CN114658142B - Ceramsite concrete wallboard mounting structure and construction method thereof - Google Patents

Abstract

The invention discloses a ceramsite concrete wallboard mounting structure and a construction method thereof. The wall body includes a plurality of main wallboards and at least one and walks line wallboard, walks line wallboard and each first wallboard and is located the coplanar, walks line wallboard and has the cavity. The steel clamping piece is fixed on the top plate and is provided with two clamping pieces arranged at intervals, and the two clamping pieces are respectively clamped on two sides of the wall body. The box is installed on walking the line wallboard, and box part is located the cavity. The pipeline is accommodated in the cavity, and the cable extends into the box body. The utility model provides a haydite concrete wallboard mounting structure is including the routing wallboard that can walk the line specially, has avoided doing the secondary on haydite concrete wallboard and has picked the chisel, shutoff, has improved haydite concrete wallboard's structural security performance, has saved engineering time, has reduced workman intensity of labour, has reduced construction cost, has improved construction quality and efficiency of construction.

Description

Ceramsite concrete wallboard mounting structure and construction method thereof

Technical Field

The invention relates to the technical field of building construction, in particular to a ceramsite concrete wallboard mounting structure and a construction method thereof.

Background

Along with the development of the assembled building, the technology of prefabricating the inner partition plate is applied and practiced in more projects with excellent anti-seismic, sound insulation, fireproof, environment-friendly and energy-saving performances. The technology of prefabricating the inner partition plate has a plurality of application directions such as a ceramsite concrete wall plate, an autoclaved lightweight aerated concrete wall plate, a light steel joist gypsum board partition wall, a GRC silicate cement wall plate and the like. The ceramsite concrete wallboard is widely applied to building construction by virtue of light weight, high strength, good shock resistance, fire resistance, high temperature resistance, heat preservation and heat insulation.

In the installation of the existing haydite concrete wallboard, the large electric boxes such as an HD household information box and an illumination distribution box are large in size and dense in pipeline arrangement, so that the wall body is severely cut during the pipeline installation, the integral stability of the wall body is damaged, and the wall body becomes a pain point for popularizing the haydite concrete wallboard.

In view of this, the present invention has been made.

Disclosure of Invention

The invention provides a ceramsite concrete wallboard mounting structure and a construction method thereof.

The following technical scheme is adopted:

the first object of the present invention is to provide a ceramsite concrete wallboard mounting structure, comprising:

the wall body comprises a plurality of main wallboards and at least one wiring wallboard, the wiring wallboards and the main wallboards are positioned in the same plane, and the wiring wallboards are provided with cavities;

the steel clamping piece is fixed on the top plate and is provided with two clamping pieces arranged at intervals, and the two clamping pieces are respectively clamped at two sides of the wall body;

the box body is arranged on the wiring wallboard, and the box body part is positioned in the cavity;

and the pipeline is accommodated in the cavity, and the cable extends into the box body.

Optionally, the wiring wallboard includes first wallboard and second wallboard, first wallboard has the recess, the second wallboard connect in first wallboard, the second wallboard covers the oral area of recess forms the cavity.

Optionally, the box body is installed on the first wallboard, and the second wallboard is provided with an avoidance port;

and in the state that the second wallboard is arranged on the first wallboard, the box body extends out of the avoidance port.

Optionally, the first wallboard has a main wall and side walls arranged on two sides of the main wall, the second wallboard is supported on two side walls, and the second wallboard is fixed on two side walls through adhesive bonding.

Optionally, the ceramsite concrete wallboard mounting structure further comprises a fixing plate, wherein the fixing plate is positioned in the cavity and is fixedly connected with the wiring wallboard;

the box body is arranged on the fixed plate.

Optionally, the main wallboard and walk the line wallboard along width direction's both sides all be provided with tongue-and-groove and tenon respectively, between the adjacent main wallboard, or the tenon concatenation of one between adjacent main wallboard and the line wallboard is in another tongue-and-groove.

The second object of the present application is to provide a construction method of the above-mentioned ceramic aggregate concrete wallboard mounting structure, comprising:

s1, paying out wall bit lines on the ground according to the wall body position determined by the typesetting diagram, and leading the lines to a ceiling and a side wall;

s2, fixing the steel clamping piece on a concrete structure or a first wallboard;

s3, installing a main wallboard, a wiring wallboard, a box body and a pipeline;

s4, sealing the top and the bottom of the wall;

and S5, adopting mortar to smooth gaps formed between the wallboards.

