CN113002232A

CN113002232A - Glass mosaic normal position adjustment rolling extrusion laying device

Info

Publication number: CN113002232A
Application number: CN202110145888.8A
Authority: CN
Inventors: 谢竟海
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-02-03
Filing date: 2021-02-03
Publication date: 2021-06-22

Abstract

The invention relates to the field of glass mosaics, in particular to a rolling extrusion laying device for righting the glass mosaics. The technical problem of the invention is that: provides a rolling extrusion laying device for adjusting the true position of a glass mosaic. The technical implementation scheme of the invention is as follows: a glass mosaic orthostatic adjusting rolling extrusion laying device comprises a bearing plate component, a moving unit and the like; the bearing plate assembly is connected with the mobile unit. According to the invention, the gaps on the glass mosaic are hooked, the glass mosaic is subjected to positive position adjustment and is conveyed piece by piece at a constant speed, then, dust on the surface of the glass mosaic is cleaned, the glass mosaic is vertically upwards, then the glass mosaic is laid on the wall by moving from top to bottom, and meanwhile, the glass mosaic is extruded, so that the glass mosaic is firmly laid on the wall, the laying quality is improved, the laying is firmer, the falling-off condition is avoided, and the later use experience is enhanced.

Description

Glass mosaic normal position adjustment rolling extrusion laying device

Technical Field

The invention relates to the field of glass mosaics, in particular to a rolling extrusion laying device for righting the glass mosaics.

Background

The glass mosaic, called glass mosaic or glass paper brick, it is a small-size colored facing glass, the general specification is 20 millimetres x 20 millimetres, 30 millimetres x 30 millimetres, 40 millimetres x 40 millimetres, the thickness is 4-6 millimetres, it is the small vitreous mosaic material of various colors, the glass mosaic is made of natural mineral substance and glass powder, it is the safest building materials, it is outstanding environment-friendly material too, it is acid and alkali-resistant, corrosion-resistant, the building material of most suitable fitting wall ground of bathroom, it is the most ingenious finishing material, the possibility of the combination change is very much: the patterns with the image are jump or transition in shade in the same color system, or are decorated with patterns of other decorative materials such as ceramic tiles and the like.

At present, in the use to glass mosaic, the fastness of laying is the key factor that influences glass mosaic quality and effect, among the prior art, when laying glass mosaic, mostly be manual operation, lay glass mosaic open the back, directly spread on the wall surface, then, the staff presses glass mosaic with the hand again, then reuse the instrument to pressurize glass mosaic, make it paste wall surface again, this kind of method, the dynamics that can't guarantee artifical each time makes is all unanimous, very easily lead to the condition that drops to appear after glass mosaic lays, influence product quality, and the use in later stage is experienced.

In summary, it is necessary to develop a rolling extrusion laying device for adjusting the true position of the glass mosaic to overcome the above problems.

Disclosure of Invention

In order to overcome the defects that at present, in the use of glass mosaics, the paving firmness is a key factor influencing the quality and the effect of the glass mosaics, in the prior art, when the glass mosaics are paved, most of the glass mosaics are manually operated, the glass mosaics are paved and spread on the surface of a wall directly, then workers press the glass mosaics with hands, and then press the glass mosaics by using tools to stick the glass mosaics to the surface of the wall, so that the method cannot ensure that the strength of the glass mosaics made by the workers each time is consistent, the glass mosaics are easy to fall off after being paved, the product quality is influenced, and the later-stage use experience is influenced, the technical problems of the invention are that: provides a rolling extrusion laying device for adjusting the true position of a glass mosaic.

The technical implementation scheme of the invention is as follows: a glass mosaic orthostatic adjusting rolling extrusion laying device comprises a bearing plate assembly, a uniform feeding unit, a laying unit, a moving unit, a control screen and a bottom plate assembly; the bearing plate component is connected with the mobile unit; the bearing plate component is connected with the control screen; the bearing plate component is connected with the bottom plate component; the uniform feeding unit is connected with the laying unit; the uniform feeding unit is connected with the bottom plate assembly; the laying unit is connected with the bottom plate component; the mobile unit is connected with the bottom plate component.

In a preferred embodiment of the invention, the constant-speed feeding unit comprises a feeding box, a first motor, a first transmission shaft, a first sliding sleeve, a first bevel gear, a second bevel gear, a first electric push rod, a rotary disc, a mechanical hook, a third bevel gear, a fourth bevel gear, a second transmission shaft, a fifth bevel gear, a sixth bevel gear, a third transmission shaft, a first transmission wheel, a second transmission wheel, a fourth transmission shaft, a first screw rod, a first sliding plate, a second sliding plate and a guide plate; the feeding box is fixedly connected with the bottom plate component; a first motor is arranged below the feeding box; the first motor is fixedly connected with the bottom plate assembly; the first motor is fixedly connected with the first transmission shaft; the first transmission shaft is connected with the laying unit; the first transmission shaft is rotatably connected with the bottom plate assembly; the first transmission shaft is connected with the first sliding sleeve; the first sliding sleeve is fixedly connected with the first bevel gear; the first sliding sleeve is fixedly connected with the second bevel gear; the first sliding sleeve is fixedly connected with the first electric push rod through a rotating shaft; the first electric push rod is fixedly connected with the bottom plate component; the first transmission shaft is fixedly connected with the turntable; the rotary table is fixedly connected with the three groups of mechanical hooks; the first transmission shaft is fixedly connected with the third bevel gear; the third bevel gear is connected with the laying unit; a fourth bevel gear is arranged on one side of the first bevel gear; the fourth bevel gear is fixedly connected with the second transmission shaft; the second transmission shaft is rotatably connected with the bottom plate assembly; the second transmission shaft is fixedly connected with a fifth bevel gear; the fifth bevel gear is meshed with the sixth bevel gear; the sixth bevel gear is fixedly connected with the third transmission shaft; the third transmission shaft is rotatably connected with the bottom plate assembly; the third transmission shaft is fixedly connected with the first transmission wheel; the first driving wheel is in transmission connection with the second driving wheel through a belt; the second driving wheel is fixedly connected with the fourth transmission shaft; the fourth transmission shaft is rotatably connected with the bottom plate assembly; the fourth transmission shaft is fixedly connected with the first screw rod; the first screw rod is rotatably connected with the bottom plate assembly; the first screw rod is connected with the first sliding plate in a rotating mode; the first sliding plate is in sliding connection with the guide plate; the first screw rod is connected with the second sliding plate in a rotating mode; the second sliding plate is in sliding connection with the guide plate; the guide plate is fixedly connected with the bottom plate component; the guide plate is connected with the laying unit.

