CN220395067U - Reinforced anti-drop ceramic tile - Google Patents

Abstract

The utility model discloses a reinforced anti-drop ceramic tile, which comprises a fixing surface, wherein a honeycomb groove is arranged on the fixing surface, the honeycomb groove comprises a spherical surface structure and a groove bottom structure, the dovetail wall surface of the groove bottom structure opposite to the spherical surface structure is an arc surface or is obliquely arranged, an opening of the groove bottom structure is smaller than the bottom surface of the groove bottom structure, a separation rib is also arranged on the fixing surface and used for separating the honeycomb groove, and the separation rib is provided with a force unloading slope; the reinforced anti-drop ceramic tile is provided with the irregular hooking surface, the multi-angle direction is combined with the wall surface, the firmness of adhesion installation and use can be improved, the spherical structure is based on the structural design of the spherical structure, and the die design based on the structure is further disclosed by the utility model, so that the production can be conveniently carried out, the service performance of the ceramic tile cannot be influenced, and on the basis, the ceramic tile design can improve the integral strength, is not easy to crack during use and installation and segmentation, and the service life of the ceramic tile is more excellent.

Description

Reinforced anti-drop ceramic tile

Technical Field

The utility model relates to the technical field of building ceramic bricks, in particular to a reinforced anti-drop ceramic tile.

Background

With the wide application of ceramic tiles on building walls, particularly the use of ceramic tiles with low water absorption rate on the walls, the ceramic tiles face the risk of laying empty drums on the walls; improvements to reduce these risks, typically direct changes to the way they are applied, such as improved adhesives, with high bond strength tile adhesives; such as dry-hanging ceramic tiles with an adhesive. In order to strengthen the application effect of the ceramic tile and expand the application range of the ceramic tile, the structure of the ceramic tile can be correspondingly improved. If a pore structure with a water retention effect is formed on the back grain part of the ceramic tile, the bonding strength of the adhesive and the ceramic tile is improved, but the pore structure realizes the water retention effect by the water absorption rate, which is equivalent to the lateral improvement of the bonding effect of the adhesive, the structural change of the ceramic tile is not large, and the bonding effect is not remarkably improved.

The back grain structure of the ceramic tile is changed to improve the mechanical meshing effect of the adhesive and the ceramic tile, for example, the back grain of the ceramic tile is designed into grooves with different inclined angles, and the design can better improve the bonding strength of the ceramic tile during paving, but the design of the groove structure also leads to the improvement of the difficulty of manufacturing the ceramic tile, particularly the design of the inclined groove, so that the strength is ensured, the manufacturing and demolding are convenient, and the cost is increased; for example, in the prior art CN200420012677.9, cement binding force tiles are reinforced, tiles with such structural shapes are produced, and due to the structural defects, the mould of the tiles is required to be drawn out from the side surfaces of the loose core mould relative to the movable mould and the static mould, so that an anti-drop structure is formed, and the overall size of the mould can be very large.

Therefore, the back grain structure of the existing ceramic tile needs to be further improved to facilitate the design and production of the mold, so that the production of the ceramic tile can be effectively improved, and the strength and the anti-drop effect of the product are not reduced.

Disclosure of Invention

In view of the prior art, the utility model aims to provide the anti-drop ceramic tile with a specific technical structure, which can be more firmly adhered to the wall surface and the ground, and the specific technical structure has the characteristic of convenient production and processing.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides a consolidate anticreep ceramic tile, includes the fixed surface, be provided with the honeycomb groove on the fixed surface, the honeycomb groove includes sphere structure and tank bottom structure, the dovetail wall that tank bottom structure and sphere structure are relative is cambered surface or slope setting, the opening of tank bottom structure is less than the bottom surface setting of tank bottom structure, the fixed surface still is provided with the separation arris, the separation arris is used for separating the honeycomb groove, just the powerful slope setting of separating the arris strip.

As a further arrangement of the above, the openings of the honeycomb cells are arranged opposite or opposite to the adjacent honeycomb cells.

As a further arrangement of the scheme, the side wall of the groove bottom structure opposite to the dovetail wall surface is provided with an inner wall structure, and the inner wall structure is arranged in an arc surface or a vertical bottom surface opposite to the bottom surface.

As a further arrangement of the scheme, the spherical structure of the honeycomb groove is arranged in the same way as the circle center of the dovetail wall surface which is arranged in a radian shape or in an inclined manner.

