KR101295029B1 - Reverse construction method using fiber rods - Google Patents

Abstract

PURPOSE: A reverse construction method using a fiber rod is provided to freely construct a curve or plane surface mixed type building design with a simple method without a mold. CONSTITUTION: A reverse construction method using a fiber comprises as follows. A bottom frame is installed (S110). A fiber rod is installed in order to correspond to a shape of a structure (S120). A mesh is installed on an inner surface or an outer surface of the fiber rod (S130). High strength polymer mortar is constructed by being sprayed on a mesh surface (S140). The high strength polymer mortar is cured (S150). [Reference numerals] (AA) Start; (BB) End; (S110) Installation of a bottom frame; (S120) Installation of a fiber rod; (S130) Installation of a mesh; (S140) Spray construction of high strength polymer mortar; (S150) Curing and completion

Description

Ceramic construction method using fiber rod {REVERSE CONSTRUCTION METHOD USING FIBER RODS}

The present invention relates to a construction method of a building, and more particularly, using a fiber rod and a high-strength polymer mortar, the construction method including a step of constructing a high strength wall in a simplified process by constructing the outer wall of the building without formwork The invention relates to.

If you look at the construction method of the general concrete-type building, first secure the foundation by using piles on the ground to be constructed.

And the floor of the building is constructed on the foundation. At this time, the construction of the bottom is to reinforce the reinforcing bar on the foundation, install the formwork according to the shape of the floor, and then after curing the concrete to construct the bottom.

Then, after constructing the column for supporting the load structure of the building, the wall is constructed.

At this time, the pillars and walls also reinforce the reinforcement, install the formwork, and then cast / cure concrete in the formwork to complete the column and wall.

Next, the slabs and the roof are constructed on the walls and the pillars to complete the basic structure of the building.

Of course, in the case of a multi-layered structure, it is also possible to construct the exterior wall after constructing the columns and slabs sequentially to the design height.

Subsequently, when the basic structure including the basic frame and the wall is completed, exterior construction is performed to finish the outer wall of the wall.

 The exterior construction can be largely divided into insulation construction and waterproof construction and exterior construction for the aesthetics of the external wall, it is also possible to selectively install some of them depending on the type of building and material.

Next, the construction of the building is completed by performing interior work such as wall finishing and interior construction.

However, the above-described prior art has the following problems.

That is, the conventional building method requires a form like the wall form on the drawing to form the wall of the building. Therefore, in order to form curved and geometrical walls, formwork dedicated to the structure must be produced separately, thereby significantly increasing the construction cost and increasing the complexity of the construction process.

Therefore, considering the construction cost and construction period, most buildings currently have a problem that the flat wall is mainly used to use the standardized Euroform.

Republic of Korea Patent No. 10-0603627

The present invention has been made to solve the conventional problems as described above, the present invention of the predesign concrete-type rod housing is a construction method of the building to be able to freely implement a curved / flat mixed building design in a simple way without using a formwork To provide.

In addition, the present invention is to provide a building construction method to provide a building outer wall of the seamless structure integrated structure, to provide a housing structure strong in the disaster, excellent seismic performance, low energy consumption.

According to a feature of the present invention for achieving the object as described above, the present invention, in the construction method using a fiber rod, without a formwork (thin concrete panel, which is a material for finishing walls, roofs, etc. as a substitute for formwork, or Fasten dry bite styrofoam, fiber or zinc mesh, or thin iron plate finish, wood finish, stone finish, or tile finish) to the base frame (round or square iron pipe, 'c' stud, wood) After installing rods made of fibers (impregnated with garnet or steel slag ball, silica sand, etc.) on the inside of the fixing brackets, the high-strength polymer mortar is sprayed with 2cm ~ 10cm to seamlessly integrate the structure. The main feature is the construction of this high house or structure on the ground or on the water in a mobile or fixed manner.

In addition, the present invention has been used in the construction of the existing house or structure, after the construction of the final construction after installing a structure such as a wall after the foundation work, the present invention is a basic frame (circular or Square metal pipes, 'c' type studs, wood) are installed first, and rods impregnated with glass, aramid, carbon fiber rods impregnated with garnet or silica sand, or steel slag balls are used instead of steel. It is installed in 10cm × 10cm (horizontal length), 20cm × 20cm, 30cm × 30cm intervals and sprayed with high-strength eco-friendly polymer mortar.

On the other hand the present invention comprises the steps of (I) installing the floor frame; (II) installing a base frame for making a design shape by connecting to the floor frame; (III) installing a fiber rod in a lattice form on the base frame so as to correspond to the shape of the structure to be constructed; (IV) installing a fiber or iron mesh in the form of a mesh or cloth on either of the inner surface or the outer surface of the fiber rod; And (V) constructing a high-strength polymer mortar on the inside and the outside of the mesh surface, wherein the fiber rod is garnet, silica sand, or rods including any one of glass fiber, aramid fiber or carbon fiber. It is impregnated with steel slag ball.

