CN113027077A - Ceramic tile platform of plastering for building - Google Patents

Abstract

The invention relates to the field of buildings, in particular to a tile plastering platform for buildings. Can be used for plastering ceramic tiles. Including the upset subassembly of plastering, driver part, the coating part, the bracket component, even board, the connecting band, even the board is connected between a plurality of upset subassemblies of plastering, driver part is plastered the subassembly with middle upset and is connected, the input motor is driving the shaft coupling and is rotating, and then drive the rotation of middle-end rotary column through the shaft coupling, and then drive awl tooth A through middle-end rotary column and rotate, and then drive awl tooth B motion through awl tooth A, and then drive awl tooth C through awl tooth B and rotate, drive stirring leaf one and stirring leaf two motions simultaneously, and then make the masking liquid in the coating box rotate, and then prevent that the masking liquid from producing the sediment.

Description

Ceramic tile platform of plastering for building

Technical Field

The invention relates to the field of buildings, in particular to a tile plastering platform for buildings.

Background

The ceramic tile plastering platform for the building is a common device in the field of buildings, but the function of the common ceramic tile plastering platform for the building is single.

Disclosure of Invention

The invention aims to provide a ceramic tile plastering platform for buildings, which can be used for plastering and processing ceramic tiles.

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

the utility model provides a ceramic tile platform of plastering for building, including the upset subassembly of plastering, driver element, coating element, bracket component, even board, connecting band, even the board is connected between a plurality of upsets are plastered the subassembly, and driver element is plastered the subassembly with middle upset and is connected, and coating element is connected with the bracket component, even the board is connected with coating element, and the connecting band is connected and is plastered between subassembly and the coating element in the upset, and the connecting band is connected between two adjacent upsets are plastered the subassembly.

As a further optimization of the technical scheme, the invention relates to a tile plastering platform for buildings, which comprises a plastering support, a first driving rotary column, a first annular groove, a first end face half gear, a first belt wheel, a first driving slider, a hinged slider, a first straight gear, a first driving rotary block, a plastering plate, a first expansion sliding plate, a first inner end bevel gear, a second inner end bevel gear, a first inner end bevel gear shaft, a third inner end bevel gear, a fourth inner end bevel gear, a first manual rotary rod, a second inner end bevel gear shaft, a second expansion sliding plate, a fifth inner end bevel gear, a third inner end bevel gear shaft and a first outer side push spring, wherein the first driving rotary column is rotatably connected with the plastering support, the first annular groove is arranged on the first driving rotary column, the first end face half gear is fixedly connected with the first driving rotary column, the first belt wheel is fixedly connected with the first driving rotary column, the driving slider is slidably connected with the first annular groove, the driving slider is hingedly connected with the hinged slider and the plastering plate is slidably connected, a first straight tooth is fixedly connected with the plastering plate, a first expansion sliding plate is connected with the plastering plate in a sliding manner, the inner end of the plastering plate is hollowed, the plastering plate is connected with a driving rotating block in a rotating manner, the driving rotating block is connected with a plastering bracket in a rotating manner, a first outer side push spring is fixedly connected with the driving rotating block, a first inner end bevel tooth is fixedly connected with a second inner end bevel tooth shaft, the second inner end bevel tooth shaft is connected with the plastering bracket in a rotating manner, the first expansion sliding plate is connected with the second inner end bevel tooth shaft in a threaded manner, the second expansion sliding plate is connected with the plastering plate in a sliding manner, a fifth inner end bevel tooth is rotatably connected with a third inner end bevel tooth shaft, the third expansion sliding plate is connected with a third inner end bevel tooth shaft in a threaded manner, the second inner end bevel tooth is meshed with the first inner end bevel tooth and the fifth inner end bevel tooth in a transmission manner, the first inner end bevel tooth shaft is fixedly connected with the second inner bevel tooth, and the third inner bevel tooth, the inner end bevel gear III is in meshing transmission with the inner end bevel gear IV, the inner end bevel gear IV is fixedly connected with the manual rotating rod I, and the manual rotating rod I is rotatably connected with the plastering plate.

As a further optimization of the technical scheme, the tile plastering platform for the building is provided with a plurality of overturning plastering assemblies, and belt wheels I between the two connected overturning plastering assemblies are connected through a connecting belt.

