CN219840262U - High-strength light energy-saving brick - Google Patents

Abstract

The utility model discloses a high-strength light energy-saving brick, which comprises a ceramic brick layer, an adhesive layer, a heat preservation layer and a cement slurry layer which are sequentially distributed and fixed from top to bottom; the ceramic tile comprises a ceramic tile layer, an adhesive layer, a heat preservation layer and cement paste layers, wherein a plurality of first straight channels and a plurality of second straight channels are formed in the lower surface of the upper layer between every two adjacent layers in the ceramic tile layer, a plurality of first convex ribs and a plurality of second convex ribs are formed in the upper surface of the lower layer between every two adjacent layers, the first convex ribs are located in the corresponding first straight channels, and the second convex ribs are located in the second straight channels. The high-strength light energy-saving brick has the advantages that the upper layer and the lower layer between two adjacent layers are firmly and reliably connected and are not easy to fall off, the first convex ribs and the second convex ribs play the role of reinforcing ribs, and the structural strength of each layer is higher.

Description

High-strength light energy-saving brick

Technical Field

The utility model relates to the technical field of building material tiles, in particular to a high-strength light energy-saving tile.

Background

As one of popular and common decoration building materials, the ceramic tile has excellent texture, color, texture, hand feeling, visual effect, characteristics of difficult color change, difficult contamination and the like, and has a plurality of functions for a building. The traditional ceramic tile mainly comprises a cement paste layer and a ceramic tile layer on the surface of the cement paste layer, and the ceramic tile has heavy weight and poor heat preservation and heat insulation effects, so that the light energy-saving tile is gradually developed.

The light energy-saving brick is disclosed in the patent document of China patent application No. 201621067277.7, and generally comprises a ceramic brick layer, an adhesive layer, a heat-insulating layer and a cement paste layer which are sequentially distributed from top to bottom. Under the condition of the same thickness, compared with the traditional magnet, the light energy-saving brick has the advantages that the overall weight is reduced due to the existence of the inner heat-insulating layer, the light energy-saving brick has the characteristics of light weight, the heat-insulating layer also has the functions of heat preservation and heat insulation due to the low heat conduction, the loss of energy can be reduced, and the energy-saving effect is achieved. However, also because of the presence of the insulating layer, the strength of the lightweight energy-saving tile is generally lower than that of a conventional tile; and when the light energy-saving brick is processed, the light energy-saving brick is identical to the traditional ceramic brick, tiling and whole tiling are adopted, the gripping force between each layer of the ceramic brick after tiling and whole tiling is small, the ceramic brick is easy to fall off, the firmness is poor, and the problem of low strength of the light energy-saving brick is more outstanding.

Disclosure of Invention

The utility model aims to provide a high-strength light energy-saving brick.

The technical scheme for realizing the aim of the utility model is as follows: a high-strength light energy-saving brick comprises a ceramic brick layer, an adhesive layer, a heat-insulating layer and a cement paste layer which are sequentially distributed and fixed from top to bottom;

the lower surface of the upper layer between every two adjacent layers in the ceramic brick layer, the adhesive layer, the heat preservation layer and the cement slurry layer is provided with a plurality of first straight channels and a plurality of second straight channels, the first straight channels are parallel and distributed at intervals along the length direction of the upper layer, the second straight channels are parallel and distributed at intervals along the width direction of the upper layer, and the first straight channels and the second straight channels are crossed to form a grid shape;

the upper surfaces of the lower layers between every two adjacent layers in the ceramic brick layer, the adhesive layer, the heat preservation layer and the cement slurry layer are provided with a plurality of first convex ribs and a plurality of second convex ribs, the first convex ribs are parallel and distributed at intervals along the length direction of the lower layer, the second convex ribs are parallel and distributed at intervals along the width direction of the lower layer, and the first convex ribs and the second convex ribs are crossed to form a grid shape;

the first convex ribs are in one-to-one correspondence with the first straight channels, are positioned in the corresponding first straight channels and are clamped and fixed with the first straight channels; the second convex ribs are in one-to-one correspondence with the second straight channels, and are clamped in the second straight channels and are clamped with the second straight channels.

Further, the lower layer between every two adjacent layers and the first convex rib and the second convex rib on the lower layer are of an integrated structure.

According to the high-strength light energy-saving brick, the first straight channels and the second straight channels are arranged on the lower surfaces of the upper layers of the two adjacent layers in the ceramic brick layer, the adhesive layer, the heat preservation layer and the cement paste layer, and the first ribs and the second ribs are arranged on the upper surfaces of the lower layers of the two adjacent layers, so that when the ceramic brick layer, the adhesive layer, the heat preservation layer and the cement paste layer are tiled and pressed into the high-strength light energy-saving brick, the first ribs of the lower layers of the two adjacent layers can be correspondingly filled into the first straight channels of the upper layers and matched with the first straight channels, and the second ribs can be correspondingly filled into the second straight channels and matched with the second straight channels.

