CN216552487U

CN216552487U - Deformation-resistant silicon rock plate

Info

Publication number: CN216552487U
Application number: CN202123290324.8U
Authority: CN
Inventors: 钟华; 李远秋
Original assignee: Huizhou Yuemg New Material Co ltd
Current assignee: Huizhou Yuemg New Material Co ltd
Priority date: 2021-12-24
Filing date: 2021-12-24
Publication date: 2022-05-17
Anticipated expiration: 2031-12-24

Abstract

The utility model discloses an anti-deformation silicalite plate, which relates to the technical field of silicalite plates and aims to solve the problems that the existing silicalite plate is easy to deform during transportation or installation and a silicalite plate core exposed after cutting is easy to corrode from the outside to influence the heat preservation effect of the silicalite plate core; the sealing mechanism comprises a sealing cover, a clamping block, a sliding block and a sliding groove. The deformation-resistant silicalite plate can effectively improve the deformation-resistant strength of the silicalite plate body through the reinforcing plate and the reinforcing ribs, so that the silicalite plate body is not easy to deform during installation and transportation, the corrosion of an inner core of the silicalite plate to the outside is reduced, and the heat insulation effect of the silicalite plate body is improved.

Description

Deformation-resistant silicon rock plate

Technical Field

The utility model relates to the technical field of silicalite plates, in particular to an anti-deformation silicalite plate.

Background

The silicon rock plate is a heat-insulating material with excellent performances such as high compression resistance, low water absorption, moisture resistance, air impermeability, light weight, corrosion resistance, aging resistance, low heat conductivity coefficient and the like, and is a high-quality heat-insulating and heat-insulating material commonly used in the building industry at present;

the existing silicon rock plate is easily influenced by external force to cause the silicon rock plate to deform in the transportation process or the installation process, the existing silicon rock plate needs to be cut and installed according to the size required on site during installation, after the silicon rock plate is cut, the silicon rock plate core inside the silicon rock plate core is exposed, and the exposed silicon rock plate core is easily corroded by the outside to influence the heat preservation effect of the silicon rock plate core.

SUMMERY OF THE UTILITY MODEL

The deformation-resistant silica rock plate provided by the utility model solves the problem that the insulation effect of the silica rock plate is easily influenced by external erosion when the silica rock plate is easily deformed during transportation or installation and a silica rock plate core exposed after cutting.

In order to achieve the purpose, the utility model adopts the following technical scheme:

an anti-deformation silicalite plate comprises a silicalite plate body, wherein a sealing mechanism is arranged on one side of the silicalite plate body and used for sealing an exposed cut inner core, and a silicalite plate inner core structure is arranged on one side of the sealing mechanism and used for reinforcing the silicalite plate body;

sealing mechanism includes sealed lid, fixture block, sliding block and sliding tray, sealed lid is the symmetry setting with the axis of silicon rock plate body, the fixture block is connected with one side of sealed lid, the sliding block is located the top and the bottom of fixture block, just the one end of sliding block is connected with sealed lid, the sliding block matches with the sliding tray.

Preferably, the silicalite board inner core structure includes reinforcing plate, strengthening rib, connecting plate, first silicalite inner core, fixed block, second silicalite inner core, silicalite board shell and draw-in groove, the silicalite board shell is located the top of reinforcing plate, just the silicalite board shell is the symmetry setting with the axis of reinforcing plate.

Preferably, the strengthening rib is located between reinforcing plate and the silicalite slab shell, just the one end that the strengthening rib is close to the silicalite slab shell is connected with the fixed block, the one end that the strengthening rib was kept away from to the fixed block is connected with the silicalite slab shell.

Preferably, the first silicalite inner core is located inside the reinforcing plate, and the second silicalite inner core is located between the silicalite plate outer shell and the reinforcing plate.

Preferably, the one end that the reinforcing plate was kept away from to the connecting plate is connected with strengthening rib and silicon rock plate shell, the one end that the silicon rock plate shell was kept away from to the connecting plate is connected with the reinforcing plate, just the connecting plate is the symmetry setting with the axis of reinforcing plate.

Preferably, the draw-in groove is located the both ends of silicalite board shell, just draw-in groove and fixture block phase-match, the top and the sliding tray of silicalite board shell are connected, just the sliding tray evenly sets up along the length direction of silicalite board shell.

