KR20040064083A - Formwork supporting apparatus for hanging type formwork system and formwork using the same - Google Patents

Abstract

PURPOSE: A holder of a suspended type mold and a mold assembly thereof are provided to reduce the construction time effectively. CONSTITUTION: A body portion(10) has a yoke combination portion(15) and a joist serration groove(12). The yoke combination portion combines with a yoke member(100) to support a mold to be separatable. The joist serration groove inserts and settles a joist member(250) for supporting the mold. A suspension member combination portion(20) fixes the body portion by combining with a suspension member(H) to be fixed in an upper structure.

Description

Suspended formwork and formwork {Formwork supporting apparatus for hanging type formwork system and formwork using the same}

The present invention relates to a formwork support and a formwork assembly using the same, which is used in the reverse casting method, and more particularly, it is used in the suspension type non-inverted reverse casting method of forming a structure by using a suspension formwork to break the construction period. It relates to a formwork support which can be shortened and a formwork assembly using the same.

Recently, as the economic growth, the demand for buildings is increasing and land prices are continuously increasing. As a result, office buildings that are constructed in urban areas with high land prices have tended to increase the height of buildings in order to efficiently use the land.

On the other hand, when constructing a structure underground, the conventional method, first to excavate the underground soil or rock to the depth necessary for the formation of the underground structure, and to prevent the collapse of the excavation surface supporting earth wall (strut strut) or earth anchor ( After the excavation was completed by installing an earth anchor, etc., it was made according to the method of constructing structures of basement and ground layers from the foundation in order. However, according to this conventional method, the construction and dismantling of temporary construction takes considerable cost and time, and if the construction is inadequate, a large accident may occur due to the collapse of the earth retaining wall. There has been a problem of lengthening.

Accordingly, the conventional method for constructing a structure as described above has been developed and applied to build an underground structure from the ground to the ground and to build a ground structure in parallel. The reverse casting method is also called top down method or downward construction method. Instead of digging the ground first to the required depth of the basement, the steel column is pre-installed and the slab and column molds are installed based on the pre-installed steel columns to install the ground layer. It is a construction method to build a basement structure from below. According to the reverse casting method, the ground is not excavated at the same time as the required depth, so the risk of collapse caused by underground excavation can be reduced, and the construction of the ground layer can be performed simultaneously with the construction of the underground construction. It is true that it works.

In the reverse casting method as described above, the method of placing concrete structures such as slabs or beams on the ground in the state of stopping the ground and the method of digging the ground, picking the ground, setting up the clubs and installing the formwork, and then placing the concrete It is used. However, in accordance with these methods, in order to start the excavation work of the lower layer after placing concrete, it is necessary to wait until the structure develops its strength through sufficient curing period, which inevitably occurs. In addition, in order to excavate the ground of the lower part of the structure, the formwork and the copper barge were dismantled and moved to the upper floor so as not to interfere with the work of gulting, and the gulting work was carried out, which was cumbersome and difficult in terms of air and cost.

Therefore, in order to solve the above problems, a suspension member such as strand wire or rock bolt is fixed to the upper layer structure, the slab formwork modularized thereto is suspended and supported, and then the concrete frame is placed on the formwork. After the excavation work of the lower layer, the suspended supporting form is placed in a manner of repeatedly descending the suspended supporting form as it is to proceed with the lower layer process, and has been filed by the present inventors. Can be found in Republic of Korea Patent Publication No. 96-34595 or Republic of Korea Patent Registration No. 10-0261775.

Unlike the ordinary reverse casting method, the suspension type reversal method is a method of performing a reverse casting process using a suspension formwork without using a prop, that is, a slab supporting copper bar, and when using this method, a temporary copper bar is used. By not doing so, the construction work is simplified and the cost is reduced, and when applying the normal reversal method, when the work of the floor is performed, no digging work can be performed under the floor. Even during the curing curing period, it is possible to promote the excavation work under the formwork, which has the advantage of shortening the construction period.