In this case, the (V) step may be performed by repeatedly constructing the wall to the construction thickness of the wall by using the equipment to spray the high-strength polymer mortar in the direction in which the fiber rod is located in the front with the mesh surface as the rear surface. have.

And the present invention comprises the steps of (A) constructing a floor foundation; (B) installing a base frame on the floor foundation; (C) installing the bracket on the base frame; (D) fixing the exterior member and the fiber rod to the bracket; And (E) constructing a wall of the building by spraying high strength polymer mortar toward the exterior material from the inside of the building, wherein the base frame is formed of round or square pipes and 'c' studs. The frame includes a ceramic construction method using a fiber rod configured in a form corresponding to the shape of the building to fix the exterior material and the fiber rod.

Wherein (A) step, (A1) excavating the ground on which the building is located to a predetermined depth, and constructing a pile (pile) on the excavation surface bottom; (A2) is connected to the head of the pile to reinforce the fiber rod on the bottom surface, and placing and curing concrete or high-strength polymer mortar.

In addition, the present invention comprises the steps of (a) constructing an underwater foundation on the sea bottom; (b) constructing an upper foundation above the underwater foundation; (c) constructing a bottom slab on the upper foundation; (d) installing a base frame on the floor slab; (e) installing the bracket on the base frame; (f) fixing the exterior material and the fiber rod to the bracket; And (g) constructing a wall of the building by spraying high-strength polymer mortar toward the exterior material from the inside of the building; The basic frame, the basic frame is a frame consisting of a round or square pipe, 'c' type stud or wood, and also using a fiber rod configured in a form corresponding to the shape of the building to fix the exterior material and the fiber rod Includes ball construction methods.

Wherein the step (a) comprises: (a1) perforating the seabed or seabed rock; (a2) placing the fiber rod in the perforation space; And (a3) pouring VOC-cutting epoxy mortar into the perforation space.

At this time, the step (b) comprises the steps of: (b1) installing any one of the pillar formwork made of PE, PVC, PP or corrosion-resistant steel pipe on the underwater foundation; (b2) placing the fiber rod into the pillar formwork; And (b3) pouring the VOC-cutting underwater epoxy mortar or underwater concrete into the column formwork to form an upper foundation into which the fiber rod is inserted. Extending a predetermined length to the upper base, the elongated fiber rod may be connected to the fiber rod of the upper foundation under the upper foundation, the underwater foundation and the upper foundation may be integrally formed.

And (c) the step (c1) wherein the bottom slab binds the fiber rod and the fiber rod for slab extending from the upper base to reinforce the fiber rod; (c2) installing a fiber net or zinc net at the bottom and attaching a vinyl cover; (c3) spraying the lower surface with high-strength polymer mortar; (c4) It may be constructed, including the step of placing a concrete slab or high strength mortar to complete the floor slab.

In addition, the bracket, one side is fixed to the base frame, the other side is fixed to the exterior material, and the like, a fixing piece for fixing the fiber rod in the longitudinal and transverse direction may be formed.

And the exterior material is a concrete panel, the surface is coated with a polymer mortar, styrofoam, fibrous mesh net, zinc mesh net, iron mesh net, stone panel, wood panel with an inverted trapezoidal, square or 'V' shaped groove on the inner surface Or it may be one of iron panels.

In addition, the present invention is a carbon dioxide measuring device for measuring the amount of carbon dioxide indoor; It further comprises a ventilation system interlocked with the carbon dioxide meter: If the measured value of the carbon dioxide meter is more than a predetermined range, it is possible to operate the ventilation equipment to prevent oxygen deficiency.

And the styrofoam, after installing the styrofoam exterior material and the fiber rod of 50 to 150mm thickness in the bracket, the polymer mortar is injected into the groove of the styrofoam by injecting the polymer mortar to integrate the polymer mortar, fiber rod and styrofoam In addition, the polymer mortar may be applied by dry bit to finish the external insulation.

In addition, the connecting portion between the outer styrofoam face material, attaching the waterproof sheet to the inner side with a spacing of 1 to 15 mm; Caulking the adhesive flexible waterproofing material in the groove between the styrofoam exterior materials; Finishing caulking may be performed with a hardened flexible caulking material outside the groove between the styrofoam exterior materials.

On the other hand, the present invention comprises the steps of (A) constructing a floor foundation; (B) installing a base frame on the floor foundation; (C) installing the bracket on the base frame; (D) attaching the exterior material to the base frame, and fixing the fiber rod to the bracket; And (E) constructing a wall of the building by spouting high strength polymer mortar from the inside of the building toward the sheathing material: the base frame is a round or square pipe, 'c' shaped stud or wood. In order to fix the exterior material and the fiber rod to the frame to be configured includes a ceramic construction method using a fiber rod configured in a form corresponding to the shape of the building.

The present invention also comprises the steps of (a) constructing an underwater foundation on the sea bottom; (b) constructing an upper foundation above the underwater foundation; (c) constructing a bottom slab on the upper foundation; (d) installing a base frame on the floor slab; (e) installing the bracket on the base frame; (f) attaching an exterior material to the base frame and fixing the fiber rod to the bracket; And (g) constructing a wall of the building by spraying high-strength polymer mortar toward the exterior material from the inside of the building; The basic frame is a frame consisting of a round or square pipe, a 'c' type stud or wood, and uses a ceramic construction method using a fiber rod configured in a form corresponding to the shape of a building to fix an exterior material and a fiber rod. Include.

