KR100934415B1 - Construction method of buidlings using flexible form - Google Patents

Abstract

The present invention relates to a construction method of a building using a flexible formwork, after constructing an air film-type formwork using the flexible formwork to the frame frame structure, and constructing an intermediate material and a waterproofing material to maintain the shape of the air film-form formwork, and finally, The present invention relates to a method of placing a mortar on an external surface and curing to complete a theme-shaped building of a prescribed strength. In the building construction method of the present invention, the complex construction intended by the designer by applying a wet construction method to solidify by pouring the liquid material in the field after the formwork using a flexible formwork for the construction of the external wall and roof of the building, etc. And various types of themed buildings can be constructed in short air at low cost.

Flexible formwork, air film, building construction, urethane, sandwich structure

Description

Construction method of building using flexible formwork {Construction method of buidlings using flexible form}

The present invention relates to a construction method of a building, and more particularly, after constructing an air film-type formwork using a flexible formwork on a frame frame structure, constructing an intermediate material and a waterproof material to maintain the shape of the air film-type formwork, and finally, The present invention relates to a method of placing a mortar on an external surface and curing to complete a theme-shaped building of a prescribed strength.

There are various problems in the construction of general concrete buildings. For example, in order to achieve the purpose of long-term construction of air, the necessity of facilities such as heavy equipment, the functional aspects such as waterproofing and heat dissipation, and the purpose of design vision which should be good to see. There is a burden of economic costs due to the use of expensive interior / exterior building materials, and additional problems include inconvenience of pedestrians and passing vehicles due to the occupation of surrounding roads during construction.

Therefore, in the industry, a module building method of a concept of manufacturing a factory using a building module or a panel and simply constructing it in the field has been proposed and used, but this has a disadvantage that it can be used only in a temporary building or a small building. .

Although not all can be enumerated, the basic considerations in the selection of architectural structures are: First, the building is the container of human life. First, the safety of human being must be safely accommodated. Second, waterproofing, insulation, Habitability to secure physical performance such as mining, ventilation, etc. Third, durability to be able to maintain physical and mechanical performance as it is used for a long time, economical to consider the reduction of air and construction cost while satisfying constant performance, Fifth, since the structural method itself is an expression of architecture, it is necessary to select a structural method that is reasonable.

In general, the building structure can be classified by its construction method, type, member material and construction method, and depending on the material, wood construction (timber structure), brick construction (most), and most large building structures It is applied to cement block and mortar with a bearing wall, and if necessary, cement block construction reinforced with reinforcing steel and mortar in the inner space of the block, and reinforcing steel in molds and concrete in between It can be classified into reinforced concrete structure which is integrally formed by pouring. Recently, it is a structure made of steel (steel, steel plate), which is made of steel, and it is steel structure using welding, rivets, bolts for joining members, fireproof, durable, Steel reinforced concrete structure using steel frame and reinforced concrete group together for seismic performance is applied.

In addition, depending on the construction method, water is required to manufacture the structure, such as masonry structure and reinforced concrete structure, and there are limits to unit work and standardized members such as wet construction, wood structure, and steel structure, which require a certain time for hardening. Dry construction that can shorten the air without the time required for drying the water and the members by assembling the structure, and the structure for manufacturing, processing, assembling and installing the members for the construction of the structures described above in a large area. Field construction, which requires the site area of the building, as well as the fabrication and processing of the members in the factory, and assembly and installation in the field, reduces the construction cost and ensures uniform quality and reduces the air quality due to mass production. There is a prefabricated structure.

Also, it is a classification of structure type, which consists of pillars, beams, and floors, and uses the curved surface stress by using a plate member with a thin curved surface than the ramen structure, sheet structure, and curvature radius used for reinforced concrete and steel structures. The shell structure of the long span processing method, the three-dimensional truss space frame structure in which a single member is combined three-dimensionally, and the technical field to which the present invention belongs, are characterized by the structural stability and the ability to freely make openings. It is economical and has excellent economical efficiency. It is designed to save the uniqueness of curved surface in a form that is wide and diverse, and has abundant ups and downs (high and low) regardless of large and small size, and a structure that can build a high visual effect with strong impact. Truss Membrane Structure; Suspension Membrane structure; Air dome.

Since the construction field of the present invention mainly relates to a theme building having a complex external structure and simultaneously performing internal functions of a general building and further having various advantages, a description of a general building will be omitted below.

The building used in the present invention is not only a general building but also an exhibition hall that holds annual events under various themes such as a firefly festival and a butterfly festival, which can be called today's formative buildings, a museum of a specific theme, an art hall, a cultural hall, It means a themed building with complex appearance applied to cafes, restaurants, amusement parks, amusement parks, etc.

Themed buildings with such complex shapes, such as surrealism, a mixture of elements such as decorative motifs reminiscent of plant shapes, fantastic curves, curved surfaces, neo-Gothic, art nouveau, etc. It is very difficult to build a building, such as the Gaudi style of the Spanish architect Antonio Gaudi.

