CN215670396U - Passive form is exempted from to tear open heat preservation floor template for building - Google Patents

Abstract

The utility model discloses a non-dismantling heat preservation floor slab template for a passive building, which belongs to the field of buildings and comprises a template main body, wherein steps are arranged on two sides of the bottom of the template main body; chamfers are arranged at the corners of the upper plane and the side surface of the template main body; a groove is formed in the side face of the template main body, close to the step; the side parts of the steps on the two sides of the template main body are respectively provided with a notch and a bulge which are matched with each other, and the two adjacent template main bodies are spliced through the notches and the bulges; holes are formed in the template main body; the utility model can reduce the consumption of reinforcing steel bars and concrete of the floor slab, simplify the construction steps of the floor slab, reduce the construction cost and increase the heat and sound insulation effect of the floor slab; the laying of the pipeline can be facilitated.

Description

Passive form is exempted from to tear open heat preservation floor template for building

Technical Field

The utility model relates to a non-dismantling heat preservation floor slab template for a passive building, and belongs to the technical field of buildings.

Background

In a passive building, the disassembly-free heat-insulating template is a novel building energy-saving and structure-integrated technical system, has the characteristics of good heat-insulating and fireproof performance, safe and reliable quality, simple and convenient design and construction, same service life with a building, convenient construction and the like, and has better social and economic benefits when being popularized and applied.

The existing disassembly-free heat preservation floor slab template has the following problems in actual construction:

1. the concrete consumption is large, and the material cost is high.

2. The existing floor slab template needs formwork support and formwork removal, and construction is complex.

3. The wall plate formed by the existing floor slab template is difficult to lay pipelines.

In view of the above, the prior art is obviously inconvenient and disadvantageous in practical use, and needs to be improved.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problems that the non-dismantling heat preservation floor slab template for the passive building is provided, so that the using amount of reinforcing steel bars and concrete of the floor slab can be reduced, the construction steps of the floor slab are simplified, the construction cost is reduced, and the heat and sound insulation effect of the floor slab is improved; the laying of the pipeline can be facilitated.

In order to solve the technical problems, the utility model adopts the following technical scheme: a non-dismantling heat preservation floor slab template for a passive building comprises a template main body, wherein steps are arranged on two sides of the bottom of the template main body; chamfers are arranged at the corners of the upper plane and the side surface of the template main body; a groove is formed in the side face of the template main body, close to the step;

the side parts of the steps on the two sides of the template main body are respectively provided with a notch and a protrusion which are matched with each other, and the two adjacent template main bodies are spliced through the notches and the protrusions.

Further, be equipped with C type fossil fragments in the template main part, C type fossil fragments are connected as an organic whole with the template main part, C type fossil fragments extend to the other end from the one end of template main part.

Furthermore, the C-shaped keel is an integral structure formed by bending a galvanized steel plate; the C-shaped keel comprises a main plane, and the main plane is vertical to the lower plane of the template main body; horizontal planes are respectively arranged on two sides of the main plane and are perpendicular to the main plane; the end part of the horizontal plane is provided with a bending edge which extends towards the interior of the template main body; the bending edge is perpendicular to the horizontal plane.

Further, the lower plane of the step is flush with the lower plane of the template main body; the template main part and the step are integrally formed, and the template main part and the step are made of EPS heat-insulating materials.

Furthermore, the number of the C-shaped keels is two, and the two C-shaped keels are symmetrically arranged by taking the width center line of the template main body as a reference; two C type fossil fragments opening one side sets up in opposite directions.

Furthermore, through holes are formed in the template main body, and the number of the through holes is one or two; the through hole is arranged between the two C-shaped keels; the through hole extends along the length direction of the template main body.

Further, the horizontal plane of the lower end of the C-shaped keel is flush with the lower plane of the template main body.

Further, the cross sections of the notches and the protrusions are semicircular.

