JP5966916B2 - Power storage device - Google Patents

Description

  The present invention includes an annular seal member interposed between the inner surface of the lid and the base seating surface of the electrode terminal, and an insulating cover sandwiched between the inner surface of the lid and the base seating surface. The present invention relates to a power storage device.

  A vehicle such as an EV (Electric Vehicle) or a PHV (Plug in Hybrid Vehicle) is equipped with a secondary battery as a power storage device that stores power supplied to the traveling motor. As a secondary battery, there is a battery configured by housing an electrode assembly in a case. The case includes a case main body and a lid welded to the case main body. In addition, electrode terminals are electrically connected to the electrode assembly housed in the case body, and the electrode terminals protrude from the inside of the case body to the outside through the insertion holes of the lid. An insulation distance is secured between the inner peripheral surface of the insertion hole and the peripheral surface of the electrode terminal facing the inner peripheral surface. And the secondary battery is provided with the sealing structure of the insertion hole (for example, refer patent document 1).

  As shown in FIG. 9, the battery 80 of Patent Document 1 is configured by accommodating a winding electrode body 84 inside an outer can 83 formed by welding a lid body 82 to both ends of a cylindrical body 81. . An electrode terminal mechanism 85 is attached to the lid 82, and the take-up electrode body 84 and the electrode terminal mechanism 85 are connected.

  The electrode terminal mechanism 85 includes a positive electrode lead terminal 86 made of a screw member that is attached through the lid 82 of the outer can 83, and includes a flange 86 a at the base end of the positive electrode lead terminal 86. A resin insulating member 87 is attached to the gap between the inner peripheral surface of the through hole 82 a and the outer peripheral surface of the positive electrode lead-out terminal 86, and the insulating member 87 seals between the lid 82 and the positive electrode lead-out terminal 86. As well as ensuring electrical insulation. A washer 88 is fitted to the positive electrode lead-out terminal 86 from the outside of the outer can 83, and a first nut 89a and a second nut 89b are screwed together. And the sealing performance of the through-hole 82a is improved by fastening the 1st nut 89a and pinching the insulation member 87 with the collar part 86a and the washer 88 of the positive electrode derivation | leading-out terminal 86. FIG.

  However, in Patent Document 1, in order to ensure the sealing performance of the through hole 82a, the insulating member 87 having a complicated shape must be in close contact with the periphery of the through hole 82a while being caulked. It was complicated, and the mounting was troublesome, and the formation of the seal structure was troublesome. Therefore, Patent Document 2 discloses an O-ring having a simple structure as a sealing member.

  As shown in FIG. 10, in the sealed battery 90 of Patent Document 2, the lid body 91 includes a terminal lead hole 91a, and the positive terminal 92 attached to the terminal lead hole 91a includes an inner member 93 and an outer member 94. Prepare. The seal member compression portions 93a and 94a of the inner member 93 and the outer member 94 are respectively provided with annular grooves 93b and 94b, and O-ring seal members 95 and 96 are attached to the annular grooves 93b and 94b, respectively.

  A resin insulating member 97 is mounted between the inner peripheral surface of the terminal lead hole 91a and the outer peripheral surface of the positive electrode terminal 92, and a resin is provided on the outer peripheral portion of the seal member compression portion 93a in the inner member 93. The insulating member 98 made of is attached. The inner member 93 and the outer member 94 are welded, so that the seal members 95 and 96 are sandwiched between the seal member compression portions 93a and 94a and the lid body 91 in a compressed state. Further, the lid 91 and the positive electrode terminal 92 are insulated by the insulating members 97 and 98.

JP 2000-149915 A JP 2009-134985 A

  By the way, in patent document 2, since the inner member 93 has the annular groove 93b, the portion on the radially outer side of the positive electrode terminal 92 with respect to the seal member 95 in the seal member compression portion 93a has a lid rather than the recess of the annular groove 93b. It becomes the convex part 93d which protrudes to the body 91 side. For this reason, in the seal member compression part 93a, the thickness of the convex part 93d is thicker than the thickness of the part where the recess of the annular groove 93b is formed, and the gap formed between the lid 91 and the convex part 93d is It is narrower than the gap formed between the lid 91 and the recess of the annular groove 93b. Therefore, in a state in which the seal member 95 is compressed between the lid body 91 and the annular groove 93b, the insulating member 98 sandwiched between the lid body 91 and the convex portion 93d may be damaged.

  An object of the present invention is to provide a power storage device that can prevent an insulating cover sandwiched between an inner surface of a lid and a seat surface of a base from being damaged while sealing an insertion hole with a seal member.

