JP3302105B2 - Flat battery sealing device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement in a sealing device for a flat battery.

[0002]

2. Description of the Related Art As a conventional sealing device for a flat type battery, there is known a sealing device described in Japanese Patent Publication No. 57-28453. This sealing device will be described below with reference to FIG. A lower rotating disk 61 having an arc groove 60 on the periphery is fixed on a rotating table 62. Through hole 63 ₁ is opened in the rotary table 62. The through hole 6
3 The _first recess 6 which is inserted in non-sealing the battery is sealed
A sealing die 65 having a 4 is inserted to be vertically movable. A cap nut 66 ₁ is inserted into the through hole 63 ₁ so that its lower part projects downward from the lower surface of the turntable 62. The sealing die 65 is screwed to the cap nut 66 ₁ located in the through hole 63 ₁ . The cap nut 66 ₁ protruding from the lower surface of the turntable 62 has a cylindrical sealing cylinder 67 with a bottom.
Is screwed at the upper end. Upper Knuckout 68a
Is inserted near the upper portion in the cylinder 67 through the sealing die 65. The upper knuckout 68
The lower knockout 68b is located below the cylinder 6
7 are disposed through the bottom. The upper knuckout 6 is provided between the upper and lower knacks 68a and 68b.
A coil spring 69 for urging the upper portion 8a upward is interposed. The lower NACK-out 68b lower pressure roller 70 ₁ lower end in the region to be sealed of the is adapted to be pressed. An upper rotating disk 71 is disposed above the rotating disk 61. Through hole 63 ₂ is formed in the upper rotating disk 71. Pressing punch holder 72 is inserted vertically movably in the through-hole 63 _2.
At the lower end of the holder 72, a pressing punch 73 is provided with a cap nut 6.
It is fixed via a 6 _2. A roller follower 74 is attached to an upper side wall of the holder 72. The roller follower 74 is engaged with a cam groove 76 of a ring-shaped cam 75, and moves along the cam groove 76 with the rotation of the rotary disks 61 and 71 and the rotary table 62, thereby causing the holder 72 to move. It moves up and down. Furthermore, the upper end of the holder 72 in the area to be sealed upper pressure roller 70 ₂ is adapted to be pressed.

[0003] A sealing method using the sealing device will be described with reference to FIGS. 11 and 12 described above. As shown in FIG. 11 described above, the pressing punch holder 72 is located above,
In a state where the pressing punch 73 is sufficiently separated from the lower rotating disk 61 and the upper end surface of the upper knuckout 68a is positioned on the upper surface of the concave portion 64 of the sealing die 65,
The unsealed battery B ₃ is supplied upside down into the arc groove 60 of the lower rotating disk 61.

Then, when the lower rotary disk 61 and the upper rotary disk 71 are rotated, the roller follower 74 of the holder 72 moves along the cam groove 76 of the cam 75 and is inclined downward. The holder 72 is lowered at the cam groove 76 portion. As a result, the pressing punch 73 at the lower end of the holder 72 is lowered, and the pressing punch 73 passes through the arc groove 60 and the sealing die 65.
Is inserted within, the lower end surface lowers the battery B ₃ against the biasing force of the non-sealing cell B ₃ wherein while being abutted against the coil spring 69.

Next, as shown in FIG. 12, when the lower rotating disk 51, the upper rotating disk 61 and the rotating table 52 are rotated, the engagement between the cam 65 and the cam groove 66 is released and the sealing is performed. The holder 62 is pressed by the upper pressure roll 60 ₂ to push the battery B ₃ into the recess 54 of the sealing die 55,
By opening of the battery B ₃ is in contact with bent inner bottom surface of the recess 54, sealing is performed. In addition,
In sealing process the lower NACK-out 58b in sliding contact with the lower pressure roll _601, the rotation of the rotary table 52 and the upper and lower rotary disc 61 and 51 is prevented alienated.

However, the lower rotary disk in a state in which the is not selected sealing battery B ₃ tilted in this manner the sealing device 51
When placed in the circular groove 50 and sealed, the airtightness is reduced. For placing always horizontally the non sealing battery B ₃ to the arcuate grooves 50 in the above-mentioned sealing apparatus is difficult, a problem of low sealing precision.

[0007]

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems, and an object of the present invention is to provide a sealing device capable of accurately sealing an unsealed flat battery. .

