KR20220060495A - Under-tensioned formwork support structure and non-post construction method using the same - Google Patents

Abstract

The present invention can provide an under-tensioned formwork support structure and a non-post construction method using the same. The under-tensioned formwork support structure comprises: a central support which extends to a predetermined length; a variable support at both ends, one end of which is mounted on an end of the central support and the other end of which is variable in length in a longitudinal direction of the central support and mounted on a support structure; and a weighting means coupled to a lower part of the central support to apply prestress. According to the method, by introducing the prestress, deflection control and camber adjustment by the weight of the support structure, a concrete pouring pressure and the load of an RC member are possible, so that the installation of supports required during the construction of reinforced concrete beams can be omitted. In addition, variable response to a span length is possible and quick assembly, installation and disassembly works can be possible.

Description

UNDER-TENSIONED FORMWORK SUPPORT STRUCTURE AND NON-POST CONSTRUCTION METHOD USING THE SAME}

The present invention relates to an under-tensioned formwork support structure and a non-post construction method using the same, and more particularly, by introducing pre-stress, not only the self-weight of the support structure itself, but also control of deflection and camber control by the load of concrete placing pressure and RC member This makes it possible to omit the installation of copper bars for construction, to variably respond to the length of the span, and to an under-tension formwork support structure that enables quick assembly, installation and release of shuttering and a non-pole construction method using the same. .

In general, reinforced concrete structure is a structure in which reinforcement and concrete are integrated, and is a very common structure. The process of installing the formwork on the ship is necessarily accompanied by the process of installing the dongbari.

That is, in the construction of general reinforced concrete beams, copper bars are applied as temporary temporary structures to support the load from pouring concrete to the beam formwork until strength is developed after curing.

However, such a conventional dongbari is cumbersome to install and construct when used at the construction site, and the work space is inevitably very limited due to the already installed dongbari, and there is a risk of safety accidents due to the falling of the dongbari. It became one of the factors that lowered the construction efficiency throughout the work.

Accordingly, it is possible to omit the installation of copper bars at the construction site, secure work space and minimize the occurrence of safety accidents, and it is easy to construct and shortens the construction period so that it can function as a formwork for pouring concrete in the beam. There is a need for a new possible under-tensioned formwork support structure and a non-post construction method using the same.

In addition, when changing the length of the beam according to various construction environments, it is possible to respond to this, so it is possible to eliminate the hassle of additionally manufacturing and installing the formwork. there is a need

Korean Patent No. 10-1329383 (2013.11.14.)

In the present invention, by introducing the pre-stress, it is possible to control the deflection and camber adjustment by not only the self-weight of the support structure itself, but also the concrete pouring pressure and the load of the RC member, so that the installation of the rod for construction can be omitted and it can respond variably to the length of the span. An object of the present invention is to provide an under-tension formwork support structure capable of omitting the existing formwork installation and a non-post construction method using the same.

According to one aspect of the present invention, the present invention includes a central support formed extending to a predetermined length; One end is mounted on the end of the central support, the other end is variable in length along the longitudinal direction of the central support, both ends variable support mounted on the support structure; It is possible to provide an under-tension formwork support structure comprising a; pressing means coupled to the lower portion of the central support to apply pre-stress.

Here, the both ends of the variable support is inserted into the inner end of the central support in an insert manner, the length can be changed according to the sliding movement with respect to the central support.

In addition, the central support is formed in a closed type (tube type) shape, such as a ㅁ, ㅇ shape, in addition to a c, H shape, including a lower panel and a side panel in which the lower end is coupled to the upper surface of both ends of the lower panel, , The variable support at both ends is insert-mounted on the inside of the central support and is moved in a sliding manner in the longitudinal direction of the central support so that the length can be varied.

In this case, the variable support at both ends is hinged at the end of the central support and rotates in a folding manner with respect to the central support so that the length can be changed.

In addition, the central support is formed in a closed type (tube type) such as a ㅁ, ㅇ shape other than a C, H shape, including a lower panel and a side panel in which the lower end is coupled to the upper surface of both ends of the lower panel, The variable support at both ends, is rotatably coupled to the hinge part mounted to the end of the central support, is seated on the upper surface of the central support when folded, is configured to overlap, and extends in the longitudinal direction of the central support when unfolded It may include a folding member.

In addition, the both ends of the variable support is mounted in a scissor manner with respect to the central support, the length can be changed by moving forward and backward in the longitudinal direction of the central support.

Furthermore, the variable support at both ends, a plurality of link members configured in an X-shape, and a scissor link comprising a plurality of link members are hinge-coupled, and the scissor link, one end of which is coupled to the end of the central support, and the other The ends are coupled to the variable support at both ends and can be stretched back and forth in the longitudinal direction of the central support.

In addition, it further comprises a central form plate mounted on the upper surface of the central support and both ends of the form plate mounted on the upper surface of the variable support at both ends, and the central support and both ends are variable on the upper surface of the central form plate and the both ends of the form plate. It may further include a pair of side shutters that are arranged in parallel to the left and right along the longitudinal direction with respect to the support and are vertically mounted.

According to another aspect of the present invention, the present invention is a central support; One end is coupled to the end of the central support, the other end is a variable support at both ends having a variable length along the longitudinal direction of the central support; In the construction method of the under-tension formwork support structure comprising; a pressing means coupled to the lower part of the central support to give pre-stress, a) the central support and the upper surfaces of the both ends of the variable support, respectively, a central form plate and a form plate at both ends After installation, the steps of installing a pair of side shutters on the upper surfaces of the central form plate and both ends of the form play to configure an under-tension formwork support structure; b) mounting the undertension formwork support structure to the support structure; It is possible to provide a non-post construction method using an under-tensioned formwork support structure comprising; c) applying a pre-stress to any one of steps a) or b) through a pressing means.

On the other hand, since the description of the technology disclosed in this specification is merely an embodiment for structural or functional description, the scope of the disclosed technology should not be construed as being limited by the embodiment described in the text. That is, since the embodiment may have various changes and may have various forms, it should be understood that the scope of the disclosed technology includes equivalents capable of realizing the technical idea. In addition, since the object or effect presented in the disclosed technology does not mean that a specific embodiment should include all of them or only such effects, it should not be understood that the scope of the disclosed technology is limited thereby.

In addition, the meaning of the terms described in the present invention should be understood as follows. Terms such as “first” and “second” are for distinguishing one component from another, and the scope of rights should not be limited by these terms. For example, a first component may be termed a second component, and similarly a second component may be termed a first component.

Furthermore, when it is mentioned that a certain element is "connected" to another element, it may be directly connected to the other element, but it should be understood that other elements may exist in between. On the other hand, when it is mentioned that a certain element is "directly connected" to another element, it should be understood that the other element does not exist in the middle. On the other hand, other expressions describing the relationship between elements, that is, "between" and "between" or "neighboring to" and "directly adjacent to", etc., should be interpreted similarly.

The singular expression is to be understood to include the plural expression unless the context clearly dictates otherwise, and terms such as "comprises" or "have" refer to the specified feature, number, step, action, component, part or these It is intended to indicate that a combination exists, and it should be understood that it does not preclude the possibility of the existence or addition of one or more other features or numbers, steps, operations, components, parts, or combinations thereof.

The under tension formwork support structure and the non-post construction method using the same according to the present invention can provide the following effects.

First, by introducing the pre-stress, it is possible to control the deflection and camber by the load of the concrete pouring pressure and RC member as well as the self-weight of the support structure itself, so it is possible to omit the installation of copper bars during the construction of reinforced concrete beams, and the length of the span is variable. of course, it is possible to quickly assemble, install, and disassemble.

Second, in the construction of reinforced concrete girder (beam), the overall work of the formwork process can be simplified and construction efficiency can be increased, and when the construction technology is applied to the basement construction, it can be made into a construction method, thereby promoting technological scalability.

Third, the lower part of the girder (beam) can be used as a work space during concrete curing by omitting the copper bar, thereby increasing work efficiency and enabling safe construction.

Fourth, it is possible to reduce temporary construction, simplify the process, and shorten the period by omitting the necessary work related to Dongbari.

Fifth, in relation to the Dongbari temporary construction, independent temporary planning such as construction, dismantling, and exporting can be omitted, and separate material ordering and processing at the site can be omitted. there is.

1 is a perspective view illustrating a central support and both ends variable support on which a form plate of an under-tension formwork support structure is mounted according to an embodiment of the present invention.
2 is a perspective view showing a central support and both ends of the variable support in the under tension formwork support structure according to an embodiment of the present invention.
3 is a perspective view illustrating an embodiment in which a plurality of central supports and both ends variable supports are provided in the under tension formwork support structure according to another embodiment of the present invention.
4 is a view showing the operation of the variable support at both ends mounted in the insert method in the under tension formwork support structure according to an embodiment of the present invention.
5 is a view showing the operation of the variable support at both ends of the folding method in the under tension formwork support structure according to an embodiment of the present invention.
6 is a view showing the operation of the variable support at both ends of the scissor method in the under tension formwork support structure according to an embodiment of the present invention.
7A, 7B, and 7C are views illustrating a state in which side shutters are installed in the under-tensioned formwork support structure according to an embodiment of the present invention.
8 is a view showing a pressing means configured with a central fixing unit of the under tension formwork support structure according to an embodiment of the present invention.
9 is a view showing the concept of the installation and construction sequence of the under tension formwork support structure according to an embodiment of the present invention.

Hereinafter, it will be described in more detail with reference to preferred embodiments to which the present invention pertains.

First, the under tension formwork support structure according to the embodiment of the present invention may include a central support 100 , both ends variable supports 200c , 200b , 200c , and a pressing means 300 .

The central support 100 is configured in a preset length, and both ends of the central support 100 are equipped with variable supports 200c, 200b, and 200c at both ends, and the central support 100 and the upper portions of the variable supports 200a at both ends. A central form plate 130 and both end form plates 213, which will be described later, are mounted on the surface, respectively, to constitute an under-tension formwork support structure.

Here, the support structure may include a structure capable of supporting both ends of the variable supports 200c, 200b, 200c, such as a column, a column form, a girder, a girder form, and the like.

The central support 100, as shown in FIG. 2, preferably has a U-shape in the shape of the longitudinal section, but depending on the construction environment or purpose, it can be configured in various ways without limiting its shape, such as a U-shape, a U-shape, etc. there is.

The variable supports 200c, 200b, and 200c at both ends are mounted at one end to the end of the central support 100, and the other end of which is variable in length along the longitudinal direction of the central support 100 and mounted on the support structure. These both ends of the variable support (200c, 200b, 200c) is configured to be variable in its length can respond variably to a change in the length of the girder (beam) span.

In addition, the both ends of the variable support (200c, 200b, 200c) may be detachably coupled to the end of the central support (100). Here, the attachment and detachment method of the both ends variable support (200c, 200b, 200c) can be applied in various ways in response to the structure of the central support 100, and can be variously applied by an insert method, a folding method, a scissor method, etc. to be described later. , a detailed description thereof will be provided later.

This under-tensioned formwork support structure enables rapid assembly, installation, and dismantling of side shutters formed of plywood or steel (metal) on the upper part, thereby simplifying the overall work of the girder (beam) formwork process in reinforced concrete construction. Construction efficiency can be increased. In addition, due to the installation of the side shuttering 400, which will be described later, it is possible to omit a separate formwork installation work for pouring concrete in the field, thereby shortening the air period.

The both ends of the variable support 200a may be provided with a variable length so that the other end may be mounted on the support structure, and may further include an end binder (not shown) for more stable mounting and installation.

The pressing means 300 is coupled to the lower portion of the central support 100 to apply prestress, and controls the deflection of the central support 100 while concrete is poured and cured or serves to provide camber.

This pressing means 300 enables control of deflection and camber adjustment by the load of the girder and the concrete pouring pressure as well as the self-weight of the under-tension formwork support structure itself, thereby omitting the installation of copper bars, and through this It not only ensures structural safety, but also makes it possible to secure an efficient work space.

In detail, the pressing means 300 may include sag struts 310 , a tension member 320 , fixing units 330a and 330b , and a central fixing unit 340 .

The sag strut 310 may be coupled to the lower portion of the central support 100 to provide camber, and a plurality of sag struts are disposed to be spaced apart along the longitudinal direction of the central support 100 .

In the drawing, the sag strut 310 has a seating groove formed at the lower end so that the tension member 320 is inserted and seated, so that the tension member 320 can be easily installed.

The sag strut 310 shows that the tension member 320 is inserted and seated in the seating groove in the drawing, but in a preferred embodiment, a through hole through which the tension member 320 passes may be formed.

The tension member 320 is connected to the sag struts 310 and serves to impart prestress. The tension member 320 may be a known wire, but is not limited thereto.

The fixing units 330a, 330b, and 330c are coupled to the lower end of the central support 100 and fixed to the end of the tension member 320, so that the fixing units 330a, 330b of one side or the other side or the central fixing unit 330C) It serves to introduce a prestress to the tension member 320 in one of them.

Here, various configurations capable of adjusting the tension of the tension member 320 may be applied to the biasing part, which is one of the fixing part 330a on one side or the fixing part 330b on the other side.

The fixing units 330a and 330b are formed in a wedge shape as shown, and the tension member 320 may be formed to be horizontally or inclinedly fixed. The fixing parts 330a and 330b may have a through hole through which the tension member 320 is inserted, and a fastening binding part may be provided at an end of the tension member 320 penetrating the through hole.

On the other hand, as shown in FIG. 8, in the present invention, the central fixing unit 340 is additionally configured to the pressing means 300, and one end of the tension member 320 is fixedly coupled to the fixing units 330a and 330b. , the other end may be mounted on the central fixing unit 340 to give a pre-stress to the central support (100).

Referring to this, a central fixing unit 340 is configured at the lower end of the sag strut 310 configured in the central portion of the central support 100 among the plurality of sag struts 310 coupled to the lower portion of the central support 100 .

Here, both ends of the tension member 320 are mounted to the fixing units 330a and 330b and the central fixing unit 340, respectively. At this time, one end of the tension member 320 is fixedly coupled to the fixing units 330a and 330b, The other end of the tension member 320 penetrates the inlet of the central fixing unit 340 and is mounted to protrude to the exit, and the tension of the tension member 320 can be adjusted through a tension adjusting means separately configured in the central fixing unit 340. .

1, the present invention further includes a central form plate 130 and both end form plates 213 respectively installed on the upper surfaces of the central support 100 and the both ends of the variable supports 220a, 220b, 220c. can The central form plate 130 and both ends of the form plate 213 are formed in a plate shape with a plurality of perforations, and the side shutters 400 may be mounted on the upper surface.

On the other hand, in the present invention, as shown in FIG. 3 , it is possible to arrange a pair of central supports 100 arranged in parallel to the left and right. Although a pair of central supports 100 are illustrated in the drawings of the present invention, it is possible to configure and install two or more central supports 100 depending on the installation environment and construction purpose.

Hereinafter, various embodiments of the variable support at both ends 200a will be described with reference to FIGS. 4 to 7 .

4 shows the insert type variable support at both ends (200a).

Referring to the drawings, both ends of the variable support 200a may be inserted in an insert manner inside the end of the central support 100 , and the length may be changed according to sliding movement with respect to the central support 100 .

On the other hand, the central support 100, including the lower panel 110, and the lower end of the side panel 120 is coupled to the upper surface of both ends of the lower panel 110, the longitudinal cross-sectional shape to be formed in a 'C' shape. can

Accordingly, the variable support at both ends 200a is inserted and seated inside the central support 100 to slide and move, and in detail, it may be configured to include a pair of sliding panels 211 and a connection panel 212 .

The sliding panel 211 is inserted to face the side panel 120 of the central support 100 .

A plurality of connection panels 212 have both ends coupled to the inner surfaces of a pair of sliding panels and are spaced apart from each other in the longitudinal direction of the sliding panel 211 .

According to the above description, the insert type variable supports 200a at both ends have an insert panel structure, and the span can be adjusted according to the movement of the sliding panel 211 .

Figure 5 shows the both ends of the variable support (200b) of the folding method.

Referring to the drawings, both ends of the variable support 200b may be hinged to the central support 100 and rotate with respect to the central support 100 in a folding manner to change the length.

Here, the central support 100 may be configured to include a central form plate 130 in the form of a plate in which a plurality of perforations are formed.

Here, the both ends of the variable support 200b is a hinge portion 221 coupled to the end of the central support 100, and the hinge portion 221 is rotatably coupled to the upper surface of the central support 100 when folded. It is configured to be seated and overlapped and may include a folding member 222 extending in the longitudinal direction of the central form plate 130 when unfolded.

Referring to this, the both ends of the variable support 200b of the folding type can be adjusted in span by rotation of the hinge part 221, and the hinge part 221 and the folding member 222 are configured as one unit length. It is possible to expand the span control by providing a plurality according to the design.

6 shows the variable support at both ends of the scissor method (200c).

Referring to the drawings, both ends of the variable support 200c is coupled to the central support 100 in a scissor manner and is moved back and forth in the longitudinal direction of the central support 100 so that the length can be changed.

Here, both ends of the variable support 200c, one side is coupled to the end side of the central support 100, a plurality of link members 231 are configured in an 'X' shape, and the intersection point is a hinge 232 coupled to the center It may include a scissor link 230 that moves forward and backward in the longitudinal direction of the support 100 , and both end form plates 213 coupled to the other side of the scissor link 230 .

Next, FIGS. 7a, 7b, and 7c show the central support 100 and the both ends of the variable support 200a, 200b, and 200c respectively installed on the upper surface of the central form plate 130 and both ends of the form plate 213 on the upper surface of the central support. It may be configured to further include a pair of side shutters 400 spaced apart from one another on the basis of (100).

Accordingly, the side shutters 400 are formed in a vertical plate shape, and the lower portion of the side shutters 400 is perpendicular to the support grooves (not shown) formed in the central form plate 130 and both end form plates 213 . It is configured to be insertable.

In the present invention, in installing the side shuttering boards 400 on the central form plate 130 and both ends form plates 213, it is possible to construct the under-tension formwork support structure after transferring the under-tension formwork support structure to the construction site. Installation can be omitted. In addition, after varying the length of the both ends variable support (200c, 200b, 200c) at the construction site according to the construction environment and purpose, it is possible to install and use the side shutters 400 of the corresponding length.

Hereinafter, as shown in FIG. 9, a non-post construction method using an under-tensioned formwork support structure according to an embodiment of the present invention will be described. Here, the detailed description of the under-tensioned formwork support structure has been described above, so it will be omitted. do it with

On the other hand, the both ends variable support (200c, 200b, 200c), as described above, is composed of one of an insert method, a folding method, a scissor method, both ends variable supports corresponding to the configuration of the both ends variable support (200c, 200b, 200c) The length of (200c, 200b, 200c) can be varied. For example, in the case of the insert method, the sliding panel 211 can be changed by sliding with respect to the central support 100, and in the case of the folding method, the folding member 222 is rotated to change it, and in the case of the scissor method, the scissor link 230 ) can be adjusted.

