CN216787700U - Lightweight enhanced composite board - Google Patents

Abstract

The utility model discloses a lightweight enhanced composite board, which comprises a steel bar frame and an opening, wherein an A phenolic foam board and a B phenolic foam board are respectively arranged on two sides of the steel bar frame, an A polystyrene foam board and a B polystyrene foam board are respectively arranged on one side of the A phenolic foam board and one side of the B phenolic foam board, and a plurality of groups of longitudinal grooves are respectively formed between one side of the A polystyrene foam board and one side of the B polystyrene foam board and the A phenolic foam board and between the one side of the B polystyrene foam board and the B phenolic foam board. The utility model increases the firmness effect of the composite board to the maximum extent through the reinforcing steel frame and the light Portland cement layer A, the light Portland cement layer B, the wear-resistant metal plate layer and the compression-resistant metal plate layer which are respectively arranged at the two ends of the reinforcing steel frame, ensures the stability of the composite board in the using process, increases the fireproof heat-insulating effect of the composite board through the phenolic aldehyde foam plate A and the phenolic aldehyde foam plate B, improves the protective effect of the composite board, and embodies the quality enhancement effect of the composite board.

Description

Lightweight enhanced composite board

Technical Field

The utility model relates to the technical field of composite boards, in particular to a lightweight enhanced composite board.

Background

The composite board refers to a board made of a combination of two or more materials. In fact, the concept and manufacturing method of the composite board are different for boards of different materials. In daily life, metal composite plates, wood-plastic composite plates and glass fiber reinforced plastic composite plates are mainly used. With the development of the building and decoration industry, indoor decoration materials are developing towards three aspects of light weight, environmental protection and energy conservation.

The existing composite board cannot ensure the stability of the composite board under the condition of light weight, the firmness effect of the composite board in use is influenced, the protection effect of the composite board is reduced, and the use of the composite board is influenced; meanwhile, various materials in the composite board are adhered through resin, and the materials cannot be adhered in all directions by the resin, so that the composite board is easy to fall off.

SUMMERY OF THE UTILITY MODEL

The utility model provides a lightweight enhanced composite board, which solves the problems that the stability of the composite board cannot be ensured under the condition of lightweight of the existing composite board, the firmness effect of the composite board in use is influenced, the protection effect of the composite board is reduced, and the use of the composite board is influenced; meanwhile, various materials in the composite board are adhered through resin, and the materials cannot be adhered in all directions by the resin, so that the composite board is easy to fall off.

In order to achieve the purpose, the utility model adopts the following technical scheme: the utility model provides a lightweight enhancement mode composite board, includes steel bar frame and opening, the opening is the multiunit array and sets up on the steel bar frame, A phenolic foam board and B phenolic foam board are installed respectively to the steel bar frame both sides, multiunit resin circulation hole has all been seted up on A phenolic foam board and the B phenolic foam board, A polystyrene foam board and B polystyrene foam board are installed respectively to A phenolic foam board and B phenolic foam board one side, A polystyrene foam board and B polystyrene foam board one side respectively with A phenolic foam board and B phenolic foam board between seted up the vertical recess of multiunit, horizontal recess has all been seted up to vertical recess top and bottom.

Preferably, the through openings and the resin flow holes are square, and the thickness of the A polystyrene foam plate and the B polystyrene foam plate is larger than that of the A phenolic foam plate and the B phenolic foam plate.

Preferably, the cross sections of the transverse grooves and the longitudinal grooves are semicircular, and the cross section of the reinforcing steel bar frame is circular.

Preferably, one side of the polystyrene foam board A and one side of the polystyrene foam board B are respectively provided with a light Portland cement layer A and a light Portland cement layer B.

Preferably, one side of the A light Portland cement layer and one side of the B light Portland cement layer are respectively provided with a wear-resistant metal plate layer and a compression-resistant metal plate layer.

