KR102775719B1 - Truss Diagonal Reinforcement - Google Patents

Abstract

A truss diagonal reinforcement bar according to one embodiment of the present invention is intended to provide a truss diagonal reinforcement bar that not only simplifies the reinforcement procedure but also minimizes reinforcement costs, thereby enabling easy reinforcement of a building frame. The truss diagonal reinforcement bar for reinforcing a main frame and a sub-frame of a building which are arranged parallel to each other includes a first diagonal reinforcement body that supports one side of the main frame and the sub-frame, a second diagonal reinforcement body that is rotatably connected to one end of the first diagonal reinforcement body and supports the other side of the main frame, and a third diagonal reinforcement body that is rotatably connected to the other end of the first diagonal reinforcement body and supports the other side of the sub-frame.

Description

Truss Diagonal Reinforcement

The present invention relates to a truss diagonal reinforcement bar, and more particularly, to a truss diagonal reinforcement bar that can prevent distortion of a building by reinforcing the frame of an existing building and thereby improving the bearing capacity.

In general, various types of buildings are formed by including columns that are erected vertically and beams that are connected to the columns and support the structure. Here, the beams are formed by steel, reinforced concrete, wood, I-beams, H-shaped steel, and hollow pipes. (Hereinafter, the structure that supports the building, such as columns and beams, is called the 'building frame'.)

As the building frame gradually ages due to continuous load, its supporting power becomes unstable, and when the load is added due to the rise of the building, the supporting power of the building becomes even more unstable, which increases the risk of accidents and can cause serious casualties.

In order to prevent casualties, reinforcement of the building frame is essential, but replacing the building frame for reinforcement can result in excessive costs, and many variables, such as distortion of the building, can occur.

In addition, even when reinforcing a building frame by means other than replacement, the cost of reinforcement is not small depending on the reinforcement method selected, making it difficult to easily reinforce aged or expanded buildings.

Accordingly, the development of reinforcing supports that can easily reinforce buildings at low installation costs while maintaining the existing building frame is essential.

Korean Patent Publication No. KR10-2008-0078968 (Published on August 29, 2008)

The present invention has been made to solve the above problems, and provides a truss diagonal reinforcing bar that not only simplifies the reinforcing procedure but also minimizes the reinforcing cost, thereby easily reinforcing a building frame.

According to one embodiment of the present invention, a truss diagonal reinforcement bar is a truss diagonal reinforcement bar for diagonally reinforcing a main frame and a sub-frame of a building that are arranged parallel to each other, the truss diagonal reinforcement bar includes a first diagonal reinforcement body that supports one side of the main frame and the sub-frame and is joined to the main frame and the sub-frame so as to form an acute angle, a second diagonal reinforcement body that is rotatably connected to one end of the first diagonal reinforcement body and is connected to form an acute angle with the main frame to support the other side of the main frame, and a third diagonal reinforcement body that is rotatably connected to the other end of the first diagonal reinforcement body and is connected to form an acute angle with the sub-frame to support the other side of the sub-frame.

The first diagonal reinforcement may include a first upper inner insertion portion including a first upper coupling portion formed so that one side of the main frame is inserted and one end of which is rotatably coupled with the second diagonal reinforcement portion, a first support portion formed so as to extend from the other end of the first upper inner insertion portion and configured to have an acute angle with the main frame and the sub-frame and having a surface facing the second diagonal reinforcement portion, and a first lower inner insertion portion including a first lower coupling portion formed so as to extend from one end of the first support portion and one end of which is rotatably coupled with the third diagonal reinforcement portion.

The second diagonal reinforcing body includes a second upper inner insertion portion including a second upper coupling portion that is formed so that the other side of the main frame is inserted and has one end rotatably connected to the first upper coupling portion, and a second support portion that is formed by extending from one end of the second upper inner insertion portion but is configured to have an acute angle with the main frame and has a surface facing the first support portion, and the third diagonal reinforcing body includes a second lower inner insertion portion including a second lower coupling portion that is formed so that the other side of the sub-frame is inserted and has one end rotatably connected to the first lower coupling portion, and a third support portion that is formed by extending from one end of the second lower inner insertion portion but is configured to have an acute angle with the sub-frame, and the third support portion can be formed to overlap the first support portion and the second support portion in one direction.

The first to third support members are fixed as fixed pieces with respect to the overlapping surfaces, and the first and second support members can be additionally fixed as fixed pieces with respect to the surface that does not overlap with the third support member.

