KR100882163B1 - Truss girder intergrated deck panel form structure for reinforced concrete slab - Google Patents

Abstract

A truss girder integrated deck panel form structure for reinforced concrete slab is provided to produce a lightweight rigid deck plate which can be used repetitively. A truss girder integrated deck panel form structure for reinforced concrete slab comprises a deck panel(100) which is made from aluminum and has a plurality of through holes, a truss girder(200) including a bottom reinforcing bar(204), and a connector(300) in which a vertical joint hole(302b) is formed. The deck panel includes a bent seating part and a down protrusion to be mated with those of other deck plates on both sides.

Description

Truss girder integrated deck panel formwork for reinforced concrete slabs {TRUSS GIRDER INTERGRATED DECK PANEL FORM STRUCTURE FOR REINFORCED CONCRETE SLAB}

The present invention relates to a truss girder integrated deck panel formwork structure for reinforced concrete slabs, and more particularly, to provide a significant reduction in manufacturing and construction costs, easy construction workability, safety, excellent field applicability and construction quality. It relates to a truss girder integrated deck panel formwork for reinforced concrete slabs.

Generally, reinforced concrete structures, which are mainly used for the construction of various buildings, are complex structures that obtain excellent durability and seismic resistance by using a combination of concrete as a compression material and rebar as a tension material, and curing curing concrete by injecting fluid concrete into the formwork. It is then formed through the process of removing the formwork.

The conventional method of constructing a concrete slab made of a sheet using reinforced concrete to form a floor, etc., is a formwork made of plywood, lumber, etc. to form the outer surface of concrete, and a copper bar supporting the formwork. After the construction of the column, rebars were placed on the formwork, concrete was then placed inside the formwork, and when the concrete was cured through curing, the formwork and the club were removed.

However, this conventional method requires a considerable amount of air due to the large manpower / hours required due to the construction and dismantling of formwork and copper bars, and the manpower / hours required due to the reinforcement of the reinforcement work and the need for finishing work due to the poor surface of the structure. There was a problem that is increased.

In addition, the conventional method is difficult to apply to high-rise building structure, damaged formwork among the used formwork is not reusable, causing waste of resources, there was also a problem of poor economic efficiency due to the waste material generation.

Therefore, in recent years, the deck panel (deck panel) to form the formwork without the use of bundling and formwork, and a truss girder, which is a reinforcement / steel assembly for reinforcing the strength of the concrete slab, coupled to the deck panel It uses a lot of formwork.

This truss girder integrated deck panel formwork can be pre-assembled with truss girder and deck panels in advance in factories, enabling unified formwork, reinforcement and finishing processes, resulting in significant reductions in air and construction costs. In addition, material requirements such as steel wire can be reduced as much as possible.

In addition, since it is a non-supporting method, the construction is very simple, and also has excellent structural stability such as overcoming sag, and also has excellent construction quality.

Prior arts for such new formwork structures include "crank welding apparatus for truss girder deck panels for reinforced concrete slabs" in Korean Patent Registration No. 10-0590288, and "Reinforced concrete slabs for patent registration No. 10-0653696-0000". Deck Panel Manufacturing Method of Deck Panel and Deck Panel ", Utility Model Registration No. 20-0360312, Deck Panel for Reinforced Concrete Slab, Utility Model Registration No. 20-0343678," Assembly Structure of Prefabricated Deck Panel ", Patent Publication No. 10 -2004-0085481, "Fastening member of prefabricated deck panel", "Trussed deck panel with supporting wire and manufacturing method thereof" of patent registration No. 10-0592932, "Fixed vertically to the end of lattice steel wire of patent registration No. 10-0658831 Truss-type deck plate with a rod "," non-contact fixed truss-type deck panel and its manufacturing method "of patent registration No. 10-0658832, special Triangular truss deck panel end structure of Korean Patent No. 10-2006000, Utility Model Registration “Truss deck plate of fixed protrusion truss deck” of Korean Patent No. 20-0396892, “Truss girder for reinforced concrete slab”, Patent Publication No. 10-2005-0021144 A plurality of known structures, such as a fixing structure and a method of fixing thereof, "a fastening structure of plywood decks" of Utility Model Registration No. 20-0366793, and a "truss deck assembly of a ring fixing" of Patent Publication No. 10-2006-0082950.

Among the many prior arts, such a technology that is currently evaluated as the best in terms of structural stability and workability is a "truss girder integrated slab formwork structure" of Patent Registration No. 10-0814379, the technique is shown in Figures 1 to 5 It demonstrates below with reference.

The formwork structure according to the art includes a deck panel 10, a truss girder 20, and a connector 30.

