JPS63174735A - Molding equipment for beltlike lattice body - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Application Field) The present invention generally relates to a filter metal alloy (
Concerning the manufacture of strip grids made of lead, copper, titanium) or plastic.

More specifically, the present invention provides an apparatus for manufacturing such a band-shaped lattice, which includes a linear matrix and a punch that are tapered in the conveyance direction of continuous band-shaped objects and are movable relative to each other, and and a power drive means for moving the punch toward the matrix during the operating stroke in synchronization with the conveyance of the strip, the punch having a The present invention relates to a belt-like grid forming device comprising a wave-forming blade arranged in rows on both sides, which cooperate with a wave-forming blade provided in the belt.

(Prior Art) The applicant of the present application is currently using a band-like grid forming apparatus having the above-mentioned configuration at a factory. In this known forming device, each forming blade is shaped like a single tooth. Moreover, when sheet lead is cut and formed, the cut portions take the shape of forming blades, creating a grid with approximately diamond-shaped meshes. When cutting and forming in this way, the forming blade supported by the punch rises to the sum of the length of the diagonal connecting the acute vertices of the diamond-shaped mesh and the length of the knot between this mesh and the previously formed mesh. The strip is fed out of the supply roll by a corresponding distance.

It is clear that the production speed of this device corresponds to the product of the number of cuts made by the forming blade multiplied by the mesh pitch. However, the maximum number of cuts of the punch, in other words, the maximum number of operating strokes of the punch, is when the mesh pitch is 23 mm.
If it is about 500 times per minute, the production speed is limited to about 11.5 m per minute.

Since the production speed is limited in this way, an integrated production line is formed by connecting the lattice forming equipment to the next stage equipment, which has twice the production speed (approximately 25 m and 7 minutes) and applies the active material to the strip lattice. It is not possible.

Also, in order to improve the performance of the accumulator, grids are produced with meshes having small mesh dimensions, in particular with a pitch in the diagonal direction equal to approximately half the current pitch. In this case, the production speed of the previously known device is likely to be half that of the previously described device, while achieving the same number of cuts per minute.

(Objective of the Invention) The present invention has a high production speed, and moreover, even if the size of the mesh of the lattice formed from the strip is the same, the production speed can be approximately twice that of the conventional device, and the next stage of active material The pasting can be directly connected to the equipment, and furthermore, if a grid is formed with a mesh having a pitch that is less than half the length of the long diagonal of the current mesh, the production speed will not be lower than that of the conventional equipment, as mentioned above. The purpose of this invention is to provide a type of lattice forming apparatus.

(Structure of the Invention) The above-mentioned object of the present invention is to provide each cutting blade in a forming device of the above-mentioned type with at least two consecutive cutting teeth along the conveying direction of the strip, so that each cutting blade is provided with at least two consecutive cutting teeth in a single punching operation. This can be achieved by arranging that at least two incisions are made in the strip during the working stroke of.

The width of each cutting blade in the direction of conveyance of the strip is the same as that used in conventional devices, and in this case, given the same production speed, the device according to the invention has a smaller mesh size ( A lattice with half the pitch in the long diagonal direction is obtained. From another perspective, if the width of each cutting blade is twice the number of teeth of the cutting blade used in conventional equipment, the number of cuts per punch stroke and the size of each mesh will be the same. In this case, it is possible to achieve a production speed that is twice the production speed of conventional equipment.

According to the present invention, it is desirable to provide a pair of dies so that one dies serves as an extension of the other in the conveying direction of the strip.

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FIG. 1 shows a forming apparatus according to the invention, which is suitable for producing strip grids made of lead alloy and used in the production of lead accumulator plates.

The illustrated device consists of a housing I and a multistage expansion die device 2 placed on the top of the housing I. For example, a lead alloy strip N is fed from a supply reel B of a supply unit 3 rotating around a horizontal axis. It passes through the multi-stage expansion die device 2.

The multi-stage expansion die device 2 is provided inside a protective cover 4 having a heat exhaust duct 5 at the top for discharging heat generated during operation to the outside.

The cover 4 is also provided with a power drive unit 6 equipped with an electric motor (not shown), and also has an unloading lower where the strips formed in the strip lattice are carried out as they pass through the multi-stage expansion die device 2 as described below. is formed.

The strip N is unwound from a supply reel B, and is intermittently fed through the multistage expansion die device 2 at a predetermined speed by a drive pinch roller (not shown).

The grid strips discharged from the forming device are sent directly to a cutting machine to form the grid for the accumulator and then to a device for applying the active material to the grid. The cutting machine and the pasting device may be conventionally known ones, and are not illustrated because they are not the object of the present invention.

The configuration of the multi-stage expansion die apparatus 2 is briefly shown in FIGS. 2 and 3. As shown, the die apparatus 2 includes:
In the conveying direction of the strip (
It consists of a pair of dies 8 arranged along the arrow F). Both dies 8 have substantially the same construction, and are shown in detail in FIGS. 4 to 6. Briefly, each die 8 consists of a base 9 on which is mounted a support lO of matrix II, said matrix lO
l is constituted by a rod-shaped body tapered toward the conveyance direction F of the strip N, and on both sides thereof, forming blades 12 that cooperate with one forming blade 13 provided on the punch 14 are provided. There is. Punch 14 itself is Matrix 11
It is made of a rod-shaped body tapered along the conveyance direction F, and a plate 15 is placed on the rod-shaped body parallel to the base 9 and movable vertically thereto. This plate 15 is supported by a base by a group of pillars 16, and the pillars 16 are movable up and down via the base 9, and usually, a pin 18 that slides and guides the vertical movement of the board 15 is provided. It is biased to the raised position by a compression spring 17.

