KR102754469B1 - Apparatus supporting panel for constructing slab of building - Google Patents

Abstract

The present invention relates to a panel support device for slab construction of a building, which minimizes damage to a prop head during the process of dismantling the prop head after curing of slab concrete.
In the panel support device for slab construction of the present invention, a prop head is formed by protruding from the bottom surface of a main body and extending, and a reinforcing filler is combined inside a hollow supporter coupled to the top of a support, and a guide cap is formed integrally with a body having an insertion hole formed in the center of a square plate-shaped upper surface into which the supporter is inserted, and an insertion groove formed on the bottom surface of the supporter to fit into the top of the support.
In the present invention, since the connection between the prop head and the support is more closely and firmly formed, the probability of the prop head detaching from the connection portion with the support is reduced during the process of tilting the upper end of the support to which the prop head is coupled toward the ground in order to dismantle the prop head after curing of slab concrete, and even if it detaches, it is closer to the ground, that is, even if it detaches and hits the ground, the impact is reduced.

Description

{APPARATUS SUPPORTING PANEL FOR CONSTRUCTING SLAB OF BUILDING}

The present invention relates to a device for supporting a panel for the construction of a concrete slab of a building, and more specifically, to a device for supporting a panel for the construction of a slab of a building, which is connected to the upper part of a support erected on the ground during slab construction to connect and support a slab beam, and which ensures close connection with the support by reinforcing a connecting support member of a prop head, thereby minimizing damage to the prop head during the dismantling process of the prop head after the curing of the slab concrete.

Typically, when constructing a multi-story concrete structure such as an apartment or building, formwork for the walls and slabs is installed, concrete is poured and cured, then the formwork is dismantled, the formwork materials are lifted to the upper floor, and the process of installing, pouring, and dismantling the concrete is repeated.

In general, recent architectural formwork is mainly made of an assembly of panels made of metal materials such as iron or aluminum. The wall formwork is assembled by continuously joining unit wall panels formed into rectangles whose vertical length is relatively larger than their width at intervals equal to the thickness of the wall to be constructed so as to cover the area of the wall. The slab formwork is formed by continuously arranging square unit slab panels on a single plane between supports erected vertically from the floor and beams supported on the top of the wall formwork, thereby forming a supporting floor surface for pouring concrete.

Once the wall formwork and slab formwork have been installed and concrete has been poured into the formwork and cured, the formwork is dismantled. However, in most buildings, the height between the floor and the ceiling (floor height) is much higher than the worker's height. Therefore, in order to dismantle the slab panels, the worker uses a ladder to separate the assembled panels and dismantle them. In the process, the separated slab panels fall to the floor due to their own weight. In this process, damage to the metal panels and the risk of safety accidents inevitably occur. In addition, the noise and dust generated when colliding with the floor have acted as factors that worsen the environment of not only the construction site but also the surrounding area.

As a solution to the above problems raised in the formwork construction method applied in existing building construction, Korean Patent Registration No. 10-0484512 discloses a new method of constructing a formwork for slab construction, in which, when dismantling the formwork after the pouring and curing of concrete for forming a wall and slab using the formwork is completed, the slab panel does not fall directly from the ceiling to the floor, but is supported in a state where it is lowered to a height that the worker does not need to use a stepladder or ladder, so that the worker can directly lift the panel to the floor.

The above-mentioned patented formwork for slab construction solves all the problems that have been pointed out in existing formwork at once, and also has the advantage of allowing stable dismantling work with minimal damage to the panels, without requiring special skills in formwork installation and dismantling, and is therefore called the "drop construction method" in the relevant industry, and its use as an eco-friendly formwork construction method is continuously expanding in the construction of high-rise buildings including apartments.

Meanwhile, FIG. 1 shows the installation structure of the architectural formwork panel assembly disclosed in Patent Registration No. 10-1514395, which implements the architectural formwork panel assembly structure applied to the above-mentioned drop construction method. As illustrated, wall panels (WP) for constructing side walls are connected and assembled facing each other with a space equal to the thickness of the wall to be constructed along the outer perimeter of the floor, and a slab panel beam (50) supported at one end by a soffit length (SL) located at the top of the wall panel is installed, and a slab panel (SP) supported by this is arranged in a grid pattern, and a prop head (52) coupled to the top of a support (51) vertically erected from the floor is located at the connection portion of the slab panel beam (50) to connect the slab panel beams (50) and, at the same time, to enable the slab panel beam (50) and the slab panel (SP) assembly supported by this to be supported in the air at a distance from the ground.