According to a truss diagonal reinforcement member according to one embodiment of the present invention, the building frame can be reinforced more easily through simple construction in an existing building.

In addition, according to the truss diagonal reinforcement according to one embodiment of the present invention, stability can be increased by adding a simple pipe or the like to an existing building frame and combining them.

In addition, according to the truss diagonal reinforcement according to one embodiment of the present invention, the stability of the building frame can be increased, thereby preventing casualties.

In addition, according to the truss diagonal reinforcement according to one embodiment of the present invention, a structure that may become unstable due to excessive load when the height of a building increases can be reinforced.

FIG. 1 is a perspective view of a truss diagonal reinforcement according to one embodiment of the present invention.
Figure 2 is a front elevation of a truss diagonal reinforcement according to one embodiment of the present invention.
FIG. 3 is a side view of a truss diagonal reinforcement according to one embodiment of the present invention.
FIG. 4 is a side view showing a process of attaching a truss diagonal reinforcing member to a main frame and a sub-frame according to one embodiment of the present invention.
FIG. 5 is a side view showing a state in which a truss diagonal reinforcement member according to one embodiment of the present invention is connected to a main frame and a sub-frame.
FIG. 6 is a front view showing a state in which a truss diagonal reinforcement member according to one embodiment of the present invention is connected to a main frame and a sub-frame.
FIG. 7 is a perspective view of a truss diagonal reinforcement according to another embodiment of the present invention.

The advantages and features of the present invention, and the methods for achieving them, will become apparent by referring to the embodiments described in detail below together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in other various forms, and the present embodiments are provided only to make the disclosure of the present invention complete and to fully inform those skilled in the art of the scope of the invention, and the present invention is defined only by the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, the present invention will be described in detail through various embodiments of the present invention. The present invention relates to a truss diagonal reinforcing bar (10) that can reinforce an existing building through simple installation, and is for reinforcing a main frame (1) and a sub-frame (3) of a building that are arranged parallel to each other. Here, the main frame (1) may be understood to mean an existing support frame that supports the building, and the sub-frame (3) may be understood as a frame temporarily installed to reinforce the main frame (1). However, the main frame (1) and the sub-frame (3) are not limited to the above-described description and may mean frames that support the building. Various embodiments of the present invention may be recognized with reference to FIGS. 1 to 7.

FIG. 1 is a perspective view of a truss diagonal reinforcement member (10) according to one embodiment of the present invention, FIG. 2 is a front view of a truss diagonal reinforcement member (10) according to one embodiment of the present invention, FIG. 3 is a side view of a truss diagonal reinforcement member (10) according to one embodiment of the present invention, FIG. 4 is a side view showing a process of attaching a truss diagonal reinforcement member (10) according to one embodiment of the present invention to a main frame (1) and a sub-frame (3), FIG. 5 is a side view showing a state in which a truss diagonal reinforcement member (10) according to one embodiment of the present invention is attached to a main frame (1) and a sub-frame (3), and FIG. 6 is a front view showing a state in which a truss diagonal reinforcement member (10) according to one embodiment of the present invention is attached to a main frame (1) and a sub-frame (3).

Referring to FIGS. 1 to 6, a truss diagonal reinforcement member (10) according to one embodiment of the present invention is intended to reinforce a main frame (1) and a sub-frame (3) of a building that are arranged parallel to each other, and includes a first diagonal reinforcement member (100), a second diagonal reinforcement member (200), and a third diagonal reinforcement member (300). The first diagonal reinforcement member (100), the second diagonal reinforcement member (200), and the third diagonal reinforcement member (300) may be separated from or combined with each other as needed.

The first diagonal reinforcing member (100) is diagonally connected to the main frame (1) and the sub-frame (3) to reinforce the main frame (1) and the sub-frame (3). The first diagonal reinforcing member (100) is in contact with the main frame (1) and the sub-frame (3) to support one side, and includes a first upper inner portion (110), a first support portion (120), and a first lower inner portion (130) formed integrally. The first diagonal reinforcing member (100) may be formed of a high-strength metal material so as to support the main frame (1) and the sub-frame (3) and distribute the load, but is not limited thereto and may include a synthetic resin material, etc.

The first upper inner insert (110) comes into contact with the main frame (1) and disperses the load concentrated on the main frame (1). The first upper inner insert (110) is configured in an inner insert shape so that the main frame (1) can be inserted on one side, and supports the main frame (1) as the main frame (1) is inserted.

