CN214152747U

CN214152747U - Switch assembly equipment

Info

Publication number: CN214152747U
Application number: CN202023087128.6U
Authority: CN
Inventors: 胡昌波; 刘益军
Original assignee: Huizhou Hongjingwei Automation Equipment Co ltd
Current assignee: Huizhou Hongjingwei Automation Equipment Co ltd
Priority date: 2020-12-18
Filing date: 2020-12-18
Publication date: 2021-09-07
Anticipated expiration: 2030-12-18

Abstract

The utility model discloses a switch assembling device relates to the technical field of assembling devices, and is provided with a conveying mechanism, a processing mechanism and a transmission mechanism, wherein the conveying mechanism is used for conveying materials, and the transmission mechanism is used for transmitting power to the processing mechanism so that the processing mechanism can process the materials; in the practical application process, can set up a plurality of guide cambered surfaces on always passing the axle, every guide cambered surface one-to-one guides a time transaxle to rotate or slide to make each time the transaxle can carry out power input to a plurality of processing mechanisms, generally speaking, use the rotation of the total transaxle of single total drive piece drive to drive a plurality of processing mechanisms, the technical problem that need set up the power original paper to each station respectively among the prior art has been solved, equipment cost has been practiced thrift and the whole compact degree of equipment has still been improved simultaneously.

Description

Switch assembly equipment

Technical Field

The utility model relates to an equipment field especially relates to a switch equipment.

Background

The appearance of equipment has improved the production machining efficiency of various accessories effectively, for example, switch equipment can assemble the switch automatically, has removed the loaded down with trivial details of manual equipment switch from, has improved switch production efficiency, but current switch equipment still has the technical problem who surely needs to overcome:

the existing switch assembling equipment is usually provided with a plurality of stations, each station is arranged in sequence along the conveying direction of materials, and therefore the purpose of assembling the switch is achieved, however, each station needs to use a motor or a cylinder as a power element, so that the whole volume of each station is large, the whole compactness of the switch assembling equipment is reduced, and meanwhile, the whole manufacturing cost of the equipment is increased.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the weak point among the prior art, providing a switch equipment, this switch equipment can solve and need set up the technical problem of power original paper respectively to each station.

The purpose of the utility model is realized through the following technical scheme:

a switch assembling device comprises a conveying mechanism and a processing mechanism, wherein the conveying mechanism is used for conveying materials, and the processing mechanism is used for processing the materials on the conveying mechanism;

the switch assembling equipment further comprises a transmission mechanism, wherein the transmission mechanism comprises a main driving piece, a main transmission shaft and a secondary transmission rod, the main driving piece is used for driving the main transmission shaft to rotate, a guide arc surface is arranged on the main transmission shaft, the sliding end of the secondary transmission rod is used for rotating or sliding relative to the conveying mechanism when sliding along the guide arc surface, and the output end of the secondary transmission rod is used for being in driving connection with the machining mechanism.

In one embodiment, the transmission mechanism further comprises a support seat, the secondary transmission rod comprises a rod body, a roller and a driving connection seat, the rod body is rotatably arranged on the support seat, one end of the rod body is connected with the roller, and the other end of the rod body is connected with the driving connection seat;

the roller is the sliding end of the secondary transmission rod, and the driving connecting seat is the output end of the secondary transmission rod.

In one embodiment, the processing mechanism comprises a riveting device, the riveting device comprises a riveting head, a riveting guide seat and a riveting sliding block, the riveting head is arranged on the driving connecting seat, the riveting guide seat is arranged on the conveying mechanism, and the riveting sliding block is arranged on the riveting guide seat in a sliding manner;

when the rod body rotates relative to the supporting seat, the riveting head is used for propping the riveting sliding block to slide relative to the riveting guide seat, and the riveting sliding block is used for propping the pressing handle to be riveted on the base.

