CN216616747U - Auxiliary structure that green ceramic tile was laid - Google Patents

Abstract

The application discloses an auxiliary structure for laying green and environment-friendly ceramic tiles, which relates to the field of equipment for interior decoration, and comprises a bottom plate, pulleys arranged on the bottom plate, a support frame arranged on the bottom plate, an installation rod and an adsorption rod arranged on the installation rod; the vacuum adjusting device is characterized in that a vacuum chuck is arranged on the adsorption rod, and a vacuum adjusting assembly used for adjusting the vacuum degree between the vacuum chuck and the ceramic tile is arranged between the support frame and the vacuum chuck. This application has the effect of being convenient for by taking off the ceramic tile on the bottom plate, and adjacent ceramic tile separates along vertical direction simultaneously to can reduce the risk of ceramic tile mutual wearing and tearing.

Description

Auxiliary structure that green ceramic tile was laid

Technical Field

The utility model belongs to the technical field of equipment for interior decoration and specifically relates to an auxiliary structure that green ceramic tile laid is related to.

Background

Ceramic tiles are a building material used to decorate floors or walls. At present, the tile is usually laid manually, and the main steps are as follows: performing base layer treatment, namely leveling the ground or the wall surface; line snapping, namely popping a cross line on the ground or the wall surface; paving, namely smearing tile glue on the back of the tile and then paving the tile glue on the brushed cement mortar leveling layer.

At present, in order to reduce the labor intensity of constructors, an auxiliary structure convenient for tile laying is provided, and the auxiliary structure generally comprises a bottom plate, universal wheels arranged on the lower surface of the bottom plate, a pushing handle arranged on the bottom plate and a limiting assembly arranged on the bottom plate and used for limiting the motion range of tiles. When the ceramic tile is required to be moved to the indoor space, the ceramic tile is placed on the bottom plate, and then the bottom plate is pushed to the indoor space.

With respect to the related art among the above, the inventors consider that the following drawbacks exist: when constructor need take off the ceramic tile on the bottom plate, because the ceramic tile adopts the mode of piling up to place, and the clearance is less between two adjacent ceramic tiles, constructor usually can the level earlier promote the ceramic tile that is located the top, then takes out the ceramic tile of top again, and the operation of taking out the ceramic tile is more complicated, and leads to the easy mutual wearing and tearing of ceramic tile easily.

SUMMERY OF THE UTILITY MODEL

In order to improve the problem that is not convenient for take off the ceramic tile and the easy ceramic tile that wears off on by the bottom plate, this application provides an auxiliary structure that green ceramic tile laid.

The application provides a pair of auxiliary structure that green ceramic tile laid adopts following technical scheme:

an auxiliary structure for paving green environment-friendly ceramic tiles comprises a bottom plate, pulleys arranged on the bottom plate, a support frame arranged on the bottom plate, a mounting rod and an adsorption rod arranged on the mounting rod; the vacuum adjusting device is characterized in that a vacuum chuck is arranged on the adsorption rod, and a vacuum adjusting assembly used for adjusting the vacuum degree between the vacuum chuck and the ceramic tile is arranged between the support frame and the vacuum chuck.

Through adopting above-mentioned technical scheme, when needing to place or take off the ceramic tile on the bottom plate, constructor removes the absorption pole through the installation pole, and place vacuum chuck and laminate on the ceramic tile, vacuum between rethread vacuum regulation subassembly promotion vacuum chuck and the ceramic tile, and then vacuum chuck adsorbs on the ceramic tile steadily, rethread removes the installation pole along vertical direction and can takes off the ceramic tile from the bottom plate, thereby realize being convenient for by the effect of taking off the ceramic tile on the bottom plate, adjacent ceramic tile separates along vertical direction simultaneously, thereby can reduce the risk of the mutual wearing and tearing of ceramic tile.

Optionally, the number of the adsorption rods is multiple, and the multiple adsorption rods are arranged at intervals along the length direction of the mounting rod.

Through adopting above-mentioned technical scheme, a plurality of absorption poles can adsorb a plurality of ceramic tiles simultaneously to can promote the transport of ceramic tile and lay efficiency.