In a preferred embodiment of the present invention, the paving unit comprises a seventh bevel gear, a fifth transmission shaft, an eighth bevel gear, a second sliding sleeve, a ninth bevel gear, a tenth bevel gear, a first fixing plate, a second electric push rod, a sixth transmission shaft, a third transmission wheel, a fourth transmission wheel, a seventh transmission shaft, a straight gear, a rack, a support frame, a brush, a guide frame, a fifth transmission wheel, a sixth transmission wheel, an eighth transmission shaft, a first rotating roller, a third electric push rod, a second fixing plate, a fourth electric push rod and a second rotating roller; the third bevel gear is meshed with the seventh bevel gear; the seventh bevel gear is fixedly connected with the fifth transmission shaft; the fifth transmission shaft is rotatably connected with the bottom plate assembly; the fifth transmission shaft is fixedly connected with the eighth bevel gear; a second sliding sleeve is arranged on one side of the eighth bevel gear; the second sliding sleeve is fixedly connected with the ninth bevel gear; the second sliding sleeve is fixedly connected with the tenth bevel gear; the second sliding sleeve is connected with the first fixing plate; the first fixing plate is fixedly connected with the second electric push rod; the second electric push rod is fixedly connected with the bottom plate component; the second sliding sleeve is connected with the sixth transmission shaft; the sixth transmission shaft is rotatably connected with the bottom plate assembly; the sixth transmission shaft is fixedly connected with the third transmission wheel; the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the fourth transmission wheel is fixedly connected with the seventh transmission shaft; the seventh transmission shaft is rotatably connected with the bottom plate assembly; the seventh transmission shaft is fixedly connected with the straight gear; the straight gear is meshed with the rack; the rack is fixedly connected with the support frame; the support frame is fixedly connected with the brush; the brush is connected with the flow guide frame in a sliding way; the guide frame is fixedly connected with the bottom plate assembly; the guide frame is fixedly connected with the guide plate; a fifth driving wheel is arranged on one side of the flow guide frame; the first transmission shaft is fixedly connected with the fifth transmission wheel; the fifth driving wheel is in transmission connection with the sixth driving wheel through a belt; the sixth driving wheel is fixedly connected with the eighth transmission shaft; the eighth transmission shaft is rotatably connected with the flow guide frame; the eighth transmission shaft is fixedly connected with the first rotating roller; the diversion frame is fixedly connected with the third electric push rod; the third electric push rod is fixedly connected with the second fixing plate; the second fixing plate is fixedly connected with the fourth electric push rod; the fourth electric push rod is fixedly connected with the flow guide frame; the second fixed plate is rotatably connected with the second rotating roller.

In a preferred embodiment of the present invention, the moving unit includes a second motor, a ninth transmission shaft, a second lead screw, a tenth transmission shaft, a seventh transmission wheel, an eighth transmission wheel, an eleventh transmission shaft, a third lead screw and a twelfth transmission shaft; the second motor is fixedly connected with the bearing plate component; the second motor is fixedly connected with the ninth transmission shaft; the ninth transmission shaft is rotatably connected with the bearing plate assembly; the ninth transmission shaft is fixedly connected with the second screw rod; the second screw rod is fixedly connected with the tenth transmission shaft; the second screw rod is connected with the bottom plate component in a rotating mode; the tenth transmission shaft is rotatably connected with the bearing plate component; the tenth transmission shaft is fixedly connected with the seventh transmission wheel; the seventh driving wheel is in transmission connection with the eighth driving wheel through a belt; the eighth transmission wheel is fixedly connected with the eleventh transmission shaft; the eleventh transmission shaft is rotatably connected with the bearing plate component; the eleventh transmission shaft is fixedly connected with the third screw rod; the third screw rod is connected with the bottom plate assembly in a screwing manner; the third screw rod is fixedly connected with the twelfth transmission shaft; the twelfth transmission shaft is rotatably connected with the bearing plate component.

In a preferred embodiment of the present invention, a protruding strip is disposed at a connection portion of the first transmission shaft and the first sliding sleeve, and a groove is disposed on the first sliding sleeve.

In a preferred embodiment of the invention, three sets of mechanical hooks are annularly and equidistantly arranged on the outer annular surface of the rotary disc.