In addition, the method is to produce a modular formwork regularly and after finishing the pouring of one floor to use it as it is to form a downstairs of the lower floor, it also appears that the cost and time can be reduced according to the installation of the formwork.

The construction of the structure by applying the suspension type unsupported reverse casting method as described above can promote the excavation work of the subsequent lower layer while the slab concrete is poured and cured, which can shorten the overall construction period and reduce the formwork of the upper layer. As it is lowered and used for the lower floor, it is true that there is no need to manufacture a formwork separately, thus saving the cost and time required for construction work to some extent. However, as a result of practical application of the above method, it was found that the effect of shortening the air and reducing the cost was not as expected as expected due to the technical limitations inherent in the above method, which has been verified by various construction examples.

In other words, after the concrete is laid to form the concrete structure, the form survival period is required to maintain the formwork for a considerable period of time until there is sufficient strength to withstand the weight of the cured concrete and the load applied during construction. In the case of some difference depending on the outside temperature and the type of cement used, but usually about 7 to 8 days (approximately two-thirds of the design reference strength) under the temperature of 10 ℃ or more.

Therefore, it will be possible to demold and lower the formwork and install it at the position where the lower layer will be formed after approximately 8 days after the concrete is laid, but the above period means only the period during which the formwork can be demolded, Any form of loading, including reinforcement and concrete placement, is unacceptable for the safety of the concrete structure being cured. There was no choice but to wait for the process, which inevitably caused a process delay.

As a result, due to the limitations of the suspension formwork system above, the existing suspension formwork method required at least one month of construction period per floor, and a large part of this period was the waiting time for subsequent work until the upper floor concrete was cured. This is a period of time that needs to be improved.

On the other hand, in the conventional suspension formwork system, the H-shaped steel is used in forming the formwork, such that the H-shaped steel is not only a relatively expensive material but also has a considerable unit weight, thereby increasing the weight of the entire formwork. . In addition, when forming a formwork using such H-shaped steel, the H-shaped steel should be cut to the necessary dimensions and used only for the formwork. This H-shaped steel is used only for other purposes after its use as a formwork. Because of the extremely limited use of materials, there have been disadvantages in terms of versatility and economy of materials.

The present invention is to improve the conventional suspended solid-free formwork as described above, demoulding only after the minimum period of the form of the formwork to enable the formwork and concrete pouring of the next floor immediately, which is required for the basement floor compared to the existing construction method It is a technical object to provide a suspension formwork support and formwork assembly using the same that can significantly shorten the period.

In addition, the present invention is not easy to use the H-shaped steel in forming the formwork as in the prior art by using a light steel frame and reinforce it with a truss to reduce the weight of the overall formwork and at the same time easy to construct by using a material having universality and utility And another object of the present invention is to provide a suspension form assembly having excellent economic efficiency.

1 is a perspective view showing a preferred embodiment of the suspension formwork support according to the present invention.

Figure 2 is a plan view showing the configuration of the suspension formwork assembly according to the present invention and a side cross-sectional view thereof.

Figure 3 is a detailed cross-sectional view showing a coupling state of the hanging formwork support and the formwork of the present invention.

Figure 4 is a perspective view showing the configuration of a sleeve used in the present invention.

5a to 5f are diagrams sequentially illustrating the construction and demolding process of the suspension formwork assembly of the present invention.

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

1: Suspended formwork 10: Body

12: Jangsun Home 15: yoke coupling

15 ': coupling pin hole 20: suspension reengagement

30: coupling pin 32: drilling hole

35: spring 38: strap

40: separation rod 100: yoke member

200: joist member 250: joist joist member

300: slab formwork panel 350: honorable formwork panel

400: sleeve C: concrete

H: Suspension member H ': Turnbuckle

T: Truss B: Brace

In order to achieve the technical object as described above, the present invention is a suspension formwork support used in the top down method, the yoke coupling portion is formed on the lower side so that the yoke member can be detachably coupled to the formwork support; The body portion is formed with a joist support groove so that the formwork support joist member is inserted, mounted on the side; And a suspension reassembling unit attached to the body to suspend and secure the body by hanging with the suspension member fixed to the upper layer structure.

