KR20090009517A - The long span structure and this construction technique which synthesized an arch and a under tension - Google Patents

Abstract

A long-span structure by composing an arch and under-tension and the construction method thereof are provided to minimize the moment acing on a composite member and to maximize efficiency by composing a girder with the optimized under-tension composed of a compression member and a cable to an arch. A long-span structure by composing an arch and under-tension comprises two supports(100) installed by columns or beams, an arch(200) forming a shaft in the curved shape, an upper chord member(300) composed of a pipe having the fixed curvature, a tension member(400) having the fixed curvature, and many compression members(500) fixed vertically between the upper chord and the tension member and connecting the arch, the upper chord and the tension member.

Description

The long span structure and this construction technique which synthesized an arch and a under tension}

The present invention relates to a long span structure in which an arch and an under tension are synthesized, and a construction method thereof. In particular, the structural advantages of the arch are maximized within the allowable range, and the under tension is synthesized in the arch to these composite members. The present invention relates to a long span structure that synthesizes an arch and undertension with a minimal moment acting and a construction method thereof.

In general, arches have the advantage of minimizing moments and receiving only axial forces, so that the span can be increased if the material used is strong, but the disadvantage is that all the loads of long spans are subjected to axial forces. Arch is difficult to hypothesis if the foundation ground is weak.

Accordingly, in order to solve the problems as described above, an under tension long span and a construction method thereof using the principle of Patent Application 10-0707726 have been proposed.

Under tension long span using the principle of the conventional bow and its construction method, as shown in Fig. 1, the upper chord and the both ends of the upper chord mounted on the points of the two sides installed by the column or beam The cable is connected to and fixed to a pair of fixing brackets installed at the lower side, and the compression member installed between the lower side of the upper chord and the cable and the compressive force upward at the upper chord by the compression member as the tensile force is introduced into the cable. The under tension long span which is transmitted to introduce a load-bearing force, which is a compressive force, is characterized in that the compressing member is joined to the upper chord and the compressing member, and the compressing member and the cable are joined by the clamp.

Under tension long span using the principle of the conventional bow made of the above configuration and its construction method is installed on the point of the beam, the upper chord at the point, then fixedly installed the cable at the bottom, by introducing a tension force to the cable to the compression member By the compressive force is introduced in the present phase, the construction ability to install bridges and building structures is very excellent, high durability and low installation cost can be installed, and if the bridges and building structures are aged, it can be easily repaired. The beauty is beautiful and the efficiency is outstanding.

However, the under tension long span and the construction method using the conventional bow principle having the configuration as described above are structurally very vulnerable to wind pressure and seismic force, which are external forces acting in the horizontal direction of the long span.

Accordingly, the present invention has been made to solve the above problems, to maximize the structural advantages of the arch within the mold allowance (mold height, beam height) within the allowable, and the present current and compression on the arch Optimized under tension consisting of members and cables by combining the designed girders (beams) to minimize the moment acting on these composite members as well as to maximize efficiency, the long span structure that synthesizes arch and under tension and its construction method The purpose is to provide.

The long span structure synthesized by the arch and the under tension according to the present invention for achieving the above object is the point portion of both sides installed by a column or beam; An arch mounted on the point portion, the arch having a member axis curved; An upper chord positioned on both ends of the arch and formed of a pipe having a constant curvature; A tension member joined downward at both ends of the phase current and having a constant curvature; A plurality of vertically fixed between the phase chord and the tension member is installed, characterized in that composed of a compression member for connecting the arch and the phase chord and the tension member.

In addition, in the construction method of the long span structure synthesized with the arch and the under tension according to the present invention for achieving the above object is mounted on the arch of the member shaft is formed in a curved portion at both side points provided by the column or beam, Mounting the upper chord consisting of a pipe having a constant curvature at both ends of the arch, and joining the tension member having a constant curvature at both ends of the image current, and installing a compression member vertically between the upper chord and the tension member, It is characterized by constructing a long span structure by connecting the current and the tension member.

The long span structure synthesized with the arch and the under tension according to the present invention having the configuration as described above and its construction method has the following effects.

First, the present invention minimizes the moment of the arch, and receives only the axial force, thereby maximizing the structural advantages that can be increased between the mold (mold height, height) within the allowable range, and optimized design of under tension girders ( Beam) is synthesized to minimize the moment acting on the arch.

Second, the present invention has the advantage of maximizing the structural efficiency as a structure that can introduce a tensile force as a composite structure of the arch and the under tension.

Third, the present invention has the advantage that all tension members such as cables and steel rods can be used as the tension material.

Fifth, the present invention has the advantage that the compression member in the lower tension regardless of its shape, in the case of the two-dimensional member can be used as a compression member, such as pipes and square pipes.

