KR102671439B1 - Brackets to prevent movement of structures using PreStressed wale and Square Strut Method - Google Patents

Abstract

The present invention relates to a bracket for preventing the flow of structures in an earth retaining method. In the earth retaining method, a structure is constructed in which braces and auxiliary interpolations are positioned vertically and horizontally using square steel pipes or steel beams, and the structural rigidity of the braces and auxiliary interpolations located vertically and horizontally is improved. In the anti-flow bracket of a structure using an earth retaining method that connects a brace and an auxiliary beam to prevent overflow, the anti-flow bracket (100) is a cross-sectional upper or lower horizontal surface perpendicular to the longitudinal direction of the brace composed of a square steel pipe or steel beam. A binding horizontal piece 112 is formed with a length corresponding to the length of the binding horizontal piece 112, and a connecting vertical piece 114 is formed downward along a vertical line by half or greater than half of the left and right vertical length of the cross section of the brace on the left and right of the binding horizontal piece 112. A connection hinge bracket 110 is formed symmetrically and has a first hinge member 116 of either a male or a female formed at the lower end of the connection vertical piece 114 to be hinged; A second hinge section 122 of either a male or a female hinged corresponding to the first hinge section 116 formed at the bottom of the connection vertical piece 114 of the connection hinge bracket 110 is formed at the upper end of the brace. The support vertical pieces 124 are integrally formed left and right symmetrically directly below the second hinge member 122 to extend to a length corresponding to the left and right vertical lengths, and are respectively hinged with the left and right connection vertical pieces 114 of the connection hinge bracket 110. At least one fastening bolt hole is provided to be bolted to one side of the upper part of the auxiliary beam, which is made of a square steel pipe or steel beam on the lower side that is bent at a right angle to the opposite side of the support vertical piece 124, which is symmetrical, and intersects the brace. It relates to a bracket for preventing flow of a structure using an earth retaining method, characterized in that it is formed by a binding hinge bracket (120) on which a horizontal fixing piece (126) is formed.

Description

Brackets to prevent movement of structures using PreStressed wale and Square Strut Method}

The present invention relates to a bracket for preventing the flow of a structure using the black retaining method, and more specifically, to installing a brace using a square steel pipe or steel beam (H-beam, I-beam) used in the retaining method, and installing a brace using a square steel pipe or steel beam. The bracket that binds the auxiliary beams that are installed cross-over using beams to prevent the flow of the braces is divided into three, so that only the parts corresponding to the upper and lower lengths of the cross sections orthogonal to the longitudinal direction of the braces can be replaced and used, so the entire bracket can be used. This relates to a bracket for preventing the flow of structures using the earth retaining method, which is more economical as it allows replacement and use of only some parts without the need to have various sizes, and makes bonding and bracket combination easier.

Generally, in civil engineering and construction sites, laying the foundations of structures and buildings is preceded by temporary retaining work to prevent soil collapse during excavation work. This temporary retaining work is carried out using various methods depending on the situation and environment. do.

Recently, the earth retaining method (PS-P method) is mainly used. The earth retaining method (PS-P method) was developed to improve the shortcomings and limitations of the earth retaining temporary method (conventional bracing method), and its main features include increasing constructability and improving economic feasibility by expanding the work space and reducing the amount of input. It is ordered.

The main content of the earth retaining method (PS-P method) is that the strips and braces, which are essential during brace construction, are replaced with PS-waps and square steel pipe braces, respectively. Here, the PS-band expands the spacing between braces, and the closed-section square steel pipe brace makes it possible to omit the reinforcement materials that were previously installed, thereby dramatically improving constructability and economic efficiency through two configurations: the PS-band and the square steel pipe brace. It has been improved.

Through this, the difference between the conventional strut method and the earth retaining method (PS-P method) can be easily confirmed, and the earth retaining method (PS-P method) can secure a wider gap when installing braces compared to the conventional strut method. In other words, compared to the strut spacing of the conventional strut method, which was usually around 3m, the earth retaining method (PS-P method) can be expanded to about 7.5m, and by securing such a wide spacing, an expanded work space is secured. It is possible to improve construction speed and shorten construction time due to convenience of work for workers and easy use of various equipment.