Further, the height of the step is gradually reduced from one end close to the template main body to one end far away from the template main body.

After the technical scheme is adopted, compared with the prior art, the utility model has the following advantages:

the utility model can reduce the consumption of reinforcing steel bars and concrete of the floor slab, simplify the construction steps of the floor slab, reduce the construction cost and increase the heat and sound insulation effect of the floor slab; the laying of the pipeline can be facilitated.

The present invention will be described in detail below with reference to the accompanying drawings and examples.

Drawings

FIG. 1 is a schematic structural view of the present invention;

figure 2 is a schematic view of a C-shaped keel.

In the figure, the position of the upper end of the main shaft,

1-template body, 11-chamfer, 12-groove, 2-C-shaped keel, 21-main plane, 22-horizontal plane, 23-bent edge, 3-through hole, 4-step, 5-notch and 6-bulge.

Detailed Description

In order to more clearly understand the technical features, objects, and effects of the present invention, embodiments of the present invention will now be described with reference to the accompanying drawings.

Example 1

As shown in fig. 1-2, the utility model provides a non-dismantling heat preservation floor slab template for a passive building, which comprises a template main body 1, wherein the template main body 1 is of a cuboid structure, steps 4 are arranged on two sides of the bottom of the template main body 1, and the heights of the steps 4 are gradually reduced from one end close to the template main body 1 to one end far away from the template main body 1; the lower plane of the step 4 is flush with the lower plane of the template main body 1; the template main body 1 and the steps are integrally formed by EPS heat insulation materials.

A chamfer 11 is arranged at the corner of the upper plane and the side surface of the template main body 1; the side surface of the template main body 1 is provided with a groove 12 at a position close to the step 4.

Be equipped with notch 5 and arch 6 of mutually supporting on the both sides step 4 of template main part 1 respectively, the cross-section of notch 5 and arch 6 is the arc, in this embodiment, the cross-section of notch 5 and arch 6 is semi-circular, through notch 5 and arch 6, can splice a plurality of floor templates.

The C-shaped keel 2 is arranged in the template main body 1, the C-shaped keel 2 is connected with the template main body 1 into a whole, and the C-shaped keel 2 extends from one end of the template main body 1 to the other end; the number of the C-shaped keels 2 is two, and the two C-shaped keels 2 are symmetrically arranged by taking the width center line of the template main body 1 as a reference; two C type fossil fragments 2 open-ended one side sets up in opposite directions.

The C-shaped keel 2 is an integral structure formed by bending a galvanized steel sheet; the C-shaped keel 2 comprises a main plane 21, and the main plane 21 is vertical to the lower plane of the template main body 1; horizontal planes 22 are respectively arranged on two sides of the main plane 21, and the horizontal planes 22 are perpendicular to the main plane 21.

The end part of the horizontal plane 22 is provided with a bending edge 23, and the bending edge 23 extends towards the interior of the template main body 1; the bent edge 23 is perpendicular to the horizontal plane 22.

Further, the horizontal plane 22 at the lower end of the C-shaped keel 2 is flush with the lower plane of the formwork body 1.

The template main body 1 is provided with a through hole 3, the through hole 3 is used for placing a water and electricity pipeline, and the through hole 3 is arranged between the two C-shaped keels 2; in this embodiment, the number of the through holes 3 is preferably two, and the two through holes 3 are symmetrically arranged with the width center line of the template main body 1 as a reference; the through-hole 3 extends in the longitudinal direction of the formwork body 1.

According to construction requirements, the number of the through holes can be one, and when one through hole is formed, the diameter of the through hole is correspondingly increased so as to accommodate a thicker pipeline.

The length of the floor slab template can be produced or cut in a fixed length mode according to needs.

