CN117966995A - Flexible stone bearing construction structure on arc wall surface and construction method - Google Patents

Abstract

The utility model provides a stone material flexible load-bearing construction structure and construction method on arc wall, relate to construction technical field, stone material flexible load-bearing construction structure on the arc wall, the dry vermicelli of arc structure wall is the arcwall face, the bottom of arcwall face is a horizontal vertical face, including connecting two upper embedded plates on arcwall face top, connect two lower embedded plates at vertical face, upper and lower embedded plates symmetry sets up, the wire rope of drawknot between corresponding upper and lower embedded plates, support through wire rope, connect the dry link on the arcwall face, the stone material of link on the dry link. The invention solves the problems that the stone on the arc-shaped structure wall is inconvenient to install and each stone cannot be perfectly attached to the wall surface of the arc-shaped structure wall, and simultaneously solves the problems that the rigid vertical keel of the material in the prior art is used as a bearing member, the bending prefabrication is needed in advance in factories, the radian cannot be adjusted on site, and the flexibility is small.

Description

Flexible stone bearing construction structure on arc wall surface and construction method

Technical Field

The invention relates to the technical field of building construction, in particular to a stone flexible bearing construction structure on an arc wall surface and a construction method.

Background

The prior art is that the buried plate is installed on the structural wall body, the vertical keels are fixed through the connecting pieces, the stone is hung on the vertical keels through the switching leveling assembly, but the vertical keels are made of rigid materials, the bending prefabrication is needed in advance, the radian cannot be adjusted on site, and the flexibility is small.

Disclosure of Invention

The invention aims to provide a flexible stone bearing construction structure on an arc-shaped wall and a construction method, which solve the problems that the installation of stones on the arc-shaped wall is inconvenient, each stone cannot be perfectly attached to the wall of the arc-shaped wall, and meanwhile, the problems that in the prior art, a rigid vertical keel is used as a bearing member, bending prefabrication is needed in advance in factories, the radian cannot be adjusted on site, and the flexibility is small.

In order to achieve the above purpose, the invention adopts the following technical scheme:

The utility model provides a stone material flexible load-bearing construction structures on arc wall, the dry vermicelli of arc structure wall is the arcwall face, and the bottom of arcwall face is a horizontal vertical face, including connecting two upper embedded plates on arcwall face top, connect two lower embedded plates at vertical face, upper and lower embedded plates symmetry sets up, and the wire rope of drawknot between corresponding upper and lower embedded plates supports, connects the dry link spare on the arcwall face through wire rope, articulates the stone material on the dry link spare.

The stones are distributed on the arc-shaped surface in groups, the stones in each group are sequentially distributed from top to bottom, and four corners of each stone are connected to the arc-shaped surface.

The dry-hanging connecting piece comprises a pair of rectangular steel wire rope clamping plates, a pair of U-shaped openings are formed in the middle of the top edges of the pair of steel wire rope clamping plates, U-shaped clamping pieces are clamped between the pair of U-shaped openings, and the pair of steel wire rope clamping plates are clamped through the U-shaped clamping pieces; four corners of the pair of steel wire rope clamping plates are connected through connecting bolts.

The wire rope is connected between a pair of wire rope clamping plates in a penetrating way.

The center of the steel wire rope clamping plate is connected to the arc surface of the arc-shaped structure wall body through a connecting rod.

A stone hanging piece is hung on the pair of steel wire rope clamping plates, and the stone hanging piece is clamped with the outer side surfaces of the steel wire rope clamping plates through H-shaped inserting blocks; the center of the top surface of the stone pendant is provided with a threaded hole, a height adjusting screw rod is connected in the threaded hole from top to bottom in a penetrating way, and the bottom end of the height adjusting screw rod is propped against the bottom surface of the U-shaped clamping piece; the center of the front of the stone pendant is provided with a threaded hole, a front-back distance adjusting screw rod is connected in the threaded hole from outside to inside in a penetrating way, and the front-back distance adjusting screw rod is used as a stone hanging point.

Further preferred technical scheme: the connecting rod comprises a mechanical anchor bolt and a drawknot bolt.

