CN114210484A - Graphene capillary graphene coating repairing device - Google Patents

Abstract

The invention relates to the field of graphene, in particular to a graphene capillary tube graphene coating repairing device. The technical problem is as follows: the fixture is easy to damage the capillary tube in the graphene coating spraying process of the graphene capillary tube, and the firmness of the graphene coating of the capillary tube cannot be detected. The technical scheme is as follows: a graphene capillary graphene coating repairing device comprises a working machine bottom plate, a supporting connection column, a first gathering and scattering fixing system, a second gathering and scattering fixing system and a coating spraying system; four supporting and connecting columns are fixedly connected to the top of the bottom plate of the working machine. The method and the device realize the effects of performing coating spraying repair on the capillary tube with the damaged surface graphene coating, repeatedly dispersing and gathering, enabling the damaged area on the surface of the capillary tube to be completely covered and repaired by the graphene coating, drying the capillary tube, erasing redundant coating on the surface of the capillary tube, and detecting the coating firmness on the surface of the capillary tube with the dried surface coating.

Description

Graphene capillary graphene coating repairing device

Technical Field

The invention relates to the field of graphene, in particular to a graphene capillary tube graphene coating repairing device.

Background

At present, in the prior art, when a capillary tube is used, a graphene coating on the surface of the capillary tube is damaged under the condition of abrasion in use, in the repairing process, the graphene coating on the surface of the capillary tube needs to be sprayed again, the diameter of the capillary tube is small, a plurality of capillary tubes can be sprayed only at one time, in the industrial operation process, a hard metal clamp is often adopted to clamp the plurality of capillary tubes, and the capillary tubes are easy to deform in an extrusion manner, so that the capillary tubes cannot be normally used; meanwhile, when a plurality of capillaries are subjected to paint spraying at one time, the capillaries are mostly gathered when being clamped and sprayed, so that the inner capillaries can be attached with paint only by soaking the outer paint into the inner capillaries, the efficiency is low, and part of the inner capillaries cannot be attached with paint, namely, the gathered capillaries cannot be dispersedly arranged by the existing clamp, and the spraying effect is poor; and after the spraying on the surface of the capillary tube is finished and the capillary tube is dried, the surface of the capillary tube is not subjected to firmness detection, so that the capillary tube with part of coatings unstable is put into use, and the graphene coating is easy to fall off.

To solve the problems, a graphene capillary graphene coating repairing device is provided.

Disclosure of Invention

In order to overcome the defect that the graphene coating on the surface of the capillary tube is damaged when the graphene coating on the surface of the capillary tube is worn in use in the process of using the capillary tube in the prior art, the graphene coating on the surface of the capillary tube needs to be sprayed again in the repairing process, the diameter of the capillary tube is small, a plurality of capillary tubes can be sprayed at one time, and in the industrial operation process, a hard metal clamp is often adopted to clamp the plurality of capillary tubes, so that the capillary tubes are easy to deform in an extrusion manner, and cannot be normally used; meanwhile, when a plurality of capillaries are subjected to paint spraying at one time, the capillaries are mostly gathered when being clamped and sprayed, so that the inner capillaries can be attached with paint only by soaking the outer paint into the inner capillaries, the efficiency is low, and part of the inner capillaries cannot be attached with paint, namely, the gathered capillaries cannot be dispersedly arranged by the existing clamp, and the spraying effect is poor; and after capillary surface spraying is accomplished and dries, do not carry out the fastness to its surface and detect, lead to the insecure capillary of partial coating to put into use, the shortcoming that graphite alkene coating very easily drops, technical problem: provided is a graphene capillary graphene coating repairing device.

The technical scheme is as follows: a graphene capillary graphene coating repairing device is characterized by comprising a working machine bottom plate, a supporting connecting column, a working machine bed plate, an electric moving assembly, a moving bearing part, a first gathering and scattering fixing system, a second gathering and scattering fixing system, a coating spraying system and a capillary surface detection system; the top of the bottom plate of the working machine is fixedly connected with four supporting and connecting columns; the top parts of the four supporting and connecting columns are fixedly connected with a working machine bed plate; the top of the working machine tool plate is provided with an electric moving assembly; the top of the electric moving component is connected with a moving bearing part in a sliding way; the top of the movable bearing part is provided with a first collecting and dispersing fixing system; a second dispersion fixing system is arranged on the rear side of the movable bearing part at the top of the working machine tool plate; a coating spraying system for spraying capillary tubes is arranged at the top of the working machine tool plate; the coating spraying system is positioned above the middle position of the first dispersion fixing system and the second dispersion fixing system; the middle part of the working machine tool plate is provided with a capillary tube surface detection system.

Preferably, the second dispersion fixing system comprises a mounting vertical column, a connecting mounting short plate, a dispersion bearing control assembly and a dispersion fixing assembly; the top of the working machine tool plate is provided with a mounting vertical column; the top of the mounting vertical column is fixedly connected with a connecting mounting short plate; the mounting vertical column is connected with a gathering and scattering bearing control assembly; the top of the connecting installation short plate is provided with a gathering and scattering fixing component; the lower side of the gathering and scattering fixing component is connected with the gathering and scattering bearing control component; the second diverging fixation system has the same structure as the first diverging fixation system.

