CN110017025B

CN110017025B - Paving process for corridor stone floor

Info

Publication number: CN110017025B
Application number: CN201910336064.1A
Authority: CN
Inventors: 刘永海
Original assignee: Foshan Shunde Harris Decoration Engineering Co ltd
Current assignee: Foshan Shunde Harris Decoration Engineering Co ltd
Priority date: 2019-04-24
Filing date: 2019-04-24
Publication date: 2021-01-08
Anticipated expiration: 2039-04-24
Also published as: CN110017025A

Abstract

The invention relates to a pavement and sticking process for a passageway stone floor, which comprises the following steps: s1, constructing a waterproof layer; building a handrail fixing block on one side of the passageway facing outdoors, and sequentially arranging a leveling layer and a waterproof layer above the passageway; s2, laying a protective layer; arranging a protective layer on the waterproof layer; s3, water dispersing construction; drilling a through mounting hole on the side wall of the railing fixing block, inserting a water outlet pipe into the mounting hole, and gluing and fixing; s4, paving the stone; the stone which is not cut is named as a complete panel; cutting the stone to form a wall facing panel and a face facing panel, and drilling a water taking hole on the face facing panel; mounting a cushion block, a rod facing cushion block and a support structure on the protective layer, and mounting a complete panel, a rod facing panel and a wall facing panel above the cushion block, the rod facing cushion block and the support structure; s5, constructing skirting lines; and S6, constructing the structure on the railing fixing block. The stone and the protective layer are overhead, and the face plate of the adjacent rod is provided with the water outlet hole, so that the water drainage on the passageway is facilitated.

Description

Paving process for corridor stone floor

Technical Field

The invention relates to the technical field of floor paving, in particular to a corridor stone floor paving process.

Background

A corridor is a roofed passageway that connects two large areas of an elongate zone. The outdoor corridor connects the outdoor space and the indoor space, and has a transitional effect. Because outdoor weather is difficult to measure, stone is generally used as a material for paving the ground in order to prolong the service life of the corridor ground and facilitate cleaning.

As shown in fig. 6, the prior art construction method of the corridor passageway stone ground is as follows: s1, building a railing fixing block 11 on one side of the passageway 1 far away from the structural wall 2; s2, paving cement mortar on the passageway 1 to form a leveling layer 12; s3, paving a layer of cement mortar on the leveling layer 12, placing the stone on the cement mortar, and beating the surface of the stone by using a rubber hammer to make the stone and the cement mortar fully contact; correcting the flatness of the surface of the stone by using a horizontal ruler; s4, fixing the skirting line 22 on one side of the structural wall 2 by using cement mortar, wherein the bottom of the skirting line 22 is tightly propped against the upper surface of the stone; s5, fixing the balustrade 111 on the balustrade fixing block 11, and then paving the protective panel 112 on the surface of the balustrade fixing block 11 by using cement mortar, wherein the protective panel 112 is the same as the skirting line 22 in material and color.

The above prior art solutions have the following drawbacks: because one side in aforementioned passageway is external space, when meetting rainwater weather, the rainwater can get into in the passageway, leads to the rainwater to save between skirting line and railing fixed block, can't carry out fine scattered water.

Disclosure of Invention

The invention aims to provide a paving process for a stone floor of a passageway, which can better disperse water for rainwater accumulated in the passageway in rainy days, thereby facilitating people to walk on the passageway.

The above object of the present invention is achieved by the following technical solutions:

a paving and pasting process for a passageway stone floor comprises the following steps;

s1, constructing waterproof layer

Building a railing fixing block on one side of the corridor far away from the structural wall, and paving cement mortar between the railing fixing block and the wall to form a leveling layer; laying a waterproof layer above the leveling layer, wherein one side of the waterproof layer extends to the surface of the structural wall;

s2, laying a protective layer

Paving cement mortar on the waterproof layer to form a protective layer;

s3, water dispersing construction

Drilling a hole on one side of the railing fixing block, which faces to the structural wall body, to form a mounting hole which penetrates through the railing fixing block; inserting a water outlet pipe into the mounting pore channel, and gluing and fixing an opening of the water outlet pipe facing one end of the structural wall body and the railing fixing block;