In another aspect, the present invention is a slab formwork assembly used in the suspension back-pouring method, having a configuration as described above and a plurality of suspended formwork support coupled to the suspension member fixed to the upper layer structure; and the lower formwork support A yoke member detachably coupled to the side; and a joist member provided at an upper portion of the yoke member at predetermined intervals; and a joist joist member inserted into a joist holding groove formed at an upper portion of the suspension formwork support; And a slab formwork panel installed on the joist member and the survivor joist member.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention by the preferred embodiment according to the present invention.

1 is a perspective view of a preferred embodiment of the suspended formwork support according to the present invention with reference to the drawings, the suspension formwork support according to the invention is suspended on the body portion 10 around the body portion 10 as a whole; It is configured by laying the recombination portion 20, the yoke coupling portion 15 is formed on the lower side of the body portion 10 so that the formwork yoke member 100 can be detachably coupled, the upper side is It can be seen that the housing support member 12 is formed so that the formwork supporting joist member 250 can be inserted and mounted.

In addition, according to the preferred embodiment the yoke member 100 and the yoke coupling portion 15 is coupled in a pin fixing manner using a coupling pin 30, the coupling pin 30 is the head portion on one side The formed pin is provided with a compression spring 35 at the head side and a drilling hole 32 is formed at the other end thereof to be fixed by inserting a separation rod 40 having a predetermined length in the drilling hole 32. In addition, it can be seen that the coupling state can be released due to the elasticity of the compression spring 35 by pulling the separation rod 40 from the upper side, which is also a feature of the present invention as a preferred configuration.

First, the body portion 10 is to be the main body of the suspension formwork support (1) of the present invention, the suspension recombination portion 20 to be described later is integrally attached to the suspension member (H) is fixed to the upper layer structure (H) Hanging and fixed by the combination with) serves to support the entire formwork.

The material of the body portion 10 is required to have a sufficient strength to be suitable for the role of the formwork support, such material may be considered a metal or synthetic resin. In particular, in the present embodiment, the steel plate is used to be inverted U-shaped by bending the steel plate, the yoke coupling portion 15 to be described later by allowing the yoke member for the form support to be fitted to the open portion thereof downwards I can play a role as).

Yoke coupling portion 15 is formed on the lower side of the body portion so that the mold support yoke member 100 can be coupled. The yoke member 100 is a member constituting the support frame of the suspension-type formwork to be the object of the present invention with the joist members 200 and 250 installed to be orthogonal to the upper portion of the yoke member 100 of the body portion 10 The yoke coupling portion 15 formed in the lower portion is coupled to the body portion 10 as a medium so that the entire formwork can be suspended. The yoke member 100 is coupled to the yoke coupling portion 15 so as to be detachable, whereby after the concrete is poured, the yoke member 100 is separated from the yoke coupling portion 15 by the suspension type of the present invention. The formwork support (1) and the remaining joist member 250 installed on the upper portion and the slab formwork side plate supported by it is to be able to lower the rest of the entire formwork.

The coupling of the yoke member 100 and the yoke coupling portion 15 is to be able to release the coupling after a predetermined period of time after the concrete is placed. Examples of such a coupling method is the coupling and locking projections by bolts and nuts. In this embodiment, but the fitting can be used, but in this embodiment, a pin fixing method by the coupling pin 30 is proposed as a preferred configuration for the convenience of operation.

In this embodiment, as a more preferable configuration, the coupling pin 30 is provided with a head portion at one side, and a compression spring 35 is installed at the head portion, and at the same time, a drilling hole 32 is formed at the other end. Adopting a coupling pin, the function and action of the coupling pin 30 configured as described above will be described in more detail later, but when described roughly, the coupling pin 30 is formed on the side of the yoke coupling portion 15 When the insertion pin is inserted into the hole 15 'and the separation rod 40, which is a separate member, is inserted into the drilling hole 32, the coupling pin 30 is fixed while the compression spring 35 is compressed. Then, when the separation rod 40 is drawn out, the coupling pin 30 is bounced out by the elastic force of the compression spring 35, thereby releasing the coupling. At this time, in order to prevent the loss of the coupling pin 30, the body portion 10 and the coupling pin 30 is preferably connected to each other using a connecting strap 38.

