KR101931343B1 - Curved bridge and Method for controlling the torsional rotation of thereof - Google Patents

Abstract

The present invention discloses a twist control method for a curved bridge and a curved bridge that are constructed with at least one or more spans. A curved plate having an inner side adjacent to the center of the radius of curvature and an outer side extending outwardly from the inner side; a first abdomen connected to the first span to extend from the lower end of the outer side; A second abdomen connected to the second span and extending from a lower end of the medial portion and a second abdomen disposed to be symmetrical with respect to the first abdomen and the second abdomen, A first torsion resistance steel wire disposed adjacent to a center portion in the longitudinal direction of the first span or adjacent to a connecting portion to which the first span is connected and a second torsion resistance steel wire disposed in the longitudinal center portion of the second span, And a second torsion resistance steel wire provided at a lower portion of a connecting portion to which the second span is connected.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a curved bridge and a curved bridge,

The present invention relates to an apparatus and a control method, and more particularly to a curved bridge and a method of controlling a twist of a curved bridge.

The use of curved bridges is increasing due to congested traffic and economic and environmental factors. Recently, bridges that effectively utilize the material characteristics of concrete and PS steel have been actively developed due to the improvement of analysis, design and construction technology of bridges. These bridges have been made slimmer by using the tension force of PS wire efficiently .

7A is a partial perspective view showing a conventional curved bridge.

7A, the curved bridge 10 has a curved plate 11, a plurality of northern portions 12, 13, and a PS steel wire 14. However, as the curved bridge 10 becomes slimmer, the rigidity is lowered, and the resistance against vibration and fatigue can be reduced. Also, as the abdomen and upper flange that make up the cross section become thinner, the torsional resistance is also reduced. Therefore, accurate interpretation and control of the torsional behavior of the curved bridge 10 is required.

In general, torsional analysis of thin plate structures requires pure torsion and warping torsion behavior.

Control of section rotation caused by torsional moments caused by geometric nonlinearity of the girder along with deflection control in the case of long span curved bridge construction using FCM (Free Cantilever Method) or ILM (Incremental Launching Method) Is required.

In the case where these section rotations are not controlled appropriately, there is a mismatch between the joints of the two girders due to the time-dependent / independent torsional behavior in the process of final consolidation of the two girders, Resulting in structural safety problems.

In addition, the continuous torsional rotation behavior can shorten the expected lifetime of bridges by changing the initial stress state, cross-sectional shape and reaction force of the bridge in the long term.

It is an object of the present invention to provide a curved bridge capable of controlling twisting of a curved bridge. Another object of the present invention is to provide a twisting control method for a curved bridge. However, these problems are exemplary and do not limit the scope of the present invention.

According to an embodiment of the present invention there is provided a curved bridge constructed with at least one or more spans, comprising: a curved plate having an inner portion adjacent the center of the radius of curvature and an outer portion extending outwardly from the inner portion; A second abdomen connected to the second span to correspond to the first abdomen and extending from a lower end of the medial side, and a second abdomen connected to the second abdomen to correspond to the first abdomen, A main strand disposed so as to be symmetrical to the abdomen and continuously disposed so as to rise at both ends in the longitudinal center of the first span and the second span and a second main span adjacent to the center in the longitudinal direction of the first span, A first torsion-resistant steel wire disposed adjacent to a connecting portion to which the second span is connected, and an upper portion of the longitudinal center portion of the second span or the second span is connected It provides a curved bridge and a second torsion resistance wire which is provided at the lower part of the connecting portion.

The first torsion resistance steel wire also generates a resistance force against torsion in the downward direction of the first abdomen and the second torsion resistance steel wire generates a resistance force against torsion in the upward direction of the second abdomen can do.

Also, the first torsion resistance steel wire may be arranged asymmetrically with respect to the second torsion resistance steel wire.

Also, the first span or the second span may be a prestressed concrete (PSC) girder or a steel composite girder.

The apparatus may further include a third abdomen disposed between the first abdomen and the second abdomen, and a fourth abdomen disposed between the third abdomen and the second abdomen, wherein the third abdomen and the fourth abdomen And the third abdomen is arranged so that the first torsion resistance steel wire is symmetrical with respect to the first abdomen, and the fourth abdomen is arranged such that the second torsion resistance steel wire is arranged symmetrically with respect to the second abdomen It can be arranged to be opposed.