The truss girder 20 having a long length in the longitudinal direction is coupled to the upper portion of the deck panel 10 at regular intervals along the width direction. At this time, the truss girder 20 and the deck panel 10 are connected through a plurality of connectors 30. Are coupled to be spaced apart from each other by a predetermined interval in the vertical direction.

The truss girder 20 is a lattice iron wire 26 formed in a continuous bent form repeatedly repeated on both sides around the upper reinforcing bar 22, which is one long rod shape, the lower outer side of the two lattice iron wire 26 by welding Each of the lower reinforcing bar 24 having a long rod shape each one is made to be integrated by welding.

That is, the truss girder 20 has a triangular vertical cross-sectional shape by one upper reinforcing bar 22 and two lower reinforcing bars 24.

Deck panel 10 is formed of a thin plate having a suitable thickness to sufficiently withstand the load of concrete and other various construction loads placed thereon.

Specifically, the deck panel 10 is formed of an iron plate of steel sheet material having a thickness of about 4 mm and a size of about 600 × 2,400 mm.

On the deck panel 10 a plurality of through holes 12 are formed along a position corresponding to the lower reinforcing bars 24 of the plurality of truss girders 20 joined thereto.

That is, since one truss girder 20 has two lower reinforcing bars 24, the through holes 12 are formed in two rows with respect to one truss girder 20 so as to correspond to the two lower reinforcing bars 24. .

At this time, the through holes 12 provided at both ends of the start and end portions along the longitudinal direction are formed so that two rows are arranged on the same line along the width direction, and thus, the connector 30 is coupled to each other one by one. Increase in the number of) can smoothly support the load that is excessively added to both ends.

In relation to this, both ends along the longitudinal direction are endless and easily deformed, and more load can be applied as workers are frequently raised during construction. In order to reinforce the bearing force, the through holes 12 are formed to be densely packed.

In addition, the two rows of through holes 12 formed in the middle portion between the two end portions are formed in a zigzag form so that their positions are staggered from each other, so that the truss girder 20 is stably coupled to the deck panel 10 with only a small number. In addition, to facilitate the installation and disassembly.

The connector 30 couples the truss girder 20 and the deck panel 10 in the middle, and is a member for separating the deck panel 10 on the lower side at the time after curing of the concrete, as shown in FIG. 4. And a fixing bolt 36 and a fixing pin 34 respectively fastened and inserted with respect to the body member 32.

The body member 32 has a seating recess 32a, which is recessed so that the lower reinforcing bar 24 of the truss girder 20 is seated on the upper end side, and a fixing bolt 36 is formed at the center of the lower end side. A female screw groove 32b that can be fitted and fastened from the bottom is formed in the vertical direction.

Further, protruding piece portions 32c are formed on both sides of the seating depressions 32a so as to protrude upwards, and pin holes 32d are formed on the protruding piece portions 32c in the horizontal direction on the same line, respectively. The fixing pin 34 is inserted so as to be common to the pin holes 32d on both sides.

Accordingly, the fixing bolt 36 is formed from the bottom through the hole 12 on the deck panel 10 and the female thread groove 32b on the body member 32 while the body member 32 is seated on the deck panel 10. By being fitted in and fastened, the connector 30 may be coupled to the deck panel 10.

In addition, the fixing pins with respect to the pin holes 32d on the both protruding pieces 32c in the state where the lower reinforcing bar 24 of the truss girder 20 is inserted and seated into the seating depressions 32a on the body member 32. By inserting the 34, the lower reinforcing bar 24 may be restrained so that the connector 30 may be coupled with the truss girder 20.

With the above structure, the construction method of the concrete slab using it is demonstrated below.

First, mass production of the truss girder 20 consisting of the upper reinforcing bar 22, lattice iron wire 26 and the lower reinforcing bar 24 in a factory or the like.

Then, the connector 20 is coupled to each through hole 12 formed on the deck panel 10 through the fastening of the fixing bolt 36 to mass produce the deck panel 10 to which the connector 20 is coupled.

Subsequently, the lower reinforcing bar 24 of the truss girder 20 is positioned on the plurality of connectors 20 coupled to the deck panel 10, and the fixing pin 34 is inserted into the deck panel 10 and the truss girder ( 20).

Subsequently, the assembly is lifted at the construction site and seated so that both ends of the truss girder 20 hang on a support such as beams on both sides, and then the concrete is poured on the deck panel 10.

Then, when the concrete is sufficiently cured, the fixing bolt 36 exposed to the lower part of the deck panel 10 is released and the deck panel 10 is demolded and discharged in the downward direction, thereby completing the process of forming the concrete slab. .