Another main feature of the earth retaining method (PS-P method) is the reduction in the amount of steel. This means that economical construction is possible and the use of steel materials is minimized to secure work space. In the earth retaining method (PS-P method), the amount of steel is reduced due to the braces that are omitted through PS-bands, and the conventional two-row H -The section where the beam was installed can be replaced with just one row of square steel pipe braces. Alternatively, it is possible to omit the reinforcement, and in the section where 2 rows are changed to 1 row, the brace reduction rate is about 50%.

In addition, the earth retaining method (PS-P method) is a factory manufacturing-on-site assembly method rather than an on-site manufacturing method, so it can be installed and dismantled only by bolting rather than welding.

During the field assembly process of the earth retaining method (PS-P method), which has these advantages, flow is more likely to occur compared to existing welding. First of all, there is a problem that flow due to the load of the steel can easily occur at a distance from the existing beam or steel used as a brace. After the beam or steel flow is fully assembled, vibration occurs, and the occurrence of such vibration is highly likely to cause safety problems in earth retaining construction, so auxiliary beams are installed to connect the braces, and usually the braces are the final beams. In the direction, the auxiliary beam is connected to the brace in the transverse direction to prevent the flow of the brace.

Accordingly, structural rigidity is increased by connecting beams used as braces or auxiliary beams installed to prevent and fix the flow of force, and connection of square steel pipes and H-beams used as braces and auxiliary beams, or between H-beams and H-beams. A separate bracket is used to prevent flow through the connection between pipes or between square steel pipes.

The brackets used to prevent the flow of beams or steel used as such braces or auxiliary beams are usually of a shape corresponding to the edge of a square steel pipe or beam, that is, as shown in Figure 1, the open part with the letter "ㄷ" is below. It has a shape in which horizontal pieces (3) for fastening bolts protrude to the left and right on a bracket that is erected at a right angle facing the side.

Looking at the installation structure of the H-beam or square steel pipe, which is a structure of the conventional earth retaining method as described above, the brace of the square steel pipe is installed in the longitudinal direction, and the auxiliary beam is installed to increase structural rigidity by crossing the H-beam of the brace. To prevent flow between the individual components of the square steel pipe and H-beam, a flow prevention bracket is installed and used in the field as shown in Figure 1.

However, conventional brackets for preventing flow have the problem of having to individually manufacture a configuration that meets the specifications of a square steel pipe or H-beam. The commonly used standard is to use square steel pipes or H-beams with a width of 300mm to 350mm, but there is a problem in that individual brackets must be manufactured according to the above standards, which is not economical.

Meanwhile, in order to further improve this, as shown in Figure 2, the upper horizontal piece of the conventional bracket is divided in half and hinged. However, this also has the problem of having to be manufactured according to specifications, and rather, the two bisected pieces are each divided into two halves. There is a hassle to prepare. dt

The conventional bracket is formed with a horizontal part (1) corresponding to half of the upper length of the H-beam, and a vertical part (2) is formed by bending at right angles on the left and right outer sides of the H-beam and lowering it to the bottom of the vertical part. It is configured to form a horizontal piece (3) for binding with a fastening hole for binding to the auxiliary beam, and the brackets corresponding to each half are joined on the left and right sides of the H-beam facing each other, and then pinned to the central hinge portion (4). After joining through coupling, it is configured to control the flow of the H-beam, which is a support beam, by bolting it to the auxiliary beam through the fastening hole of the horizontal piece for binding.

Here, when fastening bolts through the fastening hole of the horizontal piece, when fastening force is applied to the auxiliary beam side, the vertical part is pulled and the bent part is deformed, and as a result, the force is transmitted to the hinged part in the direction opposite to the fastening force direction, causing the hinge part to move upward. There is a problem that it rises or is easily damaged, which leads to the problem of exposing the vulnerability of the square steel pipe or H-beam to flow, resulting in the loss of the function of the bracket to prevent flow. Furthermore, due to the above problems, work time is long, disassembly time after use is long, and reuse is difficult due to damage to the bracket during the disassembly process.