Because the construction cost of forming formwork or interior / exterior materials construction is much higher than that of general buildings, compared to the artistic properties of the finished building, the general owners use enormous costs to build such buildings, prolong the construction air, This is because construction is not easy due to limitations.

On the other hand, Silla is based on the original and splendid Silla style by accepting and subjecting the northern Scythian culture, Gaya, Baekje, Korean culture of Goguryeo, China's 6 trillion and sudan culture, and southern marine culture such as India. When you want to build earthenware-type tea houses, you should construct them with complex buildings.

Looking at the outline of this construction process, first, clay, wood, synthetic resins (styrofoam, urethane, etc.) and metal materials are carved to form a prototype. The prototype is released (released), that is, surfactant is applied and formwork is made of gypsum, FRP, FRC or steel.

After demolding the formwork, all of the circular material is removed, and the formwork is assembled as it is. Cast using all possible materials, including resin, gypsum, metals and wood. In other words, it is made by attaching various building materials inside or outside and finally remove the formwork.

However, when building the complex outline-type building described above according to the conventional building method, there are the following problems.

It is necessary to make a prototype with enormous manpower and capital. This is expensive because the individual components of a complex building must be carved, and the process of making formwork is very complicated, so that the desired complex sculptures cannot be made as desired. Thus, architectural appearances are constructed that are quite different from the original designer's intentions.

In addition, the process of dismantling the formwork is very cumbersome and requires a lot of manpower, the problem of environmental pollution due to the disposal of the formwork material, and the complex, detailed and sophisticated appearance architecture required by modern people with high eye level, In other words, it cannot meet the demands of modern people who prefer curved and curved surfaces and strange shapes.

Eventually, due to these problems, the unit price of the building is so high that the builder has to give up the construction of the complex building from the beginning of the building, and it is difficult to see the beautiful building around us.

In recent years, the demand for construction of various themed buildings with strange appearances in Korea and other parts of the world has been increasing day by day, and the construction method that meets the standards required by the Building Code and is easy to build and does not cause an increase in construction costs is urgently required.

As learned from the above example, the formative buildings of the Silla era are roughly compared to the total cost of construction and the finished artistic value (though not a simple comparison, of course). It is far more than a side, so unfortunately, despite the socio-cultural demands such as ripe ripe deterioration, the realization of formative buildings is unfortunate.

Therefore, the present invention has been invented in consideration of the above points, and after constructing the air film-type formwork using the flexible formwork to the frame frame structure, construct the intermediate material and the waterproofing material to maintain the shape of the air film-type formwork, and finally The purpose is to provide a method of finishing themed buildings of specified strength by pouring and curing mortar on the outer surface.

In order to achieve the above object, the present invention,

Constructing a frame skeleton structure in consideration of the shape of the building;

Manufacturing a flexible formwork for forming an external shape of a building to be constructed and covering and fixing it on the outer side of the frame frame structure;

Forming an air film-type formwork maintained in the shape of the building by blowing compressed air into the inner space of the flexible formwork fixedly fixed to the frame frame structure using a blowing means;

Constructing an intermediate material on the surface of the air film-type formwork while maintaining the internal space of the air film-type formwork using the blowing means to impart shape retention and strength to the formwork;

Constructing a waterproofing material on an outer surface of the intermediate material in the finished state, and placing and curing mortar on the inner and outer surfaces of the intermediate material and the waterproofing material;

It provides a construction method of the building using a flexible formwork including a.

In a preferred embodiment, the step of forming the air film-shaped formwork is characterized in that the air frame-shaped formwork is formed by installing a diaphragm in the frame frame structure and blowing compressed air into the interior space of the room formed by the flexible formwork and the diaphragm. .

In addition, the diaphragm is installed in the frame framework in the step of forming the air film-type formwork to partition the inner space of the entire flexible formwork into several sealed rooms,

The compressed air is blown into the inner space of the closed room to form an air film-type formwork, and the process of constructing an intermediate material for the air film-type formwork is characterized in that it is carried out for each partitioned room.

In addition, in order to form an air film body having an outer shape of the convex portion in the step of forming the air film-shaped formwork, it is characterized in that the internal pressure is maintained at a pressure higher than atmospheric pressure in the corresponding portion of the flexible formwork.

In addition, after the diaphragm is installed into the frame frame structure, the internal pressure of the sealed room formed by the flexible formwork and the diaphragm is maintained at a pressure higher than atmospheric pressure.

In addition, in order to form an air membrane body having an outer shape of a concave portion in the step of forming the air membrane type die, the inner pressure of the sealed room formed by the flexible die and the diaphragm is lower than atmospheric pressure after installing the diaphragm inside the frame frame structure. It is characterized by maintaining the pressure.

