CN221255936U - Roof edge inclined plane component structure - Google Patents

Abstract

The utility model provides a roof edge inclined plane component structure, which relates to the technical field of civil building construction and comprises prefabricated laths, an outer cantilever plate, a first support, a second support and an inclined plane cast-in-situ component, wherein the first support is arranged on the outer cantilever plate, and the first support is provided with an inclined plane; the second support protrudes from the outer wall and is arranged on the outer wall, and the second support is positioned above the first support; the prefabricated lath is obliquely arranged, and two ends of the prefabricated lath are respectively abutted with the first support and the second support, so that a triangular structure is formed among the prefabricated lath, the outer cantilever plate and the outer wall; the steel bars are arranged in the prefabricated laths; the inclined surface cast-in-situ member is connected with the outer wall, is positioned above the prefabricated lath and has the same inclination angle as the prefabricated lath, and the utility model has the advantages of reducing the construction difficulty of the roof inclined surface member, improving the working efficiency and the appearance quality and avoiding the problem that the formwork is difficult to recover when being supported.

Description

Roof edge inclined plane component structure

Technical Field

The utility model relates to the technical field of civil building construction, in particular to a roof edge inclined plane component structure.

Background

In recent years, many civil buildings, especially residential projects, are added with a circle of inclined surface modeling at the edge of a roof to simulate the style of ancient Chinese style buildings in order to improve the overall decoration effect.

The lower half of the ramp member passes over parapet wall and forms a closed triangular area with the extended roof slab and is located outside the exterior wall of the building.

The present inventors found that there are at least the following technical problems in the prior art:

the current roofing edge inclined plane component structure construction degree of difficulty is great, hardly guarantees the roughness on inclined plane, and then influences figurative overall effect, and in addition, confined triangle-shaped region is cavity, and the template is strutted the degree of difficulty and is big, and unable recycle, and economic nature is relatively poor.

Disclosure of utility model

The utility model aims to provide a roof edge inclined plane component structure, which solves the problems that the construction difficulty of the existing roof edge inclined plane component structure is high, the flatness of an inclined plane is difficult to ensure, the overall effect of modeling is affected, in addition, a closed triangular area is hollow, the formwork support difficulty is high, the recycling is impossible, and the economical efficiency is poor. The preferred technical solutions of the technical solutions provided by the present utility model can produce a plurality of technical effects described below.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

The utility model provides a roof edge inclined plane component structure, which comprises prefabricated laths, outer cantilever plates, a first support, a second support and an inclined plane cast-in-situ component, wherein:

The first support is arranged on the outer cantilever plate and is provided with an inclined plane;

the second support protrudes out of the outer wall and is arranged on the outer wall, and the second support is positioned above the first support;

The prefabricated lath is obliquely arranged, and two ends of the prefabricated lath are respectively abutted against the first support and the second support, so that a triangular structure is formed among the prefabricated lath, the outer cantilever plate and the outer wall; the steel bars are arranged in the prefabricated laths;

The inclined surface cast-in-situ member is connected with the outer wall, is positioned above the prefabricated lath and has the same inclination angle with the prefabricated lath.

Preferably, the prefabricated lath comprises a first body and a second body integrally formed, wherein:

the first main body and the second main body are arranged at an obtuse angle.

Preferably, the cross section of the first main body adopts a rectangular structure, and the cross section of the second main body adopts a right trapezoid structure.

Preferably, the cross section of the first support adopts a right trapezoid, and an obtuse angle is formed between an inclined plane of the right trapezoid and the outer cantilever plate.

Preferably, the cross section of the second support is rectangular.

Preferably, the reinforcement bar comprises a first pre-embedded portion, a second pre-embedded portion and a third pre-embedded portion, wherein:

An obtuse angle is formed between the first embedded part and the second embedded part;

the second embedded part and the third embedded part form a right angle;

The first embedded part extends into the first main body, and one end of the second embedded part is connected with the first embedded part and is positioned in the first main body; the other end of the second embedded part extends out of the prefabricated strip plate from the second main body, and the third embedded part is connected to the other end of the second embedded part.

Preferably, a filling layer is also included, said filling layer being interposed between said second support and said prefabricated lath.

Preferably, the filling layer is made of fine stone concrete.