s4, paving the stone;

cutting the stone to form a wall facing panel and a face facing panel, and drilling a water taking hole on the face facing panel; the stone which is not cut is named as a complete panel; placing cushion blocks on the protective layer, wherein the cushion blocks are arranged at equal intervals; placing a rod approaching cushion block on the protective layer close to the railing fixing block, wherein the rod approaching cushion block is abutted against the railing fixing block; mounting a support structure on the protective layer adjacent to the structural wall;

placing a complete panel above the cushion blocks, wherein four corners of the complete panel are respectively positioned on the upper surfaces of the four cushion blocks; a face plate is arranged between the face cushion block and the cushion block adjacent to the face cushion block, and the end face of the face plate abuts against the surface of the handrail fixing block; placing a wall facing plate between the supporting structure and the cushion block adjacent to the supporting structure, wherein the end surface of the wall facing plate is abutted against the protective layer on the structural wall; filling joint mixtures in joint positions of the rod facing panel and the rod facing panel, the rod facing panel and the complete panel, the complete panel and the wall facing panel, the wall facing panel and the wall facing panel;

s5 skirting line construction

Coating cement mortar on the structural wall, attaching the skirting line to the cement mortar, and enabling the bottom of the skirting line to abut against the wall face plate;

s6 construction of upper structure of railing fixing block

Installing a railing on the railing fixing block, smearing cement mortar on the outer surface of the railing fixing block, and attaching a protective panel on the cement mortar; the protective panel located above the face plate interferes with the face plate.

Through adopting above-mentioned technical scheme, the water of accumulating on the passageway can enter into between protective layer and the stone material through the lower water hole, and the rethread outlet pipe is discharged outdoor, can reduce the ponding in the passageway for the ground in passageway can supply people to normally walk.

Beat between the opening of outlet pipe towards structure wall body one end and the railing fixed block and glue fixedly, can improve the joint strength between outlet pipe and the railing fixed block to reduce the probability of rainwater from the position infiltration between outlet pipe outer wall and the railing fixed block.

The joint mixture can improve the connection strength and the connection integrity between the stones, thereby prolonging the service life of the aisle floor.

The invention is further configured to: in the laying of the protective layer of S2, a water-spreading slope is formed on the upper surface of the protective layer, and the water-spreading slope is obliquely arranged downwards from the structural wall towards the direction of the railing fixing block.

Through adopting above-mentioned technical scheme for the rainwater that the stone material surface was amassed flows down the launching hole fast under the direction of inclined plane, has improved the effect of scattered water.

The invention is further configured to: in the water distribution construction of S3, a plurality of installation holes are arranged along the length direction of the railing fixing block.

Through adopting above-mentioned technical scheme, further improve the scattered water effect.

The invention is further configured to: in the water distribution construction of S3, the mounting hole is inclined downwards from one side of the railing fixing block towards the structure wall to one side of the railing fixing block away from the structure wall, and the mounting hole is located at the bottom of one end of the railing fixing block towards the structure wall and aligned with the top surface of the protective layer.

Through adopting above-mentioned technical scheme for the speed that the rainwater flows is accelerated, thereby improves water guide efficiency.

The invention is further configured to: in the stone paving of S4, the construction process of the support structure is as follows, taking a vertical steel pipe, and welding a transverse steel plate at one end of the vertical steel pipe; building concrete on the protective layer, inserting the vertical steel pipe into the concrete, and forming a fixed concrete block after the concrete is solidified; the upper surface of the transverse steel plate is positioned above the upper surface of the cushion block adjacent to the transverse steel plate, and one side of the wall panel is supported on the transverse steel plate.

Through adopting above-mentioned technical scheme, horizontal steel sheet has more excellent compressive strength and toughness, can carry out better support to facing the shingle nail. Because the upper surface of horizontal steel sheet is located the top of the cushion upper surface adjacent with it for the rainwater can be along the position in the faster flow lower water hole in stone material surface under the action of gravity, thereby improves the efficiency of launching.