In addition, the first torsional resistance steel wire or the second torsional resistance steel wire may be arranged in a straight line parallel to the longitudinal direction of the first abdomen.

The first torsion resistance steel wire may be disposed adjacent to a longitudinal center portion of the first span and may include at least one of a downwardly concave first steel wire and a second steel wire that is disposed at a connecting portion to which the first span is connected, .

The second torsion resistance steel wire may have at least one of a third steel wire convex upward at an upper portion of a longitudinal center portion of the second span and a fourth steel wire concave downward at a lower portion of a connecting portion to which the second span is connected .

Also, the first torsional resistance wire or the second torsional resistance wire may be at least partially flat at the center in the longitudinal direction.

According to another aspect of the present invention, there is provided a curved bridge to which at least one span is applied, comprising: a curved plate having an inner portion adjacent to the center of the radius of curvature and an outer portion extending outward from the inner portion; A second abdomen connected to a second span to correspond to the first abdomen and extending from a lower end of the medial side; and a second abdomen coupled to the first abdomen and the second abdomen, The main spirals being arranged so as to rise at both ends in the longitudinal direction center of the first span and the second span and a second main span disposed at a center or an end of the main span in the longitudinal direction, And a torsion-resistant steel wire that produces a resistance to twisting of the second abdomen.

In addition, the main strand and the second strand may be symmetrically disposed, and the torsion resistance strands may be arranged asymmetrically with respect to each other.

The torsion resistance steel wire may include a first torsion resistance steel wire disposed along the main steel wire in the first abdomen portion and a second torsion resistance steel wire spaced from the upper or lower portion of the main steel wire in the second abdomen portion .

In addition, the first torsional resistance generated in the first abdomen may be different from the second torsional resistance generated in the second abdomen, or may be opposite in direction.

The torsion resistance steel wire may have at least one of a first torsion resistance steel wire disposed in the first abdomen portion and a second torsion resistance steel wire disposed in the second abdomen portion.

According to another aspect of the present invention, there is provided a method of manufacturing a tire, comprising the steps of: providing a first abdominal portion and a second abdominal portion by connecting a curved span having a main steel wire; The method according to any one of claims 1 to 3, further comprising the steps of: preparing a curved plate on which the first abdomen is disposed at an outer side extending from the medial side to the outside; Placing a torsional resistance wire on at least one of the abdomen and compressing or tensioning the torsional resistance wire to create a resistance force in a direction opposite to the twisting force generated in the first abdomen or the second abdomen, The present invention provides a twist control method for a bridge.

Also, the step of disposing the torsion-resistant steel wire may be arranged such that the torsion-resistant steel wire disposed on the first abdomen and the torsion-resistant steel wire disposed on the second abdomen are asymmetric.

The step of disposing the torsion resistance steel wire may be arranged such that the torsion resistance steel wire is disposed along the main steel wire in the first abdomen portion or spaced from the upper or lower portion of the main steel wire in the second abdomen portion.

The method may further include measuring torsion generated in the first abdomen and the second abdomen prior to the step of disposing the torsion-resistant steel wire.

According to one embodiment of the present invention as described above, the curved bridge can generate a resistance against twisting of the torsion-resistant steel wire, thereby controlling and minimizing twisting. The torsion resistance wire can generate a moment opposite to twist in the opposite direction of twist to control twist. Of course, the scope of the present invention is not limited by these effects.

1 is a perspective view showing a curved bridge according to an embodiment of the present invention.
Figure 2 is a top view of the curved bridge of Figure 1;
3 is a cross-sectional view showing a cross section of the curved bridge of FIG.
4 is a cross-sectional view showing a cross section of the abdomen of the curved bridge of Fig. 1;
5A to 5D are sectional views showing a modified example of a curved bridge.
6A to 6C are side views showing a curved bridge according to another embodiment.
FIG. 7A is a partial perspective view showing a conventional curved bridge, and FIG. 7B is a partial perspective view showing a twisted deformation of a conventional curved bridge.
8 is a flowchart showing a method of controlling twist of the curved bridge of FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, Is provided to fully inform the user. Also, for convenience of explanation, the components may be exaggerated or reduced in size. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of explanation, and thus the present invention is not necessarily limited to those shown in the drawings.

