RU2506385C1 - Building of panel elements - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction, in particular, to buildings from panel elements. Bearing panels of the building are made in the form of bearing reinforced concrete panel frames, the inner space of which is filled with a light piece material. External walls rest against the bearing crossbar with thermal slots, panels of the slab are arranged in plan above the adjacent rooms in mutually perpendicular directions. In the ends of the upper shelf of the slab panels there are cuts for arrangement of keyholes, platform joints of wall panels and panels of the slab are solidified jointly with reinforcement protrusions along the upper surface of crossbars of panel frames.

EFFECT: provision of high energy efficiency and viability of a structural system of a building, possibility for future recycling of buildings with application of recycled materials and structures of up to 85-90%.

6 dwg

Description

The present invention relates to the field of construction and is intended to create energy-efficient prefabricated structural systems of residential and civil buildings based on the full resource cycle of biosphere-compatible technologies.

There are known skeletons of multi-storey buildings, the main load-bearing structures of which are prefabricated, prefabricated-monolithic or monolithic columns, hollow core slabs and stiffness diaphragms, combined into a single spatial system with reinforced concrete bearing and connecting elements of flat ceilings, (see AS No. 1776734, IPC EB04 1/18, publ. 1992)

The drawback of such a constructive solution is that such frames are economically inefficient due to the high energy and material consumption of the supporting structures, the production of which requires high energy costs (especially in winter). They are quite laborious during the construction.

Known prefabricated frame of a multi-storey building with increased rigidity, the main supporting structures of which are prefabricated open volumetric blocks with flat ceilings, (see Reinforced Concrete Structures / Ed. By Polyakov L.P., Lysenko E.F. and Kuznetsova L.V .-- K .: Vishcha school. Head publishing house, 1984. - Fig. XII. 8, p. 253.)

The disadvantage of this constructive solution is that the manufacture of volume units used in such a frame requires the use of powerful expensive technological lines, and has an increased complexity.

Also known is a prefabricated cross-wall structural system of prefabricated panel elements, including longitudinal and transverse load-bearing wall panels, floor slabs, supported along a contour or three sides, and bearing or self-supporting external walls. (see Residential and public buildings: A brief reference to a design engineer / Edited by Yu.A. Dykhovichny, V.I. Kolchunov. In 3 volumes. - M., DIA Publishing House, 2011. - T. 2. - Fig. 6.4, p. 7.)

The disadvantage of such a constructive solution is that with such a constructive system, the seams of the connected load-bearing elements go to the outer contour of the building, this leads to freezing and violation of the tightness of the seams. Bearing or self-supporting external walls with such a constructive system in order to meet modern requirements for heat engineering require an additional increase in the consumption of materials. For example, if the outer wall is made of load-bearing elements, then an increase in its thickness and the installation of an inner insulating layer are required; if the wall is self-supporting, it is also required to ensure its stability to the entire height of the building and the installation of insulating and protective layers, which leads to an additional consumption of materials.

The closest solution to the claimed invention is a building frame made of panel elements, including bearing longitudinal and transverse wall panels connected to floor slabs, external self-supporting walls, and floor slabs above rooms with a protruding bay window have thermal connectors in the form of specially designed holes filled with effective heat-insulating material due to perforation of their edges, sections of the outer walls of the bay windows made combined in the form of masonry from piece insulating blocks, opio sliding along the edge of the slab, characterized in that the bearing longitudinal and transverse wall panels are additionally connected to each other in height at least in two places, the external self-supporting walls are made with floor cuts, floor slabs above rooms with a protruding bay window have a thickening of the marginal area, sections the external walls of rooms without bay windows are made of a combined crossbar with thermal connectors in the form of holes in the crossbar shelf and masonry from piece insulating blocks. (see RF Patent No. 2281365, IPC Е04Н 1/00, publ. 2006)

