CN216911823U - Iron shell riveting mechanism - Google Patents

Abstract

The utility model relates to the technical field of automation, in particular to an iron shell riveting mechanism which comprises a first riveting component and a second riveting component, wherein the first riveting component comprises a first riveting driving piece, a first riveting driving piece and a first riveting piece, the first riveting driving piece is used for driving the first riveting driving piece to rotate, and the first riveting driving piece is used for driving the first riveting piece to be close to or far away from the second riveting component after being driven by the first riveting driving piece; the second riveting component is matched with the first riveting component to be used for riveting the iron shell. According to the riveting device, the first riveting driving piece is driven to move back and forth through the rotation of the first riveting driving piece, so that the effect of riveting the iron shell is achieved by matching with the second riveting component, and the required space can be obtained.

Description

Iron shell riveting mechanism

Technical Field

The utility model relates to the technical field of automation, in particular to an iron shell riveting mechanism.

Background

When assembling an electric connector, such as a connecting wire or a connector, the iron shell needs to be riveted after being assembled so as to ensure that the iron shell cannot be loosened. The conventional riveting mechanism only needs to perform linear motion, so that the conventional linear driving mechanism is adopted to perform motion, the occupied space is large, and the use is not facilitated.

Disclosure of Invention

The utility model provides an iron shell riveting mechanism aiming at the problems in the prior art, which can realize the riveting of an iron shell on the premise of reducing the space use.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the utility model provides an iron shell riveting mechanism which comprises a first riveting component and a second riveting component, wherein the first riveting component comprises a first riveting driving piece, a first riveting driving piece and a first riveting piece, the first riveting driving piece is used for driving the first riveting driving piece to rotate, and the first riveting driving piece is used for driving the first riveting piece to be close to or far away from the second riveting component after being driven by the first riveting driving piece; the second riveting component is matched with the first riveting component to be used for riveting the iron shell.

Furthermore, the first riveting driving piece comprises a riveting motor and a riveting speed reducer, and the riveting motor drives the first riveting driving piece to rotate through the riveting speed reducer.

Furthermore, the first riveting driving part comprises a rotating part, a driven part and a guide groove, the first riveting driving part is in driving connection with the rotating part, the driven part is arranged on the rotating part, the first riveting part is provided with a transmission groove, and the driven part is movably arranged in the transmission groove; the first riveting driving piece is used for driving the rotating piece to rotate so as to drive the driven piece to do circular motion in the transmission groove, so that the first riveting piece moves back and forth in the guide groove.

Preferably, a first riveting groove is formed in one side, close to the second riveting mechanism, of the first riveting piece, and the first riveting groove is used for clamping the iron shell and moving the iron shell towards the second riveting component.

Furthermore, the second riveting component comprises a second riveting driving piece, a riveting seat and a second riveting piece, the second riveting piece is movably arranged on the riveting seat, and the second riveting driving piece drives the second riveting piece to be close to or far away from the first riveting piece through the second riveting driving piece.

Furthermore, the second riveting transmission part is provided with an inclined groove, the second riveting part is provided with a driving hole, the riveting seat is provided with a bolt, and the bolt is arranged in the inclined groove and the driving hole; the second riveting driving piece is used for driving the second riveting driving piece to lift so as to drive the second riveting piece to be close to or far away from the first riveting piece.

Preferably, the second riveting transmission piece is provided with a limiting groove, and the second riveting piece is arranged on the riveting seat in a lifting manner; the two sides of the limiting groove are respectively communicated with an inclined groove, and the second riveting piece is movably arranged in the limiting groove.

More preferably, the top and the bottom of the inclined groove are respectively communicated with a buffer groove, and the buffer grooves are used for accommodating the bolts.

Furthermore, a second riveting groove is formed in one side, close to the first riveting piece, of the second riveting piece, the radian of the inner wall of the second riveting groove is matched with the radian of the iron shell, and the second riveting groove is used for abutting against the iron shell.

Furthermore, the first riveting assembly comprises a first riveting limiting block, the second riveting assembly comprises a second riveting limiting block, and when the iron shell is riveted, the first riveting limiting block and the second riveting limiting block abut against each other to avoid excessive riveting of the iron shell.

