KR20060036630A - Connecting structure of supporting beams, and reinforcing member used therefor - Google Patents

Abstract

The present invention is to connect the brace to be installed in order to prevent the collapse of the earth wall, by using a bending reinforcement for reinforcing the connection portion, it is possible to reduce the number of bolts used in the brace connection, and to have a structure that is advantageous to secure the stability of the connection It relates to a joint structure of the brace and bending reinforcement for reinforcing the connection used therein.

In the present invention, the upper flange 101, the lower flange 103, made of a steel beam comprising a web 102, the end of the brace 100 is integrally coupled to the end plate 110 made of steel In the connection structure, the space between the end plate 110 and the upper flange 101 and the end plate 110 and the lower flange 103 in a state in which the end plate 110 of both side braces 100 face each other. Bending reinforcement (200a, 200b) is installed in the space between the upper and lower, the bending reinforcement (200a, 200b), the horizontal plate 201 in contact with the upper flange 101 and the lower flange 103 and The vertical plate 202 in contact with the inner surface of the end plate 110 is integrally bent in a bent form to be perpendicular to each other on one side to have a bent shape; The vertical plates 202 of the bending reinforcement members 200a and 200b are integrally bolted to the vertical plates 202 of the bending reinforcement members installed on both side end plates 110 and neighboring braces; The upper flange plate 101 and the lower flange plate 103 of the both side beams 100 connection portions are provided with an upper connecting plate 120 and a lower connecting plate 130 made of steel plates, respectively; The horizontal plate 201 of the bending reinforcement (200a, 200b) is bolted integrally with the upper flange 101 and the lower flange 103, and the upper connecting plate 120 and the lower connecting plate 130, respectively, Provided is a connection structure of a brace and characterized in that the connecting portion is reinforced and a bending reinforcement for connecting portion reinforcement used therein.

Earth wall, brace, connection, reinforcement, bending, bolt

Description

Connecting Structure of Supporting Beams, and Reinforcing Member used therefor}

1 is a perspective view showing a state in which the earth wall is supported by a brace connected by a conventional connection method,

Figure 2 is a detailed view of the circle A of Figure 1, a detailed view of the connection structure of the brace according to the prior art.

Figure 3a is a perspective view showing the structure of the buttress connection according to the present invention,

3B is a perspective view of the perspective view shown in FIG. 3A, inverted so that the bottom of the brace connection part is on the upper surface.

Figure 4 is a perspective view of the bending reinforcement for reinforcing the connection portion used in the support structure according to the present invention.

 Explanation of symbols on the main parts of the drawings

1 earth wall 3 vertical beam

5: panel 10: brace

100: brace 120: upper connecting plate

130: lower connecting plate 200a, 200b: upper and lower bending reinforcement

The present invention relates to a connection structure of a brace to be installed to prevent the collapse of a structure such as earth wall (hereinafter referred to as "earth wall") and to the bending reinforcement for reinforcing the connection used therein, in particular, in connecting the brace By using the bending reinforcement for reinforcing connection, the number of bolts used in the reinforcing connection can be reduced, and the connection structure and connection method of the reinforcing reinforcement for the reinforcing connection used to have a structure that is advantageous for securing stability of the connection, It is about.

In constructing the temporary wall, earth wall, and so on, a brace is installed to support the lateral earth pressure. As a brace, a beam is mainly used, and a plurality of beams are connected when necessary.

In the drawings, Figure 1 is a schematic perspective view showing a state supporting the earth wall as a brace, Figure 2 is a detailed view of the circle A of Figure 1, a schematic diagram showing in detail the connection structure of the brace according to the prior art.

In order to prevent the collapse of the excavation site, as shown in FIG. 1, a vertical beam 3 is mounted in the excavation site. Then, the earth wall 1 is constructed by stacking the panels 5 between the vertical beams 3 and the vertical beams 3 which are inserted. The earth wall 1 is designed to withstand the earth pressure by itself, but when the earth pressure is large, a force for supporting the earth wall 1 so as not to collapse is required. In this way, a support 10 is installed between the facing earth walls 1 to support the earth walls 1 to reinforce the earth walls 1.

