CN110523707B

CN110523707B - 5G connects processing apparatus

Info

Publication number: CN110523707B
Application number: CN201910820496.XA
Authority: CN
Inventors: 崔莹
Original assignee: Xiexun Electronic Jian Co Ltd
Current assignee: Xiexun Electronic Jian Co Ltd
Priority date: 2019-09-02
Filing date: 2019-09-02
Publication date: 2022-03-29
Anticipated expiration: 2039-09-02
Also published as: CN110523707A

Abstract

The invention relates to the field of 5G accessory processing, in particular to a 5G joint processing device. The rectangular accessory groove with the groove can fall towards the right side and fall towards the left side through the two rack bodies with opposite movement directions; stopping removing impurities or releasing the accessories through the two connecting seats which are close to or far away from each other; carry high-pressure air to the recess that corresponds the both ends accessory respectively through the blast pipe that sets up at both ends and carry out the edulcoration, the faint piece then can be siphoned away through dust extraction.

Description

5G connects processing apparatus

Technical Field

The invention relates to the field of 5G accessory processing, in particular to a 5G joint processing device.

Background

In recent years, the fifth generation mobile communication system 5G has become a focus of discussion in the communication industry and academia, china has entered into 5G for business for the first year, and the production scale of 5G accessories has gradually increased, and the requirement for smaller accessories is sensitive to touch, and the requirement for auxiliary accessories such as shielding iron shells thereon is very strict, and it is not allowed to contain chips or dust left by processing, and small accessories, especially accessories with grooves, are not convenient for removing impurities.

Disclosure of Invention

The invention aims to provide a 5G joint processing device which can be used for quickly removing impurities from a rectangular accessory with a groove.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a 5G connects processing apparatus, includes main pipe way, anti-sticking mechanism, processing rack, actuating mechanism, screening pipeline, clean room, stop gear, air feeder and frame, anti-sticking mechanism is connected to the upside of main pipe way, and processing rack mirror symmetry is provided with two, two processing racks all with the right side sliding connection of main pipe way, actuating mechanism and main pipe way rigid coupling, actuating mechanism and two processing rack meshing transmissions, the left end rigid couplings of screening pipeline and main pipe way, the lower extreme of clean room rigid coupling at main pipe way and screening pipeline, stop gear rigid coupling on main pipe way and screening pipeline, air feeder and clean room are connected, main pipe way and screening pipeline rigid coupling are in the frame.

Main pipeline includes flash tank, main line, slide pipe, the opening of beating, guide frame, axle bed and intercommunication mouth I, the lower extreme rigid coupling main line of flash tank, slide pipe of upside rigid coupling and intercommunication of main line right-hand member, the middle part of main line right-hand member sets up two openings of beating, axle bed of both sides rigid coupling respectively around the main line right-hand member, two axle beds all are located two between the opening of beating, be equipped with a guide frame in two openings respectively, two guide frame mirror image settings and all with the main line rigid coupling, intercommunication mouth I sets up the left end at the main line, the lower extreme of intercommunication mouth I is located directly over the opening upper end.

The anti-jamming mechanism comprises a telescopic device, a connecting plate and a pushing rod, wherein the movable end of the telescopic device is fixedly connected with the connecting plate, and the other end of the connecting plate is fixedly connected with the pushing rod; the expansion device is fixedly connected at the front end of the flash tank, and the push rod is connected in the sliding pipe in a sliding mode.

The processing rack comprises a rack body and a guide groove, and the guide groove is formed in the upper end of the rack body; two guides are sliding connection respectively in two guide slots, and two rack bodies are sliding connection respectively in two break-through mouths.

The driving mechanism comprises a motor I, a gear and a motor base I, wherein the gear is fixedly connected to an output shaft of the motor I, and the motor I is fixedly connected to the motor base I; the motor base I is fixedly connected with the front end of the main pipeline, the gear is in meshing transmission with the right end of the rack body located at the upper end, and the gear is in meshing transmission with the left end of the rack body located at the lower end.