In order to solve the above problem, the power storage device according to claim 1 includes a case main body having an opening, a lid that closes the opening and has an insertion hole through which an electrode terminal is inserted, and the case main body. The electrode assembly housed in the electrode and the end of the pole column protruding from the lid through the insertion hole formed in the lid are parallel to the lid at the ends located in the case body. The electrode terminal having a cross-sectional area larger than the area of the insertion hole in a cross section and electrically connected to the electrode assembly, and the case in the lid around the pole column portion An annular seal member interposed between an inner surface on the main body side and a seating surface of the base portion facing the inner surface; and an inner surface of the lid on a radially outer side in the pole column portion than the seal member , Insulation cap sandwiched between the seating surfaces A power storage device having an outer peripheral surface located between a circumferential surface of the pole column portion and an inner circumferential surface of the seal member, and radially outside the pole column portion from the circumferential surface of the pole column portion The seating surface is continuous to the outer side in the radial direction of the polar column part than the seal member, and there is no convex part protruding toward the lid from the seating surface. , the width of the insulation cover in the axial direction of the pole portion is longer than the distance from the bearing surface in the axial direction of the pole column portion to the end face of the stepped portion, in the axial direction of the pole portion, the and the inner surface of the lid, have a clearance between the stepped portion, the length of the gap in the axial direction of the pole portion, said in an assembled state between the inner surface and the seating surface of the lid The gist is that the length of the seal member is at least half the thickness of the pole column in the axial direction .
In order to solve the above problem, the power storage device according to claim 2 includes a case main body having an opening, a lid that closes the opening and has an insertion hole through which an electrode terminal is inserted, and the case main body. The electrode assembly housed in the electrode and the end of the pole column protruding from the lid through the insertion hole formed in the lid are parallel to the lid at the ends located in the case body. The electrode terminal having a cross-sectional area larger than the area of the insertion hole in a cross section and electrically connected to the electrode assembly, and the case in the lid around the pole column portion An annular seal member interposed between an inner surface on the main body side and a seating surface of the base portion facing the inner surface; and an inner surface of the lid on a radially outer side in the pole column portion than the seal member , Insulation cap sandwiched between the seating surfaces A power storage device having an outer peripheral surface located between a circumferential surface of the pole column portion and an inner circumferential surface of the seal member, and radially outside the pole column portion from the circumferential surface of the pole column portion The seating surface is continuous to the outer side in the radial direction of the polar column part than the seal member, and there is no convex part protruding toward the lid from the seating surface. The width of the insulating cover in the axial direction of the polar column part is longer than the distance from the seating surface in the axial direction of the polar column part to the end surface of the stepped part, and in the axial direction of the polar column part, There is a gap between the inner surface of the lid and the stepped portion, and the stepped portion extends from the circumferential surface of the pole column portion toward the outer circumferential surface of the stepped portion in the axial direction of the pole column portion. The gist is to have a tapered surface inclined in a direction away from the inner surface.

According to these claims 1 and 2, the step portion, the sealing member is prevented from moving in the radial direction of the pole portion along the seat surface. Further, the step portion allows the seal member to be disposed at a position surrounding the pole column portion on the radially outer side of the pole column portion. Then, since the pole column portion is inserted into the insertion hole, the periphery of the insertion hole can be surrounded by the seal member surrounding the pole column portion, and the seal member is located in a state of protruding into the insertion hole in a plan view of the lid. Can be prevented. As a result, the insertion hole can be sealed by the seal member. In addition, even if a step is provided to position the seal member at a position where the sealing performance can be ensured, the seating surface is continuous on the outer side in the radial direction of the pole column portion than the seal member, and the lid is positioned more than the seating surface. There is no convex part protruding toward the surface. For this reason, the clearance gap between a seat surface and the inner surface of a lid | cover becomes constant along the radial direction of a polar pillar part, and a clearance gap does not become narrow in the radial direction outer side in a polar pole part rather than a sealing member. Therefore, a sufficient gap is secured between the seating surface and the inner surface of the lid, and the width of the insulating cover can be made longer than the distance from the seating surface to the end surface of the stepped portion, and between the inner surface of the lid and the seating surface. Even if the insulating cover is sandwiched, the insulating cover can be prevented from being damaged. Further, the step portion does not contact the inner surface of the lid, and the lid and the electrode terminal can be insulated.
Moreover, in the power storage device according to claim 1, the length of the gap in the axial direction of the pole column portion is set in the axial direction of the pole column portion of the seal member in a state assembled between the inner surface of the lid and the seat surface. Therefore, even when the electrode terminal is fastened to the lid and the seal member is crushed, a sufficient gap is provided between the inner surface of the lid and the end surface of the stepped portion. It is possible to secure the insulation between the lid and the electrode terminal.
On the other hand, in the power storage device according to claim 2, the stepped portion has a tapered shape that inclines in a direction away from the inner surface of the lid in the axial direction of the pole column portion from the peripheral surface of the pole column portion toward the outer peripheral surface of the stepped portion. Since it has a surface, when the sealing member is packaged on the pole column portion, the sealing member can be easily moved radially outward from the outer peripheral surface of the stepped portion by the tapered surface.

Further, the seating surface is continuous on the radially outer side from the outer peripheral surface of the stepped portion. For this reason, the electrode terminal which has a level | step-difference part can be manufactured by forge, and manufacture of an electrode terminal becomes easy.
Further, when a cylindrical surface partially overlapping the inner peripheral surface of the insertion hole and extending in the axial direction of the pole column portion is used as a reference surface, the outer peripheral surface of the stepped portion is on the reference surface or the reference surface It is preferable that it is located radially outside.

  According to this, the seal member is disposed radially outward from the outer peripheral surface of the stepped portion. Therefore, by defining the position of the outer peripheral surface of the stepped portion, the seal member can be reliably positioned at a position surrounding the insertion hole.

