WO2019064777A1 - Current breaking device and power storage device - Google Patents

Abstract

This current breaking device is provided with a first current-carrying member, a second current-carrying member, and a deformable member. The first current-carrying member is connected to an electrode terminal. The second current-carrying member is connected to an electrode. The second current-carrying member is spaced away from the first current-carrying member and disposed so as to face the first current-carrying member. The second current-carrying member also has a recess formed therein on the side facing the first current-carrying member. The deformable member is disposed between the first current-carrying member and the second current-carrying member. Ends of the deformable member are joined to the first current-carrying member. When the pressure inside a case is not more than a prescribed value, a central part of the deformable member gets connected to the second current-carrying member within the recess of the second current-carrying member so as to cause conduction between the first and second current-carrying members. In addition, when the pressure inside the case exceeds the prescribed value, snap-buckling takes place in the deformable member so as to bring the first and second current-carrying members into a nonconductive state.

Description

Current interrupting device and power storage device

The technology disclosed herein relates to a current interrupting device and a storage device.

Development of a current interrupting device that cuts off the current flowing between the electrode terminals (positive and negative terminals) using pressure rise in the case when the storage device is overcharged or a short circuit occurs internally is advanced. ing. The current interrupting device is disposed between the electrode terminal and the electrode (between the positive electrode terminal and the positive electrode or between the negative electrode terminal and the negative electrode). In WO 2013/164897 (hereinafter referred to as Patent Document 1), it is connected to a first conducting member (pressure-sensitive member holder) connected to an electrode terminal (positive electrode terminal) and an electrode (positive electrode sheet). A second current-carrying member (current collecting plate) in the form of a rectangular plate, and a deformation member (pressure-sensitive member) whose end is joined to the first current-carrying member and whose center is joined to the second current-carrying member A current interrupting device is disclosed. The deformation member of Patent Document 1 is capable of snap-through buckling, and the central portion is joined to the upper surface of the second current-carrying member (surface on the first current-carrying member side).

Patent Document 1 prevents the malfunction of the current interrupting device (the fact that the current interrupting device is actuated by a slight increase in the pressure in the case), and the re-conduction after the actuation (recontact between the deformation member and the second current-carrying member) In order to prevent this, a snap-buckling type of deformation member is used. In other words, Patent Document 1 maintains the state in which the central portion protrudes toward the second current passing portion with respect to the end and is in contact with the second current passing member until the pressure in the case exceeds a predetermined value. When the value of d exceeds a predetermined value, a deformable member is used which has a characteristic in which the central part rapidly protrudes (reversals) on the end side of the end opposite to the second conducting part. In order to prevent malfunction and re-conduction reliably, it is necessary to secure a sufficient amount of projection of the deformation member (protrusion distance of the central portion with respect to the end). That is, it is necessary to secure a sufficient distance between the first current-carrying member and the second current-carrying member and to secure a space for arranging the deformation member. Therefore, the current interrupting device of Patent Document 1 can not avoid an increase in size of the device. It is an object of the present specification to provide a compact current interrupting device using a snap-buckle deformation member.

The current interruption measure disclosed in the present specification interrupts the conduction between the electrode terminal provided in the case and the electrode provided in the case when the pressure in the case of the power storage device exceeds a predetermined value. The current interrupting device includes a first current-carrying member connected to the electrode terminal, a second current-carrying member connected to the electrode, and a deformation member disposed between the first current-carrying member and the second current-carrying member. You may be equipped. The second current-carrying member may be disposed to face the first current-carrying member at an interval from the first current-carrying member. In addition, a recess may be provided in the second current-carrying member on the side of the first current-carrying member. The deformation member may have an end connected to the first current-carrying member. Further, when the pressure in the case is equal to or less than a predetermined value, the deformation member is connected to the second conduction member in the center of the depression of the second conduction member, and the first conduction member and the second conduction member are conducted. When the pressure in the case exceeds a predetermined value, snap-through buckling may occur to make the first current-carrying member and the second current-carrying member nonconductive.

In the above current blocking device, the deformation member and the second current-passing member are in contact in the recess, so the conventional current-breaking device in which the deformation member and the second current-passing member are in contact on the upper surface of the second current-passing member As compared with the above, the gap between the first current-carrying member and the second current-carrying member can be made smaller. As a result, the current interrupting device can be made smaller than the conventional current interrupting device, and the space for arranging the current interrupting device in the case can be reduced. By using the current interrupting device, a space for disposing the electrode (electrode assembly) in the case can be widely secured, and the storage capacity can be increased.