Accordingly, the conventional bracket has the following problems. First, if the length of the upper or lower side of the H-beam is not precisely formed during the hinge connection process, the hinge connection itself may not be achieved, or after the hinge connection, the left and right sides do not adhere closely to the side of the H-beam and a space appears. There is a problem that it is difficult to prevent left and right movement of the H-beam.

Second, if the length varies depending on the width of the upper and lower surfaces of the H-beam due to the two-part configuration, all two-part brackets of the size appropriate for the H-beam must be produced, so it can be used by replacing only part of the existing parts. impossible.

Third, in the process of fastening bolts to the auxiliary beam, the vertical length is shortened and if excessive fastening is performed, the left and right sides of the hinge joint in the upper center are pulled downward, causing deformation, which causes the problem of the hinge joint rising upward. There is a problem that solidarity becomes weak. That is, during the fastening process, force is generated vertically, and the hinge portion is rotatable, so deformation of the bent portion causes the hinge joint portion to lift, making the binding vulnerable.

Fourth, due to the third problem, deformation of the hinge part and bending part easily occur, which makes reuse difficult and requires complete replacement.

Therefore, there is a need to improve the bracket to prevent the flow of the conventional braces as described above, and the flow of the braces is urgently needed as problems with safety accidents may be raised not only through the earth retaining method but also when installing the braces on slopes or cut surfaces. There is a situation.

Meanwhile, as a technology that is being disclosed to perform a similar function as described above, the H-beam safety connection device is being disclosed in Korea Registered Utility Model No. 20-0490975, registration date of January 22, 2020.

The safety connection device is a safety connection device that allows semi-permanent use without forming a drilling hole in the brace and connects it by drilling only a hole in the auxiliary beam. The safety connection device is applied to the H-beam, and the left and right edge sides of the safety connection device serve as holders on the lower horizontal piece with the H-beam lying at a right angle, so that the brace is coupled to the auxiliary beam.

This can only be applied to H-beams or I-beams, and cannot be applied to square steel pipes. In addition, since only the lower part of the H-beam or I-beam is bound, there is a problem that it is difficult to control when flow due to vibration occurs on the upper side. However, although it is characterized by the fact that it can be used universally for any size of H-beam or I-beam, due to the nature of the site, flow due to external shock or vibration can easily occur, and as a result, the flow of the installed beam causes the bonding of the facility. This may be released or problems with limited support may occur.

1. Republic of Korea Registered Utility Model No. 20-0490975, registration date: January 22, 2020.

Therefore, the present invention was created to solve the above-mentioned problems, and the anti-flow bracket is divided into three parts, and only one part of them is manufactured and replaced according to the specifications of a square steel pipe or H-beam, and the rest is reused. It has a more economical advantage as it can be used without the need for manufacturing according to separate standards, and precision manufacturing is possible to increase the cohesion of the brace, which can increase cohesion, and deformation due to fastening force is minimized to improve construction quality, making it a square steel pipe. Alternatively, the purpose is to provide a bracket for preventing the flow of a structure using an earth retaining method that can prevent the flow of a brace made of steel beams (H-beam, I-beam).