The utility model has the beneficial effects that:

1. increase the reinforcing plate through the inner core at the silicalite board body, then pour into the silicalite inner core into in the inside of reinforcing plate, increase the wave strengthening rib in the inside of silicalite board body afterwards, pour into the silicalite inner core into at the lateral wall of strengthening rib afterwards, the resistance to deformation intensity of reinforcing plate and strengthening rib can effectual improvement silicalite board body for the silicalite board body is difficult for producing the deformation when installation and transportation.

2. The sliding groove on the back silicalite board shell is tailor through aligning the sliding block on the closing plate, then promotes the closing plate for the sliding block slides in the sliding groove, then will seal the fixture block of covering and fix inside the draw-in groove, thereby can effectually will tailor the silicalite board inner core that exposes and seal, reduce the silicalite board inner core and receive external erosion, improve the heat preservation effect of silicalite board body.

To sum up, the device passes through the resistance to deformation intensity that reinforcing plate and strengthening rib can effectual improvement silicon rock plate body for silicon rock plate body is difficult for producing when installation and transportation and is out of shape, has reduced the silicon rock plate inner core simultaneously and has received external erosion, improves the heat preservation effect of silicon rock plate body, facilitates the use.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural diagram of the silicalite plate core of the present invention.

Fig. 3 is a schematic view of the disassembly structure of the present invention.

Fig. 4 is an enlarged schematic view of the structure at a in fig. 3 according to the present invention.

Reference numbers in the figures: 1. a silica rock plate body; 2. a sealing mechanism; 201. a sealing cover; 202. a clamping block; 203. a slider; 204. a sliding groove; 3. a silicon rock plate inner core structure; 301. a reinforcing plate; 302. reinforcing ribs; 303. a connecting plate; 304. a first silicalite core; 305. a fixed block; 306. a second silicalite inner core; 307. a silica rock plate housing; 308. a clamping groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-4, the anti-deformation silicalite plate comprises a silicalite plate body 1, wherein a sealing mechanism 2 is arranged on one side of the silicalite plate body 1, the sealing mechanism 2 is used for sealing an exposed cut inner core, a silicalite plate inner core structure 3 is arranged on one side of the sealing mechanism 2, and the silicalite plate inner core structure 3 is used for reinforcing the silicalite plate body 1;

the sealing mechanism 2 comprises a sealing cover 201, a fixture block 202, a sliding block 203 and a sliding groove 204, the sealing cover 201 is symmetrically arranged on the central axis of the silicalite plate body 1, the fixture block 202 is connected with one side of the sealing cover 201, the sliding block 203 is located at the top end and the bottom end of the fixture block 202, one end of the sliding block 203 is connected with the sealing cover 201, and the sliding block 203 is matched with the sliding groove 204.

As shown in fig. 2 and 3, the silicalite plate inner core structure 3 includes a reinforcing plate 301, a reinforcing rib 302, a connecting plate 303, a first silicalite inner core 304, a fixing block 305, a second silicalite inner core 306, a silicalite plate outer shell 307 and a clamping groove 308, the silicalite plate outer shell 307 is located at the top end of the reinforcing plate 301, the silicalite plate outer shell 307 is symmetrically arranged with the central axis of the reinforcing plate 301, the reinforcing rib 302 is located between the reinforcing plate 301 and the silicalite plate outer shell 307, one end of the reinforcing rib 302 close to the silicalite plate outer shell 307 is connected with the fixing block 305, one end of the fixing block 305 far away from the reinforcing rib 302 is connected with the silicalite plate outer shell 307, the first silicalite inner core 304 and the second silicalite inner core 306 exposed by cutting can be effectively sealed through a sealing cover 201, the corrosion of the silicalite inner core to the outside is reduced, and the heat preservation effect is improved.

As shown in fig. 3 and 4, the first silicalite inner core 304 is located inside the reinforcing plate 301, the second silicalite inner core 306 is located between the silicalite plate outer shell 307 and the reinforcing plate 301, one end of the connecting plate 303, which is far away from the reinforcing plate 301, is connected with the reinforcing rib 302 and the silicalite plate outer shell 307, one end of the connecting plate 303, which is far away from the silicalite plate outer shell 307, is connected with the reinforcing plate 301, the connecting plate 303 is symmetrically arranged with respect to the central axis of the reinforcing plate 301, the clamping grooves 308 are located at two ends of the silicalite plate outer shell 307, the clamping grooves 308 are matched with the clamping blocks 202, the top end of the silicalite plate outer shell 307 is connected with the sliding groove 204, the sliding groove 204 is uniformly arranged along the length direction of the silicalite plate outer shell 307, and the deformation resistance strength of the silicalite plate body 1 can be effectively improved through the arrangement of the reinforcing plate 301, the reinforcing rib 302 and the connecting plate 303.

