CN209860330U - Socket rotating riveting device - Google Patents

Abstract

The utility model discloses a rotatory riveting device of socket belongs to socket assembly technical field. The socket rotating riveting device comprises a riveting mechanism, a workbench, a turntable, a feeding mechanism and a shifting-out mechanism, wherein the turntable, the feeding mechanism and the shifting-out mechanism are arranged on the workbench, the turntable can rotate intermittently relative to the workbench, a plurality of lower dies are arranged on the turntable at uniform intervals in the circumferential direction, the feeding mechanism, the riveting mechanism and the shifting-out mechanism are sequentially arranged around the turntable and respectively correspond to one of the lower dies, the feeding mechanism is configured to convey a socket to the corresponding lower die, and the shifting-out mechanism is configured to shift out the socket which is riveted by the riveting mechanism from the lower dies. The utility model discloses an automatic riveting of socket, greatly reduced workman's intensity of labour, reduced the potential safety hazard.

Description

Socket rotating riveting device

Technical Field

The utility model relates to a socket equipment technical field especially relates to a rotatory riveting device of socket.

Background

Sockets are electrical connectors used in a wide variety of electrical circuits and are important electromechanical components for connecting two devices to transmit current or signals, connecting conductors or wires to appropriate mating components, and completing electrical circuits.

The socket comprises an insulating body and three-pole conductive terminals arranged on the insulating body, and when the socket is assembled, the three-pole conductive terminals are firstly inserted into the insulating body and then riveted and fixed by using a riveting mechanism. However, when stamping, the socket needs to be manually placed into the riveting mechanism, the labor intensity of workers is high, and potential safety hazards exist.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a rotatory riveting device of socket can alleviate workman's intensity of labour, reduces the potential safety hazard.

To achieve the purpose, the utility model adopts the following technical proposal:

a socket rotating riveting device comprises a riveting mechanism, a workbench, a turntable, a feeding mechanism and a shifting-out mechanism, wherein the turntable, the feeding mechanism and the shifting-out mechanism are arranged on the workbench, the turntable can rotate intermittently relative to the workbench, a plurality of lower dies are arranged on the turntable at uniform intervals in the circumferential direction, the feeding mechanism, the riveting mechanism and the shifting-out mechanism are sequentially arranged around the turntable and respectively correspond to one of the lower dies, the feeding mechanism is configured to convey a socket to the corresponding lower die, and the shifting-out mechanism is configured to shift out the socket which is riveted by the riveting mechanism from the lower die.

Preferably, the socket rotary riveting device further comprises a blowing mechanism arranged on the workbench, the blowing mechanism is arranged between the riveting mechanism and the moving-out mechanism, and the blowing mechanism can correspond to any lower die.

Preferably, the feeding mechanism comprises an input channel for conveying a socket, a first clamping jaw cylinder is arranged above the input channel, and the first clamping jaw cylinder can convey the socket on the input channel to the lower die.

Preferably, the feeding mechanism further comprises a first driving assembly for driving the first clamping jaw cylinder to move, the first driving assembly comprises a first horizontal cylinder for driving the first clamping jaw cylinder to move horizontally and a first lifting cylinder for driving the first clamping jaw cylinder to move vertically, the first lifting cylinder is connected to the first clamping jaw cylinder, and the first horizontal cylinder is connected to the first lifting cylinder.

Preferably, the removing mechanism comprises an output channel, a clamping assembly is arranged above the output channel, and the clamping assembly can convey the socket on the lower die to the output channel.

Preferably, a rotating assembly is arranged between the turntable and the output channel, the clamping assembly can convey the socket on the lower die to the rotating assembly and convey the socket on the rotating assembly to the output channel, and the rotating assembly can drive the socket to rotate horizontally.