In addition, a plurality of deck panels 10 are connected to each other in the width direction according to the area of the building, and specifically, as shown in FIG. 5, adjacent deck panels 10 on both sides overlap a little through the ends. By making it possible.

However, the formwork according to the prior art as described above has the following problems.

First, the deck panel 10 made of iron plate is very heavy, there is a problem that the dismantling work is very difficult at the time of dismantling later.

Secondly, the deck panel 10 made of iron plate is easily bent during use, rust on the surface, and as a result, the number of times of use is limited to about two times, so frequent production replacement is required, hassle and cost There are also problems that cause disturbances and waste of resources.

Third, in the case of the connector 20 which is a very large number of consumables, the shape of the body member 32 is very complicated, and since it is made of a cylindrical member, there is a problem of causing excessive cost.

Fourth, the process of coupling the truss girder 20 and the deck panel 10 using the connector 20, the first process of seating the connector 20 in accordance with the position of the through hole 12 on the deck panel 10 , The second process of coupling the deck panel 10 and the connector 30 by fastening the fixing bolt 36 to the lower reinforcing bar 24 of the truss girder 20 in the seating depression 32a of the connector 20. The third process of seating, the fourth process of coupling the truss girder 20 and the connector 30 by inserting the fixing pin 34 into the pin hole (32d) of the connector 30, all made of four times However, there is a problem that the combined work is difficult, and a lot of work labor.

Fifth, since the connector 30, which is a very large number of consumables, is composed of three parts of the body member 32, the fixing pin 34, and the fixing bolt 36, the cost is excessive due to the large number of parts. There is also a problem.

Sixth, when a plurality of deck panels 10 are connected to each other to cover a large area of the building, the neighboring deck panels 10 are connected so that their one end simply overlaps one another up and down, so that the casting of concrete According to the overlapping portion, the moisture contained in the concrete and some concrete can be easily leaked, and the end of the deck panel 10 of the overlapping lower side is easily pushed and drooped according to the load of the concrete to be poured. This can easily be broken and collapsed, the overlapping connected portion is not even the upper surface, there is a problem in the final poor workability, low construction quality.

Seventh, depending on the construction conditions it is necessary to cut the deck panel 10 in the middle to use only a part, depending on the cutting to further provide a connector 20 for the reinforcement of the coupling force and the support force Frequently occurs, as described above in the field to combine the connector 20 through the process of four times there is also a problem that the workability is poor.

That is, since only a small number of the plurality of connectors 30 are provided in a zigzag form between the two end portions, the corresponding portions are end portions when the middle portion is cut, and thus the connector 20 is additionally provided and reinforced. Workability is very poor.

Eighth, the fixing pin 34 plugged into the connector 30 during the transfer, lifting and construction process is frequently pulled out and detached, there is also a problem that the important safety is poor above all.

The present invention was devised to solve the above-mentioned problems, the deck panel can exhibit a sufficient support strength, yet its weight can be very light, the dismantling work can be easily carried out, and the existing iron plate The purpose of the present invention is to provide a truss girder integrated deck panel formwork for reinforced concrete slabs that can be used almost semi-permanently, in contrast to being replaced after being used two times.

In addition, the present invention can significantly reduce the manufacturing cost of a very large number of connectors used as consumables, to provide a truss girder integrated deck panel formwork structure for reinforced concrete slabs that can provide a maximum cost reduction. have.

In addition, the present invention can simplify the process of joining the truss girder and the deck panel by using the connector can provide a significant reduction in the work maneuver, and the components of the connector is also simplified to remove some parts The purpose is to provide a truss girder integrated deck panel formwork for reinforced concrete slabs that can provide significant cost savings in this respect as well.

In addition, the present invention, when a plurality of deck panels are connected to each other, the connection portion may not be easily opened and also can form a horizontal upper surface through the connection portion to provide excellent construction workability and construction quality It is an object of the present invention to provide a truss girder integrated deck panel formwork for reinforcement concrete slabs.

In addition, the present invention, if you need to be equipped with additional connectors in accordance with the case of using a part of the deck panel cut in accordance with the construction conditions in the field, it is possible to perform additional coupling work of the connector very easily, excellent field application An object of the present invention is to provide a truss girder integrated deck panel formwork for reinforced concrete slabs that can provide the properties.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

Truss girder integrated deck panel formwork for reinforced concrete slab of the present invention for achieving the above object is formed of an aluminum material, L-shaped bent seating portion is formed at one end along the width direction and two or more at the other end A deck panel in which downward protrusions are formed to be closely coupled to the bent seating portions when they are connected to each other along the width direction, and a plurality of through holes are formed at required locations throughout the entire area; A truss girder coupled to an upper side of the deck panel at regular intervals along a width direction and having a rebar / long wire assembly having a long rod shape on a lower side thereof as a long rebar / steel assembly in a longitudinal direction; And an L-shaped plate member having a horizontal insertion hole in a horizontal direction in which the lower reinforcing bar of the truss girder is inserted at an upper end side of the vertical portion, and a fixing bolt together with the through hole on a horizontal portion seated on the deck panel through a lower surface. A connector formed with a vertical fastening hole in a vertical direction fastened by the; It includes.

