A high-strength thermal insulation stone composite board

By introducing reinforcing ribs and reinforcing frames into the insulated stone composite panel, combined with a Z-shaped mortar shell and snap-fit ​​structure, the problem of insufficient strength of the insulated stone composite panel is solved, achieving high strength and convenient installation.

CN224495643UActive Publication Date: 2026-07-14LAIZHOU CHANGYU NEW MATERIAL TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
LAIZHOU CHANGYU NEW MATERIAL TECHNOLOGY CO LTD
Filing Date
2025-06-25
Publication Date
2026-07-14

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Abstract

This utility model discloses a high-strength thermal insulation stone composite panel, belonging to the field of stone composite panels. It includes a mortar shell, alkali-resistant fiberglass cloth, reinforcing ribs, a reinforcing frame, thermal insulation filler, snap-fit ​​blocks, snap-fit ​​grooves, and a stone veneer. The alkali-resistant fiberglass cloth is fixedly installed at the inner end of the mortar shell. A reinforcing rib is vertically fixedly installed in the middle of the inner end of the alkali-resistant fiberglass cloth, and a reinforcing frame is horizontally fixedly installed at the inner end of the alkali-resistant fiberglass cloth. The key technical point is that by setting up a reinforcing frame to reinforce the area divided by the reinforcing ribs, the device possesses high strength and durability. Furthermore, the fixed connection between the reinforcing frame and the reinforcing ribs allows the internal reinforcing structures to complement each other, more effectively improving the device's strength. The stone veneer is then manufactured using an ultra-thin process and bonded to the outer end of the mortar shell, thus forming a stone composite panel. The ultra-thin process reduces the overall weight of the device, making it lightweight, easy to handle, and aesthetically pleasing.
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Description

Technical Field

[0001] This utility model relates to the field of stone composite panels, and in particular to a high-strength thermal insulation stone composite panel. Background Technology

[0002] Insulated stone composite panels, also known as exterior wall insulated stone composite panels, granite insulated composite panels, integrated stone insulated and decorative panels, stone composite insulated panels, etc., have good fire resistance, good insulation effect, light weight, which can significantly reduce the building load, are durable, and are quick to install and easy to construct. They can be directly pasted to the exterior wall of the building to complete the construction in one step, which greatly improves the construction efficiency.

[0003] Common insulated stone composite panels rely on water-resistant substrates. However, these products lack nail-holding power, cannot be secured with nails or screws, and have no load-bearing capacity. Therefore, they cannot be used alone as shelf panels or countertops, and are primarily used as wall and floor coverings, rarely as home furnishings. Chinese Patent Publication No. CN218881436U discloses a novel stone composite panel that effectively solves the aforementioned problems through the collaboration of multiple components. However, in practical use, the device relies solely on horizontal and vertical square wooden pieces, significantly reducing its strength. Therefore, we propose a high-strength insulated stone composite panel. Utility Model Content

[0004] In order to overcome the shortcomings of the existing technology, the purpose of this utility model is to provide a high-strength thermal insulation stone composite board. By setting a reinforcing frame to reinforce the area after the reinforcing ribs are divided, the device has high strength and durability. The fixed connection between the reinforcing frame and the reinforcing ribs also makes the internal reinforcing structure of the device mutually support each other, which more effectively improves the strength of the device.

[0005] The above-mentioned technical objective of this utility model is achieved through the following technical solution:

[0006] A high-strength thermal insulation stone composite panel includes a mortar shell, alkali-resistant fiberglass cloth, reinforcing ribs, reinforcing frame, thermal insulation filler, interlocking blocks, interlocking grooves, and stone veneer.

[0007] An alkali-resistant fiberglass cloth is fixedly installed at the inner end of the mortar shell. A reinforcing rib is vertically fixedly installed in the middle of the inner end of the alkali-resistant fiberglass cloth. A reinforcing frame is horizontally fixedly installed at the inner end of the alkali-resistant fiberglass cloth. The interior of the reinforcing frame is filled with thermal insulation material. A snap-fit ​​block is fixedly installed on the left side of the lower end of the mortar shell. A snap-fit ​​groove is opened inside the right side of the upper end of the mortar shell. A stone veneer is fixedly installed at the upper end of the mortar shell. By setting the reinforcing rib, a supporting structure is provided in the middle of the interior of the mortar shell, thereby preventing the mortar shell from being easily damaged by force when the area is large.

