CN212562291U - Overhead ceramic tile paving structure - Google Patents

Abstract

The application discloses an overhead tile paving structure, which comprises a plurality of tiles erected on the ground, wherein side edge edges of two opposite sides of the back surface of each tile are respectively provided with a side edge connecting piece and a gasket, and the bottom of each side edge connecting piece is provided with an adjusting foot component; the side connecting piece comprises an upper flat plate and a lower flat plate which are bonded below the back of the ceramic tile, the lower flat plate is arranged on the side of the upper flat plate in a suspended mode, and the lower flat plate is slightly lower than the upper flat plate; the last plane of dull and stereotyped is equipped with a plurality of edge grooves down, and the gasket lower surface is equipped with a plurality of edges that match, and the edges on the gasket can cooperate the lock joint under on dull and stereotyped edge groove. This application ceramic tile is laid on ground and need not to stir cement, has avoided the more condition of job site dust, and the ceramic tile is spread the in-process and can be made level fast simultaneously, guarantees the roughness of every ceramic tile.

Description

Overhead ceramic tile paving structure

Technical Field

The application relates to an overhead ceramic tile paving structure.

Background

In the existing home decoration, the ceramic tile is often favored by people due to the characteristics of easy cleaning and beautiful appearance. However, when the ceramic tile floor is paved, a large amount of dust often exists, the whole construction period is long, and the labor cost for paving the existing cement worker is also high.

In addition, in the existing ceramic tile installation technology, the installation period is long, the requirement on manual skill of workers is high, and dust is easily generated on a construction site.

Disclosure of Invention

To the above-mentioned technical problem that prior art exists, the utility model aims at providing an overhead ceramic tile spreads pastes structure.

The overhead tile paving structure is characterized by comprising a plurality of tiles erected on the ground, wherein side edge edges of two opposite sides of the back of each tile are respectively provided with a side edge connecting piece and a gasket, and the bottom of each side edge connecting piece is provided with an adjusting foot component; the side connecting piece comprises an upper flat plate and a lower flat plate which are bonded below the back of the ceramic tile, the lower flat plate is arranged on the side of the upper flat plate in a suspended mode, and the lower flat plate is slightly lower than the upper flat plate;

the upper plane of the lower flat plate is provided with a plurality of prismatic grooves, the lower surface of the gasket is provided with a plurality of matched prismatic strips, and the prismatic strips on the gasket can be matched and buckled on the prismatic grooves of the lower flat plate; the ceramic tile is horizontally lapped on the ground through the adjusting foot component, and the space between the ceramic tile and the ground can be adjusted under the adjusting action of the adjusting foot component; a plurality of ceramic tiles laminate in proper order and align, and every lower flat board of ceramic tile back connection all is connected with the gasket cooperation at the adjacent next ceramic tile back, and then sets up a plurality of ceramic tiles concatenation subaerial.

The overhead ceramic tile paving structure is characterized in that an adhesive is arranged on the upper plane of the lower flat plate; when two adjacent ceramic tiles are matched and connected, the lower flat plate connected to the back of one ceramic tile is matched and fastened with the gasket on the back of the other adjacent ceramic tile, and the gasket is further bonded and fixed with the lower flat plate through the adhesive arranged on the upper surface of the lower flat plate.

The overhead tile paving structure is characterized in that when two adjacent tiles are connected in a matched mode, the back faces of the adjacent corners of the two tiles are fixedly bonded with diagonal connecting pieces through adhesives, and adjusting foot members are arranged at the bottoms of the diagonal connecting pieces.

The overhead ceramic tile paving structure is characterized in that the diagonal connecting pieces are of square plate structures, and the diagonal connecting pieces are averagely divided into 4 small square corners; when the 4 ceramic tiles are jointed together to form a large square structure, the back sides of the corners of the 4 ceramic tiles are respectively fixed on the 4 small square corners of the diagonal connecting piece through adhesive bonding.

The overhead tile paving structure is characterized in that the upper surfaces of 3 small square corners in the 4 small square corners of the diagonal connecting piece are positioned on the same plane, and the upper surface of the 4 th small square corner is slightly convex.

