KR101202761B1 - Dome Type Roof - Google Patents

Abstract

PURPOSE: A dome-shaped roof is provided to improve strength and waterproof properties by coating the roof with flame retardant polyurea. CONSTITUTION: A dome-shaped roof comprises multiple triangular structures(100) and cores(200). The triangular structures have core insertion grooves(160). The cores couple the triangular structures to each other. Each core has separation prevention protrusions(210) and separation prevention grooves(220). The separation prevention protrusions are inserted into the core insertion grooves of the triangular structures.

Description

Dome Type Roof

The present invention relates to a domed roof, and more particularly, characterized in the weight of the plurality of triangular structure, the core structure to combine the triangular structure and the configuration of the triangular structure to form a domed roof in the prefabricated dome house A domed roof with improved thermal insulation, non-combustibility and water resistance.

In general, the dome-shaped roof of the dome house is mainly composed of a polyhedron with a icosahedron as a matrix. In particular, the triangular structure used here has a considerable size and weight, which requires a lot of manpower and equipment during construction.

In addition, the triangular structure used in the conventional dome-shaped roof is a structure made by the icosahedron, which is large in size, and a lot of material loss occurs when using a commercially available standard material, and various kinds of equipment are required during construction. Also, the selection of the finishing material is not easy, there is a problem that the selection of the finishing material is narrow.

In addition, the conventional triangular structure plural triangular structures can not be expected to be superior in functionality, such as color, heat insulation and non-combustible, peanut-shaped core is used to combine two or more triangular structures are assembled into a dome roof, peanuts If a core of the shape is used cracks, there is a problem that various defects occur such that the finish material is separated and leaks occur.

With reference to Figure 1 looks at the coupling of the existing triangular structure.

For reference, FIG. 1 is a view showing a domed roof formed by combining a plurality of triangular structures by peanut cores.

As shown in FIG. 1, one side of the triangular structure A (1) and the triangular structure B (2) comes into contact with each other, and the hole 6 formed as the triangular structure A (1) and the triangular structure B (2) come into contact with each other. Peanut core A (3) is inserted and pushed to one end, and then the peanut core B (4) is inserted and pushed to the other end, and finally, the finishing block (5) is the hole (60) By blocking the two triangular structures are combined.

In this case, the slide groove 7 is formed at each side surface of the triangular structure 1 and 2 so that the inserted peanut cores 3 and 4 are pushed in a slide manner and arranged at one side end and the other end.

However, the peanut core (3, 4) portion fitted in the slide groove (7) of the sensory structure is formed to be rounded in a circular shape, the angular deviation is caused by the triangular structure and the play, and due to the movement of the sensory structure to the external finishing material There is a problem that the crack occurs and the departure of the finish material occurs.

Patent Document 1: Republic of Korea Patent Publication 10-0932795 (2009.12.10)

Therefore, the present invention is to make the size of the conventional triangular structure to 1/4 size, widen the selection of the processing material, and the finishing material by the technology that can process the non-combustible vermiculite board and perlite board using styrofoam processing, mold more precisely Its purpose is to provide dome-shaped roofs with improved functions such as crack insulation, water leakage, etc., as well as vulnerable insulation and non-combustibility.

In order to achieve the above object, the domed roof according to the present invention includes a core for coupling a plurality of triangular structures and a plurality of triangular structures in forming a domed roof on the upper part of the wall of the building, a plurality of triangular The core is inserted into the core insertion groove formed on the side of the structure, and the triangular structure includes a column structure composed of any one of styrofoam, glass wool, and rock wool, a mesh attached to the surface of the column structure, vermiculite fine mortar coated on the surface of the mesh, and vermiculite. Polyurea coated on the surface of the fine mortar, and expanded vermiculite thermal insulation mortar coated on the surface of the polyurea, the core is a symmetrical cross-section cross-section, the core insertion groove of the triangular structure bonded to both sides in the longitudinal direction The separation prevention jaw is formed so as to be inserted into the slide method on the separation, the departure prevention jaw is made of an oval structure It is characterized in that the portion corresponding to the long axis of the ellipse is inserted into the core insertion groove 160 in a standing state.

The domed roof according to the present invention has an effect of improving the working efficiency of the worker by making the size of the existing triangular structure 1/4, that is, the size of one worker can easily work, and the coating of mash and non-combustible vermiculite fine mortar It has the effect of improving the nonflammability, and the effect of improving the strength and waterproofing by coating the flame retardant polyurea, and the effect of improving the nonflammability and insulation by spraying the vermiculite nonflammable insulation mortar. .