Sixth, the present invention has the advantage that the three-dimensional configuration in the cross-sectional shape in the cross-sectional shape at the time of installation of the compression member in a semi-circular convex downward.

In addition, in the case of a three-dimensional configuration, the compression member serves to integrate the arch and the under tension and at the same time has the advantage of serving as a cross beam in the bridge.

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

2 is a plan view showing a long span structure synthesized with the arch and the under tension according to the present invention, Figure 3 is a side view showing a long span structure synthesized with the arch and the under tension according to the present invention.

As shown in these figures, the long span structure combining the arch and the under tension according to the present invention includes a branch portion 100 on both sides provided by a column or beam; An arch 200 mounted on the point part 100 and having a member axis curved; An upper chord 300 positioned on both ends of the arch 200 and formed of a pipe having a constant curvature; A tension member 400 bonded to both ends of the upper chord 300 and having a predetermined curvature; A plurality of vertically fixed between the upper chord 300 and the tension member 400, and consists of a compression member 500 for connecting the arch 200, the upper chord 300 and the tension member 400.

That is, the long span structure in which the arch and the under tension according to the present invention are synthesized is a structure in which the arch 200 and the under tension B are organically combined.

Here, the arch 200, which is the former, is a structural part that maximizes the mold height (mold height or beam height), which is a structural advantage, minimizes the moment applied to the arch 200, and receives only the axial force.

On the other hand, the latter under tension (B) is a structure in which the upper chord 300, the tension member 400 and the compression member 500 is fixed.

Here, the phase current 300 is made of a pipe having a certain curvature, or put out that a variety of materials, such as concrete, steel, wood.

In addition, the tension member 400 will be understood to be composed of any one or a combination of steel wire, steel wire rope, cable, steel bar, steel rod, PC steel.

And it is noted that the tension member 400 may be introduced into the tensile force as necessary.

4 is a cross-sectional view taken along the line A-A of FIG. 3, and FIG. 5 is a cross-sectional view taken along the line B-B of FIG.

As shown in these figures, the compression member 500 is formed in a semicircular shape that is triangular or convex downward when the cross-sectional shape is a cross-sectional shape, the arch 200 in the upper middle of the compression member 500 made of the semicircular shape ) Is inserted, a plurality of tension members 400 are inserted into the lower end of the arch 200, and the upper chord 300 is inserted into both ends thereof.

Here, it is noted that the cross-sectional shape of the compression member 500 may be formed in any one of three-dimensional cross-sectional shape of V-shaped, semi-circular, U-shaped.

In addition, it is noted that the compression member 500 may have the arch 200, the phase chord 300, and the tension member 400 disposed on the same plane.

The construction of the long span structure synthesized with the arch and the under tension according to the present invention having the configuration as described above will be described.

6 is an exemplary view showing a state in which a long span structure synthesized with an arch and an under tension according to the present invention is installed on a bridge.

As shown in this figure, the construction method of the long span structure synthesized with the arch and the under tension according to the present invention is the arch 200 formed in a curved shape of the member axis in the point portion 100 on both sides provided by the column or beam Mounting, mounting the upper chord 300 made of a pipe having a constant curvature at both ends of the arch 200, bonded to the tension member 400 having a constant curvature at both ends of the upper chord 300, A compression member 500 is vertically installed between the upper chord 300 and the tension member 400 to connect the arch 200 with the upper chord 300 and the tension member 400 to construct a long span structure.

Here, the tension member 400 is constructed of any one or a combination of steel wire, steel wire rope, cable, steel rod, steel rod, PC steel, it is noted that the tensile force may be introduced as necessary.

In addition, the compression member 500 may be disposed in the same plane on the arch 200, the phase chord 300 and the tension member 400, or may be formed in any one of three-dimensional cross-sectional shape of V-shaped, semi-circular, U-shaped. Let's find out.

The long span structure synthesized with the arch and the under tension according to the present invention composed of the structure and construction as described above and the construction method thereof is mounted on the arch portion 200 on the branch portion 100, the lower end of the arch 200 After installing the upper chord 300 made of pipes on the branch portion 100 installed on both sides, and then extending the tension member 400 at both ends of the upper chord 300, the lower portion of the upper chord 300 And a compression member 500 is installed between the tension member 400 and a tensile force is introduced to the tension member 400 so that an upward compression force is transmitted to the upper current 300 by the compression member 500. Compression force that can withstand dead and live loads acting on) has the effect of being continuously introduced by the tension of the tension member (400).