Preferably, the removing mechanism further comprises a second driving assembly for driving the clamping assembly to move, the clamping assembly comprises a second clamping jaw air cylinder and a third clamping jaw air cylinder connected to one side of the second clamping jaw air cylinder, the second clamping jaw air cylinder is configured to clamp the socket on the lower die and is placed on the rotating assembly, and the third clamping jaw air cylinder is configured to clamp the socket on the rotating assembly and is placed on the output channel;

the second drive assembly comprises a second horizontal cylinder and a second lifting cylinder, the second horizontal cylinder is used for driving the second clamping jaw cylinder and the third clamping jaw cylinder to move horizontally, the second lifting cylinder is used for driving the second clamping jaw cylinder and the third clamping jaw cylinder to move up and down, the second horizontal cylinder is connected with the second clamping jaw cylinder and the third clamping jaw cylinder, and the second lifting cylinder is connected with the second horizontal cylinder.

Preferably, the removing mechanism further includes a detection assembly and a material shifting plate, the detection assembly is disposed above the output channel, the detection assembly is connected to the third clamping jaw cylinder and configured to detect the socket clamped by the third clamping jaw cylinder, and the material shifting plate is configured to push the detected socket out of the detection station along the output channel.

Preferably, the removing mechanism further comprises a defective product flow channel arranged below the output channel, the output channel comprises a lifting plate, and when the lifting plate is lifted, the kick-out plate can push the defective product to the defective product flow channel.

Preferably, a support seat is arranged at the bottom of the riveting mechanism, and the support seat is configured to support the lower die during riveting.

The utility model has the advantages that:

the utility model comprises a workbench, a turntable arranged on the workbench, a feeding mechanism, a riveting mechanism and a shifting-out mechanism, wherein the feeding mechanism is used for automatically feeding materials to the turntable which rotates intermittently, and the socket is rotated to the riveting mechanism through the turntable for riveting, and then the shifting-out mechanism can be used for automatically shifting out the riveted socket, thereby realizing the automatic riveting of the socket, facilitating the operation of personnel, greatly reducing the labor intensity of workers and reducing the potential safety hazard; in addition, set up a plurality of lower moulds on the carousel, make feed mechanism, riveting mechanism and shift out the mechanism and can work simultaneously to work efficiency has been improved.

Drawings

Fig. 1 is a schematic perspective view of a socket rotary riveting device according to an embodiment of the present invention;

fig. 2 is a schematic top view of a socket rotary riveting device according to an embodiment of the present invention;

fig. 3 is a schematic perspective view of a turntable and a lower mold according to an embodiment of the present invention;

fig. 4 is a schematic perspective view of a feeding mechanism according to an embodiment of the present invention;

fig. 5 is a schematic perspective view of another perspective view of the feeding mechanism according to the embodiment of the present invention;

fig. 6 is a schematic perspective view of a riveting mechanism according to an embodiment of the present invention;

fig. 7 is a schematic perspective view of a removing mechanism according to embodiment 1 of the present invention;

fig. 8 is a schematic perspective view of another perspective view of the removing mechanism according to embodiment 1 of the present invention;

fig. 9 is a schematic partial perspective view of a removing mechanism according to embodiment 1 of the present invention.

In the figure: 1-a workbench, 2-a feeding mechanism, 21-a first bottom plate, 22-a first bracket, 23-a first driving component, 231-a first horizontal cylinder, 232-a first feeding slide block, 233-a first lifting cylinder, 24-a first clamping jaw cylinder, 25-a proximity switch, 26-a conveyor belt side plate, 27-a driving motor, 3-a turntable, 4-a riveting mechanism, 41-a supporting seat, 5-a shifting-out mechanism, 51-a second bottom plate, 52-a rotating component, 521-a rotating cylinder, 522-a testing seat, 523-a testing carrier, 53-a clamping component, 531-a second clamping jaw cylinder, 532-a third clamping jaw cylinder, 54-a second driving component, 541-a second lifting cylinder and 542-an up-down sliding seat, 543-a second feeding slide block, 544-a second horizontal cylinder, 55-a detection assembly, 551-a high-pressure test plate, 552-a probe, 56-an output channel, 561-a lifting plate, 57-a second bracket, 58-a defective product flow channel, 59-a material-shifting plate, 510-a third lifting cylinder, 511-a third horizontal cylinder, 6-an air blowing mechanism, 7-a lower die and 8-a support fixing plate.