Meanwhile, a support guide (53) is installed on the outer surface of the support (51) just below the connection between the prop head (52) and the slab panel beam (50), and a stopper (54) is formed on the lower support (51).

In the slab panel assembly of the above structure, after the curing of the slab concrete is completed, the slab panel beam (40) separated from the prop head (52) and the slab panel (SP) supported by it are guided to the support guide (53) coupled to the support (51) below and lowered. At this time, the support guide (53) does not fall all at once but gradually lowers due to the frictional action of a reinforcing member (not shown in the drawing) that contacts the outer surface of the support (51) in a pressurized state by the elastic force of the spring.

As described above, the slab panel assembly, which is slowly lowered while being guided by the support guide (53), is stopped from further lowering by the stopper (54) formed on the support (51) at the bottom of the support guide (53). Since the height of the slab panel assembly in the stopped state is such that a worker can lift the panel down to the floor by hand while standing on the ground, the worker can place the slab panel and beam on the floor without generating noise without having to climb up a step or ladder, or move them directly to the work space for construction on the upper floor.

In this way, after the slab panel (SP) and the slab panel beam (50) along the support (51) and the support guide (53) are lowered, after a certain amount of time has passed, the support (51) and the prop head (52) that is connected to the top of the support and supports the bottom surface of the slab concrete that has completed curing are removed.

First, by operating the height adjustment device equipped on the support (51) to lower the height of the support itself, the prop head (50) attached to the top is separated from the bottom surface of the cured slab. Then, the worker slowly tilts the top of the support (51) toward the floor, but the problem is that during this process, the prop head (50) with its considerable weight falls off the top of the support (51) and onto the floor, or some workers intentionally drop the prop head onto the concrete floor for the sake of speed and convenience of work.

In this way, the impact that occurs when the prop head is separated or detached from the support and falls to the ground can cause damage or breakage to the prop head as well as noise. The most serious part of this is the support part that extends from the bottom of the prop head body and is inserted into the top of the support.

Since the above-mentioned support is formed in a hollow tube shape and extends a predetermined length from the bottom surface of the prop head body, when the prop head is separated from the support and falls, there is a high possibility that it will hit the floor first compared to other parts, and when it hits like that, it will be deformed from its original shape or damaged, which will ultimately result in the prop head itself being impossible to reuse.

The prop head used in the slab panel drop construction method has a complex cross-sectional shape and structure, so it is a component that requires a relatively large number of processing and welding parts compared to other components during the production stage, and thus, it is a component that requires a lot of manufacturing costs. Therefore, when it cannot be reused after use, it causes an economic loss, and there is a demand for improvement or supplementation in this regard.

The present invention is intended to solve the problems of the above-mentioned prior art, and provides a panel support device for building slab construction, which improves the impact resistance against collision of a prop head with the floor that inevitably occurs during the dismantling process of a support and a prop head supported by the support, while inducing the prop head to detach from the support at a vertical height with the gap from the ground as narrow as possible, thereby reducing the amount of impact and noise with the floor, and thereby increasing the recyclability of the prop head.

The above object of the present invention is achieved by a panel support device for slab construction of a building, in which a slab panel beam is installed, the outer end of which is supported by a soffit length located at the top of a wall panel, and a prop head coupled to the top of a support erected vertically from the floor is positioned at the connection portion of the slab panel beam so as to connect and support the slab panel beam, wherein the prop head is formed by protruding from the bottom surface of the main body and having a reinforcing filler member coupled to the inside of a hollow support coupled to the top of the support, and a guide cap formed integrally with a body having an insertion hole formed in the center of the upper surface of a square plate into which the support is inserted, and an insertion groove formed on the bottom surface of the support to be fitted into the top of the support.

The support of the above prop head is a pipe made of aluminum with a circular or polygonal cross-section, one end of which is joined to the center of the bottom surface of the prop head by welding, and the other free end forms a tube body extending in a straight line with a predetermined length, and a reinforcing filler is inserted into the inside of this hollow tube-shaped support.

The above reinforcing filler is made of a metal material and is formed to have a length and cross-section that can fill the entire hollow portion of the support, so that when the reinforcing filler is combined with the support, the support is no longer a hollow pipe but a kind of circular bar with a circular cross-section filled with metal material, thereby increasing impact resistance and fracture strength through strength reinforcement.

Meanwhile, it is preferable that the connection between the support member and the reinforcing filler member be configured such that a female thread portion is formed on the inner surface of the support member, and the reinforcing filler member is configured such that a male thread is formed to screw-connect with the female thread portion on the inner surface of the support member, so that the connection between the support member and the reinforcing filler member can be achieved through screw connection.