  Further, the length of the gap in the axial direction of the pole column part is more than half of the thickness in the axial direction of the pole column part of the seal member in a state assembled between the inner surface of the lid and the seat surface. It is preferable that the length is.

  According to this, even if the electrode terminal is fastened to the lid and the seal member is crushed, a sufficient gap is secured between the inner surface of the lid and the end surface of the stepped portion, and the lid and the electrode Terminal insulation can be ensured.

Moreover, it is preferable that the terminal insulating member is arrange | positioned between the internal peripheral surface of the said insertion hole, and the peripheral surface of the said pole column part.
According to this, it can prevent that a sealing member jumps out of a case main body from an insertion hole by a terminal insulating member.

Before Symbol power storage device is a secondary battery.

  ADVANTAGE OF THE INVENTION According to this invention, it can prevent that the insulating cover pinched | interposed between the inner surface of a lid | cover and the seat surface of a base is damaged, sealing an insertion hole with a sealing member.

The disassembled perspective view which shows the secondary battery of embodiment. The perspective view which shows the external appearance of the secondary battery of embodiment. The perspective view which shows the state which integrated the lid | cover with the electrode assembly. The top view which shows a positive electrode electrically-conductive member, a positive electrode terminal, and an insulation cover. FIG. 5 is a cross-sectional view taken along the line 5-5 in FIG. FIG. 6A is a cross-sectional view taken along line 6-6 of FIG. 3 showing an insulating structure of a positive electrode terminal, and FIG. 6B is an enlarged cross-sectional view showing an O-ring and a stepped portion. (A) is sectional drawing which shows the state which has arrange | positioned O-ring to the radial direction outer side of a level | step-difference part, (b) is an expanded sectional view which shows an O-ring and a level | step difference part. (A) And (b) is sectional drawing which shows another example of a level | step-difference part. The figure which shows the background art of patent document 1. FIG. The figure which shows the background art of patent document 2. FIG.

Hereinafter, an embodiment embodying the present invention will be described with reference to FIGS.
As shown in FIGS. 1 to 3, in a secondary battery 10 as a power storage device, an electrode assembly 20 is accommodated in a metal case 12. The case 12 includes a rectangular parallelepiped case main body 13 having an opening 13 d and a rectangular flat plate-shaped lid 14 that closes the opening 13 d of the case main body 13. The case body 13 and the lid 14 are both made of metal (for example, stainless steel or aluminum), and the case body 13 and the lid 14 are joined by laser welding. The case body 13 includes a rectangular bottom plate 13a, a short side wall 13b erected from a pair of opposed short side edges of the bottom plate 13a, and a long side wall 13c erected from a pair of long side edges of the bottom plate 13a. With. In addition, the secondary battery 10 of the present embodiment is a prismatic battery whose outer shape is rectangular. Further, the secondary battery 10 of the present embodiment is a lithium ion battery.

  As shown in FIG. 6A, the electrode assembly 20 includes a positive electrode 21 and a negative electrode 22 and has a layered structure with a separator 23 interposed between the positive electrode 21 and the negative electrode 22. It is a laminate. The positive electrode 21 has a rectangular positive electrode metal foil (aluminum foil in the present embodiment) 21a and positive electrode active material layers 21b on both surfaces of the positive electrode metal foil 21a. The negative electrode 22 has a rectangular negative electrode metal foil (copper foil in this embodiment) 22a and negative electrode active material layers 22b on both surfaces of the negative electrode metal foil 22a.

  As shown in FIG. 1, a protruding positive electrode current collecting tab 31 is provided on a part of one side of the positive electrode 21. The positive electrode current collecting tab 31 is disposed at the same position in each positive electrode 21 constituting the electrode assembly 20 and has the same shape. A protruding negative electrode current collecting tab 32 is provided on a part of one side of the negative electrode 22. The negative electrode current collecting tab 32 is disposed at the same position in each negative electrode 22 constituting the electrode assembly 20 and has the same shape.

  The positive electrode current collecting tabs 31 are laminated so that the respective positive electrode current collecting tabs 31 are arranged in a line along the lamination direction. Similarly, the negative electrode current collecting tabs 32 are stacked such that the respective negative electrode current collecting tabs 32 are arranged in a row along the stacking direction so as not to overlap the positive electrode current collecting tabs 31. The plurality of positive electrode current collecting tabs 31 are collected in a range from one end to the other end of the electrode assembly 20 in the stacking direction. Similarly, the plurality of negative electrode current collecting tabs 32 are collected in a range from one end to the other end in the stacking direction of the electrode assembly 20.

  The electrode assembly 20 includes a positive electrode tab group 45 formed by collecting positive electrode current collecting tabs 31. The positive electrode tab group 45 is welded to the positive electrode conductive member 33. The electrode assembly 20 includes a negative electrode tab group 46 formed by collecting the negative electrode current collecting tabs 32. The negative electrode tab group 46 is welded to the negative electrode conductive member 37.

  The positive electrode conductive member 33 and the negative electrode conductive member 37 have a terminal connection portion 34 having a square plate shape. The positive electrode conductive member 33 and the negative electrode conductive member 37 have a rising portion 35 rising from the terminal connection portion 34 and a tab weld portion 36 extending from the rising portion 35 in a direction away from the terminal connection portion 34. The welded portion 36 has a rectangular plate shape. Then, the tab welded portion 36 of the positive electrode conductive member 33 is welded to the positive electrode tab group 45 of the electrode assembly 20, and the tab welded portion 36 of the negative electrode conductive member 37 is welded to the negative electrode tab group 46 of the electrode assembly 20. Yes.

