CN111129912B - Automatic assembling equipment for 5G backboard connector - Google Patents

Abstract

The invention discloses automatic assembling equipment for a 5G backboard connector, which comprises a cutting bridge machine and an automatic assembling machine which are sequentially arranged from front to back; the automatic assembly machine comprises a second frame, a second control device, a second feeding device, a first CCD detection device, a high-voltage measurement device, a second CCD detection device, an inner cover assembly device, an inner cover detection device, an outer cover assembly device, an outer cover riveting device, an outer cover detection device, a hot melting device, an inner cover and outer cover contact detection device, a third CCD detection device, a defective product cutting and removing device and a third feeding device, wherein the second control device, the second feeding device, the first CCD detection device, the high-voltage measurement device, the second CCD detection device, the inner cover assembly device, the outer cover riveting device, the outer cover detection device, the hot melting device, the inner cover and outer cover contact detection device, the third CCD detection device and the third feeding device are arranged on the second frame. Through the cooperation utilization each device, can carry out automatic assembly, detection and defective products to 5G backplate connector and get rid of, the whole process need not the manual work and touches the finished product semi-manufactured goods, effectively improves the production efficiency of product, reduces the manpower loss to greatly reduced cost of labor offers convenience for the production operation.

Description

Automatic assembling equipment for 5G backboard connector

Technical Field

The invention relates to the technology in the field of connector manufacturing, in particular to automatic assembly equipment for a 5G backboard connector.

Background

The backplane connector (backplane connector) is a type of connector commonly used for large-scale communication devices, ultra-high performance servers and supercomputers, industrial computers, high-end storage devices. The main function is to connect a single board (daughter card) and a back board, the single board and the back board form a 90-degree vertical structure, and the single board and the back board transmit high-speed differential signals (DIFFERENCIAL SIGNAL) or single-ended signals (SINGLE END SIGNAL) and large current.

Currently, the main structure of a back board connector applied to the 5G field generally includes a body, an inner cover and an outer cover, wherein the body is composed of an insulating board and a plurality of conductive terminals embedded and formed on the insulating body, the inner cover is covered on the body, and the outer cover is overlapped on the inner cover and riveted and fixed with the body. In the prior art, the 5G backboard connector mainly relies on manual disassembly, the whole production process needs to manually touch a finished product and a semi-finished product, the manpower loss is large, the production efficiency is low, and the labor cost is increased. Therefore, it is necessary to study a scheme to solve the above-mentioned problems.

Disclosure of Invention

In view of the above, the present invention aims at overcoming the drawbacks of the prior art, and its primary objective is to provide an automatic assembly device for a 5G backplane connector, which can effectively solve the problems of low efficiency, large manpower loss and high labor cost existing in the existing 5G backplane connector.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

an automatic assembling device for a 5G backboard connector comprises a cutting bridge machine and an automatic assembling machine which are sequentially arranged front and back;

the cutting bridge machine comprises a first frame, a first control device, a first discharging device, a first feeding device, a cutting die and a material pulling device, wherein the first control device, the first discharging device, the first feeding device, the cutting die and the material pulling device are arranged on the first frame; the first rack is provided with a first conveying trough; the first discharging device, the first feeding device, the cutting die and the material pulling device are connected with the first control device and are sequentially arranged along the first conveying trough;

The automatic assembly machine comprises a second frame, a second control device, a second feeding device, a first CCD detection device, a high-voltage measurement device, a second CCD detection device, an inner cover assembly device, an inner cover detection device, an outer cover assembly device, an outer cover riveting device, an outer cover detection device, a hot melting device, an inner cover and outer cover contact detection device, a third CCD detection device, a defective product cutting and removing device and a third feeding device, wherein the second control device, the second feeding device, the first CCD detection device, the high-voltage measurement device, the second CCD detection device, the inner cover assembly device, the inner cover detection device, the outer cover assembly device, the outer cover riveting device, the outer cover detection device, the hot melting device, the inner cover and outer cover contact detection device, the third CCD detection device, the defective product cutting and removing device and the third feeding device are arranged on the second frame; the second frame is provided with a second conveying trough, and the second conveying trough is positioned behind the first conveying trough; the second feeding device, the first CCD detection device, the high-voltage detection device, the second CCD detection device, the inner cover assembly device, the inner cover detection device, the outer cover assembly device, the outer cover riveting device, the outer cover detection device, the hot melting device, the inner cover and outer cover contact detection device, the third CCD detection device, the defective product cutting and removing device and the third feeding device are all connected with the second control device and are sequentially arranged along the second conveying trough.