In order to achieve this purpose, the bracket for preventing structural flow in the earth retaining method according to the present invention is composed of a structure in which braces and auxiliary interpolations are positioned vertically and horizontally using square steel pipes or steel beams in the earth retaining method, and the braces and auxiliary interpolations are positioned vertically and horizontally. In the structural anti-flow bracket of the earth retaining method that connects the brace and the auxiliary beam to improve the structural rigidity of the interpolation and prevent the flow, the anti-flow bracket (100) is perpendicular to the longitudinal direction of the brace composed of a square steel pipe or steel beam. A binding horizontal piece 112 is formed with a length corresponding to the length of the upper or lower horizontal surface of the cross-section, and a connecting vertical piece is formed downward along a vertical line in half or greater than half of the left and right vertical lengths of the cross section of the brace to the left and right of the binding horizontal piece 112. (114) is formed symmetrically left and right, and the connection vertical piece 114 has a first hinge bracket 110 formed at the lower end of the connection vertical piece 114 to be hinged, and a first hinge member 116 of either a male or a female is formed; A second hinge section 122 of either a male or a female hinged corresponding to the first hinge section 116 formed at the bottom of the connection vertical piece 114 of the connection hinge bracket 110 is formed at the upper end of the brace. The support vertical pieces 124 are integrally formed left and right symmetrically directly below the second hinge member 122 to extend to a length corresponding to the left and right vertical lengths, and are respectively hinged with the left and right connection vertical pieces 114 of the connection hinge bracket 110. At least one fastening bolt hole is provided to be bolted to one side of the upper part of the auxiliary beam, which is made of a square steel pipe or steel beam on the lower side that is bent at a right angle to the opposite side of the support vertical piece 124, which is symmetrical, and intersects the brace. It is characterized in that it is formed by a binding hinge bracket 120 on which a horizontal fixing piece 126 is formed.

Here, the inner length where the binding horizontal piece 112 and the connecting vertical piece 124 of the connecting hinge bracket 110 are bent at right angles are formed to match the length of the upper or lower horizontal surface of the cross section orthogonal to the longitudinal direction of the brace. As the left and right lengths of the inner lower surface of the binding horizontal piece 122 match the length of the upper surface of the brace, the binding horizontal piece 122 can be coupled to the brace in close contact without forming a flow space and restrict the flow. Characterized in that, from one side of the support vertical piece 124 extending directly below the second hinge member 122 of the binding hinge bracket 120, toward the upper surface of the horizontal fixing piece 126 bent at a right angle at the bottom of the support vertical piece. It is also preferable that at least one reinforcement rib 128 is formed at an angle.

The present invention divides the anti-flow bracket into three parts so that only one part can be manufactured and replaced according to the specifications of a square steel pipe or H-beam, and the remaining parts can be used without the need for reuse or manufacturing according to separate specifications, making it more economical. There is an advantage, and precision manufacturing is possible to increase the cohesion of the brace, which can increase the cohesion. Deformation due to the fastening force is minimized and construction quality can be improved. It is composed of square steel pipes or steel beams (H-beam, I-beam). It has the effect of preventing the movement of the brace.

Figure 1 is a perspective view showing an embodiment of a conventional anti-flow bracket.
Figure 2 is a perspective view showing another embodiment of a conventional anti-flow bracket.
Figure 3 is a perspective view of the installation state of the bracket for preventing structural movement of the earth retaining method according to the present invention.
Figure 4 is a perspective view of a bracket for preventing structure flow in the earth retaining method according to the present invention.
Figure 5 is an exploded perspective view of a bracket for preventing structural flow in the earth retaining method according to the present invention.
Figure 6 is a front view of a bracket for preventing structure flow in the earth retaining method according to the present invention.
Figure 7 is a perspective view of another embodiment of a bracket for preventing structure flow in the earth retaining method according to the present invention.
Figure 8 is a front view showing an installation example of another embodiment of a bracket for preventing structural movement of the earth retaining method according to the present invention.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and will be implemented in many different forms.

In this specification, the present embodiments are provided to ensure that the disclosure of the present invention is complete and to fully inform those skilled in the art of the scope of the invention. And the present invention is only defined by the scope of the claims. Accordingly, in some embodiments, well-known components, well-known operations and well-known techniques are not specifically described in order to avoid ambiguous interpretation of the present invention.

Like reference numerals refer to like elements throughout the specification. Also, the terms used (mentioned) in this specification are for describing embodiments and are in no way intended to limit the present invention. As used herein, singular forms also include plural forms, unless specifically stated otherwise in the context. Additionally, components and operations referred to as 'including (or, including)' do not exclude the presence or addition of one or more other components and operations.