Here, the outer cover is made of styrofoam formed in the inner surface of the trapezoidal, square or 'V' shape; The base frame and the exterior member may be attached to the base frame by being seated in a channel-shaped groove formed on an inner surface of the styrofoam.

The high-strength mortar may be filled in the inverted trapezoidal, square or 'V' shaped groove.

On the other hand, the construction of the high-strength polymer mortar of step (E) or (g) step, the step of spraying the high-strength polymer mortar around the intersection of the fiber rod; It may be carried out including the step of spraying a general mortar on the high-strength polymer mortar construction surface.

In addition, the vertical joining surface of the styrofoam, the grooves into which the fiber rod can be inserted are formed, respectively, the end of the fiber rod is embedded in the groove may be formed a wall.

As described above, the ceramic construction method using the fiber rod according to the present invention is cheaper in construction cost, can shorten the construction period, and can implement various types of walls, and can freely implement a curved / flat mixed building design at a low construction cost. There are advantages to it.

In addition, the present invention has an advantage that can be easily installed on the ground-water housing structure excellent in seismic performance, low energy consumption because the building outer wall is formed as a seamless structure integrated.

In addition, the present invention uses a fiber rod, which is lighter than conventional reinforcing rods and has excellent corrosion resistance and chemical resistance, thereby facilitating the construction of the contractor and extending the life of the building structure. There is an advantage that does not cause problems.

Therefore, in the case of the marine structure, it can be formed in an integrated structure from the bottom of the sea floor to the end of the ground exposure site, has the advantage of excellent durability and corrosion does not occur by sea water.

In addition, the present invention can be simply finished with a plastering or spraying heat-reflective insulation or heat insulation lightweight mortar or thermal insulation of the interior of the house or structure can be simply finished with a concrete panel, etc., it is possible to increase the insulation and significantly reduce labor costs.

And one embodiment of the present invention has the advantage of installing a device to prevent oxygen deficiency by interlocking with an external ventilation system by installing a Co2 measuring instrument inside the house and to apply an environmentally friendly finish to the interior to create an environment-friendly house.

In addition, the present invention, after installing the window frame or door frame in the basic frame (round or square iron pipe, 'c' type stud, wood) to make a design form even when installing the window, door, front door, and then install the finishing material on the basic frame And since it installs the structural fiber rods in the interior and integrates the structure with the spraying, there is no effective space in terms of insulation because no space is generated.

1 is a cross-sectional view showing an embodiment of the fiber rod used in the ceramic construction method using the fiber rod according to the present invention.
Figure 2 is a flow chart showing the construction procedure of the first embodiment of a coat construction method using a fiber rod according to the present invention.
Figures 3a to 3e is a flow chart showing the actual construction sequence sequentially showing the construction of the first embodiment of the coating construction method using the fiber rod according to the present invention.
Figure 4 is a flow chart showing the construction procedure of a second embodiment of a coat construction method using a fiber rod according to the present invention.
Figure 5a is an exemplary view showing a state in which the basic frame is installed on the base bottom surface by a second embodiment of the present invention.
Figure 5b is an exemplary view showing a state in which the exterior material is installed in the base frame according to a second embodiment of the present invention.
Figure 5c is an illustration showing various members applied to the base frame according to the present invention.
Figure 5d is an illustration showing the processing form between the finish according to the present invention.
Figure 6 is a flow chart showing the construction procedure of a third embodiment of a coat construction method using a fiber rod according to the present invention.
7 is an exemplary view showing a state in which the foundation of the offshore structure is constructed by a third embodiment of the present invention.
8 is an exemplary view showing a form of a wall according to another embodiment of the present invention.
Figure 9 is an illustration showing the form of the vertical joint of the packaging material according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a specific embodiment of the present invention.

First, the basic materials used in the ceramic construction method using the fiber rod according to the present invention will be described, and next, specific examples of the method according to the present invention will be described.

1 is a cross-sectional view showing an embodiment of the fiber rod used in the ceramic construction method using the fiber rod according to the present invention. As shown in FIG. 1, the fiber rod 1 includes a wire 11, an adhesive layer 21, a fiber layer 31, a resin layer 41, and a steel slag layer 51.

The wire 11 is formed by weaving a plurality of iron cores, which are used selectively in consideration of the topographic conditions and tensile strength, the material has a rigidity, retains sufficient tensile strength and excellent corrosion resistance, elasticity Most preferably, stainless steel is used.

In addition, the adhesive layer 21 is formed by applying a resin to the outer surface of the wire 11, which increases the rigidity of the wire 11, as well as becomes more robust when weaving the fiber layer 31.

At this time, the resin is most preferably to be selectively used by the user of the epoxy resin and polyester resin.

