SU802482A1 - Framework of multistorey earthquake-proof building - Google Patents

Description

(54) FRAME OF SEISM RESISTANT MULTILEVEL BUILDING

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The invention relates to construction and can be used in frames of earthquake-resistant buildings.

The connection frame of an earthquake-resistant building is known, in which a rectangular rod contour is installed in each cell of communications, to the corners of which the ends of the cross-diagonal connections 1 are rigidly attached.

With this solution, the crosses work alternately for stretching and compression, and the rectangular contour for bending.

The disadvantage of this frame is that the rigid attachment of the braces to the rectangular frame does not work only for stretching, therefore the compressed brace loses its stability and quickly collapses under alternating loading, just like ordinary crosses.

Closest to the invention is a frame comprising columns and girders forming cells, and diagonally arranged links in them, united by a closed loop in the form of a ring located in the center of the cells and rigidly attached to the links m 2.

The disadvantage of such a solution is that the cross ties, working in tension and compression, are expedient only with a low flexibility of diagonals, which takes place with a small length and high level of normal forces from seismic loads. With a large length of braces and quite normal forces in them, it is economically advantageous to have cross ties that work only for stretching. The rigid attachment of braces to a closed loop does not ensure the work of the ties only on stretching, therefore, in the case of calculating the links only on stretching, the compressed diagonal loses stability and quickly collapses with alternating loading, just like ordinary crosses.

The aim of the invention is to increase the seismic resistance of the building and reduce the metal intensity of the bonds by ensuring their work on stretching.

This is achieved by installing in the frame of an earthquake-resistant multi-storey building, including columns and girders that form cells, and placed in them diagonally connected, combined by a closed loop in the form of a ring, a closed loop

connected to the connections by means of intermediate elements, which are rigidly connected to the closed loop and movably to the connections, the gap being formed between the contour and the connections.

Fig. 1 shows a seismic resistant frame of a multi-storey building, general view; in fig. 2 - the same for one-story buildings; in fig. 3 - communication node with an annular contour; in fig. 4 is a view A-A of FIG. 3

The earthquake-resistant frame of the building includes columns 1, crossbars 2, bracing 3 cross ties, ring loops 4, gaskets 5, bolts 6 and nuts 7.

From a horizontal load in one crossbar 3, a tensile force arises, while in the second there is no normal force, since its end moves freely along the bolts 6.

Under the action of tensile strut forces 3, the circular contours 4 are deformed. When changing the direction of the horizontal forces by 180 ° for stretching, the braces 3 of the other direction start working, as a result of which the annular contours 4 are deformed in the opposite direction.

The dimensions of the annular circuits 4 are chosen in such a way that, under wind and crane loads, they operate in an elastic stage, and with a design seismic load, one of them develops plastic deformations, as a result of which the energy of the seismic effects is absorbed, and the vibrations of the frame quickly attenuate. The annular contours 4 are made of sheet steel or cut from round pipes, and the thickness and width may be the same or different. Due to the proposed constructive solution, the bond ties 3 work only for stretching.

THAT ensures their reliable operation during earthquakes.

The proposed circuit 4 well works in the elastic-plastic stage for alternating seismic loads, thereby ensuring a high seismic resistance of the building.

The proposed structures of bond frames have high seismic resistance due to reliable elastic-plastic operation of ring loops. The use of such a constructional solution simultaneously reduces the seismic loads acting on the frame of the building and reduces the metal consumption on the link.

Claims (2)

1. USSR author's certificate number 562630, cl. K 04 H 9/02, 1974. 2. USSR author's certificate for application No. 2723717 / 29-33. cl. E 04 H 9/02, 04.01.79. X / J Phg / city / FU8.2 Fig.Z