  A positive electrode terminal 41 as an electrode terminal is welded to the terminal connection portion 34 of the positive electrode conductive member 33, and a negative electrode terminal 42 as an electrode terminal is welded to the terminal connection portion 34 of the negative electrode conductive member 37. Each of the positive electrode terminal 41 and the negative electrode terminal 42 has a base portion 43 having a square plate shape. A cylindrical pole post 44 is erected from the center of the base 43. The pole portion 44 includes a male screw 44a on its outer peripheral surface and a female screw 44b on its inner peripheral surface.

  As shown in FIG. 5, in the base 43, a surface facing the inner surface 14 a of the lid 14 is a seating surface 43 a, and a surface opposite to the seating surface 43 a in the thickness direction of the base 43 is an end surface 43 b. Further, in the base portion 43, a surface that intersects the seat surface 43 a and the end surface 43 b perpendicularly and forms the outer shape of the base portion 43 is a side surface 43 c of the base portion 43.

  The pole portion 44 includes a stepped portion T on an end portion side located in the case body 13 among both end portions in the axial direction in which the axis L extends. The step T extends from the peripheral surface of the pole column 44 to the outside in the radial direction of the pole column 44. The outer peripheral surface Ta of the stepped portion T extends in the axial direction of the polar column portion 44 at a radially outer side than the peripheral surface of the polar column portion 44 and is concentrically provided over the entire circumference of the polar column portion 44 in the circumferential direction. It has been.

  In the stepped portion T, a surface parallel to the inner surface 14a of the lid 14 is defined as a stepped portion end surface Tb. The step portion end surface Tb is located at a position farther toward the tip side of the pole column portion 44 than the seat surface 43a, and the step portion end surface Tb and the seat surface 43a are stepped. Therefore, the step portion end surface Tb, the outer peripheral surface Ta of the step portion T, and the seat surface 43a are stepped.

  As shown in FIG. 6B, the distance from the seating surface 43a to the stepped portion end surface Tb in the axial direction of the polar column portion 44 is H. A cylindrical surface that partially or entirely overlaps with the inner peripheral surface of the insertion hole 14 b along the thickness direction of the lid 14 and extends in the axial direction of the pole column portion 44 is defined as a reference surface R. The outer peripheral surface Ta of the stepped portion T is located on the radially outer side of the polar column portion 44 with respect to the reference surface R. A gap S is provided between the stepped portion end surface Tb of the stepped portion T and the inner surface 14a of the lid 14. Let Y be the length of the gap S along the axial direction of the pole post 44.

  As shown in FIGS. 1 and 4, a resin insulating cover 50 is attached to the base 43. The insulating cover 50 includes a lid-side insulating plate 51 that is sandwiched between the seating surface 43a of the base portion 43 and the inner surface 14a of the lid 14, and the lid-side insulating plate 51 allows the lid 14, the positive terminal 41, and the negative terminal. 42 is electrically insulated.

  As shown in FIG. 6B, when the width (thickness) of the lid-side insulating plate 51 in the axial direction of the pole column portion 44 is F, the width F of the lid-side insulating plate 51 is from the seat surface 43a to the stepped portion. It is longer than the distance H to the end face Tb. As shown in FIG. 4, the lid-side insulating plate 51 has an insertion portion 51a through which the pole column portion 44 is inserted in the thickness direction, and the inner peripheral edge of the lid-side insulating plate 51 has an arc shape. The lid-side insulating plate 51 has a cut-out communication portion 51b that opens the insertion portion 51a to one side of the lid-side insulation plate 51, and the lid-side insulation plate 51 is formed by the insertion portion 51a and the communication portion 51b. It is U-shaped in plan view.

  As shown in FIG. 5, the case-side insulating plate 52 extends in a direction away from the lid 14 from the end edge of the lid-side insulating plate 51 on the opposite side of the communicating portion 51b across the insertion portion 51a. The case body insulating plate 52 is electrically insulated from the positive terminal 41 and the negative terminal 42 by the case-side insulating plate 52. The case-side insulating plate 52 has a rectangular plate shape and extends perpendicular to the lid-side insulating plate 51. In the case-side insulating plate 52, the assembly-side insulating plate 53 extends in the same direction as the lid-side insulating plate 51 from the tip on the side away from the lid 14. The positive electrode terminal 41 and the negative electrode terminal 42 are electrically insulated. The case side insulating plate 52 has a rectangular plate shape.

  The insulating cover 50 having the above configuration is attached to the positive terminal 41 and the negative terminal 42 from the short side wall 13b side of the case body 13. As shown in FIG. 4, the pole column portion 44 is inserted into the insertion portion 51a of the lid-side insulating plate 51, and the lid-side insulating plate 51 covers almost the entire circumference of the outer peripheral surface Ta of the step portion T except for the communication portion 51b. Surrounding. The lid-side insulating plate 51 is supported on the seating surface 43 a of the base 43.

