TWM520987U - Structure of force magnifying plate - Google Patents

Description

Double force plate structure

This creation belongs to a type of force plate, especially a structure that increases the structural strength and reduces the complexity and cost of the process.

The conventional Bally sheet is made of wood or metal in its production, and its heavy weight makes it difficult for people to move and transport, which leads to an increase in time, labor and cost of the overall operation.

In order to solve the above-mentioned deficiency, a honeycomb core type composite board 1 is proposed, as shown in Fig. 1, which comprises two composite sheets 10, and a honeycomb core 11 between each of the composite sheets 10, through The arrangement of the honeycomb core 11 can reduce the overall weight of the honeycomb core-type composite sheet 1, so that the personnel can easily carry the transportation, thereby improving the time and cost of the step by one step.

However, the honeycomb core 11 is not easily unfolded during the process, and is not easily bonded to each of the composite sheets 10, thereby increasing the difficulty in fabricating the honeycomb core-type composite sheet 1. In addition, the side core resistance of the honeycomb core 11 is not sufficient. When the honeycomb core-type composite sheet 1 is subjected to extrusion bending, the honeycomb core 11 is easily deformed and damaged. Therefore, the conventional cardboard structure has the necessity of improvement.

The purpose of this creation is to propose a force plate structure having a wave layer disposed inside another wave layer to increase structural strength and reduce process complexity and cost.

According to the foregoing object, the present invention proposes a force plate structure comprising at least one force structure, at least one plate disposed on one side of the force structure, and at least one disposed between the plate and the force structure. Paper layer. The force structure includes a first wave layer having at least one second wave layer located inside the first wave layer.

Further, the wave spacing of the first wave layer is reduced; or the wave spacing of the second wave layer is reduced.

Further, the first wave layer and the second wave layer are staggered.

Further, the multiple force structure is set to a complex number, and each of the multiple force structures is sequentially pushed and connected.

Further, each of the multiple force structures is staggered.

Further, the first wave layer is set as corrugated paper; or the second wave layer is set as corrugated paper.

Further, the paper layer is set as a kraft paper layer.

Further, the gap between the paper layer and the first wave layer is filled with a fireproof foam or a heat resistant material or an anti-burning agent.

Further, the gap between the first wave layer and the second wave layer is filled with a fireproof foam or a heat resistant material or an anti-burning agent.

Further, the sheet is set to be a wood or metal sheet or a cardboard or plastic sheet or a dense board or a fiberglass board or an asbestos board.

The characteristics of this creation are:

1. The present invention increases the structural strength of the interior of the first wave layer through a multiple force structure formed by the second wave layer in the first wave layer, thereby improving the overall joint strength of the force plate structure.

2. The creation can increase the contact area of the first wave layer with the paper layer by reducing the wave spacing of the first wave layer, thereby improving the joint strength of the force plate structure.

3. The creation can also increase the contact area between the second wave layer and the first wave layer by reducing the wave spacing of the second wave layer, thereby improving the joint strength of the force plate structure.

4. When the multiple force structure is set to a plurality of numbers, each of the multiple force structures may be further staggered to further improve the joint strength of the force plate structure.

5. The first wave layer and the second wave layer are all made of corrugated paper, and the light weight can reduce the overall weight of the double force plate structure, thereby facilitating the transportation of personnel, thereby reducing the time and cost of the overall operation. Cost.

6. The first wave layer and the second wave layer have a simple structure and can be changed or expanded according to different requirements, so that the structure of the force plate is light and flexible, and is suitable for different needs.

In the following, together with the attached drawings, it is more convenient to understand how the structure of the creation is combined and used. It is easier to understand the purpose, technical content, characteristics and effects of the creation.

Referring to FIG. 2 to FIG. 3-2, a force plate structure 2 according to the present invention includes at least one force structure 20 and at least one plate 21 disposed on one side of the force structure 20. And at least one paper layer 22 disposed between the sheet 21 and the force structure 20. The dynamite structure 20 includes a first undulating layer 200 having at least one second undulating layer 201 located inside the first undulating layer 200. In the embodiment of the present invention, the second wave layer 201 in the first wave layer 200 is set as a layer, but is not limited thereto.