The first upper inner portion (110) may, for example, be bent outwardly so that the main frame (1) can be positioned in a curved area. The first upper inner portion (110) may have a semicircular shape so as to support the main frame (1) formed in a pipe or circular shape.

The first upper inner portion (110) may, as another example, be configured to have an outwardly angular shape so that the main frame (1) is positioned. In this case, the first upper inner portion (110) may be easily configured to support the main frame (1) configured as a beam or square.

One end of the first upper insertion portion (110) may include a first upper coupling portion (111) that is rotatably coupled with the second diagonal reinforcement body (200). The first upper insertion portion (110) may be separated from or coupled with the second diagonal reinforcement body (200) through the first upper coupling portion (111).

The first upper coupling part (111) is rotatably coupled with the second upper coupling part (211) formed on the second diagonal reinforcing body (200). The first upper coupling part (111) can be fittedly coupled with the second upper coupling part (211). Referring to Fig. 1, the first upper coupling part (111) may include, for example, a first upper coupling piece (1111) and a first upper coupling hole (1113) formed spaced apart from the first upper coupling piece (1111).

The first upper connecting piece (1111) is formed in a protruding tooth shape, and the outer end is formed wider than the tooth body. The first upper connecting piece (1111) is formed so that it can be inserted into and fitted into the second upper connecting hole (2113) formed in the second upper connecting portion (211) to be described later. The first upper connecting hole (1113) is formed as a fitting hole into which the second upper connecting piece (2111) to be described later is inserted and fixed.

Accordingly, the first upper coupling part (111) can be fitted into the upper coupling hole formed in the second upper coupling part (211). However, the first upper coupling part (111) is not limited to the above-described form, and may include any form that can be rotatably coupled with the second upper coupling part (211).

The other end of the first upper inner portion (110) is connected to the first support portion (120). The first support portion (120) is configured in a diagonal direction to have an acute angle with the main frame (1) and the sub-frame (3), as shown in FIG. 6. The first support portion (120) is formed to extend from the first upper inner portion (110) and to have a surface facing the second diagonal reinforcing body (200). The first support portion (120) is connected to have an acute angle with the tangent line of the first upper inner portion (110). The first support portion (120) can be formed to be combined with the second support portion (220) and the third support portion (320). The first support portion (120) can be configured in a plate or square shape.

The first support portion (120) is formed to have a surface facing the second support portion (220), and may include a first support plate (121) formed in the center and a first protruding plate (123) formed at both ends of the first support plate (121). The first support plate (121) is formed in the center area of the first support portion (120), and may be formed as a flat plate-shaped plate.

The first support plate (121) may include a rough surface having a plurality of concave grooves and convex grooves on the inner surface facing the second support plate (221).

The first protruding plate (123) is arranged at both ends of the first support plate (121) and formed on both sides of the first support portion (120), and may be formed as a plate with a protruding shape.

The first protruding plate (123) may, for example, protrude outwardly. The first protruding plate (123) may be formed so that its cross-section has a semicircular shape.

As another example, the first protrusion plate (123) may protrude inwardly facing the second support member (220). At this time, the first protrusion plate (123) may be formed so that a part of its cross-section has a semicircular shape, and the protruding end may be formed in a flat plate shape. In this case, the first protrusion plate (123) may be in surface contact with the end of the second protrusion plate (223) described later, thereby improving the fixing force.

The first support member (120) may include a first stop-joining hole (1211) so that it can be combined with the second support member (220) and the third support member (320). The first support member (120) is fixed to the second support member (220) and the third support member (320) through a fixing piece inserted into the first stop-joining hole (1211). The first stop-joining holes (1211) may be formed in a plurality spaced apart from each other and may be composed of a first overlapping hole (1211a) that overlaps the second support member (220) in one direction and a second overlapping hole (1211b) that overlaps the second support member (220) and the third support member (320) in one direction.

As an example, the first stop coupling hole (1211) may be formed in multiple numbers spaced apart from each other in the length direction on the first support plate (121). As another example, the first stop coupling hole (1211) may be formed in multiple numbers spaced apart from each other in the length direction on each of the first support plate (121) and the first protrusion plate (123).

The first lower inner insert (130) comes into contact with the sub-frame (3) and disperses the load concentrated on the sub-frame (3). The first lower inner insert (130) is provided in an oblique direction so that the tangent line forms an acute angle with the first support part (120). The first lower inner insert (130) is configured in an inner shape so that the sub-frame (3) can be inserted, and supports the sub-frame (3) as the sub-frame (3) is inserted.

