RU169712U1 - Large-panel building - Google Patents

Abstract

The utility model relates to construction and can be used in industrial construction of buildings, in large-panel housing construction. The invention consists in the fact that in the transverse direction of a large-panel building, tape, continuous, multi-span, precast-monolithic floors are discretely formed, instead of individual single-span plates, the size of room and resting on four sides on wall panels (see Fig. 4, sec. 3-3, Fig. 7). Cross, multi-span, prefabricated-monolithic ceilings are based on internal and external longitudinal bearing walls and sometimes also on a transverse inter-apartment wall, if it is present in the installation area of a specific multi-span floor, this allows to exclude from the structural design of the building the intra-apartment load-bearing transverse interior wall panels in a particular apartment with replacing them with less thin interior partitions. The preferred option when choosing the width of the tape, transverse, continuous, precast-monolithic, multi-span floors is a size equal to the size of the narrow transverse step of the panel building, i.e. the length of the bearing longitudinal inner and outer wall panels, or be a multiple of their length, i.e. the width of single-span floor slabs existing at the base block sections, the width of existing rooms. This allows you to unify and maintain the products and equipment for their production as much as possible with the current change in floor-standing apartmentography of the base unit of the section or when changing the layout options of apartments. In one equipment it will be possible to produce both floor slabs with support on four sides, and prefabricated slabs for composite, continuous, multi-span, prefabricated-monolithic, overlap, while only the length of the slabs will be changed due to the installation of a transverse liner in the form of a snap. The connection of prefabricated elements with each other as part of a single transverse, continuous, multi-span, precast-monolithic overlap is carried out at their joint, due to the monolithic reinforcement outlets, these joints are located outside Lamy supports, in the form of longitudinal load-bearing walls, in the zone of zero bending moment multispan overlap. Multi-span ceilings can have cantilevered parts, outside the supports, in the form of external load-bearing walls, these consoles can form balconies and bay windows in apartments. Prefabricated plate elements in a transverse continuous multi-span precast-monolithic overlap are divided into internal (30-1; 33-1), external (3-1; 4-1; 32-1; 34-1) and external with consoles (Fig. 4 ) In a variant of an apartment with free lay-outs, the composite prefabricated elements of the transverse, continuous, multi-span, precast-monolithic floors have a width equal to the width of split single-span slabs per room in the form of rigid layouts, and the length of the prefabricated inner slab (30-1; 33-1 ; Fig. 4), based on two internal longitudinal bearing walls, is longer than the length of the slab in the form of rigid layouts (30; 33; Fig. 2) by the length of two or one consoles, the length of the outer slab (3-1; 4-1; 32-1; 34-1; Fig. 4), in the absence of a balcony console, less than s plate (3; 4; 32; 34;. FIG 2) in the embodiment, the rigid plan, in an embodiment of the balcony console its length increases in the required width of the balcony. Thus, due to the fact that the plates in the two layouts have the same width, they can be made in the same tooling for both options, by changing their lengths with liners and additional partitions in existing forms. Longitudinal joints of tape, continuous, transverse, multi-span, precast-monolithic ceilings with each other are carried out through keyways in their longitudinal ends (sec. 2-2; Fig. 6) and through embedded parts or local loop joints in their standard solution for the formation of a single e tazhny disk of overlapping, it simplifies the design and factory production of prefabricated slab elements of transverse, multi-span, continuous, prefabricated monolithic overlap, prefabricated slab elements, in this case, will have reinforcing outlets, for the entire length of the side of the plate, not on all four sides, but maximum on two sides, at the place of the assembly precast-monolithic junction of precast plate elements with each other as part of a transverse, continuous, multi-span, precast-monolithic overlap (Fig. 4, sec. 1-1, FIG. 5), also in this joint, mounting support consoles are used, used in the assembly of multi-span, transverse, continuous, precast-monolithic floors, consisting of prefabricated plate elements. If necessary, a longitudinal joint of two adjacent tape, transverse, continuous, multi-span, precast-monolithic floors with each other is possible due to the monolithic reinforcing outlets of adjacent prefabricated floor slabs (Fig. 6, Sec. 2-2 of Fig. 5, sec. 1 -1), in this case, by calculation, in apartments other than internal transverse walls, there can be

Description

The utility model relates to construction and can be used in the industrial construction of buildings, in large-panel housing construction.