  As shown in FIGS. 4 and 5, an O-ring 56 as a seal member is interposed between the inner surface 14 a of the lid 14 and the seating surface 43 a of the base portion 43 around the pole column portion 44. . The seating surface 43 a is flat from the outer peripheral surface Ta of the stepped portion T to the side surface 43 c of the base portion 43. The O-ring 56 is made of a rubber material and has an annular shape. The O-ring 56 is disposed on the outer side in the radial direction from the outer peripheral surface Ta of the stepped portion T. Therefore, the stepped portion T is located between the peripheral surface of the pole column portion 44 and the inner peripheral surface of the O-ring 56. In the O-ring 56, the inner peripheral surface 56a is in contact with the outer peripheral surface Ta of the stepped portion T over the entire periphery.

  The O-ring 56 is disposed in the insertion portion 51 a of the lid-side insulating plate 51 in the radial direction of the pole column portion 44, and the O-ring 56 is substantially surrounded by the lid-side insulating plate 51. In other words, the O-ring 56 is surrounded by the inner peripheral edge of the lid-side insulating plate 51 except for the portion facing the communication portion 51b. Therefore, the lid-side insulating plate 51 of the insulating cover 50 is sandwiched between the inner surface 14 a of the lid 14 and the seating surface 43 a on the radially outer side of the pole column portion 44 than the O-ring 56.

  The O-ring 56 is crushed between the inner surface 14 a of the lid 14 and the seating surface 43 a of the base 43, and is in close contact with the inner surface 14 a of the lid 14 and the seating surface 43 a of the base 43. As shown in FIG. 6B, when the thickness of the O-ring 56 assembled between the inner surface 14a of the lid 14 and the seating surface 43a and being crushed is W, the thickness W of the O-ring 56 is Half (1/2 W) is longer than the length Y of the gap S.

  As shown in FIGS. 5 and 6, the pole portion 44 inserted through the insertion portion 51 a of the lid-side insulating plate 51 protrudes from the inside of the case main body 13 through the insertion hole 14 b provided in the lid 14. (Exposed). The base portions 43 of the positive electrode terminal 41 and the negative electrode terminal 42 are provided at end portions located in the case main body 13 among both end portions of the polar column portion 44. The base 43 has a cross-sectional area in a cross section parallel to the inner surface 14a of the lid 14 larger than the opening area of the insertion hole 14b. For this reason, the base 43 cannot be removed from the case main body 13 through the insertion hole 14b.

  A terminal insulating member 19 is disposed between the inner peripheral surface of the insertion hole 14 b and the peripheral surface of the pole column portion 44, and the lid 14 and the pole column portion 44 are insulated by the terminal insulating member 19. . The terminal insulating member 19 includes a cylindrical portion 19a and an annular flange portion 19b protruding from one axial end edge of the cylindrical portion 19a. The cylindrical portion 19 a is interposed between the inner peripheral surface of the insertion hole 14 b and the peripheral surface of the pole column portion 44. The terminal insulating member 19 has a cylindrical portion 19 a that overlaps the stepped portion end surface Tb of the stepped portion T over the entire circumference when viewed from the axial direction of the pole column portion 44. Further, in the cylindrical portion 19a, the distal end surface on the side away from the flange portion 19b is separated from the stepped portion end surface Tb of the stepped portion T.

  The flange portion 19 b has a locking surface 19 c that is locked to the outside of the insertion hole 14 b on the outer surface 14 c of the lid 14. The length of the cylindrical portion 19a in the direction away from the locking surface 19c is set to be the same as the thickness of the lid 14. For this reason, the tip of the cylindrical portion 19a is located on the same plane as the inner surface 14a of the lid 14 and covers the O-ring 56 from the lid 14 side.

  A nut 55 is screwed into the pole post 44. A flange portion 19b of the terminal insulating member 19 is interposed between the nut 55 and the outer surface 14c of the lid 14, and the nut 55 and the lid 14 are insulated by the flange portion 19b. Further, the flange portion 19 b, the lid 14, and the lid-side insulating plate 51 are sandwiched between the nut 55 and the base portion 43, and the pole column portion 44 is fastened to the lid 14. In this fastened state, the O-ring 56 is crushed between the inner surface 14a of the lid 14 and the seating surface 43a of the base portion 43, is in close contact with the inner surface 14a of the lid 14 and the seating surface 43a of the base portion 43, and the insertion hole 14b. And the insertion hole 14b is sealed.

Next, the effect | action of the secondary battery 10 is demonstrated with a manufacturing method.
First, in the positive electrode conductive member 33 and the negative electrode conductive member 37, the base portions 43 of the positive electrode terminal 41 and the negative electrode terminal 42 are welded to the terminal connection portions 34, and the positive electrode conductive member 33 and the positive electrode terminal 41 are integrated and electrically connected. At the same time, the negative electrode conductive member 37 and the negative electrode terminal 42 are integrated and electrically connected. Next, the tab weld portion 36 of the positive electrode conductive member 33 is welded to the positive electrode tab group 45 of the electrode assembly 20, and the tab weld portion 36 of the negative electrode conductive member 37 is welded to the negative electrode tab group 46 of the electrode assembly 20. .

