CN108526378B

CN108526378B - Riveting tool and method for assembling connector hardware

Info

Publication number: CN108526378B
Application number: CN201810183860.1A
Authority: CN
Inventors: 陈雷; 胡炼
Original assignee: SHENZHEN KAIZHONG PRECISION TECHNOLOGY CO LTD
Current assignee: SHENZHEN KAIZHONG PRECISION TECHNOLOGY CO LTD
Priority date: 2018-03-06
Filing date: 2018-03-06
Publication date: 2024-03-12
Anticipated expiration: 2038-03-06
Also published as: CN108526378A

Abstract

The invention relates to the technical field of connector assembly, in particular to a riveting tool for assembling connector hardware, which comprises: the first tool (1) and the second tool (2) are distributed in parallel in the vertical direction, and a first punch (4) preassembled with the first component (6) and a second punch (5) preassembled with the second component (7) under the action of external force are respectively arranged on the first tool and the second tool, and are oppositely and correspondingly arranged; the power mechanism is connected with the second tool and used for driving the second tool to move towards or away from the first tool so that the first punch and the second punch are preassembled with the first component and the second component respectively and then apply acting force for riveting the first component and the second component. A riveting method for assembling the connector hardware is also provided. The invention provides a riveting tool and a riveting method for assembling connector hardware, which are simple in positioning operation in a riveting process and do not affect a product.

Description

Riveting tool and method for assembling connector hardware

Technical Field

The invention relates to the technical field of connector assembly, in particular to a riveting tool and a riveting method for assembling connector hardware.

Background

The connector comprises an injection molding piece and hardware, and the hardware is complex in structure and is generally required to be connected into a whole through multiple processing riveting. The traditional riveting mode adopts the riveting head to prop the riveting points one by one, and then uses the flat pressing block to flatten the riveting points so as to achieve the riveting effect. However, the riveting mode has poor consistency of riveting points after riveting, more waste products, time and labor waste in the riveting process, low working efficiency and high product cost.

To solve the above technical problem, chinese patent document CN204067828U discloses a riveting device of a D-type connector, comprising: the upper die is arranged at the stamping end of the stamping mechanism and is used for fixing the rivet head and the stripper plate; the riveting head is vertically fixed at the lower end of the upper die and is used for riveting the D-type connector; the discharging plate is fixed on the upper die through a spring, and is provided with a through hole for a rivet to pass through and is used for discharging the riveted D-shaped connector; the lower die is arranged at the end to be punched of the punching mechanism and is used for fixing the D-type connector; the positioning block is fixed on the lower die, and a riveting hole which corresponds to the riveting head up and down is arranged on the positioning block and is used for fixing the D-type connector. Firstly, riveting can be performed after the rivet head, a point to be riveted of the D-type connector and a rivet hole of the positioning block are positioned twice and completely correspond to each other, so that the requirement on operators in the riveting operation process is high; secondly, even if the rivet head, the point to be riveted of the D-shaped connector and the rivet hole of the positioning block are vertically corresponding, accurate riveting of the rivet head to the point to be riveted of the D-shaped connector is guaranteed, but in the riveting process, the rivet head penetrates through the point to be riveted of the D-shaped connector and is inserted into the rivet hole of the positioning block, so that at least one rivet hole is necessarily reserved on the D-shaped connector, and the riveting device is not applicable to connector hardware with high processing requirements.

Disclosure of Invention

Therefore, the technical problem to be solved by the invention is to overcome the defects that the positioning operation of the connector riveting device in the prior art is complex, a riveting hole is left on a product after the riveting is finished, and the actual requirement cannot be met, so that the riveting tool and the riveting method for assembling the connector hardware, which have simple positioning operation in the riveting process and do not influence the product, are provided.

In order to solve the above technical problems, the present invention provides a riveting tool for assembling connector hardware, comprising:

the first tool and the second tool are arranged in parallel in the vertical direction, a first punch head preassembled with the first component and a second punch head preassembled with the second component under the action of external force are respectively arranged on the first tool and the second tool, and the first punch head and the second punch head are oppositely and correspondingly arranged;

the power mechanism is connected with the second tool and used for driving the second tool to move towards or away from the first tool, so that the first punch and the second punch are pre-assembled with the first component and the second component respectively and then apply acting force for riveting the first component and the second component with each other.