In addition, the construction of the intermediate material is characterized in that the process of foaming by spraying the application of a liquid urethane to the surface of the flexible formwork forming the air film-form formwork.

In addition, the construction of the intermediate material is an internal coating for urethane on the inner surface of the flexible formwork forming the air film-like formwork, an external coating for urethane on the outer surface of the flexible formwork, on the inner and outer surfaces of the flexible formwork It characterized in that it proceeds to any one of the internal and external mixed coating construction for constructing urethane.

In addition, the construction of the intermediate material,

Constructing a low foaming urethane layer on a surface of the flexible formwork to form a low foaming urethane layer;

Constructing a high foaming urethane layer on the surface of the low foaming urethane layer to form a high foaming urethane layer;

Constructing a low foaming urethane layer on the surface of the high foaming urethane layer to form a low foaming urethane layer;

Proceed to characterized in that the construction of the sandwich material intermediate structure.

In addition, the low-foaming urethane layer is applied to the surface of the flexible formwork and the surface of the high-foaming urethane layer,

After the low foaming urethane is coated, the glass fiber material is laminated on the surface thereof, and then the low foaming urethane and the glass fiber material are laminated alternately until the desired thickness is obtained.

In addition, the glass fiber material is characterized in that using one or a mixture of two or more of the glass fiber mat manufactured by weaving the glass fiber, glass fiber material or glass fiber of the fiber itself.

In addition, in the case of applying the urethane to the outer surface of the flexible formwork to form a concave by shaping the material of the outer coated urethane layer or to form a protrusion by additionally adding the urethane to the outer coated urethane layer partially. It features.

In addition, after the construction of a plurality of iron pins penetrating through the flexible formwork, intermediate material, and waterproofing material in the entire area where the mortar is constructed before the mortar construction, the both ends of the iron pins are embedded in the mortar to be installed on the interior and exterior surfaces of the building. It is characterized in that the internal mortar and the external mortar is bound by the iron pin.

In addition, a T-shaped iron pin is used as the iron pin, and a pad having absorber washer and a waterproofing agent is installed in the T-shaped iron pin, and then the T-shaped iron pin is penetrated from the outer surface of the waterproofing material to absorb the waterproofing agent. The waterproof material is characterized in that the iron pin is embedded in the waterproof completely.

In addition, in the process of mortar on the outer surface, before installing the mortar, the elastic material for cutting the material along the boundary line is installed on the outer surface on which the waterproofing material is constructed, and then mortar is poured on both sides of the boundary line, together with the mortar construction. Characterized in that the material break construction.

In addition, the mortar construction is characterized by proceeding by repeatedly carrying out the construction of the mortar and the structural material in a manner of placing the mortar and then placing the structural material on the target surface until the final thickness.

In addition, the structural material is characterized in that the selected one of the rebar, wire mesh, glass fiber material, steel fiber, metal lath.

In addition, the construction method of the building using the flexible form of the present invention as described above, to complete the construction of the building by finally proceeding to the construction of the interior, exterior materials required during the construction of asphalt single, wood, stone, steel, tile, paint on the surface of the mortar. It further comprises a step.

Accordingly, according to the building construction method of the present invention, it is possible to construct a theme-shaped building of various shapes using a flexible formwork, perfect waterproof, insulation, sound insulation, by construction of intermediate materials and waterproof materials using materials such as urethane Fire prevention, dustproofing, etc. can be made, and finally, mortar can be poured and cured inside and outside of a building, and the building of a prescribed intensity | strength can be completed.

In particular, since the formwork itself already has a condition that does not have air, and a separate waterproof material is installed on the outside, construction of a building having a perfect waterproof function is possible.

In addition, the urethane constructed as a structural material for maintaining the shape of the formwork has a very excellent thermal insulation performance, as well as the liquid is sprayed and applied to the entire surface of the formwork sealed the inside of the urethane to solidify the construction, so that heat is lost Completely blocking and closing the exit route will allow the construction of buildings with perfect insulation.

In addition, since the entire interior and exterior are completely covered with mortar, the entire surface is covered with mortar without the part exposed to the material that is weak to heat and flame, thus enabling perfect flame and fire prevention.

In addition, since the mortar and the structural material are repeatedly laminated, the integrated structure forms a structure that is strong in tension and compression at the same time as the tunnel structure, so that the construction of a building that is extremely resistant to vibration and earthquake (lateral force) is possible.

In addition, by constructing the formwork using the flexible formwork for the external wall of the building, we apply the wet construction method that solidifies by pouring the liquid material on-site. There is an advantage to being able to.

In particular, by applying a low cost of construction, a short construction period, and a simple construction technology, there is an advantage that it is possible to construct more detailed, beautiful and sophisticated themed buildings, regardless of the size of the building.

Hereinafter, the features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. The terms or words used in the present specification and claims are consistent with the technical spirit of the present invention on the basis of the principle that the inventor can appropriately define the concept of the term in order to explain his invention in the best way. It should be interpreted as meaning and concept.

