JP2005056649A - Sealed battery - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sealed battery capable of reliably stopping the rotation of insulating packing and an output terminal without aligning the insulating packing to a lid and without aligning the output terminal to the insulating packing. <P>SOLUTION: A terminal mounting hole 13 is provided in a lid 7 for blocking the upper-surface opening of a battery case 1. A positive electrode terminal 11 is fitted to the terminal mounting hole 13 via the insulating packing 9. The positive electrode terminal 11 has a head 16 and an axial section 17. The insulating packing 9 has a flange 28 and a cylinder 29 that allows the axial section 17 of the positive electrode terminal 11 to be inserted and is internally fitted to the terminal mounting hole 13. A terminal-side projection 26 projects on the lower surface at the head 16 in the positive electrode terminal 11. On the upper surface of the lid 7, a lid-side projection 33 projects at a place where a flange 28 in the insulating packing 9 comes into contact. The axial section 17 of the positive electrode terminal 11 is caulked, thus enabling the terminal-side projection 26 to engage into the upper surface of the flange 28 in the insulating packing 9 and enabling the lid-side projection 33 to engage into the lower surface of the flange 28 in the insulating packing 9. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a sealed battery such as a lithium battery or a lithium ion secondary battery used for a power source for a meter or a power source for backup.

  In a sealed battery, a terminal attachment hole is provided in a penetrating manner in a lid that closes the upper surface opening of the battery case, and a positive terminal (output terminal) is attached to the terminal attachment hole. The positive terminal has a shaft portion whose outer diameter is smaller than the inner diameter of the terminal mounting hole and a head portion on the upper end side of the shaft portion and whose outer diameter is larger than the inner diameter of the terminal mounting hole. It is crimped and fixed in the terminal mounting hole so that it cannot be removed. With this insulating packing, the positive electrode terminal and the lid are sealed to be kept in an airtight / liquidtight state and electrically insulated.

  As this type of insulation packing, for example, as shown in FIG. 5, a flange portion 28 sandwiched between the head portion 16 of the positive electrode terminal 11 and the lid 7, and a cylindrical portion that fits in the terminal mounting hole 13 provided in the lid 7. 29, and a configuration in which the insertion hole 30 is provided in the cylindrical portion 29 in a vertically penetrating manner is conceivable. According to this, when the shaft portion 17 of the positive electrode terminal 11 is inserted into the insertion hole 30 of the cylindrical portion 29 and attached to the terminal mounting hole 13, the lower end portion of the shaft portion 17 is bent outward and caulked. Further, the shaft portion 17 expands and deforms and comes into close contact with the insertion hole 30 of the insulating packing 9, so that the space between the shaft portion 17 and the insulating packing 9 is sealed. At the same time, the cylindrical portion 29 of the insulating packing 9 fitted around the shaft portion 17 expands and deforms and comes into close contact with the peripheral portion of the terminal mounting hole 13, thereby sealing between the insulating packing 9 and the lid 7.

  In such a sealed battery, an external lead plate is often welded to the head 16 of the positive electrode terminal 11 when being attached to a device. In the structure of FIG. 5, vibration or the like is transmitted to the positive electrode terminal 11 through the external lead plate, and the positive electrode terminal 11 may turn around the insulating packing 9. At this time, the insulating packing 9 is scraped by friction with the positive electrode terminal 11, and the sealing performance between the shaft portion 17 of the positive electrode terminal 11 and the insulating packing 9 may not be maintained.

  With respect to this point, in Patent Document 1, a protrusion provided on the lid of the storage battery is fitted into a recess provided on the bushing with a terminal to prevent rotation of the bushing with a terminal. It is possible to apply to.

JP 59-141163 (page 2, lower left column, Fig. 1-4)

  In the detent mechanism of Patent Document 1, it is necessary to align the projection of the lid with the recess of the bushing. If this alignment is performed accurately and the projection of the lid does not fit into the recess of the bushing with a terminal, the terminal is attached. There is a problem where the bushing turns around.

