RU145953U1 - Cable-stayed Bridge - Google Patents

Abstract

A cable-stayed bridge containing pylons installed along the facade of the bridge and mounted on bridge supports, and a stiffening beam supported by inclined parallel shafts located on both sides of each pylon and one end fixed on the stiffener, and the other end on the pylon along the height of the pylon, characterized in that each pylon is made of two inclined and diverging to the sides of the branches and from the side of the facade has the appearance of a dovetail, in addition, each pylon is equipped with a rigid cable connecting the ends of the divergent Wei pylons.

Description

The utility model relates to the field of bridge construction, namely to the construction of cable-stayed-beam bridges.

Known cable-stayed bridge, which contains a stiffener beam; two-pillar pylons with upright racks, a metal beam of rigidity and two pairs of cables. The disadvantages of this technical solution is the reduced spatial rigidity due to the fact that this design provides for the fastening of the stiffness beam with only two cables; as well as the need for a large number of building materials (SU 1353864, IPC E01D 11/00, publ. 23.11.87, Bull. No. 43).

The prototype of the proposed cable-stayed bridge is a cable-stayed bridge with parallel cables (Cable-stayed bridges., Ed. By Doctor of Technical Sciences, Professor .. A.A. Petropavlovsky, Moscow, "Transport", 1985, p. 13, Fig. 1.12, d, p. 64, Fig. 3.1, c). Known and adopted as a prototype cable-stayed bridge contains pylons installed along the facade of the bridge and mounted on bridge supports, and a stiffener beam supported by inclined parallel cables. The cables are located on both sides of each pylon and are fixed at one end to a stiffener beam, and at the other end to a pylon along its entire height.

The presence of stiffness beams in the prototype allows to increase the stiffness of the bridge, its bearing capacity, aerodynamic stability, and also simplifies the installation of the bridge structure.

In the classical cable-stayed system, to which the specified prototype also applies, the height of the pylon should be approximately 1 to 10; that is, for every 1 meter of height there is 10 meters of the span, this is the scheme that provides the best stability and rigidity of the structure, therefore a large pylon height is required. The disadvantage of this scheme is the high cost of building a pylon with large span lengths; and with a high pylon height, the length of the cables increases, which also affects the cost of the bridge; difficulties arise when tensioning the cables, their anchoring, which often leads to rupture of the cable bundles during tension.

The objective of the utility model is to create the most economical design of the cable-stayed bridge with overlapping large spans while maintaining load-bearing capacity, increasing aerodynamic stability and simplifying installation.

The technical result during the operation of the proposed cable-stayed bridge is to increase the rigidity of the structure, increase the stability of the stiffener by improving torsional work and increasing resistance to wind loads.

The task and the technical result are achieved as follows.

The cable-stayed bridge according to the utility model, like the prototype, contains pylons mounted along the facade of the bridge and mounted on bridge supports, and a stiffening beam supported by inclined parallel cables located on both sides of each pylon and one end mounted on the stiffener and the other end - over the entire height of the pylon.

Unlike the prototype, in the inventive cable-stayed bridge, each pylon is made of two inclined and diverging branches to the sides and from the facade it has the appearance of a dovetail. The cables are fixed parallel to the entire height of the pylon branches. The difference is also that each pylon is equipped with a rigid cable connecting the ends of the diverging branches of the pylon.

The resulting design in the form of a "dovetail" allowed to reduce the height of the pylon, the length of the cables, reduce the number of building materials to create this design, while maintaining the rigidity of the supporting structure and the aerodynamic characteristics of the cable-stayed bridge. Reducing the height of the pylon according to the proposed design allowed us to solve the problem.

The essence of the utility model is illustrated by the drawing, which shows a General view of the span of the cable-stayed bridge.

The cable-stayed bridge contains a beam of rigidity 1, pylons mounted on a bridge support 5 and made of two branches 2 and 6; and cables 3, some ends of which are fixed on the beam 1, and others - along the height of the pylon, that is, along the entire length of the branches 2, 6 pylons. A rigid cable 4 connects the branches 2, 6 of the pylon for stability.

The manufacture of this bridge is carried out in stages:

1. The construction of the support 5 for the further creation of the pylon.

2. Creation of a temporary construction site at the design level of the roadway.

3. Creating a formwork for mounting the branches of the pylon, with the subsequent placement of a reinforcing cage into it and pouring concrete into it.

4. Installation of the stiffening beam 1, with the simultaneous fastening of the cables 3 both on the stiffening beam 1, and along the entire height of the pylon branch.

The claimed cable-stayed bridge operates as follows.

The vertical load from the vehicles is perceived by a stiffener 1, which, through a system of spatially arranged cables 3, transfers pressure to the pylon parts (branches 2, 6). At the same time, the spatially located guys 3 improve the work of the structure for torsion and the perception of wind loads, allow you to support the stiffener 1 for a large extent.

Claims (1)

A cable-stayed bridge containing pylons installed along the facade of the bridge and mounted on bridge supports, and a stiffening beam supported by inclined parallel shafts located on both sides of each pylon and one end fixed on the stiffener, and the other end on the pylon along the height of the pylon, characterized in that each pylon is made of two inclined and diverging to the sides of the branches and from the side of the facade has the appearance of a dovetail, in addition, each pylon is equipped with a rigid cable connecting the ends of the divergent Wei pylons.