Detailed Description

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

As shown in fig. 1 to 9, a socket rotating riveting device includes a riveting mechanism 4, a workbench 1, and a turntable 3, a feeding mechanism 2 and a moving-out mechanism 5 which are arranged on the workbench 1, wherein the turntable 3 can rotate intermittently relative to the workbench, a plurality of lower dies 7 are arranged on the turntable 3 at uniform intervals in the circumferential direction, the feeding mechanism 2, the riveting mechanism 4 and the moving-out mechanism 5 are sequentially arranged around the turntable 3 and respectively correspond to one of the lower dies 7, the feeding mechanism 2 is configured to convey a socket to the corresponding lower die 7, and the moving-out mechanism 5 is configured to move out the socket riveted by the riveting mechanism from the lower die 7.

When the turntable 3 stops rotating, the feeding mechanism 2, the riveting mechanism 4 and the shifting-out mechanism 5 are respectively corresponding to one lower die 7, the socket is conveyed to the corresponding lower die 7 by the feeding mechanism 2, the socket on the corresponding lower die 7 is riveted by the riveting mechanism 4, the socket on the corresponding lower die 7 is shifted out by the shifting-out mechanism 5, the turntable 3 stops after rotating for a certain angle, the feeding mechanism 2, the riveting mechanism 4 and the shifting-out mechanism 5 repeat corresponding actions, the socket is not required to be manually placed into the riveting mechanism 4 in the whole process, automatic riveting of the socket is realized, personnel operation is facilitated, the labor intensity of workers can be greatly reduced, and potential safety hazards are reduced.

As shown in fig. 3, the lower die 7 is detachably connected to the turntable 3 through the supporting and fixing plate 8, so that the lower die 7 can be conveniently replaced and the application range of the socket rotating riveting device can be enlarged.

As shown in fig. 4 and 5, the feeding mechanism 2 includes an input channel for conveying a socket, a first clamping jaw cylinder 24 is arranged above the input channel, and the first clamping jaw cylinder 24 can convey the socket on the input channel to the lower die 7. The first jaw cylinder 24 includes jaws and power to control the jaws to open and close. The input channel comprises a conveyor belt connected above the first bottom plate 21 and a conveyor belt side plate 26 for fixing the conveyor belt, a stop block is arranged at the end part of the conveyor belt side plate 26, a proximity switch 25 is fixed on the stop block, and the conveyor belt is driven by a driving motor 27. The sockets to be riveted are sequentially arranged on the conveyor belt, the conveyor belt conveys the sockets forwards, when the sockets are conveyed to the proximity switch 25, the conveyor belt stops conveying, and when the sockets are removed, the conveyor belt continues conveying.

Further, feed mechanism 2 still includes the first drive assembly 23 that drives first clamping jaw cylinder 24 and remove, and first drive assembly 23 includes first horizontal cylinder 231 and the first lift cylinder 233 that is used for driving first clamping jaw cylinder 24 horizontal migration that is used for driving first clamping jaw cylinder 24 to reciprocate, and first lift cylinder 233 connects in first clamping jaw cylinder 24, and first horizontal cylinder 231 connects in first lift cylinder 233. The first driving assembly 23 further includes a first feeding sliding block 232, the first feeding sliding block 232 is slidably connected to the first support 22 fixed on the first base plate 21, a sliding direction of the first feeding sliding block 232 is parallel to a conveying direction of the conveyor belt, and the first horizontal cylinder 231 is fixed on the first support 22 to drive the first feeding sliding block 232 to slide. The first lifting cylinder 233 is connected to the first feeding slider 232 to drive the first jaw cylinder 24 to move up and down. When a socket needs to be conveyed to the lower die 7, the first lifting cylinder 233 acts to lift the socket clamped by the first clamping jaw cylinder 24, then the first horizontal cylinder 231 acts to push the socket to the upper side of the lower die 7, then the first lifting cylinder 233 acts to move the socket downwards, the first clamping jaw cylinder 24 acts to release the socket, the socket is placed on the lower die 7, and then the first lifting cylinder 233, the first horizontal cylinder 231 and the first clamping jaw cylinder 24 act in sequence to prepare for conveying of the next socket.

