A high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure

By incorporating closed-cell structures and interwoven fibers into inorganic artificial stone, the cracking problem of inorganic artificial stone is solved, improving its thermal insulation performance and flexural strength, and extending its service life.

CN224426783UActive Publication Date: 2026-06-30YUNFU YUNSHI MEIGANG STONE CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
YUNFU YUNSHI MEIGANG STONE CO LTD
Filing Date
2025-06-30
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Inorganic artificial stone is prone to cracking and has poor heat insulation, which affects its service life.

Method used

By combining artificial stone components and crack-resistant insulation components, a closed-cell structure is formed. Interlaced fiber filaments are used to improve flexural strength, and crack-resistant insulation blanks are wrapped inside the grooves to ensure integrity.

Benefits of technology

It improves the heat insulation and flexural strength of inorganic artificial stone, inhibits the propagation of microcracks, and extends its service life.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure, comprising: an artificial stone component, which includes an inorganic artificial stone blank; and a crack-resistant and heat-insulating component, which includes a first inorganic blank positioned above the inorganic artificial stone blank, a first fiber filament penetrating the first inorganic blank, a second inorganic blank positioned above the first inorganic blank, a circular hole gap formed on the second inorganic blank, a first heat-insulating material layer positioned above the second inorganic blank, and a third inorganic blank positioned below the inorganic artificial stone blank. This utility model, through the cooperation of the artificial stone component and the crack-resistant and heat-insulating component, achieves a closed-cell structure formed by the heat-insulating material and the circular hole gap during use, improving the heat insulation effect of the inorganic artificial stone. Furthermore, the interlaced fiber filaments improve the flexural strength of the inorganic artificial stone, inhibit the propagation of microcracks, and extend the service life of the inorganic artificial stone.
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Description

Technical Field

[0001] This utility model relates to the field of inorganic artificial stone technology, specifically to a high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure. Background Technology

[0002] Inorganic artificial stone is a type of stone made primarily from inorganic materials such as cement, quartz sand, and mineral powder. These materials are mixed to form a raw material, which is then fired. In the current technology, inorganic artificial stone is prone to surface cracks during use, affecting its service life. Furthermore, inorganic artificial stone has poor heat insulation properties. Utility Model Content

[0003] Therefore, the purpose of this utility model is to provide a high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure. Through the cooperation of the artificial stone components and the crack-resistant heat-insulating components, the closed-cell structure formed by the gap between the heat-insulating blank and the round hole is achieved during use, which improves the heat insulation effect of the inorganic artificial stone. In addition, the interlaced fiber filaments improve the flexural strength of the inorganic artificial stone, inhibit the propagation of microcracks, and improve the service life of the inorganic artificial stone.

[0004] To solve the above-mentioned technical problems, according to one aspect of this utility model, the present utility model provides the following technical solution: a high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure, comprising:

[0005] An artificial stone assembly, the artificial stone assembly comprising an inorganic artificial stone blank;

[0006] A crack-resistant and heat-insulating component, comprising a first inorganic block disposed above the inorganic artificial stone block, a first fiber filament penetrating the first inorganic block, a second inorganic block disposed above the first inorganic block, a circular hole gap formed on the second inorganic block, a first heat-insulating material layer disposed above the second inorganic block, a third inorganic block disposed below the inorganic artificial stone block, a second fiber filament penetrating the third inorganic block, a fourth inorganic block disposed below the third inorganic block, and a second heat-insulating material layer disposed below the fourth inorganic block.

[0007] As a preferred embodiment of the high-temperature resistant inorganic artificial stone with heat insulation and crack resistance structure described in this utility model, there are several first and second fiber filaments distributed at equal intervals, and the first and second fiber filaments are distributed in an alternating manner.

[0008] As a preferred embodiment of the high-temperature resistant inorganic artificial stone with heat insulation and crack resistance structure described in this utility model, the fourth inorganic blank has a circular hole gap with the same structure, and the circular hole gap is distributed on the top and bottom surfaces of the second and fourth inorganic blanks.

[0009] As a preferred embodiment of the high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure described in this utility model, the artificial stone component further includes a first groove formed on the top surface of the inorganic artificial stone block and a second groove formed on the bottom surface of the inorganic artificial stone block.

[0010] As a preferred embodiment of the high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure described in this utility model, the first inorganic blank, the second inorganic blank, and the first heat-insulating blank layer are placed in the first groove.