As a further optimization of the technical scheme, the invention relates to a tile plastering platform for buildings, which comprises a driving part, an upper end boss I, an upper end boss II, a manual rotating rod II, an inner end bevel gear VI, an inner end bevel gear VII, an inner end bevel gear shaft III and a driving straight gear I, wherein the upper end boss I is fixedly connected with the driving sleeve, the upper end boss II is slidably connected with the driving sleeve, the manual rotating rod II is rotatably connected with the driving sleeve, the inner end bevel gear VI is fixedly connected with the manual rotating rod II, the inner end bevel gear VI is in meshing transmission with the inner end bevel gear VII, the inner end bevel gear VII is fixedly connected with the inner end bevel gear shaft III, the inner end bevel gear shaft III is rotatably connected with the driving sleeve, the driving straight gear I is fixedly connected with the inner end bevel gear shaft III, the inner end bevel gear shaft III is in meshing transmission with the upper end boss II, the lower end of the upper end boss II is provided with a rack A, and the driving.

As a further optimization of the technical scheme, the invention relates to a tile plastering platform for buildings, which comprises a paint box body, an upper end bracket, a bevel gear A, a middle end rotary column, a bevel gear B, a bevel gear shaft B, a bevel gear C, a stirring blade I, a connecting pipe I, a coupling, a belt wheel II, a connecting pipe II, a driving slide rod I, a driving slide rod push spring I, a closing rod, a rectangular terminal and a stirring blade II, wherein the upper end bracket is fixedly connected with the paint box body, the bevel gear A is rotatably connected with the upper end bracket, the middle end rotary column is fixedly connected with the bevel gear A, the stirring blade II is rotatably connected with the middle end rotary column, the bevel gear B is in meshing transmission with the bevel gear A, the bevel gear B is fixedly connected with the bevel gear shaft B, the bevel gear shaft B is rotatably connected with the paint box body, the bevel gear C is in meshing transmission with the bevel gear B, the bevel gear C is fixedly connected with the stirring blade I, and the connecting pipe I is fixedly connected and communicated with the paint box body, the driving slide bar is fixedly connected with the rectangular terminal, the lower end of the driving slide bar is in contact with the upper boss I and the upper boss II, and the connecting plate is fixedly connected with the connecting tube II.

As a further optimization of the technical scheme, the invention relates to a ceramic tile plastering platform for buildings, which comprises a bracket main body, a carrier belt, a first inner end roller, a belt wheel A, a belt wheel B, a first bevel gear, a second bevel gear, a belt wheel C, a belt wheel belt B and an input motor, wherein the first inner end roller is rotationally connected with the bracket main body, the two inner end rollers are connected with the carrier belt, one inner end roller is fixedly connected with the belt wheel A, the belt wheel B is fixedly connected with the first bevel gear, the first bevel gear is rotationally connected with the bracket main body, the belt wheel belt A is connected between the belt wheel A and the belt wheel B, the first bevel gear is fixedly connected with the first bevel gear, the first bevel gear is fixedly connected with the second bevel gear, the second bevel gear is fixedly connected with an output shaft of the input motor, and the input motor is fixedly connected with the bracket main body, the belt pulley belt B is fixedly connected with an output shaft of the input motor, the coating box body is fixedly connected with the support main body, the coupler is fixedly connected with the output shaft of the input motor, and the belt pulley belt B is connected with the driving rotary column in a matched mode.

The ceramic tile plastering platform for the building has the beneficial effects that:

according to the tile plastering platform for buildings, an input motor drives a coupler to rotate, a middle-end rotating column is driven to rotate through the coupler, a bevel gear A is driven to rotate through the middle-end rotating column, a bevel gear B is driven to move through the bevel gear A, a bevel gear C is driven to rotate through the bevel gear B, a first stirring blade and a second stirring blade are driven to move simultaneously, coating liquid in a coating box body is rotated, and the coating liquid is prevented from precipitating.

Drawings

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

FIG. 1 is a first general structural diagram of the present invention;

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

fig. 3 is a first diagrammatic view of the construction of the present invention plastering assembly 1;

fig. 4 is a second structural schematic view of the reverse plastering assembly 1 of the present invention;

fig. 5 is a schematic view three of the construction of the reverse plastering assembly 1 of the present invention;

FIG. 6 is a first schematic structural diagram of the driving member 2 of the present invention;

FIG. 7 is a second schematic structural view of the driving member 2 of the present invention;

FIG. 8 is a third schematic structural view of the driving member 2 of the present invention;

FIG. 9 is a first schematic structural view of a coating element 3 according to the present invention;

FIG. 10 is a second schematic structural view of the coating element 3 of the present invention;

FIG. 11 is a schematic illustration of the construction of the coating element 3 according to the invention;

FIG. 12 is a fourth schematic structural view of the coating element 3 of the present invention;

FIG. 13 is a first schematic structural view of the bracket assembly 4 of the present invention;

fig. 14 is a second structural schematic view of the bracket assembly 4 of the present invention.