The first lower inner portion (130) may be formed in the same shape as the first upper inner portion (110), but is not limited thereto.

The first lower inner portion (130) may, for example, be bent outwardly so that the sub-frame (3) can be positioned in a curved portion. The first lower inner portion (130) may have a semicircular shape so as to support the sub-frame (3) configured as a pipe or circle.

The first lower inner portion (130) may, as another example, be configured to have an outwardly angular shape so that the sub-frame (3) is positioned. In this case, the first lower inner portion (130) may be easily configured to support the sub-frame (3) configured as a beam or square.

One end of the first lower insertion portion (130) may include a first lower coupling portion (131) that is rotatably coupled with the third diagonal reinforcement body (300). The first lower insertion portion (130) may be separated from or coupled with the third diagonal reinforcement body (300) through the first lower coupling portion (131).

The first lower coupling part (131) is rotatably coupled with the second lower coupling part (311) formed on the third diagonal reinforcing body (300). The first lower coupling part (131) can be fittedly coupled with the second lower coupling part (311). Referring to Fig. 1, the first lower coupling part (131) may include, for example, a first lower coupling piece (1311) and a first lower coupling hole (1313) formed spaced apart from the first lower coupling piece (1311).

The first lower joint piece (1311) is formed in a protruding tooth shape, with the outer end formed wider than the tooth body. The first lower joint piece (1311) is formed so that it can be inserted into and fitted into the second lower joint hole (3113) formed in the second lower joint portion (311) to be described later. The first lower joint hole (1313) is formed as a fitting hole into which the second lower joint piece (3111) to be described later is inserted and fixed.

However, the first upper coupling part (111) is not limited to the aforementioned form, and may include any form that can be rotatably coupled with the second upper coupling part (211).

The second diagonal reinforcement (200) is joined to the main frame (1) at an acute angle to reinforce the main frame (1). The second diagonal reinforcement (200) is in contact with the main frame (1) to support the other side, and is joined to the first diagonal reinforcement (100) to support the main frame (1). The second diagonal reinforcement (200) includes a second upper inner portion (210) and a second support portion (220) that are formed integrally. The second diagonal reinforcement (200) can be formed of the same material as the first diagonal reinforcement (100).

The second upper inner insert (210) comes into contact with the main frame (1) and, together with the first upper inner insert (110), disperses the load concentrated on the main frame (1). The second upper inner insert (210) is configured in an inner insert shape so that the other side of the main frame (1) can be inserted, and is formed symmetrically with the first upper inner insert (110).

The second upper inner portion (210) may be curved outwardly so that the main frame (1) is positioned in a curved area, similar to the first upper inner portion (110), but is not limited thereto and may be configured to have an angled shape in the outward direction.

One end of the second upper insertion portion (210) may include a second upper coupling portion (211) that is rotatably coupled with the first diagonal reinforcement body (100). The second upper insertion portion (210) may be separated from or coupled with the first diagonal reinforcement body (100) through the second upper coupling portion (211).

The second upper coupling part (211) can be fitted and connected to the first upper coupling part (111). The second upper coupling part (211) can include, for example, a second upper coupling piece (2111) and a second upper coupling hole (2113) formed spaced apart from the second upper coupling piece (2111). The second upper coupling piece (2111) is formed in the same shape as the first upper coupling piece (1111), but is inserted into and fitted into the first upper coupling hole (1113). The second upper coupling hole (2113) is formed as a fitting hole into which the first upper coupling piece (1111) described above is inserted and fixed.

The other end of the second upper inner portion (210) is connected to the second support portion (220). The second support portion (220), as shown in FIG. 6, is configured in an oblique direction to have an acute angle with the sub-frame (3). The second support portion (220) is formed to have a surface facing the first support portion (120), and the second support portion (220) may be formed symmetrically to the first support portion (120). The second support portion (220) is connected in an oblique direction to have an acute angle with the tangent line of the second upper inner portion (210). The second support portion (220) may include a second support plate (221) formed in the center and second protrusion plates (223) formed at both ends of the second support plate (221).

The second support plate (221) is formed in the central area of the second support member (220) and may be formed as a flat plate-shaped plate. The second support plate (221) may include a protruding surface having a plurality of concave grooves and convex grooves on the inner surface facing the first support plate (121), and may include a protruding surface having the same shape as the inner surface on the outer surface facing the third support plate.