A second recess may be provided at a position opposite to the recess on the opposite side to the first current-carrying member side of the second current-carrying member. The deformation member is connected to the second conduction member in a recess (hereinafter, referred to as a first depression) provided on the first conduction member side of the second conduction member. That is, the inside of the first recess is a connection portion between the deformation member and the second current-carrying member. If a shock is applied to the connection, the connection may be damaged, which may cause the connection between the electrode terminal and the electrode to be interrupted, or the current interrupting device may malfunction. By providing a second recess (hereinafter referred to as a second recess) on the opposite side (the back surface of the connection portion) of the second current-carrying member to the side of the first current-carrying member, as a result, it protrudes to surround the back surface of the connection portion A department is provided. The projection prevents the parts (electrode assembly and the like) in the case from coming into contact with the back surface of the connection portion, and can suppress the impact applied to the connection portion. That is, by providing the second depression in the second current-carrying member, the connection portion between the deformable member and the second current-carrying member can be protected.

BRIEF DESCRIPTION OF THE DRAWINGS The sectional view of the electrical storage apparatus provided with the electric current interruption apparatus of 1st Example is shown. The enlarged view of the range enclosed with the broken line II of FIG. 1 is shown. The state after the action | operation of the current interrupting apparatus of 1st Example is shown. The comparison figure of the electric current interruption apparatus of 1st Example and the conventional electric current interruption apparatus is shown. The current interruption device of the 2nd example is shown.

(First embodiment)
Power storage device 100 will be described with reference to FIG. Power storage device 100 is a secondary battery, and includes current interrupt device 10. The storage device 100 includes a case 1, an electrode assembly 3 housed in the case 1, and a positive electrode connection terminal 5 and a negative electrode connection terminal 7 fixed to the case 1. In the following description, the positive electrode connection terminal 5 and the negative electrode connection terminal 7 may be collectively referred to as electrode connection terminals 5 and 7. The case 1 is made of metal and is a box-shaped member having a substantially rectangular parallelepiped shape. An electrode assembly 3 and a current interrupting device 10 are housed inside the case 1. The electrode assembly 3 is electrically connected to the electrode connection terminals 5 and 7. The current interrupting device 10 is disposed between the electrode assembly 3 and the negative electrode connection terminal 7. In the inside of the case 1, an electrolytic solution is injected, and the air is removed. Moreover, the electrode assembly 3 is immersed in the electrolyte solution.

The case 1 includes a main body 111 and a lid 112 fixed to the main body 111. The lid 112 covers the top of the main body 111. The lid 112 is provided with mounting holes 81 and 82. The positive electrode connection terminal 5 communicates with the inside and the outside of the case 1 through the mounting hole 81. The negative electrode connection terminal 7 communicates with the inside and the outside of the case 1 through the mounting hole 82.

The electrode assembly 3 includes a positive electrode, a negative electrode, and a separator (not shown). The separator is disposed between the positive electrode and the negative electrode. The electrode assembly 3 has a structure in which a plurality of laminates (unit cells) including a positive electrode, a negative electrode, and a separator are stacked. Each of the plurality of positive electrodes includes a positive current collecting member and a positive electrode active material layer formed on the positive current collecting member. An aluminum foil is mentioned as an example of a positive electrode current collection member. Further, each of the plurality of negative electrodes includes a negative electrode current collecting member and a negative electrode active material layer formed on the negative electrode current collecting member. A copper foil is mentioned as an example of a negative electrode current collection member. The electrode assembly 3 further includes a positive electrode current collecting tab 51 provided for each positive electrode and a negative electrode current collecting tab 52 provided for each negative electrode. The positive electrode current collection tab 51 is provided on the upper end of the positive electrode (the end on the lid 112 side of the electrode assembly 3). The negative electrode current collection tab 52 is provided at the upper end of the negative electrode. The positive electrode current collection tab 51 and the negative electrode current collection tab 52 protrude above the electrode assembly 3 (the lid 112 side). The plurality of positive electrode current collection tabs 51 are collected into one and connected to the positive electrode lead 53. The plurality of negative electrode current collection tabs 52 are put together and connected to the negative electrode lead 54.

