CN215790402U - Punching die - Google Patents

Abstract

The utility model relates to a punching die, which is characterized by comprising the following components: go up mould subassembly and lower mould subassembly. Go up the mould subassembly and include: an upper die plate and a knife plate fixed to the upper die plate and including a knife edge formed thereon. The lower die assembly includes: a lower template; the cutter holder is fixed to the lower template and is suitable for supporting a piece to be punched; and the bracket is positioned between the lower template and the tool apron and is suitable for supporting the tool apron, and the bracket comprises at least one support selected from a modular support group.

Description

Punching die

Technical Field

The utility model relates to a punching die, in particular to a punching die for punching paper-plastic products.

Background

It is becoming more common in modern society to package products using, for example, paper-plastic products. For example, a common example is a paper tray for carrying products in an electronic product package such as a cell phone, personal tablet, or the like. Taking such a tray as an example, the opening edge thereof is generally flat and is obtained by performing a separate processing using a die on a blank including a plurality of trays, which is formed by pressing.

In the prior art, the blank is generally machined using a steel wire cutting die. On one hand, the template and the machine table are usually fastened by a screw pressing plate and are easy to loosen under the condition of pressure, so that frequent displacement of the mold is generated, the product has large deviation from the expected quality, and the deviation is poor in a typical condition. In addition, this results in time-consuming re-mold calibration operations that are required only a few hours apart, which leads to problems of low throughput, wasted labor and production materials.

On the other hand, the base of the lower die of the steel wire cutting die and the cutting board of the upper die are made of wood boards or bakelite which has low density, low strength and easy deformation under stress, so that the processing precision and the positioning precision are poor. In another aspect, the cutting edge of the knife die blade is formed by manual bending, and the cutting edge of the knife can only form a plane punching surface, but can not be processed into a cambered surface or a bevel surface to punch products with corresponding shapes. For products with special-shaped surfaces, the prior art has the problem that the mold opening is carried out separately for each product, so that the cost is high.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a punching die which overcomes the defects. The punching die according to the present invention is characterized by comprising:

go up mould subassembly, include: mounting a template; and a knife plate fixed to the upper mold plate and including a knife edge formed thereon; and

a lower die assembly comprising: a lower template; the cutter holder is fixed to the lower template and is suitable for supporting a piece to be punched; and the bracket is positioned between the lower template and the tool apron and is suitable for supporting the tool apron, and the bracket comprises at least one support selected from a modular support group.

In the punching die of the utility model, due to the use of the support in modular design, only the cutting plate and the tool apron can be designed for the piece to be punched, and the cutting plate and the tool apron can be very light and easy to replace. The lower template can be fixed on a machine table as a common part suitable for various pieces to be punched, and the lower template does not need to be replaced no matter what types of pieces to be punched are punched. In addition, due to the adoption of the support with the modular design, the support with the shape required by splicing one or more geometrical support members can be selected from the existing support member group for different cutter holders without mold reopening. That is, in the punching mold according to the present invention, both the upper and lower pattern plates and the support member group can be used as common parts, and only the cutting die (the cutting plate and the holder) needs to be designed, whereby the overall cost of the mold is reduced to only a fraction of the original cost.

Preferably, the set of modular supports comprises at least a support having a first geometry and a support having a second geometry different from the first geometry.

Preferably, the bracket comprises a plurality of supports which are spliced together to form the bracket.

Preferably, the supporting member is at least one of a rectangular block, a square block, a triangular block, and an L-shaped block.

Thereby, the desired stent can be quickly assembled by selecting supports from the set of supports. And the multiple geometries provide a very versatile and flexible choice for the stent configuration with a limited number of struts, i.e., the need to make an excessive number of struts to meet the multiple configuration stent requirements is eliminated.

Preferably, the support is of aluminium alloy. Such supports have the advantages of low cost, high compression capacity, and long service life.

Preferably, the seat is stainless steel. Such a tool holder has the advantages of a smooth surface, good mechanical strength, and corrosion resistance. Therefore, the error increase caused by deformation when the pressure is applied is avoided, and the service life is prolonged.

Preferably, the cutting edge is integrally formed with the cutting plate.

Preferably, the cutting edge is a profiled cutting edge formed by CNC machining.

Preferably, the blade and the cutting edge are integrally formed from SKD 11.

The cutting edge has high precision, and the cutting plate and the cutting edge can be designed into any required shape for a special-shaped piece along the direction of the axis Z, such as an arc surface, an inclined surface and the like, thereby providing a comprehensive choice for punching various pieces to be punched with special-shaped surfaces.

