KR102473106B1 - Precast concrete slab form and manufacturing method of thereof - Google Patents

Abstract

The precast slab formwork structure according to the present invention includes a bottom plate formwork 100 supporting the bottom surface of the concrete (C) to be poured; A side formwork 200 coupled to the upper surface of the bottom plate formwork 100 to support the left, right, rear and front sides of the concrete (C); A fixing member 300 coupled to the bottom plate formwork 100 to fix the side formwork 200 and supporting an outer surface of the side formwork 200; It is installed in the concrete (C) pouring area (S) formed by the bottom plate formwork (100) and the side formwork (200), but is embedded in the inside when pouring concrete (C) and reinforced so as to protrude outward from the side formwork (200) Rebar 500; but including, the fixing member 300 is a standing portion 310 coupled to the bottom plate formwork 100 in an upright structure; a protruding portion 320 coupled to the standing portion 310 so as to rotationally drive the standing portion 310 as an axis; It includes a side anti-support portion 330 and a lower anti-support portion 340 coupled to the protrusion 320 to support the side formwork 200 laterally and downward.

Description

Precast slab formwork structure and precast slab manufacturing method using the same {PRECAST CONCRETE SLAB FORM AND MANUFACTURING METHOD OF THEREOF}

The present invention relates to the field of construction, and more particularly to precast slab formwork structures.

Conventionally, when manufacturing a concrete structure, a cast-in-place method was mainly used to complete the structure by arranging reinforcing bars and pouring concrete at the site. However, in sites requiring environmental pollution regulation, such as offshore structures, or sites requiring rapid construction, a precast concrete assembly structure method, which is pre-fabricated in a factory and assembled on site, is used.

In the case of assembling a precast concrete structure, a process of pouring on-site concrete occurs in some sections or connections in order to interconnect the precast concrete products.

At this time, for the rigid coupling structure of the connection part, the precast concrete structure must be manufactured so that the embedded reinforcing bars protrude from the side or in a partial area when the precast concrete structure is manufactured.

However, due to the structure of the protruding reinforcing bars, there has been a difficulty in that a groove portion through which the reinforcing bar protrudes must be formed in a formwork supporting the protruding reinforcing bar, and the concrete poured into the groove portion must be manufactured so as not to flow out.

In order to solve this problem, conventionally, Styrofoam, rubber plates, wooden logs, etc. are used to block the grooves and pour concrete, but there is a problem that the member blocking the grooves is distorted or the finished surface of the grooves is not smooth due to the pressure and weight of the concrete being poured. come.

The present invention has been devised to solve the above problems, and proposes a precast slab formwork structure in which the installation and disassembly of the formwork is easy while effectively closing the groove of the side formwork where the reinforcing bars protrude, and a precast slab manufacturing method using the same. do.

In order to solve the above problems, the precast slab formwork structure according to the present invention is a bottom plate formwork 100 for supporting the bottom surface of the concrete (C) to be poured; Side formwork 200 coupled to the upper surface of the bottom plate formwork 100 to support the left, right, rear and front side surfaces of the concrete (C); A fixing member 300 coupled to the bottom plate formwork 100 to fix the side formwork 200 and supporting an outer surface of the side formwork 200; It is installed in the concrete (C) pouring area (S) formed by the bottom plate formwork (100) and the side formwork (200), and is buried inside during the pouring of the concrete (C), as well as to the outside of the side formwork (200). Including, the fixing member 300 is a standing part 310 coupled to the bottom plate formwork 100 in an upright structure; a protruding part 320 coupled to the standing part 310 so as to rotationally drive the standing part 310 as an axis; It includes a side anti-support portion 330 and a lower anti-support portion 340 coupled to the protrusion 320 to support the side formwork 200 laterally and downward.

The side formwork 200 includes a front formwork 200a, a rear formwork 200b, one side formwork 200c, and the other formwork 200d, but is a steel structure having an "L" shaped cross section, and the bottom plate formwork 100 ) The bottom plate 210 installed on; A standing plate 220 coupled to the bottom plate 210 in an upright structure; and, in the standing plate 220, from the upper surface of the standing plate 220 so that the edge of the reinforcing bar 500 protrudes outward. It is preferable that the groove portion (h) formed in the downward direction is formed.

After the reinforcement 500 is installed in the groove part (h), the stopper member 400 is installed on the outer surface of the standing plate 220 to prevent the concrete (C) from being ejected into the groove part (h). desirable.

The reinforcing bars 500 are upper reinforcing bars 510; The upper reinforcing bars 510 and the lower reinforcing bars 520, which are arranged in a two-row structure and protrude into the groove (h) It is preferable that the edges of the interconnected structure.