In one embodiment, the driving connecting seat comprises a rotating shaft and a rotating driving seat, the rotating shaft is connected with the rod body, and the rotating driving seat is rotatably arranged on the rotating shaft;

the processing mechanism comprises a pressing device, the pressing device comprises a pressing seat and a pressing block, the pressing seat is arranged on the rotation driving seat, and the pressing block is arranged on the pressing seat;

when the rod body rotates relative to the supporting seat, the pressing block is used for mutually supporting the pressing handle.

In one embodiment, the transmission mechanism further comprises a transmission sliding seat, the secondary transmission rod comprises a sliding rod, a sliding wheel and an output seat, the sliding rod is arranged on the transmission sliding seat in a sliding mode, one end of the sliding rod is connected with the sliding wheel, and the other end of the sliding rod is connected with the output seat;

the sliding wheel is the sliding end of the secondary transmission rod, and the output seat is the output end of the secondary transmission rod.

In one embodiment, the processing mechanism comprises a pressing handle material shifting device, the pressing handle material shifting device comprises a pressing handle material feeding rail, a dislocation seat and a pressing handle material shifting piece, the dislocation seat is provided with a dislocation accommodating groove, the pressing handle material feeding rail is used for conveying the pressing handle to the dislocation accommodating groove, the dislocation seat is connected with the output seat in a sliding manner, and the pressing handle material shifting piece is arranged on the output seat;

when the sliding rod slides, the dislocation seat is used for sliding relative to the output seat, and the pressing handle material shifting part is used for propping the pressing handle in the dislocation accommodating groove to move to the conveying mechanism.

In one embodiment, the output seat is provided with a guide through hole, the pressing handle material shifting device further comprises a dislocation roller, the dislocation roller penetrates through the guide through hole and is rotatably connected with the dislocation seat, and the hole wall of the guide through hole is used for being mutually supported by the dislocation roller.

In one embodiment, the processing mechanism comprises a feeding device, the feeding device comprises a feeding guide rail, a feeding slide seat and a one-way feeding sheet, the feeding slide seat is slidably arranged on the feeding guide rail, the feeding slide seat is connected with the output seat, and the one-way feeding sheet is rotatably arranged on the feeding slide seat;

when the sliding rod slides, the one-way feeding sheet is used for propping the base to move along the conveying mechanism.

In one embodiment, the processing mechanism comprises a testing device, the testing device comprises a testing probe, and the testing probe is arranged on the output seat;

when the sliding rod slides, the test probe is used for contacting with the test terminal on the base.

In one embodiment, the main transmission shaft is provided with a guide sliding groove, and the guide arc surface is located on a groove wall of the guide sliding groove.

Compared with the prior art, the utility model discloses advantage and beneficial effect below having at least:

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic structural view of a switch assembly apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a switch;

fig. 3 is a schematic structural diagram of a switch assembling apparatus according to an embodiment of the present invention;

FIG. 4 is an enlarged schematic view of FIG. 1 at A;

fig. 5 is a schematic structural view of a switch assembly apparatus according to another embodiment of the present invention;

fig. 6 is an exploded view of a switch assembly apparatus according to an embodiment of the present invention;

fig. 7 is a schematic view of an internal structure of a switch assembly apparatus according to an embodiment of the present invention;

FIG. 8 is an enlarged schematic view at B of FIG. 7;

fig. 9 is a schematic structural view of another angle of the switch assembling apparatus according to an embodiment of the present invention;

fig. 10 is an enlarged schematic view at C of fig. 1.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1, the switch assembling apparatus 10 includes a conveying mechanism 100 and a processing mechanism 200, wherein the conveying mechanism 100 is used for conveying materials, and the processing mechanism 200 is used for processing the materials on the conveying mechanism 100.

It should be noted that the switch assembly apparatus 10 is used for assembling and testing switches; the conveying mechanism 100 is used for conveying materials; the processing mechanism 200 is used for assembling and testing materials.

