KR101963665B1 - Method for constructing structure by using mesh and mortar - Google Patents

Abstract

The present invention relates to a method of constructing a structure using a mesh and a mortar, which can overcome the disadvantages of existing steel structures and reinforced concrete works. The structure construction method is characterized in that a first spacer located between a first insulation material and a second insulation material is spaced apart from the first insulation material and a second insulation material so that a second space is formed at an upper portion of the first insulation material or the second insulation material Producing a unitary insulation block in which a third spacer is positioned below the first insulation material or the second insulation material; Forming a group of heat insulating blocks by arranging the unit heat insulating blocks laterally in parallel; Installing molds on top and bottom of the group of heat insulating blocks; Injecting mortar into a first space between the first insulation and the second insulation, a second space between the first insulation and the second insulation and the mold; Removing the mold after the mortar has hardened; Wherein in the group of heat insulating blocks, the first space and the second space communicate with each other.
According to this configuration, a structure construction method excellent in durability, vibration resistance, and fire resistance is provided while drastically reducing the construction period and construction cost compared to the existing reinforced concrete structure or steel frame structure, reducing the weight of the structure, improving the heat insulation performance can do.

Description

{METHOD FOR CONSTRUCTION STRUCTURE BY USING MESH AND MORTAR}

The present invention relates to a method of constructing a structure using a mesh and a mortar, which can overcome the disadvantages of existing steel structures and reinforced concrete works.

Generally, a structural or reinforced concrete structure is used as a structural member for constructing a skeleton in construction or civil engineering work.

The steel structure is a structure in which a steel plate and various sections are assembled by a joining method such as rivet, bolt, and welding. The steel structure has a high strength, a constant shape and size, a high safety and reliability of the joint, and an advantage of constructing a long span structure. However, it has a weak point in heat and preservation.

The reinforced concrete structure combines the compressive performance of concrete with the tensile performance of reinforcing bars. The reinforced concrete structure has advantages of durability, vibration resistance, fire resistance and freedom of design, but it has a disadvantage of long air, high construction cost, and heavy weight.

A new structure construction method which is excellent in heat insulation performance and has durability, vibration resistance, fire resistance, weight reduction, construction period and construction cost is required instead of the conventional steel structure or reinforced concrete structure which is generally used.

Korean Patent Registration No. 10-1020652

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a method of manufacturing a reinforced concrete structure or a steel frame structure that significantly reduces construction time and construction cost, And a method for constructing a structure excellent in fire resistance.

The method for constructing a structure according to the present invention for realizing the above object is characterized in that the first insulation material and the second insulation material are separated from each other by a first spacer positioned between the first insulation material and the second insulation material, Or a second space is located on top of the second insulation, and a third spacer is positioned below the first insulation or the second insulation; Forming a group of heat insulating blocks by arranging the unit heat insulating blocks laterally in parallel; Installing molds on top and bottom of the group of heat insulating blocks; Injecting mortar into a first space between the first insulation and the second insulation, a second space between the first insulation and the second insulation and the mold; Removing the mold after the mortar has hardened; Wherein in the group of heat insulating blocks, the first space and the second space communicate with each other.

Further, in the unit heat insulating block, a mesh is disposed between the first heat insulating material and the second heat insulating material, the upper part of the first heat insulating material or the second heat insulating material, the first heat insulating material or the lower part of the second heat insulating material.

The mortar is compounded with a fiber reinforcing material.

Further, after the mold is removed, the mortar is continuously formed so as to have a truss shape or a lattice shape in cross section cut along the arrangement direction of the unit heat insulating blocks.

The unitary heat insulating block for constructing the structure according to another embodiment of the present invention includes: a first heat insulating material; A second heat insulator disposed to face the first heat insulator; A first spacer positioned between the first heat insulator and the second heat insulator such that the first heat insulator and the second heat insulator are spaced apart from each other; A second spacer positioned above the first insulation or the second insulation; A third spacer positioned below the first insulation or the second insulation; .

The first spacer may include a first insertion portion and a second insertion portion formed to be sharp at both ends and a separation portion connecting the first insertion portion and the second insertion portion, And the second inserting portion is inserted into the second insulating material.

The second spacer includes a sharp third insertion portion and a third extension portion extending to face the third insertion portion. The third spacer includes a sharp fourth insertion portion, And a fourth extending portion extending opposite to the insertion portion.

A mesh positioned between the first heat insulator and the second heat insulator, the upper portion of the first heat insulator or the second heat insulator, the first insulator or the lower portion of the second insulator; And the mesh is supported by the first spacer, the second spacer, and the third spacer.