In the figure: a plastering assembly 1 is overturned; 1-1 of a plastering support; driving a first rotating column 1-2; 1-3 annular grooves; 1-4 of end face half gear; 1-5 of a belt wheel I; 1-6 of a driving slider; hinged sliders 1-7; 1-8 straight teeth I; driving the rotating blocks 1-9; 1-10 parts of plastering plate; 1-11 parts of an expansion sliding plate; 1-12 parts of inner end bevel gear I; inner end bevel teeth II 1-13; 1-14 of an inner end bevel gear shaft; 1-15 parts of inner end bevel gear III; 1-16 parts of inner end bevel teeth; 1-17 of a manual rotating rod; a second bevel gear shaft 1-18 at the inner end; 1-19 of a second expansion sliding plate; 1-20 parts of inner end bevel teeth; an inner end bevel gear shaft III 1-21; the outer side push spring I is 1-22; a drive member 2; a drive sleeve 2-1; 2-2 parts of an upper end boss I; 2-3 of an upper end boss II; 2-4 of a manual rotating rod II; inner end bevel teeth six 2-5; 2-6 parts of inner end bevel teeth; an inner end bevel gear shaft III 2-7; driving straight teeth I2-8; a paint member 3; 3-1 of a paint box body; an upper end bracket 3-2; bevel teeth A3-3; 3-4 of a middle-end rotary column; bevel teeth B3-5; a bevel gear shaft B3-6; bevel teeth C3-7; 3-8 parts of a first stirring blade; 3-9 of a connecting pipe I; 3-10 parts of a coupler; 3-11 of a second belt wheel; 3-12 parts of a connecting pipe II; driving the first sliding rod 3-13; driving a sliding rod push spring I3-14; 3-17 of a closing rod; rectangular terminals 3 to 18; stirring the second leaf for 3 to 19 times; a bracket assembly 4; a stent body 4-1; a carrier belt 4-2; the inner end roller I is 4-3; belt pulley A4-4; a pulley belt A4-5; a pulley B4-6; 4-7 parts of a first bevel gear shaft; 4-8 parts of first bevel gear; 4-9 parts of second conical teeth; pulley C4-10; pulley belt B4-11; 4-12 of input motor; a connecting plate 5; and a connecting belt 6.

Detailed Description

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

The fixed connection in the device is realized by welding, thread fixing and other modes, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying way, a spring retainer ring groove is arranged on the shaft or the shaft hole, and the axial fixation of the bearing is realized by clamping the elastic retainer ring in the retainer ring groove, so that the rotation is realized; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint refers to a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 14, and a tile plastering platform for construction includes a turnover plastering assembly 1, a driving unit 2, a paint unit 3, a bracket assembly 4, a connecting plate 5, and a connecting band 6, where the connecting plate 5 is connected between the multiple turnover plastering assemblies 1, the driving unit 2 is connected with the middle turnover plastering assembly 1, the paint unit 3 is connected with the bracket assembly 4, the connecting plate 5 is connected with the paint unit 3, the connecting band 6 is connected between the turnover plastering assembly 1 and the paint unit 3, and the connecting band 6 is connected between two adjacent turnover plastering assemblies 1.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-14, and the embodiment further describes the first embodiment, and the reversible plastering assembly 1 comprises a plastering support 1-1, a driving rotary column 1-2, an annular groove 1-3, a face half gear 1-4, a belt pulley 1-5, a driving slider 1-6, a hinged slider 1-7, a straight tooth 1-8, a driving rotary block 1-9, a plastering plate 1-10, an expanding sliding plate 1-11, an inner end bevel tooth 1-12, an inner end bevel tooth two 1-13, an inner end bevel gear shaft 1-14, an inner end bevel gear three 1-15, an inner end bevel gear four 1-16, a manual rotary rod 1-17, an inner end bevel gear shaft two 1-18, an expanding sliding plate two 1-19, an inner end bevel gear five 1-20, an inner end bevel gear shaft three 1-21, a manual rotary rod 1-17, a manual rotary rod one, an inner end bevel gear shaft two 1-18, an expanding, The outer side of the push spring I1-22, the driving rotary column I1-2 is rotatably connected with the plastering support 1-1, the annular groove I1-3 is arranged on the driving rotary column I1-2, the end face half gear 1-4 is fixedly connected with the driving rotary column I1-2, the belt pulley I1-5 is fixedly connected with the driving rotary column I1-2, the driving slider 1-6 is slidably connected with the annular groove I1-3, the driving slider 1-6 is hinged with the hinged slider 1-7, the hinged slider 1-7 is slidably connected with the plastering plate 1-10, the straight teeth I1-8 is fixedly connected with the plastering plate 1-10, the expansion sliding plate I1-11 is slidably connected with the plastering plate 1-10, the inner end of the plastering plate 1-10 is hollowed, the plastering plate 1-10 is rotatably connected with the driving rotary block 1-9, the driving rotating block 1-9 is rotatably connected with the plastering bracket 1-1, the outer side push spring 1-22 is fixedly connected with the driving rotating block 1-9, the outer side push spring 1-22 is fixedly connected with the plastering bracket 1-1, the inner end bevel gear 1-12 is fixedly connected with the inner end bevel gear shaft 1-18, the inner end bevel gear shaft 1-18 is rotatably connected with the plastering bracket 1-1, the expansion sliding plate 1-11 is in threaded connection with the inner end bevel gear shaft 1-18, the expansion sliding plate 1-19 is in sliding connection with the plastering plate 1-10, the inner end bevel gear five 1-20 is rotatably connected with the inner end bevel gear shaft three 1-21, the inner end bevel gear shaft three 1-21 is rotatably connected with the plastering bracket 1-1, and the expansion sliding plate two 1-19 is in threaded connection with the inner end bevel gear shaft three 1-21, the inner end bevel gear II 1-13 is in meshed transmission with the inner end bevel gear I1-12 and the inner end bevel gear V1-20, the inner end bevel gear shaft I1-14 is fixedly connected with the inner end bevel gear II 1-13, the inner end bevel gear III 1-15 is fixedly connected with the inner end bevel gear shaft I1-14, the inner end bevel gear III 1-15 is in meshed transmission with the inner end bevel gear IV 1-16, the inner end bevel gear IV 1-16 is fixedly connected with the manual rotating rod I1-17, and the manual rotating rod I1-17 is in rotating connection with the plastering plate 1-10.