The disadvantage of this design solution is that the longitudinal and transverse wall panels are made of one material - structural concrete, relatively high energy intensity and material consumption. In addition, load-bearing mono-walls do not allow the use of environmentally friendly recyclable and low-energy materials and ensure their quick replacement during reconstruction and disposal of the building. Floor slabs also have high energy intensity, material consumption and low sound insulation indicators. Crossbars with thermal connectors are made with a shelf rectangular in plan and do not allow to perform proper thermal protection of the protruding part. The platform joints of the inner wall panels in height, made in the prefabricated version, have a relatively low bearing capacity, which limits the number of storeys when using such a structural system and reduces its structural safety and survivability under design and especially beyond design impacts.

The problem to which the invention is directed is to create an industrial energy-, resource-efficient structural system of residential and civil buildings based on the full resource cycle of biopherocompatible technologies, to ensure the overall spatial stability of the frame, increase its structural safety and survivability, improve the heat-shielding properties of the outer contour of the building, reducing the time and cost of construction with the maximum use of recycled materials and structures at all stages of life nnogo building cycle.

This is achieved by the fact that in a building made of industrial-made panel elements, including longitudinal and transverse wall panels connected to floor slabs and to each other in height at least in two places, external self-supporting walls, and floors above rooms with a plan part of the building are carried out using a wide crossbar, curved in plan view, having thermal connectors in the form of holes in its contour, and over the rectangular not protruding part, are made from transversely connected panels about the profile, based on crossbars with a width equal to the thickness of the outer wall, also having thermal connectors in the cantilever shelf, according to the invention, the building's load-bearing panels are made in the form of load-bearing reinforced concrete panel-frames, the crossbar of which has reinforcing outlets, and the remaining space in the plane of such a panel is filled with light environmentally friendly recycled wall material. The external self-supporting walls of the building are layered, combined and supported by a straight or curvilinear crossbar in plan view with thermal connectors in the form of holes in the cantilever shelf of the crossbar. The overlapping panels have a multiply connected cross section with large polygonal, ovaloidal or other forms of voids, in the ends of the upper shelf of which there are cutouts for arranging keys. Overlapping panels are arranged in plan above adjacent overlapping rooms in mutually perpendicular directions. Platform joints of wall panels and floor panels are monolithic together with reinforcing outlets available on the upper surface of the crossbars of wall panels-frames.

The invention is illustrated by drawings, where: in Fig.1 shows a General view of a fragment of the frame in isometry; figure 2 - wall panel-frame; figure 3 - panel overlap; figure 4 - strapping bolt with a rectilinear or curved in terms of a cantilever shelf; figure 5 shows the platform joint of wall panels and floor panels with various options for supporting floor slabs; figure 6 shows the node supporting the floor panels on the crossbar with a cantilevered cantilevered shelf and the interface nodes of the floor panels with the outer wall.

The frame of the structural system of a multi-storey building (Fig. 1) includes load-bearing longitudinal and transverse wall panels 1, floor slabs of a multiply connected cross section 2, strapping crossbars with a straight 3 or curved 4 in plan cantilever shelf having thermal connectors in the form of holes in the shelf 5, the outer laminated wall 6, the connection between the bearing wall panels 7, prefabricated-monolithic platform joint 8 between the floor slabs and wall panels.

