RU2837751C1 - Building from panel elements - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction, in particular to buildings from industrial panel elements. Load-carrying frame of the building is made in the form of reinforced concrete U-shaped and L-shaped panels-frames connected to each other along the height of the building by means of steel plates and plug-in joints; the hollow-core slabs rest on the prefabricated part of the load-carrying girders of the panel-frames. In the support part of the posts of the inverted U-shaped and L-shaped elements, reinforcing rods are installed, which are bent into the monolithic part of the bearing and binding girder, the space between the ends of the floor slabs, the opening in the frames of the panels-frames together with all the reinforcement elements is embedded with concrete.

EFFECT: solution in the aggregate of all elements ensures the perception of varying power flows in the structural system of the building under special and emergency effects and is aimed at protection against progressive collapse.

1 cl, 6 dwg

Description

The proposed invention relates to the field of construction and is intended to create a safe structural system of panel and panel-frame residential and civil buildings with increased survivability, ensuring the perception of changing force flows under special and emergency impacts and protection against progressive collapse.

A building frame made of panel elements is known (RU patent for invention No. 2281365 C2, publication date 10.04.2006, authors Kolchunov V.I., Safonov G.A., Klyueva N.V., Meleshkova E.A., RU), which includes load-bearing longitudinal and transverse wall panels that are connected to floor slabs, external self-supporting walls. The load-bearing longitudinal and transverse wall panels are additionally connected to each other along the height in at least two places. The external self-supporting walls are designed with a floor-by-floor cut. The floor slabs above the rooms with a protruding bay window have a thickening of the contour zone, the sections of the external walls of the rooms without bay windows are made combined. They consist of a load-bearing beam with thermal connectors in the form of holes in the beam shelf and masonry from individual insulating blocks.

The disadvantage of such a design solution is the longitudinal and transverse wall panels made of structural concrete, which has high energy and material consumption. The platform joints of the internal wall panels made in a prefabricated version have a relatively low bearing capacity in height, which limits the number of storeys when using such a design system and reduces its structural safety and survivability under design and special off-design impacts.

A building frame made of industrially manufactured panel elements is known (RU patent for invention No. 2506385 C1, publication date 10.02.2014, authors Ilyichev V.A., Kolchunov V.I., Klyueva N.V., Bukhtiyarova A.S., RU), in which the reinforced concrete load-bearing panels of the building are made in the form of frame panels, the interior space of which is filled with lightweight concrete. The beam is made with thermal connectors and has reinforcement releases, the floor panels are located in the plan above the adjacent overlapped rooms in mutually perpendicular directions. The platform joints of the wall panels and floor slabs are monolithic together with reinforcement releases protruding from the upper surface of the beams of the wall frame panels.

The disadvantage of this design solution for the building is that the reinforcement frame installed in concrete, monolithically embedded between the ends of the floor slabs, does not provide a rigid connection between the floor slabs and the wall panel posts when the force flows in the structural system change under special impacts, which is an important factor for increasing survivability and ensuring the protection of the building from progressive collapse.

The closest to the claimed solution is a building made of panel elements (RU Patent for Invention No. 2790148 C1, publication date 14.02.2023, authors Kolchunov V.I., Moskovtseva V.S., Fedorova N.V., Savin S.Yu., RU), including load-bearing building panels-frames in the form of precast-monolithic reinforced concrete inverted U-shaped elements, the beam of which has reinforcement releases for creating a monolithic beam section in the space between the ends of the floor slabs, in which longitudinal and transverse reinforcement bars are installed and, additionally, individual bent reinforcement bars connecting the longitudinal reinforcement of the beams installed in the monolithic section with the working reinforcement of the racks of the overlying panel-frames. The racks of the load-bearing wall panel-frames are connected by reinforcement releases and tie-plates with the overlying panel. The frame panels are connected vertically by means of embedded elements in at least two places.

The disadvantage of the described design solution is the increased material consumption due to the formation of double and triple columns at the junction of inverted “U”-shaped elements in the longitudinal and transverse directions of the building.

The technical result, which the invention is aimed at achieving, consists in the creation of a safe industrial, quickly erected structural system of residential and civil buildings with low material consumption, with increased load-bearing capacity and survivability, ensuring the perception of changing force flows from special off-design impacts.

The technical result is achieved in that a building made of panel elements, including load-bearing panels made in the form of panel frames, the beams of which have reinforcement releases, floor slabs of a multi-connected cross-section with voids of a polygonal, ovaloid or other shape, monolithic joints of the beams of the frame panels and the floor panels along the reinforcement releases, wherein the panel frames in the transverse direction of the building frame are made of an inverted "U"-shaped element and "L"-shaped elements successively adjacent to it, through a cantilever projection, in the lower part of the racks of which through openings are arranged, in the longitudinal direction of the panel frames from inverted "U"-shaped elements and "L"-shaped elements are connected by monolithic tie beams arranged between the racks of the frame panels and in the middle of the span of the load-bearing beams of the "U"-shaped elements and "L"-shaped elements, multi-hollow the slabs resting on the prefabricated part of the load-bearing beams of these elements are connected to them by round keys formed during monolithic casting of the upper monolithic part of the beam together with the voids in the slabs, the hollow-core slabs have prismatic keys along the longitudinal side surfaces, which are monolithic together with the longitudinal tie beams, reinforcement bars are installed in the support part of the uprights of the inverted "U"-shaped and "L"-shaped elements, which are bent into the monolithic part of the load-bearing and monolithic tie beam and are overlapped with the longitudinal working reinforcement of these beams, the space between the ends of the floor slabs, the opening in the uprights of the panel frames together with all the reinforcement elements are monolithic with concrete, the uprights of the panel frames along the height of the building are connected to each other by metal plates and plug joints.