Preferably, the gathering and scattering bearing control assembly comprises a first opening and closing control electric rotating shaft, a first open-close plate, a second open-close plate and a multi-groove rubber ribbon board; a first opening and closing control electric rotating shaft is arranged at the top of the front side of the mounting vertical column; the front side and the rear side of the outer ring surface of the first opening and closing control electric rotating shaft are connected with a first opening and closing plate; the middle part of the outer ring surface of the first opening and closing control electric rotating shaft is connected with a second opening and closing plate; the tops of the first plywood and the second plywood are connected with a multi-groove rubber slat; a rectangular through hole is formed in the middle of the multi-groove rubber slat; the upper side of the outer surface of the multi-groove rubber slat is connected with a gathering and scattering fixing component.

Preferably, the anti-extrusion damage assembly comprises a first installation strip plate, an anti-folding spring and a second installation strip plate; a first installation batten is connected in the rectangular through hole of the multi-groove rubber batten; a plurality of anti-folding springs are equidistantly arranged at the top of the first mounting strip; a second installation batten is arranged on the plurality of anti-folding spring tops; the second mounting batten is connected to the top in the rectangular through hole of the multi-groove rubber batten.

Preferably, the gathering and scattering fixing assembly comprises a first electric slide rail frame, a first electric slide seat, an installation inserting column, a connecting seat and a rubber strip cover plate; the top of the connecting installation short plate is fixedly connected with a first electric slide rail frame; the front side in the first electric slide rail frame is connected with a first electric slide seat in a sliding way; the front part of the first electric sliding seat is fixedly connected with an installation inserting column; the mounting inserting column is fixedly inserted with a connecting seat; the bottom of the connecting seat is connected with a rubber strip cover plate; the rubber strip cover plate is sleeved on the upper side of the outer surface of the multi-groove rubber slat.

Preferably, the coating spraying system comprises a first mounting support plate, a second electric slide rail column and a spraying assembly; a first mounting support plate is arranged on the left side of the top of the working machine tool plate; a second mounting support plate is arranged on the right side of the top of the working machine tool plate; the first mounting support plate and the second mounting support plate are positioned on two sides of the first scattering fixing system and the second scattering fixing system, and two second electric slide rail columns are symmetrically mounted between the first mounting support plate and the second mounting support plate; the outer surfaces of the two second electric slide rail columns are connected with a spraying assembly in a sliding mode.

Preferably, the spraying assembly comprises a movable mounting frame, a drying hot air pipe and a coating spray pipe; the outer surfaces of the two second electric slide rail columns are connected with a movable mounting frame in a sliding manner; a drying hot air pipe is inserted on the left side surface of the movable mounting frame; the bottom surface of the movable mounting frame is inserted with a coating spray pipe.

Preferably, the device further comprises a wiping component, wherein the wiping component comprises a first detachable mounting seat, a second detachable mounting seat, an inserted fixing rod, a first electric push rod, a second electric push rod, a first mounting frame plate, a second mounting frame plate, a first electric rotating clamping roller and a second electric rotating clamping roller; a first detachable mounting seat and a second detachable mounting seat are symmetrically mounted on the right side of the movable mounting frame; two ends of the inserted fixed rod are respectively inserted into the inner sides of the first detachable mounting seat and the second detachable mounting seat; a first electric push rod and a second electric push rod are fixedly inserted on the right side of the movable mounting frame; the outer surfaces of the telescopic ends of the first electric push rod and the second electric push rod are fixedly connected with a first mounting frame plate; the telescopic ends of the first electric push rod and the second electric push rod are fixedly connected with a second mounting frame plate; a first electric rotating clamping roller is arranged on the inner side of the first mounting frame plate; and a second electric rotating clamping roller is arranged on the inner side of the second mounting frame plate.

Preferably, the capillary surface detection system comprises a collecting channel plate, a liquid flow pipe, a first hollow channel plate, a second hollow channel plate, a first linear electric sliding rail, a second electric sliding seat, a mounting inserting plate, a second linear electric sliding rail and a friction detection assembly; the bottom of the working machine tool plate is provided with a collecting channel plate; a liquid flow pipe is fixedly inserted into the collecting channel plate; a first hollow channel plate and a second hollow channel plate are fixedly inserted at two sides above the working machine tool plate respectively; the hollow channel plate is close to the first mounting support plate, the second hollow channel plate is close to the second mounting support plate, and a first linear electric slide rail is mounted at the top of the working machine tool plate; the first linear electric sliding rail is positioned between the first hollow channel plate and the second hollow channel plate, and the top of the first linear electric sliding rail is connected with a second electric sliding seat in a sliding manner; the front side and the rear side of the second electric sliding seat are symmetrically fixedly inserted with installation batten plates; the top of the installation batten plate is provided with a second linear electric sliding rail; and the second linear electric sliding rail is connected with a friction detection assembly in a sliding manner.

Preferably, the friction detection assembly comprises a sliding installation bar, a second opening and closing control electric rotating shaft, a first opening and closing clamping plate, a second opening and closing clamping plate, a first friction fiber pad and a second friction fiber pad; the second linear electric sliding rail is connected with a sliding installation bar column in a sliding way; the top of the sliding mounting bar column is provided with a second opening and closing control electric rotating shaft; the front side and the rear side of the outer ring surface of the second opening and closing control electric rotating shaft are connected with first opening and closing clamping plates; the front middle part and the rear middle part of the outer ring surface of the second opening and closing control electric rotating shaft are connected with a second opening and closing clamp plate; the top of the first opening and closing splint is connected with a first friction fiber pad; the top of the second opening and closing splint is connected with a second friction fiber pad.

Preferably, two rows of circular drain holes are formed in the middle of the working machine bed plate.