The working principle is as follows: when the device is used, the reinforcing plate 301 is connected with the reinforcing rib 302, the other end of the reinforcing rib 302 is connected with the silicalite plate outer shell 307, the reinforcing plate 301, the reinforcing rib 302 and the silicalite plate outer shell 307 are connected through the connecting plate 303, after the connection is finished, the first silicalite inner core 304 and the second silicalite inner core 306 are respectively injected into the reinforcing plate 301 and the side wall of the reinforcing rib 302, the deformation resistance strength of the silicalite plate body 1 can be effectively improved through the arrangement of the reinforcing plate 301, the reinforcing rib 302 and the connecting plate 303, so that the device is not easy to deform during transportation or installation, when the device is required to be cut according to the size of a site, the sealing cover 201 is moved to a position where the silicalite plate cutting inner core is exposed, then the sliding block 203 is aligned with the sliding groove 204 on the silicalite plate outer shell 307, then the sealing cover 201 is pushed forward, so that the clamping block 202 is clamped in the clamping groove 308 at the silicalite plate outer shell 307, therefore, the inner core exposed by cutting can be effectively sealed, the phenomenon that the silicalite inner core is corroded by the outside is reduced, and the heat insulation effect is improved.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims

1. The anti-deformation silicalite plate comprises a silicalite plate body (1), and is characterized in that a sealing mechanism (2) is arranged on one side of the silicalite plate body (1), the sealing mechanism (2) is used for sealing an exposed cut inner core, a silicalite plate inner core structure (3) is arranged on one side of the sealing mechanism (2), and the silicalite plate inner core structure (3) is used for reinforcing the silicalite plate body (1);

sealing mechanism (2) are including sealed lid (201), fixture block (202), sliding block (203) and sliding tray (204), sealed lid (201) are the symmetry setting with the axis of silicon rock plate body (1), fixture block (202) is connected with one side of sealed lid (201), sliding block (203) are located the top and the bottom of fixture block (202), just the one end of sliding block (203) is connected with sealed lid (201), sliding block (203) and sliding tray (204) phase-match.

2. The deformation-resistant silica rock plate as claimed in claim 1, wherein the silica rock plate inner core structure (3) comprises a reinforcing plate (301), reinforcing ribs (302), a connecting plate (303), a first silica rock inner core (304), a fixing block (305), a second silica rock inner core (306), a silica rock plate outer shell (307) and clamping grooves (308), the silica rock plate outer shell (307) is located at the top end of the reinforcing plate (301), and the silica rock plate outer shell (307) is symmetrically arranged with respect to the central axis of the reinforcing plate (301).

3. A deformation-resistant silica rock plate according to claim 2, wherein the reinforcing rib (302) is located between the reinforcing plate (301) and the silica rock plate shell (307), and one end of the reinforcing rib (302) close to the silica rock plate shell (307) is connected with the fixing block (305), and one end of the fixing block (305) far from the reinforcing rib (302) is connected with the silica rock plate shell (307).

4. A deformation-resistant silica rock panel according to claim 2, wherein the first silica rock core (304) is located inside the reinforcement panel (301) and the second silica rock core (306) is located between the silica rock panel outer shell (307) and the reinforcement panel (301).

5. A deformation-resistant silica gel plate as claimed in claim 2, wherein the end of the connecting plate (303) remote from the reinforcement plate (301) is connected to the reinforcement bar (302) and the silica gel plate shell (307), the end of the connecting plate (303) remote from the silica gel plate shell (307) is connected to the reinforcement plate (301), and the connecting plates (303) are symmetrically arranged about the central axis of the reinforcement plate (301).

6. The deformation-resistant silicalite plate as claimed in claim 2, wherein the clamping grooves (308) are located at two ends of the silicalite plate shell (307), the clamping grooves (308) are matched with the clamping blocks (202), the top end of the silicalite plate shell (307) is connected with the sliding groove (204), and the sliding groove (204) is uniformly arranged along the length direction of the silicalite plate shell (307).