  The insulating cover 50 is attached to the positive terminal 41, and the lid-side insulating plate 51 is supported on the seating surface 43a of the base 43 and the assembly-side insulating plate 53 is mounted as shown in FIGS. 7 (a) and 7 (b). Arranged below the base 43. The insulating cover 50 is pushed in until the case-side insulating plate 52 comes into contact with the opposing base portion 43. Although not shown, the insulating cover 50 is also attached to the negative terminal 42.

  Next, an O-ring 56 is attached around each pole post 44. At this time, the inner peripheral surface 56 a of the O-ring 56 is positioned on the radially outer side from the outer peripheral surface Ta of the stepped portion T. Then, the O-ring 56 is prevented from moving along the seat surface 43a radially inward and outward from the outer peripheral surface Ta of the stepped portion T. Further, the O-ring 56 before being crushed is thicker than the lid-side insulating plate 51 and protrudes from the outer surface of the lid-side insulating plate 51 (the surface in contact with the inner surface 14a of the lid 14).

  Next, when the lid 14 is assembled to the pole column portion 44 while being inserted into the insertion hole 14 b of the lid 14, the inner surface 14 a of the lid 14 comes into contact with the O-ring 56, and the O-ring 56 is pushed toward the base portion 43. Also at this time, the O-ring 56 is prevented from moving along the seat surface 43a radially outward and inward by the outer peripheral surface Ta of the stepped portion T. As a result, as shown in FIG. 4, the O-ring 56 is disposed concentrically around the pole column portion 44 and the stepped portion T, and is disposed inside the lid-side insulating plate 51. Further, a gap S exists between the stepped portion end surface Tb of the stepped portion T and the inner surface 14 a of the lid 14, and the lid 14 is insulated from the positive electrode terminal 41 and the negative electrode terminal 42 by this gap S.

  Next, as shown in FIGS. 6A and 6B, the cylindrical portion 19 a of the terminal insulating member 19 is inserted into the insertion hole 14 b of the lid 14 and the flange portion 19 b is locked to the outer surface 14 c of the lid 14. Let Then, the space between the inner peripheral surface of the insertion hole 14b and the peripheral surface of the pole column portion 44 is made substantially the same over the entire circumference by the cylindrical portion 19a, and the outer periphery of the stepped portion T in the plan view of the lid 14 The surface Ta comes to be located on the radially outer side than the inner peripheral surface of the insertion hole 14b.

  Then, when the lid 14 is supported by the O-ring 56, the nut 55 is screwed onto the male screw 44 a of the pole post 44. Then, the inner surface 14 a of the lid 14 comes into contact with the lid-side insulating plate 51, and the O-ring 56 is crushed toward the base 43 by the lid 14. At this time, since the lid-side insulating plate 51 has a sufficient thickness, the lid-side insulating plate 51 is not damaged, and the O-ring 56 is pushed excessively by the lid 14 by the lid-side insulating plate 51. It is prevented from being crushed. As a result, the O-ring 56 is positioned at a position in close contact with the inner surface 14a of the lid 14 and the seating surface 43a of the base portion 43 and surrounding the periphery of the insertion hole 14b. Thereafter, the electrode assembly 20 is accommodated in the case main body 13, and the lid 14 is welded to the case main body 13 to form the case 12. As a result, the secondary battery 10 is manufactured.

According to the above embodiment, the following effects can be obtained.
(1) The positive electrode terminal 41 and the negative electrode terminal 42 have a stepped portion T, and the stepped portion T is located between the peripheral surface of the pole column portion 44 and the inner peripheral surface 56 a of the O-ring 56. For this reason, when assembling the positive electrode terminal 41 and the negative electrode terminal 42 to the lid 14, and after assembling, the O-ring 56 can be prevented from moving along the seat surface 43a radially outward and inward. As a result, the O-ring 56 can be positioned at the position surrounding the pole column 44 concentrically by the stepped portion T, and the insertion hole 14 b through which the pole column 44 is inserted can be surrounded by the O-ring 56. Therefore, the insertion hole 14 b can be reliably sealed by the O-ring 56.

  Further, in the base portion 43, the seat surface 43 a has a flat surface on the outer side in the radial direction of the pole column portion 44 than the outer peripheral surface Ta of the step portion T. In the structure in which the groove is provided in the base 43 for positioning the O-ring 56, a convex portion that protrudes closer to the lid 14 than the position where the groove is formed is present outside the groove. However, if the seating surface 43 a is flat, the outer side of the groove is also flat, so that the thickness of the base 43 on the radially outer side of the O-ring 56 is reduced. For this reason, the gap between the seating surface 43 a and the inner surface 14 a of the lid 14 is constant along the radial direction of the pole column portion 44, and the gap does not narrow outside the O-ring 56. Therefore, a wide gap is ensured between the seating surface 43a and the inner surface 14a of the lid 14, and the width F of the lid-side insulating plate 51 interposed in the gap can also be secured. As a result, the strength of the lid-side insulating plate 51 is increased, and even if the lid-side insulating plate 51 is sandwiched between the inner surface 14a of the lid 14 and the seating surface 43a, the lid-side insulating plate 51 can be prevented from being damaged. . Furthermore, since the thickness of the base 43 can be reduced, the base 43 does not become heavy. Further, unlike the case where a groove is formed in the base portion 43, the positive electrode terminal 41 and the negative electrode terminal 42 including the step portion T can be easily manufactured by forging.