The positive electrode lead 53 is connected to the positive electrode current collection tab 51 and the positive electrode connection terminal 5. The positive electrode current collection tab 51 and the positive electrode connection terminal 5 are electrically connected via the positive electrode lead 53. An insulating member 70 is disposed between the positive electrode lead 53 and the case 1. The insulating member 70 insulates the positive electrode lead 53 and the case 1 (the lid 112).

The negative electrode lead 54 is connected to the negative electrode current collection tab 52 and the connection terminal 56. The connection terminal 56 is electrically connected to the negative electrode connection terminal 7 via the current interrupting device 10. That is, the negative electrode current collection tab 52 and the negative electrode connection terminal 7 are electrically connected via the negative electrode lead 54, the connection terminal 56 and the current interrupting device 10. As a result, a conduction path connecting the electrode assembly 3 and the negative electrode connection terminal 7 is formed. The current interrupting device 10 can interrupt this current path. Details of the current interrupting device 10 will be described later. An insulating member 71 is disposed between the negative electrode lead 54 and the case 1. The insulating member 71 insulates the negative electrode lead 54 and the case 1 (the lid 112).

Gaskets 62 and 63 made of resin are disposed on the upper surface of the lid 112 (outside of the case 1). The gaskets 62 and 63 have insulating properties. The gasket 62 is fixed to the positive electrode connection terminal 5. In addition, a positive electrode external terminal (metal plate) 60 is disposed on the upper surface of the gasket 62. A through hole 60 a is formed in the positive electrode external terminal 60. The size of the lower surface side of the through hole 60a is larger than that of the upper surface side. The gasket 62 insulates the lid 112 and the positive electrode external terminal 60. The bolt 64 passes through the through hole 60a. Specifically, the head of the bolt 64 is accommodated in the through hole 60a. Further, the shaft portion of the bolt 64 protrudes above the positive electrode external terminal 60 through the through hole 60 a. The positive electrode connection terminal 5, the positive electrode external terminal 60, and the bolt 64 are electrically connected to form a positive electrode terminal.

The gasket 63 is fixed to the negative electrode connection terminal 7. A negative electrode external terminal (metal plate) 61 is disposed on the upper surface of the gasket 63. In the negative electrode external terminal 61, a through hole 61a similar to the through hole 60a of the positive electrode external terminal 60 is formed. The head portion of the bolt 65 is accommodated in the through hole 61 a, and the shaft portion of the bolt 65 protrudes above the negative electrode external terminal 61 through the through hole 61 a. The configurations of the gasket 63, the negative electrode external terminal 61, and the bolt 65 are the same as the configurations of the gasket 62, the positive electrode external terminal 60, and the bolt 64 described above. The negative electrode connection terminal 7, the negative electrode external terminal 61, and the bolt 65 are electrically connected, and constitute a negative electrode terminal.

The current interrupting device 10 will be described with reference to FIG. The current interrupting device 10 includes a negative electrode connection terminal 7, a deformation plate 20, a breaking plate 30, and a holder 80. The negative electrode connection terminal 7 is an example of a first current-carrying member, the deformation plate 20 is an example of a deformation member, and the breaking plate 30 is an example of a second current-carrying member. The negative electrode connection terminal 7 is fixed to the lid 112 by caulking. The negative electrode connection terminal 7 is a caulking component (a caulking terminal). The negative electrode connection terminal 7 includes a cylindrical portion 94, a base 95, and a fixing portion 96. The cylindrical portion 94 passes through the mounting hole 82. The cylindrical portion 94 also has a through hole 97. The base 95 is annular and fixed to the lower end of the cylindrical portion 94. The base 95 is disposed inside the case 1. The base 95 has a flat surface extending along the lid 112. At the end in the plane direction of the base 95, a protrusion 99 is provided which protrudes downward (toward the electrode assembly 3). In addition, a recess 98 is formed in the base 95. The through hole 97 is located at the center of the recess 98. The recess 98 and the through hole 97 communicate with each other. Therefore, the space 12 in the recess 98 is maintained at atmospheric pressure. The fixing portion 96 is fixed to the upper end of the cylindrical portion 94. The fixing portion 96 is disposed outside the case 1. The negative electrode connection terminal 7 is fixed to the case 1 (lid part 112) by the fixing part 96.