The utility model has the beneficial effects that: according to the riveting device, the first riveting driving piece is driven to move back and forth through the rotation of the first riveting driving piece, so that the effect of riveting the iron shell is achieved by matching with the second riveting component, and the required space can be obtained.

Drawings

FIG. 1 is a schematic view of the present invention.

Fig. 2 is an exploded view of the first rivet assembly of the present invention.

Fig. 3 is an exploded view of a second rivet assembly of the present invention.

Reference numerals: 1-a first riveting component, 2-a second riveting component, 3-a first riveting driving component, 4-a first riveting driving component, 5-a first riveting component, 6-a second riveting driving component, 7-a second riveting driving component, 8-a riveting seat, 9-a second riveting component, 10-a first riveting limiting block, 11-a second riveting limiting block, 31-a riveting motor, 32-a riveting speed reducer, 41-a rotating component, 42-a driven component, 43-a guide groove, 51-a transmission groove, 52-a first riveting groove, 71-an inclined groove, 72-a limiting groove, 73-a buffer groove, 81-a translation groove, 91-a driving hole and 92-a second riveting groove.

Detailed Description

In order to facilitate understanding of those skilled in the art, the present invention will be further described with reference to the following examples and drawings, which are not intended to limit the present invention. The present invention is described in detail below with reference to the attached drawings.

As shown in fig. 1 to 3, the iron shell riveting mechanism provided by the present invention includes a first riveting component 1 and a second riveting component 2, where the first riveting component 1 includes a first riveting driving element 3, a first riveting transmission element 4, and a first riveting element 5, the first riveting driving element 3 is used for driving the first riveting transmission element 4 to rotate, and the first riveting transmission element 4 is used for driving the first riveting element 5 to approach or leave the second riveting component 2 after being driven by the first riveting driving element 3; the second riveting component 2 is matched with the first riveting piece 5 to be used for riveting the iron shell.

During the in-service use, first riveting driving piece 3 drive first riveting driving piece 4 rotates, and first riveting driving piece 4 carries out the round trip movement through the mode conversion of pivoted to first riveting 5, and the riveting effect to the iron-clad has been realized to cooperation second riveting subassembly 2. Compared with the traditional mode of directly adopting cylinders and the like to drive and rivet, the utility model adopts a rotating mode to realize driving, so that the requirement on space caused by formation reasons can be reduced, and the required space of the utility model is smaller.

In this embodiment, the first riveting driving component 3 includes a riveting motor 31 and a riveting reducer 32, and the riveting motor 31 drives the first riveting transmission component 4 to rotate through the riveting reducer 32. That is, after the riveting motor 31 is converted by the riveting speed reducer 32, the output rotating speed tends to be more stable, and the first riveting transmission member 4 can be effectively controlled to rotate, so that the effect of controlling the first riveting member 5 to move back and forth is achieved.

Specifically, the first riveting driving member 4 includes a rotating member 41, a driven block 42 and a guide groove 43, the first riveting driving member 3 is connected to the rotating member 41 in a driving manner, the driven block 42 is disposed on the rotating member 41, the first riveting member 5 is provided with a transmission groove 51, and the driven block 42 is movably disposed in the transmission groove 51; the first riveting driving member 3 is used for driving the rotating member 41 to rotate so as to drive the driven block 42 to make a circular motion in the transmission groove 51, so that the first riveting member 5 moves back and forth in the guide groove 43. That is, riveting speed reducer 32 drives and rotates piece 41, make to set up and carry out the circumference thereupon in the follower 42 of rotating piece 41 and rotate, because the activity of follower 42 sets up in driving groove 51, and first riveting piece 5 activity only can the round trip movement in guide way 43, consequently when follower 42 pivoted, it can be decomposed into level and vertical direction motion, the motion of vertical direction makes follower 42 go up and down in driving groove 51, the level is reverse then to be used for driving first riveting piece 5 round trip movement, thereby reached and be close to or keep away from the effect of second riveting subassembly 2, realized carrying out the action of iron-clad riveting with the cooperation of second riveting subassembly 2. According to the structure of the first riveting transmission part 4, the rotating action is ingeniously converted into the linear action of the first riveting part 5, and due to the structural characteristics of the riveting motor 31 and the riveting speed reducer 32, the spatial distribution of all parts of the first riveting component 1 can be more flexible, and the space utilization rate is improved.

