CN220539091U - Connection structure of ultra-thin stone and building facade - Google Patents

Abstract

The utility model relates to a connection structure of ultra-thin stone material and outer facade of building relates to the field of construction structure, including fossil fragments and stone slab, fossil fragments include a plurality of connecting pieces and a plurality of horizontal cardboard, and the connecting piece is fixed on outer wall, and horizontal cardboard level is fixed on the connecting piece, and a horizontal cardboard is connected with a plurality of connecting pieces, is connected with fastener one on the horizontal cardboard, and stone slab sets up between two adjacent horizontal cardboard, has seted up the chute on the stone slab surface, and stone slab passes through chute and fastener butt. The method has the effect of reducing the installation cost of the thinner stone.

Description

Connection structure of ultra-thin stone and building facade

Technical Field

The application relates to the field of building construction structures, in particular to a connecting structure of ultrathin stone and an outer vertical surface of a building.

Background

In the field of building construction, when building main body is built, stone plates are required to be installed on the outer vertical face of a building, so that the attractive effect is achieved.

Related stone installation structure of building facade generally uses dry-hanging stone material technology, and constructor processes the recess at stone material middle part at first, then installs the connecting piece on the building outer wall, installs the stone material between two adjacent connecting pieces again, makes the connecting piece joint in the recess of stone material, reaches the effect of fixing the stone material on the outer wall.

The related technical proposal has the defects that when the thickness of the stone plate is smaller, the stone is easy to break by processing the groove on the stone, and the stone installation cost is higher.

Disclosure of Invention

In order to reduce the installation cost of thinner stone, the application provides a connection structure of ultrathin stone and building facade.

The application provides a connection structure of ultra-thin stone material and building facade adopts following technical scheme:

the utility model provides a connection structure of ultra-thin stone material and outer facade of building, includes fossil fragments and stone slab, and fossil fragments include a plurality of connecting pieces and a plurality of horizontal cardboard, and the connecting piece is fixed on outer wall, and horizontal cardboard level is fixed on the connecting piece, and a horizontal cardboard is connected with a plurality of connecting pieces, is connected with fastener one on the horizontal cardboard, and stone slab sets up between two adjacent horizontal cardboard, has seted up the chute on the stone slab surface, and stone slab passes through chute and a fastener butt.

Through adopting above-mentioned technical scheme, through installing the connecting piece on the building outer wall, make horizontal cardboard can pass through the connecting piece level to be fixed on the outer wall, a plurality of horizontal cardboard are along vertical direction equidistance interval setting, constructor is through setting up the slabstone between two adjacent horizontal cardboard, can make slabstone joint on the outer wall, form the chute through grinding on the slabstone, make the chute can the butt on fastener one, and then make slabstone and horizontal cardboard joint, the in-process of processing slabstone reduces the step of fluting or drilling, make the success rate of processing slabstone higher, can reduce the installation cost of thinner stone.

Optionally, a cross section of the clamping piece is in an isosceles triangle shape.

Through adopting above-mentioned technical scheme, through making the cross street face of fastener one set to isosceles triangle, make the chute of stone panel can block between two cross clamping boards and respectively with upside and downside butt of fastener one, can make things convenient for the user to install stone panel.

Optionally, the connecting piece includes horizontal part and vertical portion, and the connecting piece is sheet metal bending type and forms, and horizontal part and vertical portion are perpendicular, and vertical portion passes through bolt fastening on the outer wall, and horizontal part passes through bolt fastening with horizontal cardboard.

Through adopting above-mentioned technical scheme, through buckling the connecting piece and forming horizontal portion and vertical portion, make horizontal portion and horizontal cardboard be connected, make vertical portion and outer wall connection, and then make horizontal cardboard can fix on the outer wall.

Optionally, be connected with on the horizontal cardboard and erect the cardboard, erect cardboard and horizontal cardboard vertically, stone slab joint is between two adjacent erects the cardboard.

Through adopting above-mentioned technical scheme, through setting up a plurality of perpendicular cardboard on horizontal cardboard, make perpendicular cardboard along the length direction equidistance interval setting of horizontal cardboard, and then make perpendicular cardboard can block in the both sides of stone slab, promote the connection stability of stone slab and outer wall, can reduce the probability that stone slab slided on horizontal cardboard.

Optionally, a second clamping piece is arranged on the vertical clamping plate and is abutted to the chute of the stone slab.

Through adopting above-mentioned technical scheme, through setting up fastener two on erecting the cardboard, all offer the chute on the four sides of stone slab, make the chute can block on fastener one and fastener two to further promote the connection stability of stone slab and outer wall.

Optionally, the stone slab is set to square plate, and the cross section of fastener one is the same with fastener two.

Through adopting above-mentioned technical scheme, through setting up the stone slab into square plate, make stone slab can install between horizontal cardboard and perpendicular cardboard with arbitrary direction, rotate the step of stone slab when reducing the high altitude construction of user, facilitate the use.