The invention has the beneficial effects that: in order to solve the problem that in the prior art, when a capillary tube is used, a graphene coating on the surface of the capillary tube is worn in use, the graphene coating on the surface of the capillary tube is damaged, in the repairing process, the graphene capillary tube surface coating needs to be sprayed again, the diameter of the capillary tube is small, a plurality of capillary tubes can be sprayed only at one time, in the industrial operation process, a hard metal clamp is often adopted to clamp the plurality of capillary tubes, and the capillary tubes are easy to deform in an extrusion manner, so that the capillary tubes cannot be normally used; meanwhile, when a plurality of capillaries are subjected to paint spraying at one time, the capillaries are mostly gathered when being clamped and sprayed, so that the inner capillaries can be attached with paint only by soaking the outer paint into the inner capillaries, the efficiency is low, and part of the inner capillaries cannot be attached with paint, namely, the gathered capillaries cannot be dispersedly arranged by the existing clamp, and the spraying effect is poor; after the capillary tube surface is sprayed and dried, firmness detection is not carried out on the surface of the capillary tube, so that the capillary tube with part of coatings being weak is put into use, and the graphene coating is easy to fall off;

designing a first dispersion fixing system, a second dispersion fixing system, a coating spraying system and a capillary surface detection system, respectively fixing two ends of a capillary to the first dispersion fixing system and the second dispersion fixing system when in use, enabling the capillary to be arranged in a dispersion manner, connecting a coating storage tank with the coating spraying system by using a communicating pipe, namely providing a graphene coating for the coating spraying system by the coating storage tank, then controlling the first dispersion fixing system and the second dispersion fixing system to gather the capillary fixed by the first dispersion fixing system and the second dispersion fixing system, then controlling the coating spraying system to carry out re-spraying of the graphene coating on the surface of the capillary, simultaneously controlling the first dispersion fixing system and the second dispersion fixing system to drive the capillary fixed by the first dispersion fixing system and the second dispersion fixing system to repeatedly scatter and gather, enabling the surface of the capillary to be uniformly sprayed, and arranging two rows of circular drain holes in the middle part of a working machine tool plate, the redundant paint can flow out of the drain hole and is collected to a capillary tube surface detection system, the coating spraying system is controlled to wipe and dry the sprayed capillary tube after the spraying is finished, the redundant graphene paint on the surface of the capillary tube is wiped, after the paint is completely dried, the first dispersion fixing system is controlled to loosen the fixing of one side of the capillary tube, namely only the second dispersion fixing system fixes one side of the capillary tube at the moment, then the capillary tube surface detection system is controlled to detect the surface of the capillary tube, and the firmness of the graphene coating is detected;

the method and the device realize the effects of performing coating spraying repair on the capillary tube with the damaged surface graphene coating, repeatedly dispersing and gathering, enabling the damaged area on the surface of the capillary tube to be completely covered and repaired by the graphene coating, drying the capillary tube, erasing redundant coating on the surface of the capillary tube, and detecting the coating firmness on the surface of the capillary tube with the dried surface coating.

Drawings

FIG. 1 is a first perspective view of the present invention;

FIG. 2 is a second perspective view of the present invention;

FIG. 3 is a schematic perspective view of a work machine plate according to the present invention;

FIG. 4 is a schematic diagram of a first perspective structure of a second dispersal fixing system according to the present invention;

FIG. 5 is a second perspective view of a second dispersal fixing system according to the present invention;

FIG. 6 is a perspective view of the combination of the accumulation and dispersion load control assembly and the crush damage prevention assembly of the present invention;

FIG. 7 is a perspective view of the crush damage prevention assembly of the present invention;

FIG. 8 is a perspective view of the present invention;

FIG. 9 is a schematic perspective view of the coating spray system of the present invention;

FIG. 10 is a schematic perspective view of a spray assembly and wiper assembly combination of the present invention;

FIG. 11 is a perspective view of a wiping assembly of the present invention;

FIG. 12 is a schematic perspective view of a capillary surface detection system according to the present invention;

fig. 13 is a schematic perspective view of the friction detecting assembly of the present invention.

Description of reference numerals: 1_ work machine base plate, 2_ support connection column, 3_ work machine bed plate, 4_ electric moving assembly, 5_ moving carrier, 6_ first gathering and scattering fixing system, 7_ second gathering and scattering fixing system, 8_ coating spraying system, 9_ capillary surface detection system, 10_ collection box, 11_ paint storage tank, 701_ installation vertical column, 702_ connection installation short plate, 703_ first opening and closing control electric rotating shaft, 704_ first opening and closing plate, 705_ second opening and closing plate, 706_ multi-groove rubber strip, 707_ first installation strip, 708_ anti-folding spring, 709_ second installation strip, 7010_ first electric slide rail frame, 7011_ first electric slide carriage, 7012_ installation plug column, 7013_ connection seat, 7014_ rubber strip cover plate, 801_ first installation support plate, 802_ second installation support plate, 803_ second electric slide rail column, 804_ moving installation frame, 805_ drying pipe, 806_ paint spray pipe, 807_ first detachable mounting seat, 808_ second detachable mounting seat, 809_ internal insertion fixing rod, 8010_ first electric push rod, 8011_ second electric push rod, 8012_ first mounting frame plate, 8013_ second mounting frame plate, 8014_ first electric rotary clamping roller, 8015_ second electric rotary clamping roller, 901_ collecting channel plate, 902_ fluid pipe, 903_ first hollow channel plate, 904_ second hollow channel plate, 905_ first linear electric slide rail, 906_ second electric slide base, 907_ mounting insert plate, 908_ second linear electric slide rail, 909_ slide mounting bar, 9010_ second open-close control electric rotary shaft, 9011_ first open-close splint, 9012_ second open-close splint, 9013_ first friction fiber pad, 9014_ second friction fiber pad.