Optionally, the routing wallboard includes a first wallboard and a second wallboard, the first wallboard has a groove, and step S3 includes:

s31, installing a main wallboard and a first wallboard;

s32, installing pipelines and a box body on the first wallboard, and covering the second wallboard;

wherein, step S31 includes: the special mortar is uniformly scraped on the end part of the periphery of the first wallboard, the positioning lines are aligned up and down, the first wallboard is pushed into the steel clamping piece, the tenon groove of one of the first wallboard and the adjacent main wallboard is spliced with the tenon of the other, the wood wedges are driven into the upper part and the lower part of the first wallboard and the main wallboard and wedged, and the verticality and the flatness of the adjacent board are adjusted.

Optionally, step S32 includes:

s321, positioning an ink line on a first wallboard, installing a fixed plate, laying a pipeline, and installing a box body;

step S322, a box body position line is sprung out on the second wallboard, and an avoidance port is cut according to the box body position line;

step 323, coating adhesive on the side walls of the two sides of the first wallboard, uniformly scraping mortar on one circle of the second wallboard, and adhering the second wallboard to the first wallboard.

Optionally, step S4 includes:

s41, pouring adhesive mortar into the top of the wall body to form a mortar tenon, and filling the bottom of the wall body with dry hard fine stone concrete;

and S42, taking out the wooden wedge after the wall body is installed for a set period of time, and filling the wedge hole with the hard fine stone concrete.

By adopting the technical scheme, the invention has the following beneficial effects:

the utility model provides a haydite concrete wallboard mounting structure is including the routing wallboard that can walk the line specially, has avoided doing the secondary on haydite concrete wallboard and has picked the chisel, shutoff, has improved haydite concrete wallboard's structural security performance, has saved engineering time, has reduced workman intensity of labour, has reduced construction cost, has improved construction quality and efficiency of construction.

The following describes the embodiments of the present invention in further detail with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and together with the description serve to explain the invention, without limitation to the invention. It is evident that the drawings in the following description are only examples, from which other drawings can be obtained by a person skilled in the art without the inventive effort. In the drawings:

FIG. 1 illustrates a schematic cross-sectional view of a molding cavity modification of a first lightweight high frequency partition board extruder;

FIG. 2 illustrates a modified front view of a molding cavity of a first lightweight high frequency partition board extruder;

FIG. 3 illustrates a schematic cross-sectional view of a molding cavity modification of a second lightweight high frequency partition board extruder;

FIG. 4 is a schematic view of a construction plane structure of a ceramsite concrete wallboard mounting structure;

FIG. 5 is a schematic view of a construction front view structure of a ceramsite concrete wallboard mounting structure;

FIG. 6 is a schematic view of a construction front section of a ceramsite concrete wallboard mounting structure;

fig. 7 is a schematic side view of a ceramsite concrete wall panel installation structure.

In the figure, 1, a first light high-frequency partition plate extruder; 11. a molding cavity; 12. a vertical trowelling plate; 2. a second light high frequency partition plate extruder; 21. a molding cavity; 22. a vertical trowelling plate; 3. a main wallboard; 4. a wiring wallboard; 41. a first wallboard; 411. a main wall; 412. a sidewall; 413. a groove; 42. a second wallboard; 421. an avoidance port; 5. a steel clamping piece; 6. a case; 8. A pipeline; 9. a fixing plate; a. a tongue and groove; b. a tenon; c. mortar; d. floor slab, e, reinforcing bar.

It should be noted that these drawings and the written description are not intended to limit the scope of the inventive concept in any way, but to illustrate the inventive concept to those skilled in the art by referring to the specific embodiments.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions in the embodiments will be clearly and completely described with reference to the accompanying drawings in the embodiments of the present invention, and the following embodiments are used to illustrate the present invention, but are not intended to limit the scope of the present invention.