The stopper member 400 is rotationally driven along the outer surface of the standing plate 220 to block the groove portion (h), and the reinforcing bar groove portion so that the upper reinforcing bar 510 is inserted into the stopper member 400 during rotational driving. It is preferable that (h2) is formed.

The stopper member 400 is a steel plate material having an “F” shape structure, and includes a standing steel plate 410 hinged in a structure in which an inner surface contacts an outer surface of the standing plate 220; an upper protruding plate 420 protruding to one side from the upper side of the standing steel plate 410; It is preferable to include; a lower protrusion plate 430 spaced apart from the lower side of the upper protrusion plate 420 and protruding to one side.

The standing steel plate 410 is coupled to each other with a rotation coupling pin 460 so as to drive a hinge with the standing plate 220, and the coupling pin 460 is the lower area of the lower protruding plate 430. 410), and the rotational driving of the stopper member 400 is preferably performed by lateral driving of a rotational opening/closing driving member 600 hinged to the lower end of the standing steel plate 410.

The rotational opening/closing driving member 600 is mutually coupled by a lower coupling pin 470 coupled to the lower end of the standing steel plate 410, and the stopper member 400 has the coupling pin 460 as an axis, It is rotationally driven by the lateral driving of the rotation opening/closing driving member 600, and by the rotational driving of the stopper member 400, the protruding reinforcing bar 500 is connected to the upper protrusion plate 420 and the lower protrusion plate ( 430), it is preferable that the upper region 440, which is the region between them, and the lower region 450, which is the lower side of the lower protruding plate 430, are located.

A precast slab manufacturing method using a precast slab formwork structure according to an embodiment of the present invention includes a formwork installation step of installing the bottom plate formwork 100 and the side formwork 200; A formwork fixing step of fixing the formwork by installing the fixing member 300; A reinforcement step of arranging the reinforcement 500 so that an edge protrudes into the groove portion h of the standing plate 220; Rotatingly driving the cap member 400 to prevent the concrete (C) poured into the groove (h) from being ejected; A concrete pouring step of pouring the concrete (C); It includes a form dismantling step of curing the concrete (C) and removing the bottom plate formwork 100 and the side formwork 200.

The present invention can effectively reinforce the reinforcing bars protruding to the side of the formwork and effectively prevent the pouring of the poured concrete around the protruding reinforcing bars.

1 is a perspective view of a precast slab formwork structure according to an embodiment of the present invention
2 is a view showing that reinforcement is placed inside a precast slab formwork structure according to an embodiment of the present invention
Figure 3 is a side view showing that the fixing member is installed according to an embodiment of the present invention
4 is a cross-sectional view of a side formwork according to an embodiment of the present invention
5 is a view showing that reinforcing bars protrude to the side of the side formwork according to an embodiment of the present invention
6 is a view showing closing the groove of the side formwork with a stopper member according to an embodiment of the present invention
7 is a front view showing a coupling structure of a stopper member according to an embodiment of the present invention;
8 is a view showing that a rotation coupling pin is coupled to a stopper member according to an embodiment of the present invention;

An embodiment of a precast slab formwork structure and a method of manufacturing a precast slab using the same according to the present invention will be described in detail with reference to the accompanying drawings, and in the description with reference to the accompanying drawings, the same or corresponding components are the same The drawing numbers are given and overlapping descriptions thereof will be omitted.

In addition, terms such as first and second used below are only identification symbols for distinguishing the same or corresponding components, and the same or corresponding components are not limited by terms such as first and second. not.

In addition, coupling does not mean only the case of direct physical contact between each component in the contact relationship between each component, but another configuration intervenes between each component so that the component is in the other configuration. It should be used as a concept that encompasses even the case of contact with each other.

Hereinafter, a precast slab formwork structure and a method of manufacturing a precast slab using the same will be described in detail with reference to the accompanying drawings.

The precast slab formwork structure according to the present invention includes a bottom plate formwork 100 supporting the bottom surface of the concrete (C) to be poured; A side formwork 200 coupled to the upper surface of the bottom plate formwork 100 to support the left, right, rear and front sides of the concrete (C); A fixing member 300 coupled to the bottom plate formwork 100 to fix the side formwork 200 and supporting an outer surface of the side formwork 200; It is installed in the concrete (C) pouring area (S) formed by the bottom plate formwork (100) and the side formwork (200), but is embedded in the inside when pouring concrete (C) and reinforced so as to protrude outward from the side formwork (200) Rebar 500; but including, the fixing member 300 is a standing portion 310 coupled to the bottom plate formwork 100 in an upright structure; a protruding portion 320 coupled to the standing portion 310 so as to rotationally drive the standing portion 310 as an axis; It includes a side anti-support portion 330 and a lower anti-support portion 340 coupled to the protrusion 320 to support the side formwork 200 laterally and downward.

