CN210417622U - Ceramic tile support structure - Google Patents

Abstract

The utility model provides a ceramic brick is beaten and is held in palm structure, include: the ceramic tile fixing device comprises a tray, a first bracket fixing position, a second bracket fixing position and a ceramic tile fixing position, wherein the first bracket fixing position is arranged on the first side of the tray; the ceramic tile fixing position is used for placing a ceramic tile to be held, a first support is placed on the first support fixing position, and a second support is placed on the second support fixing position; a first binding belt for fixing the ceramic tiles is arranged between the second side and the fourth side of the tray, and a second binding belt for fixing the ceramic tiles is arranged between the first support and the second support. The utility model discloses a side at the tray sets up first support, second support, first bandage and second bandage for the packing of pottery brick is more firm, and practices thrift the packing cost, is convenient for transport.

Description

Ceramic tile support structure

Technical Field

The utility model relates to a pottery brick is beaten and is held in the palm technical field, what especially relate to is a pottery brick beats and holds in the palm structure.

Background

As ceramic tile manufacturing technology advances, ceramic tiles also grow larger in size. The large-size ceramic tile (the area of a single tile is not less than 0.64 square meter) can be applied to the ground, the wall surface and the furniture table surface, the application scenes are more and more extensive, and the sales volume is increased year by year.

In the prior art, the small-size ceramic tiles can be placed in a mutually perpendicular mode when being stacked, the ceramic tiles cannot topple due to the fact that the ceramic tiles are mutually supported in four directions, and the whole support transportation and long-distance transportation of the ceramic tiles can normally operate. The large-size ceramic tiles are limited by the size of the container and cannot be placed in a mutually perpendicular mode.

Currently, two methods are generally adopted in packaging pallets. One way is to lay flat on pallets, surrounded by wooden boards around and on top, with the upper pallet pressing on the wooden posts below during stacking. The horizontal placement mode is easy to damage in the transportation process, the number of ceramic tiles placed in each box is small, the stacking height is small due to the limitation of the bearing force of the wood columns, and the warehouse space utilization rate is low. The other way is to place the ceramic tiles on the tray in a vertical way, the ceramic tiles lean against the middle A-shaped wooden frame, the periphery and the top of the ceramic tiles are surrounded by wooden plates, and the upper tray is pressed on the lower wooden column during stacking. The mode can reduce the damage in the transportation process, but still has the problems of less stacking height caused by the limitation of the bearing capacity of the wood columns, more wood consumption and higher packaging cost. That is, in the prior art, when the ceramic tile is subjected to support, the packaging cost is high, and the transportation is not facilitated.

Therefore, the prior art has defects and needs to be improved and developed.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model lies in, to prior art's above-mentioned defect, provide a pottery brick and beat and hold in the palm structure, when aiming at solving among the prior art to beating the support to pottery brick, the packing cost is high, and is unfavorable for the problem of transportation.

The utility model provides a technical scheme that technical problem adopted as follows:

a ceramic tile setback structure, comprising: the ceramic tile fixing device comprises a tray, a first bracket fixing position, a second bracket fixing position and a ceramic tile fixing position, wherein the first bracket fixing position is arranged on the first side of the tray; the ceramic tile fixing position is used for placing a ceramic tile to be held, a first support is placed on the first support fixing position, and a second support is placed on the second support fixing position; a first binding belt for fixing the ceramic tiles is arranged between the second side and the fourth side of the tray, and a second binding belt for fixing the ceramic tiles is arranged between the first support and the second support.

Further, the first bracket includes: the first supporting rib and the second supporting rib are vertically arranged; the second supporting ribs are in contact with the first support fixing positions, and the first supporting ribs are used for being in contact with the ceramic tiles to be held.

Furthermore, the second support is L-shaped, and the first support and the second support are arranged in a staggered mode.

Furthermore, the first support is in an inverted T shape, and the length of the second support rib is equal to that of the first side of the tray; the fixed connection position of the first support rib and the second support rib is the midpoint of the second support rib; and both sides of the middle point of the second support rib and the middle point of the first support rib are fixedly connected with fourth support ribs, and the fourth support ribs are symmetrically arranged by taking the first support ribs as symmetry axes.

Further, the ceramic tiles placed on the ceramic tile fixing positions are vertical ceramic tile blocks stacked by a plurality of ceramic tiles, and each vertical ceramic tile block comprises: a first and a second stacking surface adjacent to the tray and located at opposite positions, a first and a second tile surface adjacent to the tray and located at opposite positions, and a third stacking surface opposite to the tray.

Further, the first stacking surface, the second stacking surface, the first tile surface and the second tile surface are all perpendicular to the tray; the third stacking surface is parallel to the tray.