Preferably, the deck panel may be formed of Al 6061 material.

Also preferably, the deck panel, in the cross-sectional shape along the width direction, is formed from a portion coupled to the bending seat portion, the thick plate portion having a predetermined width length is formed thick, and the predetermined width is formed relatively thin thickness The thin plate part of the length is formed to be alternated, the downward protrusion is connected to the thin plate portion, the downward protrusion and the rear plate portion is formed with the same height of the lower surface, the downward protrusion in the state seated on the bent seat The upper surface is formed in a horizontal plane as a whole, the truss girder may be coupled to the upper portion of the rear plate portion position.

Also preferably, the connector may include a tab portion formed by protruding upward the peripheral portion of the vertical fastening hole and having a female thread portion for screwing the fixing bolt on an inner diameter surface thereof; It may be provided.

Also preferably, the connector is provided with a welded coupled to the upper portion of the vertical fastening hole position, the nut member having a female threaded portion formed on the inner diameter surface for screwing the fixing bolt; It may be provided.

Also preferably, a hook insertion groove which is additionally provided at a position where reinforcing force is required and is hooked to the lower reinforcing bar of the truss girder is formed on the vertical portion as an L-shaped plate member, An auxiliary connector having a vertical fastening hole in a vertical direction fastened by a fixing bolt together with the through hole on a horizontal portion of the horizontal panel seated on the deck panel; It may further include.

Also preferably, the auxiliary connector, the tab portion is formed by the circumferential portion of the vertical fastening hole is projected upward and the female thread portion for screwing the fixing bolt is formed on the inner diameter surface; Or a nut member provided to be welded to an upper portion of the vertical fastening hole position and having a female screw portion formed on an inner diameter surface for screwing the fixing bolt; It may be provided.

According to the present invention, since the deck panel can exhibit sufficient support strength and its weight is made of a very light aluminum material, the dismantling operation can be performed very easily, and the deck panel can be used semi-permanently and repeatedly. Therefore, the effect of preventing the hassle caused by the repetitive manufacturing replacement and enabling resource saving can be achieved.

In addition, according to the present invention, since the shape of the connector, which is a very large number of consumables, is very simple and made of a thin plate member, it can be easily manufactured by one press work, and thus the manufacturing cost thereof is about 1 compared to the conventional one. Significant savings can be achieved with / 6, which can provide significant cost savings.

And, according to the present invention, the process of combining the truss girder and the deck panel using the connector is the first step of coupling the truss girder and the connector by inserting the horizontal insertion hole of the connector to the lower reinforcement of the truss girder, the deck panel It consists of a total of three times of the second process of seating on the top and the third process of fastening the fixing bolts to connect the connector and the deck panel, which is simpler than the existing four times, thereby reducing the number of work for the joining work. The effect can also be achieved.

Furthermore, according to the present invention, since the connector is composed of only two parts of the body member and the fixing bolt does not use the existing fixed pin component, the effect that can provide a cost reduction due to the deletion of the fixed pin component can also be achieved. Can be.

Furthermore, since the deck panels are connected to each other in such a manner that the downward protrusions formed at the other end thereof are joined to the L-shaped bending seating portion formed at one end of the deck panel, the connection portion is added to the added concrete load. While it may not be opened or deformed at all, a horizontal top surface can also be formed through the connecting portion, so that an effect of providing excellent construction workability and construction quality can also be achieved.

Furthermore, according to the present invention, when the coupling force and the support force is required to be reinforced in the field according to the construction conditions, the auxiliary connector can be easily additionally combined, so that the effect of providing excellent field applicability and construction quality can be achieved. Can be.

Furthermore, according to the present invention, since the lower reinforcing bar of the truss girder coupled to the connector or the auxiliary connector is unlikely to be released at all during the transport, lifting and construction processes, the effect of providing safety can also be achieved.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 6 is a perspective view showing a truss girder integrated deck panel formwork structure for reinforced concrete slab according to a preferred embodiment of the present invention, Figure 7 is a side view thereof.

