CN106099129B - Lateral pressure type shaping equipment for zinc-manganese battery - Google Patents

Abstract

The invention discloses side-pressing type shaping equipment for a zinc-manganese battery, which comprises a rotating shaft, a cam, a punch rod assembly, a limiting mechanism and a die assembly, wherein the cam is fixed on the rotating shaft and rotates along with the rotating shaft, one end of the punch rod assembly is connected with the cam in a sliding mode and moves up and down along with the rotation of the cam, the limiting mechanism is sleeved outside the punch rod assembly and used for limiting the movement stroke of the punch rod assembly, and the die assembly is fixed at the other end of the punch rod assembly and used for extruding the opening end of a cylinder wall from the outer side to the axis direction of a zinc cylinder along with the up-and-down movement of the punch rod assembly. The limiting mechanism, the punch rod assembly and the shaping die are arranged to shape the open end of the cylinder wall of the battery, so that the open end of the cylinder wall is prevented from having defects in the battery assembling process, and the safety of the battery is improved.

Description

Lateral pressure type shaping equipment for zinc-manganese battery

Technical Field

The invention relates to the technical field of batteries, in particular to a lateral pressure type shaping device of a zinc-manganese battery.

Background

Currently, the structure of a zinc-manganese dry battery includes a zinc can as a negative active material, in which a mixture containing manganese dioxide chemically reacting therewith is contained, a carbon rod as a battery power lead-out body is fixed at the center, and a zinc can cover and a metal plate which is aesthetically and electrically connected to the bottom of the zinc can.

The preparation process includes punching metal zinc plate into circular cake, punching with a punch to form barrel structure with bottom, filling the barrel with mixture containing manganese dioxide and carbon rod, sealing and installing the zinc metal barrel. However, the zinc can has more or less defects as shown in fig. 1 during the manufacturing process of the battery. Namely, the opening end of the cylinder wall of the battery is collided in the battery assembling process, so that the opening end of the cylinder wall is uneven.

However, in the existing manufacturing process of the zinc-manganese battery, the defect is not adjusted in the later period, so that the produced battery flows into the market, and great potential safety hazard is caused.

Disclosure of Invention

In view of the above problems in the prior art, the present invention aims to provide a lateral pressure type shaping apparatus for a zinc-manganese battery, which extrudes an opening end of a cylindrical wall to shape the opening end of the cylindrical wall of the zinc-manganese battery.

The specific technical scheme is as follows:

the utility model provides a side pressure formula plastic equipment of zinc-manganese cell, includes the rotation axis, fixes follow on the rotation axis rotatory cam, one end and cam sliding connection and follow the rotatory and up-and-down motion's of cam jumper bar subassembly, cover establish outside the jumper bar subassembly, it is right the stop gear that the motion stroke of jumper bar subassembly was injectd, fix the other end of jumper bar subassembly is followed the up-and-down motion of jumper bar subassembly carries out extruded mould subassembly to section of thick bamboo wall open end from the outside to the axle center direction of zinc section of thick bamboo, the mould subassembly includes the shell body, the shell body includes a plurality of arcs, the one end of arcs links to each other, and the other end is incurve and mutually noninterfere, the mould subassembly still includes the holding in the shell body, with the shell body cooperatees, through sliding control the regulation pole that the shell body opened and shut.

Preferably, a dovetail groove is formed in the inner wall of each arc-shaped piece, and a sliding rail matched with the dovetail groove is arranged on the adjusting rod.

Preferably, the plunger assembly comprises a plunger having one end slidably connected to the cam and moving up and down along with the rotation of the cam, and the other end connected to the adjusting rod, and a guide cylinder sleeved outside the plunger and slidably connected to the limiting mechanism.

Preferably, the limiting mechanism is a sliding groove for limiting the axial displacement of the guide cylinder, and a first protrusion embedded in the sliding groove is arranged outside the guide cylinder.

Preferably, the punch rod is further sleeved with a rubber ring.

Preferably, the inner wall of the guide cylinder is further provided with a second protrusion matched with the rubber ring, the second protrusion drives the guide cylinder to move downwards when the plunger moves downwards and a third protrusion matched with the rubber ring, and the third protrusion drives the guide cylinder to move upwards when the plunger moves upwards.

Preferably, an outer groove is formed in the inner wall of the other end of the arc-shaped piece, and an annular recess matched with the outer groove is formed in one end, opposite to the bent end of the arc-shaped piece, of the adjusting rod.

