KR102553850B1 - Non-supporting formwork system - Google Patents

Abstract

The present invention combines a pair of self-supporting formwork including a truss girder coupled in the vertical direction to the rear surface of the panel with a through bolt at the position of the yoke provided in the horizontal direction on the rear surface of the self-supporting formwork, so that the weight is light and the rigidity is high It is about a non-column formwork system for opposite walls that can increase the size of the formwork, reduce the number of yoke steps, and has excellent workability.
The non-column formwork system for opposite walls of the present invention is for constructing a reinforced concrete opposite wall, and includes a panel for forming a wall surface, a pair of lower chords, an upper chord provided to be spaced apart from the lower chord, and the upper chord and the lower chord. A pair of self-supporting formwork composed of a plurality of rows of truss girders that are connected and supported by lattice and coupled in a vertical direction to the rear surface of the panel and are spaced apart to face each other; A plurality of yokes composed of a pair of upper and lower yoke pipes, provided in a horizontal direction on the rear surface of each self-supporting formwork and supported across the truss girder; A through bolt protruding between the yoke pipes through a pair of self-supporting dies at the location of the yoke and fastened with a fixing nut; And a yoke mounting hole (4) in which the yoke is mounted as being coupled to the rear surface of the self-supporting formwork; It is characterized by consisting of.

Description

Non-supporting formwork system for facing walls {Non-supporting formwork system}

The present invention combines a pair of self-supporting formwork including a truss girder coupled in the vertical direction to the rear surface of the panel with a through bolt at the position of the yoke provided in the horizontal direction on the rear surface of the self-supporting formwork, so that the weight is light and the rigidity is high It is about a non-column formwork system for opposite walls that can increase the size of the formwork, reduce the number of yoke steps, and has excellent workability.

When constructing various structures, walls are installed outside the excavated underground space, and these underground external walls are divided into combined walls and facing walls according to the construction method.

In general, when a building is adjacent to a site or a retaining wall such as an earth plate, CIP, or SCW is installed due to the depth of excavation, a plywood wall that uses the retaining wall as an external formwork and installs formwork only on the inside is mainly used.

In addition, when there is no building on the adjacent site and the excavation depth is not deep, the open-cut method is used to support the formwork on both sides of the wall with form ties, so the opposite wall is mainly used.

For the opposite wall construction, conventionally, formwork such as euroform was installed on both sides, and a plurality of euroforms were integrated by installing a yoke in the horizontal direction on the back of the formwork.

At this time, since the euroform is coupled with an angle-shaped reinforcing frame on the back of the panel, the weight is large and the size is limited. Therefore, it takes a lot of time to install and dismantle the formwork, and many yokes are required to support the lateral pressure during wall concrete pouring.

KR 10-2020-0136127 A

In order to solve the above problems, the present invention is to provide a non-column formwork system for buttress walls capable of minimizing the number of yoke stages and obtaining excellent workability by using a self-supporting formwork that is light in weight and high in rigidity and can make the formwork medium or large in size. do.

The present invention according to a preferred embodiment is for constructing a reinforced concrete opposite wall, and connects a panel and a pair of lower chords for forming a wall surface, an upper chord provided to be spaced apart from the lower chord, and the upper chord and the lower chord. A pair of self-supporting formwork composed of a plurality of rows of truss girders coupled to the rear surface of the panel in a vertical direction and arranged spaced apart to face each other; A plurality of yokes composed of a pair of upper and lower yoke pipes, provided in a horizontal direction on the rear surface of each self-supporting formwork and supported across the truss girder; A through bolt protruding between the yoke pipes through a pair of self-supporting dies at the location of the yoke and fastened with a fixing nut; And provided between a pair of truss girders, one end supported by the panel of the self-supporting formwork, and the other end protruding forward of the truss girder and fixed to the mounting bracket on which the yoke is mounted and one side of the mounting bracket, horizontal direction A yoke holder composed of a horizontal hanging bar supported on the lattice by passing through both truss girders and being arranged as; It provides a non-column formwork system for facing walls, characterized in that consisting of.

