 9 wherein the rib projecting from the edge of the shielding portion extending in the direction of the X-axis has a gas through hole. Electricity storage device according to one of Claims 5 to 10 , further comprising a reinforcing rib, which is connected to the shielding portion and the rib. Electricity storage device according to one of Claims 5 to 11 wherein, when the shielding member is viewed from a side of the wall on which the electrode assembly is located toward the inner surface of the wall, the rib is present within a plane defined by a contour of the shielding portion. Electricity storage device according to Claim 1 or 2 wherein the shielding member is in the form of a box and has a central axis extending in a Y-axis direction; and the shielding member includes: a gas inlet provided in an opening at one axial end, a gas outlet open toward the pressure release valve at another axial end, and a sheet changing wall extending in a gas path from the gas inlet to the gas inlet Gas outlet is located. Electricity storage device according to one of Claims 1 to 13 wherein the electrodes having different polarities are a positive electrode and a negative electrode, the positive electrode and the negative electrode have a positive electrode tab and a negative electrode tab, respectively, and the positive electrode tab is formed to protrude from the end face of the electrode assembly the power storage device further comprises: a positive electrode lead member connected to the positive electrode tab; and a negative electrode lead member connected to the negative electrode tab, wherein the positive electrode tab and the positive electrode lead member have a lower melting point than the negative electrode tab and the negative electrode lead member, the positive electrode lead member and the negative electrode lead member are aligned in a direction of the Y-axis in that the shielding member has a rib extending in the X-axis direction and being toward the positive electrode line member from the pressure release valve; a path of gas aligned in a planar direction of the wall toward the pressure relief valve from a side on which the positive electrode conduit member is located defines a positive electrode side gas delivery path, a path of gas in the planar direction of the wall leading to the Pressure relief valve is directed from a side on which the negative electrode line member is located, defines a negative Elektrodenseitengasabgabebahn, and a flow path resistance that is generated with respect to the gas in the positive Elektrodenseitengasabgabebahn, greater than a flow path resistance, with respect to the gas in the negative Elektrodenseitengasabgabbahn is produced. Electricity storage device according to Claim 14 wherein the positive side electrode gas delivery path has a flow path area smaller than that of the negative side gas discharge passageway. Electricity storage device according to Claim 14 or 15 wherein the rib has a projection end projecting from the shielding portion toward the wall to a position beyond the positive electrode conduit member. Electricity storage device according to Claim 16 wherein the projection end of the rib is spaced from the inner surface of the wall. Electricity storage device according to one of Claims 14 to 17 further comprising a movement restricting member restricting movement of the shielding member in the Y-axis direction between the inner surface of the wall and the end surface of the electrode assembly. Electricity storage device according to Claim 18 wherein the movement restricting member restraining movement of the shielding member toward the positive electrode lead member is the positive electrode lead member, and the movement restricting member restricting movement of the shielding member toward the negative electrode lead member is a stripe group formed by assembling the negative electrode strips in FIG the direction of the X-axis is designed. Electricity storage device according to Claim 18 wherein the movement restricting member restricting movement of the shielding member toward the positive electrode lead member is the positive electrode lead member, and the movement restricting member restricting movement of the shielding member toward the negative electrode lead member is the negative electrode lead member. Electricity storage device according to one of Claims 14 to 20 wherein the positive electrode tab and the negative electrode tab project from the end face of the electrode assembly and are spaced from each other in the Y-axis direction, and the shield member has a baffle overlapping the positive electrode tab and the negative electrode tab when from an outer surface of the wall from, and covers the positive electrode strip and the negative electrode strip along the direction of the Y-axis. Electricity storage device according to one of Claims 14 to 21 wherein one of the positive electrode lead member and the negative electrode lead member has an overlapping portion overlapping the wall and the shield member when viewed from an outer surface of the wall. Electricity storage device according to Claim 22 wherein one of the conduit members has a bent portion bent so that the overlapping portion is directed toward the pressure relief valve. Electricity storage device according to one of Claims 14 to 23 wherein a center position of the pressure relief valve in the direction of the Y-axis is closer to the negative electrode conduction member than a center position between the positive Electrode strips and the negative electrode strip in the direction of the Y-axis. Electricity storage device according to one of Claims 14 to 24 wherein a gap is formed between the positive electrode tab and the rib in the Y-axis direction, and a gas striking member covers the gap from a side of the wall where the gap is located. Electricity storage device according to one of Claims 1 to 25 wherein the shielding member is spaced from an inner wall of the housing. Electricity storage device according