CN117644000B

CN117644000B - Composite flocking stone brick, preparation process and equipment

Info

Publication number: CN117644000B
Application number: CN202410120845.8A
Authority: CN
Inventors: 沈阳; 潘杨; 丁飞; 杨桂华
Original assignee: JIANGSU BAIDAI ENERGY-SAVING BUILDING MATERIALS CO LTD
Current assignee: JIANGSU BAIDAI ENERGY-SAVING BUILDING MATERIALS CO LTD
Priority date: 2024-01-29
Filing date: 2024-01-29
Publication date: 2024-04-05
Anticipated expiration: 2044-01-29
Also published as: CN117644000A

Abstract

The invention discloses a composite flocking stone brick, a preparation process and equipment, which comprises a bin body with an opening at the upper end, and further comprises the following components: the track plate is arranged at the upper end of the bin body; the bracket is movably arranged on the track plate, has a first state of moving horizontally along the track plate and a second state of lifting over the bin body, and can support stone brick blank to descend to close the upper end opening of the bin body in the second state of the bracket; the rubber plate is arranged on the track plate in a lifting manner and is positioned on the outer side of the bin body, and the rolling brush is rotationally arranged in the rubber plate. According to the invention, the stone brick blank is carried by the bracket in the first state to move so as to automatically brush glue, the bracket in the second state drives the stone brick blank to descend so as to seal the upper end opening of the bin body, and then electrostatic flocking is carried out, so that fluff can be prevented from flying out, and additional sealing structures and operations are saved; in addition, the rubber plate can drive the rolling brush to reduce the height before the return process after the stone brick flocking so as to avoid the adhesion of fluff.

Description

Composite flocking stone brick, preparation process and equipment

Technical Field

The invention relates to the technical field of refractory material production, in particular to a composite flocking stone brick, a preparation process and equipment.

Background

The gypsum board or gypsum brick is made of building gypsum as main raw material, and has the advantages of light weight, high strength, convenient processing, good sound insulation, heat insulation, fire resistance and other properties, is a good novel light building material, and has been widely used for inner partition walls, wall cladding panels, ceilings, acoustic boards, ground base plates, various decorative plates and the like of various buildings such as houses, office buildings, shops, hotels, industrial plants and the like.

The gypsum flocking has good water absorbability, plasticity and cohesive force, also has certain sound and heat insulation effects, can effectively improve indoor environment and life quality, and is a common means for improving the performance of gypsum building materials at present. Patent document CN111992459a discloses an electrostatic flocking device on day 17 of 11 in 2020, the technical scheme of which comprises: the device comprises a base, the up end of base is provided with retrieves box and device body, the medial surface of retrieving the box is provided with the rack, one side of retrieving the box is provided with the drawer, one side of drawer is provided with the handle, the preceding terminal surface of device body is provided with rotation axis and connector, the surface of rotation axis is provided with the closing cap, the preceding terminal surface of closing cap is provided with the observation window. The beneficial effects are that: through setting up rotation axis, closing cap and observation window, can protect the switch on the device, prevent that the device from being touched by user's mistake when the operation, avoid user's production work to receive the influence, through setting up rack, drawer and handle, can collect the flocking that shakes off on the article, the person of facilitating the use retrieves the flocking in the recovery box, for user's recovery work provides convenience.

In view of the flocking of the stone brick, the existing flocking equipment needs an additional sealing structure to seal the space where flocking occurs after the stone brick blank is put into the pile, so that a composite flocking stone brick preparation process and equipment are needed to solve the problems.

Disclosure of Invention

The invention aims to provide a composite flocking stone brick, a preparation process and equipment, so as to solve the defects in the prior art.

In order to achieve the above object, the present invention provides the following technical solutions:

the utility model provides a compound flocking stone brick preparation facilities, includes upper end open-ended storehouse body, still includes: the track plate is arranged at the upper end of the bin body; the bracket is movably arranged on the track plate, has a first state of moving horizontally along the track plate and a second state of lifting over the bin body, and can support stone brick blank to descend to close the upper end opening of the bin body in the second state of the bracket; the rubber plate is arranged on the track plate in a lifting manner and is positioned on the outer side of the bin body, and the rubber plate is rotationally provided with a rolling brush corresponding to the moving path in the first state of the bracket.