In addition, the fiber layer 31 is formed by splicing fibers to the adhesive layer 21, which is formed by splicing a plurality of strands of fiber, the fiber is selectively used by the user of aramid fiber, carbon fiber, glass fiber It is most desirable to enable this.

At this time, the resin layer 41 is formed by applying a resin to the outer surface of the fiber layer 31, which can be selectively used epoxy resin and polyester resin, to form a steel slag layer by the adhesive force It is preferable.

The steel slag layer 51 is to bond the steel slag having a different thickness to the outer surface of the resin layer 41, wherein the steel slag is to facilitate the physical property bonding with the cement mortar, wherein the steel slag Of course, it can be used alternatively as garnet and geumgangsa.

The fiber rod has a high tensile strength of 4 to 10 times the reinforcing bar used as a general reinforcing material, the specific gravity is 1/5 of the steel has the advantage that the weight is light.

The construction and effect of the fiber rod as described above has been demonstrated as shown in Patent No. 10-0603627 and New Construction No.403.

On the other hand, high-strength polymer mortar used in the coating construction method using the fiber rod according to the present invention is a polymer mortar used in the repair / reinforcement of the structure is manufactured and marketed by various manufacturers, mostly 400kgf / ㎠ or more (28 It has a characteristic of compressive strength).

Preferably, one-component or two-component polymer mortars exhibiting compressive and bending strengths of 100 kgf / cm2 or more (based on 28-day age) or more are used (e.g., product name SM-Morter, etc.). ).

In addition, the surface finishing material used in the coating construction method using the fiber rod according to the present invention may be used a conventional surface finishing material, preferably adhesion strength 20kgf / ㎠ or more, neutralization depth 0.4mm, moisture permeability 3g / ㎡, Clay's inorganic anticorrosive is used.

And the heat insulating material used in the coating construction method using the fiber rod according to the present invention may be applied to a common heat insulating material that can be applied by the construction to be made of liquid or powder to be sprayed, preferably an inorganic mortar to be sprayed (for example For example, the product name RE-insulation motor, etc.) may also be used, and insulation materials used in general construction may also be used in parallel.

In addition, the waterproof material used in the coating construction method using the fiber rod according to the present invention may be a rubber asphalt coating film waterproof material having a high adhesion non-curing properties.

Hereinafter will be described a specific embodiment of the ceramic construction method using the fiber rod according to the present invention.

Here, each embodiment is an embodiment that does not install the base frame (Example 1), an embodiment that installs the ground frame by installing the base frame (Example 2) and an embodiment of the construction of the marine structure by installing the base frame Each divided into (Example 3) will be described.

The first embodiment of the ceramic construction method using the fiber rod according to the present invention is a construction method that can be effectively used in a small structure, especially the structure is not necessary because the basic frame is relatively compared to other embodiments of the present invention The construction method has a simple advantage.

Referring to the first embodiment of the present invention, Figure 2 is a flow chart showing the construction procedure of the first embodiment of the ceramic construction method using the fiber rod according to the present invention, Figures 3a to 3e is a fiber rod according to the present invention It is a flow chart showing the actual construction sequence sequentially showing the construction of the first embodiment of the pottery construction method using.

As shown in these figures, the first embodiment of the ceramic construction method using the fiber rod according to the present invention begins with the installation of the floor frame (S110).

At this time, the floor frame is a part that forms the shape of the building floor, and supports the end of the fiber rod to be installed, as shown in Figure 3a, the steel is mainly used, but formed using a variety of members, such as wood It is also possible.

On the other hand, after installing the bottom frame, the fiber rod is installed in the form of the structure to be installed (S120).

 The fiber rod has the configuration as described above, and exhibits high ductility including the fiber layer, so that various geometric shapes can be freely expressed (see FIG. 3B).

In other words, the fiber rod is installed in a lattice form as shown to form a skeleton of a wall to be formed.

Next, the mesh is installed on any one surface of the inner surface or the outer surface of the fiber rod (S130). The mesh may be attached to a high-strength polymer mortar, which will be described later, and may be stacked or formed to form a wall.

On the other hand, the mesh may be installed in a single ply, or a plurality of ply may be installed depending on the installation form and the mixing viscosity of the high-strength polymer mortar.

After that, the high-strength polymer mortar is sprayed on the mesh surface (S140). In other words, the mesh surface is sprayed by using the equipment to spray the high-strength polymer mortar in the direction in which the fiber rod is located in the front to the rear.

The spraying is repeatedly performed until the high strength polymer mortar is laminated to cover the fiber rod by a predetermined thickness.

Then, if necessary, it is also possible to spray the high strength polymer mortar in a thin thickness on the opposite side of the mesh.

And curing the high-strength polymer mortar is completed building according to the first embodiment of the present invention (S150).

In addition, the outer surface of the building may be coated with a waterproofing material, a heat insulating material or a finishing material, etc. as necessary.

Briefly summarized the construction method according to the first embodiment of the present invention, the fiber + iron composite rod manufactured by inserting the fiber rod or iron wire made of glass, aramid, or carbon fiber inside as designed after the foundation concrete is placed (Φ2 ~ After installation of Φ15), it is applied to environment-friendly high strength polymer mortar (compressive strength more than 400㎏f / ㎠) without spraying and plastering with 20 ~ 100mm thickness inside and outside. It is a construction method for constructing houses and sculptures.