As a preferable scheme, the inner cover assembling device comprises an inner cover conveying groove, an inner cover discharging mechanism, an inner cover feeding mechanism, an inner cover cutting mechanism, an inner cover suction shifting mechanism and an inner cover positioning mechanism; the inner cover conveying groove is arranged on the second frame, the inner cover discharging mechanism, the inner cover feeding mechanism, the inner cover cutting mechanism and the inner cover absorbing and shifting mechanism are sequentially arranged along the inner cover conveying groove, the inner cover absorbing and shifting mechanism is positioned between the inner cover conveying groove and the second conveying groove, and the inner cover positioning mechanism is arranged on the second conveying groove and positioned beside the output end of the inner cover absorbing and shifting mechanism.

As a preferable scheme, the outer cover assembling device comprises an outer cover conveying groove, an outer cover discharging mechanism, an outer cover feeding mechanism, an outer cover cutting mechanism, an outer cover absorbing and shifting mechanism and an outer cover positioning mechanism; the outer cover conveying groove is arranged on the second frame, the outer cover discharging mechanism, the outer cover feeding mechanism, the outer cover cutting mechanism and the outer cover absorbing and shifting mechanism are sequentially arranged along the outer cover conveying groove, the outer cover absorbing and shifting mechanism is positioned between the outer cover conveying groove and the second conveying groove, and the outer cover positioning mechanism is arranged on the second conveying groove and positioned beside the output end of the outer cover absorbing and shifting mechanism.

As a preferable scheme, the first feeding device comprises a claw piece and a driving cylinder, wherein the claw piece can be movably arranged beside the first conveying trough in a back-and-forth mode, and the driving cylinder is fixed on the first frame and drives the claw piece to move back-and-forth along the extending direction of the first conveying trough.

As a preferable scheme, the material pulling device comprises a fluted disc and a motor, wherein the fluted disc is vertically arranged beside the first conveying trough in a rotatable manner, and the motor is fixed on the first rack and drives the fluted disc to rotate.

As a preferred scheme, the hot melting device comprises a positioning seat, a heating head, a first driving mechanism and a second driving mechanism, wherein the positioning seat can be vertically movably arranged in the second conveying trough, the heating head is positioned right above the positioning seat and can be vertically movably arranged above the second conveying trough, a plurality of heating columns are convexly arranged at the bottom of the heating head, the first driving mechanism is arranged on the second rack and drives the positioning seat to vertically move, and the second driving mechanism is arranged on the second rack and drives the heating head to vertically move.

As a preferred scheme, defective products cuts discharging equipment and includes defective products collection box, baffle box and cutting mechanism, and this defective products collection box is located the below of second transport silo, and this baffle box intercommunication second transport silo and defective products collection box between, and this cutting mechanism sets up in the top of second transport silo and is located the top of baffle box.

As a preferable mode, the inner cover assembling device and the outer cover assembling device are arranged on the second rack in a bilateral symmetry mode.

Compared with the prior art, the invention has obvious advantages and beneficial effects, and in particular, the technical scheme can be as follows:

Through the cooperation utilization each device, can carry out automatic assembly, detection and defective products to 5G backplate connector and get rid of, the whole process need not the manual work and touches the finished product semi-manufactured goods, effectively improves the production efficiency of product, reduces the manpower loss to greatly reduced cost of labor offers convenience for the production operation.

In order to more clearly illustrate the structural features and efficacy of the present invention, the present invention will be described in detail below with reference to the accompanying drawings and examples.