At this time, it is preferable that the bolt for the reinforcing filler member be formed so that the total length of the male screw portion that is combined with the female screw portion of the support is the same as the total length of the support, and that a conventional head such as a hexagon or octagon is integrally formed on the outer end, and the material is preferably carbon steel, particularly high-strength steel.

As another embodiment of the above-mentioned bolt-shaped reinforcing filler member, a metal rod having a circular cross-section and an outer diameter matching the inner diameter of the support member may be inserted into the inside of the support member without the need for threading the inner surface of the support member, and the two members may be fixed by welding.

Meanwhile, it is preferable that the fixing plate in which the guide cap support insertion hole is formed has a flat surface, and that the insertion groove formed inside the wall of the cylindrical body portion is formed so that the upper part of the existing support can be fitted into the inside in a close state while making surface contact all around. In addition, it is more preferable that the guide cap coupled to the support is welded at the coupling end so that the support and the guide cap are maintained in a fixed state.

When the reinforcing filler member described above is connected to the prop of the prop head by means of screw connection or the like and the prop is inserted through the prop insertion hole of the guide cap connected to the upper part of the support, the lower surface of the stop key catch provided on the upper part of the prop and the upper surface of the settling plate come into surface-to-surface contact with each other, and a close connection is formed with almost no surface contact or gap between the outer surface of the prop of the prop head inserted through the prop insertion hole and the inner surface of the body of the guide cap.

As the connection between the prop head and the support is made more closely and firmly in this way, the probability of the prop head coming off from the connection with the support is reduced when the top of the support to which the prop head is connected is tilted toward the ground in order to dismantle the prop head after the slab concrete has cured, and even if it does come off, it will be closer to the ground, that is, even if it comes off and hits the ground, the impact will be less.

In addition, since the prop head of the present invention has a relatively high risk of damage or breakage when it protrudes and collides with the ground, the rigidity of the support member is increased by combining it with a reinforcing filler member, so that even if it collides with the ground, the risk of damage or breakage is reduced.

In the present invention, since the connection between the prop head and the support is more closely and firmly formed, the probability of the prop head detaching from the connection portion with the support is reduced during the process of tilting the upper end of the support to which the prop head is coupled toward the ground in order to dismantle the prop head after curing of slab concrete, and even if it detaches, it is closer to the ground, that is, even if it detaches and hits the ground, the impact is reduced.

In addition, since the prop head of the present invention has a relatively high risk of damage or breakage when it protrudes and collides with the ground, the rigidity of the support member is increased by combining it with a reinforcing filler member, so that even if it collides with the ground, the risk of damage or breakage is reduced.

Figure 1 is a structural drawing of an architectural formwork panel assembly applied to a conventional drop construction method.
Figure 2 is a perspective view prior to joining a prop head and a reinforcing filler member according to one embodiment of the present invention.
Figure 3 is a partial cross-sectional front view of the combined state of a prop head and a reinforcing filler member according to one embodiment of the present invention.
Figures 4 (a) and (b) show a guide cap according to one embodiment of the present invention.
(A) is a longitudinal cross-sectional view,
(I) am a flat surface.
Figure 5 is a partial cross-sectional front view of the combined state of the prop head and support according to the present invention.
Figures 6 (a) and (b) show reinforcing filler members of other embodiments according to the present invention.
(A) is a front view of the reinforcing filler member,
(I) is a partial cross-sectional front view of the reinforcing filler member attached to the prop head.

The above-described purpose of the present invention, the specific configuration of the device, and the unique features of the slab drop construction process using the device will be understood in more detail through a detailed description with reference to the drawings below.

First, FIG. 2 is a perspective view before joining a prop head and a reinforcing filler member according to an embodiment of the present invention, and FIG. 3 is a partial cross-sectional front view of the joined state of a prop head and a reinforcing filler member according to an embodiment of the present invention.

As shown in Fig. 2, the prop head (10) is formed with a square-sectioned stop key mounting portion (12), a stop key step portion (13), and a support (14) extending downward from the bottom surface of the main body (11). The support (14) is a hollow pipe with a circular cross-section and has a female screw (14a) formed on its inner surface.

Meanwhile, the reinforcing filler (15) is formed integrally with a body part having a screw portion (15a) formed in a conventional bolt shape and a rectangular head part such as a hexagon or octagon.