The riveting tool for assembling the connector hardware comprises a first die holder and a first movable plate which are arranged in parallel in the vertical direction, wherein the first punch and a first elastic component for adjusting the relative position of the first punch and the first movable plate are arranged between the first die holder and the first movable plate; the second tool comprises a second die holder and a second movable plate which are arranged in parallel in the vertical direction, a second punch and a second elastic component used for adjusting the relative position of the second punch and the second movable plate are arranged between the second die holder and the second movable plate, and a first through hole and a second through hole which allow the first punch and the second punch to penetrate out are respectively formed in the first movable plate and the second movable plate.

The riveting tool for assembling the connector hardware comprises a first elastic component, a second elastic component and a second connecting column, wherein the first elastic component comprises a first connecting column movably connected between the first die holder and the first movable plate and a first spring sleeved on the first connecting column, and the second elastic component comprises a second connecting column movably connected between the second die holder and the second movable plate and a second spring sleeved on the second connecting column.

The riveting tool for assembling the connector hardware comprises a first die holder, a second die holder, a first connecting column, a second connecting column, a first die base, a second die base, a first connecting column and a second connecting column.

The riveting tool for assembling the connector hardware is characterized in that a plurality of first limit columns and second limit columns for limiting the maximum deformation of the first elastic component and the second elastic component are further arranged between the first die holder and the first movable plate and between the second die holder and the second movable plate.

The riveting tool for assembling the connector hardware is characterized in that the first movable plate is provided with an assembling space for the first component and the second component, and a stripping component for ejecting an assembled finished product upwards is arranged below the first movable plate.

The riveting tool for assembling the connector hardware comprises a supporting plate, an ejection piece arranged on the supporting plate and positioned below the assembling space, and a driving mechanism for driving the supporting plate to reciprocate.

The riveting tool for assembling the connector hardware is characterized in that a first riveting part and a second riveting part which are matched with the parts to be riveted of the first component and the second component are respectively formed on the end surfaces of the first punch and the second punch which are oppositely arranged.

The riveting tool for assembling the connector hardware further comprises a plurality of guide posts arranged on the first die holder and guide sleeves correspondingly arranged on the second die holder.

The invention also provides a riveting method for assembling the connector hardware, which comprises the following steps:

firstly, installing a first tool and a second tool in parallel in the vertical direction, and connecting a power mechanism with the second tool; then, placing the first component and the second component in an assembly space of the first tool; then driving the power mechanism to enable the second tool to move towards the first tool, preassembling the first punch and the second punch with the first component and the second component respectively, and applying acting force for riveting the first component and the second component to each other until the assembly is completed; and finally, driving a driving mechanism to eject the finished product from the first tool.

The technical scheme of the invention has the following advantages:

1. the first punch and the second punch which are used for pre-assembling the first component and the second component are correspondingly arranged on the first tool and the second tool respectively in opposite directions. Before assembling, the first punch and the second punch can be preassembled with the first component and the second component, namely the positions of the first punch and the second punch are relatively determined, and then riveting assembling is completed under the continuous driving of the power mechanism.

2. According to the riveting tool for assembling the connector hardware, the first punch and the second punch penetrate out of the first movable plate and the second movable plate under the action of the first elastic component and the second elastic component respectively, so that preassembly is completed with the first component and the second component, the relative positions of the first component and the second component are determined, force is only required to be applied according to a preset direction in the subsequent assembling process, the assembling accuracy is guaranteed, and meanwhile, the assembled product is convenient to take out.

3. According to the riveting tool for assembling the connector hardware, the material removing component below the first movable plate is arranged, so that after the first component and the second component are assembled, the first component and the second component can be ejected upwards and smoothly under the action of the material removing component, and the product is conveniently taken out.