  As shown in FIGS. 1 and 2, the sealed battery according to the present invention includes a lid 7 that closes the upper surface opening of the battery case 1, a terminal mounting hole 13 that is provided in a penetrating manner in the lid 7, and a terminal mounting hole 13. And an output terminal 11 fitted through the insulating packing 9. The output terminal 11 has a head portion 16 having an outer diameter larger than the inner diameter of the terminal mounting hole 13 and a shaft portion 17 projecting downward from the lower surface of the head portion 16 and having an outer diameter smaller than the inner diameter of the terminal mounting hole 13. And have. The insulating packing 9 includes a flange portion 28 sandwiched between the head portion 16 of the output terminal 11 and the lid 7, and a cylinder that fits in the terminal mounting hole 13 in a state where the shaft portion 17 of the output terminal 11 is inserted into the terminal mounting hole 13. Part 29. The head portion 16 of the output terminal 11 is pressed against the flange portion 28 of the insulating packing 9 by caulking the shaft portion 17 of the output terminal 11.

  In the sealed battery according to the present invention, a terminal-side protrusion 26 protrudes downward from the lower surface of the head portion 16 of the output terminal 11, and the flange portion 28 of the insulating packing 9 is in contact with the upper surface of the lid 7. In addition, a lid-side protrusion 33 protrudes upward. Thus, the terminal-side protrusion 26 bites into the upper surface of the flange portion 28 of the insulating packing 9 by the pressing force of the head 16 of the output terminal 11 toward the flange portion 28 side, and the lid-side protrusion 33 of the insulating packing 9 It is characterized by biting into the lower surface of the flange portion 28.

  The caulking form of the shaft portion 17 of the output terminal 11 here is the case where the lower end portion of the shaft portion 17 is bent outward as shown in FIG. 5, and the shaft portion 17 is compressed and expanded downward as shown in FIG. And caulking in a tapered shape. For the insulating packing 9, a material having a hardness lower than that of the lid 7 and the output terminal 11 is selected. For example, the lid 7 and the output terminal 11 are made of metal, whereas the insulating packing 9 is made of synthetic resin.

  Specifically, as shown in FIGS. 1 and 2, an insulating plate 10 that has a packing insertion hole 36 formed therethrough and a presser plate 12 that has a shaft insertion hole 37 formed therethrough are sequentially arranged below the lid 7. In the packing insertion hole 36, the lower end portion of the cylindrical portion 29 of the insulating packing 9 through which the shaft portion 17 of the output terminal 11 is inserted is fitted. The lower end portion of the shaft portion 17 of the output terminal 11 protruding from the tube portion 29 of the insulating packing 9 is fitted into the shaft insertion hole 37. Then, by pressing the shaft portion 17 of the output terminal 11, the pressing plate 12 is pressed against the lid 7 side by the shaft portion 17 of the output terminal 11 through the insulating plate 10.

  A plurality of lid-side protrusions 33 are provided at equal intervals in the circumferential direction of the terminal mounting hole 13, and a plurality of terminal-side protrusions 26 are provided at equal intervals around the outer periphery of the shaft portion 17 of the output terminal 11. In a state where the output terminal 11 is fitted into the terminal mounting hole 13 through the insulating packing 9, the terminal side protrusion 26 and the lid side protrusion 33 are positioned in the radial direction so that they do not overlap vertically. Staggered.

  A recess 14 is formed in the opening peripheral wall of the terminal mounting hole 13 on the upper surface of the lid 7, and the lower portion of the flange portion 28 of the insulating packing 9 is fitted to the seat 14 of the lid 7. The lid-side protrusion 33 can be provided at a location where the lower surface of the flange portion 28 of the insulating packing 9 contacts. The shaft portion 17 of the output terminal 11 may be caulked in a downwardly expanding taper shape.

  According to the present invention, when the lid-side protrusion 33 of the lid 7 bites into the insulating packing 9, the insulating packing 9 is prevented from rotating with respect to the lid 7, and the terminal-side projection 26 of the output terminal 11 bites into the insulating packing 9. As a result, the output terminal 11 is prevented from rotating with respect to the insulating packing 9. Even if the insulating packing 9 is not aligned with the lid-side protrusion 33 of the lid 7 or the terminal-side protrusion 26 of the output terminal 11 is aligned with the insulating packing 9, the above-described detent can be easily and reliably performed.

  Therefore, the insulating packing 9 can be reliably prevented from being scraped by friction around the terminal mounting hole 13 of the lid 7. It is possible to reliably prevent the output terminal 11 from turning around the insulating packing 9 and scraping the insulating packing 9 by friction. As a result, the airtight / liquid tight action of the insulating packing 9 can be maintained for a long time, and a highly reliable sealed battery can be obtained. The labor and time for manufacturing the battery can be reduced by the amount that the alignment can be omitted.