According to another aspect of the present invention, there is provided a spacer for use in construction, comprising: a circular first body portion having a first opening formed at a center thereof and having a predetermined thickness; and a second body portion extending integrally with the first body portion, A first insert having a pointed first pointed portion; A second insertion portion having a circular second body portion having a second opening formed at the center and having a predetermined thickness and a second forward end portion extending integrally with the second body portion and having a pointed end; A separating portion including a first fitting portion fitted in the first opening, a second fitting portion fitted in the second opening, and a connecting portion connecting the first fitting portion and the second fitting portion; .

According to the present invention, there is provided a method of constructing a structure excellent in durability, vibration resistance and fire resistance while drastically reducing the construction period and construction cost, reducing the weight of the structure and improving the heat insulation performance, compared with the existing reinforced concrete structure or steel structure can do.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a structure constructed according to a method of constructing a structure according to an embodiment of the present invention; FIG.
FIG. 2 is a view showing a unit insulation block according to an embodiment of the present invention. FIG.
Fig. 3 is a view showing a state in which the unit heat-insulating blocks of Fig. 2 are arranged side by side on a mold. Fig.
FIG. 4 is a schematic view showing a state in which a mortar is laid in FIG. 3; FIG.
5 is a view showing a first spacer according to an embodiment of the present invention.
6 is a view showing a second spacer according to an embodiment of the present invention.
7A to 7E are views sequentially illustrating a method of constructing a structure according to another embodiment of the present invention.
8A to 8C are views showing various types of structures according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, like reference numerals refer to like elements throughout. The same reference numerals in the drawings denote like elements throughout the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a structure constructed according to a method of constructing a structure according to an embodiment of the present invention; FIG. FIG. 2 is a view showing a unit insulation block according to an embodiment of the present invention. FIG. Fig. 3 is a view showing a state in which the unit heat-insulating blocks of Fig. 2 are arranged side by side on a mold. Fig. FIG. 4 is a schematic view showing a state in which a mortar is laid in FIG. 3; FIG. 5 is a view showing a first spacer according to an embodiment of the present invention. 6 is a view showing a second spacer according to an embodiment of the present invention.

The method of constructing a structure according to an embodiment of the present invention can be used for construction of a building or civil structure.

2, the unit insulating block 100 includes a first insulating material 110, a second insulating material 120, first through third spacers 130, 140, and 140, and a mesh 160. do.

The first heat insulator 110 and the second heat insulator 120 are disposed facing each other. The first heat insulator 110 and the second heat insulator 120 may have various shapes such as a sphere, a polyhedron, and a curved surface. The first heat insulator 110 and the second heat insulator 120 are preferably bead insulators with flame retardant performance. In this embodiment, the first heat insulating material 110 and the second heat insulating material 120 have the same shape, but the first heat insulating material 110 and the second heat insulating material 120 may have different shapes.

The first to third spacers 130, 140 and 150 serve to determine the thickness of the mortar 20 while fixing the insulator and the mesh 160 in the mold 10. [

The first spacer 130 is positioned between the first insulation 110 and the second insulation 120 such that the first insulation 110 and the second insulation 120 are spaced apart.

Referring to FIG. 5, the first spacer 130 includes a first inserting portion 131 inserted into the first insulator 110, a second inserting portion 132 inserted into the second insulator 120, And a spacing part 133 connecting the first insertion part 131 and the second insertion part 132.

The first insertion portion 131 may include first body portions 131a, 131b and 131c and first tip portions 131d and 131e.

The first body parts 131a, 131b and 131c are formed in a circular shape having a predetermined thickness and having a first opening at the center. In the present embodiment, the first body portions 131a, 131b and 131c include a ring-shaped portion 131a for forming an opening, a plurality of support portions 131b radially extending from the ring-shaped portion 131a, And a ring-shaped circular portion 131c connecting the ring portion 131b.

The ring-shaped portion 131a has a step portion 131a 'on the inner side. The front portion of the ring-shaped portion 131a is extended in the front than the rear portion of the step portion 131a'. That is, the diameter of the opening formed by the ring-shaped portion 131a is formed to be slightly larger forward than the rear portion with respect to the step 131a '. Here, the forward direction refers to the direction in which the first leading ends 131d and 131e are located.

The first prongs 131d and 131e are formed integrally with the first body parts 131a, 131b and 131c to extend forward and have a sharp end so as to penetrate the first object. For example, the first prongs 131d and 131e have rod portions 131d integrally formed with the support portions 131b and extending forward, and a pointed end portion integrally formed with the rod portions 131d. And a portion 131e. The pointed portion 131e may be formed by combining a plurality of protruding portions 131e 'that are reduced in section in the forward direction. The protrusion 131e 'protrudes outside the rod portion 131d. When the first inserting portion 131 is inserted into the first insulator 110, the protrusion 131e 'is supported by the first insulator 110 so that the first inserting portion 131 is moved backward Thereby effectively preventing movement.

The second insertion portion 132 includes second body portions 132a, 132b and 132c and second tip portions 132d and 132e. The second inserting portion 132 has the same configuration as the first inserting portion 131.

The second body portions 132a, 132b and 132c are formed in a circular shape having a predetermined thickness and having a second opening at the center. The second body portions 132a, 132b, and 132c are formed of a ring-shaped portion 132a, a plurality of support portions 132b, and a circular portion 132c. The ring-shaped portion 132a has a step portion 132a 'on the inner side. The first prongs 132d and 132e may be composed of a rod portion 132d and a beak 132e.

The spacing part 133 includes a first fitting part 133a inserted into the first opening of the first body part 131a 131b 131c and a second fitting part 133b integrally formed with the first fitting part 133a, A second portion 133b having a wide cross section and a third portion 133c extending rearward from the second portion 133b in a sectional area smaller than that of the second portion 133b and a second body portion 132b, And a fourth portion 133e integrally formed with the second fitting portion 133d and having a wider cross section than the second opening 133d. The second portion 133b, the third portion 133c and the fourth portion 133e may be referred to as a connecting portion that connects the first fitting portion 133a and the second fitting portion 133d.

The first fitting portion 133a and the second fitting portion 133d have the same configuration. When the head is inserted into the opening of the second inserting portion 132, the head portion is compressed and enters the opening, and then the step portion 132a 'is inserted into the second inserting portion 133d. The area of the head can be enlarged. Accordingly, the head is supported by the step portion 132a 'so that the spacing portion 133 can not be moved backward even if an external force is applied. A cutout 133d 'may be formed in the second fitting portion 133d in the lateral direction so that the head portion can be compressed. When the head is subjected to the pressure, the two heads divided by the cutout 133d 'are contracted toward the cutout 133d' so that they can pass through the cutout 133d '.

The second spacer 140 is positioned on the upper side of the first heat insulating material 110 or the second heat insulating material 120 so that the upper surface of the first insulating material 110 or the upper surface of the second heat insulating material 120 . The third spacer 150 is positioned below the first heat insulating material 110 or the second heat insulating material 120 so that the lower surface of the first insulating material 110 or the second heat insulating material 120 .

Referring to FIG. 6, the second spacer 140 includes a sharp third insertion portion 141 and a third extension portion 142 extending to face the third insertion portion 141.

The third insertion portion 141 may include third body portions 141a, 141b and 141c and third tip portions 141d and 141e. The third inserting portion 141 has the same configuration as the first inserting portion 131.

The third insertion portion 141 includes third body portions 141a, 141b and 141c and third tip portions 141d and 141e. The third body portions 141a, 141b, and 141c are formed of a ring-shaped portion 141a, a plurality of support portions 141b, and a circular portion 141c. The ring-shaped portion 141a has a step portion 141a 'on its inner surface. The third prongs 141d and 141e may be composed of a rod 141d and a beak 141e.

The third extended portion 142 includes a first portion 142a that is inserted into the opening of the third body portion 141a, 141b, and 141c, and a second portion 142b that is integrally formed with the first portion 142a and has a wider cross- A second portion 142b and a third portion 142c extending rearward from the second portion 133b in a reduced cross-sectional area than the second portion 133b. The first part 142a and the second part 142b have the same configuration as the first part 133a and the second part 133b shown in FIG.

The third spacer 150 has the same configuration as the second spacer 140. Accordingly, the third spacer 150 includes a fourth insertion portion having a sharp point and a fourth extension portion extending to face the fourth insertion portion.

2, the mesh 160 may be disposed between the first insulation 110 and the second insulation 120, the top of the first insulation 110 or the second insulation 120, the first insulation 110, Is located at the bottom of the secondary insulation (120). Mesh 160 can be made of plastic, glass fiber, or metal.

The meshes 160 may be connected to each other in the unit heat insulating block 100, or a plurality of meshes 160 may be separately installed. The mesh 160 prevents cracking of the mortar 20 to be installed later and enables a firm coupling.

The mesh 160 may be supported by the first to third spacers 130, 140 and 150. The mesh 160 can be supported by the spacing part 133 by inserting the spacing part 133 into the opening while the mesh 160 is placed on the opening of the first body parts 131a, 131b and 131c. The position at which the mesh 160 is supported between the first heat insulator 110 and the second heat insulator 120 can be adjusted by adjusting the thicknesses of the first body portions 131a, 131b, and 131c.

The mesh 160 can be supported by the third extension 142 by inserting the third extension 142 into the opening in the state where the mesh 160 is placed over the openings of the third bodies 141a, 141b, and 141c . It is possible to adjust the position where the mesh 160 is supported between the upper portion of the first insulation material 110 or the second insulation material 120 and the mold 10 by adjusting the thickness of the third body portions 141a, 141b, have.

As shown in FIG. 3, in order to construct the structure, the unitary heat insulating blocks 100 are arranged side by side to form a heat insulating block group. At this time, adjacent unit heat insulating blocks 100 may be arranged in the same direction or in different directions. If necessary, the unit insulation block 100 may be further arranged in the vertical direction.

The mold 10 is installed on the upper and lower sides of the heat insulating block group, that is, the unit heat insulating block 100 arranged side by side. Thereafter, a mortar 20 (20) is inserted into a first space between the first insulation material 110 and the second insulation material 120, and a second space between the first insulation material 110 and the second insulation material 120 and the mold 10 ). The mortar 20 is obtained by kneading cement and sand with water, and other additives may be mixed.

Since the first space and the second space are communicated with each other in the group of the heat insulating blocks, the mortar 20 can be entirely injected into the heat insulating block group by one injection using high pressure. If necessary, a plurality of holes may be formed in the mold 10, and the mortar 20 may be injected through these holes.

After the mortar 20 hardens, the mold 10 is removed. The thickness of the mortar 20 formed along the length of the first to third spacers 130, 140 and 150 can be adjusted.

The mortar 20 from which the mold 10 has been removed is formed as a whole in a truss shape or a lattice shape in cross section cut along the arrangement direction of the unit heat insulating blocks (see Figs. 8A to 8C). The truss or lattice is structurally proven in terms of strength and safety and is designed to have the strength of a steel structure or a reinforced concrete structure as a structure of the present invention formed by a unitary insulating block 100, a mesh 160 and a mortar 20 To achieve this.

According to the method for constructing a structure of the present invention, it is possible to improve the heat insulating performance by the heat insulating material, to construct the long span structure having the durability, the earthquake resistance and the fire resistance of the steel structure or the reinforced concrete structure, Compared with the structure, the construction period and the construction cost can be reduced while reducing the load of the structure.

In addition, the method of constructing a structure of the present invention is capable of manufacturing a mold frame of a conventional method only by simple training, and by providing a heat block at a factory and supplying it to the construction site, the construction period and the construction cost are remarkably improved When the mold 10 is removed, the walls or slabs are made of mortar so that additional finishing work is not required.

FIG. 1 illustrates a structure 500 constructed according to a method of constructing a structure of the present invention. Such a structure may include pillars 510, beams 520, bottoms or slabs 530, walls, and the like.

The unit heat insulating block 100 is formed of the first heat insulating material 110 and the second heat insulating material 120. The unit heat insulating block 100 may be formed of a material other than the first heat insulating material 110 and the second heat insulating material 120 A plurality of first heat insulating materials 110 and a plurality of second heat insulating materials 120 may be combined.

7A to 7E are views sequentially illustrating a method of constructing a structure according to another embodiment of the present invention. In this embodiment, the mesh 160 is not provided in the unit heat insulating block 100, but a fiber reinforcing material is mixed in the mortar 20 instead of the mesh 160. This embodiment can be used when it is difficult to install the mesh 160 according to the shape of the unit heat insulating block 100.

7A, the first heat insulating material 110 and the second heat insulating material 120 are separated from each other by the first spacer 130 positioned between the first heat insulating material 110 and the second heat insulating material 120, A second space 140 is positioned above the heat insulating material 110 or the second heat insulating material 120 and a unit where the third spacers 150 are located below the first heat insulating material 110 or the second heat insulating material 120 The heat insulating block 100 is manufactured. No mesh is installed in the unit insulation block 100.

Referring to FIG. 7B, the unitary heat insulating blocks 100 are laterally arranged in parallel to form a heat insulating block group.

Referring to FIG. 7C, molds 10 are installed on the upper and lower sides of the heat insulating block group.

7D, a first space between the first insulating material 110 and the second insulating material 120, a second space between the first insulating material 110 and the second insulating material 120 and the mold 10, The mortar 20 is injected. In the group of heat insulating blocks, the first space and the second space communicate with each other.