The fracture plate 30 has conductivity. The fracture plate 30 is disposed below the negative electrode connection terminal 7 at a position facing the base 95. The fracture plate 30 and the negative electrode connection terminal 7 (base 95) are not in direct contact with each other, and a gap (a gap) is provided between them. A first recess 31 is provided on the upper surface (the surface on the negative electrode connection terminal 7 side) of the fracture plate 30. The first recess 31 is provided in the central portion 34 of the breaking plate 30. At the bottom of the first recess 31, a first flat surface 31a is provided. In addition, the upper surface of the fracture | rupture board 30 is substantially flat except the part (central part 34 of the fracture | rupture board 30) in which the 1st hollow 31 is provided. The side wall 31 b of the first recess 31 is inclined from the opening surface of the first recess 31 (upper surface of the rupture plate 30) toward the bottom surface (first flat end surface 31 a) of the first recess 31. Therefore, the size of the bottom surface of the first recess 31 is smaller than that of the opening surface. In other words, in a plane parallel to the surface of the fracture plate 30 (plane parallel to the first flat end face 31 a), the area of the first recess 31 (that is, the area of the void provided in the fracture plate 30) is the fracture plate 30. It becomes small as it goes to the 1st flat end face 31a from the upper surface of a.

A second recess 32 is provided on the lower surface (surface opposite to the negative electrode connection terminal 7) of the fracture plate 30. The second recess 32 is provided at a position facing the first recess 31. That is, the second recess 32 is provided in the central portion 34 of the breaking plate 30. The bottom of the second recess 32 is provided with a second flat surface 32 a. In addition, the lower surface of the fracture | rupture board 30 is also substantially flat except the part (central part 34) provided with the 2nd hollow 32. As shown in FIG. An annular breaking groove 33 is provided on the second flat surface 32 a. A connection terminal 56 is connected to the side end of the breaking plate 30. The fracture plate 30 is connected to the negative electrode via the connection terminal 56 (see also FIG. 1).

The fracture plate 30 is supported by the holder 80. The holder 80 is formed of polyphenylene sulfide (PPS) resin. The holder 80 is disposed in the case 1 so as to surround the base 95 of the negative electrode connection terminal 7. The holder 80 has an upper portion 79 and a lower portion 78. The upper portion 79 has a flat surface extending along the lid 112 of the case 1. A through hole 79 a is provided at the center of the upper portion 79. The cylindrical portion 94 of the negative electrode connection terminal 7 passes through the through hole 79a. The upper portion 79 is disposed between the lid 112 of the case 1 and the base 95 of the negative electrode connection terminal 7. The holder 80 is fixed to the case 1 together with the negative electrode connection terminal 7. That is, the holder 80 is fixed to the negative electrode connection terminal 7. The holder 80 has an insulating property. The holder 80 insulates the case 1 (the lid 112) and the negative electrode connection terminal 7 (the base 95).

The lower portion 78 of the holder 80 extends downward from the outer peripheral edge of the upper portion 79. The lower portion 78 of the holder 80 extends below the lower end of the base 95 (the end of the protrusion 99 on the rupture plate 30 side). The base 95 is disposed inside the lower portion 78. The fracture plate 30 is supported by the holder 80 via a connection layer 75 provided on the end face of the lower portion 78. The connection layer 75 is welded to both the fracture plate 30 and the holder 80. By fixing the breaking plate 30 to the lower end of the holder 80, the negative electrode connection terminal 7 (base 95) and the breaking plate 30 are connected without direct contact. That is, the holder 80 connects the negative electrode connection terminal 7 and the breaking plate 30 in a state in which the distance between them is maintained. In addition, a part of the lower end of the holder 80 is recessed and is not in contact with a part of the breaking plate 30. Therefore, a communication hole 77 is formed in a part between the holder 80 and the breaking plate 30. The communication hole 77 communicates the space 14 between the deformation plate 20 and the breaking plate 30 and the space in the case 1 (the space outside the current interrupting device 10).