Preferably, the lower template comprises a plurality of lower template positioning holes, each lower template positioning hole comprises a threaded section and a positioning section, the tool apron comprises a tool apron positioning hole, and the supporting piece comprises a supporting piece positioning hole.

Preferably, the lower die assembly further comprises an inner hexagonal socket head shoulder screw passing through the tool apron positioning hole, the support member positioning hole and the lower die plate positioning hole and threadedly coupled to the threaded section.

Therefore, the multiple parts of the lower die assembly 20 are simultaneously positioned and fixed through the simple operation of the pin positioning, so that the operation is simple, the installation speed is high, the labor is saved, the relative displacement is not easy to generate among the multiple parts, and the punching precision is ensured.

Preferably, the plurality of lower template locating holes form an array of lower template locating holes.

Preferably, the upper die plate includes a plurality of upper die plate positioning holes forming an upper die positioning hole array.

The array of locating holes of the upper and lower die plates according to the present invention can be adapted to mount thereon cutting boards and holders having different shapes.

The punching die according to the utility model can be used in particular for punching paper-plastic articles.

Drawings

FIG. 1 is a schematic exploded perspective view of a shear punching die according to an embodiment of the present invention;

FIGS. 2A through 2C are schematic perspective views of a lower die assembly of the shear die shown in FIG. 1, illustrating how the lower die assembly is assembled;

FIG. 3 is a partial perspective cross-sectional view of the assembled lower die assembly taken in a section through the aligned locating holes of the lower die plate, support and tool holder;

fig. 4A is a schematic perspective view of an upper die assembly of a shear punching die according to the present invention;

FIG. 4B is an enlarged, fragmentary, schematic cross-sectional view of the knife plate of the upper die assembly according to the present invention;

FIG. 5A is a cross-sectional side view of the upper and lower die assemblies of the shear punching die after closure thereof in accordance with the present invention;

FIG. 5B is an enlarged view of the portion encircled by frame A in FIG. 5A;

fig. 6 is an example of a profile member obtained by blanking using a blanking die according to the present invention;

fig. 7A is a schematic perspective view of an upper die assembly used to die cut the profile shown in fig. 6;

fig. 7B is an enlarged view of one of the cells of the knife plate shown in fig. 7A, in order to more clearly show its shape.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the drawings of the embodiments of the present invention.

Unless defined otherwise, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this invention belongs. The word "comprising" or "comprises", and the like, means that the element or item preceding the word covers the element or item listed after the word and its equivalents, but does not exclude other elements or items.

To better describe the solution according to the utility model, an orthogonal coordinate system XYZ is established, in which the XY plane formed by the axes X and Y is the plane on which the blanking die 1 lies in the normal operating state, and the axis Z is perpendicular to the XY plane and points in its forward direction towards the upper die assembly. The terms "upper" and "lower" directions are defined with respect to axis Z.

Fig. 1 shows a schematic perspective view of a blanking die 1 according to an embodiment of the utility model.

As shown in fig. 1, the blanking die 1 includes an upper die assembly 10 and a lower die assembly 20. In particular, the punching die is used for punching paper-plastic products. In normal operating conditions, lower die assembly 20 is arranged in a plane defined by axes X and Y, such as a bench plane.

The lower mold assembly 20 includes a lower mold plate 210, and the lower mold plate 210 may be a rectangular plate having a certain thickness, and in a normal operation state, the lower mold plate 210 is fixed on the workbench.

The lower die assembly 20 further includes a tool holder 220, the tool holder 220 being fixed to the lower die plate 210 and adapted to support the member to be die-cut 90. The member to be die-cut 90 may be a paper-plastic product that has not been cut, such as a paper-plastic tray after press forming, or the like. In the stamping die, these paper-plastic products are cut into the desired finished products. In the example shown in fig. 1, the piece to be blanked 90 will be blanked out into four generally rectangular finished products, as desired.

Lower die assembly 20 also includes a bracket 230. The bracket 230 is located between the lower template 210 and the blade holder 220 and is adapted to support the blade holder 220. The blade holder 220 is fixed to the lower die plate 210 via the bracket 230, that is, the blade holder 220 is indirectly fixed to the lower die plate 210.

The lower die assembly 20 of the blanking die 1 according to the present invention is described in detail below with reference to an example of fig. 2A to 2C.