In the following embodiments, the x-axis, the y-axis, and the z-axis are not limited to three axes on the orthogonal coordinate system, and can be interpreted in a broad sense including the three axes. For example, the x-axis, y-axis, and z-axis may be orthogonal to each other, but may refer to different directions that are not orthogonal to each other.

On the other hand, when various elements such as layers, films, regions, plates and the like are referred to as being " on " another element, not only is it directly on another element, .

1 is a perspective view showing a curved bridge 100 according to an embodiment of the present invention, FIG. 2 is a plan view of the curved bridge 100 of FIG. 1, and FIG. 3 is a perspective view of a curved bridge 100 4 is a cross-sectional view showing a cross section of the abdomen of the curved bridge 100 of FIG.

The curved bridge 100 may be implemented in a curved shape and installed in a curved bridge, an intersection, or the like. The curved bridge 100 may be formed of a prestressed concrete (PSC), a steel, or a steel composite.

1 to 4, a curved bridge 100 includes a curved plate 110, a first abdomen 120, a second abdomen 130, a main steel wire 140, a torsion resistance steel wire 170, .

The curved plate 110 is installed on the upper portion of the first abdomen 120 and the second abdomen 130, and at least a part of the curved plate 110 may be formed in a curved shape. The curved plate 110 may have an inner portion 110b adjacent to the center O of the radius of curvature R and an outer portion 110a extending outward from the inner portion 110b. The curved plate 110 may be formed, assembled, or installed at the same time with the first abdomen 120 or the second abdomen 130, respectively.

The first abdomen 120 and the second abdomen 130 may be installed on the lower side of the curved plate 110 to support the curved plate 110. The first abdomen 120 may have a "T" shape as shown in FIG. 1, or an "I" shape or a "|" shape as shown in FIG. 6A.

The first abdomen 120 may be installed under the outer side 110a of the curved plate 110 and may be connected by connecting a plurality of first spans. The second abdomen 130 may be installed below the inner portion 110b of the curved plate 110 and may be installed by connecting a plurality of second spans. The first abdomen 120 and the second abdomen 130 may be disposed to face each other.

A plurality of spans are connected to the first abdomen 120 or the second abdomen 130, and the number is not limited to a specific number. Hereinafter, for convenience of explanation, three spans are connected to each other. The span can be connected to neighboring spans at points i and j.

The main wire 140 may be installed in the first abdomen 120 or the second abdomen 130. [ The main wire 140 may be arranged to be symmetrical to the first and second belts 120 and 130, respectively. That is, the main steel wire 140 installed on the first abdomen 120 and the main steel wire 140 installed on the second abdomen 130 can be symmetrical with respect to each other.

The main steel wire 140 may be arranged to be wavy along the first abdomen 120 or the second abdomen 130. The main steel wire is disposed at a lower portion at the center of each span, and is arranged so as to be higher at both ends. Therefore, the first abdomen 120 or the second abdomen 130, which are connected as a whole, can have a continuous wave shape since they are disposed at both ends where the spans are connected. The lowest point of the main steel wire 140 is the center portion of each span, and the highest point is the connecting point of the span.

When the main wire 140 is tensioned and installed in the first or second staple part 120 or 130 so that the compressive force of the main steel wire 140 is applied to the first staple part 120 or the second staple part 130, And the tensile strength can be improved. Also, the main steel wire 140 may be a PS steel wire, a post tension type inserted into a sheath tube, or a pre-tensioned type formed like a span. The main steel wire 140 may increase the apparent bending strength of the first abdomen 120 or the second abdomen 130 to minimize sagging or cracking of the bridge.

The torsion-resistant steel wire 170 generates a resistance force against the twisting generated in the curved bridge 100, thereby preventing deformation of the curved bridge 100. The torsion resistance steel wire 170 may include a first torsion resistance steel wire 150 provided on the first abdomen portion 120 and a second torsion resistance steel wire 160 installed on the second abdomen portion 130. The first steel wire 151 and the second steel wire 152 may be arranged to be asymmetric with respect to each other.

The torsion resistance wire 170 may be formed of a PS wire and may be disposed on at least one of the first and second belts 120 and 130. That is, it may be installed in one of the first and second belly portions 120 and 130, or may be installed in both the first and second belly portions 120 and 130. Also, the torsion resistance wire 170 can be intermittently installed.