Detailed Description

The invention is further described with reference to the following figures and detailed description.

Example 1

A graphene capillary graphene coating repairing device is shown in figures 1-3 and comprises a working machine base plate 1, a supporting connecting column 2, a working machine bed plate 3, an electric moving assembly 4, a moving bearing part 5, a first gathering and scattering fixing system 6, a second gathering and scattering fixing system 7, a coating spraying system 8, a capillary surface detection system 9, a collecting box 10 and a coating storage tank 11; four supporting and connecting columns 2 are welded at the top of the bottom plate 1 of the working machine; the tops of the four supporting and connecting columns 2 are welded with a working machine bed plate 3; the top of the working machine bed plate 3 is connected with an electric moving assembly 4 through bolts; the top of the electric moving component 4 is connected with a moving bearing part 5 in a sliding way; the top of the movable bearing part 5 is provided with a first collecting and dispersing fixing system 6 for fixing one side of the capillary; a second dispersion fixing system 7 for fixing the other side of the capillary is arranged on the rear side of the top of the working machine bed plate 3; a coating spraying system 8 for spraying capillary tubes is arranged at the top of the working machine bed plate 3; the coating spraying system 8 is positioned above the middle position of the first dispersion fixing system 6 and the second dispersion fixing system 7; a capillary tube surface detection system 9 for performing firmness detection on the repaired capillary tube coating on the surface of the capillary tube is arranged in the middle of the working machine bed plate 3; a collecting box 10 is arranged on the right front side of the top of the bottom plate 1 of the working machine; a coating storage tank 11 is arranged at the right rear side of the top of the bed plate 3 of the working machine.

Two rows of circular drain holes are formed in the middle of the working machine tool plate.

When the graphene capillary graphene coating repairing device is used, two ends of a capillary tube are respectively fixed to a first dispersion fixing system 6 and a second dispersion fixing system 7, the capillary tubes are arranged in a dispersion manner, a coating storage tank 11 is connected with a coating spraying system 8 by using a communicating pipe, namely, the coating of a graphene coating is provided for the coating spraying system 8 through the coating storage tank 11, then the first dispersion fixing system 6 and the second dispersion fixing system 7 are controlled to gather the fixed capillary tubes, then the coating spraying system 8 is controlled to re-spray the graphene coating on the surfaces of the capillary tubes, and meanwhile, the first dispersion fixing system 6 and the second dispersion fixing system 7 are controlled to drive the fixed capillary tubes to repeatedly disperse and gather, so that the surfaces of the capillary tubes can be uniformly sprayed, and redundant coating can flow out from a drain hole in the middle part of a working machine bed plate 3 and is collected into a capillary tube surface detection system 9, after the spraying is finished, the coating spraying system 8 is controlled to wipe and dry the sprayed capillary tube, redundant graphene paint on the surface of the capillary tube is wiped off, after the paint is completely dried, the first gathering and scattering fixing system 6 is controlled to loosen the fixing of one side of the capillary tube, namely, only the second dispersion fixing system 7 fixes one side of the capillary, then the capillary surface detection system 9 is controlled to detect the surface of the capillary, the firmness of the graphene coating is detected, the qualified capillary is placed in the collection box 10, the coating spraying repair of the capillary with the damaged graphene coating on the surface is realized, and repeatedly dispersed and gathered, so that the damaged area on the surface of the capillary can be completely covered and repaired by the graphene coating, and drying the capillary tube, wiping off redundant paint on the surface of the capillary tube, and detecting the paint firmness on the surface of the capillary tube with dried surface paint.

Example 2

On the basis of the embodiment 1, as shown in fig. 4-5, the second scattering fixing system 7 comprises a mounting vertical column 701, a connecting mounting short plate 702, a scattering bearing control component, a compression damage preventing component and a scattering fixing component; the top of the working machine bedplate 3 is connected with an installation vertical column 701 through a bolt; the top of the mounting vertical column 701 is fixedly connected with a connecting mounting short plate 702; the mounting vertical column 701 is connected with a gathering and scattering bearing control assembly; the inner side of the gathering and scattering bearing control component is provided with an anti-extrusion damage component; the top of the connecting installation short plate 702 is provided with a gathering and scattering fixing component; the lower side of the gathering and scattering fixing component is connected with the gathering and scattering bearing control component; the second diverging fixation system 7 has the same structure as the first diverging fixation system 6.

The device comprises a gathering and scattering fixing assembly, a gathering and scattering bearing control assembly, a capillary tube, a pressing assembly and a pressing assembly, wherein the gathering and scattering fixing assembly is controlled to move upwards to leave the gathering and scattering bearing control assembly, one side of the capillary tube is placed on the top of the gathering and scattering bearing control assembly, the gathering and scattering fixing assembly is controlled to move downwards to clamp one side of the capillary tube, and the pressing damage prevention assembly can prevent the capillary tube from being damaged by clamping.