In each group of stones, the centers of the steel wire rope clamping plates positioned on two vertex angles of the uppermost stone and the centers of the steel wire rope clamping plates positioned on two bottom angles of the lowermost stone are connected to the arc-shaped structural wall body through mechanical anchor bolts, and the centers of the steel wire rope clamping plates positioned at the rest positions are connected to the arc-shaped surface of the arc-shaped structural wall body through drawknot bolts.

Further preferred technical scheme: the stone material pendant is an integral structure, including U-shaped bayonet part and isosceles trapezoid supporting part, the both ends of U-shaped bayonet part and the bottom of isosceles trapezoid supporting part all are equipped with the U-shaped socket.

Further preferred technical scheme: the U-shaped bayonet part is clamped on the outer sides of the top edges of the pair of steel wire rope clamping plates, and the isosceles trapezoid supporting part is supported on the outer side surfaces of the steel wire rope clamping plates.

Further preferred technical scheme: the H-shaped plug block is spliced in the U-shaped socket in a fit way.

Further preferred technical scheme: the top edges of the two upper embedded plates do not exceed the top edge of the stone material positioned at the uppermost end.

Further preferred technical scheme: two steel wire ropes are tied between each pair of corresponding upper embedded plates and lower embedded plates, and the two steel wire ropes are positioned on two sides of the mechanical anchor bolt or two sides of the tie bolt.

Further preferred technical scheme: the upper embedded plate and the lower embedded plate have the same structure, the upper embedded plate is a rectangular plate, and four corners are connected to the arc surface of the arc-shaped structural wall body through anchor bolts; the two lower embedded plates are connected to the vertical surface of the arc-shaped structural wall body through anchor bolts.

Further preferred technical scheme: the stone is a flat stone or an arc stone.

The construction method of the stone flexible bearing construction structure on the arc wall surface comprises the following steps:

Step one, paying off and positioning according to a design drawing.

And paying off to determine the positions of the upper embedded plate and the lower embedded plate and the positions and elevations of stone hanging points on all dry hanging connecting pieces.

And step two, clamping the U-shaped clamping piece between a pair of steel wire rope clamping plates, and clamping the space between the pair of steel wire rope clamping plates.

And thirdly, fixing the top end of the steel wire rope at the top of the arc-shaped structural wall body by using an upper embedded plate, fixing the bottom end of the steel wire rope at the bottom of the arc-shaped structural wall body by using a lower embedded plate, and tensioning the steel wire rope.

Two steel wire ropes are fixed on each embedded plate.

And fourthly, fixing a pair of steel wire rope clamping plates on the arc-shaped structural wall body through a mechanical anchor bolt, clamping the steel wire ropes on two sides of the pair of steel wire rope clamping plates, sealing the steel wire ropes in the pair of steel wire rope clamping plates through connecting bolts, and simultaneously ejecting the steel wire ropes outwards through the mechanical anchor bolt.

Step five, the stone pendant is clamped on the pair of steel wire rope clamping plates, and then an H-shaped inserting block is inserted into a gap between the pair of steel wire rope clamping plates to be clamped.

Step six, screwing a height adjusting screw rod, and adjusting the upper and lower positions of the stone hanging piece to the designed height; and screwing the front-back distance adjusting screw to adjust the front-back position of the stone pendant to the designed hanging point position.

And seventhly, hanging the stone on a hanging point of the stone hanging piece, and coating stone glue to finish installation.

Compared with the prior art, the invention has the following characteristics and beneficial effects:

According to the invention, the steel wire rope is used as a weighing component of the stone, the radian of the steel wire rope can be adjusted according to the field requirement, and the flexible support of the stone is realized through the steel wire rope, so that the adjustable stone is stronger than the existing rigid support.

The invention solves the primary technical problem of how to adapt to stone installation of the wall surface of the wall body with the arc-shaped structure and ensures that each stone can be perfectly attached to the wall surface of the wall body with the arc-shaped structure.

The steel wire rope is tightly fixed with the dry-hanging connecting piece on the back of the stone, and then the stone is dry-hung on the dry-hanging connecting piece, so that the connecting mode ensures the firmness of stone connection, and can also effectively resist external forces such as wind pressure, earthquake and the like.