The first torsion resistance steel wire 150 may be installed in the first abdomen 120. The first torsion resistance steel wire 150 may include a first steel wire 151 and a second steel wire 152 depending on the arrangement position. The first steel wire 151 may be disposed adjacent to the longitudinal center portion of the first span and the second steel wire 152 may be disposed adjacent to the connection end to which the first span is connected.

The first steel wire 151 and the second steel wire 152 may be formed in a straight line shape. The first wire 151 and the second wire 152 can prevent deformation of the first abdomen 120.

The second torsion resistance steel wire 160 may be installed in the second abdomen 130. [ The second torsion resistance steel wire 160 may include a third steel wire 161 and a fourth steel wire 162 depending on the arrangement position thereof. The third strand 161 may be disposed at an upper portion of the central portion in the longitudinal direction of the second span and the fourth strand 162 may be disposed at a lower portion of the connecting portion to which the second span is connected.

The first torsion resistance steel wire 150 is disposed adjacent to the main steel wire 140 but the first torsion resistance wire 150 is common to the first and second wire strands 151 and 152 in that the first and second wires 151 and 152 are disposed at the center or connection point of the span. The second torsion resistance steel wire 160 is disposed so as to be spaced apart from the main steel wire 140. Specifically, the first steel wire 151 is disposed at the center of the span and is disposed below the span. However, the third steel wire 161 is disposed on the upper side of the span so as to be spaced apart from the center of the span. The second steel wire 152 is disposed on both ends of the span and on the upper side of the span. However, the fourth steel wire 162 is disposed at both ends of the span so as to be spaced apart from the span, and is provided below the span.

FIG. 7A is a partial perspective view showing a conventional curved bridge, and FIG. 7B is a partial perspective view showing a twisted deformation of a conventional curved bridge.

Conventional curved bridges require accurate interpretation and control of torsional behavior as the components become thinner. In general, torsional analysis of thin plate structures requires pure torsion and warping torsion behavior.

In particular, concrete curved bridges are characterized by geometric nonlinearity of bridges, which is an initial condition of torsional rotation caused by self-weight at the initial stage of construction. Therefore, the elasticity coefficient is expressed by drying, shrinkage and creep phenomenon, Behavior occurs.

That is, curved bridges are deformed by pure twisting and twisting. Referring to FIG. 7B, the first twist force T1 is generated in the downward direction of the outer side of the curved girder due to the pure twist and the twist, and the second twist force T2 is generated in the upward direction inside. Deformation of θ degrees in the downward direction seriously deteriorates the safety of the entire structure, so the deformation must be removed or minimized.

The torsion-resistant steel wire 170 may produce different resistance forces in the abdomen of the curved bridge 100. The torsion resistance wire 170 may have a different magnitude of the resistance generated in the first and second belly portions 120 and 130, and the resistance may be generated in the opposite direction.

The torsion resistance steel wire 170 can minimize the deformation of the curved bridge 100 by controlling the torsional moment and bimoment generated in the curved bridge 100. The first torsion resistance steel wire (150) and the second torsion resistance steel wire (160) are disposed opposite to each other. Thus, the first torsional resistance F1 generated in the first torsion resistance steel wire 150 and the second torsion resistance force F2 generated in the second torsion resistance steel wire 160 are generated in opposite directions.

In addition, the torsion resistance wire 170 may be installed on at least one of the first abdomen 120 or the second abdomen 130. [ The first torsion resistance steel wire 150 may be provided only on the first abdomen portion 120 or the second torsion resistance steel wire 160 may be installed only on the second abdomen portion 130. [ In addition, the torsion resistance wire 170 may be installed on each of the first and second abdomen portions 120 and 130. The torsion-resistant steel wire can generate a resistance force in the opposite direction between the inner side and the outer side of (170).

The first torsional resistance wire 150 and the second torsional resistance wire 160 can cause the vertical component of the torsional force to produce a torsional resistance moment and the horizontal component of the torsional force to produce a resistance bimoment.

5A to 5D are sectional views showing a modified example of a curved bridge.

5A to 5C, the curved plate 110, the first abdomen 120, the second abdomen 130 and the main steel wire 140 of the curved bridge 100a are connected to the curved bridge (described above) 100, detailed description thereof will be omitted or abbreviated. Hereinafter, the first torsional resistance steel wire 150a and the second torsional resistance steel wire 160b will be described in detail.