The formwork is installed in the structure shown in FIG. 1, and the side formwork 200 includes a front formwork 200a, a rear formwork 200b, one side formwork 200c and the other formwork 200d, but has an “L” shaped cross section. As a section steel structure having, a bottom plate 210 installed on the bottom plate formwork 100; A standing plate 220 coupled to the bottom plate 210 in an upright structure; and, the standing plate 220 is formed in a downward direction from the upper surface of the standing plate 220 so that the edge of the reinforcing bar 500 protrudes outward. It is preferable that the groove portion (h) is formed.

As described above, in order to apply a precast concrete structure to a site, the precast concrete products must be interconnected on site. At this time, a process of pouring on-site concrete is required in some sections or joints.

At this time, for the rigid coupling structure of the connection part, the precast concrete structure is manufactured so that the embedded reinforcing bars protrude from the side or in a partial area when the precast concrete structure is manufactured.

Due to the structure of the protruding reinforcing bars, a groove through which the reinforcing bar protrudes must be formed in the formwork supporting the protruding reinforcing bar, and the groove is blocked using Styrofoam, a rubber plate, or a piece of wood to prevent the concrete being poured into the groove from flowing out. should be laid out

As shown in FIG. 5, the formwork structure according to the present invention is to prevent concrete (C) from being ejected into the groove (h) after the reinforcing bar (500) is installed in the groove (h) on the outer surface of the standing plate (220). It is preferable that the stopper member 400 is installed.

The reinforcing bars 500 are upper reinforcing bars 510; The lower reinforcing bars 520 are installed to be spaced apart from the upper reinforcing bars 510; It is installed in a connected ring structure. Such a ring structure is shown in FIG. 5 or 6.

The stopper member 400 is rotationally driven along the outer surface of the standing plate 220 to block the groove portion h, and the stopper member 400 has a reinforcing bar groove portion h2 so that the upper reinforcing bar 510 is inserted during rotational driving. it is desirable

In this case, the stopper member blocks the groove by the rotational drive as shown in FIG. 6 to prevent the pouring or pouring of the concrete being poured.

Above all, the stopper member 400 according to the present invention is a steel plate material having an "F" type structure, and includes a standing steel plate 410 hinged in a structure in which the inner surface contacts the outer surface of the standing plate 220; an upper protruding plate 420 protruding to one side from the upper side of the standing steel plate 410; It is preferable to include; a lower protrusion plate 430 spaced apart from the lower side of the upper protrusion plate 420 and protruding to one side.

Due to the “F” type structure, the entire section between the upper and lower reinforcing bars is closed to effectively prevent the pouring out of the concrete being poured.

The standing steel plate 410 is mutually coupled with the standing plate 220 and the rotational coupling pin 460 so as to drive the hinge, the coupling pin 460 is the lower area of the lower protruding plate 430 It is coupled to the standing steel plate 410 , The rotational driving of the stopper member 400 is preferably performed by the lateral driving of the rotary opening/closing driving member 600 hinged to the lower end of the standing steel plate 410.

In this case, the rotational opening/closing driving member 600 is coupled to each other by a lower coupling pin 470 coupled to the lower end of the standing steel plate 410, and the stopper member 400 rotates to open and close with the coupling pin 460 as an axis. It is rotationally driven by the lateral driving of the driving member 600, and by the rotational driving of the stopper member 400, the protruding reinforcing bar 500 is located on the upper side of the area between the upper and lower projecting plates 420 and 430. It is preferable that the area 440 and the lower area 450 below the lower protruding plate 430 are located.

Such a structure can be clearly explained through FIGS. 5, 6, and 7.

The rotational opening/closing driving member 600 induces the stopper member 400 to rotate around the coupling pin 460 while driving in the lateral direction. Therefore, there is an advantage in that the installation and disassembly of the formwork is easy, and the groove part can be completely blocked.

A precast slab manufacturing method using a precast slab formwork structure according to an embodiment of the present invention includes a formwork installation step of installing a bottom plate formwork 100 and a side formwork 200; Formwork fixing step of fixing the formwork by installing the fixing member 300; A reinforcement step of arranging the reinforcement 500 so that the edge protrudes into the groove portion h of the standing plate 220; Rotating and driving the cap member 400 to prevent the concrete (C) poured into the groove (h) from being ejected; A concrete pouring step of pouring concrete (C); It includes a form dismantling step of curing the concrete (C) and removing the bottom plate formwork 100 and the side formwork 200.