Referring to fig. 1, the switch assembling apparatus 10 further includes a transmission mechanism 300, the transmission mechanism 300 includes a main driving member 310, a main transmission shaft 320 and a sub transmission rod 330, the main driving member 310 is used for driving the main transmission shaft 320 to rotate, the main transmission shaft 320 is provided with a guiding arc surface 340, when a sliding end 350 of the sub transmission rod 330 slides along the guiding arc surface 340, the sub transmission rod 330 is used for rotating or sliding relative to the transmission mechanism 100, and an output end 360 of the sub transmission rod 330 is used for being drivingly connected with the processing mechanism 200.

It should be noted that the main driving member 310 is used for driving the main transmission shaft 320 to rotate; the main transmission shaft 320 is used for transmitting power to the secondary transmission rod 330; the secondary transmission rod 330 is used for transmitting the power on the main transmission shaft 320 to the processing mechanism 200 so as to enable the processing mechanism 200 to work; the guide arc surface 340 is used for guiding the sliding end 350 of the secondary transfer lever 330 to move;

during the rotation of the main transmission shaft 320, the sliding end 350 of the secondary transmission rod 330 slides along the contour of the guiding arc 340, so that the secondary transmission rod 330 can rotate or slide along a predetermined track according to a predetermined period, and the output end 360 of the secondary transmission rod 330 can drive the processing mechanism 200 to work.

In addition to the above, the processing mechanism 200 may include a plurality of structures with different functions, and may be used for assembling the switch, and also for testing the switch; the number of the guiding arcs 340 may be plural, and the profile of each guiding arc 340 may be different, so as to drive each secondary transmission rod 330 to move in a sliding or rotating manner at different periods or speeds, thereby driving each different structure of the processing mechanism 200 to work at a predetermined period or speed.

Referring to fig. 2, the material 20 of the present invention includes a base 21 and a pressing handle 22, wherein the pressing handle 22 is disposed on the base 21.

First embodiment

Referring to fig. 3, in one embodiment, the transmission mechanism 300 further includes a support base 370, the secondary transmission rod 330 includes a rod 331, a roller 332 and a driving connection base 333, the rod 331 is rotatably disposed on the support base 370, one end of the rod 331 is connected to the roller 332, and the other end of the rod 331 is connected to the driving connection base 333;

in the present embodiment, the roller 332 is a sliding end 350 of the secondary lever 330, and the driving connecting seat 333 is an output end 360 of the secondary lever 330.

It should be noted that the supporting seat 370 is used for supporting the rod body 331 to rotate; the rod body 331 plays a role in transmitting power, and specifically, the rod body 331 is used for driving the driving connecting seat 333 to rotate; the roller 332 is used as the sliding end 350 of the secondary lever 330 to slide along the guiding arc 340, so that the sliding end 350 of the secondary lever 330 can be smoother during the movement process; the driving connection seat 333 is used for further transmitting the power of the rod 331 to the processing mechanism 200, so that the processing mechanism 200 works, and the processing mechanism 200 can assemble and process the material.

Further, referring to fig. 2 and fig. 3, in one embodiment, the processing mechanism 200 includes a riveting device 210, the riveting device 210 includes a riveting head 211, a riveting guide seat 212, and a riveting slider 213, the riveting head 211 is disposed on the driving connection seat 213, the riveting guide seat 212 is disposed on the transmission mechanism 100, and the riveting slider 213 is slidably disposed on the riveting guide seat 212;

when the rod 331 rotates relative to the support base 370, the rivet joint 211 is used for propping the riveting slider 213 to slide relative to the riveting guide base 212, and the riveting slider 213 is used for propping the pressing handle to be riveted on the base.

It should be noted that the riveting device 210 is used for riveting the pressing handle to the base, so as to complete the assembly of the switch; in an actual riveting process, when the rod 331 drives the driving connection seat 333 to rotate, the rivet joint 211 is driven by the driving connection seat 333 to synchronously rotate, so that the rivet joint 211 impacts the riveting slider 213, the riveting slider 213 slides relative to the riveting guide seat 212, the riveting slider 213 impacts the press handle, and the press handle is finally riveted on the base of the transmission mechanism 100.