Preferably, the track board outside is provided with the drive storehouse, the activity is provided with the synchronizing plate in the drive storehouse, liftable be connected with the cantilever on the synchronizing plate, cantilever and bracket fixed connection, be provided with the drive assembly that is used for driving the synchronizing plate and the linkage subassembly that drives the cantilever and go up and down in the drive storehouse.

Preferably, the drive assembly comprises a drive plate movably arranged in the drive bin and a motor fixedly arranged outside the drive bin, a first gear is coaxially connected to the output end of the motor, a first rack meshed with the first gear is arranged on the drive plate, the synchronous plate is elastically movably connected to the drive plate along the length direction of the drive plate, and the linkage assembly is used for linkage cantilever lifting when the synchronous plate and the drive plate relatively move.

Preferably, the driving plate is connected with a polish rod which movably penetrates through the synchronous plate through two spaced abutting blocks, and a first elastic piece is arranged between one end of the synchronous plate and the corresponding side abutting block.

Preferably, the linkage assembly comprises a linkage shaft which is rotatably arranged on the synchronous plate, two ends of the linkage shaft are respectively and coaxially connected with a second gear and a third gear, a second rack meshed with the second gear is arranged on the driving plate, and a third rack meshed with the third gear is arranged on the cantilever.

Preferably, a substrate fixedly connected with the track plate is arranged at the lower side of the rubber plate, a plurality of second elastic pieces are connected between the rubber plate and the substrate, and the lifting of the rubber plate is movably linked with the driving plate.

Preferably, the track board entity is internally provided with a sliding groove, the sliding groove is internally provided with a first sliding block fixedly connected with the rubber disc in a lifting manner, the first sliding block is horizontally movably connected with a second sliding block, both ends of the driving board are respectively provided with a deflector rod, one side of the second sliding block, away from the rubber disc, is fixedly provided with a sliding rod in a movable path between the two corresponding deflector rods, the side wall of the track board is provided with a track groove matched with the sliding rod, one end of the track groove, close to the bin body, is horizontally arranged as a limiting section, and one end, away from the bin body, of the track groove is obliquely upwards arranged as a guiding section.

Preferably, the lower side of the base plate is provided with a rubber cylinder and an air pump, the air outlet end of the air pump is connected with the inner part of the rubber cylinder, the upper end of the rubber cylinder is connected with the inner part of the rubber plate through a guide pipe, and the lower end of the rubber plate is fixedly connected with an air pumping rod for driving the air pump to pump.

The preparation process of the composite flocking stone brick is based on the preparation equipment of the composite flocking stone brick, and comprises the following steps: placing stone brick blanks in a bracket in a first state, and lifting a rubber disc to enable the rolling brush to be kept in a movement path of the bracket in the first state; the bracket moves to the upper part of the bin body, so that the lower surface of the stone brick blank material is contacted with the rolling brush in a rolling way to brush glue; after the bracket corresponds to the upper part of the bin body, the bracket carries stone brick blank material to descend to seal the upper end opening of the bin body, and in addition, the rubber disc moves downwards to reduce the height of the rolling brush; electrostatic flocking is carried out on the lower surface of the stone brick blank in the bin body; the carriage is raised back to the first state and then traversed away from above the cartridge body.

The composite flocking stone brick is manufactured based on the preparation process of the composite flocking stone brick and comprises a stone brick, wherein a fluff layer is arranged on the surface of the stone brick.

In the technical scheme, the invention has the beneficial effects that:

according to the composite flocking stone brick preparation equipment, through the arrangement of the brackets in two motion states, the brackets in the first state bear stone brick raw materials to move so as to brush glue automatically, and the brackets in the second state drive the stone brick raw materials to descend so as to seal the upper end opening of the bin body, then electrostatic flocking is carried out, fluff can be prevented from flying out, and additional sealing structures and operations are saved; in addition, the rubber plate can drive the rolling brush to reduce the height before the return process after the stone brick flocking so as to avoid the adhesion of fluff.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

This document provides an overview of various implementations or examples of the technology described in this disclosure, and is not a comprehensive disclosure of the full scope or all of the features of the disclosed technology.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

