SU1767137A1 - Large-panel earthquake-proof building - Google Patents

Abstract

Usage: construction of coarse earthquake-resistant buildings providing increased seismic resistance. SUMMARY OF THE INVENTION: the ends of the longitudinal wall panels, the longitudinal edges of the floor slabs and the inner transverse wall panels are made with notches, and the side faces and the inner ends of the transverse wall panels with protrusions. between the ends of the longitudinal wall panels and the lateral faces of the floor slabs with the combination of their vertical and horizontal channels. The transverse wall panels are connected with longitudinal wall panels and with floor slabs with tensioned fittings. 3 il.

Description

The invention relates to the construction and can be used in the construction of large-panel buildings in earthquake-prone areas.

A large-panel building is known in which the structure of a butt joint of panels comprises a protrusion on one of its side faces and a groove on the other side. In this case, both the protrusions forming the groove and the protrusion corresponding to the groove contain longitudinal voids. During installation, the voids of the protrusions of the adjacent panels are combined with the formation of a common hollow shaft through which the reinforcement passes through the entire length, which is embedded with concrete throughout the entire trunk volume.

The disadvantage of the considered design is the possibility of connecting the panels with each other only in the plane.

The closest technical solution is the building of the Sepp Firnkas system used in the construction of seismic resistant large-panel buildings up to 20 floors. The supporting structures are transverse walls, internal longitudinal walls and floors. The seismic resistance of the building is provided by tensioning the entire height of steel rods passed through the channels in the panels of transverse walls and annealed into the foundation. The tension of the reinforcement is carried out by floor. Longitudinal seams between hollow-core slabs are reinforced with rods and monolithic.

The disadvantages of this design are insufficient earthquake resistance due to the fact that the steel tension rods pass only through the channels of the transverse walls, connecting in this way only the underlying transverse panels with the overlying ones. This principle of joining is not intended to connect adjacent transverse walls, nor to connect transverse walls with longitudinal ones, nor to connect slabs with each other and with wall panels.

The aim of the invention is to increase the seismic resistance

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This goal is achieved by the fact that in a large-panel building that includes supporting longitudinal and transverse wall panels and floor slabs with protrusions, grooves and, respectively, vertical and horizontal channels in the protrusions and in the junction areas and tensioned reinforcement passed through the channels of the wall panels and floor slabs, The taps are made on the ends of the longitudinal wall panels, and the protrusions are on the lateral faces and the inner erets of the latter, inserted by the ends between the ends of the longitudinal wall panels and the lateral faces of the floor slabs ovmescheniem with their vertical and horizontal channels, and a compound of the transverse wall panels with longitudinal wall panels and slabs perekryy Guy armature voltage.

FIG. 1 shows a building; in fig. 2 axonometric fragments of the first floor at the installation stage; in fig. 3 - view of the transverse wall panel.

The building includes load-bearing longitudinal wall panels 1, transverse wall panels 2 and alternating plates 3 and 4 floors.

The longitudinal wall panels 1 have recesses 5 on both end faces, formed by protrusions 6 containing vertical channels 7.

The transverse wall panels 2 contain a recess 8 on the inner face, bounded by the projections 9, or a protrusion 10 corresponding to the recess 8 in the wall plane and two protrusions 11 from the wall plane. The outer ends also have protrusions 11. The protrusions 9, 10 and 11 contain vertical channels 12. The transverse external panels have only one protrusion 11. The transverse panels 2 in their upper part at the level of overlap contain horizontal projections 13 with longitudinal open walls above channels 14.

The overlap is formed of alternating hollow core plates 3 and 4. On the side faces of the plate 3, there is a recess 15 on each side, limited by projections 16, and each side of the side faces of the plates 4 have a protrusion 17, limited by the notches 18. The shape and dimensions of the protrusions 17 and the notches 15 and the protrusions 16 and the notches 18 correspond to each other. The projections 16 and 17 contain longitudinal open channels 19 from above.

Each transverse wall panel 2 is wedged between adjacent longitudinal wall panels so that the protrusions 11 of panel 2 go into the notches of 5 adjacent panels 1.