Further, the first support is in contact with a first stacking surface of the vertical porcelain brick block, and the second support is in contact with a second stacking surface of the vertical porcelain brick block.

Furthermore, the end surface of the first supporting rib facing the first stacking surface is provided with a clamping groove, and the clamping groove is clamped with the edge of the middle ceramic tile on the first stacking surface.

Further, the plane of the first binding band is perpendicular to the tray, and the plane of the second binding band is parallel to the tray.

The utility model provides a ceramic brick is beaten and is held in palm structure, include: the ceramic tile fixing device comprises a tray, a first bracket fixing position, a second bracket fixing position and a ceramic tile fixing position, wherein the first bracket fixing position is arranged on the first side of the tray; the ceramic tile fixing position is used for placing a ceramic tile to be held, a first support is placed on the first support fixing position, and a second support is placed on the second support fixing position; a first binding belt for fixing the ceramic tiles is arranged between the second side and the fourth side of the tray, and a second binding belt for fixing the ceramic tiles is arranged between the first support and the second support. The utility model discloses a side at the tray sets up fixed position for fixed first support, second support, first bandage and second bandage, make the packing of pottery brick more firm, and practice thrift the packing cost, the transportation of being convenient for.

Drawings

Fig. 1 is a schematic structural view of a preferred embodiment of the ceramic tile support structure of the present invention.

Fig. 2 is a schematic structural view of another perspective of the preferred embodiment of the ceramic tile support structure of the present invention.

Fig. 3 is a schematic structural diagram of a third side front view of a tray according to a preferred embodiment of the method for making ceramic tiles of the present invention.

Fig. 4 is a schematic structural diagram of a first side front view of a tray according to a preferred embodiment of the method for making ceramic tiles of the present invention.

Fig. 5 is a schematic structural view of the "L" shaped first and second supports in the preferred embodiment of the method for making ceramic tiles of the present invention.

FIG. 6 is a schematic view of a second structure of the "L" shaped first and second supports of another preferred embodiment of the method for making ceramic tiles of the present invention.

Fig. 7 is a schematic structural view of the inverted T-shaped first support and the second support in the preferred embodiment of the method for ceramic tile buttressing of the present invention.

Description of reference numerals:

100. a tray; 210. a first bracket; 400. a first stacking surface; 440. a first tile face; 420. A third stacking face; 300. a first strap; 310. a second strap; 110. a first side; 200. ceramic tiles; 211. a first support rib; 212. a second support rib; 213. a third support rib; 214. a fourth support rib; 221. a fifth support rib; 222. a sixth support rib; 130. a second side; 410. a second stacking face; 120. a third side; 220. a second bracket; 230. an intermediate ceramic.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer and clearer, the present invention will be described in further detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1 and fig. 2, an embodiment of the present invention provides a ceramic tile support structure, including: the tray 100 comprises a first bracket fixing position arranged on a first side 110 of the tray 100, a second bracket fixing position arranged on a third side 120 of the tray 100 and a ceramic tile fixing position arranged on the upper end surface of the tray 100; the ceramic tile fixing position is used for placing a ceramic tile to be held, a first bracket 210 is placed on the first bracket fixing position, and a second bracket 220 is placed on the second bracket fixing position; a first tie 300 for fixing the ceramic tiles is arranged between the second side 130 and the fourth side of the tray 100, and a second tie 310 for fixing the ceramic tiles is arranged between the first bracket 210 and the second bracket 220.

The ceramic tiles are placed on a tray 100 to form a stack of upright tiles 200. The vertical type tile brick 200 is formed by stacking a plurality of ceramic tiles in a uniform direction. Specifically, the tray 100 is rectangular, and the uniform direction is a length direction or a width direction of the tray 100. Preferably, the length of the tray 100 is set to be equal to the length of the ceramic tiles, and the width of the tray 100 is the stacking height of the plurality of ceramic tiles.

Further, the ceramic tile placed on the ceramic tile fixing position is a brick upright 200 stacked by a plurality of ceramic tiles, and the brick upright 200 includes: a first stacking surface 400 and a second stacking surface 410 adjacent to and in an opposite position to the tray 100, a first tile surface 440 and a second tile surface adjacent to and in an opposite position to the tray 100, and a third stacking surface 420 opposite to the tray 100. It will be appreciated that a plurality of tiles are stacked to form 4 stacked faces, 2 tile faces, with one face in contact with the tray 100.

Further, the first stacking surface 400, the second stacking surface 410, the first tile surface 440, and the second tile surface are perpendicular to the tray 100; the third stacking surface 420 is parallel to the tray 100.