FIG. 1 is a schematic diagram of an overall structure according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a driving cabin according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a relationship structure between a bracket and a driving assembly according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a glue tray according to an embodiment of the present invention;

fig. 5 is a schematic diagram of a front sectional structure of a rubber disc according to an embodiment of the present invention;

FIG. 6 is an enlarged schematic view of the structure shown in FIG. 5A according to an embodiment of the present invention;

fig. 7 is a schematic diagram of a cross-sectional front view of a linkage shaft according to an embodiment of the present invention;

FIG. 8 is an enlarged schematic view of the structure shown in FIG. 7B according to an embodiment of the present invention;

FIG. 9 is a schematic side view of a cross-sectional structure according to an embodiment of the present invention;

fig. 10 is an enlarged schematic view of the structure at C in fig. 9 according to an embodiment of the present invention.

Reference numerals illustrate:

1. a bin body; 2. a track plate; 3. a bracket; 4. a rubber plate; 5. a rolling brush; 6. a driving bin; 7. a synchronizing plate; 8. a cantilever; 9. a driving plate; 10. a motor; 11. a first gear; 12. a first rack; 13. abutting blocks; 14. a polish rod; 15. a first elastic member; 16. a linkage shaft; 17. a second gear; 18. a third gear; 19. a second rack; 20. a third rack; 21. a substrate; 22. a second elastic member; 23. a slip groove; 24. a first slider; 25. a second slider; 26. a deflector rod; 27. a sliding rod; 28. a track groove; 29. a rubber cylinder; 30. an air pump; 31. a conduit; 32. an inflation rod; 33. a kit.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present disclosure more apparent, the technical solutions of the embodiments of the present disclosure will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present disclosure. It will be apparent that the described embodiments are some, but not all, of the embodiments of the present disclosure. All other embodiments, which can be made by one of ordinary skill in the art without the need for inventive faculty, are within the scope of the present disclosure, based on the described embodiments of the present disclosure.

Referring to fig. 1 to 10, the apparatus for preparing a composite flocked stone tile according to the embodiment of the present invention includes a bin body 1 with an opening at an upper end, and further includes: the track plate 2 is arranged at the upper end of the bin body 1; the bracket 3 is movably arranged on the track plate 2, has a first state of moving horizontally along the track plate 2 and a second state of lifting over the bin body 1, and can support stone brick blank to descend to seal the upper end opening of the bin body 1 in the second state of the bracket 3; the rubber plate 4 is arranged on the track plate 2 in a lifting manner and is positioned outside the bin body 1, and a rolling brush 5 corresponding to the moving path in the first state of the bracket 3 is rotationally arranged in the rubber plate.