The overhead tile paving structure is characterized in that the adjusting foot component comprises a base, an adjusting seat, an adjusting rod and a limiting cavity block, wherein the base, the adjusting seat, the adjusting rod and the limiting cavity block are arranged from bottom to top; a cavity with a downward opening is vertically arranged on the limiting cavity block, and the upper end of the adjusting rod is matched and plugged into the cavity of the limiting cavity block.

The overhead tile paving structure is characterized in that a convex block for conveniently stirring and rotating the adjusting rod is further arranged on the side part of the adjusting rod.

The overhead tile paving structure is characterized in that in a side connecting piece arranged on the back of a tile, the bottom of an upper flat plate is provided with at least 2 adjusting foot components, and the bottom of a lower flat plate is provided with at least 1 adjusting foot component; in the diagonal connecting piece fixed by the back knot of the corner part of the ceramic tile, at least 2 adjusting foot components are arranged at the bottom of the diagonal connecting piece.

The overhead ceramic tile paving structure is characterized by further comprising an L-shaped side keel, wherein one side of the side keel is attached to a wall surface and is fixedly installed on the wall surface, and an L-shaped opening of the side keel is arranged upwards; when installing the ceramic tile that sets up along the wall, the ceramic tile lateral part is laminated with the wall, and the bottom of ceramic tile and the one side upper surface of limit fossil fragments bond fixedly through the gluing agent.

The overhead ceramic tile paving structure is characterized in that soundproof cotton is filled in a gap between a ceramic tile and the ground.

The beneficial effect that this application was got is:

to the problem that current ground ceramic tile shop pasted the existence, this application development a ground ceramic tile spreads subsides technique fast, and the ground ceramic tile shop of this application need not the cement stirring, has avoided the more condition of job site dust, and this scheme can make the ceramic tile shop paste the in-process and make level fast simultaneously, guarantees the roughness of every ceramic tile, has promoted the precision of making level.

Drawings

FIG. 1 is a schematic structural view of a tile and its bottom side connectors, spacers and diagonal connectors;

FIG. 2 is a side plan view of the tile and its bottom side and diagonal connectors;

FIG. 3 is a top view of a tile and its bottom side and diagonal connectors;

FIG. 4 is a schematic view of the installation and laying of the tiles on the ground;

FIG. 5 is a side view of the side attachment member and its bottom adjustment foot member;

FIG. 6 is a schematic structural view of an adjustment foot member;

in the figure: 1-ceramic tile, 2-side connecting piece, 21-upper flat plate, 22-lower flat plate, 3-diagonal connecting piece, 4-adjusting foot component, 401-base, 402-adjusting seat, 403-adjusting rod, 404-limiting cavity block and 5-gasket.

Detailed Description

The present invention is further illustrated by the following examples, which should not be construed as limiting the scope of the invention.

Example (b): compare fig. 1-6

An overhead tile paving structure comprises a plurality of tiles 1 erected on the ground, wherein side edge connectors 2 and gaskets 5 are respectively arranged at the side edge edges of two opposite sides of the back surface of each tile 1, and an adjusting foot component 4 is arranged at the bottom of each side edge connector 2; the side connecting piece 2 comprises an upper flat plate 21 and a lower flat plate 22 which are bonded below the back surface of the ceramic tile 1, the lower flat plate 22 is arranged on the side part of the upper flat plate 21 in a suspended mode, and the lower flat plate 22 is slightly lower than the upper flat plate 21. The last plane of dull and stereotyped 22 is equipped with a plurality of edge grooves down, and 5 lower surfaces of gasket are equipped with a plurality of edges that match, and the edge on the gasket 5 can cooperate the lock joint on dull and stereotyped 22's edge groove down.