In a preferred embodiment of the present invention, the first lead screw is bounded by a middle section and has opposite thread directions at two ends.

In a preferred embodiment of the present invention, a protruding strip is disposed at a connection position of the sixth transmission shaft and the second sliding sleeve, and a groove is disposed on the second sliding sleeve.

Compared with the prior art, the invention has the following advantages:

1. for solving at present, in the use to glass mosaic, the fastness of laying is the key factor that influences glass mosaic quality and effect, among the prior art, when laying glass mosaic, mostly for manual operation, lay glass mosaic open the back, directly spread on the wall surface, then, the staff presses glass mosaic with the hand again, then reuse the instrument to pressurize glass mosaic, make its subsides wall surface again, this kind of method, the dynamics size that can't guarantee artifical at every turn and make is all unanimous, very easily lead to the condition that drops to appear after glass mosaic lays, influence product quality, and the problem of the use experience of later stage.

2. By arranging the uniform-speed feeding unit, the laying unit and the moving unit, when the device is used, a glass mosaic orthostatic adjusting rolling extrusion laying device is placed at a position to be used, then is externally connected with a power supply, and is controlled to start through the control screen; firstly, a worker stacks a whole stack of glass mosaics in a uniform feeding unit on a bottom plate assembly in order, then the uniform feeding unit hooks gaps on the glass mosaics, the glass mosaics are conveyed to a laying unit piece by piece at a uniform speed after being subjected to position correction adjustment, then the laying unit cleans dust on the surfaces of the glass mosaics, then the moving unit on a bearing plate assembly moves from top to bottom, the glass mosaics are laid on a wall in a matched mode with the operation of the laying unit, and the laying unit extrudes the glass mosaics from top to bottom while moving, so that the glass mosaics are firmly laid on the wall.

3. According to the invention, the gaps on the glass mosaic are hooked, the glass mosaic is subjected to positive position adjustment and is conveyed piece by piece at a constant speed, then, dust on the surface of the glass mosaic is cleaned, the glass mosaic is vertically upwards, then the glass mosaic is laid on the wall by moving from top to bottom, and meanwhile, the glass mosaic is extruded, so that the glass mosaic is firmly laid on the wall, the laying quality is improved, the laying is firmer, the falling-off condition is avoided, and the later use experience is enhanced.

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 constant velocity feeding unit according to the present invention;

FIG. 4 is a schematic perspective view of a first part of the constant velocity feeding unit according to the present invention;

FIG. 5 is a schematic perspective view of a second part of the constant velocity feeding unit according to the present invention;

FIG. 6 is a schematic perspective view of a paving unit of the present invention;

FIG. 7 is a schematic perspective view of a first portion of the paving unit of the present invention;

FIG. 8 is a schematic perspective view of a second portion of the paving unit of the present invention;

FIG. 9 is a schematic perspective view of a third portion of the paving unit of the present invention;

fig. 10 is a schematic perspective view of a mobile unit according to the present invention.

Wherein the figures include the following reference numerals: 1. a bearing plate component, 2, a constant-speed feeding unit, 3, a laying unit, 4, a moving unit, 5, a control panel, 6, a bottom plate component, 201, a feeding box, 202, a first motor, 203, a first transmission shaft, 204, a first sliding sleeve, 205, a first bevel gear, 206, a second bevel gear, 207, a first electric push rod, 208, a rotary table, 209, a mechanical hook, 210, a third bevel gear, 211, a fourth bevel gear, 212, a second transmission shaft, 213, a fifth bevel gear, 214, a sixth bevel gear, 215, a third transmission shaft, 216, a first transmission wheel, 217, a second transmission wheel, 218, a fourth transmission shaft, 219, a first screw rod, 220, a first sliding plate, 221, a second sliding plate, 222, a guide plate, 301, a seventh bevel gear, 302, a fifth transmission shaft, 303, an eighth bevel gear, 304, a second sliding sleeve, 305, a ninth bevel gear, 306, a tenth bevel gear, 307, a first fixing plate, 308. a second electric push rod 309, a sixth transmission shaft 310, a third transmission wheel 311, a fourth transmission wheel 312, a seventh transmission shaft 313, a spur gear 314, a rack 315, a support frame 316, a brush 317, a guide frame 318, a fifth transmission wheel 319, a sixth transmission wheel 320, an eighth transmission shaft 321, a first rotating roller 322, a third electric push rod 323, a second fixing plate 324, a fourth electric push rod 325, a second rotating roller 401, a second motor 402, a ninth transmission shaft 403, a second screw rod 404, a tenth transmission shaft 405, a seventh transmission wheel 406, an eighth transmission wheel 407, an eleventh transmission shaft 408, a third screw rod 409 and a twelfth transmission shaft.

Detailed Description

It is to be noted that, in the case of the different described embodiments, identical components are provided with the same reference numerals or the same component names, wherein the disclosure contained in the entire description can be transferred to identical components having the same reference numerals or the same component names in a meaningful manner. The positional references selected in the description, such as upper, lower, lateral, etc., refer also to the directly described and illustrated figures and are to be read into the new position in the sense of a change in position.

Example 1

A glass mosaic orthostatic adjusting rolling extrusion laying device is shown in figures 1-10 and comprises a bearing plate component 1, a uniform feeding unit 2, a laying unit 3, a moving unit 4, a control screen 5 and a bottom plate component 6; the bearing plate component 1 is connected with the mobile unit 4; the bearing plate component 1 is connected with the control screen 5; the bearing plate component 1 is connected with the bottom plate component 6; the uniform feeding unit 2 is connected with the laying unit 3; the uniform feeding unit 2 is connected with the bottom plate assembly 6; the laying unit 3 is connected with the bottom plate component 6; the mobile unit 4 is connected to a floor assembly 6.

