KR101127923B1 - Pylon of cable-stayed bridge having composite combination structure and construction method thereof - Google Patents

Abstract

The present invention relates to a cable-stayed bridge column tower and a construction method thereof, wherein the main column pier part of the steel pillar column and the reinforced concrete structure is a composite coupling structure.

The cable-stayed bridge pylon having a composite coupling structure according to an embodiment of the present invention is a steel pylon is erected at a pylon pier made of concrete, and the pylon pier is extended to an upper portion of the pylon support and the pylon support on which the lower end of the steel pylon is mounted. The composite reinforcement portion may be provided with a leveler embedded in the pylon support portion so as to be exposed from the pylon support, and the steel pylon may have a space in which the synthetic rebar is disposed in the base, and a plurality of studs may be provided on the inner side of the base. It is provided, it may be configured to be provided with a synthetic concrete part that is combined with the stud and synthetic reinforcing portion inside.

By the configuration as described above, the present invention is a direct composite coupling is made to the structure that the main tower made of the reinforcement-concrete structure pier and steel meshing with each other to minimize the enlargement of the cross section of the main tower support, the connection portion of the pier and steel pylon Maintenance can be minimized and durability can be improved by minimizing damage such as corrosion.

Cable Stayed Bridge, Pier, Pylon, Reinforcing Bar, Concrete, Steel, Composite

Description

Cable-stayed bridge column with synthetic bonding structure and its construction method {PYLON OF CABLE-STAYED BRIDGE HAVING COMPOSITE COMBINATION STRUCTURE AND CONSTRUCTION METHOD THEREOF}

The present invention relates to a cable-stayed bridge column tower and a construction method thereof, wherein the main column pier part of the steel pillar column and the reinforced concrete structure is a composite coupling structure.

In general, the cable-stayed bridge pylon is constructed so that the steel pylon is made of a steel material on the top of the main tower piers made of a single concrete or concrete.

When the cable-stayed bridge tower is constructed with concrete structure, no separate connection structure occurs because concrete is used as the whole material. However, when the concrete is made of a single material, there is a problem that the overall size must be increased in order to increase the structurally sufficient strength because the total load increases. In addition, there is a disadvantage that the air is long in construction.

On the other hand, in the case of a cable-stayed bridge tower made of a heterogeneous material in which the pylon pier is made of a concrete material and the steel pylon is built in the pier, the total load can be reduced, and the specification can be sufficiently small. However, in the case of a cable-stayed bridge pylon consisting of dissimilar members, a connection joint for coupling a steel pylon made of steel to a concrete structure occurs at the top of a foundation or a piers.

As shown in FIGS. 1A and 1B, in the case of the cable-stayed bridge pylon 1 made of steel, the steel pylon 20 having reinforcing ribs 22 provided therein, the steel pylon 20 and a pylon pier made of concrete. The connection method of (10) is made of an anchor frame method which is a generally known base connection method.

In the anchor frame method, the anchor frame 11 is embedded in the concrete forming the pylon piers 10, and the steel bar or bolt 13 is fixed so as to protrude to the upper portion of the pylon support 10a, and the steel rod or bolt 13 The lower flange 21 of the steel main tower 20 is fitted to be fixed with a nut 14 or the like. In addition, the pressure plate 12 is further provided between the main column support 10a and the lower surface of the steel main tower 20 to distribute the load of the steel main tower 20 to the main column pier 10.

In this case, since the steel bar or bolt 13 and the nut 14 for fixing the steel main tower 20 to the pier are exposed to the outside air, periodical separate maintenance is required.

In addition, in order to fix the steel pylon 20 to the pier, the anchor frame 11 in which the steel rods or bolts 13 are fixed must be embedded in the concrete pylon pier 10, in this case, the anchor frame 11. Sufficient cross-sectional thickness for embedding the anchor frame 11 in order to provide a sufficient coupling force because the fixing force of the steel pylon 20 is determined by the force of the steel bar or bolt 13 fixed to the nut 14 is coupled to the nut 14. Must be secured.