After the socket is placed on the lower die 7 by the feeding mechanism 2, the socket is riveted by matching the upper die and the lower die 7 on the riveting mechanism 4 after the socket rotates to the riveting mechanism 4. As shown in fig. 6, a support seat 41 is provided at the bottom of the riveting mechanism 4, and the support seat 41 is configured to support the lower mold 7 during riveting, so as to increase the stability of the riveting process.

As shown in fig. 1, the socket rotary riveting device further comprises a blowing mechanism 6 arranged on the workbench 1, wherein the blowing mechanism 6 is arranged between the riveting mechanism 4 and the moving-out mechanism 5, and the blowing mechanism 6 can correspond to any lower die 7. The blowing mechanism 6 comprises a blowing seat connected with an air source, and the blowing seat is fixed on the workbench 1. The blowing mechanism 6 can blow off copper scraps on the riveted socket.

As shown in fig. 7, 8 and 9, the removing mechanism 5 includes an output channel 56, a clamping assembly 53 is disposed above the output channel 56, and the clamping assembly 53 can convey the socket on the lower mold 7 to the output channel 56. The rear end of the output duct 56 is connected to a conveying device, and the socket removed from the output duct 56 can be conveyed to the next process by the conveying device.

When the socket on the lower die 7 is rotated to the output channel 56, the orientation of the socket on the lower die 7 is not consistent with the required placing orientation of the socket on the output channel 56, therefore, in order to facilitate the operation of the next process, the rotating assembly 52 is arranged between the turntable 3 and the output channel 56, the clamping assembly 53 can convey the socket on the lower die 7 to the rotating assembly 52 and convey the socket on the rotating assembly 52 to the output channel 56, and the rotating assembly 52 can drive the socket to rotate horizontally. When the socket on the lower die 7 is conveyed to the output channel 56, the socket can be horizontally rotated by 90 degrees by using the rotating assembly 52 so as to meet the placement requirement of the socket on the output channel 56, and the operation of the next process is convenient.

The removing mechanism 5 further comprises a second driving assembly 54 for driving the clamping assembly 53 to move, the clamping assembly 53 comprises a second clamping jaw air cylinder 531 and a third clamping jaw air cylinder 532 connected to one side of the second clamping jaw air cylinder 531, the second clamping jaw air cylinder 531 is configured to clamp the socket on the lower die 7 and placed on the rotating assembly 52, and the third clamping jaw air cylinder 532 is configured to clamp the socket on the rotating assembly 52 and placed on the output channel (56). The second clamping jaw air cylinder 531 and the third clamping jaw air cylinder 532 both comprise clamping jaws and power for controlling the clamping jaws to open and close. Through the setting of second clamping jaw cylinder 531 and third clamping jaw cylinder 532, can go on with the removal of socket with rotatory synchronous, simple structure has simplified the flow.