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used with meanings that can be commonly understood by those skilled in the art to which the present invention pertains. Additionally, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless they are defined.

Hereinafter, with reference to the attached drawings, technical features according to embodiments of the bracket for preventing structural movement of the roll-type earth retaining method according to the present invention will be described in detail.

Figure 3 is a perspective view of the installation state of the bracket for preventing the flow of the structure of the earth retaining method according to the present invention, Figure 4 is a perspective view of the bracket for preventing the flow of the structure of the earth retaining method according to the present invention, and Figure 5 is a structure of the earth retaining method according to the present invention. It is an exploded perspective view of a bracket for preventing flow, Figure 6 is a front view of a bracket for preventing flow in a structure of the earth retaining method according to the present invention, Figure 7 is a perspective view of another embodiment of a bracket for preventing flow in a structure in the earth retaining method according to the present invention, and Figure 8 is This is a front view showing an installation example of another embodiment of a bracket for preventing structural movement of the earth retaining method according to the present invention.

The bracket for preventing the flow of structures in the earth retaining method according to the present invention is an improvement over the existing problems. The anti-flow bracket is divided into three parts and only one part of them is manufactured according to the specifications of the square steel pipe or steel beam (H-beam, I-beam). It is constructed to be manufactured and replaced, and the rest can be used without the need for reuse or manufacturing according to separate specifications, which has a more economical advantage. It is a precision device to increase the binding force to prevent the flow of the prop of the earth retaining method composed of square steel pipes or steel beams. It is possible to manufacture, and construction quality can be improved by minimizing deformation due to fastening force. It is possible to secure safety by preventing the flow of braces made of square steel pipes or steel beams (H-beam, I-beam). This is an earth retaining method. A structure is constructed using square steel pipes or steel beams to position the braces and auxiliary interpolations vertically and horizontally, and the structure uses an earth retaining method to fasten the braces and auxiliary beams to improve the structural rigidity of the braces and auxiliary interpolations located vertically and horizontally and to prevent flow. We would like to launch a prevention bracket.

Accordingly, the flow prevention bracket 100, which is a structure flow prevention bracket of the earth retaining method according to the present invention, is divided into three, and as shown in Figure 5, the width corresponding to the length perpendicular to the longitudinal direction of the square steel pipe or steel beam A connection hinge bracket (110) in the shape of "┏┓" and a binding hinge bracket (120) in the shape of "┛" and "┗" that are hinged so that they can rotate to the left and right of the connection hinge bracket (110) and are symmetrically coupled to the left and right. It is composed.

Here, the connection hinge bracket 110 is installed to prevent the flow of square steel pipes or steel beams used in various fields such as earth retaining methods, and as an embodiment, it is a support and auxiliary to the earth retaining method using square steel pipes or steel beams. I would like to explain it in terms of beam configuration. The connection hinge bracket 110 is a support beam of a typical earth retaining method and is configured to be coupled in a direction perpendicular to the longitudinal direction to be coupled to the upper surface of the auxiliary beam on the lower side, as shown in Figures 3 to 6. , It consists of a binding horizontal piece (112), a connecting vertical piece (114), and a first hinge section (116).

The binding horizontal piece 112 is formed in a cross-sectional shape in a direction perpendicular to the longitudinal direction of the brace and has a length corresponding to the length of the upper or lower horizontal surface. Here, the length of the binding horizontal piece 112 can be precisely manufactured with respect to the length of the horizontal surface of the square steel pipe or steel beam, and through this, precision is also secured at the bent portion where the connecting vertical piece 114, which will be described later, is bent at a right angle downward. It can be tightly coupled to the brace without unnecessary space, so flow cannot occur due to the flow area of the brace due to space formation.

Meanwhile, the connecting vertical piece 114 is precisely adjusted to a length corresponding to the left and right lengths of the upper or lower sides of the square cross-section of the square steel pipe or steel beam constituting the brace. It is designed to fit closely to the side and limit the flow of the brace, and is configured to be formed downward in a vertical line by half or greater than half of the left and right vertical length of the cross section of the brace on the left and right of the binding horizontal piece 112.