Preferably, the axial width of the sliding groove is the sum of the displacement of the axial movement of the guide cylinder and the thickness of the first bulge; the moving distance of the adjusting rod relative to the outer shell is the sum of the axial distance between the second bulge and the third bulge and the thickness of the rubber ring.

Preferably, still include feeding mechanism, feeding mechanism includes: import chuck, work chuck and export chuck, the work chuck inlays to be established on the rotation axis, the import chuck is fixed on first driven shaft, be provided with on the first driven shaft with driving gear engaged with first driven gear, the export chuck is fixed on the second driven shaft, be provided with on the second driven shaft with driving gear engaged with second driven gear.

The positive effects of the technical scheme are as follows:

(1) The limiting mechanism, the punch rod assembly and the shaping die are arranged to shape the open end of the cylinder wall of the battery, so that the open end of the cylinder wall is prevented from having defects in the battery assembling process, and the safety of the battery is improved.

(2) Simultaneously the utility model discloses well jumper bar subassembly cooperatees with the mould subassembly, along with the up-and-down motion of jumper bar subassembly for the shell body can open and shut, thereby extrudees the section of thick bamboo wall open end by the axis direction of outside lateral perpendicular to zinc section of thick bamboo, and the plastic method of this side pressure formula has replaced the plastic mode of current punching press from top to bottom, prevents that punching press from top to bottom from producing to collide with section of thick bamboo wall open-ended tip, makes the plastic effect better.

(3) And set up the third arch for the guide cylinder simultaneous movement is driven when the mould subassembly resets, prevents that shell body and regulation pole from producing relative displacement, makes the shell body keep the closed state and breaks away from section of thick bamboo wall open end, makes the plastic effect better.

Drawings

FIG. 1 is a schematic diagram of a defect in a battery;

FIG. 2 is a schematic structural diagram of a lateral pressure type shaping device of a zinc-manganese battery of the invention;

FIG. 3 is a front view of an arc-shaped sheet in the lateral pressure type shaping equipment of the zinc-manganese battery of the invention;

FIG. 4 is a cross-sectional view of a side view of an arc-shaped piece in the lateral pressure type reforming equipment of the zinc-manganese dioxide battery;

FIG. 5 is a top view of an arc-shaped sheet in the lateral pressure type shaping equipment of the zinc-manganese dioxide battery;

FIG. 6 is a top view of an adjusting rod in the lateral pressure type shaping device of the zinc-manganese dioxide battery;

FIG. 7 is a front view of an adjusting rod in the lateral pressure type shaping equipment of the zinc-manganese battery of the invention;

FIG. 8 is a sectional view showing a developed state of a mold assembly in a lateral pressure type reforming apparatus for a Zn-Mn battery according to the present invention;

FIG. 9 is a plan view showing the expanded state of a mold assembly in the lateral pressure type reforming apparatus for a Zn-Mn battery according to the present invention;

FIG. 10 is a sectional view showing a closed state of a mold assembly in a lateral pressure type reforming apparatus for a Zn-Mn battery according to the present invention;

FIG. 11 is a schematic structural view of a guide cylinder in the lateral pressure type reforming apparatus for a Zn-Mn battery according to the present invention;

FIG. 12 is a schematic view showing the first working state of the punch assembly and the die assembly of the lateral pressing type shaping device of the zinc-manganese dioxide battery according to the present invention;

FIG. 13 is a schematic view showing the working states of the punch assembly and the die assembly of the lateral pressing type shaping device of the zinc-manganese dioxide battery of the present invention;

FIG. 14 is a third schematic view of the working states of the punch assembly and the die assembly of the lateral pressure type shaping device of the zinc-manganese dioxide battery of the invention;

FIG. 15 is a fourth schematic view showing the working states of the punch assembly and the die assembly of the lateral pressing type shaping device of the zinc-manganese dioxide battery of the present invention;

FIG. 16 is a fifth schematic view showing the working states of the punch assembly and the die assembly of the lateral pressing type shaping device of the zinc-manganese dioxide battery of the present invention;

FIG. 17 is a sixth schematic view of the working states of the punch assembly and the die assembly of the lateral pressure type reforming device of the zinc-manganese dioxide battery of the invention;

FIG. 18 is a plan view of a feeding mechanism in a lateral pressure type reforming apparatus for a Zn-Mn battery according to the present invention;

FIG. 19 is a front view of a retainer ring in the lateral pressing type reforming apparatus for a Zn-Mn battery according to the present invention.