The truss girder integrated deck panel formwork structure according to the present invention is formed of aluminum material, L-shaped bent seating portion 104 is formed at one end along the width direction and two or more at the other end along the width direction of each other. Deck panel 100 and deck having a plurality of through-holes 102 are formed in the required position throughout the entire area is formed that can be seated tightly coupled to the bent seating portion 104 when connected; The truss girder 200 is provided on the upper side of the panel 100 at regular intervals along the width direction and is a rebar / steel assembly that is long in the longitudinal direction. The fixed ball together with the through hole 102 is formed on the horizontal portion in which the horizontal insertion hole 302a in the horizontal direction into which the lower reinforcing bar 204 of the 200 is inserted and is seated on the deck panel 100 through the lower surface thereof. And a connector (300) is aligned perpendicular to fastening holes (302b) formed in the vertical direction is fastened by 304.

Deck panel 100 is made of aluminum so that it can be easily dismantled by the operator because the weight is very light while being able to exert adequate support strength to sufficiently support the concrete loads and other construction loads placed thereon. Is formed.

That is, in the past, the material of the deck panel 100 has been replaced by iron plate in the plywood, in the present invention is replaced by aluminum in the iron plate.

The facts obtained through various experiments, but especially among aluminum, duralumin Al 6061 material can be preferably adopted.

Deck panel 100 formed of aluminum material is not rust is generated at all by the moisture contained in the concrete to be poured therein, may not be deformed at all even to the addition of excessive load, and also exhibit excellent corrosion resistance against acidic concrete As many times as possible, the number of uses can be used semi-permanently and repeatedly.

This can provide convenience and cost savings as compared to replacing the old iron plate deck panels with new ones and then replacing them with new ones.

Of course, the aluminum material is expensive compared to the iron material, but the cost merit may be sufficient in that it can be used repeatedly semi-permanently.

The plurality of through holes 102 formed to penetrate up and down on the deck panel 100 may be formed in the same manner as in the prior art, and the arrangement, number, size, etc. of the through holes 102 are not particularly limited.

Referring to FIG. 8, the deck panel 100 has an L-shaped bent seating portion 104 formed at one end thereof in a cross-sectional shape along the width direction, and at the other end thereof at the bent seating portion 104. Downward protrusions 106 are formed that can be seated in close fit and connected to one another.

Therefore, when two or more deck panels 100 are connected to each other along the width direction to cover a large construction area, as shown in FIG. 9, the bent seating portion 104 on the one side deck panel 100 is used. The downward protrusions 106 on the neighboring deck panel 100 can be easily connected to each other by being seated in tight fit.

As a result, the upper surface of the connection portion can be formed in the same horizontal plane as the other portions in the state in which the deck panel 100 on both sides are connected to each other, so that the lower surface of the concrete being poured thereon is formed in the horizontal surface and after the concrete slab is formed There may not be a separate finishing work for the bottom surface.

In addition, even when the load of concrete or the addition of various other construction loads, the connection portion may not be opened or deformed at all, thereby providing excellent construction workability.

In the deck panel 100, the thick plate portion 108a having a predetermined width and the thin plate portion 108b having a relatively thin thickness are alternately disposed at portions between both ends in the width direction. Is formed.

The rear plate portion 108a of one side is coupled to the bent seating portion 104 to reinforce the bent seating portion 104 which can be freely deformed and easily deformed.

In addition, the heights of the lower surfaces of the downward protrusions 106 and the thick plate portion 108a are the same, and accordingly, the middle portion of the deck panel 100 is cut along the width direction of the thick plate portion 108a according to the construction conditions in the field. In the case where) becomes the end, when the corresponding rear plate portion 108a is seated and connected to the bent seating portion 104, the upper surface may be formed in a horizontal plane.

Truss girder 200 is coupled to the upper side of the rear plate portion 108a, thereby sufficiently supporting the connection sphere 300 and the truss girder 200, while the connector 300 on the thin plate portion 108b. And truss girder 200 is not coupled.

That is, the through holes 102 formed on the deck panel 100 are formed only at the position of the rear plate portion 108a.

The thin plate portion 108b reduces the manufacturing cost by reducing the amount of material required for manufacturing according to the thickness reduction, and further reduces the weight of the deck panel 100.

Specifically, the deck panel 100 according to the present invention may have a thickness of the thick plate portion 108a in a range of 8 to 16 mm, and the thin plate portion 108b is about 1 / t of the thickness of the thick plate portion 108a. It can be formed at two levels.

The deck panel 100 of the aluminum material as described above may be formed at one time through the extrusion (extruding) process to have a corresponding shape.