As shown in fig. 6, the collecting and distributing bearing control assembly includes a first opening and closing control electric spindle 703, a first opening and closing plate 704, a second opening and closing plate 705, and a multi-groove rubber strip 706; a first opening and closing control electric rotating shaft 703 is installed at the top of the front side of the installation vertical column 701; a first open-close plate 704 and a second open-close plate 705 are respectively fixedly connected to two opposite rotating parts on the outer side of the first open-close control electric rotating shaft 703; a multi-groove rubber strip 706 is adhered to the tops of the first opening plate 704 and the second opening plate 705; a rectangular through hole is formed in the middle of the multi-groove rubber slat 706; an anti-extrusion damage component is arranged in a rectangular through hole in the middle of the multi-groove rubber slat 706; the upper side of the outer surface of the multi-groove rubber strip 706 is connected with a gathering and scattering fixing component.

One side of the capillary is placed at the top of the multi-groove rubber strip 706, the capillary is arranged at the top of the multi-groove rubber strip 706 and is dispersed, at the moment, the first opening and closing control electric rotating shaft 703 is controlled to drive the first opening plate 704 and the second opening plate 705 to upwards rotate and close towards the middle, then the first opening plate 704 and the second opening plate 705 are closed to drive the two sides of the multi-groove rubber strip 706 to merge towards the middle, and then the two sides of the multi-groove rubber strip 706 merge towards the middle to drive the capillaries arranged at the top of the multi-groove rubber strip to converge towards the middle.

As shown in fig. 7, the crush damage prevention assembly includes a first mounting strip 707, a fold prevention spring 708, and a second mounting strip 709; a first installation strip 707 is bonded at the bottom in the multi-groove rubber strip 706; a plurality of anti-folding springs 708 are equidistantly arranged on the top of the first mounting strip 707; a second mounting strip 709 is mounted on the tops of the anti-folding springs 708; a second mounting strip 709 is adhered to the inner top of the multi-slot rubber strip 706.

When the both sides of multislot rubber slat 706 merge to the centre, multislot rubber slat 706 middle part position can take place to fold this moment, can press from both sides the capillary and press from both sides tight the deformation, but the elasticity of preventing folding spring 708 this moment provides the holding power, the top and the bottom that make first installation slat 707 and second installation slat 709 respectively withstand multislot rubber slat 706 inboard top and bottom, and then multislot rubber slat 706 middle part is regional by upwards propping up, can not take place to fold and produce the crease, and then can not produce the damage to the capillary.

As shown in fig. 8, the collecting and dispersing fixing component includes a first electric sliding rail frame 7010, a first electric sliding base 7011, an installation inserting column 7012, a connecting base 7013 and a rubber strip cover 7014; the top of the connecting installation short plate 702 is connected with a first electric slide rail frame 7010 through bolts; the inner side of the first electric slide rail frame 7010 is slidably connected with a first electric slide carriage 7011; the first electric sliding seat 7011 is fixedly inserted with an installation inserting column 7012; the mounting inserting column 7012 is fixedly inserted with an engaging seat 7013; a rubber strip cover plate 7014 is bonded at the bottom of the connecting seat 7013; the rubber strip cover plate 7014 is sleeved on the upper side of the outer surface of the multi-groove rubber ribbon board 706.

When the capillaries are arranged on the top of the multi-slot rubber slat 706 and the capillaries are dispersed, the first electric sliding rail frame 7010 is controlled to drive the first electric sliding seat 7011 to move downwards, that is, the first electric sliding seat 7011 drives the installation post 7012, the connecting seat 7013 and the rubber strip cover plate 7014 to move downwards, and then the rubber strip cover plate 7014 can move downwards to be sleeved on the outer side of the multi-slot rubber slat 706, and then the rubber strip cover plate 7014 fixes the capillaries to the top of the multi-slot rubber slat 706, when the multi-slot rubber slat 706 is folded upwards to drive the capillaries to fold, the first electric sliding rail frame 7010 is controlled to drive the first electric sliding seat 7011 to move upwards for a short distance, that is, the capillaries on the lower side of the multi-slot rubber slat 706 are released, and a certain gap is left so that the capillaries can be folded after the multi-slot rubber slat 706 is combined upwards.

Example 3

On the basis of the embodiment 2, as shown in fig. 9, the coating spraying system 8 comprises a first mounting support plate 801, a second mounting support plate 802, a second electric slide rail column 803, a spraying component and a wiping component; the top of the working machine bedplate 3 is welded with a first mounting support plate 801; a second mounting support plate 802 is welded at the top of the working machine bed plate 3; two second electric sliding rail columns 803 are symmetrically arranged between the first installation support plate 801 and the second installation support plate 802; the outer surfaces of the two second electric slide rail columns 803 are connected with a spraying assembly in a sliding manner; the right side of the spraying component is provided with a wiping component.

Firstly, the capillary tube is gathered, then the coating spraying system 8 is controlled to re-spray the graphene coating on the surface of the capillary tube, namely, the spraying component can downwards spray the graphene coating to the gathered surface of the capillary tube, and the second electric slide rail column 803 can be controlled to drive the spraying component and the wiping component to move, so that the uniform spraying of the spraying component on the capillary tube is realized.

As shown in fig. 10, the spraying assembly includes a movable mounting frame 804, a drying hot air duct 805 and a coating nozzle 806; the outer surfaces of the two second electric slide rail columns 803 are connected with a movable mounting frame 804 in a sliding manner; a drying hot air pipe 805 is fixedly inserted into the movable mounting frame 804; a coating spray pipe 806 is fixedly inserted into the movable mounting frame 804; the right side of the movable mounting frame 804 is provided with a wiping component.