Known prefabricated frame "CUB" with no beam reinforced concrete, multi-span overlap without prestressing reinforcement, formed from flat, not hollow, over column, intercolumn and middle precast plates, equipped around the perimeter with mounting support cantilever platforms and reinforcing outlets, with monoling joints between the plates and their joints with columns. Overlapping, without beams and girders protruding from its plane, allows free planning within the limits of the column spacing.

The disadvantage of this prefabricated, without beam, reinforced concrete, continuous, multi-span overlapping, in the frame version, is the high consumption of reinforcement in the above the column plate, due to the metal-intensive connecting node of the column column with the column, as well as the concentration of large efforts in this small area support section from horizontal and vertical loads on the building and floors and the presence of bending moments in the column plate in two mutually perpendicular directions, along the longitudinal and along the sides The axial axes of the building are standard disadvantages inherent to a greater or lesser extent in all frameless bezelless schemes, in comparison with the wall design of the building. Another disadvantage of this prefabricated floor is the high material consumption of the molds for the manufacture of components of this floor, reinforced concrete slabs and the complexity of their reinforcement, which is due to the presence on all four sides of the slabs of the valve outlets and mounting support cantilever platforms (AS RU No. 2247812).

Known beamless reinforced concrete precast-monolithic frame of a multi-storey building, formed by floor disks and vertical load-bearing elements - pylons, installed with the possibility of perception of the whole complex of vertical and horizontal loads and located in plan arbitrarily relative to each other in accordance with the bearing capacity and planning structure of the building, each of which is made in the form of a flat reinforced concrete wall floor cut rectangular in terms of section, with a thickness equal to the thickness m of an apartment or interior partition, on the lower and upper horizontal faces of which reinforcing releases are made to join the pylons to each other over the entire height of the building and two centering vertically located butt elements, on the lower side in the form of concrete truncated cones, and on the upper in the form of monolithic during molding pylon of metal pipe segments, and the floor disks are made of the same type of reinforced concrete, preferably flat, subdivided depending on the location in the disk of the floor about in relation to pylons for inter-pylon, supporting-row and ordinary, floor panels of various, by a multiple of 300 mm, length and / or width, having loop reinforcing outlets of various bearing capacities and trapezoidal depressions along the perimeter on the end surfaces with a step corresponding to a module of 300 mm and on two opposite ends there are bevels and two supporting sections-protrusions connected to each other in the flooring disk with monolithic concrete seams with a width limited by the ends of the flooring panels, at the level of the flooring disks, formed x reinforcing loop outlets at the ends of the floor panels and working reinforcement of the seams located in the inter-loop space, and the pylons were joined together in height and with the floor disks by means of concrete montage of the contact-loop assembly located in the gap between the upper and lower horizontal faces of the pylons at the level of the floor disks and formed by the butt elements on the lower and upper horizontal faces of the pylon, reinforcing outlets on them, the extreme of which are connected between wallpaper on welding, reinforcing loop outlets on the ends adjacent to the node of the floor panels, trapezoidal depressions on them and supporting sections-protrusions on the ends of these panels to support the floor panels on the pylons, while the vertical and horizontal loads of the building were transferred from the upstream pylon to the downstream over the entire horizontal surface of the pylons joined in the assembly and the operation of the overlapping disks according to a continuous pattern with the formation of rigid frame assemblies in the mates of the pylons with intersection disks life. The disadvantage of this frame is the presence of discreetly located wall pylons having a limited cross-sectional area, in the absence of extended supporting inter-apartment walls along their entire length in the form of closed stable inter-apartment cellular circuits, which significantly increases the load on the pylon wall elements and ceilings, increases the complexity of building construction , due to the need for inter-apartment walls made of small-sized materials, as well as the limited operational stability of the department pylons taken in the direction of their thickness, which requires the preferable presence of laborious rigid butt joints for connecting wall pylons with floor slabs and floor slabs to each other, for transferring horizontal forces in the building structure to adjacent pylons with a perpendicular orientation, as well as the presence of pylons in the area apartments limits the possibility of their free layouts (metro number 76050).

