KR20050035498A - Insulated concrete structure using reinforced pressed cement and metal stud - Google Patents

Abstract

The present invention relates to a frame panel system for constructing concrete structures such as foundation walls, walls, floors, or roofs of concrete-based structures, and various retaining walls, pipelines, soundproof walls, and fences for civil engineering. More specifically, the thermal insulation material includes a compressed cement board reinforced with glass fibers, a foamed plastic panel molded with a multi-heat wire molding machine, and a vertical reinforcing member penetrated by reinforcing bars or steel pipes in the transverse direction and bent at both edges longitudinally. The present invention relates to a stationary formwork panel system using a compressed cement plate and a steel pillar that both serve as an interior and exterior material and have a rigid structure.

Description

Stationary formwork panel system using compressed cement plate and steel columns {INSULATED CONCRETE STRUCTURE USING REINFORCED PRESSED CEMENT AND METAL STUD}

The present invention relates to a fixed formwork panel system using a compaction panel constituting a foundation wall, an interlayer floor, a roof of a building or a concrete structure, and a compressed cement board using a metal plate pill for vertical reinforcement.

1 is a perspective view showing a mold of a concrete frame structured by a formwork system using a conventional plywood formwork and rebar. As shown in Figure 1, the conventional construction or construction of a concrete structure of the construction is mainly to arrange the reinforcing bars (1, 3) vertically and horizontally in accordance with the thickness and height of the wall designed to form the foundation wall or wall and The circumference was bent with other reinforcing bars (3) to make a square or circular shape, and the reinforcement work was performed in the order of wrapping or padding and tying again with wire. In addition, along the mold of the reinforcement of the reinforcement of the reinforcing rods (4, 5) of the timber or steel stand up to face each other through the holes (6) of the connecting pins formed in the form (4, 5) to pin the connection pins Form the form of formwork in the method, and after pouring the concrete (7) into the form of the reinforcing bar and formwork after curing and drying for about 3 to 1 week, the form (4, 5) when the concrete (7) is hardened It was to dismantle. In addition, selecting a support pin protruding from the surface of the concrete or protrusion of the surface of the concrete has been widely used in the construction of the retaining wall reinforcement and the framework of the concrete.

This conventional retaining wall reinforced concrete framework method not only requires a large amount of wooden boards or sheet metal formwork, but also requires a large amount of subsidiary materials, including supports, etc., in order to form a mold by connecting and supporting the formwork with each other. This burden was considerable, and in addition, after the concrete was dried, the form was dismantled and dismantled, along with the construction and binding work of forming a frame in which a large amount of rebars were placed vertically, bent and bent other bars and crossed and tied together or wired together. The time and expense of many materials and manpower required was greatly consumed. In addition, in the construction of a structure such as a building, it was troublesome to add a separate mortar such as foamed polystyrene, rock wool, and glass fiber to cement mortar and attach it to the surface of concrete for insulation and insulation.

On the other hand, in order to improve this problem of the retaining wall reinforced concrete framework method, a technique using a foamed polystyrene hollow block as a formwork has been devised.

Figure 2 is a perspective view showing the configuration of the expanded polystyrene hollow block produced using a conventional foam molding machine. As illustrated in FIG. 2, the expanded polystyrene hollow block manufactured by the foam molding machine includes the expanded polystyrene block portion 8 and the expanded polystyrene block portion 8 and the expanded polystyrene block portion 8 having the protrusion 9 formed thereon. It was to include a block support pin 11 of a metal material disposed between the 8).

The foam polystyrene hollow block is manufactured by injecting a foamed polystyrene having a light and excellent thermal insulation effect into a mold through a foam molding machine in a state in which a metal block support pin 11 is placed inside a mold, and then demolding by applying high temperature and high pressure steam. It was then molded by cooling and drying.

However, since the expanded polystyrene hollow block is manufactured using a mold, in order to enable demoulding, the shape and structure of the hollow block are limited, and as the size of the hollow block increases, the mold also needs to be large. In addition to the need for an expensive foam molding machine, even if the size and shape of the hollow block is slightly changed, it was necessary to manufacture a separate mold corresponding to it, so the equipment cost for manufacturing the hollow block was a significant burden. In addition, the molding process for the foam molding, cooling and drying process takes a lot of time there was a disadvantage that the productivity is not good.

In addition, since the hollow block of the mold method does not connect the support pins of the metal with the support pins of the other hollow blocks, the rebar arrangement and the wires are arranged by placing rebars vertically and horizontally in a hollow block and tying them together with separate wires. Absent from the work process was a lot of manpower and time. In addition, when the concrete is poured into the expanded polystyrene hollow block, the foamed polystyrene hollow blocks may collapse due to the weight and pressure caused by the filled concrete, or liquid concrete may flow out to the connection area between the hollow blocks. It required a separate cumbersome work of bonding or bonding the connecting parts of the hollow blocks arranged in the lower, left, and right with adhesive materials such as polyurethane foam.

In addition, the foamed polystyrene foam is exposed to the outer surface of the structure even after the concrete filled in the foamed polystyrene hollow block is vulnerable to fire.To solve this problem, paint, wallpaper or wood, tile, Before attaching various internal and external materials such as marble, cement must be applied to the entire surface of the structure. Since cement is not easily adhered to polystyrene material, attach a separate glass fiber or wire mesh and apply mortar such as cement thickly. Needed work. In addition, there was a need to perform plastering and finishing work on the interior and exterior separately after attaching the wood or metal material on it.