The first hinge member 116 is configured to be a reference that can be rotated to be coupled or released on the auxiliary beam to prevent movement of the brace by the binding hinge bracket 120, which will be described later, and the connecting vertical piece 114 described above. ) It is formed as either a male or female to be hinged at the lower end.

As described above, the binding hinge bracket 120 is bolted to the upper surface of the auxiliary beam that is installed across the brace so as to be bound while surrounding the upper and left and right edges of the brace by the connecting hinge bracket 110, so that the brace can move. It is provided to prevent, and as shown in FIGS. 3 to 6, it consists of a second hinge member 122, a vertical support piece 124, and a horizontal fixing piece 126.

The second hinge member 122 is formed to enable binding and disengagement by rotating the binding hinge bracket 120 around the hinge coupling portion to the outside of the brace, and is a connecting vertical piece of the connecting hinge bracket 110. (114) It is composed of one of a male and a female that are hinged in response to the first hinge section 116 formed at the bottom. That is, if the first hinge member is female, the second hinge member is male, and if the first hinge member is male, the second hinge member is female.

The support vertical piece 124 is configured to surround the side of the brace on an extension of the connection vertical piece 114, in which the above-described second hinge 122 is formed at the upper end and is symmetrical to the left and right of the connection hinge bracket 120. In this way, the support vertical pieces 124 are integrally formed left and right symmetrically directly below the second hinge member 122 to extend to a length corresponding to the left and right vertical lengths of the brace, so that the left and right connection vertical pieces 114 of the connection hinge bracket 110 are formed. It is configured to be hinged to each other. That is, the support vertical piece 124 is configured to prevent the flow by wrapping the vertical length on the left and right sides of the brace so that the horizontal fixing piece 126, which will be described later, is close to or in contact with the upper surface of the auxiliary beam.

The horizontal fixing piece 126 is configured to be bolted to the upper surface of the auxiliary beam so that the connection hinge bracket 120 surrounding the upper surface and left and right sides of the brace is in close contact with the auxiliary beam side to prevent movement, and is formed left and right symmetrically. At least one fastening bolt hole is formed to be bolted to the upper surface of the auxiliary beam, which is made of a square steel pipe or steel beam on the lower side that is bent at a right angle to the opposite side of the support vertical piece 124 and intersects the brace.

As mentioned above, the bracket for preventing flow of structures in the earth retaining method of the present invention according to this configuration includes a connecting hinge bracket 110 that surrounds the top and left and right sides of the brace to prevent flow, and binds it to the auxiliary beam to prevent the flow of the brace. It is formed as a binding hinge bracket 120 to prevent, as shown in FIGS. 3, 4, and 6, a horizontal binding piece with a length corresponding to the length of the upper side on the square cross-section along the longitudinal direction of the brace. (112) is formed. Thereafter, the connecting vertical piece 114 is bent at a right angle so that the left and right sides correspond to the vertically bent corners of the upper length of the brace and correspond to the left and right vertical surfaces, so that the overall shape is composed of a "┏┓" shape.

As shown in FIG. 6, the above shape is intended to ensure that the upper surface of the brace and the three sides of the left and right sides correspond precisely, and by manufacturing only the connecting hinge bracket 110 separately according to the length of the upper side of the brace, There is an advantage in that only a part of the connecting hinge bracket that can be precisely adhered to the size of the brace is manufactured without the problem of having to manufacture it, and the connecting hinge bracket can be reused and used more economically.

Furthermore, during the bolt fastening process, when the bolt is fastened through the fastening bolt hole formed in the horizontal fixing piece 126 of the binding hinge bracket 120, the force generated according to the fastening force in the left and right directions of the present invention is applied and transmitted to the left and right. Even if the pulling external force is not the same, the deformation rate is reduced by the connection hinge bracket 110 that is precisely manufactured and closely attached to the size of the brace, and it is difficult to form a flow space due to deformation, so the brace can be fixed more stably.