In order to support between the facing earth walls 1, the brace 10 should be as long as the space between the earth walls 1, but if the length of the brace 10 is shorter than the space, as shown in FIG. It is used to connect the brace 10 of the length.

FIG. 2 is a detailed view of circle A of FIG. 1, showing a state in which a short brace is connected by a conventional method.

In the construction site, in order to make a brace having a length equal to the distance between the earth walls (1), the brace 10 of a short length is connected. Beams generally used as braces 10 are in addition to the top flange 11, the bottom flange 13, and the web 12, end plates 14 and side surfaces for reinforcing the end plates 14. Reinforcing ribs 15 are provided. The end plate 14 is fillet welded to the end of the brace 10 is installed.

Conventionally, in order to connect the brace 10, at the end of the brace 10, a plurality of through holes are drilled through the upper flange 11 and the lower flange 13, and the brace 10 to be connected is connected to each end plate ( 14) are installed to abut each other. Through-holes are also formed in the end plate 14, respectively. The connecting plate 20 made of steel plates is coupled to the upper flange 11 and the lower flange 13 of the brace 10, and the connecting plate 20 has a through hole formed at an end of each brace 10; The through hole is drilled at the corresponding point.

In this way, in the state where the end plate 14 of both braces 10 are in contact with each other, the upper and lower connecting plates 20 are positioned over the upper flange 11 and the lower flange 13 of both braces 10. , The bolt 22 is passed through the through holes formed in each of the upper flange 11 and the lower flange 13 of the connecting plate 20 and the brace 10, and then tighten the nut 24 from the opposite side to connect the connecting plate ( 20) connect the two braces (10). In addition, the end plates 14 are also coupled to each other by fastening the bolts 22 to the end plates 14 facing each other and fastening with the nut 24.

The brace 10 connected in this way is in contact with the earth wall 1 facing both ends thereof to reinforce the earth wall 1.

In the conventional support structure as described above, the compressive force is transmitted by the end plates 14 which are opposed to each other. In comparison, the bending moment is transmitted entirely by the bolts 22. The greater the number of bolts 22 used, the greater the bending moment stiffness at the brace connection, but in the case of using the bolts 22 a lot, the following disadvantages occur.

First, as the number of bolts used increases, the number of holes to be drilled in the beam and the connecting piece increases accordingly. This drilling operation takes time and cost, and thus lowers the economic efficiency.

In particular, since the through-hole formed in the brace and the through-hole formed in the connecting plate must correspond to each other, a precise drilling operation must be performed, the more the number of bolts used, there is a disadvantage that the more effort and cost is required.

Secondly, the through-holes corresponding to the large number of bolts mean the loss of the beam cross section, which can lead to weakening of the beam cross section and disadvantageous recycling of the beam.

Therefore, in the above connection structure of the reinforcement, reducing the number of bolts required is very advantageous for saving time and cost for the reinforcement connection work, and it is very important that the construction period and construction cost may influence the overall construction of the earthen block. It is recognized as a matter.

The present invention aims to reduce the number of bolts used in the brace connection structure, which is recognized as a very important problem in the construction of the earth block as described above, and significantly reduces the number of bolts used in comparison with the conventional brace connection structure. It is an object of the present invention to provide a new type of support structure and a bending reinforcement for reinforcing the connection used therein, which can be further improved.

In order to achieve the above object, in the present invention, the upper flange, the lower flange, made of a steel beam comprising a web, the end of the connection structure of the brace to which the end plate made of steel is integrally coupled, In a state where the end plates face each other, bending reinforcements are installed at upper and lower portions in the space between the end plate and the upper flange and the space between the end plate and the lower flange, and the bending reinforcement is in contact with the upper flange and the lower flange. A horizontal plate and a vertical plate in contact with the inner surface of the end plate are integrally coupled to each other in a bent form at one side to be bent and bent; The vertical plate of the bending stiffener is bolted integrally with the vertical plate of the bending stiffeners installed on both end plates and neighboring braces; Upper and lower connecting plates each consisting of a steel plate are installed on the upper flange and the lower flange of the both side beam connecting portions; The horizontal plate of the bending reinforcement is bolted integrally with the upper flange and the lower flange, and the upper connecting plate and the lower connecting plate, respectively, is provided with a connecting structure of the reinforcement, characterized in that the connecting portion of the reinforcement.