  By caulking the shaft portion 17 of the output terminal 11, when the pressing plate 12 is pressed against the lid 7 via the insulating plate 10 by the shaft portion 17 of the output terminal 11, the reaction of the output terminal 11 is caused by a reaction accompanying this pressing. The head 16 is firmly pressed against the flange portion 28 of the insulating packing 9, so that the insulating packing 9 and the output terminal 11 can be reliably prevented from rotating with respect to the lid 7.

  If the terminal-side protrusion 26 and the lid-side protrusion 33 are arranged with their positions shifted in the radial direction of the terminal mounting hole 13 so that they do not overlap each other, the terminal-side protrusion 26 and the lid-side protrusion 33 It is possible to prevent the flange portion 28 of the insulating packing 9 from having a hole due to the interference, and it is possible to reliably prevent the airtight / liquid-tight action of the insulating packing 9 from being lowered by the hole.

  When the lower portion of the flange portion 28 of the insulating packing 9 is fitted to the seat 14 on the lid 7 side, the flange portion 28 of the insulating packing 9 is prevented from protruding upward from the lid 7, and the battery as much as this amount. The length dimension in the vertical direction can be reduced.

  1 to 4 show a sealed battery as an object of the present invention. As shown in FIG. 2, a bottomed cylindrical battery case 1 having an open top surface and electrodes loaded in the battery case 1 are shown. The body and the non-aqueous electrolyte, and a sealing structure that closes the upper surface opening of the battery case 1 are included. The battery case 1 is formed by deep drawing a stainless steel plate or a steel plate nickel-plated on iron, and also serves as an output terminal on the negative electrode side.

  In the electrode body, a sheet-like positive electrode 2 using manganese dioxide as an active material and a negative electrode 3 made of lithium foil are spirally wound with a separator 4 made of a microporous polyethylene film interposed therebetween. Conductive tabs 5 and 6 are led out from the positive electrode 2 and the negative electrode 3, respectively. The negative electrode 3 has an outer peripheral surface covered with a separator 4 and is welded to the inner surface of the battery case 1 via a nickel current collector.

As a non-aqueous electrolyte, LiCF ₃ SO ₃ was mixed at a ratio of 0.5 mol / liter with a solvent in which propylene carbonate (PC) and 1,2-dimethoxyethane (DME) were mixed at a volume ratio of 1: 1. A dissolved solution was used.

  The sealing structure includes a disc-shaped lid 7 that closes the upper surface opening of the battery case 1, a plastic insulator 8 disposed inside the lid 7, an annular insulating plate 10 for insulation, and the lid 7. And a positive output terminal (positive terminal) 11 that is caulked and fixed through the insulating packing 9 and the insulating plate 10, and an annular metal pressing plate 12 that is caulked and fixed with the positive terminal 11. .

  The lid 7 is made of a press-formed product made of a stainless steel plate or a steel plate nickel-plated on steel, and is sealed and welded to the periphery of the opening of the battery case 1 with a laser. In the center of the lid 7, as shown in FIG. 3, a circular terminal mounting hole 13 through which the insulating packing 9 and the positive electrode terminal 11 pass is provided in a penetrating manner. On the upper surface of the lid 7, a receiving seat 14 is recessed in the opening peripheral wall of the terminal mounting hole 13.

  The positive electrode terminal 11 includes a disk-shaped head portion 16, a columnar shaft portion 17 projecting downward from the center of the lower surface of the head portion 16, and a conical recess formed upward on the lower end surface of the shaft portion 17. 18 and a shaft body made of a stainless steel plate. The outer diameter of the head 16 is set to be larger than the inner diameter of the terminal mounting hole 13, and the outer diameter of the shaft portion 17 is set to be smaller than the inner diameter of the terminal mounting hole 13.

  A neck portion 22 having a circular cross section protrudes from the lower surface of the head portion 16 of the positive electrode terminal 11, and the shaft portion 17 is disposed at the center of the lower surface of the neck portion 22. The outer peripheral surface of the neck portion 22 is formed in a tapered shape having a downward concavity.

  The upper end of the shaft portion 17 is connected to the neck portion 22 via a tapered portion 23 having a lower conical shape. By forming the neck portion 22 and the upper end side of the shaft portion 17 in a tapered shape, the adhesion with the insulating packing 9 is enhanced. Near the outer periphery of the lower surface of the head 16, as shown in FIG. 4, three substantially cylindrical projections (terminal-side protrusions) 26 protrude downward at equal intervals around the outer periphery of the shaft portion 17 of the positive electrode terminal 11. It is installed.