to one of Claims 1 to 26 wherein the shielding member is disposed on the end surface of the electrode assembly. Electricity storage device according to one of Claims 1 to 27 wherein the shielding member is made of metal. Electricity storage device according to one of Claims 1 to 28 wherein the shielding member is heat resistant. Electricity storage device according to one of Claims 1 to 29 wherein the inner surface of the shield member has a flat planar shape. An electricity storage device, comprising: an electrode assembly having a layered structure and having electrodes which are insulated from each other and have different polarities; an electrolytic solution; a housing housing the electrode assembly and the electrolytic solution; a pressure relief valve provided in a wall of the housing and configured to be torn open when a pressure in the housing reaches a relief pressure to release the pressure from the housing; and a shield member that is closer to the electrode assembly than to the pressure relief valve, the shield member comprising: a shielding portion that covers the pressure relief valve from a side of the wall on which the electrode assembly is located, and a rib that rises from the shielding portion toward the wall and has a surface that intersects a gas path that extends along a planar direction of the shielding portion. An electricity storage device, comprising: an electrode assembly having a layered structure and having electrodes which are insulated from each other and have different polarities; an electrolytic solution; a housing housing the electrode assembly and the electrolytic solution; and a pressure release valve provided in a wall of the housing and configured to be torn open when a pressure in the housing reaches a relief pressure to release the pressure from the housing; the wall has a shielding member located between an inner surface of the wall and an end surface of the electrode assembly facing the inner surface, an axis extending in a stacking direction of the electrodes is referred to as an X-axis, an axis orthogonal to the X-axis and parallel to the wall is referred to as a Y-axis, a point located in a center of the housing in a front view of the housing taken in an X-axis direction and located in an average of a dimension of the electrode assembly in the X-axis direction as a center referred to as, an area surrounded by a plane connecting the center and a contour of the pressure relief valve at a shortest distance, referred to as a three-dimensional area, and the shielding member has a shielding portion that completely covers a cross section of the three-dimensional area along the end surface of the electrode assembly. A power storage device comprising: an electrode assembly having a layered structure and having electrodes insulated from each other and having different polarities; an electrolytic solution; a housing housing the electrode assembly and the electrolytic solution; and a pressure relief valve provided in a wall of the housing and configured to be torn open when a pressure in the housing reaches a relief pressure to vent the pressure from the housing, the wall having a shield member extending between a housing Inner surface of the wall and an end surface of the electrode assembly, which faces the inner surface, an axis extending in a stacking direction of the electrodes is referred to as an X-axis, an axis orthogonal to the X-axis and parallel to the wall as is a Y-axis, a plane passing through a center of the housing in a front view of the housing taken in the X-axis direction and parallel to the end surface of the electrode assembly is referred to as a hypothetical plane; a line that reflects a straight line, the two ends of the pressure relief valve in a direction of the Y axis, at the hypothetical level, if when viewed from an outer surface of the wall, referred to as a hypothetical line, a plane formed by reflecting the hypothetical line completely over a dimension of the electrode assembly in the direction of the X-axis is called a bottom plane, an area surrounded by a plane connecting a contour of the bottom plane and a contour of the pressure relief valve at a shortest distance, referred to as a three-dimensional area, the shielding member has a shielding portion that completely covers a cross section of the three-dimensional area along the end face of the electrode assembly. An electricity storage device, comprising: an electrode assembly having a layered structure and having electrodes which are insulated from each other and have different polarities; an electrolytic solution; a housing housing the electrode assembly and the electrolytic solution; a pressure relief valve provided in a wall of the housing and configured to be ruptured when a pressure in the housing reaches a relief pressure to release pressure from the housing; and a shielding member located between an inner surface of the wall and an end surface of the electrode assembly facing the inner surface, wherein an axis extending in a stacking direction of the electrodes is referred to as an X-axis, an axis orthogonal to the X-axis and parallel to the wall is referred to as a Y-axis, a line passing through a center of the housing in a front view of the housing taken in the X-axis direction and extending in the X-axis direction, called a center line, an area surrounded by a plane connecting a moving point located at a given position on the center line and a contour of the depressurizing valve at a shortest distance, referred to as a three-dimensional area, and an entire area in which the three-dimensional area moves when the moving point is moved along the entire line of the electrode assembly in the X-axis direction along the center line is referred to as an entire three-dimensional area, the shielding member has a shielding portion that completely covers a cross section of the entire three-dimensional area along the end surface of the electrode assembly.

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