Drawings

FIG. 1 is a perspective view of the overall structure of a preferred embodiment of the present invention;

FIG. 2 is a front view of the overall structure of the preferred embodiment of the present invention;

FIG. 3 is a perspective view of the main structure of the preferred embodiment of the present invention;

FIG. 4 is an enlarged partial schematic view of FIG. 3;

FIG. 5 is an enlarged partial schematic view of FIG. 4;

FIG. 6 is another enlarged partial schematic view of FIG. 3;

FIG. 7 is a top view of FIG. 6;

FIG. 8 is an enlarged partial schematic view of FIG. 6;

FIG. 9 is an enlarged schematic view of a first CCD detection device and a second CCD detection device in a preferred embodiment of the present invention;

FIG. 10 is an enlarged schematic view of a hot melt apparatus according to a preferred embodiment of the present invention;

FIG. 11 is an enlarged view of a third CCD detecting device and a defective product cutting and removing device according to the preferred embodiment of the present invention;

FIG. 12 is an enlarged partial schematic view of the inner cap assembly device in accordance with the preferred embodiment of the present invention;

FIG. 13 is another enlarged partial schematic view of the inner cap assembly device in accordance with the preferred embodiment of the present invention;

FIG. 14 is an enlarged view of a portion of the cover assembly device according to the preferred embodiment of the present invention;

FIG. 15 is another enlarged partial schematic view of the cover assembly device according to the preferred embodiment of the present invention;

FIG. 16 is an enlarged schematic view of the cover riveting device according to the preferred embodiment of the invention;

FIG. 17 is an exploded view of a 5G backplane connector in accordance with a preferred embodiment of the present invention;

Fig. 18 is a perspective view of the 5G backplane connector according to the preferred embodiment of the invention after assembly.

The attached drawings are used for identifying and describing:

10. Cutting bridge machine 11, first frame

12. First control device 13, first discharging device

14. First feeding device 141, jaw members

142. Driving cylinder 15 and cutting die

16. Pulling device 161 and fluted disc

162. Motor 101, first delivery chute

20. Automatic assembly machine 21, second frame

22. Second control device 23, second feeding device

24. First CCD detecting device 25 and high-voltage measuring device

26. Second CCD detecting device 27 and inner cap assembling device

271. Inner cover conveying groove 272 and inner cover discharging mechanism

273. Inner cap feeding mechanism 274 and inner cap cutting mechanism

275. Inner cap suction displacement mechanism 276 and inner cap positioning mechanism

28. Inner cap detecting device 29 and outer cap assembling device

291. Outer cover conveying groove 292 and outer cover discharging mechanism

293. Outer cover feeding mechanism 294 and outer cover cutting mechanism

295. Outer cover sucking and shifting mechanism 296 and outer cover positioning mechanism

21', Cover riveting device 22', cover detecting device

23', Hot melt device 231', positioning seat

232', Heating head 2321', heating column

233', First drive mechanism 234', second drive mechanism

24', Inner lid to outer lid contact detecting means 25', third CCD detecting means

26', Defective product cutting removal device 261', defective product collection box

262', Guide chute 263', cutting mechanism

27', Third feeding device 201, second conveying trough

30. 5G backboard connector 31 and body

311. Insulating plate 312 and conductive terminal

32. Inner cap 33, outer cap

301. Fixing column 302, material belt.

Detailed Description

Referring to fig. 1 to 16, a specific structure of a preferred embodiment of the present invention is shown, which includes a bridge cutting machine 10 and an automatic assembling machine 20 arranged in sequence.

As shown in fig. 3 to 6, the cutting bridge machine 10 includes a first frame 11, a first control device 12, a first discharging device 13, a first feeding device 14, a cutting die 15 and a material pulling device 16, which are disposed on the first frame 11.

The first frame 11 is provided with a first conveying trough 101; the first discharging device 13, the first feeding device 14, the cutting die 15 and the material pulling device 16 are connected with the first control device 12 and are sequentially arranged along the first conveying trough 101; the first discharging device 13 is a turntable type discharging device, which is used for discharging the bodies 31 of the 5G back board connectors 30 of the wound materials one by one, the specific structure and the working principle of the first discharging device 13 are all the prior art, and the specific structure of the first discharging device 13 is not described in detail herein; the first feeding device 14 is configured to convey the body 31 of the 5G back board connector 30, the first feeding device 14 includes a jaw member 141 and a driving cylinder 142, the jaw member 141 is movably disposed beside the first conveying trough 101, the driving cylinder 142 is fixed on the first frame 11 and drives the jaw member 141 to move back and forth along the extending direction of the first conveying trough 101, and the driving cylinder 142 is a cylinder; the cutting die 15 is used for cutting the material bridge on the body 31 of the 5G back board connector 30, and the specific structure and working principle of the cutting die 15 are all in the prior art, and the specific structure of the cutting die 15 will not be described in detail herein; the material pulling device 16 is used for pulling the body 31 of the 5G back plate connector 30, the material pulling device 16 includes a fluted disc 161 and a motor 162, the fluted disc 161 is rotatably and vertically disposed beside the first conveying trough 101, and the motor 162 is fixed on the first frame 11 and drives the fluted disc 161 to rotate.