The present invention according to another preferred embodiment provides a non-column formwork system for opposite walls, characterized in that the tip portion of the polygonal cross section is formed at the end of the through bolt.

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In the present invention according to another preferred embodiment, the mounting bracket has one end in close contact with the panel and the other end protruding forward of the truss girder, a horizontal mounting bar provided at the upper part of the other end of the horizontal mounting bar and a yoke hanging bar and the horizontal mounting It provides a non-column formwork system for facing walls, characterized in that it is composed of an inclined support bar provided at an angle to the lower part of the bar to support the horizontal support bar.

According to another preferred embodiment of the present invention, a left and right pair of mounting brackets are spaced apart from each other, and the through bolt is installed between the pair of mounting brackets.

According to another preferred embodiment, the present invention provides an upper support piece mounted on the upper surface of the upper yoke pipe, a vertical connection piece provided in the lower vertical direction from the outer end of the upper support piece, and an inner horizontal direction provided from the lower end of the vertical connection piece to the lower Provided is a non-column formwork system for a butt wall, characterized in that the lower yoke pipe is fixed to the lower part of the upper yoke pipe by a locking hole composed of a lower support piece on which the yoke pipe is mounted.

According to another preferred embodiment of the present invention, one end is caught on the upper chord of the truss girder and the other end is a fixing hook penetrating between the upper and lower yoke pipes and a pressure fixing plate coupled to the other end of the fixing hook and the other end of the fixing hook outside the pressure fixing plate Provides a non-column formwork system for buttress walls, characterized in that the upper and lower yoke pipes are fixed to the outside of the truss girder by a fixture consisting of a fixing nut coupled to and fixing the position of the press fixing plate.

According to the present invention, there are the following effects.

First, since a self-supporting formwork including a truss girder coupled in the vertical direction to the rear surface of the panel is used, it is possible to minimize the panel thickness and reduce the weight of the formwork due to increased formwork rigidity. Therefore, the unit formwork can be made medium to large in size, and the installation and disassembly time of the formwork can be greatly reduced.

Second, on the rear surface of the self-supporting formwork, a yoke composed of upper and lower yoke pipes is disposed in a horizontal direction across a plurality of rows of truss girders. At this time, since the bending rigidity is greatly improved by the truss girder, the number of stages of the yoke can be minimized, so it is possible to save time and construction costs.

Third, since the through bolt is installed through the pair of self-supporting forms at the position of the yoke, the yoke forms a fulcrum, thereby increasing the bending stiffness of the yoke. Therefore, it is possible to minimize the number of installation stages of the yoke, and to increase the size by connecting a plurality of self-supporting dies with a yoke, it is possible to reduce the installation and removal time of the dies. In addition, since the yoke is fixed using a through bolt connecting the self-supporting formwork on both sides, the installation and construction of the formwork are performed quickly.

1 is a perspective view showing a non-column formwork system for facing walls of the present invention.
Figure 2 is a perspective view showing a self-supporting formwork.
Figure 3 is a perspective view showing a through bolt.
Figure 4 is a perspective view showing a yoke mount.
Figure 5 is a perspective view showing a state in which the yoke is coupled by the yoke holder.
Figure 6 is a view showing the construction sequence of the non-column formwork system for the opposite wall of the present invention using a yoke mount.
Fig. 7 is a perspective view showing a locking tool;
Figure 8 is a perspective view showing the upper and lower yoke pipe coupled by the hook.
9 is a view showing the construction sequence of the non-column formwork system for facing walls of the present invention using a hook.
Fig. 10 is a perspective view showing a fixture;
Figure 11 is a view showing the assembly sequence of the self-supporting formwork using a fixture.

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

1 is a perspective view showing a non-column formwork system for facing walls of the present invention, and FIG. 2 is a perspective view showing a self-supporting formwork.