In addition, on the upper side of the body portion 10 is a joist holding groove 12 is formed so that the formwork supporting joist member 250 is inserted, mounted. The suspension formwork supported by the suspension formwork support of the present invention is made by placing the yoke members in parallel at predetermined intervals and installing the joist members at predetermined intervals at right angles thereon, and then installing the formwork panels thereon. Of these, the yoke member is fixed to the yoke coupling portion 15 formed in the body portion 10, so that the entire formwork is suspended and supported as described above. In addition, the upper part of the coupled yoke member 100 is provided with a joist member (200, 250), some of them are installed to be inserted into the jogger mounting groove (12).

The joist holding groove 12 is formed in the upper portion of the body portion 10 so that the formwork joist member 250 can be inserted from the top and the depth is formed up to the height of the upper surface of the yoke member 100 coupled approximately It is desirable to be able to be used uniformly with other joist members. In addition, the number of the Jangsun holding grooves 12 may be determined as necessary, but it will be safe to form two symmetrically on both sides of the body portion 10 as in this embodiment.

As described above, by constructing a suspension formwork using the suspension formwork support (1) according to the present invention and placing concrete therein, the yoke member (100) is separated from the yoke coupling portion (15) during demolding thereof. As a result, the entire formwork including the yoke member, the joist member and the formwork panel is separated from the formwork support of the present invention and lowered to form a die. At this time, the joist members 250 mounted on the jogger mounting groove 12 and the formwork panel installed on the upper part are supported by the formwork support of the present invention despite the lowering of the formwork to maintain the installed state as it is. They continue to exist until the full design reference strength is developed to support the slab structure from below.

In addition, the body portion 10 is provided with a suspension recombination unit 20 to be coupled to the suspension member (H) fixed to the upper layer structure. That is, the suspension support (H) is coupled to the suspension recombination unit 20, the formwork support of the present invention is supported by hanging on the upper layer structure and also the yoke coupling portion 15 and the yoke member of the formwork (formed in the formwork support) By the coupling between the 100, the entire hanging formwork can be suspended.

At this time, the suspending member (H) in the present invention may be used a stranded wire (thread wire) or a threaded rod (threaded rod) formed on the outer surface, preferably in terms of ease of coupling and joints, etc. Screw rods are suitable.

Such a suspension recombination unit 20 is a form that can be integrated with the suspension member (H) is possible in a variety of structures, as an example of this long long nut in the present embodiment in the upper portion of the body portion 10 It was supposed to install by welding. In other words, when the long nut is used as described above, when the hanging member is a screw rod, it can be easily coupled by screwing, and even when a strand wire is used as the hanging member, an adapter having a threaded portion at its end is provided. You can connect and facilitate the coupling via this.

On the other hand, in applying the reverse casting method using the suspension formwork, when the construction of the floor is completed, the formwork is lowered to the construction position of the lower floor, and at the same time, the fixed slab is fixed to the completed slab and the hanging member is fixed thereto. It shall be able to support the weight of fixed formwork, the weight of concrete to be poured and the working load. However, there is a problem that the work of removing and reinstalling these anchorages is very cumbersome every time the formwork is laid down.

Therefore, in the present invention, in supporting the hanging formwork, a separate support is provided and the formwork is supported by using the formwork, so that the support as the preferred configuration of the present invention performs the role of the anchorage as well. The effort and cost of collecting and reinstalling the anchorage can be saved. That is, as can be seen in Figure 1 in the preferred embodiment of the present invention by suspending the suspension recombination unit 20 by laying a member bent threaded on the inner peripheral surface as a hollow member on the upper portion of the inverted U-shaped body portion 10 The bar member is connected to the formwork installed downstairs so that it can be coupled from the lower portion of the suspension recombination unit, it does not require a separate anchorage for fixing the suspension member.