In practical applications of the apparatus, it may be necessary to convert the arc motion of the output end 360 of the rod 331 into a linear motion in order to drive the processing mechanism 200 with different power input modes.

Referring to fig. 4 and 5, in one embodiment, the driving connecting seat 333 includes a rotating shaft 3331 and a rotating driving seat 3332, the rotating shaft 3331 is connected to the rod 3332, and the rotating driving seat 3332 is rotatably disposed on the rotating shaft 3331;

the processing mechanism 200 comprises a pressing device 220, the pressing device 220 comprises a pressing seat 221 and a pressing block 222, the pressing seat 221 is arranged on a rotation driving seat 333, and the pressing block 222 is arranged on the pressing seat 221;

when the lever body 331 rotates relative to the support seat 370, the pressing block 222 is used for propping the pressing handle.

It should be noted that the rotating shaft 3331 is disposed so that the rotating driving seat 3332 can rotate relative to the driving connecting seat 333; the rotary driving seat 3332 is used for fixing the pressing seat 221; the pressing base 221 is used for fixing the pressing block 222; the pressing block 222 is used for pressing the pressing handle on the base.

Further, in order to prevent the pressing seat 221 from irregularly swinging during the moving process, please refer to fig. 4 and 5, in one embodiment, the pressing device 220 further includes a guide block 223, the conveying mechanism 100 is provided with a guide channel 224, and the guide block 223 is slidably disposed in the guide channel 224.

So, guide block 223 is spacing by the lateral wall of guide way 224 all the time for guide block 223 can only slide along the lateral wall of guide way 224, thereby makes rotation drive seat 3332 when driving clamp seat 221 and remove, will only remove along the predetermined direction, and then has prevented that compact heap 222 from taking place the swing at the removal in-process, and then has improved compact heap 222's stability of movement.

In addition, in order to prevent the pressing base 221 from irregularly swinging during the moving process, referring to fig. 4, in another embodiment, the pressing device 220 further includes a guide block 223 and a pressing guide base, and a channel for accommodating the guide block 223 is opened on the pressing guide base.

Therefore, the guide block 223 can only be limited in the channel on the pressing guide seat, so that the pressing block 222 can only slide along a preset track, and the moving stability of the pressing block 222 is further improved.

When the sliding end 350 of the secondary transmission rod 330 is used to slide along the guiding arc 340, the secondary transmission rod 330 may drive the processing mechanism 200 to work in the above-mentioned several ways with respect to the implementation mode of the rotation of the conveying mechanism 100, however, the implementation mode of the present invention is not limited to the above-mentioned several examples, and those skilled in the art may flexibly set the transmission mechanism 300 and the processing mechanism 200 according to the difference of the actual working procedures.

Second embodiment

Referring to fig. 6 and 7, in one embodiment, the transmission mechanism 300 further includes a transmission slide carriage 380, the secondary transmission rod 330 includes a sliding rod 334, a sliding wheel 335 and an output seat 336, the sliding rod 334 is slidably disposed on the transmission slide carriage 380, one end of the sliding rod 334 is connected to the sliding wheel 335, and the other end of the sliding rod 334 is connected to the output seat 336;

the sliding wheel 335 is a sliding end 350 of the secondary lever 330, and the output seat 336 is an output end 360 of the secondary lever 330.

It should be noted that the transmission slide 380 is used for limiting the sliding rod 334, so that the sliding rod 334 can only slide along a predetermined track relative to the transmission slide 380 under the guidance of the guiding arc 340; the sliding rod 334 is used for transmitting the power of the main transmission shaft 320 to the output seat 336; the sliding wheel 335 is configured to slide along the profile of the guiding arc 340, and in the sliding process of the sliding wheel 335, because the sliding rod 334 is always limited on the transmission slide carriage 380, the sliding wheel 335 will drive the sliding rod 334 to slide together relative to the transmission slide carriage 380 under the supporting of the guiding arc 340, and further drive the output base 336 to slide synchronously.