Referring to FIG. 5A, the first torsion resistance steel wire 150a and the second torsion resistance steel wire 160a may be concave or convex. The first steel wire 151a of the first torsion resistance steel wire 150a is convex downward at the center of the span and is disposed adjacent to the main steel wire 140. [ And the second steel wire 152a of the first torsion resistance steel wire 150a is formed to be convex upward at both ends of the span. The first torsion resistance steel wire 150a may include at least one of a first steel wire 151a and a second steel wire 152a.

The third steel wire 161a of the second torsion resistance steel wire 160a may be provided so as to be spaced apart from the center of the span to the upper side of the main steel wire 140 and be convex upward. The fourth steel wire 162a of the second torsion resistance steel wire 160a may be formed to be spaced apart from the opposite ends of the main steel wire 140 at both ends of the span and be convex downward.

The curved portion of the first torsion resistance steel wire 150a and the second torsion resistance steel wire 160a may generate an upward force or a downward force on the main steel wire 140 while being deformed flatly at the time of generation of a compressive force or a tensile force. The generated upward force or downward force acts as a resistance force of torsion. The resistance force acts in a direction opposite to the twist of the first abdomen 120 or the second abdomen 130 to prevent deformation of the curved bridge 100a.

Referring to FIG. 5B, the first torsion resistance steel wire 150b and the second torsion resistance steel wire 160b may be concave or convex. The first steel wire 151b of the first torsion resistance steel wire 150b is convex downward at the center of the span and is disposed adjacent to the main steel wire 140. [ The center of the first steel wire 151b is arranged to be in contact with the main steel wire 140 and both ends thereof are bent and extended upward along the main steel wire 140. [ And the second steel wire 152b of the first torsion resistance steel wire 150b is formed to be convex upward at both ends of the span. The center of the second steel wire 152b is disposed flush with the main steel wire 140 so that both ends thereof are bent and extend downward along the main steel wire 140. The first torsion resistance steel wire 150b may include at least one of a first steel wire 151b and a second steel wire 152b.

The shape of the third steel wire 161b of the second torsion resistance steel wire 160b is similar to the shape of the second steel wire 152b and the shape of the third steel wire 161b is spaced apart from the center of the span to the upper side of the main steel wire 140 do. The shape of the fourth steel wire 162b of the second torsion resistance steel wire 160b is similar to that of the first steel wire 151b and the fourth steel wire 162b is spaced apart from the opposite ends of the main steel wire 140 do.

The bent portions of the first torsion resistance steel wire 150b and the second torsion resistance steel wire 160b may generate an upward force or a downward force on the main steel wire 140 while being deformed flatly at the time of compression or tensile force generation. The generated upward force or downward force acts as a resistance force of torsion. The resistance force acts in a direction opposite to the twist of the first abdomen 120 or the second abdomen 130 to prevent deformation of the curved bridge 100b.

Referring to FIG. 5C, the first torsion resistance steel wire 150c and the second torsion resistance steel wire 160c may be concave or convex. The first steel wire 151c of the first torsion resistance steel wire 150c is convex downward at the center of the span and is disposed adjacent to the main steel wire 140. [ The center of the first steel wire 151c is curved so as to be in contact with the main steel wire 140 and both ends thereof are curved so as to contact the main steel wire 140. [ The second steel wire 152c of the first torsion resistance steel wire 150c is formed to be convex upward at both ends of the span. The center of the second steel wire 152c is curved so as to be in contact with the main steel wire 140 and both ends thereof are curved so as to contact the main steel wire 140. [ The first torsion resistance steel wire 150c may include at least one of a first steel wire 151c and a second steel wire 152c.

The shape of the third steel wire 161c of the second torsion resistance steel wire 160c is similar to that of the second steel wire 152c and the third steel wire 161c is spaced apart from the center of the span to the upper side of the main steel wire 140 do. The shape of the fourth steel wire 162c of the second torsion resistance steel wire 160c is similar to that of the first steel wire 151c and the fourth steel wire 162c is spaced below the main steel wire 140 at both ends of the span do.