Optionally, the adsorption rod includes a fixed part connected to the installation rod and two adjusting parts movably connected to two ends of the fixed part respectively; the vacuum chuck is arranged on the lower surface of the adjusting part; the fixing part is provided with an adjusting component for adjusting the position of the adjusting part.

Through adopting above-mentioned technical scheme, when adsorbing the ceramic tile, two adjustment portions adsorb respectively in the both ends of ceramic tile, and then can promote the stability of being connected of adsorbing pole and ceramic tile. Simultaneously when carrying different sizes, the adjustment subassembly can adjust the interval between two adjustment portions to be applicable to and adsorb the not ceramic tile of equidimension steadily, be favorable to expanding auxiliary structure's application scope.

Optionally, the adjusting assembly includes two adjusting screws corresponding to the adjusting portions one to one, both ends of the fixing portion are respectively provided with a threaded hole adapted to the adjusting screws in a penetrating manner, and the adjusting portion is provided with an adjusting groove; the end part of the adjusting screw rod penetrates through the threaded hole and is inserted into the adjusting groove, and the end part of the adjusting screw rod is abutted and matched with the bottom wall of the adjusting groove.

Through adopting above-mentioned technical scheme, when the interval between two adjustment portions need be adjusted, forerunner makes adjusting screw rotatory, until adjusting screw and the diapire separation of adjustment tank, orders about the adjustment portion again and slides along the length direction of fixed part, when the interval size between two adjustment portions matches with the interval size of ceramic tile, orders about adjusting screw reversal again, until adjusting screw's tip supports tightly in the diapire of adjustment tank, can restrict the activity of adjustment portion to can adsorb the ceramic tile of different sizes steadily.

Optionally, the adjusting assembly includes an adjusting gear rotatably connected to the fixing portion, two adjusting racks respectively connected to the two adjusting portions, and a locking member for limiting rotation of the adjusting gear; the two adjusting racks are respectively positioned on two opposite sides of the adjusting gear and are meshed with the adjusting gear.

Through adopting above-mentioned technical scheme, when the interval between two adjustment portions of needs adjustment, forerunner makes the adjusting gear rotatory to through the meshing transmission between adjusting gear and two adjustment racks, and then drive two adjustment portions and be close to each other or keep away from, when the interval size between two adjustment portions matches with the interval size of ceramic tile, the rotation of rethread locking piece restriction adjusting gear can restrict the activity of adjustment portion, and can adsorb not unidimensional ceramic tile steadily.

Optionally, the adjusting gear is coaxially connected with a rotating rod, and an end of the rotating rod penetrates through the fixing part and the mounting rod;

the locking part comprises an operating ring movably sleeved on the rotating rod, a locking ring fixed on the mounting rod and sleeved on the periphery of the rotating rod and a clamping block fixed on the outer wall of the operating ring; the operating ring can enter the locking ring along the axial direction of the rotating rod and synchronously rotate with the rotating rod; the inner wall of the locking ring is provided with a plurality of clamping grooves matched with the clamping blocks in a clamping mode, and the plurality of clamping grooves are axially arranged at intervals along the inner wall of the locking ring.

By adopting the technical scheme, when the adjusting gear needs to be rotated, the operating ring gradually moves away from the locking ring along the axial direction of the rotating rod by the aid of the forerunner until the operating ring is separated from the locking ring, and the clamping block is separated from the clamping groove, so that the adjusting gear can be rotated; when the rotation of the adjusting gear needs to be limited, the operating ring is gradually close to the locking ring along the axial direction of the rotating rod by the aid of the forerunner until the operating ring is inserted into the locking ring, and the clamping block is inserted into the clamping groove, so that the rotation of the adjusting gear can be limited.

Optionally, the vacuum adjusting assembly includes a mounting plate disposed on the supporting frame, a vacuum generator mounted on the mounting plate, and a plurality of hoses connected to the vacuum generator; the hoses are respectively in one-to-one correspondence with and connected with the vacuum suckers.