In addition, since the pressure plate 12 is to be disposed between the steel pylon 20 and the pylon pier 10, the area of the pylon support 10a must be increased in order to secure a sufficient acupressure area, and the concrete pylon pier 10 It is essential to secure the cross section of concrete bridge over a certain thickness in order to prevent edge breakage. In addition, since the reinforcing bars of the anchor frame 11 and the steel bar or bolt 13 and the main column pier 10 must be arranged to minimize interference with each other, it is difficult to install such as reinforcement or installation, or to increase air. .

In this case, even if the cross-sectional area of the concrete pier is secured, the load increases as the cross-sectional area increases, so it is impossible or very difficult to secure sufficient bonding force or durability.

Due to these problems, not only the workability is degraded, but the air is long.

The present invention is made by recognizing at least one of the needs or problems occurring in the construction of the conventional cable-stayed bridge tower and the cable-stayed bridge tower.

One object of the present invention is to allow the steel pylon is a direct composite bond with the pylon pier that is a reinforced concrete structure.

Another object of the present invention is to minimize the enlargement of the cross section of the pylon support provided in the pylon pier to support the steel pylon at the connection of the pylon pier and the steel pylon which is a concrete structure.

Another object of the present invention is to minimize the maintenance of the connection between the main column pier and steel main tower which is a concrete structure in common.

Another object of the present invention to exclude the anchor frame for the connection between the pylon pier and the steel pylon of the concrete structure to exclude or minimize unnecessary interference with the reinforcing bars inside the pylon pier, to provide convenience in construction will be.

Another object of the present invention is to minimize the inclination of the steel pylon to enable fine vertical degree control of the steel pylon, and to distribute the load uniformly to ensure structural safety.

Another object of the present invention is to maintain the airtight (sealed) to the connection portion of the main column pier and the steel main column of the concrete structure to minimize damage such as corrosion during common use.

A cable stayed bridge pylon having a synthetic coupling structure related to an embodiment for realizing at least one of the above problems may include the following features.

The present invention is based on the fact that the steel pylons, which are basically made of reinforcing-concrete structures, include a main column pier and a steel main column, which are directly interlocked with each other.

In the cable-stayed bridge main column having a composite coupling structure according to an embodiment of the present invention, a steel main column is erected in a main column pier made of concrete.

In this case, the pylon piers may be provided with a pylon support portion on which the lower end of the steel pylon is placed, a composite rebar portion extending to the upper portion of the pylon support portion, and a leveler embedded in the pylon support portion while the upper portion is exposed from the pylon support. And, the steel pylon is provided with a space in which the composite reinforcing bar is disposed in its base, a plurality of studs are provided on the inner side of the steel pylon, and the base of the steel pylon is combined with the stud and the synthetic reinforcing bar The concrete part may be provided.

Meanwhile, the steel main column may further include a boundary plate, and the upper portion of the synthetic concrete part may be disposed in a state where the boundary plate is exposed.

On the other hand, the steel main column is further provided with a boundary plate, the boundary plate may be disposed in a state buried in the synthetic concrete part.

In this case, the boundary plate may be formed of an annular structure along the inner circumference at the base of the steel main tower along the inner circumference to distribute the load of the steel main tower to an area capable of being transferred to the main tower support. Alternatively, the steel main column may include reinforcing ribs disposed in an upper region of the boundary plate, or partition walls may be disposed above and below the boundary plate.

The leveler may be disposed at each corner portion of the steel pylon. In this case, the leveler may be made of H-beam.

In addition, a sealing member may be further disposed between the circumference of the lower end of the steel pylon and the leveler contacting the circumference of the lower end of the steel pylon and the pylon support.

According to another aspect of the present invention, there is provided a construction method of a cable stayed bridge pylon having a composite coupling structure, including: forming a plurality of studs on an inner side surface of a steel pillar; A pier forming step in which a pylon support is formed and the composite rebar is extended to the upper portion of the pylon support; Forming a leveler mount on top of the pylon support; Installing a leveler on the leveler mounting unit to adjust a level of the leveler so that a main tower having a stud formed on the base may be installed in a horizontal state; The steel pylon is disposed on the pylon support in a state in which the horizontal level is adjusted by the leveler; And, by pouring and curing the concrete inside the base of the steel pylon installed in the pylon support to form a synthetic concrete portion that is combined with the stud and synthetic reinforcement portion; may be made.