The performance of the presented structural system of the building from panel elements is ensured as follows. The crossbars of the bearing longitudinal and transverse wall panels-frames are connected by a platform joint 8 with monolithic 10 along the outlets of the reinforcement 9 with floor slabs (Fig. 5). The transverse wall panels facing the external contour of the building are connected to the strapping bolts through cutouts 11 arranged in the panels (Fig. 2). The longitudinal and transverse panel frames 1 in height are interconnected using embedded elements 7 in at least two places. This solution provides the perception and transfer of vertical and horizontal loads from one frame element to another and then to the building foundation, the overall stability of the building frame and increases the structural safety and survivability of such a structural system in the event of an emergency shutdown of the individual structural elements of the frame during design and beyond design . The implementation of the panels in the form of U-shaped elements filled with lightweight wall material 12 (see figure 2) provides, on the one hand, the use of two-component recyclable easily recyclable materials with high thermal and noise insulation properties, and on the other, high load-bearing capacity. The installation of a crossbar with thermal connectors in the cantilever shelf in the form of holes allows not only thermal protection over the entire thickness of the floor, but also the overall spatial rigidity of the entire structural system of the building as a whole. The execution of the crossbar panel-frame 1 at the same time with the precast-monolithic platform joint 8 allows you to provide high bearing capacity of the platform joint with a relatively low height of the prefabricated part of the crossbar h _r (see figure 3). The arrangement of the panels in two mutually perpendicular directions and the connection of the bearing longitudinal and transverse wall panels with strapping beams having thermal connectors in the cantilever shelf, using embedded parts, provides spatial stiffness of the shear disk and the joint work of all vertical and horizontal load-bearing elements. This reduces the overall material consumption of the building frame.

When erecting a building frame with the proposed structural system, the consumption of materials on the external walls, which in this case are not bearing, is reduced and they are performed by three-two or even single-layer self-supporting on one floor in the form of masonry from piece insulating blocks resting on cantilever shelves of crossbars with thermal connectors . The use of self-supporting floor walls of the external contour of the building reduces the time of its construction, as the construction of such single-layer, two- or three-layer walls, as well as filling the internal wall frames, does not require high qualification of masons, and the device of thermal connectors in the form of holes in the crossbar shelf filled with heat-insulating material is performed by industrial methods in the factory. The combination of such thermal connectors and used recycled thermal insulation materials increases the thermal insulation properties of the outer wall.

Since floor slabs (Fig. 3) are supported either on wall panels or on strapping beams (see Fig. 6), this solution provides reinforcement of slabs that does not differ from reinforcing such floor slabs, which is adopted in the same way as in the former standard series.

The combination of elements adopted in the proposed structural system allows the installation of the building frame and walling using independent, self-contained closed self-supporting fragments of cells from individual elements, which significantly increases the speed of building construction.

The proposed industrial system of residential and civil buildings provides the spatial stability of the skeleton of the building, provides high energy efficiency on all floors, increases its survivability during beyond design impacts, improves the environmental qualities of all elements of the skeleton of the outer contour of the building, provides the opportunity for innovative modernization of the existing base and equipment of the construction industry of house building plants for production of lightweight wall panels and floor panels Deer, reducing construction time and costs, enables the future utilization of buildings with the use of recyclable materials and designs to 85-90%.

Claims (1)

A building made of panel elements, including bearing longitudinal and transverse wall panels connected to floor slabs and to each other in at least two places in height, external self-supporting walls, and floors over rooms with a part of the building projecting in plan are made using a wide curvilinear the plan of the crossbar shelf, which has thermal connectors in the form of holes along its contour, and above the rectangular not protruding part, are made of multiply connected transverse profile panels resting on crossbars with a width equal to the thickness the external wall, also having thermal connectors in the cantilever shelf, characterized in that the supporting panels of the building are made in the form of supporting reinforced concrete panels-frames, the crossbar of which has reinforcing outlets, and the rest of the space in the plane of such a panel is filled with light environmentally friendly recycled wall material, external self-supporting walls the buildings are layered, combined and supported by a straight or curvilinear crossbar in plan with thermal connectors in the form of holes in the cantilever shelf of the crossbar, and the panel roofs have a multiply connected cross section with large polygonal, ovaloidal or other shaped voids, in the ends of the upper shelf of which there are cutouts for dowels, while the floor panels are placed in plan above adjacent overlapping rooms in mutually perpendicular directions, and the platform joints of wall panels and floor panels monolithic together with reinforcing outlets available on the upper surface of the crossbars of wall panels-frames.

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