Fig. 2A is a schematic perspective view of the lower template 210 of the lower die assembly 20, showing the side of the lower template 210 facing the upper template 110. The lower platen 210 is, for example, a generally rectangular shaped plate. At each of the four corners of the lower die plate 210 are guide posts 218 extending in the axial direction Z for guiding and positioning the upper die plate 110 during the die cutting process, as will be described in detail below.

The lower plate 210 may include a plurality of lower plate locating holes 211. In the preferred embodiment shown in fig. 2A-2C, these lower template registration holes 211 form an array of lower template registration holes.

The support 230 may include at least one support 231, as shown in fig. 2B, the support 231 is fixed on the lower mold plate 210, and the tool holder 220 is fixed on the support 230 formed by the support 231 (fig. 2C). In the solution according to the present invention, the support 231 constituting the bracket 230 may be selected from a modular support group. Herein, the modular support member group refers to a group consisting of a plurality of support members in which the support members are independent of each other to form an individual module, and each support member is formed in a predetermined shape. In use, the required support or supports may be selected from the set of modular supports to form the cradle according to the shape of the tool holder.

In the punching die of the utility model, due to the use of the support in modular design, only the cutting plate and the tool apron can be designed for the piece to be punched, and the cutting plate and the tool apron can be very light and easy to replace. The lower template can be used as a common part suitable for various tool holders and fixed on a machine table, and the lower template does not need to be replaced no matter what kind of to-be-punched parts are punched.

The modular support stack includes at least a support having a first geometry and a support having a second geometry different from the first geometry. Further, to support the tool holder, the bracket 230 may include a plurality of supports 231, the plurality of supports 231 being spliced together to form the bracket 230. For example, in the example shown in fig. 2C, the tool post 220 has a rectangular outer frame and a cross frame in the middle to divide the entire tool post 220 into 4 identical regions. At this time, as shown in fig. 2B, a plurality of rectangular elongated support members 231 may be selected, and these support members 231 may have substantially the same height (in the axis Z direction) but may have different lengths (extending in the XY plane). The bracket 230 formed by the selected supports 231 being spliced together includes an area adapted to support the blade seat 220.

It is understood that the support 231 may have a shape different from that shown in the drawings. For example, the supporting member 231 may be at least one of a rectangular block, a square block, a triangular block, and an L-shaped block, which may be combined as needed to quickly form a tool seat suitable for different shape requirements. Due to the adoption of the support with the modular design, supports with different geometries and required shapes at the splicing positions of the supports can be selected from the existing support groups for different cutter holders without mold reopening. That is, in the punching mold according to the present invention, both the upper and lower die plates and the support member group can be used as common parts, and only the cutting die (the cutting plate and the holder) needs to be designed, whereby the overall cost of the mold is reduced to only a fraction of the original cost.

The positioning and fixing manner of the lower mold plate 210, the support 231 and the tool post 220 will be described with reference to fig. 3. In the case of pressure, since a plurality of parts stacked in the pressure direction are liable to be relatively misaligned, thereby causing problems of poor product accuracy and high fraction defective, it is also a key to solve the technical problem. FIG. 3 is a partial perspective cross-sectional view of the lower die plate 210, the bracket 230, and the tool holder 220 of the lower die assembly 20 shown in FIG. 2C, assembled and secured in cross-section through aligned locating holes of the lower die plate 210, the support 231, and the tool holder 220. Specifically, as shown in fig. 3, the lower template positioning hole 211 includes a threaded section 211A and a positioning section 211B, and the threaded section 211A is located below the positioning section 211B and adjacent to the positioning section 211B. Accordingly, the tool holder 220 includes the holder positioning hole 221, and the support 231 includes the support positioning hole 2311. The lower template locating hole, the supporting piece locating hole and the tool apron locating hole extend along the direction of the axis Z. The tool holder 220, the supports of the bracket 230, and the lower die plate 210 may be positioned and fixed to each other by means of socket head cap shoulder screws 280. Specifically, the socket head cap shoulder screw 280 passes through the aligned tool holder location hole 221, the corresponding support member location hole 2311, and the corresponding location section 211B of the lower template location hole 211, and is threaded into the threaded section 211A of the lower template location hole 211. Therefore, the multiple parts of the lower die assembly 20 are simultaneously positioned and fixed through the simple operation of the pin positioning, so that the operation is simple, the installation speed is high, the labor is saved, the relative displacement is not easy to generate among the multiple parts, and the punching precision is ensured.

Preferably, the support 231 is an aluminum alloy, which has the advantages of low cost, high pressure capacity, and long service life.

