RU158433U1 - SEISMIC RESISTANT HYDRODYNAMIC ROMBIC COLUMN - Google Patents

Abstract

An earthquake-resistant hydrodynamic column, consisting of four metal pipes of the same diameter, located in the base in the form of a rhombus, connected around the perimeter by tie braces with bowls arranged in a checkerboard pattern.

Description

The field of technology.

The utility model relates to the field of bridge construction and can be used in the design and construction of multifunctional bridges in order to save the bridge from destruction during various vibrations and during an earthquake.

The level of technology.

As an analogue to the presented utility model, the applicant points to the patent of the invention No. 2475586 "DEVICE FOR THE HYDRODYNAMIC EXTINGUISHER OF OSCILLATIONS OF THE BRIDGE SPAN" with a priority of July 29, 2011, designed to damp the vibrations of the bridge span. However, this technical solution, as described, acts from top to bottom (from the carriageway to the supports) and is already applicable for the shaking bridge.

Disclosure of a utility model.

- the presence of structural elements;

- characteristics of the elements and their relationship.

The main objective of the technical solution is to maintain the integrity of the bridge from destruction during various vibrations and during an earthquake.

The essence of the utility model is that an earthquake-resistant hydrodynamic rhombic column consists of four metal pipes of the same diameter, located in the base in the form of a rhombus, connected around the perimeter by tie braces with bowls arranged in a checkerboard pattern.

A brief description of the drawings.

The essence of the utility model is illustrated by drawings, where:

Fig. 1 - General image of an earthquake-resistant hydrodynamic rhombic column.

Implementation of a utility model.

The inventive utility model "Earthquake-resistant hydrodynamic rhombic column" relates to the field of bridge construction and can be used in the design and construction of bridges for multifunctional purposes in order to save the bridge from destruction during various vibrations and during an earthquake.

The column consists of four metal pipes of the same diameter, two of which are supporting (1, 2), and two auxiliary (3, 4). The pipes are lowered into the drilled wells to a depth of 3-4 meters, secured with concrete (11), located in the shape of a rhombus at the base. Pipes are made of anticorrosive metal or metal plastic. The thickness and diameter of the pipes are calculated from the load. The pipes are connected using the most durable, having 4 stiffening ribs rhombic tie-rods (5) fixed at an angle of 45 degrees. To install the couplers on the pipes, sleeves (6) with eyes (7) are fastened with bolts (10). Tie-spacers distribute the load along the perimeter of the column between the pipes and in the event of an earthquake they will transfer shocks from one pipe to another, since not all four will bounce pipes. Flat tie-rods (8) hold all four pipes in a given direction, and with pushing the flat couplers will bend, because two pipes will jump up for fractions of a second before the others, and thereby dampen the vibrations. Sliding bushings with eyelets give rigidity and strength to the pipes, while maintaining the flexibility of the pipes on which they are located. Bowls (9) with stiffeners made of plastic are dressed stiffly on pipes in a staggered manner, starting from the foundation, when pushing from below they will compress the water particles in the bowl, since the propagation velocity of the shock wave in solid materials is higher than in water, then braking will occur shock wave on the upper layers of water above the bowls. When the pipes are lowered back, the conical shape of the bowls will not contribute to a sharp jump down to the foundation.

If the wave has a height of more than 5 meters, then it will also be 5 meters below the horizon, and so that the bowls are not exposed to the waves, they should stand on the pipes below the expected minimum wave level.

This technical solution allows you to save the bridge from destruction during various vibrations and during an earthquake.

Claims (1)

An earthquake-resistant hydrodynamic column, consisting of four metal pipes of the same diameter, located in the base in the form of a rhombus, connected around the perimeter by tie braces with bowls arranged in a checkerboard pattern.

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