The truss girder 200 may be made to be integrated into the upper reinforcement 202, the lattice reinforcing wire 206 and the lower reinforcing bar 204 as the conventional long rebar / steel wire assembly.

However, since the detailed configuration of the truss girder 200 is not a gist of the present invention, the present invention should not be limitedly interpreted by the configuration.

The truss girder 200 is provided on the deck panel 100 so as to be coupled at regular intervals along the width direction, that is, at positions corresponding to the rear plate portion 108a of the deck panel 100.

Of course, the truss girder 200 is finely spaced apart from the deck panel 100 in the vertical direction by the connector 300 provided to intervene with the deck panel 100.

The connector 300 is a member that is coupled on the deck panel 100 to couple between the deck panel 100 and the truss girder 200 on the upper side, and is a consumable that is consumed by being embedded in concrete to be poured later.

10 to 12, the connector 300 is formed of a thin plate-shaped L-shaped, and has a vertical portion and a horizontal portion connected to the bent portion according to the L-shape.

One horizontal insertion hole 302a penetrates in the horizontal direction at the upper end side of the vertical portion, and the lower reinforcing bar 204 of the truss girder 200 is inserted into the horizontal insertion hole 302a to connect the connector 300 with the corresponding connector 300. The truss girder 200 may be combined.

At this time, the inner diameter of the horizontal insertion hole 302a is slightly larger than the outer diameter of the lower reinforcing bar 204 of the truss girder 200, while the lower reinforcing bar 204 of the truss girder 200 can be easily inserted. In the inserted state as much as possible, the lower rebar 204 may not flow.

Therefore, since the connector 300 and the truss girder 200 are directly coupled to each other without using a separate fixing pin component as in the prior art, it is possible to obtain cost savings due to deletion of the fixing pin component.

In addition, the horizontal portion of the connector 300 is a portion which is seated on the upper surface of the deck panel 100 through the lower surface, and has one vertical fastening hole 302b penetrating in the vertical direction, and the corresponding vertical fastening hole 302b. As the fixing bolt 304 is commonly fastened from the bottom in a state of being aligned with the through hole 102 on the lower side deck panel 100, the corresponding connector 300 may be coupled to the deck panel 100. .

Here, in order to allow the fixing bolt 304 to be fastened to the vertical fastening hole 302b through screwing, as shown through (a) of FIG. 10 and (a) of FIG. 11, the vertical fastening hole ( 302b is formed through a tab portion 302c formed so that its circumferential portion protrudes slightly upward, and the tab portion 302c can be formed at a time through tapping using a drill to have a female screw portion on an inner diameter surface.

Alternatively, as shown in FIGS. 10B and 11B, the vertical fastening holes 302b are simply formed in a vertically penetrating hole shape, and are positioned at an upper portion of the vertical fastening holes 302b. A separate nut member 302c 'may be provided to be coupled by spot welding or the like, and of course, a female screw portion is formed on the inner diameter surface of the nut member 302c'.

Thus, as shown in FIG. 12, the fixing bolt 304 is substantially fastened to form a screw connection to the tab portion 302c or the nut member 302c 'of the connector 300.

In this regard, since the connector 300 according to the present invention is very simple in shape and can be easily manufactured through a single press working with a thin plate member, the manufacturing cost thereof may be about 1/6, which is very inexpensive. Can be.

Here, the reduction of the cost can provide a significant cost savings, considering that the connector 300 is used in a very large number, as well as parts that are consumed by being embedded in concrete to be poured later.

Furthermore, according to the present invention, there is also provided an auxiliary connector 400 which can be easily coupled when additional reinforcement of the binding force and the holding force is required at the construction site, as shown in Figs. 13 and 14, corresponding auxiliary The connector 400 is L-shaped like the connector 300 described above, and the vertical fastening hole 402b is formed in the horizontal part thereof, and the tab part 402c or the nut member 402c 'is formed with respect to the vertical fastening hole 402b. Are formed or combined the same.

However, the auxiliary connector 400 has an L-shaped hook-type insertion groove 402a on its vertical portion, and the lower reinforcing bar 204 of the truss girder 200 is laterally connected to the hook-shaped insertion groove 402a. The auxiliary connector 400 can be easily coupled in such a way as to be suspended from the lower reinforcing bar 204 of the truss girder 200 by being coupled from the inner upper surface after being inserted from the upper surface.

The connector 300 and the auxiliary connector 400 can be formed very easily at a time through press processing using a pro-molding body except for the tab parts 302c and 402c and the nut members 302c 'and 402c'. .

The method of coupling the truss girder integrated deck panel formwork for reinforced concrete slabs according to the present invention having the above-described configuration and concrete slab construction method using the same will be described below.