[0008] Furthermore, the mortar shell has a Z-shaped structure, and the inner end of the mortar shell and the reinforcing frame are fixedly connected. The left and right ends of the Z-shaped mortar shell fit together, thus providing a snap-fit ​​positioning structure when the device is arranged in a cycle. The interlocking of the two ends also makes the surface of the device highly flat after being arranged in a cycle.

[0009] Furthermore, the snap-fit ​​block and the snap-fit ​​slot are compatible. The snap-fit ​​block has a T-shaped structure. Through the compatibility of the snap-fit ​​block and the snap-fit ​​slot, when the device is connected in a circular manner on a plane, the snap-fit ​​block snaps into the corresponding snap-fit ​​slot, so that the device can be connected together after being arranged in a circular manner. The design of this structure allows the device to be connected without the need for auxiliary fixing parts such as bolts when it is used in a circular manner. Similarly, it also eliminates the need for drilling or other operations after the device is connected in a circular manner, which can effectively protect the integrity of the device and thus improve the service life of the device.

[0010] Furthermore, the reinforcing frame and the reinforcing rib are fixedly connected. The reinforcing frame is symmetrically distributed in the middle of the left and right ends of the reinforcing rib. The reinforcing frame is used to reinforce the area after the reinforcing rib is divided, thereby giving the device high strength and durability. The fixed connection between the reinforcing frame and the reinforcing rib also makes the internal reinforcing structure of the device mutually support each other, which more effectively improves the strength of the device.

[0011] Furthermore, the reinforcing frame has a grid structure, the thermal insulation filler has a block structure, the thermal insulation filler is distributed in an array inside the alkali-resistant fiberglass cloth, and the number of thermal insulation fillers is several blocks.

[0012] Furthermore, the alkali-resistant fiberglass cloth has a Z-shaped structure and a mesh structure.

[0013] Furthermore, the left end and the right end of the mortar shell are adapted to each other.

[0014] Furthermore, the stone veneer is fixedly installed at both ends of the mortar shell.

[0015] In summary, this utility model has the following beneficial effects:

[0016] 1. By setting up a reinforcing frame to reinforce the area after the reinforcing ribs are divided, the device has high strength and durability. The fixed connection between the reinforcing frame and the reinforcing ribs also makes the internal reinforcing structure of the device mutually support each other, which more effectively improves the strength of the device. Then, the stone veneer is manufactured using an ultra-thin process and is attached to the outer end of the mortar shell to form a stone composite panel. The ultra-thin process can reduce the overall weight of the device, making the device lightweight, easy to handle, and aesthetically pleasing.

[0017] 2. By setting the outer mortar shell in a Z-shaped structure, and then setting a snap-fit ​​block on the lower left side of the mortar shell, and opening a snap-fit ​​groove on the upper right side of the mortar shell, when the device is connected in a circular manner on the plane, the snap-fit ​​block snaps into the corresponding snap-fit ​​groove, so that the device can be connected together after being arranged in a circular manner. The design of this structure allows the device to be connected without the need for bolts or other auxiliary fixing parts when used in a circular manner. At the same time, it also eliminates the need for drilling or other operations after the device is connected in a circular manner, which can effectively protect the integrity of the device and thus improve the service life of the device. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the overall structure in this embodiment;

[0019] Figure 2 This is a cross-sectional structural diagram of this embodiment;

[0020] Figure 3 This is in this embodiment Figure 2 Enlarged structural diagram of A in the middle;

[0021] Figure 4 This is in this embodiment Figure 2 Enlarged structural diagram of B;

[0022] Figure 5 This is a three-dimensional structural diagram of the reinforcing frame in this embodiment.

[0023] In the diagram, 1. Mortar shell; 2. Alkali-resistant fiberglass cloth; 3. Reinforcing ribs; 4. Reinforcing frame; 5. Thermal insulation filler; 6. Connecting block; 7. Connecting groove; 8. Stone veneer. Detailed Implementation

[0024] The present invention will be further described in detail below with reference to the accompanying drawings.