In the description of the present invention, it should be noted that the directions or positional relationships indicated by the terms "upper", "lower", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or component referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted", "connected" and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

Example 1

Referring to fig. 1 to 7, a first embodiment of the present application provides a ceramsite concrete wallboard mounting structure, including: wall body, steel fastener 5, box 6 and pipeline 8. The wall body comprises a plurality of main wallboards 3 and at least one wiring wallboard 4, the wiring wallboards 4 and the main wallboards 3 are positioned in the same plane, and the wiring wallboards 4 are provided with cavities. The steel fastener 5 can be fixed in on roof (floor d), steel fastener 5 has two cards that the interval set up, two the card respectively the joint in the both sides of wall body (the both sides of main wallboard 3 and/or wiring wallboard 4), box 6 install in on the wiring wallboard 4, box 6 part is located in the cavity. The line 8 is received in the cavity and the cable extends into the box 6. The box 6 may be an HD home information box, a lighting distribution box or other larger electrical box.

The utility model provides a haydite concrete wallboard mounting structure is including walking line wallboard 4 that can walk the line specially, has avoided doing the secondary on haydite concrete wallboard and has got the chisel, shutoff, has improved haydite concrete wallboard's structural security performance, has saved engineering time, has reduced workman intensity of labour, has reduced construction cost, has improved construction quality and efficiency of construction.

In one possible embodiment, the track wall panel 4 includes a first wall panel 41 and a second wall panel 42, the first wall panel 41 having a groove 413, the second wall panel 42 being connected to the first wall panel 41, the second wall panel 42 covering the mouth of the groove 413 to form the cavity. The first wall plate 41 has a groove 413 therein to facilitate internal wiring, and then the second wall plate 42 is mounted to close the groove 413.

In one possible embodiment, the case 6 is mounted on the first wall plate 41, and the second wall plate 42 is provided with a relief opening 421. In a state where the second wall plate 42 is mounted on the first wall plate 41, the case 6 extends out of the avoiding port 421.

Referring to fig. 7, the first wall panel 41 includes at least two sub-wall panels, each of which is disposed in sequence in the longitudinal direction, and the grooves 413 of the first wall panel 41 of at least two of the sub-wall panels are opposite in direction (referring to fig. 7, the upper and lower portions are each a sub-wall panel). Wherein, the sub-wallboards each comprise a first wallboard 41 and a second wallboard 42, when the grooves 413 of the first wallboards 41 of the two sub-wallboards are oriented differently, the corresponding installed boxes can be provided for two adjacent households respectively. Referring to fig. 4, the two cases are oriented differently and are different in size because of the different roles of the two cases.

Referring to fig. 4, both sides of the main wall board 3 and the routing wall board 4 along the width direction are respectively provided with a tenon groove a and a tenon b, and the tenon b between adjacent main wall boards 3 or between adjacent main wall boards 3 and the routing wall board 4 is spliced in the tenon groove a of the other.

The first wall plate 41 has a main wall 411 and side walls 412 disposed on both sides of the main wall 411, the second wall plate 42 is supported on both the side walls 412, and the second wall plate 42 is adhesively fixed on both the side walls 412 by an adhesive.

Referring to fig. 6, the ceramsite concrete wall board mounting structure further includes a fixing plate 9, the fixing plate 9 is located in the groove 413, and the fixing plate 9 is fixedly connected to the routing wall board 4. The box 6 is mounted on the fixing plate 9. The fixing plate 9 is provided with a fitting flanging, and the fitting flanging is fitted and fixed with the inner wall of the groove 413.

The fixed plate 9 comprises a main plate, two sides of the main plate are respectively provided with a fitting flanging, and the two fitting flanging are respectively connected to the two side walls 412 in a fitting manner. Wherein, the fixing plate 9 can be formed by bending galvanized steel. In order to facilitate the arrangement of the cables, the fixing plate 9 is provided with a wiring hole through which the pipeline 8 runs.

Example two

Referring to fig. 1 to 7, a second embodiment of the present application provides a construction method of the ceramsite concrete wallboard mounting structure in the first embodiment, including:

s1, releasing wall bit lines on the ground according to the wall positions determined by the typesetting diagram, and leading the lines to a ceiling (floor slab) and a side wall.

Step S2, fixing the steel clamping piece 5 on a concrete structure (such as a floor slab d) or the first wallboard 41. When the steel clamping pieces 5 are installed on the top plate (floor slab d) and the beam, the distance between the steel clamping pieces 5 is not more than 600mm, each slat is not less than 2 fixed points, and when the steel clamping pieces 5 are installed on the wall column, the distance between the steel clamping pieces 5 is not more than 1000mm. Can be nailed and fixed on the steel clamping piece 5 through a nail. The shooting nail can be PS-type shooting nail, the diameter of the top is 7.6mm, the diameter of the nail rod is 3.7mm, and the length of the nail rod is 37mm. Each steel clamping piece 5 can be fixed by 3 shooting nails, and the shooting nails are distributed in a triangular shape.