In this case, the leveler may be installed to be disposed at each corner of the steel main column. In addition, the sealing member may be further disposed at the position of the pylon support where the base of the steel pylon is disposed before the steel pylon is arranged above the pylon support in a state where the steel pylon is horizontally adjusted.

In addition, the leveler may be embedded by the buried member so that the remaining area except the surface in contact with the lower end of the steel main tower is not exposed to the outside. On the other hand, the sealing member may be arranged so that the leveler is not exposed to the outside.

In addition, the steel pylon may form a composite concrete part by pouring and curing concrete in the base of the steel pylon in a state where only the lower block constituting the steel pylon is disposed above the leveler.

Meanwhile, the steel pylon may further include a boundary plate formed therein, and the pouring of concrete forming the composite concrete part may be performed with the boundary plate exposed. On the contrary, the steel pylon may further include a boundary plate formed therein, and the pouring of concrete to form a composite concrete part may be performed with the boundary plate embedded in concrete.

As described above, according to the present invention, the steel main tower made of the reinforcement-concrete structure and the steel pylon, which is made of steel, are directly engaged with each other, thereby minimizing cross-sectional expansion of the pylon support.

In addition, according to the present invention, the steel main tower made of steel-reinforced-concrete structure and the steel pylon made of steel material are directly interlocked to each other, thereby maintaining the connection between the pylon and the steel pylon, which are concrete structures in common. Can be minimized.

In addition, according to the present invention, by removing the anchor frame for the connection between the pylon pier and the steel pylon, which is a concrete structure, it is possible to exclude or minimize unnecessary interference with the reinforcing bars inside the pylon pier, thereby making construction easier It can shorten the air.

In addition, according to the present invention, the components for connecting the pylon pier and the steel pylon, which are concrete structures, may not be exposed to the outside air, thereby minimizing maintenance during public use, and minimizing damage such as corrosion, thereby improving durability. Can be.

In addition, according to the present invention, it is possible to control the fine vertical degree of the steel pylon, thereby minimizing the inclination of the steel pylon, and also to ensure structural safety by uniformly distributing the load.

In addition, according to the present invention, by maintaining the airtight (sealed) in the connection portion between the main column pier and the steel main tower of the concrete structure it is possible to minimize damage such as corrosion during public use.

In order to help the understanding of the features of the present invention as described above, it will be described in detail with respect to the cable-stayed bridge column having a synthetic coupling structure and the construction method thereof according to the embodiment of the present invention.

Hereinafter, exemplary embodiments will be described based on embodiments best suited for understanding the technical characteristics of the present invention, and the technical features of the present invention are not limited by the illustrated embodiments, It is to be understood that the present invention may be implemented as illustrated embodiments. Accordingly, the present invention may be modified in various ways within the technical scope of the present invention through the embodiments described below, and such modified embodiments fall within the technical scope of the present invention.

In order to facilitate understanding of the embodiments to be described below, in the reference numerals shown in the accompanying drawings, among the constituent elements which perform the same function in each embodiment, the related constituent elements are indicated by the same or an extension line number.

Embodiments related to the present invention are based on a direct composite coupling in which a steel pylon consisting of a steel column pier and a steel pylon, which are basically reinforced concrete structures, mesh with each other.

2a and 2b is a lower cross-section of the steel pylon 200 is directly engaged with the pylon pier 100 is a reinforced concrete structure for the composite coupling structure of the cable-stayed bridge pylon according to an embodiment of the present invention have.

The cable-stayed bridge pylon according to an embodiment is configured such that a part of the pylon-pier pier 100 which is a reinforced concrete structure extends inside the steel pylon base B, which is one end of the steel pylon main body 210, and engages with the base B. Can be. For this structure, a plurality of studs 211 may be provided on an inner side surface of the base B. The stud 211 may be coupled to the inner surface of the base B by a separate member such as welding or bolting. In this case, the stud 211 may be made of a simple rod or may be provided with a head such as a bolt.

