JPH03275343A - Connection structure of lithic composite panel - Google Patents

Abstract

PURPOSE:To use a thin lithic material by reinforcing the strength thereof by laminating the lithic material to the upper surface of a reinforcing plate to form a lithic composite panel. CONSTITUTION:A lithic material 2 is laminated to the upper surface of a reinforcing plate 1 so that at least one end part of the lithic material is inwardly shifted from the end edge of the reinforcing plate 1 to form a lithic composite panel 3. Next, an engaging part 4 is provided to the end surface of the reinforcing plate 1 at a position of a predetermined dimension from the upper surface of the lithic material 2 in the thickness direction thereof and the adjacent lithic composite panels 3 are abutted at the mutual end surfaces of the reinforcing plates 1 and the engaging parts 4 of the respective lithic composite panels 3 are mutually engaged.

Description

[Detailed description of the invention] [Industrial application field]

The present invention relates to a connection structure for stone composite boards used as interior and exterior materials such as wall materials, floor materials, and ceiling materials.

[Conventional technology]

Stone materials such as natural stones, tiles, and artificial stones have unique beauty and durability. In order to take advantage of these characteristics, these stone materials are often used as interior and exterior materials such as walls, floors, and ceiling materials of buildings.

[Problem to be solved by the invention]

However, stone materials have disadvantages in terms of strength against impact and the like, so they need to be used in a thickness of about 20 to 50+++ meters, which poses a problem in that they are heavy and difficult to construct. In addition, stone materials have difficulty in machining accuracy and tend to vary in thickness due to α, and when installing multiple stone materials side by side, it is difficult to align the surfaces of each stone material on the same plane, and the surfaces of adjacent stone materials There was also the problem that there was a difference in level between the two. Furthermore, there is also the problem that it is difficult to carry out construction so as to form joints with predetermined designed dimensions between adjacent stone materials. The present invention has been made in view of the above points, and can be formed to be lightweight, and can be connected flush with each other without creating a step on the surface of the stone materials. The object of the present invention is to provide a connection structure for stone composite plates that can form joints according to dimensions.

[! Measures to solve the problem]

The connection structure of the stone composite board according to the present invention is such that the stone material 2 is laminated on the upper surface of the reinforcing board 1 at a position where at least one of the four edges of the stone material 2 is shifted inward from the edge of the reinforcing board 1. A composite plate 3 is formed, and an engaging portion 4 is provided on the end face of the reinforcing plate 1 at a position of a predetermined dimension in the thickness direction from the top surface of the stone material 2, and adjacent stone composite plates 3 are connected between the end faces of the reinforcing plate 1. It is characterized in that the engaging portions 4 of the stone composite plates 3 are butted against each other and engaged with each other.

[For use]

In the present invention, since the stone material 2 is laminated on the upper surface of the reinforcing plate 1 to form the stone composite board 3, the strength of the stone material 2 is reinforced by the reinforcing plate 1, and the thickness of the stone material 2 is increased. You can use a thin one. Furthermore, an engaging portion 4 is provided on the end face of the reinforcing plate 1 at a position of a predetermined dimension in the thickness direction from the upper surface of the stone material 2, and an engaging portion 4 of the adjacent stone composite plate 3 is provided.
In order to engage each other with each other, the dimension in the thickness direction between the surface of the stone material 2 and the engaging part 4 provided on the reinforcing plate 1 is related to the thickness of the stone material 2 in each stone composite board 3. By setting the values to be constant, even if the thickness of the stone materials 2 varies, the surfaces of the stone materials 4 of each stone composite board 3 can be aligned and connected to the same plane. moreover,
The stone material 2 is laminated on the reinforcing plate 1 at a position where at least one edge of the stone material 2 is shifted inward from the edge of the reinforcing plate 1 to form a stone composite board 3, and the adjacent stone composite board 3 is reinforced. Since the end surfaces of the plates 1 are butted against each other, the reinforcing plate 1
A joint can be formed between the edges of the stone materials 2 of adjacent stone composite plates 3 by a predetermined dimension in which the edges of the stone materials 2 are shifted from the edges of the stone materials 2.