First, a large amount of truss girder 200 composed of an upper reinforcing bar 202, a lattice iron wire 206, and a lower reinforcing bar 204 is produced in a factory, and at this time, as many connectors as necessary for the lower reinforcing bar 204 ( 300) is produced in a combined state.

That is, a plurality of connector 300 is inserted into the lower reinforcing bar 204 through the horizontal insertion hole 302a is produced in the form of hanging.

In addition, a large number of deck panels 100 having a plurality of through holes 102 are produced in a factory or the like.

Subsequently, the truss girder 200 on which the plurality of connectors 300 are suspended is positioned on the upper side of the deck panel 100, and then the vertical fastening hole 302b of each of the hanging connectors 300 is suspended on the deck panel 100. The connector 300 is seated on the deck panel 100 in a state in which it is in position (102), and then the fixing bolt 304 is inserted into the through hole 102 and each connector 300 of the deck panel 100 from the bottom. Commonly inserted and fastened to the vertical fastening hole 302b of the truss girder 200 and the deck panel 100 is coupled.

Next, at the building site, the assembly is lifted and seated so that both ends of the truss girder 200 hang on a support such as beams on both sides.

In this case, the plurality of deck panels 100 may be connected to each other so as to cover all of the building area, and at this time, the downward protrusions of the next deck panel 100 may be connected to the bent seating portion 104 of the deck panel 100 on one side. 106) are tightly mated and connected to seat.

In addition, if necessary to cover the entire building area, the deck panel 100 may be cut in the middle, and the rear plate portion 108a of the cut portion may be seated and connected to the downward protrusion 106 of the other deck panel 100. .

In addition, the part that needs to reinforce the coupling force and the holding force according to the cutting and construction conditions in the middle, etc. is to hang the auxiliary connector 400 directly by the hook type on the lower reinforcing bar 204 of the truss girder 200. Insert and fasten the fixing bolts 304 so as to be common to the vertical fastening hole 402b of the auxiliary connector 400 which is suspended and the hole 102 on the deck panel 100 which can be formed by directly drilling in the field. Through the truss girder 200 and the deck panel 100 is to be coupled.

Thus, the construction of the formwork is completed.

Next, the concrete is poured on the deck panel 100 of the formed formwork structure, and when the poured concrete is sufficiently cured, the fixing bolt 304 exposed to the lower part of the deck panel 100 is released and the deck panel ( 100) is demoulded in the downward direction and taken out, whereby the construction of the concrete slab can be completed.

According to the present invention as described above, the process of combining the truss girder 200 and the deck panel 100 using the connector 300, the horizontal of the connector 300 to the lower reinforcing bar 204 of the truss girder 200 Inserting the insertion hole 302a, the first process of coupling the truss girder 200 and the connector 300, the second process of seating the connector 300 on the deck panel 100, fastening the fixing bolt 304 Since the process consists of only a total of three times of the third process of coupling the connector 300 and the deck panel 100, one process can be reduced compared to the existing four times, significantly reducing the number of work for the coupling work Can be.

In addition, when it is necessary to reinforce the bonding force and the support force according to the construction conditions, it can be easily reinforcement using the auxiliary connector 400 directly on the site, it can also provide excellent field applicability and construction quality.

In the foregoing description, it should be understood that those skilled in the art can make modifications and changes to the present invention without changing the gist of the present invention as merely illustrative of a preferred embodiment of the present invention.

1 is a perspective view showing a truss girder integrated slab formwork according to the prior patent registration No. 10-0814379,

Figure 2 is a side view showing a truss girder integrated slab formwork according to the conventional patent registration No. 10-0814379,

3 is a perspective view showing a deck panel provided in the truss girder integrated slab formwork according to the prior patent registration No. 10-0814379,

4 is a perspective view showing a connector provided in the truss girder integrated slab formwork according to the prior patent registration No. 10-0814379,

5 is a schematic cross-sectional view showing a state in which the adjacent deck panel is connected to each other in the truss girder integrated slab formwork according to the prior patent registration No. 10-0814379,

Figure 6 is a perspective view showing a truss girder integrated deck panel formwork structure for reinforced concrete slab according to a preferred embodiment of the present invention,

7 is a side view showing a truss girder integrated deck panel formwork structure for reinforced concrete slab according to a preferred embodiment of the present invention,

8 is a perspective view showing a deck panel provided in the truss girder integrated deck panel formwork for reinforced concrete slab according to a preferred embodiment of the present invention,

9 is a cross-sectional view showing a state in which both deck panels are connected to each other in the truss girder integrated deck panel formwork for reinforced concrete slab according to an embodiment of the present invention,