  The insulating packing 9 is made of a synthetic resin having thermoplasticity and insulating properties such as polypropylene and polyphenylene sulfide, and as shown in FIG. 3, an annular flange portion 28 and a cylinder projecting downward from the center of the flange portion 28. A cylindrical portion 29. The lower part of the flange portion 28 of the insulating packing 9 is fitted into the seat 14 of the lid 7 as shown in FIG.

  The shaft portion 17 of the positive electrode terminal 11 is inserted into the insertion hole 30 provided in the center of the cylindrical portion 29 of the insulating packing 9. The lower end portion of the shaft portion 17 of the positive electrode terminal 11 protrudes below the cylindrical portion 29 of the insulating packing 9. In FIG. 3, the upper end side of the insertion hole 30 is formed in a tapered shape with a lower concavity, and the lower end side of the insertion hole 30 is formed in a tapered shape that expands downward. On the outer peripheral side of the lower end of the cylindrical portion 29 of the insulating packing 9, a downwardly tapered taper portion 31 is formed.

  In the seat 14 of the lid 7, three conical small projections (lid-side projections) 33 are arranged in the circumferential direction, as shown in FIG. 4, near the outer periphery where the lower surface of the flange portion 28 of the insulating packing 9 contacts. Are projected upward at equal intervals. In the assembled state of FIG. 1, the small protrusion 33 of the lid 7 is displaced from the small protrusion 26 of the positive terminal 11 in the radial direction of the terminal mounting hole 13. The small protrusions 26 are arranged so as not to overlap each other. This prevents the small protrusion 33 of the lid 7 and the small protrusion 26 of the positive terminal 11 from interfering with each other in the assembled state of FIG.

  A circumferential wall 34 is formed around the terminal mounting hole 13 at the opening periphery of the terminal mounting hole 13 on the upper surface of the lid 7, and a circumferential wall 35 is formed around the outer periphery of the terminal mounting hole 13 on the lower surface of the lid 7. Protrusions are formed. The circumferential wall 34 on the upper surface of the lid 7 bites into the lower surface of the flange portion 28 of the insulating packing 9 and improves the adhesion between the lid 7 and the insulating packing 9. The circumferential wall 35 on the lower surface of the lid 7 bites into the upper surface of the insulating plate 10 and improves the adhesion between the lid 7 and the insulating plate 10.

  The insulating plate 10 is made of a synthetic resin having thermoplasticity, heat resistance and insulating properties, such as polypropylene and polyphenylene sulfide, like the insulating packing 9. The pressing plate 12 is made of a stainless steel plate. As the insulating plate 10, a punched product that penetrates the packing insertion hole 36 is used. The insulating plate 10 is sandwiched between the lower surface of the lid 7 and the pressing plate 12.

  The diameter dimension of the insertion hole 30 of the insulating packing 9 is substantially the same as or slightly smaller than the outer diameter dimension of the shaft portion 17 of the positive electrode terminal 11. The outer diameter dimension of the cylindrical portion 29 of the insulating packing 9 is substantially the same as or slightly larger than the diameter dimension of the terminal mounting hole 13 of the lid 7.

  The diameter of the packing insertion hole 36 of the insulating plate 10 is larger than the inner diameter of the terminal mounting hole 13 of the lid 7 and smaller than the outer diameter of the tapered portion 31 of the insulating packing 9. Thereby, in the assembled state of FIG. 1, the tapered portion 31 of the insulating packing 9 is fitted into the inner surface of the packing insertion hole 36 of the insulating plate 10 in close contact.

  As the pressing plate 12, a punched product formed through the shaft insertion hole 37 is used. The upper end side of the shaft insertion hole 37 is formed in a taper shape with a lower concavity, and the lower end side of the shaft insertion hole 37 is formed in a taper shape that expands downward.

  The positive electrode terminal 11, the insulating packing 9, the insulating plate 10, and the holding plate 12 are assembled in the state shown in FIG. 1 so that the lower end of the shaft portion 17 of the positive electrode terminal 11 protrudes downward from the holding plate 12. The length dimension in the vertical direction of the shaft portion 17 of the terminal 11 is set. The positive terminal 11, the insulating packing 9, the insulating plate 10, and the holding plate 12 are integrated with the lid 7 by caulking and fixing the positive terminal 11.