According to the high-strength light energy-saving brick, the first protruding ribs are positioned in the first straight channels and matched with the first straight channels, the second protruding ribs are positioned in the second straight channels and matched with the second straight channels, on one hand, the surface areas of the lower surfaces of the upper layers and the lower surfaces of the adjacent two layers are increased, the fixing surfaces of the upper layers and the lower layers of the adjacent two layers are increased, the first protruding ribs extend into the first straight channels to be embedded and fixed, the second protruding ribs extend into the second straight channels to be embedded and fixed, and the connection and fixation of the upper layers and the lower layers of the adjacent two layers are firmer and more reliable due to the increased fixing surfaces and the embedded and fixed structures, so that the brick is not easy to fall off; on the other hand, the first convex rib is positioned in the first straight channel, the second convex rib is positioned in the second straight channel, and after the first convex rib and the first straight channel, the second convex rib and the second straight channel are mutually limited, and the first convex rib and the second convex rib are distributed along the length and the width directions of each layer respectively, so that the length and the width directions of each layer are limited, the limit completely avoids the relative movement of the upper layer and the lower layer between two adjacent layers, and the outward diffusion of each layer is limited while the upper layer and the lower layer between two adjacent layers are fixed, so that the mounting structure of the upper layer and the lower layer between two layers is firmer; in addition, the first protruding muscle with the protruding muscle of second separates each layer into a plurality of fritters, and the deformation resistance of fritter is stronger, first protruding muscle with the effect of strengthening rib is played to the protruding muscle of second, can let each layer structural strength higher.

Drawings

FIG. 1 is a schematic view of the structure of the high strength lightweight energy-saving brick of the present utility model;

FIG. 2 is a schematic diagram of the distribution structure of the first and second straight channels of each layer of the high strength lightweight energy-saving brick of the present utility model;

fig. 3 is a schematic diagram of the distribution structure of the first bead and the second bead of each layer of the high-strength lightweight energy-saving brick of the present utility model.

Description of the embodiments

The following describes the specific embodiments of the high-strength light energy-saving brick according to the present utility model in detail with reference to the accompanying drawings:

as shown in fig. 1 to 3, the high-strength light energy-saving brick comprises a ceramic brick layer 1, an adhesive layer 2, a heat preservation layer 3 and a cement slurry layer 4 which are sequentially distributed and fixed from top to bottom;

the lower surfaces of the upper layers between every two adjacent layers in the ceramic brick layer 1, the adhesive layer 2, the heat preservation layer 3 and the cement slurry layer 4 are provided with a plurality of first straight channels 51 and a plurality of second straight channels 52, the first straight channels 51 are parallel and distributed at intervals along the length direction of the upper layer, the second straight channels 52 are parallel and distributed at intervals along the width direction of the upper layer, and the first straight channels 51 and the second straight channels 52 are crossed to form a grid shape;

the upper surfaces of the lower layers between every two adjacent layers in the ceramic brick layer 1, the adhesive layer 2, the heat preservation layer 3 and the cement slurry layer 4 are provided with a plurality of first convex ribs 61 and a plurality of second convex ribs 62, the first convex ribs 61 are parallel and distributed at intervals along the length direction of the lower layer, the second convex ribs 62 are parallel and distributed at intervals along the width direction of the lower layer, and the first convex ribs 61 and the second convex ribs 62 are crossed to form a grid shape;

the first ribs 61 are in one-to-one correspondence with the first straight channels 51, and the first ribs 61 are positioned in the corresponding first straight channels 51 and are clamped with the first straight channels 51; the second ribs 62 are in one-to-one correspondence with the second straight channels 52, and the second ribs 62 are clamped in the second straight channels 52 and are clamped with the second straight channels 52.

The high-strength light energy-saving brick is formed by tiling and pressing the ceramic brick layer 1, the adhesive layer 2, the heat preservation layer 3 and the cement paste layer 4. Wherein the ceramic tile layer 1 is used as the surface of the ceramic tile; the adhesive layer 2 is used for attaching the heat preservation layer 3 to the bottom surface of the ceramic tile layer 1; the heat preservation layer 3 plays roles of filling, heat preservation and heat insulation; the cement paste layer 4 is a bottom hard layer and provides hardness for the high-strength light energy-saving brick.

In the high-strength light energy-saving brick, in the ceramic brick layer 1, the adhesive layer 2, the heat preservation layer 3 and the cement slurry layer 4, the first straight channels 51 and the second straight channels 52 arranged on the lower surfaces of the upper layers of the adjacent two layers correspond to the first convex ribs 61 and the second convex ribs 62 arranged on the upper surfaces of the lower layers, wherein the first straight channels 51 and the first convex ribs 61 are distributed along the length direction of each layer, and the first convex ribs 61 are positioned in the first straight channels 51 and matched with the first straight channels 51; the second straight channels 52 and the second ribs 62 are distributed along the width direction of each layer, and the second ribs 62 are located in the second straight channels 52 and matched with the second straight channels 52.

