RU2256045C2 - Reconstructed multistory building - Google Patents

Abstract

FIELD: construction, particularly to reconstruct residential and public buildings and architectural masterpieces.

SUBSTANCE: load-bearing system of the building is made as partial building frame with columns located in building center and rested upon existent strip foundations by monolithic reinforced concrete bases of the columns. The building frame is provided with flat floor structures supported by the columns in building center and by outer walls along floor structure peripheries with the use of monolithic reinforced concrete dowels and/or by means of floor structure cantilevers. The dowels are integrally formed with floor structures during mounting thereof and located in recesses for supporting demounted floor structures. The cantilevers extend beyond outer walls and pass through openings of building walls. The cantilevers are adapted for balconies or other additional building structures arrangement. The frame may be formed of composite reinforced concrete members. Each floor structure is composed of composite hollow-core slabs with opened cavities located along their perimeters. The slabs are united into groups along sides thereof by interslab joints. Each group extends in floor structure plane and is located in closed reinforced concrete frame defined by load-bearing and tying cross-bars connected in frame corners and concealed in floor structure plane. Hollow-core slab ends rest upon load-bearing cross-bars through reinforced concrete dowels integrally formed with them and arranged in opened cavities of the hollow-core slabs. All floor structure is provided with monolithic reinforced concrete wall cross-bars installed along structure perimeter and having reinforced concrete dowels on outer faces thereof extending through the full floor structure thickness. The above dowels are located in wall depressions. Cantilevers of floor structures passing beyond the walls are made in through openings thereof on extensions of load-bearing or tie cross-bars and support hollow-core slabs through monolithic reinforced concrete dowels. Partial building frame may be constructed of monolithic reinforced concrete and have flat floor structures made as integrated slab inside building. Cantilevers of the floor structures formed as separate bars integrally formed with the slab may pass through outer wall openings. The bars are connected one to another from outside by flat slab. Column base in multistory building to be reconstructed may be formed as monolithic reinforced concrete raft with thickness increasing from column to strip foundation edges and supported by strip foundation ledges in central part thereof and by adjoining reinforced ground base in end parts. Additional building stories are provided with outer walls lying in plane with existent ones, floor structures supported by outer walls along the perimeter thereof and by columns in building center. Additional stories may be constructed of single-layer walls of cellular concrete block work. Reinforcing structure with decorative coating is formed on outer surfaces of existent outer building walls. Upper building story is made as a half-story.

EFFECT: reduced specific material consumption, maximum possible retention of old structures and pre-existing architectural building appearance along with increased building quality.

6 cl, 12 dwg

Description

The invention relates to the construction and reconstruction of residential and public buildings, both mass development, and having architectural and historical significance.

Known reconstructed building, presented in the known method of construction, restoration or reconstruction of buildings, structures [1]. In the famous building, common foundations are used for old and new parts of the building, the frame or its parts, including prefabricated columns, slabs, crossbars with ledges, old or reconstructed walls.

The famous building is technologically advanced and can be erected at a fast pace, since the work is mechanized.

At the same time, a small number of old structures are preserved in the famous reconstructed building, it has high material consumption and therefore its cost is quite high.

A reconstructed residential building is known, containing a building with supports on an independent foundation, old foundations and external walls, as well as new forms with a superstructure [2].

The known solution is intended for low-rise buildings, and its application for high-rise buildings reduces their reliability due to the implementation of the attached volumes on independent foundations. As a result of this, unequal precipitation of old and new parts can lead to damage to the joints of the mates of these parts.

Closest to the proposed is a reconstructed multi-story building - a residential building of secondary development [3]. The known solution includes the lower building part and the upper building part located along and above the reconstructed building. A common monolithic ceiling is mounted above the old and attached parts of the house, and pylons are mounted to its height along the old part from the back of the attached one, and bay windows and / or loggias can be located between them. The known solution allows you to get a secondary building more compact, which increases the efficiency of the use of previously built middle parts of cities.