The screening pipeline comprises a screening pipeline body and a communication port II, and the communication port II is arranged on the upper side of the right end of the screening pipeline body; screening pipeline body and the left end of main line are solid joint, and intercommunication mouth II communicates with intercommunication mouth I.

The cleaning chamber comprises a dust collection device, frames and guide plates with grooves, the rear end of the dust collection device is fixedly connected with the two frames, the two frames are arranged in a mirror symmetry mode, and the front end and the rear end of the lower end of each frame are fixedly connected with the guide plates with grooves respectively; the left frame and the right frame are respectively and fixedly connected with the lower ends of the screening pipeline body and the main pipeline.

The stopping mechanism comprises a motor base II, a stabilizing pipe, a motor II, a connecting rod I, a connecting rod II, connecting seats and guide block parts, wherein the motor base II is fixedly connected with the stabilizing pipe, the motor II is fixedly connected to the motor base II, an output shaft of the motor II is rotatably connected to the stabilizing pipe, the middle part of the connecting rod I is fixedly connected with the output shaft of the motor II, two ends of the connecting rod I are respectively hinged to one end, the other ends of the two connecting rods II are respectively hinged to one connecting seat, the two connecting seats are respectively fixedly connected to the outer ends of the two connecting seats, and the front end and the rear end of each connecting seat are respectively fixedly connected to one guide block part; the motor base II is fixedly connected at the rear ends of the two frames, the two guide block parts positioned at the left end are respectively and slidably connected in the two belt groove guide plates positioned at the left end, and the two guide block parts positioned at the right end are respectively and slidably connected in the two belt groove guide plates positioned at the right end.

The air feeder comprises a fan and an air supply pipe; two ends of the air feeder are respectively fixedly connected and communicated with an air supply pipe; the fan is fixedly connected to the rear ends of the main pipeline and the screening pipeline body, and the two air supply pipes are respectively located at the outer ends of the two frames.

And polishing the inner end surface of the main pipeline.

The 5G joint processing device has the beneficial effects that:

the expansion tank and the main pipeline fall down according to the specified direction, the accessory groove with the groove in the cuboid can fall down on the right side towards the right side and fall down on the left side towards the left side through the two rack bodies with opposite movement directions; stopping removing impurities or releasing the accessories through the two connecting seats which are close to or far away from each other; carry high-pressure air to the recess that corresponds the both ends accessory respectively through the blast pipe that sets up at both ends and carry out the edulcoration, the dust piece then can be siphoned away through dust extraction.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram showing the overall structure of a 5G joint processing device according to the present invention;

FIG. 2 is a second overall structural schematic of the present invention;

FIG. 3 is a first schematic diagram of the main conduit structure of the present invention;

FIG. 4 is a schematic view of the main duct structure of the present invention;

FIG. 5 is a partial schematic view of the main conduit of the present invention;

FIG. 6 is a schematic view of the anti-seize mechanism of the present invention;

FIG. 7 is a schematic view of a machined rack configuration of the present invention;

FIG. 8 is a schematic view of the drive mechanism of the present invention;

FIG. 9 is a schematic view of a screening conduit according to the present invention;

FIG. 10 is a schematic view of the cleaning chamber of the present invention;

FIG. 11 is a schematic view of the stop mechanism of the present invention;

FIG. 12 is a schematic view of the air feeder of the present invention;

fig. 13 is a schematic view of the internal parts of the present invention falling.