Next, a formwork assembly assembled using a suspension formwork support according to the present invention will be described with reference to the accompanying drawings.

Figure 2 is a planar layout and side cross-sectional view showing the assembled state of the formwork assembly using the suspension formwork support according to the present invention and Figure 3 is a coupling detail of the suspension formwork support and formwork of the present invention. One drawing.

Referring to FIG. 2, the suspension formwork assembly of the present invention includes a plurality of suspension formwork supports 1 and lower portions of the suspension formwork support 1 installed coupled to a suspension member fixed to an upper layer structure. The yoke member 100 and the yoke member 100 installed at an upper portion of the yoke member 100 and the suspending mold support 1 formed at an upper portion of the suspension formwork support 1 are detachably coupled to the yoke member 100. It can be seen that it is a formwork assembly comprising a slab formwork panel 300 installed on the top of the joist member 250 and the joist member 200 and the joist member 250 for the installed. At this time, in the planar layout of FIG. 2, the illustration of the slab formwork panel is omitted in order to more clearly show its configuration.

As shown in the figure, the suspension formwork assembly of the present invention receives a construction load such as the weight of the formwork and the weight of the concrete and is a horizontal member that is transferred to the suspension member through the suspension formwork support 1 as described above. The members 100 are installed parallel to each other at regular intervals and orthogonally placed thereon, and then the slab panels 300 are formed thereon. Here, the joist members 200 and 250 are inserted into the joist member grooves formed in the upper part of the general joist member 200 and the suspension formwork support 1 installed on the yoke member 100 to form a mold. Even after demolding, it is divided into a staying joist member 250 that remains for a certain period of time.

When the suspension formwork is formed as described above it is coupled to the plurality of suspension formwork support connected to the suspension member to be supported by the hanging member. At this time, the arrangement of the suspension formwork supports 1 is preferably located at the bottom of the beam and at the center and four vertices of the slab portion as shown in Fig. 2, in particular near the four vertices. It is preferable to connect the elevator to the installed suspension formwork support to be responsible for the lowering of the formwork when demolding.

The combined state of the formwork and the suspension formwork support as described above is shown in detail in FIG. As shown in Figure 3, the coupling is a suspension formwork support (1) to the suspension member (H) is fixed to the upper layer is connected through the suspension recombination unit 20 and the yoke member 100 is coupled to the yoke and yoke The joist member 250 is installed on the upper portion of the member 100, and the joist member 250 is formed by being supported by a joist mounting groove formed on the suspension formwork support 1. Figure 3 shows the case of using a screw rod as a suspension member, it is preferable that such a suspension member is not to be embedded in the concrete even after the concrete is placed to facilitate disassembly and reuse, the suspension member (H) and the separation rod for this purpose The sleeve 400 is installed to protect the periphery of the 40. In addition, the sleeve 400 is composed of a conical hollow body 410 and the lower cap 420 as shown in detail in Figure 4 so that after the hardening of concrete can be easily separated to the lower side to be reused in the lower layer. This is preferred.

In addition, FIG. 3 illustrates a case in which a pin fixing method is used as a coupling method of the yoke member 100 and the suspension formwork support 1, and springs in the head as a preferable configuration to facilitate subsequent demolding. Coupling pins 30 with 35 are adopted.

In addition, a perforation hole is formed at the end of the coupling pin 30 to insert a member such as the separation rod 40 into the drilling hole so that the coupling pin 30 can be fixed and remove the spring ( The coupling pin 30 is separated by the elasticity of 35. This separation rod may be pulled out from the bottom of the formwork, but as shown, by lengthening the length of the separation rod 40 long enough to rise above the planned surface of the slab concrete, and pulled it from the top when demolding the formwork It is more desirable to be able to demould in a simple and safe form.