C: concrete h: groove
S: pouring area 100: bottom plate structure
200: side formwork 200a: front formwork
200b: rear formwork 200c: one side formwork
200d: other side formwork 210: bottom plate
220: standing plate 300: fixing member
310: standing part 320: protruding part
330: side support 340: lower support
400: stopper member 410: standing steel plate
420: upper projection plate 430: lower projection plate
450: lower area 460: rotation coupling pin
470: bottom coupling pin 500: rebar

Claims (9)

Bottom plate formwork 100 for supporting the bottom surface of the concrete (C) to be poured;
Side formwork 200 coupled to the upper surface of the bottom plate formwork 100 to support the left, right, rear and front side surfaces of the concrete (C);
A fixing member 300 coupled to the bottom plate formwork 100 to fix the side formwork 200 and supporting an outer surface of the side formwork 200;
It is installed in the concrete (C) pouring area (S) formed by the bottom plate formwork (100) and the side formwork (200), and is buried inside during the pouring of the concrete (C), as well as to the outside of the side formwork (200). Including; reinforcing bars 500 arranged so as to protrude;
The fixing member 300 is
A standing part 310 coupled to the bottom plate formwork 100 in an upright structure;
a protruding part 320 coupled to the standing part 310 so as to rotationally drive the standing part 310 as an axis;
Precast slab formwork structure, characterized in that it comprises a; lateral support 330 and lower support 340 coupled to the protrusion 320 to support the side formwork 200 laterally and downward.
According to claim 1,
The side formwork 200 is
Including a front die (200a), a rear die (200b), one side die (200c) and the other side die (200d),
As a section steel structure having an "L" shaped cross section, a bottom plate 210 installed on the bottom plate formwork 100;
Including; a standing plate 220 coupled to the bottom plate 210 in an upright structure;
The precast slab formwork structure, characterized in that the standing plate 220 is formed with a groove (h) formed in a downward direction from the upper surface of the standing plate 220 so that the edge of the reinforcing bar 500 protrudes outward.
According to claim 2,
On the outer surface of the standing plate 220, after the reinforcing bar 500 is installed in the groove part h, a stopper member 400 for preventing the concrete C from spouting into the groove part h is installed. A characterized precast slab formwork structure.
According to claim 3,
The rebar 500 is
Upper reinforcement bar (510);
The upper reinforcing bars 510 and the lower reinforcing bars 520, which are arranged in a two-row structure and protrude into the groove (h) Precast slab formwork structure, characterized in that the edge of the interconnected structure.
According to claim 4,
The stopper member 400 is
It is characterized in that the groove portion (h) is blocked by rotational driving along the outer surface of the standing plate 220, and the reinforcing bar groove portion h2 is formed in the stopper member 400 so that the upper reinforcing bar 510 is inserted during rotational driving. as a precast slab formwork structure.
According to claim 5,
The stopper member 400 is a steel plate material having an “F” shape structure,
a standing steel plate 410 hinged in a structure in which an inner surface contacts an outer surface of the standing plate 220;
an upper protruding plate 420 protruding to one side from the upper side of the standing steel plate 410;
A precast slab formwork structure characterized in that it comprises a; lower protrusion plate 430 spaced apart from the upper protrusion plate 420 and protruding to one side.
According to claim 6,
The erecting steel plate 410 is coupled to each other with a rotational coupling pin 460 so as to drive a hinge with the erecting plate 220,
The coupling pin 460 is coupled to the standing steel plate 410, which is the lower region of the lower protruding plate 430,
The rotational drive of the stopper member 400 is a precast slab formwork structure, characterized in that the lateral drive of the rotational opening and closing driving member 600 hinged to the lower end of the standing steel plate 410.
According to claim 7,
The rotational opening/closing driving member 600 is mutually coupled by a lower coupling pin 470 coupled to the lower end of the standing steel plate 410,
The stopper member 400 is
With the coupling pin 460 as an axis, it is rotationally driven by the lateral driving of the rotation opening/closing driving member 600,
By the rotational driving of the stopper member 400,
The protruding reinforcing bar 500 is located in the upper region 440 between the upper projecting plate 420 and the lower projecting plate 430 and the lower region 450 below the lower projecting plate 430. as a precast slab formwork structure.
A precast slab manufacturing method using the precast slab formwork structure according to claim 8,
A formwork installation step of installing the bottom formwork 100 and the side formwork 200;
A formwork fixing step of fixing the formwork by installing the fixing member 300;
A reinforcement step of arranging the reinforcement 500 so that an edge protrudes into the groove portion h of the standing plate 220;
Rotatingly driving the cap member 400 to prevent the concrete (C) poured into the groove (h) from being ejected;
A concrete pouring step of pouring the concrete (C);
Precast slab manufacturing method characterized in that it comprises a; formwork dismantling step of curing the concrete (C) and removing the bottom plate formwork (100) and the side formwork (200).

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