Specifically, when placing ceramic tiles, all the ceramic tiles are tightly and vertically stacked on the tray 100 to form the vertical ceramic block 200, the ceramic tiles are not easy to slide, the unstable structure of the stacked vertical ceramic block 200 cannot be caused, the structural stability is realized to the maximum utilization degree of space, and the ceramic tiles are protected from being abraded in the transportation process.

In the preferred embodiment of the present invention, in order to fix the stacking surface of the ceramic blocks, the present invention further provides a first bracket fixing position on the first side 110 of the tray 100 for fixing the first stacking surface 400; the third side 120 of the tray 100 is provided with a second bracket fixing position for fixing the second stacking surface 410; the first holder fixing portion and the first stacking surface 400 are located at the first side 110 of the tray 100, the second holder fixing portion and the second stacking surface 410 are located at the third side 120 of the tray 100, and the first side 110 and the third side 120 of the tray 100 are opposite to each other. The upper end surface of the tray 100 is provided with a ceramic tile fixing position for fixing a stacking surface contacting with the tray 100.

Further, the first prop 210 is in contact with the first stacking surface 400 of the vertical tile 200, and the second prop 220 is in contact with the second stacking surface 410 of the vertical tile 200.

Referring to fig. 3 and 4, the first rack 210 is placed on the first rack fixing position, and the plane of the first rack 210 is parallel to and in contact with the first stacking surface 400; the second bracket 220 is placed on the second bracket fixing position, and the plane of the second bracket 220 is parallel to and in contact with the second stacking surface 410. A first tie 300 for fixing the ceramic tiles is disposed between the second side 130 and the fourth side of the tray 100, the first tie 300 fixes the first tile surface 440 to the second side 130 of the tray 100, and fixes the second tile surface to the fourth side of the tray 100, and the second side 130 of the tray 100 is opposite to the fourth side. A second binding belt 310 for fixing the ceramic tiles is arranged between the first bracket 210 and the second bracket 220, the second binding belt 310 fixes the first bracket 210 on the first side 110 of the tray 100, and simultaneously fixes the second bracket 220 on the third side 120 of the tray 100, and the first side 110 and the third side 120 of the tray 100 are opposite. When packing, the vertical type tile block 200 is horizontally bound to the first bracket 210 and the second bracket 220 by winding the second binding band 310 along the first tile surface 440, the first stacking surface 400, the second tile surface, and the second stacking surface 410; the vertical tiles 200 are bundled together in a vertical direction by winding the first binding band 300 along the first tile face 440, the third stacking face 420, the second tile face, and the stacking face contacting the tray 100.

First bracket 210 can be held in place against first stacking surface 400 and second bracket 220 can be held in place against second stacking surface 410 using second strap 310. The contact space between the ceramic tiles is compressed, so that the ceramic tiles are tightly contacted, and the firmness of the ceramic tiles in support is enhanced.

Further, the plane of first strap 300 is perpendicular to tray 100, and the plane of second strap 310 is parallel to tray 100. First strap 300 and second strap 310 are perpendicular to each other for added structural integrity. Preferably, each of first strap 300 and second strap 310 is provided in an amount of 3.

Further, the first bracket 210 includes: first and second support ribs 211 and 212 vertically disposed; the second support rib 212 is in contact with the first bracket fixing position, and the first support rib 211 is used for being in contact with the ceramic tile to be held.

The second bracket 220 includes: a fifth support rib 221 and a sixth support rib 222 vertically arranged; the sixth support rib 222 is in contact with the second bracket fixing position, and the fifth support rib 221 is used for being in contact with the ceramic tile to be held. Since the first bracket 210 and the second bracket 220 have the same structure, the first support rib 211 and the fifth support rib 221 have the same structure, and the second support rib 212 and the sixth support rib 222 have the same structure. Only the first support rib 211 and the second support rib 212 of the first bracket 210 are described in detail, and the fifth support rib 221 and the sixth support rib 222 of the second bracket 220 are not described in detail.

The length of the first support rib 211 is the width of the ceramic tile, and the vertical distance between the first bracket 210 and the second bracket 220 is the length of the ceramic tile.

Specifically, the first support rib 211 and the second support rib 212 are vertically connected, the best connection mode is welding, and the first support rib 211 and the second support rib 212 can be integrated through welding. It can be known, the utility model provides a connected mode is not limited to the welding, also can use screw, screw combination to use for connect first bracing piece 211 and second bracing piece 212, it is fixed also to set up the adapter sleeve in first bracing piece 211 and second bracing piece 212 junction, the utility model provides a connected mode is not limited to above example, and all can be connected first bracing piece 211 and second bracing piece 212 as a whole, perhaps make into a holistic mode through certain production technology, and no matter whether this whole can be dismantled, this kind of mode is the utility model discloses a variant mode.