[0008]

The present invention has a circular vertical hole.
And a table to be inserted into the circular vertical hole of the table
As well as a circle with almost the same dimensions as an unsealed flat battery
The recess is smaller in size than the circular recess connected to it
A crimp die and a cylindrical hole is formed, the circular
The cylindrical hole portion of the crimp mold from the vertical hole and the
A knuckout that moves up and down a space extending over the circular recess, a battery supply unit that supplies an unsealed battery to an upper end surface of the knuckout positioned at the same height as the upper surface of the table, and the circle.
It is disposed above the form recesses, flat type, characterized by comprising a vertically movable pushing means having a push-fit to push the non-sealing said circular inner recess battery state sandwiched together with the NACK-out at the bottom This is a battery sealing device.

The present invention more particularly has a circular vertical bore,
The circular vertical hole is a table including a circular concave portion having substantially the same size as an unsealed flat battery and a cylindrical hole portion smaller in size than the circular concave portion connected thereto, and a vertically movable member inserted into the circular vertical hole. A knuckout, a first driving means for moving the knuckout up and down, a battery supply means for supplying an unsealed battery to the knuckout upper end surface raised to the same height as the upper surface of the table, and an upper part of the circular vertical hole , A vertically movable push-in means having a cylindrical hollow portion formed in a lower central portion, a second drive means for vertically moving the push-in means, and a lower end of the cylindrical hollow portion having a lower end of the push-in means. And a cylindrical holding member having a lower inner diameter that is slightly larger than an outer diameter of the unsealed battery, and a cylindrical hollow portion of the pressing means. A first coil spring disposed between the inner surface of the upper portion and the presser die; and a first coil spring inserted from the hollow portion of the presser die into the first coil spring and having an upper end in the upper inner surface of the cylindrical hollow portion. A cylindrical press-type having a dimension longer than the fixed press-type, and a cylindrical press-type rod suspended by inserting a lower portion of the press-type into a hollow portion so as to protrude downward from a lower end of the press-type. A second coil spring disposed between the inner surface of the upper portion of the cylindrical cavity of the pushing means and the cylindrical holding rod; and a battery collecting means for collecting a sealed battery in the circular vertical hole of the table. This is a sealing device for a flat battery.

[0010]

According to the present invention, the unsealed battery supplied to the upper end surface of the knuckout located at the same height as the upper surface of the table by the pushing type of the pushing means which can move up and down is sandwiched together with the knuckout. By pushing the unsealed battery into the circular vertical hole, the unsealed battery descends while always maintaining a horizontal state along the inner surface of the circular concave portion of the circular vertical hole. The open end of the container to be abutted is bent inward. As a result, the unsealed battery can be accurately sealed.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below in detail with reference to FIGS. FIG. 1 is a plan view showing a table, a battery supply means and a battery discharge means of a flat battery sealing device of the present invention, FIG. 2 is a perspective view showing a table of the device of FIG. 1, and FIG. FIG. 4 is an enlarged sectional view of a main part of the apparatus of FIG.

As shown in FIGS. 1 to 3, the table 1 comprises a rectangular block 2 and a top plate 3 supported by a side plate (not shown) integrated with the block 2. A circular vertical hole 4 is formed in the rectangular block 2 of the table 1. A slit 5 communicating with the circular vertical hole 4 is formed on a side surface of the block 2 on the top plate 3 side and a side surface opposite to the side surface along the vertical hole 4. The cylindrical crimp mold 6 is inserted into the upper end of the circular vertical hole 4 . Such crimp mold
6, a circular recess 7 having the same size as the diameter of the unsealed flat battery is formed in the upper portion of the hollow portion 7a . The hollow
The portion 7a has a cylindrical hole smaller in size than the circular concave portion 7.
Part.

A driving rod 8 and a knockout 9 connected to the upper end of the driving rod 8 are inserted into the vertical hole 4, and the driving rod 8 is moved up and down by first driving means 10. Near the lower part of the drive rod 8, a shaft 11 is mounted so as to penetrate in the horizontal direction, and both ends of the shaft 11 project outside from the slit 5 of the block 2. Further, rollers 12 that engage with a U-shaped notch described later are supported at both ends of the shaft 11, respectively. The first driving means 10 includes a lever 13 having a left end bifurcated and arranged in parallel at a predetermined distance from each other. Support 14
In the upper part, two support pieces 15 facing each other in parallel with each other are formed, and the lever 13 is provided between the support pieces 15.
A fulcrum shaft 16 for pivotally supporting a central portion of the slidable body is mounted on the slewing shaft. Near one end (right end) of the lever 13,
An elongated hole 17 is opened in the length direction. A cylinder 18b having a vertically moving cylinder rod 18a is disposed above one end of the lever 13, and a pin 18c is mounted near the lower end of the cylinder rod 18a so as to penetrate horizontally. One end of the pin 18c is engaged with the elongated hole 17 opened at one end of the lever 13. The bifurcations 13a and 13b of the lever 13
2 in which the slit 5 of the rectangular block 2 is formed
U-shaped cutouts 19 are formed so as to sandwich the two side faces and to engage with the rollers 12 of the drive rod 8 near the other end.