The automatic assembly machine 20 comprises a second frame 21, a second control device 22, a second feeding device 23, a first CCD detection device 24, a high-voltage electric measurement device 25, a second CCD detection device 26, an inner cover assembly device 27, an inner cover detection device 28, an outer cover assembly device 29, an outer cover riveting device 21', an outer cover detection device 22', a hot melting device 23', an inner cover and outer cover contact detection device 24', a third CCD detection device 25', a defective product cutting and removing device 26' and a third feeding device 27', which are arranged on the second frame 21. The second frame 21 is provided with a second conveying trough 201, and the second conveying trough 201 is positioned behind the first conveying trough 101; the second feeding device 23, the first CCD detection device 24, the high-voltage electric measuring device 25, the second CCD detection device 26, the inner cover assembling device 27, the inner cover detection device 28, the outer cover assembling device 29, the outer cover riveting device 21', the outer cover detection device 22', the hot melting device 23', the inner cover and outer cover contact detection device 24', the third CCD detection device 25', the defective product cutting removal device 26' and the third feeding device 27' are connected with the second control device 22 and are sequentially arranged along the second conveying trough 201.

The second feeding device 23 is used for feeding the body 31 into the second conveying trough 201, and the specific structure and working principle of the second feeding device 23 are all the prior art, and the specific structure of the second feeding device 23 will not be described in detail herein.

The first CCD detecting device 24 is configured to take a photograph of the body 31 to detect whether the body 31 has a defect, as shown in fig. 9, the specific structure and working principle of the first CCD detecting device 24 are both conventional, and the specific structure of the first CCD detecting device 24 will not be described in detail herein.

The high-voltage measurement device 25 is used for performing high-voltage measurement on the body 31 to detect whether the body 31 meets the high-voltage requirement, and the specific structure and working principle of the high-voltage measurement device 25 are all in the prior art, and the specific structure of the high-voltage measurement device 25 will not be described in detail herein.

The second CCD detecting device 26 is configured to take a photograph of another position of the body 31 to detect whether a flaw exists in the other position of the body 31, as shown in fig. 9, the specific structure and working principle of the second CCD detecting device 26 are both related art, and the specific structure of the second CCD detecting device 26 will not be described in detail herein.

The inner cap assembling device 27 and the outer cap assembling device 29 are symmetrically disposed on the second frame 21, and as shown in fig. 12 and 13, the inner cap assembling device 27 includes an inner cap conveying groove 271, an inner cap discharging mechanism 272, an inner cap feeding mechanism 273, an inner cap cutting mechanism 274, an inner cap sucking and shifting mechanism 275 and an inner cap positioning mechanism 276; the inner cap conveying groove 271 is provided on the second frame 21, the inner cap discharging mechanism 272, the inner cap feeding mechanism 273, the inner cap cutting mechanism 274 and the inner cap suction shifting mechanism 275 are arranged in this order along the inner cap conveying groove 271, and the inner cap suction shifting mechanism 275 is located between the inner cap conveying groove 271 and the second conveying groove 201, the inner cap positioning mechanism 276 is provided on the second conveying groove 201 and is located beside the output end of the inner cap suction shifting mechanism 275, the inner cap discharging mechanism 272 is for discharging the inner cap 32 of the wound material, the inner cap feeding mechanism 273 is for feeding the inner cap 32 into the inner cap conveying groove 271, the inner cap cutting mechanism 274 is for cutting the inner cap 32 from the material tape, the inner cap suction shifting mechanism 275 is for sucking up the inner cap 32 and moving from the inner cap conveying groove 271 into the second conveying groove 201, and the inner cap positioning mechanism 276 is for positioning the inner cap 32 on the body 31.

The inner cap detecting device 28 is used for detecting whether the inner cap 32 is in place or not, and is mainly used for electrically measuring by a probe, and the specific structure and working principle of the inner cap detecting device 28 are all the prior art, and the specific structure of the inner cap detecting device 28 will not be described in detail herein.