By adopting the technical scheme, when the tile is required to be adsorbed, the vacuum generator and the hose are used for pumping air between the vacuum sucker and the tile, so that the vacuum sucker can be stably adsorbed on the tile; when the tile is required to be separated, the vacuum generator and the hose stop pumping out air between the vacuum chuck and the tile, and then the vacuum chuck and the tile can be separated.

Optionally, the end of the mounting plate is rotatably connected to the support frame.

By adopting the technical scheme, the movable area of the adsorption rod can be enlarged by the rotatable mounting plate, so that the working area of constructors can be enlarged.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the two adjusting parts are respectively placed at the two ends of the ceramic tile, the vacuum chuck is attached to the ceramic tile, air between the vacuum chuck and the ceramic tile is pumped out through the vacuum generator and the hose, the vacuum chuck is stably adsorbed on the ceramic tile, the ceramic tile can be taken down from the bottom plate by moving the mounting rod in the vertical direction, the effect of taking the ceramic tile down from the bottom plate is achieved, meanwhile, the adjacent ceramic tiles are separated in the vertical direction, and therefore the risk of mutual abrasion of the ceramic tiles can be reduced;

2. the adjusting parts are driven to slide along the length direction of the fixing part, and when the space between the two adjusting parts is matched with the space between the ceramic tiles, the adjusting screw rod is driven to rotate reversely until the end part of the adjusting screw rod is abutted against the bottom wall of the adjusting groove, so that the movement of the adjusting parts can be limited, and the ceramic tiles with different sizes can be stably adsorbed;

3. through ordering about the adjustment gear rotatory to through the meshing transmission between adjustment gear and two adjustment racks, and then drive two adjustment portions and be close to each other or keep away from, when the interval size between two adjustment portions matches with the interval size of ceramic tile, the rotation of rethread operating ring, locking ring and joint piece restriction adjustment gear can restrict the activity of adjustment portion, and can adsorb the ceramic tile of different sizes steadily.

Drawings

Fig. 1 is a schematic overall structure diagram of a first embodiment of the present application.

FIG. 2 is a schematic structural diagram of a mounting rod, an adsorption rod and an adjustment assembly according to an embodiment of the present application.

Fig. 3 is a partially enlarged schematic view of a portion a in fig. 1.

FIG. 4 is a schematic structural diagram of a second mounting rod, a suction rod and an adjusting assembly according to an embodiment of the present application.

FIG. 5 is a schematic structural view of a second mounting rod, a fixing portion, an adjusting gear and a locking member according to an embodiment of the present invention.

Fig. 6 is a partially enlarged schematic view of a portion B in fig. 5.

Reference numerals: 1. a base plate; 11. a pulley; 12. a push rod; 13. a support frame; 131. a rotating cylinder; 2. mounting a rod; 21. an operating handle; 3. an adsorption rod; 31. a fixed part; 311. an adjusting block; 312. a threaded hole; 32. an adjustment part; 321. an adjustment groove; 322. a vacuum chuck; 4. an adjustment assembly; 41. adjusting the screw rod; 42. adjusting the gear; 421. rotating the rod; 4211. a limiting groove; 43. adjusting the rack; 44. a locking member; 441. an operating ring; 4411. a limiting block; 442. locking a ring; 4421. a clamping groove; 443. a clamping block; 5. a vacuum adjustment assembly; 51. mounting a plate; 52. a vacuum generator; 53. a hose.

Detailed Description

The present application is described in further detail below with reference to figures 1-6.

The first embodiment is as follows:

the embodiment of the application discloses auxiliary structure that green ceramic tile laid. Referring to fig. 1 and 2, the auxiliary structure for paving green environmental protection tiles comprises a bottom plate 1, a pulley 11 arranged on the lower surface of the bottom plate 1 through a screw, a push rod 12 connected to the bottom plate 1 through a welding mode, a support frame 13 arranged on the bottom plate 1 through a screw, a mounting rod 2 capable of freely moving, and an adsorption rod 3 arranged on the mounting rod 2. The pulleys 11 can be provided as directional wheels or universal wheels, and the pulleys 11 are provided with four and are respectively positioned at four corners of the bottom plate 1.