  Specifically, the insulating plate 10 and the pressing plate 12 are arranged in this order on the lower side of the lid 7, and the cylindrical portion 29 of the insulating packing 9 is passed from the upper surface side of the lid 7 through the terminal mounting hole 13 of the lid 7 to be a tapered portion. 31 is fitted in the packing insertion hole 36 of the insulating plate 10, and the shaft portion 17 of the positive electrode terminal 11 is passed through the insertion hole 30 of the insulating packing 9. At this time, the lower end of the shaft portion 17 of the positive electrode terminal 11 protrudes through the shaft insertion hole 37 of the pressing plate 12 to the lower side of the pressing plate 12.

  By pressing the head portion 16 of the positive electrode terminal 11 with a jig or the like and compressing the shaft portion 17 of the positive electrode terminal 11 toward the head portion 16 side, the shaft portion 17 of the positive electrode terminal 11 tapers downward as shown in FIG. The diameter is expanded and deformed. Then, the shaft portion 17 of the positive electrode terminal 11 is pressed against the inner surface side of the terminal mounting hole 13 of the lid 7 through the cylindrical portion 29 of the insulating packing 9. Further, the shaft insertion hole 37 of the pressing plate 12 is pressed obliquely upward, and the pressing plate 12 is pressed against the lid 7 side through the insulating plate 10. Before the compression, the outer diameter of the shaft portion 17 of the positive electrode terminal 11 is the same from the upper end to the lower end of the shaft portion 17.

  As a result, the space between the positive electrode terminal 11 and the terminal mounting hole 13 of the lid 7 is tightly sealed with the insulating packing 9, and the insulating plate 10 is sandwiched between the lid 7 and the holding plate 12 and these are held. And the space between the lid 7 and the pressing plate 12 is tightly sealed. In this state, the lid 7 and the positive electrode terminal 11 attached to the terminal attachment hole 13 are kept in an airtight / liquid tight state and are electrically insulated.

  The peripheral edge of the terminal mounting hole 13 of the lid 7 is sandwiched between the head 16 of the positive electrode terminal 11 (directly the flange portion 28 of the insulating packing 9) and the pressing plate 12 (directly the insulating plate 10). The terminal 11, the insulating packing 9, the insulating plate 10, and the pressing plate 12 are integrated with the lid 7.

  When the shaft portion 17 of the positive electrode terminal 11 is caulked, the head portion 16 of the positive electrode terminal 11 is pressed against the flange portion 28 of the insulating packing 9 by the reaction of the pressing force when the pressing plate 12 is pressed against the lid 7 side. As shown in FIG. 1, each small protrusion 26 of the head portion 16 of the positive electrode terminal 11 bites into the upper surface of the flange portion 28 of the insulating packing 9. Furthermore, each small protrusion 33 of the lid 7 is pressed against the lower surface of the flange portion 28 of the insulating packing 9 and bites.

  The insulating packing 9 is prevented from rotating with respect to the lid 7 by the biting of the small protrusions 33 of the lid 7, and the small terminal 26 of the positive electrode terminal 11 bites into the insulating packing 9, so that the positive electrode terminal 11 passes through the insulating packing 9. Stopped at 7.

  Therefore, the insulating packing 9 is prevented from being scraped by friction around the terminal mounting hole 13 of the lid 7, and similarly, the positive terminal 11 is rotated around the insulating packing 9 and the insulating packing 9 is scraped by friction. It is prevented.

  Since the pressing plate 12 is made of metal as described above, a pressing force by the shaft portion 17 is applied to almost the entire lower surface of the insulating plate 10 via the pressing plate 12 when the positive electrode terminal 11 is caulked. The entire upper surface of the plate 10 is in close contact with the inner surface (back surface) of the lid 7. The conductive tab 5 on the positive electrode side described above is welded to the lower end surface of the shaft portion 17 of the positive electrode terminal 11 (FIG. 2).

  When assembling the entire battery, first, the conductive tab 6 on the negative electrode side is welded to the inner surface of the battery case 1, and the insulator 8 is mounted in the battery case 1. Next, in the assembly in which the positive electrode terminal 11 and the like are integrally assembled with the lid 7, the positive electrode side conductive tab 5 is welded to the lower end of the shaft portion 17 of the positive electrode terminal 11.