In the drawings: 11. a rotating shaft; 12. a driving gear; 2. a cam; 3. a ram assembly; 31. a guide cylinder; 311. a first protrusion; 312. a third protrusion; 313. a second protrusion; 32. punching; 321. a rubber ring; 4. a mold assembly; 41. an outer housing; 411. an arc-shaped piece; 412. a dovetail groove; 413. an outer groove; 42. adjusting a rod; 421. a slide rail; 422. an annular recess; 43. a cavity; 5. a battery; 51. the opening end of the cylinder wall; 61. an inlet chuck; 611. an inlet retainer ring; 62. a work chuck; 621. a working retainer ring; 63. an outlet chuck; 631. an outlet retainer ring; 64. a roller; 7. a limiting mechanism; 71. a chute; (ii) a 81. A second driven gear; 82. a second driven shaft; 91. a first driven gear; 92. a first driven shaft.

Detailed Description

In order to make the technical means, the creation features, the achievement purposes and the effects of the invention easy to understand, the following embodiments are provided for specifically describing the invention with the attached drawings.

Fig. 2 is a schematic structural diagram of a lateral pressure type shaping device of a zinc-manganese battery according to the present invention, please refer to fig. 1. The shaping device of the zinc-manganese battery is used for shaping the battery 5 in the assembling process and comprises a feeding part, a shaping part and a discharging part, wherein the shaping part comprises a rotating shaft 11, a cam 2, a limiting mechanism 7, a punch component 3 and a die component 4. The rotary shaft 11 is connected with the driving assembly, the cam 2 is sleeved on the rotary shaft 11 and rotates along with the rotary shaft 11, one end of the punch rod assembly 3 is arranged in the cam 2 in a sliding mode, the limiting mechanism 7 is sleeved outside the punch rod assembly 3 and limits the stroke of the punch rod assembly 3, the punch rod assembly 3 moves up and down along with the rotation of the cam 2, the other end of the punch rod assembly 3 is provided with the die assembly 4, the battery 5 is located below the die assembly 4 and moves up and down along with the punch rod assembly 3, the die assembly 4 moves up and down along with the die assembly 4, opening and closing of a die cavity are controlled, and the die assembly 4 extrudes the opening end 51 of the cylinder wall to the axis direction of the zinc cylinder from the outer side.

In the following description, a specific embodiment is described, and it should be noted that the structures, processes, and materials described in the following embodiment are only used to illustrate the feasibility of the embodiment, and are not intended to limit the scope of the present invention.

FIG. 3 is a front view of an arc-shaped sheet in the lateral pressure type shaping equipment of the zinc-manganese dioxide battery; FIG. 4 is a cross-sectional view of a side view of an arc-shaped piece in the lateral pressure type reforming equipment of the zinc-manganese dioxide battery; FIG. 5 is a top view of an arc-shaped sheet in the lateral pressure type shaping equipment of the zinc-manganese battery of the invention; FIG. 6 is a top view of an adjusting rod in the lateral pressure type shaping device of the zinc-manganese dioxide battery; FIG. 7 is a front view of an adjusting rod in the lateral pressure type shaping equipment of the zinc-manganese battery of the invention; FIG. 8 is a sectional view showing a developed state of a mold assembly in a lateral pressure type reforming apparatus for a zinc-manganese battery according to the present invention; FIG. 9 is a plan view showing a developed state of a mold assembly in the lateral pressure type reforming apparatus for a zinc-manganese battery according to the present invention; fig. 10 is a cross-sectional view showing a closed state of a mold assembly in a lateral pressure type reforming apparatus for a zinc-manganese battery according to the present invention, with reference to fig. 3 to 10. The mold assembly 4 includes: the adjusting device comprises an outer shell 41 and an adjusting rod 42, wherein the outer shell 41 comprises a plurality of arc-shaped pieces 411, one ends of the arc-shaped pieces 411 are connected to form an annular ring, the other ends of the arc-shaped pieces 411 are outwards bent and do not interfere with each other, a dovetail groove 412 is formed in the inner wall of each arc-shaped piece 411, an outer groove 413 is further formed in the inner wall of the bent end of each arc-shaped piece 411, the adjusting rod 42 is embedded in the outer shell 41, a slide way matched with the dovetail groove 412 is formed in the adjusting rod 42, and an annular recess 422 matched with the outer groove 413 is formed in one end, opposite to the bent end of the adjusting rod 42 and the arc-shaped piece 411. The adjustment rod 42 moves toward the end where the outer groove 413 is formed, and the bent end of the outer housing 41 is closed by the dovetail groove 412, so that the outer housing 41 has a cylindrical structure. The outer groove 413 and the annular recess 422 are matched to form an annular cavity 43, and the adjusting rod 42 is of a cylindrical structure.