The deformation plate 20 is a conductive diaphragm, and has a property of snap-through buckling when a predetermined force is applied to the surface. The deformation plate 20 is disposed below the negative electrode connection terminal 7. Specifically, the deformation plate 20 is disposed between the negative electrode connection terminal 7 (base 95) and the breaking plate 30. The deformation plate 20 has a central portion 21 and an outer peripheral portion (end portion) 22. When the inside of the case 1 is a normal pressure (less than a predetermined value), the central portion 21 of the deformation plate 20 is convex downward and is in contact with the central portion 34 of the fracture plate 30. Specifically, the central portion 21 is welded to the bottom (first flat surface 31 a) of the first recess 31. As described above, the side wall 31 b of the first recess 31 is inclined from the upper surface of the fracture plate 30 toward the first flat end surface 31 a. The first recess 31 is formed along the shape of the deformation plate 20. In other words, since the side wall 31b is inclined, the gap between the deformation plate 20 and the side wall 31b is kept substantially constant in the depth direction of the first recess 31 (the direction orthogonal to the upper surface of the rupture plate 30). . The central portion 21 is welded to the first flat surface 31 a in a range 40 inside the fracture groove 33. In other words, the breaking groove 33 is provided outside the joint portion (welded portion) of the deformation plate 20 and the breaking plate 30.

The end (outer periphery) 22 of the deformation plate 20 is joined (welded) to the negative electrode connection terminal 7 (base 95). The recess 98 of the negative electrode connection terminal 7 is covered by the deformation plate 20. Therefore, the space 12 in the recess 98 is separated from the opposite space (the space 14 between the deformation plate 20 and the breaking plate 30) via the deformation plate 20. The space 12 in the recess 98 communicates with the space outside the case 1 through the through hole 97, and is separated from the space in the case 1 (the space inside the case 1 and outside the current interrupting device 10) . The deformation plate 20 separates the space outside the case 1 and the space inside the case 1 (space outside the current interrupting device 10).

The operation of the current interrupting device 10 will be described with reference to FIGS. 2 and 3. As shown in FIG. 2, in the power storage device 100, when the pressure in the case 1 is in a normal state (less than a predetermined value), the deformation plate 20 protrudes downward, and the central portion 34 of the fracture plate 30 (first flat surface 31 a In contact with). Therefore, the negative electrode connection terminal 7 and the breaking plate 30 are electrically connected via the deformation plate 20. The negative electrode connection terminal 7 and the negative electrode current collection tab 52 (negative electrode) are electrically connected via the current interrupting device 10. That is, power storage device 100 is in the conductive state.

As described above, the deformation plate 20 separates the space outside the case 1 and the space inside the case 1. Therefore, atmospheric pressure acts on the upper surface of the deformation plate 20 and pressure in the case 1 acts on the lower surface. As the pressure in the case 1 increases, the pressure acting on the lower surface of the deformation plate 20 increases. As shown in FIG. 3, when the pressure in the case 1 increases and exceeds a predetermined value, the deformation plate 20 is inverted, the central portion 21 moves upward, and the deformation plate 20 changes to a state of being upwardly convex. . With the inversion of the deformation plate 20, the breaking plate 30 starts from the breaking groove 33 and breaks, and the central portion 34 of the breaking plate 30 moves upward together with the deformation plate 20. As a result, the conduction path between the deformation plate 20 and the breaking plate 30 is cut off, and the negative electrode connection terminal 7 and the negative electrode current collection tab 52 become nonconductive. That is, current interruption device 10 operates, and power storage device 100 is in a non-conductive state.

As described above, the fractured plate 30 is provided with the annular fractured groove 33, and the deformable plate 20 is joined (welded) to the fractured plate 30 in the range 40 surrounded by the fractured grooves 33. Since the deformation plate 20 is joined to the breaking plate 30, the conduction between the deformation plate 20 and the breaking plate 30 is stabilized when the pressure in the case 1 is in the normal state. For example, even when vibration is applied to power storage device 100, the contact between deformation plate 20 and breaking plate 30 can be maintained, and power storage device 100 can be prevented from becoming nonconductive. Further, a breaking groove 33 is provided on the outside of the joint portion (range 40) of the deformation plate 20 and the breaking plate 30. When the deformation plate 20 moves upward (is inverted), the breaking plate 30 is broken starting from the outside of the range 40 (that is, the breaking groove 33). Therefore, the deformation plate 20 can be reversed at a predetermined pressure without being affected by the bonding strength between the deformation plate 20 and the breaking plate 30.