  Next, a non-aqueous electrolyte is injected into the battery case 1. Thereafter, the lid 7 is fitted into the upper end of the battery case 1 and the fitting surface between the lid 7 and the battery case 1 is laser welded and sealed. At this time, since the heat resistant resin is used for the insulating packing 9 which is easily affected by the welding heat, the insulating packing 9 is not deformed / deformed or melted by the welding heat. Thereby, the battery is completed.

  The neck portion 22 may be omitted, and the shaft portion 17 may be provided directly on the lower surface of the head portion 16. The output terminal 11 may be crimped by bending the lower end portion of the shaft portion 17 outward as in FIG. The insulating packing 9 and the insulating plate 10 may be formed of rubber having an insulating property. In this case, each small protrusion 26 of the positive electrode terminal 11 and each small protrusion 33 of the lid 7 bite in by elastically deforming the flange portion 28 of the insulating packing 9.

The longitudinal cross-sectional view which shows the principal part of the sealing structure of the sealed battery of this invention Whole vertical section of sealed battery Longitudinal sectional view of each member of the sealing structure Perspective view of the main part of the sealing structure Longitudinal sectional view of the sealing structure for explaining the problem

Explanation of symbols

1 Battery Case 7 Lid 9 Insulating Packing 10 Insulating Plate 11 Positive Terminal (Output Terminal)
12 Presser plate 13 Terminal mounting hole 14 Receiving seat 16 Head portion of positive terminal 17 Shaft portion 26 of positive terminal Small protrusion (terminal side protrusion) of positive terminal
28 Insulating packing flange 29 Insulating packing cylinder 33 Small projection on the lid (protrusion on the lid side)
36 Insulating plate packing insertion hole 37 Holding plate shaft insertion hole

Claims (5)

A lid for closing the upper surface opening of the battery case, a terminal mounting hole provided in a penetrating manner in the lid, and an output terminal fitted to the terminal mounting hole via an insulating packing;
The output terminal has a head portion whose outer diameter is larger than the inner diameter of the terminal mounting hole, and a shaft portion protruding downward from the lower surface of the head portion and having an outer diameter smaller than the inner diameter of the terminal mounting hole. Have
The insulating packing includes a flange portion sandwiched between the head portion of the output terminal and the lid, and a cylindrical portion that fits into the terminal mounting hole in a state where the shaft portion of the output terminal is inserted into the terminal mounting hole. And
In the sealed battery in which the head portion of the output terminal is pressed against the flange portion of the insulating packing by caulking the shaft portion of the output terminal.
A terminal-side protrusion is provided to protrude downward on the lower surface of the head of the output terminal,
On the top surface of the lid, the projection on the lid side is provided so as to protrude upward at the location where the flange portion of the insulating packing contacts.
The terminal side protrusions bite into the upper surface of the flange part of the insulating packing by the pressing force of the output terminal to the flange part side of the insulating packing by the head portion, and the lid side protrusion is the surface of the insulating packing. A sealed battery characterized by biting into the lower surface of the flange portion. On the lower side of the lid, an insulating plate penetrating the packing insertion hole and a pressing plate penetrating the shaft insertion hole are sequentially arranged,
In the packing insertion hole, a lower end portion of the cylindrical portion of the insulating packing inserted through the shaft portion of the output terminal is internally fitted,
In the shaft insertion hole, a lower end portion of the shaft portion of the output terminal protruding from the tube portion of the insulating packing is internally fitted,
The sealed battery according to claim 1, wherein the pressing plate is pressed against the lid via the insulating plate by the shaft portion of the output terminal by caulking the shaft portion of the output terminal. A plurality of the lid-side protrusions are provided at equal intervals in the circumferential direction of the terminal mounting hole,
A plurality of the terminal side protrusions are provided at equal intervals around the shaft portion of the output terminal,
With the output terminal fitted in the terminal mounting hole via the insulating packing, the terminal side protrusion and the lid side protrusion are shifted in the radial direction so that they do not overlap vertically. The sealed battery according to claim 2, wherein the sealed battery is disposed. A recess is formed in the opening peripheral wall of the terminal mounting hole on the upper surface of the lid, and the lower portion of the flange portion of the insulating packing is fitted to the seat of the lid,
The sealed battery according to claim 3, wherein the lid-side protrusion is provided at a location where the lower surface of the flange portion of the insulating packing contacts the seat.   The sealed battery according to claim 4, wherein the shaft portion of the output terminal is caulked in a downwardly expanding taper shape.

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