The lower flat plates 22 connected with the back surfaces of the ceramic tiles 1 are matched and connected with the gasket 5 on the back surface of the next adjacent ceramic tile 1, so that the two adjacent ceramic tiles 1 can be fixedly installed. In order to further ensure the stability of the fixed installation between two adjacent ceramic tiles 1, the upper plane of the lower flat plate 22 is provided with an adhesive; when two adjacent ceramic tiles 1 are connected in a matching mode, the lower flat plate 22 connected to the back of one ceramic tile 1 is matched with the gasket 5 connected to the back of the other adjacent ceramic tile 1 in a matching and fastening mode, and the gasket 5 is further bonded and fixed with the lower flat plate 22 through the adhesive arranged on the upper surface of the lower flat plate 22. Wherein set up the edge groove on the dull and stereotyped 22 down, set up corresponding rib on the gasket 5, lower dull and stereotyped 22 cooperates with gasket 5 to bond when fixed, and the gluing agent on the dull and stereotyped 22 is difficult to outwards spill over down.

Referring to fig. 1 and 2, the back of the corner of the tile 1 is further provided with a diagonal connector 3, the diagonal connector 3 is in a square plate structure, and the diagonal connector 3 can be divided into 4 small square corners on average. In contrast to fig. 2, the corner of one tile 1 is placed at one of the small square corners of the diagonal connector 3. It can be seen that: when two adjacent ceramic tiles 1 are connected in a matching manner, the back surfaces of the adjacent corners of the two ceramic tiles 1 are also fixedly bonded with a diagonal connector 3 through adhesive, and the bottom of the diagonal connector 3 is provided with an adjusting foot member 4.

As is clear from a comparison of fig. 2, one diagonal connector 3 can be adhesively secured to the corners of four tiles 1. When the 4 ceramic tiles 1 are jointed together to form a large square structure, the backs of the corners of the 4 ceramic tiles 1 are respectively fixed on the 4 small square corners of the diagonal connecting piece 3 through adhesive bonding. Set up the aim at of diagonal connector 3, further strengthen the steadiness of installation ceramic tile, the corner limit of the ceramic tile of also being convenient for in addition aligns the laminating.

To facilitate the installation of the tiles, the diagonal connector 3 has 4 small square corners, of which the upper surfaces of the 3 small square corners are located in the same plane and the upper surface of the 4 th small square corner is slightly convex. That is, the height of the upper surface of one of the small square corners of the diagonal connector 3 is slightly higher than the height of the upper surfaces of the remaining three small square corners. The reason is that in the process of installing the ceramic tiles, when 4 ceramic tiles which can be jointed together to form a large square structure need to be installed, one small square corner of the diagonal connecting piece 3 is fixed on the back of the corner of the first ceramic tile in advance through adhesive, and then the first ceramic tile is laid on the ground; and then the other three tiles are installed, glue is applied in the process of laying the other three tiles, and the thickness of the adhesive on the upper surfaces of the other three small square corners of the diagonal connecting pieces 3 is slightly larger so as to facilitate the installation of the tiles.

In contrast, in fig. 1, in the side connecting piece 2 provided on the back surface of the tile 1, 2 adjusting foot members 4 are provided at the bottom of the upper plate 21, and 2 adjusting foot members 4 are provided at both ends of the bottom of the upper plate 21. The bottom of the lower flat plate 22 is provided with 1 adjusting foot component 4, and 1 adjusting foot component 4 is arranged in the middle of the bottom of the lower flat plate 22. It can be seen that the bottom of the side connecting piece 2 is provided with 3 adjusting foot members 4, and the 3 adjusting foot members 4 are distributed in an isosceles triangle shape.

Referring to fig. 1, in the diagonal connector 3 fixed to the back of the corner of the tile 1, 2 adjusting foot members 4 are provided at the bottom of the diagonal connector 3, and the 2 adjusting foot members 4 are provided at the bottoms of two opposite corners of the diagonal connector 3.

Referring to fig. 6, the adjusting foot member 4 includes a base 401, an adjusting seat 402, an adjusting rod 403 and a limiting cavity block 404, which are arranged from bottom to top, the lower surface of the base 401 is a plane, the adjusting seat 402 is arranged on the base 401, a thread groove with an upward opening is vertically arranged on the adjusting seat 402, a male thread is processed at the lower end of the adjusting rod 403, and the lower end of the adjusting rod 403 is screwed on the thread groove of the adjusting seat 402; a cavity with a downward opening is vertically arranged on the limit cavity block 404, and the upper end of the adjusting rod 403 is matched and plugged into the cavity of the limit cavity block 404; the side of the adjusting lever 403 is also provided with a protrusion for facilitating the rotation of the adjusting lever 403.

