RU2024689C1 - Device for antiseismic protection of structures - Google Patents

Abstract

FIELD: antiseismic protection. SUBSTANCE: device comprises support articulated to above-foundation part of the structure and rests on the foundation via the members of movable joint in the form of balls enclosed in cage. Installed on foundation coaxially with support is an open-top sleeve accommodating a spring whose upper end bears against lower surface of support. EFFECT: improved design. 3 cl, 3 dwg

Description

 The invention relates to earthquake-resistant construction and can be used in the construction of foundations of buildings constructed in seismic areas.

 In the construction of structures erected in seismic regions, devices are widely used that ensure the reduction of overloads transferred to the building during an earthquake.

 A known design of a seismic insulating sliding belt, made in the form of a series of supports located between the foundation of the building and above-ground structures. Each support has two plates - stainless steel and fluoroplastic - 4. In the event of an earthquake, when the inertial loads exceed a certain level, the building along the plane of the steel and fluoroplastic plate begins to slip relative to the foundation, which leads to a decrease in the accelerations affecting the building. To reduce the horizontal movement of the building relative to the foundation in the sliding belt, limiters are provided, which are made elastic in the form of rubber parallelepipeds to mitigate the collisions of the supports with the foundation.

 Known design elasto-sliding supports for auth. N 910989, consisting of two metal sheets, one of which is fixedly attached to the building structure, and the other is made in the form of a pallet and mounted freely on the supporting surface of the building structure (foundation). Between these sheets there is an elastic layer and springs. The springs are fixed on the top sheet and have the ability to slide (rolling) relative to the bottom sheet of the pallet.

 Under seismic action, parts of the structure move relative to each other with a decrease in the resulting vertical and horizontal accelerations.

The disadvantages of this design, as well as the seismically insulating sliding belt, is that the maximum transverse load transmitted to the structure (which is the most critical for the structure compared to the vertical) is uniquely determined by the friction force (coefficient) in the contact zone of the pallet with the supporting surface of the foundation and cannot be less than this effort, namely:
X _max = F _max = n _max ^y - G - f _mp , where X _max - maximum lateral load;
F _max - the maximum friction force in the contact of the pallet with the supporting surface of the foundation;
n _max ^y - maximum vertical overload;
G is the weight of the structure per one support;
f _mp is the coefficient of friction.

Since n _max ^y and G are given parameters that cannot vary, the load X _max is determined by the coefficient of friction. This does not allow to achieve a high level of seismic isolation of the structure.

 The devices described in the application of Japan N 47-39174 and ed.St. N 896190, contain a solution that allows to reduce the maximum lateral loads on structures in an earthquake while limiting the relative lateral movements. It consists in mounting the structure on rolling bearings with the installation of damping devices "working" with these supports in parallel. The purpose of the damping devices is to reduce the relative movements of the structure relative to the foundation, subject to the restrictions on the transmitted loads. The effectiveness of solving this problem is determined by the type and stability of the power characteristics of the damping device (the dependence of the transverse force on the kinematic parameters of the displacement of the structure relative to the foundation).

 The research results show that the best type of characteristic is the characteristic of "dry friction" - see Fig. 1.

 The indicated dry friction type characteristic allows, with the required transverse load limitation, to achieve the greatest efficiency in reducing the relative transverse displacements of the structure and foundation, to avoid resonance phenomena in the wide frequency spectrum that characterizes the earthquake conditions.

 The "elastic" type of characteristic is substantially less effective (when the force is almost uniquely determined by the magnitude and sign of the displacement - regardless of the direction of movement at this displacement) - see Fig. 2.

 For any specific parameters, the characteristics of the shaking spectrum always contain frequencies that lead to resonance phenomena, leading to increased loads and displacements.

 The device according to the application of Japan N 47-39174 (class E 04 B 1/98, 1972) contains two rows of rollers located one above the other and separated by an intermediate plate, providing lateral displacements of the structure relative to the foundation. The plates, between which the rollers are placed, are equipped with ribs running along the perimeter, which in the lower plate, fastened to the foundation, forms a groove, which includes a rib fastened to the top plate fixed to the structure. The groove is filled with fine-grained material.

 During an earthquake, the movement of fine-grained material placed in the groove occurs with the help of a rib attached to the top plate, which dampens (reduces) the vibrations of the structure relative to the foundation.

 The disadvantages of the damping device used in this development include the lack of elements for regulating its power characteristics, its instability due to the dependence of the arising forces on the high-speed displacement mode (as opposed to the dry friction characteristic), which reduces the seismic isolation efficiency of the structure to a certain extent.

 The closest in design to the device is a device for auth. N 896190.

 The device contains enclosed ball elements on which a structure (building) is installed, placed between the flat sections of the support block and the lower base plate. A spherical recess is made in the plate, in which a ball element is also placed. The radius of this ball element is less than the radius of the spherical recess. The device has a spring-loaded rod located in the vertical hole of the support block, resting with its flat head on a ball element placed in a spherical recess. The compression of the spring-loaded rod of the elastic element is regulated by means of an adjusting nut installed on the rod.

 At the moment of seismic impact, lateral vibrations of the foundation relative to the building occur, and spherical elements, perceiving the weight of the building, roll over the flat sections of the support block and the lower base plate. Friction arising in this case in contact of the ball elements with the supporting surfaces and cages, to some extent contribute to the damping of vibrations. In addition, the ball element, enclosed in a spherical recess, moves upward along its surface along with the rod, compressing the elastic element. Under the action of elastic forces, the ball element tends to return to its original position, helping to reduce the lateral displacements of the building relative to the structure.