Drawings

FIG. 1 is a perspective view of a flexible load bearing construction structure for stone material on an arcuate wall surface in accordance with the present invention;

FIG. 2 is an enlarged view of portion A of FIG. 1 in accordance with the present invention;

FIG. 3 is a perspective view of a flexible load bearing construction of stone material on an arcuate wall surface in accordance with the present invention;

FIG. 4 is a perspective view of a dry-hang connector of the present invention;

FIG. 5 is a schematic view of a mechanical anchor in the uppermost dry-hang connector of the present invention;

FIG. 6 is a schematic illustration of a mechanical anchor of the present invention;

FIG. 7 is a schematic view of a tie bolt in a centrally located dry-hang connector of the present invention;

FIG. 8 is a schematic view of a tie bolt of the present invention;

FIG. 9 is a perspective view of the connection of a pair of wire rope clamps and a U-shaped clip of the present invention;

FIG. 10 is a schematic view of a pair of wire rope clamps of the present invention;

FIG. 11 is a schematic view of a stone hanger of the present invention;

FIG. 12 is a schematic view of a U-shaped clip of the present invention;

FIG. 13 is a schematic view of an H-shaped insert block of the present invention;

FIG. 14 is a schematic view of an upper embedment plate of the present invention;

FIG. 15 is a schematic view of a steel cord of the present invention;

Reference numerals:

1-upper pre-embedded plate, 2-lower pre-embedded plate, 3-stone, 4-dry hanging connecting piece, 5-steel wire rope,

4.1-Wire rope clamp plate, 4.2-U-shaped clamp piece, 4.3-U-shaped opening, 4.4-connecting bolt, 4.5-drawknot bolt, 4.6-mechanical anchor bolt, 4.7-stone pendant, 4.8-H-shaped insert block, 4.9-height adjusting screw rod, 4.10-front-back distance adjusting screw rod, and,

4.7.1-U-shaped sockets.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 to 15, the flexible stone bearing construction structure and the construction method on the arc wall surface of the invention; the stone flexible bearing construction structure on the arc-shaped wall surface is characterized in that dry noodles of the arc-shaped wall surface are arc-shaped surfaces, and the bottom end of each arc-shaped surface is a transverse vertical surface; including connecting two upper embedded plates 1 on arcwall face top, connect two lower embedded plates 2 at vertical face, upper and lower embedded plates symmetry sets up, and wire rope 5 of drawknot between corresponding upper and lower embedded plates supports, connects the dry link 4 on the arcwall face through wire rope 5, articulates the stone material 3 on the link 4 that hangs futilely.

The stones 3 are distributed on the arc-shaped surface of the arc-shaped structural wall body in groups, and the stones 3 in each group are tightly arranged up and down and connected on the arc-shaped surface.

The stone 3 is a slab stone or an arc stone, in a specific embodiment, the length of the arc stone is 785mm, the width is 800mm, the thickness is 25mm, the diameter of a circle where the arc of the arc stone is located is 9055mm, and the arc length is 818.4mm; the specific size and radian of the stone 3 are determined according to the arc-shaped surface of the arc-shaped structure wall body, and are adapted to the radian of the arc-shaped surface; compared with arc stone and flat stone, the overall effect of the arc stone after installation is better.

The top end of the arc-shaped surface of the arc-shaped structure wall body is transversely connected with two upper embedded plates 1 at intervals, and the vertical surface is transversely connected with two lower embedded plates 2 at intervals; the top edges of the two upper embedded plates 1 do not exceed the top edge of the stone material 3 at the uppermost end, namely the two upper embedded plates 1 are hidden behind the stone material 3 at the uppermost end; the upper embedded plate 1 is a rectangular plate, and four corners of the upper embedded plate are connected to the arc surface of the arc-shaped structural wall through anchor bolts; the two lower embedded plates 2 are connected to the vertical surface of the arc-shaped structural wall body through anchor bolts.

Four corners of the back of the stone 3 are connected to the arc surface of the arc structure wall body through dry hanging connecting pieces 4.