Preferably, the thickness of the A light Portland cement layer and the thickness of the B light Portland cement layer are both larger than that of the wear-resistant metal plate layer and the compression-resistant metal plate layer and are the same as those of the A phenolic foam plate and the B phenolic foam plate.

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

1. through the reinforcing bar frame with the A light portland cement layer, the B light portland cement layer, wear-resisting sheet metal layer and the firm effect of resistance to compression sheet metal layer furthest increase this composite board that its both ends were installed respectively, guarantee its stability in the use, increase this composite board's fire prevention heat preservation effect through A phenolic foam board and B phenolic foam board, promote this composite board's protective effect, embody this composite board's quality reinforcing effect.

2. Through the multiunit resin circulation hole that all seted up on A phenolic foam board and the B phenolic foam board, the vertical recess of multiunit and the horizontal recess that cooperation A polystyrene foam board and B polystyrene foam board one side were seted up increases the storage capacity of resin to guarantee the firm effect of adhesion between each panel.

Drawings

Fig. 1 is a schematic perspective view of a lightweight reinforced composite board according to the present invention;

FIG. 2 is a schematic view of an installation three-dimensional structure of a lightweight reinforced composite board according to the present invention;

FIG. 3 is a schematic cross-sectional installation perspective view of a lightweight reinforced composite board according to the present invention;

fig. 4 is an enlarged perspective view of the styrofoam plate of fig. 1.

In the figure: 100. a wear-resistant metal plate layer; 101. a light Portland cement layer; 102. a polystyrene foam board; 103. a transverse groove; 104. a longitudinal groove; 105. a phenolic foam board; 106. a resin flow hole; 107. a reinforcing steel bar frame; 108. a port; 109. b, polystyrene foam board; 110. b a light Portland cement layer; 111. a compression-resistant metal plate layer; 112. and B, phenolic foam board.

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.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1 to 4, a lightweight reinforced composite board includes a steel bar frame 107 and through holes 108, the through holes 108 are arranged on the steel bar frame 107 in a plurality of sets of arrays, the cross section of the steel bar frame 107 is circular, an a-phenolic foam board 105 and a B-phenolic foam board 112 are respectively arranged on two sides of the steel bar frame 107, a plurality of sets of resin flow holes 106 are respectively arranged on the a-phenolic foam board 105 and the B-phenolic foam board 112, the through holes 108 and the resin flow holes 106 are both square, an a-polystyrene foam board 102 and a B-polystyrene foam board 109 are respectively arranged on one side of the a-phenolic foam board 105 and one side of the B-phenolic foam board 112, the a-polystyrene foam board 102 and the B-polystyrene foam board 109 are thicker than the a-phenolic foam board 105 and the B-phenolic foam board 112, a plurality of longitudinal grooves 104 are respectively arranged between one side of the a-polystyrene foam board 102 and one side of the B-phenolic foam board 109 and the a-phenolic foam board 105 and the B-phenolic foam board 112, the top and the bottom of the longitudinal groove 104 are both provided with a transverse groove 103, the cross sections of the transverse groove 103 and the longitudinal groove 104 are both semicircular, and the storage capacity of resin is increased by matching a plurality of groups of longitudinal grooves 104 and transverse grooves 103 which are arranged on one sides of the A polystyrene foam board 102 and the B polystyrene foam board 109 through a plurality of groups of resin circulation holes 106 which are arranged on the A phenolic foam board 105 and the B phenolic foam board 112, so that the stable effect of adhesion among all the plates is ensured;