 The disadvantages of this design include the following.

 The spring-loaded rod system with a ball located in a spherical recess has an “elastic” type of power characteristic, moreover, the characteristic is “rigid”, that is, with stiffness increasing with increasing lateral displacement (see Fig. 2).

 The indicated characteristic, being “elastic”, does not ensure the elimination of resonance phenomena, and being “rigid” cannot provide a high degree of seismic protection, since, giving a good effect in terms of reducing relative displacements, such a characteristic implements rather significant loads. The damping effect of the frictional forces of the ball elements on the building vibrations that occur during an earthquake, firstly, is insignificant (since this is rolling friction), and secondly, the device does not have elements that allow these forces to be set to the required level (preload adjustment device springs are intended for installation at a given level of "elastic" force, returning the support block to its original state).

 The aim of the invention is to develop a reliable seismic isolating structure with a high degree of protection (reduced level of loads transferred to the structures) by using a damping device with the characteristic of "dry friction" with a given level of effort in this design.

 The goal is achieved in that the spring-loaded element is made in the form of a cup, the bottom of which, facing the foundation, has coatings with predetermined frictional properties. The glass bottom part is supported on the foundation plate. The pressing of the cup to the foundation plate is carried out by means of the cup springs and the shim installed between the bottom of the cup and the bottom of the recess. The thickness of the gasket is selected in accordance with the specific value of the coefficient of friction in the contact of the glass with the foundation plate, the values of stiffness and preload of the disk cup springs. A support clip fastened with it is placed along the perimeter of the support, in which an annular fluoroplastic seal in contact with the base plate is mounted. The ball bearing is installed with radial clearances relative to the support elements equal to half the maximum displacement of the structure during an earthquake of the calculated intensity.

 In FIG. 3 shows a longitudinal section of the device.

 The device comprises a support 4 pivotally connected to a building (structure) 1 and a support 4. An elastic rubber-metal stops 5 mounted with a gap relative to the support 4 are fixed to the foundation 3 and are mounted in the recess of the support 4 with a vertical movement of a glass 6, the bottom of which on the surface facing the foundation, has the specified frictional properties. Between the bottom part of the cup 6 and the bottom part of the recess, the belleville springs packs 7 and the adjusting gasket 8 are installed. The yoke 9 attached to it is mounted along the perimeter of the support, in which an annular fluoroplastic seal 10 is in contact with the plate 2. a flat ball bearing made of balls 11, placed in an annular cage 12 and in contact with the plate 2 and 13, is placed with a clearance relative to the support. The clearance Δ is half the maximum displacement δ of the building Tel'nykh foundation in the earthquake that provides nesoudarenie ball bearing with a support.

 The thickness of the adjusting gasket 8, affecting the compressive force of the disc spring package 7, and therefore the friction force in the contact of the cup 6 with the plate 2, is selected based on the required friction force, which provides an acceptable level of load on the structure and permissible relative displacement of the foundation and facilities.

 During an earthquake of foundation 3, structure 1 begins to oscillate, which leads to a transverse reaction in the contact of the support 4 with the foundation 3. As soon as the magnitude of this reaction reaches the total friction force: rolling friction of the ball bearing and sliding friction of the cup 6 on the foundation plate 2, the support begins move relative to the foundation 3.

 A further increase in the intensity of vibrations of the foundation 3 does not lead to an increase in the reaction, and therefore limits the level of acceleration transmitted to the building 1. If the movement 3 relative to the building 1 exceeds the gap between the cage 9 of the support and the rubber-metal stops 5, these stops are crimped with the emergence in them of efforts to facilitate the centering of the support relative to the foundation 3.

 The movement of the ball bearing Δ relative to the support 4 occurs in the range not exceeding half the maximum displacement δ of the foundation relative to the building, which ensures non-impact of the ball bearing with the support.

 Seal 10 during operation of the device under both normal and earthquake conditions prevents foreign contaminants from entering the internal cavity of the support, which could interfere with the normal operation of the ball bearing and spring-loaded cup.

The proposed device seismic isolation of structures in comparison with known similar devices allows you to:
- reduce the loads transferred to the structures during an earthquake;
- increase the reliability of seismic isolation of the structure.

 A technical project has been developed for the seismic isolation device of a hotel weighing 300 - 1000 ton-force, which reduces lateral loads transmitted by an earthquake of 9 points by 8 times with a maximum relative displacement of 200 mm.

Claims (3)

 1. DEVICE FOR SEISMIC INSULATION OF THE STRUCTURE, including a support located between the supra-foundation part of the structure and the foundation and supported on the foundation through mobile communication elements in the form of balls joined by an annular separator, a spring with an element of its adjustable compression, placed in the axial recess of the support on its lower surface and abutted into the bottom of the recess, and the transverse stops, characterized in that the device is equipped with plates in contact with the balls, mounted on facing surfaces of the support and pounds nta, and a glass opened upward, mounted on the foundation plate coaxially with the recess of the support, the spring being formed by a package of disk elements and resting with its lower end on its bottom, the element of adjustable spring compression is made in the form of a gasket, and the transverse stops are elastic and fixed to the foundation with a gap relative to the side surface of the support.  2. The device according to p. 1, characterized in that the separator of the mobile communication element is placed relative to the protrusion contouring the recess with an annular gap formed on the lower surface of the support, equal to half the maximum displacement of the supra-foundation part of the structure relative to the foundation during an earthquake of calculated intensity.  3. The device according to claim 2, characterized in that it is provided with a clip fixed to the support along its perimeter, in which an annular seal made of fluoroplastic is in contact with the foundation.

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