In addition, in the present invention, the bent reinforcement for reinforcing the reinforcement connecting portion used in the above-mentioned reinforcement connection structure, the horizontal plate in contact with the upper flange or the lower flange of the two reinforcement and the vertical plate in contact with the inner surface of the end plate is inclined form perpendicular to each other at one side Are integrally coupled with; With the end plates of both braces facing each other, the space between the end plate and the upper flange and the end plate and the lower flange are positioned so that the horizontal plates in contact with the flange are bolted to the upper flange and the lower flange, respectively, The vertical plate in contact with the end plate is bolted integrally with the vertical plate of the bend reinforcement provided in both end plates and neighboring braces, reinforcing the connecting portion of the braces is provided with a bending reinforcement for reinforcing the brace connection.

In the following, with reference to the accompanying drawings, specific embodiments of the connecting structure of the reinforcement according to the present invention, and the bent reinforcement for reinforcing connection used therein will be described in detail.

In FIG. 3A, a perspective view showing a support structure according to the present invention is illustrated in FIG. 3A, and FIG. 3B illustrates a perspective view of an inverted bottom surface of the support connector connected to the upper surface in the perspective view illustrated in FIG. 3A. Figure 4 is a perspective view of the bent reinforcement for connection reinforcement used in the support structure according to the present invention.

As shown in Figure 3a and 3b, in the connection structure of the present invention, at the end of the connection portion of the support beam 100 made of steel beams end plate 110 made of steel perpendicular to the support beam 100 by a method such as welding Is integrally attached to each other, when both braces 100 are connected to each other, each end plate 110 is in contact with each other. The brace 100 is composed of an upper flange 101, a lower flange 103 and the web 102, when the steel brace 100 is connected, in the state where the end plate 110 is facing, both braces ( 100, the upper connecting plate 120 and the lower connecting plate 130 made of steel plates are integrally coupled to the upper flange 101 and the lower flange 103, respectively.

The upper connecting plate 120 and the upper flange 101, and the lower connecting plate 130 and the lower flange 103 are bolted, respectively, as shown in the figure, in the present invention is used in the upper and lower It is preferable that there is a difference in the number of bolts 140.

In general, when the bending moment acts on the brace, the positive moment acts on the connection portion of the beam. Thus, the upper flange 101 portion is substantially the compression side, and the lower flange 103 portion is the tension side. Therefore, it is preferable that a larger number of bolts are installed in the portion of the lower flange 103 that is tensioned than the upper flange 101.

In the embodiment shown in the drawings, the upper connecting plate 120 to be coupled to the upper flange 101 of the end of the brace 100 is provided with a total of four bolts 140, two on one side (Fig. 3a) In the lower connecting plate 130, a total of eight bolts 140 are installed on each side (four) (Fig. 3b). That is, two bolts 140 each on both sides of the web 102 of the brace 100 are coupled to the side of the lower connection plate 130 at the side engaging with the lower flange 103 at one end of the brace 100. It is installed.

In the present invention, the space between the end plate 110 and the upper flange 101 and the end plate 110 and the lower flange 103 in a state in which the end plate 110 of both side brace 100 is facing each other. Bending reinforcement (200a, 200b) is installed in the upper and lower portions in the space between.

In the web 102 of the brace 100, a reinforcing rib 111 for supporting the end plate 110 may be installed perpendicular to the center portion of the web 102, as described above. Is installed, the connection between the reinforcing rib 111 and the upper flange 101 and the end plate 110, and between the reinforcing rib 111 and the lower flange 103 and the end plate 110, respectively. The upper bending reinforcement 200a and the lower bending reinforcement 200b are installed. However, the reinforcing rib 111 may not be provided.

Figure 4 shows a perspective view of the lower bending reinforcement (200b) as a bending reinforcement for the reinforcement of the connection portion used in the support structure according to the present invention. As shown in the figure, the lower bending reinforcement (200b) is a two plate made of steel, that is, the horizontal plate 201 and the vertical plate 202 is integrally coupled to each other in a cut form at right angles to each other at one side "a" or The horizontal plate 201 is bolted integrally with the lower flange 103 and the lower connecting plate 130 in contact with the lower flange 103, the vertical plate 202 is In contact with the inner side of the end plate 110 is bolted integrally with the vertical plate 202 of the bending reinforcement provided on both side end plate 110 and the adjacent brace.