  (2) The width F of the lid-side insulating plate 51 is longer than the distance H from the seating surface 43a to the step portion end surface Tb, and a gap S is secured between the step portion end surface Tb and the inner surface 14a of the lid 14. Yes. For this reason, it is possible to insulate the lid 14 from the positive electrode terminal 41 and the negative electrode terminal 42 by the lid-side insulating plate 51 and the gap S while positioning the O-ring 56 by the step portion T.

  (3) The outer peripheral surface Ta of the stepped portion T prevents the O-ring 56 from moving or deforming in the radial direction. For this reason, even if the internal pressure of the case 12 rises and the internal pressure acts from the outer peripheral surface of the O-ring 56 toward the inner peripheral surface, the O-ring 56 does not move or deform, and the state where the insertion hole 14b is sealed is maintained. it can.

  (4) The outer peripheral surface Ta of the stepped portion T is located radially outward from the inner peripheral surface of the insertion hole 14b. For this reason, the O-ring 56 positioned by the stepped portion T is also positioned radially outward from the inner peripheral surface of the insertion hole 14b. Therefore, the insertion hole 14 b can be reliably sealed by surrounding the insertion hole 14 b with the O-ring 56.

  (5) The length Y of the gap S along the axial direction of the pole portion 44 is more than half the thickness W of the O-ring 56 assembled between the inner surface 14a of the lid 14 and the seat surface 43a. It is. For this reason, even if the O-ring 56 is crushed, the gap S can be secured and insulation between the lid 14 and the positive terminal 41 and the negative terminal 42 can be secured.

  (6) The cylindrical portion 19a of the terminal insulating member 19 that insulates between the pole column portion 44 and the lid 14 is disposed between the peripheral surface of the pole column portion 44 and the inner peripheral surface of the insertion hole 14b. Yes. The cylindrical portion 19 a of the terminal insulating member 19 overlaps the stepped portion end surface Tb of the stepped portion T when viewed from the axial direction of the pole column portion 44. For this reason, it is possible to prevent the O-ring 56 from being crushed by the tip of the cylindrical portion 19a. Further, for example, even if the internal pressure of the case 12 rises and the internal pressure acts on the O-ring 56, the cylindrical portion 19a can prevent the O-ring 56 from being lifted to the lid 14 side. It is possible to prevent the case 12 from slipping out of the case 12 from between the inner peripheral surface of the insertion hole 14 b and the outer peripheral surface of the pole post 44.

  (7) Since a gap S is secured between the stepped portion end surface Tb of the stepped portion T and the inner surface 14 a of the lid 14, the stepped portion end surface Tb is at a position lower than the outer surface of the lid-side insulating plate 51. . And before the lid | cover 14 is assembled | attached, the O-ring 56 supported by the seat surface 43a will jump out from the outer surface of the lid | cover side insulating board 51 supported by the seat surface 43a. Therefore, the thickness of the O-ring 56 that protrudes from the lid-side insulating plate 51 is a crushing allowance for the O-ring 56. Therefore, the crushing margin of the O-ring 56 can be set by the width F of the lid-side insulating plate 51.

  (8) The lid-side insulating plate 51 of the insulating cover 50 is interposed between the lid 14 and the base 43 when the nut 55 is screwed into the male screw 44 a of the pole column 44. For this reason, the lid-side insulating plate 51 functions as a spacer between the lid 14 and the base 43, and the nut 55 can be prevented from excessively screwing. Therefore, the O-ring 56 can be prevented from being excessively crushed by interposing the lid-side insulating plate 51.

In addition, you may change the said embodiment as follows.
As shown in FIG. 8A, the stepped portion T is separated from the inner surface 14 a of the lid 14 in the axial direction of the polar column portion 44 from the peripheral surface of the polar column portion 44 toward the outer peripheral surface Ta of the stepped portion T. You may have the taper-shaped surface Tc which inclines in a direction.

  With this configuration, when the O-ring 56 is externally mounted on the pole column portion 44, the O-ring 56 is easily moved radially outward from the outer peripheral surface Ta of the stepped portion T by the tapered surface Tc. As a result, it becomes easy to arrange the O-ring 56 on the radially outer side of the stepped portion T.

○ As shown in FIG. 8B, the stepped portion T does not have to be erected from the seating surface 43 a, and extends in a disk shape radially outward from the circumferential surface of the pole column portion 44. Also good.
In the embodiment, the outer peripheral surface Ta of the stepped portion T is positioned on the outer side in the radial direction of the pole column portion 44 than the reference surface R. However, the outer peripheral surface Ta of the stepped portion T is positioned on the reference surface R. Also good.

If the insulation between the inner surface 14a of the lid 14 and the stepped portion end surface Tb of the stepped portion T can be secured, the position (height) of the stepped portion end surface Tb along the axial direction of the pole column portion 44 may be changed as appropriate. Good.
In the embodiment, the seal member is embodied as the O-ring 56 having a circular cross section, but the cross-sectional shape is not limited to the circular shape, and may be an O-ring having another cross-sectional shape.