【Example】

The present invention will be explained in detail below with reference to Examples. The stone material 2 is made of something that has the appearance of stone, such as natural stone, tile, or artificial stone, and has a thickness of approximately several I. The reinforcing board 1 is made of foamed concrete board, wood chip cement board, MDF (medium density fiberboard), plywood, organic foam board, etc., which has higher strength against impact etc. than the stone material 2, is lighter than the stone material 2, and is easy to cut. A plate that is relatively easy to process is used. By laminating the stone material 2 on the surface of this reinforcing plate 1 with adhesive etc.
It is used as a stone composite board 3, and in order to laminate the stone material 2 on the surface of the reinforcing board 1 in this way, the stone material 2 can be reinforced with the reinforcing board 1, and as described above, the stone material 2
This makes it possible to form the film to a thickness as thin as several tens. FIG. 2 shows an embodiment of the stone composite board 3, in which the reinforcing board 1 and the stone material 2 are both formed into a square (or rectangular) planar shape. Then, on the end faces of two sides adjacent to the reinforcing plate 1, a protruding step part 7 is provided at the lower part thereof, and on the end face of the other two adjacent sides, a four step part 8 is provided at the lower part.
It is recessed. In the embodiment shown in FIG. 2, the protruding part 7 and the concave part 8 form an engaging part 4 for connecting the stone composite board 3, and the thickness direction of the stone composite board 3 is , so that the dimension t from the surface of the stone material 2 to the upper surface of the protruding step 7 and the dimension t2 from the lower surface of the recessed step 8 are approximately the same constant dimensions.
A protruding step portion 7 and a recessed step portion 8 are formed in each stone composite board 3. In practice, t should be slightly larger than t2 (for example, t=141.i=13.
5mm). Even if there are variations in the thickness of the stone material 2, this tl and t2
It is preferable that the engaging portion 4 is formed on the reinforcing plate 1 after the stone material 2 is laminated on the reinforcing plate 1 so that the size is set to a predetermined constant size. In addition, the size of the stone material 2 is formed to be slightly smaller than the reinforcing plate 1, and the edges of two adjacent sides of the stone material 2 are aligned with the edges of the two sides of the reinforcing plate 1 on which the recessed step portion 8 is provided. As a result, the stone material 2 is laminated on the reinforcing plate 1 so that the edges of the other two sides of the stone material 2 are shifted inward from the edges of the two sides of the reinforcing plate 1 on which the protruding portions 7 are provided. Due to this misalignment, a concave step g9 for a joint is formed between the surface of the reinforcing plate 1 and the side end surface of the stone material 2. The width dimension of this recessed step 9 for joints is determined by the width of each stone composite board 3.
It is preferable to set the dimensions to be equal in smell. For example, the stone composite board 3 shown in FIG.
Apply adhesive with a coating amount of w2, overlay stone material 2 made of stone with a thickness of 8 cm, and apply a pressure of 5 kg/c112.
It can be created by attaching the stone material 2 to the reinforcing plate 1 under the condition of a press time of 24 hours, and then cutting the engaging portion 4 to the reinforcing plate 1. When constructing the stone composite board 3 formed as described above as a wall material, floor material, ceiling material, etc., it is necessary to
This can be done by arranging and fixing a plurality of stone composite boards 3 in rows and columns on a mounting base 10 such as a ceiling base. When connecting adjacent stone composite plates 3.3, each reinforcing plate 1 of the stone composite plates 3, 3 is connected as shown in Fig. 1.
, 1 are butted against each other, and the concave step 8 of the other stone composite board 3 is placed over the protruding step 7 of one stone composite board 3 to engage the engaging parts 4, 4 with each other. This can be done by letting In this way, when connecting a plurality of stone composite plates 3, 3,... Since the dimension t2 to the bottom surface of the portion 8 is set to be approximately the same constant dimension, the surfaces of the stone materials 2, 2... of each stone composite board 3, 3... are on the same plane. It will be arranged on top, and the adjacent stone composite board 3,
There is no difference in level between the surfaces of the stone materials 2°2 and 3. In addition, a joint 11 is formed between the end faces of the stone materials 2, 2 of the adjacent stone composite plates 3, 3 by the four-stage joint portion 9, but the adjacent stone composite plates 3, 3 are connected to the reinforcing plates 1, 1. Since the end faces of the joints are butted against each other, the width of the joint 11 is almost the same as the width of the joint recess 9, and the joint 11 can be easily formed with a predetermined designed width. . Mounting base 1
Fixing of each stone composite board 3 to the mounting base 10 can be done by using an adhesive or by driving nails, screws, etc. from the protrusion 7 into the mounting base 10. The protruding portion 7 may be provided with screw holes penetrating both the front and back sides. In addition, in order to prevent the recessed step part 8 from rising up from the protrusion part 7, an adhesive may be applied to both or one side of the upper surface of the protrusion part 7 and the lower surface of the recessed step part 8, or each of these surfaces may be bonded. It is preferable to attach a sheet-like fastening material, commonly called a surface fastener, to the surface of the fastener, or to connect it with metal fittings6.In the embodiment shown in FIG. 8 are provided on each two sides of the stone composite board 3 so that the stone composite board 3 can be connected vertically and horizontally.
They may be provided only on each opposing side. In the embodiment shown in FIG. 2 above, the engaging portion 4 is formed by the protruding step portion 7 and the recessed step portion 8, but in the embodiment shown in FIG. It is designed to be formed with a real concave portion 13. That is, the actual protrusions 12 are provided protrudingly in the upper and lower middle portions of the end faces of the two adjacent sides of the reinforcing plate 1, and the actual protrusions 12 are provided approximately in the same size as the actual protrusions 12 in the approximately middle portions of the other two adjacent sides. A real concave portion 13 is formed, and a real protrusion i! is formed from the surface of the stone material 2 in the thickness direction of the stone composite board 3. The actual protrusion 12 and the actual recess 13 are formed in each stone composite board 3 so that the dimensions 3 up to 1s12 and the dimension t up to the lower surface of the actual recess 13 are approximately the same constant dimensions. That's how it is. The stone composite board 3 formed as shown in FIG. 4 can be connected by inserting and engaging the real protrusion 12 and the real recess 13 as shown in FIG. In this case, since the actual protrusion 12 and the actual recess 13 are inserted and engaged, lifting does not occur, and there is no need to glue the engaging portions as in the case of the embodiment shown in FIG. . The stone composite board 3 can also be fixed to the mounting base 10 by driving nails, screws, etc. into the mounting base 10 through the actual protrusion 12 into the bonding area. In the embodiment shown in FIG. 4, the actual projections 12 and the actual recesses 13 are provided on each two sides of the stone composite board 3 so that the stone composite board 3 can be connected vertically and horizontally. The concave portions 13 may be provided only on each opposing side of the stone composite board 3. FIG. 16 shows still another embodiment of the present invention,
In this case, engagement grooves 14 are provided on each end face of the four sides of the reinforcing plate 1, and the engagement portions 4 are formed by the engagement m14. Each engagement groove 14 on the four sides has a dimension t from the surface of the stone material 2 to the engagement groove 14 in the thickness direction of the stone composite board 3;
Each stone composite board 3 is formed so that it has approximately the same fixed dimensions. $6 For the stone composite board 3 shaped as shown in Figure 5, the connecting plates 15 are inserted and engaged into the respective engagement grooves 14, 14 of the adjacent stone composite boards 3 as shown in Figure 5. Accordingly, connection can be made via the connection plate 15. In this embodiment, since the engagement MS4 can be formed only by groove machining, machining becomes easy. In addition, in the embodiment shown in FIG. 6, the engagement grooves 14 are provided on two sides of the stone composite plate 3 so that the stone composite plates 3 can be connected vertically and horizontally. It is also possible to provide it only on one side of the opposite side.