On the other hand, the upper portion of the base (B) may be further provided with a boundary plate 212 therein. The boundary plate 212 may be used to determine the level of concrete that is poured into the interior of the base B as described below.

On the other hand, the boundary plate 212 may be made to serve as a pressure plate. The boundary plate 212 may be configured to be supported by the concrete on which the bottom surface is poured. On the other hand, in order to pour the concrete into the base (B), the boundary plate 212 may be made of a structure through the center portion. For example, the boundary plate 212 has an annular structure along the inner circumference of the upper portion of the base (B) to distribute the load of the steel pylon 200 to have an area that can be transmitted to the pylon support 110. It may be configured.

The steel main tower 200 may be further provided with a reinforcing rib 213 along the longitudinal direction of the inner surface at the upper position of the base (B) like a general main tower. In addition, the steel main tower 200 may be configured to have a reinforcement structure when the partition wall 214 is further provided therein when the cross section width is wide. In this case, the partition wall 214 may be further provided on the inner side of the base B, and the stud 211 may be further provided on the partition wall 214 provided on the inner side of the base B.

The steel pylon 200 may be coupled to the pylon support 110 of the pylon pier 100 to be engaged with the pylon support 110.

As shown in FIGS. 3A and 3B, the pylon pier 100 may be provided with a pylon support 110 at one position thereof. The pylon pier 100 and the pylon support 110 are configured in a state in which reinforcing rods 120 are arranged inside, and a portion of the reinforcing rods 120 extends to an upper portion of the pylon support 110 so that the composite reinforcing portion is formed. This constitutes 121.

The synthetic reinforcing portion 121 may be reinforced to be inserted into the base B of the steel main tower 200. In this case, the reinforcement of the synthetic reinforcing portion 121 may be made of the reinforcement position and the amount of reinforcement that can provide a sufficient coupling force for the main column pier 100 and the steel main column (200). On the other hand, the composite reinforcing bar 121 may be disposed so that the reinforcing bar is disposed between the stud 211 provided inside the main column base (B).

A leveler mounting part 112 is formed at an upper portion of the main column support part 110 as an outer region of the synthetic rebar part 121. The leveler mounting unit 112 is for mounting the leveler 130 to control the verticality of the steel pylon 200 may be formed so that the leveler 130 can be inserted by removing a region of the pylon support 110. have.

The leveler 130 may be disposed on the leveler mounting unit 112 to adjust the horizontality. That is, the vertical degree of the steel pylon 200 is achieved by horizontally adjusting the leveler 130. In this case, the leveler 130 may be disposed to support each corner of the steel main tower 200. On the other hand, the leveler 130 may be composed of H-shaped steel.

That is, a plurality of leveler mounting units 112 are formed on the main column support unit 110, and levelers 130 are disposed on the leveler mounting units 112 to adjust horizontality between the levelers 130. The leveler 130 disposed as described above enables the control of fine verticality of the steel pylon 200, thereby minimizing the inclination of the steel pylon 200, and allowing the load of the steel pylon 200 to be uniformly distributed. have.

As shown in FIG. 4, the leveler 130 may be fixed in a state where the leveler 130 is buried in the upper portion of the pylon support 110 by the buried member 110b. In this case, the buried portion 110b may be formed by grout mortar having high fluidity, or may be made of concrete of the same material as the pylon support 110.

In this case, the upper surface of the leveler 130 may be exposed to the outside to support the lower portion of the steel main tower 200, and only the remaining area may be filled by the buried member 110b.

Meanwhile, the sealing member 140 may be further disposed at a position where the steel main tower 200 is mounted on the main tower support 110.

That is, the position of the main column support portion 110, the base (B) of the main column is disposed before the steel main column 200 is arranged on the upper portion of the main column support portion 110 in a state that the horizontal level is adjusted by the leveler 130. The sealing member 140 may be further disposed on the.

In this case, the sealing member 140 may be disposed along the edge such that the bottom edge of the base B is in close contact, and may be disposed so that the leveler 130 is not exposed to the outside.