Typical series of multi-storey buildings are known from panels of internal and external load-bearing walls, floor slabs, with built-in and attached loggias (TsNIIEP dwellings working drawings for series 90, section block 90-05 / 1.2, 90-05 / 01.86 (List of typical design documentation for residential buildings for construction in cities and towns of urban type. P2.01-2002 / GUP TsPP. - M .: GUP TsPP, 2002 - p. 17; Building catalog, part 2, Typical projects of enterprises, buildings and structures - Typical project 90-05 /1.2, TsITP, USSR, June 1982; Building catalog, part 2, Standard projects of enterprises, building of buildings and structures - Standard design decision 90-05.01.86, TsITP, USSR, October 1986); The disadvantage of panel houses, according to these model series, is the limited possibility of free layouts of apartments, the small area of the rooms, due to the limited span of floor slabs that do not have prestressing and, accordingly, the need for apartments in place of mobile self-supporting interior partitions, the presence of stationary interior bearing walls.

A large-panel building is known with planning modules, in the form of rooms and in the form of attached loggias, in which the internal dimensions of the width and height of the modules are the same, and the inner surfaces of their transverse wall panels and floor slabs, when docking these modules, are in the same plane, while the building made with transverse and longitudinal bearing wall panels and flat floor slabs, with attached and built-in loggias, while the wall panels of the attached loggia are made bearing with the possibility of installation in alignment the end face of any internal transverse wall panel of the building, with the formation of a single load-bearing composite wall having uniform dimensions and the shape of a rectangular parallelepiped, and the outer wall panels of the building have length and height dimensions equal to or, taking into account the mounting clearances, smaller than the corresponding internal dimensions adjoining planning modules, in the plane of the data of the external panels, while made with the possibility of installation, as anywhere in the main planning module - the room, and anywhere additional ADDITIONAL planning module - loggia, depending on the desired area. In this building, in any room, due to the combination of built-in or attached loggias, you can increase or decrease its length (AS No. 2511327). The disadvantage of this building is the inability to change the width of the rooms and the lack of the possibility of free layouts of apartments, i.e. the presence of in-house bearing walls.

The prototype of the utility model (Fig. 1) is a large-panel building KB them. A.A. Yakusheva, RD-17.04 series (http://www.rassianrealty.ru/useful/serii_domov/27652; http://www.zdanija.ru/forum/topic-442.html), block section of Bryansk Construction Company LLC and Sayany LLC (Housing Construction magazine, No. 10, 2015, p. 26) with longitudinal and transverse load-bearing walls. Buildings have four longitudinal bearing walls, two internal and two external, transverse bearing walls have a narrow step, i.e. less than 4.5 meters, single-span floor slabs, split without prestressing, not hollow and have a bearing on the contour, on four sides. Depending on the required set of apartments on the floor, these base unit sections can have from six to eight layout options, while, as a rule, the longitudinal and transverse wall panels and ceilings do not change their location, they only change the location of door and window openings, technological holes. The disadvantage of this building is the restrictions on the increase in the area of individual rooms of apartments and the lack of the possibility of combining separate rooms of apartments into a common room, for example, combining a common room with a kitchen or hallway, in the form of a bezel-less floor, i.e. in the absence of a free layout option.

The objective of the utility model is, in one base unit of a section of a panel building with rigid planning solutions, having a narrow pitch of transverse load-bearing walls, having continuous reinforced concrete floor slabs without prestressing, the size of a room and resting on four sides on wall panels, to provide a parallel possibility of having one floor of two types of overlap - single-span for one-room apartments on two sides of the building and for living-type apartments, and multi-span floors for one, two and t ehkomnatnyh apartments, both types of ceilings provide a free apartment layout, with the presence of floor slab disk along with multi-span single-span beams overlap significantly simplifies the design and installation of building. It will also allow, due to multi-span ceilings, to combine several rooms or rooms of the apartment into a single space, or to provide a maximum floor area above the entire apartment, without inside the apartment intermediate supports, while, in accordance with the required layout, the interior transverse load-bearing wall panels can be completely dismantled. Due to this, it is possible in the base unit of the section, which has several options for sets of apartments on the floor, in each of these options, or to obtain free layouts of all apartments, or only locally, in the required transverse axes of the building, which increases the options for space-planning decisions of the base unit , reduces the volume of consumption of precast concrete as a result of liquidation, or the replacement of part of the inter-apartment interior bearing walls with thinner self-supporting partitions. At the same time, it is also necessary to ensure the weight of the prefabricated slabs of this overlap within the carrying capacity of the factory and assembly cranes, as well as to maintain the high installation speed inherent in large-panel buildings, while at the same time, the factory of the efficiency does not change the fleet of existing equipment for new metal-intensive power pallets necessary for production prestressed floor slabs, factory technology does not change, new technological equipment is not required.