When in use, the glass mosaic true position adjusting rolling extrusion laying device is firstly placed at a position to be used, then is externally connected with a power supply, and is controlled to start through the control screen 5; firstly, orderly stacking a whole stack of glass mosaics in a uniform feeding unit 2 on a bottom plate component 6 by workers, hooking gaps on the glass mosaics by the uniform feeding unit 2, carrying out position adjustment on the glass mosaics, then conveying the glass mosaics to a laying unit 3 piece by piece at a uniform speed, cleaning dust on the surfaces of the glass mosaics by the laying unit 3, then moving the glass mosaics from top to bottom by a moving unit 4 on a bearing plate component 1, laying the glass mosaics on a wall by matching with the operation of the laying unit 3, extruding the glass mosaics by the laying unit 3 from top to bottom while moving, and firmly laying the glass mosaics on the wall. With the dust cleanness on glass mosaic surface to make glass mosaic vertical upwards, then through from top to bottom removing, lay glass mosaic on the wall, extrude glass mosaic simultaneously, make firm the laying on the wall of glass mosaic, promoted the quality of laying, make to lay more firmly, avoided the condition that drops, strengthened the use in later stage and experienced.

The uniform-speed feeding unit 2 comprises a feeding box 201, a first motor 202, a first transmission shaft 203, a first sliding sleeve 204, a first bevel gear 205, a second bevel gear 206, a first electric push rod 207, a rotary table 208, a mechanical hook 209, a third bevel gear 210, a fourth bevel gear 211, a second transmission shaft 212, a fifth bevel gear 213, a sixth bevel gear 214, a third transmission shaft 215, a first transmission wheel 216, a second transmission wheel 217, a fourth transmission shaft 218, a first screw rod 219, a first sliding plate 220, a second sliding plate 221 and a guide plate 222; the feeding box 201 is fixedly connected with the bottom plate assembly 6; a first motor 202 is arranged below the feeding box 201; the first motor 202 is fixedly connected with the bottom plate assembly 6; the first motor 202 is fixedly connected with the first transmission shaft 203; the first transmission shaft 203 is connected with the laying unit 3; the first transmission shaft 203 is rotatably connected with the bottom plate assembly 6; the first transmission shaft 203 is connected with the first sliding sleeve 204; the first sliding sleeve 204 is fixedly connected with a first bevel gear 205; the first sliding sleeve 204 is fixedly connected with the second bevel gear 206; the first sliding sleeve 204 is fixedly connected with a first electric push rod 207 through a rotating shaft; the first electric push rod 207 is fixedly connected with the bottom plate component 6; the first transmission shaft 203 is fixedly connected with the turntable 208; the turntable 208 is fixedly connected with three groups of mechanical hooks 209; the first transmission shaft 203 is fixedly connected with the third bevel gear 210; the third bevel gear 210 is connected with the laying unit 3; a fourth bevel gear 211 is provided at one side of the first bevel gear 205; the fourth bevel gear 211 is fixedly connected with the second transmission shaft 212; the second transmission shaft 212 is rotatably connected with the bottom plate assembly 6; the second transmission shaft 212 is fixedly connected with a fifth bevel gear 213; the fifth bevel gear 213 is meshed with the sixth bevel gear 214; the sixth bevel gear 214 is fixedly connected with a third transmission shaft 215; the third transmission shaft 215 is rotatably connected with the bottom plate assembly 6; the third transmission shaft 215 is fixedly connected with the first transmission wheel 216; the first driving wheel 216 is in driving connection with the second driving wheel 217 through a belt; the second driving wheel 217 is fixedly connected with the fourth transmission shaft 218; the fourth transmission shaft 218 is rotatably connected with the bottom plate assembly 6; the fourth transmission shaft 218 is fixedly connected with the first screw rod 219; the first screw rod 219 is rotatably connected with the bottom plate assembly 6; the first screw rod 219 is screwed with the first sliding plate 220; the first sliding plate 220 is slidably connected with the guide plate 222; the first screw rod 219 is screwed with the second sliding plate 221; the second sliding plate 221 is connected with the guide plate 222 in a sliding manner; the guide plate 222 is fixedly connected with the bottom plate assembly 6; the deflector 222 is connected to the laying unit 3.