Of course, the driven block 42 is preferably cylindrical, so that when the driven block 42 moves in the transmission slot 51, the friction between the driven block 42 and the transmission slot 51 is reduced, the transmission effect is ensured, and the service life is prolonged.

As another embodiment of the present embodiment, the shape of the first riveting transmission member 4 can be circular or cam-shaped, and the transmission effect can be achieved as well.

Preferably, a first riveting groove 52 is formed in one side of the first riveting member 5 close to the second riveting mechanism, and the first riveting groove 52 is used for clamping an iron shell and moving the iron shell towards the second riveting component 2. That is, when the first riveting member 5 contacts with the iron shell, the iron shell is accommodated in the first riveting groove 52 and is pushed by the first riveting member 5 to move towards the second riveting member 9, so that the riveting effect is realized.

In this embodiment, the second riveting component 2 includes a second riveting driving element 6, a second riveting driving element 7, a riveting base 8 and a second riveting element 9, the second riveting element 9 is movably disposed on the riveting base 8, and the second riveting driving element 6 drives the second riveting element 9 to approach or be away from the first riveting element 5 through the second riveting driving element 7. Second riveting driving piece 6 preferably selects conventional linear driving mechanism such as my electric cylinder or cylinder for drive second riveting driving piece 7 goes up and down, goes up and down by second riveting driving piece 7 and drives second riveting 9 round trip movement, can promote space utilization equally.

Specifically, the second riveting transmission member 7 is provided with an inclined groove 71, the second riveting member 9 is provided with a driving hole 91, and the riveting seat 8 is provided with a plug (not shown in the figure) which is arranged in the inclined groove 71 and the driving hole 91; the second riveting driving piece 6 is used for driving the second riveting driving piece 7 to ascend and descend so as to drive the second riveting piece 9 to be close to or far away from the first riveting piece 5.

That is, the second riveting transmission member 7 only performs a lifting action under the driving of the second riveting driving member 6, because the inclined groove 71 exists, and the plug pin enables the inclined groove 71 and the driving hole 91 to be always communicated, so along with the lifting of the second riveting transmission member 7, the second riveting member 9 moves in the horizontal direction, and the second riveting member 9 does not lift due to the limitation of the riveting seat 8 in the vertical direction, thereby enabling the second riveting member 9 to realize the effect of horizontal movement. According to the riveting device, the lifting drive is converted into the translation motion of the second riveting piece 9, so that the second riveting driving piece 6 and the second riveting piece 9 can be arranged in the same vertical plane, and the space utilization rate is improved.

Specifically, the riveting seat 8 is provided with a translation groove for allowing the bolt to slide.

Preferably, the second riveting transmission member 7 is provided with a limiting groove 72, and the second riveting member 9 is arranged on the riveting seat 8 in a liftable manner; the two sides of the limiting groove 72 are respectively communicated with an inclined groove 71, and the second riveting piece 9 is movably arranged in the limiting groove 72. The arrangement of the limiting groove 72 enables the second riveting piece 9 to move back and forth in the second riveting transmission piece 7, so that the transmission effect of the second riveting transmission piece 7 on the second riveting piece 9 is guaranteed, and the problem that the second riveting piece 9 is staggered to cause unreliable transmission is avoided.

More preferably, the top and the bottom of the inclined groove 71 are respectively communicated with a buffer groove 73, and the buffer groove 73 is used for accommodating a plug. The buffer slot 73 is used for limiting the plug pin and ensuring that the plug pin cannot move when the second riveting transmission member 7 moves to the highest or lowest position, so that the effect of locking the second riveting member 9 is realized.

Specifically, the second riveting piece 9 is close to one side of the first riveting piece 5 is provided with a second riveting groove 92, the radian of the inner wall of the second riveting groove 92 is adapted to the radian of the iron shell, and the second riveting groove 92 is used for abutting against the iron shell. That is, after the first riveting groove 52 positions the iron shell, the second riveting groove 92 clamps the iron shell, and as the second riveting groove 92 approaches or enters the first riveting groove 52, the effect of riveting the opened iron shell can be achieved.