Hereinafter, a second embodiment of the ceramic construction method using the fiber rod according to the present invention will be described.

Figure 4 is a flow chart showing the construction procedure of the second embodiment of the coating construction method using the fiber rod according to the present invention, Figure 5a is a state in which the basic frame is installed on the base floor surface by the second embodiment of the present invention 5B is an exemplary view illustrating a state in which an exterior material is installed in a basic frame according to a second embodiment of the present invention.

As shown in these figures, the second embodiment of the present invention starts with the construction of the floor foundation 110 (S210).

The construction of the floor foundation may be applied to a variety of construction methods depending on the size, use, design load, ground conditions, etc. of the building, in the present specification will be described with an example that the pile foundation is applied.

In the construction of the floor foundation, first, the ground on which the building is to be located is excavated to a predetermined depth, and a pile (pile) is constructed at the bottom of the excavation surface.

And it is connected to the pile head to pour / curing reinforced concrete on the bottom surface.

In this case, in order to increase the strength of the bottom surface, it is also possible to replace the reinforcing bar of the bottom surface with the fiber rod (1), it is also possible to use a mixture of the general reinforcing bar and the fiber rod (1).

Next, the base frame 120 is installed on the bottom surface 110 (S220).

The base frame 120 is a frame consisting of a round or square pipe, 'c' type studs for fixing the exterior member 140 and the fiber rod (1) to be described later.

To this end, the basic frame 120 is configured in a form corresponding to the shape of the building, but corresponds to a different configuration than the steel of the steel structure. That is, while the steel structure of the steel structure is to bear the load of the building, the basic frame 120 of the present invention is a stone plate, tile board, wooden board or concrete panels or styrofoam panel constituting the outer wall of the building ( Hereafter referred to collectively as 'exterior materials' and the fiber rod (1), and the steel structure for bearing the load is a separate configuration that is distinguished in function and configuration.

Therefore, the basic frame 120 is configured in the form corresponding to the outer wall shape of the building to be constructed, as shown in Figure 5a.

Next, a bracket 130 for fixing the exterior member 140 and the fiber rod 1 is installed on the basic frame 120 (S230).

In this case, the bracket may be used in various forms, but basically one side may be fixed to the base frame 120, the other side is formed in a form that can be fixed to the exterior.

And the bracket 130 is formed with a fixing piece for fixing the fiber rod (1). And the fixing piece is composed of two kinds of directions perpendicular to each other so that the fiber rod 1 can be fixed in the longitudinal direction and the transverse direction.

In addition, the bracket 130 is fixed at an appropriate interval and position so as to stably support the exterior member and the fiber rod 1 at a predetermined interval.

Next, the bracket 130 and the like and the fiber rod 1 is fixed (S240).

As shown in Figure 5b, the exterior member 140 is fixed to the outside surface of the bracket 130 to form the outer surface of the building, the concrete panel, the surface of the styrofoam coated with polymer mortar (or after finishing the construction May be applied with a polymer mortar), fiber mesh net, zinc or iron mesh net, stone panel, wood panel and the like.

And the fiber rod 1 is fixed to the fixing piece of the bracket 130 to be located between the exterior material 140 and the base frame 120. At this time, between the exterior member 140 is provided with an accessory component such as the window frame of the window to be installed in the building, the door frame of the door.

On the other hand, the base frame 120 may be composed of a variety of structural members. As shown in FIG. 5C, the basic frame 120 may include a circular pipe 122, a square pipe 124, or a 'c' shaped stud 126.

And between the exterior material 140 and the exterior material 140, as shown in Figure 5d, the waterproofing is performed.

At this time, looking at the styrofoam applied to the exterior material, as shown in Figure 5b, after installing the styrofoam 142 and the fiber rod 1 of 50 to 150mm thickness on the bracket 130, the styrofoam ( Injecting the polymer mortar into the groove of the groove 142, the polymer mortar is introduced to integrate the polymer mortar, the fiber rod (1) and the styrofoam (142), and the polymer mortar is dry-bit coated so as to allow external insulation. .

And as shown in Figure 5d, and the connecting portion between the outer member formed of the outer styrofoam 142, attaching the waterproof sheet 144 to the inner side with a space of 1 to 15mm.

Next, after caulking the adhesive flexible waterproofing material 146 in the grooves between the styrofoam 142, and finish caulking with a hardened flexible caulking material 148 on the outer side of the groove between the styrofoam 142 waterproofing between the finish. Perform construction.

Thereafter, the high-strength polymer mortar is sprayed toward the exterior of the building to form a wall of the building (S250).

At this time, the high-strength polymer mortar is sprayed repeatedly until the high-strength polymer mortar is laminated to cover the fiber rod 1 by a predetermined thickness and a wall having a predetermined thickness is formed.