4. According to the riveting tool for assembling the connector hardware, the first riveting part and the second riveting part which are matched with the parts to be riveted of the first component and the second component are respectively formed on the end surfaces of the first punch and the second punch which are arranged in opposite directions, so that the firmness of pre-assembly is ensured, and meanwhile, the damage to the structures of the first component and the second component is reduced.

5. According to the riveting method for assembling the connector hardware, the second tool moves towards the first tool under the drive of the power mechanism, the first punch head and the first component and the second punch head and the second component are preassembled, and then the first component and the second component are riveted and assembled, so that the assembly is accurate, positioning steps among the components are reduced, meanwhile, damage to the structure of a product is reduced to the greatest extent, and the actual production requirement is met.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are needed in the description of the embodiments or the prior art will be briefly described, and it is obvious that the drawings in the description below are some embodiments of the present invention, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of a riveting tool for assembling connector hardware provided by the present invention;

FIG. 2 is a cross-sectional view of a riveting tool for assembling connector hardware provided by the present invention;

FIG. 3 is an enlarged partial cross-sectional view of FIG. 2;

FIG. 4 is another angular cross-sectional view of FIG. 1;

FIG. 5 is an enlarged cross-sectional view of the second spring assembly of FIG. 4;

FIG. 6 is a cross-sectional view of the riveting tool in operation;

FIG. 7 is another cross-sectional view of the riveting tool in operation;

FIG. 8 is a schematic view of an assembly space on a first movable plate;

fig. 9 is a schematic diagram of a position on the second movable plate corresponding to the assembly space on the first movable plate.

Reference numerals illustrate:

1-a first tool; 2-a second tool; 3-guide posts; 4-a first punch; 5-a second punch; 6-a first component; 7-a second component; 8-stripping components; 9-an assembly space; 10-guiding sleeve; 11-a first die holder; 12-a first movable plate; 13-a first elastic component; 14-a first limit column; 15-a first fixing plate; 21-a second die holder; 22-a second movable plate; 23-a second elastic component; 24-a second limit column; 25-a second fixing plate; 31-a first guide post; 32-a second guide post; 81-supporting plates; 82-an ejector; 83-a drive mechanism; 91-positioning blocks; 92-locking screws; 231-second connection post.

Detailed Description

The following description of the embodiments of the present invention will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the invention are shown. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In addition, the technical features of the different embodiments of the present invention described below may be combined with each other as long as they do not collide with each other.

One embodiment of a riveting tool for assembling connector hardware, as shown in fig. 1-9, comprises a first tool 1 and a second tool 2 distributed in parallel in the vertical direction, and a stamping machine connected to the second tool 2. In this embodiment, the first tooling 1 is disposed below, the second tooling 2 is disposed above, a first punch 4 preassembled with the first component 6 and a second punch 5 preassembled with the second component 7 under the action of external force are respectively disposed on the first tooling 1 and the second tooling 2, and three groups of the first punch 4 and the second punch 5 are correspondingly disposed in opposite directions; the first component 6 and the second component 7 are respectively part of hardware, when the punching machine drives the second tool 2 to move towards the first tool 1, the first punch 4 and the second punch 5 are respectively assembled with the first component 6 and the second component 7 in advance, and then the second component 2 moves downwards continuously, and then the acting force is applied to the first component 6 and the second component 7 for riveting each other, so that the first component 6 and the second component 7 are assembled.