Firstly, a worker stacks a whole stack of glass mosaics in a feeding box 201 orderly, then the worker hooks a gap on the glass mosaics through a mechanical hook 209 to rotate, thereby conveying the glass mosaics to a guide plate 222 piece by piece at a constant speed, a first motor 202 is started to drive a first sliding sleeve 204 to rotate through a first transmission shaft 203, the first transmission shaft 203 rotates to drive a laying unit 3 to operate, the first sliding sleeve 204 rotates to drive a first bevel gear 205 to rotate, the first sliding sleeve 204 rotates to drive a second bevel gear 206 to rotate, the first transmission shaft 203 rotates to drive a rotary table 208 to rotate, the rotary table 208 rotates to drive the mechanical hook 209 to rotate, further conveying the glass mosaics stacked in the feeding box 201 to the guide plate 222, the first transmission shaft 203 rotates to drive a third bevel gear 210 to rotate, the third bevel gear 210 rotates to drive the laying unit 3 to operate, and then the first sliding plate 220 and a second sliding plate 221 move relatively, further adjusting the position of the glass mosaic to keep the glass mosaic moving linearly, the first electric push rod 207 controls the first sliding sleeve 204 to slide on the first transmission shaft 203 through the rotating shaft, and further controls the engagement between the first bevel gear 205 and the second bevel gear 206 with the fourth bevel gear 211, when the first bevel gear 205 is engaged with the fourth bevel gear 211, the first bevel gear 205 rotates to drive the fourth bevel gear 211 to rotate, the fourth bevel gear 211 rotates to drive the fifth bevel gear 213 to rotate through the second transmission shaft 212, the fifth bevel gear 213 rotates to drive the sixth bevel gear 214 to rotate, the sixth bevel gear 214 rotates to drive the first transmission wheel 216 to rotate through the third transmission shaft 215, the first transmission wheel 216 rotates to drive the second transmission wheel 217 to rotate through the belt, the second transmission wheel 217 rotates to drive the first lead screw 219 to rotate through the fourth transmission shaft 218, the first lead screw 219 rotates to drive the first sliding plate 220 and the second sliding plate 221 to move relatively, and further adjusting the position of the glass mosaic to keep the glass mosaic moving linearly, then, the first electric push rod 207 controls the first sliding sleeve 204 to slide on the first transmission shaft 203 through the rotating shaft, controls the second bevel gear 206 to be meshed with the fourth bevel gear 211, and is opposite to the situation when the first bevel gear 205 is meshed with the fourth bevel gear 211, so that the first sliding plate 220 and the second sliding plate 221 move and reset relatively, then, the rotating disc 208 rotates to drive the mechanical hook 209 to rotate, so that the glass mosaic is conveyed to the laying unit 3, the uniform-speed feeding unit 2 realizes the hooking of the gap on the glass mosaic, after the glass mosaic is subjected to normal position adjustment, the glass mosaic is conveyed to the laying unit 3 piece by piece at a uniform speed, and the laying unit 3 is driven to operate.

The paving unit 3 comprises a seventh bevel gear 301, a fifth transmission shaft 302, an eighth bevel gear 303, a second sliding sleeve 304, a ninth bevel gear 305, a tenth bevel gear 306, a first fixing plate 307, a second electric push rod 308, a sixth transmission shaft 309, a third transmission wheel 310, a fourth transmission wheel 311, a seventh transmission shaft 312, a straight gear 313, a rack 314, a support frame 315, a brush 316, a guide frame 317, a fifth transmission wheel 318, a sixth transmission wheel 319, an eighth transmission shaft 320, a first rotating roller 321, a third electric push rod 322, a second fixing plate 323, a fourth electric push rod 324 and a second rotating roller 325; the third bevel gear 210 is meshed with the seventh bevel gear 301; the seventh bevel gear 301 is fixedly connected with a fifth transmission shaft 302; the fifth transmission shaft 302 is rotatably connected with the bottom plate assembly 6; the fifth transmission shaft 302 is fixedly connected with an eighth bevel gear 303; a second sliding sleeve 304 is arranged on one side of the eighth bevel gear 303; the second sliding sleeve 304 is fixedly connected with a ninth bevel gear 305; the second sliding sleeve 304 is fixedly connected with a tenth bevel gear 306; the second sliding sleeve 304 is connected with the first fixed plate 307; the first fixing plate 307 is fixedly connected with the second electric push rod 308; the second electric push rod 308 is fixedly connected with the bottom plate component 6; the second sliding sleeve 304 is connected with the sixth transmission shaft 309; the sixth transmission shaft 309 is rotatably connected with the bottom plate assembly 6; the sixth transmission shaft 309 is fixedly connected with a third transmission wheel 310; the third driving wheel 310 is in driving connection with a fourth driving wheel 311 through a belt; the fourth driving wheel 311 is fixedly connected with the seventh transmission shaft 312; the seventh transmission shaft 312 is rotatably connected with the bottom plate assembly 6; the seventh transmission shaft 312 is fixedly connected with a straight gear 313; the straight gear 313 is meshed with the rack 314; the rack 314 is fixedly connected with the support frame 315; the supporting frame 315 is fixedly connected with the brush 316; the brush 316 is connected with the guide frame 317 in a sliding way; the guide frame 317 is fixedly connected with the bottom plate assembly 6; the guide frame 317 is fixedly connected with the guide plate 222; a fifth driving wheel 318 is arranged on one side of the guide frame 317; the first transmission shaft 203 is fixedly connected with a fifth transmission wheel 318; the fifth driving wheel 318 is in driving connection with the sixth driving wheel 319 through a belt; the sixth driving wheel 319 is fixedly connected with the eighth transmission shaft 320; the eighth transmission shaft 320 is rotatably connected with the guide frame 317; the eighth transmission shaft 320 is fixedly connected with the first rotating roller 321; the guide frame 317 is fixedly connected with the third electric push rod 322; the third electric push rod 322 is fixedly connected with the second fixed plate 323; the second fixing plate 323 is fixedly connected with the fourth electric push rod 324; the fourth electric push rod 324 is fixedly connected with the guide frame 317; the second fixing plate 323 is rotatably coupled to the second rotating roller 325.