As shown in fig. 14 and 15, the cover assembling device 29 includes a cover conveying groove 291, a cover discharging mechanism 292, a cover feeding mechanism 293, a cover cutting mechanism 294, a cover sucking and shifting mechanism 295 and a cover positioning mechanism 296; the cover conveying groove 291 is provided on the second frame 21, the cover discharging mechanism 2, the cover feeding mechanism 293, the cover cutting mechanism 294 and the cover sucking and shifting mechanism 295 are sequentially arranged along the cover conveying groove 291, the cover sucking and shifting mechanism 295 is positioned between the cover conveying groove 291 and the second conveying groove 201, the cover positioning mechanism 296 is provided on the second conveying groove 201 and beside the output end of the cover sucking and shifting mechanism 295, the cover discharging mechanism 292 is used for discharging the cover 33 of the wound material, the cover feeding mechanism 293 is used for feeding the cover 33 into the cover conveying groove 291, the cover cutting mechanism 294 is used for cutting the cover 33 out of the material band, the cover sucking and shifting mechanism 295 is used for sucking the cover 33 up and shifting from the cover conveying groove 291 into the second conveying groove 201, and the cover positioning mechanism 296 is used for superposing the cover 33 on the cover 32 and positioning the body 31.

The outer cover riveting device 21' is used for riveting and fixing the outer cover 33 on the body 31, and the specific structure and working principle of the outer cover riveting device 21' are all the prior art, and the specific structure of the outer cover riveting device 21' will not be described in detail herein.

The cover detection device 22' is used for detecting whether the cover 33 is in place or not, and is mainly used for electrically measuring by using a probe, and the specific structure and working principle of the cover detection device 22' are all the prior art, and the specific structure of the cover detection device 22' is not described in detail herein.

The hot-melting device 23' is configured to heat and melt the fixing column 301 on the body 31, so that the body 31 and the outer cover 33 are firmly fixed, as shown in fig. 10, the hot-melting device 23' includes a positioning seat 231', a heating head 232', a first driving mechanism 233' and a second driving mechanism 234', the positioning seat 231' is movably disposed in the second conveying trough 201 up and down, the heating head 232' is disposed right above the positioning seat 231' and movably disposed above the second conveying trough 201 up and down, a plurality of heating columns 2321' are convexly disposed at the bottom of the heating head 232', the first driving mechanism 233' is disposed on the second frame 21 and drives the positioning seat 231' to move up and down, and the second driving mechanism 234' is disposed on the second frame 21 and drives the heating head 232' to move up and down, in this embodiment, the first driving mechanism 233' and the second driving mechanism 234' are cylinders.

The inner cap and outer cap contact detecting device 24' is used for detecting whether the outer cap 33 and the inner cap 32 are in good contact, and is mainly electrically measured by a probe, and the specific structure and the working principle of the inner cap and outer cap contact detecting device 24' are all the prior art, and the specific structure of the inner cap and outer cap contact detecting device 24' will not be described in detail herein.

The third CCD detecting device 25' is used for photographing and detecting the assembled 5G back board connector 30 to detect whether the overall appearance of the 5G back board connector 30 has flaws, and the specific structure and working principle of the third CCD detecting device 25' are all of the prior art, and the specific structure of the third CCD detecting device 25' will not be described in detail herein.

The defective product cutting and removing device 26 'is used for cutting and removing defective products from the material belt 302, as shown in fig. 11, the defective product cutting and removing device 26' includes a defective product collecting box 261', a guide chute 262', and a cutting mechanism 263', the defective product collecting box 261' is located below the second conveying chute 201, the guide chute 262 'is communicated between the second conveying chute 201 and the defective product collecting box 261', and the cutting mechanism 263 'is disposed above the second conveying chute 201 and above the guide chute 262'.

The third feeding device 27' is used for feeding out the assembled and qualified 5G backplane connector 30, and the specific structure and working principle of the third feeding device 27' are all the prior art, and the specific structure of the third feeding device 27' will not be described in detail herein.