In this embodiment, the first riveting component 1 includes a first riveting limiting block 10, the second riveting component 2 includes a second riveting limiting block 11, and when the iron shell is riveted, the first riveting limiting block 10 and the second riveting limiting block 11 abut against each other to avoid over-riveting the iron shell, so as to ensure the safety of the present invention and the yield of the iron shell. Specifically, the first riveting limiting block 10 can be provided with a positioning insertion block, the second riveting limiting block 11 can be provided with a positioning insertion slot, positioning is realized by inserting the positioning insertion block into the positioning insertion slot, and dislocation of the first riveting component 1 and the second riveting component 2 is further avoided.

Although the present invention has been described with reference to the above preferred embodiments, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the utility model as defined by the appended claims.

Claims (10)

1. The utility model provides an iron-clad riveting mechanism which characterized in that: the riveting device comprises a first riveting assembly and a second riveting assembly, wherein the first riveting assembly comprises a first riveting driving piece, a first riveting transmission piece and a first riveting piece, the first riveting driving piece is used for driving the first riveting transmission piece to rotate, and the first riveting transmission piece is used for driving the first riveting piece to be close to or far away from the second riveting assembly after being driven by the first riveting driving piece; the second riveting component is matched with the first riveting component to be used for riveting the iron shell.

2. The iron shell riveting mechanism of claim 1, wherein: the first riveting driving piece comprises a riveting motor and a riveting speed reducer, and the riveting motor drives the first riveting driving piece to rotate through the riveting speed reducer.

3. The iron shell riveting mechanism of claim 1 or 2, wherein: the first riveting driving part comprises a rotating part, a driven part and a guide groove, the first riveting driving part is in driving connection with the rotating part, the driven part is arranged on the rotating part, the first riveting part is provided with a transmission groove, and the driven part is movably arranged in the transmission groove; the first riveting driving piece is used for driving the rotating piece to rotate so as to drive the driven piece to do circular motion in the transmission groove, so that the first riveting piece moves back and forth in the guide groove.

4. The iron shell riveting mechanism of claim 3, wherein: one side of the first riveting piece, which is close to the second riveting mechanism, is provided with a first riveting groove, and the first riveting groove is used for clamping an iron shell and moving the iron shell towards the second riveting component.

5. The iron shell riveting mechanism of claim 1, wherein: the second riveting component comprises a second riveting driving piece, a riveting seat and a second riveting piece, the second riveting piece is movably arranged on the riveting seat, and the second riveting driving piece drives the second riveting piece to be close to or far away from the first riveting piece through the second riveting driving piece.

6. The iron shell riveting mechanism of claim 5, wherein: the second riveting transmission part is provided with an inclined groove, the second riveting part is provided with a driving hole, the riveting seat is provided with a bolt, and the bolt is arranged in the inclined groove and the driving hole; the second riveting driving piece is used for driving the second riveting driving piece to lift so as to drive the second riveting piece to be close to or far away from the first riveting piece.

7. The iron shell riveting mechanism of claim 6, wherein: the second riveting transmission piece is provided with a limiting groove, and the second riveting piece is arranged on the riveting seat in a lifting manner; the two sides of the limiting groove are respectively communicated with an inclined groove, and the second riveting piece is movably arranged in the limiting groove.

8. The iron shell riveting mechanism of claim 6 or 7, wherein: the top and the bottom of the inclined groove are respectively communicated with a buffer groove, and the buffer grooves are used for accommodating the bolts.

9. The iron shell riveting mechanism of claim 5, wherein: one side that the second riveting is close to first riveting is provided with the second riveting groove, the inner wall radian in second riveting groove suits with the radian of iron-clad, the second riveting groove is used for contradicting with the iron-clad.

10. The iron shell riveting mechanism of claim 1, wherein: the first riveting assembly comprises a first riveting limiting block, the second riveting assembly comprises a second riveting limiting block, and when the iron shell is riveted, the first riveting limiting block is abutted against the second riveting limiting block so as to avoid excessive riveting of the iron shell.

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