As a further arrangement of the scheme, the manufacturing mould adopted by the ceramic tile comprises a static mould, a movable mould which is movably arranged relative to the static mould and a core mould which is provided with a rotating structure which is arranged relative to the movable mould, and the core mould is provided with a movable mould matched with the honeycomb groove.

The beneficial effects are that: compared with the prior art, the reinforced anti-drop ceramic tile has an irregular hooking surface, is combined with a wall surface in a multi-angle direction, can improve the firmness of adhesion installation and use, has a spherical structure, is based on the structural design of the spherical structure and the die design based on the structure, is further disclosed by the utility model, can be conveniently produced, and does not influence the service performance of the spherical structure, on the basis, the honeycomb groove design achieved by the ceramic tile can improve the integral strength, and the structural design of the back surface can ensure that the ceramic tile is not easy to crack during use and segmentation, so that the service life of the ceramic tile is more excellent.

Drawings

Fig. 1 is a schematic view of the tile structure of the present utility model.

Fig. 2 is an enlarged schematic view of the structure of the tile of fig. 1 at a.

Fig. 3 is a schematic cross-sectional view of a honeycomb of the present utility model.

Fig. 4 is a schematic view of a production mold designed based on the special structure of the ceramic tile of the present utility model.

Fig. 5 is a drawing of the demolding state shown in fig. 3 according to the present utility model.

Reference numerals: 1. a fixing surface; 2. a honeycomb groove; 21. a spherical structure; 22. a groove bottom structure; 23. an opening; 24. a bottom surface; 25. dovetail wall surfaces; 3. separating ribs; 31. a force unloading slope; 6. static mold; 7. a movable mold; 8. and (5) a core mold.

Detailed Description

In order that the above-recited objects, features and advantages of the present utility model will be more clearly understood, a more particular description of the utility model will be rendered by reference to the appended drawings and appended detailed description. In addition, the embodiments of the present application and the features in the embodiments may be combined with each other without conflicting with each other.

The reinforced anti-drop ceramic tile shown in fig. 1-5 comprises a fixing surface 1, wherein a honeycomb groove 2 is arranged on the fixing surface 1, the honeycomb groove 2 comprises a spherical surface structure 21 and a groove bottom structure 22, a dovetail wall surface 25 of the groove bottom structure 22 opposite to the spherical surface structure 21 is in an arc surface or inclined arrangement, an opening 23 of the groove bottom structure 22 is smaller than a bottom surface 24 of the groove bottom structure 22, the fixing surface 1 is further provided with separation ribs 3, the separation ribs 3 are used for separating the honeycomb groove 2, and the separation ribs 3 are provided with a force unloading slope 31.

As a further arrangement of the above, the openings 23 of the cells 2 are arranged opposite or opposite to the adjacent cells 2.

As a further arrangement of the above solution, the side wall of the groove bottom structure 22 opposite to the dovetail wall 25 is provided with an inner wall structure, and the inner wall structure is arranged in an arc surface or perpendicular to the bottom surface 24 opposite to the bottom surface 24.

As a further arrangement of the above-mentioned solution, the spherical structure 21 of the honeycomb groove 2 is arranged at the same center as the center of the dovetail wall 25 arranged in a radian shape or in an inclined manner.

As a further arrangement of the scheme, the manufacturing mould adopted by the ceramic tile comprises a static mould 6, a movable mould 7 movably arranged relative to the static mould 6 and a core mould 8 provided with a rotating structure arranged relative to the movable mould 7, wherein the core mould 8 is provided with a movable module 84 matched with the honeycomb groove 2.

The mandrel 8 shown in fig. 3-5 includes a mandrel plate 81 horizontally movable relative to the moving die 7, a moving rod 82 fixedly connected to the mandrel plate 81, the moving rod 82 is fixedly arranged relative to the mandrel plate 81 in the circumferential direction and the axial direction by arranging a welded or riveted or clamped fixing structure 86, the mandrel 8 further includes a moving module 84, the moving module 84 is matched with the shape of the groove bottom structure 22, the moving module 84 is hinged relative to the moving die 7, the hinge shaft is fixedly connected with a waist hole rod 83, a waist hole 85 arranged on the waist hole rod 83 is used for moving a sliding block 87 arranged on the moving rod 82, the moving die 7 is further provided with a moving groove 88 for moving the moving rod 82, the moving module 84, the waist hole rod 83 and the like, the working principle of the structure is as shown in fig. 3 and 5, fig. 3 is a molding state, the material at this time is molded and solidified into a tile ready for demolding, and the demolding step: the core mold plate 81 is driven to translate in a set direction by the external cylinder, at this time, the moving rod 82 fixedly connected with the core mold plate 81 moves along with the moving rod, so that when the moving rod 82 moves upwards as shown in fig. 5, the waist hole rod 83 slides relatively in the waist hole 85 based on the sliding block 87 of the moving rod 82, the waist hole rod 83 gradually transits to the state of fig. 5 from fig. 3, in the process, the waist hole rod 83 is pushed by the inclined direction of the moving rod 82, and swings, and the moving module 84 swings along with the design of the hinge shaft fixedly connected with the moving module 84, so that the moving module 84 is separated from the groove bottom structure 22 of the ceramic tile, the demolding is completed, and then the moving mold 7 and the static mold 6 can be separated relatively to complete the demolding.