The communicating pipe is firstly used for connecting the coating spray pipe 806, so that the coating of the graphene coating is provided for the coating spray pipe 806, namely, the coating can be sprayed out downwards from the coating spray pipe 806, and further, when the second electric slide rail drives the movable installation frame 804 to move, the movable installation frame 804 drives the coating spray pipe 806 to move, the capillary below the coating spray pipe is fully sprayed, after the spraying is finished, the wiping component is controlled to wipe the surface of the capillary, and then the drying hot air pipe 805 is controlled to spray hot air to the capillary below to dry the coating on the surface of the capillary.

As shown in fig. 11, the wiping assembly includes a first detachable mounting seat 807, a second detachable mounting seat 808, an internal insertion fixing rod 809, a first electric pushing rod 8010, a second electric pushing rod 8011, a first mounting frame plate 8012, a second mounting frame plate 8013, a first electric rotating clamping roller 8014 and a second electric rotating clamping roller 8015; a first detachable mounting seat 807 is detachably mounted on the right side of the movable mounting frame 804; a second detachable mounting seat 808 is detachably mounted on the right side of the movable mounting frame 804; a torsion spring rotating shaft socket is respectively arranged at the inner sides of the first detachable mounting seat 807 and the second detachable mounting seat 808; two sides of the inserted fixing rod 809 are movably inserted into the torsion spring sockets on the inner sides of the first detachable mounting seat 807 and the second detachable mounting seat 808 respectively; a first electric push rod 8010 is fixedly inserted at the right side of the movable mounting frame 804; a second electric push rod 8011 is fixedly inserted at the right side of the movable mounting frame 804; a first mounting frame plate 8012 is fixedly connected to the outer surfaces of the telescopic ends of the first electric push rod 8010 and the second electric push rod 8011; the telescopic ends of the first electric push rod 8010 and the second electric push rod 8011 are fixedly connected with a second mounting frame plate 8013; a first electric rotating clamping roller 8014 is arranged on the inner side of the first mounting frame plate 8012; a second motorized pivoting pinch roller 8015 is mounted inside the second mounting frame plate 8013.

Firstly, a roll of wiping absorbing cloth is sleeved outside an inner inserting fixing rod 809, then two sides of the inner inserting fixing rod 809 are inserted into a first detachable mounting seat 807 and a second detachable mounting seat 808, the first detachable mounting seat 807 and the second detachable mounting seat 808 are mounted to a movable mounting frame 804, then one side end of the wiping absorbing cloth is pulled out to pass through a gap between a first electric rotating clamping roller 8014 and a second electric rotating clamping roller 8015, then the first electric rotating clamping roller 8014 and the second electric rotating clamping roller 8015 are controlled to rotate reversely, the wiping absorbing cloth is pulled downwards, meanwhile, the first electric push rod 8010 and the second electric push rod 8011 can be controlled to extend, then the first electric push rod 8010 and the second electric push rod 8011 can drive a first mounting frame plate 8012, a second mounting frame plate 8013, the first electric rotating clamping roller 8014 and the second electric rotating clamping roller 8015 to perform horizontal fine adjustment, control first electronic rotation pinch roll 8014 and the electronic rotation pinch roll 8015 antiport of second, and then will clean the absorption cloth and pull downwards, until clean the capillary surface that absorbs the cloth bottom and contact the downside, clean the absorption with the unnecessary coating in capillary surface, remove the installing frame 804 simultaneously and can drive and clean the absorption cloth and remove, and then when cleaning the absorption cloth and remove, clean the absorption cloth and can wipe the unnecessary coating in capillary surface, control drives the capillary and disperses and gathers together repeatedly, make and clean the absorption cloth and can clean the capillary surface completely, make it accelerate the stoving, then control stoving hot-blast main 805 of drying downwards spout hot-blastly can dry it.

Example 4

Based on embodiment 3, as shown in fig. 12, a capillary surface detection system 9 includes a collecting channel plate 901, a fluid pipe 902, a first hollow channel plate 903, a second hollow channel plate 904, a first linear electric slide rail 905, a second electric slide 906, a mounting plug plate 907, a second linear electric slide rail 908, and a friction detection assembly; a collecting channel plate 901 is arranged at the bottom of the bed plate 3 of the working machine; a liquid flow pipe 902 is fixedly inserted into the collecting channel plate 901; a first hollow channel plate 903 and a second hollow channel plate 904 are fixedly inserted at two sides of the working machine bed plate 3 respectively; the top of the bed plate 3 of the working machine is connected with a first linear electric slide rail 905 by a bolt; the top of the first linear electric sliding rail 905 is connected with a second electric sliding seat 906 in a sliding manner; the second electric sliding seat 906 is fixedly inserted with a mounting batten plate 907; a second linear electric sliding rail 908 is arranged at the top of the installation batten plate 907; the second linear electric rail 908 is slidably connected to a friction detecting assembly.

Unnecessary coating can flow down to collect inside the canal board 901 and be collected, then the coating flows out from flowing liquid pipe 902, and then can use the container to collect the coating, after the coating on capillary surface is dried, the capillary is in the state of scattering this moment, then control first linear electric slide rail 905 and drive second electric slide seat 906 and move, then second electric slide seat 906 drives installation plug board 907, second linear electric slide rail 908 and friction detection subassembly and moves, then can control friction detection subassembly and detect the capillary surface.