The bent portions of the first torsion resistance steel wire 150c and the second torsion resistance steel wire 160c may be deformed flatly at the time of the generation of the compressive force or the tensile force to generate an upward force or a downward force to the main wire 140. [ The generated upward force or downward force acts as a resistance force of torsion. The resistance force acts in a direction opposite to the twisting of the first abdomen 120 or the second abdomen 130 to prevent deformation of the curved bridge 100c.

5D, the curved bridge 100d includes a first abdomen 120 disposed on the outside of the curved plate 110, a second abdomen 130 disposed on the inside, a first abdomen 120, And a fourth abdomen 131 disposed between the second abdomen 130 and the third abdomen 121 and between the third abdomen 121 and the second abdomen 130. [

The first torsion resistance steel wire 150 is disposed on the first abdomen portion 120 and the second torsion resistance steel wire 160 is disposed on the second abdomen portion 130. The third torsion resistance steel wire 160 is disposed on the third abdomen portion 121, And a fourth torsion resistance steel wire 163 is disposed on the fourth abdomen portion 131. [

The shape and arrangement of the first torsion resistance steel wire 150 disposed on the first abdomen portion 120 is substantially the same as the shape and arrangement of the third torsion resistance steel wire 153 disposed on the third abdomen portion 121, The shape and arrangement of the second torsion resistance steel wire 160 disposed on the two abdomen portions 130 is substantially the same as the shape and arrangement of the fourth torsion resistance steel wire 163 disposed on the fourth abdomen portion 131. [ That is, the shape and arrangement of the torsion-resistant steel wire disposed at the outer abdomen of the curved plate 110 are substantially identical to each other, and the shape and arrangement of the torsion-resistant steel wire disposed at the inner abdomen of the curved plate 110 are substantially Can be the same. In addition, the arrangement of the torsion-resistant steel wire disposed at the outer abdomen is different from the arrangement of the torsion-resistant steel wire disposed at the inner abdomen, and can be arranged asymmetrically.

Further, the torsion-resistant steel wire disposed in a curved bridge having two or more abdomen portions can be arranged with a variation of the torsion-resistant steel wires described in Figs. 5A to 5C, and combinations thereof.

Further, the number of abdomen is not limited to this, and may be four or more. In this case, the inner abdomen located inside the radius of curvature is formed like the second abdomen 130 or the fourth abdomen 131, and the outer abdomen located outside the radius of curvature is formed in the first abdomen 120 or the third abdomen 121 As shown in FIG.

4 to 5D illustrate that the main strand, the first torsional resistance strand and the second torsional strand are disposed on the first strand 120 and the second strand 130, but not limited thereto, (110). That is, a portion of the main strand, the first torsion-resistant strand, and the second torsion-resistant strand may be disposed in the first strand 120 or the second strand 130 and the other in the curved plate 110.

6A to 6C are side views showing a curved bridge according to another embodiment.

6A, a curved bridge 200 includes a curved plate 210, a first abdomen 220, a second abdomen 230, a main steel wire 240, a first torsion resistance steel wire 250, 2 torsion resistance steel wire 260. As shown in FIG. That is, the first abdomen 220 and the second abdomen 230 of the curved bridge 200 may have the shape of an "I" shaped beam.

6B, the curved bridge 300 includes a curved plate 310, a first abdomen 320, a second abdomen 330, a main steel wire 340, a first torsion resistance steel wire 350, 2 torsion resistance steel wire 360. That is, the curved bridge 300 may be a box girder.

6C, the curved bridge 400 includes a curved plate 410, a first abdomen 421 and a second abdomen 422, which are the outer abdomen 420, a third abdomen 422, which is the inner abdomen 430, 431, a fourth strand 432, a main strand 440, a first torsion resistance strand 450 and a second torsion resistance strand 460. That is, the outer abdomen 420 and the inner abdomen 430 of the curved bridge 400 may have the shape of an "I" shaped beam.

8 is a flowchart showing a method of controlling twist of the curved bridge of FIG.

Referring to FIG. 8, a method of controlling a twist of a curved bridge includes the steps of (S10) connecting a curved span having a main wire to a first abdomen and a second abdomen, (S30) of arranging a torsion resistance steel wire so as to correspond to a twisting force of the first abdomen or the second abdomen, a step (S30) of adjusting the torsion resistance steel wire to generate a resistance force Step S40 may be included.