The third concrete implementation mode:

in the following, the present embodiment is described with reference to fig. 1-14, and the present embodiment further describes the first embodiment, the plastering unit 1 is provided with a plurality of belt pulleys 1-5 connected by a connecting belt 6 between two connected plastering units 1.

The fourth concrete implementation mode:

the embodiment is described below by combining with figures 1-14, and the embodiment further describes the first embodiment, the driving part 2 comprises a driving sleeve 2-1, a first upper end boss 2-2, a second upper end boss 2-3, a second manual rotating rod 2-4, a sixth inner end bevel gear 2-5, a seventh inner end bevel gear 2-6, a third inner end bevel gear shaft 2-7 and a first driving straight gear 2-8, the first upper end boss 2-2 is fixedly connected with the driving sleeve 2-1, the second upper end boss 2-3 is slidably connected with the driving sleeve 2-1, the second manual rotating rod 2-4 is rotatably connected with the driving sleeve 2-1, the sixth inner end bevel gear 2-5 is fixedly connected with the second manual rotating rod 2-4, the sixth inner end bevel gear 2-5 is in meshing transmission with the seventh inner end bevel gear 2-6, an inner end bevel gear seven 2-6 is fixedly connected with an inner end bevel gear shaft three 2-7, the inner end bevel gear shaft three 2-7 is rotatably connected with a driving sleeve 2-1, a driving straight gear I2-8 is fixedly connected with the inner end bevel gear shaft three 2-7, the inner end bevel gear shaft three 2-7 is in meshing transmission with an upper end boss II 2-3, a rack A is arranged at the lower end of the upper end boss II 2-3, and the driving sleeve 2-1 is fixedly connected with a belt pulley I1-5.

The fifth concrete implementation mode:

the embodiment is described below by combining with fig. 1-14, and the embodiment further describes the first embodiment, the coating part 3 comprises a coating box body 3-1, an upper end bracket 3-2, a bevel gear A3-3, a middle end rotary column 3-4, a bevel gear B3-5, a bevel gear shaft B3-6, a bevel gear C3-7, a first stirring blade 3-8, a first connecting pipe 3-9, a coupling 3-10, a second belt wheel 3-11, a second connecting pipe 3-12, a first driving slide rod 3-13, a first driving slide rod pushing spring 3-14, a closing rod 3-17, a rectangular terminal 3-18 and a second stirring blade 3-19, the upper end bracket 3-2 is fixedly connected with the coating box body 3-1, the bevel gear A3-3 is rotatably connected with the upper end bracket 3-2, the middle end rotary column 3-4 is fixedly connected with a bevel gear A3-3, stirring vane II 3-19 is rotationally connected with middle end rotary column 3-4, bevel gear B3-5 is in meshing transmission with bevel gear A3-3, bevel gear B3-5 is fixedly connected with bevel gear shaft B3-6, bevel gear shaft B3-6 is rotationally connected with paint box 3-1, bevel gear C3-7 is in meshing transmission with bevel gear B3-5, bevel gear C3-7 is rotationally connected with paint box 3-1, stirring vane I3-8 is fixedly connected with bevel gear C3-7, connecting pipe I3-9 is fixedly connected and communicated with paint box 3-1, connecting pipe I3-9 is fixedly connected and communicated with rectangular terminal 3-18, the inner end of rectangular terminal 3-18 is hollowed out, connecting pipe II 3-12 is fixedly connected and communicated with rectangular terminal 3-18, pulley II 3-11 is fixedly connected with middle end rotary column 3-4, the coupler 3-10 is fixedly connected with the middle-end rotary column 3-4, the driving slide rod I3-13 is in sliding connection with the rectangular terminal 3-18, the driving slide rod I3-14 is in sleeve connection with the driving slide rod I3-13, the driving slide rod I3-14 is arranged between the driving slide rod I3-13 and the rectangular terminal 3-18, the closing rod 3-17 is in sliding connection with the rectangular terminal 3-18, the closing rod 3-17 is fixedly connected with the driving slide rod I3-13, the lower end of the driving slide rod I3-13 is in contact with the upper end boss I2-2 and the upper end boss II 2-3, and the connecting plate 5 is fixedly connected with the connecting pipe II 3-12.

The sixth specific implementation mode:

referring to fig. 1-14, the present embodiment will be further described, in which the carriage assembly 4 includes a carriage body 4-1, a carrier belt 4-2, an inner end roller 4-3, a pulley A4-4, a pulley belt A4-5, a pulley B4-6, a first bevel shaft 4-7, a first bevel gear 4-8, a second bevel gear 4-9, a pulley C4-10, a pulley belt B4-11, and an input motor 4-12, the inner end roller 4-3 is rotatably connected to the carriage body 4-1, the inner end roller 4-3 is specifically provided with two, the carrier belt 4-2 is connected to the inner end roller 4-3, one of the inner end rollers 4-3 is fixedly connected to the pulley A4-4, the belt wheel B4-6 is fixedly connected with a first bevel gear shaft 4-7, the first bevel gear shaft 4-7 is rotatably connected with the bracket main body 4-1, the belt wheel belt A4-5 is connected between the belt wheel A4-4 and the belt wheel B4-6, the first bevel gear 4-8 is fixedly connected with the first bevel gear shaft 4-7, the first bevel gear 4-8 is fixedly connected with the second bevel gear 4-9, the second bevel gear 4-9 is fixedly connected with the output shaft of the input motor 4-12, the input motor 4-12 is fixedly connected with the bracket main body 4-1, the belt wheel belt B4-11 is fixedly connected with the output shaft of the input motor 4-12, the paint box body 3-1 is fixedly connected with the bracket main body 4-1, and the coupling 3-10 is fixedly connected with the output shaft of the input motor 4-12, the belt wheel B4-11 is connected with the driving rotary column I1-2 in a matching way.

The invention relates to a ceramic tile plastering platform for buildings, which has the working principle that:

when the power output device is used, the input motor 4-12 is started, the input motor 4-12 drives the second bevel gear 4-9 and the belt wheel C4-10 to rotate simultaneously, the belt wheel C4-10 drives the belt B4-11 of the belt wheel to move conveniently, and power output is convenient to perform; meanwhile, the rotation of the second bevel gear 4-9 drives the first bevel gear 4-8 to rotate, further drives the first bevel gear shaft 4-7 to rotate through the first bevel gear 4-8, further drives the belt wheel B4-6 to move through the first bevel gear shaft 4-7, further drives the belt wheel belt A4-5 to move through the belt wheel B4-6, further drives the belt wheel A4-4 to move through the belt wheel belt A4-5, further drives the inner end roller one 4-3 to rotate through the belt wheel A4-4, further drives the carrying belt 4-2 to move through the inner end roller one 4-3, and further drives the tile to be plastered to move through the carrying belt 4-2; meanwhile, the ceramic tiles to be plastered are placed on the carrying belt 4-2, and the ceramic tiles to be plastered are driven to move by the carrying belt 4-2; meanwhile, the belt wheel belt B4-11 drives the driving rotary post I1-2 to rotate, and further drives the annular groove I1-3 to move through the driving rotary post I1-2, the driving sliders 1 to 6 are driven to move by the annular grooves 1 to 3, the hinged sliders 1 to 7 are driven to move by the driving sliders 1 to 6, then the articulated slider 1-7 drives the plastering plate 1-10 to move, so that the plastering plate 1-10 swings around the axis of the driving rotating block 1-9, the extreme position of the upper end of the plastering plate 1-10 is in a horizontal state, so that the straight teeth 1-8 are meshed with the end face half gears 1-4 for transmission, the plastering plate 1-10 rotates 180 degrees, the end faces of the plastering plates 1 to 10 are exchanged, so that the back of the ceramic tile is conveniently and uniformly smeared; meanwhile, manually rotating the manual rotating rod 1-17, further driving the inner end bevel gear four 1-16 to rotate through the manual rotating rod 1-17, further driving the inner end bevel gear three 1-15 to rotate through the inner end bevel gear four 1-16, further driving the inner end bevel gear shaft 1-14 to rotate through the inner end bevel gear three 1-15, further driving the inner end bevel gear two 1-13 to rotate through the inner end bevel gear shaft 1-14, further driving the inner end bevel gear one 1-12 and the inner end bevel gear five 1-20 to rotate through the inner end bevel gear two 1-13, further respectively driving the inner end bevel gear shaft two 1-18 and the inner end bevel gear shaft three 1-21 to rotate simultaneously, further enabling the expansion sliding plate 1-11 and the expansion sliding plate two 1-19 to move on both sides simultaneously, further expanding the plastering area of the plastering plate 1-10, so as to conveniently paint ceramic tiles with different specifications; meanwhile, the driving rotary column I1-2 rotates to drive the driving sleeve 2-1 to rotate, further the driving sleeve 2-1 simultaneously drives the upper end boss I2-2 and the upper end boss II 2-3 to move simultaneously, when the upper end boss I2-2 and the upper end boss II 2-3 or the driving slide bar I3-13 are contacted, further the driving slide bar I3-13 moves upwards, further the driving slide bar I3-13 drives the closing rod 3-17 to move upwards, further the connecting pipe I3-9 is communicated with the connecting pipe II 3-12, further the coating in the coating box body 3-1 flows into the rectangular terminal 3-18 through the connecting pipe I3-9, further flows into the connecting pipe II 3-12 through the rectangular terminal 3-18, further flows onto the plastering plate 1-10 through the connecting pipe II 3-12, meanwhile, along with the exchange of the plastering plates 1-10, the plastering plate 1-10 on the side where the coating falls faces to the back side of the ceramic tile, so that the coating falls on the ceramic tile, and meanwhile, the plastering plate 1-10 is used for scraping, so that the coating is conveniently and uniformly smeared on the north side of the ceramic tile; meanwhile, the middle end rotary column 3-4 is rotated, the inner end bevel gear six 2-5 is driven to rotate by the manual rotary rod two 2-4, the inner end bevel gear seven 2-6 is driven to rotate by the inner end bevel gear six 2-5, the inner end bevel gear shaft three 2-7 is driven to rotate by the inner end bevel gear seven 2-6, the driving straight gear one 2-8 is driven to rotate by the inner end bevel gear shaft three 2-7, the upper end boss two 2-3 is driven to move by the driving straight gear one 2-8, the upper end boss two 2-3 slides on the driving sleeve 2-1, the upper end boss two 2-3 expands the upper end boss one 2-2, and the contact time of the driving slide rod one 3-13 with the upper end boss two 2-3 and the upper end boss one 2-2 is changed, so that the communication time of the connecting pipe II 3-12 and the connecting pipe I3-9 is changed, the flowing-out time of the coating is changed, and the coating amount is changed; meanwhile, the input motor 4-12 drives the shaft coupler 3-10 to rotate, further drives the middle-end rotating column 3-4 to rotate through the shaft coupler 3-10, further drives the bevel gear A3-3 to rotate through the middle-end rotating column 3-4, further drives the bevel gear B3-5 to move through the bevel gear A3-3, further drives the bevel gear C3-7 to rotate through the bevel gear B3-5, and simultaneously drives the first stirring blade 3-8 and the second stirring blade 3-19 to move, so that the coating liquid in the coating box body 3-1 rotates, and further prevents the coating liquid from precipitating.

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

Claims (6)

1. The utility model provides a ceramic tile platform of plastering for building, including upset plastering subassembly (1), driver part (2), coating part (3), bracket component (4), even board (5), connecting band (6), its characterized in that: even board (5) are connected between a plurality of upset components of plastering (1), and drive unit (2) are connected with middle upset components of plastering (1), and paint unit (3) are connected with bracket component (4), and even board (5) are connected with paint unit (3), and connecting band (6) are connected between upset components of plastering (1) and paint unit (3), and connecting band (6) are connected between two adjacent upset components of plastering (1).