As shown in fig. 13, the friction detecting assembly includes a sliding mounting bar 909, a second opening and closing control electric rotating shaft 9010, a first opening and closing clamp 9011, a second opening and closing clamp 9012, a first friction fiber pad 9013, and a second friction fiber pad 9014; the second linear electric sliding rail 908 is connected with a sliding mounting bar 909 in a sliding manner; the top of the sliding mounting bar 909 is provided with a second opening and closing control electric rotating shaft 9010; two opposite rotating parts at the outer side of the second opening and closing control electric rotating shaft 9010 are respectively connected with a first opening and closing clamp plate 9011 and a second opening and closing clamp plate 9012; the top of the first opening and closing splint 9011 is connected with a first friction fiber pad 9013; the top of the second opening and closing splint 9012 is connected with a second friction fiber pad 9014.

When the first linear electric slide rail 905 drives the second electric slide rail 906 to move, then the second electric slide rail 906 drives the installation batten plate 907, the second linear electric slide rail 908 and the friction detection component to move, so that the friction detection component moves below one capillary, then the second opening and closing control electric rotating shaft 9010 is controlled to drive the first opening and closing clamp plate 9011 and the second opening and closing clamp plate 9012 to upwards merge and rotate, namely the first opening and closing clamp plate 9011 and the second opening and closing clamp plate 9012 upwards move to respectively drive the first friction fiber pad 9013 and the second friction fiber pad 9014 to upwards merge, namely the first friction fiber pad 9013 and the second friction fiber pad 9014 clamp the capillary, and then the second linear electric slide rail 908 is controlled to drive the friction detection component to integrally move, so that the first friction fiber pad 9013 and the second friction fiber pad 9014 clamp and move on the surface of the capillary, namely the first friction fiber pad 9013 and the second friction fiber pad 9014 clamp the capillary and perform moving friction, and then the weak coating of the graphene coating on the surface of the capillary tube can be attached to the surfaces of the first friction fiber pad 9013 and the second friction fiber pad 9014 by friction, namely, the surfaces of the first friction fiber pad 9013 and the second friction fiber pad 9014 are black at the moment, so that the defect that the graphene coating on the surface of the capillary tube is unqualified to repair is proved, and the repair is needed again.

Although embodiments of the present invention have been shown and described, it would be appreciated by those skilled in the art that changes may be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.

Claims (10)

1. A graphene capillary graphene coating repairing device is characterized by comprising a working machine base plate (1), a supporting connecting column (2), a working machine bed plate (3), an electric moving assembly (4), a moving bearing part (5), a first scattering fixing system (6), a second scattering fixing system (7), a coating spraying system (8) and a capillary surface detection system (9);

the top of the working machine bottom plate (1) is fixedly connected with four supporting and connecting columns (2);

the top parts of the four supporting and connecting columns (2) are fixedly connected with a working machine bed plate (3);

the top of the working machine bed plate (3) is provided with an electric moving assembly (4);

the top of the electric moving component (4) is connected with a moving bearing part (5) in a sliding way;

the top of the movable bearing part (5) is provided with a first gathering and scattering fixing system (6);

a second dispersion fixing system (7) is arranged on the rear side of the movable bearing part (5) at the top of the working machine bed plate (3);

a coating spraying system (8) for spraying capillary tubes is arranged at the top of the working machine bed plate (3); the coating spraying system (8) is positioned above the middle position of the first dispersion fixing system (6) and the second dispersion fixing system (7);

the middle part of the working machine bed plate (3) is provided with a capillary surface detection system (9).

2. The graphene capillary graphene coating repairing device according to claim 1, wherein the second scattering fixing system (7) comprises a mounting vertical column (701), a joint mounting short plate (702), a scattering bearing control component and a scattering fixing component; the top of the working machine bed plate (3) is provided with an installation vertical column (701); the top of the mounting vertical column (701) is fixedly connected with a connecting mounting short plate (702); the mounting vertical column (701) is connected with a gathering and scattering bearing control assembly; the top of the connecting installation short plate (702) is provided with a gathering and scattering fixing component; the lower side of the gathering and scattering fixing component is connected with the gathering and scattering bearing control component; the second diverging fastening system (7) has the same structure as the first diverging fastening system (6).

3. The graphene capillary graphene coating repairing device according to claim 2, wherein the collecting and scattering bearing control assembly comprises a first opening and closing control electric rotating shaft (703), a first opening and closing plate (704), a second opening and closing plate (705) and a multi-groove rubber strip plate (706); the top of the front side of the mounting vertical column (701) is provided with a first opening and closing control electric rotating shaft (703); the front side and the rear side of the outer ring surface of the first opening and closing control electric rotating shaft (703) are connected with a first opening and closing plate (704); the middle part of the outer ring surface of the first opening and closing control electric rotating shaft (703) is connected with a second opening and closing plate (705); the tops of the first split plate (704) and the second split plate (705) are connected with a multi-groove rubber lath (706); a rectangular through hole is formed in the middle of the multi-groove rubber slat (706); the upper side of the outer surface of the multi-groove rubber strip (706) is connected with a gathering and scattering fixing component.

4. The graphene capillary graphene coating repair device according to claim 3, further comprising a crush damage prevention assembly, wherein the crush damage prevention assembly comprises a first mounting strip (707), a folding prevention spring (708) and a second mounting strip (709); a first installation strip plate (707) is connected in a rectangular through hole of the multi-groove rubber strip plate (706); a plurality of anti-folding springs (708) are equidistantly arranged on the top of the first mounting strip (707); a second mounting strip plate (709) is mounted on the tops of the anti-folding springs (708); the second mounting strip (709) is connected to the inner top of the rectangular through hole of the multi-groove rubber strip (706).

