SU808659A1 - Multistorey earthquake-proof building - Google Patents

Description

  -one . .

The invention relates to construction and is intended for buildings that are exposed to dynamic effects from equipment, as well as buildings that are being built in seismically hazardous areas.

A seismic resistant building is known, including a supporting trunk with double-stem trusses, hangers and ceilings connected to the trunk by means of shock absorbers, which, with the purpose of raising the earthquake resistance of the building, 1 is equipped with additional shock absorbers placed at the points of attachment of suspensions to the two-console farm: May or in places of the latter; |. support trunk ij.

The disadvantage of this building is insufficient rigidity, which may be the reason for unacceptably large amplitudes of oscillations under low-frequency, dynamic effects.

The closest technical solution to the present invention is a multi-storey earthquake-resistant building, including spatially rigid floors, vertical diaphragms in the form of wall panels with sliding vertical joints, interlocking them, and interfloor plates installed in the upper part of the vertical joints in the upper floor, where the horizontal links are made of frictional 1m 2.

The disadvantage of this technical solution is that the switch-off links after seismic effects require restoration, which is inefficient with high-frequency dynamic effects.

The purpose of the invention is to reduce the horizontal range of building oscillations under dynamic effects and to reduce the inertial forces on a building under seismic effects.

Claims (2)

The goal is achieved by the fact that in a multi-storey seismic building, including spatially rigid floors, formed by. With panels, girders, coatings and ceilings, wall panels and communications, the upper ceiling is made flexible with adjustable stiffness, while the columns of the upper floor, located inside the building, are connected to the column. The lower floor is hinged with the ability to control stiffness. and between the columns of the upper floor, located along the perimeter of the buildings, vertical connections are established with vibration restraints. FIG. 1 shows schematically the frame of a multi-storey building, a general view; in fig. 2 shows section A-A in FIG. one; in fig. 3 shows the swivel assembly of the columns in FIG. 4 is a view ABC of FIG. 3. A multi-storey building includes columns 1, crossbars 2, interfloor overlaps, h, cover 4, vertical links 5, hinges 6, stops 7. Columns of the upper floor, arranged inside the building, are connected to columns 1 of the lower floor by means of hinges 6 with adjustable stiffness. Vertical links 5 with oscillation limiters 7 are installed between the columns of the upper floor, located along the perimeter of the building. The fastening of the wall panels of the upper level should exclude their participation in the work of the building for horizontal loads. To prevent excessive horizontal displacements of the upper flexible floor under seismic impact (due to strength), vertical links 5 are provided with limiters 7. Limiter 7 is a device that, with a certain amount of movement of the coating, includes vertical increasing the rigidity of the upper floor and limiting its movement. Springs 8 are attached to the corner profile m 10 by tensioning bolts 9. When the building oscillates due to dynamic or seismic effects, the upper flexible floor formed by columns 1 is connected to the underlying columns by means of hinges 6: redistribution of energy oscillations of the building. At the same time, the ordinates of the base of the form of natural oscillations in the level are covered by the 1st low floors of the res. 40 are reduced due to the fact that in the .rhne flexible eTs1Zh will perceive most of the vibrational energy. A similar picture will have m. Flto and for the second form its own, | fluctuations. Therefore, when building structures oscillate, even close to resonance, the dynamic displacements of the overlaps will be significantly less, the check for buildings with a rigid frame, and the displacement of the coating will be greater, which leads to an increase in the periods of lower natural modes. Depending on the type of dynamic load and its spectral component, as well as on the limiting conditions (limitations on strength, endurance or vibration velocity and vibration), it is possible to vary in a wide range with lower natural frequencies of the building, assigning the optimum firmness of the upper floor. The rigidity of the upper floor is adjusted by tension bolts 9. In the case when it is necessary to increase the period of natural oscillations of the building, bolts are inserted into the lugs welded to the corner profile m 10, and are tightened with some force. The magnitude of the force and the number of nodes where bolts are needed are determined experimentally by measuring the natural frequencies of the building. / The device of the upper flexible floor with adjustable stiffness allows a wide range of disturbances due to large displacements of coatings to reduce the amplitudes of oscillations of lower floors, to increase the natural oscillation periods and thereby protect the building from vibrations under dynsmic influences or from destruction, reducing inertial forces on the building (under seismic influences). The technical and economic efficiency of the proposed device is determined by a decrease in inertial forces on the building and a decrease in vibration amplitudes due to the indicated factors. The device of the upper flexible floor leads to a reduction of resonance movements, speeds and accelerations of 1.3-2.5 times than in a building with a rigid frame. Claims of the Invention Multi-storey seismic-resistant building, including spatially rigid, formed by columns, deadbolts, coverings and ceilings, wall panels and connections, characterized in that, in order to reduce the amplitudes of the horizontal oscillations of a building under dynamic loads from equipment and to reduce inertial forces at seismic effects, the upper floor is made of flexible s. adjustable stiffness, while the upper floor columns located inside the building are connected to the columns of the underlying floor hingedly from the air the possibility of adjusting the stiffness, and the meiad of the upper floors with layers located along the perimeter of the building, established vertical links with oscillation restraints. Sources of information taken into account in the examination 1. The author's certificate of the USSR:; 4,77227, cl. E 04 H 9/02, 1971. 2. Authors certificate of the USSR 627229, cl. E 04 H 9/02, 1976.  one - (put.f A-A aut.3 ABC view (Rig. If