The problem is solved due to the fact that in the transverse direction of a large-panel building, tape, continuous, multi-span, precast-monolithic floors are discretely formed, instead of individual single-span plates, the size of a room and resting on four sides (see Fig. 4, section 3-3 , Fig. 7). Cross, multi-span, prefabricated-monolithic, ceilings are based on internal and external longitudinal bearing walls and sometimes also on a transverse inter-apartment wall, if it is present in the installation area of a specific multi-span floor, this allows to exclude intra-apartment bearing transverse interior walls in a concrete apartment . The preferred option when choosing the width of the tape, transverse, continuous, precast-monolithic, multi-span floors is a size equal to the size of the narrow transverse step of the panel building, i.e. the length of the bearing longitudinal inner and outer wall panels, or be a multiple of their length, i.e. the width of single-span floor slabs existing at the base block sections, the width of existing rooms. This will make it possible to unify and preserve the products and equipment for their production as much as possible with the current change in the floor-standing apartmentography of the base unit of the section, or when changing the layout options of apartments. In one equipment, it will be possible to produce both floor slabs with support on four sides, and prefabricated slabs for multi-span composite spans, while only the length of the slabs will change due to the installation of a transverse liner in the molds.

The connection of prefabricated elements with each other as part of a single transverse, continuous, multi-span, precast-monolithic overlap is carried out in their joint, due to the monolithic reinforcement outlets, these joints are located outside the supports, in the form of longitudinal bearing walls, in the zone of zero bending moments of multi-span overlap . Multi-span ceilings can have cantilevered parts, outside the supports, in the form of external load-bearing walls, these consoles can form balconies and bay windows in apartments. Prefabricated plate elements in a transverse continuous multi-span precast-monolithic overlap are divided into internal (30-1; 33-1), external (3-1; 4-1; 32-1; 34-1; Fig. 4) and external with consoles . In a variant of an apartment with free lay-outs, the composite prefabricated elements of the transverse, continuous, multi-span, precast-monolithic floors have a width equal to the width of split single-span slabs per room in the form of rigid layouts, and the length of the prefabricated inner slab (30-1; 33-1 ; Fig. 4), based on two internal load-bearing walls, is longer than the length of the slab in the form of rigid layouts (30; 33; Fig. 2) by the length of two or one consoles, the length of the outer slab (3-1; 4-1; 32 -1; 34-1; Fig. 4), in the absence of a balcony console, less than the length of the plate (3; 4; 32; 34; Fig. 2) in the variant of rigid layout, in the variant of the balcony console, its length increases by the required width of the balcony. Thus, due to the fact that the plates in two variants of layouts have the same width, they can be made in one mold for both options, by changing their lengths with liners and additional partitions in existing forms.

Longitudinal joints of tape, continuous, transverse, multi-span, precast-monolithic ceilings with each other are carried out through keyways in their longitudinal ends (sec. 2-2; Fig. 6) and through embedded parts, or local loop joints in their standard solution, for the formation of a single floor disk of overlap, this simplifies the design and factory production of prefabricated slab elements of transverse, multi-span, continuous, precast-monolithic overlap, prefabricated slab elements, in this case, will have reinforcing outlets , for the entire length of the side of the slab, not on all four sides, but on a maximum of two sides, at the place of the assembly prefabricated-monolithic junction of the prefabricated slab elements with each other as part of a transverse multi-span overlap (Fig. 4, sec. 1-1, Fig. 5), also in this joint, mounting support consoles are used, used in the assembly of multi-span, transverse, continuous, precast-monolithic floors, consisting of prefabricated plate elements. If necessary, a longitudinal joint of two adjacent tape, transverse, continuous, multi-span, precast-monolithic floors with each other is possible due to the monolithic reinforcing outlets of adjacent prefabricated floor slabs (Fig. 6, Sec. 2-2 of Fig. 5, sec. 1 -1), in this case, by calculation, in apartments, in addition to the internal transverse walls, a part of the longitudinal bearing walls can be dismantled by one or two widths of composite continuous transverse multi-span ceilings, i.e. one or two lateral steps. This design scheme is preferable for the first floors of panel buildings, when commercial premises or objects of socio-cultural purpose are located in them, which require large free spaces and the presence of attached premises, as well as for apartments with windows on two sides of the building.