A plurality of spans are connected at the step of installing the first and second belts 120 and 130 by connecting the curved span having the main steel wire 140 to the first and second belts 120 and 120, 2 abdomen 130 may be provided.

 The first abdomen 120 is positioned outside the curvature radius R of the curved plate 110 in the step S20 of installing the curved plate 110 on the first abdomen 120 and the second abdomen 130 And the second abdomen 130 is disposed inside the radius of curvature R of the curved plate 110. [

The step S30 of arranging the torsion resistance wire 170 to correspond to the twisting force of the first abdomen 120 or the second abdomen 130 may be performed such that the first and second abdomen portions 120 and 130 are asymmetric The torsion resistance steel wire 170 can be disposed. The first torsion resistance steel wire 150 and the second torsion resistance steel wire 160 may be disposed on the first abdomen 120 and the second abdomen 130 respectively. And the second torsion resistance steel wire 160 may be disposed asymmetrically.

Adjusting the torsion resistance wire 170 to generate a resistance force S40 may adjust the compressive or tensile force of the first torsion resistance wire 150 or the second torsion resistance wire 160 to produce a resistance to torsion . A resistance force is generated in a direction opposite to the twisting of the curved bridge 100 caused by the nonlinearities of the first and second belly portions 120 and 130 so that the first and second belly portions 120 and 130 are twisted Can be prevented.

The first torsional resistance F1 acts on the first abdomen 120 in an upward direction and is formed to have a size corresponding to the first twist force T1 received by the first abdomen 120 in the downward direction, 120 can be reduced. The second torsion resistive force F2 acts on the second abdomen 130 in a downward direction and is deformed to a size corresponding to the second twist force T2 received by the second abdomen 130 in the upward direction, 130 can be reduced.

In addition, the method of controlling the twist of the curved bridge can alleviate and eliminate the twist of the pre-installed curved bridge. The torsion generated in the first abdomen 120 and the second abdomen 130 of the curved bridge is measured and the torsion resistance wire 170 is installed on the first abdomen 120 and the second abdomen 130 . Thereafter, the first torsion resistance steel wire 150 and the second torsion resistance steel wire 160 may be adjusted to produce a torsional resistance.

Unless there is explicitly stated or contrary to the description of the steps constituting the method according to the invention, the steps may be carried out in any suitable order. The present invention is not necessarily limited to the order of description of the above steps. The use of all examples or exemplary language (e.g., etc.) in this invention is for the purpose of describing the present invention only in detail and is not intended to be limited by the scope of the claims, But is not limited thereto. It will also be appreciated by those skilled in the art that various modifications, combinations, and alterations may be made depending on design criteria and factors within the scope of the appended claims or equivalents thereof.

Accordingly, the spirit of the present invention should not be construed as being limited to the above-described embodiments, and all ranges that are equivalent to or equivalent to the claims of the present invention as well as claims Category.

100: Curved bridges
110: Curved plate
120: first abdomen
130: second abdomen
140: Main liner
150: first torsion resistance steel wire
151: 1st liner
152: 2nd liner
153: Third torsion resistance wire
160: second torsion resistance wire
163: fourth torsion resistance wire
161: Third liner
162: Fourth liner
170: Torsion resistance wire

Claims (18)