Referring to fig. 1 and 2, the mounting rod 2 is in a strip shape, and an operating handle 21 for facilitating operation is disposed in the middle of the mounting rod 2 through a screw. The number of the adsorption rods 3 is multiple, in the embodiment of the application, two adsorption rods 3 are provided, and two adsorption rods 3 are arranged at intervals along the length direction of the mounting rod 2, and in other embodiments, the distance between two adjacent adsorption rods 3 can be adjusted.

Referring to fig. 1 and 2, the adsorption rod 3 includes a fixing portion 31 connected to the end of the installation rod 2 by a screw and two adjusting portions 32 movably connected to two ends of the fixing portion 31, the fixing portion 31 and the adjusting portions 32 are both in a strip shape, and the length directions of the fixing portion 31 and the adjusting portions 32 are perpendicular to the length direction of the installation rod 2. The adjusting portion 32 is provided with an adjusting groove 321 along the length direction thereof, the fixing portion 31 is welded with an adjusting block 311 sliding in the adjusting groove 321, so that the adjusting portion 32 stably slides along the length direction of the fixing portion 31 and is fixed on the fixing portion 31, and the fixing portion 31 is provided with an adjusting assembly 4 for adjusting the position of the adjusting portion 32.

Referring to fig. 1 and 2, the suction rod 3 is provided with vacuum cups 322, that is, the vacuum cups 322 are disposed on the lower surfaces of the adjusting portions 32, and each of the adjusting portions 32 is correspondingly provided with one vacuum cup 322. A vacuum adjusting component 5 for adjusting the vacuum degree between the vacuum suction cup 322 and the ceramic tile is arranged between the supporting frame 13 and the vacuum suction cup 322.

When placing or taking off the ceramic tile on bottom plate 1 at needs, constructor passes through handle removal installation pole 2, and drive fixed part 31 and be located the ceramic tile top respectively, place vacuum chuck 322 again and laminate on the ceramic tile, and promote the vacuum between vacuum chuck 322 and the ceramic tile through vacuum adjusting part 5, and then vacuum chuck 322 adsorbs on the ceramic tile steadily, the rethread removes installation pole 2 along vertical direction and can takes off the ceramic tile from bottom plate 1, with this effect of taking off the ceramic tile on being convenient for by bottom plate 1, and adjacent ceramic tile separates along vertical direction, thereby can reduce the risk of the mutual wearing and tearing of ceramic tile. When carrying different sizes simultaneously, adjustment assembly 4 can adjust the interval between two adjustment portions 32 to be applicable to stably adsorbing the not unidimensional ceramic tile, be favorable to expanding auxiliary structure's application scope.

Referring to fig. 1 and 2, the adjusting assembly 4 includes two adjusting screws 41 corresponding to the adjusting portions 32 one by one, two ends of the fixing portion 31 are both penetrated with threaded holes 312 adapted to the adjusting screws 41, and an extending direction of the threaded holes 312 is perpendicular to a length direction of the fixing portion 31. The end of the adjusting screw 41 is inserted into the adjusting groove 321 through the threaded hole 312, and is in abutting engagement with the bottom wall of the adjusting groove 321.

When the distance between the two adjusting portions 32 needs to be adjusted, the adjusting screw rod 41 is rotated until the adjusting screw rod 41 is separated from the bottom wall of the adjusting groove 321, then the adjusting portions 32 are driven to slide along the length direction of the fixing portion 31, and when the distance between the two adjusting portions 32 is matched with the distance between the tiles, the adjusting screw rod 41 is driven to rotate reversely until the end portion of the adjusting screw rod 41 abuts against the bottom wall of the adjusting groove 321, so that the movement of the adjusting portions 32 can be limited, and the tiles with different sizes can be stably adsorbed.