On the other hand, in general, the suspension formwork assembly is the case of using the H-shaped steel as the yoke and joist member, but in this case the weight of the formwork is heavy, so in this embodiment, the yoke and joist member of the lightweight steel member The total weight was reduced by using a truss (T) at a predetermined interval in the lower part of the formwork to reinforce the rigidity of the formwork without significantly increasing the weight of the entire formwork. In addition, as the truss, for example, the inventors of the present invention reveals that it can also be configured using a prefabricated lightweight truss filed in Korean Patent Application No. 2002-0074537.

In addition, it is preferable to reinforce using a brace B so that the truss T can be firmly fixed in the formwork, and the brace B can be fixed on both sides of the truss T using a variable brace. To the truss so that the truss can be securely fixed. By reinforcing the truss using the brace B in this way, it is possible to achieve the effect of reducing the required amount of the truss member.

Next, the process from the construction of the formwork assembly to demolding using the suspension formwork support of the present invention will be described according to the accompanying drawings, FIGS. 5A to 5H. In this case, the drawings are omitted in advance, and the scale of each member is enlarged and shown in advance so that the present invention can be easily understood.

First, as shown in FIG. 5A, the formwork is suspended by connecting the suspension formwork support 1 to the suspension member H fixed to the ground layer upper layer or the upper layer structure, and fastening the yoke member 100 of the formwork thereto. To be installed. At this time, fastening of the formwork support 1 and the yoke member 100 is using a pin fixing method provided with a spring as the most preferable configuration as described above.

Next, as shown in FIG. 5B, the joist members 250 are installed in the joist grooves provided in the upper part of the suspension formwork support 1. At this time, the formwork support in which the dovetail member is not installed in FIG. 5b corresponds to the formwork support installed at the four vertices of the slab formwork in the plan view of FIG. 3, and these are connected to a hydraulic elevator when demolding the formwork. Suspending formwork will be supported.

Subsequently, the slab formwork panels 300 and 350 are installed on the formwork frame including the yoke member and the joist member. In addition, the suspending member H and the separating rod 40 are placed on top of the formwork panels 300 and 350 so as to prevent them from being buried at the time of concrete pouring (see Fig. 5C).

When the above process is completed, the formwork installation work is completed and the concrete is poured on top of the completed formwork. After the concrete is placed, the form is held during the form's existence, until two-thirds of the design baseline strength is developed (usually about one week). When the period of time passes, the mold is demolded, and as shown in FIG. 5D, when the separation rod 40 is pulled out from the upper portion of the slab, the coupling pin 30 is formed due to the elasticity of the spring provided in the coupling pin 30. The bouncing out is the same as described above.

When the coupling pin is separated as described above, the formwork is suspended down to the construction position of the lower layer as shown in FIG. At this time, as the above-described formwork support is separated from the coupling pin is released from the formwork, the formwork will remain intact as it does not fall even when the formwork is lowered. In addition, the retaining joist member 250 mounted on the upper part thereof also remains fixed with the retaining formwork panel 350 installed on the upper part thereof, and the remaining curing period during which the overall design reference strength is expressed (28 days after pouring) Support slab structure.

As described above, when the hanging formwork is demolded and descended to install at the construction position of the subsequent lower floor, the installation work of the subsequent formwork is started. That is, a new suspension formwork support is combined and installed in a partly empty part due to the formwork panel, etc., which is retained in the upper layer structure, and newly installed formwork member 250 and slab formwork panel 350 are newly installed. Connect the suspension member (H) to the support. Wherein the suspension member (H) is fixed to the lower portion of the formwork retained in the upper layer as shown, wherein the suspension member in the middle so that the length can be adjusted using a member such as a turn buckle (H '; turn buckle) It is possible to tension the suspension member by connecting and tightening the turnbuckle (see Fig. 5f).

When all of the above work is completed and the formwork is installed, the reinforcement work and the casting of concrete can be performed immediately below, resulting in the unique technical effect of the present invention. That is, under the conventional suspension formwork system, in order to promote the reinforcement and concrete placing work of the lower floor, the entire curing period should be 28 days in addition to the existence period of the formwork, but according to the present invention, the suspension member supporting the formwork of the lower floor is fixed. Since the formwork remains intact in the lower part of the part, it does not need to wait for the subsequent work until the overall design strength is developed, thereby significantly reducing the overall construction period.