The second driving assembly 54 comprises a second horizontal cylinder 544 for driving the second clamping jaw cylinder 531 and the third clamping jaw cylinder 532 to horizontally move and a second lifting cylinder 541 for driving the second clamping jaw cylinder 531 and the third clamping jaw cylinder 532 to move up and down, the second horizontal cylinder 544 is connected to the second clamping jaw cylinder 531 and the third clamping jaw cylinder 532, and the second lifting cylinder 541 is connected to the second horizontal cylinder 544. The second driving assembly 54 further includes a second feeding block 543 and an up-down sliding seat 542, the second feeding block 543 is slidably connected to the second bracket 57 fixed on the second base plate 51, the sliding direction of the second feeding block 543 is parallel to the conveying direction of the output channel 56, and the second horizontal cylinder 544 is fixed on the second bracket 57 to drive the second feeding block 543 to slide. The upper and lower sliding base 542 is slidably connected to the second feeding slide block 543, and the second lifting cylinder 541 is connected to the upper and lower sliding base 542 and the second feeding slide block 543, and can drive the second clamping jaw cylinder 531 and the third clamping jaw cylinder 532 to move up and down. When the socket on the lower die 7 rotates to the output channel 56, the second lifting cylinder 541 and the second horizontal cylinder 544 act in sequence, the second clamping jaw cylinder 531 and the third clamping jaw cylinder 532 move upwards, then the second clamping jaw cylinder 531 moves to the lower die 7, the second clamping jaw cylinder 531 acts to clamp the socket on the lower die 7, meanwhile, the third clamping jaw cylinder 532 moves to the rotating assembly 52, the third clamping jaw cylinder 532 acts to clamp the socket on the rotating assembly 52, then the second lifting cylinder 541 and the second horizontal cylinder 544 act in sequence, the socket is placed on the rotating assembly 52 by the second clamping jaw cylinder 531, and the socket is placed on the output channel 56 by the third clamping jaw cylinder 532.

In order to facilitate the detection of the socket, the removing mechanism 5 further includes a detection assembly 55 and a material-shifting plate 59 which are disposed above the output channel 56, the detection assembly 55 is connected to the third jaw cylinder 532 and configured to detect the socket clamped by the third jaw cylinder 532, and the material-shifting plate 59 is configured to push the detected socket out of the detection station along the output channel 56. The switch board 59 is connected with a third horizontal cylinder 511, and after the socket is placed on the output channel 56 by the third clamping jaw cylinder 532, the third horizontal cylinder 511 acts to drive the switch board 59 to push the socket. The detecting assembly 55 includes a high voltage testing board 551 and a probe 552 fixed on the high voltage testing board 551, the probe 552 has three conductive terminals corresponding to three poles on the socket, the probe 552 is connected to the electrical testing apparatus, the rotating assembly 52 includes a testing seat 522, a testing carrier 523 fixed above the testing seat 522, and a rotating cylinder 521 for driving the testing seat 522 to rotate. The shape of the test carrier 523 matches the shape of the socket to adjust the position of the socket, and when the third jaw cylinder 532 clamps the socket on the rotating assembly 52, the probe 552 can contact the three-pole conductive terminal on the socket, and then the socket is detected to be qualified by the electrical measuring instrument.

As shown in fig. 9, in order to facilitate the output of the defective products, the removing mechanism 5 further includes a defective product flow channel 58 disposed below the output channel 56, the output channel 56 includes a lifting plate 561, and when the lifting plate 561 is lifted, the material-shifting plate 59 can push the defective products to the defective product flow channel 58. The third lift cylinder 510 is connected to the lift plate 561, and when a defective product is detected, the lift cylinder operates to lift the lift plate 561, and when the switch plate 59 pushes the socket, the socket is pushed toward the defective product flow path 58 through the lower side of the lift plate 561.

The utility model discloses utilize feed mechanism 2 to carry the socket to lower mould 7 on carousel 3, utilize riveting mechanism 4 to the riveting on lower mould 7, the socket after the riveting utilizes blowing mechanism 6 clean up the socket, then shift out the socket on lower mould 7 through shifting out mechanism 5, can carry out high pressure resistant detection to the product simultaneously, the automatic processing of socket riveting has been realized, greatly reduced workman's intensity of labour, intermittent type through carousel 3 can make feed mechanism 2, riveting mechanism 4, blowing mechanism 6 and shifting out mechanism 5 synchronous working, the production efficiency is improved.

The technical principle of the present invention is described above with reference to specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without any inventive effort, which would fall within the scope of the present invention.

Claims (10)

1. A socket rotating riveting device comprises a riveting mechanism (4), and is characterized by further comprising a workbench (1), a turntable (3) arranged on the workbench (1), a feeding mechanism (2) and a shifting-out mechanism (5), the rotary table (3) can intermittently rotate relative to the workbench (1), a plurality of lower dies (7) are uniformly arranged at intervals in the circumferential direction of the rotary table (3), the feeding mechanism (2), the riveting mechanism (4) and the shifting-out mechanism (5) are arranged around the turntable (3) in sequence and respectively correspond to one of the lower dies (7), the feeding mechanism (2) is configured to convey a socket to one of the lower molds (7) corresponding thereto, the removing mechanism (5) is configured to remove the socket riveted by the riveting mechanism (4) from the lower die (7).

