CN220598883U - Rock wool composite board with dislocation placing method - Google Patents

Abstract

The utility model relates to the technical field of rock wool composite boards, in particular to a rock wool composite board with a dislocation placing method, which comprises two third side baffles and a plurality of rock wool strips, wherein the rock wool strips form the rock wool board, alkali-resistant glass fiber mesh cloth is coated on four sides of the rock wool board, the two third side baffles are adhered to two symmetrical side surfaces of the alkali-resistant glass fiber mesh cloth, a first side baffle and a second side baffle are respectively connected between two ends of the two third side baffles, and a plurality of elastic parting strips are arranged between the rock wool strips in a penetrating manner along the horizontal direction. According to the scheme, the elastic parting strips are arranged between the two adjacent rock wool strips, so that the stress of the elastic parting strips can be conveniently deformed to offset part of stress intensity, the stress intensity of the rock wool is reduced, and the compressive strength of the rock wool board is improved.

Description

Rock wool composite board with dislocation placing method

Technical Field

The utility model relates to the technical field of rock wool composite boards, in particular to a rock wool composite board with a dislocation placing method.

Background

The main material of the rock wool composite board is basalt cotton board, basalt, iron ore, bauxite and the like are used as main raw materials, and an artificial inorganic fiber which is prepared by adding a proper amount of binder through high-temperature melting processing has the characteristics of light weight, small heat conductivity, heat absorption and incombustibility.

In the prior art, the disclosed patent number is a composite rock wool reinforcing plate with high tensile strength of CN 216810369U, the local stress intensity of the rock wool plate is improved in a mode of arranging a plurality of rock wool strips in a staggered mode, but the patent needs to set riveting holes into the rock wool plate and drive rivets and anchor rods, when the rock wool is impacted by larger external force, the texture of the rock wool is softer, the impacted rock wool deforms and presses other rock wool to the periphery, and due to the fact that the rock wool strips are directly connected, components for counteracting the external force intensity are arranged, the anchor rods or the rivets in the patent are in hard contact with the rock wool parts, and the anchor rods or the rivets cannot buffer the rock wool when stressed, so that the integral compressive strength of the rock wool plate is reduced.

Disclosure of Invention

The utility model aims to solve the defects in the prior art, and provides a rock wool composite board with a dislocation placing method.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides a rock wool composite sheet of dislocation putting method, includes two third side shield and a plurality of rock wool strip, and a plurality of rock wool strip establishes between two third side shield, along a plurality of on the vertical direction rock wool strip is received in turn and is contacted, along a plurality of adjacent on the horizontal direction rock wool strip between dislocation set up, a plurality of rock wool strip constitutes the rock wool board, the four sides cladding at the rock wool board has alkali-resistant glass fiber net cloth, and two third side shields bond at two symmetrical sides of alkali-resistant glass fiber net cloth, two be connected with first side shield and second side shield respectively between the both ends of third side shield, along running through between the horizontal direction a plurality of rock wool strip be equipped with a plurality of elasticity parting bead, a plurality of jack that correspond with elasticity parting bead position are seted up to the side of second side shield, the other end jack of elasticity parting bead passes and extends to its one side, the draw-in groove has been seted up on the surface of elasticity parting bead, the draw-in groove is at two symmetrical sides of second side shield.

Preferably, limiting plates are connected between the top ends and the bottom ends of the first side baffle plate and the second side baffle plate, and the surfaces of the limiting plates are in surface contact with the alkali-resistant glass fiber mesh cloth corresponding to the positions.

Preferably, the second side baffle is concave, the first side baffle is convex, and the size of the inner cavity of the second side baffle is matched with the external size of the first side baffle.

Preferably, the elastic parting bead is elastic stainless steel.

Preferably, the surfaces of the rock wool strips contacted with the elastic parting strips are bonded by glue.

Compared with the prior art, the utility model has the following beneficial effects:

according to the scheme, the elastic parting bead is arranged between the two adjacent rock wool strips, the elastic parting bead is made of elastic stainless steel, deformation is generated after the rock wool is stressed and the elastic parting bead adjacent to the stressed rock wool is stressed when the force is diffused to the periphery, and reverse acting force is generated, and the deformation amount of the elastic parting bead is gradually increased due to the fact that the external force is larger than the direction acting force of the elastic parting bead, the reverse acting force is also gradually increased, so that deformation generated by the elastic parting bead can offset part of stress intensity, the stress intensity of the rock wool is reduced, and the compression strength of the rock wool plate is improved.