Referring to fig. 1 and 3, the vacuum adjusting assembly 5 includes a mounting plate 51 provided on the support bracket 13, a vacuum generator 52 mounted on the mounting plate 51 by bolts, and a plurality of hoses 53 connected to the vacuum generator 52. The top of the support frame 13 is provided with a rotary cylinder 131 through a bolt, an output rod of the rotary cylinder 131 is arranged along the vertical direction, and the end of the mounting plate 51 is connected with the output rod of the rotary cylinder 131, so that the end of the mounting plate 51 is rotatably connected to the support frame 13. The plurality of hoses 53 are respectively connected to the plurality of vacuum chucks 322 in a one-to-one correspondence.

When the tile needs to be adsorbed, the vacuum generator 52 and the hose 53 are used for pumping out air between the vacuum suction cup 322 and the tile, so that the vacuum suction cup 322 can be stably adsorbed on the tile; when the tile is to be separated, the vacuum generator 52 and the hose 53 stop the air between the vacuum cup 322 and the tile, and the vacuum cup 322 and the tile can be separated. Meanwhile, the mounting plate 51 can be driven to rotate by the rotating cylinder 131, and the moving area of the adsorption rod 3 is enlarged, so that the working area of a constructor can be enlarged.

The implementation principle of the auxiliary structure that green ceramic tile laid in the embodiment of this application is: when placing or taking off the ceramic tile on bottom plate 1 at needs, constructor passes through handle removal installation pole 2, and drive fixed part 31 and be located the ceramic tile top respectively, place vacuum chuck 322 and laminate on the ceramic tile again, and take out the air between vacuum chuck 322 and the ceramic tile through vacuum regulating assembly 5 vacuum generator 52 and hose 53, and then vacuum chuck 322 adsorbs steadily on the ceramic tile, the rethread removes installation pole 2 along vertical direction and can takes off the ceramic tile from bottom plate 1, with this effect of taking off the ceramic tile on realizing being convenient for by bottom plate 1, and adjacent ceramic tile is along vertical direction separation, thereby can reduce the risk of the mutual wearing and tearing of ceramic tile.

Example two:

referring to fig. 4 and 5, the difference between the second embodiment and the first embodiment of the present application is that the adjusting component 4: the adjusting assembly 4 includes an adjusting gear 42 rotatably connected to the fixing portion 31, two adjusting racks 43 respectively connected to the two adjusting portions 32, and a locking member 44 for limiting the rotation of the adjusting gear 42. The adjusting gear 42 is coaxially connected with a rotating rod 421, and the end of the rotating rod 421 penetrates the middle of the fixing part 31 and the mounting rod 2 along the vertical direction, so that the adjusting gear 42 rotates around the axis of the rotating rod 421. The two adjusting racks 43 are respectively located on two opposite sides of the adjusting gear 42, and are both meshed with the adjusting gear 42.

Referring to fig. 5 and 6, the locking member 44 includes an operation ring 441 movably fitted over the rotation rod 421, a locking ring 442 fixed to the top surface of the installation rod 2 by welding and fitted over the circumferential side of the rotation rod 421, and a catching block 443 fixed to the outer wall of the operation ring 441 by welding. The peripheral wall of dwang 421 has seted up spacing groove 4211 along the axial, and the welding of the inner wall of operation ring 441 has stopper 4411 that slides in spacing groove 4211 for operation ring 441 can follow the axial of dwang 421 and get into in locking ring 442, and rotate with dwang 421 synchronous. The inner wall of the locking ring 442 is axially provided with a plurality of clamping grooves 4421 which are in clamping fit with the clamping blocks 443, and the plurality of clamping grooves 4421 are axially arranged along the inner wall of the locking ring 442 at intervals.