According to the high-strength light energy-saving brick disclosed by the utility model, the first straight channels 51 and the second straight channels 52 are arranged on the lower surfaces of the upper layers of the adjacent two layers in the ceramic brick layer 1, the adhesive layer 2, the heat preservation layer 3 and the cement slurry layer 4, the first convex ribs 61 and the second convex ribs 62 are arranged on the upper surfaces of the lower layers of the adjacent two layers, so that when the ceramic brick layer 1, the adhesive layer 2, the heat preservation layer 3 and the cement slurry layer 4 are tiled and pressed into the high-strength light energy-saving brick, the first convex ribs 61 of the lower layers of the adjacent two layers can be correspondingly filled into the first straight channels 51 of the upper layers and matched with the first straight channels 51, and the second convex ribs 62 can be correspondingly filled into the second straight channels 52 and matched with the second straight channels 52.

The high-strength light energy-saving brick comprises a first convex rib 61, a second convex rib 62, a first straight channel 51, a second straight channel 52, a first connecting rod 61, a second connecting rod 62 and a second connecting rod 62, wherein the first convex rib 61 is positioned in the first straight channel 51 and is matched with the first straight channel 51, the second convex rib 62 is positioned in the second straight channel 52 and is matched with the second straight channel 52, on one hand, the surface area of the lower surface of the upper layer and the upper surface of the lower layer between two adjacent layers is increased, the fixing surface of the upper layer and the fixing surface of the lower layer between two adjacent layers are increased, the first convex rib 61 extends into the first straight channel 51 to be fixedly embedded, and the second convex rib 62 extends into the second straight channel 52 to be fixedly embedded, and the fixing surface is increased, so that the connection and the fixing of the upper layer and the lower layer between the two adjacent layers are firm and reliable and are not easy to fall off; on the other hand, the first ribs 61 are located in the first straight channels 51, the second ribs 62 are located in the second straight channels 52, and after the first ribs 61 and the first straight channels 51, the second ribs 62 and the second straight channels 52 are mutually limited, and as the first ribs 61 and the second ribs 62 are distributed along the length and width directions of each layer, the length and width directions of each layer are limited, the limit completely avoids the relative movement of the upper layer and the lower layer between two adjacent layers, so that the upper layer and the lower layer between two adjacent layers are fixed, and simultaneously, the outward diffusion of each layer is also limited, and the mounting structure of the upper layer and the lower layer between two layers is more firm; in addition, the first ribs 61 and the second ribs 62 divide each layer into a plurality of small blocks, the deformation resistance of the small blocks is stronger, and the first ribs 61 and the second ribs 62 play the role of reinforcing ribs, so that the structural strength of each layer is higher.

The high-strength light energy-saving brick of the present utility model preferably has an integral structure of the lower layer and the first ribs 61 and the second ribs 62 thereon between every two adjacent layers.

It should be understood by those skilled in the art that the present utility model may be embodied in many different forms without departing from the spirit or essential characteristics thereof.

Claims (2)

1. A high-strength light energy-saving brick comprises a ceramic brick layer, an adhesive layer, a heat-insulating layer and a cement paste layer which are sequentially distributed and fixed from top to bottom; the method is characterized in that:

the lower surface of the upper layer between every two adjacent layers in the ceramic brick layer, the adhesive layer, the heat preservation layer and the cement slurry layer is provided with a plurality of first straight channels and a plurality of second straight channels, the first straight channels are parallel and distributed at intervals along the length direction of the upper layer, the second straight channels are parallel and distributed at intervals along the width direction of the upper layer, and the first straight channels and the second straight channels are crossed to form a grid shape;

the upper surfaces of the lower layers between every two adjacent layers in the ceramic brick layer, the adhesive layer, the heat preservation layer and the cement slurry layer are provided with a plurality of first convex ribs and a plurality of second convex ribs, the first convex ribs are parallel and distributed at intervals along the length direction of the lower layer, the second convex ribs are parallel and distributed at intervals along the width direction of the lower layer, and the first convex ribs and the second convex ribs are crossed to form a grid shape;

the first convex ribs are in one-to-one correspondence with the first straight channels, are positioned in the corresponding first straight channels and are clamped and fixed with the first straight channels; the second convex ribs are in one-to-one correspondence with the second straight channels, and are clamped in the second straight channels and are clamped with the second straight channels.

2. The high strength lightweight energy efficient tile of claim 1, wherein: the lower layer between every two adjacent layers and the first convex rib and the second convex rib on the lower layer are of an integrated structure.