In the first driving means 10 having such a structure, when the cylinder rod 18a is pressed downward by driving the cylinder 18b, one end of the lever 13 is pushed down. The forked portions 13a and 13b having the raised portions rise. When the forked portions 13a and 13b having the U-shaped notch 19 rise, the rollers 1 of the drive rod 8 engaged with the U-shaped notch 19 are moved.
2 rises, and as a result, the knockout 9 rises from the circular vertical hole 4 along the hollow portion 7a . The first driving means 10 is configured so that the cylinder rod 18a of the cylinder 18b rises so that the knuckout 9 descends following the downward movement of a circular push-in die described later.

A column 21 having a support member 20 extending in the horizontal direction is erected adjacent to the table 1. A casing 22 in which a driving component of a second driving unit to be described later is stored is mounted on the column 21.
A cylindrical rod 24 as a pushing means having a free shank 23 at an upper end is inserted and supported by the support member 20 so as to be located above the circular vertical hole 4, and is supported by the second driving means 2.
5 is moved up and down. The second driving means 25 includes a shank holder 26 whose lower part is rotatably engaged with the free shank 23, and a screw shaft which is connected to the shank holder 26 at the lower end and is located in the casing 22. (Not shown) integrated ram 27
A motor (not shown) disposed in the casing 22 and screwed to the screw shaft of the ram 27; and a motor (not shown) having a drive shaft (not shown) disposed in the casing 22. (Not shown), and an endless belt (not shown) pivotally supported by the engagement member and the drive shaft.

In the second driving means 25 having such a configuration, when the driving shaft of the motor is rotated and the engaging member pivotally supported by the endless belt is rotated, the driving shaft is screwed to the engaging member. The ram 27 having the set screw shaft rotates. When the ram 27 rotates, it is converted into a linear motion by the free shank 23 rotatably engaged with the lower end of the ram 27, and the cylindrical bar 24 connected via the free shank 23 is attached to the support member 20. It is guided and moved up and down. For example, when the engaging member is rotated clockwise, the cylindrical bar 24 is guided and lowered by the support member 20, while when the engaging member is rotated counterclockwise, the cylindrical bar 24 is supported. It is guided by the member 20 and rises.

The cylindrical rod 24 as the pushing means is
As shown in FIG. 4, a cylindrical hollow portion 28 is formed at the lower central portion, and a cylindrical pressing die 29, a cylindrical pressing die 30, and a cylindrical pressing rod 31 are formed in the hollow portion 28.
And are arranged. A disk 32 is fixed to the upper inner surface of the cylindrical hollow portion 28. The holding mold 29
Is inserted into the cylindrical hollow portion 28 so that a lower portion protrudes from a lower end of the cylindrical bar 24, and the cylindrical bar 24
It is suspended by a support ring 34 fixed to the lower end with a screw 33. The cylindrical pressing die 29 has a cylindrical pressing portion 35 having an inner diameter that is expanded to a size slightly larger than the outer diameter of the unsealed flat battery at the lower portion. First
The coil spring 36 is disposed between the disk 32 and the holding mold 29 in the cylindrical hollow portion 28.
The pressing die 30 is inserted over both the hollow portion of the pressing die 29 and the inside of the first coil spring 36 and has an upper end fixed to the bottom surface of the disk 32. The pressing die 30 has a length equal to that of the pressing die 29.
It is longer. The cylindrical spacer 37 is inserted into the pushing die 30 and has an upper end fixed to the bottom surface of the disk 32. The cylindrical holding rod 31
Is suspended in a hollow portion of the press-in die 30 so as to protrude downward from a lower end of the press-in die 29, and is suspended via a flange portion 38 having a diameter larger than that of the press-down bar 31 attached to the upper end. Have been. The second coil spring 39 includes the spacer 37 and the cylindrical holding rod 3.
1 between them.