At the same time, the vertical hollow channels 7 of the projections 6 of the panel 1 and the channels 12 of the projections 11 of the panel 2 are combined with the formation of a channel through which the tension is passed floor by floor to the upper faces of the wall panels of the reinforcement 20 using anchor devices 21. The reinforcement of the underlying and upper floors is connected with Couplings 22.

0 Channels throughout the entire territory are embedded with fine-grained concrete. The panels 1 and 2 are joined to each other so that the protrusion 10 of one transverse panel 2 enters the recess 8 of the other, and the protrusions 11 enter the recess 5

5 longitudinal panels 1. At the same time, the hollow channels 7 and 12 are combined with the formation of channels passing through the projections 9, 10 and 6, 11.

The fittings 20 are also passed through these channels with the help of anchor devices 21 and sleeves 22 and are monolithic. Plates 3 and 4 floors are combined by the recesses 15 and the protrusions 16 of the same plate with the protrusion 17 and the notches 18 of the adjacent plate, and

5 notches 15 of the slab 3 joined to the transverse wall panel 2 are aligned with its protrusion 13. The channels in the protrusions 16 and 17 of the floor plates and the protrusions 16 of the plate 3 and the protrusion 13 of the transverse wall panel 2 are also combined to form single channels through which also the entire width of the building is loaded through the reinforcement 20 using anchor devices 21 onto the ends of the plates 3 and is monolithic,

5 and the protrusions protruding beyond the ends of the plates 23 are anankers in the anti-seismic mode. The parapet part of the external longitudinal walls can be solved both by the general principle described above and by the monolithic vertical protrusions of the frameworks of the upper panels. Structures are installed on the foundation 24 with embedding the anchors 25 into it.

The constructions are mounted as follows.

The transverse wall panels 2 are installed on the foundation 24 with embedded anchors 25 with tensioned reinforcement 20. After that, adjacent longitudinal wall panels 1 are mounted. During installation, the projections 10 and 11 of the transverse panels 2 enter into the grooves 8 of the adjacent transverse and grooves 5 longitudinal panels.

5 vertical hollow channels 7 and 12 of the protrusions 6, 11 and 9, 10 combine to form common hollow vertical barrels through which tension fittings 20 are passed. After filling the trunks with fine-grained concrete, the reinforcement is tensioned by floor using anchor devices 21 on the upper edges of the wall panels . Then using fittings 22 connect the reinforcement of the lower and upper floors. After that, the overlapping plates are installed. During installation, the horizontal protrusions 13 of the transverse walls 2 and the protrusions 17 of the overlap plates 4 enter into the corresponding grooves 15 of the adjacent plates 3. The channels 14 in these protrusions combine to form uniform channels into which the reinforcement 20 is inserted throughout the entire width of the building using anchors 21 on the ends of the extreme plates 3 and they are embedded in fine-grained concrete. In this case, issues 23 are anchored to antiseismic with (not shown). After that, the structures of overlying floors are mounted in the same sequence. Parapet can be solved either by a general principle or by monolithing reinforcement releases of the upper panels of the walls. Last mounted end transverse walls 2.

The invention provides for the connection of all elements of a building with each other into a common reliable stable spatial system capable of perceiving seismic and other loads of any direction. At the same time, compounds have not only strength, but also significant

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deformability, flexibility, allowing to make oscillatory movements without breaking the links between the structural elements or destroying them.

Claims (1)

Claims of the Invention A large-panel earthquake-resistant building comprising supporting longitudinal and transverse wall panels and floor slabs with protrusions, grooves and, respectively, vertical and horizontal channels in the protrusions and in the junction areas and tensioned reinforcement missed in the channels of the wall panels and floor plates, characterized in that , in order to improve seismic resistance, the notches were made along the ends of the longitudinal wall panels, the longitudinal edges of the floor slabs and the inner ends of the transverse wall panels, and the projections —on the lateral edges and inner ends of the latter, installed by the ends between the ends of the longitudinal wall panels and the lateral edges of the floor slabs with the combination of their vertical and horizontal channels and the interconnection of the transverse wall panels with the longitudinal wall panels and with floor slabs tensioned by reinforcement. go Fig .. 1 ; z & SI it r- with gcd g // hi ei w "XJ B c-j