25 is a view showing a retaining wall type reinforced concrete frame system for constituting a conventional interlayer floor. As shown in FIG. 25, the retaining wall type reinforced concrete framework for constituting the interlayer floor of a conventional building is disposed by horizontally arranging a wooden board or a sheet metal formwork 4 between the wall 13 and the wall 14. Was used as a supporting plate (12) to be filled in, and the reinforcing bar (1) laminated on the top and the side formwork (5) and the supporting plate (12) supporting the concrete were supported by a plurality of steel pipes (15) against the bottom of the lower floor. .

The prior art method for constructing such an interlayer floor had to support a formwork and support plate 12 such as plywood by raising a steel pipe 15 on the bottom of the bottom to reduce the load of the support plate 12. Even if only one steel pipe is laid down and the supporting steel pipe is collapsed, the entire supporting plate collapses to prevent the weight and pressure of the reinforcing steel and concrete stacked on the upper side. .

The present invention has been made to solve the above problems of the prior art, the object of the present invention is to replace the reinforcing bars in the vertical direction, including a foamed plastic panel and compressed cement board so that the installation is simple but also serves as a heat insulating material and interior and exterior materials In order to provide a fixed formwork panel system using a compressed cement plate using a steel sheet pillar as a vertical reinforcement and a steel pillar.

The present invention is to reduce the material of the retaining wall type reinforcement, the excess reinforcement mainly used in the concrete frame construction method, wood plywood, sheet metal formwork in constructing the walls of concrete structures for buildings or civil engineering, and to bend the reinforcing bars or tie wire Reduce the time, manpower and cost of assembling and disassembling the mold, and eliminating the formwork, and the complicated support process of forming the mold of the formwork. It is to reduce the process of working.

In order to achieve the shape of the panel, the foamed polystyrene material is injected into the foam molding machine and the mold in a bead state, and the foam molding machine and the mold are not used as compared to the hollow block of the mold method which injects steam of high temperature and high pressure to boil out with steam. By using a hot wire molding machine to easily form a form panel of various shapes to improve the productivity and to obtain a molding beauty.

In addition, when constructing floors, girders, etc., such as buildings, it does not use formwork supporting plates and support pillars, which saves time and money, and prevents sagging during use of reinforcing bars. You get the structure.

In addition, by manufacturing the foundation and exterior walls of the structure in advance in the manufacturing plant to construct a foundation wall using reinforcing bars and formwork at the construction site and to save time and cost compared to constructing the exterior walls again.

In addition, since the foam plastic panel serves as a heat insulating material, the process of attaching the heat insulating material is shortened, and there is a heat insulating material on both sides, thereby providing excellent heat insulating effect.

In addition, by attaching a mesh-reinforced compressed cement plate excellent in strength, adhesiveness, waterproofness and non-combustibility to one side of the panel, various plaster finishes such as tiles, wood, marble, wallpaper, etc. will be easily applied.

An object of the present invention described above is arranged to face each other at a predetermined interval, the compressed cement plates formed with supporting grooves on the facing surfaces; And a metal plate 샛 pillar formed with both sides of the latching jaw inserted into the support grooves to couple the compressed cement plates, and having a hole narrowing toward the inner side thereof. A fixing piece penetrates the locking jaw of the metal plate 샛 pillar inserted therein, and the compressed cement plate and the metal plate, pillar are fixed to each other. It is achieved by a fixed formwork panel system using compressed cement plates and steel studs characterized in that the reinforcing bars are fit-fit.

In addition, the object of the present invention is disposed so as to face at a predetermined interval, facing plastics formed on the facing surface is formed with support grooves that increase in width toward the inside; At least one jaw pillar formed on both sides of the engaging jaw slidingly coupled to the support groove to couple the foamed plastic panels; And a fixed formwork panel system using a steel plate and a compressed cement plate comprising a compressed cement plate bonded to at least one of the outer sides of the foamed plastic panels arranged therein.

In order to achieve the above object, the at least one hollow hole is formed by penetrating in the transverse direction at least one hole narrowing toward the bottom, the steel hole is fitted into the hollow hole of the hollow pillar, the reinforcing bar It is preferable to fit to the hole by the wedge effect.

In order to achieve the above object, it further comprises a panel engaging member is formed with engaging jaws that are slidingly coupled to the support grooves of each of the adjacent foamed plastic panels on the same plane, the locking jaws of the panel missing member support the adjacent foamed plastic panels It is preferred that the adjacent foamed plastic panels are connected by slide coupling into the grooves, respectively.

In order to achieve the above object, the compressed cement plate is preferably reinforced with glass fibers or wire mesh.

In addition, the object of the present invention is disposed so as to face at a predetermined interval to configure the inner and outer walls, the inner and outer wall foam plastic panels for the support grooves formed in the width facing toward the inner side; Foam plastic panels for the base wall, which are arranged to face at intervals greater than the predetermined interval to form the foundation wall below the inner and outer wall foam plastic panels, and the supporting surfaces having widths of the supporting grooves increasing inwardly on the facing surfaces thereof. ; At least one inner and outer wall pillars having locking jaws that are coupled to support grooves of the foamed plastic panels for inner and outer walls on both sides; Under the inner and outer wall 적어도 pillars at least two 샛 pillar pieces formed on both sides of each other in the lateral direction is formed in the locking jaw is located on both sides of the combined 샛 pillar pieces of the foam plastic panel for the base wall At least one composite stud that is slide-coupled to the support grooves of the arm; A 'b' shaped reinforcing bar welded from one surface of the inner and outer wall columns to the surface of the composite column; And it can also be achieved by a fixed formwork panel system using a compressed cement plate and a steel pillars including compressed cement plates installed on at least one of the inner and outer wall foam plastic panels and the base wall foam plastic panels.

In addition, the object of the present invention described above is a formwork panel system for constituting a floor, an interlayer floor, a roof, etc. made of concrete, which is arranged at a predetermined interval on a horizontal plane, each having a support piece extending in the horizontal direction One support beams; A compressed cement plate on which both edges of the support pieces of the adjacent support beams are supported; A straight reinforcement member disposed on the compressed cement plate so as to be orthogonal to the support beams; A foamed plastic panel installed on an upper portion of the straight reinforcement member and having a hollow pillar insertion groove formed on an upper surface thereof, the width of which increases inwardly; And it can also be achieved by a fixed formwork deck panel system using a compressed cement plate and a steel pillars including a jaw column is formed with a locking jaw coupled to the groove pillar insertion grooves of the foamed plastic panel.

Other objects, specific advantages and novel features of the invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the configuration of a fixed formwork panel system using a compressed cement plate according to a preferred embodiment of the present invention.

Figure 3 is a perspective view showing a compressed cement plate used in the stationary formwork panel system using a compressed cement plate and steel jaw column according to the present invention. As shown in FIG. 3, the compressed cement plates 20 and 25 of the formwork panel system according to the present invention are made of magnesia cement mainly composed of magnesium oxide and magnesium chloride, or cement synthesized from silicic acid (silica) and kaolin. It is made of clay and mixed with glass fiber or synthetic resin in the composition, or reinforced by stiff glass fiber or synthetic resin on both sides, and compression molded with a high pressure roller, and generally has a compressive strength of 180 kg / cm 2 or more. Therefore, the grid-like glass fiber meshes 23 and 28 formed on the inside or both sides of the compressed cement plates 21 and 26 are included.

However, the compressed cement sheet according to the present invention may use Portland cement in place of the siliceous or magnesia cement described above, and is composed of other non-combustible cement material in the form of compression with a high-pressure roller. It is also within the scope of the present invention to use compressed high strength cement plates having compressive strength.

In addition, as a reinforcing material used to reinforce the compressed cement plate, a reinforcing material of various materials may be used to prevent the breakage of concrete such as reinforced plastic or rock wool as well as a glass fiber net.

4 is a perspective view illustrating a cement plate reinforcing coupling member and a cement plate reinforcing metal coupling member fixed to the compressed cement plate of FIG. 3. As shown in FIG. 4, the cement plate reinforcing coupling members 30 and 31 are formed by cutting the compressed cement plate to have an inverted leg or rectangular cross section. As another example of the cement plate coupling member, a metal plate having a high strength, such as a galvanized steel sheet, is bent twice to form a cement (C) type metal coupling member 33 for reinforcing cement plates.

FIG. 5 is a perspective view illustrating a compressed cement board assembly in which the compressed cement board of FIG. 3 and the cement plate reinforcing bonding member of FIG. 4 are bonded. As shown in FIG. 5, the compressed cement plate assemblies 35, 36, and 37 may have cement plate reinforcement coupling members 30 and 31 and cement plate reinforcement seeds on one surface of the compressed cement plate 20. C) type metal coupling member 33 is attached. This attachment is made by bonding with a bonding agent or fixing with a bolt or the like.

6 is a perspective view showing a cement plate coupling member for connecting the compressed cement plate assembly of the formwork panel system according to the present invention. As shown in FIG. 6, the compressed cement plate coupling members 38 and 39 are for bonding the compressed cement plate binders 35, 36 and 37 to each other, and bending a metal plate of zinc hot-dip steel sheet to 90 degrees and compressing cement. The bolt hole 40 for fixing the bolt to the plate is formed.

FIG. 7 is a perspective view illustrating the compressed cement plate assembly of the formwork panel system according to the present invention in which the compressed cement plate assembly is combined in a 'corner' and 'T' shape using a cement plate coupling member and the compressed cement plate assembly is arranged in parallel. As shown in FIG. 7, the compressed cement plate assemblies of the formwork panel system may have various configurations depending on the application. For the corner-type compressed cement plate assembly 42 or T-shaped form by arranging the compressed cement plate assembly 35 in a flat plate shape or by fixing the compressed cement plate assembly 35 placed at right angles with the cement plate coupling member 38. A compressed cement plate assembly 43 is formed.

Figure 8 is a perspective view showing a foamed plastic panel of various shapes of a stationary formwork panel system using a compressed cement plate and a steel column according to the present invention. As shown in Fig. 8, the foamed plastic panel of the formwork panel system according to the present invention has a free shape such as flat, corner, 'T' shape and the like. The support groove 51 formed between the locking projections 52 formed on one or both surfaces of the foamed plastic panels 50, 55, 57, 58, and 59 has an inverted triangle in cross section. That is, the support groove 51 has a narrow width of the inlet and the inner space is formed with a larger width than the inlet. Therefore, when the locking jaw of the post pillar to be described later is coupled to the support groove in a sliding manner, the post pillar and the foamed plastic panel are not separated from each other in the transverse direction. The foamed plastic panels 57, 58, and 59 may be formed in a vertically bent shape, and protrusions 53 are formed on an upper surface thereof, and grooves (not shown) are coupled to protrusions 53 on an upper surface thereof. When the c) is formed and stacked in the vertical direction, leakage of concrete at the interface is prevented.

FIG. 9 is a perspective view illustrating a multiple electric heating molder for processing the foamed plastic panel shown in FIG. 8. As shown in FIG. 9, the multiple electric hot wire forming machine is composed of a computer 60, a hot wire forming apparatus 62, and a power supply 61. The hot wire forming apparatus 62 has a base 63 on which guide rails 64 are formed at both sides and a table 65 on which a foamed plastic block is to be placed, and along the guide rails 64 of the base 63. The electric heating wire 67, the electric heating wire 67, and the electric heating wire 67, which are formed inside the molding machine frame 66, which are linearly movable, and which are linearly movable in the vertical direction of the molding machine frame 66, It is configured to include a control unit (not shown) to operate.

Therefore, when the foam plastic block is placed on the table 65, the computer sends a signal to the hot wire forming apparatus, and the control unit of the hot wire control device controls the linear movement of the molding machine frame and the shanghai movement of the electric heating wire so that the foam plastic block is shown in FIG. It is cut or processed into free-form foamed plastic panels such as flat, corner, and 'T' shapes. In particular, the inverted triangular support grooves, etc., which were impossible in the mold method due to the problem of demolding, can be easily processed. In addition, the multi-electric wire forming machine also processes the foamed plastic studs to be described later.

The multi-heat heater molding machine can process not only expanded polystyrene but also expanded plastic blocks of various materials such as expanded polyurethane, expanded polypropylene, or expanded polyethylene having excellent impact resistance, heat resistance, flame retardancy, sound absorption and water resistance.

Therefore, foamed plastic materials that meet the characteristics can be selected and used according to various purposes and uses.

10 is a perspective view showing various combinations of the compressed cement plate assembly and the foamed plastic panel of the stationary formwork panel system using the compressed cement plate and the steel studs according to the present invention. As shown in FIG. 10, the assembly of the compressed cement plate assemblies 35, 42, and 43 and the foamed plastic panels 55 and 57 is such that the locking jaw of the foamed plastic panel is inserted into the support groove of the cement plate assembly. Is done. In addition, it is also possible to simply attach and combine both of the cement plate assembly and the assembled surfaces of the foamed plastic panel without forming the locking step and the support groove.

11 is a view showing a bottom fixing coupling member and a metal coupling plate for coupling a pillar used in a stationary formwork panel system using a compressed cement plate and steel pillars according to the present invention. As shown in FIG. 11, the bottom fixing coupling members 70 and 75 are formed by bending a metal plate having excellent corrosion resistance and strength, such as zinc hot-dip galvanized steel sheet, and adding triangular reinforcing plates 73 to both sides by welding or the like. The coupling member 76 for connecting the pillar is formed by bending a metal plate. The bottom fixing member and the metal plate coupling member 76 for connecting the pillar pillars are formed with a hole (71) through which bolt holes 74 and reinforcing bars for fixing are formed, and the hole has a shape narrowing downward. Therefore, when the reinforcing bar is placed through the hole, the reinforcing bar is inserted into the portion where the width of the hole is narrowed by the weight of the reinforcing bar, and the reinforcing bar is firmly fitted to the hole by the wedge effect.

12 is a perspective view showing that the reinforcing bar is coupled to the metal plate 샛 pillar of the fixed formwork panel system using the compressed cement plate and the steel 샛 pillar according to the present invention. As shown in Figure 12, the reinforcement (I) type metal plate chamfer 80 is inserted into the reinforcing steel hole is narrowed down from the top to the bottom of the metal plate excellent in corrosion resistance and strength, such as galvanized steel sheet (71) ) Is formed by perforation and both ends are bent 90 degrees along the longitudinal axis through the cut portions of both edges to form the locking step 82. Although not shown in the drawings, the locking jaw may be formed with a bolt hole to assemble the bolt through the compressed cement plate. The eye (I) type metal plate spigot 80 may also form a structure in which a plurality of metal plate coupling members 76 are connected to each other. In addition, an eye (I) type metal plate asymmetrical plume 88 may be formed in a shape in which the width increases downward. Such an eye (I) type metal plate asymmetrical stud 88 can be effectively used in the case of forming a retaining wall or a foundation wall having an inclined wall surface.

Figure 13 is a perspective view showing a state in which the reinforcing bar is coupled to the 'c'-shaped metal plate 샛 pillar of the fixed formwork panel system using the compressed cement plate and the steel 샛 pillar according to the present invention. As shown in FIG. 13, the pillar 90 of the 'c' type metal plate forms a hole 71 which becomes narrower from the top to the bottom on a metal plate having good corrosion resistance and strength such as a galvanized steel sheet. Both ends are bent twice by 90 degrees with respect to the longitudinal axis to form a locking jaw 92. The reinforcing bar is fitted to the hole (71) in which the width of the 샛 pillar 90 of the 'c' type metal plate is narrowed by its own weight.

Then, two metal plate 샛 pillars face each other and fastened with a screw or aluminum rivet through the metal plate coupling member 76 for 샛 pillar connection to form a double '' 'type metal plate 샛 pillar 95. It is also possible to join by welding without using screws or the like.

In addition, when both sides of the metal plate of different widths of the upper and lower portions are bent by 90 degrees, an asymmetric 'c' type metal plate 샛 pillar 97 is formed.

14 is a perspective view showing the 'C' type metal plate 샛 pillar of the fixed formwork panel system using the compressed cement plate and the steel 샛 pillar according to the present invention. As shown in FIG. 14, the 'C' type metal plate 둥 pillar 100 forms a hole 71 which becomes narrower downwards on a metal plate having excellent corrosion resistance and strength, such as a galvanized steel sheet, and both ends thereof. Bending jaw 102 is formed by bending twice at 90 degrees along the longitudinal axis.

When the two 'C'-shaped metal plate pillars are joined to each other by a screw or aluminum rebate or spot welding, a double' C'-type metal plate pillar is formed. In addition, if the width of the upper and lower portions of the metal plate is different, the asymmetric seed (C) type metal plate 샛 pillar 107 is formed.

15 is a view showing another embodiment of the pores narrowing toward the lower side formed in the pillar of the fixed formwork panel system using the compressed cement plate and steel pillars according to the present invention. As shown in FIG. 15, the holes 71 formed in the pillars 110 may be formed in other shapes, for example, the inverted triangle holes may be formed in the pillars 111 and 112. have. That is, the shape of the pores is not limited and it is sufficient to be shaped so that the width of the hole decreases downward.

Figure 16 is a perspective view showing a foamed plastic bollard used in a stationary formwork panel system using a compressed cement plate and a steel bollard in accordance with the present invention. As shown in FIG. 16, the foamed plastic block is cut by the multiple hot wire forming apparatus shown in FIG. 9 to form an eye hole 121 and an inverted triangle locking jaw 122 to form an I-shaped foam plastic stud ( 120 or the asymmetric eye (I) -type foamed plastic studs 125 having different widths in the vertical direction are formed.

17 is a perspective view showing a first embodiment of a fixed formwork panel system using a compressed cement plate and a steel pillar according to the present invention. As shown in FIG. 17, the fixed formwork panel system using the compressed cement plate and the steel studs according to the first embodiment of the present invention is a support groove of the foamed plastic panel 55 to which the compressed cement plate assembly 35 is coupled. The locking jaws 82 and 122 of the metal plate pillar 80 and the foamed plastic pillar 120 are slide-bonded to the 51, and the compressed cement plate assembly is coupled to the other latching pillars of the pillars 80 and 120. It is formed by sliding the support groove of the foamed plastic panel combined with. Fasten the screw 107 to be coupled to the metal plate 금속 pillar 105 through the compressed cement plate assembly 35 for a firm fixing. In addition, the rebar is coupled in the horizontal direction through the hole 71 formed in the pillar.

18 is a perspective view showing a part of a second embodiment of a stationary formwork panel system using a compressed cement plate and steel studs according to the present invention. As shown in Fig. 18, a second embodiment of the formwork panel system according to the present invention relates to a foundation wall formwork panel used for constructing a concrete foundation structure or foundation wall or a retaining wall foundation for construction or civil engineering. As the compression cement plate assembly 35 is installed on one side, and the locking jaw provided on one side of the metal plate 샛 pillar assembly in which the two metal plate 샛 pillars 80 are coupled to the support groove of the compressed cement plate assembly is installed by sliding coupling and on the other side. Combining the opposing compression cement plate assembly, and to combine the bottom fixing coupling member 70 to the bottom of the metal plate 샛 pillar to fix the bottom of the metal plate 둥 pillar. In this embodiment, although the foamed plastic panel is not bonded to the inside of the compressed cement plate assembly, it is also possible to bond the foamed plastic panel to the inside of the compressed cement plate assembly. Reinforcing bars 131 are inserted into the horizontal reinforcement through the holes of the pillars, and the reinforcing bars 135, which are bent at 90 degrees, are vertically erected and welded to the metal plate pillars 80 to connect with the concrete to be cured.

19 is a perspective view showing a third embodiment of a fixed formwork panel system using a compressed cement plate and a steel pillar according to the present invention. As shown in Fig. 19, the third embodiment of the formwork panel system according to the present invention is composed of the foundation wall and the general wall integrally. The base wall formwork panel body disposed in the lower portion is coupled to the two metal plate studs 80 to which the bottom fixing coupling member 70 is fixed between the compressed cement plate coupling bodies 35. The general wall formwork panel body disposed above is one metal plate stud 80 coupled between the compressed cement plate binders 35. On the metal wall studs 80 installed on the base wall formwork panel and the general wall formwork panel, rebar 131, which is a horizontal reinforcement, penetrates and is installed in the horizontal direction. And welded to one surface of the metal plate studs 80 of the general wall formwork panel. Since the integrally formed reinforcing bar is bent to 90 and welded to the 샛 pillar, when concrete is injected and hardened, the combination of the base wall and the general wall corresponding to the inner wall or the outer wall is made more firm. In addition, the compressed cement plate coupling members 39 are fixed to a portion where the compressed cement plate coupling bodies 35 are vertically connected.

20 is a cross-sectional view showing a fourth embodiment of a stationary formwork panel system using a compressed cement plate and a steel column according to the present invention. As shown in FIG. 20, the fourth embodiment of the stationary formwork panel system using the compressed cement plate and the steel stud according to the present invention is provided in each of the compressed cement plate assemblies 35 without using a foamed plastic panel. The metal plate 둥 pillar 95 and the foamed plastic 샛 pillar 120 are directly coupled to the support grooves between the cement plate reinforcing coupling members 30, and the compressed cement plate assembly 35 and the metal plate 으로 are screwed with screws 107. The pillar 95 is fastened. In this case, the insulation effect is somewhat reduced, but the manufacturing process of the formwork panel system is simplified.

21 is a cross-sectional view showing a fifth embodiment of a stationary formwork panel system using a compressed cement plate and a steel jaw column according to the present invention. As shown in FIG. 21, the fifth embodiment of the stationary formwork panel system using the compressed cement plate and the steel stud according to the present invention is similar in configuration to the fourth embodiment of the formwork panel system shown in FIG. There is a difference in using the 'C' type metal plate stud 100 and the compressed cement plate assembly 36. The 'C' type metal plate studs 100 are fastened by a compressed cement plate assembly 36 and a screw 107.

22 is a cross-sectional view showing a sixth embodiment of a stationary formwork panel system using a compressed cement plate and a steel jaw column according to the present invention. As shown in FIG. 22, the sixth embodiment of the stationary formwork panel system using the compressed cement plate and the steel stud according to the present invention is similar in configuration to the fourth embodiment of the formwork panel system shown in FIG. However, there is a difference in that the foamed plastic panel 55 is coupled to the inside of the compressed cement plate assembly 35 disposed on one surface. At this time, the thermal insulation effect is increased by the foamed plastic panel 55 bonded to the compressed cement plate assembly 35 on one surface.

FIG. 23 is a cross-sectional view showing a seventh embodiment of a stationary formwork panel system using a compressed cement plate and a steel pillar according to the present invention. As shown in FIG. 23, the seventh embodiment of the fixed formwork panel system using the compressed cement plate and the steel stud according to the present invention is similar in configuration to the fifth embodiment of the formwork panel system shown in FIG. However, there is a difference in that the compressed cement plate assembly (35, 36) uses a different shape and the foamed plastic panel (55) is coupled to the inside of the compressed cement plate assembly (35) disposed on one side. At this time, the foamed plastic panel bonded to the compressed cement plate assembly on one side improves the thermal insulation effect.

24 is a formwork panel for the wall is inserted into a conventional metal plate pill pillar, a formwork panel for the wall is inserted asymmetrical metal plate pill pillar in a fixed formwork panel system using a compressed cement plate and steel pillars according to the present invention It is a longitudinal cross-sectional view which shows the integral composite formwork panel of a wall. As shown in FIG. 24, the form panel bodies 140, 141, 142, and 145 may be manufactured in various shapes. In particular, the wall formwork panels 140, 141, and 145 include foamed plastic panels 55 inside the compressed cement plate binders 35, but sufficient foundation wall formwork panels are not required to keep warm. 142 does not include foamed plastic panels.

Hereinafter, the configuration of the formwork deck panel system using a compressed cement plate according to the present invention will be described in detail.

Figure 26 is a view showing the coupling of the metal plate 샛 pillar constituting the girder of the interlayer floor of the formwork deck panel system using a compressed cement plate according to the present invention. As shown in Figure 26, the formwork deck panel system using a compressed cement plate according to the present invention is a coupling member for connecting the 샛 column to the two 'L' type metal plate 샛 pillar 150 to serve as a girder of the floor between floors ( Through the 76 to form a support beam 155. The support piece 152 formed by bending at the 'L'-shaped metal plate pillar supports the compressed cement plate to be described later. In addition, the support beam 160 is formed by the 'c' type metal plate pill instead of the 'L' type metal plate pill.

27 is a perspective view showing a foamed plastic bottom plate panel used in the formwork deck panel system using a compressed cement plate according to the present invention. As shown in FIG. 27, the foamed plastic bottom plate panel 170 is configured to form an interlayer bottom. A groove 172 having a rectangular cross section is formed on a lower surface thereof, and an inverted triangular support groove 174 is formed on an upper surface thereof. . In addition, when the interlayer floor is formed of a double layer, an upper bottom panel 180 made of a foamed plastic material having an inverted triangular support groove 182 formed on the upper and lower surfaces thereof is disposed above the foamed plastic bottom plate panel 170.

28 is a perspective view showing a single-layer formwork deck panel system using a compressed cement plate according to the present invention. As shown in Figure 27 and 28, the support beams 155 formed of the 'L'-shaped metal plate 샛 pillars are arranged at a predetermined interval, and for reinforcing the cement plate on the support pieces of the' L'-shaped support beams The compressed cement plate assembly 37 having the metal coupling member 33 attached to the upper surface thereof is placed, and the cement plate reinforcing metal coupling member 33 is inserted into the square groove 172 on the compressed cement plate assembly 37. Foamed plastic bottom plate panel 170 is installed so as to. A metal plate stud 80 is slidably coupled to the support groove 174 of the upper surface of the foamed plastic bottom plate panel 170. The support beam may be a support beam 120 made of a 'c' shaped metal plate stud instead of an 'L' shaped metal plate stud, and a foamed plastic stud (instead of the metal plate stud 80). It is also possible to use 120). When the concrete is filled and cured over the bottom panel with metal plates or foamed plastic studs, an interlayer floor is formed.

29 is a perspective view showing a multi-layer formwork deck panel system using a compressed cement plate according to the present invention. As shown in Figs. 27 to 29, the multi-layer formwork deck panel system using the compressed cement board is the upper bottom plate panel 180 shown in Fig. 27 on the top of the stud of the single-layer formwork deck panel system shown in Fig. 28. This is further installed and the metal plate 샛 pillar is installed on the upper surface of the upper bottom panel 180 more. Multi-layer formwork deck panel systems using compressed cement plates are filled with concrete over the top floor plate with metal plate pillars to form a multi-layer interlayer floor.

Waterworks, sewage, or drainage pipes 185 may be disposed between the bottom pillars 80 provided between the bottom panel and the upper bottom panel. Therefore, the multi-layer formwork deck panel system using the compressed cement plate has the advantage of simultaneously achieving the effect of water piping and insulation.

30 is a cross-sectional view showing a part of a building to which a formwork panel system and a formwork deck panel system according to the present invention are applied. As shown in FIG. 30, the foundation wall 190, the inner and outer walls 192, the interlayer floor 194, and the roof ( 196 is configured.

According to the fixed formwork panel system using the compressed cement plate and the steel 샛 pillar according to a preferred embodiment of the present invention having the above-described configuration in the retaining wall type reinforcement, concrete framework configuration method in constructing the walls of concrete structures for buildings or civil engineering Save time, manpower and costs such as reducing the materials of excessively used reinforcing bars, wood plywood, and sheet metal formwork, reducing the process of bending or tying steel bars and the complicated process of forming formwork, and assembling and dismantling the formwork. In addition, there is an effect of reducing the process of dismantling the formwork and then evening the surface of the support or the protrusion protruding from the concrete surface.

In a preferred embodiment of the present invention, since the compressed cement plate is used to form the concrete to be injected and cured, and the compressed cement plate is not removed even after the injected concrete is hardened, the compressed cement plate is reinforced to intensify the strength. There is an effect that can reduce the amount of cleats.

In addition, the conventional formwork after curing the concrete for about 3 to 7 days after pouring the concrete, the formwork is removed, after removing the formwork, moisture is rapidly evaporated to decrease the effect of improving the strength, according to the present invention The formwork system is a fixed type that does not remove the formwork even after pouring it. The formwork is permanently preserved, so that the moisture contained in the concrete gradually evaporates until approximately 28 days, and the strength of the concrete is about 30% compared to that of the conventional formwork. There is an effect that rises above.

In addition, without using a foam molding machine or a mold, a computer panel or an automatic controllable hot wire molding machine can be used to produce a variety of formwork panels without being limited in shape and size, but can also be manufactured in large quantities, thereby improving productivity with molding beauty.

In constructing floors, girders, etc. between buildings, it is not necessary to use formwork supporting plates and support pillars, which saves time and money, and prevents drooping when rebars are used. There is an advantage to get.

In addition, the present invention can be configured in advance in the fabrication of the base wall and the wall of the structure as a body in the construction site is reduced in time, manpower and cost compared to the method of processing and binding the reinforcing bars and formwork at the construction site.

Since the foam plastic insulation is preformed on both sides, it eliminates the process of applying mortar to the cement and attaching the insulation separately, which saves manpower and cost.Insulation material on both sides improves insulation and insulation and reduces heat permeation rate, saving energy. The effect is excellent.

Compression cement board reinforced with fiberglass reinforced with strength and adhesiveness and good waterproof non-flammable is attached to both sides of the panel, so that various plaster finishes such as tiles, wood, marble, and wallpaper can be easily applied.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications or variations without departing from the spirit and scope of the invention. Accordingly, the appended claims will cover such modifications and variations as fall within the spirit of the invention.

1 is a perspective view showing a mold of a concrete frame structured by a formwork system using conventional plywood formwork and rebar;

Figure 2 is a perspective view showing the configuration of the expanded polystyrene hollow block produced using a conventional foam molding machine,

3 is a perspective view showing a compressed cement plate used in a stationary formwork panel system using a compressed cement plate and a steel stud according to the present invention,

4 is a perspective view illustrating a cement plate reinforcing metal member formed by bending a cement plate and a metal plate reinforcing coupling member formed by cutting the compressed cement plate of FIG. 3;

FIG. 5 is a perspective view illustrating a compressed cement board assembly in which the compressed cement board of FIG. 3 and the cement plate reinforcing bonding member of FIG. 4 are bonded;

Figure 6 is a perspective view showing a cement plate coupling member for connecting the compressed cement plate of the formwork panel system according to the present invention,

7 is a perspective view showing that the compressed cement plate assembly of the formwork panel system according to the present invention is connected to the 'b' shape and 't' shape using a cement plate coupling member,

Figure 8 is a perspective view showing a foamed plastic panel of various shapes of the stationary formwork panel system using a compressed cement plate and a steel column according to the present invention,

9 is a perspective view showing a multiple electric heating molder for processing the foamed plastic panel of the formwork panel system according to the present invention,

10 is a perspective view showing various combinations of a compressed cement plate assembly and a foamed plastic panel of a stationary formwork panel system using a compressed cement plate and steel studs according to the present invention;

11 is a view showing a bottom fixing coupling member and a metal plate coupling member for coupling a pillar used in a stationary formwork panel system using a compressed cement plate and a steel pillar according to the present invention;

12 is a perspective view showing the metal plate pillars of a fixed formwork panel system using a compressed cement plate and steel pillars according to the present invention;

Figure 13 is a perspective view showing a 'c' type metal plate pillar of the fixed formwork panel system using a compressed cement plate and steel pillars according to the present invention,

14 is a perspective view showing a 'C' type metal plate 샛 pillar of a fixed formwork panel system using a compressed cement plate and steel 샛 pillars according to the present invention;

15 is a view showing another embodiment of a hole that becomes narrower downwardly formed in the metal plate 샛 pillar of the fixed formwork panel system using the compressed cement plate and the steel 샛 pillar according to the present invention,

Figure 16 is a perspective view showing a foamed plastic steam column used in a stationary formwork panel system using a compressed cement plate and a steel steam column according to the present invention,

17 is a perspective view showing a first embodiment of a stationary formwork panel system using a compressed cement plate and a steel column according to the present invention;

18 is a perspective view showing a part of a second embodiment of a stationary formwork panel system using a compressed cement plate and a steel column according to the present invention;

19 is a perspective view showing a third embodiment of a stationary formwork panel system using a compressed cement plate and a steel pillar according to the present invention;

20 is a cross-sectional view showing a fourth embodiment of a stationary formwork panel system using a compressed cement plate and steel columns according to the present invention;

21 is a cross-sectional view showing a fifth embodiment of a stationary formwork panel system using a compressed cement plate and a steel column according to the present invention;

22 is a cross-sectional view showing a sixth embodiment of a stationary formwork panel system using a compressed cement plate and steel columns according to the present invention;

23 is a cross-sectional view showing a seventh embodiment of a stationary formwork panel system using a compressed cement plate and steel columns according to the present invention;

24 is a formwork panel for the wall is inserted into a conventional metal plate pill pillar, a formwork panel for the wall is inserted asymmetrical metal plate pill pillar in a fixed formwork panel system using a compressed cement plate and steel pillars according to the present invention Longitudinal sectional view showing an integral composite formwork panel of a wall and a wall,

25 is a view showing a retaining wall type reinforced concrete framework for constituting a conventional interlayer floor,

FIG. 26 is a view showing a supporting beam constructed by combining metal plate studs to form a girder of an interlayer floor of a formwork deck panel system using a compressed cement board according to the present invention; FIG.

27 is a perspective view showing a foamed plastic bottom plate panel used in the formwork deck panel system using a compressed cement plate according to the present invention,

28 is a perspective view showing a single-layer formwork deck panel system using a compressed cement board according to the present invention;

29 is a perspective view showing a multi-layer formwork deck panel system using a compressed cement plate according to the present invention,

30 is a cross-sectional view showing a part of a building to which a formwork panel system and a formwork deck panel system according to the present invention are applied.

Explanation of the Main References

20: compressed cement plate 23: glass fiber net

35: compressed cement plate assembly 50: foamed plastic panel

76: metal plate coupling member for the pillar pillar connection

80: metal plate stud 120: foamed plastic stud

Claims (7)

Compressed cement plates are disposed to face each other at predetermined intervals, and support grooves are formed on opposite surfaces thereof; And A locking jaw inserted into the support grooves for joining the compressed cement plates includes a metal plate 둥 pillar having a hole formed on both sides thereof and having a hole narrowing toward the bottom thereof; A fixing piece penetrates the locking jaw of the metal plate 하여 pillar inserted into the support groove in the cement plate so that the compressed cement plate and the metal plate 샛 pillar are fixed to each other. The fixed formwork panel system using a compressed cement plate and steel pillars, characterized in that the reinforcing bar is fitted to the hole by the weight of the. Foamed plastic panels disposed to face each other at predetermined intervals, and facing surfaces having support grooves that increase in width toward an inner side thereof; At least one jaw pillar formed on both sides of the engaging jaw slidingly coupled to the support groove to couple the foamed plastic panels; And A stationary formwork panel system using a compressed cement plate and steel studs comprising a compressed cement plate reinforced with a reinforcement bonded to at least one of the outer sides of the foamed plastic panels disposed thereon. The method of claim 2, The at least one hollow pillar is formed by penetrating in the transverse direction at least one of the pores, the width becomes narrower downward Reinforcement is inserted into the hole of the iron pillar, the fixed formwork panel system using a compacted cement plate and steel pillars, characterized in that the reinforcement is fitted to the hole by the wedge effect of its own weight. The method of claim 2 or 3, Further comprising a panel engaging member is formed in the engaging projections which are slide coupled to the support groove of the respective foamed plastic panels on the same plane, A fixed formwork panel system using a compressed cement plate and steel studs, characterized in that the adjacent foamed plastic panels are connected to each other by the engaging jaws of the panel tie member slidingly coupled to the support grooves of the adjacent foamed plastic panels. The method according to claim 1 or 2, The reinforcement for reinforcing the compressed cement plate is a fixed formwork panel system using a compressed cement plate and a steel pillars, characterized in that made of glass fiber, wire mesh or reinforced plastic. Foam plastic panels for inner and outer walls which are disposed to face each other at predetermined intervals to form inner and outer walls, and facing surfaces having support grooves that increase in width toward the inner side; Foam plastic panels for the base wall, which are arranged to face at intervals greater than the predetermined interval to form the foundation wall below the inner and outer wall foam plastic panels, and the supporting surfaces having widths of the supporting grooves increasing inwardly on the facing surfaces thereof. ; At least one inner and outer wall pillars having locking jaws that are coupled to support grooves of the foamed plastic panels for inner and outer walls on both sides; Under the inner and outer wall 적어도 pillars at least two 샛 pillar pieces formed on both sides of each other in the lateral direction is formed in the locking jaw is located on both sides of the combined 샛 pillar pieces of the foam plastic panel for the base wall At least one composite stud that is slide-coupled to the support grooves of the arm; A 'b' shaped reinforcing bar welded from one surface of the inner and outer wall columns to the surface of the composite column; And A fixed formwork panel system using a compressed cement plate and steel pillars including compressed cement plates installed on at least one of the inner and outer wall foamed plastic panels and the base wall foamed plastic panels. In the formwork panel system for constructing concrete floors, floors, roofs, etc., Support beams disposed on the horizontal plane at predetermined intervals, each having a support piece extending in the horizontal direction; A compressed cement plate on which both edges of the support pieces of the adjacent support beams are supported; A straight reinforcement member disposed on the compressed cement plate so as to be orthogonal to the support beams; A foamed plastic panel installed on an upper portion of the straight reinforcement member and having a hollow pillar insertion groove formed on an upper surface thereof, the width of which increases inwardly; And Fixed formwork deck panel system using a compressed cement plate and a steel pillars including a jaw pillar is formed with a locking jaw coupled to the groove insert grooves of the foamed plastic panel.