Specifically, the opening at the upper end of the bin body 1 is in a rectangular groove shape, the fluff is uniformly laid in the groove, an electrostatic generator is integrated in the bin body 1, the fluff can be promoted to fly upwards in a vertical acceleration shape, and the concrete principle is the prior art and is not repeated. The track plates 2 are preferably two, are horizontally arranged on two opposite sides of the bin body 1 and are parallel to each other; the two walls of the groove vertical track plate 2 are arranged to be higher and lower, and the middle position of the track plate 2 is arranged close to one side wall of the groove. The bracket 3 is rectangular and frame-shaped, is arranged between the two track plates 2, ribs are arranged on the bottom surface close to the track plates 2 on two sides, and gypsum stone bricks are light in texture and consistent in size with the bracket 3, are embedded into the bracket 3 and are supported on the two ribs; the rectangular bracket 3 is also matched with the groove at the upper end of the bin body 1; the bracket 3 in the first state is positioned at a height between the height of the side walls of the groove I and the height of the side walls II, namely the bracket 3 moving in the first state can transversely move across the side wall of the groove II and then is blocked by the side wall of the groove II; and when the bracket 3 descends to a side wall height lower than the groove, the stone bricks carried on the bracket 3 can be matched to seal the upper end opening of the bin body 1. The glue disc 4 is arranged at the outer adjacent position of the side wall corresponding to the lower side wall of the groove, and liquid adhesives such as glue are contained in the glue disc 4; the highest position of the lifting travel of the rubber disc 4 enables the height of the upper end of the rolling brush 5 to be consistent with the height of the lower surface of the stone brick borne by the bracket 3 in the first state, and then when the stone brick borne by the bracket 3 in the first state moves past the rolling brush 5, the rolling brush 5 can automatically roll and contact with the lower surface of the stone brick, namely, the rubber brushing is automatically carried out; when the rubber plate 4 descends, namely, the height of the roller brush 5 is reduced, and the roller brush 5 does not influence the stone brick carried by the bracket 3 in the first state. In actual use, the bracket 3 is in a first state and is far away from the upper end of the bin body 1, stone brick blank is placed in the bracket 3, the rubber plate 4 is at the highest position formed by lifting, and sufficient glue is contained, and the rolling brush 5 is kept in the movement path of the bracket 3 in the first state; then, the bracket 3 moves to the upper part of the bin body 1, so that the lower surface of the stone brick blank is in rolling contact with the rolling brush 5 to brush glue; after the bracket 3 corresponds to the upper part of the bin body 1, the bracket 3 carries the stone brick blank to descend to seal the upper end opening of the bin body 1, at the moment, electrostatic flocking is carried out on the lower surface of the stone brick blank in the bin body 1, and in addition, the rubber disc 4 moves downwards in advance to reduce the height of the rolling brush 5; finally, the bracket 3 rises to the first state and then transversely moves away from the upper part of the bin body 1, so that the bracket is not influenced by the rolling brush 5; and finally, after the glue is dried, the flocking of the stone brick can be completed.

Compared with the prior art, the composite flocking stone brick preparation equipment provided by the embodiment of the invention has the advantages that the brackets 3 in two motion states are arranged, the brackets 3 in the first state bear stone brick blank to move so as to brush glue automatically, the brackets 3 in the second state drive the stone brick blank to descend so as to seal the upper end opening of the bin body 1, then electrostatic flocking is carried out, fluff can be prevented from flying out, and additional sealing structures and operations are saved; in addition, the rubber plate 4 can drive the rolling brush 5 to reduce the height before the return process after the stone brick flocking so as to avoid the adhesion of fluff.

As a preferred technical scheme of the embodiment, a driving bin 6 is arranged on the outer side of the track plate 2, a synchronous plate 7 is movably arranged in the driving bin 6, a cantilever 8 is connected to the synchronous plate 7 in a lifting manner, the cantilever 8 is fixedly connected with the bracket 3, a driving component for driving the synchronous plate 7 to move and a linkage component for driving the cantilever 8 to lift are arranged in the driving bin 6, and specifically, the synchronous plate 7 moves along the length direction of the track plate 2; the side wall of the synchronous plate 7 is provided with a sleeve 33 which is penetrated up and down; the cantilever 8 is in an inverted U shape, and is suspended from the upper end of the track plate 2 to bypass, one end of the cantilever 8 is connected with the upper end of the bracket 3 at the inner side of the track plate 2, and the other end of the cantilever slides to penetrate through the upper end of the driving bin 6 and then is movably spliced with the sleeve member 33; the driving assembly drives the synchronous plate 7 to move in a specified direction; the linkage assembly limits the lifting of the cantilever 8 relative to the sleeve 33 and can drive the cantilever 8 to lift, the linkage assembly can be triggered when the bracket 3 is in the second state, namely, the bracket 3 is right above the bin body 1, and the limiting cantilever 8 is kept at the highest lifting stroke when the bracket 3 is in the first state.