S3, installing a main wallboard 3, a wiring wallboard 4, a box body and a pipeline 8;

s4, sealing the top and the bottom of the wall;

and S5, adopting mortar to smooth gaps formed between the wallboards.

Optionally, the wiring wallboard 4 includes a first wallboard 41 and a second wallboard 42, the first wallboard 41 has a groove 413, and step S3 includes:

step S31, installing the main wallboard 3 and the first wallboard 41;

step S32, installing the pipeline 8 and the box 6 on the first wallboard 41, and covering the second wallboard 42;

wherein, step S31 includes: the special mortar is uniformly scraped on the peripheral end part of the first wallboard 41, the positioning lines are aligned up and down, the first wallboard 41 is pushed into the steel clamping piece 5, the mortises a of one of the first wallboard 41 and the adjacent main wallboard 3 are spliced with the mortises b of the other, wood wedges are driven into the upper part and the lower part of the first wallboard 41 and the main wallboard 3 and are wedged, the wood wedges are preferably placed at the solid ribs of the wallboards, and the verticality and the flatness of the adjacent board surfaces are adjusted. The steel clamping piece 5 can be a U-shaped galvanized steel plate clamping piece, the thickness of the steel clamping piece is 1.5mm, the width of the steel clamping piece is equal to the width of a wallboard, and the U-shaped length of the steel clamping piece is 40mm.

Optionally, step S32 includes:

step S321, positioning the ink-ejecting wires on the first wallboard 41, installing the fixing plate 9, laying the pipeline 8, installing the box body, and fixing the box body on the first wallboard 41 and/or the fixing plate 9.

Step S322, popping up a box body position line on the second wallboard 42, and cutting an avoidance port 421 according to the box body position line; the second wallboard 42 can be adhered with glass fiber mesh cloth at the position of the installation box body.

In step S323, adhesive is applied to the side walls 412 (e.g., end surfaces of the side walls 412) on both sides of the first wall plate 41, and mortar is uniformly scraped around the second wall plate 42 to adhere the second wall plate 42 to the first wall plate 41. The steel clamping member 5 can be arranged on the main wallboard 3 adjacent to the first wallboard 41, the steel clamping member 5 is provided with two clamping pieces, a clamping groove is formed between the two clamping pieces, and the second wallboard 42 is pushed into the clamping groove and is firmly connected with the first wallboard 41. Wood wedges can be driven into the lower part of the second wallboard 42 and wedged, the wood wedges are placed at the solid ribs of the second wallboard 42, and the verticality and the flatness of the adjacent boards are adjusted.

Optionally, step S4 includes:

and S41, pouring bonding mortar c into the top of the wall (such as the top of the wall and the gap between the beam and the slab) to form a mortar tenon, and filling the bottom of the wall with dry hard fine stone concrete.

The bonding mortar can be formed by stirring common silicate cement, sand, redispersible emulsion powder, hydroxypropyl methyl cellulose, polyvinyl alcohol, polypropylene short fibers, a waterproof agent and a water reducing agent, can realize quick bonding between wallboard and concrete structure and between wallboard, and can prevent cracking and prevent water.

And S42, taking out the wooden wedge after the wall body is installed for a set period of time (for example, 5 days), and filling the wedge hole with the hard fine stone concrete.

In step S5, mortar is used to smooth the gap formed between the wallboards, such as the gap between the adjacent main wallboards 3, or the gap between the adjacent main wallboards 3 and the wiring wallboard 4. A piece of mesh cloth can be arranged in the middle of the mortar. The mesh cloth may be a fiberglass mesh cloth.