[0025] Identical parts are indicated by the same reference numerals. It should be noted that the terms "front," "rear," "left," "right," "up," and "down" used in the following description refer to directions in the accompanying drawings, while the terms "bottom surface," "top surface," "inner," and "outer" refer to directions toward or away from the geometric center of a specific part, respectively.

[0026] Reference Figure 1-5 As shown, a high-strength thermal insulation stone composite panel in a preferred embodiment of this utility model includes a mortar shell 1, alkali-resistant fiberglass cloth 2, reinforcing ribs 3, reinforcing frame 4, thermal insulation filler 5, snap-fit ​​block 6, snap-fit ​​groove 7, and stone veneer 8.

[0027] An alkali-resistant fiberglass cloth 2 is fixedly installed at the inner end of the mortar shell 1. A reinforcing rib 3 is vertically fixedly installed in the middle of the inner end of the alkali-resistant fiberglass cloth 2. A reinforcing frame 4 is horizontally fixedly installed at the inner end of the alkali-resistant fiberglass cloth 2. The interior of the reinforcing frame 4 is filled with thermal insulation material 5. A snap-fit ​​block 6 is fixedly installed on the left side of the lower end of the mortar shell 1. A snap-fit ​​groove 7 is opened inside the right side of the upper end of the mortar shell 1. A stone veneer 8 is fixedly installed at the upper end of the mortar shell 1. By setting the reinforcing rib 3, the middle of the interior of the mortar shell 1 has a supporting structure, thereby avoiding damage to the mortar shell 1 when the area is large.

[0028] The mortar shell 1 has a Z-shaped structure. The inner end of the mortar shell 1 and the reinforcing frame 4 are fixedly connected. The left and right ends of the Z-shaped mortar shell 1 fit together, which gives the device a snap-fit ​​positioning structure when it is arranged in a cycle. The interlocking of the two ends also makes the surface of the device highly flat after it is arranged in a cycle.

[0029] The snap-fit ​​block 6 and the snap-fit ​​groove 7 are compatible. The snap-fit ​​block 6 has a T-shaped structure. Through the compatibility of the snap-fit ​​block 6 and the snap-fit ​​groove 7, when the device is connected in a circular manner on the plane, the snap-fit ​​block 6 snaps into the snap-fit ​​groove 7, so that the device can be connected together after being arranged in a circular manner. The design of this structure allows the device to be connected without the use of bolts or other auxiliary fixing parts when it is used in a circular manner. At the same time, it also eliminates the need for drilling or other operations after the device is connected in a circular manner, which can effectively protect the integrity of the device and thus improve the service life of the device.

[0030] The reinforcing frame 4 and the reinforcing rib 3 are fixedly connected. The reinforcing frame 4 is symmetrically distributed in the middle of the left and right ends of the reinforcing rib 3. The reinforcing frame 4 is used to reinforce the area after the reinforcing rib 3 is divided, thereby giving the device high strength and durability. The fixed connection between the reinforcing frame 4 and the reinforcing rib 3 also makes the internal reinforcing structure of the device mutually support each other, which can more effectively improve the strength of the device.

[0031] The reinforcing frame 4 has a grid structure, and the insulation filler 5 has a block structure. The insulation filler 5 is distributed in an array inside the alkali-resistant fiberglass cloth 2. There are several blocks of insulation filler 5. The grid structure of the reinforcing frame 4 is balanced by the force, and then the insulation filler 5 is installed inside it, so that the device has both insulation effect and better strength.

[0032] The alkali-resistant fiberglass cloth 2 has a Z-shaped structure and a mesh structure. The setting of the alkali-resistant fiberglass cloth 2 gives the inner end of the mortar shell 1 a tensile force, giving the mortar shell 1 a certain strength and toughness.

[0033] The left and right ends of the mortar shell 1 are matched, and the left and right ends of the mortar shell 1 are matched, so that the device has good connectivity when used in a cyclic arrangement.

[0034] The stone veneer 8 is fixedly installed at the upper and lower ends of the mortar shell 1. The stone veneer 8 is manufactured using an ultra-thin process and is attached to the outer end of the mortar shell 1 to form a stone composite panel. The ultra-thin process can reduce the overall weight of the device, making the device lightweight, easy to handle, and aesthetically pleasing.