The construction method applied in the utility model comprises the following steps:

1. determining the position of the beam, positioning and erecting a template bracket of the beam;

2. installing a floor formwork support;

3. marking positions and positioning according to drawings, and installing a floor slab template;

4. placing steel bars and a steel bar mesh on the floor slab template; when the reinforcing steel bars are placed, corresponding reinforcing steel bars are placed in a gap formed above the step after the two floor slab templates are spliced according to design calculation;

5. pouring concrete;

6. and after the concrete is cured, removing the bracket, and manufacturing a protective layer and a decorative surface layer according to requirements.

The utility model can reduce the consumption of reinforcing steel bars and concrete of the floor slab, simplify the construction steps of the floor slab, reduce the construction cost and increase the heat and sound insulation effect of the floor slab; the laying of the pipeline can be facilitated.

The foregoing is illustrative of the best mode of the utility model and details not described herein are within the common general knowledge of a person of ordinary skill in the art. The scope of the present invention is defined by the appended claims, and any equivalent modifications based on the technical teaching of the present invention are also within the scope of the present invention.

Claims (9)

1. The utility model provides a passive form is exempted from to tear open heat preservation floor template for building which characterized in that: the template comprises a template main body (1), steps (4) are arranged on two sides of the bottom of the template main body (1), and chamfers (11) are arranged on corners of the upper plane and the side surfaces of the template main body (1); a groove (12) is formed in the side surface of the template main body (1) close to the step (4);

the side parts of the steps (4) on the two sides of the template main body (1) are respectively provided with a notch (5) and a protrusion (6) which are matched with each other, and the two adjacent template main bodies (1) are spliced through the notch (5) and the protrusion (6).

2. The disassembly-free heat preservation floor slab template for the passive building as claimed in claim 1, wherein: be equipped with C type fossil fragments (2) in template main part (1), C type fossil fragments (2) are connected as an organic wholely with template main part (1), C type fossil fragments (2) extend to the other end from the one end of template main part (1).

3. The disassembly-free heat preservation floor slab template for the passive building as claimed in claim 2, wherein: the C-shaped keel (2) is of an integral structure formed by bending a galvanized steel plate; the C-shaped keel (2) comprises a main plane (21), and the main plane (21) is vertical to the lower plane of the template main body (1); horizontal planes (22) are respectively arranged on two sides of the main plane (21), and the horizontal planes (22) are vertical to the main plane (21); the end part of the horizontal plane (22) is provided with a bending edge (23), and the bending edge (23) extends towards the interior of the template main body (1); the bending edge (23) is perpendicular to the horizontal plane (22).

4. The disassembly-free heat preservation floor slab template for the passive building as claimed in claim 1, wherein: the lower plane of the step (4) is flush with the lower plane of the template main body (1); the heat-insulating template is characterized in that the template main body (1) and the steps (4) are integrally formed, and the template main body (1) and the steps (4) are made of EPS heat-insulating materials.

5. The disassembly-free heat preservation floor slab template for the passive building as claimed in claim 2, wherein: the number of the C-shaped keels (2) is two, and the two C-shaped keels (2) are symmetrically arranged by taking the width center line of the template main body (1) as a reference; one sides of the openings of the two C-shaped keels (2) are oppositely arranged.

6. The disassembly-free heat preservation floor slab template for the passive building as claimed in claim 5, wherein: through holes (3) are formed in the template main body (1), and the number of the through holes (3) is one or two; the through hole (3) is arranged between the two C-shaped keels (2); the through hole (3) extends along the length direction of the template main body (1).

7. The disassembly-free heat preservation floor slab template for the passive building as claimed in claim 3, wherein: the horizontal plane (22) at the lower end of the C-shaped keel (2) is flush with the lower plane of the template main body (1).

8. The disassembly-free heat preservation floor slab template for the passive building as claimed in claim 1, wherein: the cross sections of the notch (5) and the protrusion (6) are semicircular.

9. The disassembly-free heat preservation floor slab template for the passive building as claimed in claim 1, wherein: the height of the step (4) is gradually reduced from one end close to the template main body (1) to one end far away from the template main body (1).

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