In the practical application process of the apparatus, referring to fig. 6, fig. 7 and fig. 8 together, in order to achieve the purpose of conveying the press handle, in one embodiment, the processing mechanism 200 includes a press handle material-shifting device 230, the press handle material-shifting device 230 includes a press handle material-feeding rail 231, a dislocation seat 232 and a press handle material-shifting piece 233, the dislocation seat 232 is provided with a dislocation accommodating groove 234, the press handle material-feeding rail 231 is used for conveying the press handle to the dislocation accommodating groove 234, the dislocation seat 232 is slidably connected with the output seat 336, and the press handle material-shifting piece 233 is disposed on the output seat 336;

when the sliding rod 334 slides, the offset seat 232 slides relative to the output seat 336, and the pressing handle material stirring member 233 is used for propping the pressing handle in the offset accommodating groove 234 and moving to the conveying mechanism 100.

It should be noted that the material pushing and pulling device 230 is used for conveying the pressing handle; the pressing handle feeding rail 231 is used for guiding the pressing handle to be conveyed to the dislocation seat 232; the dislocation seat 232 is used for driving the pressing handle 22 to slide to a preset position, so that the dislocation accommodating groove 234 is communicated with the conveying mechanism 100, the pressing handle 22 can be conveyed to the conveying mechanism 100, the pressing handle can be conveyed to the base, and a subsequent mechanism can rivet the pressing handle on the base; the pressing handle material stirring piece 233 is used for propping the pressing handle to move; the offset receiving groove 234 is for receiving the pressing handle.

In the process of actually conveying the pressing handle, when the sliding rod 334 drives the output seat 336 to slide, the dislocation seat 232 moves relative to the output seat 336, so as to drive the dislocation accommodating groove 234 to move, and meanwhile, the pressing handle material stirring piece 233 also pushes the pressing handle in the dislocation accommodating groove 234 to move to the conveying mechanism 100 under the drive of the output seat 336, and then the pressing handle moves to the preset position of the base under the further pushing of the pressing handle material stirring piece 233, so that the pressing handle is riveted on the base by the equipment.

Further, in order to achieve the purpose that the dislocation seat 232 can drive the pressing handle to move to a predetermined position relative to the output seat 336 when the sliding rod 334 slides, referring to fig. 7, in one embodiment, a guiding through hole 3361 is formed on the output seat 336, the pressing handle material shifting device 230 further includes a dislocation roller 235, the dislocation roller 235 penetrates through the guiding through hole 3361, the dislocation roller 235 is rotatably connected with the dislocation seat 232, and a hole wall of the guiding through hole 3361 is used for supporting the dislocation roller 235.

The guiding through hole 3361 is used for guiding the shifting roller 235 to move; the dislocation roller 235 is used for driving the dislocation seat 232 to move; the dislocation seat 232 is limited in the predetermined channel, so that the dislocation seat 232 can only slide along the side wall of the predetermined channel.

In practical applications, since the misalignment roller 235 always penetrates through the guiding through hole 3361, when the output base 336 slides, the side wall of the guiding through hole 3361 will support the misalignment roller 235 to move, so that the misalignment base 232 moves to a predetermined position relative to the output base 336, and the pressing handle on the misalignment accommodating groove 234 can move to the transmission mechanism.

Specifically, referring to fig. 7 and 8, the pressing handle material-shifting device 230 further includes a limiting seat 236, the limiting seat 236 and the conveying mechanism 100 together form a misalignment channel 237, and the misalignment channel 237 is used for accommodating the misalignment seat 232.

Thus, it can be ensured that the dislocation seat 232 can only slide along the sidewall of the dislocation channel 237, and further, the dislocation seat 232 can drive the pressing handle to slide along the predetermined track.