[0035] Specific implementation process: This utility model relates to a high-strength thermal insulation stone composite board. Firstly, the outer mortar shell 1 is arranged in a Z-shaped structure. Then, a snap-fit ​​block 6 is set on the lower left side of the mortar shell 1, and a snap-fit ​​groove 7 is opened on the upper right side of the mortar shell 1. When the device is cyclically connected in a plane, the snap-fit ​​block 6 snaps into the snap-fit ​​groove 7, allowing the device to be connected together in a cyclic arrangement. This structure allows the device to be connected without the need for bolts or other auxiliary fixing components, and also eliminates the need for drilling after cyclic connection, effectively protecting the integrity of the device and thus improving its service life. Secondly, the reinforcing frame 4 is used to reinforce the area divided by the reinforcing rib 3. The device possesses high strength and durability, and the fixed connection between the reinforcing frame 4 and the reinforcing rib 3 allows the internal reinforcing structures to complement each other, effectively improving the device's strength. Finally, the stone veneer 8 is manufactured using an ultra-thin process and is attached to the outer end of the mortar shell 1, thus forming a stone composite panel. The ultra-thin process reduces the overall weight of the device, making it lightweight, easy to handle, and aesthetically pleasing. The various components of the device complement each other, and the reinforcing frame 4 with its grid structure balances the force. Then, the insulation filler 5 is installed inside, giving the device both insulation and better strength. Furthermore, the alkali-resistant fiberglass cloth 2 provides tensile strength to the inner end of the mortar shell 1, giving the mortar shell 1 a certain degree of strength and toughness.

[0036] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claims. The scope of protection of this utility model is defined by the appended claims and their equivalents.

Claims

1. A high-strength thermal insulation stone composite board, characterized in that: It includes a mortar shell (1), alkali-resistant fiberglass cloth (2), reinforcing ribs (3), reinforcing frame (4), thermal insulation filler (5), snap-fit ​​block (6), snap-fit ​​groove (7), and stone veneer (8); An alkali-resistant fiberglass cloth (2) is fixedly installed at the inner end of the mortar shell (1). A reinforcing rib (3) is fixedly installed vertically at the middle of the inner end of the alkali-resistant fiberglass cloth (2). A reinforcing frame (4) is fixedly installed horizontally at the inner end of the alkali-resistant fiberglass cloth (2). The interior of the reinforcing frame (4) is fixedly filled with thermal insulation filler (5). A snap-fit ​​block (6) is fixedly installed on the left side of the lower end of the mortar shell (1). A snap-fit ​​groove (7) is opened inside the right side of the upper end of the mortar shell (1). A stone veneer (8) is fixedly installed at the upper end of the mortar shell (1).

2. The high-strength thermal insulation stone composite board according to claim 1, characterized in that: The mortar shell (1) has a Z-shaped structure, and the inner end of the mortar shell (1) and the reinforcing frame (4) are fixedly connected.

3. The high-strength thermal insulation stone composite board according to claim 1, characterized in that: The snap-fit ​​block (6) and the snap-fit ​​groove (7) are adapted to each other, and the snap-fit ​​block (6) has a T-shaped structure.

4. The high-strength thermal insulation stone composite board according to claim 2, characterized in that: The reinforcing frame (4) and the reinforcing rib (3) are fixedly connected, and the reinforcing frame (4) is symmetrically distributed in the middle of the left and right ends of the reinforcing rib (3).

5. The high-strength thermal insulation stone composite board according to claim 1, characterized in that: The reinforcing frame (4) is a grid structure, the thermal insulation filler (5) is a block structure, the thermal insulation filler (5) is distributed in an array inside the alkali-resistant fiberglass cloth (2), and the number of thermal insulation fillers (5) is several blocks.

6. The high-strength thermal insulation stone composite board according to claim 2, characterized in that: The alkali-resistant fiberglass cloth (2) has a Z-shaped structure and a mesh structure.

7. The high-strength thermal insulation stone composite board according to claim 3, characterized in that: The left end of the mortar shell (1) and the right end of the mortar shell (1) are adapted to each other.

8. A high-strength thermal insulation stone composite board according to claim 4, characterized in that: The stone veneer (8) is fixedly installed at the upper and lower ends of the mortar shell (1).