As shown in FIGS. 1 and 2, the non-column formwork system for the opposite wall of the present invention is for constructing a reinforced concrete opposite wall, and includes a panel 11 and a pair of lower chords 121 for forming a wall surface and the above It consists of an upper chord 122 provided to be spaced apart from the lower chord 121 and a lattice 123 connecting and supporting the upper chord 122 and the lower chord 121 in a direction perpendicular to the rear surface of the panel 11. A pair of self-supporting forms (1) composed of a plurality of rows of truss girders (12) coupled and spaced apart to face each other; Consisting of a pair of upper and lower yoke pipes (2a, 2b), a plurality of stages of yokes (2) provided in the horizontal direction on the rear surface of each self-supporting formwork (1) and supporting the truss girder (12) across; and through bolts (3) protruding between the yoke pipes (2a, 2b) through the pair of self-supporting forms (1) at the position of the yoke (2) to which the fixing nut (31) is fastened; It is characterized by consisting of.

The present invention is to minimize the number of stages of the yoke (2) by using a self-supporting formwork (1) capable of making the formwork medium to large due to its light weight and high rigidity, and to provide a non-column formwork system for opposite walls with excellent workability.

The non-column formwork system for facing walls of the present invention includes a pair of self-supporting forms (1), a plurality of stages of yokes (2) and through bolts (3).

The self-supporting formwork 1 is spaced apart so that a pair faces each other.

The front side of the self-supporting formwork 1 will be described as representing the wall side and the rear side representing the opposite side of the wall.

The self-supporting formwork 1 is composed of a panel 11 for forming a wall surface and a plurality of rows of truss girders 12 coupled to the rear surface of the panel 11.

The panel 11 may use a metal plate or a synthetic resin panel such as a cone panel.

The truss girders 12 are coupled to the rear surface of the panel 11 in vertical directions to serve as joists of the formwork, and are provided in multiple rows so as to be spaced apart from each other in the width direction of the panel 11 (FIG. 2).

The truss girder 12 connects and supports a pair of lower chords 121, an upper chord 122 provided to be spaced apart from the lower chord 121, and the upper chord 122 and the lower chord 121. It consists of a lattice 123.

Since the rigidity of the form itself is greatly increased by the combination of the truss girder 12, the thickness of the panel 11 can be minimized. Therefore, not only the weight of the support structure itself, but also the weight of the panel 11 can be reduced, so that the total weight of the self-supporting formwork 1 can be greatly reduced, and as a result, the size of the unit formwork can be increased.

Furthermore, due to the increase in the size of the self-supporting formwork (1) unit, it is possible to significantly reduce the installation and disassembly time of the formwork.

The yoke 2 is composed of a pair of upper and lower yoke pipes 2a and 2b.

The yoke 2 is provided in the horizontal direction on the rear surface of each self-supporting formwork 1, and is disposed across the plurality of rows of truss girders 12.

The yoke 2 is provided with a plurality of stages spaced apart vertically.

Since the self-supporting formwork 1 is provided with a truss girder 12 to greatly improve bending rigidity, the yoke 2 can be installed in two stages, one each at the top and bottom.

Accordingly, by minimizing the number of stages of the yoke 2, it is possible to reduce air and construction costs.

The number of installation stages of the yoke 2 may be installed in two or more stages in consideration of the concrete pouring pressure according to the height or thickness of the wall.

The penetration bolts 3 are installed through a pair of self-supporting forms 1 to maintain a distance between the self-supporting forms 1 installed on both sides and to support lateral pressure during concrete pouring.

The through bolt 3 is installed at the position of the yoke 2 to connect and support not only the self-supporting formwork 1 on both sides but also the yoke 2 on both sides.

To this end, the through bolt 3 is installed to penetrate between the upper and lower yoke pipes 2a and 2b.

Since the yoke 2 is supported by the through bolt 3 to form a fulcrum, the bending rigidity of the yoke 2 increases, so that the number of installation stages of the yoke 2 can be minimized.

In addition, the yoke (2) can be integrally fixed to the self-supporting formwork (1). Therefore, by connecting the plurality of self-supporting forms 1 to each other and increasing the size, it is possible to reduce the installation and demolding time of the formwork.

In addition, since the yoke 2 is fixed using the through bolts 3 connecting the self-supporting formwork 1 on both sides, the installation and construction of the formwork can be performed quickly.