2. The socket rotary riveting device according to claim 1, further comprising a blowing mechanism (6) arranged on the workbench (1), wherein the blowing mechanism (6) is arranged between the riveting mechanism (4) and the moving-out mechanism (5), and the blowing mechanism (6) can correspond to any lower die (7).

3. The socket rotary riveting device according to claim 1, wherein the feeding mechanism (2) comprises an input channel for conveying sockets, a first clamping jaw cylinder (24) is arranged above the input channel, and the first clamping jaw cylinder (24) can convey the sockets on the input channel to the lower die (7).

4. The socket rotary riveting device according to claim 3, wherein the feeding mechanism (2) further comprises a first driving component (23) for driving the first clamping jaw cylinder (24) to move, the first driving component (23) comprises a first horizontal cylinder (231) for driving the first clamping jaw cylinder (24) to move horizontally and a first lifting cylinder (233) for driving the first clamping jaw cylinder (24) to move up and down, the first lifting cylinder (233) is connected to the first clamping jaw cylinder (24), and the first horizontal cylinder (231) is connected to the first lifting cylinder (233).

5. The socket rotary riveting device according to claim 1, wherein the removing mechanism (5) comprises an output channel (56), a clamping assembly (53) is arranged above the output channel (56), and the clamping assembly (53) can convey the socket on the lower die (7) to the output channel (56).

6. The socket rotary riveting device according to claim 5, wherein a rotary component (52) is arranged between the turntable (3) and the output channel (56), the clamping component (53) can convey the socket on the lower die (7) to the rotary component (52) and convey the socket on the rotary component (52) to the output channel (56), and the rotary component (52) can drive the socket to rotate horizontally.

7. A socket rotary riveting apparatus according to claim 6, wherein the removing mechanism (5) further comprises a second driving assembly (54) for driving the clamping assembly (53) to move, the clamping assembly (53) comprises a second clamping jaw cylinder (531) and a third clamping jaw cylinder (532) connected to one side of the second clamping jaw cylinder (531), the second clamping jaw cylinder (531) is configured to clamp the socket on the lower die (7) and to be placed on the rotating assembly (52), and the third clamping jaw cylinder (532) is configured to clamp the socket on the rotating assembly (52) and to be placed on the output channel (56);

the second driving assembly (54) comprises a second horizontal cylinder (544) for driving the second clamping jaw cylinder (531) and the third clamping jaw cylinder (532) to move horizontally and a second lifting cylinder (541) for driving the second clamping jaw cylinder (531) and the third clamping jaw cylinder (532) to move up and down, the second horizontal cylinder (544) is connected to the second clamping jaw cylinder (531) and the third clamping jaw cylinder (532), and the second lifting cylinder (541) is connected to the second horizontal cylinder (544).

8. The socket rotary riveting press device according to claim 7, wherein the removing mechanism (5) further comprises a detection assembly (55) and a material shifting plate (59) which are arranged above the output channel (56), the detection assembly (55) is connected to the third clamping jaw cylinder (532) and is configured to detect the socket clamped by the third clamping jaw cylinder (532), and the material shifting plate (59) is configured to push the detected socket out of a detection station along the output channel (56).

9. The socket rotary riveting device according to claim 8, wherein the removing mechanism (5) further comprises a defective product flow channel (58) arranged below the output channel (56), the output channel (56) comprises a lifting plate (561), and when the lifting plate (561) is lifted, the kick-out plate (59) can push a defective product to the defective product flow channel (58).

10. A socket rotary riveting apparatus according to any one of claims 1-9, wherein the riveting mechanism (4) is provided at the bottom with a support base configured to support the lower die (7) during riveting.