RU2617568C1 - Shake table - Google Patents

Abstract

FIELD: testing equipment.

SUBSTANCE: shake table relates to test equipment and reproduces the seismic loads in three-dimensional form of damped oscillations. Shake table comprises a plate element for placement of the test facility or building, mounted on bearings which are mounted on additional prokladnuyu plate which in turn rests on the foundation through pliable in a horizontal direction and is connected to the support wall and the foundation via hydraulic actuators.

EFFECT: providing the possibility of generating three-dimensional damped oscillations.

6 cl, 6 dwg

Description

The invention relates to test equipment, in particular to seismic platforms intended for testing building structures for earthquake resistance.

A known vibration platform for testing structures for earthquake resistance, containing the main platform attached to the elastic suspensions to the foundation racks, a directional vibrator, hydraulic jacks to bring the platform out of neutral position, an additional platform mounted also on elastic suspensions and connected to the main platform by hydraulic cylinders, horizontal spring shock absorbers, a system of plate brakes made with the possibility of changing the braking forces, and on the foundation of the vibration platform between the main and additional platforms mounted stops (SU No. 207438, G01M 7/04, 12/22/1967, bull. No. 2).

The disadvantage of this vibration platform is the generation of seismic effects only in the form of horizontal or vertical vibrations.

A known seismic stand containing a platform for securing the test product, elastically connected to the base, and means for exciting two-dimensional damped oscillations of the platform with the product, which are made in the form of an eccentric, drive its rotation, connecting them with a coupler coupled to disengage after one rotation of the shaft, and located at an angle to the plane of the platform of the flexible element connecting the platform to the eccentric (SU No. 808895, G01M 7/00, 02/28/1981, bull. No. 8).

The disadvantage of this seismic stand is the generation of seismic effects only in the form of two-dimensional oscillations.

The closest technical solution to the claimed seismic platform is a seismic platform containing a plate for placement of the test element of the structure or building, mounted on the pendulum supports and connected to the foundation and the wall using hydraulic actuators, the pendulum supports mounted on the support frame (Lyan-Ywan Lu et al. Eccentric Rocking Bearings with a Designable Friction Property for Seusmic Isolation: Experiment and Analysis // EARTHQUAKE SPECTRA, the professional Journal of the Earthqueke Engineering Research Institute. - 2013.- V. 29, N. 3. - P. 869-895).

The disadvantage of this vibration platform is the generation of seismic effects only in the form of horizontal or vertical vibrations.

The objective of the invention is the creation of a seismic platform that allows you to reproduce seismic loads in the form of three-dimensional damped oscillations.

The technical result is achieved by the fact that in a seismic platform containing a plate for placement of the test element of a structure or building, mounted on supports, hydraulic actuators connected to the wall and the foundation, the supports are installed on an additional gasket plate, which in turn rests on the foundation through ductile horizontal direction of the support and is connected to hydraulic drives.

An additional gasket plate can be L-shaped, the side wall of which is connected to the plate to accommodate the tested element of the structure or building using elastic elements.

An additional gasket plate can be made in a trough-shaped form, the side walls of which are connected to the plate to accommodate the tested element of the structure or building using elastic elements.

Elastic elements and supports can be made in the form of Belleville springs.

Supports can be made in the form of rubber mounts. Supports in the horizontal direction of the support can be made sliding.

The invention is illustrated by drawings, where in FIG. 1 shows a general view of a seismic platform; FIG. 2 shows a seismic platform with an L-shaped plate, FIG. 3 shows a seismic platform with a trough plate; in FIG. 4 shows a seismic platform in which the elastic elements and supports are made in the form of disk springs, in FIG. 5 shows a seismic platform in which the supports are made in the form of rubber-metal supports, in FIG. 6 shows a seismic plate in which horizontal compliant supports are made sliding.

The seismic platform contains a gasket plate 1, through hydraulic actuators 2, 3 connected to the foundation, and a hydraulic actuator 4, connected to the wall, and mounted on horizontal compliant supports 5, 6. Hydraulic actuators 2, 3, 4 operate from a hydraulic pulsating installation ( not shown). The gasket plate 1 is connected to the plate 7 to accommodate the test element 8 of a building or structure using supports 9, 10, which can be made in the form of coil springs (Fig. 1), plate springs (Fig. 4), rubber-metal supports (Fig. 5 ) On the plate 7, the test element 8 of the building or structure is placed with an offset relative to the center of the plate. The gasket plate 1 can be made L-shaped (Fig. 2), the side wall of which is connected to the plate 7 to accommodate the test element 8 of the structure or building using elastic elements 11. The gasket plate 1 can be made trough-shaped (Fig. 3) , the side walls of which are connected to the plate 7 to accommodate the test element 8 of the structure or building using elastic elements 11, 12. Horizontal compliant supports 5, 6 can be made sliding (Fig. 6).

The vibrations of the gasket plate 1 are excited by hydraulic drives 2, 3, 4. The plate 7 for accommodating the test element 8 of the structure or building is supported by the gasket plate 1 through supports 9, 10 made in the form of coil springs.

The test element 8 of the structure or building is raised to a height above the level of the gasket plate 7 in order to create a torsion moment. Also in terms of the test element 8 of the structure or building is located with an offset relative to the center of the plate 7, which creates a torsion moment.

The seismic platform works as follows: when oscillations are generated by hydraulic actuators 2, 3, 4 operating from a hydraulic pulsating installation, the gasket plate 1 performs two-dimensional movement, and the plate 7 due to the elastic elements 11, 12 and the eccentric fastening of the test element 8 of the structure or building makes a three-dimensional movement.

Claims (6)

1. A seismic platform containing a plate for placement of the test element of a structure or building, mounted on supports, hydraulic actuators connected to the wall and the foundation, characterized in that the supports are installed on an additional gasket plate, which in turn rests on the foundation through flexible horizontal direction of support and is connected to hydraulic actuators. 2. The seismic platform according to claim 1, characterized in that the additional gasket plate is made of an L-shaped shape, the side wall of which is connected to the plate to accommodate the tested element of the structure or building using elastic elements. 3. The seismic platform according to claim 1, characterized in that the additional cushioning plate is made of a trough-like shape, the side walls of which are connected to the plate to accommodate the tested element of the structure or building using elastic elements. 4. The seismic platform according to any one of paragraphs. 1-3, characterized in that the elastic elements and supports are made in the form of Belleville springs. 5. The seismic platform according to any one of paragraphs. 1-3, characterized in that the supports are made in the form of rubber mounts. 6. The seismic platform according to claim 1, characterized in that the compliant in the horizontal direction of the support is made sliding.

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