A first hinge member 116 is formed at the bottom of the connection vertical piece 114 formed on the left and right sides of the connection hinge bracket 110 formed as described above, and the left and right sides are fastened with bolts through the hinge combination of the binding hinge bracket 120. By binding, the strut movement is prevented.

That is, the bracket for preventing structural movement of the earth retaining method according to the present invention is a square shape in which the inner length of the connecting horizontal piece 122 and the connecting vertical piece 124 of the connecting hinge bracket 120 are bent at a right angle is orthogonal to the longitudinal direction of the brace. Since it can be manufactured to match the upper length in the cross section, the left and right lengths of the lower surface of the binding horizontal piece 122 correspond closely to the upper surface of the brace, making it possible to join without forming a flow space, thereby limiting the flow of the brace. It becomes possible.

Therefore, when the hinge coupling portion is formed on the upper surface of the brace, as in the case of a conventional two-part bracket, the problem caused by the creation of flow space in the coupling method by leaving a gap for smooth coupling of the hinge coupling can be solved.

Furthermore, as mentioned earlier, in the case of a conventional bracket divided into two parts according to the size of the brace, the entire bracket must be produced separately, but the present invention is divided into three parts, so that the binding horizontal piece (122) has a length corresponding to the horizontal surface of the brace. ) is produced in a size corresponding to the size of the strut, which has the advantage that manufacturing parts are simpler than before, and some parts can be used as is without the need to newly manufacture them. In other words, if the length of the upper and lower surfaces of the H-beam varies depending on the width due to the conventional two-part configuration, all two-part brackets of the size appropriate for the H-beam must be produced, so only some of the existing parts are used by replacing them. It is more economical by solving this impossible problem.

Meanwhile, as mentioned above, the present invention, when fastening bolts through the fastening bolt hole formed in the horizontal fixing piece 126 of the binding hinge bracket 120 during the bolt fastening process, is generated according to the fastening force in the left and right directions of the present invention. Even if the external force pulled as the force is applied and transmitted to the left and right is not the same, the deformation rate is reduced by the connection hinge bracket 110 that is precisely manufactured and closely attached to the size of the brace, and it is difficult to form a flow space due to deformation, so the brace is fixed. This can be done more reliably.

In other words, in the process of fastening bolts to the auxiliary beam, the vertical length is shortened and if excessive fastening is performed, the left and right sides of the hinge joint in the upper center may be pulled downward, causing deformation, and the fastening force on the left and right sides is often not the same. Rather, in the past, there is a hinge joint in the center of the upper side, so when force is applied downward by the fastening force on the left and right sides, the force is applied based on the corner side that secures free space for the hinge joint, and the corner side is deformed and the hinge is Due to the problem of the coupling portion rising upward, the problem of weakening the bond to prevent the brace from moving can be solved by symmetrically constructing the hinge coupling portion of the present invention left and right. Due to the rising action of the conventional hinge coupling portion, There is also an advantage in that the problem of difficulty in reusing the hinge area due to damage or deformation can be solved at the same time.

Moreover, as mentioned above, the present invention can be manufactured to precisely correspond to the specifications of the brace, so there is no lifting phenomenon between the brace and the bracket, and it is possible to prevent the brace from moving without binding vulnerability.

On the other hand, as briefly mentioned earlier, reuse is easy because deformation of the hinge part or bending part can be resolved, and the flow of the brace can be maintained by replacing only the connecting hinge bracket appropriate for the size of the brace without the need to replace the entire brace. This can also be an economic advantage because it can be prevented.

That is, the present invention is fastened by taking into account the length of the bolt fastened to the auxiliary beam without the need for a separate clearance so that the first hinge member at the bottom of the connecting vertical piece and the second hinge member at the top of the support vertical piece are smoothly coupled. Because this is possible, even if the support vertical piece 124 becomes somewhat shorter due to a change in the size of the brace, it can be solved by stacking washers to adjust the height or by adjusting the length of the bolt, preventing reuse or binding vulnerability to control the flow of the brace and ensure stable construction. It is a self-evident fact that this is possible.