The present invention relates to a method of constructing a building, in particular, a theme-type building using a flexible formwork, and will be described in detail with reference to the accompanying drawings.

Flexible formwork in the present invention is a formwork made using a flexible fabric fabric, which is used as an air membrane when constructing a building of the desired shape is a nylon or woven paper coated with a polyurethane on one side for the purpose of preventing air leakage and waterproofing Can be used.

Basically, a high strength fabric should be used so as not to be easily stretched by the material of the flexible formwork and not to be easily torn, and various and flexible shapes may be formed only by injecting air such as a convex part, a concave part, a protrusion or a depression as described below. The material itself must be flexible to form.

The manufacturing process of the flexible formwork used for the construction of the theme building in the present invention is disclosed in Patent No. 732252 (2007.6.19) filed and registered by the present applicant.

The present invention is to provide a method for constructing a theme-type building using the same after manufacturing the flexible formwork according to the manufacturing process of the flexible formwork disclosed in the patent.

According to the manufacturing process disclosed in the patent to produce a flexible formwork in accordance with the appearance of the theme-type buildings to be installed and install it by attaching and fixed to the frame frame structure of the building proceeding as the actual design, attached Figure 1 And FIG. 2 is a view showing a state in which a frame frame structure of a building is constructed and a state in which a flexible formwork is put on the frame frame structure, respectively.

Hereinafter, a process of constructing an air film-shaped formwork having a desired shape by applying a flexible formwork to a frame frame structure of a building will be described in more detail.

1 is a state diagram in which a frame frame structure is installed according to the shape of a building. As shown in FIG. 1, the frame frame structure 110 is constructed in consideration of the shape of the building, wherein the frame frame structure 110 is a building to be constructed. It is a structure that is assembled by using straight or curved frame members of various lengths such as H-shaped steel, c-shaped steel, and L-shaped steel to support and maintain flexible formwork according to its shape.

In the process of constructing the frame frame structure 110, assembling the frame members of various shapes to create the outline outline frame of the building, as well as to assemble the frame members in the interior to cover the desired form when the flexible formwork on the outside The construction should be advantageous to make.

In addition, in addition to the construction of the frame frame structure 110, in order to form the air chambers partitioned as needed in a state in which the flexible formwork is installed, a diaphragm or the like for partitioning the space is installed in the frame frame structure.

After the frame frame structure 110 is installed as described above, it is fixed to the outside of the frame frame structure by covering the flexible formwork 100 as shown in FIG. 2, and thereafter, blowing means (FIGS. 3 to 5) in the sealed inner space. By blowing compressed air using reference numerals 121 and 123) to form an air membrane having an external shape of the building.

At this time, basically, the compressed air is blown into the blowing means in order to construct the air membrane having the convex portion as the design of the building to make the internal air pressure of the flexible formwork higher than atmospheric pressure.

It is also possible to use a diaphragm (refer to reference numeral 111 in FIG. 5), which is provided with compressed air for a separate enclosed air chamber formed by the flexible formwork 100 and the diaphragm 111 after installing the diaphragm inside the frame framework. It is possible to maintain the internal pressure of the air chamber at a pressure higher than atmospheric pressure by blowing air (see Fig. 5).

In addition, for the part having a concave shape of the building, the diaphragm 112 is installed inside the frame frame structure to form a separate air chamber together with the outer flexible formwork 100, and the flexible formwork 100 and the diaphragm 112 are formed. The air is drawn out by the blowing means 123 to the separate sealed air chamber formed by the air chamber to maintain the internal pressure of the air chamber at a pressure lower than atmospheric pressure to form a desired concave shape (see FIG. 3).

Various methods can be applied to secure the flexible formwork on the periphery of the frame frame structure, and a method of installing a zipper on the required portion of the flexible formwork is available. So that the flexible formwork can be secured by tightening the frame framework.

Alternatively, it is possible to fasten it to the frame frame structure by tying it with a string, and to further secure the flexible formwork to the frame frame structure by using additional wires in other necessary places.

Of course, it is also possible to make a desired building shape by connecting the flexible formwork to each other after the production of the flexible formwork by dividing it into pieces and covering each frame frame structure (using a zipper method, etc.).

Flexible formwork, frame frame structure, and compressed air is added to or removed from the interior space formed by the diaphragm to create an outer shape of the building, thereby completing the air-film formwork that maintains a constant shape. The interior should be maintained at a constant pressure to avoid air deflation and should be accompanied by a proper pressure check in the formwork.

3 to 5 are views showing an example of constructing various forms of formwork using a blower as a blowing means, Figure 3 is a view showing the construction process of the concave portion.

As shown in the drawing, basically, the compressed air is blown by using a blower 121 in the sealed inner space of the flexible formwork 100 installed in the frame framework so that the convex portion is constructed. In order to construct 100a), first, a separate air chamber is made by using the diaphragm 112, and then the air is drawn out by a separate blower 123 for the air chamber to be made in a negative pressure (vacuum pressure) state.