Further, the sheet 21 is set as a wood board or a cardboard or plastic board or a dense board or a fiberglass board or an asbestos board or a metal board such as iron or a metal board such as aluminum. Wherein, the connection end between the plate 21 and the paper layer 22 can be adhered and fixed by glue or adhesive, and the connection between the paper layer 22 and the first wave layer 200 can be glued in application. Or the adhesive manner is fixed, and the connecting end of the first wave layer 200 and the second wave layer 201 can be adhered and fixed by glue or adhesive in application, but not limited thereto. In addition, the paper layer 22 can be applied to a kraft paper layer or a corrugated paper layer. In the embodiment of the present invention, the paper layer 22 is exemplified by a kraft paper layer, but is not intended to limit the creation.

In order to solve the problem of low connection strength of the prior art structure, the present invention can increase the structural strength of the interior of the first wave layer 200 through the multiple force structure 20 formed by the second wave layer 201 in the first wave layer 200. Further, the overall joint strength of the force plate structure 2 is improved.

Further, the practical work can reduce the wave pitch of the first wave layer 200 to increase the contact area of the first wave layer 200 with the paper layer 22, thereby improving the joint strength of the force plate structure 2. It is even possible to reduce the contact area of the second wave layer 201 with the first wave layer 200 by reducing the wave pitch of the second wave layer 201, thereby improving the joint strength of the force plate structure 2. More specifically, when the wave spacing is reduced, the wave is tighter, so that the contact area of the first wave layer 200 with the plate 21 is increased, and the contact area of the second wave layer 201 with the first wave layer 200 is increased. Thereby, the overall joint strength of the force plate structure 2 can be improved. In addition, in the actual operation, the first wave layer 200 and the second wave layer 201 can also be implemented by a square wave layer or a triangular wave layer or a trapezoidal wave layer, respectively. In the embodiment of the present invention, a trapezoidal wave layer is used as an example. , but not for limiting this creation.

Further, the gap between the wave between the waves of the second wave layer 201 and the wave of the first wave layer 200 can be disposed in the same direction or in different directions, and in a preferred embodiment, the gaps are arranged in different directions. In this way, the joint strength of the force plate structure 2 is further enhanced.

Referring to FIG. 4, the present invention can further add a sheet 21 positioned on the side of the urging structure 20 away from the paper layer 22 in the structure shown in FIG. 3-1, which can be used not only In order to protect the multiple force structure 20, it is less susceptible to wear and reduce the service life, and the joint strength of the overall force plate structure 2 can also be improved.

Referring to FIG. 5, the urging structure 20, the plate 21 and the paper layer 22 are both set to two, and each of the urging structures 20 is sequentially pushed and connected, and each of the paper layers 22 is separately positioned. On the outside of the multiple force structures 20, each of the sheets 21 is located outside the paper layers 22 to form another state of the force plate structure 2. Wherein, in the structure shown in FIG. 5, each of the multiple force structures 20 is directly connected in series, and can also be sequentially connected in an indirect manner as shown in FIG. 6, in an indirect manner. An abutment layer 23 is joined between each of the multiple force structures 20 to form another type of the force plate structure 2, wherein the abutment layer 23 can be applied to a corrugated cardboard or a kraft layer or a wood layer. And the connection end between each of the multiple force structure 20 and the abutting layer 23 can be fixedly fixed by glue or adhesive. The push-and-join connection method shown in Fig. 5 and Fig. 6 is not intended to limit the present creation, and even the multiple force structure 20 may be set to a three-layer or four-layer or five-layer multi-layer structure.

When the multiple force structure 20 is set to a complex number, each of the multiple force structures 20 may be alternately stacked to increase the joint strength of the force plate structure 2, as shown in FIGS. 7-1 and 7-2. Show. More specifically, the method of staggering the creation of the present invention, in the process, one of the multiple force structures 20 and the abutting layer 23 are connected to form a plurality of first channels 202, and the other of the multiple force structures 20 abuts The layer 23 forms a plurality of second channels 203 when connected, and each of the first channels 202 is interleaved with each of the second channels 203. Each of the first channels 202 and each of the second channels 203 can be disposed in an obliquely staggered or vertically staggered manner in actual operation. In the embodiment of the present invention, each of the first channels 202 is vertically interlaced. The second channel 203 is exemplified, but is not intended to limit the creation.

The first wave layer 200 and the second wave layer 201 can be made of corrugated paper. The light weight of the corrugated paper can reduce the overall weight of the force plate structure 2, thereby facilitating the transportation and transportation of the personnel, thereby reducing the overall operation. Time and cost. In addition, the first wave layer 200 and the second wave layer 201 are simple in structure, and can be changed or expanded according to different requirements, so that the double-plate structure 2 is light and flexible, and is suitable for different needs.