As shown in Fig. 3, the above reinforcing filler (15) is screw-connected to the support (14) of the prop head (10) through a screw connection. By connecting the support (14) and the reinforcing filler (15) in this way, the support (14) in the hollow pipe state before connection takes on a kind of circular cross-section in which the hollow part is filled with the reinforcing filler (15) made of a metal material.

At this time, it is desirable that the outer diameter of the head of the reinforcing filler (15) be the same as the size of the outer diameter of the inclined lower part of the support (14).

Next, Figs. 4(a) and (b) are cross-sectional views and plan views showing a guide cap according to an embodiment of the present invention. As shown, the guide cap (20) is provided with a fixing plate (22) formed of a flat surface with a support insertion hole (21) formed in the center at the top thereof, and a circular insertion groove (24) for insertion into a support is formed inside the wall of the cylindrical body portion (23) below it.

Next, Fig. 5 is a partial cross-sectional front view of the combined state of the prop head and the support according to the present invention, in which the prop head (10) to which the bolt-shaped reinforcing filler member (15) is combined is inserted through the prop insertion hole (21) of the guide cap (20) into the upper end of the support (30), and the prop head (10) is vertically supported by the support (30).

As described above, when the reinforcing filler (15) is screw-connected to the support (14) of the prop head (10) and the support is inserted through the support insertion hole (21) of the guide cap (20) coupled to the upper end of the support (30), the lower surface of the stop key catch (13) provided on the upper end of the support (14) and the upper surface of the settling plate (22) come into surface-to-surface contact with each other, and a close connection is formed with almost no surface contact or gap between the outer surface of the support (14) of the prop head inserted through the support insertion hole (21) and the inner surface of the body of the guide cap (20).

Meanwhile, (a) and (b) of Fig. 6 show reinforcing filler members of other embodiments according to the present invention, wherein (a) is a front view of the reinforcing filler member, and (b) is a partial cross-sectional front view of the reinforcing filler member coupled to the prop head. As illustrated, the reinforcing filler member (15') of the embodiment is a rod having a circular cross-section in which no screw portion is formed on the body, and a body having such a flat surface is inserted into a support (14), and a welding portion (wp) is formed at the contact portion between the lower end of the support and the reinforcing filler member (15') so that the combined state is fixed. Unexplained reference numeral 31 is a stopper.

As such, in the present invention, since the connection between the prop head (10) and the support (30) is more closely and firmly formed, the probability of the prop head detaching from the connection with the support during the process of tilting the upper end of the support to which the prop head is coupled toward the ground for dismantling the prop head after curing of the slab concrete is reduced, and even if it detaches, it is closer to the ground, that is, even if it detaches and hits the ground, the impact is reduced.

In addition, since the prop head of the present invention has a relatively high risk of damage or breakage when it protrudes and collides with the ground, the rigidity of the support member is increased by combining it with a reinforcing filler member, so that even if it collides with the ground, the risk of damage or breakage is reduced.

10: Prophead 14. Landlord
15. Reinforcing filler 20. Guide cap
21. Landlord insertion hole 22. Settling plate
24. Insert Home 30. Support

Claims (5)

In a panel support device for slab construction of a building, in which a slab panel beam is installed with an outer end supported by a soffit length located at the top of a wall panel, and a prop head is connected to the top of a support erected vertically from the floor at the connection portion of the slab panel beam, so that the slab panel beam is connected and supported, the prop head includes a reinforcing filler member connected to the inside of a hollow support that protrudes and extends from the bottom surface of the main body and is connected to the top of the support, and a guide cap formed integrally with a body having a support insertion hole formed in the center of the upper surface of a square plate in which the support is inserted while making surface contact, and an insertion groove formed so that the upper end of the support is fitted in a close state while making surface contact all around the entire circumference, wherein,
The above reinforcing filler member is made of carbon steel and is formed with a length and cross section that can fill the entire hollow space of the support, and a hexagonal or octagonal head is integrally formed at the end protruding outward from the support. This is a panel support device for building slab construction. A panel support device for slab construction of a building, characterized in that in the first paragraph, a female screw portion is formed on the inner surface of the support, and a male screw portion is formed on the outer surface of the body of the reinforcing filler member, so that the support and the reinforcing filler member are connected by screw connection. A panel support device for slab construction of a building, characterized in that in the first paragraph, the reinforcing filler member is fixed by welding at a contact point with the lower end of the support while the body portion having a flat cylindrical outer surface is inserted into the inside of the support. A panel support device for slab construction of a building, characterized in that in the first paragraph, the guide cap is welded between the lower part of the body and the outer peripheral surface of the adjacent support while being connected to the upper part of the support.



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