A pressure fixing plate 32 is coupled to the end of the through bolt 3 protruding between the upper and lower yoke pipes 2a and 2b to support the yoke pipes 2a and 2b by the through bolt 3, and the pressure fixing plate ( 32) can fasten the fixing nut 31 to the through bolt 3 from the outside (Figs. 1 and 3).

A sepa bolt and a deacon (not shown) may be provided at the center of the through bolt 3 to maintain the distance between the self-supporting forms 1 on both sides.

3 is a perspective view showing a through bolt.

As shown in FIG. 3 , a tip portion 30 having a polygonal cross section may be formed at an end of the through bolt 3 .

Since the through bolts 3 are installed through the self-supporting formwork 1 on both sides, it should be possible to work on one side when fastening the fixing nut 31. That is, in a state in which rotation is restricted by fixing the through bolt 3 at one side, the fixing nut 31 must be fastened and tightened.

However, since the end of the through-bolt 3 has a circular cross-section and a screw thread is formed on the outer circumferential surface, it is not easy to fix it so as not to rotate.

Accordingly, a tip portion 30 having a polygonal cross section may be formed at an end of the through bolt 3 . The cross section of the tip portion 30 is preferably hexagonal, but can be manufactured in other polygonal shapes as long as rotation can be restricted by combining tools.

When the tip portion 30 is provided at the end of the through bolt 3, rotation of the tip portion 30 may be restricted by fixing the tip portion 30 with a general tool.

In particular, when tightening the through bolt 3 by using an electric impact wrench, the tightening time can be greatly reduced.

Figure 4 is a perspective view showing a yoke mounting hole, Figure 5 is a perspective view showing a state in which the yoke is coupled by the yoke mounting hole.

As shown in FIGS. 4 and 5, a yoke mounting hole 4 on which the yoke 2 is mounted may be further provided by being coupled to the rear surface of the self-supporting formwork 1.

In the case of installing the self-supporting forms (1), which are single sheets, on the wall first, and then installing the yoke (2) on the back of the self-supporting formwork (1) later, fix the long yoke (2) with a through bolt (3) The operator must hold the yoke (2) until

In this case, the workability is poor, and an additional worker must be put in.

Therefore, until the yoke 2 is fixed with the through bolt 3, the yoke holder 4 for temporarily holding the yoke 2 can be coupled to the rear surface of the self-supporting formwork 1.

The yoke holder 4 can be detachably coupled to the self-supporting formwork 1 so as to be reusable.

The yoke mounting hole 4 protrudes to the outside of the truss girder 12, and the yoke 2 is mounted on the upper surface of the protruding portion.

The yoke 2 can be easily fixed by fastening the pressure fixing plate 32 and the fixing nut 31 to the through bolt 3 in a state where the yoke 2 is temporarily fixed by being placed in the yoke holder 4 .

6 is a view showing the construction sequence of the non-column formwork system for facing walls of the present invention using a yoke mount.

4 to 6, the yoke holder 4 is provided between a pair of truss girders 12, and one end is supported by the panel 11 of the self-supporting formwork 1, and the other end Protrudes forward of the truss girder 12 and is fixed to the mounting bracket 41 on which the yoke 2 is mounted and to one side of the mounting bracket 41, is disposed in the horizontal direction and penetrates the truss girder 12 on both sides It can be composed of a horizontal hanging bar 42 supported by the lattice 123.

The yoke mounting hole 4 can be configured with a mounting bracket 41 and a horizontal hanging bar 42.

The mounting bracket 41 is a part where the yoke 2 is mounted, and one end is supported in close contact with the panel 11 of the self-supporting formwork 1 and the other end protrudes forward of the truss girder 12.

The yoke 2 is mounted on the upper surface of the portion where the mounting bracket 41 protrudes forward of the truss girder 12.

The horizontal hanging bar 42 is for fixing the mounting bracket 41 to the truss girder 12, and may be fixed to one side of the mounting bracket 41 by welding or the like.

The horizontal hanging bar 42 is disposed in the horizontal direction and is coupled through both truss girders 12.