The center of the steel wire rope clamping plate 4.1 is connected to the arc surface of the arc-shaped structure wall body through a connecting rod; the connecting rod comprises a mechanical anchor bolt 4.6 and a drawknot bolt 4.5, the dry hanging connecting piece 4 comprises a pair of rectangular steel wire rope clamping plates 4.1, a pair of U-shaped openings 4.3 are formed in the middle of the top edges of the pair of steel wire rope clamping plates 4.1, a U-shaped clamping piece 4.2 is clamped between the pair of U-shaped openings, and the pair of steel wire rope clamping plates 4.1 are clamped through the U-shaped clamping pieces 4.2; four corners of the pair of steel wire rope clamping plates 4.1 are connected through connecting bolts 4.4; the centers of the steel wire rope clamping plates 4.1 positioned on two vertex angles of the uppermost stone 3 and the centers of the steel wire rope clamping plates 4.1 positioned on two bottom angles of the lowermost stone 3 are connected to the arc-shaped structural wall body through mechanical anchor bolts 4.6, the steel wire rope clamping plates 4.1 are outwards ejected through the mechanical anchor bolts 4.6, and further the steel wire ropes 5 clamped between the pair of steel wire rope clamping plates 4.1 are outwards ejected, and the installation distance is ejected between the steel wire ropes 5 and the arc-shaped surface of the arc-shaped structural wall body; the centers of the steel wire rope clamping plates 4.1 positioned at the rest positions are connected to the arc-shaped surface of the arc-shaped structure wall body through the tie bolts 4.5, and the radian of the steel wire rope 5 is adjusted through the tie bolts 4.5.

Two steel wire ropes 5 are tied between each pair of corresponding upper embedded plates and lower embedded plates, a dry hanging connecting piece 4 is arranged on the two steel wire ropes 5, a pair of steel wire rope clamping plates 4.1 are arranged in front of and behind the two steel wire ropes 5 and are sealed through connecting bolts 4.4, and the two steel wire ropes 5 are positioned on two sides of a mechanical anchor bolt 4.6 or two sides of the tie bolt 4.5.

A pair of steel wire rope clamping plates 4.1 are hung with stone hanging pieces 4.7, and the stone hanging pieces 4.7 are of an integrated structure and comprise U-shaped clamping parts and isosceles trapezoid supporting parts, and U-shaped sockets 4.7.1 are respectively arranged at two ends of the U-shaped clamping parts and at the bottom ends of the isosceles trapezoid supporting parts; the U-shaped bayonet part is clamped outside the top edges of the pair of steel wire rope clamping plates 4.1, and the isosceles trapezoid supporting part is supported on the outer side surface of the steel wire rope clamping plates 4.1; the U-shaped jack 4.7.1 and the outer side surface of the steel wire rope clamping plate 4.1 are clamped by an H-shaped inserting block 4.8, and the H-shaped inserting block 4.8 is in fit and inserted in the U-shaped jack 4.7.1; the center of the top plate of the U-shaped clamping part is provided with a threaded hole, and the threaded hole is internally provided with

A height adjusting screw 4.9 is connected from top to bottom in a penetrating way, the bottom end of the height adjusting screw 4.9 is propped against the bottom surface of the U-shaped clamping piece 4.2, and the height adjusting screw 4.9 is screwed to realize the up-down height adjustment of the stone hanging piece 4.7; the center of the top plate of the isosceles trapezoid supporting part is provided with a threaded hole, a front-rear distance adjusting screw 4.10 is connected in the threaded hole from outside to inside in a penetrating way, a fixing nut is connected in the front-rear distance adjusting screw 4.10 in a penetrating way, the front-rear distance adjusting screw 4.10 is used as a stone hanging point, and the front-rear distance adjustment of the hanging point is realized by adjusting the front-rear distance adjusting screw 4.10.

The invention relates to a construction method of a stone flexible bearing construction structure on an arc wall, which comprises the following steps:

Step one, paying off and positioning according to a design drawing.

And paying off to determine the positions of the upper embedded plate 1 and the lower embedded plate 2 and the positions and elevations of stone hanging points on all dry hanging connecting pieces 4.

And step two, clamping the U-shaped clamping piece 4.2 between the pair of steel wire rope clamping plates 4.1, and clamping the space between the pair of steel wire rope clamping plates 4.1.