5. The graphene capillary graphene coating repairing device according to claim 4, wherein the collecting and dispersing fixing assembly comprises a first electric sliding rail frame (7010), a first electric sliding base (7011), an installation inserting column (7012), a connecting base (7013) and a rubber strip cover plate (7014); the top of the connecting installation short plate (702) is fixedly connected with a first electric sliding rail frame (7010); a first electric sliding seat (7011) is connected to the front side in the first electric sliding rail frame (7010) in a sliding manner; the front part of the first electric sliding seat (7011) is fixedly connected with an installation inserting column (7012); a connecting seat (7013) is fixedly inserted on the mounting inserting column (7012); the bottom of the connecting seat (7013) is connected with a rubber strip cover plate (7014); the rubber strip cover plate (7014) is sleeved on the upper side of the outer surface of the multi-groove rubber strip plate (706).

6. The graphene capillary graphene coating repair device according to claim 5, wherein the coating spraying system (8) comprises a first mounting support plate (801), a second mounting support plate (802), a second electric slide rail column (803) and a spraying component; a first mounting support plate (801) is mounted on the left side of the top of the working machine bed plate (3); a second mounting support plate (802) is arranged on the right side of the top of the working machine bed plate (3); the first installation support plate (801) and the second installation support plate (802) are positioned at two sides of the first scattering fixing system (6) and the second scattering fixing system (7), and two second electric slide rail columns (803) are symmetrically installed between the first installation support plate (801) and the second installation support plate (802); the outer surfaces of the two second electric slide rail columns (803) are connected with a spraying assembly in a sliding mode.

7. The graphene capillary graphene coating repairing device according to claim 6, wherein the spraying assembly comprises a movable mounting frame (804), a drying hot air pipe (805) and a coating spray pipe (806); the outer surfaces of the two second electric slide rail columns (803) are connected with a movable mounting frame (804) in a sliding manner; a drying hot air pipe (805) is inserted on the left side surface of the movable mounting frame (804); the bottom surface of the movable mounting frame (804) is inserted with a paint spray pipe (806).

8. The graphene capillary graphene coating repairing device according to claim 7, further comprising a wiping component, wherein the wiping component comprises a first detachable mounting seat (807), a second detachable mounting seat (808), an internal insertion fixing rod (809), a first electric push rod (8010), a second electric push rod (8011), a first mounting frame plate (8012), a second mounting frame plate (8013), a first electric rotating clamping roller (8014) and a second electric rotating clamping roller (8015); a first detachable mounting seat (807) and a second detachable mounting seat (808) are symmetrically mounted on the right side of the movable mounting frame (804); two ends of an inserted fixing rod (809) are respectively inserted into the inner sides of the first detachable mounting seat (807) and the second detachable mounting seat (808); a first electric push rod (8010) and a second electric push rod (8011) are fixedly inserted at the right side of the movable mounting frame (804); a first mounting frame plate (8012) is fixedly connected to the outer surfaces of the telescopic ends of the first electric push rod (8010) and the second electric push rod (8011); the telescopic ends of the first electric push rod (8010) and the second electric push rod (8011) are fixedly connected with a second mounting frame plate (8013); a first electric rotating clamping roller (8014) is arranged on the inner side of the first mounting frame plate (8012); a second electric rotating clamping roller (8015) is arranged on the inner side of the second mounting frame plate (8013).

9. The graphene capillary graphene coating repairing device according to claim 8, wherein the capillary surface detection system (9) comprises a collecting channel plate (901), a liquid flowing pipe (902), a first hollow channel plate (903), a second hollow channel plate (904), a first linear electric sliding rail (905), a second electric sliding carriage (906), a mounting plug plate (907), a second linear electric sliding rail (908) and a friction detection assembly; a collecting channel plate (901) is arranged at the bottom of the working machine bed plate (3); a liquid flow pipe (902) is fixedly inserted into the collecting channel plate (901); a first hollow channel plate (903) and a second hollow channel plate (904) are fixedly inserted at two sides above the working machine bed plate (3) respectively; the hollow channel plate (903) is close to the first installation supporting plate (801), the second hollow channel plate (904) is close to the second installation supporting plate (802), and a first linear electric sliding rail (905) is installed at the top of the working machine bed plate (3); the first linear electric sliding rail (905) is positioned between the first hollow channel plate (903) and the second hollow channel plate (904), and the top of the first linear electric sliding rail (905) is connected with a second electric sliding seat (906) in a sliding manner; the front side and the rear side of the second electric sliding seat (906) are symmetrically fixedly inserted with mounting plug board (907); a second linear electric sliding rail (908) is arranged at the top of the installation batten plate (907); and a friction detection assembly is connected on the second linear electric sliding rail (908) in a sliding way.

10. The graphene capillary graphene coating repairing device according to claim 9, wherein the friction detection assembly comprises a sliding installation bar (909), a second opening and closing control electric rotating shaft (9010), a first opening and closing clamp plate (9011), a second opening and closing clamp plate (9012), a first friction fiber pad (9013) and a second friction fiber pad (9014); a sliding installation bar column (909) is connected on the second linear electric sliding rail (908) in a sliding way; the top of the sliding mounting bar (909) is provided with a second opening and closing control electric rotating shaft (9010); the front side and the rear side of the outer ring surface of the second opening and closing control electric rotating shaft (9010) are connected with a first opening and closing clamp plate (9011); the front middle part and the rear middle part of the outer ring surface of the second opening and closing control electric rotating shaft (9010) are connected with a second opening and closing clamp plate (9012); the top of the first opening and closing splint (9011) is connected with a first friction fiber pad (9013); the top of the second opening and closing splint (9012) is connected with a second friction fiber pad (9014).

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