For the production of the running wall panel 4 in the present application, the present application also prepares a first light high frequency wall panel extruder 1 for producing a first wall panel 41 and a second light high frequency wall panel extruder 2 for producing a second wall panel 42, see fig. 1, 2 and 3. Referring to fig. 1 and 2, a first lightweight high-frequency partition board extruder 1 is added with a vertical trowelling board 12 in a common wall board extruder, two sides of the vertical trowelling board are provided with forming cavities 11, the cross section of the vertical trowelling board 12 is a right triangle, and one side of the inclined plane of the triangle faces to the feeding side. By means of the vertical finishing plate, the first wall plate 41 with the groove 413 in the middle can be directly machined. The second lightweight high frequency partition board extruder 2 adds vertical trowelling plates 22 to the conventional wall board extruder, and no gap is formed on both sides of the vertical trowelling plates, so that a thinner and flat second wall board 42 can be extruded.

The foregoing description is only illustrative of the preferred embodiment of the present invention, and is not to be construed as limiting the invention, but is to be construed as limiting the invention to any simple modification, equivalent variation and variation of the above embodiments according to the technical matter of the present invention without departing from the scope of the invention.

Claims (6)

1. A ceramsite concrete wallboard mounting structure, characterized by comprising:

the ceramsite concrete wallboard mounting structure comprises a wall body, a steel clamping piece, a box body, a fixing plate and a pipeline;

the wall body comprises a plurality of main wallboards and at least one wiring wallboard, wherein each main wallboard and each wiring wallboard are positioned in the same plane, a tenon groove and a tenon are respectively arranged on two sides of the main wallboard and the wiring wallboard along the width direction, and the tenon of one main wallboard and the tenon of one wiring wallboard are spliced in the tenon groove of the other main wallboard and the tenon of the other wiring wallboard;

the wiring wallboard comprises a first wallboard and a second wallboard;

the first wallboard is provided with a groove, a main wall and side walls arranged on two sides of the main wall, and the second wallboard is supported on the two side walls; the second wallboard is connected with the first wallboard, is adhered and fixed on the two side walls through an adhesive and covers the opening of the groove to form a cavity;

the steel clamping piece is fixed on the top plate and is provided with two clamping pieces which are arranged at intervals, and the two clamping pieces are respectively clamped on two sides of the wall body;

the box body is arranged on the wiring wallboard, and the box body part is positioned in the cavity; the box body is arranged on the first wallboard, and the second wallboard is provided with an avoidance port; in a state that the second wallboard is mounted on the first wallboard, the box body extends out of the avoidance port;

the fixing plate is positioned in the cavity and fixedly connected with the wiring wallboard;

and the pipeline is accommodated in the cavity and extends into the box body.

2. The construction method of the ceramsite concrete wallboard mounting structure as set forth in claim 1, comprising:

s1, paying out wall bit lines on the ground according to the wall body position determined by the typesetting diagram, and leading the lines to a ceiling and a side wall;

s2, fixing the steel clamping piece on a concrete structure or a first wallboard;

s3, installing a main wallboard, a wiring wallboard, a box body, pipelines and a fixing plate;

s4, sealing the top and the bottom of the wall;

and S5, adopting mortar to smooth gaps formed between the wallboards.

3. The method of construction of claim 2, wherein the wiring wallboard comprises a first wallboard having grooves and a second wallboard, step S3 comprising:

s31, installing a main wallboard and a first wallboard;

and S32, installing pipelines and a box body on the first wallboard, and covering the second wallboard.

4. A construction method according to claim 3, wherein step S31 comprises:

step S311, uniformly scraping special mortar on one peripheral end part of the first wallboard, aligning the positioning lines up and down, pushing the first wallboard into the steel clamping piece, and splicing the mortises of one of the first wallboard and the adjacent main wallboard with the mortises of the other wallboard;

and S312, driving wood wedges into the upper part and the lower part of the first wallboard and the main wallboard and wedging, and adjusting the verticality and the flatness of the adjacent boards.

5. A construction method according to claim 3, wherein step S32 comprises:

s321, positioning an ink line on a first wallboard, installing a fixed plate, laying a pipeline, and installing a box body;

step S322, a box body position line is sprung out on the second wallboard, and an avoidance port is cut according to the box body position line;

step 323, coating adhesive on the side walls of the two sides of the first wallboard, uniformly scraping mortar on one circle of the second wallboard, and adhering the second wallboard to the first wallboard.

6. The construction method according to claim 2, wherein step S4 includes:

s41, pouring adhesive mortar into the top of the wall body to form a mortar tenon, and filling the bottom of the wall body with dry hard fine stone concrete;

and S42, taking out the wooden wedge after the wall body is installed for a set period of time, and filling the wedge hole with the hard fine stone concrete.