A long strip-shaped body removal rod is placed between the matrix 11 and the punch 14! 9 is interposed, which is a pair of end support members 2
It is supported by a base 9 via 0.

Two reaction plates 21 are attached to the upper surface of the plate 15. These reaction plates 21 are rotated by a horizontal shaft 23 which is orthogonal to the transport direction F of the strip N and is driven by a power drive 2 via a system not shown but known to those skilled in the art. It cooperates with cam 22.

As mentioned above, although the two dies 8 of the device 2 have the same shape, they are different in that the matrix 11 and the punch 14 have different widths because they are gradually tapered in the conveying direction F. There are only

According to the present invention, the forming blade 1 supported by the punch 14
3 is different from the forming blade used in conventional equipment currently in use. FIG. 7 shows one of the molding blades used in a conventionally known device.

In contrast, FIGS. 8 to 1θ show different embodiments of the forming blade 13 used in the apparatus of the present invention.

The conventionally known molded blade indicated by L in FIG.
It consists of a root R that is attached to the punch 14 and a single tooth as a notch.With the single tooth, when the punch 14 moves up and down while the device is in operation, it will cut into the band N. A notch corresponding to the shape of is formed, and the strip N
As it is stretched, it forms a network due to plastic deformation. When the notch is formed in this way, the single tooth is raised and the band N is intermittently fed (by a distance equal to the sum of the mesh sizes). A band-shaped lattice body as shown in the figure is formed.

The cutting blade 13 according to the present invention differs from conventionally known cutting blades in that it is attached to the punch 14 by having a root portion 13b and a plurality of cutting teeth, particularly two cutting teeth in the example shown in FIG. 13
a. Three cutting teeth 13a in the example shown in FIG. 9, and four cutting teeth 13a in the example shown in FIG. be.

Therefore, per one operating stroke of the punch 14 by the cam 22, the number of cuts corresponding to the number of teeth of the forming blade 13 of the present invention is formed in the strip N.

If the width of the forming blade 13, measured along the conveying direction F, is a multiple of the width of a conventional forming blade (equal to the number of teeth 13a), the production speed of the device according to the invention increases accordingly. For example, if the operating stroke of the punch 14 in the device according to the present invention and the conventionally known device is the same, then the width of the tooth 13 of the forming blade 13 (h<9 large - 3 thick - 4 large)
The production speed of the device according to the invention is twice, three times, and four times the production speed of the conventional device, respectively.

On the other hand, if the width of the forming blade 13 is made the same as that of a conventionally known forming blade, a strip-like lattice body with a small mesh size can be obtained at the same production speed. In other words, if the number of teeth of the forming blade 13 is 2, 3, or 4, the pitch of the mesh (the sum of the length of the long diagonal and the length of the nodules between adjacent meshes) is determined by the conventionally known number of teeth. Compared to those formed using a forming blade, the amount is reduced to 1/2.1/3.1/4, respectively.

The expansion of the strip when the number of teeth 13a of the forming blade 13 is two is shown in FIGS. 11 and 13.

Although the multi-stage expansion die device 2 is illustrated as consisting of two dies 8, if this can be configured as an integrated structure, in other words,
Needless to say, it may be constructed with one die corresponding to the length of two dies. However, if constructed with one die, a large amount of material will be used, so it is preferable to construct with two dies as in the example, and
If the device is constructed using a basic die, there is an advantage that the present invention can be easily applied to an existing device.

[Brief explanation of the drawing]

Fig. 1 is a perspective view of a forming apparatus for a lead alloy strip grid according to the present invention, Fig. 2 is a schematic perspective view of a multi-stage expansion die device in the same apparatus, and Fig. 3 is a line taken along the line ■-■ in Fig. 2. 4 is an enlarged perspective view of a portion of FIG. 2, FIG. 5 is a cross sectional view taken along line V-■ in FIG. 4, FIG. 6 is an exploded perspective view of FIG. 4, FIG. 7 is a perspective view of a conventionally known forming blade, FIGS. 8 to 10 are perspective views of different forming blades used in the present invention, and FIGS. 11 and 12 are as shown in FIG. FIG. 2 is an enlarged perspective view and a front view of a main part of the apparatus showing a state in which a band-shaped lattice body is formed using the illustrated cutting blade. l...Housing, 2...Multi-stage expansion die device, 13
... Cutting blade, 13a... Teeth, 14... Punch.

Claims (2)

[Claims] (1) Equipped with a linear matrix and a punch that are tapered in the conveying direction of a continuous strip and are movable relative to each other,
The punch comprises a multi-stage expansion die in which the strip is conveyed intermittently, and a power drive means for moving the punch toward the matrix during the operating stroke in synchronization with the conveyance of the strip. A device for forming a strip-like grid, in which wave-forming blades are provided in rows on both sides, cooperating with wave-forming blades provided on both sides of the matrix, the forming blades comprising at least two successive cutting teeth; A forming device characterized in that the cutting teeth of the punches are adjacent to each other along the conveying direction of the strip, and at least two cuts are formed in one operating stroke of the punch. (2) A device according to claim (1), in which a pair of dies are arranged along the conveyance direction of the strip so that one forms an extension of the other.