When the installation of the central support 100 and the both ends of the variable supports 200c, 200b, and 200c is completed in this way, as shown in FIG. By installing the vertical side shutters 400 on the formed support foam (not shown), an under-tension formwork support structure is constituted.

Although the above has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention as set forth in the claims below. You can do what you can do.

100: central support
110: lower panel 120: side panel
130: center form plate
200a, 200b, 200c: both ends variable support
211: sliding panel 212: connection panel
213: both ends form plate 221: hinge part
222: folding member 230: scissor link
231: link member 232: hinge
300: powering means
310: sag strut 320: tension member
330a, 330b: fixing unit 340: central fixing unit
400: side shuttering

Claims (9)

a central support extending to a predetermined length;
One end is mounted to the end of the central support, the other end is variable in length along the longitudinal direction of the central support, both ends variable support mounted on the support structure;
The under tension formwork support structure comprising a; urging means coupled to the lower part of the central support to apply pre-stress.
The method of claim 1,
The both ends of the variable support,
An under-tension formwork support structure, characterized in that it is inserted in an insert method inside the end of the central support and the length is changed according to the sliding movement with respect to the central support.
3. The method of claim 2,
The central support is
The longitudinal cross-sectional shape including the lower panel and the side panel in which the lower end is coupled to the upper surface of both ends of the lower panel is formed in a closed type (tubular) shape of one of C, H, ㅁ, and ㅇ shapes,
The both ends of the variable support,
An under tension formwork support structure, characterized in that the insert is mounted on the inside of the central support and moved in a sliding manner in the longitudinal direction of the central support to change the length.
The method of claim 1,
The both ends of the variable support,
An under-tension formwork support structure, characterized in that it is hinged at the end of the central support and rotates in a folding manner with respect to the central support to change the length.
5. The method of claim 4,
The central support is
The longitudinal cross-sectional shape including the lower panel and the side panel in which the lower end is coupled to the upper surface of both ends of the lower panel is formed in a closed type (tubular) shape of one of C, H, ㅁ, and ㅇ shapes,
The both ends of the variable support,
A hinge part mounted on the end of the central support, and
An undertension formwork support structure comprising a folding member that is rotatably coupled to a hinge and is seated on the upper surface of the central support and overlaps when folded, and extends in the longitudinal direction of the central support when unfolded.
The method of claim 1,
The both ends of the variable support,
Under tension formwork support structure, characterized in that it is mounted in a scissor method with respect to the central support and is moved forward and backward in the longitudinal direction of the central support to change the length.
7. The method of claim 6,
The both ends of the variable support,
A plurality of link members configured in an X-shape, and a scissor link comprising a plurality of link members that are hinge-coupled;
The scissor link is
One end is coupled to the end of the central support, the other end is coupled to the variable support at both ends, the under tension formwork support structure, characterized in that the forward and backward expansion and contraction in the longitudinal direction of the central support.
The method of claim 1,
It further comprises a central form plate mounted on the upper surface of the central support, and both ends of the form plate mounted on the upper surface of the variable support at both ends,
Under tension formwork support, characterized in that it further comprises a pair of side shutters arranged in parallel to the left and right along the longitudinal direction based on the central support and the variable support at both ends on the upper surface of the central form plate and the both ends of the form plate and mounted vertically. rescue.
central support; One end is coupled to the end of the central support, the other end is a variable support at both ends of which the length is variable along the longitudinal direction of the central support; In the construction method of the under-tension formwork support structure comprising a; urging means coupled to the lower portion of the central support to apply pre-stress,
a) After installing the central form plate and both ends form plate on the upper surface of the central support and both ends of the variable support, respectively, a pair of side shutters are installed on the upper surface of the central and both ends of the form play to form the under-tension formwork support structure. constructing;
b) mounting the undertension formwork support structure to the support structure;
c) applying a pre-stress to any one of steps a) or b) through a pressing means; a non-post construction method using an under-tensioned formwork support structure, comprising:

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