However, the known solution has disadvantages that significantly reduce its effectiveness. In particular, during its implementation, the reconstructed building turns out to be wide-body, and with the previous insufficient height of the floors, there are problems of lighting and insolation of the building. In addition, additional shading of the rooms is created by attached pylons with loggias. Together, this makes it difficult to put the proposed solution into practice because of the impossibility in some cases to ensure the requirements of the norms. In addition, the well-known reconstructed building is unnecessarily material-intensive due to the large volume of application of load-bearing wall structures and pylons.

The present invention solves the problem of reducing the specific material consumption of the reconstructed building, maximally preserving the old structures and the previously created architectural appearance of the building while increasing its consumer qualities to modern ones.

The solution to this problem is achieved by the fact that in the reconstructed multi-storey building containing old structures, including strip foundations, staircase elevators with wall fences and the outer walls of the reconstructed building with niches along their inner surface at the points of abutment of the dismantled floor runs, and new structures, including the supporting system of the building with ceilings, the superstructure of the top of the building and external insulation, coupled with old structures, the supporting system of the reconstructed building It is made in the form of an incomplete frame with columns supported in the middle of the building by means of monolithic reinforced concrete kneecaps on existing strip foundations, and with flat ceilings supported in the middle of the building by columns, and along the edges on the external walls by means of monolithic concrete dowels formed at the same time with ceilings at their device and placed in niches to support the dismantled ceilings, and / or by means of consoles of ceilings, released through the outer walls through the openings in them to place a ball on them ons or other additional volumes of the building. The superstructure of the top of the building is equipped with external walls made in the planes of existing walls, ceilings and coatings supported on the external walls along the contour and on the columns in the middle of the building. The entire building on each floor is equipped with partitions attached to the ceilings and walls, with the possibility of installing and transferring them to any place of the ceiling at any stage of reconstruction and / or operation.

At the same time, in a reconstructed multi-storey building, an incomplete frame with flat ceilings can be made of precast-monolithic reinforced concrete, and each overlap of an incomplete frame is formed by prefabricated multi-hollow slabs with open voids at the ends and inter-plate seams joined to the sides in groups, each group of plates in the floor plane is placed in a closed monolithic reinforced concrete frame formed by load-bearing and connecting crossbars connected at the corners of the frames, hidden in the plane of overlap. Hollow core slabs at the ends are supported on bearing crossbars using concrete dowels made at the same time and placed in open hollow multi-hollow slabs, and the entire floor contour is equipped with wall-mounted monolithic reinforced concrete crossbars, which are made along the outer faces with concrete dowels to the entire thickness of the floor and placed in niches of the walls.

In addition, in the reconstructed multi-storey building, the floor consoles for the outer walls are made in their through openings on the continuation of the monolithic load-bearing or connecting crossbars and multi-hollow slabs are supported on them along the outer wall by means of monolithic concrete dowels.

In addition, in a reconstructed high-rise building, a monolithic reinforced concrete knee pad for supporting columns on an existing strip foundation can be made in the form of a reinforced concrete pillow covering it across from above and on the sides, with a thickness increasing from the column to the edges of the strip foundation and resting in the middle part on the ledges of this the foundation, and the extreme parts beyond, on the fortified foundation of adjoining soil.

In addition, in the reconstructed high-rise building, the incomplete frame can be made of monolithic reinforced concrete with flat ceilings in the form of a single slab inside the building, and the floor consoles can be released through the openings in the outer walls as separate rods made integrally with the floor slab inside the building and combined outside with a flat stove.

In addition, in the reconstructed multi-storey building, the top of the building can be made of single-layer external walls in the form of masonry from cellular concrete stones, external insulation with a general decorative coating throughout the building is made on the outer surface of the old external walls, and the upper floor is made in the attic.

