SU702148A1 - Aseismic building - Google Patents

Description

. .1., The invention relates to the field of construction and is intended for the erection of buildings in seismic areas. The known construction of the building is frame type, made of columns, overlaps and vertical diaphragm stiffness, combined by stretching the horizontal reinforcement into a rigid spatial system that resists well the horizontal, for example. power load | zkam. At the same time, prestressed reinforcement passes in the gap between the floor panels in the plane of the columns, in which special holes are left for the reinforcement to pass the reinforcement 1. The disadvantage of this solution is that the rigidity of the frame buildings fluctuates slightly in the process of oscillation during an earthquake and The energy efficiency remains relatively low, which leads to significant seismic loads at modes close to resonant ones. The closest technical solution to the invention is an earthquake-proof building, including columns, overlapping and vertical stiffness diaphragms of the elements with seams between them crimped by pre-stressed reinforcement 2. The disadvantage of this solution is that the reduction of seismic loads here occurs only as a result of increase the energy absorption coefficient. The purpose of the invention is to reduce the seismic load on the building. This goal is achieved by the fact that in a well-known earthquake-proof building, columns, to overlap and vertical; stiffening diaphragms of the elements with seams between them, crimped by the Prestressed reinforcement, each element of the stiffness diaphragm is made with a horizontal monolithic opening in the middle part, in which in advance 1

702148

reinforcement, with openings in the vertical seams have widenesses filled with anti-corrosion plastic material ..

The invention is illustrated in the drawings, in which fig. 1 shows a cross section of an earthquake-resistant building; in fig. 2 shows the diaphragm panel design; FIG. 3 Detail of the execution of apertures diaphragm panels; in fig. 4 shows section A-A in FIG. 3

The building includes a skeleton made th; s, columns 1, floors 2; and panels of vertical stiffening diaphragms 3. In each span there are two panels high / for example, on 2 floors each {FIG. 2). (The panel of the diaphragm 3 in the middle part has an opening 4 before the passage and stretching bcHOBH5 ix of the beams of tensioned reinforcement in the plane of the overlap. The two parts of the panel are connected to each other with reinforcing bars 5, and for the Height Comparison, these are panels have reinforcements 6. The diaphragm panels consist of two parts combined

transverse mounting reinforcement 7, which passes through the channels left by Pokromkam1 aneli., The mounting beams 7 in the vertical section of the seam, have a bend in the vertical plane. The opening of the vertical seam has a widened section 8 filled with plastic anticorrosive material (for example, bitumen). The overlap panels are combined with reinforcement columns 9.

After the construction of the earthquake-resistant building is as follows. A column 1 of the frame is installed with inventory tables for supporting the ceiling panels. An on-site assembly of the stiffening diaphragm panels is performed at the construction site by installing and tensioning the transverse mounting reinforcement 7.

Connected panels are set to npoeKtHoe. Then the paneys of overlap 2 are mounted. The overlapping mi and columns are filled with quick-hardening paste. Reinforcing beams 9 are installed and tensioned, combining 1cccc with ceilings. After that, the joints are filled with concrete 4 and the joints are fiftaetH4HbiM with the broadening of the lateral seams around the vertical joints.

The magnitude of the horizontal tension of the valve, of the armature uniting the four aastGaafrGHT, was determined by that

four

hopping of diaphragm stiffness during oscillations, based on the requirement that the frictional force in vertical joints should not exceed 0.75 of the shearing force from the maximum seismic load, as determined from ytfe.TOM, of the effect of its reduction,. In the first stage of oscillation, the diaphragms work as a complete section as a single whole, and the rigidity of the building remains high and almost constant. With increasing deformations, with moving forces in the vertical seams, parts of the diaphragms make more frictional forces from the compression of the reinforcement. There is a relative shift of the parts of the diaphragms, accompanied by a spasmodic drop in strength and. significant increase. The calculation of the coefficient of energy absorption. . :

The presence of broadening with plastic filling leads to the fact that the valve does not interfere with the mutual shift of individual parts of the diaphragm.

At this second stage, oscillations of the diaphragm work as components, and the seismic load drops sharply. .

 As a result, the deformation decreases. the magnitude of the shear forces decreases, and the diaphragms again begin to work with a full cross section (the third stage of oscillations), since the tension in the horizontal reinforcement remains constant.

Thus, stiffening diaphragms perceive the overwhelming majority of horizontal loads, and the fall of the seismic impact into the First; queue cB is made with an abrupt change in stiffness.

The savings from the implementation of the invention in seismic regions will be approximately 1.79 million rubles. in gbd.

; Fore, Mule Finding

A seismic resistant building, including columns, overlaps and vertical diaphragms of stiffness from the elements with seams between them, inhabited by pre-stressed reinforcement, differs from it in order to reduce seismic load on the building, each time the stiffness diaphragm is made C a horizontal monolithic opening in the middle part, in which an extension of reinforced reinforcement is placed, with an opening of vertical joints with 570 widening, filled with an anticorrosive ductile material. Sources of information, -pring into consideration during the examination 1. Building structures, Building physics (foreign experience), Re- 486 ferativna information, Construction and architecture, Gosstroy of the USSR, L1 series (issue 1 |, M., 197b, S. 25-26. 2. USSR Copyright Certificate j No. 512279, class E 04 H 9/02, 1974; (prototype).

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