In the lower bending reinforcement 200b shown in FIG. 4, the horizontal plate 201 coupled to the lower flange 103 may have a number of bolts coupled to the lower flange 103 and the lower connecting plate 130 coupled thereto. Two bolt holes 210 are formed in conformity. Only one bolt hole 210 is formed in the vertical plate 202 coupled to the end plate 110 so as to be coupled to the end plate 110 by one bolt 140.

Meanwhile, since the inverted shape of FIG. 3B is illustrated in FIG. 3B, the shape of the upper bending reinforcement 200a installed between the upper flange 101 and the end plate 110 may be confirmed below, and the upper bending reinforcement ( The configuration of 200a) is the same as that of the lower bending reinforcement 200b described above. 3A and 3B, however, when the number of bolts installed on the upper flange 101 and the lower flange 103 are different, that is, the number of bolts installed on the upper flange 101 is small. In this case, one bolt hole 210 may be formed in one side plate of the upper bending reinforcement 200a, that is, the plate coupled to the upper flange 101.

In the bending reinforcement (200a, 200b), at the corner where the two plates are coupled, a coupling rib 203 for supporting the two plates is provided in a state integral with the plate by a welding method or the like.

Looking at the method for constructing the brace structure according to the present invention as described above, first, the end plate 110, respectively, to the ends of both braces 100 are integrally coupled by a method such as welding. The end plate 110 is pre-coupled to a conventional beam used as a brace. If necessary, the reinforcing rib 111 is integrally installed between the end plate 110 and the web 102 of the brace 100 by welding or the like. The end plate 110 bores a bolt hole 210. The bolt holes 210 are drilled one by one on each portion of the end plate 110 divided into the web 102 and the reinforcing rib 111 of the brace 100.

Opposite side braces 100 are provided with end plates 110, the end plates 110 are placed to face each other, and then the space between the end plate 110 and the upper flange 101 and the lower flange 103 Install the upper and lower bending reinforcement (200a, 200b) respectively. That is, the horizontal plates 201 of the upper and lower bent reinforcement members 200a and 200b contact the inner surfaces of the upper and lower flanges 101 and 103, and the vertical plates 202 contact the end plates 110. After installing the upper and lower bending reinforcement (200a, 200b), bolts in the bolt hole 210 formed in the vertical plate 202 of the bending reinforcement is installed on the end plate 110 and the adjacent brace 100 on both sides By passing through 140 and fastening with the nut 141, both the end plates 110 on both sides and the vertical plate 202 of the bend reinforcement on both sides are integrally bolted together.

Subsequently, the upper connecting plate 120 and the lower connecting plate 130 are respectively installed on the upper flange 101 and the lower flange 103 at both end portions of the brace 100, and the horizontal plate of the upper bending reinforcement 200a. Through the bolt 140 through the bolt hole 210 formed in the 201 and the upper flange 101, and the upper connecting plate 120, all of them are fastened with a nut 141 and all of them are integrally bolted together In addition, the horizontal plate 201 of the lower bending reinforcement (200b) is also bolted integrally with the lower flange 103 and the lower connecting plate 130 using the bolt 140 and the nut 141.

As described above, in the present invention, by using a bending reinforcing material in bolting the beam, the number of bolts used for joining can be significantly reduced. This can be confirmed by the following calculation method.

First, in the case of the conventional connection structure that does not use the bending reinforcement of the present invention, the bolt to couple the upper flange and the upper connecting plate is to support the tensile force by the shear of the cross section of the bolt. The same is true for bolts that join the bottom flange and the bottom connecting plate. That is, in the conventional connection structure, the bolt that couples the flange and the connection plate is to support the tensile force by one side shear. Therefore, in the conventional structure having one side shear of the bolt, the allowable bending moment M _a of the connection portion is determined by Equation 1 below.

 In Equation 1, n is the number of bolts used, F is the allowable force of the bolt, d is the height of the beam.                     

