KR100778269B1 - Truss girder integrated slab form structure - Google Patents

Abstract

A slab form structure integrated with truss girder is provided to ensure a sufficient wide lower working place by curing concrete without additional supporters. A support member(400) is installed in a point in which a lower iron bar(230) and a lattice member (220) positioned at two opposite sides of a lower portion of a truss girder. The first support part(421) having an insertion member is formed at the first side of the body(410) of the support member(400). The second support part faces to the first support part(421). The two sides of the lower end portion of the truss girder(200) is inserted into the second support part and another support part, and inserted into the insertion member(421a) of the first support part(421) so that both sides of the lower portion of the truss girder is supported by the upper portion of a support structure.

Description

Truss girder integrated slab form structure

The present invention relates to a truss girder integrated slab formwork, in particular, the slab formwork panel is coupled to be suspended by being spaced apart from the bottom of the truss girder, and to both sides of the truss girder to stably seat the truss girder to the support The truss girder is configured to be securely supported by the support by interposing the support.

In general, the majority of building structures are constructed using reinforced concrete. The building structure using reinforced concrete is a composite structure in which a combination of concrete as a compression material and a reinforcing material is used together with a tensile material, and after repositioning formwork, reinforcing reinforcing bars and pouring concrete, it is obtained by repeating the process of dismantling formwork after curing is completed. Can be.

At this time, the formwork is installed with plywood, lumber, etc., and there is a problem in that a lot of air is consumed due to the dismantling work for dismantling the formwork after the curing step of concrete and reinforcement work such as reinforcement.

In order to solve this problem, it is installed between beams, which are structures for constructing buildings, and has a deck plate shape that can support the weight of concrete itself generated in the process of curing concrete and concrete being poured thereon. Formwork or formwork panels have been proposed.

As shown in FIG. 1, the proposed die panel is a through hole 810 formed in the slab formwork panel 800, and a bolt 820 is exposed upward to form a coupling groove 832 between both sides of the pinhole 831. The coupling hole 830 is formed in the lower portion opposed to the coupling groove 832 is formed, the truss girder 840 is formed in the coupling groove 832 formed in the coupling hole 830 The truss girder 840 is configured to be coupled to the slab formwork panel 800 by a fixing pin 834 fitted with the lower reinforcement 841 to be seated in the pinhole 831.

That is, in the configuration in which the conventional slab formwork panel 800 is suspended from the truss girder 840 by the coupling hole 830, when both sides of the truss girder 840 is installed on the upper portion of the support, the coupling Due to the configuration of the sphere 830, except for both ends, the space between the lower reinforcement 832 of the truss girder 840 and the upper surface of the slab formwork panel 800 is formed, the truss girder At both ends of the 840, the slab formwork panel 800 is bent upwardly due to the self-loading of the truss girder 840, so that the slab formwork panel 800 comes into contact with the truss girder 840. It is done.

When concrete is poured into the slab formwork panel 800 in this structure, both ends of the slab formwork panel 800 may be severely drooped or pushed down. In addition, all the load of the concrete is transmitted to the support (not shown) for supporting the truss girder 840 through both ends of the truss girder 840 coupled to the lower reinforcement 832, the lattice material and the upper reinforcement, Due to the deflection phenomenon at both ends of the slab formwork panel 800, the load of the concrete cannot be transferred directly to the support, resulting in the slab being collapsed, or the truss girder 840 and the slab formwork panel 800 are deformed. It was structurally unsafe. Therefore, the configuration in which the truss girder 840 and the slab formwork panel 800 are separated is not actually commercialized due to the structural instability as described above.

In order to prevent such a collapse accident, a plurality of clubs were installed at the lower part of the slab formwork panel 800 to distribute the load. In this case, the bottom space is reduced by the clubs so that subsequent work cannot be easily performed. There was another problem.

According to the present invention, the truss girder and the formwork panel are coupled to each other by the support of the lower end of the truss girder, and the lower side of the truss girder is installed on the upper part of the support. In order to prevent deformation, and in addition, in the process of curing the concrete, sufficient curing can be achieved without using a separate club, so that the work space underneath can be secured widely.

The present invention is coupled so that the slab formwork panel 100 is suspended to be spaced apart by a plurality of coupling holes 300 in the lower portion of the truss girder 200, the slab formwork panel 100 is a plurality of through holes 110 The truss girder 200 is punched to correspond to the lower reinforcement 230 of the truss girder 200, and the truss girder 200 is welded to the lattice material 220 bent in a wave shape around the upper reinforcement 210. Is coupled, the bottom of the lattice material 220, the lower reinforcement 230 is welded coupled to the triangular form, the coupling sphere 300 is composed of a pedestal 310 and the fixing bolt 320, The pedestal 310 has a seating portion 311 is formed in the upper portion of the pedestal 310 so that the lower reinforcement 230 is seated, the fixing bolt 320 is located at the center of the pedestal 310 The female thread groove 312 is formed to be screwed upward to be screwed The fixing bolt 320 is screwed into the female thread groove 312 of the pedestal 310 through a through hole 110 drilled in the slab formwork panel 100, the slab formwork panel 100 is the truss girder ( In the truss girder integrated slab formwork configured to be detachably coupled from
The support 400 is forcibly fitted at the point where the lower reinforcement 230 and the rats material 220 are coupled to both lower ends of the truss girder 200, and the support 400 is the support 400. A first support portion 421 having a fitting hole 421a is formed on one side of the upper portion of the body 410, and the second support portion 422 and 422 in a vertical direction on both sides of the upper portion opposite to the first support portion 421. ') Are respectively formed, and the lower ends of both sides of the truss girder 200 are interposed between the second support part 422 of the supporter 400 and another second support part 422'. The lower end of both sides of the truss girder 200 is inserted into the fitting hole 421a of 421 to be supported on the upper portion of the support.

In addition, blades 422a and 422a 'are respectively formed in the second support portions 422 and 422' of the supporter 400, and the lower portions of the blades 422a and 422a 'are respectively formed. The inclined portions 422b and 422b 'are formed on the support legs, and the support legs 430 are formed at each corner of the lower portion of the body 410 of the supporter 400.

In addition, protrusions 350 and 350 ′ are formed in the vertical direction on both sides of the seating portion 311 of the pedestal 310, respectively, and pin grooves 313 and 313 ′ in the protrusions 350 and 350 ′. Are respectively formed so as to penetrate in the direction crossing the seating portion 311, and each support leg 314 is formed at the lower edge of the pedestal 310, the female thread groove 312 and each support leg The space portion 315 is integrally formed between the 314 and the fixing pin 330 is inserted into the pin grooves 313 and 313 ′ so that the lower reinforcement 230 seated on the seating portion 311 is coupled. It is characterized by.

In addition, the truss girder 200 has an upper bent portion 221 of the lattice material 220 such that the lattice material 220 bent in a wave shape on both sides of the upper reinforcement 210 is opened downward. The truss girder integrated slab formwork is coupled to the spot welding part 250, and the lower reinforcement 230 is coupled to the two-point welding part 260 on the outer side of the lower bent portion 222 of the lattice material 220. In providing a structure.

The present invention has the effect of allowing the slab formwork panel to be easily detachable from the truss girder, and at the same time configured to support the support on both ends of the truss girder to ensure that the truss girder is supported securely to the support The effect can be obtained.

In addition, as shown in the present invention, the structure in which the support is forcibly inserted at both ends of the truss girder is structurally safe because the support is stably supporting the truss at the upper portion of the support, and the deflection of the slab formwork panel due to the concrete load is remarkable. In addition, it is possible to prevent the truss girder and slab formwork panels from being deformed due to the concentrated load in the process of placing concrete.

In addition, in the process of curing the poured concrete, sufficient curing can be achieved without using a separate club, and thus, the work space under the wider space can be secured more.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

Figure 2 is a perspective view showing the truss girder integrated slab formwork according to the present invention, Figure 3 is a partially exploded perspective view of the truss girder integrated slab formwork according to the present invention, Figure 4 is applied to the truss girder integrated slab formwork according to the present invention 5 is a perspective view showing a preferred embodiment of the support applied to the truss girder integrated slab formwork according to the present invention, Figure 6 is an exploded perspective view of a coupler applied to the truss girder integrated slab formwork according to the present invention, Figure 7 is a bottom exploded perspective view of a coupler applied to the truss girder integrated slab formwork according to the present invention, Figure 8 is a front view of the truss girder applied to the truss girder integrated slab formwork according to the invention, Figure 9 is a truss girder according to the present invention Concrete is poured using integrated slab formwork Is a longitudinal sectional view showing, Figure 10 is a longitudinal cross-sectional view illustrating a state that the Li after the truss girder with concrete in one-piece slab mold cured slab formwork panels of the present invention also minutes.

Truss girder integrated slab formwork structure according to the present invention is composed of the slab formwork panel 100, the truss girder 200, the coupler 300 and the support member 400, as shown in Figs. . That is, the slab formwork panel 100 is coupled to the lower portion of the truss girder 200 in a separated state by a plurality of coupling holes 300, both sides of the truss girder 200 is supported by the support ( It is configured to be supported by (400).

Here, the slab formwork panel 100 has a predetermined width and length and is configured such that a plurality of through holes 110 are formed in a zigzag form so as to correspond to the lower reinforcement 230 of the truss girder 200. .

The truss girder 200 is a lattice material 220 bent in a wave shape on both sides of the upper reinforcement 210 is coupled to the weld joint, and the lower reinforcement 230 is formed on the bottom outside of the lattice material 220. It is configured to have a triangular shape by being joined by welding joints.

The upper lattice material 220 of the lattice material 220 bent in a wave shape coupled to a welded joint at both sides with respect to the upper reinforcement 210 of the truss girder 200 has a shape that opens toward the bottom ( As shown in FIG. 8, 221 is coupled by a one-point welding part 250 consisting of one point, and the lower reinforcing bars 230 are respectively formed on the outer side of the lower bent part 222 of the lattice material 220. It is configured to be coupled by a two-point welding part 260 made of a dot.

The coupler 300 is a slab formwork panel 100 is to be detachably coupled to the bottom of the truss girder 200, as shown in Figure 6 and 7, the pedestal 310 and the fixing bolt 320 )

The pedestal 310 has a seating portion 311 is formed on the upper portion of the pedestal 310 so that the lower reinforcement 230 is seated, and the fixing bolt 320 is screwed to the center lower portion of the pedestal 310 The female screw groove 312 is configured to be formed to the upper portion to be.

Therefore, the fixing bolt 320 is screwed into the female thread groove 312 of the pedestal 310 through the through hole 110 drilled in the slab formwork panel 100, the slab formwork panel 100 is the truss girder It is configured to be detachably coupled from the (200).

In addition, protruding pieces 350 and 350 'are formed at both sides of the seating portion 311 of the pedestal 310 in the vertical direction, and pin grooves 313 and 313' are formed in the protruding pieces 350 and 350 '. It is comprised so that each may be penetrated in the direction which cross | intersects this said mounting part 311. As shown in FIG.

In addition, a support leg 314 is formed at each of the lower edges of the pedestal 310, and a space portion 315 is integrally formed between the female thread groove 312 and each support leg 314 so that the pedestal ( It is configured to enter between the concrete being poured while reducing the amount of material 310).

In addition, the fixing pin 330 is inserted into the pin grooves 313 and 313 'so that the lower reinforcement 230 seated on the seating portion 3111 is coupled to be separated.

The support 400 has a function of preventing deformation due to concentration of load, as shown in FIGS. 4 and 5, and the fitting hole 421a on the upper side of the body 410 of the support 400. The first support part 421 is formed, and the second support part 422 is formed in the vertical direction on opposite sides of the upper side opposite to the first support part 421, respectively, so that both lower ends of the truss girder 200 are formed. It is configured to be supported between the second support part 422 of the supporter 400 and another second support part 422 'while being seated in the fitting hole 421a.

In addition, as shown in FIG. 5, the second supporting portions 422 and 422 'of the support 400 have blade portions 422a and 422a' facing the center portion, and the blade portions 422a. The inclined portions 422b and 422b 'are formed under the 422a', respectively.

And the support leg 430 is formed at each corner of the lower body 410 of the support 400 to be integrally formed toward the bottom.

Truss girder integrated slab formwork having such a configuration, first formed through-hole 110 in the slab formwork panel 100 to correspond to the position where the truss girder 200 is to be placed, and then fixed upward to the lower portion of the through-hole 110. The bolt 320 is inserted to be exposed, and couples the female screw groove 312 formed at the bottom of the coupling hole 300 to the fixing bolt 320 exposed to the upper portion of the through hole 110. At this time, the through hole 110 is preferably to be formed in a zigzag form.

Next, the lower reinforcing bar 230 positioned below the truss girder 200 is seated on each seating portion 311 formed as an upper portion of the coupling hole 300, and then the protrusion piece 350 of the coupling hole 300 is placed thereon. Fixing pins 330 are inserted into the respective pin grooves 313 and 313 ′ formed by the first and second ends of the slab formwork panel 100, that is, the support legs 314 of the coupling hole 300. The lower reinforcement 230 of the truss girder 200 is coupled to have a distance from the height of the seating portion 311 to the height of the seating portion 311.

Next, the support 400 is forcibly fitted at the point where the lower reinforcement 230 and the rats material 220 are coupled to both lower ends of the truss girder 200, and the support 400 is the support ( A first support part 421 having a fitting hole 421a is formed at one upper side of the body 410 of the body 400, and the second support part 422 is perpendicular to both sides of the other upper part facing the first support part 421. 422 'are formed, and the lower ends of both sides of the truss girder 200 are sandwiched between the second support 422 of the supporter 400 and another second support 422'. 1 is to be fitted to the fitting hole (421a) of the support portion (421).

Thus, one support 400 is inserted into the lower reinforcement 230 of the truss girder 200, and then the other support 400 is inserted into the other side of the lower reinforcement 230 in the same manner. In the present invention, the support member 400 is coupled to the lower reinforcement 230 in the state in which the lower reinforcement 230 is coupled to the slab formwork panel 100 by the coupler 300, but the lower reinforcement 230 is the slab formwork panel 100. It may be to be coupled to the support 400 before being fixed to).

     Through this process, the truss girder integrated slab formwork structure of the present invention presupposes the truss girder integrated slab formwork structure consisting of the conventional slab formwork panel 100, the truss girder 200, and the coupling hole 300, and the truss girder It is characterized in that the support member 400 is inserted into both ends of the truss girder 200 of the integral slab formwork structure so that the truss girder 200 is supported by the support. The support is generally horizontal bar of the wooden formwork 710 as shown in Figure 9, may be a flange of the cheolgolbo depending on the shape of the building structure. More specifically, in the present invention, as shown in FIG. 9, the support member 400 made of plastic material including the fitting hole 421a, the first support part 421, and the second support part 422, 422 ′ is formed in the truss. It is forcibly fitted to both sides of the girder 200, and both sides of the truss girder 200 to which the support 400 is coupled are installed on the upper portion of the support. At this time, both ends of the slab formwork panel 100 may be temporarily fixed to the horizontal square, which is the support, with a fixing pin. In the present invention, the coupler 300 serves to suspend the slab formwork panel 100 is coupled to the truss girder 200, the support 400 is the truss girder 200 is stable to the support It serves to be supported by.

Next, the slab formwork disassembly sequence of the present invention first removes the horizontal box, vertical box and plywood of the wooden formwork 710 to form a girder after the concrete 700 has been sufficiently cured and slab formwork panel 100 After unfastening the fixing bolt 320 exposed to the bottom of the slab formwork panel 100 by separating, the slab construction work is finished as shown in FIG.

1 is a longitudinal sectional view showing a slab formwork according to the prior art;

Figure 2 is a perspective view of the truss girder integrated slab formwork according to the present invention.

3 is a partially exploded perspective view of the truss girder integrated slab formwork according to the present invention.

Figure 4 is a perspective view of a support applied to the truss girder integrated slab formwork according to the present invention.

Figure 5 is a perspective view showing a preferred embodiment of the support applied to the truss girder integrated slab formwork according to the present invention.

Figure 6 is an exploded perspective view of the coupler applied to the truss girder integrated slab formwork according to the present invention.

Figure 7 is a bottom exploded perspective view of the coupler applied to the truss girder integrated slab formwork according to the present invention.

8 is a front view of the truss girder applied to the truss girder integrated slab formwork according to the present invention.

Figure 9 is a longitudinal sectional view showing a state in which concrete is poured using the truss girder integrated slab formwork according to the present invention.

Figure 10 is a longitudinal sectional view showing a state in which the slab formwork panel is separated after the concrete poured on the truss girder integrated slab formwork according to the present invention.

<Brief description of symbols for the main parts of the drawings>

100: slab formwork panel 110: Through hole

200: Truss girder 210: Upper reinforcement

220: Lattice material 230: lower reinforcing bar

300: fitting 310: stand

311: Seat 312: Female thread

320: fixing bolt 400: support

410: body

421: first support 421a: fitting hole

422: second support

Claims (4)

The slab formwork panel 100 is coupled to be suspended from the lower portion of the truss girder 200 by a plurality of coupling holes 300, the slab formwork panel 100 is a plurality of through-holes 110 is the truss The truss girder 200 is punched to correspond to the lower reinforcement 230 of the girder 200, the lattice material 220 bent in a wave shape on both sides of the upper reinforcement 210 is welded, The bottom reinforcement of the lattice material 220, the lower reinforcement 230 is welded and composed of a triangular shape, the coupler 300 is composed of a pedestal 310 and the fixing bolt 320, the pedestal ( 310 is a mounting portion 311 is formed in the upper portion of the pedestal 310 so that the lower reinforcement 230 is seated, the fixing bolt 320 is screwed to the lower center of the pedestal 310 The female thread groove 312 is formed toward the top so that the fixed ball The trough 320 is screwed into the female thread groove 312 of the pedestal 310 through the through-hole 110 drilled in the slab formwork panel 100, the slab formwork panel 100 is the truss girder 200 In the truss girder integrated slab formwork, which is configured to be detachably coupled from the The support 400 is forcibly fitted at the point where the lower reinforcement 230 and the rats material 220 are coupled to both lower ends of the truss girder 200, and the support 400 is the support 400. A first support portion 421 having a fitting hole 421a is formed on one side of the upper portion of the body 410, and second support portions 422 and 422 in a vertical direction on both sides of the upper portion opposite to the first support portion 421. ') Are respectively formed, the lower end of both sides of the truss girder 200 is sandwiched between the second support portion 422 and the second support portion 422' of the support 400 and the first support portion Truss girder integrated slab formwork structure, characterized in that the lower end of both sides of the truss girder 200 is inserted into the fitting hole (421a) of the support (421) is supported on the upper portion of the support. The method of claim 1, The second supporting portions 422 and 422 'of the supporter 400 are formed with blade portions 422a and 422a' facing toward the center portion, and inclined portions below the blade portions 422a and 422a '. (422b) (422b ') is formed, respectively, the truss girder integrated slab formwork structure, characterized in that the support leg 430 is formed at each corner of the lower portion of the body 410 of the support (400). The method of claim 1, Protruding pieces 350 and 350 'are formed in the vertical direction on both sides of the seating portion 311 of the pedestal 310, and pin grooves 313 and 313' are formed in the protruding pieces 350 and 350 '. It is formed to penetrate in the direction crossing the seating portion 311, respectively, the lower edge of the pedestal 310 is formed with a support leg 314, respectively, female thread groove 312 and each support leg 314 The space portion 315 is integrally formed therebetween, and the lower pin 230 mounted on the seating portion 311 is coupled to the fixing pin 330 by the pin grooves 313 and 313 '. Truss girder integrated slab formwork. The method according to claim 1, wherein The truss girder 200 has one point of the upper bent portion 221 of the lattice material 220 so that the lattice material 220 bent in a wave shape on both sides of the upper reinforcement 210 to be spread downward. The truss girder integrated slab formwork structure is coupled to the welding portion 250, the lower reinforcement 230 is coupled to the two-point welding portion 260 on the outer side of the lower bent portion 222 of the lattice material 220 .

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