For example, the base unit of the prototype section, in terms of flatography, has five options for sets of apartments on the floor - 1-1-1-1-1-1-1-1, 1-1-1-1-2-2, 1-1-1- 3-3, 1-1-2-2-3, 2-2-3-2 (Fig. 1), taking into account hotel-type apartments (studio apartments), the number of options increases significantly. Of these five options for sets of apartments, in three versions at the ends of the block sections, one-room apartments are constantly located on two sides of the building, in which multi-span overlap is not necessary, because there are no intra-apartment transverse load-bearing walls, and there are enough single-span ceilings supported along the contour of the room, this one-span overlap will be in hotel type apartments, these apartments can be located in the area of any room in the base unit, the rest of the floor disk may depending on the existing floor apartment be made in the form of transverse, multi-span, continuous, precast monolithic ceilings, which will allow for maximum dismantling of longitudinal apartments and transverse interior load-bearing walls and provide free planning in the apartments. With the current changes in the sets of apartments on the floor in the base unit of the section, the mutual arrangement and combination of single-span and multi-span ceilings will constantly change, while prefabricated slabs, including as part of multi-span ceilings, will always be made in the same tooling.

Thus, due to the fact that in the base unit of the section (Fig. 1), the disk of the general floor overlap from a split single-span scheme of the floor slabs constituting it (Fig. 2), we have turned into a scheme where in the floor disk of the floor can be combined in any location and in any percentage ratio, as single-span floor slabs, supported along a contour, with an area of a room, and multi-span prefabricated slabs according to a continuous pattern (Fig. 4, Fig. 7) in the form of tape, transverse, multi-span, continuous, precast monolithic floors having a width equal to w In the irina of the rooms, with their support on the longitudinal bearing walls, we got the opportunity to organize free lay-outs of apartments in any places of the base unit of the section, with an increase in the options for their space-planning solutions, we reduced the volume of precast concrete consumption as a result of the liquidation, or replacement of part of the intra-room interroom bearing walls on thinner self-supporting partitions, provided the weight of prefabricated slabs of this overlap within the carrying capacity of factory and assembly cranes, and also maintained a high installation speed it is inherent in large-panel buildings, while at the same time the efficiency plant does not change the existing tooling fleet for new metal-intensive power pallets necessary for the production of prestressed floor slabs, the factory technology does not change, new technological equipment is not required.

In FIG. 1 shows the basic b / c, with a set of apartments on the floor 1-1-1-1-1-1-1-1 and apartment layouts, in the form of floor slabs, supported on four sides on the longitudinal and transverse, interior and interroom bearing walls. In FIG. 2 shows the installation plan of floor slabs in a variant of this layout and structural design.

As an example, we show the option of organizing free layouts in the base unit of a section, in two arbitrarily taken one-room apartments, in the axes of a building 2-4. In FIG. Figure 3 shows the free layouts of these one-room apartments, in which there are no internal apartment interior walls on the transverse axis of the 3 block section, a single space is created from the areas of the kitchen, hallway, common room, partitions are present only in the sanitary unit and bathroom. Other layouts of apartments are also possible, when the kitchen area, sleeping places, bathroom and sanitary unit can change their location and area within the walls of the apartment walls, respectively, the self-supporting partitions of these apartment premises can change their location.