The battery supply means and the battery discharge means are shared by one transport means 40. The transfer means 40 includes a positioning plate 41 as shown in FIG. The positioning plate 41 has a U-shaped notch 42 that matches the circular vertical hole 4 while moving along a fixed rectangular locus, and a V-shaped notch 43 that discharges a battery. The positioning plate 41 is operated by a third driving unit (not shown) arranged below the top plate 3 of the table 1 so as to draw a fixed rectangular locus. The third
The driving means includes two non-rotating guides extending in the X and Y axis directions (not shown). A first movable block (not shown) is engaged with the detent guide extending in the X-axis direction so as to freely reciprocate in the X-axis direction, and the detent guide extending in the Y-axis direction is provided on the movable block. Fixed. In the detent guide extending in the Y-axis direction,
A second movable block (not shown) is engaged so as to reciprocate in the Y-axis direction. The plate 41 is fixed to the second movable block via a support pin (not shown) penetrating the top plate 3 vertically. Each of the first and second movable blocks has a cylinder (not shown). In the third driving means having such a configuration, when the rod of the cylinder in the Y-axis direction is advanced and the second movable block is moved in the Y-axis direction by a fixed distance along the detent guide, the positioning plate 41 The second movable block is moved by a predetermined distance in the same direction as the movement of the second movable block. Subsequently, the rod of the cylinder in the X-axis direction is advanced, and when the first movable block moves in the X-axis direction for a fixed distance along the detent guide, the plate 41 moves in the same direction as the first movable block. Moved a certain distance. Continued, said Y
When the rod of the cylinder in the axial direction is retracted, the plate 41 returns in the Y-axis direction by the retracted distance. afterwards,
When the rod of the cylinder in the X-axis direction is retracted, the plate 41 returns by the retreat distance in the X-axis direction and returns to the initial position, so that the plate 41 is operated to draw a fixed rectangular locus.

A supply conveyor 45 having guides 44 on both sides is attached to the side surface of the top plate 3 and supplies unsealed batteries to the transport means 40. Guide 4 on one side
6 is provided with the discharge conveyor 47,
And discharges the sealed battery housed in the conveying means 40.

Next, the operation of the above-described flat battery sealing device will be described with reference to FIGS. 1 to 3 and FIGS. FIG. 5 is a sectional view showing an unsealed zinc-air battery, and FIGS.
FIG. 9 is a sectional view showing a step of sealing the unsealed battery, and FIG. 10 is a sectional view showing an air zinc battery sealed by the above-described device.

[0021] First, a zinc-air battery B ₁ of unsealed opening in a state of inverted as shown in FIG. A gel zinc 49 is stored in the negative electrode container 48. A laminate formed of a polytetrafluoroethylene (PTFE) film 52, a carbon sheet 53, and a separator 54 is pressed on the inner surface of the positive electrode container 51 having the air holes 50 opened. An insulating gasket 55 is provided between the negative electrode container 48 and the positive electrode container 51.
It is interposed between.

The cylinder 18 of the first driving means 10
By driving b, the knuckout 9 is raised up to the same height as the upper surface of the block 2 as shown in FIG. As shown in FIG. 1 described above, the unsealed battery B
₁ is stored in the U-shaped notch 42 of the positioning plate 41 from the supply conveyor 45. By advancing the rod of the cylinder in the Y-axis direction of the third driving means, the positioning plate 41 is
Housed battery B ₁ is being moved in the Y-axis direction until it is placed on the NACK-out 9 in the circular longitudinal hole 4. Subsequently, when the rod of the cylinder in the X-axis direction of the third driving means is advanced, only the positioning plate 41 moves in the X-axis direction, so that the unsealed battery B ₁ is centered on the upper end surface of the knuckout 9. Left to be located. Subsequently, the rods of the cylinder in the Y-axis direction and the cylinder in the X-axis direction are sequentially retracted, so that the U-shaped notch 42 of the positioning plate 41 faces the supply conveyor 45 again.

Next, when the engaging member of the second driving means 25 is rotated clockwise and the cylindrical rod 24 is lowered via the ram 27, as shown in FIG. It said contact in the central portion of the non-sealing battery B _1. The unsealed battery B ₁ is sandwiched between the holding rod 31 and the knuckout 9.

Next, when the engaging member of the second driving means 25 is further rotated clockwise to further lower the cylindrical rod 24, the second coil spring 39 is compressed as shown in FIG. Therefore, the presser mold 29 is lowered, and the lower cylindrical presser 35 is moved to the unsealed battery B.
Touches the periphery of ₁ . When the second coil spring 39 is compressed, the downward pressure of the presser rod 31 is absorbed, so that the unsealed battery B ₁ is excessively moved by the presser rod 31 with the lowering of the cylindrical rod 24. Pressing can be prevented.