In a curved bridge constructed with at least one or more spans,
A curved plate having a medial side adjacent the center of the radius of curvature and an outward side extending outwardly from the medial side;
A first abdomen connected to the first span to extend from a lower end of the outer side;
A second abdomen connected to the second span to correspond to the first abdomen and extending from a lower end of the medial side;
A main steel wire arranged to be symmetrical to the first abdomen and the second abdomen and continuously arranged to rise at both ends in a longitudinal direction center of the first span and the second span;
A first torsion resistance steel wire adjacent to a central portion in a longitudinal direction of the first span or adjacent to a connecting portion to which the first span is connected; And
And a second torsion resistance steel wire installed at an upper portion of a central portion in a longitudinal direction of the second span or at a lower portion of a connection portion to which the second span is connected,
The first torsion resistance steel wire
A first steel wire disposed adjacent to the longitudinal center of the first span and recessed downward; And
A second steel wire disposed at a connecting portion to which the first span is connected and which is convex upward; Wherein the curved bridge comprises at least one of the curved bridges. The method according to claim 1,
Wherein the first torsional resistance wire creates a resistance to resist torsion downwardly of the first abdomen and the second torsion resistance wire creates a resistance to torsion upwardly of the second abdomen, Curved bridges. The method according to claim 1,
Wherein the first torsion resistance steel wire is disposed asymmetrically with respect to the second torsion resistance steel wire. The method according to claim 1,
The first span or the second span
Curved bridges, which are prestressed concrete (PSC) girders or steel composite girders. The method according to claim 1,
A third abdomen disposed between the first abdomen and the second abdomen; And
And a fourth abdomen disposed between the third abdomen and the second abdomen,
Wherein the main strand is disposed symmetrically with respect to the third abdomen and the fourth abdomen and the first torsion resistance steel wire is arranged symmetrically with respect to the first abdomen, 2 < / RTI > torsion-resistant steel wire is disposed to face the second abdomen. delete delete The method according to claim 1,
The second torsion resistance steel wire
A third steel wire which is convex upward at an upper portion of the central portion in the longitudinal direction of the second span; And
A fourth steel wire which is concave downward at a lower portion of a connecting portion to which the second span is connected; Wherein the curved bridge comprises at least one of the curved bridges. delete In a curved bridge constructed with at least one or more spans,
A curved plate having a medial side adjacent the center of the radius of curvature and an outward side extending outwardly from the medial side;
A first abdomen connected to the first span to extend from a lower end of the outer side;
A second abdomen connected to the second span to correspond to the first abdomen and extending from a lower end of the medial side;
A main steel wire arranged to be symmetrical to the first abdomen and the second abdomen and continuously arranged to rise at both ends in a longitudinal direction center of the first span and the second span;
A first torsion resistance steel wire provided at a center or an end portion in the longitudinal direction of the main steel wire and provided in the first abdomen to generate a resistance against torsion or a second torsion resistance steel wire provided at the second abdomen to generate a resistance against torsion, And a torsion-resistant steel wire,
Wherein the first torsional resistance wire or the second torsional resistance wire is at least partially flat at the longitudinal center. 11. The method of claim 10,
The first abdomen and the second abdomen
Wherein the main steel wire is disposed symmetrically and the torsion resistance steel wires are arranged asymmetrically with respect to each other. 11. The method of claim 10,
The torsion resistance steel wire
A first torsion resistance steel wire disposed along the main steel wire in the first abdomen; And
And a second torsion-resistant steel wire disposed on the second abdomen at an upper portion or a lower portion of the main steel wire. 11. The method of claim 10,
The torsion resistance steel wire
Wherein the first torsion resistive force generated in the first abdomen is different in magnitude from or opposite in direction to the second torsional resistance force generated in the second abdomen. 11. The method of claim 10,
The torsion resistance steel wire
A first torsion resistance steel wire disposed in the first abdomen, and a second torsion resistance steel wire disposed in the second abdomen. Connecting the curved first span having the main steel wire to the first abdomen, and connecting the curved second span to the second abdomen
Providing a curved plate in which the second abdomen is disposed at an inner side adjacent to a center of curvature radius and the first abdomen is disposed at an outer side extending outward from the inner side;
Disposing a twist resistance wire in at least one of the first abdomen and the second abdomen to correspond to a twisting force generated in the first abdomen or the second abdomen; And
And compressing or tensioning the torsion-resistant steel wire to generate a resistance force in a direction opposite to the twisting force generated in the first abdomen or the second abdomen,
The step of disposing the torsion-
A first torsion resistance steel wire having at least one of a first steel wire which is disposed adjacent to the longitudinal center of the first span and which is concave downwardly and a second steel wire which is disposed at a connecting portion where the first span is connected to each other and which is convex upward, Is installed on the first abdomen. 16. The method of claim 15,
The step of disposing the torsion-resistant steel wire
Wherein the torsion-resistant steel wire disposed on the first abdomen is arranged asymmetrically with the torsion-resistant steel wire disposed on the second abdomen. 16. The method of claim 15,
The step of disposing the torsion-resistant steel wire
Wherein the torsion-resistant steel wire is disposed along the main steel wire on the first abdomen or is disposed on the second abdomen so as to be spaced apart from the upper or lower portion of the main steel wire. 16. The method of claim 15,
Further comprising measuring torsion occurring in said first abdomen and said second abdomen prior to said step of disposing said torsion-resistant steel wire.

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