Next, curing the high-strength polymer mortar is completed the building according to the second embodiment of the present invention (S260). Of course, it is also possible to perform a plastering work by the construction to spray the high-strength polymer mortar by the plastering on the exterior surface of the building material 140.

In addition, the outer surface of the building may be coated with a waterproofing material, a heat insulating material or a finishing material, etc. as necessary.

Hereinafter, a third embodiment of the ceramic construction method using the fiber rod according to the present invention will be described.

Figure 6 is a flow chart showing the construction procedure of the third embodiment of the ceramic construction method using the fiber rod according to the present invention, Figure 7 is a view showing the construction of the foundation of the marine structure by the third embodiment of the present invention This is an example.

As shown in these figures, the third embodiment of the present invention starts with the construction of the underwater foundation 210 on the sea bottom (S310).

As shown in FIG. 7, the underwater foundation 210 drills a seabed (or a seabed) and inserts the fiber rod 1 into the perforated space of the seabed. The foundation of the underwater 210 is poured by pouring the VOC-cutting underwater epoxy mortar.

Next, the upper foundation 220 is constructed on the underwater foundation 210 (S320).

The upper foundation 220 is installed on the underwater foundation 210, the pillar formwork made of PE, PP or corrosion-resistant steel pipe, and after placing the fiber rod (1) in the pillar formwork The VOC cut type epoxy mortar or underwater concrete is poured to complete the upper foundation 220 into which the fiber rod 1 is inserted.

At this time, the fiber rod 1 reinforcement to the underwater foundation 210 is extended to a predetermined length above the underwater foundation 210, the extended fiber rod 1 is the upper portion below the upper foundation 220 The underwater foundation 210 and the upper foundation 220 are integrally formed with the fiber rod 1 of the foundation 220.

On the other hand, when the upper foundation 220 is constructed, the bottom slab 230 is constructed on the upper foundation 220 (S330).

After the bottom slab 230 binds the fiber rod 1 extending from the upper foundation 220 and the fiber rod 1 for the slab and reinforces the fiber rod 1, a fiber net or a zinc net To the bottom and attach to the bottom with plastic cover.

The bottom slab is constructed by spraying the bottom with a primary high-strength polymer mortar and curing it, and then spraying or plastering a general mortar or a special high strength mortar.

At this time, since the bottom surface of the bottom slab 230 is constructed of a high-strength polymer mortar, there is a very advantageous advantage in corrosion resistance to seawater compared to the general concrete foundation.

Thereafter, the construction method for completing the structure on the floor slab 230 is constructed in the same manner as the steps 220 to 260 described in the second embodiment of the present invention.

That is, the base frame is installed on the floor slab 230 (S340).

Next, a bracket for fixing the exterior member and the fiber rod 1 is installed on the basic frame (S350), and the exterior member and the fiber rod 1 are fixed to the bracket (S360).

Then, the high-strength polymer mortar is sprayed from the inside of the building toward the exterior material and the like to form a wall of the building (S370).

Next, curing the high-strength polymer mortar is completed the building according to the second embodiment of the present invention (S380).

On the other hand, inside the building according to the present invention (in particular the kitchen) carbon dioxide meter and the ventilation control system interlocked with this can be installed. Therefore, when the measured value of the carbon dioxide meter is more than a predetermined range (at least oxygen, Co2 1000ppm or more), it is also possible to operate the ventilation equipment to prevent oxygen deficiency.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

For example, as shown in FIG. 8, when another embodiment in which the styrofoam 142 is applied to the exterior material is examined, the inverted trapezoidal channel groove 144 having the dovetail shape of the styrofoam 142 is formed. The inverted trapezoidal channel groove 144 is a part in which (high strength) mortar is filled, which is a part for enhancing the adhesion between the high strength mortar and the styrofoam to be sprayed in a later process.

On the other hand, the styrofoam 142 is formed with a channel-shaped groove into which the base frame 120 can be inserted as shown, so that the base frame 120 is inserted into the styrofoam 142.

At this time, the bracket 132 is provided in a form capable of supporting the fiber rod 1 spaced apart from the styrofoam 142 on the outer side basic frame 120 of the styrofoam 142.

Therefore, as shown in FIG. 8, after the styrofoam (exterior material) 142 and the basic frame 120 mill fiber rod 1 are installed, high-strength mortar may be used to form a wall of a building. .

On the other hand, in this case, the spraying can also be carried out in parallel with a high strength mortar and a general mortar. That is, an embodiment in which high-strength mortar is sprayed only a predetermined thickness (about 5 cm) around the intersection of the fiber rod, and the remaining wall design thickness is sprayed with a relatively inexpensive general mortar to secure economic feasibility.

In addition, the edge portion to which the styrofoam 142 exterior member is coupled may be finished as shown in FIG. 9.

That is, as shown in Figure 9, the styrofoam 142 and the side styrofoam 142 ′ perpendicularly bonded to the styrofoam 142 may be inserted into the fiber rods (1, 1 ′) that are disposed perpendicularly to each other A groove may be formed so that the fiber rods 1, 1 'are embedded in the groove to form an integrated wall.