In the figure: a main conduit line 1; a flash tank 101; a main pipeline 102; a slide pipe 103; a perforating opening 104; a guide frame 105; a shaft seat 106; a communication port I107; an anti-jamming mechanism 2; a telescopic device 201; a connecting plate 202; a push rod 203; machining the rack 3; a rack body 301; a guide groove 302; a drive mechanism 4; a motor I401; a gear 402; a motor base I403; a screening pipeline 5; a screening pipe body 501; a communication port II 502; a cleaning chamber 6; a dust suction device 601; a frame 602; a grooved guide plate 603; a stop mechanism 7; a motor base II 701; a stabilizer tube 702; a motor II 703; a connecting rod I704; a connecting rod II 705; a socket 706; a seat 707; a guide block portion 708; an air feeder 8; a fan 801; a blast pipe 802; a frame 9.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

as shown in fig. 1 to 13, a 5G joint processing device comprises a main conduit path 1, an anti-seize mechanism 2, a processing rack 3, a driving mechanism 4, a screening conduit 5, a cleaning chamber 6, a stopping mechanism 7, an air feeder 8 and a rack 9, wherein the anti-seize mechanism 2 is connected to the upper side of the main conduit path 1, the processing rack 3 is arranged in mirror symmetry, the two processing racks 3 are both slidably connected to the right side of the main conduit path 1, the driving mechanism 4 is fixedly connected to the main conduit path 1, the driving mechanism 4 is in meshing transmission with the two processing racks 3, the screening conduit 5 is fixedly connected to the left end of the main conduit path 1, the cleaning chamber 6 is fixedly connected to the lower ends of the main conduit path 1 and the screening conduit path 5, the stopping mechanism 7 is fixedly connected to the main conduit path 1 and the screening conduit path 5, the air feeder 8 is connected to the cleaning chamber 6, and the main conduit path 1 and the screening conduit path 5 are fixedly connected to the rack 9. The expansion tank 101 and the main pipeline 102 fall down according to the specified direction, and the groove of the accessory with the groove of the cuboid falls down towards the right side and the groove falls down towards the left side through the two rack bodies 301 with opposite movement directions; stopping the accessory from removing impurities or releasing the accessory through two connecting seats 706 which are close to or far away from each other; the high-pressure air is respectively conveyed into the grooves corresponding to the accessories at the two ends through the air supply pipes 802 arranged at the two ends to remove impurities, and dust and debris can be sucked away through the dust suction device 601.

The second embodiment is as follows:

as shown in fig. 1-13, the main conduit line 1 includes a flash tank 101, a main conduit line 102, a sliding pipe 103, an opening 104, guide frames 105, shaft seats 106, and a communication port i 107, the lower end of the flash tank 101 is fixedly connected to the main conduit line 102, the upper side of the right end of the main conduit line 102 is fixedly connected to and communicated with the sliding pipe 103, two opening ports 104 are disposed in the middle of the right end of the main conduit line 102, the front and rear sides of the right end of the main conduit line 102 are fixedly connected to the shaft seats 106, the two shaft seats 106 are disposed between the two opening ports 104, the two opening ports 104 are respectively provided with one guide frame 105, the two guide frames 105 are arranged in a mirror image manner and are fixedly connected to the main conduit line 102, the communication port i 107 is disposed at the left end of the main conduit line 102, and the lower end of the communication port i 107 is disposed directly above the upper end of the opening ports 104. The 5G line connector fittings with grooves in the cuboid are placed in a flash tank 101, and are collectively called as the fittings or fittings with grooves in the following, the front and back thicknesses of the flash tank 101 are the same as the thinner thicknesses of the fittings, the fittings are placed in the flash tank 101 in the direction of the same thickness, the space in a main pipeline 102 is just to enable the grooves of the fittings to enter towards the right or left, the depth of the grooves is close to the length of the long sides of the fittings in the cuboid, for example, in fig. 13, two fittings with grooves exist in the main pipeline 102, and the directions of the grooves on the two fittings are opposite.