Optionally, the vertical cardboard tip is provided with the butt board, and the butt board passes through bolt fixed connection on horizontal cardboard.

Through adopting above-mentioned technical scheme, through setting up the butt board on erecting the cardboard, make butt board card between two adjacent horizontal cardboard to make erect the cardboard and play the effect of supporting and connecting horizontal cardboard, can promote the structural stability of horizontal cardboard.

Optionally, the vertical clamping plate is provided with a glue layer, and the glue layer is used for bonding the vertical clamping plate and the stone slab.

Through adopting above-mentioned technical scheme, through setting up the glue film on erecting the cardboard, make perpendicular cardboard and stone slab can bond each other, and then promote the connection inseparable degree of stone slab and fossil fragments.

In summary, the beneficial technical effects of the application are:

1. through setting up fastener one on the horizontal cardboard, set up the chute on the slabstone, make the chute form through abrasive machining, the user can install the slabstone between two adjacent horizontal cardboard, make chute and fastener one butt, and then make the slabstone fix on the outer wall, remove from the operation of slotting or drilling on the slabstone lateral wall, the success rate of processing the chute on the slabstone is higher, can reduce the cost of installing the slabstone;

2. through setting up the vertical cardboard between the horizontal cardboard, set up the fastener two on the vertical cardboard, make fastener two and fastener one can enclose in the stone slab outside and block the stone slab, thus promote the connection stability of stone slab on fossil fragments;

3. through setting up the stone slab into square plate, make stone slab can install between horizontal cardboard with arbitrary direction, rotate the operation of stone slab when reducing constructor overhead working, facilitate the use.

Drawings

Fig. 1 is a schematic overall structure of an embodiment of the present application.

Fig. 2 is a schematic view of the mounting structure of the transverse clamping plate according to the embodiment of the application.

Fig. 3 is a schematic diagram of a connection structure of a vertical clamping plate and a horizontal clamping plate according to an embodiment of the present application.

Reference numerals: 1. a keel; 11. a connecting piece; 111. a horizontal portion; 112. a vertical portion; 12. a transverse clamping plate; 121. the clamping piece I; 13. a vertical clamping plate; 131. an abutting plate; 132. the second clamping piece is provided with a second clamping piece; 2. a stone slab; 21. and a chute.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings.

The embodiment of the application discloses connection structure of ultra-thin stone material and building facade, refer to fig. 1 and 2, including fossil fragments 1 and stone slab 2, fossil fragments 1 include a plurality of connecting pieces 11 and a plurality of horizontal cardboard 12, and connecting piece 11 is fixed on the outer wall, and horizontal cardboard 12 level is fixed on connecting piece 11, and a plurality of horizontal cardboard 12 are along vertical direction equidistance interval arrangement, stone slab 2 and building outer wall parallel arrangement, a plurality of stone slab 2 arrangement joint is between horizontal cardboard 12.

Referring to fig. 1 and 2, the connection member 11 includes a horizontal portion 111 and a vertical portion 112, the connection member 11 is formed by bending a metal plate, the horizontal portion 111 is perpendicular to the vertical portion 112, the vertical portion 112 is fixed on an outer wall by bolts, the plurality of connection members 11 are arranged at equal intervals in a horizontal direction, and one transverse clamping plate 12 is fixedly connected with the horizontal portions 111 of the plurality of connection members 11.

Referring to fig. 1 and 2, the transverse clamping plate 12 is fixed on the connecting piece 11 through a bolt, the transverse clamping plate 12 is connected with a clamping piece one 121, the transverse clamping plate 12 is parallel to the length direction of the clamping piece one 121, the clamping piece one 121 is located on one side, far away from the outer wall, of the transverse clamping plate 12, and the cross section of the clamping piece one 121 is in an isosceles triangle shape. The stone slab 2 is a rectangular slab, inclined grooves 21 are formed in two opposite sides of the surface of the stone slab 2, and the inclined grooves 21 are located on the surface of one side, far away from the outer wall, of the stone slab 2. By respectively abutting the chute 21 on the transverse clamping plates 12 on the upper side and the lower side of the stone slab 2, a user can make the clamping member one 121 abut against the chute 21, and further the effect of clamping the stone slab 2 on the outer wall is achieved. By grinding the chute 21 on the stone slab 2, the success rate of processing the thinner stone slab 2 is higher, the probability of cracking the stone slab 2 is reduced, and the processing cost can be reduced.