Drawings

FIG. 1 is an isometric view of a rock wool composite panel of a misplacement method of the present utility model;

FIG. 2 is a schematic diagram of a connection structure of rock wool strips and elastic parting strips of a rock wool composite board according to a dislocation putting method of the utility model;

FIG. 3 is a schematic view of a second side baffle of a rock wool composite board according to the present utility model;

FIG. 4 is a schematic view of a connection structure between a first side baffle and an elastic parting strip of a rock wool composite board according to the dislocation putting method of the utility model;

FIG. 5 is a schematic view of a connection structure between a second side baffle and an elastic parting strip of a rock wool composite board according to the dislocation putting method of the utility model;

fig. 6 is a schematic diagram of connection between alkali-resistant glass fiber mesh cloth and rock wool strips of a rock wool composite board by a dislocation laying method of the utility model.

In the figure: 1. a third side baffle; 2. a first side baffle; 3. a second side baffle; 4. an elastic parting bead; 5. a rock wool strip; 6. a clamping groove; 7. a jack; 8. a limiting plate; 9. alkali-resistant glass fiber mesh cloth.

Detailed Description

The following description is presented to enable one of ordinary skill in the art to make and use the utility model. The preferred embodiments in the following description are by way of example only and other obvious variations will occur to those skilled in the art.

The rock wool composite board comprises two third side baffles 1 and a plurality of rock wool strips 5, wherein the rock wool strips 5 are arranged between the two third side baffles 1, the rock wool strips 5 are sequentially contacted in a tail-to-tail manner along the vertical direction, the rock wool strips 5 are arranged in a staggered manner along the horizontal direction between the adjacent rock wool strips 5, the rock wool boards are formed by the rock wool strips 5, alkali-resistant glass fiber mesh cloth 9 is coated on four sides of the rock wool boards, and the two third side baffles 1 are adhered to two symmetrical side surfaces of the alkali-resistant glass fiber mesh cloth 9; the waterproof glue layer is coated on the surface of the alkali-resistant glass fiber mesh cloth 9, so that the alkali-resistant glass fiber mesh cloth 9 has excellent performances such as water resistance, alkali resistance, tensile resistance, crack resistance and the like, and the overall strength of the rock wool composite board is further improved.

The two ends of the two third side baffles 1 are respectively connected with a first side baffle 2 and a second side baffle 3 through rivets, a plurality of elastic parting strips 4 are arranged between a plurality of rock wool strips 5 along the horizontal direction in a penetrating way, and the types of the elastic parting strips 4 are SUS304 type elastic stainless steel; after the rock wool strip 5 is stressed and the force is applied to the surrounding rock wool strips 5, the impact force is applied to the elastic parting strips 4 adjacent to the stressed rock wool strip 5, the elastic parting strips 4 deform after being stressed and generate reverse acting force, and the deformation amount of the elastic parting strips 4 is gradually increased due to the fact that the external force is larger than the direction acting force of the elastic parting strips 4, the reverse acting force is gradually increased after the deformation amount is increased, the part of impact force can be counteracted by the counterforce after the lifting, and the deformation generated by the stress of the elastic parting strips is facilitated to counteract part of stress intensity and used for improving the compressive strength of the rock wool composite board.