【Effect of the invention】

As described above, in the present invention, since the stone material is laminated on the upper surface of the reinforcing plate to form a stone composite board, the strength of the stone material can be reinforced by the reinforcing plate, and the thickness of the stone material can be increased. It is possible to use thin materials,
It can be made lightweight. In addition, an engaging part is provided on the end face of the reinforcing plate at a predetermined dimension position in the thickness direction from the top surface of the stone material, so that the engaging parts of adjacent stone composite plates are engaged with each other, so that the surface of the stone material By setting the dimension in the thickness direction between the reinforcing plate and the two engagement parts of each stone composite plate to be constant regardless of the thickness of the stone material, even if there are variations in the thickness of the stone material, , the surfaces of the stone materials of each stone composite board can be aligned and connected to the same plane, and it is possible to prevent a difference in level from occurring between the surfaces of adjacent stone materials. Further, the stone material is laminated on the reinforcing plate at a position where at least one edge of the stone material deviates inward from the edge of the reinforcing plate to form a stone composite plate, and the adjacent stone composite plate is stacked on the edge of the reinforcing plate. Since they are butted against each other, a joint can be formed at the #I edge of the stone material of the adjacent stone composite board at a predetermined dimension where the edge of the stone material is shifted from the edge of the reinforcing board. This makes it possible to easily form joints with predetermined designed dimensions.

[Brief explanation of drawings]

Figure 1 is a sectional view of one embodiment of the present invention, Figures 2 (a) and (b)
) (c) is a plan view, a cross-sectional view along the E-I line, and a cross-sectional view along the Ro-Ro line of the stone composite board used in the above, FIG. 3 is a cross-sectional view of another embodiment of the same, and FIGS. c) is a plan view, a Haber line sectional view, a Uni line sectional view, and the fifth
The figure is a sectional view of still another embodiment same as above, and FIG. 6(a) (
b) and (c) are a plan view, a cross-sectional view taken along the Hoch line, and a cross-sectional view taken along the Hoh line. 1 is a reinforcing plate, 2 is a stone material, 3 is a stone composite board, and 4 is an engaging portion. 1st m1 1... Reinforcement plate 2 - 5th grade material 3... Stone composite board 4 - Engagement part

Claims (1)

[Claims] (1) A stone composite board is formed by laminating a stone material on the top surface of the reinforcing plate at a position where at least one edge of the stone material is shifted inward from the edge of the reinforcing plate. Engaging parts are provided on the end faces of the reinforcing plates at predetermined dimensional positions, and adjacent stone composite plates are butted against each other with their end faces, and the engaging parts of each stone composite plate are engaged with each other. A connection structure of stone composite plates characterized by: