KR101293407B1 - A large size artificial rock manufacturing method - Google Patents

Abstract

PURPOSE: A construction method for large artificial rock is provided to increase the structural strength and stability of artificial rock by interior reinforcement material and a second crude steel reinforcement and prevent the corrosion of integrated configuration elements and hardened molding material (or concrete). CONSTITUTION: A construction method for large artificial rock comprises following eight steps. A first step installs an angle (10) on a structure (S) by using an anchor bolt. A second step fixes a first crude steel reinforcement (20) of a lattice form to be isolated with a certain distance from the structure. A third step arranges a metal net (30) at a front side or a rear side of the first crude steel reinforcement and binds the first crude steel reinforcement and metal net with a binding wire. A fourth step fixes interior reinforcement material (40) of a lattice form to the angle and installs the interior reinforcement material to be isolated with a certain distance towards a front of the metal net. A fifth step fixes a second crude steel reinforcement (50) to the angle to be isolated with a certain distance from a front side of the interior reinforcement material. A sixth step fixes one side of an I-form reinforcement steel (60) to the first crude steel reinforcement and fixes the other side to the second crude steel reinforcement. A seventh step fixes one side of a X-type reinforcement steel (70) to the angle and fixes the other side to the second crude steel reinforcement. An eighth step implements the shape and color of the artificial rock by repeating the spraying and curing of molding material (80) in a front of the second crude steel reinforcement.

Description

A Large Size Artificial Rock Manufacturing Method

The present invention relates to a synthetic rock construction method of a large structure, and more particularly to a synthetic rock construction method of a large structure that can improve the structural stability.

In recent years, the urban environment is being improved by forming an artificial composition in order to make the city feel the natural environment.

Artificial composition is not a natural composition, but by artificially creating the surface of artificial waterfalls and artificial rocks, which is intended to satisfy modern people's visual satisfaction, and such artificial compositions have recently been introduced to various amusement parks and other modern It is widely established in buildings and streets.

In particular, the artificial rock of the artificial composition is similar to the natural rock to the extent that it is difficult to distinguish the general public in terms of texture and color, volume, and strength.

Therefore, artificial rock is commonly used for rock climbing, such as artificial rock climbing or artificial waterfall for improving the environment of roads, which is recently spotlighted as a hobby.

Since artificial rock is very effective in creating a resting place for urban people who are difficult to encounter nature in the urbanized society of concrete civilization, it is rapidly spreading to zoos, fountains, swimming pools, ponds, etc. Situation.

However, the conventional artificial rock has a problem in that its structural strength is low or the components of the molding material constituting the artificial rock are not suitable, so that cracks are generated or various reinforcing bars serving as skeletons of the artificial rock are easily corroded.

Application No .: 10-2010-0111647, Application Date: November 10, 2010, Applicant (patent holder): Deukil Kim, Name of invention: Durable artificial rock manufacturing method

The present invention has been made to solve the above problems of the prior art, it is possible to improve the structural stability of the artificial rock as well as to prevent the corrosion of various steel materials required to form the shape of the artificial rock The purpose is to provide an artificial rock construction method.

Artificial rock construction method of a large structure according to the present invention for solving the above problems is the first step of installing an angle to the structure using the anchor bolt; A second step of fixing the first shaped reinforcing bar in a lattice shape to the angle to be spaced apart from the structure by a predetermined distance; A third step of disposing a metal mesh on the front side or the rear side of the first steel reinforcing bar and binding the first steel bar and the metal net by a binding line; A fourth step of fixing the internal reinforcing material having a lattice form at the angle, and installing the internal reinforcing material at a predetermined distance from the front side of the metal mesh; A fifth step of fixing the second model reinforcing bars having a lattice shape to the angle to be spaced apart at a distance in front of the internal reinforcing material; A sixth step of fixing one end of the I-shaped reinforcing bar to the first steel bar and the other end to the second steel bar; A seventh step of fixing one end of the X-shaped reinforcing bar to the angle and the other end of the X-shaped reinforcing bar; And an eighth step of realizing the shape and color of the artificial rock by repeatedly repeating the injection and curing of the molding material in front of the second steel reinforcing bar.

Here, in the eighth step, two kinds of molding materials are sprayed and cured. The first sprayed molding materials are 38 to 48% by weight of cement, 5 to 15% by weight of limestone, 28 to 33% by weight of silica sand, and iron oxide pigments. 1-3 wt%, moldine 1-2 wt%, water 10-15 wt%, water reducing agent 0.3-0.5 wt%, pump aid 0.3-0.5 wt%, polypropylene fiber 2-5 wt%, high strength PVA fiber 2 ~ 5% by weight, glass fiber 2-3% by weight, the second molding material sprayed on the upper surface of the first injection molding material is 45-55% by weight of cement, 20-30% by weight of silica sand, 5 ~ limestone 15 wt%, polypropylene fiber 2-5 wt%, high strength PVA fiber 2-5 wt%, water 10-15 wt%, moldine 1-2 wt%, iron oxide pigment 1-3 wt%.

In addition, the artificial rock construction method of the large structure according to the present invention comprises a first step of installing an angle to the structure using an anchor bolt; Fixing a GFRC artificial cancer panel or a GRS artificial cancer panel to an end of the angle; A third step of fixing the second shaped reinforcing bar in a lattice form at a predetermined distance from the structure; A fourth step of fixing a lattice-shaped internal reinforcing material to the angle between the second reinforcing bar and the structure; A fifth step of fixing the first shaped reinforcing bar in a lattice form between the internal reinforcing material and the structure; A sixth step of fixing one end of the I-shaped reinforcing bar to the first steel bar and the other end to the second steel bar; A seventh step of fixing one side of the X-shaped reinforcing bar to the angle and the other side to the GFRC artificial arm panel or the GRS artificial arm panel and the angle; An eighth step of disposing a metal mesh on the front or rear surface of the first steel reinforcing bar and binding the first steel and metal net by a binding line; Consists of the ninth step of curing the concrete between the metal mesh and the GFRC artificial rock panel or GRS artificial rock panel.

Artificial rock construction method of a large structure according to the present invention configured as described above is the internal reinforcing material and the second reinforcing bar is placed in the middle of the molding material (or concrete) and hardened like the molding material (or concrete), the internal reinforcing material and Two-bar steel can act as a skeleton of the artificial rock has the advantage of improving the structural strength and stability of the artificial rock.

In addition, angle, type 1 reinforcing bar, metal mesh, internal reinforcing material, type 2 reinforcing bar, type I reinforcing bar and X type reinforcing bar are integrated with the molding material (or concrete) to improve the structural stability of the artificial rock. As well as various components integrated with hardened molding material (or concrete) (angle, steel reinforcing bars, metal mesh, internal reinforcing materials, steel reinforcing bars, type I reinforcing bars and type X reinforcing bars). There is an advantage that can prevent corrosion.

In addition, the I-shaped reinforcing bar maintains a constant interval between the first and second reinforcing bars and is provided with a lattice-shaped internal reinforcing material. Since the structures of the first steel bar and the second steel bar can be prevented from being deformed, there is an advantage in that the artificial rock can be manufactured in a desired shape.

1 is a block diagram showing a method of constructing the artificial rock by the injection of the molding material of the artificial rock construction method of a large structure according to the present invention.
Figure 2 is a view showing a state of the artificial rock constructed by the method shown in FIG.
Figure 3 is a block diagram showing a method of constructing the artificial rock by the use of GFRC artificial rock panel or GRS artificial rock panel of the artificial rock construction method of a large structure according to the present invention.
4 is a view showing a state of the artificial rock constructed by the method shown in FIG.

Hereinafter, with reference to the accompanying drawings an embodiment of the artificial rock of a large structure according to the present invention will be described in detail.

1 is a block diagram showing a method of constructing the artificial rock by the injection of the molding material of the artificial rock construction method of the large structure according to the present invention, Figure 2 is a view of the artificial rock constructed by the method shown in FIG. Is shown.

The artificial rock construction method of a large structure according to the present invention shown in Figure 1 is largely completed through a eight-step process.

The first step S110 is a process of installing a plurality of angles 10 in the structure (S). One end of the angle 10 is firmly fixed to the structure S by using a coupling means such as a bolt or anchor bolt.

The angle 10 is provided in plural in the structure (S) installed for structural stability, such as the inclined slope. In more detail, the angle 10 has a 'b' shaped cross section, and a plurality of ends are installed to fix one end to the structure (S).

The second step (S120) is a process of installing the first model reinforcing bar 20 having a lattice shape to be spaced a predetermined distance from the angle 10 installed in the first step S110. The first steel reinforcement 20 is composed of a plurality of transverse reinforcing bars 21 and longitudinal reinforcing bars 22 intersecting with each other, the welding of the vertical reinforcing bars 22 to the angle 10 to fix and to implement The longitudinal reinforcing bar 22 is bent properly so as to match the shape. In addition, the plurality of horizontal rebars 21 are disposed on the front or rear side of the longitudinal reinforcing bar 22 while being welded and fixed, and bent appropriately so as to be matched to the shape of the artificial arm. 20) to the angle (10).

In more detail, the first shaped rebar 20 includes a plurality of horizontal rebars 21 spaced apart in the vertical direction and a plurality of vertical rebars 22 spaced apart in the horizontal direction (or horizontal direction). The cross bars are arranged in a lattice form, and the longitudinal reinforcing bars 22 are disposed to be spaced apart by a predetermined distance in front of the structure S, and the horizontal reinforcing bars 21 are fixed to the front or rear of the longitudinal reinforcing bars 22. do. At this time, the horizontal reinforcing bar 21 and the longitudinal reinforcing bar 22 of the first model reinforcing bar 20 is formed to be similar or the same as the shape of the artificial rock to be implemented by bending properly.

In the third step (S130), the metal mesh 30 is disposed on the front or the rear of the first steel reinforcement 20, and the metal mesh 30 and the first steel reinforcement 20 are firmly bound by a binding line. It is the process of fixing it.

The metal mesh 30 is installed to be in contact with the front or rear of the first steel reinforcement (20). In more detail, the first reinforcing bar 20 is installed to be in close contact with the front of the rebar 21. When the metal mesh 30 is sprayed, the metal mesh 30 is cured like the molding material 80 to form a body with the molding material 80. When the molding material 80 is sprayed from the front of the metal mesh 30 due to the viscosity of the molding material 80 as well as the gap between the metal wires constituting the metal mesh 30 is narrow, the metal mesh 30 It does not leak to the rear of).

The fourth step (S140) is a process of fixing the internal reinforcing material 40 of the grid shape to the angle (10). More specifically, the horizontal reinforcing bar 41 and the vertical reinforcing bar 42 are installed to be spaced apart at a predetermined distance toward the front of the metal mesh 30 formed by cross fixing.

The internal reinforcing material 40 is fixed to one side of the angle 10, it is installed to be spaced a predetermined distance toward the front of the metal mesh (30). The internal reinforcing material 40 is made of steel, such as reinforcing bar, the shape is reinforced in a form similar to the shape of the artificial rock to be implemented. In more detail, the internal reinforcing material 40 is a plurality of transverse reinforcing bars 41 are spaced apart in the vertical direction and a plurality of longitudinal reinforcing bars 42 are spaced apart in the horizontal direction (or horizontal direction) cross each other It is composed of a grid. At this time, the horizontal reinforcing bar 41 and the longitudinal reinforcing bar 42 of the internal reinforcing material 40 is formed to be similar or the same as the shape of the artificial rock to be implemented by bending properly.

The fifth step (S150) is a process of fixing the second model reinforcing bar 50 in the form of a grid at the end of the angle (10). The second model reinforcing bar 50 is composed of a plurality of transverse reinforcing bars 51 and the longitudinal reinforcing bars 52 intersecting with each other, and fixed by welding a plurality of longitudinal reinforcing bars 52 spaced apart from the end of the angle (10) At the same time, the longitudinal reinforcing bar 52 is appropriately bent to match the shape of the artificial rock. In addition, the plurality of horizontal rebars 51 are disposed on the front or rear surface of the longitudinal reinforcing bar 52 of the second reinforcing bar 50 while being welded and fixed, and suitably matched to the shape of the artificial arm. By bending, the second model steel bar 50 is installed on the angle 10.

In other words, the plurality of second model reinforcing bar 50 is installed so as to be fixed to the other end of the angle 10, it is installed to be spaced a predetermined distance toward the front of the internal reinforcing material (40). In more detail, the second type reinforcing bar 50 is arranged in a shape similar to that of the artificial rock to be implemented, and is horizontally (or horizontally) with a plurality of horizontal rebars 51 spaced apart in the vertical direction. A plurality of longitudinal reinforcing bars (52) arranged to be spaced apart from each other is configured in a grid form to cross each other.

The reinforcing bar 51 is disposed to be spaced apart a predetermined distance in front of the internal reinforcing material 40, the longitudinal reinforcing bar 52 is fixed to the front or rear of the horizontal reinforcing bar (51). At this time, the horizontal reinforcing bar 51 and the longitudinal reinforcing bar 52 of the second model steel bar 50 is formed to be similar or identical to the shape of the artificial rock to be implemented by appropriately bent.

The sixth step (S160) is a process of installing the I-shaped reinforcing bar 60. In more detail, one end of the I-shaped reinforcing bar 60 is fixed to the first steel bar 20 and the other end is fixed to the second steel bar 50.

Both ends of the I-shaped reinforcing bar 60 are fixed to the first forming bar 20 and the second forming bar 50, respectively, so that a gap between the first forming bar 20 and the second forming bar 50 is As a reinforcement to be maintained, it is composed of a first connecting reinforcement 61, a central reinforcing bar 62 and a second connecting reinforcing bar (63).

The first connecting reinforcement 61 is formed to extend in the downward direction from the upper side, it is fixed to the first shaped reinforcement 20 by a method such as welding.

One end of the central reinforcing bar 62 is fixedly connected to the central portion of the first connecting reinforcing bar 61 and extends in the direction of the second model reinforcing bar 50. The center reinforcing bar 62 is firmly fixed to each other by the binding line or welding also with the metal mesh 30, if there is a metal mesh 30 on the extension path.

The second connecting reinforcement 63 is a center portion is fixed to the end of the central reinforcing bar 62, is formed long in the upper direction from the lower side and fixed to the second reinforcing bar 50 by a method such as welding do.

The seventh step (S170) is a process of installing the X-shaped reinforcing bar 70, the overall shape is similar to the letter 'X'. In more detail, one end of the X-shaped reinforcing bar 70 is fixed to the angle 10, and the other end is fixed to the second steel bar 50.

When the X-shaped reinforcing bar 70 passes through a specific point in the process of installing the X-shaped reinforcing bar 70 between the angle 10 and the second steel bar (50), the first steel bar (20), When contacted with the internal reinforcing material 40 or the I-shaped reinforcing bar 60, the contact point of the X-shaped reinforcing bar 70 and the first reinforcing bar 20, the X-shaped reinforcing bar 70 and the internal reinforcing material 40 The contact point and the contact point of the X type reinforcing bar 70 and the I type reinforcing bar 60 are also fixed by the same method as welding so that each member is connected and fixed to each other so as to enhance rigidity. The X-shaped reinforcing bar 70 and the metal mesh 30 are also firmly fixed to each other by a method such as a binding line or welding.

In other words, the X-shaped reinforcing bar 70 is a reinforcing material having an alphabet 'X' shape, it is composed of a down reinforcing reinforcement 71, and an upward reinforcing reinforcement 72 is fixed to the down reinforcing reinforcement (71). .

One end of the downward reinforcing reinforcement 71 is fixed to the angle 10 by welding or the like, and in this state is disposed to be inclined downward so that the other end is connected to the second reinforcing bar 50 by welding or the like. do.

One end of the upward reinforcing reinforcement 72 is fixed to the angle 10 by welding or the like, and in this state is disposed to be inclined upward and the other end is fixed to the second reinforcing bar 50. In addition, the upper reinforcing reinforcement 72 is fixed to the center portion of the down reinforcement reinforcement 71 in the same manner as the welding.

Eighth step (S180) is a process of realizing the shape and color of the artificial rock by repeating the injection and curing of the molding material 80 in front of the second steel reinforcement (50).

The molding material 80 is sprayed from the front of the second steel reinforcement 50 to protrude from the metal mesh 30 to the front of the second steel reinforcement 50 to cure. The molding material 80 is sprayed by a process called soaking, wherein the sprayed molding material 80 reaches the metal net 30 and hardens. Therefore, a part of the metal mesh 30, the internal reinforcing material 40, the second reinforcing steel bar 50, the I type reinforcing bar 60 and the X type reinforcing bar 70 is formed by the hardening of the molding material 80. That is, the integrated reinforcing material 40 contained in the molding material 80, the second reinforcing bar 50 or the I-shaped reinforcing bar 60 and the X-shaped reinforcing bar 70 is prevented from corrosion. By preventing corrosion, it is possible to obtain an effect of maintaining structural rigidity for a long time. In addition, the internal reinforcing material 40 and the second reinforcing bar 50 is cured like the molding material 80 in the interior of the molding material 80 and its position is fixed to the internal reinforcing material 40 and the second forming reinforcement 50 ) Acts as a central skeleton of the artificial rock, thereby strengthening the structural strength of the artificial rock.

On the other hand, when the molding material 80 is sprayed in detail in the eighth step (S180), two types of molding material 80 are sprayed.

The first injection molding material is 38 to 48% by weight of cement, 5 to 15% by weight of limestone, 28 to 33% by weight of silica sand, 1 to 3% by weight of iron oxide pigment, 1 to 2% by weight of moldine, and 10 to 15% by weight of water. It is composed of 0.3 ~ 0.5% by weight of water reducing agent, 0.3 ~ 0.5% by weight of pump aid, 2-5% by weight of polypropylene fiber, 2-5% by weight of high strength PVA fiber, 2-3% by weight of glass fiber.

The second molding material sprayed on the upper surface (or the entire surface) of the first sprayed molding material is 45 to 55% by weight of back cement, 20 to 30% by weight of silica sand, 5 to 15% by weight of limestone, and 2 to 5 polypropylene fibers. Weight%, high strength PVA fiber 2-5% by weight, water 10-15% by weight, moldine 1-2% by weight, iron oxide pigment 1-3% by weight.

If the first injection molding material is sprayed to a certain thickness and then hardened to serve as the structure of the artificial rock, the second injection molding material plays a role of directing the surface of the artificial rock.

Although the first injection molding material is sprayed once and then semi-cured, the second injection molding material can be sprayed and cured. However, when the first injection molding material needs to be thick, the first injection is required. It is also possible to repeat the process of semi-curing the molding material is divided into a plurality of times, three times or more times, and then cured after spraying the second injection molding material thereon.

On the other hand, the limestone included in the molding material 80 allows the molding material 80 to be cured quickly so that the subsequent work can proceed in a short time to shorten the air.

In addition, the polypropylene fiber or the high-strength PVA fiber and the glass fiber included in the molding material 80 suppress the occurrence of cracks or cracks due to thermal expansion, plastic shrinkage, dry shrinkage, etc. generated during the curing process of the molding material 80. Do it.

In addition, since the molding material 80 includes a moldine, adhesive force is increased to prevent the first injection molding material and the second injection molding material from being peeled off, and thus the first injection molding material and the second injection are prevented. The molding material to be firmly integrated.

The above has been described with reference to FIGS. 1 to 2, and the artificial rock construction method of the large structure according to the present invention will be described below with reference to FIGS. 3 to 4. 1 and 2, the description thereof will be omitted here.

Figure 3 is a block diagram showing a method for constructing the artificial rock by the use of the GFRC artificial rock panel or GRS artificial rock panel of the artificial rock construction method of a large structure according to the present invention, Figure 4 is a method shown in Figure 3 The figure shows the shape of artificial rock constructed by

The artificial rock construction method of the large structure according to the present invention shown in Figure 3 is largely completed through a nine-step process.

The first step S210 is a process of installing the angle 10 to the structure (S) using the anchor bolt.

The second step (S220) is a process of fixing the GFRC artificial cancer panel or GRS artificial cancer panel 90 to the end of the angle (10).

The GFRC artificial rock panel or GRS artificial rock panel 90 is already pre-fabricated before construction of the artificial rock in the field is welded to the angle 10 or bolted or fixed by other means. The GFRC artificial rock panel or GRS artificial rock panel 90 constitutes the surface of the artificial rock is the part visible from the outside.

In the embodiment shown in Figures 1 and 2 to construct a large-scale artificial rock according to the present invention by spraying the molding material 80 to complete the body of the artificial rock, and at the same time constituted the surface of the artificial rock, In another embodiment shown in Figures 3 and 4 to configure the surface of the artificial rock using a GFRC artificial rock panel or GRS artificial rock panel 90.

The third step S230 is a process of fixing the second model reinforcing bar 50 having a lattice form to the angle 10 so as to be spaced apart from the structure S by a predetermined distance. The second model reinforcing bar 50 is spaced apart from the structure (S) by a predetermined distance and a predetermined distance from the GFRC artificial rock panel or GRS artificial rock panel 90 installed in the second step (S220). Therefore, when the concrete 100 is poured in the ninth step S290 to be described later, the concrete 100 is cured together with the concrete 100.

The fourth step (S240) is a process of fixing the internal reinforcing material 40 having a lattice form between the second reinforcing bar 50 and the structure S to the angle 10. The internal reinforcing material 40 installed in this step is located in the concrete 100 to be poured in the ninth step (S290) and hardened together with the concrete 100 so that the second molding reinforcement installed in the third step (S230) Together with (50) will act as a skeleton of artificial rock. Therefore, the artificial rock constructed by the present invention will have a solid skeleton by the second reinforcing bar 50 and the internal reinforcing material (40).

The fifth step (S250) is a process of fixing the first steel reinforcing bar 20 of the grid form between the internal reinforcing material 40 and the structure (S) to the angle (10).

The sixth step S260 is a process of fixing one end of the I-shaped reinforcing bar 60 to the first protruding bar 20 and the other end of the I-shaped rebar 60. When the I-shaped reinforcing bar 60 is installed in this way, the concrete 100 is poured in the ninth step (S290), even if the concrete 100 is placed on the first and second bar 20 and 50. Since the interval between the first reinforcing bar 20 and the second reinforcing bar 50 is maintained, it is easy to implement the artificial rock of the desired shape and thickness.

Step 7 (S270) is a process of fixing one side of the X-shaped reinforcing bar 70 to the angle 10 and the other side to the GFRC artificial arm panel or GRS artificial arm panel 90 and the angle (10) to be.

The eighth step S280 is a process of disposing the metal mesh 30 on the front or the rear of the first steel reinforcement 20 and binding the first steel reinforcement 20 and the metal mesh 30 by a binding line.

The ninth step (S290) is a process of pouring concrete 100 between the metal mesh 30 and the GFRC artificial rock panel or GRS artificial rock panel 90 to stiffen. In one embodiment shown in FIGS. 1 and 2, the sculpted molding material 80 constitutes the inside and the surface of the artificial rock, whereas in another embodiment shown in FIGS. 3 and 4, the GFRC artificial rock panel or GRS artificial rock Panel 90 constitutes the surface of the artificial rock and the interior thereof is made of concrete 100. Thus, the concrete 100 is poured into the metal net 30, the first steel reinforcement 20, the internal reinforcing material 40, the second steel reinforcement 50, the I-shaped reinforcing steel 60 and the concrete (100) inside The included X-shaped reinforcing bar 70, the angle 10 and the like is hardened together so that the artificial arm has a solid structure.

10: angle 20: steel rod 1
21: Horizontal rebar 22: Vertical rebar
30: metal mesh 40: internal reinforcement
41: horizontal rebar 42: longitudinal rebar
50: Type 2 steel bar 51: Horizontal bar
52: longitudinal reinforcement 60: type I reinforcement steel
61: first connecting bar 62: center bar
63: second connecting bar 70: X type reinforcing bar
71: downward rebar 72: upward rebar
80: molding material
90: GFRC artificial rock panel or GRS artificial rock panel
100: concrete
S: Structure

Claims (4)

First step (S110) for installing the angle (10) to the structure (S) using an anchor bolt; A second step (S120) of fixing the first shaped reinforcing bar 20 having a lattice shape to the angle 10 so as to be spaced apart from the structure S by a predetermined distance; A third step (S130) of disposing the metal mesh 30 on the front or rear surface of the first steel reinforcing bar 20 and binding the first steel reinforcing steel 20 and the metal mesh 30 by a binding line; A fourth step (S140) of fixing the internal reinforcement member 40 having a lattice shape to the angle 10, and installing the internal reinforcement member 40 at a predetermined distance from the front side of the metal mesh 30; A fifth step (S150) of fixing the second model reinforcing bar 50 having a lattice shape to the angle 10 so as to be spaced apart at a distance in front of the internal reinforcing material 40; A sixth step (S160) of fixing one end of the I-shaped reinforcing bar 60 to the first protruding bar 20 and the other end of the I-shaped rebar 60; A seventh step S170 of fixing one end of the X-shaped reinforcing bar 70 to the angle 10 and the other end of the X-shaped reinforcing bar 70; Including the eighth step (S180) to implement the shape and color of the artificial rock by repeating the injection and curing of the molding material 80 in front of the second steel reinforcement 50,
The X-shaped reinforcing bar 70 is disposed downwardly inclined downward in a state where one end is connected to the angle 10, and one end is inclined upwardly in a state where it is connected to the angle 10, and The central portion is composed of an upward reinforcing bar 72 is fixed to the central portion of the down reinforcing bar 71,
The I-shaped reinforcing bar 60 is the first connecting reinforcement 61 is fixed to the first model reinforcing bar 20, and the central reinforcing bar 62, one end is fixed to the central portion of the first connecting reinforcement 61 And, the artificial portion construction method of a large structure, characterized in that the center portion is composed of a second connecting reinforcement (63) fixed to the end of the central reinforcing bar (62) and fixed to the second reinforcing bar (50).
The method according to claim 1,
In the eighth step S180, two kinds of molding materials 80 are sprayed and cured,
The first injection molding material is 38 to 48% by weight of cement, 5 to 15% by weight of limestone, 28 to 33% by weight of silica sand, 1 to 3% by weight of iron oxide pigment, 1 to 2% by weight of moldine, and 10 to 15% by weight of water. Composed of 0.3 ~ 0.5% by weight, 0.3 ~ 0.5% by weight of pump aid, 2-5% by weight of polypropylene fiber, 2-5% by weight of high strength PVA fiber, 2-3% by weight of glass fiber,
The second molding material sprayed on the upper surface of the first sprayed molding material is 45 to 55% by weight of cement, 20 to 30% by weight of silica sand, 5 to 15% by weight of limestone, 2 to 5% by weight of polypropylene fiber, high strength PVA A large-scale artificial rock construction method comprising 2 to 5% by weight of fiber, 10 to 15% by weight of water, 1 to 2% by weight of moldine, and 1 to 3% by weight of iron oxide pigment.
First step (S210) for installing the angle (10) to the structure (S) using an anchor bolt; A second step (S220) of fixing the GFRC artificial cancer panel or the GRS artificial cancer panel 90 to the end of the angle 10; A third step (S230) of fixing the second model reinforcing bar (50) having a lattice shape to the angle (10) to be spaced apart from the structure (S) by a predetermined distance; A fourth step S240 of fixing the internal reinforcing material 40 having a lattice form between the second reinforcing bar 50 and the structure S to the angle 10; A fifth step (S250) of fixing the first shaped reinforcing bar 20 having a lattice form between the internal reinforcing material 40 and the structure S to the angle 10; A sixth step (S260) of fixing one end of the I-shaped reinforcing bar 60 to the first protruding bar 20 and the other end of the I-shaped rebar 60; A seventh step (S270) of fixing one side of the X-shaped reinforcing bar 70 to the angle 10 and the other side to the GFRC artificial arm panel or GRS artificial arm panel 90 and the angle 10; An eighth step (S280) of disposing the metal mesh 30 on the front or rear surface of the first steel reinforcing bar 20 and binding the first steel reinforcing steel 20 and the metal mesh 30 with a binding line; Consists of the ninth step (S290) to pour the concrete 100 between the metal mesh 30 and the GFRC artificial rock panel or GRS artificial rock panel 90 to stiffen;
The X-shaped reinforcing bar 70 is disposed downwardly inclined downward in a state where one end is connected to the angle 10, and one end is inclined upwardly in a state where it is connected to the angle 10, and The central portion is composed of an upward reinforcing bar 72 is fixed to the central portion of the down reinforcing bar 71,
The I-shaped reinforcing bar 60 is the first connecting reinforcement 61 is fixed to the first model reinforcing bar 20, and the central reinforcing bar 62, one end is fixed to the central portion of the first connecting reinforcement 61 And, the artificial portion construction method of a large structure, characterized in that the center portion is composed of a second connecting reinforcement (63) fixed to the end of the central reinforcing bar (62) and fixed to the second reinforcing bar (50). delete

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