In contrast, in the case of the present invention, since the bending reinforcement (200a, 200b) is used, both the bolt connecting the upper flange and the upper connecting plate, and the bolt connecting the lower flange and the lower connecting plate all have two-side shear. Therefore, in the structure of the present invention having the second surface the front end of this bolt, allows the bending moment of the connection _(a M) is determined by the equation (2) below.

 As in Equation 1, n is the number of bolts used, F is the allowable force of the bolt, d is the height of the beam.

As can be seen from Equation 1 and Equation 2 above, when the same type and number of bolts are used for beams of the same height, the connection structure according to the present invention has an allowable bending moment which is twice that of the conventional structure. do. Therefore, about the same allowable bending moment, in the connection structure according to the present invention, only about half of the bolt may be used as compared with the conventional connection structure.

Specifically, as can be seen in contrast with the conventional structure shown in FIG. 2 and the embodiment of the present invention shown in FIGS. 3A and 3B, in the conventional case, 12 bolts are used for the upper connecting plate and the lower connecting plate, respectively. In total, 28 bolts are to be used with 4 bolts for end plate connection. However, in the case of the present invention, only 16 bolts are sufficient, as shown in Figs. 3A and 3B.

As such, in the connection structure of the present invention using the bending reinforcement material, the number of bolts to be used for the connection of the reinforcement can be remarkably reduced as compared with the prior art. This reduces the number of bolting operations, reducing the time, effort, and cost associated with connecting the support.

In addition, by reducing the number of bolts used, it is possible to minimize the loss of the beam cross-section, thereby reducing the disadvantages such as weakening the beam cross-section, recycling disadvantages.

Although the technical idea of the connection structure of the support beam of the present invention has been described above with the accompanying drawings, this is illustrative of the best embodiments of the present invention and is not intended to limit the present invention.

Claims (2)

It consists of a steel beam including an upper flange 101, the lower flange 103 and the web 102, the connection structure of the brace 100, which is integrally coupled to the end plate 110 made of steel at the end of the connection portion To In the state where the end plates 110 of both side braces 100 face each other, the space between the end plate 110 and the upper flange 101 and the space between the end plate 110 and the lower flange 103 are Bending reinforcement (200a, 200b) is installed on the upper and lower, The bending reinforcing members 200a and 200b may include a horizontal plate 201 in contact with the upper flange 101 and a lower flange 103, and a vertical plate 202 in contact with an inner surface of the end plate 110. Integrally bent in a vertically bent shape to have a bent shape; The vertical plates 202 of the bending reinforcement members 200a and 200b are integrally bolted to the vertical plates 202 of the bending reinforcement members installed on both side end plates 110 and neighboring braces; The upper flange plate 101 and the lower flange plate 103 of the both side beams 100 connection portions are provided with an upper connecting plate 120 and a lower connecting plate 130 made of steel plates, respectively; The horizontal plate 201 of the bending reinforcement (200a, 200b) is bolted integrally with the upper flange 101 and the lower flange 103, and the upper connecting plate 120 and the lower connecting plate 130, respectively, Connection structure of the braces, characterized in that the connection is reinforced. It is made of a steel beam including the upper flange 101, the lower flange 103, the web 102, the end plate 110 is used to connect the brace 100, which is integrally coupled to the end plate 110 made of steel Bending reinforcement for connection reinforcement, The horizontal plate 201 in contact with the upper flange 101 or the lower flange 103 of both braces 100 and the vertical plate 202 in contact with the inner surface of the end plate 110 are integrally formed in a steel-like shape on one side. Combined; In the state where the end plate 110 of both side brace 100 is in contact with each other, the space between the end plate 110 and the upper flange 101 and the reinforcing end plate 110 and the lower flange 103 is located The horizontal plate 201 in contact with the flange is bolted to the upper flange 101 and the lower flange 103, respectively, and the vertical plate 202 in contact with the end plate 110 has both end plates 110 and neighbors. Bending reinforcement for reinforcing the reinforcement connection portion, characterized in that the bolt is integrally coupled to the vertical plate 202 of the bending reinforcement installed in the reinforcement, to reinforce the connecting portion of the reinforcement (100).

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