For the purpose of conveying the material, please refer to fig. 1 and fig. 9 together, in one embodiment, the processing mechanism 200 includes a feeding device 240, the feeding device 240 includes a feeding guide rail 241, a feeding slide 242 and a unidirectional material feeding sheet 243, the feeding slide 242 is slidably disposed on the feeding guide rail 241, the feeding slide 242 is connected to the output base 336, and the unidirectional material feeding sheet 243 is rotatably disposed on the feeding slide 242;

wherein the one-way material feeding sheet 243 is used to support the chassis to move along the transport mechanism 100 when the sliding bar 334 slides.

It should be noted that the feeding device 240 is used for conveying materials; the feeding guide rail 241 is used for guiding the feeding slide 242 to be conveyed along a preset track; the unidirectional material feed plate 243 is used to hold the material to slide along the conveyor 100.

During the actual material conveying process, the sliding rod 334 drives the feeding slide 242 to slide along the feeding guide rail 241 through the output seat 336, and the feeding slide 242 drives the unidirectional material feeding sheet 243 to move synchronously during the sliding process, so that the unidirectional material feeding sheet 243 can push the material to move along the conveying mechanism 100.

Further, when the feeding slide 242 is driven to return, in order to prevent the unidirectional material feeding piece 243 from driving the material to retreat, referring to fig. 9, a unidirectional transmission groove 244 is formed in the feeding slide 242, and the unidirectional material feeding piece 243 is rotatably disposed in the unidirectional transmission groove 244.

Thus, when the feeding slide 242 drives the unidirectional material feeding sheet 243 to reset, that is, the unidirectional material feeding sheet 243 moves in the direction opposite to the feeding direction, the unidirectional material feeding sheet 243 lacks the limit of the unidirectional transmission groove 244 and rotates, so that the unidirectional material feeding sheet 243 cannot continuously push against the material to move; when the feeding slide 242 drives the unidirectional material feeding sheet 243 to move in the same direction as the feeding direction, the unidirectional material feeding sheet 243 and the groove wall of the unidirectional conveying groove 244 are mutually supported, so that the unidirectional material feeding sheet 243 can support the material to move in the material conveying direction.

After the switch is assembled, the switch is also required to be tested, referring to fig. 10, in one embodiment, the processing mechanism 200 includes a testing device 250, the testing device 250 includes a testing probe 251, and the testing probe 251 is disposed on the output base 336;

wherein the sliding rod 334 slides, the test probe 251 is used to contact with the test terminal on the base.

It should be noted that the testing device 250 is used for detecting the electrical property of the switch; the test probe 251 is driven by the output base 336 to be conducted with the test terminal of the base, so that the device can detect the performance of the lead of the switch.

In addition to the above two embodiments, in order to smoothly guide the sliding end 350 of the secondary transmission rod 330 to slide along the predetermined track, please refer to fig. 3, fig. 6, fig. 7 and fig. 9, in one embodiment, the main transmission shaft 320 is provided with a guiding sliding slot 321, and the guiding arc surface 340 is located on a groove wall of the guiding sliding slot 321.

It should be noted that the guiding sliding slot 321 is used for limiting the sliding end 350 of the secondary transmission rod 330; during the rotation of the main transmission shaft 320, the sliding end 350 is always limited in the guiding sliding groove 321, so as to drive the secondary transmission rod 330 to rotate or slide at a predetermined period or speed.

In addition, according to different practical application scenarios, the moving track, the moving period, and the moving speed of the secondary transfer rod 330 can be adjusted by opening the guide sliding groove 321 into different profiles, so as to adapt to the processing mechanisms 200 with different structures.

In another embodiment, referring to fig. 5, a cam 322 is disposed on the main transmission shaft 320, and the guiding arc surface 340 is disposed on the cam 322.