The third concrete implementation mode:

as shown in fig. 1-13, the anti-jamming mechanism 2 includes a telescopic device 201, a connecting plate 202 and a pushing rod 203, wherein the movable end of the telescopic device 201 is fixedly connected to the connecting plate 202, and the other end of the connecting plate 202 is fixedly connected to the pushing rod 203; the expansion device 201 is fixedly connected to the front end of the flash tank 101, and the push rod 203 is slidably connected in the slide pipe 103. When the upper end fitting of the main pipeline 102 cannot fall and be blocked, the telescopic device 201 is started, the telescopic device 201 can be a mechanism such as an electric telescopic rod, the movable end of the telescopic device 201 drives the push rod 203 to reciprocate, and the push rod 203 pushes the fitting in the flash tank 101 to reciprocate, so that the fitting can fall smoothly.

The fourth concrete implementation mode:

as shown in fig. 1 to 13, the processing rack 3 includes a rack body 301 and a guide groove 302, and the guide groove 302 is provided at an upper end of the rack body 301; the two guide frames 105 are respectively slidably connected in the two guide grooves 302, and the two rack bodies 301 are respectively slidably connected in the two opening holes 104. Before the screening pipeline is used, the rack body 301 at the upper end moves leftwards to the maximum stroke to block the accessories with the grooves above the rack body 301 from falling, when the accessories with the grooves are fully distributed above the rack body 301 at the upper end, the gear 402 starts to rotate in a reciprocating mode, the rack body 301 at the upper end starts to move rightwards, and the rack body 301 at the lower end starts to move leftwards, as shown in fig. 13, if the first accessory groove in contact with the rack body 301 at the upper end faces leftwards, the accessories fall onto the rack body 301 at the lower end after falling, and when the rack body 301 at the lower end starts to move rightwards, the rack body 301 at the upper end moves leftwards, the accessories are pushed leftwards to move by the rack body 301 at the upper end, and the accessories enter the screening pipeline body 501 through the communication port I107 and the communication port II 502 in sequence.

The fifth concrete implementation mode:

as shown in fig. 1-13, the driving mechanism 4 includes a motor i 401, a gear 402 and a motor base i 403, the gear 402 is fixedly connected to an output shaft of the motor i 401, and the motor i 401 is fixedly connected to the motor base i 403; the motor base I403 is fixedly connected with the front end of the main pipeline 102, the gear 402 is in meshing transmission with the right end of the rack body 301 at the upper end, and the gear 402 is in meshing transmission with the left end of the rack body 301 at the lower end. Before the electric bicycle is used, the motor I401 is started, the output shaft of the motor I401 drives the gear 402 to rotate, the motor I401 drives the gear 402 to rotate in a reciprocating mode according to a certain stroke, and the gear 402 drives the two rack bodies 301 to move in a reciprocating mode according to a certain stroke.

The sixth specific implementation mode:

as shown in fig. 1 to 13, the screening pipeline 5 includes a screening pipeline body 501 and a communication port ii 502, and the communication port ii 502 is disposed on the upper side of the right end of the screening pipeline body 501; the screening pipeline body 501 is fixedly connected with the left end of the main pipeline 102, and the communication port II 502 is communicated with the communication port I107. The rack body 301 pushes the left fitting of the groove to move leftwards, and the fitting enters the screening pipeline body 501 through the communication port I107 and the communication port II 502 in sequence.

The seventh embodiment:

as shown in fig. 1-13, the cleaning chamber 6 includes a dust collector 601, frames 602 and slotted guide plates 603, the rear end of the dust collector 601 is fixedly connected with the two frames 602, the two frames 602 are arranged in mirror symmetry, and the front and rear ends of the lower end of each frame 602 are respectively fixedly connected with a slotted guide plate 603; the left and right frames 602 are respectively fixed to the lower ends of the screening pipe body 501 and the main pipe 102. The dust extraction device 601 is activated, and the dust extraction device 601 is used to extract the dust in the two pipes, and may be a simple fan or an industrial vacuum cleaner.

