RU41736U1 - DEVICE FOR LOWERING BRIDGE SPAN STRUCTURES - Google Patents

Abstract

The utility model relates to bridge building and can be used when lowering the span to permanent supports. The method of lowering the bridge spans consists in sequentially choosing the deflection of the bridge span on the bridge supports, mounting the support bags on the sub-frame, resting the span on them, installing sandboxes with hydraulic jacks built into their pistons, resting the span on sandboxes and gradually lowering the span to the project position by gradually removing sand from sandboxes and the corresponding elements of safety bags. On each intermediate support, a battery of at least 4 sandboxes with hydraulic jacks built into the pistons is installed along the axes of the extreme planes of the span, and on the extreme supports a battery of at least 2 sandboxes with hydraulic jacks integrated into the pistons, hydraulically combine the hydraulic jacks with each other in the battery with the help of pipelines, after which a sequential stepwise lowering of the span on each support is carried out simultaneously on two extreme planes of the span. A uniform distribution of support reactions between sandboxes is achieved by constantly maintaining the working pressure in the battery of jacks during the lowering of the span, while the size of the single-stage lowering on one support should be no more than 100 mm. A device for lowering bridge spans contains safety bags, sandboxes with hydraulic jacks integrated in the piston, supports mounted on the crossbar and interacting through the pistons and hydraulic jacks with the main span beams with

Description

The utility model relates to bridge construction and, in particular, to the technology for lowering bridge spans.

There is a method of lowering the bridge spans, consisting in the sequential selection of the deflection of the bridge span on the bridge supports, mounting the supports of the support packages on the sub-shells and resting the span on them, installing sandboxes with hydraulic jacks built into their pistons, resting the span on the sandboxes and phasing down the span to the design position by gradually removing sand from the sandboxes / 1 /.

The disadvantage of this method of lowering the spans is the impossibility of meeting strict technological requirements for observing the uniform distribution of support reactions between sandboxes, when there are more than two of them on one support.

A device for lowering the span, including safety bags, sandboxes with hydraulic jacks integrated in the piston, mounted on the bolt of the support and interacting through the pistons and hydraulic jacks with the main beams of the span / 1 /.

A disadvantage of the known device is the use in single sandboxes of jacks of low carrying capacity, which are used only for splitting and not allowing to ensure uniform lowering of the planes of the superstructure.

The utility model aims at eliminating distortions when lowering the span, providing an even distribution of support reactions in the process of lowering the span between sandboxes when there are more than two of them on one support.

The problem is solved due to the fact that in the method of lowering the bridge spans, consisting in the sequential choice of deflection

the span structure on the bridge supports, the installation of safety bag supports on the sub-frame and resting the span structure on them, installing sandboxes with hydraulic jacks embedded in their pistons, resting the span structure on the sandboxes and gradually lowering the span structure to the design position by gradually removing sand from the sandboxes and corresponding elements safety bags, at each intermediate support, at least 4 sandboxes with hydraulic jacks built into the pistons are installed along the axes of the extreme planes, hydraulically and combine the hydraulic jacks with each other in the battery using pipelines, after which sequential stepwise lowering of the span on each support is carried out simultaneously along the two extreme planes of the span, uniformly distributing support reactions between the sandboxes by constantly maintaining the working pressure in the jack battery during lowering of the span structures, while the value of a single stage of lowering on one support should not exceed 100 mm.

The problem is also solved due to the fact that in the device for lowering the bridge spans containing safety belts, sandboxes with hydraulic jacks integrated in the piston, bearings mounted on the crossbar and interacting via pistons and hydraulic jacks with the main span beams, sandboxes with hydraulic jacks built into the piston combined in batteries of 4 pcs. in each, located under the main beams of the extreme lateral branches of the superstructure, the hydraulic jacks built into the pistons of the sandboxes have a large carrying capacity, for example, at least 200 te, and are hydraulically interconnected by pipelines.

Figure 1 shows the omitted span, top view. Figure 2 shows a sandbox mounted on a bridge support, side view. The span structure of 1 bridge after sliding it into the span is supported through knurling devices on supports 2, 3, 4, 5, and the bottom of the span 1 is located above the design elevation, as practice shows, by 1.5-3.0 m. To lower the span Building 1 to design position

successively on each of the supports 2, 3, 4, 5, select a deflection, remove the knurling devices, mount the safety bags 6 on the sub-fermenters of the supports 2, 3, 4, 5 and rest on them the span 1. Then on the supports 2, 3, 4, 5 carry out the installation of the device for lowering the span 1, including batteries of 4 sandboxes 7 with hydraulic jack batteries 8 of heavy lifting capacity 8 (at least 200 te) and a pump station 9. Battery jacks 8 of each sandbox battery 7 are hydraulically interconnected using pipelines 10.

Batteries of 4 sandboxes 7 and 4 hydraulic jacks 8 are placed on the intermediate supports 3, 4 along the axes of the extreme planes 11, 12 of the span 1.

Batteries of 2 sandboxes 7 and 2 hydraulic jacks 8 are placed on the extreme supports 2, 5 also along the axes of the extreme planes 11, 12 of the span 1.

Lowering the span is as follows. On the intermediate support 3 with the help of hydraulic jacks 8, the span 1 is raised to a visible separation from the top of the safety bags b, the safety half rings (not shown) are installed on the pistons 13. Safety bags 6 rebuild, reducing their height by the value of a single lowering of at least 100 mm. Then at the same time along the extreme planes 11, 12, by removing sand from the sandboxes, the pistons 13 with hydraulic jacks 8 of the sandboxes 7 and, accordingly, the bottom of the span 1 are lowered until it rests on the safety bag 6. Then, the operations on the supports 2, 4, 5 are carried out sequentially in stages. etc. to the final lowering of the span.

The uniform distribution of support reactions between the sandboxes 7 is carried out by maintaining a constant working pressure in the integrated hydraulic system of the hydraulic jack battery 8 during the entire period of lowering the span 1, which ultimately ensures the elimination of emergency situations associated with unforeseen deformations of the span being lowered. Also indicated technology

allows you to constantly monitor changes in supporting reactions throughout the lowering of spans.

Source of information taken into account:

1. A.V. Kruchinkin, V.K.Bely “Installation of steel spans for bridges”, Moscow, “Transport”, 1978, pp. 120-123, “Installation of spans for supporting parts”.

Claims (1)

A device for lowering bridge spans, containing safety bags, sandboxes with hydraulic jacks integrated in the piston, supports mounted on the crossbar and interacting via pistons and hydraulic jacks with the main span beams, characterized in that sandboxes with hydraulic jacks integrated in the piston are combined in at least 2 batteries PCS. in each, they are located under the main beams of the extreme lateral branches of the superstructure, and the hydraulic jacks built into the pistons of the sandboxes are constantly under working pressure, have a large load capacity, for example, at least 200 tf, and are hydraulically interconnected by pipelines.