Further, in actual operation, the gap between each of the paper layers 22 and the first wave layer 200 is filled with a fireproof foam or a heat resistant material or an anti-burning agent, or the first wave layer 200 and the second The gap between the wave layers 201 is filled with a fireproof foam or a heat resistant material or an anti-burning agent, thereby increasing the heat resistance of the double force plate structure 2.

In summary, the present invention increases the structural strength of the first wave layer 200 through a multiple force structure formed by the second wave layer 201 in the first wave layer 200, thereby improving the structure of the force plate 2 The overall strength of the connection. Moreover, the present invention can increase the contact area of the first wave layer 200 and the paper layer 22 by reducing the wave pitch of the first wave layer 200, thereby improving the joint strength of the force plate structure 2. Moreover, the present invention can also increase the contact area between the second wave layer 201 and the first wave layer 200 by reducing the wave pitch of the second wave layer 201, thereby improving the joint strength of the force plate structure 2. In addition, when the multiple force structure 20 is set to a plurality of numbers, each of the multiple force structures 20 may be further staggered to further improve the joint strength of the force plate structure 2 . Furthermore, the first wave layer 200 and the second wave layer 201 are all made of corrugated paper, and the light weight thereof can reduce the overall weight of the force plate structure 2, thereby facilitating the transportation and transportation of the personnel, thereby reducing the overall operation. Time and cost. In addition, the first wave layer 200 and the second wave layer 201 have a simple structure and can be changed or expanded according to different requirements, so that the double-plate structure 2 is light and flexible, and is suitable for different needs.

The foregoing is only a preferred embodiment of the present invention, and its purpose is to enable the skilled person to understand the content of the present invention and implement it, and is not intended to limit the scope of the present invention; Equivalent variations or modifications of the shapes, configurations, and features described herein are intended to be included within the scope of the present application.

[study]
1‧‧‧ Honeycomb paper core composite sheet
10‧‧‧Composite sheet
11‧‧‧Hive core (this creation)
2‧‧‧倍力板结构
20‧‧‧ 倍力结构
200‧‧‧First wave layer
201‧‧‧Second wave layer
202‧‧‧First Passage
203‧‧‧second channel
21‧‧‧ plates
22‧‧‧paper layer
23‧‧‧Affirmation

Figure 1: A three-dimensional combination of conventional honeycomb core-type composite sheets. Fig. 2 is an exploded perspective view showing the first embodiment of the present invention. Fig. 3-1 is a perspective assembled view of the first embodiment of the present invention. Fig. 3-2: is a partial enlarged view of Fig. 3-1. Fig. 4 is a perspective assembled view of the second embodiment of the present invention. Fig. 5 is a perspective assembled view of the third embodiment of the present invention. Fig. 6 is a perspective assembled view of the fourth embodiment of the present invention. Figure 7-1 is a perspective assembled view of the fifth embodiment of the present invention. Fig. 7-2: is a partial enlarged view of Fig. 7-1.

2‧‧‧倍力板结构

20‧‧‧ 倍力结构

21‧‧‧ plates

22‧‧‧ cardboard

Claims (10)

A force plate structure comprising: at least a multiple force structure, the multiple force structure comprising a first wave layer, the first wave layer having at least one second wave layer inside the first wave layer; at least one a sheet material disposed on one side of the force-receiving structure; and at least one paper layer disposed between the sheet material and the force-relief structure. The force plate structure according to claim 1, wherein the wave spacing of the first wave layer is reduced; or the wave spacing of the second wave layer is reduced. The force plate structure according to claim 1, wherein the first wave layer and the second wave layer are alternately disposed. The double force plate structure according to claim 1, wherein the multiple force structure is set to a plurality, and each of the multiple force structures is sequentially pushed and connected. The double force plate structure according to claim 4, wherein each of the multiple force structures is staggered. The force plate structure according to any one of claims 1 to 5, wherein the first wave layer is made of corrugated paper; or the second wave layer is made of corrugated paper. The force plate structure according to any one of claims 1 to 5, wherein the paper layer is a kraft paper layer. The force plate structure according to claim 1, wherein the gap between the paper layer and the first wave layer is filled with a fireproof foam or a heat resistant material or an anti-burning agent. The force plate structure according to claim 1 or 8, wherein the gap between the first wave layer and the second wave layer is filled with a fireproof foam or a heat resistant material or an anti-burning agent. The double-ply structure as described in claim 1, wherein the plate is set to be a wood or metal plate or a cardboard or plastic plate or a dense board or a fiberglass board or an asbestos board.