And thirdly, fixing the top end of the steel wire rope 5 at the top of the arc-shaped structural wall body by using the upper embedded plate 1, fixing the bottom end of the steel wire rope 5 at the bottom of the arc-shaped structural wall body by using the lower embedded plate 2, and tensioning the steel wire rope 5.

Two steel wire ropes 5 are fixed on each embedded plate.

And fourthly, fixing a pair of steel wire rope clamping plates 4.1 on the arc-shaped structural wall body through the mechanical anchor bolts 4.6, clamping the steel wire ropes on two sides of the pair of steel wire rope clamping plates 4.1, sealing the steel wire ropes 5 in the pair of steel wire rope clamping plates 4.1 through the connecting bolts 4.4, and simultaneously ejecting the steel wire ropes 5 outwards through the mechanical anchor bolts 4.6.

Step five, the stone hanging piece 4.7 is clamped on the pair of steel wire rope clamping plates 4.1, and then the H-shaped inserting block 4.8 is inserted into a gap between the pair of steel wire rope clamping plates 4.1 to be clamped.

Step six, screwing the height adjusting screw 4.9, and adjusting the upper and lower positions of the stone hanging piece 4.7 to the designed height; the front-back distance adjusting screw 4.10 is screwed, and the front-back position of the stone pendant 4.7 is adjusted to the designed hanging point position.

And seventhly, hanging the stone 3 on a hanging point of the stone hanging piece 4.7, and coating stone glue to finish the installation.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. The utility model provides a stone material flexible load-bearing construction structure on arc wall, the dry vermicelli of arc structure wall body is the arcwall face, and the bottom of arcwall face is a horizontal vertical face, its characterized in that: the stone material dry-hanging device comprises two upper embedded plates (1) connected to the top end of an arc-shaped surface, two lower embedded plates (2) connected to a vertical surface, steel wire ropes (5) which are tied between the corresponding upper embedded plates and the corresponding lower embedded plates, dry-hanging connecting pieces (4) which are supported and connected to the arc-shaped surface through the steel wire ropes (5), and stone materials (3) which are hung on the dry-hanging connecting pieces (4);

The stones (3) are distributed on the arc-shaped surface in groups, the stones (3) in each group are sequentially distributed from top to bottom, and four corners of each stone (3) are connected to the arc-shaped surface;

The dry hanging connecting piece (4) comprises a pair of rectangular steel wire rope clamping plates (4.1), a pair of U-shaped openings (4.3) are formed in the middle of the top edges of the pair of steel wire rope clamping plates (4.1), U-shaped clamping pieces (4.2) are clamped between the pair of U-shaped openings, and the pair of steel wire rope clamping plates (4.1) are clamped through the U-shaped clamping pieces (4.2); four corners of the pair of steel wire rope clamping plates (4.1) are connected through connecting bolts (4.4);

the steel wire rope (5) is connected between a pair of steel wire rope clamping plates (4.1) in a penetrating way;

The center of the steel wire rope clamping plate (4.1) is connected to the arc surface of the arc-shaped structure wall body through a connecting rod;

a stone hanging piece (4.7) is hung on the pair of steel wire rope clamping plates (4.1), and the stone hanging piece (4.7) is clamped with the outer side surfaces of the steel wire rope clamping plates (4.1) through an H-shaped inserting block (4.8); the center of the top surface of the stone pendant (4.7) is provided with a threaded hole, a height adjusting screw (4.9) is connected in the threaded hole from top to bottom in a penetrating way, and the bottom end of the height adjusting screw (4.9) is propped against the bottom surface of the U-shaped clamping piece (4.2); the center in front of stone material pendant (4.7) is opened there is the screw hole, and threaded hole from outside to interior cross-under has front and back distance adjusting screw (4.10), and front and back distance adjusting screw (4.10) are as stone material string point.

2. The flexible stone load-bearing construction structure for an arcuate wall surface according to claim 1, wherein: the connecting rod comprises a mechanical anchor bolt (4.6) and a drawknot bolt (4.5);

In each group of stones, the centers of the steel wire rope clamping plates (4.1) positioned on the two top angles of the uppermost stone (3) and the centers of the steel wire rope clamping plates (4.1) positioned on the two bottom angles of the lowermost stone (3) are connected to the arc-shaped structural wall body through mechanical anchor bolts (4.6), and the centers of the steel wire rope clamping plates (4.1) positioned at the rest positions are connected to the arc-shaped surface of the arc-shaped structural wall body through tie bolts (4.5).