Next, when the engaging member of the second driving means 25 is further rotated clockwise to further lower the cylindrical rod 24, the first coil spring 39 is compressed as shown in FIG. Therefore, the pushing die 30 is lowered. Wherein the lower end thereof push-fit 30 is lowered to press downwardly in contact with the non-sealing cell B _1, the NACK-out 9 and following this will lower the crimp die 6 of the cylindrical. The non sealing for battery B ₁ represents the descending remains along the inner surface of the circular recess 7 of the crimp die 6 is constantly horizontal state maintained, the open end is the circular container 51 to be sealed mouth of the battery B ₁ It is bent inward by contacting the lower inner surface of the recess 7. As a result, it is possible to manufacture the sealed battery B2 with _high precision as shown in FIG.

Next, by driving the cylinder 18b of the first driving means 10 again, the knuckout 9 is raised up to the same height as the upper surface of the block 2 as shown in FIG. Thereafter, the non-sealing cell B ₁ as shown in FIG. 1 described above the supply conveyor 4
5 to the U-shaped notch 4 of the positioning plate 41
2 The positioning plate 41 is the for discharging extruded sealing battery B ₂ which is placed on the NACK-out 9 in the V-shaped notch 43 by advancing the rod of the Y-axis direction of the cylinder of the third driving means It is stored in the conveyor 47. At this time, the unsealed battery B ₁ housed in the U-shaped notch 42 is placed on the knockout 9 in the circular vertical hole 4.

Therefore, the unsealed battery B ₁ is fixed at the center thereof by the pressing rod 31 immediately before the sealing, and the periphery thereof is covered by the cylindrical pressing part 35 below the pressing die 29. In this state, when the unsealed battery B ₁ is pressed downward by the press-in die 30, the unsealed battery B ₁ keeps a horizontal state constantly along the inner surface of the circular concave portion 7 of the crimp mold 6. To descend, the battery B ₁
The opening end of the container 51 to be closed abuts against the lower inner surface of the circular recess 7 and is bent inward. As a result, it is possible to manufacture the sealed battery B2 with _high accuracy.

In the above embodiment, the apparatus in which the battery supply means and the battery recovery means are shared by one transport means 40 has been described. However, the battery supply means and the battery recovery means may be different means. It is possible.

[0029]

As described above in detail, according to the present invention, it is possible to provide a sealing device capable of accurately sealing an unsealed flat battery.

[Brief description of the drawings]

FIG. 1 is a plan view showing a table, a battery supply means, and a battery discharge means of a flat-type battery sealing device of the present invention.

FIG. 2 is an enlarged perspective view of a main part showing the vicinity of a table of the apparatus of FIG. 1;

FIG. 3 is a cross-sectional view of the device of FIG. 1 taken along line AA.

FIG. 4 is an enlarged sectional view of a main part of the apparatus of FIG. 1;

FIG. 5 is a sectional view showing an unsealed air zinc battery.

FIG. 6 is a sectional view showing a step of sealing an unsealed zinc-air battery.

FIG. 7 is a sectional view showing a step of sealing an unsealed zinc-air battery.

FIG. 8 is a sectional view showing a step of sealing an unsealed zinc-air battery.

FIG. 9 is a sectional view showing a step of sealing an unsealed zinc-air battery.

FIG. 10 is a sectional view showing a zinc-air battery sealed by the apparatus of FIG. 1;

FIG. 11 is a cross-sectional view showing a step of sealing an unsealed battery with a conventional flat battery sealing device.

FIG. 12 is a cross-sectional view showing a step of sealing an unsealed battery by a conventional flat battery sealing device.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Table, 2 ... Block, 3 ... Top plate, 4 ... Circular vertical hole, 7 ... Circular recessed part, 9 ... Knuckout, 10 ... 1st drive means, 24 ... Push-in means, 25 ... 2nd drive means, 28
... Cylindrical cavity, 29 ... Cylinder holding type, 30
... Cylindrical push-in type, 31 ... Cylindrical holding rod, 36 ... First coil spring, 39 ... Second coil spring, 4
0: conveying means, 45: supply conveyor, 47: discharge conveyor.

Claims (1)

(57) [Claims] And 1. A table that have a circular longitudinal hole, while being inserted in said circular longitudinal hole of the table, raw
A circular recess with approximately the same dimensions as the flat battery
A cylindrical hole having a size smaller than that of the circular concave portion is formed.
The crimping die being formed, and the cylindrical vertical hole from the circular vertical hole to the cylindrical hole portion of the crimping die.
A knuckout that moves up and down in a space extending over the circular recess , a battery supply unit that supplies an unsealed battery to the top surface of the knuckout that is positioned at the same height as the upper surface of the table, and is disposed above the circular recess. And a vertically movable push-in means having a push die at a lower portion for pushing the unsealed battery into the circular recess while sandwiching the unsealed battery together with the knuckout.