1 is a view showing a domed roof formed by combining a plurality of triangular structures by peanut cores,
2 is a view in which a plurality of triangular structures constituting the domed roof according to the present invention are coupled in a slide manner by a core;
3 is a view in which a plurality of triangular structures constituting the domed roof according to the present invention are joined in a manner that is twisted by a core;
4 is a view in which a plurality of triangular structures constituting the domed roof according to the present invention are combined in a manner in which a slide method and a pulled method are integrated by a core;
5 is a diagram illustrating a configuration of a triangular structure constituting the domed roof according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concept of the term appropriately in order to describe its own invention in the best way. The present invention should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

2 is a view illustrating a combination of a domed roof and a triangular structure constituting a domed roof by a core according to the present invention.

As shown in FIG. 2, the domed roof according to the present invention includes a plurality of triangular structures 100 and a core 200 coupling the plurality of triangular structures 100.

The domed roof shown in FIG. 2 may be assembled by constructing the triangular structure 100 directly by the core 200 at a construction site, and the five or six triangular structures 100 are hexagonal and hexagonal in combination. The structures may be reassembled and assembled.

Conventional domed roofs have a large triangular structure, so that ten hexagonal structures and six hexagonal structures are combined, but the domed roof according to the present invention reduces the size of the triangular structure 100 for the convenience of the operator. Sixty hexagonal structures and six pentagonal structures are assembled together.

As shown in FIG. 5, the triangular structure 100 includes a column structure 110, which is a selected product, such as an intermediate filling material, thermal insulation styrofoam, glass wool, rock wool, and a mesh 120 coupled to both sides of the column structure 110. , Vermiculite fine mortar 130 is coated on the surface of the mesh 120, polyurea 140 is coated on the surface of the vermiculite fine mortar 130, and expanded vermiculite insulation on the surface of the polyurea 140. Mortar 150 is coated is configured.

The non-flammability of the triangular structure 100 is improved due to the coating of the mash 120 and the non-combustible vermiculite fine mortar 130, and the polyurea 140 has a thickness of 2 mm to 3 mm and the vermiculite fine mortar 130. Due to the coating and lamination thereon, the strength and waterproofing function of the triangular structure 100 are improved, and finally, as the expanded vermiculite non-combustive mortar 150 is sprayed and stacked with a thickness of 3 mm to 10 mm, non-combustibility and thermal insulation are improved. .

More detailed description of the above-described configuration constituting the triangular structure 100, the polyurea 140 is a heat insulating material, but also excellent thermal conductivity, shrinkage expansion is superior to color steel sheet, crack prevention, waterproof, strength reinforcement and impact Absorption may be performed at the same time. In particular, in relation to shock absorption, the polyurea 140 has a high shock absorption rate and thus does not have deformation even in a strong impact, and thus has excellent coating effect on a portion of the filling.

In addition, the expanded vermiculite non-combustible thermal insulation mortar 150 may be an environmentally friendly material that prevents condensation and radiant heat, as well as air purification.

Meanwhile, it is preferable that a core insertion groove 160 is formed at an edge portion of the triangular structure 100, as the core insertion groove 160 is formed so that the plurality of triangular structures 100 are in contact with each other. This is because the core insertion hole 300 into which the core 200 can be inserted is formed.

That is, as shown in Figure 2, the two triangular structure 100 is a pair of the triangular structure by inserting the core 200 in a slide manner into the core insertion groove 300 formed by contacting one side surfaces ( 100) will be combined.

In this case, the core 200 inserted into the core insertion groove 160 in a slide manner has a symmetrical structure in cross section, and both ends thereof are inserted into the core insertion groove 160 so as to be caught from the triangular structure 100. A departure prevention jaw 210 to prevent the departure is to be formed.

In addition, the core 200 has a separation prevention groove 220 is formed between the center, that is, the separation prevention jaw 210 in order to compensate for cracks generated due to rotation of the combined triangular structure 100, angle deviation, and the like. It is preferable that it is done.

The departure preventing groove 220 is also applied to other embodiments described later.

In order to minimize the departure from the triangular structure 100, the separation prevention jaw 210 is formed in an elliptical structure instead of a conventional circular structure, and at this time, a portion corresponding to the long axis of the ellipse is erected. The insertion groove 160 is to be inserted.

In another embodiment, the triangular structure 100 is characterized in that coupled to the core 200 in a twisted manner.