One end of each elastic parting strip 4 is welded on the side surface of the first side baffle 2, a plurality of insertion holes 7 corresponding to the positions of the elastic parting strips 4 are formed in the side surface of the second side baffle 3, the other end of each elastic parting strip 4 penetrates through each insertion hole 7 and extends to one side of each insertion hole, clamping grooves 6 are formed in the surface of each elastic parting strip 4, and the clamping grooves 6 are sleeved on two symmetrical side surfaces of the second side baffle 3; one end of the elastic parting bead 4 is welded and fixed with the first side baffle plate 2, at the moment, the position of one end of the elastic parting bead 4 is fixed, the other end of the elastic parting bead 4 is inserted on two symmetrical side surfaces of the second side baffle plate 3 through a clamping groove 6 and used for improving the stability of connection between the elastic parting bead 4 and the second side baffle plate 3, the positions of the two ends of the elastic parting bead 4 are fixed after being stressed, and the stability in the deformation process of the elastic parting bead 4 after being stressed is improved; when the clamping groove 6 of the elastic parting bead 4 is separated from the second side baffle plate 3, the elastic parting bead 4 is removed from the jack 7, so that separation and disassembly between the elastic parting bead 4 and the second side baffle plate 3 are facilitated.

Limiting plates 8 are connected between the top ends and the bottom ends of the first side baffle plate 2 and the second side baffle plate 3 through rivets, and the surfaces of the limiting plates 8 are in surface contact with alkali-resistant glass fiber mesh cloth 9 corresponding to the positions; after the rock wool strips 5 corresponding to the positions of the limiting plates 8 are stressed, the rock wool strips 5 respectively transmit external force to the surfaces of the corresponding limiting plates 8 and the corresponding alkali-resistant glass fiber mesh cloth 9, the acting force of the limiting plates 8 is to prevent the rock wool strips 5 from being extruded from the mesh holes of the alkali-resistant glass fiber mesh cloth 9 after being stressed, and the stability of the rock wool strips 5 in the alkali-resistant glass fiber mesh cloth 9 is improved.

The second side baffle plate 3 is concave, the first side baffle plate 2 is convex, and the size of the inner cavity of the second side baffle plate 3 is matched with the external size of the first side baffle plate 2; when two adjacent rock wool composite boards are installed, the second side baffle 3 and the first side baffle 2 between the two adjacent rock wool composite boards are matched with each other, so that installation between the two rock wool composite boards is facilitated.

The surfaces of the rock wool strips 5 contacted with the elastic parting strips 4 are bonded by glue; the stability of connection of the elastic parting strips 4 and the rock wool strips 5 is improved, and meanwhile, the disassembly operation of later maintenance is also facilitated.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made therein without departing from the spirit and scope of the utility model, which is defined by the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (5)

1. The utility model provides a rock wool composite sheet of dislocation putting method, includes two third side shield (1) and a plurality of rock wool strip (5), along a plurality of on the vertical direction rock wool strip (5) head and tail contact, along a plurality of adjacent on the horizontal direction rock wool strip (5) dislocation set up, a plurality of rock wool strip (5) are constituteed the rock wool board, and the four sides cladding at the rock wool board has alkali-resisting glass fiber net cloth (9), and two third side shield (1) bond two symmetrical sides at alkali-resisting glass fiber net cloth (9), a serial communication port, two be connected with first side shield (2) and second side shield (3) between the both ends of third side shield (1) respectively, along a plurality of on the horizontal direction rock wool strip (5) run through between and are equipped with a plurality of elasticity parting bead (4), a plurality of the one end welding of elasticity parting bead (4) is at the side of first side shield (2), the side of second side shield (3) has seted up a plurality of jack (7) corresponding with elasticity bead (4) position, jack (7) are cut apart to the jack (6) on the side of second side shield (6) and the jack (6) is passed to the jack (6).

2. The rock wool composite board of the dislocation putting method according to claim 1, wherein limiting plates (8) are connected between the top ends and the bottom ends of the first side baffle plate (2) and the second side baffle plate (3), and the surfaces of the limiting plates (8) are in contact with the surfaces of alkali-resistant glass fiber mesh cloth (9) corresponding to the positions.

3. The rock wool composite board according to the dislocation putting method of claim 1, wherein the second side baffle plate (3) is concave, the first side baffle plate (2) is convex, and the size of the inner cavity of the second side baffle plate (3) is matched with the external size of the first side baffle plate (2).

4. The rock wool composite board of a dislocation laying method as claimed in claim 1, wherein the elastic parting strip (4) is elastic stainless steel.

5. The rock wool composite board of a dislocation laying method according to claim 1, characterized in that the surfaces of the rock wool strips (5) with which the elastic parting strips (4) are in contact are bonded by glue.