When the air is blown out by the blower 123 in the separate sealed air room, a portion corresponding to the air room of the flexible formwork 100 is pulled inward to express the concave portion 100a.

4 is a view showing an example of constructing an irregular outer form including a depression, after installing an additional diaphragm in the frame frame structure blows compressed air into the blower 121, the projection and the depression by the diaphragm is divided When the flexible formwork 100 is expanded to have a shape, the formwork of a desired shape is possible.

5 is a view showing another example of the construction of the irregular shape of the form, additionally installed a diaphragm 111 in a specific portion as needed, and fixed by covering the flexible formwork (100) with a blower 121 in the inner space Blowing compressed air enables the construction of protrusions with certain parts protruding outward.

After the air film-type formwork is constructed as the shape of the building, it must be strengthened by spraying and applying intermediate materials with a certain strength on the inside / outside of the formwork, and the blower is maintained to maintain the constant pressure until the form reaches a certain strength as the designer intended. You must continue to infuse air by means.

In this way, the flexible formwork of the present invention is completed and applied to the construction of a theme-type building, and in the subsequent process, a material (reinforcement material) having a suitable strength is applied by molding to form a wall or roof having a strength that meets the building code standards. do.

Hereinafter, a process of constructing an intermediate member after constructing a flexible formwork according to the shape of the building to the frame frame structure will be described in more detail.

6 is a view of a state in which the construction of the intermediate material is completed by applying compressed air to a partitioned enclosed space of the flexible form by blowing air to form a convex shape air film body and applying the internal material to the portion where the air film body is formed. to be.

In addition, Figure 7 is a state of completing the construction of the intermediate material after covering the flexible frame to the frame frame structure, Figures 8 to 11 are attached to the cross-sectional view showing an example of the construction of the intermediate material, a variety of intermediate materials in the flexible formwork The state of coating and lamination is shown.

Intermediate materials are installed on the inner and outer surfaces of the flexible formwork for the effect of sound insulation and insulation, and during construction, the intermediate material also serves to maintain the shape of the flexible formwork until the construction of the reinforcement is completed.

As the material of the intermediate material, a material that can be solidified after being applied to the inner and outer surfaces of the flexible formwork is used.In this case, if the intermediate material is solidified after application, the shape of the flexible formwork can be maintained, and the construction of the intermediate material is completed and then compressed by a blower. It allows to maintain the shape of the flexible formwork without blowing air. In other words, the flexible formwork is not to be turned off or settled down by the intermediate material.

First, FIG. 8 is a view showing an example in which the intermediate material is applied to the inner surface of the flexible formwork, that is, internal coating, and FIG. 9 is a view showing an example of the intermediate material applied to the outer surface of the flexible formwork. 10 is a view showing an example in which both the inner / outer mixed coating, that is, the intermediate material is installed on both the inner and outer surfaces of the flexible formwork.

In the building construction process of the present invention to be described later, the intermediate material may be installed on both the inner and outer surfaces of the flexible formwork or only on one of the inner or outer surfaces. In other words, the internal coating of FIG. 8, the external coating of FIG. 9, and the internal / external mixed coating of FIG. 10 may be selectively applied in consideration of construction conditions according to each part of the building.

Referring to the internal coating process of Figure 8, using the urethane as the material of the intermediate material, preferably an intermediate material having a sandwich structure as a whole by laminating in the order of low-foam urethane, high-foam urethane, low-foam urethane on the inner surface of the flexible formwork Construct it.

At this time, the worker enters the inner space of the flexible formwork 10 and spray-coated a low-foaming urethane material on the inner surface of the flexible formwork using a urethane coating machine to laminate the low-foaming urethane layer 11 first, followed by a low-foaming urethane. The high foaming urethane material is spray-coated on the inner surface of the layer to laminate the high foaming urethane layer 12, and then the low foaming urethane material is sprayed on the inner surface of the high foaming urethane layer to stack the low foaming urethane layer 11. Construct.

As described above, a low-foam, high-foam, low-foam urethane layer (11, 12) of the intermediate structure of the sandwich structure is constructed, the low-foam urethane has a small pore and dense material has a relatively high strength, Polyurethane has a relatively low strength due to its large pores and less dense material.

Highly foamed urethanes can form thick layers in the same amount but have low strength, and low foamed urethanes form relatively thin layers but have high strength. Therefore, the use of high foamed urethane alone makes it easy to obtain the desired thickness, but it is difficult to obtain the strength to support the flexible formwork. If the high foamed urethane alone is used to achieve the desired strength, it must be constructed to a considerable thickness using a considerable amount of material. .