Referring to fig. 2 and 3, a vertical clamping plate 13 is arranged between two horizontal clamping plates 12, the vertical clamping plate 13 is of a rectangular plate structure, abutting plates 131 are connected to two ends of the vertical clamping plate 13, the abutting plates 131 are perpendicular to the vertical clamping plates 13, the abutting plates 131 abut against the horizontal clamping plates 12 and are connected through bolts, a user can fix the vertical clamping plates 13 between the two horizontal clamping plates 12 through the abutting plates 131, and when the vertical clamping plates 13 are installed between the horizontal clamping plates 12, the length direction of the vertical clamping plates 13 is perpendicular to the length direction of the horizontal clamping plates 12. The vertical clamping plates 13 are installed at both sides of the stone slab 2, thereby playing the role of supporting and fixing the stone slab 2.

Referring to fig. 3, a second clamping member 132 is disposed on the vertical clamping plate 13, and the vertical clamping plate 13 is parallel to the length direction of the second clamping member 132. The length of the second clamping piece 132 is smaller than that of the vertical clamping plates 13, and the second clamping piece 132 is positioned between the vertical clamping plates 13. The second clamping piece 132 is arranged on the surface of one side, far away from the outer wall, of the vertical clamping plate 13, and the cross section of the second clamping piece 132 is in the shape of an isosceles triangle. Chute 21 are all offered at stone slab 2 surface edge, and stone slab 2 passes through chute 21 and fastener two 132 butt. The stone slab 2 can be fixed on the outer wall through the horizontal clamping plates 12 and the vertical clamping plates 13, and the connection fastening degree of the stone slab 2 is improved.

Referring to fig. 2 and 3, the vertical clamping plates 13 are provided with glue layers, a user can apply an adhesive to the vertical clamping plates 13, then install the stone slab 2 between the horizontal clamping plates 12 and abut against one side of the second clamping member 132, at this time, the stone slab 2 abuts against the vertical clamping plates 13, and the adhesive can promote the connection firmness degree of the stone slab 2 between the vertical clamping plates 13.

The implementation principle of the embodiment of the application is as follows: through setting up connecting piece 11 on the outer wall, make horizontal cardboard 12 pass through connecting piece 11 and install on the outer wall, the use personnel can install stone slab 2 between two upper and lower horizontal cardboard 12, make chute 21 and the fastener 121 butt on stone slab 2 surface, and then reach the effect of installing thinner stone slab 2 on the outer wall, through setting up perpendicular cardboard 13 between horizontal cardboard 12, make perpendicular cardboard 13 play the effect of blocking stone slab 2, further promote stone slab 2 and outer wall connection's firm degree.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. The utility model provides a connection structure of ultra-thin stone material and building facade which characterized in that: including fossil fragments (1) and slabstone (2), fossil fragments (1) include a plurality of connecting pieces (11) and a plurality of horizontal cardboard (12), connecting piece (11) are fixed on the outer wall, horizontal cardboard (12) level is fixed on connecting piece (11), a horizontal cardboard (12) are connected with a plurality of connecting pieces (11), be connected with fastener one (121) on horizontal cardboard (12), slabstone (2) set up between two adjacent horizontal cardboard (12), slabstone (2) offered chute (21) on the surface, slabstone (2) pass through chute (21) and fastener one (121) butt.

2. The connection structure of ultra-thin stone and building facade according to claim 1, characterized in that: the cross section of the clamping piece I (121) is in an isosceles triangle shape.

3. The connection structure of ultra-thin stone and building facade according to claim 1, characterized in that: the connecting piece (11) comprises a horizontal part (111) and a vertical part (112), the connecting piece (11) is formed by bending a metal plate, the horizontal part (111) is perpendicular to the vertical part (112), the vertical part (112) is fixed on an outer wall through a bolt, and the horizontal part (111) is fixedly connected with the transverse clamping plate (12) through a bolt.

4. The connection structure of ultra-thin stone and building facade according to claim 1, characterized in that: the horizontal clamping plates (12) are connected with vertical clamping plates (13), the vertical clamping plates (13) are perpendicular to the horizontal clamping plates (12), and the stone plates (2) are clamped between two adjacent vertical clamping plates (13).

5. The connection structure of ultra-thin stone and building facade according to claim 4, characterized in that: the vertical clamping plate (13) is provided with a second clamping piece (132), and the second clamping piece (132) is abutted to the chute (21) of the stone slab (2).

6. The connection structure of ultra-thin stone and building facade according to claim 5, characterized in that: the stone slab (2) is arranged to be a square plate, and the cross sections of the clamping piece I (121) and the clamping piece II (132) are the same.

7. The connection structure of ultra-thin stone and building facade according to claim 6, characterized in that: the end part of the vertical clamping plate (13) is provided with an abutting plate (131), and the abutting plate (131) is fixedly connected to the horizontal clamping plate (12) through bolts.

8. The connection structure of ultra-thin stone and building facade according to claim 7, characterized in that: the vertical clamping plate (13) is provided with a glue layer, and the glue layer is used for bonding the vertical clamping plate (13) and the stone plate (2).