The first tooling 1 comprises a first die holder 11, a first movable plate 12 and a first fixed plate 15, wherein the first die holder 11 and the first movable plate 12 are arranged in parallel in the vertical direction, and the first fixed plate 15 is fixedly installed with the first die holder 11 through a plurality of bolts. The first punch 4 and the first elastic components 13 for adjusting the relative positions of the first punch 4 and the first movable plate 12 are arranged between the first fixed plate 15 and the first movable plate 12, six first elastic components 13 are respectively arranged between the first fixed plate 15 and the first movable plate 12 and are distributed in two rows, and three first elastic components are arranged in each row to ensure the stability of force application. The second tooling 2 comprises a second die holder 21, a second movable plate 22 and a second fixed plate 25, wherein the second die holder 21 and the second movable plate 22 are arranged in parallel in the vertical direction, and the second fixed plate 25 is arranged between the second die holder 21 and the second movable plate 22 and is fixedly installed with the second die holder 21 through a plurality of bolts. The second punch 5 and the second elastic components 23 for adjusting the relative positions of the second punch 5 and the second movable plate 22 are arranged between the second fixed plate 25 and the second movable plate 22, six second elastic components 23 are respectively arranged between the second fixed plate 25 and the second movable plate 22 and are distributed in two rows, and three second elastic components are arranged in each row. The first movable plate 12 and the second movable plate 22 are respectively formed with a first through hole and a second through hole which allow the first punch 4 and the second punch 5 to pass through. Before the first tooling 1 and the second tooling 2 are assembled by punching, the first punch 4 and the second punch 5 are respectively positioned between the first movable plate 12 and the first fixed plate 15 and between the second movable plate 22 and the second fixed plate 25, i.e. do not pass through the first through hole and the second through hole; when the first tooling 1 and the second tooling 2 are assembled by punching, under the action of the first elastic component 13 and the second elastic component 23, the first movable plate 12 and the second movable plate 22 move towards the directions of the first fixed plate 15 and the second fixed plate 25 respectively, and at this time, the first punch 4 and the second punch 5 pass through the corresponding first through hole and the second through hole respectively so as to apply force to the first component 6 and the second component 7.

The first elastic component 13 includes a first connecting column movably connected between the first die holder 11 and the first movable plate 12, and a first spring sleeved on the first connecting column, that is, one end of the first connecting column is installed on the first die holder 11 through the first fixing plate 15. Specifically, a mounting groove with a depth greater than 3mm of the first connecting column end cap is formed at the connection position of the first die holder 11 and the first connecting column, that is, before the first spring is compressed, the movement allowance of the first connecting column between the first movable plate 12 and the first die holder 11 is 3mm. As shown in fig. 5, the second elastic component 23 includes a second connecting post 231 movably connected between the second die holder 21 and the second movable plate 22, and a second spring sleeved on the second connecting post 231, that is, one end of the second connecting post 231 is installed on the second die holder 21 through the second fixing plate 25. Specifically, a mounting groove with a depth greater than 3mm of the height of the end cap of the second connecting post 231 is formed at the connection position of the second die holder 21 and the second connecting post 231, that is, the movement allowance of the second connecting post 231 between the second movable plate 22 and the second die holder 21 is 3mm before the second spring is compressed.

As shown in fig. 6, a plurality of first and second limiting posts 14 and 24 for limiting the maximum deformation amount of the first and second elastic members 13 and 23 are further provided between the first fixed plate 15 and the first movable plate 12 and between the second fixed plate 25 and the second movable plate 22. The first limiting posts 14 and the second limiting posts 24 are uniformly distributed, and before the first elastic component 13 and the second elastic component 23 are compressed, the distance between one ends of the first limiting posts 14 and the second limiting posts 24 and the first movable plate 12 and the second movable plate 22 is 3mm, namely the maximum deformation of the first elastic component 13 and the second elastic component 23.

As shown in fig. 3, 6, 8 and 9, the first movable plate 12 is formed with an assembling space 9 of the first component 6 and the second component 7, which is three in parallel in this embodiment, the assembling space 9 is surrounded by eight positioning blocks 91, a locking screw 92 for fixing is provided beside each assembling space 9, a groove is formed on the second movable plate 22 at a position corresponding to the assembling space 9 of the first movable plate 12, and before assembling, the first component 6 and the second component 7 are placed in the assembling space 9 according to a predetermined position. And a stripping assembly 8 for ejecting the assembled finished product upwards is arranged below the first movable plate 12. The stripping assembly 8 comprises a supporting plate 81, an ejection piece 82 arranged on the supporting plate 81 and located below the assembly space 9, and a driving mechanism 83 for driving the supporting plate 81 to reciprocate, wherein the ejection piece 82 is a lower stripping and ejection pin, a third through hole allowing the lower stripping and ejection pin to penetrate out is formed in a corresponding position of the first movable plate 12, the driving mechanism 83 is a hydraulic cylinder and is respectively arranged at two ends of the supporting plate 81 along the length direction so as to apply force simultaneously, and the lower stripping and ejection pin on the supporting plate 81 is driven to eject an assembled product embedded into the assembly space 9 upwards, so that the stripping is facilitated.

First riveting parts and second riveting parts which are matched with the parts to be riveted of the first component 6 and the second component 7 are respectively formed on the end surfaces of the first punch 4 and the second punch 5 which are arranged in opposite directions. The part to be riveted of the first component 6 is a bulge, the part to be riveted of the second component 7 is a groove matched with the bulge, and the opposite surface forms a bulge; correspondingly, the first riveting part is a protruding part formed at one end of the first punch 4, the second riveting part is a concave part formed at one end of the second punch 5, and the concave part is matched with the protrusion of the opposite surface of the second component 7, so that the first component is assembled preliminarily, then is riveted and assembled, and the positioning is more accurate.

The device also comprises a plurality of guide posts 3 arranged on the first die holder 11 and guide sleeves 10 correspondingly arranged on the second die holder 21. The guide post 3 and the guide sleeve 10 are respectively arranged at the edges of the first die holder 11 and the second die holder 21, the guide post 3 comprises a first guide post 31 arranged outside and a second guide post 32 positioned between two adjacent first guide posts 31, and the guide post 3 can penetrate into the guide sleeve 10, so that the guide positioning function is achieved, and the accuracy of the opposite movement of the first tool 1 and the second tool 2 is ensured.

A riveting method for assembling connector hardware, comprising the steps of:

first, the first tooling 1 and the second tooling 2 are installed in parallel in the vertical direction through a plurality of guide posts 3 installed at the edge, and the punching machine is connected with the second tooling 2. The first component 6 and the second component 7 are then both placed in the assembly space 9 of the first tool 1. The punching machine is then driven so that the second tooling 2 moves towards the first tooling 1, and at the same time, a first spring arranged between the first die holder 11 and the first movable plate 12, and a second spring arranged between the second die holder 21 and the second movable plate 22 are extruded and contracted, and the first punch 4 and the second punch 5 respectively penetrate through the first through hole on the first movable plate 12 and the second through hole on the second movable plate 22. As the second tooling 2 continues to move down, the first riveting portion of the first punch 4 and the second riveting portion of the second punch 5 are preassembled with the protrusion of the first component 6 and the protrusion of the second component 7, respectively, and then the second tooling 2 applies a force to rivet the first component 6 and the second component 7 with each other, that is, the protrusion of the first component 6 is assembled with the groove of the second component 7 in a riveting manner until the assembly is completed. The punching machine is driven again, the second tooling 2 moves upwards along the guide post 3, and the first movable plate 12 and the second movable plate 22 recover to the initial positions under the elastic action of the first spring and the second spring. And finally, driving a hydraulic cylinder to eject the finished product from the first tool 1 through a lower stripping and ejection pin so as to prepare for next assembly.

Alternatively, the first elastic component 13 and the second elastic component 23 may be compression springs, and the first connection post and the second connection post 231 are not provided, and only the first limit post 14 and the second limit post 24 are used to limit the maximum deformation amount of the compression springs.

Alternatively, the power mechanism is a pneumatic press or an oil press.

It is apparent that the above examples are given by way of illustration only and are not limiting of the embodiments. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. While still being apparent from variations or modifications that may be made by those skilled in the art are within the scope of the invention.