Comparison of the proposed technical solution with the prototype allows us to conclude that it differs from the known one by the following features: (1) the supporting system of the reconstructed building is made in the form of an incomplete frame with (2) columns supported in the middle of the building with monolithic reinforced concrete kneecaps on existing strip foundations, and ( 3) with flat ceilings supported on columns in the middle of the building, and along the edges of the external walls by means of (4) monolithic concrete keys formed along with the ceilings when they are installed and located in niches supporting the dismantled ceilings, and / or (5) through consoles of ceilings, released through the outer walls through openings in them to place balconies or other additional volumes of the building. (6) The superstructure of the top of the building is provided with external walls made in the planes of existing walls, ceilings and coatings supported on the external walls along the contour and on the columns in the middle of the building. (7) The whole building on each floor is equipped with partitions attached to the ceilings and walls with the possibility of installing and transferring them to any place of the ceilings at any stage of reconstruction or operation of the building. At the same time (8) an incomplete frame with flat ceilings can be made of precast-monolithic reinforced concrete, and (9) each overlap of an incomplete frame is formed by prefabricated multi-hollow slabs with open voids at the ends and inter-plate seams joined into sides, (10) each group slabs in the floor plane is placed in a closed monolithic reinforced concrete frame formed by load-bearing and connecting crossbars connected at the corners of the frames, hidden in the floor plane, (11) multi-hollow slabs at the ends are supported on the load-bearing crossbars by means of concrete dowels made at the same time with multi-hollow slabs placed in them in open voids, and (12) the entire overlap along the contour is equipped with wall-mounted monolithic reinforced concrete crossbars, which (13) are made along the outer faces with concrete dowels to the entire thickness of the overlap and are placed in the niches of the walls . In addition, (14) floor consoles for the outer walls are made in their through openings on the continuation of the monolithic load-bearing or connecting crossbars and (15) multi-hollow slabs are supported on them along the outer wall by means of monolithic concrete dowels. In addition, (16) a monolithic reinforced concrete sub-column for supporting columns on a strip foundation is made in the form of a monolithic reinforced concrete pillow covering it across from above and on the sides with (17) thickness increasing from the column to the edges of the strip foundation and resting in the middle part on the ledges of this foundation , and the extreme parts beyond to the fortified base of adjoining soil. In addition, (18) an incomplete frame can be made of monolithic reinforced concrete with flat ceilings in the form of a single slab inside the building, and (19) the consoles can be released through openings in the outer walls as separate rods made integrally with the slab inside the building and united outside by a flat stove. In addition, (20) the superstructure of the top of the building can be made of single-layer external walls in the form of masonry from cellular concrete stones, (21) on the outer surface of the old external walls, external insulation with a common decorative and finishing coating throughout the building is made, and the upper floor is made in the attic .

All of the listed features, as will be shown below, make it possible to obtain a universal technical solution for the reconstructed building, both residential and public, with the complete fulfillment of the task of reducing material consumption for construction, maximizing the use of old structures, preserving the architectural appearance of the building while increasing its consumer qualities to modern .

All of the listed features of the proposed technical solution in the above amount are unknown, and the achieved technical results are superior to the known ones, they allow us to solve the problem and create a super-total result due to the mutual reinforcement of each of the above signs.

The essence of the proposed solution is illustrated by the example of its implementation by drawings. Figure 1 shows the floor plan of the original reconstructed building, figure 2 - floor plan of the reconstructed building; figure 3 is a cross section of the reconstructed source building according to aa in figure 1; figure 4 is a transverse section along BB of the reconstructed building in figure 2; figure 5 - node And the reconstructed building in figure 2; figure 6 is the same, a section bb in figure 5; Fig.7 is the same, section GG in Fig.5; in Fig.8 - node B of the reconstructed building in Fig.2; figure 9 is the same, a section DD in Fig; figure 10 is the same, a cross-section EE in figure 8; figure 11 - node In the reconstructed building in figure 4; in Fig.12 is the same, section FJ in Fig.11.

The reconstructed building (Figs. 2 ... 12) contains the reconstructed building (Figs. 1, 3) with the external walls 1 used in the reconstructed building, the staircases 2, the wall fences 3 of these nodes 2, the foundations 4, the basement 5 with an overlap 6 above him. If the overlap 6 is complete, it can be saved with the entire structure of basement 5 and in the reconstructed building.