According to the roof edge inclined plane component structure, the prefabricated lath, the outer cantilever plate, the first support, the second support and the inclined plane cast-in-situ component are arranged, the construction form is optimized on the premise of meeting the decoration effect, the inclined plane cast-in-situ component in the area is changed into the prefabricated component by splitting the closed triangular area, two ends of the prefabricated component are connected with the cast-in-situ structure, the shape of the residual cast-in-situ structure is more regular, the formwork support and the concrete construction are more convenient, the inclined plane flatness is easier to control, and when in construction, the construction difficulty of the roof inclined plane component can be reduced, the working efficiency and the appearance quality are improved, and the problem that the formwork support is difficult to recycle is avoided.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of one embodiment of a roof edge ramp member structure of the present utility model;

FIG. 2 is a schematic view of the construction of a prefabricated lath in the construction of the roof edge chamfer member of the present utility model;

Fig. 3 is a schematic view of the structure of the reinforcement of the prefabricated lath in the structure of the roof edge bevel member according to the present utility model.

In the figure: 1. prefabricating the lath; 11. a first body; 12. a second body; 2. an outer cantilever plate; 3. a first support; 31. an inclined plane; 4. a second support; 5. a beveled cast-in-situ component; 6. reinforcing steel bars; 61. a first pre-buried part; 62. a second pre-embedding part; 63. a third pre-embedding part; 7. an outer wall; 8. a filling layer; 9. roof deck floor.

Detailed Description

In order to make the objects, technical solutions and advantages of the present utility model more apparent, the technical solutions of the present utility model will be described in detail below. It will be apparent that the described embodiments are only some, but not all, embodiments of the utility model. All other embodiments, based on the examples herein, which are within the scope of the utility model as defined by the claims, will be within the scope of the utility model as defined by the claims.

The utility model provides a roof edge inclined plane component structure, and fig. 1 is a schematic structural view of the embodiment, and as shown in fig. 1, the roof edge inclined plane component structure comprises prefabricated laths 1, outer cantilever plates 2, a first support 3, a second support 4 and an inclined plane cast-in-situ component 5.

Wherein, the first support 3 is arranged on the outer cantilever plate 2, and the first support 3 is provided with an inclined plane 31; the second support 4 protrudes from the outer wall 7 and is arranged on the outer wall 7, and the second support 4 is positioned above the first support 3; the prefabricated lath 1 is obliquely arranged, and two ends of the prefabricated lath are respectively abutted against the first support 3 and the second support 4, so that a triangular structure is formed among the prefabricated lath 1, the outer cantilever plate 2 and the outer wall 7; the steel bars 6 are arranged in the prefabricated lath 1; the inclined cast-in-situ member 5 is connected with the outer wall 7, is positioned above the prefabricated lath 1, and has the same inclination angle as the prefabricated lath 1.

According to the roof edge inclined surface component structure, the prefabricated lath 1, the outer cantilever plate 2, the first support 3, the second support 4 and the inclined surface cast-in-situ component 5 are arranged, under the premise of meeting the decoration effect, the structural form is optimized, the partial inclined surface cast-in-situ component in the area is changed into the prefabricated component by splitting the closed triangular area, the two ends of the prefabricated component are connected with the cast-in-situ structure, the shape of the residual cast-in-situ structure is more regular, the formwork support and the concrete construction are more convenient, the inclined surface flatness is easier to control, and during construction, the construction difficulty of the roof inclined surface component can be reduced, the working efficiency and the appearance quality are improved, and the problem that the formwork support is difficult to recover is avoided.

As an alternative embodiment, fig. 2 is a schematic structural view of the prefabricated lath in the present embodiment, and as shown in fig. 2, the prefabricated lath 1 includes a first body 11 and a second body 12 integrally formed.

Specifically, the cross section of the first body 11 adopts a rectangular structure, and the cross section of the second body 12 adopts a right trapezoid structure.

Wherein, be the obtuse angle setting between first main part 11 and the second main part 12, during the use, the inclined plane 31 butt of first main part 11 and first support 3, second main part 12 and second support 4 butt are including being obtuse angle and integrated into one piece's first main part 11 and second main part 12 through setting up prefabricated slat, can increase the contact between prefabricated slat 1 and first support 3, the second support 4 to security and stability when improving the use.

As an alternative embodiment, the cross section of the first support 3 is in a right trapezoid shape, and an obtuse angle is formed between the inclined plane of the right trapezoid and the outer cantilever plate 2. The second support 4 has a rectangular cross section.

The first support 3 and the outer cantilever plate 2, the second support 4 and the outer wall 7 in this embodiment are all integrated, so that the overall stability of the roof edge slope structural member structure is better.

As an alternative embodiment, fig. 3 is a schematic structural diagram of the reinforcement bar of the prefabricated lath in this embodiment, and as shown in fig. 3, the reinforcement bar 6 includes a first pre-embedded portion 61, a second pre-embedded portion 62, and a third pre-embedded portion 63.