3. The flexible stone load-bearing construction structure for an arcuate wall surface according to claim 1, wherein: the stone material pendant (4.7) is an integral structure, including U-shaped bayonet part and isosceles trapezoid supporting part, the both ends of U-shaped bayonet part and the bottom of isosceles trapezoid supporting part all are equipped with U-shaped socket (4.7.1).

4. A flexible stone load-bearing construction structure for an arcuate wall surface according to claim 3, wherein: the U-shaped bayonet part is clamped on the outer sides of the top edges of the pair of steel wire rope clamping plates (4.1), and the isosceles trapezoid supporting part is supported on the outer side surface of the steel wire rope clamping plates (4.1).

5. A flexible stone load-bearing construction structure for an arcuate wall surface according to claim 3, wherein: the H-shaped plug block (4.8) is in fit connection with the U-shaped socket (4.7.1).

6. The flexible stone load-bearing construction structure for an arcuate wall surface according to claim 1, wherein: the top edges of the two upper embedded plates (1) do not exceed the top edge of the stone (3) positioned at the uppermost end.

7. The flexible load-bearing construction structure for stone material on an arcuate wall surface according to claim 2, wherein: two steel wire ropes (5) are tied between each pair of corresponding upper embedded plates and lower embedded plates, and the two steel wire ropes (5) are positioned at two sides of the mechanical anchor bolt (4.6) or two sides of the tie bolt (4.5).

8. The flexible stone load-bearing construction structure for an arcuate wall surface according to claim 1, wherein: the upper embedded plate (1) is a rectangular plate, and four corners are connected to the arc surface of the arc-shaped structural wall body through anchor bolts; the two lower embedded plates (2) are connected to the vertical surface of the arc-shaped structural wall body through anchor bolts.

9. The flexible stone load-bearing construction structure for an arcuate wall surface according to claim 1, wherein: the stone (3) is a flat stone or an arc stone.

10. The construction method of the flexible stone bearing construction structure on the arc-shaped wall surface according to claim 1, wherein the construction method comprises the following steps:

Step one, paying off and positioning according to a design drawing;

Paying off to determine the positions of the upper embedded plate (1) and the lower embedded plate (2) and the positions and elevations of stone hanging points on all dry hanging connecting pieces (4);

step two, clamping the U-shaped clamping piece (4.2) between a pair of steel wire rope clamping plates (4.1), and clamping the space between the pair of steel wire rope clamping plates (4.1);

Fixing the top end of the steel wire rope (5) on the top of the arc-shaped structural wall body by using an upper embedded plate (1), fixing the bottom end of the steel wire rope (5) on the bottom of the arc-shaped structural wall body by using a lower embedded plate (2), and tensioning the steel wire rope (5);

Two steel wire ropes (5) are fixed on each embedded plate;

Fixing a pair of steel wire rope clamping plates (4.1) on an arc-shaped structural wall body through a mechanical anchor bolt (4.6), clamping steel wires on two sides of the pair of steel wire rope clamping plates (4.1), sealing the steel wire ropes (5) in the pair of steel wire rope clamping plates (4.1) through connecting bolts (4.4), and simultaneously ejecting the steel wire ropes (5) outwards through the mechanical anchor bolt (4.6);

step five, clamping the stone hanging piece (4.7) on a pair of steel wire rope clamping plates (4.1), and then inserting an H-shaped inserting block (4.8) into a gap between the pair of steel wire rope clamping plates (4.1) for clamping;

step six, screwing a height adjusting screw (4.9) and adjusting the upper and lower positions of the stone hanging piece (4.7) to the designed height; screwing the front-rear distance adjusting screw (4.10) to adjust the front-rear position of the stone hanging piece (4.7) to the designed hanging point;

And seventhly, hanging the stone (3) on a hanging point of the stone hanging piece (4.7) and coating stone glue to finish installation.