Preferably, the tool holder 220 is stainless steel, such as a stainless steel plate. It has the advantages of smooth surface, good mechanical strength and corrosion resistance. Therefore, the error increase caused by deformation when the pressure is applied is avoided, and the service life is prolonged.

Next, an upper die assembly of the blanking die 1 according to the present invention will be described with reference to fig. 4A and 4B.

Fig. 4A shows a side of upper die assembly 10 facing lower die assembly 20. As shown in fig. 4A, the upper die assembly 10 may include an upper die plate 110 and a knife plate 120 fixed to the upper die plate 110. The upper die plate 110 may be a rectangular plate having a certain thickness, and may include guide post guides 118 at four corners thereof corresponding to the guide posts 218 of the lower die plate 210, so as to be sleeved on the guide posts during the punching process, thereby achieving precise guiding between the upper and lower die plates, avoiding relative translation between the upper and lower die assemblies, and ensuring the punching accuracy.

The upper die plate 110 may include a plurality of upper die plate positioning holes 111, and the upper die plate positioning holes 111 form an upper die plate positioning hole array, similar to the lower die plate positioning holes, to accommodate the cutter plate 120 having a different shape.

The knife plate 120 includes a knife edge 121 (fig. 4B) formed thereon. In a preferred embodiment, the knife plate 120 and the knife edge 121 are integrally formed, as shown in the enlarged view of FIG. 4B. More preferably, the cutting board and the cutting edge are integrally machined and formed by SKD11 cold-work die steel through a numerical control machine (CNC). The cutting board and the cutting edge are quenched by heat treatment and then are subjected to CNC finish machining again, so that assembly errors are avoided. In particular, the cutting plate 120 and the cutting edge 121 are shaped cutting plates and shaped cutting edges machined by CNC machines, which is particularly advantageous in case the piece to be blanked is shaped, since the cutting plate and the cutting edge can be designed in the direction of the axis Z for any desired shape of the shaped piece, such as arcs, bevels, etc. which are not possible in the prior art, as will be described in detail below with reference to fig. 6, 7A and 7B.

The blanking die according to the present invention will be described with reference to fig. 5A and 5B. Fig. 5A shows a cross-sectional side view of the upper die assembly 10 and the lower die assembly 20 of the blanking die 1 after closing, and fig. 5B shows an enlarged view of a portion encircled by frame a in fig. 5A. The upper platen 110 is secured to an upper plate (not shown) of the molding machine, such as by bolts or pins, and the upper platen 110 need not be removed and replaced when changing the tool holder and blade for different products. The upper die plate 110 is fixed (e.g., by bolts or pins) to the knife plate 120. The lower platen 210 is secured to the machine bed (not shown) of the molding machine, such as by bolts or pins, and the lower platen 210 need not be removed and replaced when changing the blade holder and blade plate for different products. When the upper mold assembly 10 and the lower mold assembly 20 are closed, the upper mold plate 110 and the lower mold plate 120 are guided and positioned by the corresponding guide sleeves and guide pillars, and the relative displacement between the upper mold plate and the lower mold plate is avoided. Therefore, frequent re-mold-filling calibration operation is not needed, labor is saved, the productivity is improved, and the service life of the universal mold is prolonged.

The holder 230 is built up by modular supports 231 and can thus be adapted to any form of cutting die. The lower plate 210, due to the array of positioning holes, is also adapted to mount thereon a bracket 230 of a different shape built up from modular supports 231. And the lower template, the bracket and the tool apron are provided with positioning holes which can be aligned with each other, so that the same inner hexagonal cylinder head shaft shoulder screw can pass through, and the error of mutual positioning among multiple components is eliminated. The upper die plate 110 is similarly positioned to the knife plate 120.

The blade 121 punches the piece to be punched 90 with extremely high precision, thanks to the elimination of the displacements of the upper and lower die plates with respect to the respective stands and to the elimination of the errors of positioning of the parts in the upper and lower die assemblies, thus obtaining a satisfactory product of high quality.

Fig. 6 shows an example of a profile member obtained by blanking using a blanking die according to the present invention. Fig. 7A shows an upper die assembly used for die cutting the profile piece shown in fig. 6, and fig. 7B is an enlarged view of one of the units of the cutting plate shown in fig. 7A, in order to show its shape more clearly.