The second protruding plate (223) is arranged at both ends of the second support plate (221) and formed on both sides of the second support portion (220), and may be formed as a plate with a protruding shape.

The second protruding plate (223) may, for example, protrude outwardly. The second protruding plate (223) may be formed so that its cross-section has a semicircular shape.

The second protrusion plate (223) may, as another example, protrude inwardly facing the first support member (120). At this time, the second protrusion plate (223) may be formed so that a portion of its cross-section has a semicircular shape, and the protruding end may be formed in a flat plate shape. In this case, the second protrusion plate (223) may be in surface contact with the end of the first protrusion plate (123), thereby improving the fixing force.

The second support portion (220) is formed to extend from the second upper inner portion (210) and to have a surface facing the first diagonal reinforcing body (100). The second support portion (220) can be formed to be combined with the first support portion (120) and the third support portion (320). The second support portion (220) is first fixed to the first support portion (120) through a fixing member at a position overlapping the first support portion (120). In addition, the second support portion (220) is secondarily fixed to the first support portion (120) and the third support portion (320) through a fixing member at a position overlapping the first support portion (120) and the third support portion (320).

The second support member (220) may include a second stop joint hole (2211) into which a fixing member is inserted so as to be coupled with the first support member (120) and the third support member (320). The second support member (220) is fixed to the first support member (120) and the third support member (320) through the fixing member inserted into the second stop joint hole (2211). The second stop joint hole (2211) is arranged to overlap the first stop joint hole (1211).

The third diagonal reinforcement (300) is connected to the sub-frame (3) at an acute angle as shown in Fig. 6 to reinforce the sub-frame (3). The third diagonal reinforcement (300) is in contact with the sub-frame (3) to support the other side, and is connected to the first diagonal reinforcement (100) to support the sub-frame (3). The third diagonal reinforcement (300) includes a second lower inner portion (310) and a third support portion (320) that are formed integrally. The third diagonal reinforcement (300) can be formed of the same material as the first diagonal reinforcement (100).

The second lower inner insert (310) comes into contact with the sub-frame (3) and, together with the first lower inner insert (130), disperses the load concentrated on the sub-frame (3). The second lower inner insert (310) is configured in an inner insert shape so that the other side of the sub-frame (3) can be inserted, and is formed symmetrically with the first lower inner insert (130).

The second lower inner portion (310) may be curved outwardly so that the sub-frame (3) is positioned in a curved area, similar to the first lower inner portion (130), but is not limited thereto and may be configured to have an angled shape in the outward direction.

One end of the second lower insertion portion (310) may include a second lower coupling portion (311) that is rotatably coupled with the first diagonal reinforcement body (100). The second lower insertion portion (310) may be separated from or coupled with the first diagonal reinforcement body (100) through the second lower coupling portion (311).

The second lower coupling part (311) can be fitted and connected to the first lower coupling part (131). The second lower coupling part (311) can include, for example, a second lower coupling piece (3111) and a second lower coupling hole (3113) formed spaced apart from the second lower coupling piece (3111). The second lower coupling piece (3111) is formed in the same shape as the first lower coupling piece (1311), but is inserted into and fitted into the first lower coupling hole (1313). The second lower coupling hole (3113) is formed as a fitting hole into which the first lower coupling piece (1311) described above is inserted and fixed.

The other end of the second lower inner portion (310) is connected to the third support portion (320). The third support portion (320) is configured in an oblique direction to form an acute angle with the sub-frame (3). The third support portion (320) is formed to extend from the second lower inner portion (310) and to have a surface facing the second diagonal reinforcing body (200). The third support portion (320) is connected in an oblique direction to form an acute angle with the tangent line of the second lower inner portion (310). The third support portion (320) can be formed to be combined with the first support portion (120) and the second support portion (220).

The third support part (320) is formed to have a surface facing the second support part (220), and the third support part (320) is formed shorter than the first support part (120) and the second support part (220). The third support part (320) overlaps the first support part (120) and the second support part (220) in one direction. That is, the third support part (320) is formed to overlap the first support part (120) and the second support part (220) in a direction perpendicular to the longitudinal direction.

The third support member (320) may include a third stop-joining hole (321) that can be joined to the first support member (120) and the third support member (320). The third support member (320) is secured to the first support member (120) and the second support member (220) through a fixing piece inserted into the third stop-joining hole (321). The third stop-joining holes (321) are formed in multiple numbers spaced apart from each other, but are arranged to overlap the first stop-joining hole (1211) and the second stop-joining hole (2211).