Specifically, the horizontal hanging bar 42 may be inserted and mounted at a portion where the lattice 123 and the upper chord 122 of the truss girder 12 meet.

In this way, since the horizontal hanging bar 42 is inserted and mounted through the truss girder 12, the installation and disassembly of the yoke mounting hole 4 is simple.

When the upper and lower yoke pipes 2a and 2b of the yoke 2 are separated from each other, the lower yoke pipe 2b is mounted on the upper portion of the mounting bracket 41 of the yoke mounting hole 4, and the upper yoke pipe 2a It can be configured to be mounted on the top of the through bolt (3).

In this case, referring to FIG. 6, the construction sequence of the non-column formwork system for the opposite wall of the present invention using the yoke holder 4 will be described as follows.

First, the yoke holder 4 is installed on the rear surface of the self-supporting formwork 1 (Fig. 6 (a)).

In addition, the lower yoke pipe 2b is mounted on the upper part of the yoke holder 4, that is, the upper part of the mounting bracket 41 of the yoke holder 4 (Fig. 6(b)).

Next, the through bolt 3 is installed through the pair of self-supporting forms 1 so that the lower yoke protrudes to the top of the pipe 2b (FIG. 6(c)).

Thereafter, the upper yoke pipe 2a is mounted on the top of the through bolt 3 (Fig. 6(d)).

Finally, by fastening the pressure fixing plate 32 and the fixing nut 31 to the protruding end of the through bolt 3, the pipes 2a and 2b are fixed to the upper and lower yokes (Fig. 6(e)).

As shown in FIG. 4 , the mounting bracket 41 has one end in close contact with the panel 11 and the other end of the horizontal mounting bar 411 protruding forward of the truss girder 12 and the horizontal mounting bar 411. It can be composed of a hanging bar 412 provided at the upper part of the other end of the yoke 2 to which the yoke 2 is hung and an inclined support bar 413 provided obliquely below the horizontal mounting bar 411 to support the horizontal mounting bar 411. there is.

The mounting bracket 41 includes a horizontal mounting bar 411 on which the yoke 2 is mounted, an inclined support bar 413 supporting the lower portion of the horizontal mounting bar 411, and a hook preventing the yoke 2 from leaving. It may consist of a bar 412.

The horizontal hanging bar 42 may be fixed to the horizontal mounting bar 411 or the inclined support bar 413 by welding or the like.

The horizontal mounting bar 411 and the inclined support bar 413 are supported in close contact with the panel 11 at their respective ends spaced apart from each other up and down. And the horizontal hanging bar 42 is caught and supported by the upper chord 122 and the lattice 123 of the truss girder 12. Therefore, even if the yoke 2 is mounted on the upper portion of the horizontal mounting bar 411 and a downward load acts, the yoke holder 4 is not rotated and the position is fixed.

One end of the horizontal support bar 411 and the inclined support bar 413 on the side of the panel 11 may be connected to a vertical support bar 414 to form a right triangle shape.

As shown in FIG. 4 , the left and right pairs of the mounting brackets 41 may be spaced apart from each other, and the through bolts 3 may be installed between the pair of mounting brackets 41 .

The mounting bracket 41 may be configured as a left and right pair so that the through bolt 3 can be installed at the position of the yoke mounting hole 4.

That is, a pair of the mounting brackets 41 may be provided to be spaced apart from each other left and right, and the through bolt 3 may be installed to penetrate between the pair of mounting brackets 41 .

The pair of mounting brackets 41 may be integrally configured with the horizontal hanging bar 42 while maintaining a mutual distance by fixing each to the horizontal hanging bar 42.

The mounting bracket 41 can be manufactured by cutting a steel plate.

Figure 7 is a perspective view showing the hook, Figure 8 is a perspective view showing the upper and lower yoke pipe coupled by the hook, Figure 9 is a construction sequence of the non-column formwork system for the opposite wall of the present invention using the hook it is a drawing

7 to 9, the upper support piece 51 mounted on the upper surface of the upper yoke pipe 2a and the vertical connection piece 52 provided in the lower vertical direction at the outer end of the upper support piece 51 ) and the lower support piece 53 provided in the inner horizontal direction from the lower end of the vertical connection piece 52 to which the lower yoke pipe 2b is mounted, the lower yoke pipe 2b is moved to the upper It can be configured to be fixed to the lower part of the yoke pipe (2a).