In the embodiment, the O-ring 56 is embodied as a seal member, but may be changed to a resin gasket or the like.
In the embodiment, the terminal insulating member 19 is formed in a cylindrical shape, and the cylindrical portion 19 a is arranged over the entire circumference between the inner peripheral surface of the insertion hole 14 b and the peripheral surface of the pole column portion 44. The portion 19 a may be inserted only in a part of the circumferential direction between the inner peripheral surface of the insertion hole 14 b and the peripheral surface of the pole column portion 44. The cylindrical portion 19 a may overlap only a part of the stepped portion T in the circumferential direction when viewed from the axial direction of the pole column portion 44.

In the embodiment, the stepped portion T is formed in an annular shape extending over the entire circumference of the polar column portion 44, but may be formed with only a part in the circumferential direction of the polar column portion 44 being spaced.
The number of the positive electrode 21 and the negative electrode 22 which comprise the electrode assembly 20 may be changed suitably.

○ The shape of the case 12 may be cylindrical or elliptical.
The present invention may be embodied as a nickel hydride secondary battery as an electricity storage device or an electric double layer capacitor.

  F: Insulation cover width, H: Distance, R: Reference plane, S ... Gap, T ... Stepped portion, Ta ... Outer peripheral surface, Tb ... End surface of stepped portion, Tc ... Tapered surface, W ... Thickness, Y ... Long 10 ... secondary battery as power storage device, 13 ... case body, 13d ... opening, 14 ... lid, 14a ... inner surface, 14b ... insertion hole, 14c ... outer surface, 19 ... terminal insulating member, 20 ... electrode assembly , 41... Positive electrode terminal as an electrode terminal, 42... Negative electrode terminal as an electrode terminal, 43... Base, 43 a... Seat surface, 44. As an O-ring, 56a ... inner peripheral surface.

Claims (6)

A case body having an opening;
A lid that closes the opening and has an insertion hole through which the electrode terminal is inserted;
An electrode assembly housed in the case body;
Out of both ends of the pole post protruding from the lid through the insertion hole formed in the lid, the end located in the case main body has a cross section parallel to the lid and is larger than the area of the insertion hole. The electrode terminal having a base having a large cross-sectional area and electrically connected to the electrode assembly;
Around the pole column portion, an annular seal member interposed between the inner surface of the lid on the case body side and the seat surface of the base portion facing the inner surface;
A power storage device having an insulating cover sandwiched between an inner surface of the lid and the seat surface on a radially outer side of the pole column portion than the seal member,
A step portion located between the peripheral surface of the polar column portion and the inner peripheral surface of the seal member, and extending from the peripheral surface of the polar column portion to the radially outer side of the polar column portion;
The seating surface is continuous on the radially outer side of the pole column part than the sealing member, and there is no convex part protruding toward the lid from the seating surface,
The width of the insulating cover in the axial direction of the pole column is longer than the distance from the seating surface to the end surface of the stepped portion in the axial direction of the pole column,
In the axial direction of the polar column part, there is a gap between the inner surface of the lid and the step part,
The length of the gap in the axial direction of the pole column is at least half the thickness of the seal member in the axial direction of the seal member in a state assembled between the inner surface of the lid and the seating surface. power storage device which is a by.   A case body having an opening;
  A lid that closes the opening and has an insertion hole through which the electrode terminal is inserted;
  An electrode assembly housed in the case body;
  Out of both ends of the pole post protruding from the lid through the insertion hole formed in the lid, the end located in the case main body has a cross section parallel to the lid and is larger than the area of the insertion hole. The electrode terminal having a base having a large cross-sectional area and electrically connected to the electrode assembly;
  Around the pole column portion, an annular seal member interposed between the inner surface of the lid on the case body side and the seat surface of the base portion facing the inner surface;
  A power storage device having an insulating cover sandwiched between an inner surface of the lid and the seat surface on a radially outer side of the pole column portion than the seal member,
  A step portion located between the peripheral surface of the polar column portion and the inner peripheral surface of the seal member, and extending from the peripheral surface of the polar column portion to the radially outer side of the polar column portion;
  The seating surface is continuous on the radially outer side of the pole column part than the sealing member, and there is no convex part protruding toward the lid from the seating surface,
  The width of the insulating cover in the axial direction of the pole column is longer than the distance from the seating surface to the end surface of the stepped portion in the axial direction of the pole column,
  In the axial direction of the polar column part, there is a gap between the inner surface of the lid and the step part,
  The step portion has a tapered surface inclined in a direction away from the inner surface of the lid in the axial direction of the pole column portion from the peripheral surface of the pole column portion toward the outer peripheral surface of the step portion. Power storage device. If the cylindrical surface that partially overlaps the inner peripheral surface of the insertion hole and extends in the axial direction of the pole column portion is a reference surface, the outer peripheral surface of the stepped portion is on the reference surface or more than the reference surface The power storage device according to claim 1 , wherein the power storage device is located on a radially outer side. The length of the gap in the axial direction of the pole column is at least half the thickness of the seal member in the axial direction of the seal member in a state assembled between the inner surface of the lid and the seating surface. Sadea Ru electric storage device according to 請 Motomeko 2. The power storage device according to any one of claims 1 to 4 , wherein a terminal insulating member is disposed between an inner peripheral surface of the insertion hole and a peripheral surface of the polar column portion.   The power storage device according to any one of claims 1 to 5, wherein the power storage device is a secondary battery.