In FIG. 4 shows the installation plan and the structural solution of the disk of overlapping the block section in the axes 2-4, which allowed to refuse in two one-room apartments from the bearing transverse intra-apartment interior walls. Between the axes 2-3, a multi-span, continuous, transverse, precast-monolithic ceiling is mounted for three spans, length from axis B to axis D, and width from axis 2 to axis 3. In this precast-monolithic overlap, the inner plate 33-1 is in addition to its width equal to the width of the inner corridor, the section block (see Fig. 2, pos. 33) receives two cantilevered protrusions, towards the axes B and D, the length of both consoles is determined from the condition of finding the joints of the inner corridor plate 33-1 with the outer plates 3-1 and 34-1 in the zone of zero bending moments for three flight, continuous, precast-monolithic, transverse overlap (see Fig. 7, sec. 3-3), the length of the outer plate 3 (Fig. 2), respectively, decreases, as well as the length of the plate 34 (Fig. 2), but for of the plate 34, it is possible to preserve its length, then with its cantilevered protrusion it will go beyond the axis D towards the axis E and can replace the loggia with the plate 35 with a balcony formed by the cantilever part of the plate 34. The transverse, multi-span, continuous, is mounted on the same principle, precast-monolithic overlap in the axes 3-4 block section for three spans, length from the axis to axis E (FIG. 4, FIG. 7), at the inner plate 30-1, the size of its width increases due to the appearance of two cantilever parts in the direction of the axes B and E, and the length of the external floor slabs 4-1 and 32-1 decreases accordingly, the length of the floor slab 4 can also not decrease , and form a cantilever departure, which will instead of a loggia slab 5 arrange a balcony. The transverse joints of precast slabs 30-1 (33-1), 4-1 (3-1), 32-1 (34-1) with each other as part of a continuous, multi-span, transverse, precast-monolithic overlap are carried out in the form of a rigid unit according to the construction of the Perederi joint, due to monolithic in the constructional conditions of the reinforcing outlets of adjacent plates (see Fig. 5), or cable loop outlets. The longitudinal joints of the two above-mentioned continuous, multi-span, precast-monolithic floors with each other along the axis 3 are carried out by means of a key joint (see Fig. 6) and embedded parts that are installed in increments and working sections, based on regulatory requirements, to create a single floor drive from prefabricated floor slabs for panel buildings.

Installation of continuous, transverse, multi-span, precast-monolithic flooring is carried out in the following sequence, first the internal floor slab with consoles 33-1 (30-1) is mounted, this plate is supported by two longitudinal load-bearing walls in the axes G and B and on temporary mounting racks - supports mounted on the side of the consoles. In the second turn, external floor slabs 3-1 (4-1) and 34-1 (32-1) are mounted, which are supported on the external bearing walls along the D and B axes at one end and on the mounting supporting platforms located on the console part of the inner plate overlapping 33-1 (30-1), these bearing pads are either immediately made in plates at the factory when they are molded, or they are welded in the form of segments of rolling corners to embedded parts specially installed in the plate. Cross joints of plates with each other as part of a prefabricated-monolithic multi-span overlap are monolithic, joints of external prefabricated floor slabs 3-1 (4-1) and 34-1 (31-1) with load-bearing outer panels are also monolithic, but not over the entire width of the plates and fragments in the variant of the loop joints of the vertical external panels and horizontal floor slabs, by analogy with the Peredery joint, the joints of horizontal internal floor slabs with vertical internal longitudinal load-bearing walls can be solved by the same constructive principle, but these joints can also be hinged (platform) if the bearing capacity of transverse, multi-span, continuous, precast-monolithic overlapping in spans and the stability of internal, longitudinal bearing walls are provided, for example, due to the presence of corridor transverse wall panels.

Thus, in the base unit of a section of a panel building, with floor slabs without prestressing, it is possible in any variant of a set of apartments on the floor to organize their free layouts, i.e. remove all the intra-apartment transverse panels of the bearing walls, for this it is necessary to arrange the floors in the form of transverse, multi-span, continuous, prefabricated-monolithic ceilings on both sides of the given transverse bearing wall panels, with their support on the panel of the longitudinal bearing walls. Floor slabs in the single-span version, with their support along the contour, and in the multi-span version can be made in one form of equipment, because have the same width, and their changing length is regulated by the installation of liners in the form. The option of dimensions of prefabricated slabs (3-1; 4-1; 30-1; 32-1; 33-1; 34-1) continuous, multi-span, precast-monolithic overlap can significantly reduce the number of sizes of floor slabs in the multivariate base unit section, if it is used both for the option of slabs supported along the contour, and for actually multi-span ceilings, in this case it is necessary to revise only their reinforcement, while maintaining the formwork dimensions of the slabs.