In addition, the bridge and the building is aging by using the tension member 400 installed in the lower portion of the phase current 300 as described above to reinforce the load capacity of the bridge and building or to raise the load bearing capacity of the bridge and building by one step. If the tension force is introduced again into the tension member 400 pre-installed in the lower end of both ends of the current 300, there is an effect of simply increasing the load capacity of the bridge and building.

On the other hand, Figure 7 (a) is the same principle as the moment due to the load acting on the bridges and buildings on the upper pole 300 by applying the load after the top chord 300 is mounted on the point portion 100 on both sides. Fig. 7 (b) shows the moment size of the hatched portion generated by applying a load after the arch is mounted to the point portions on both sides, and Fig. 7 (c) shows the moment size of the hatched portion introduced. The upward compressive force transmitted to the compression member 500 by the tensile force introduced to the tension member 400 installed in the lower portion of the upper chord 300 represents the moment size of the hatched portion generated by being introduced to the upper chord 300, Figure 7 (d) is a composite of the moment generated in Figures 7 (a) and 7 (b) and 7 (c), and eventually the long span structure synthesized by the arch and under tension according to the present invention is installed and in use This represents the moment size of the hatched portion that occurs in the.

Therefore, as shown in (d) of FIG. 7 (d), the magnitude of the moment generated in the upper chord 300 is greatly reduced, so that the floor height of the upper chord 300 can be designed more effectively, thereby enabling a lighter weight. Demonstrates the economical and beautiful structure that can be applied to the bridges and buildings in the city.

1 is an exemplary view showing a conventional under tension long span,

2 is a plan view showing a long span structure that synthesizes the arch and the under tension according to the invention,

Figure 3 is a side view showing a long span structure synthesized arch and under tension according to the present invention,

4 is a cross-sectional view taken along the line A-A of FIG.

5 is a cross-sectional view taken along the line B-B of FIG.

6 is an exemplary view showing a state in which a long span structure synthesized with an arch and an under tension according to the present invention is installed on a bridge;

Figure 7 is an illustration showing the moment acting on the long span structure synthesized arch and under tension according to the present invention.

Explanation of symbols on the main parts of the drawing

100: branch 200: arch

300: phase present 400: tension member

500: compression member B: under tension

Claims (10)

Branch portions 100 on both sides provided by the pillar or beam; An arch 200 mounted on the point part 100 and having a member axis curved; An upper chord 300 positioned on both ends of the arch 200 and formed of a pipe having a constant curvature; A tension member 400 bonded to both ends of the upper chord 300 and having a predetermined curvature; Arch is characterized in that a plurality of vertically fixed between the upper chord 300 and the tension member 400, consisting of a compression member 500 for connecting the arch 200, the upper chord 300 and the tension member 400. Long span structure that combines and under tension. The method of claim 1, The tension member 400 is a long span structure synthesized arch and under tension, characterized in that composed of any one or a combination of steel wire, steel wire rope, cable, steel bar, steel rod, PC steel. The method according to claim 1 or 2, Longitudinal structure synthesized by the arch and the under tension, characterized in that the tensile force is introduced to the tension member 400. The method of claim 1, The compression member 500 has a long span structure of the arch and the under tension, characterized in that the arch 200, the upper chord 300 and the tension member 400 is arranged in the same plane. The method according to claim 1 or 3, The compression member 500 is a long span structure synthesized with the arch and under tension, characterized in that formed in three-dimensional shape of the cross-section of the V-shaped, semi-circular, U-shaped. The shaft 200 is formed on both sides of the branch portion 100 installed by a column or beam, and the member shaft has a curved shape, and the upper chord 300 made of a pipe having a constant curvature is provided at both ends of the arch 200. Mounting, bonding the tension member 400 having a constant curvature at both ends of the upper chord 300, and install a compression member 500 vertically between the upper chord 300 and the tension member 400, the arch ( The method of constructing a long span structure combining the arch and the under tension, characterized in that the construction of the long span structure by connecting the 200 and the phase chord 300 and the tension member 400. The method of claim 6, The tension member 400 is a long span structure construction method for synthesizing the arch and under tension, characterized in that the construction of any one or a combination of steel wire, steel wire rope, cable, steel bar, steel rod, PC steel. The method according to claim 6 or 7, The tension member 400 is a long span structure construction method of synthesizing the arch and the under tension, characterized in that the introduction of a tensile force. The method of claim 6, The compression member 500 has a long span structure construction method synthesized arch and under tension, characterized in that the arch 200, the upper chord 300 and the tension member 400 is arranged in the same plane. The method according to claim 6 or 9, The compression member 500 is a long span structure construction method of the composite of the arch and under tension, characterized in that formed in three-dimensional cross-sectional shape of any one of V-shaped, semi-circular, U-shaped.

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