As a preferred technical scheme of the embodiment, the driving assembly comprises a driving plate 9 movably arranged in the driving bin 6 and a motor 10 fixedly arranged outside the driving bin 6, a first gear 11 is coaxially connected to the output end of the motor 10, a first rack 12 meshed with the first gear 11 is arranged on the driving plate 9, a synchronous plate 7 is elastically and movably connected to the driving plate 9 along the length direction of the driving plate 9, when the synchronous plate 7 and the driving plate 9 relatively move, the linkage assembly links the cantilever 8 to lift, specifically, a guide groove arranged along the length direction of the cantilever is formed in the outer side wall of the track plate 2, and a guide block embedded in the guide groove is fixedly arranged on the driving plate 9; the driving plate 9 is L-shaped, one section is close to and parallel to the track plate 2, and the other section is vertical to the track plate 2; the first rack 12 is arranged at the lower end of the driving plate 9 and is far away from one side of the track plate 2; the two track plates 2 are provided with driving components, and motors 10 of the two groups of driving components are controlled by a servo system to synchronously start and stop in the same direction, so that the bracket 3 is driven to move stably; the synchronous plate 7 is elastically and movably connected with the driving plate 9, when the bracket 3 is not blocked by external force, the synchronous plate 7 synchronously moves along with the driving plate 9, and when the bracket 3 abuts against the inner wall of the groove at the upper end of the bin body 1, the synchronous plate 7 stops moving, the driving plate 9 can continuously move so as to generate relative movement with the synchronous plate 7, further trigger a linkage assembly, and the synchronous plate 7 stores elastic force for moving back relative to the driving plate 9, at the moment, the linkage assembly links the cantilever 8 to descend, namely the bracket 3 performs descending movement in a second state; then, the driving plate 9 moves back, the synchronous plate 7 still keeps at the original position under the elastic force, and then the driving plate 9 and the synchronous plate 7 move reversely and relatively, and further the linkage assembly is triggered, at the moment, the linkage assembly links the cantilever 8 to ascend, namely the bracket 3 performs the ascending movement in the second state.

As a further preferable technical scheme of the embodiment, a polish rod 14 which is movably penetrated through the synchronous plate 7 is connected to the driving plate 9 through two spaced abutting blocks 13, a first elastic piece 15 is arranged between one end of the synchronous plate 7 and the corresponding side abutting block 13, and specifically, the abutting blocks 13 are fixedly arranged at the inner side of an L-shaped included angle of the driving plate 9; the axial direction of the polish rod 14 is consistent with the moving direction of the driving plate 9; the first elastic piece 15 may be a spring, and is sleeved on the polish rod 14, the first elastic piece 15 may be preferably disposed at one end of the polish rod 14 away from the direction of the bin body 1, after the bracket 3 moves towards the upper side of the bin body 1 and abuts against the inner wall of the bin body 1, the driving plate 9 continues to move in the same direction, and then the abutting block 13 is driven to extrude the first elastic piece 15, the first elastic piece 15 compresses and stores elastic potential energy, at this time, the synchronous plate 7 is fixed in position relative to the bin body 1, the driving plate 9 moves relative to the synchronous plate 7, the linkage assembly can be triggered, then the driving plate 9 moves back, the elastic potential energy of the first elastic piece 15 is released, the synchronous plate 7 is still fixed in position relative to the bin body 1, the driving plate 9 moves relative to the synchronous plate 7, and the linkage assembly can also be triggered.

As a preferred technical scheme of the embodiment, the linkage assembly comprises a linkage shaft 16 rotatably arranged on the synchronous plate 7, two ends of the linkage shaft 16 are respectively and coaxially connected with a second gear 17 and a third gear 18, a second rack 19 meshed with the second gear 17 is arranged on the driving plate 9, a third rack 20 meshed with the third gear 18 is arranged on the cantilever 8, a support is specifically arranged at the upper end of the synchronous plate 7, the linkage shaft 16 is rotatably connected on the support, and the axial direction of the linkage shaft 16 is perpendicular to the side surface of the track plate 2; the second gear 17 is arranged above the driving plate 9, and the second rack 19 is fixedly arranged at the upper end of the driving plate 9 along the length direction of the driving plate 9; the part of the cantilever 8 plug-in sleeve 33, which is close to one side of the track plate 2, is provided with a movable groove, a third gear 18 is embedded into the movable groove, and a third rack 20 is fixedly arranged on the inner wall of one side of the movable groove along the lifting direction of the cantilever 8. In actual use, when the bracket 3 moves to be right above the bin body 1, the driving plate 9 continues to move in the same direction and moves relative to the synchronous plate 7, at this time, the driving plate 9 drives the second rack 19 to move so as to drive the second gear 17 to rotate, the second gear 17 drives the third gear 18 to rotate through the linkage shaft 16, and the third gear 18 drives the third rack 20 so as to enable the cantilever 8 to move downwards; when the driving plate 9 moves back, the driving process is performed and the driving plate is reversed, so that the cantilever 8 is driven to rise.