Meanwhile, as shown in FIGS. 7 and 8, a horizontal fixer is bent at a right angle from one side of the support vertical piece 124 extending directly below the second hinge member 122 of the binding hinge bracket 120 to the bottom of the support vertical piece. It is preferable that at least one reinforcing rib 128 is formed slanted toward the upper surface of the piece 126.

The reinforcing rib 128 brings the support vertical piece into close contact with the side of the brace and can generate a supporting force in the left and right flow of the brace, allowing additional response in preventing the brace from flowing. Additionally, when a lateral external force is applied to the brace, the supporting force of the bracket can be improved through the reinforcing ribs.

In the above, the present invention has been described in detail as an embodiment, but the scope of the present invention is not limited thereto, and it is clear that many variations and modifications can be made by those skilled in the art within the scope of the technical idea, and the present invention It will be said to include the scope of substantial equivalence with the embodiment of. The technical features will be described in detail.

1: horizontal part 2: vertical part
3: horizontal piece 4: hinge portion
100: Anti-flow bracket 110: Connection hinge bracket
112: Binding horizontal piece 114: Connecting vertical piece
116: First hinge section 120: Binding hinge bracket
122: Second hinge district 124: Support vertical section
126: horizontal fixing piece 128: reinforcing rib

Claims (3)

In the retaining method, a structure is constructed using square steel pipes or steel beams to position the braces and auxiliary interpolations vertically and horizontally, and the retaining method involves fastening the braces and auxiliary beams to prevent flow and improve the structural rigidity of the braces and auxiliary interpolations located vertically and horizontally. In the structure anti-flow bracket,
The anti-flow bracket 100 has a binding horizontal piece 112 formed with a length corresponding to the length of the upper or lower horizontal surface of the cross section orthogonal to the longitudinal direction of the brace composed of a square steel pipe or steel beam, and a binding horizontal piece ( 112) The connecting vertical piece 114, which is formed downward along a vertical line by half or greater than half of the left and right vertical length of the left and right cross sections of the brace, is formed left and right symmetrically, and the lower end of the connecting vertical piece 114 has either a male or female so as to be hinged. A connecting hinge bracket 110 on which a first hinge section 116 is formed;
A second hinge member 122 of either a male or female hinged corresponding to the first hinge member 116 formed at the bottom of the connection vertical piece 114 of the connection hinge bracket 110 is formed at the upper end of the brace. The support vertical pieces 124 are integrally formed left and right symmetrically directly below the second hinge member 122 to extend to a length corresponding to the left and right vertical lengths, and are hinged to the left and right connection vertical pieces 114 of the connection hinge bracket 110, respectively. At least one fastening bolt hole is provided to be bolted to one side of the upper part of the auxiliary beam, which is made of a square steel pipe or steel beam on the lower side that is bent at a right angle to the opposite side of the support vertical piece 124, which is symmetrical in left and right directions, and intersects the brace. A bracket for preventing flow of a structure using an earth retaining method, characterized in that it is formed of a binding hinge bracket (120) formed with a horizontal fixing piece (126).
According to clause 1,
The inner length of the connecting horizontal piece 112 and the connecting vertical piece 124 of the connecting hinge bracket 110 are bent at right angles to match the length of the upper or lower horizontal surface of the cross section orthogonal to the longitudinal direction of the brace,
As the left and right lengths of the inner lower surface of the binding horizontal piece 112 match the length of the upper surface of the brace, the binding horizontal piece 112 can be coupled to the brace in close contact without forming a flow space and can restrict the flow. A bracket for preventing movement of structures using an earth retaining method, characterized in that:
According to clause 1,
At least one reinforcing rib is inclined from one side of the support vertical piece 124 extending directly below the second hinge member 122 of the binding hinge bracket 120 toward the upper surface of the horizontal fixing piece 126 bent at a right angle at the bottom of the support vertical piece. (128) A bracket for preventing flow of a structure using an earth retaining method, characterized in that it is formed.

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