The multi-storey ceiling 7, the internal longitudinal 8 and transverse 9 load-bearing walls, as well as the attic (not indicated in the drawings) of the reconstructed building, have been dismantled. The dismantled floors 7 in the reconstructed building were supported on the inner walls 8 and 9, as well as on the outer walls 1 in niches 10.

In the reconstructed building, the supporting system is an incomplete frame with vertical columns 11 in the middle of the building supported on a strip foundation 4 by means of a kneecap 12. The column 12 is made in the form of a monolithic reinforced concrete pillow covering the tape foundation 4 on top and sides and resting on top of this foundation 4 The edges of the pillow 12, in addition, are supported by the consoles 13 developed in plan along its edges on the reinforced soil 14 of the base. The sinuses 15 around the pillow of the kneecap 12 are filled with coarse material mixed with soil, with their layer-by-layer compaction.

The overlapping 16 of the incomplete frame in the middle of the building, in turn, is supported on the columns 11, and along the contour on the external walls 1 by means of concrete keys 17 made integral with the overlap 16 and placed in the niches 10 of the support of the dismantled ceilings 7. The keys 17 in height are made on the thickness of the overlap 16. The overlap 16 can also be supported on the walls 1 by means of consoles 18, passed through the outer walls 1 in the through openings 19. On the consoles 18 can be made balconies, loggias, bay windows, etc.

Overlappings 16 can be made of precast-monolithic reinforced concrete and formed by hollow-core slabs 20, united into groups by means of concrete mezzanine joints 21. Each group of slabs 20 in the overlapping plane along the contour is bordered by monolithic reinforced concrete frames formed by rigidly joined corners with monolithic bearing 22 and connection 23 crossbars. The contour along the outer wall of the ceiling is provided with wall beams 24, including beams 22 or 23 located here. On the lateral outer edge of the wall beams 24, concrete keys 17 are placed along with them, located in the niches 10 of the outer walls 1. Consoles 18 of prefabricated-monolithic overlap are made on continuation of bearing 22 or connection 23 crossbars. Multi-hollow slabs 20 in the overlap inside the building are supported on supporting crossbars 22 by means of concrete dowels 25, made at the same time with crossbars 22 and placed in prefabricated slab openings at the ends. The support of the plates 20 located outside the building along the outer wall 1, on the console 18 is made similarly, forming the overlap of the balcony or bay window. For the device of the balcony console in the gap between the side face of the plate 20 and the outer wall, a heat-insulating gasket 26 is placed, and a doorway is arranged in the wall 1 (not shown in the drawing).

The incomplete frame of the reconstructed building can be made of monolithic reinforced concrete with floors 16 inside the building in the form of a solid flat plate. The floor consoles for the outer walls 1 can also be erected through the through openings 19 in the form of separate reinforced concrete rods, as well as the consoles 18. These rods are integral with the slab 16 inside the building and are connected outside the wall 1 with a flat monolithic slab (not shown).

Above the top of the reconstructed building, for the development of its volumes and the recoupment of the costs of reconstruction, it is advisable to carry out the superstructure of the floors. The superstructure can be made with single-layer outer walls 27 in the form of a masonry of cellular concrete stones, supported on existing external walls 1. In this case, it is advisable to carry out external insulation 28 with the general decorative-finishing coating on the entire surface of the old outer walls 1. The upper floor can be made in the form of an attic 29 of lightweight structures.

On flat disks of floors 16 in any place in accordance with space-planning needs can be placed fixed to the floors 16, the outer walls 1 or the fence 3 of the staircase partitions of the partition (not shown). If there is no built-in elevator in the reconstructed building, to increase the comfort of living, the attached wall elevators 30 with exits to the stairwells of the unit 2 are attached to the staircases 2 outside the building.