2. A tile plastering platform for construction according to claim 1, wherein: the overturning plastering assembly (1) comprises a plastering support (1-1), a driving rotary column I (1-2), an annular groove I (1-3), an end face half gear (1-4), a belt wheel I (1-5), a driving slider (1-6), a hinged slider (1-7), a straight tooth I (1-8), a driving rotary block (1-9), a plastering plate (1-10), an expanding sliding plate I (1-11), an inner end bevel tooth I (1-12), an inner end bevel tooth II (1-13), an inner end bevel tooth shaft I (1-14), an inner end bevel tooth III (1-15), an inner end bevel tooth IV (1-16), a manual rotary rod I (1-17), an inner end bevel tooth shaft II (1-18), an expanding sliding plate II (1-19), an inner end bevel tooth V (1-20), An inner end bevel gear shaft III (1-21) and an outer side push spring I (1-22), wherein a driving rotary column I (1-2) is rotatably connected with a plastering support (1-1), an annular groove I (1-3) is arranged on the driving rotary column I (1-2), an end face half gear (1-4) is fixedly connected with the driving rotary column I (1-2), a belt wheel I (1-5) is fixedly connected with the driving rotary column I (1-2), a driving slider (1-6) is slidably connected with the annular groove I (1-3), the driving slider (1-6) is hinged with a hinged slider (1-7), the hinged slider (1-7) is slidably connected with a plastering plate (1-10), a straight tooth I (1-8) is fixedly connected with the plastering plate (1-10), an expansion sliding plate I (1-11) is slidably connected with the plastering plate (1-10), the inner ends of the plastering plates (1-10) are hollow, the plastering plates (1-10) are rotatably connected with driving rotary blocks (1-9), the driving rotary blocks (1-9) are rotatably connected with a plastering support (1-1), the outer side push springs (1-22) are fixedly connected with the driving rotary blocks (1-9), the outer side push springs (1-22) are fixedly connected with the plastering support (1-1), the inner end bevel gears (1-12) are fixedly connected with the inner end bevel gear shafts (1-18), the inner end bevel gear shafts (1-18) are rotatably connected with the plastering support (1-1), the expansion sliding plates (1-11) are in threaded connection with the inner end bevel gear shafts (1-18), the expansion sliding plates (1-19) are in sliding connection with the plastering plates (1-10), and the inner end bevel gears (1-20) are rotatably connected with the inner end bevel gear shafts (1-21), an inner end bevel gear shaft III (1-21) is rotatably connected with a plastering support (1-1), an expansion sliding plate II (1-19) is in threaded connection with the inner end bevel gear shaft III (1-21), an inner end bevel gear II (1-13) is in meshing transmission with an inner end bevel gear I (1-12) and an inner end bevel gear V (1-20), an inner end bevel gear shaft I (1-14) is fixedly connected with the inner end bevel gear II (1-13), an inner end bevel gear III (1-15) is fixedly connected with an inner end bevel gear shaft I (1-14), an inner end bevel gear III (1-15) is in meshing transmission with an inner end bevel gear IV (1-16), an inner end bevel gear IV (1-16) is fixedly connected with a manual rotating rod I (1-17), and a manual rotating rod I (1-17) is rotatably connected with a plastering plate (1-10).

3. A tile plastering platform for construction according to claim 2, wherein: the turnover plastering assemblies (1) are provided with a plurality of belt wheels I (1-5) between two connected turnover plastering assemblies (1) which are connected through a connecting belt (6).

4. A tile plastering platform for construction according to claim 1, wherein: the driving part (2) comprises a driving sleeve (2-1), an upper end boss I (2-2), an upper end boss II (2-3), a manual rotating rod II (2-4), an inner end bevel gear VI (2-5), an inner end bevel gear VII (2-6), an inner end bevel gear shaft III (2-7) and a driving straight gear I (2-8), the upper end boss I (2-2) is fixedly connected with the driving sleeve (2-1), the upper end boss II (2-3) is in sliding connection with the driving sleeve (2-1), the manual rotating rod II (2-4) is in rotating connection with the driving sleeve (2-1), the inner end bevel gear VI (2-5) is fixedly connected with the manual rotating rod II (2-4), the inner end bevel gear VI (2-5) is in meshing transmission with the inner end bevel gear VII (2-6), an inner end bevel gear seven (2-6) is fixedly connected with an inner end bevel gear shaft three (2-7), the inner end bevel gear shaft three (2-7) is rotatably connected with a driving sleeve (2-1), a driving straight gear I (2-8) is fixedly connected with the inner end bevel gear shaft three (2-7), the inner end bevel gear shaft three (2-7) is in meshing transmission with an upper end boss II (2-3), a rack A is arranged at the lower end of the upper end boss II (2-3), and the driving sleeve (2-1) is fixedly connected with a belt pulley I (1-5).