The invention is further configured to: in the stone paving of S4, before concrete is poured, a short steel plate is attached to the protective layer on the structural wall; the short steel plate and the fixed concrete block are integrally poured, and after the fixed concrete block is poured, the transverse steel plate and the short steel plate are welded.

Through adopting above-mentioned technical scheme, the setting of short steel sheet can be protected the protective layer that corresponds the structure wall body. Secondly, short steel sheet and horizontal steel sheet welding are whole for whole bearing structure's bulk strength is better, can carry out better support to facing the shingle nail.

The invention is further configured to: in the stone paving of S4, the cushion blocks and the adjacent rod cushion blocks are consistent in size and are arranged in a round platform shape.

Through adopting above-mentioned technical scheme, the cushion of round platform shape and face the pole cushion and have better structural strength and structural stability to carry out better support to the stone material.

The invention is further configured to: in the stone paving of S4, inserting a sleeve into the sewer hole, and fixedly adhering the outer wall of the sleeve and the inner wall of the sewer hole; after the face plate is arranged between the face cushion block and the cushion block adjacent to the face cushion block, the lower water hole on the face plate is close to the railing fixing block.

Through adopting above-mentioned technical scheme, telescopic setting can be protected the lower water hole to the extension faces the life of pole panel, and reduces and faces the probability that the crack appears in pole panel lower water hole perisporium because stress concentration.

The invention is further configured to: a spiral raised line is arranged inside the sleeve.

Through adopting above-mentioned technical scheme, the spiral sand grip can lead the rainwater of going on to sleeve inside to reduced the rainwater and to the jam in sewer hole when too much, can improve the flow efficiency of rainwater.

The invention is further configured to: in the stone paving of S4, inserting vertical rods into the middle positions between the face plate and the face plate, between the face plate and the complete plate, between the complete plate and the face plate, and between the face plate and the face plate, and then filling the gap filler; after the vertical rod is pulled out, a water drainage hole is formed in the middle of the gap filler.

By adopting the technical scheme, the drainage efficiency is further improved.

In conclusion, the beneficial technical effects of the invention are as follows:

1. arranging a cushion block, a temporary rod cushion block and a supporting structure between the stone and the protective layer to form an overhead layer between the stone and the protective layer; the face plate of the adjacent rod is provided with a water drainage hole, so that rainwater accumulated on the upper surface of the stone can enter the protective layer through the water drainage hole and then is discharged to the outside through the water outlet pipe, and the probability of water accumulation on the ground on the passageway is reduced;

2. the upper surface of the protective layer is provided with a water dispersing slope, so that the water dispersing efficiency is improved.

Drawings

Fig. 1 is a schematic view of the vertical cross-section structure of the present invention.

Fig. 2 is a partially enlarged schematic view of a portion a in fig. 1.

Fig. 3 is a schematic view of the structure of the steel mold in the present invention.

Fig. 4 is a partially enlarged schematic view of a portion B in fig. 1.

Fig. 5 is a schematic top view of the present invention.

Fig. 6 is a schematic view of a vertical cross-section of the prior art.

In the figure, 1, a passageway; 11. a railing fixing block; 111. a railing; 112. a protective panel; 12. leveling layer; 13. a waterproof layer; 14. a protective layer; 141. a water dispersion slope; 142. a limb pad; 143. cushion blocks; 2. a structural wall; 21. a short steel plate; 22. skirting lines; 3. installing a pore channel; 31. a water outlet pipe; 4. a wall facing panel; 5. a face plate; 51. a drain hole; 52. a sleeve; 521. a convex strip; 6. a complete panel; 7. steel molding; 8. a support structure; 81. fixing a concrete block; 82. erecting a steel pipe; 83. a transverse steel plate; 9. a gap filling layer; 91. a water drainage through hole.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1, the paving process for the stone floor of the aisle, disclosed by the invention, comprises the following steps;

s1, constructing a waterproof layer 13

Referring to fig. 1, a handrail fixing block 11 is built on one side of the aisle 1 far away from the structural wall 2, and cement mortar is laid between the handrail fixing block 11 and the wall to form a leveling layer 12. And paving a waterproof layer 13 above the leveling layer 12, wherein one side of the waterproof layer 13 extends to the surface of the structural wall 2. The waterproof layer 13 may be waterproof paint or waterproof roll.