In the present invention, the upper yoke pipe (2a) is mounted on top of the through bolt (3), and the lower yoke pipe (2b) can be configured to be supported by hanging on the upper yoke pipe (2a).

That is, the C-shaped hook 5 may be mounted on the upper yoke pipe 2a, and the lower yoke pipe 2b may be mounted on the hook 5 to be hung.

To this end, the hook 5 is an upper support piece 51 mounted on the upper surface of the upper yoke pipe 2a, a vertical connection piece 52 provided downward from the outer end of the upper support piece 51, and the vertical The lower support piece 53 provided in the inner horizontal direction from the lower end of the connection piece 52 may be configured to form a U-shape as a whole.

The lower yoke pipe (2b) is mounted on the upper portion of the lower support piece (53).

In order to prevent the hooking hole 5 mounted on the upper yoke pipe 2a from being separated, a hooking piece 54 may be further provided at the front end of the upper support piece 51 in the lower vertical direction.

Referring to FIG. 9, the construction sequence of the non-column formwork system for the facing wall of the present invention when the hook is provided is as follows.

First, the through bolt 3 is installed to penetrate the pair of self-supporting forms 1 (Fig. 9 (a)), and then the pipe 2a is placed on the upper yoke on the top of the through bolt 3 ( Figure 9 (b)).

And the hook 5 is mounted on the upper surface of the upper yoke pipe 2a so that the upper support piece 51 is mounted (Fig. 9 (c)).

Thereafter, the lower yoke pipe 2b is mounted and installed on the lower support piece 53 of the hook 5 (Fig. 9(d)).

Finally, the pressure fixing plate 32 and the fixing nut 31 are fastened to the end protruding outward of the through bolt 3 to fix the upper and lower yoke pipes 2a and 2b (FIG. 9(e)).

The embodiment shown in FIG. 9 is another embodiment in which the yoke 2 is temporarily mounted on the self-supporting formwork 1, and is applied when the self-supporting formwork 1 is pre-installed and then the yoke 2 is installed later do.

Figure 10 is a perspective view showing a fixture, Figure 11 is a view showing the assembly sequence of the self-supporting formwork using the fixture.

10 and 11, one end is caught on the upper chord 122 of the truss girder 12 and the other end is the fixing hook 61 penetrating between the upper and lower yoke pipes 2a and 2b and the fixing hook A fixture composed of a pressure fixing plate 62 coupled to the other end of the pressure fixing plate 62 and a fixing nut 63 coupled to the other end of the fixing hook 61 outside the pressure fixing plate 62 to fix the position of the pressure fixing plate 62 By (6), the upper and lower yoke pipes 2a and 2b can be configured to be fixed to the outside of the truss girder 12.

If you want to assemble and install a plurality of self-supporting forms (1) in a field workshop without installing the self-supporting formwork (1) in a single sheet, first fix the yoke (2) to the self-supporting formwork (1) to Of the self-supporting formwork (1) can be integrated.

At this time, a fixture 6 may be used to fix the yoke 2 to the self-supporting formwork 1.

The fixture 6 has one end bent and coupled to a J-shaped fixing hook 61 hooked to the upper chord 122 of the truss girder 12 and the other end of the fixing hook 61 to press the yoke 2 It can be composed of a pressing fixing plate 62 and a fixing nut 63 for fixing.

Referring to FIG. 11, the assembly sequence of the self-supporting formwork using the fixture is as follows.

First, a plurality of self-supporting forms 1 are placed on the ground, and the yoke 2 is mounted on the upper part of the truss girder 12 of the self-supporting forms 1 (Fig. 11 (a)).