Thus, the sliding end 350 will slide along the surface profile of the cam 322, and at the same time, since the cam 322 itself is incompressible, it can apply a force to the secondary lever 330 through the cam 322 and further transmit the force to the processing mechanism 200, and the fitting portion needs to be pressed or riveted.

the utility model discloses a switch assembling device relates to the technical field of assembling devices, and is provided with a conveying mechanism, a processing mechanism and a transmission mechanism, wherein the conveying mechanism is used for conveying materials, and the transmission mechanism is used for transmitting power to the processing mechanism so that the processing mechanism can process the materials; in the practical application process, can set up a plurality of guide cambered surfaces on always transmitting the axle, every guide cambered surface one-to-one guides a time transaxle to rotate or slide to make each time the transaxle can carry out power input to a plurality of processing mechanisms, generally speaking, use the rotation of the total transaxle of single total drive piece drive to can drive a plurality of processing mechanisms, solved the technical problem that needs set up the power original paper to each station respectively among the prior art, still improved the whole day compactness of equipment when having practiced thrift equipment cost.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims

1. The utility model provides a switch equipment, includes transport mechanism and processing agency, transport mechanism is used for conveying the material, processing agency is used for to material on the transport mechanism processes, its characterized in that still includes:

the transmission mechanism comprises a main driving piece, a main transmission shaft and a secondary transmission rod, the main driving piece is used for driving the main transmission shaft to rotate, a guide arc surface is arranged on the main transmission shaft, the sliding end of the secondary transmission rod is used for rotating or sliding relative to the transmission mechanism when sliding along the guide arc surface, and the output end of the secondary transmission rod is used for being in driving connection with the processing mechanism.

2. The switch assembly device of claim 1, wherein the transmission mechanism further includes a support base, the secondary transmission rod includes a rod, a roller and a driving connection base, the rod is rotatably disposed on the support base, one end of the rod is connected to the roller, and the other end of the rod is connected to the driving connection base;

3. The switch assembly device according to claim 2, wherein the processing mechanism includes a riveting device including a riveting head, a riveting guide seat and a riveting slider, the riveting head is disposed on the driving connection seat, the riveting guide seat is disposed on the conveying mechanism, and the riveting slider is slidably disposed on the riveting guide seat;

4. The switch assembly device according to claim 2, wherein the driving connection seat includes a rotation shaft connected to the rod body and a rotation driving seat rotatably disposed on the rotation shaft;

5. The switch assembly device according to claim 1, wherein the transmission mechanism further comprises a transmission slide, the secondary transmission rod comprises a sliding rod, a sliding wheel and an output seat, the sliding rod is slidably disposed on the transmission slide, one end of the sliding rod is connected with the sliding wheel, and the other end of the sliding rod is connected with the output seat;

6. The switch assembly equipment according to claim 5, wherein the processing mechanism comprises a press handle material shifting device, the press handle material shifting device comprises a press handle material feeding rail, a dislocation seat and a press handle material shifting piece, the dislocation seat is provided with a dislocation accommodating groove, the press handle material feeding rail is used for conveying the press handle to the dislocation accommodating groove, the dislocation seat is connected with the output seat in a sliding manner, and the press handle material shifting piece is arranged on the output seat;

7. The switch assembling equipment according to claim 6, wherein the output seat is provided with a guiding through hole, the pressing handle material shifting device further comprises a dislocation roller, the dislocation roller penetrates through the guiding through hole, the dislocation roller is rotatably connected with the dislocation seat, and the hole wall of the guiding through hole is used for being mutually supported by the dislocation roller.

8. The switch assembly equipment according to claim 5, wherein the processing mechanism comprises a feeding device, the feeding device comprises a feeding guide rail, a feeding slide and a one-way feeding sheet, the feeding slide is slidably disposed on the feeding guide rail, the feeding slide is connected with the output base, and the one-way feeding sheet is rotatably disposed on the feeding slide;

9. The switch assembly device of claim 5, wherein the machining mechanism includes a testing device including a test probe disposed on the output block;

10. The switch assembling equipment according to claim 1, wherein the main transmission shaft is provided with a guide sliding groove, and the guide arc surface is located on a groove wall of the guide sliding groove.