S2, laying a protective layer 14

And paving cement mortar on the waterproof layer 13, and utilizing a shovel blade to find the slope on the upper surface of the cement mortar. And forming a protective layer 14 after the cement mortar is solidified, wherein a water dispersion slope 141 with the gradient of 3-5 per mill is formed on the upper surface of the protective layer 14, and the water dispersion slope 141 inclines downwards from the structural wall 2 to the direction of the railing fixing block 11.

S3, water dispersing construction

With reference to fig. 1 and 2, a hole is drilled on the balustrade fixing block 11 toward one side of the structural wall 2 to form a mounting hole 3, and the mounting hole 3 is provided in a plurality along the length direction of the balustrade fixing block 11. The mounting hole 3 is inclined downwards from one side of the railing fixing block 11 towards the structural wall 2 and penetrates through the railing fixing block 11. The mounting hole 3 is located at one end of the railing fixing block 11 facing the structural wall 2, and the lowest point of the inner wall is aligned with the top surface of the portion of the protective layer 14 corresponding to the passageway 1. Insert outlet pipe 31 in installation pore 3, one end of outlet pipe 31 flushes with railing fixed block 11 towards one side of structure wall 2 to scribble waterproof glue between the opening of outlet pipe 31 towards structure wall 2 one end and railing fixed block 11 and fix.

S4, paving the stone;

the stone material is a 600mm by 600mm panel. The position of the protective layer 14 corresponding to the aisle 1 is lofted and the amount of stone material along the width of the aisle 1 is determined. Cutting the stone to form a wall facing plate 4 and a face facing plate 5, and drilling a water outlet 51 on the face facing plate 5, wherein the diameter of the water outlet 51 is 3 cm. A sleeve 52 with the height consistent with the thickness of the stone is selected, and a spiral convex strip 521 is arranged inside the sleeve 52. Glue is applied to the outer wall of the sleeve 52 and the sleeve 52 is inserted into the lower water hole 51 to be fixed.

The stone material which is not cut is named as a complete panel 6, and the wall facing panel 4 and the rod facing panel 5 are positioned at two sides of the complete panel 6 during paving.

The adjacent rod pad 142 is placed on the protective layer 14 close to the railing fixing block 11, and the surface of the adjacent rod pad 142 and the surface of the protective layer 14 are fixed by glue, so that the adjacent rod pad 142 is abutted against the railing fixing block 11. The cushion blocks 143 are placed on the protective layer 14, the distance between the centers of the upper surfaces of the adjacent cushion blocks 143 is 600mm, and the cushion blocks 143 and the surface of the protective layer 14 are fixed by glue.

The cushion 143 is the same as the adjacent rod cushion 142 in size, and the manufacturing method is as follows:

referring to fig. 3, a cylindrical steel mold 7 is made of an iron plate, and the steel mold 7 is provided with an opening corresponding to the cylindrical large end. And pouring fine stone concrete in the steel die 7, and demoulding after the fine stone concrete is solidified to form a circular truncated cone-shaped structure.

With reference to fig. 1 and 4, a short steel plate 21 is attached to the protective layer 14 on the structural wall 2, and a support structure 8 is mounted on the side of the short steel plate 21 remote from the structural wall 2. The supporting structure 8 comprises a fixed concrete block 81, a vertical steel pipe 82 and a transverse steel plate 83, and the construction process is as follows:

a vertical steel pipe 82 is taken, and a transverse steel plate 83 is welded at one end of the vertical steel pipe 82. A formwork is built on one side of the short steel plate 21, so that a rectangular space is formed between the formwork and the short steel plate 21, and concrete is poured in the space. And the vertical steel pipe 82 is inserted into the concrete, a fixed concrete block 81 is formed after the concrete is solidified, and the transverse steel plate 83 and the short steel plate 21 are welded. At this time, the upper surface of the lateral steel plate 83 is located above the upper surface of the pad 143 adjacent thereto.