Further, as described above, the deformation plate 20 has a snap-through buckling property. Therefore, even if the pressure in the case 1 slightly increases (below a predetermined value) and the pressure acting on the lower surface of the deformation plate 20 slightly increases, the deformation plate 20 does not turn upward. It is possible to prevent the current interrupting device 10 from malfunctioning. In addition, since the deformation plate 20 has the property of snap-through and buckling, after operation of the current interrupting device 10, the deformation plate 20 reverses downward and the deformation plate 20 and the fracture plate 30 re-contact (power storage device Reactivation of 100) is also suppressed.

The advantages of the current interrupt device 10 will be described with reference to FIG. FIG. 4 shows a current interrupting device 10 and a conventional current interrupting device 210. The current interrupting devices 10 and 210 differ in the structure of the rupture plates 30 and 230, and the structures of other parts are the same. That is, in the current interrupting devices 10 and 210, the structures of the negative electrode connection terminal 7 and the deformation plate 20 are the same. The thickness of the breaking plate 230 is equal to the thickness of the breaking plate 30. However, the first recess 31 is provided on the upper surface of the fracture plate 30, and the depression is not provided on the upper surface of the fracture plate 230. The upper surface of the fracture plate 230 is flat, and the deformation plate 20 is joined to the upper surface (flat surface) of the fracture plate 230. On the other hand, in the current interrupting device 10, the deformation plate 20 is joined to the breaking plate 30 in the first recess 31. Therefore, in the current interrupting device 10, the gap 10g between the negative electrode connection terminal 7 and the breaking plate 30 can be smaller than the gap 210g between the negative electrode connection terminal 7 and the breaking plate 230 in the current interrupting device 210. The current interrupting device 10 is smaller than the conventional current interrupting device 210. The thickness T10 (the distance from the back surface of the lid portion 112 to the lower surface of the fracture plate 30) occupied by the current interrupting device 10 in the case 1 is smaller than the thickness T210 occupied by the current interrupting device 210 in the case 1. The current interrupting device 10 can reduce the arrangement space in the case 1 as compared with the conventional current interrupting device 210.

In the conventional current interrupting device 210, the size (thickness T210) of the current interrupting device can be reduced even if the thickness of the breaking plate 230 is simply decreased. However, simply reducing the thickness of the fracture plate 230 narrows the current passage and increases the resistance. Furthermore, if the thickness of the breaking plate 230 is reduced, the strength of the breaking plate also decreases. The current interrupting device 10 can reduce the arrangement space in the case 1 while suppressing the strength reduction and the resistance increase of the fracture plate. By using the current interrupt device 10, a space for disposing an electrode (electrode assembly) in the case 1 can be widely secured, and the storage capacity can be increased.

Further, in the conventional current interrupter 210, the breaking plate 230 is fixed to the holder 80 in a state where the force is applied from the breaking plate 230 to the deformation plate 20 and the gap between the negative electrode connection terminal 7 and the breaking plate 230 is smaller than the gap 210g. Even in this case, the size of the current interrupting device can be reduced (in this case, the size of the holder 80 is also changed). That is, even if the breaking plate 230 is fixed to the holder 80 in a state in which a force is applied to the deformation plate 20 and the amount of protrusion of the central portion 21 with respect to the end 22 is reduced, the size of the current interrupting device decreases. However, in this case, the internal stress remaining in the deformation plate 20 becomes large, and the reversal pressure of the deformation plate 20 deviates from the design value. That is, the current interrupter does not operate at the desired pressure. Therefore, the reliability of the current interrupting device can not be secured. The current interrupting device 10 can be smaller in size than the conventional one while securing reliability.

Further, as described above, in the current interrupting device 10, the side wall 31b of the first recess 31 is inclined, and the first recess 31 is formed along the shape of the deformation plate 20. Therefore, in the current interrupting device 10, for example, the volume of the recess (air gap) can be reduced as compared with a configuration in which the side wall of the first recess vertically extends from the top surface of the breaking plate 30 toward the bottom surface of the first recess. it can. In other words, the current interrupting device 10 does not change the thickness of the breaking plate 30 as compared with the configuration in which the side wall of the first recess vertically extends from the upper surface of the breaking plate 30 toward the bottom of the first recess. The volume of thirty (the volume of material of the rupture plate 30) can be increased. As a result, the current interrupting device 10 can increase the strength of the breaking plate 30 without increasing the size (without increasing the thickness of the breaking plate 30).