10 is a perspective view showing two forms of the connector provided in the truss girder integrated deck panel formwork for reinforced concrete slab according to a preferred embodiment of the present invention,

11 is a cross-sectional view of two forms of the connector provided in the truss girder integrated deck panel formwork for reinforced concrete slab according to a preferred embodiment of the present invention,

12 is a cross-sectional view showing a state in which the thrust girder and the deck panel is coupled through the connector in the truss girder integrated deck panel formwork for reinforced concrete slab according to an embodiment of the present invention,

Figure 13 is a perspective view showing two forms of auxiliary connectors provided in the truss girder integrated deck panel formwork for reinforced concrete slab according to a preferred embodiment of the present invention,

FIG. 14 is a cross-sectional view illustrating a state in which a thrust girder and a deck panel are coupled through an auxiliary connector in a truss girder integrated deck panel formwork for reinforced concrete slab according to a preferred embodiment of the present invention.

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

100: deck panel 102: through-hole

104: bending seat 106: downward protrusion

108a: thick plate portion 108b: thin plate portion

200: truss girder 202: upper rebar

204: lower reinforcing bar 206: lattice iron wire

300: connector 302a: horizontal insertion hole

302b: Vertical fastening hole 302c: Tab part

302c ': Nut member 304: Fixing bolt

400: auxiliary connector 402a: hook-type insertion groove

402b: vertical fastening hole 402c: tab part

402c ': Nut member

Claims (7)

It is formed of an aluminum material and formed an L-shaped bent seat at one end along the width direction, and at the other end is formed a downward protrusion to be closely coupled to the bent seat when two or more are connected to each other along the width direction. A deck panel having a plurality of through-holes formed at required locations throughout the entire area; A truss girder coupled to an upper side of the deck panel at regular intervals along a width direction and having a rebar / long wire assembly having a long rod shape on a lower side thereof as a long rebar / steel assembly in a longitudinal direction; And As an L-shaped plate member, a horizontal insertion hole in a horizontal direction in which the lower reinforcing bar of the truss girder is inserted is formed at the upper end side of the vertical part, and on the horizontal part seated on the deck panel through the lower surface, the fixing bolt is formed together with the through bolt. A connector having a vertical fastening hole in a vertical direction fastened by the fastener; Truss girder integrated deck panel formwork for reinforced concrete slabs comprising a. The method of claim 1, The deck panel, Truss girder integrated deck panel formwork for reinforced concrete slabs, which is formed of Al 6061 material. The method of claim 1, The deck panel, In the cross-sectional shape along the width direction, Is formed from the portion coupled to the bent seating portion is formed so that the thick plate portion of a certain width length is formed thick, and the thin plate portion of a predetermined width length is formed relatively thin, alternately, The downward protrusion, In contact with the thin plate portion, The downward protrusion and the rear plate portion, To form the same height, In the state where the downward protrusion is seated on the bent seating portion, the upper surface is formed in a horizontal plane as a whole, Truss girder integrated deck panel formwork structure for reinforced concrete slabs, characterized in that the truss girder is coupled to the upper portion of the rear plate portion. The method according to claim 1 or 2, The connector, A tab portion formed by a protruding upward portion of the vertical fastening hole and having a female screw portion formed on an inner diameter surface for screwing the fixing bolt; Truss girder integrated deck panel formwork structure for reinforced concrete slab characterized in that it comprises a. The method according to claim 1 or 2, The connector, A nut member provided to be welded to an upper portion of the vertical fastening hole position and having a female screw portion formed on an inner diameter surface for screwing the fixing bolt; Truss girder integrated deck panel formwork structure for reinforced concrete slab characterized in that it comprises a. The method according to claim 1 or 2, It is additionally provided at a position where reinforcing force is required, and an L-shaped plate member is formed on the vertical portion of which a hook insertion groove is hooked to the lower reinforcing bar of the truss girder and is formed on the deck panel through a lower surface. An auxiliary connector formed with a vertical fastening hole in a vertical direction fastened by a fixing bolt together with the through hole on a horizontal part of the seat; Truss girder integrated deck panel formwork structure for reinforced concrete slabs further comprising a. The method of claim 6, The auxiliary connector, A tab portion formed by a protruding upward portion of the vertical fastening hole and having a female screw portion formed on an inner diameter surface for screwing the fixing bolt; Or a nut member provided to be welded to an upper portion of the vertical fastening hole position and having a female screw portion formed on an inner diameter surface for screwing the fixing bolt; Truss girder integrated deck panel formwork structure for reinforced concrete slab characterized in that it comprises a.

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