[0011] As a preferred embodiment of the high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure described in this utility model, the third inorganic blank, the fourth inorganic blank, and the second heat-insulating blank layer are placed in the second groove.

[0012] As a preferred embodiment of the high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure described in this utility model, the artificial stone component further includes a marking strip disposed on the top surface of the inorganic artificial stone block.

[0013] Compared with the prior art, the advantages of this utility model are:

[0014] 1. By combining the artificial stone components and the crack-resistant and heat-insulating components, the closed-cell structure formed by the gap between the heat-insulating blank and the round hole during use is achieved, which improves the heat insulation effect of the inorganic artificial stone. In addition, the interwoven fiber filaments improve the flexural strength of the inorganic artificial stone, inhibit the propagation of micro-cracks, and extend the service life of the inorganic artificial stone.

[0015] Second, by setting the first and second slots, the crack-resistant and heat-insulating blank can be directly wrapped and sealed with inorganic artificial stone raw materials, thus ensuring the integrity of the inorganic stone firing and avoiding the problem of delamination. Attached Figure Description

[0016] To more clearly illustrate the technical solutions of the embodiments of this utility model, the present utility model will be described in detail below with reference to the accompanying drawings and detailed embodiments. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort. Among them:

[0017] Figure 1 This is a first-view structural diagram of the present invention;

[0018] Figure 2 This is a second-view structural diagram of the present invention;

[0019] Figure 3 This is a structural diagram showing the position of the circular hole in this utility model;

[0020] Figure 4 This is a structural diagram showing the position of the marking strip of this utility model.

[0021] In the figure: 11, inorganic artificial stone block; 12, first groove; 13, second groove; 14, marking strip; 21, first inorganic block; 22, first fiber filament; 23, second inorganic block; 24, gap between round holes; 25, first heat insulation material layer; 26, third inorganic block; 27, second fiber filament; 28, fourth inorganic block; 29, second heat insulation material layer. Detailed Implementation

[0022] To make the above-mentioned objectives, features and advantages of this utility model more apparent and understandable, the specific embodiments of this utility model will be described in detail below with reference to the accompanying drawings.

[0023] Many specific details are set forth in the following description in order to provide a full understanding of the present invention. However, the present invention may also be implemented in other ways different from those described herein. Those skilled in the art can make similar extensions without departing from the spirit of the present invention. Therefore, the present invention is not limited to the specific embodiments disclosed below.

[0024] Secondly, this utility model is described in detail with reference to the schematic diagrams. When describing the embodiments of this utility model, for ease of explanation, the cross-sectional views illustrating the device structure may be partially enlarged, not adhering to the usual scale. Furthermore, the schematic diagrams are merely examples and should not limit the scope of protection of this utility model. In addition, actual manufacturing should include the three-dimensional spatial dimensions of length, width, and depth.

[0025] To make the objectives, technical solutions, and advantages of this utility model clearer, the embodiments of this utility model will be described in further detail below with reference to the accompanying drawings.

[0026] This utility model provides a high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure. Through the cooperation of the artificial stone components and the crack-resistant heat-insulating components, a closed-cell structure is formed by the gap between the heat-insulating blank and the round hole during use, which improves the heat insulation effect of the inorganic artificial stone. In addition, the interlaced fiber filaments improve the flexural strength of the inorganic artificial stone, inhibit the propagation of microcracks, and improve the service life of the inorganic artificial stone.

[0027] Figures 1-4The diagram shown is an overall structural schematic of an embodiment of the high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure according to this utility model. Please refer to [link / reference]. Figures 1-4 The main structure of this embodiment includes: artificial stone components and crack-resistant heat insulation components.

[0028] The artificial stone component is used in conjunction with the crack-resistant and heat-insulating component. Specifically, the artificial stone component includes an inorganic artificial stone blank 11.

[0029] In practical use, the crack-resistant and heat-insulating components are set and used based on inorganic artificial stone blocks 11 in order to achieve the effect of crack resistance and heat insulation.

[0030] The crack-resistant and heat-insulating component is used to improve the service life of inorganic artificial stone. Specifically, the crack-resistant and heat-insulating component includes a first inorganic block 21 positioned above the inorganic artificial stone block 11, a first fiber filament 22 penetrating the first inorganic block 21, a second inorganic block 23 positioned above the first inorganic block 21, a circular hole gap 24 opened on the second inorganic block 23, a first heat-insulating material layer 25 positioned above the second inorganic block 23, a third inorganic block 26 positioned below the inorganic artificial stone block 11, a second fiber filament 27 penetrating the third inorganic block 26, a fourth inorganic block 28 positioned below the third inorganic block 26, and a second heat-insulating material layer 29 positioned below the fourth inorganic block 28.