Conversely, using low foaming urethanes alone makes it easy to achieve the desired strength, but requires a significant amount of material to achieve the desired thickness, resulting in high costs. In particular, when a single layer structure using only low foaming urethane is used, not a sandwich structure, the surface is hard but the low foaming urethane is a single layer, so that the entire layer is easily bent, thereby supporting the formwork during the subsequent process. There will be no.

Accordingly, the low-foam and high-foam urethane is appropriately mixed, but when the construction of a sandwich structure in which the low-foam urethane layer 11 is laminated on both sides of the high-foam urethane layer 12, the desired thickness and strength can be easily achieved. It is possible to obtain economical construction.

In short, in order to maintain the shape of the flexible formwork forming the air film-type formwork, the low foaming urethane layer 11 is first applied to the inner surface of the flexible formwork 10, and then the high foaming urethane layer 12 is laminated thereon. Finishing again with a low foaming urethane layer 11, the intermediate material of the desired strength and thickness to a sandwich structure filled with a high foaming urethane therein.

In addition, in the sandwich structure in which two hard layers are stacked on one side of a relatively soft layer, the whole layer can be bent by a large force, but the bending phenomenon is greatly reduced. The layers are against tension and the other one against compression, resulting in a very strong overall structure.

When urethane foaming is applied by spraying the material on the target surface with a urethane coating machine, the material is solidified while being instantaneously foamed within a short time, and the desired urethane layer can be formed.

In addition, in order to construct a single low-foaming urethane layer 11, by spraying the material and then spraying the material again, the spray coating is repeatedly applied several times to obtain a desired thickness. In the construction of 12), spraying is repeated several times to obtain a desired thickness.

And, in a preferred embodiment, each of the low-foaming urethane layer 11 itself can be constructed in a sandwich structure, for this purpose is constructed by alternately laminating a low-foaming urethane material and glass fiber material.

That is, after spray coating the low-foaming urethane material to solidify at the same time as the foaming, laminated the glass fiber material on the surface, and then spray-coating the low-foaming urethane material to form a layer, and then again on the surface of the glass fiber material In this way, the two materials are laminated alternately until the desired thickness is obtained to construct a low foaming urethane layer.

The glass fiber material may be a glass fiber mat manufactured by weaving glass fiber, glass fiber material in the form of ordinary glass fiber, 촙 of the fiber itself, and these are commercially available materials. Of course, one of the aforementioned glass fiber materials or two or more kinds of mixed materials may be used.

As a result, when constructing a low-foaming urethane layer 11 using a glass fiber composite as described above it is possible to obtain a very high strength layer while being a structure in which the glass fiber and the urethane is integrated.

In addition, instead of using low-foam urethane, a sandwich structure may be constructed by applying FRP material, high-foam urethane material, and FRP material in order to the inner surface of the flexible formwork. In the construction of FRP material, a wet method is applied to solidify the liquid material in the target surface.

On the other hand, it is possible to apply the intermediate material for maintaining the shape on the outer surface of the flexible formwork, this external application will be described with reference to FIG.

First, the low-foaming urethane layer 11 is formed by spray-coating and foaming a low-foaming urethane material using an urethane coating machine on the outer surface of the flexible formwork 10.

At this time, the low-foaming urethane layer 11 to be laminated on the outer surface of the flexible die 10 is constructed by alternately laminating a low-foaming urethane material and glass fiber material similarly to the low-foaming urethane layer constructed in the inner coating process of FIG. .

That is, after spray coating the low-foaming urethane material to solidify at the same time as the foaming, laminated the glass fiber material on the surface, and then spray-coating the low-foaming urethane material to form a layer, and then again on the surface of the glass fiber material In this way, the two materials are laminated alternately until the desired thickness is obtained to construct a low foaming urethane layer.

The glass fiber material may be a glass fiber mat manufactured by weaving a glass fiber, a glass fiber material in the form of 촙 or glass fiber of the fiber itself.

After the low foaming urethane layer 11 is constructed as described above, a high foaming urethane layer 12 and a low foaming urethane layer 13 are sequentially formed on the outer surface thereof, and the outer surface of the low foaming urethane layer 13 is formed. After laminating the glass fiber material 14 to the low-foaming urethane layer 13 to form a laminate.

The external coating process proceeds to a process of foaming and solidifying the urethane material on the outer surface of the flexible formwork.

On the other hand, Figure 10 is a cross-sectional view showing the construction state of the inner / outer mixed coating to laminate the intermediate material on the inner / outer surface of the flexible formwork, as an example of the inner / outer mixed coating, the inner surface of the flexible form (10) In the same manner as in the application example of the low foaming urethane layer 11, the high foaming urethane layer 12, the low-foaming urethane layer (11) of the sandwich coating structure is applied internally, the high foaming urethane on the outer surface of the flexible formwork (10) External coating to form layer 12 is performed.

As described above, examples of the application of internal coating, external coating, and internal / external blending have been described. According to various conditions, such as building appearance and construction conditions for each part of the flexible formwork, any one of internal coating and external coating and internal / external mixed coating can be used. One can be selected and constructed properly.