The working principle of the embodiment is described in detail as follows:

As shown in fig. 17, the 5G back plate connector 30 is composed of a body 31, an inner cover 32 and an outer cover 33, the body 31 includes an insulating plate 311 and a plurality of conductive terminals 312 insert-molded and fixed on the insulating plate 311, the inner cover 32 is laminated on the body 31 by assembling, and then the outer cover 33 is laminated on the inner cover 32.

In operation, the body 31, the inner lid 32 and the outer lid 33 of the roll material are mounted on the first discharging device 13, the inner lid discharging mechanism 272 and the outer lid discharging mechanism 292, respectively, and then the apparatus is started.

First, the first control device 12 controls the first discharging device 13, the first feeding device 14, the cutting die 15 and the pulling device 16 to work cooperatively, the first discharging device 13 discharges the bodies 31 one by one, the first feeding device 14 sends the bodies 31 into the first conveying trough 101, the cutting die 15 cuts the material bridge on the bodies 31, and the pulling device 16 pulls the bodies 31.

Next, the second control device 22 controls the second feeding device 23, the first CCD detecting device 24, the high-voltage measuring device 25, the second CCD detecting device 26, the inner cap assembling device 27, the inner cap detecting device 28, the outer cap assembling device 29, the outer cap riveting device 21', the outer cap detecting device 22', the hot melting device 23', the inner cap and outer cap contact detecting device 24', the third CCD detecting device 25', the defective product cutting removing device 26' and the third feeding device 27' to cooperate with each other to operate:

First, the second feeding device 23 feeds the body 31 into the second conveying chute 201; then, the first CCD detecting device 24 performs a photographing detection on the main body 31 to detect whether the main body 31 has a flaw; then, the high-voltage measurement device 25 performs high-voltage measurement on the body 31 to detect whether the body 31 meets the high-voltage requirement; then, the second CCD detecting device 26 performs a photographing detection on another position of the main body 31 to detect whether a flaw exists on another position of the main body 31; then, the inner cap assembling device 27 assembles the inner cap 32 to the body 31 which is qualified for detection, and does not assemble the inner cap 32 to the body 31 which is unqualified for detection; next, the inner cap detecting means 28 detects whether the inner cap 32 is mounted in place; then, the outer cap assembly means 29 assembles the outer cap 33 to the inner cap 32 that is qualified for inspection; then, the outer cap riveting device 21' rivets and fixes the outer cap 33 on the body 31; then, the cover detecting means 22' detects whether the cover 33 is mounted in place; then, the fixing column 301 on the body 31 is heated and melted by the hot melting device 23', so that the body 31 and the outer cover 33 are firmly fixed; then, the inner lid-to-outer lid contact detecting means 24' detects whether or not the outer lid 33 is in good contact with the inner lid 32; then, the third CCD detecting device 25' performs a photographing detection on the assembled 5G back board connector 30 to detect whether the overall appearance of the 5G back board connector 30 has a defect; the defective product cutting and removing device 26 'cuts and removes the defective product found in any one of the above detection stations from the material tape 302, and the defective product is collected in the defective product collection box 261'; finally, the third feeding device 27' will complete the assembly and all qualified 5G backplane connectors 30 are fed out.

The design focus of the invention is that: through the cooperation utilization each device, can carry out automatic assembly, detection and defective products to 5G backplate connector and get rid of, the whole process need not the manual work and touches the finished product semi-manufactured goods, effectively improves the production efficiency of product, reduces the manpower loss to greatly reduced cost of labor offers convenience for the production operation.

The foregoing description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so any minor modifications, equivalent changes and modifications made to the above embodiments according to the technical principles of the present invention are still within the scope of the technical solutions of the present invention.

Claims (6)

1. An automatic equipment of 5G backplate connector, its characterized in that: comprises a cutting bridge machine and an automatic assembling machine which are sequentially arranged from front to back;

the cutting bridge machine comprises a first frame, a first control device, a first discharging device, a first feeding device, a cutting die and a material pulling device, wherein the first control device, the first discharging device, the first feeding device, the cutting die and the material pulling device are arranged on the first frame; the first rack is provided with a first conveying trough; the first discharging device, the first feeding device, the cutting die and the material pulling device are connected with the first control device and are sequentially arranged along the first conveying trough;