[0031] In practical use, based on the inorganic artificial stone block 11, the first inorganic block 21 is bonded to the inorganic artificial stone block 11, and then the second inorganic block 23 and the first heat insulation material layer 25 are bonded together. Liquid raw materials of inorganic artificial stone are used for casting, directly forming the bonded inorganic artificial stone block 11 into a whole. At this time, the distributed first fiber filaments 22 improve the flexural strength and inhibit the propagation of microcracks, and the first heat insulation material layer 25 improves the heat insulation effect. In the same principle, the third inorganic block 26, the fourth inorganic block 28 and the second heat insulation material layer 29 are cast together. Since the second fiber filaments 27 and the first fiber filaments 22 are interspersed, the coverage of the fiber filaments is increased, further improving the crack resistance effect.

[0032] Furthermore, the artificial stone component also includes a first groove 12 formed on the top surface of the inorganic artificial stone block 11 and a second groove 13 formed on the bottom surface of the inorganic artificial stone block 11.

[0033] In practical use, the first inorganic block 21, the second inorganic block 23 and the first heat-insulating material layer 25 are placed in the first groove 12; the third inorganic block 26, the fourth inorganic block 28 and the second heat-insulating material layer 29 are placed in the second groove 13. This avoids the loss of liquid raw materials during casting, allows for better fusion, ensures the integrity of the inorganic artificial stone after firing, and avoids delamination.

[0034] Furthermore, the artificial stone component also includes a marking strip 14 disposed on the top surface of the inorganic artificial stone blank 11;

[0035] After firing, cut along the marked strip 14 to cut the border area not covered by the fiber filaments and insulation layer, thus ensuring the uniformity of the entire artificial stone.

[0036] Although the present invention has been described above with reference to embodiments, various modifications can be made and components can be replaced with equivalents without departing from the scope of the present invention. In particular, as long as there is no structural conflict, the features in the embodiments disclosed in this invention can be combined with each other in any way. The lack of an exhaustive description of these combinations in this specification is merely for the sake of brevity and resource conservation. Therefore, the present invention is not limited to the specific embodiments disclosed herein, but includes all technical solutions falling within the scope of the claims.

Claims

1. A high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure, characterized in that, include: Artificial stone assembly, the artificial stone assembly comprising an inorganic artificial stone blank (11). The crack-resistant and heat-insulating component includes a first inorganic block (21) positioned above the inorganic artificial stone block (11), a first fiber filament (22) penetrating the first inorganic block (21), a second inorganic block (23) positioned above the first inorganic block (21), a circular hole gap (24) formed on the second inorganic block (23), a first heat-insulating material layer (25) positioned above the second inorganic block (23), a third inorganic block (26) positioned below the inorganic artificial stone block (11), a second fiber filament (27) penetrating the third inorganic block (26), a fourth inorganic block (28) positioned below the third inorganic block (26), and a second heat-insulating material layer (29) positioned below the fourth inorganic block (28).

2. The high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure according to claim 1, characterized in that, The first fiber filament (22) and the second fiber filament (27) are distributed at equal intervals, and the first fiber filament (22) and the second fiber filament (27) are interleaved.

3. The high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure according to claim 1, characterized in that, The fourth inorganic preform (28) has a circular hole gap (24) with the same structure, and the circular hole gap (24) is distributed on the top and bottom surfaces of the second inorganic preform (23) and the fourth inorganic preform (28).

4. The high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure according to claim 1, characterized in that, The artificial stone component also includes a first slot (12) on the top surface of the inorganic artificial stone block (11) and a second slot (13) on the bottom surface of the inorganic artificial stone block (11).

5. A high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure according to claim 4, characterized in that, The first inorganic preform (21), the second inorganic preform (23) and the first heat-insulating preform layer (25) are placed in the first slot (12).

6. A high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure according to claim 4, characterized in that: The third inorganic preform (26), the fourth inorganic preform (28), and the second heat-insulating preform layer (29) are placed in the second slot (13).

7. A high-temperature resistant inorganic artificial stone with a heat-insulating and crack-resistant structure according to claim 6, characterized in that: The artificial stone assembly also includes a marking strip (14) disposed on the top surface of the inorganic artificial stone block (11).