Second Embodiment
The current interrupting device 110 will be described with reference to FIG. The current interrupting device 110 is a modified example of the current interrupting device 10. About the current interrupt device 110, about the same structure as the current interrupt device 10, description may be abbreviate | omitted by attaching | subjecting the same reference number with the same or lower two digits.

In the current interrupting device 110, a recess (a structure corresponding to the second recess 32 of the current interrupting device 10) is not provided on the lower surface of the fracture plate 130. In other words, in the current interrupting device 110, the lower surface of the breaking plate 130 is substantially flat. Since the current blocking device 110 does not have a recess on the lower surface of the fracture plate 130, the manufacturing process (the step of forming the recess on the lower surface) can be omitted. Further, since the fractured groove 33 is formed on a flat surface (the lower surface of the fractured plate 130), the fractured groove 33 can be easily processed.

In the current interrupting device 110, the thickness of the breaking plate 130 is the same as the thickness of the breaking plate 30 of the current interrupting device 10. Further, the thickness of the central portion 134 of the rupture plate 130 is also the same as the thickness of the central portion 34 of the rupture plate 30 of the current interrupting device 10. In the current interrupting device 110, since a recess is not provided on the lower surface of the breaking plate 130, a recess 131 deeper than the first recess 31 provided on the breaking plate 30 is provided on the upper surface of the breaking plate 130. In other words, the distance from the upper surface of the fracture plate 130 to the flat surface 131 a provided at the bottom of the recess 131 is longer than the distance from the upper surface of the fracture plate 30 to the bottom surface (first flat surface 31 a). Therefore, the current interrupting device 110 can shorten the distance between the negative electrode connection terminal 7 and the breaking plate 130 as compared with the current interrupting device 10. As a result, the current interrupting device 110 can be smaller in size than the current interrupting device 10. In the current interrupt device 110, the depth of the recess 131 is deeper than the first recess 31 of the current interrupt device 10. Therefore, the current interrupt device 110 makes the inclination angle of the side wall 131 b of the depression 131 smaller than the inclination angle of the side wall 31 b of the first depression 31 in order to facilitate processing. However, as in the case of the current interrupting device 10, the recess 131 may be formed along the shape of the deformation plate 20.

In the above embodiment, a communication hole is provided in a part between the holder and the breaking plate, and the space between the deformation plate and the breaking plate (the lower surface of the deformation plate) and the space inside the power storage device (inside the electric storage device) Has been described. This form is excellent in that the strength of the rupture plate is maintained. However, if necessary, a communication hole may be provided in the rupture plate to communicate the space between the deformation plate and the rupture plate with the space in the case.

Further, in the above embodiment, the example in which the current interrupting device is disposed on the current path of the negative electrode and the negative electrode terminal has been described. However, the current interrupting device may be disposed on the conduction path of the positive electrode and the positive terminal, or may be disposed on both the conduction path of the negative electrode and the negative terminal and on the conduction path of the positive electrode and the positive terminal. Good.

The specific examples of the technology disclosed in the present specification have been described above in detail, but these are merely examples and do not limit the scope of the claims. The art set forth in the claims includes various variations and modifications of the specific examples illustrated above. The technical elements described in the present specification or the drawings exhibit technical usefulness singly or in various combinations, and are not limited to the combinations described in the claims at the time of filing.

Claims (4)

1. A current interrupting device for interrupting conduction between an electrode terminal provided in the case and an electrode provided in the case when the pressure in the case of the storage device exceeds a predetermined value,
   A first current-carrying member connected to the electrode terminal;
   A second current-carrying member disposed opposite to the first current-carrying member at a distance from the first current-carrying member and connected to the electrode and having a recess on the first current-carrying member side When,
   A central portion is disposed between the first conductive member and the second conductive member and has an end joined to the first conductive member and the pressure in the case is less than the predetermined value. It connects with the said 2nd electricity supply member in the said hollow, and has electrically conducted the said 1st electricity supply member and the said 2nd electricity supply member, and when the said pressure exceeds the said predetermined value, it snaps and it buckles and said 1st electricity supply A member and a deformation member for making the second current-carrying member nonconductive;
   A current interrupter equipped with.
2. The current interrupting device according to claim 1, wherein a second recess is provided at a position facing the recess on the opposite side to the first current-carrying member side of the second current-carrying member.
3. A power storage device comprising the current interrupting device according to claim 1.
4. The power storage device according to claim 3, wherein the power storage device is a secondary battery.

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