Claims

1. A riveting tool for assembling connector hardware, comprising:

the device comprises a first tool (1) and a second tool (2) which are distributed in parallel in the vertical direction, wherein a first punch (4) preassembled with a first component (6) and a second punch (5) preassembled with a second component (7) under the action of external force are respectively arranged on the first tool (1) and the second tool (2), and the first punch (4) and the second punch (5) are correspondingly arranged in opposite directions; the first tool (1) comprises a first die holder (11) and a first movable plate (12) which are arranged in parallel in the vertical direction, wherein a first punch (4) and a first elastic component (13) for adjusting the relative position of the first punch (4) and the first movable plate (12) are arranged between the first die holder (11) and the first movable plate (12); the second tool (2) comprises a second die holder (21) and a second movable plate (22) which are arranged in parallel in the vertical direction, the second punch (5) and a second elastic component (23) used for adjusting the relative positions of the second punch (5) and the second movable plate (22) are arranged between the second die holder (21) and the second movable plate (22), a first through hole and a second through hole which allow the first punch (4) and the second punch (5) to penetrate are formed in the first movable plate (12) and the second movable plate (22) respectively, and before the first tool (1) and the second tool (2) are assembled in a punching mode, the first punch (4) and the second punch (5) do not penetrate through the first through hole and the second through hole; the first movable plate (12) is provided with an assembly space (9) for the first component (6) and the second component (7), the assembly space (9) is surrounded by eight positioning blocks (91), a locking screw (92) for fixing is arranged beside each assembly space (9), the second movable plate (22) is provided with a groove at the position corresponding to the assembly space (9), and a stripping component (8) for ejecting an assembled finished product upwards is arranged below the first movable plate (12); a first riveting part and a second riveting part which are matched with the parts to be riveted of the first component (6) and the second component (7) are respectively formed on the end surfaces of the first punch (4) and the second punch (5) which are arranged in opposite directions, the parts to be riveted of the first component (6) are bulges, the parts to be riveted of the second component (7) are grooves matched with the bulges, and the opposite surfaces form bulges; the first riveting part is a protruding part formed at one end of the first punch (4), the second riveting part is a concave part formed at one end of the second punch (5), and the concave part is matched with a protrusion of the other surface opposite to the second component (7);

the power mechanism is connected with the second tool (2) and is used for driving the second tool (2) to move towards or away from the first tool (1), so that the first punch (4) and the second punch (5) are respectively preassembled with the first component (6) and the second component (7), and then the acting force is applied to the first component (6) and the second component (7) for mutual riveting.

2. The riveting tool for assembling connector hardware according to claim 1, wherein the first elastic component (13) comprises a first connecting column movably connected between the first die holder (11) and the first movable plate (12) and a first spring sleeved on the first connecting column, and the second elastic component (23) comprises a second connecting column (231) movably connected between the second die holder (21) and the second movable plate (22) and a second spring sleeved on the second connecting column (231).

3. The riveting tool for assembling connector hardware according to claim 2, wherein the first die holder (11) and the second die holder (21) are provided with a mounting groove which reserves a movement space for the first connecting post and the second connecting post (231) to move in a direction perpendicular to the first die holder (11) and the second die holder (21), respectively, at positions corresponding to the first connecting post and the second connecting post (231).

4. A riveting tool for assembling connector hardware according to any one of claims 1-3, characterized in that between the first die holder (11) and the first movable plate (12) and between the second die holder (21) and the second movable plate (22) there are also provided a number of first and second limit posts (14, 24) for limiting the maximum deformation of the first and second elastic assemblies (13, 23).

5. Riveting tool for assembling connector hardware according to claim 1, characterized in that the stripper assembly (8) comprises a support plate (81), an ejector (82) mounted on the support plate (81) and located below the assembly space (9) and a driving mechanism (83) driving the support plate (81) to reciprocate.

6. Riveting tool for assembling connector hardware according to any of claims 1-3 or 5, further comprising a number of guiding studs (3) provided on the first mould base (11) and guiding sleeves (10) provided on the second mould base (21) respectively.

7. A riveting method for assembling connector hardware based on the riveting tool for assembling connector hardware according to claim 5, characterized by comprising the steps of:

firstly, installing a first tool (1) and a second tool (2) in parallel in the vertical direction, and connecting a power mechanism with the second tool (2); then, placing both the first component (6) and the second component (7) in an assembly space (9) of the first tool (1); the power mechanism is driven, so that the second tool (2) moves towards the first tool (1), and after the first punch (4) and the second punch (5) are respectively preassembled with the first component (6) and the second component (7), acting force for riveting the first component (6) and the second component (7) is applied until the assembly is completed; and finally, driving a driving mechanism (83) to eject the finished product from the first tool (1).