Thus, in the reconstructed building, its volume is maximally cleared from vertical supporting structures (longitudinal 8 and transverse 9 walls). With flat ceilings 16 without protruding parts of the structure, partitions can be placed on each floor and fixed in any places where they are required by space-planning solutions. These solutions can be infinitely varied in accordance with the needs of the consumer. The volume of the building can be increased as a superstructure above it, and due to the removal of the consoles 18 by the extension on the sides within the limits of technical feasibility. If bay windows are arranged on consoles 18, the existing external wall 1 is disassembled within the bay window width and a floor-supported outer wall of lightweight masonry products is arranged at the ends of the cantilever plates 18 (not shown in the drawings).

The reconstructed building with superstructures and extensions can be placed on existing foundations 4 using monolithic reinforced concrete cushions 12 with consoles 13. This is also facilitated by the fact that the partitions and outer walls 27 of the superstructure and attic are made of light materials and products (cellular concrete, frame-sheathed constructions from sheet products, etc.), and longitudinal 8 and transverse 9 walls of heavy brickwork were dismantled.

In general, the proposed technical solution fulfills the task of reducing the specific material consumption of the reconstructed building, since the old structures (walls, staircases, etc.) are preserved to the fullest extent and new effective structural elements, such as an incomplete frame, superstructures and extensions, are introduced into the structure of the building. and a rational pairing of old and new designs is proposed. Compared with analogues [1, 2] and prototype [3], the proposed technical solution to the fullest extent ensures the preservation of the architectural appearance of the building and even its possible enrichment with additional plastic facades, balconies, etc. It is especially effective to increase the consumer qualities of the reconstructed building in comparison with the known ones [1, 2, 3, etc.], because, in contrast to them, flat floor disks and individual rare columns 11 in the building volume allow obtaining flexible planning solutions. These decisions even on each floor can be different and not repeated in the house. Therefore, the building becomes multifunctional. It can be both residential and public for various purposes. The reconstructed building can be energy efficient and comfortable, because it can be successfully applied with external insulation 28 and a superstructure, and vertical transport can be provided with elevators 30. This means that in the reconstructed building, while maintaining its architectural expressiveness, consumer qualities are upgraded to modern ones.

The reconstruction of the building is carried out in the following sequence. The reconstructed building, the operation of which is stopped, is enclosed. It removes the roof, attic floors, internal walls 8 and 9, interfloor ceilings 7, remove niches 10 from the walls from building debris 1. The position of the outer walls 1 is fixed relative to the wall fencing 3 staircases 2 to prevent loss of their resistance to wind, 2 fastening through window openings on the upper floors with temporary flat wooden trusses (not shown in the drawings). The walls of the basements 6 at the locations of the columns 11 are cut to the entire height and on the strip foundations 4 are arranged monolithic reinforced concrete pillars-pillows 12 with releases from them upward of the working reinforcement of the columns 11. Reinforced concrete columns 11 are arranged to the height of the floor with the releases of their reinforcement to the next next highest floor. On supporting devices (not shown), prefabricated slabs 20 are placed in the design position, working reinforcement of load-bearing bolts 22 is placed between their ends on the formwork, and reinforcement of connecting bolts 23 is placed along the group of plates 20. Similarly, the reinforcement of consoles is simultaneously inserted into the made openings 19 in the outer walls 18. After this, in a single cycle, the load-bearing 22 and connecting 23 crossbars, consoles 18, inter-plate joints 21 and concrete keys 17 in the niches 10 of the outer walls 1 are concreted. As a result, a disk of overlap 16 inside the building with the console s 18 outer wall 1 of a building.

After the casting of the required strength with the monolithic concrete of the floor, the supporting devices and the formwork from under them are dismantled and reinstalled on this finished floor, and the cycle of the device of the next floor is repeated. Thus, the use of quick-hardening concrete allows for the reconstruction of the building at a high rate and, in general, the reconstruction of the building in 2 ... 3 months, followed by the installation of load-bearing structures with the use of partitions, insulation, decoration and installation of engineering equipment.