5. A tile plastering platform for construction according to claim 1, wherein: the coating part (3) comprises a coating box body (3-1), an upper end support (3-2), bevel teeth A (3-3), a middle end rotary column (3-4), bevel teeth B (3-5), a bevel gear shaft B (3-6), bevel teeth C (3-7), a first stirring blade (3-8), a first connecting pipe (3-9), a coupler (3-10), a second belt wheel (3-11), a second connecting pipe (3-12), a first driving slide rod (3-13), a first driving slide rod pushing spring (3-14), a closing rod (3-17), a rectangular terminal (3-18) and a second stirring blade (3-19), wherein the upper end support (3-2) is fixedly connected with the coating box body (3-1), and the bevel teeth A (3-3) are rotatably connected with the upper end support (3-2), the middle-end rotating column (3-4) is fixedly connected with the bevel gear A (3-3), the stirring blade II (3-19) is rotatably connected with the middle-end rotating column (3-4), the bevel gear B (3-5) is in meshing transmission with the bevel gear A (3-3), the bevel gear B (3-5) is fixedly connected with the bevel gear shaft B (3-6), the bevel gear shaft B (3-6) is rotatably connected with the paint box body (3-1), the bevel gear C (3-7) is in meshing transmission with the bevel gear B (3-5), the bevel gear C (3-7) is rotatably connected with the paint box body (3-1), the stirring blade I (3-8) is fixedly connected with the bevel gear C (3-7), the connecting pipe I (3-9) is fixedly connected and communicated with the paint box body (3-1), the connecting pipe I (3-9) is fixedly connected and communicated with the rectangular terminal (3-18), the inner ends of the rectangular terminals (3-18) are hollowed, the connecting pipe II (3-12) is fixedly connected and communicated with the rectangular terminals (3-18), the belt wheel II (3-11) is fixedly connected with the middle-end rotating column (3-4), the shaft coupling (3-10) is fixedly connected with the middle-end rotating column (3-4), the driving slide bar I (3-13) is slidably connected with the rectangular terminals (3-18), the driving slide bar push spring I (3-14) is connected with the driving slide bar I (3-13) in a sleeved mode, the driving slide bar push spring I (3-14) is arranged between the driving slide bar I (3-13) and the rectangular terminals (3-18), the closing bar (3-17) is slidably connected with the rectangular terminals (3-18), and the closing bar I (3-17) is fixedly connected with the driving slide bar I (3-13), the lower end of the driving slide rod I (3-13) is contacted with the upper end boss I (2-2) and the upper end boss II (2-3), and the connecting plate (5) is fixedly connected with the connecting pipe II (3-12).

6. A tile plastering platform for construction according to claim 1, wherein: the support assembly (4) comprises a support main body (4-1), a carrying belt (4-2), an inner end roller I (4-3), a belt wheel A (4-4), a belt wheel belt A (4-5), a belt wheel B (4-6), a first bevel gear shaft I (4-7), a first bevel gear (4-8), a second bevel gear (4-9), a belt wheel C (4-10), a belt wheel belt B (4-11) and an input motor (4-12), wherein the inner end roller I (4-3) is rotatably connected with the support main body (4-1), the number of the inner end roller I (4-3) is specifically two, the carrying belt (4-2) is connected with the inner end roller I (4-3), one of the inner end roller I (4-3) is fixedly connected with the belt wheel A (4-4), the belt wheel B (4-6) is fixedly connected with a first bevel gear shaft I (4-7), the first bevel gear shaft I (4-7) is rotatably connected with the support main body (4-1), the belt wheel belt A (4-5) is connected between the belt wheel A (4-4) and the belt wheel B (4-6), the first bevel gear (4-8) is fixedly connected with the first bevel gear shaft I (4-7), the first bevel gear (4-8) is fixedly connected with a second bevel gear (4-9), the second bevel gear (4-9) is fixedly connected with an output shaft of an input motor (4-12), the input motor (4-12) is fixedly connected with the support main body (4-1), the belt wheel belt B (4-11) is fixedly connected with an output shaft of the input motor (4-12), the paint box body (3-1) is fixedly connected with the support main body (4-1), the shaft couplings (3-10) are fixedly connected with output shafts of the input motors (4-12), and the belt pulleys B (4-11) are connected with the driving rotary columns I (1-2) in a matching mode.

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