The objective of the proposed invention is to increase the protection of the frame from progressive collapse during a sudden change in the direction of force flows from a special impact in the form of removing one of the frame panel posts, as well as simplifying the construction technology and reducing the material consumption of the entire building frame.

The essence of the claimed invention is explained by drawings, where:

- Fig. 1 shows a general view of a fragment of the building frame in 3D;

- Fig. 2 shows a fragment of the building plan;

- Fig. 3 shows an inverted “U”-shaped element of the building frame and a section of this element along 2-2;

- Fig. 4 shows an “L”-shaped element of the building frame and a section of this element along 3-3;

- Fig. 5 shows the connection node of inverted “U”-shaped elements and “L”-shaped elements (node A);

- Fig. 6 shows a fragment of the support of hollow-core floor slabs on the beam of an inverted “U”-shaped element (section 1-1)

The framework of the building's structural system made of panel elements includes load-bearing frame panels in the form of inverted "U"-shaped (1) and "L"-shaped (2) elements and hollow-core slabs (3) of the floor. The frame panels in the transverse direction of the building's framework are made of an inverted "U"-shaped (1) element and "L"-shaped (2) elements successively adjoining it through a cantilever projection, in the lower part of the posts of which through openings are arranged. In the longitudinal direction, the frame panels from inverted "U"-shaped and "L"-shaped elements are connected by monolithic tie beams (4), arranged between the posts of the frame panels and in the middle of the span of the load-bearing beams of the "U"-shaped (1) elements and "L"-shaped (2) elements. Hollow-core slabs (3) resting on the prefabricated part of the load-bearing beams of these elements are connected to them by round keys formed during monolithic casting of the upper monolithic part of the beam together with the voids in the slabs. Hollow-core slabs (3) have prismatic keys along the longitudinal side surfaces, which are monolithic together with the connecting beams (4) of the longitudinal direction. In the support part of the uprights of the inverted "U"-shaped (1) and "L"-shaped (2) elements, reinforcing bars (5) are installed, which are bent into the monolithic part of the load-bearing and tie beam and are overlapped with the longitudinal working reinforcement of these beams, the space between the ends of the floor slabs, the opening in the uprights of the panel frames together with all the reinforcing elements is monolithically filled with concrete, the uprights of the panel frames along the height of the building are connected to each other with metal plates (6) and plug joints (7).

The operability of the presented structural system of the building from panel elements is ensured as follows. In the transverse direction of the building frame, the inverted "U"-shaped elements and "L"-shaped elements are successively adjacent to each other through a cantilever projection, in the longitudinal direction the panel-frames are connected by monolithic tie beams arranged between the posts of the panel-frames and in the middle of the span of the bearing beams. In the near-support part of the post of the panel-frame, reinforcement rods are installed, bent into the monolithic part of the bearing and monolithic tie beam and connected to the longitudinal working rods of these beams. The uprights of the inverted "U"-shaped elements and "L"-shaped elements are connected to each other along the height of the building by means of steel plates and plug joints and after filling the monolithic part of the beam, the space between the ends of the slabs and the openings in the uprights of the panel frames with monolithic concrete they form a solid precast-monolithic horizontal rigid floor disk. Such a solution in the aggregate of all elements ensures the perception and transfer of vertical and horizontal loads from one element of the building frame to another, an increase in the static indeterminacy of the building frame and its overall stability in the event of a special impact - an emergency shutdown of individual frame structures, and the redistribution of internal forces in the building frame; the cross system of load-bearing and tie beams and floor slabs connected to them by means of keys ensures the creation of closed floor-by-floor structural elements of a high-rigidity system that form a common jointly deformable spatial structural system adaptive to a change in the signs of internal forces caused by a sudden removal of one of the load-bearing structures.

The proposed industrial precast-monolithic structural system for residential and civil buildings has a high load-bearing capacity under sudden changes in force flows and spatial rigidity of the building, both under operational loads and under special emergency impacts, including those caused by the sudden removal of one of the load-bearing structures, increases the survivability of the structural system under all types of impacts, including special and emergency ones.

Thus, the described technical solution of the building allows for high spatial rigidity of the building frame and the joint operation of all frame elements during the redistribution of force flows caused by a special impact - the sudden removal of one of the supporting structures.

Claims (12)

A building made of panel elements, including: load-bearing panels made in the form of frame panels, the beams of which have reinforcement releases, floor slabs of multi-connected cross-section with voids of polygonal, oval or other shape, monolithic joints of platform beams of frame panels and floor panels along reinforcement releases, characterized in that the frame panels in the transverse direction of the building frame are made of an inverted U-shaped element and L-shaped elements successively adjoining it through a cantilever projection, in the lower part of the posts of which through openings are arranged, in the longitudinal direction, the frame panels made of inverted U-shaped elements and L-shaped elements are connected by monolithic connecting beams arranged between the uprights of the frame panels and in the middle of the span of the supporting beams of the U-shaped elements and L-shaped elements, hollow-core slabs resting on the prefabricated part of the load-bearing beams of these elements are connected to them by round dowels formed during the monolithic casting of the upper monolithic part of the beam together with the voids in the slabs, hollow-core slabs have prismatic keys on their longitudinal side surfaces, which are monolithic together with the longitudinal beams, in the support part of the uprights of the inverted U-shaped and L-shaped elements, reinforcing bars are installed, which are bent into the monolithic part of the load-bearing and monolithic connecting beam and are overlapped with the longitudinal working reinforcement of these beams, the space between the ends of the floor slabs, the opening in the frame panel posts together with all the reinforcement elements are filled with concrete, The panel frame posts along the height of the building are connected to each other with metal plates and plug joints.