As shown in FIG. 5, the steel pylon 200 may be disposed on an upper portion of the pylon support 110. That is, the lower end of the base B of the steel main tower 200 may be disposed in a state supported by the leveler 130. In this case, as mentioned above, the leveler 130 may be disposed to support each corner portion of the base B of the steel pylon 200 so that the steel pylon 200 may be erected in a state in which the verticality is adjusted. On the other hand, the steel pylon 200 is made up of a plurality of blocks, in this case, the rest of the steel pylon 200 in a state in which only the bottom block is coupled to the pylon support 110 in the state standing on the pylon support 110. Blocks may be built.

On the other hand, when the sealing member 140 is further provided, the steel main tower 200 is the base (B) is placed on the sealing member 140 and the lower end of the leveler 130 and the main column base (B) and The confidentiality can be maintained.

In the state where the steel pylon 200 is placed on the pylon support 110, the additional vertical degree of the steel pylon 200 may be further adjusted. In other words, the fine vertical degree of the steel pylon 200 may be further adjusted.

After the steel main tower 200 is disposed to be mounted on the main tower support 110 as described above, as shown in FIGS. 6A and 6B, concrete is poured and cured in the interior of the main tower base B so that the composite concrete part is disposed. To form (111).

That is, the concrete poured into the interior of the pylon base B is cured, and the reinforcement 121 extending to the upper portion of the stud 211 and the pylon support 110 provided on the inner surface of the pylon base B. ) Is composed of a synthetic concrete part 111 forming a synthetic bond. That is, the steel main tower 200 has a main column pier by the coupling force of the composite reinforcement 121 and the studs 211 and the synthetic concrete portion 111 whose base B extends from the main column support 110. It may be installed at (100).

As mentioned above, the pouring of concrete constituting the synthetic concrete part 111 is poured after only the bottom block of the steel main tower 200 provided with the main column base B, or some blocks or the entire steel main column 200 After this hypothesis may be poured through a manhole provided in the steel main tower (200).

In addition, as mentioned above, when the boundary plate 212 is provided in the steel main tower 200, concrete is poured and cured in a state in which the boundary plate 212 is exposed to form a synthetic concrete portion 111. It may be. On the contrary, the boundary plate 212 may be cast and cured so that the concrete concrete portion 111 may be formed to be embedded in the synthetic concrete portion 111.

The construction method of the cable-stayed bridge column and the cable-stayed bridge column with the composite coupling structure according to the present invention is not limited to the embodiments of the cable-stayed bridge tower and the construction method having the composite coupling structure described above, All or some of the embodiments may be selectively combined to enable various modifications.

1A is a longitudinal sectional view schematically showing the structure of a conventional cable-stayed pylon.

FIG. 1B is a partially enlarged cross-sectional view of "A" shown in FIG. 1A.

Figure 2a is a cross-sectional view schematically showing an example of the configuration of the lower portion of the cable-stayed bridge tower having a composite coupling structure according to an embodiment of the present invention.

Figure 2b is a cross-sectional view schematically showing another example of the configuration of the lower part of the cable-stayed bridge tower having a composite coupling structure according to an embodiment of the present invention.

3A is a partial longitudinal cross-sectional view illustrating a state in which a leveler and a composite reinforcing part are installed in a main column support part of a main column pier to construct a cable stayed bridge main column having a composite coupling structure according to an embodiment of the present invention.

3B is a partial plan view of FIG. 3A.

Figure 4 is a partial longitudinal cross-sectional view showing a state in which the sealing member is disposed in the area in contact with the lower portion of the steel pylon to construct a cable-stayed bridge having a composite coupling structure according to an embodiment of the present invention.

Figure 5 is a partial longitudinal cross-sectional view showing a state in which the steel pylon is disposed on the pylon support for the construction of the cable-stayed bridge pylon having a composite coupling structure according to an embodiment of the present invention.

Figure 6a is a partial longitudinal cross-sectional view showing a configuration example of the structure of the steel pylon and the pylon pier of the cable stayed bridge pylon having a composite coupling structure according to an embodiment of the present invention.