FIG. 11 is a schematic structural view of a guide cylinder in the lateral pressure type reforming apparatus for a Zn-Mn battery according to the present invention; fig. 12 is a schematic view showing the working states of the punch assembly and the die assembly of the lateral pressing type shaping device of the zinc-manganese dioxide battery of the present invention, which is shown in fig. 11 and 12. The punch assembly 3 comprises a punch 322 and a guide cylinder 31, one end of the punch 322 is connected with the cam 2 in a sliding mode and moves up and down along with the rotation of the cam 2, the other end of the punch 322 is connected with one end of the adjusting rod 42, and a rubber ring 321 is further sleeved on the punch 322. One end of the guide cylinder 31 is movably connected with the plunger 322, and the other end is detachably connected with the outer shell 41. The guide cylinder 31 is slidably arranged in the limiting mechanism 7, a first protrusion 311 is further arranged on the outer wall of the guide cylinder 31, and a sliding groove 71 matched with the first protrusion 311 is arranged in the limiting mechanism 7, so that the stroke of the axial movement of the guide cylinder 31 is limited. The inner wall of the guide cylinder 31 is provided with a second protrusion 313 and a third protrusion 312 which are matched with the rubber ring 321, and the second protrusion 313 and the third protrusion 312 are respectively arranged along the axial direction. When the rubber ring 321 is located above the second protrusion 313, the plunger 322 moves downwards to abut against the second protrusion 313, and drives the guide cylinder 31 to move downwards; the rubber ring 321 is located below the third protrusion 312, and the plunger 322 pushes against the second protrusion 313 when moving upward, so as to drive the guide cylinder 31 to move upward.

The axial width of the slide groove 71 is the sum of the displacement of the guide cylinder 31 in the axial direction and the thickness of the first protrusion 311. The moving distance of the adjusting rod 42 relative to the outer shell 41 is the sum of the axial distance between the second protrusion 313 and the third protrusion 312 and the thickness of the rubber ring 321.

FIG. 13 is a schematic view showing the working states of the punch assembly and the die assembly of the lateral pressing type shaping device of the zinc-manganese dioxide battery of the present invention; FIG. 14 is a third schematic view of the working states of the punch assembly and the die assembly of the lateral pressure type shaping device of the zinc-manganese dioxide battery of the invention; FIG. 15 is a fourth schematic view showing the working states of the punch assembly and the die assembly of the lateral pressing type shaping device of the zinc-manganese dioxide battery of the present invention; FIG. 16 is a fifth schematic view showing the working states of the punch assembly and the die assembly of the lateral pressing type shaping device of the zinc-manganese dioxide battery of the present invention; fig. 17 is a sixth schematic view of the working states of the punch assembly and the die assembly of the lateral pressing type reforming device for the zinc-manganese dioxide battery of the present invention, and is shown in fig. 13-17. The concrete working process of the shaping equipment is as follows: in the initial state, the rubber ring 321 on the plunger 322 is located above the second protrusion 313 and abuts against the second protrusion 313, and the first protrusion 311 on the guide cylinder 31 abuts against the upper edge of the sliding slot 71, as shown in fig. 12; the cam 2 rotates, so that the plunger 32 moves downwards, and the plunger 322 drives the guide cylinder 31 to move downwards through the rubber ring 321 until the first protrusion 311 abuts against the lower edge of the sliding slot 71, as shown in fig. 13. At this time, the stroke of the plunger 32 is not yet finished, the plunger continues to move downwards under the action of the cam 2, and due to the elasticity of the rubber ring 321, the plunger 322 continues to move downwards through the second protrusion 313, at this time, the adjusting rod 42 and the housing are relatively displaced, the adjusting rod 42 moves downwards relative to the outer housing 41, the outer housing 41 is gradually closed along with the movement of the slide rail 421 on the adjusting rod 42 in the dovetail groove 412, as shown in fig. 14, the plunger 32 continues to move downwards until the plunger passes through the third protrusion 312, at this time, the outer housing 41 is completely closed, the annular recess 422 on the adjusting rod 42 and the outer groove 413 on the outer housing 41 cooperate to form the cavity 43, and the open end 51 of the cylindrical wall is pressed during the closing of the outer housing 41 to reshape the cylindrical wall, as shown in fig. 15. When the plunger 32 moves upward, the rubber ring 321 abuts against the lower edge of the third protrusion 312 to drive the guide cylinder 31 to move upward, as shown in fig. 16, at this time, the adjusting rod 42 does not move relative to the outer shell 41, so the outer shell 41 is still closed until the first protrusion 311 abuts against the upper edge of the sliding slot 71, and the guide cylinder 31 stops moving; the plunger 32 continues to move upwards, the rubber ring 321 passes through the third protrusion 312, the outer shell 41 and the adjusting rod 42 are offset and displaced, the outer shell 41 starts to be closed, as shown in fig. 17, the outer shell 41 is completely opened along with the continuous upward movement of the plunger 32 until the rubber ring 321 passes through the second protrusion 313, and the state of fig. 12 is restored, namely, a shaping stroke is finished.