The design of the proposed overlap of a large-panel building is illustrated by the following drawings:

In FIG. 1 shows the installation plan of the internal and external walls, the base unit of the prototype section, the planning decisions of the apartments of this block section;

In FIG. 2 shows a wiring plan of floor slabs of the base unit of the prototype section;

In FIG. 3 shows the installation plan of the internal and external walls of the base unit section with two single multi-span, continuous, transverse, precast-monolithic floors in axes 2-3 and 3-4 and free layouts of two apartments in these axes;

In FIG. 4 shows the installation plan of the floor slabs of the block section with two single multi-span, continuous, transverse, precast-monolithic floors in axes 2-3 and 3-4, the configuration of which corresponds to the new planning decisions of the apartments of this block section;

In FIG. 5 shows a cross section. 1-1 - rigid monolithic equal-strength mounting joint of prefabricated plate elements with each other as part of a continuous, transverse, multi-span, precast-monolithic overlap;

In FIG. 6 is a sectional view. 2-2 - monolithic longitudinal mounting joint of continuous, transverse, multi-span, precast-monolithic overlapping with adjacent floor slabs;

In FIG. 7 is a sectional view. 3-3 - the composition and design of continuous, transverse, multi-span, precast-monolithic ceilings in the axes 2-3 and 3-4.

The combination in the large-panel building of a wall construction scheme with longitudinal load-bearing walls and continuous, transverse, multi-span, precast-monolithic flooring allows you to build large-panel buildings with free floor plans.

Claims (7)

1. A large-panel building, including prefabricated panels of transverse load-bearing walls and panels of longitudinal load-bearing walls in an amount of three or more walls, in which two walls of these longitudinal load-bearing walls are load-bearing external walls, having prefabricated floor slabs supported by these load-bearing walls, characterized the fact that the prefabricated floor slab is supported on the internal longitudinal bearing walls, having cantilevered projections towards the longitudinal external load-bearing walls of the building, and the cantilevered departures have supporting platforms, this prefabricated pl The overlap it forms in the transverse direction of the building a linear multi-span, continuous, prefabricated-monolithic overlap, together with prefabricated floor slabs resting at one end on the outer longitudinal load-bearing walls, and the other end on the supporting platforms of the consoles of this floor slab, resting on the internal load-bearing longitudinal walls. 2. A large-panel building according to claim 1, characterized in that the transverse, continuous, multi-span, precast-monolithic ceilings can have cantilevered parts outside the supporting outer panels. 3. A large-panel building according to claim 2, characterized in that balconies and a bay window can be arranged on the console parts of transverse, continuous, multi-span, precast-monolithic ceilings. 4. A large-panel building according to claim 1, characterized in that the transverse, continuous, multi-span, prefabricated-monolithic floors can be organized both on the entire area of the floor disk of the building's floor, and only on its part. 5. A large-panel building according to claim 1, characterized in that as part of the transverse, continuous, multi-span, precast-monolithic ceilings, the joints of the precast slabs are located outside the supporting longitudinal bearing walls, in the zone of zero bending moments. 6. A large-panel building according to claim 5, characterized in that as part of the transverse, continuous, multi-span, prefabricated-monolithic ceilings, the joints of the prefabricated slabs with each other and with the longitudinal bearing external wall panels are carried out by concrete monolithing of the reinforcing outlets according to the type of connection of Perederia, or cable loop releases. 7. A large-panel building according to claim 1, characterized in that between the transverse, continuous, multi-span, prefabricated-monolithic floors, or between the transverse load-bearing wall and the transverse, continuous, multi-span, prefabricated-monolithic overlap, split slabs can be mounted with their support on both sides of the data transverse, continuous, multi-span, precast-monolithic floors or on one side of the transverse load-bearing wall, while there may be no longitudinal load-bearing walls under the cutting plates ekrytiya their length.

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