SU1260450A1 - Earthquake-proof support - Google Patents

Abstract

The invention relates to earthquake resistant supports and makes it possible to increase their earthquake resistance. The seismic resistant support is located between foundation 1 and the supra-foundation structure 2 and consists of upper and lower support plates 3 and 4, made with stop flanges 5 and 6 and with a shock-absorbing ring 9 between the stop collars, ball elements 7 placed in an elastic separator 8 between the support plates 3 and 4 and anchored in the base of the conical sleeve 13. The conical sleeve 13 interacts with the lower support plate 4 by means of a hollow conical element 12 rigidly attached to the lower surface of the plate 4 and coaxially placed in nical holder 13 with a gap, in which a spring 20 in the form of a corrugated conical shell. The cavity of the conical element 12 and the gap between it and the conical sleeve 13 are filled with an anti-friction fluid 21. Under seismic influence, its horizontal and vertical components are perceived by a shock-absorbing ring 9, an elastic separator 8 and a spring 20. 6 Il. (L 1C and about 1 SP

Description

The invention relates to the construction, in particular to the design of earthquake-resistant supports of buildings and structures.

The purpose of the invention is to increase the seismic stability of the support.

FIG. 1 shows earthquake-resistant supports along the baseline with the seismic structure located on them; in fig. 2 — node I in FIG. one; in fig. 3 - corrugated conic spring; in fig. 4 is a view A of FIG. 3; in fig. 5 is a variant of a set of toroidal hollow or elastic springs; in fig. 6 is a variant of corrugated lamellar springs located along the generatrix of a cone.

Earthquake support is placed between the foundation 1 and the superfoundment structure 2 and contains the top 3 and bottom 4 base plates. A thrust flange 5 is rigidly attached to the upper support plate 3, and a thrust flange 6 is fixed to the lower support plate 4. Spherical elements 7 located in the hemispherical slots of elastic separators 8 are placed between the support plates 3 and 4. Between the thrust flanges 5 and 6 a shock-absorbing ring 9 is installed. The upper support plate 3 is made with the upper convex spherical part 10, which is connected to the supra-foundation structure 2 by means of a vertical rod 11. The lower support plate 4 is made with a hollow conical element 12, which is attached 1 conical yoke 13, anchored in base 1. Last placed in foundation 1 with excess relative to its upper edge and made with outer anchor rings 14, and supporting plates 3 and 4 are connected between themselves by means of horizontal lugs 15 with studs 16. Lower support plate 4 is supported on the upper end of the conical sleeve 13 through elastic gaskets 17, and the conical element 12 is made with a hole 18 at the top and with through holes 19 in the upper part and placed in a conical holder 13 with a gap in which the springs are located and 20, made in the form of a corrugated conical shell with slits on the side of its top. The cavity of the conical element 12 and the gap between it and the tapered yoke are filled with an anti-friction fluid 21.

Earthquake support works as follows.

Before the seismic effects at the statically balanced position, all the support elements are located symmetrically about the vertical axis under the action of only vertical static loads. In this case, the corrugated conic spring 20 is in the initial tense position between the yoke 13 and the conical element 12 under the action of a vertical load and is held

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by the vertical component on the lines of contact of the surface of the conical element 12 with a corrugated conical spring 20, which in turn conveys the same force and the conical holder 13.

Under seismic action in any direction at an angle ct with amplitude A, the underframe structure 2 is moved relative to foundation 1. The movement by A value is perceived by the resistance and deformation of the elastic elements 8 and the damping ring 9, which absorbs the energy of the horizontal seismic force component.

The vertical component of the force and amplitude of the seismic impact A sinoC is perceived by a corrugated conical spring 20, which can be calculated to the calculated magnitude of the seismic effects.

At the end of the seismic action under the influence of elastic separators 8, covering the spherical elements 7, corrugated conical spring 20 building, the structure moves up to -shift with the vertical axis of all support elements, smoothly damping without sharp jolts.

The technical and economic advantages of a seismic resistant support lie in its ability to perceive the seismic effects of an increased scale. At the same time, the shock-absorbing and damping devices of the support ensure a smooth return of the structure, the building, to its original static state.

Claims (1)

Invention Formula A seismic resistant support placed between the foundation and the superstructure of the structure, including the upper and lower support plates with abutting sides, ball and elastic elements placed between the support plates, a shock-absorbing ring installed between the enclosing sides of the support plates, and vertical springs, with the upper support plate made with a convex spherical upper part connected to the superstructure with a vertical rod, characterized in that, in order to increase the seismic resistance and the structure, the support is provided with a tapered tapering downward casing placed in the foundation exceeding relative to its upper edge and made with external support and anchor rings, and the support plates are interconnected by horizontal lugs with studs, and the lower support plate is supported on the upper end of the conical sleeve through elastic straps and is made with a conical element rigidly attached to it. having a through hole at the apex and placed with a gap in the conical holder, the springs are made in the form of a corrugated conical shell with slots on the side of its vertex and are installed in the gap between the conical holder and the conical element, and the elastic elements are made in the form of a separator with sockets for ball elements, while the cavity of the conical element and the gap between it and the tapered yoke are filled with antifriction fluid. { { View K FIG. four fpuz.3 7J