Although the present invention has been described in detail only by the embodiments described, it will be apparent to those skilled in the art that various modifications and changes are possible within the scope of the technical idea of the present invention, and such modifications and modifications belong to the appended claims. .

According to the present invention as described above, it is possible to embark on the formwork and concrete pouring work of the next floor by demoulding only after the minimum period of retention of the formwork, so it is possible to drastically shorten the construction period required for the basement floor compared to the existing construction method. Has the effect. In addition, the present invention is to form a formwork using a light steel frame instead of the H-shaped steel commonly used in the prior art and to reduce the weight of the entire formwork by reinforcing the lower part of the formwork with a truss, and the light steel member and the truss for other uses The use of a universal member that can be used as a furnace has the effect of providing a form assembly having excellent material utilization and economic efficiency.

Claims (15)

As the formwork support used for the suspension type reversing method, A yoke coupling portion is formed on the lower side to allow the yoke member to be detachably coupled to the yoke member, and an upper portion of the body portion is formed on the upper side so as to be inserted and mounted on the die supporting joist member; And, Suspension recombination unit is attached to the body portion to be suspended and fixed to the body portion by engaging with a suspension member fixed to the upper layer structure; Suspended formwork supports, including. The suspension formwork support of claim 1, wherein the yoke member and the yoke coupling portion are coupled in a pin fixing manner using a coupling pin. According to claim 2, wherein the coupling pin is a pin with a head portion on one side is provided with a compression spring on the head portion side and the other end is formed with a hole Suspended formwork support is fixed by inserting the separation rod having a predetermined length in the drilling hole, the engagement state is released due to the elasticity of the compression spring by pulling and separating the separation rod. 4. The suspension formwork support of claim 3, wherein the separation rod has a length sufficient to be exposed to the upper portion of the slab concrete placing surface so that the separation rod can be pulled apart from the upper portion of the slab. The suspension formwork support of claim 2 or 3, wherein the coupling pin is connected to the body portion by a connection string. The suspension formwork support according to claim 1, wherein the suspension recombination portion is a hollow member having a female thread cut on an inner surface thereof so that the lower layer slab formwork suspension member can be coupled from the lower side. Slab formwork assembly used in suspension reversal method, Suspended formwork support according to any one of claims 1 to 6 installed coupled to the suspension member fixed to the upper layer structure; A yoke member detachably coupled to a lower side of the suspension formwork support; A joist member installed on the yoke member at predetermined intervals; A joist joist member installed and inserted into a joist hold groove formed at an upper portion of the suspension formwork support; And A slab formwork panel installed above the joist member and the joist joist member; Suspended formwork assembly using a suspension formwork support comprising a. 10. The suspension formwork assembly using the suspension formwork support according to claim 7, wherein a conical sleeve surrounding the suspension member is additionally installed so that the suspension member does not come into contact with the concrete. 10. The suspension formwork assembly of claim 8, wherein the sleeve comprises a conical hollow body and a lower cap. 10. The suspension formwork assembly using the suspension formwork support of claim 7, wherein the yoke member, the joist member and the joist joist member are made of lightweight steel frame members. The suspension formwork assembly using the suspension formwork support, characterized in that the cross-sectional shape is Ω type in claim 10 The suspension formwork assembly using the suspension formwork support, characterized in that the lower portion of the yoke member is further provided with a truss at a predetermined interval. The suspension formwork assembly using the suspension formwork support according to any one of claims 8 to 11, characterized in that the lower portion of the yoke member is further provided with a truss at predetermined intervals. 13. The suspension formwork assembly using the suspension formwork support of claim 12, wherein a brace connecting them to each other is further provided between the truss and the yoke member. 14. The suspension formwork assembly using the suspension formwork support of claim 13, wherein braces connecting them to each other are further provided between the truss and the yoke member.