The mortar 20 is compounded with a fiber reinforcing material. Fiber reinforcement is a substitute for mesh, and is generally used in construction or civil engineering fields such as nylon fiber, PVA fiber, and polypropylene fiber. The fiber reinforcement prevents cracking of the mortar 20 and allows for a rigid bond. The mortar 20 of this embodiment can be used when it is difficult to provide a mesh to the unit heat insulating block 100.

Referring to FIG. 7E, after the mortar 20 hardens, the mold 10 is removed.

The structure construction method of this embodiment uses a mortar 20 in which a fiber reinforcing material is incorporated instead of a mesh, and can have the same effect as the embodiment of FIGS. 2 to 4.

8A to 8C are views showing various types of structures according to an embodiment of the present invention.

In the structure 200 of FIG. 8A, the heat insulating material 210 has a triangular section in cross section, and the mortar 220 has a truss shape as a whole.

In the structure 300 of FIG. 8B, the heat insulating material 310 has a rectangular cross-section, and the mortar 320 has a lattice shape as a whole. In the present invention, the grid shape means a structure in which rectangular shapes are continuously combined between the upper side and the lower side.

8C. In the structure 400, the heat insulating material 410 has a shape in which the honeycomb structure is combined, and the mortar 420 is entirely truss-shaped. Generally, a truss structure refers to a structure in which a straight rod is assembled into a triangle. In the present invention, a truss shape refers to a structure in which one or more polygonal shapes are continuously combined between an upper side and a lower side.

As described above, in the structure construction method of the present invention, the heat insulating material can have various shapes and is not limited to a specific shape. In this structure construction method, unit heat insulating blocks which are not limited to a special shape are arranged side by side, and the space between the heat insulating material and the space between the heat insulating material and the mold is communicated to inject the mortar into the space therebetween. Accordingly, the structure construction method of the present invention is capable of constructing a structure having excellent heat insulation performance while reducing the load of the structure, reducing the construction period and construction cost while having the advantages of the steel structure and the reinforced concrete structure.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention will be.

10: mold
20: Mortar
100: Unit insulation block
110: Primary insulation
120: Secondary insulation
130: first spacer
131: first insertion portion
132:
133:
133a: first fitting portion
133d: second fitting portion
133b, 133c, and 133e:
140: Second spacer
141: third insert
142: third extension part
150: third spacer
151: fourth insertion portion
152: fourth extension part
160: Mesh

Claims (9)

In the structure construction method,
The second space is positioned above the first insulation or the second insulation while the first insulation is separated from the second insulation by the first spacer located between the first insulation and the second insulation, Or a unitary insulation block in which a third spacer is located at the bottom of the second insulation;
Forming a group of heat insulating blocks by arranging the unit heat insulating blocks laterally in parallel;
Installing molds on top and bottom of the group of heat insulating blocks;
Injecting mortar into a first space between the first insulation and the second insulation, a second space between the first insulation and the second insulation and the mold;
Removing the mold after the mortar has hardened;
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Wherein the first space and the second space communicate with each other in the heat block group. The method according to claim 1,
In the unit heat insulating block,
Wherein a mesh is positioned between the first heat insulator and the second heat insulator, the upper portion of the first heat insulator or the second heat insulator, and the lower portion of the first heat insulator or the second heat insulator. The method according to claim 1,
Wherein the mortar is compounded with a fiber reinforcing material. The method according to claim 1,
Wherein after the mold is removed, the mortar is continuously formed in a truss shape or a lattice shape on the cross section cut along the arrangement direction of the unit heat insulating blocks. A unitary heat insulating block for constructing a structure,
First insulation;
A second heat insulator disposed to face the first heat insulator;
A first spacer positioned between the first heat insulator and the second heat insulator such that the first heat insulator and the second heat insulator are spaced apart from each other;
A second spacer positioned above the first insulation or the second insulation;
A third spacer positioned below the first insulation or the second insulation;
And a unit insulation block for constructing a structure including the unit insulation block. 6. The method of claim 5,
Wherein the first spacer includes a first insertion portion and a second insertion portion formed to be sharp at both ends and a spacing portion connecting the first insertion portion and the second insertion portion,
Wherein the first inserting portion is inserted into the first heat insulating material, and the second inserting portion is inserted into the second heat insulating material. The method according to claim 6,
The second spacer includes a sharp third insertion portion and a third extension portion that extends to face the third insertion portion,
Wherein the third spacer includes a sharp fourth formed insert and a fourth extended portion extending opposite to the fourth inserted portion. 6. The method of claim 5,
A mesh positioned between the first insulation and the second insulation, the top of the first insulation or the second insulation, the first insulation or the bottom of the second insulation;
Further comprising:
Wherein the mesh is supported by the first spacer, the second spacer, and the third spacer. delete

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