FIG. 6B is a diagram illustrating an example of the “A-A” cross-sectional structure illustrated in FIG. 6A.

* Description of the main parts of the drawings *

100 ... pylon pier 110 ... pylon support

111 ... Synthetic concrete section 120 ... Rebar

121 ... Composite rebar 130 ... Leveler

140 ... sealing member 200 ... steel pylon

210 ... pylon body 211 ... stud

212 ... border plate 213 ... reinforcement rib

B ... Pylon Donation

Claims (13)

In the cable-stayed bridge pylon, where the steel pylon is erected from steel, The pylon pier is provided with a pylon support portion on which the lower end of the steel pylon is placed, a composite reinforcing bar extending to an upper portion of the pylon support portion, and a leveler embedded in the pylon support portion with an upper portion exposed from the pylon support portion. The steel pylon is provided with a space in which the composite reinforcing portion is disposed inside, a plurality of studs are provided on an inner surface of the steel pylon base, and the inside of the steel pylon base is combined with the stud and the synthetic reinforcing portion. Cable-stayed bridge tower having a composite coupling structure, characterized in that the composite concrete unit is provided. [Claim 2] The cable stayed bridge of claim 1, wherein the steel main column is further provided with a boundary plate, and the boundary plate is disposed in a state of being embedded in a synthetic concrete part. The composite coupling structure of claim 2, wherein the boundary plate has an annular structure along an inner circumference at an upper position of the steel pylon base to distribute the load of the pylon to the pylon support. Having a cable-stayed pylon. 3. The cable-stayed bridge column according to claim 2, wherein the steel main column has a reinforcing rib disposed in an upper region of the boundary plate, or a partition wall is disposed above and below the boundary plate. 2. The cable stayed bridge pylon of claim 1, wherein the leveler is disposed at each corner of the steel pillar. The cable-stayed bridge pylon having a composite coupling structure according to claim 1, wherein a sealing member is further disposed between the circumference of the lower end of the steel pylon and the leveler and the pylon support that are in contact with the circumference of the bottom of the steel pylon. Forming a plurality of studs on the inner side of the steel pylon base; A pier forming step in which a pylon support is formed and the composite reinforcing parts are extended to an upper portion of the pylon support; Forming a leveler mounting portion on top of the pylon support; Installing a leveler on the leveler mounting unit to adjust a level of the leveler so that a main tower having a stud formed at a base thereof can be installed in a horizontal state; Placing the steel pylon on the pylon support in a state in which the steel pylon is horizontally adjusted by the leveler; Placing and curing concrete inside the steel pylon base installed in the pylon support to form a synthetic concrete portion to be combined with the stud and the synthetic reinforcing portion; the cable-stayed bridge pylon having a composite coupling structure comprising a Construction method. The composite coupling device of claim 7, wherein the leveler is installed to be disposed at each corner of the steel pylon and is buried by a buried member so that the remaining area except the surface contacting the lower end of the steel pylon is not exposed to the outside. Construction method of cable-stayed pylon with structure. 8. The sealing member according to claim 7, wherein the sealing member is further disposed at a position of the main column support where the base of the steel main column is disposed before the steel main column is horizontally adjusted by the leveler. Construction method of the cable-stayed bridge pylon having a synthetic coupling structure. 10. The method of claim 9, wherein the sealing member is disposed so that the leveler is not exposed to the outside. The cable stayed bridge having a composite coupling structure according to claim 7, wherein the steel pylon forms a synthetic concrete part by placing and curing concrete in the steel pylon base in a state in which only the lower blocks constituting the pylon are disposed above the leveler. Construction method of pylon 8. The construction of the cable-stayed bridge pylon with composite coupling structure according to claim 7, characterized in that the steel main column further has a boundary plate formed therein, and the casting of concrete forming the composite concrete part is carried out with the boundary plate exposed. Way. 8. The cable-stayed bridge pylon having a composite coupling structure according to claim 7, wherein the steel main tower further has a boundary plate formed therein, and the pouring of concrete forming the composite concrete part is carried out with the boundary plate embedded in concrete. Construction method.

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