SU1656107A1 - Multistory earthquake-proof building - Google Patents

Abstract

The invention relates to multi-story earthquake-resistant buildings. The aim of the invention is to increase seismic resistance and reliability. The filling panel is rigidly attached to the lower bolt and, through elastic connections, to the columns and upper bolts of the frame cells. The filling panels are placed with a gap relative to the columns and upper girders of the framework cells. Elastic couplings are located in the body of the columns and the upper bolt and are made in the form of closed hollow cylindrical elements with a piston inside. The pistons of the adjacent closed hollow cylindrical elements of the columns and filling panels have rods interconnected by a hinged angular element. In the gaps between the piston and the end walls of the closed hollow cylindrical elements mounted springs. 6 Il.

Description

The invention relates to the construction of multi-storey earthquake-resistant, frame and frame-panel buildings.

The purpose of the invention is to increase the seismic stability of the building and reliability.

FIG. Figure 1 shows a fragment of a building framework cell with an internal filling panel; in fig. 2 — node I in FIG. one; in fig. 3 - node II in FIG. one; in fig. 4 and 5 are the kinematic diagrams of the node I, respectively, with vertical and horizontal oscillations; in fig. 6 shows the kinematic scheme of the node II in the horizontal oscillation of the frame,

A multistory seismic resistant building contains columns 1 and horizontal bearing elements 2 (crossbars) forming cells 3, in which they are placed with gaps 4 and 5 relative to columns 1 and upper crossbars 2

filling panels 5, rigidly attached to the lower bolts of the cells 3 and having a notch: 7 in the upper part.

In the body of the columns 1 and the filling panels 6, vertically hollow closed cylindrical elements 8 arranged with a central hole 9 in the outer end wall 10 are placed along the vertical face of the columns 1 and the notches 7.

The filling panels 6 are connected to the columns 1 and the upper bolt 2 of the cells 3 by means of elastic couplings 11 in the form of pair pistons 12 with rods 13 and springs 14. One of the pistons 12 is placed in the cavity of the cylindrical elements 8 in the column 1 or crossbar 2, and the other in the cavity of the cylindrical element 8 in the filling panel 6,

Between the pistons 12 and the end walls 10 and 15, a gap 16 is formed, in which

Pre-stressed springs 17 are installed. The pistons 12 have rods 18, which are passed into the openings 9 of the end walls 10 of the cylindrical elements 8 and are interconnected by a hinge 19, for example, with fingers, bolts, etc., by means of corner elements 20 placed in the notches 7 filling panels 6

The building framework works as follows. v, v, "i" hv

With vertical oscillations of the bolt 2, nodes 1 come into operation. In this case, the end (deaf) wall 15 of the cylindrical element 8 interacts with the rods 18 by compressing the upper spring 17 (Fig. 4), and the rod 18 moves down the axis, straightening the upper spring 14 and compressing the bottom. The corner element 20, turning in the hinges 19, causes a displacement of the rod 18 of the adjacent elastic connection 11 of the panel 6, where the left spring 14c first engages in interaction with the right spring 14. In the reverse movement, similar actions occur.

With horizontal oscillations of the armature, the bolt 2, displaced relative to the panel G, transmits movement through the corner element 20 of the rod 18 of the panel 6. At the same time, the possibility of jamming the rod

18 and the springs 14 due to the swivel 19 of the stem 18 with the corner elements 20. Similarly to the operation of the node poi horizontal oscillations of the frame, the operation of the node II occurs.

The magnitudes of the greatest compression (rigidity) of each spring 14 I select r in accordance with the maximum displacements when the frame vibrates. When two nodes work simultaneously, the vibrational energy is intensely quenched, and the seismic forces are significantly reduced.

The present invention allows repair and recovery measures to be taken on failure of nodes I and II. The failure of nodes I and II with seismic forces far exceeding the calculated ones is possible as a result of significant frame movements, the values of which exceed the distance between the hinges.

19 of the connecting corner element 20, which may be a favorable moment - the option of switching off connections (break of the fingers in the hinges)

The fabrication of elastic connections 11 and the installation of the nodal joints between the frame and

panel 6 are performed in the following sequence.

A stem 18 is inserted into the cylindrical element 8. Then springs 14 are inserted on each side. After preloading the springs 14, the end walls 10 and 15 are rigidly attached to the cylindrical element 8. In the manufacture of columns 1 and filling panels 6, elastic connections 11 are installed in their formwork fixed in project

position, install all the necessary reinforcement products, and then perform concreting. Elastic couplings 11 are interconnected when the frame is mounted by means of corner elements 20

fingers or bolts

Claims (1)

Claims of the Invention Multi-storey seismic resistant building including columns and horizontal bearing elements forming cells, in which they are placed with gaps relative to the columns and upper horizontal bearing elements of the filling panel, rigidly attached to the lower horizontal supporting elements and having cutouts in The upper part, and elastic connections, characterized in that, in order to increase seismic resistance and reliability, the building is equipped with hollow closed cylindrical elements placed vertically in the body of columns and filling panels along the vertical face of the columns and cutouts of filling panels and made with a central hole in the outer end wall, and the elastic connections are made paired in the form of paired pistons, one of which is placed in the cavity of cylindrical elements of columns or a horizontal bearing element, and the other in the cavity of a cylindrical element of the filling panel with gaps relative to the end walls in which prestressed springs are installed, while the pistons are equipped with rods missed in the holes of the end walls of the cylindrical elements and interconnected pivotally through corner elements located in the notches of the filling panels about „ with lgo / / / / UL Do it / (HGCH (Y YOU GG- 5 1 ftSa Xi s / Wt J 1 h fl m   . . fl l  77 /// f (C / L Z / ЈЈfJ A Ml hio. .  u (vf:: H ST, - - 1B g e dviO j K garda Cc, iasMre ii- G / Renova expQA (Orgen S. Korrektor A Osaulenko sh mr (VVVVVVSXN five  777S77 s- A