After the glass mosaic is conveyed to the guide frame 317, the dust on the surface of the glass mosaic is cleaned by the brush 316, the third bevel gear 210 rotates to drive the seventh bevel gear 301 to rotate, the seventh bevel gear 301 rotates to drive the eighth bevel gear 303 to rotate through the fifth transmission shaft 302, then the second electric push rod 308 is started to control the second sliding sleeve 304 to slide on the sixth transmission shaft 309 through the first fixing plate 307, so as to control the engagement of the ninth bevel gear 305 and the tenth bevel gear 306 with the eighth bevel gear 303, when the ninth bevel gear 305 is engaged with the eighth bevel gear 303, the eighth bevel gear 303 rotates to drive the ninth bevel gear 305 to rotate, the ninth bevel gear 305 rotates to drive the sixth transmission shaft 309 to rotate through the second sliding sleeve 304, the sixth transmission shaft 309 rotates to drive the third driving wheel 310 to rotate, the third driving wheel 310 rotates to drive the fourth driving wheel 311 to rotate through the belt, the fourth driving wheel 311 rotates to drive the spur gear 313 to rotate through the seventh driving shaft 312, the spur gear 313 rotates to drive the rack 314 to move, the rack 314 moves to drive the brush 316 to move along the guide frame 317 through the support frame 315, thereby cleaning the dust on the surface of the glass mosaic, then, the second electric push rod 308 is started to control the second sliding sleeve 304 to slide on the sixth driving shaft 309 through the first fixing plate 307, control the tenth bevel gear 306 to be meshed with the eighth bevel gear 303, opposite to the ninth bevel gear 305 to be meshed with the eighth bevel gear 303, thereby driving the brush 316 to reciprocate, thereby cleaning the dust on the surface of the glass mosaic, then, the glass mosaic is laid on the wall, the first driving shaft 203 rotates to drive the fifth driving wheel 318 to rotate, the fifth driving wheel 318 rotates to drive the sixth driving wheel 319 to rotate through the belt, the sixth driving wheel 319 rotates to drive the first rotating roller 321 to rotate through the eighth driving shaft 320, then the glass mosaic is driven to vertically move upwards, then, the third electric push rod 322 and the fourth electric push rod 324 are started to control the second rotating roller 325 to move through the second fixing plate 323, so that the second rotating roller 325 drives the upper end part of the glass mosaic to be attached to the wall, then, the moving unit 4 is used to move from top to bottom, so as to drive the second rotating roller 325 to move from top to bottom, thereby laying the glass mosaic on the wall, extruding the glass mosaic when the second rotating roller 325 is moved, so that the glass mosaic is firmly laid on the wall, the laying unit 3 realizes that the dust on the surface of the glass mosaic is cleaned and the glass mosaic is vertically upward, and then, the moving unit 4 is used for moving from top to bottom, the glass mosaic is paved on the wall, and meanwhile, the glass mosaic is extruded, so that the glass mosaic is firmly paved on the wall.

The moving unit 4 comprises a second motor 401, a ninth transmission shaft 402, a second screw 403, a tenth transmission shaft 404, a seventh transmission wheel 405, an eighth transmission wheel 406, an eleventh transmission shaft 407, a third screw 408 and a twelfth transmission shaft 409; the second motor 401 is fixedly connected with the bearing plate component 1; the second motor 401 is fixedly connected with the ninth transmission shaft 402; the ninth transmission shaft 402 is rotatably connected with the bearing plate assembly 1; the ninth transmission shaft 402 is fixedly connected with a second screw 403; the second screw 403 is fixedly connected with a tenth transmission shaft 404; the second screw 403 is screwed with the bottom plate assembly 6; the tenth transmission shaft 404 is rotatably connected with the bearing plate assembly 1; the tenth transmission shaft 404 is fixedly connected with a seventh transmission wheel 405; the seventh driving wheel 405 is in driving connection with the eighth driving wheel 406 through a belt; the eighth driving wheel 406 is fixedly connected with the eleventh transmission shaft 407; the eleventh transmission shaft 407 is rotatably connected with the bearing plate assembly 1; the eleventh transmission shaft 407 is fixedly connected with the third screw rod 408; the third screw rod 408 is screwed with the bottom plate assembly 6; the third screw rod 408 is fixedly connected with a twelfth transmission shaft 409; the twelfth drive shaft 409 is rotatably connected to the load bearing plate assembly 1.

The second lead screw 403 and the third lead screw 408 rotate to drive the bottom plate assembly 6 to move, and further cooperate with the laying unit 3 to lay the glass mosaic on the wall, and simultaneously extrude the glass mosaic to firmly lay the glass mosaic on the wall, the second motor 401 is started to drive the second lead screw 403 to rotate through the ninth transmission shaft 402, the second lead screw 403 rotates to drive the tenth transmission shaft 404 to rotate, the tenth transmission shaft 404 rotates to drive the seventh transmission wheel 405 to rotate, the seventh transmission wheel 405 rotates to drive the eighth transmission wheel 406 to rotate through the belt, the eighth transmission wheel 406 rotates to drive the third lead screw 408 to rotate through the eleventh transmission shaft 407, the third lead screw 408 rotates to drive the twelfth transmission shaft 409 to rotate, the second lead screw 403 and the third lead screw 408 rotate to drive the bottom plate assembly 6 to move downwards, and further the second rotating roller 325 moves from top to bottom, so as to lay the glass mosaic on the wall, when moving, extrude the glass mosaic, make the firm laying of glass mosaic on the wall, moving element 4 has realized that the cooperation is laid the operation of unit 3, lays the glass mosaic on the wall, and meanwhile, extrudees the glass mosaic, makes the firm laying of glass mosaic on the wall.