The automatic assembly machine comprises a second frame, a second control device, a second feeding device, a first CCD detection device, a high-voltage measurement device, a second CCD detection device, an inner cover assembly device, an inner cover detection device, an outer cover assembly device, an outer cover riveting device, an outer cover detection device, a hot melting device, an inner cover and outer cover contact detection device, a third CCD detection device, a defective product cutting and removing device and a third feeding device, wherein the second control device, the second feeding device, the first CCD detection device, the high-voltage measurement device, the second CCD detection device, the inner cover assembly device, the inner cover detection device, the outer cover assembly device, the outer cover riveting device, the outer cover detection device, the hot melting device, the inner cover and outer cover contact detection device, the third CCD detection device, the defective product cutting and removing device and the third feeding device are arranged on the second frame; the second frame is provided with a second conveying trough, and the second conveying trough is positioned behind the first conveying trough; the second feeding device, the first CCD detection device, the high-voltage detection device, the second CCD detection device, the inner cover assembly device, the inner cover detection device, the outer cover assembly device, the outer cover riveting device, the outer cover detection device, the hot melting device, the inner cover and outer cover contact detection device, the third CCD detection device, the defective product cutting removal device and the third feeding device are all connected with the second control device and are sequentially arranged along the second conveying trough; the inner cover assembling device comprises an inner cover conveying groove, an inner cover discharging mechanism, an inner cover feeding mechanism, an inner cover cutting mechanism, an inner cover suction shifting mechanism and an inner cover positioning mechanism; the inner cover conveying groove is arranged on the second frame, the inner cover discharging mechanism, the inner cover feeding mechanism, the inner cover cutting mechanism and the inner cover absorbing and shifting mechanism are sequentially arranged along the inner cover conveying groove, the inner cover absorbing and shifting mechanism is positioned between the inner cover conveying groove and the second conveying groove, and the inner cover positioning mechanism is arranged on the second conveying groove and is positioned beside the output end of the inner cover absorbing and shifting mechanism; the outer cover assembly device comprises an outer cover conveying groove, an outer cover discharging mechanism, an outer cover feeding mechanism, an outer cover cutting mechanism, an outer cover suction shifting mechanism and an outer cover positioning mechanism; the outer cover conveying groove is arranged on the second frame, the outer cover discharging mechanism, the outer cover feeding mechanism, the outer cover cutting mechanism and the outer cover absorbing and shifting mechanism are sequentially arranged along the outer cover conveying groove, the outer cover absorbing and shifting mechanism is positioned between the outer cover conveying groove and the second conveying groove, and the outer cover positioning mechanism is arranged on the second conveying groove and positioned beside the output end of the outer cover absorbing and shifting mechanism.

2. The automatic 5G backplane connector assembly apparatus of claim 1, wherein: the first feeding device comprises a claw piece and a driving cylinder, wherein the claw piece can be movably arranged beside the first conveying trough in a back-and-forth mode, and the driving cylinder is fixed on the first frame and drives the claw piece to move back-and-forth along the extending direction of the first conveying trough.

3. The automatic 5G backplane connector assembly apparatus of claim 1, wherein: the material pulling device comprises a fluted disc and a motor, wherein the fluted disc is vertically arranged beside the first conveying trough in a rotatable manner, and the motor is fixed on the first rack and drives the fluted disc to rotate.

4. The automatic 5G backplane connector assembly apparatus of claim 1, wherein: the hot melting device comprises a positioning seat, a heating head, a first driving mechanism and a second driving mechanism, wherein the positioning seat can be movably arranged in the second conveying trough from top to bottom, the heating head is positioned right above the positioning seat and can be movably arranged above the second conveying trough from top to bottom, a plurality of heating columns are convexly arranged at the bottom of the heating head, the first driving mechanism is arranged on the second rack and drives the positioning seat to move from top to bottom, and the second driving mechanism is arranged on the second rack and drives the heating head to move from top to bottom.

5. The automatic 5G backplane connector assembly apparatus of claim 1, wherein: defective products cuts discharging equipment and collects box, baffle box and cutting mechanism including the defective products, and this defective products is collected the box and is located the below of second transport silo, and this baffle box intercommunication second transport silo and defective products are collected between the box, and this cutting mechanism sets up in the top of second transport silo and is located the top of baffle box.

6. The automatic 5G backplane connector assembly apparatus of claim 1, wherein: the inner cover assembling device and the outer cover assembling device are arranged on the second rack in a bilateral symmetry mode.