That is, as shown in FIG. 3, the core 200 is positioned between the two triangular structures 100, and the triangular structure 100 is coupled in a manner of being squashed on both sides of the core 200.

At this time, in the present embodiment, the core 200 has a symmetrical structure in cross section, but the separation prevention jaw 210 formed at the left and right side ends is formed to have a rounded outer side to facilitate the twisting of the combined triangular structure 100. And, it is characterized in that the inner side is formed to be angled to minimize the departure of the combined triangular structure (100).

As another embodiment, the triangular structure 100 is characterized in that the core 200 and the slide method and the twisting method is applied in a complex manner to apply both.

That is, as shown in FIG. 4, first, the core 200 is inserted into the core insertion groove 160 of the triangular structure 100 by a deviation preventing jaw 210 of one side end thereof in a slide manner. When combined with, then the other triangular structure 100 is coupled in a manner that is pulled on the departure prevention jaw 210 of the other end.

At this time, in the present embodiment, the core 200 has a cross-sectional asymmetric structure unlike the above-described embodiments, and more specifically, the separation prevention jaw 210 formed at one end of the core inserted in the slide method is first. As described in the second embodiment, the elliptical structure is formed, and the separation prevention jaw 210 formed at the other end of the core coupled to the triangular structure 100 in a twisted manner is easy to be twisted as described in the second embodiment. The inner side is formed to be rounded, the inner side is angled to minimize the departure of the triangular structure 100 coupled in a twisted manner.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that various modifications and changes may be made without departing from the scope of the appended claims.

100: triangular structure 110: column structure
120: mash 130: vermiculite fine mortar
140: polyurea 150: expanded vermiculite thermal insulation mortar
160: core insertion groove
200: core 210: release prevention jaw
220: departure prevention groove
300: insertion hole

Claims (7)

In forming a domed roof on the upper part of the wall of the building,
A plurality of triangular structures 100; And
Includes a departure prevention groove 220, core 200 for coupling the plurality of triangular structure (100),
The core 200 is inserted into a core insertion groove 160 formed on a side of the triangular structure 100,
The core 200 has a symmetrical structure in cross section, and a separation prevention jaw 210 is formed to be inserted into and hung in the core insertion groove 160 of the triangular structure 100 coupled to both sides in a longitudinal direction.
The separation prevention jaw 210 is made of an elliptical structure, the dome-shaped roof, characterized in that inserted into the core insertion groove 160 in a state in which a portion corresponding to the long axis of the ellipse is standing.
The method of claim 1,
The triangular structure 100
Styrofoam, glass wool, rock wool, any one of the pillar structure 110;
A mesh 120 attached to a surface of the pillar structure 100;
Vermiculite fine mortar 130 coated on the surface of the mash 120;
Polyurea 140 is coated on the surface of the vermiculite fine mortar 130; And
Domed roof comprising a; expanded vermiculite thermal insulation mortar (150) coated on the surface of the polyurea (140).
delete delete delete In forming a domed roof on the upper part of the wall of the building,
A plurality of triangular structures 100; And
Includes a departure prevention groove 220, core 200 for coupling the plurality of triangular structure (100),
The core 200 is inserted into a core insertion groove 160 formed on a side of the triangular structure 100,
The core 200 has a symmetrical structure in cross section, and a separation prevention jaw 210 is formed to be inserted and caught in the core insertion groove 160 of the triangular structure 100 coupled to both sides in a longitudinal direction. ,
The departure prevention jaw 210 is formed in the outer side is rounded to help the coupling of the triangular structure, the domed roof, characterized in that the inner side is formed to be angled to prevent the departure.
In forming a domed roof on the upper part of the wall of the building,
A plurality of triangular structures 100; And
Includes a departure prevention groove 220, core 200 for coupling the plurality of triangular structure (100),
The core 200 is inserted into a core insertion groove 160 formed on a side of the triangular structure 100,
The core 200 has a cross-sectional asymmetrical structure, and is inserted into the core insertion groove 160 of the triangular structure 100 coupled to both sides in the longitudinal direction so as to be inserted in a sliding manner and a twisted manner so as to have a different structure at both ends. Departure prevention jaw 210 is formed,
One side of the departure prevention jaw 210 is formed to be rounded on the outside to help the coupling of the triangular structure 100, the inner side is formed to be angled to prevent the departure,
The other side of the release prevention jaw 210 is made of an elliptical structure, dome-shaped roof, characterized in that the structure is inserted into the core insertion groove 160 in a state corresponding to the long axis of the ellipse is standing.

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