In addition, the fixing hook 61 is inserted between the upper and lower yoke pipes 2a and 2b so that the lower end of the fixing hook 61 is caught on the upper chord 122 of the truss girder 12, but the upper end of the fixing hook 61 is Install the fixture 6 so that it protrudes (Fig. 11 (b)).

Finally, the press fixing plate 62 is coupled to the upper end of the fixing hook 61, and the yoke 2 is fixed to the self-supporting formwork 1 by fastening the fixing nut 63 (Fig. 11 (c)) .

1: self-supporting formwork 11: panel
12: truss girder 121: lower current
122: phase present 123: lattice
2: yoke 2a, 2b: yoke pipe
3: through bolt 30: tip part
31: fixing nut 32: pressure fixing plate
4: yoke mount 41: mount bracket
411: horizontal mounting bar 412: hanging bar
413: inclined support bar 414: vertical support bar
42: horizontal hanging bar 5: hanging hole
51: upper support piece 52: vertical connection piece
53: lower support piece 54: locking piece
6: fixture 61: fixing hook
62: pressure fixing plate 63: fixing nut

Claims (8)

For constructing reinforced concrete buttresses,
A panel 11 for forming a wall surface, a pair of lower chords 121, an upper chord 122 provided to be spaced apart from the lower chord 121, and the upper chord 122 and the lower chord 121 A pair of self-supporting formworks (1) composed of a plurality of rows of truss girders (12) coupled to the rear surface of the panel (11) in a vertical direction and arranged spaced apart to face each other, composed of lattice (123) for connecting and supporting;
Consisting of a pair of upper and lower yoke pipes (2a, 2b), a plurality of stages of yokes (2) provided in the horizontal direction on the rear surface of each self-supporting formwork (1) and supporting the truss girder (12) across;
Through-bolts (3) protruding between the yoke pipes (2a, 2b) through a pair of self-supporting forms (1) at the position of the yoke (2) to which the fixing nut (31) is fastened; and
It is provided between a pair of truss girders 12, one end is supported by the panel 11 of the self-supporting formwork 1, and the other end protrudes forward of the truss girder 12 and the yoke 2 is mounted Yoke consisting of a mounting bracket 41 and a horizontal hanging bar 42 fixed to one side of the mounting bracket 41 and disposed in the horizontal direction and supported by the lattice 123 through the truss girder 12 on both sides. sphere (4); A non-column formwork system for facing walls, characterized in that consisting of.
In paragraph 1,
The end of the through bolt (3) is formed with a tip portion (30) of polygonal cross section.
delete delete In paragraph 1,
One end of the mounting bracket 41 is in close contact with the panel 11, and the other end is provided on the upper part of the horizontal mounting bar 411 protruding forward of the truss girder 12 and the other end of the horizontal mounting bar 411 to form a yoke Non-column formwork for opposite walls, characterized in that it consists of a hanging bar 412 on which (2) is hung and an inclined support bar 413 provided obliquely at the bottom of the horizontal mounting bar 411 to support the horizontal mounting bar 411 system.
In paragraph 1,
The mounting brackets (41) are provided with a pair of left and right spaced apart from each other, and the through bolt (3) is installed between the pair of mounting brackets (41).
In paragraph 1,
The upper support piece 51 mounted on the upper surface of the upper yoke pipe 2a and the vertical connection piece 52 provided in the lower vertical direction from the outer end of the upper support piece 51 and the lower end of the vertical connection piece 52 The lower yoke pipe 2b is fixed to the lower part of the upper yoke pipe 2a by the locking hole 5 composed of the lower support piece 53 provided in the inner horizontal direction and on which the lower yoke pipe 2b is mounted. Characterized by non-column formwork system for opposite walls.
In paragraph 1,
One end is caught on the upper chord 122 of the truss girder 12 and the other end is coupled to the fixing hook 61 penetrating between the upper and lower yoke pipes 2a and 2b and the other end of the fixing hook 61 Pressing fixing plate ( 62) and the fixing nut 63 coupled to the other end of the fixing hook 61 outside the press fixing plate 62 to fix the position of the press fixing plate 62, the upper and lower yoke pipes 2a, 2b) is fixed to the outside of the truss girder (12).

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