The specific implementation mode is eight:

as shown in fig. 1-13, the stopping mechanism 7 includes a motor base ii 701, a stabilizing pipe 702, a motor ii 703, a connecting rod i 704, a connecting rod ii 705, a connecting seat 706, a connecting seat 707 and a guide block portion 708, the motor base ii 701 is fixedly connected with the stabilizing pipe 702, the motor ii 703 is fixedly connected to the motor base ii 701, an output shaft of the motor ii 703 is rotatably connected to the stabilizing pipe 702, the middle portion of the connecting rod i 704 is fixedly connected to the output shaft of the motor ii 703, two ends of the connecting rod i 704 are respectively hinged to one end of the connecting rod 705, the other ends of the two connecting rods ii are respectively hinged to the connecting seat 706, the two connecting seats 706 are respectively fixedly connected to the outer ends of the two connecting seats 707, and the front end and the rear end of each connecting seat 707 are respectively fixedly connected to the guide block portion 708; motor base ii 701 is fixedly connected to the rear ends of two frames 602, two guide block portions 708 at the left end are slidably connected to two belt groove guide plates 603 at the left end, and two guide block portions 708 at the right end are slidably connected to two belt groove guide plates 603 at the right end. The socket 706 is used to hold up or release the first wave fitting or to clamp down the remaining fittings.

The specific implementation method nine:

as shown in fig. 1 to 13, the air feeder 8 includes a fan 801 and a blast pipe 802; two ends of the air feeder 8 are respectively fixedly connected and communicated with an air supply pipe 802; the fan 801 is fixedly connected to the main pipeline 102 and the rear end of the screening pipeline body 501, and the two blast pipes 802 are respectively located at the outer ends of the two frames 602. The fan 801 is started, the fan 801 guides air into the two blast pipes 802, the grooves of the two fittings are blown by high air pressure blown by the two blast pipes 802, and dust or impurities in the grooves are blown out by the air pressure and are sucked away by the dust suction device 601.

The detailed implementation mode is ten:

as shown in fig. 1 to 13, the inner end surface of the main pipe 102 is subjected to polishing treatment. Avoiding influencing the falling of the fittings.

The invention relates to a 5G joint processing device, which has the working principle that:

as shown in fig. 13, two fittings with grooves are arranged in the main pipeline 102, the directions of the grooves on the two fittings are opposite, and one fitting with a groove is arranged in the screening pipeline body 501. before the screening pipeline is used, the motor i 401 is started, the output shaft of the motor i 401 drives the gear 402 to rotate, so that the motor i 401 drives the gear 402 to rotate in a reciprocating manner according to a certain stroke, the gear 402 further drives the two rack bodies 301 to move in a reciprocating manner according to a certain stroke, and the rack body 301 at the upper end moves leftwards to the maximum stroke to block the fitting with the groove above from falling; when accessories with grooves are fully distributed above the rack body 301 at the upper end, the gear 402 is made to rotate in a reciprocating mode, the rack body 301 at the upper end starts to move rightwards, and the rack body 301 at the lower end starts to move leftwards, as shown in fig. 13, if the first accessory groove in contact with the rack body 301 at the upper end faces leftwards, the accessories fall behind and fall on the rack body 301 at the lower end, when the rack body 301 at the lower end starts to move rightwards and the rack body 301 at the upper end moves leftwards, the rack body 301 at the upper end pushes the accessories to move leftwards, and the accessories enter the screening pipeline body 501 through the communication port I107 and the communication port II 502 in sequence; the fitting falling toward the right of the second groove falls on the rack body 301 at the upper end, when the rack body 301 at the upper end moves rightward, the rack body 301 at the lower end moves leftward, the fitting falls on the rack body 301 at the lower end, when the rack body 301 at the lower end starts moving rightward, the rack body 301 at the upper end moves leftward, the fitting falls, the rack body 301 at the upper end is inserted into the groove of the fitting, and the upper end of the inner end face of the fitting contacts the upper end face of the rack body 301 at the upper end, when the rack body 301 at the upper end moves rightward, the rack body 301 at the lower end moves leftward, the fitting is inserted into the groove of the fitting, the fitting continues to fall, the upper end face of the rack body 301 at the lower end contacts the upper end face of the fitting, and at this time, the fitting with the third groove falls on the upper end of the second grooved fitting, when the next two rack bodies 301 continue to move, the second accessory falls down to the connecting seat 706, if the groove direction of the third accessory with the groove is leftward, the accessory is pushed into the screening pipeline body 501, if the groove direction of the third accessory is rightward, then when the next two rack bodies 301 continue to move, the third accessory repeats the falling step of the second accessory, that is, the second accessory is inserted into the upper rack body 301, then inserted into the lower rack body 301, and finally falls onto the connecting seat 706, otherwise, the principle is the same as the above principle, as a result, the accessory with the groove leftward is screened into the screening pipeline body 501, the accessory with the groove rightward is left in the main pipeline 102, the accessories in the two pipelines both fall down onto the connecting seat 706, and at this time, the dust suction device 601 is started, and is used for sucking away the dust in the two pipelines, which can be a simple fan or an industrial dust collector, then the fan 801 is started, the fan 801 guides air into the two air supply pipes 802, the grooves of the two accessories are blown by high air pressure blown by the two air supply pipes 802, dust or impurities in the grooves are blown out by the air pressure and then are sucked away by the dust suction device 601, the motor II 703 is started, the motor II 703 drives the connecting rod I704 to swing in a reciprocating mode, the two connecting rods II 705 drive the two connecting seats 707 to move in a reciprocating mode, the two connecting seats 707 are close to or far away, when the two connecting seats 707 are far away, the accessories are not blocked by the connecting seats 707 and fall smoothly to be discharged out of the dust collector, when the two connecting seats 707 are close to each other, the next accessory is clamped at the air supply pipes 802 for dust removal, and when the two connecting seats 707 are far away again, the accessories are released.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a 5G connects processing apparatus, includes main pipe way (1), anti-sticking mechanism (2), processing rack (3), actuating mechanism (4), screening pipeline (5), clean room (6), stop gear (7), air feeder (8) and frame (9), its characterized in that: anti-sticking mechanism (2) is connected to the upside of main pipe way (1), processing rack (3) mirror symmetry is provided with two, two processing racks (3) all with the right side sliding connection of main pipe way (1), actuating mechanism (4) and main pipe way (1) rigid coupling, actuating mechanism (4) and two meshing transmissions of processing rack (3), screening pipeline (5) and the left end rigid coupling of main pipe way (1), clean-up room (6) rigid coupling is at the lower extreme of main pipe way (1) and screening pipeline (5), stop gear (7) rigid coupling is on main pipe way (1) and screening pipeline (5), air feeder (8) are connected with clearance room (6), main pipe way (1) and screening pipeline (5) rigid coupling are on frame (9).

2. The 5G splice processing device of claim 1, wherein: the main conduit (1) comprises a flash tank (101), a main conduit (102), a slide pipe (103), an opening (104), a guide frame (105), a shaft seat (106) and a communication port I (107), the lower extreme rigid coupling main line (102) of flash tank (101), the upside rigid coupling of main line (102) right-hand member communicates a slide pipe (103), the middle part of main line (102) right-hand member sets up two and beats opening (104), axle bed (106) of both sides rigid coupling respectively around main line (102) right-hand member, two axle beds (106) all are located two and beat between opening (104), be equipped with one guide frame (105) respectively in two and beat opening (104), two guide frame (105) mirror image setting and all with main line (102) rigid coupling, intercommunication mouth I (107) set up the left end at main line (102), the lower extreme of intercommunication mouth I (107) is located directly over the opening (104) upper end.