In another embodiment of the present invention, a substrate 21 fixedly connected with the track plate 2 is disposed at the lower side of the glue tray 4, a plurality of second elastic members 22 are connected between the glue tray 4 and the substrate 21, and the lifting of the glue tray 4 is movably linked with the driving plate 9, specifically, the second elastic members 22 may be preferably springs; the second elastic member 22 is provided to keep pushing the adhesive disc 4 away from the base plate 21, i.e., to keep the adhesive disc 4 at the highest position; the lifting of the rubber disc 4 and the movable linkage of the driving plate 9 are specifically as follows: under the movement of the driving plate 9, the driving bracket 3 approaches to the upper part of the bin body 1 and finally is embedded into the bin body 1 downwards, and the linkage rubber disc 4 descends and is kept at the lowest position at the last section of the single movement of the driving plate 9; then, under the back movement of the driving plate 9, in the process that the driving bracket 3 rises first and then moves away from the bin body 1, the last section of the unidirectional movement of the driving plate 9, the linkage rubber disc 4 rises and keeps the highest position under the action of the second elastic piece 22, and further corresponds to: after the stone brick carried by the bracket 3 completely spans the rolling brush 5 to brush glue, the glue tray 4 descends and keeps a low position, then the bracket 3 moves back, the stone brick carried by the bracket is not affected by the rolling brush 5, and finally, after the bracket 3 completely spans the rolling brush 5 again in the moving back process, the glue tray 4 triggers rising and resetting, and the next glue brushing operation can be prepared.

As a preferred technical scheme of the embodiment, a sliding groove 23 is formed in a solid body of the track plate 2, a first sliding block 24 fixedly connected with the rubber disc 4 is arranged in the sliding groove 23 in a lifting manner, a second sliding block 25 is horizontally and movably connected to the first sliding block 24, two ends of the driving plate 9 are both provided with deflector rods 26, one side, far away from the rubber disc 4, of the second sliding block 25 is fixedly provided with a sliding rod 27 corresponding to a moving path between the two deflector rods 26, a track groove 28 matched with the sliding rod 27 is formed in the side wall of the track plate 2, one end, close to the bin body 1, of the track groove 28 is horizontally arranged as a limiting section, and one end, far away from the bin body 1, of the track groove is obliquely upwards arranged as a guiding section, and specifically, the first sliding block 24 moves in the sliding groove 23 in a lifting manner, namely moves synchronously with the rubber disc 4; the first sliding block 24 is provided with a through notch along the length direction of the track plate 2 at one side far away from the rubber plate 4, namely, the first sliding block 24 is shaped like a Chinese character '', and the second sliding block 25 is arranged in the notch in a sliding way and can horizontally slide relative to the first sliding block 24; the deflector rod 26 is fixedly connected to the lower end of the driving plate 9 and is close to one side of the track plate 2; the sliding rod 27 is arranged perpendicular to the side wall of the track plate 2; the inner top surface of the limit section of the track groove 28 can be preferably arranged in a concave manner; the slide bar 27 slides only along the track groove 28. In actual use, in the process that the driving plate 9 drives the bracket 3 to approach to the upper side of the bin body 1 and finally is embedded into the bin body 1 downwards, the last section of the single movement of the driving plate 9 can drive the deflector rod 26 at one end far away from the bin body 1 to push the sliding rod 27, so that the sliding rod 27 firstly slides downwards along the guiding section of the track groove 28, the sliding rod 27 drives the rubber disc 4 to move downwards through the second sliding block 25 and the first sliding block 24, the second elastic piece 22 compresses and stores elastic potential energy, and at the end of the unidirectional movement of the driving plate 9, the sliding rod 27 slides into the limiting section of the track groove 28, so that the lifting of the first sliding block 24 can be limited, and the rubber disc 4 is fixed at the lowest position; then, in the process that the driving plate 9 moves back to drive the bracket 3 to rise first and then move away from the bin body 1, the last section of the unidirectional movement of the driving plate 9 can drive the deflector rod 26 close to one end of the bin body 1 to push the sliding rod 27, so that the sliding rod 27 is separated from the limit section of the track groove 28, then the elastic potential energy of the second elastic piece 22 is released, the rubber disc 4 is pushed to rise and reset, and the sliding rod 27 is reset to the uppermost end of the guide section of the track groove 28.

In another embodiment of the present invention, a rubber tube 29 and an air pump 30 are disposed on the lower side of the base plate 21, the air outlet end of the air pump 30 is connected with the interior of the rubber tube 29, the upper end of the rubber tube 29 is connected with the interior of the rubber disc 4 through a conduit 31, the lower end of the rubber disc 4 is fixedly connected with an air pump rod 32 for driving the air pump 30 to pump, specifically, the air pump 30 is sucked by a one-way valve, and when the air pump 30 drives the air pump to pump, the air is led into the rubber tube 29 through the air outlet end; the interior of the rubber cylinder 29 is divided into a rubber chamber and a plenum chamber, the plenum chamber is inflated by the air pump 30, and then the glue in the rubber chamber is led into the rubber disc 4 through the guide pipe 31, so that fresh glue is continuously replenished in the rubber disc 4; the conduit 31 is preferably a hose; the air pump 30 is provided with a feed supplement port communicated with the glue chamber, and the feed supplement port can be sealed and opened and closed; according to the above structure, the air pump 30 can be triggered to drive the glue cylinder 29 to automatically supplement fresh glue into the glue tray 4 after each descent of the glue tray 4.

The preparation process of the composite flocking stone brick is based on the preparation equipment of the composite flocking stone brick, and comprises the following steps: placing stone brick blank in a bracket 3 in a first state, and lifting a rubber disc 4 to enable a rolling brush 5 to be kept in a movement path of the bracket 3 in the first state; the bracket 3 moves to the upper part of the bin body 1, so that the lower surface of the stone brick blank material is contacted with the rolling brush 5 in a rolling way to brush glue; after the bracket 3 corresponds to the upper part of the bin body 1, the bracket 3 carries stone brick blank to descend to seal the upper end opening of the bin body 1, and in addition, the rubber disc 4 moves downwards to lower the height of the rolling brush 5; electrostatic flocking is carried out on the lower surface of the stone brick blank in the bin body 1; the bracket 3 is lifted to the first state, and then transversely moves away from the upper part of the bin body 1, and the concrete stone brick blank is matched with the shape of the bracket 3; when the bracket 3 is positioned at one end far away from the position of the bin body 1 in the first state, the glue tray 4 is positioned between the bin body 1 and the bracket 3, so that the bracket 3 can be ensured to finish crossing the rolling brush 5, namely, the stone brick blank on the bracket 3 can be ensured to be brushed with glue smoothly in the whole surface.

The composite flocking stone brick is prepared based on the preparation process of the composite flocking stone brick, and comprises a stone brick, wherein a fluff layer is arranged on the surface of the stone brick, and specifically, the stone brick can be provided with a single-sided or double-sided fluff layer; the arrangement of the fluff layer ensures that the stone brick has good water absorbability, plasticity and cohesive force, has certain sound insulation and heat insulation effects, and can effectively improve the indoor environment.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the invention, which is defined by the appended claims.

Claims

1. The composite flocking stone brick preparation equipment comprises a bin body (1) with an opening at the upper end, and is characterized by further comprising:

the track plate (2) is arranged at the upper end of the bin body (1);

the bracket (3) is movably arranged on the track plate (2) and is provided with a first state of horizontally moving along the track plate (2) and a second state of lifting over the bin body (1), and in the second state of the bracket (3), stone brick blanks can be supported to descend to seal the upper end opening of the bin body (1);

the rubber plate (4) is arranged on the track plate (2) in a lifting manner and is positioned at the outer side of the bin body (1), and a rolling brush (5) corresponding to the moving path of the bracket (3) in the first state is rotationally arranged in the rubber plate;

the track board (2) outside is provided with drive storehouse (6), drive storehouse (6) internalization is provided with synchronizing plate (7), liftable on synchronizing plate (7) are connected with cantilever (8), cantilever (8) and bracket (3) fixed connection, be provided with the drive assembly who is used for driving synchronizing plate (7) to remove and the linkage subassembly that drives cantilever (8) and go up and down in drive storehouse (6).