As shown in fig. 1-3, the back of the tile structure with the anti-falling function in this embodiment, i.e. the surface coated with the fixing agent toward the wall surface is provided with a plurality of honeycomb grooves 2, and unlike the prior art, the honeycomb grooves 2 of this embodiment have an irregular design of the opening 23 toward the bottom of the honeycomb groove 2, i.e. the honeycomb groove 2 has a dovetail wall 25 with a reverse hook with respect to the fixing surface 1, and the opposite surface of the dovetail wall 25 is provided with a structure with radian, during installation, the honeycomb groove 2 formed by the dovetail wall 25 with the fixing surface 1 is filled with the fixing agent, after the fixing agent is hardened, the formed hardening layer is relatively hooked with the honeycomb groove 2, and is not designed based on the irregular opening 23, the multi-angle and multi-directional stress of the honeycomb groove 2 has stronger fixing force and anti-falling effect than the prior art, and a plurality of separation ribs 3 between the adjacent honeycomb grooves 2 are further arranged on the fixing surface 1 of the tile, as shown in fig. 3 has a lifting force-unloading slope surface 31, the connection surface with a non-uniform lifting force can be avoided, and the problem of the crack can be avoided by the air bubble in the process.

Furthermore, based on the structural design of the honeycomb groove 2 in the embodiment, the mold for producing ceramic tiles of the present utility model can be further simplified, the structural design reduces the requirements for producing the mold, improves the production efficiency and reduces the production difficulty, as shown in fig. 4, based on the characteristic structure of the honeycomb groove 2, the mold can be arranged on the core mold 8 arranged on the movable mold 7, when the movable mold 7 is closed and then demolded, the core mold 84 is turned first, and then the movable mold 7 is moved again; each core module 84 can independently control the turning angle (can be controlled in batch, and a plurality of core templates 81 are stacked and arranged to be relatively movable), so that the honeycomb groove 2 porcelain make-up design with the inverted hook and chamfer inclined surface structure of the embodiment can be obtained, the die is relatively small and simple in shape and structure, and secondly, the die cavity design of each honeycomb groove 2 on the movable die 7 based on the embodiment is the same and independent, so that more porcelain make-up products with the same pattern can be further adapted through size adjustment of the movable die.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present utility model without departing from the spirit or scope of the utility model. Thus, it is intended that the present utility model also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (4)

1. The utility model provides a consolidate anticreep ceramic tile which characterized in that: including stationary plane (1), be provided with honeycomb groove (2) on stationary plane (1), honeycomb groove (2) are including sphere structure (21) and tank bottom structure (22), dovetail wall (25) that tank bottom structure (22) are relative with sphere structure (21) are cambered surface or slope setting, opening (23) of tank bottom structure (22) are less than bottom surface (24) setting of tank bottom structure (22), stationary plane (1) still is provided with separates rib (3), separate rib (3) are used for separating honeycomb groove (2), just separate rib (3) have to unload power slope (31) setting.

2. A reinforced anti-slip tile as claimed in claim 1, wherein: the openings (23) of the honeycomb grooves (2) are arranged opposite or opposite to the adjacent honeycomb grooves (2).

3. A reinforced anti-slip tile as claimed in claim 1, wherein: the groove bottom structure (22) is provided with an inner wall structure relative to the side wall of the dovetail wall surface (25), and the inner wall structure is arranged in an arc surface or perpendicular to the bottom surface (24) relative to the bottom surface (24).

4. A reinforced anti-slip tile according to claim 3, wherein: the spherical structure (21) of the honeycomb groove (2) is arranged in the same way as the circle center of the dovetail wall surface (25) which is arranged in a radian shape or in an inclined manner.