Further, the end surface of the first support rib 212 facing the first stacking surface is provided with a retaining groove, and the retaining groove is retained with the edge of the middle ceramic tile on the first stacking surface.

Specifically, the end surface of the first support rib 211 facing the first stacking surface is provided with a clamping groove, and similarly, the end surface of the second support rib 212 facing away from the first bracket fixing position is also provided with a clamping groove, and the clamping groove is formed at an angle of 90 °; the clamping grooves are arranged to fasten the vertical porcelain brick blocks 200 together, so that the ceramic tiles are prevented from being inclined in the placing and transporting process, and transportation is facilitated.

Preferably, the first support rib 211 and the second support rib 212 are made of steel, but not limited to steel, and materials with better strength, such as plastic, toughened glass, iron, etc., can be substituted for the steel of the present invention.

The utility model discloses to the structure of first support 210 and second support 220, there are three kinds of best structures.

As shown in fig. 5 and 6, the first structure is "L" shaped, the first support 210 is "L" shaped, and the length of the second support rib 212 is half of the length of the first side 110 of the tray 100; a third support rib 213 is fixedly connected between the first support rib 211 and the second support rib 212, and the third support rib 213 is disposed in an inclined manner.

The third support rib 213 may be provided in plurality.

Further, the second bracket 220 is L-shaped, and the first bracket 210 and the second bracket 220 are staggered.

When the first bracket 210 and the second bracket 220 are alternately arranged, the structure of fig. 5 is realized in this way.

Specifically, when the ceramic tiles are packed, the first support rib 211 on the first support and the holding groove on the fifth support rib 221 on the second support are used for respectively holding one ceramic tile, two ceramic tiles are tightly close to each other and are called as a middle ceramic tile 230, then the middle ceramic tile 230 is used as a base point, other ceramic tiles are respectively placed on two sides of the middle ceramic tile 230, after the placement is finished, the vertical ceramic tile 200 is formed, and finally the vertical ceramic tile 200 is tightly bound with the first support 210 and the second support 220 by using the first binding band 300 and the second binding band 310.

Further, the second bracket 220 is L-shaped, and the first bracket 210 and the second bracket 220 are arranged on the same side.

When the first bracket 210 and the second bracket 220 are disposed on the same side, the structure of fig. 6 is adopted.

Specifically, when packaging is performed, the same ceramic tile is clamped by the clamping grooves of the first support rib 211 on the first support and the fifth support rib 221 on the second support, the ceramic tiles are arranged oppositely, other ceramic tiles are arranged along the direction of the ceramic tile, the vertical ceramic tile block 200 is formed after the arrangement is completed, and finally the vertical ceramic tile block 200 is tightly bound with the first support 210 and the second support 220 by the first binding band 300 and the second binding band 310.

It will be appreciated that the same two configurations shown in figure 6 may be provided in a back-to-back arrangement.

As shown in fig. 7, the second structure is an inverted "T" shape, the first support 210 is an inverted "T" shape, and the length of the second support rib 212 is equal to the length of the first side 110 of the tray 100; the fixed connection position of the first support rib 211 and the second support rib 212 is the midpoint of the second support rib 212; fourth support ribs 214 are fixedly connected between both sides of the midpoint of the second support rib 212 and the first support rib 211, and the fourth support ribs 214 are symmetrically arranged with the first support rib 211 as a symmetry axis.

Specifically, when the ceramic tiles are packed, the first support rib 211 on the first support and the holding groove on the fifth support rib 221 on the second support are used for respectively holding one ceramic tile, two ceramic tiles are tightly close to each other and are called as a middle ceramic tile 230, then the middle ceramic tile 230 is used as a base point, other ceramic tiles are respectively placed on two sides of the middle ceramic tile 230, after the placement is finished, the vertical ceramic tile 200 is formed, and finally the vertical ceramic tile 200 is tightly bound with the first support 210 and the second support 220 by using the first binding band 300 and the second binding band 310.

Preferably, at least two fourth supporting ribs 214 are provided, and the fourth supporting ribs 214 are respectively provided at two sides of the second supporting rib 212, so that the knock-up structure is more stable.

In the implementation, the intermediate ceramic tiles 230 in the above three schemes can also be provided as isolation plates.

Specifically, a ceramic tile fixing position is arranged on the upper end surface of the tray 100, a first support 210 and a second support 220 are respectively arranged on two sides of the ceramic tile fixing position, and a separation plate is arranged between the first support 210 and the second support 220 and is perpendicular to the tray 100.