The third support member (320) may include a third support plate formed at the center and a third protruding plate formed at both ends of the third support plate. The third support plate may include a concave surface having a plurality of concave grooves and convex grooves on the inner surface facing the second support plate (221).

The third protruding plate is arranged on both ends of the third support plate and formed on both side surfaces of the third support member (320), and may be formed as a plate with a protruding shape.

Hereinafter, a truss diagonal reinforcement member (10) according to another embodiment of the present invention will be described. A description of the same configuration as the above-described configuration of the truss diagonal reinforcement member (10) according to another embodiment of the present invention will be omitted.

Figure 7 is a perspective view of a truss diagonal reinforcement member (10) according to another embodiment of the present invention.

Referring to FIG. 7, a truss diagonal reinforcement member (10) according to another embodiment of the present invention includes a first diagonal reinforcement member (100), a second diagonal reinforcement member (200), and a third diagonal reinforcement member (300). The third diagonal reinforcement member (300) includes a second lower inner portion (310), a third support member (320), and further includes an extension block (323) connected to the third support member (320).

The extension block (323) is hinge-joined to one end of the third support member (320) by a hinge (3231) so as to be folded with the third support member (320). The extension block (323) is rotated about the hinge (3231) and extended from the third support member (320) and fixed. The extension block (323) may include a fourth end joining hole (not shown) that overlaps the first to third end joining holes (321). The extension block (323) may be tertiarily fixed to the first support member (120) to the third support member (320) by a fixing member through the fourth end joining hole (not shown) that overlaps the first to third end joining holes (321) in a folded state.

At this time, the fourth stop joint hole (not shown) can be formed to overlap the first and second stop joint holes in a state where the extension block (323) is not folded. That is, even when the extension block (323) is rotated and extended and fixed from the third support member (320), the fourth stop joint hole (not shown) can overlap the first and second stop joint holes (2211) and be fixed to the first support member (120) and the second support member (220).

Although the present invention has been described with reference to the embodiments shown in the attached drawings, these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

10: truss diagonal reinforcement, 100: first diagonal reinforcement,
110: First upper inner part, 120: First support part,
130: 1st lower internal part, 200: 2nd diagonal reinforcement,
210: Second upper inner part, 220: Second support part,
300: 3rd diagonal reinforcement, 310: 2nd lower inner part,
320: Third Support Division.

Claims (4)

In a truss diagonal reinforcement bar for reinforcing the main frame and sub-frame of a building arranged parallel to each other in a diagonal direction,
A first diagonal stiffener supporting one side of the main frame and the subframe and being joined to the main frame and the subframe so as to have an acute angle;
A second diagonal reinforcement member rotatably connected to one end of the first diagonal reinforcement member and joined to the main frame at an acute angle to support the other end of the main frame; and
A third diagonal reinforcement member is rotatably connected to the other end of the first diagonal reinforcement member and is joined to the sub-frame at an acute angle to support the other end of the sub-frame.
The first diagonal reinforcement is,
A first upper inner insertion portion including a first upper joining portion formed so that one side of the main frame is inserted and one end of which is rotatably connected to the second diagonal reinforcing body;
A first support member formed by extending from the other end of the first upper inner portion and configured to have an acute angle with the main frame and the sub-frame, and having a surface facing the second diagonal reinforcement member; and
A truss diagonal reinforcement member including a first lower inner insertion portion that is formed by extending from one end of a first support portion and into which one side of a sub-frame is inserted, and has one end rotatably connected to a third diagonal reinforcement member.
delete In the first paragraph,
The second diagonal reinforcement is,
A second upper inner portion including a second upper coupling portion formed to be inserted into the other side of the main frame and having one end rotatably coupled to the first upper coupling portion; and
A second support portion is formed by extending from one end of the second upper inner portion and configured to have an acute angle with the main frame, and includes a surface facing the first support portion.
The third diagonal reinforcement is,
A second lower insertion portion including a second lower coupling portion formed to be inserted into the other side of the subframe and having one end rotatably coupled to the first lower coupling portion; and
Includes a third support member formed by extending from one end of the second lower inner portion and configured to have an acute angle with the subframe;
The third support member is a truss diagonal reinforcement member formed to overlap the first and second support members in one direction.
In the third paragraph,
The first to third supports are fixed to the overlapping surfaces as fixed pieces,
A truss diagonal reinforcement member in which the first and second supports are additionally fixed as fixed pieces on a surface that does not overlap with the third support.

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