A convex strip is arranged at the joint of the first transmission shaft 203 and the first sliding sleeve 204, and a groove is arranged on the first sliding sleeve 204.

The first sliding sleeve 204 can be made to slide on the first transmission shaft 203 and keep rotating, so that the engagement of the first bevel gear 205 and the second bevel gear 206 with the fourth bevel gear 211 is controlled by the first electric push rod 207.

Three sets of mechanical hooks 209 are annularly and equidistantly arranged on the outer annular surface of the rotary disc 208.

The rotating disc 208 can drive the mechanical hook 209 to rotate when rotating, and the glass mosaic can be smoothly conveyed.

The first lead screw 219 is bounded by a middle section and has opposite thread directions at both ends.

The first sliding plate 220 and the second sliding plate 221 can be moved relatively to adjust the glass mosaic in a correct position.

A convex strip is arranged at the connection position of the sixth transmission shaft 309 and the second sliding sleeve 304, and a groove is arranged on the second sliding sleeve 304.

The second sliding sleeve 304 can be made to slide on the sixth transmission shaft 309 and keep rotating, so that the engagement of the ninth bevel gear 305 and the tenth bevel gear 306 with the eighth bevel gear 303 is controlled by the second electric push rod 308.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting the protection scope of the present invention, and although the present invention is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention.

Claims

1. The utility model provides a glass mosaic normal position adjustment rolls extrusion laying device, including bearing plate subassembly (1), control panel (5) and bottom plate subassembly (6), characterized by: the device also comprises a uniform feeding unit (2), a laying unit (3) and a moving unit (4); the bearing plate component (1) is connected with the mobile unit (4); the bearing plate component (1) is connected with the control screen (5); the bearing plate component (1) is connected with the bottom plate component (6); the uniform feeding unit (2) is connected with the laying unit (3); the uniform feeding unit (2) is connected with the bottom plate component (6); the laying unit (3) is connected with the bottom plate component (6); the mobile unit (4) is connected with the bottom plate component (6).

2. The glass mosaic true position adjusting rolling extrusion laying device according to claim 1, wherein the constant speed feeding unit (2) comprises a feeding box (201), a first motor (202), a first transmission shaft (203), a first sliding sleeve (204), a first bevel gear (205), a second bevel gear (206), a first electric push rod (207), a turntable (208), a mechanical hook (209), a third bevel gear (210), a fourth bevel gear (211), a second transmission shaft (212), a fifth bevel gear (213), a sixth bevel gear (214), a third transmission shaft (215), a first transmission wheel (216), a second transmission wheel (217), a fourth transmission shaft (218), a first screw rod (219), a first sliding plate (220), a second sliding plate (221) and a guide plate (222); the feeding box (201) is fixedly connected with the bottom plate component (6); a first motor (202) is arranged below the feeding box (201); the first motor (202) is fixedly connected with the bottom plate component (6); the first motor (202) is fixedly connected with the first transmission shaft (203); the first transmission shaft (203) is connected with the laying unit (3); the first transmission shaft (203) is rotatably connected with the bottom plate component (6); the first transmission shaft (203) is connected with the first sliding sleeve (204); the first sliding sleeve (204) is fixedly connected with the first bevel gear (205); the first sliding sleeve (204) is fixedly connected with the second bevel gear (206); the first sliding sleeve (204) is fixedly connected with the first electric push rod (207) through a rotating shaft; the first electric push rod (207) is fixedly connected with the bottom plate component (6); the first transmission shaft (203) is fixedly connected with the turntable (208); the turntable (208) is fixedly connected with three groups of mechanical hooks (209); the first transmission shaft (203) is fixedly connected with the third bevel gear (210); the third bevel gear (210) is connected with the laying unit (3); a fourth bevel gear (211) is arranged on one side of the first bevel gear (205); the fourth bevel gear (211) is fixedly connected with the second transmission shaft (212); the second transmission shaft (212) is rotatably connected with the bottom plate assembly (6); the second transmission shaft (212) is fixedly connected with a fifth bevel gear (213); the fifth bevel gear (213) is meshed with the sixth bevel gear (214); a sixth bevel gear (214) is fixedly connected with a third transmission shaft (215); the third transmission shaft (215) is rotatably connected with the bottom plate assembly (6); the third transmission shaft (215) is fixedly connected with the first transmission wheel (216); the first driving wheel (216) is in transmission connection with the second driving wheel (217) through a belt; the second driving wheel (217) is fixedly connected with the fourth transmission shaft (218); the fourth transmission shaft (218) is rotatably connected with the bottom plate component (6); the fourth transmission shaft (218) is fixedly connected with the first screw rod (219); the first screw rod (219) is rotatably connected with the bottom plate assembly (6); the first screw rod (219) is connected with the first sliding plate (220) in a screwing way; the first sliding plate (220) is in sliding connection with the guide plate (222); the first screw rod (219) is connected with the second sliding plate (221) in a screwing way; the second sliding plate (221) is in sliding connection with the guide plate (222); the guide plate (222) is fixedly connected with the bottom plate component (6); the guide plate (222) is connected with the laying unit (3).