2. The composite type flocking stone brick preparation device according to claim 1, wherein the driving assembly comprises a driving plate (9) movably arranged in the driving bin (6) and a motor (10) fixedly arranged outside the driving bin (6), the output end of the motor (10) is coaxially connected with a first gear (11), a first rack (12) meshed with the first gear (11) is arranged on the driving plate (9), the synchronizing plate (7) is elastically movably connected to the driving plate (9) along the length direction of the driving plate (9), and when the synchronizing plate (7) and the driving plate (9) relatively move, the linkage assembly is linked with the cantilever (8) to lift.

3. The composite flocked stone tile production device according to claim 2, wherein the driving plate (9) is connected with a polish rod (14) which is movably penetrated through the synchronizing plate (7) through two spaced abutting blocks (13), and a first elastic piece (15) is arranged between one end of the synchronizing plate (7) and the corresponding side abutting block (13).

4. The composite flocked stone tile production equipment according to claim 2, wherein the linkage assembly comprises a linkage shaft (16) rotatably arranged on the synchronous plate (7), two ends of the linkage shaft (16) are respectively and coaxially connected with a second gear (17) and a third gear (18), a second rack (19) meshed with the second gear (17) is arranged on the driving plate (9), and a third rack (20) meshed with the third gear (18) is arranged on the cantilever (8).

5. The composite flocking stone brick preparation device according to claim 2, wherein a base plate (21) fixedly connected with the track plate (2) is arranged at the lower side of the rubber plate (4), a plurality of second elastic pieces (22) are connected between the rubber plate (4) and the base plate (21), and lifting of the rubber plate (4) is movably linked with the driving plate (9).

6. The composite flocking stone brick preparation equipment according to claim 5, wherein a sliding groove (23) is formed in the entity of the track plate (2), a first sliding block (24) fixedly connected with the rubber disc (4) is arranged in the sliding groove (23) in a lifting manner, a second sliding block (25) is horizontally and movably connected to the first sliding block (24), deflector rods (26) are arranged at two ends of the driving plate (9), a sliding rod (27) in a movable path between the two deflector rods (26) is fixedly arranged on one side, away from the rubber disc (4), of the second sliding block (25), a track groove (28) matched with the sliding rod (27) is formed in the side wall of the track plate (2), one end, close to the bin body (1), of the track groove (28) is horizontally arranged as a limiting section, and one end, away from the bin body (1), of the track groove is obliquely upwards arranged as a guiding section.

7. The composite flocked stone tile preparing device according to claim 5, wherein a rubber cylinder (29) and an air pump (30) are arranged on the lower side of the base plate (21), the air outlet end of the air pump (30) is connected with the inner part of the rubber cylinder (29), the upper end of the rubber cylinder (29) is connected with the inner part of the rubber plate (4) through a guide pipe (31), and an air pumping rod (32) for driving the air pump (30) to pump is fixedly connected with the lower end of the rubber plate (4).

8. A process for preparing a composite flocked stone tile based on the composite flocked stone tile preparing apparatus according to any one of claims 1 to 7, characterized by comprising: placing stone brick blanks in a bracket (3) in a first state, and lifting a rubber disc (4) to enable a rolling brush (5) to be kept in a movement path of the bracket (3) in the first state; the bracket (3) moves to the upper part of the bin body (1) to enable the lower surface of the stone brick blank to be in rolling contact with the rolling brush (5) for brushing glue; after the bracket (3) corresponds to the upper part of the bin body (1), the bracket (3) carries stone brick blank to descend to seal the upper end opening of the bin body (1), and in addition, the rubber disc (4) moves downwards to enable the height of the rolling brush (5) to be reduced; electrostatic flocking is carried out on the lower surface of the stone brick blank in the bin body (1); the bracket (3) is lifted to the first state and then transversely moves away from the upper part of the bin body (1).

9. A composite flocked stone tile made based on the process for making a composite flocked stone tile as claimed in claim 8, comprising a stone tile, the surface of the stone tile being provided with a pile layer.