When the adjustment foot member 4 is installed on the ground, the lower surface of the base 401 may be adhesively fixed to the ground by an adhesive. The upper surface of the limiting cavity block 404 can be fixedly arranged at the bottom of the side connecting piece 2 or the bottom of the diagonal connecting piece 3 through adhesive.

Therefore, through the structure, the ceramic tile 1 is horizontally lapped on the ground through the adjusting foot members 4, and the space between the ceramic tile 1 and the ground can be adjusted under the adjusting effect of the adjusting foot members 4. Wherein the gap between the tile 1 and the ground can be filled with soundproof cotton.

When laying the ceramic tile on ground, a plurality of ceramic tiles 1 laminate in proper order and align, and the lower flat plate 22 of every ceramic tile 1 back connection all is connected with the gasket 5 cooperation at the adjacent next ceramic tile 1 back, and then sets up a plurality of ceramic tiles 1 concatenation subaerial.

In addition, ceramic tiles also need to be installed along the wall surface, so that the structure of the application also comprises an L-shaped side keel (the side keel can adopt L-shaped angle steel), one side of the side keel is attached to the wall surface and is installed and fixed on the wall surface, and an L-shaped opening of the side keel is arranged upwards; when installing the ceramic tile 1 that sets up along the wall, 1 lateral part of ceramic tile and wall laminating, and the bottom of ceramic tile 1 and the one side upper surface of limit fossil fragments bond fixedly through gluing agent. It can be seen that the edge keel can support the ceramic tile to a certain extent.

The method for mounting the overhead ceramic tile paving structure comprises the following steps:

1. according to the height of the ceramic tile to be installed, the edge keel is fixedly installed on the wall surface in advance;

2. bonding a side connecting piece and a diagonal connecting piece on the back of the ceramic tile, and respectively installing an adjusting foot member at the bottom of the side connecting piece and the bottom of the diagonal connecting piece;

3. when installing tiles, the tiles need to be installed in sequence from one side of the wall to the opposite other side. Firstly, installing a ceramic tile along one side wall surface, attaching the side part of the ceramic tile to the wall surface, bonding and fixing the bottom of the ceramic tile and a side keel on the wall surface through an adhesive, and filling sound insulation cotton at the bottom of the installed ceramic tile;

4. then, sequentially installing the inner-side ceramic tiles, wherein a lower flat plate connected with the back of each ceramic tile is matched and connected with a gasket on the back of the next adjacent ceramic tile, the backs of the corners of the ceramic tiles are fixed on diagonal connecting pieces through adhesives, and then splicing and erecting a plurality of ceramic tiles on the ground, and filling soundproof cotton at the bottom of the installed ceramic tiles;

5. and finally, installing the last ceramic tile close to the other side face of the wall, enabling the side part of the last ceramic tile to be close to the other side face of the wall, bonding and fixing the bottom of the last ceramic tile and the edge keel on the other side face of the wall through an adhesive, and finally completing installation.

Wherein, when installing along the ceramic tile of wall setting: carry out the ceramic tile side bottom of cementing with the limit fossil fragments and need not to set up side connecting piece or gasket again, the direct one side upper surface with the limit fossil fragments in ceramic tile side bottom surface bond fixedly can through the gluing agent.

The statements in this specification merely set forth a list of implementations of the inventive concept and the scope of the present invention should not be construed as limited to the particular forms set forth in the examples.