Referring to fig. 1 and 5, the complete panel 6 is placed above the spacers 143, and four corners of the complete panel 6 are respectively located on the upper surfaces of the four spacers 143. If the length of one side of the selected stone is larger than 600mm, the cushion block 143 needs to be additionally arranged below the side length of the stone so as to improve the supporting effect on the stone.

The face facing plate 5 is arranged between the face facing pad 142 and the pad 143 adjacent to the face facing pad, the end face of the face facing plate 5 abuts against the surface of the rail fixing block 11, and the water outlet 51 is close to the rail fixing block 11.

The wall facing plate 4 is placed between the supporting structure 8 and the cushion blocks 143 adjacent to the supporting structure, and the end face of the wall facing plate 4 is abutted against the protective layer 14 on the structural wall 2. Inserting a vertical rod (not shown in the figure) in the middle position between the face plate 5 and the face plate 5, between the face plate 5 and the complete plate 6, between the complete plate 6 and the face plate 4, and between the face plate 4 and the face plate 4, and then filling gap fillers; so that the gap filler is interrupted by the vertical bars. When the gap filler is in a semi-fluid state, the vertical rod is pulled out, a gap filler layer 9 is formed after the gap filler is solidified, and a water drainage through hole 91 is formed in the middle of the gap filler layer 9.

S5 construction of skirting line 22

Cement mortar is coated on the structural wall 2, the skirting line 22 is attached to the cement mortar, the skirting line 22 is located below the protective layer 14 of the structural wall 2, and the bottom of the skirting line 22 is abutted against the upper surface of the wall panel 4.

S6 construction of upper structure of railing fixing block 11

The rail 111 is mounted on the rail fixing block 11. Cement mortar is smeared on the outer surface of the rail fixing block 11, a protection panel 112 is attached to the cement mortar, and the protection panel 112 positioned above the face plate 5 is mutually abutted against the face plate 5. The protective panel 112 is made of the same material and color as the skirting line 22.

The embodiments of the present invention are preferred embodiments of the present invention, and the scope of the present invention is not limited by these embodiments, so: all equivalent changes made according to the structure, shape and principle of the invention are covered by the protection scope of the invention.

Claims

1. A paving and pasting process for a passageway stone floor is characterized in that: comprises the following steps;

s1, construction of waterproof layer (13)

Building a railing fixing block (11) on one side of the passageway (1) far away from the structural wall (2), and paving cement mortar between the railing fixing block (11) and the wall to form a leveling layer (12); a waterproof layer (13) is laid above the leveling layer (12), and one side of the waterproof layer (13) extends to the surface of the structural wall body (2);

s2, laying a protective layer (14)

Cement mortar is laid on the waterproof layer (13) to form a protective layer (14);

s3, water dispersing construction

Drilling a hole on the railing fixing block (11) towards one side of the structural wall body (2) to form a mounting hole (3), wherein the mounting hole (3) penetrates through the railing fixing block (11); inserting a water outlet pipe (31) into the mounting hole (3), and gluing and fixing an opening of one end of the water outlet pipe (31) facing the structural wall (2) and the railing fixing block (11);

s4, paving the stone;

cutting the stone to form a wall facing panel (4) and a face rod facing panel (5), and drilling a water taking hole (51) on the face rod facing panel (5); the stone which is not cut is named as a complete panel (6); placing cushion blocks (143) on the protective layer (14), wherein the cushion blocks (143) are placed at equal intervals; a near rod cushion block (142) is arranged on the protective layer (14) close to the railing fixing block (11), and the near rod cushion block (142) is abutted against the railing fixing block (11); mounting a support structure (8) on a protective layer (14) adjacent to the structural wall (2);

a complete panel (6) is placed above the cushion blocks (143), and four corners of the complete panel (6) are respectively positioned on the upper surfaces of the four cushion blocks (143); a face plate (5) is arranged between the face pad (142) and the adjacent pad (143), and the end surface of the face plate (5) is tightly propped against the surface of the rail fixing block (11); a wall facing plate (4) is arranged between the supporting structure (8) and the cushion block (143) adjacent to the supporting structure, and the end surface of the wall facing plate (4) is abutted against the protective layer (14) on the structural wall body (2); filling joint fillers in joint positions of the face plate (5) and the face plate (5), the face plate (5) and the complete plate (6), the complete plate (6) and the face plate (4), and the face plate (4);

s5 construction of skirting line (22)