Preferably, the isolation plate is a flat plate with a flat surface, and the material of the isolation plate can be a wood plate, a steel plate, a plastic plate and the like.

Specifically, the utility model discloses it is to beat the support to the big size pottery brick.

The utility model discloses a structure of asking has reduced the packing cost, has utilized the space occupancy well, and the utility model discloses a structure repeatedly usable, for detachable construction, has saved the packing cost, has improved the pile number of piles simultaneously, has improved warehouse space utilization and has rateed highly; moreover, the support structure of the utility model is stable, the transportation damage rate is reduced, and the transportation is convenient; the problems of high packaging cost, few stacking layers, low warehouse space utilization rate and high transportation damage rate in a flat-laying mode in the prior art are solved.

To sum up, the utility model discloses a ceramic brick is beaten and is held in palm structure and method, include: the ceramic tile fixing device comprises a tray, a first bracket fixing position, a second bracket fixing position and a ceramic tile fixing position, wherein the first bracket fixing position is arranged on the first side of the tray; the ceramic tile fixing position is used for placing a ceramic tile to be held, a first support is placed on the first support fixing position, and a second support is placed on the second support fixing position; a first binding belt for fixing the ceramic tiles is arranged between the second side and the fourth side of the tray, and a second binding belt for fixing the ceramic tiles is arranged between the first support and the second support. The utility model discloses a side at the tray sets up first support, second support, first help area and second bandage for the packing of pottery brick is more firm, and practices thrift the packing cost, is convenient for transport.

It is to be understood that the invention is not limited to the above-described embodiments, and that modifications and variations may be made by those skilled in the art in light of the above teachings, and all such modifications and variations are intended to be included within the scope of the invention as defined in the appended claims.

Claims (10)

1. A ceramic tile backing structure, comprising: the ceramic tile fixing device comprises a tray, a first bracket fixing position, a second bracket fixing position and a ceramic tile fixing position, wherein the first bracket fixing position is arranged on the first side of the tray; the ceramic tile fixing position is used for placing a ceramic tile to be held, a first support is placed on the first support fixing position, and a second support is placed on the second support fixing position; a first binding belt for fixing the ceramic tiles is arranged between the second side and the fourth side of the tray, and a second binding belt for fixing the ceramic tiles is arranged between the first support and the second support.

2. The ceramic tile bracketing structure of claim 1, wherein said first support includes: the first supporting rib and the second supporting rib are vertically arranged; the second supporting ribs are in contact with the first support fixing positions, and the first supporting ribs are used for being in contact with the ceramic tiles to be held.

3. The ceramic tile tray making structure according to claim 2, wherein the first bracket is "L" shaped, and the length of the second support rib is half of the length of the first side of the tray; and a third supporting rib is fixedly connected between the first supporting rib and the second supporting rib, and the third supporting rib is obliquely arranged.

4. The ceramic tile butting structure according to claim 3, wherein the second support is L-shaped, and the first support and the second support are staggered.

5. The ceramic tile tray-making structure according to claim 2, wherein the first support is in an inverted "T" shape, and the length of the second support rib is equal to the length of the first side of the tray; the fixed connection position of the first support rib and the second support rib is the midpoint of the second support rib; and both sides of the middle point of the second support rib and the middle point of the first support rib are fixedly connected with fourth support ribs, and the fourth support ribs are symmetrically arranged by taking the first support ribs as symmetry axes.

6. The ceramic tile tray-making structure according to claim 3 or 5, wherein the ceramic tile placed on the ceramic tile fixing station is a vertical ceramic tile block stacked by a plurality of ceramic tiles, and the vertical ceramic tile block comprises: a first and a second stacking surface adjacent to the tray and located at opposite positions, a first and a second tile surface adjacent to the tray and located at opposite positions, and a third stacking surface opposite to the tray.

7. The ceramic tile buttressing structure of claim 6, wherein the first stacking face, the second stacking face, the first tile face and the second tile face are all perpendicular to the tray; the third stacking surface is parallel to the tray.

8. The ceramic tile tray structure as claimed in claim 7, wherein the first bracket contacts with the first stacking surface of the vertical type of the tiles, and the second bracket contacts with the second stacking surface of the vertical type of the tiles.

9. The ceramic tile backing structure as claimed in claim 8, wherein the end surface of the first supporting rib facing the first stacking surface is provided with a retaining groove for retaining the edge of the middle ceramic tile on the first stacking surface.

10. A ceramic tile buttressing structure as claimed in claim 9, wherein the first strap is in a plane perpendicular to the tray and the second strap is in a plane parallel to the tray.

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