Claims (10)

1. An overhead tile paving structure is characterized by comprising a plurality of tiles (1) erected on the ground, wherein side edge edges of two opposite sides of the back of each tile (1) are respectively provided with a side edge connecting piece (2) and a gasket (5), and the bottom of each side edge connecting piece (2) is provided with an adjusting foot component (4); the side connecting piece (2) comprises an upper flat plate (21) and a lower flat plate (22) which are bonded below the back of the ceramic tile (1), the lower flat plate (22) is arranged on the side of the upper flat plate (21) in a suspended mode, and the lower flat plate (22) is slightly lower than the upper flat plate (21);

the upper plane of the lower flat plate (22) is provided with a plurality of edge grooves, the lower surface of the gasket (5) is provided with a plurality of matched edge strips, and the edge strips on the gasket (5) can be matched and buckled on the edge grooves of the lower flat plate (22);

the ceramic tile (1) is horizontally lapped on the ground through the adjusting foot component (4), and the distance between the ceramic tile (1) and the ground can be adjusted under the adjusting action of the adjusting foot component (4); a plurality of ceramic tiles (1) are sequentially attached and aligned, the lower flat plate (22) connected with the back of each ceramic tile (1) is matched and connected with the gasket (5) at the back of the adjacent lower ceramic tile (1), and then the ceramic tiles (1) are spliced and erected on the ground.

2. An overhead tile laying structure as claimed in claim 1, wherein the upper plane of said lower plate (22) is provided with adhesive; when two adjacent ceramic tiles (1) are matched and connected, the lower flat plate (22) connected with the back of one ceramic tile (1) is matched and fastened with the gasket (5) at the back of the other adjacent ceramic tile (1), and the gasket (5) is further bonded and fixed with the lower flat plate (22) through the adhesive arranged on the upper surface of the lower flat plate (22).

3. An overhead tile paving structure as claimed in claim 1, wherein when two adjacent tiles (1) are connected in a matching manner, the back surfaces of the adjacent corners of the two tiles (1) are also fixedly bonded with diagonal connectors (3) by adhesives, and the bottoms of the diagonal connectors (3) are provided with adjusting foot members (4).

4. An overhead tile paving structure as claimed in claim 3, characterized in that said diagonal connector (3) is a square plate structure, said diagonal connector (3) being divided into 4 small square corners on average; when the 4 ceramic tiles (1) are jointed together to form a large square structure, the backs of the corners of the 4 ceramic tiles (1) are respectively bonded and fixed on the 4 small square corners of the diagonal connecting piece (3) through adhesives.

5. An overhead tile decking structure as claimed in claim 4, wherein the diagonal connector (3) has 4 small square corners, with the upper surfaces of the 3 small square corners lying in the same plane and the upper surface of the 4 small square corner being slightly convex.

6. An overhead tile paving structure as claimed in claim 1, wherein the adjusting foot member (4) comprises a base (401), an adjusting seat (402), an adjusting rod (403) and a limiting cavity block (404) arranged from bottom to top, the lower surface of the base (401) is a plane, the adjusting seat (402) is arranged on the base (401), a thread groove with an upward opening is vertically arranged on the adjusting seat (402), a male thread is processed at the lower end of the adjusting rod (403), and the lower end of the adjusting rod (403) is in fit screw connection with the thread groove of the adjusting seat (402); a cavity with a downward opening is vertically arranged on the limiting cavity block (404), and the upper end of the adjusting rod (403) is matched and plugged into the cavity of the limiting cavity block (404).

7. An overhead tile laying structure as claimed in claim 6, wherein the side of the adjusting bar (403) is further provided with a projection for facilitating the rotation of the adjusting bar (403).

8. An overhead tile laying structure as claimed in claim 4, wherein in the side connectors (2) provided on the back of the tile (1), at least 2 adjustment leg members (4) are provided on the bottom of the upper plate (21), and at least 1 adjustment leg member (4) is provided on the bottom of the lower plate (22); in the diagonal connecting piece (3) fixed on the back of the corner of the ceramic tile (1), at least 2 adjusting foot members (4) are arranged at the bottom of the diagonal connecting piece (3).

9. The overhead tile paving structure of claim 1, further comprising an L-shaped side keel, wherein one side of the side keel is attached to and fixed to the wall surface, and the L-shaped opening of the side keel is upwardly disposed; when installing ceramic tile (1) that sets up along the wall, ceramic tile (1) lateral part and wall laminating, and the bottom of ceramic tile (1) and the one side upper surface of limit fossil fragments bond fixedly through the gluing agent.

10. An overhead tile laying construction as claimed in claim 1, wherein the gap between the tile (1) and the ground is filled with sound-insulating cotton.

Images