the A lightweight Portland cement layer 101 and the B lightweight Portland cement layer 110 are respectively arranged on one side of the A polystyrene foam board 102 and one side of the B polystyrene foam board 109, the wear-resistant metal plate layer 100 and the compression-resistant metal plate layer 111 are respectively arranged on one side of the A lightweight Portland cement layer 101 and one side of the B lightweight Portland cement layer 110, the thicknesses of the A lightweight Portland cement layer 101 and the B lightweight Portland cement layer 110 are both larger than those of the wear-resistant metal plate layer 100 and the compression-resistant metal plate layer 111 and are the same as those of the A phenolic foam board 105 and the B phenolic foam board 112, the reinforcing frame 107 and the A lightweight Portland cement layer 101, the B lightweight Portland cement layer 110, the wear-resistant metal plate layer 100 and the compression-resistant metal plate layer 111 which are respectively arranged at the two ends of the reinforcing frame increase the firm effect of the composite board to the maximum extent, ensure the stability of the composite board in the use process, and the fireproof and heat preservation effects of the composite board are increased by the A phenolic foam board 105 and the B phenolic foam board 112, the protection effect of the composite board is improved, and the quality enhancement effect of the composite board is reflected.

When the composite board is used, the reinforcing frame 107 and the wear-resistant metal plate layers 100, the compression-resistant metal plate layers 111, the light Portland cement layers 101 and the light Portland cement layers 110 on two sides of the composite board are arranged in the composite board, so that the double-sided density and the supporting strength of the composite board are increased, the stable effect of the composite board in the using process is ensured, meanwhile, the fireproof and heat-insulating effects of the composite board are increased through the phenolic aldehyde foam plates 105 and 112, and finally, through the through holes 108 in the reinforcing frame 107, the phenolic aldehyde foam plates 105 and the phenolic aldehyde foam plates 112, a plurality of groups of resin through holes 106 are formed, so that the bonding stability among materials in the composite board is facilitated through resin.

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 (6)

1. A lightweight reinforced composite board comprises a reinforcing steel bar frame (107) and through holes (108), characterized in that the through holes (108) are arranged on the reinforcing steel bar frame (107) in a plurality of groups of arrays, a phenolic aldehyde foam plate (105) and a B phenolic aldehyde foam plate (112) are respectively arranged on two sides of the steel bar frame (107), a plurality of groups of resin circulation holes (106) are arranged on the phenolic aldehyde foam plate A (105) and the phenolic aldehyde foam plate B (112), one side of the A phenolic foam board (105) and one side of the B phenolic foam board (112) are respectively provided with an A polystyrene foam board (102) and a B polystyrene foam board (109), a plurality of groups of longitudinal grooves (104) are respectively arranged between one side of the polystyrene foam board A (102) and one side of the polystyrene foam board B (109) and the phenolic aldehyde foam board A (105) and the phenolic aldehyde foam board B (112), the top and the bottom of the longitudinal groove (104) are both provided with a transverse groove (103).

2. The reinforced lightweight composite board according to claim 1, wherein the through openings (108) and the resin flow holes (106) are square in shape, and the a-polystyrene foam boards (102) and the B-polystyrene foam boards (109) have a thickness greater than the a-phenol formaldehyde foam boards (105) and the B-phenol formaldehyde foam boards (112).

3. The reinforced lightweight composite board as claimed in claim 1, wherein the cross-sections of the transverse grooves (103) and the longitudinal grooves (104) are semicircular, and the cross-section of the reinforcing steel bar frame (107) is circular.

4. The reinforced lightweight composite board as recited in claim 1, wherein a layer of light portland cement (101) and a layer of light portland cement (110) are respectively mounted on one side of the a polystyrene foam board (102) and one side of the B polystyrene foam board (109).

5. The reinforced lightweight composite board as recited in claim 4, wherein the wear-resistant metal plate layer (100) and the pressure-resistant metal plate layer (111) are respectively mounted on one sides of the A lightweight Portland cement layer (101) and the B lightweight Portland cement layer (110).

6. The reinforced lightweight composite board according to claim 5, wherein the A lightweight Portland cement layer (101) and the B lightweight Portland cement layer (110) are thicker than the wear-resistant metal slab layer (100) and the pressure-resistant metal slab layer (111) and have the same thickness as the A phenolic foam board (105) and the B phenolic foam board (112).

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