Cement mortar is coated on the structural wall body (2), the skirting line (22) is attached to the cement mortar, and the bottom of the skirting line (22) is abutted against the wall facing plate (4);

s6, construction of the upper structure of the railing fixing block (11)

Installing a handrail (111) on the handrail fixing block (11), smearing cement mortar on the outer surface of the handrail fixing block (11), and attaching a protective panel (112) on the cement mortar; the protective panel (112) positioned above the face plate (5) interferes with the face plate (5).

2. The aisle stone floor paving process as claimed in claim 1, wherein the process comprises the following steps: in the laying of the protective layer (14) of S2, a water dispersion slope (141) is formed on the upper surface of the protective layer (14), and the water dispersion slope (141) is obliquely and downwards arranged from the structural wall (2) to the direction of the railing fixing block (11).

3. The aisle stone floor paving process as claimed in claim 1, wherein the process comprises the following steps: in the water distribution construction of S3, a plurality of mounting holes (3) are arranged along the length direction of the railing fixing block (11).

4. The aisle stone floor paving process as claimed in claim 3, wherein the aisle stone floor paving process comprises the following steps: in the water distribution construction of S3, the mounting hole (3) is obliquely arranged downwards from one side of the railing fixing block (11) facing the structural wall (2) to one side of the railing fixing block (11) far away from the structural wall (2), and the bottom of one end, facing the structural wall (2), of the railing fixing block (11) in the mounting hole (3) is aligned with the top surface of the protective layer (14).

5. The aisle stone floor paving process as claimed in claim 1, wherein the process comprises the following steps: in the stone paving of S4, the construction process of the support structure (8) is as follows, a vertical steel pipe (82) is taken, and one end of the vertical steel pipe (82) is welded with a transverse steel plate (83); building concrete on the protective layer (14), inserting the vertical steel pipe (82) into the concrete, and forming a fixed concrete block (81) after the concrete is solidified; the upper surface of the transverse steel plate (83) is positioned above the upper surface of the cushion block (143) adjacent to the upper surface, and one side of the wall panel (4) is supported on the transverse steel plate (83).

6. The aisle stone floor paving process as claimed in claim 5, wherein the process comprises the following steps: in the stone paving of S4, before concrete is poured, a short steel plate (21) is attached to a protective layer (14) positioned on a structural wall body (2); the short steel plate (21) and the fixed concrete block (81) are integrally cast, and after the fixed concrete block (81) is cast, the transverse steel plate (83) and the short steel plate (21) are welded.

7. The aisle stone floor paving process as claimed in claim 1, wherein the process comprises the following steps: in the stone paving process of S4, the cushion blocks (143) and the rod facing cushion blocks (142) are consistent in size and are arranged in a truncated cone shape.

8. The aisle stone floor paving process as claimed in claim 1, wherein the process comprises the following steps: in the stone paving of S4, inserting the sleeve (52) into the lower water hole (51), and gluing and fixing the outer wall of the sleeve (52) and the inner wall of the lower water hole (51); after the face rod panel (5) is placed between the face rod cushion block (142) and the cushion block (143) adjacent to the face rod cushion block, the lower water hole (51) on the face rod panel (5) is close to the railing fixing block (11).

9. The aisle stone floor paving process as claimed in claim 8, wherein the process comprises the following steps: a spiral convex strip (521) is arranged inside the sleeve (52).

10. The aisle stone floor paving process as claimed in claim 1, wherein the process comprises the following steps: in the stone paving of S4, inserting vertical rods into the middle positions between the face plate (5) and the face plate (5), between the face plate (5) and the complete plate (6), between the complete plate (6) and the face plate (4), and between the face plate (4) and the face plate (4), and then filling caulking agents; after the vertical rod is pulled out, a water outlet through hole (91) is formed in the middle of the gap filler.