Wherein, the first embedded part 61 and the second embedded part 62 form an obtuse angle; the second embedded part 62 and the third embedded part 63 form a right angle. The first embedded part 61 extends into the first main body 11, and one end of the second embedded part 62 is connected with the first embedded part 61 and is positioned in the first main body 11; the other end of the second pre-embedded part 62 extends out of the prefabricated lath 1 from the second main body 12, and the third pre-embedded part 63 is connected to the other end of the second pre-embedded part 62.

As an alternative embodiment, a filling layer 8 is also included, the filling layer 8 being interposed between the second support 4 and the prefabricated lath 1. Specifically, the filler layer 8 is made of fine stone concrete.

The construction method of the roof edge inclined plane component structure adopts the roof edge inclined plane component structure and comprises the following steps:

S1: preparation for construction, comprising:

When the top layer of the building is constructed, pouring the roof layer floor 9, the outer cantilever plates 2 and the first support 3 according to requirements, and reserving roof member steel bars;

Manufacturing a prefabricated slat 1, and embedding reinforcing steel bars 6 in the prefabricated slat;

s2: binding reinforcing steel bars of vertical and inclined surface cast-in-situ components of the roof, supporting templates, and pouring concrete;

S3: after the construction of other cast-in-situ structures is completed and the strength requirement is met, respectively placing the two ends of the prefabricated lath 1 on the first support 3 and the second support 4, and sequentially arranging along the edge of the roof, and tightly connecting to form a ring-shaped whole;

S4: filling fine stone concrete at the connection part of the second support 4 and the prefabricated lath 1, vibrating and collecting the surface, wherein the gradient of the collecting surface is consistent with that of the prefabricated lath 1 and the inclined surface cast-in-situ member 5;

S5: and constructing a subsequent leveling layer, a waterproof layer and a decorative layer after curing.

By adopting the construction method of the roof edge inclined plane component structure, the construction form is optimized on the premise of meeting the decoration effect, the partial inclined plane cast-in-situ component in the area is changed into the prefabricated component by splitting the closed triangular area, the two ends of the prefabricated component are connected with the cast-in-situ structure, so that the shape of the residual cast-in-situ structure is more regular, the formwork support and the concrete construction are more convenient, the inclined plane flatness is easier to control, the construction difficulty of the roof inclined plane component can be reduced, the working efficiency and the appearance quality are improved, and the problem that the formwork support is difficult to recover is avoided.

The foregoing is merely illustrative of the present utility model, and the present utility model is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present utility model. Therefore, the protection scope of the present utility model shall be subject to the protection scope of the claims.

Claims (8)

1. A roof edge ramp structure, characterized by: including prefabricated slat, outer cantilever plate, first support, second support and cast-in-place component in inclined plane, wherein:

The first support is arranged on the outer cantilever plate and is provided with an inclined plane;

the second support protrudes out of the outer wall and is arranged on the outer wall, and the second support is positioned above the first support;

The prefabricated lath is obliquely arranged, and two ends of the prefabricated lath are respectively abutted against the first support and the second support, so that a triangular structure is formed among the prefabricated lath, the outer cantilever plate and the outer wall; the steel bars are arranged in the prefabricated laths;

The inclined surface cast-in-situ member is connected with the outer wall, is positioned above the prefabricated lath and has the same inclination angle with the prefabricated lath.

2. A roof edge ramp member structure according to claim 1, wherein: the prefabricated lath includes integrated into one piece's first main part and second main part, wherein:

the first main body and the second main body are arranged at an obtuse angle.

3. A roof edge ramp member structure according to claim 2, wherein: the cross section of the first main body adopts a rectangular structure, and the cross section of the second main body adopts a right trapezoid structure.

4. A roof edge ramp member structure according to any one of claims 1-3, wherein: the cross section of first support adopts right trapezoid, right trapezoid's inclined plane with be the obtuse angle between the outer cantilever plate.

5. A roof edge ramp member structure according to any one of claims 1-3, wherein: the section of the second support is rectangular.

6. A roof edge ramp member structure according to claim 2 or 3, wherein: the steel bar comprises a first embedded part, a second embedded part and a third embedded part, wherein:

An obtuse angle is formed between the first embedded part and the second embedded part;

the second embedded part and the third embedded part form a right angle;

The first embedded part extends into the first main body, and one end of the second embedded part is connected with the first embedded part and is positioned in the first main body; the other end of the second embedded part extends out of the prefabricated strip plate from the second main body, and the third embedded part is connected to the other end of the second embedded part.

7. A roof edge ramp member structure according to any one of claims 1-3, wherein: and a filling layer arranged between the second support and the prefabricated lath.

8. A roof edge ramp member structure according to claim 7, wherein: the filling layer is made of fine stone concrete.