3. The 5G splice processing device of claim 2, wherein: the anti-jamming mechanism (2) comprises a telescopic device (201), a connecting plate (202) and a push rod (203), wherein the movable end of the telescopic device (201) is fixedly connected with the connecting plate (202), and the other end of the connecting plate (202) is fixedly connected with the push rod (203); the expansion device (201) is fixedly connected to the front end of the expansion tank (101), and the push rod (203) is connected in the sliding pipe (103) in a sliding mode.

4. The 5G splice processing apparatus of claim 2 or 3, wherein: the machining rack (3) comprises a rack body (301) and a guide groove (302), wherein the guide groove (302) is formed in the upper end of the rack body (301); the two guide frames (105) are respectively connected in the two guide grooves (302) in a sliding mode, and the two rack bodies (301) are respectively connected in the two punching holes (104) in a sliding mode.

5. The 5G splice processing device of claim 4, wherein: the driving mechanism (4) comprises a motor I (401), a gear (402) and a motor base I (403), the gear (402) is fixedly connected to an output shaft of the motor I (401), and the motor I (401) is fixedly connected to the motor base I (403); the motor base I (403) is fixedly connected with the front end of the main pipeline (102), the gear (402) is in meshing transmission with the right end of the rack body (301) located at the upper end, and the gear (402) is in meshing transmission with the left end of the rack body (301) located at the lower end.

6. The 5G splice processing device of claim 2, wherein: the screening pipeline (5) comprises a screening pipeline body (501) and a communication port II (502), and the communication port II (502) is arranged on the upper side of the right end of the screening pipeline body (501); the screening pipeline body (501) is fixedly connected with the left end of the main pipeline (102), and the communication port II (502) is communicated with the communication port I (107).

7. The 5G splice processing device of claim 6, wherein: the cleaning chamber (6) comprises a dust collection device (601), frames (602) and a guide plate (603) with a groove, the rear end of the dust collection device (601) is fixedly connected with the two frames (602), the two frames (602) are arranged in a mirror symmetry mode, and the front end and the rear end of the lower end of each frame (602) are respectively fixedly connected with the guide plate (603) with the groove; the left frame and the right frame (602) are respectively and fixedly connected with the lower ends of the screening pipeline body (501) and the main pipeline (102).

8. The 5G splice processing device of claim 7, wherein: the stopping mechanism (7) comprises a motor base II (701), a stabilizing pipe (702), a motor II (703), a connecting rod I (704), a connecting rod II (705), a connecting seat (706), a connecting seat (707) and a guide block part (708), wherein the motor base II (701) is fixedly connected with the stabilizing pipe (702), the motor II (703) is fixedly connected with the motor base II (701), an output shaft of the motor II (703) is rotatably connected in the stabilizing pipe (702), the middle part of the connecting rod I (704) is fixedly connected with the output shaft of the motor II (703), each end of the connecting rod I (704) is respectively hinged with one end of the connecting rod II (705), the other ends of the two connecting rods II are respectively hinged with the connecting seat (706), the two connecting seats (706) are respectively fixedly connected with the outer ends of the two connecting seats (707), and the front end and the rear end of each connecting seat (707) are respectively fixedly connected with the guide block part (708); the motor base II (701) is fixedly connected to the rear ends of the two frames (602), the two guide block parts (708) positioned at the left end are respectively and slidably connected into the two grooved guide plates (603) positioned at the left end, and the two guide block parts (708) positioned at the right end are respectively and slidably connected into the two grooved guide plates (603) positioned at the right end.

9. The 5G splice processing device of claim 8, wherein: the air feeder (8) comprises a fan (801) and an air supply pipe (802); two ends of the air feeder (8) are respectively fixedly connected and communicated with an air supply pipe (802); the fan (801) is fixedly connected to the rear ends of the main pipeline (102) and the screening pipeline body (501), and the two blast pipes (802) are respectively located at the outer ends of the two frames (602).

10. The 5G splice processing device of claim 2, wherein: the inner end surface of the main pipeline (102) is polished.