The present invention relates to a construction method including a step of constructing an outer wall of a building without formwork by using a fiber rod and a high strength polymer mortar, and constructing a high strength wall in a simplified process, and according to the present invention, the construction cost is low. And, not only shorten the construction period but also can implement various types of walls, there is an advantage that can freely implement a curved / flat mixed building design at a low construction cost.

1: fiber rod 11: wire
12: adhesive layer 31: fiber layer
41 resin layer 51 steel slag layer
110: ground foundation 120: basic frame
130: bracket 140: exterior material
142: styrofoam 144: waterproof sheet
146: waterproofing material 148: caulking material
210: underwater foundation 220: upper foundation
230: floor slab

Claims (23)

(I) installing a floor frame;
(II) installing a base frame for making a design shape by connecting to the floor frame;
(III) installing a fiber rod in a lattice form on the base frame so as to correspond to the shape of the structure to be constructed;
(IV) installing a fiber or iron mesh in the form of a mesh or cloth on either of the inner surface or the outer surface of the fiber rod; And
(V) constructing a high-strength polymer mortar to the inside and outside of the mounting member surface of step (IV), including:
The fiber rod,
Ceramic construction method using a fiber rod, characterized in that the rod containing any one of glass fiber, aramid fiber or carbon fiber impregnated with garnet, silica sand, or steel slag ball.
The method of claim 1,
In step (V),
Fiber rod, characterized in that carried out by repeated installation to the construction thickness of the wall, using the equipment to spray the high-strength polymer mortar in the direction in which the fiber rod in the front position the installation member surface of the step (IV) in the rear Pottery construction method using
(A) constructing a floor foundation;
(B) installing a base frame on the floor foundation;
(C) installing the bracket on the base frame;
(D) fixing the exterior member and the fiber rod to the bracket; And
(E) constructing a wall of the building by spraying high-strength polymer mortar from the inside of the building toward the sheathing material:
The basic frame,
Frame construction consisting of round or square pipes, 'c' type studs or wood, in the form of a structure corresponding to the shape of the building in order to fix the exterior material and fiber rods.
The method of claim 3, wherein
The step (A)
(A1) digging the ground on which the building is to be located to a predetermined depth, and constructing a pile (pile) on the excavation surface;
(A2) Pottery construction method using a fiber rod, characterized in that performed by connecting to the pile head to the fiber rod on the bottom surface, and placing and curing concrete or high-strength polymer mortar.
(a) constructing an underwater foundation at the bottom of the sea;
(b) constructing an upper foundation above the underwater foundation;
(c) constructing a bottom slab on the upper foundation;
(d) installing a base frame on the floor slab;
(e) installing the bracket on the base frame;
(f) fixing the exterior material and the fiber rod to the bracket; And
(g) constructing a wall of the building by spraying high-strength polymer mortar toward the exterior material from the inside of the building;
The basic frame,
The basic frame is a frame consisting of a round or square pipe, 'c' type studs or wood, in order to fix the exterior material and the fiber rod, the ceramic construction using a fiber rod, characterized in that the configuration corresponding to the shape of the building Method.
The method of claim 5, wherein
Step (a),
(a1) perforating the seabed or seabed rock;
(a2) placing the fiber rod in the perforation space; And
(a3) Pottery building construction method using a fiber rod, characterized in that it is carried out including the step of pouring the epoxy mortar of the VOC-cutting type in the perforated space.
The method according to claim 6,
In step (b),
(b1) installing any one of the pillar formwork made of PE, PVC, PP or anticorrosive steel pipe on the underwater foundation;
(b2) placing the fiber rod into the pillar formwork; And
(b3) pouring the VOC-cutting underwater epoxy mortar or underwater concrete into the pillar formwork to form an upper foundation into which the fiber rod is inserted;
The fiber rod reinforced to the underwater foundation extends to a predetermined length above the underwater foundation, and the extended fiber rod is connected to the fiber rod of the upper foundation under the upper foundation so that the underwater foundation and the upper foundation are integrated. Pottery construction method using a fiber rod, characterized in that formed.
The method of claim 7, wherein
In step (c),
(c1) the bottom slab binding the fiber rod extending from the upper base and the fiber rod for slab to reinforce the fiber rod;
(c2) installing a fiber net or zinc net at the bottom and attaching a vinyl cover;
(c3) spraying the lower surface with high-strength polymer mortar;
(c4) Pottery construction method using a fiber rod, characterized in that the construction including the step of placing a concrete slab or high-strength mortar to complete the floor slab.
9. The method according to any one of claims 3 to 8,
The bracket
One side is fixed to the base frame, the other side is fixed to the exterior material, etc., the ceramic construction method using a fiber rod, characterized in that the fixing piece is formed to fix the fiber rod in the longitudinal and transverse direction.
9. The method according to any one of claims 3 to 8,
The exterior material,
Concrete panel, Styrofoam, Fiber mesh, Zinc mesh, Iron mesh, Stone panel, Wood panel or Iron panel with polymer mortar and inner trapezoidal, square or 'V' shaped grooves Pottery construction method using fiber rod, characterized in that one.