As shown in fig. 6, the profile member 80 has a substantially rectangular shape in a plan view, but the two long sides 81 and the two short sides 82 thereof do not lie in the same plane, that is, the opening face thereof is shaped, wherein the heights of the two long sides 81 in the direction of the axis Z vary. As the shapes of packaged products in modern society are more diversified, various and varied requirements are also generated for irregular packaging. Fig. 6 shows only one example of this for illustration, and it should be understood that other forms of shaped pieces are also within the scope of the present invention. As mentioned above, in the existing blanking die, it is difficult if a satisfactory profile is desired. On the one hand, the long blade is manually bent into the cutter die blade, only a plane cutting edge can be formed, and due to the fact that external force is applied to the blade during bending and stress exists in the blade, the straightness of the formed cutter die blade is low, and the precision of the cutter die blade cannot be guaranteed. On the other hand, because the knife board is made of a material with a loose and low-strength gap, such as a wood board or bakelite, when the blade is embedded into the knife slot in the knife board, the knife slot cannot correct the blade with errors, and the deformation is intensified when the blade is subjected to high pressure, so that the product is deformed undesirably. In the blanking die according to the present invention, however, the profiled blade can be applied at a lower cost and with a higher accuracy. An example of a profiled cutting board 120 for punching out the profiled piece shown in fig. 6 is shown in fig. 7A. As shown, the cutting plate 120 comprises four units (fig. 7B), each unit being bent towards the lower die plate at both ends in the direction of the axis X, whereby the cutting edges 121 engage the profiled open face of the piece to be blanked (not shown). The seat (not shown) has a form matching the cutting plate 120 and the piece to be blanked fits into the seat, so that the piece to be blanked does not deform so much during blanking, thereby obtaining a high quality and high stability product. Moreover, the punching die can replace a hardware die to a great extent, but the manufacturing period is only about half of that of the hardware die.

It is to be understood that the structures described above and shown in the attached drawings are merely examples of the present invention, which can be replaced by other structures exhibiting the same or similar function for obtaining the desired end result. Furthermore, it should be understood that the embodiments described above and shown in the drawings are to be regarded as only constituting non-limiting examples of the present invention and that it can be modified in a number of ways within the scope of the patent claims.

Claims (13)

1. A blanking die (1), characterized in that it comprises:

an upper die assembly (10) comprising:

an upper template (110) is arranged on the upper template,

a knife plate (120) fixed to the upper die plate (110) and including a knife edge (121) formed thereon; and

a lower die assembly (20) comprising:

a lower template (210),

a seat (220) fixed to the lower die plate (210) and adapted to support a piece to be blanked, an

A bracket (230) located between the lower platen (210) and the blade holder (220) and adapted to support the blade holder (220), the bracket comprising at least one support (231) selected from a modular support set.

2. The shear die of claim 1, wherein the set of modular supports includes at least a support having a first geometry and a support having a second geometry different from the first geometry.

3. A cutting die according to claim 2, characterized in that the carrier comprises a plurality of supports (231) which are spliced together to form the carrier (230).

4. The blanking die of any of claims 1 to 3, wherein the support member (231) is at least one of a rectangular block, a square block, a triangular block, and an L-shaped block.

5. A cutting die according to any one of claims 1 to 3, characterised in that the support (231) is of aluminium alloy.

6. A blanking die according to any one of claims 1 to 3, wherein the seat (220) is stainless steel.

7. The trimming die of any one of claims 1 to 3, wherein the blade (121) is integrally formed with the blade (120).

8. The blanking die of claim 7, wherein the cutting edge (121) is a profiled cutting edge formed by a numerically controlled machine tool.

9. The piercing die of claim 8, wherein the blade and the cutting edge are integrally formed from SKD 11.

10. The trimming die of any one of claims 1 to 3, wherein the lower die plate (210) comprises a plurality of lower die plate positioning holes (211), each lower die plate positioning hole (211) comprising a threaded segment (211A) and a positioning segment (211B), the blade holder (220) comprises a blade holder positioning hole (221), and the support member (231) comprises a support member positioning hole (2311).

11. The trimming die of claim 10, wherein the lower die assembly (20) further includes an inner hexagonal socket head shoulder screw (280) passing through the holder positioning hole (221), the holder positioning hole (2311) and the lower die plate positioning hole (211) and threadedly coupled to the threaded section (211A).

12. The shear die of claim 11, wherein the plurality of lower template locator holes (211) form an array of lower template locator holes.

13. The shear die of any of claims 1 to 3, wherein the upper die plate (110) includes a plurality of upper die plate locating holes (111) that form an array of upper die locating holes.

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