That is, a diaphragm is installed inside the frame frame structure and a flexible formwork is installed outside the frame frame structure to partition the inner space of the flexible form into several sealed rooms, and then compressed air with a blower inside the divided rooms. After blowing the air-filled formwork, select the appropriate method of internal or external application and internal / external application for the flexible form of the air chamber while maintaining the pressure in the interior space constant. To construct intermediate materials. At this time, the construction of the intermediate material may proceed in a predetermined order for each room.

In order to form the outer shape of the building to be constructed during the construction of the intermediate material closer to the actual shape (shape of the intended animal or object), as shown in FIG. When the material of the layer 12) is partially appropriately cut, or when urethane is partially added to the externally applied urethane layer, the recesses and protrusions can be constructed in a desired shape and position. This makes it possible to express more realistic and desired detailed shapes.

12 is a cross-sectional view of a state in which an elastic waterproof urethane or waterproof paint 15 is applied to the outer surface after completing the external coating process of the intermediate material for maintaining the shape of the flexible formwork as shown in FIG.

As shown, after the waterproof urethane coating or waterproofing paint coating for waterproofing on the outer surface of the intermediate material is mortar construction.

Attached Figure 13 is a cross-sectional view of the completion of the iron pin connection binding and mortar construction, after the waterproofing material on the outer surface of the intermediate material, the iron pin (31) construction and mortar (21) construction, flexible formwork (10 ) And the intermediate material (11, 12, 13, 14), the waterproof material 15 is installed through the T-shaped iron pin (31).

At this time, the T-shaped iron pins 31 to penetrate inward from the outside of the waterproofing material 15 so that both ends of the iron pins 31 protrude to the inside and outside of the pre-installed structure, the head of the iron pins 31 Outside of, the ends are projected into the interior of the structure.

In addition, a separate member 32 may be horizontally installed at the end of the iron pin 31, and the member may be fixed to the end of the iron pin by a welding method or a screwing method.

The iron pin 31 constructed as described above binds the mortar 21 installed on the inner and outer surfaces of the building to each other, and serves to stably bind each floor material constituting the wall of the building as a whole. .

The iron pins 31 use iron pins having a protruding structure on the surface in order to increase the binding force with the material, and construct them at predetermined positions with respect to the entire walls of the building, taking into consideration various construction conditions such as the shape of the building. Install at appropriate intervals.

As a result, the whole mortar 21, the intermediate material (11, 12, 13, 14), the mortar 21 is installed on the outside is bounded by the T-shaped iron pin 31 as a whole sandwich structure It will form a, thereby constructing a very solid and sturdy building wall.

14 is a view showing the T-shaped iron pins used in the present invention, the iron pins 31 may include a washer 31a and an elastic pad 31b fitted to the pad 31b. The T-shaped iron pins are driven in the state in which the waterproofing agent is absorbed, and the pad 31b absorbing the waterproofing agent completely waterproofs the hole embedded with the iron pins on the outer surface of the waterproofing material.

After completing the construction of the iron pin 31, as shown in Fig. 13, by spraying and applying mortar (mixing sand + cement + water at an appropriate ratio according to the required strength) (21) on the inner surface and the outer surface In this case, the mortar 21 and the structural member 22 are installed together by installing the structural member 22 on the target surface and pouring the mortar 21 to a predetermined thickness. Repeat until

As the structural member 22 to be constructed together with the mortar 21, a reinforcing bar, a wire mesh, a glass fiber material, a steel fiber (wire form), a metal lath, or the like, preferably a wire mesh having flexibility, an excellent metal lath, etc. It is better to use and these structural materials may be used in combination.

As the glass fiber material, a surface-coated product is used to be resistant to alkali, and such glass fiber material can be constructed at a high price but structurally excellent in strength, and commercialized products are available.

15 is a view illustrating a state in which a structural material such as a metal lath is constructed on an inner surface of the present invention, and FIG. 16 is a view illustrating a state in which a structural material such as metal lath is constructed on an outer surface of a waterproof material.

In a preferred embodiment, the mortar construction should be combined with the material break construction, which is to be installed before the mortar casting using the elastic material.

That is, after installing the elastic material 23 for breaking the material along a predetermined boundary on the outer surface on which the waterproofing material 15 is constructed, the mortar 21 is poured on both sides of the boundary to construct the exterior of the building.

If the material is not cut off on the exterior surface, the exterior surface constructed with mortar contracts and expands repeatedly due to the rapid external temperature change of the building, causing cracks to occur.

Therefore, the construction of the external material that is bound to the T-shaped iron pin 31 to the internal material of the building, that is, when the construction of the mortar (21) of the external material undergoing a sudden temperature change, the material must be cut off at an appropriate location. As the material cutting material, a known building material having elasticity, PVC, wood, or the like may be used.