The principle of the second embodiment is as follows: when the distance between the two adjusting portions 32 needs to be adjusted, the operating ring 441 is gradually separated from the locking ring 442 along the axial direction of the rotating rod 421 until the operating ring 441 is separated from the locking ring 442 and the clamping block 443 is separated from the clamping groove 4421, then the adjusting gear 42 is driven to rotate and the two adjusting gear racks 43 are driven to be meshed and driven to drive the two adjusting portions 32 to approach or separate from each other, and when the distance between the two adjusting portions 32 is matched with the distance between the tiles, the operating ring 441 is gradually driven to approach the locking ring 442 along the axial direction of the rotating rod 421 until the operating ring 441 is inserted into the locking ring 442 and the clamping block 443 is inserted into the clamping groove 4421, so that the movement of the adjusting portions 32 can be limited and the tiles with different sizes can be stably adsorbed.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: equivalent changes in structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides an auxiliary structure that green ceramic tile laid, includes bottom plate (1), set up pulley (11) on bottom plate (1) and set up in support frame (13) on bottom plate (1), its characterized in that: the device also comprises a mounting rod (2) and an adsorption rod (3) arranged on the mounting rod (2);

the ceramic tile vacuum adsorption device is characterized in that a vacuum sucker (322) is arranged on the adsorption rod (3), and a vacuum adjusting assembly (5) used for adjusting the vacuum degree between the vacuum sucker (322) and a ceramic tile is arranged between the support frame (13) and the vacuum sucker (322).

2. An auxiliary structure for green environmental tile laying according to claim 1, wherein: the adsorption rods (3) are arranged in a plurality, and the adsorption rods (3) are arranged at intervals along the length direction of the mounting rod (2).

3. An auxiliary structure for green environmental tile laying according to claim 1, wherein: the adsorption rod (3) comprises a fixed part (31) connected to the mounting rod (2) and two adjusting parts (32) respectively and movably connected to two ends of the fixed part (31);

the vacuum sucker (322) is arranged on the lower surface of the adjusting part (32);

the fixing part (31) is provided with an adjusting component (4) for adjusting the position of the adjusting part (32).

4. An auxiliary structure for green environmental tile laying according to claim 3, wherein: the adjusting assembly (4) comprises two adjusting screws (41) which are in one-to-one correspondence with the adjusting parts (32), two ends of the fixing part (31) are respectively provided with a threaded hole (312) matched with the adjusting screws (41) in a penetrating manner, and the adjusting parts (32) are provided with adjusting grooves (321);

the end part of the adjusting screw rod (41) passes through the threaded hole (312) and is inserted into the adjusting groove (321), and is in butt fit with the bottom wall of the adjusting groove (321).

5. An auxiliary structure for green environmental tile laying according to claim 3, wherein: the adjusting assembly (4) comprises an adjusting gear (42) rotatably connected to the fixing part (31), two adjusting racks (43) respectively connected with the two adjusting parts (32) and a locking part (44) used for limiting the rotation of the adjusting gear (42);

the two adjusting racks (43) are respectively positioned on two opposite sides of the adjusting gear (42) and are meshed with the adjusting gear (42).

6. An auxiliary structure for green environmental tile laying according to claim 5, wherein: the adjusting gear (42) is coaxially connected with a rotating rod (421), and the end part of the rotating rod (421) penetrates through the fixing part (31) and the mounting rod (2);

the locking piece (44) comprises an operating ring (441) movably sleeved on the rotating rod (421), a locking ring (442) fixed on the mounting rod (2) and sleeved on the peripheral side of the rotating rod (421), and a clamping block (443) fixed on the outer wall of the operating ring (441);

the operating ring (441) can enter the locking ring (442) along the axial direction of the rotating rod (421) and synchronously rotate with the rotating rod (421);

the inner wall of the locking ring (442) is provided with a plurality of clamping grooves (4421) matched with the clamping blocks (443) in a clamping mode, and the clamping grooves (4421) are arranged at intervals along the axial direction of the inner wall of the locking ring (442).

7. An auxiliary structure for green environmental protection tile laying according to any one of claims 1-6, wherein: the vacuum adjusting assembly (5) comprises a mounting plate (51) arranged on the support frame (13), a vacuum generator (52) mounted on the mounting plate (51) and a plurality of hoses (53) connected with the vacuum generator (52);

the hoses (53) are respectively in one-to-one correspondence with and connected to the vacuum chucks (322).

8. An auxiliary structure for green environmental tile laying according to claim 7, wherein: the end part of the mounting plate (51) is rotatably connected to the support frame (13).

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