The adopted technology is effective both at a high pace of work and the ability to perform them in a confined space, limited by external walls and finished ceilings. Therefore, its use is also advisable in winter conditions at low air temperatures, providing heating in a closed limited volume.

In general, the proposed technical solution fully implements the task, is relatively easy to implement in practice, and the effectiveness of the evidence is obvious. It will find wide application in the reconstruction of residential and public buildings.

SOURCES OF INFORMATION

1. RF patent No. 2198270, cl. E 04 V 1/20, E 04 G 23/00, bull. No 4, 09/05/2001

2. RF patent №2114960, class. E 04 G 23/00, bull. No. 19, 04/10/1998.

3. RF patent No. 2198550, cl. E 04 G 23/00, bull. No. 16, 06/10/1998.

Claims (6)

1. A reconstructed multi-storey building containing old structures, including strip foundations, staircase elevators with wall fencing and the outer walls of the building being reconstructed with niches along their inner surface in places where abutment runs of dismantled ceilings are supported, and new structures that include the building's load-bearing system with ceilings superstructure of the top of the building and external insulation, coupled with old structures, characterized in that the supporting system of the reconstructed building is made in the form of incomplete about a frame with columns supported in the middle of the building by means of monolithic reinforced concrete pillars on existing strip foundations, and by flat ceilings, supported in the middle of the building by columns, and along the edges by external walls by means of monolithic concrete dowels, formed at the same time with ceilings during their installation and placed in niches for supporting the dismantled ceilings, and / or by means of consoles of ceilings, released over the external walls through the through openings in them to place balconies or other accessories on them volume of the building, the superstructure of the top of the building is equipped with external walls made in the planes of the existing walls of the building being reconstructed, with ceilings and coatings supported on the external walls along the contour and on columns in the middle of the building, and the entire building on each floor is equipped with partitions attached to the ceilings and walls , with the ability to install and transfer them anywhere in the ceiling at any stage of reconstruction and operation. 2. The reconstructed multi-storey building according to claim 1, characterized in that the incomplete frame with flat ceilings, without protruding parts in the building volume, is made of precast-monolithic reinforced concrete, each flat floor of an incomplete frame is formed by prefabricated multi-hollow slabs with voids open at the ends and united on the sides by inter-tile seams into groups, each group of plates in the floor plane is placed in a closed monolithic reinforced concrete frame formed by load-bearing and connecting beams connected at the corners of the frames, hidden by thickness in the floor plane, multi-hollow plates at the ends are supported on the bearing beams by means of concrete dowels, multi-hollow slabs made at the same time with them and placed in open voids, and the entire overlap along the contour is equipped with wall-mounted monolithic reinforced concrete crossbars, which are made according to aruzhnym faces with concrete dowels on the entire thickness of the slab and placed in niches of the walls. 3. The reconstructed multi-storey building according to claims 1 and 2, characterized in that the floor consoles for the outer walls are made in their through openings on the continuation of the monolithic load-bearing or connecting crossbars and multi-hollow slabs are supported on them along the outer wall by means of monolithic concrete dowels. 4. The reconstructed multi-storey building according to claims 1-3, characterized in that the monolithic reinforced concrete column for supporting columns on an existing strip foundation is made in the form of a reinforced concrete pillow covering it across from above and on the sides, with a thickness increasing from the column to the edges of the strip foundation, and leaning in the middle part on the ledges of this foundation, and in the extreme parts outside it on the fortified base of adjoining soil. 5. The reconstructed multi-storey building according to claim 1, characterized in that the incomplete frame is made of monolithic reinforced concrete with flat ceilings in the form of a single slab inside the building, and the floor consoles are released through openings in the outer walls in the form of separate rods made in one piece with the floor slab inside buildings and combined outside with a flat stove. 6. The reconstructed multi-storey building according to claims 1 to 4, characterized in that the superstructure of the top of the building is made of single-layer external walls in the form of masonry from cellular concrete stones, external insulation with a general decorative and finishing coating throughout the building is made on the outer surface of the old external walls, and the upper floor is attic.

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