The rotation axis 11 with 2 keys-type connections of cam, pivot rotary drive 2 rotations of cam, the cover is equipped with driving gear 12 in the pivot, driving gear 12 follows the pivot is rotatory and synchronous revolution.

The cam 2 is provided with a sinusoidal running track, one end of the plunger 32 is clamped in the running track through a bearing, the plunger 32 is also clamped in the limit block 7 below the cam 2 to prevent the plunger 32 from rotating along with the cam 2, the plunger 32 periodically runs up and down along the running track along with the rotation motion of the cam 2, the shaping mold 4 is matched with the battery 5 when the plunger 32 runs to the lowest point of the running track, and the shaping mold 4 shapes the opening end 51 of the cylinder wall.

The shaping mechanism further comprises a feeding mechanism, the feeding mechanism is positioned below the die mechanism and used for conveying the battery 5, and the feeding mechanism comprises: import chuck 61, work chuck 62 and export chuck 63, work chuck 62 inlays and establishes on the rotation axis 11, follow rotation axis 11 is rotatory, import chuck 61 is fixed on first driven shaft 92, be provided with on the first driven shaft 92 with driving gear 12 engaged with first driven gear 91, driving gear 12 rotary drive first driven gear 91 is rotatory, thereby drives first driven shaft 92 is rotatory, finally drives import chuck 61 moves. The outlet chuck 63 is fixed on a second driven shaft 82, a second driven gear 81 engaged with the driving gear 12 is arranged on the second driven shaft 82, and the outlet chuck 63 is driven to rotate by the driving gear 12.

Work chuck 62 respectively with import chuck 61 and export chuck 63 cooperate, at rotatory in-process one of them screens of import chuck 61 with work chuck 62 correspond screens parallel from top to bottom, and export chuck 63 one of them screens with overlap from top to bottom corresponding screens on the work chuck 62, foretell chuck outside all still is provided with the retaining ring, the import chuck 61 outside is provided with curved import retaining ring 611, the outside of export chuck 63 also is equipped with curved export retaining ring 631, import retaining ring 611 with the opening direction of export retaining ring 631 is the same to opposite with the opening direction of work retaining ring 621, and import retaining ring 611, export retaining ring 631 and the chuck part that work retaining ring 621 is right all is provided with battery 5.

Fig. 12 is a front view of a retainer ring of the reforming apparatus for a zinc-manganese dioxide battery according to the present invention, please refer to fig. 12. Further inlet retaining ring 611, export retaining ring 631 and work retaining ring 621 face one side of chuck still is provided with roller 64, roller 64 with rotation axis 11 is parallel, prevents that battery 5 in the chuck rotation in-process screens produces the friction with the retaining ring, leads to battery 5's surface impaired.

The limiting mechanism 7, the punch component 3 and the shaping die are arranged in the battery pack 5 shaping device, so that the open end 51 of the cylinder wall of the battery 5 is shaped, the defect of the open end 51 of the cylinder wall in the battery 5 assembling process is prevented, and the safety of the battery 5 is improved. And simultaneously the utility model discloses well jumper bar subassembly 3 cooperatees with mould subassembly 4, along with the up-and-down motion of jumper bar subassembly 3 for shell body 41 can open and shut, thereby extrudees section of thick bamboo wall open end 51 by the axis direction of outside lateral perpendicular to zinc section of thick bamboo, and the plastic method of this side pressure formula has replaced the plastic mode of current punching press from top to bottom, prevents that the punching press from top to bottom from colliding with section of thick bamboo wall open-ended tip production, makes the plastic effect better. And, set up third arch 312 for drive guide cylinder 31 simultaneous movement when mould subassembly 4 resets, prevent to produce relative displacement between shell body 41 and regulation pole 42, make shell body 41 keep the closed state to break away from section of thick bamboo wall open end 51, make the plastic effect better.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention.