3. A glass mosaic true position adjusting rolling extrusion laying device according to claim 2, the paving unit (3) is characterized by comprising a seventh bevel gear (301), a fifth transmission shaft (302), an eighth bevel gear (303), a second sliding sleeve (304), a ninth bevel gear (305), a tenth bevel gear (306), a first fixing plate (307), a second electric push rod (308), a sixth transmission shaft (309), a third transmission wheel (310), a fourth transmission wheel (311), a seventh transmission shaft (312), a straight gear (313), a rack (314), a support frame (315), a brush (316), a guide frame (317), a fifth transmission wheel (318), a sixth transmission wheel (319), an eighth transmission shaft (320), a first rotating roller (321), a third electric push rod (322), a second fixing plate (323), a fourth electric push rod (324) and a second rotating roller (325); the third bevel gear (210) is meshed with the seventh bevel gear (301); the seventh bevel gear (301) is fixedly connected with a fifth transmission shaft (302); the fifth transmission shaft (302) is rotatably connected with the bottom plate assembly (6); the fifth transmission shaft (302) is fixedly connected with the eighth bevel gear (303); a second sliding sleeve (304) is arranged on one side of the eighth bevel gear (303); the second sliding sleeve (304) is fixedly connected with a ninth bevel gear (305); the second sliding sleeve (304) is fixedly connected with a tenth bevel gear (306); the second sliding sleeve (304) is connected with the first fixing plate (307); the first fixing plate (307) is fixedly connected with the second electric push rod (308); the second electric push rod (308) is fixedly connected with the bottom plate component (6); the second sliding sleeve (304) is connected with the sixth transmission shaft (309); the sixth transmission shaft (309) is rotatably connected with the bottom plate assembly (6); the sixth transmission shaft (309) is fixedly connected with the third transmission wheel (310); the third driving wheel (310) is in driving connection with the fourth driving wheel (311) through a belt; the fourth driving wheel (311) is fixedly connected with a seventh transmission shaft (312); the seventh transmission shaft (312) is rotatably connected with the bottom plate assembly (6); the seventh transmission shaft (312) is fixedly connected with the straight gear (313); the straight gear (313) is meshed with the rack (314); the rack (314) is fixedly connected with the support frame (315); the support frame (315) is fixedly connected with the brush (316); the brush (316) is connected with the flow guide frame (317) in a sliding way; the guide frame (317) is fixedly connected with the bottom plate component (6); the guide frame (317) is fixedly connected with the guide plate (222); a fifth driving wheel (318) is arranged on one side of the guide frame (317); the first transmission shaft (203) is fixedly connected with a fifth transmission wheel (318); the fifth driving wheel (318) is in driving connection with the sixth driving wheel (319) through a belt; the sixth driving wheel (319) is fixedly connected with the eighth transmission shaft (320); the eighth transmission shaft (320) is rotatably connected with the flow guide frame (317); the eighth transmission shaft (320) is fixedly connected with the first rotating roller (321); the guide frame (317) is fixedly connected with a third electric push rod (322); the third electric push rod (322) is fixedly connected with the second fixed plate (323); the second fixed plate (323) is fixedly connected with the fourth electric push rod (324); the fourth electric push rod (324) is fixedly connected with the flow guide frame (317); the second fixing plate (323) is rotatably connected to the second rotating roller (325).

4. A glass mosaic true position adjusting rolling extrusion paving device according to claim 3, characterized in that the moving unit (4) comprises a second motor (401), a ninth transmission shaft (402), a second screw rod (403), a tenth transmission shaft (404), a seventh transmission wheel (405), an eighth transmission wheel (406), an eleventh transmission shaft (407), a third screw rod (408) and a twelfth transmission shaft (409); the second motor (401) is fixedly connected with the bearing plate component (1); the second motor (401) is fixedly connected with the ninth transmission shaft (402); the ninth transmission shaft (402) is rotatably connected with the bearing plate component (1); the ninth transmission shaft (402) is fixedly connected with a second screw rod (403); the second screw rod (403) is fixedly connected with the tenth transmission shaft (404); the second screw rod (403) is in screwed connection with the bottom plate component (6); the tenth transmission shaft (404) is rotatably connected with the bearing plate component (1); the tenth transmission shaft (404) is fixedly connected with a seventh transmission wheel (405); the seventh driving wheel (405) is in transmission connection with the eighth driving wheel (406) through a belt; the eighth driving wheel (406) is fixedly connected with the eleventh transmission shaft (407); the eleventh transmission shaft (407) is rotatably connected with the bearing plate component (1); the eleventh transmission shaft (407) is fixedly connected with the third screw rod (408); the third screw rod (408) is in screwed connection with the bottom plate component (6); the third screw rod (408) is fixedly connected with a twelfth transmission shaft (409); the twelfth transmission shaft (409) is rotatably connected with the bearing plate component (1).

5. The rolling extrusion laying device for the glass mosaic orthomorphism adjustment according to claim 4, characterized in that the connection of the first transmission shaft (203) and the first sliding sleeve (204) is provided with a convex strip, and the first sliding sleeve (204) is provided with a groove.

6. A glass mosaic true position adjusting rolling extrusion laying device according to claim 5, characterized in that the outer annular surface of the turntable (208) is provided with three sets of mechanical hooks (209) at equal intervals in a circular manner.

7. A glass mosaic true position adjusting rolling extrusion laying apparatus according to claim 6, characterized in that the first screw (219) is bounded by a middle section and has opposite thread directions at both ends.

8. The glass mosaic true position adjusting rolling extrusion laying device according to claim 7, wherein the connection part of the sixth transmission shaft (309) and the second sliding sleeve (304) is provided with a convex strip, and the second sliding sleeve (304) is provided with a groove.