The method according to any one of claims 1 to 8,
A carbon dioxide meter for measuring indoor carbon dioxide amount;
It further comprises a ventilation system interlocked with the carbon dioxide meter:
If the measured value of the carbon dioxide measuring instrument is more than a predetermined range, the ceramic construction method using a fiber rod, characterized in that to prevent the oxygen deficiency by operating the ventilation equipment.
11. The method of claim 10,
The styrofoam is,
After installing the styrofoam sheath and fiber rod of 50 to 150mm thickness on the bracket,
Injecting the polymer mortar into the grooves of the styrofoam into the polymer mortar to integrate the polymer mortar, the fiber rod and the styrofoam,
Pottery building construction method using a fiber rod, characterized in that by applying a dry bit-coated polymer mortar to enable external insulation.
13. The method of claim 12,
The connection between the outer styrofoam outer covering,
Attaching the waterproof sheet to the inner side with a spacing of 1 to 15 mm;
Caulking the adhesive flexible waterproofing material in the groove between the styrofoam exterior materials;
Pottery building construction method using a fiber rod, characterized in that the finish caulking with a hardened flexible caulking material outside the groove between the styrofoam exterior.
(A) constructing a floor foundation;
(B) installing a base frame on the floor foundation;
(C) installing the bracket on the base frame;
(D) attaching the exterior material to the base frame, and fixing the fiber rod to the bracket; And
(E) constructing a wall of the building by spraying high-strength polymer mortar from the inside of the building toward the sheathing material:
The basic frame,
The frame is composed of a circular or square pipe, a ceramic construction method using a fiber rod, characterized in that it is configured in the form corresponding to the shape of the building to fix the exterior material and the fiber rod.
15. The method of claim 14,
The step (A)
(A1) digging the ground on which the building is to be located to a predetermined depth, and constructing a pile (pile) on the excavation surface;
(A2) Pottery construction method using a fiber rod, characterized in that performed by connecting to the pile head to the fiber rod on the bottom surface, and placing and curing concrete or high-strength polymer mortar.
(a) constructing an underwater foundation at the bottom of the sea;
(b) constructing an upper foundation above the underwater foundation;
(c) constructing a bottom slab on the upper foundation;
(d) installing a base frame on the floor slab;
(e) installing the bracket on the base frame;
(f) attaching an exterior material to the base frame and fixing the fiber rod to the bracket; And
(g) constructing a wall of the building by spraying high-strength polymer mortar toward the exterior material from the inside of the building;
The basic frame,
The basic frame is a frame consisting of a circular or square pipe, a ceramic construction method using a fiber rod, characterized in that it is configured in a form corresponding to the shape of the building to fix the exterior material and the fiber rod.
17. The method of claim 16,
Step (a),
(a1) perforating the seabed or seabed rock;
(a2) placing the fiber rod in the perforation space; And
(a3) Pottery building construction method using a fiber rod, characterized in that it is carried out including the step of pouring the epoxy mortar of the VOC-cutting type in the perforated space.
17. The method of claim 16,
In step (b),
(b1) installing any one of the pillar formwork made of PE, PVC, PP or anticorrosive steel pipe on the underwater foundation;
(b2) placing the fiber rod into the pillar formwork; And
(b3) pouring the VOC-cutting underwater epoxy mortar or underwater concrete into the pillar formwork to form an upper foundation into which the fiber rod is inserted;
The fiber rod reinforced to the underwater foundation extends to a predetermined length above the underwater foundation, and the extended fiber rod is connected to the fiber rod of the upper foundation under the upper foundation so that the underwater foundation and the upper foundation are integrally formed. Pottery construction method using a fiber rod, characterized in that formed.
17. The method of claim 16,
In step (c),
(c1) the bottom slab binding the fiber rod extending from the upper base and the fiber rod for slab to reinforce the fiber rod;
(c2) installing a fiber net or zinc net at the bottom and attaching a vinyl cover;
(c3) spraying the lower surface with high-strength polymer mortar;
(c4) Pottery construction method using a fiber rod, characterized in that the construction including the step of placing a concrete slab or high-strength mortar to complete the floor slab.
20. The method according to any one of claims 14 to 19,
The exterior material is composed of styrofoam formed in the inner surface of the trapezoidal, square or 'V'shape;
Attachment of the base frame and the exterior material,
Ceramic construction method using a fiber rod, characterized in that the base frame is seated in the channel-shaped groove formed on the inner surface of the styrofoam.
21. The method of claim 20,
The inverted trapezoidal, square or 'V' shaped groove,
Pottery construction method using fiber rod, characterized by high strength mortar is filled.
21. The method of claim 20,
The construction work of the high strength polymer mortar,
Constructing a high-strength polymer mortar at the intersection of the fiber rods;
Pottery construction method using a fiber rod, characterized in that carried out including the step of spraying a general mortar on the high-strength polymer mortar construction surface.
21. The method of claim 20,
On the vertical joint surface of the styrofoam,
And each of the grooves into which the fiber rods can be inserted is formed, and an end portion of the fiber rod is embedded in the groove to form a wall.

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