Claims (9)

1. The side pressure type shaping equipment for the zinc-manganese battery is characterized by comprising a rotating shaft (11), a cam (2) fixed on the rotating shaft (11) and rotating along with the rotating shaft (11), a punch assembly (3) with one end connected with the cam (2) in a sliding manner and moving up and down along with the rotation of the cam (2), and a die assembly (4) sleeved outside the punch assembly (3) and used for limiting the movement stroke of the punch assembly (3), and a die assembly (4) fixed at the other end of the punch assembly (3) and used for extruding a cylinder wall open end (51) along with the up-and-down movement of the punch assembly (3), wherein the die assembly (4) comprises a shell body (41), the shell body (41) comprises a plurality of arc-shaped sheets (411), one ends of the arc-shaped sheets (411) are connected, the other ends of the arc-shaped sheets bend outwards and do not interfere with each other, the die assembly (4) further comprises a die assembly accommodated in the shell body (41), is matched with the shell body (41), and is used for controlling the opening and closing of an adjusting rod (42) of the shell body (41) through sliding.

2. The lateral pressure type shaping equipment for the zinc-manganese dioxide battery according to claim 1, wherein a dovetail groove (412) is formed in the inner wall of each arc-shaped sheet (411), and a slide rail (421) matched with the dovetail groove (412) is arranged on the adjusting rod (42).

3. The lateral pressure type shaping device of the zinc-manganese battery according to claim 2, wherein the punch assembly (3) comprises a punch (32) with one end connected with the cam (2) in a sliding manner and moving up and down along with the rotation of the cam (2), the other end of the punch (32) is connected with an adjusting rod (42), and the punch assembly (3) further comprises a guide cylinder (31) sleeved outside the punch (32) and connected with the limiting mechanism (7) in a sliding manner.

4. The lateral pressure type shaping device of the zinc-manganese battery according to claim 3, wherein the limiting mechanism (7) is a sliding groove (71) for limiting the axial displacement of the guide cylinder (31), and a first protrusion (311) embedded in the sliding groove (71) is arranged outside the guide cylinder (31).

5. The lateral pressure type shaping device of the zinc-manganese dioxide battery as claimed in claim 4, wherein the punch (32) is further sleeved with a rubber ring (321).

6. The lateral pressure type shaping device of zinc-manganese dioxide battery as claimed in claim 5, wherein the inner wall of the guide cylinder (31) is further provided with a second protrusion (313) which is matched with the rubber ring (321) and drives the guide cylinder (31) to move downwards when the punch (32) moves downwards and a third protrusion (312) which is matched with the rubber ring (321) and drives the guide cylinder (31) to move upwards when the punch (32) moves upwards.

7. The lateral pressure type reforming apparatus for zinc-manganese dioxide batteries according to any one of claims 1 to 6, wherein the other end of the arc-shaped sheet (411) is provided with an outer groove (413) on the inner wall, and the end of the adjusting lever (42) opposite to the bent end of the arc-shaped sheet (411) is provided with an annular recess (422) which is matched with the outer groove (413).

8. The lateral pressure type reforming apparatus for a zinc-manganese dioxide battery according to claim 6, wherein the axial width of the chute (71) is the sum of the displacement of the guide cylinder (31) in the axial movement and the thickness of the first projection (311); the moving distance of the adjusting rod (42) relative to the outer shell (41) is the sum of the axial distance between the second bulge (313) and the third bulge (312) and the thickness of the rubber ring (321).

9. The lateral pressure type shaping device of the zinc-manganese dioxide battery as claimed in claim 1, further comprising a feeding mechanism, wherein the feeding mechanism comprises: import chuck (61), work chuck (62) and export chuck (63), work chuck (62) inlay and establish on rotation axis (11), import chuck (61) is fixed on first driven shaft (92), be provided with on first driven shaft (92) with driving gear (12) engaged with first driven gear (91), export chuck (63) are fixed on second driven shaft (82), be provided with on second driven shaft (82) with driving gear (12) engaged with second driven gear (81).