RU47412U1 - MULTI-STOREY PANEL BUILDING - Google Patents

Abstract

The utility model relates to the field of construction and relates to the construction of a multi-storey panel building. The objective of the utility model is to increase the stiffness of the building, to ensure the stability of a compact in terms of the structural system during emergency impacts. The building contains central and extreme modules formed by the outer and inner longitudinal and transverse walls and united by a slab disk. The building is equipped with frames installed floor-by-floor in the outer modules parallel to the longitudinal axis of the building in the area where the end of the bay window is connected to the outer wall of the building, the other end of which is connected to the internal longitudinal wall in the area of the connection of this bay window end with the outer wall. In this case, the longitudinal walls in the outermost modules are load-bearing, and the joint of the floor slabs is located on the frame crossbar and connected to it. The frames installed in the end modules are located on the same axis.

Description

The utility model relates to the field of construction and relates to the construction of a multi-storey panel building.

A multi-storey panel building is known, containing central and extreme modules formed by external and internal longitudinal and transverse walls and united by a slab consisting of plates, bay windows located in the external walls, some of which are connected at one end to the internal longitudinal wall in the connection zone bay window with an external wall, (see Typical design P44T-4/17 "17-storey residential block sections with bay windows and exterior wall panels with brick-like tiles for mass use from 04.30.99.99-Appendix

The disadvantages of the known solutions are as follows:

Low longitudinal structural rigidity, which does not allow to put a stand-alone block section. The decision of the ends of the building does not allow to ensure the reliability of the structures during emergency impacts.

The objective of the utility model is to increase the stiffness of the building, to ensure the stability of a compact in terms of the structural system during emergency impacts.

The essence of the claimed utility model consists in the fact that a multi-storey panel building containing central and extreme modules formed by external and internal longitudinal and transverse walls and united by a slab made up of slabs located in the outer walls of the bay window, some of which are connected by one end with an internal longitudinal wall in the area of the bay window connecting with the external wall, equipped with frames installed floor by floor in the outer modules parallel to the longitudinal axis of the building in the connection zone for the other end of the bay window with the outer wall of the building, while the longitudinal walls in the end modules are load-bearing, and the joint of the floor slabs is located on the frame crossbar and connected to it.

The frames installed in the end modules are located on the same axis.

Distinctive features of the proposed solution from the prototype are that the building is equipped with frames installed floor-by-floor in the end modules parallel to the longitudinal axis of the building in the zone of connection of the other end of the bay window with the outer wall of the building, while the longitudinal walls in the end modules are load-bearing and the joint of the floor slabs is located on the crossbar of the frame and connected to it.

The frames installed in the end modules can be located on the same axis.

The essence of the utility model is illustrated by drawings, where Figure 1 shows the floor plan of a multi-storey panel building. Figure 2 - the connection node of the floor slabs with the crossbar of the frame. The multi-storey panel building contains central modules 1 and extreme modules 2 formed by the outer 3 and inner 4 walls. The modules are connected by a ceiling disk 5 consisting of slabs 6. Bay windows 7 and 8 are located in the outer walls 3. The bay windows 8 of the outermost modules 2 are connected at one end to the inner 4 longitudinal wall in the area where the bay window 8 is connected to the outer 3 wall, and the other end of the bay window 8 is connected with external 3 wall and frame 9. Frames are installed on the floor parallel to the longitudinal axis of the building. The outer longitudinal walls 10 of the extreme modules are load-bearing. On the crossbar of the frame 9 there is a joint of floor slabs, which is connected to the crossbar. Floor-by-frame frames are interconnected by vertical links. Frames 9 extreme modules are located on the same line.

Frames and supporting external walls of the facade in the outer modules receive floor loads and horizontal wind loads and are involved in ensuring the stability of the end walls in an emergency.

Such a constructive solution leads to the formation of 2 stiffness cores in each end of the building, which ensures the longitudinal stiffness of the building and its resistance to progressive collapse.

In addition, this constructive implementation improves the "mobility" of a single-section building in a new and

existing buildings; due to the compactness of the plan, it contributes to the compaction of buildings; contributes to the expressiveness of development and the approximation of a set of apartments to modern demographic requirements.

Claims (2)

1. A multi-storey panel building containing central and extreme modules formed by external and internal longitudinal and transverse walls and united by a disk of overlap consisting of plates, bay windows located in the external walls, some of which are connected at one end to the internal longitudinal wall in the zone the connection of this end of the bay window with the outer wall, characterized in that the building is equipped with frames installed floor-by-floor in the outer modules parallel to the longitudinal axis of the building in the connection zone of the other end of the bay window ra with the outer wall of the building, while the longitudinal walls of the modules are made in extreme bearing and joint plates overlap located on the frame girder and connected to it. 2. The multi-storey panel building according to claim 1, characterized in that the frames installed in the extreme modules are located on the same axis.