When the mortar construction is completed as described above, the final interior and exterior construction of the building such as asphalt single (Asphalt shingles), wood, stone, steel, tiles, paint, etc. on the surface of the mortar proceeds to obtain the desired color and texture of the building, This completes the construction of the building.

Thus, in the present invention, it is possible to construct a theme-shaped building of various shapes using a flexible formwork, perfect waterproof, heat insulation, sound insulation, fireproof, dustproof (防) by construction of intermediate materials and waterproof materials using materials such as urethane Iii), etc., and finally, mortar is placed and cured inside and outside the building to complete the building of the specified strength.

In particular, since the formwork itself already has a condition that does not have air, and a separate waterproof material is installed on the outside, construction of a building having a perfect waterproof function is possible.

In addition, the urethane constructed as a structural material for maintaining the shape of the formwork has a very excellent thermal insulation performance, as well as the liquid is sprayed and applied to the entire surface of the formwork sealed the inside of the urethane to solidify the construction, so that heat is lost Completely blocking and closing the exit route will allow the construction of buildings with perfect insulation.

In addition, since the entire interior and exterior are completely covered with mortar, the entire surface is covered with mortar without the part exposed to the material that is weak to heat and flame, thus enabling perfect flame and fire prevention.

In addition, since the mortar and the structural material are repeatedly laminated, the integrated structure forms a structure that is strong in tension and compression at the same time as the tunnel structure, so that the construction of a building that is extremely resistant to vibration and earthquake (lateral force) is possible.

According to the building construction method of the present invention, by applying the wet construction method to solidify by pouring the liquid material in the field after the formwork using a flexible formwork for the construction of the external wall of the building, the designer intended and complicated There is an advantage that can be constructed themed buildings having a variety of shapes.

In particular, by applying a low construction cost, a short construction period, a simple construction technology, there is an advantage that can be constructed more detailed, beautiful and sophisticated theme-type buildings compared to the conventional regardless of the size of the building.

In the above, a specific preferred embodiment according to the present invention has been described. However, it is to be understood that the present invention is not limited to the above-described embodiments, and the above-described embodiments merely represent a part of various embodiments to which the principles of the present invention are applied. Those skilled in the art to which the present invention pertains may make various changes without departing from the spirit of the technical idea of the present invention described in the claims below.

1 is a view showing a state in which the frame frame structure in the present invention,

Figure 2 is a view of a state in which the flexible formwork frame the frame structure in the present invention,

3 to 5 is a view showing an example of constructing the formwork of various shapes using a blowing means in the present invention,

Figure 6 is a view of a state of completing the construction of the intermediate material by the internal coating method to the air membrane formed part in the present invention,

7 is a view of the completed state of the construction of the intermediate material after covering the flexible formwork frame frame structure in the present invention,

8 to 11 is a cross-sectional view showing an example of the construction of the intermediate material in the present invention, showing a state in which the laminated construction by applying the intermediate material in various structures to the flexible formwork,

12 is a cross-sectional view of a state in which an elastic waterproof urethane or waterproof paint is applied to the outer surface after completing the external coating process of the intermediate material for maintaining the shape of the flexible formwork in the present invention,

Figure 13 is a cross-sectional view of the completed state of the iron pin connection binding and mortar construction in the present invention,

14 is a view showing a T-shaped iron pin used in the present invention,

15 is a view showing a state in which a structural material such as metal lath on an inner surface of the present invention;

Figure 16 is a view of a construction material such as metal lath on the outer surface of the waterproof material is applied in the present invention.

<Explanation of symbols for the main parts of the drawings>

10: flexible die 11: low foaming urethane layer

12: high foaming urethane layer 13: low foaming urethane layer

15: waterproofing material 21: mortar

22: structural member 23: material breaking elastic material

31: iron pin 100: flexible formwork

110: frame structure 121, 123: blowing means (blower)

Claims (1)

Constructing a frame skeleton structure in consideration of the shape of the building; Manufacturing a flexible formwork for forming an external shape of a building to be constructed and covering and fixing it on the outer side of the frame frame structure; Forming an air film-type formwork maintained in the shape of the building by blowing compressed air into the inner space of the flexible formwork fixedly fixed to the frame frame structure using a blowing means; Constructing an intermediate material on the surface of the air film-type formwork while maintaining the internal space of the air film-type formwork using the blowing means to impart shape retention and strength to the formwork; Constructing a waterproofing material on the outer surface of the intermediate material in the finished state, and placing and curing mortar on the inner and outer surfaces of the intermediate material and the waterproofing material; In the construction method of the building using a flexible formwork, including; In the process of mortar on the outer surface, before installing the mortar, the elastic material for cutting the material along the boundary line is installed on the outer surface on which the waterproofing material is constructed, and then mortar is poured on both sides of the boundary line, and the material together with the mortar construction A construction method of a building using a flexible formwork, characterized in that the breaking construction.

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