RU100117U1 - RECONSTRUCED BUILDING - Google Patents

Abstract

 1. A reconstructed building containing a reconstructed base building with a roof, vertical supports erected from the outside of the base building along its longitudinal walls and having a height that is not less than the height of the base building with a roof, as well as a superstructure with floors, walls and roof, characterized the fact that the superstructure contains a steel frame supported on the heads of vertical supports and rigidly connected to them from rigidly interconnected tiers, the number of which is equal to the number of floors of the superstructure, each the frame mustache is made of rigidly connected outer truss walls, internal transverse truss walls and at least one internal longitudinal, middle truss wall, all truss walls mentioned above are made with parallel upper and lower belts, the distance between which is equal to the height corresponding to this tier of the floor of the superstructure, while the outer truss walls are located on the axes of the outer walls of the superstructure, the inner transverse truss walls are located on the axes of at least the internal transverse walls of the superstructure rooks, and the inner longitudinal middle truss wall is located on the central longitudinal axis of the building, all the truss walls mentioned above are made of lightweight assembly units-modules rigidly interconnected, which are a series of several typical fragments of truss walls providing openings in the location of windows and doors corresponding to the project, the outer and inner truss walls are tiered rigidly joined by interfloor ceilings, which are adjacent adjacent to the level of the lower truss belt

Description

The utility model relates to the construction, namely, the reconstruction of existing large-panel, large-block, brick and other buildings with a superstructure of additional floors without stopping the operation of the existing building, in particular without resettlement of residents, in urban areas.

From the achieved level of technology, a reconstructed building is known that contains a reconstructed base building, including at least external and internal walls, interfloor ceilings and a foundation, as well as a monolithic reinforced concrete continuous solid slab installed during reconstruction instead of a roofing, as well as a structure supporting trusses and add-in. The base building includes vertical supports that are erected around the perimeter of the outer side of the base building and have a height that is not less than the height of the base building. The vertical supports were erected on a general additional foundation independent of the foundation of the base building, which is located along the perimeter of the base building, outside the zone of compressible soil thickness of the foundation foundation of the base building and is deeper than it. Bearing trusses are installed on the heads of vertical supports, while the superstructure is erected on bearing trusses, which are made with parallel belts (see patent RU-C1-No.2036291, 1995).

The main disadvantage of this reconstructed building is that the construction of the superstructure on load-bearing trusses supported on the heads of vertical supports imposes strict restrictions on the number of floors to be built, since the superstructure is essentially only a load on the load-bearing trusses and the bearing capacity of the walls and floors of the superstructure practically not used. In addition, the replacement of the roofing of the base building with a continuous solid slab, which has a significantly greater weight compared to the roofing, increases the load on the walls and foundation of the base building. Therefore, the known technical solution can only be used if there are reserves of the bearing capacity of the walls and the foundation of the base building. It should be noted here that the placement of vertical supports not only along the outer longitudinal walls of the base building, but also along its outer transverse walls will necessitate the use of lifting equipment moving along the base building and outside the development spot. This fact casts doubt on the possibility of reconstructing the base building without stopping its operation, which is mentioned in the description of the above-mentioned patent.

Also, a reconstructed building, taken as a prototype and containing a base building, including at least external and internal walls, interfloor ceilings, a foundation and a roof, an additional foundation, which is made deeper than the base building basement, bearing vertical supports, is also known. erected on an additional foundation and having a height that is not less than the height of the base building with a roof. Bearing vertical supports are located on the outside of the base building along its longitudinal outer walls. Interfloor ceilings are made over the entire surface of the superstructure and are fixed on vertical supports. The walls of the superstructure are made in the form of masonry, supported on floor floors, and a roof is mounted on top of the upper floor floor (see patent RU-C1-No. 2256046, 2005).

The disadvantage of the prototype is that the superstructure is not characterized by high bearing capacity, as well as high torsional rigidity, since the walls of the superstructure are, in essence, only a load on the floors. In other words, the prototype cannot be used for the construction of superstructures with increased number of storeys, for example, from 8-10 floors or higher.

This utility model is aimed at solving the technical problem of ensuring the high load-bearing capacity of the superstructure, as well as its high torsional rigidity, while increasing the degree of industrialization of the work, reducing the complexity and simplifying the construction work.

The problem was solved in that in a reconstructed building containing a reconstructed base building with a roof, vertical supports erected from the outside of the base building along its longitudinal walls and having a height that is not less than the height of the base building with a roof, as well as a superstructure with floor floors, walls and roof, according to a utility model, the superstructure comprises a vertical support supported on the heads of vertical supports and a steel frame rigidly connected to them from tiers rigidly interconnected, the number of which is equal to each floor of the superstructure, each tier of the frame is made of rigidly interconnected external truss walls, internal transverse truss walls and at least one internal longitudinal, middle truss wall, all the truss walls mentioned above are made with parallel upper and lower belts, the distance between which is equal to the height of the superstructure floor corresponding to this tier, while the outer truss walls are located on the axes of the outer walls of the superstructure, the inner transverse truss walls are located on the axes of at least supporting internal transverse walls of the superstructure, and the inner longitudinal middle truss wall is located on the central longitudinal axis of the building, all the truss walls mentioned above are made of lightweight assembly units-modules rigidly interconnected, which are a series of several typical fragments of truss walls, providing the formation of openings in the design of the location of windows and doors, the outer and inner truss walls are tiered rigidly joined by interfloor ceilings, which are located the wives are adjacent at the level of the lower girdle of the truss walls of the corresponding tier of the frame, and the floors are supported by metal supporting elements, which are either rigidly fixed to the lower girdle of the truss walls corresponding to each floor, or are made integrally with the lower girdles of these truss walls , and each interfloor overlap is formed in one piece with its construction and monolithic along its entire contour with the lower belts bordering it corresponding to each interfloor overlap of truss walls o at the same time with his device.

In addition, in the reconstructed building, each interfloor overlap is prefabricated and monolithic and includes a profiled metal sheet and a coating with a flat upper surface located along its entire upper surface, which is the upper surface of the interfloor overlap, while the sheet is supported on metal supporting elements, and the coating is made made of concrete or reinforced concrete and monolithic when it is installed along the entire contour of the interfloor overlap with the lower belts surrounding the corresponding trusses a fir tree.

The advantage of the patented utility model in comparison with the prototype is that the patented superstructure frame in the form of a high-strength spatial multi-tiered truss structure, together with patented interfloor ceilings, form an integral geometrically unchanged spatial system that perceives external influences and is characterized by high torsional rigidity, as well as high bearing capacity, due not only to the high bearing capacity of the truss walls, but also the bearing capacity combined with the truss walls of the floors.

Other technical results achieved using the patentable utility model will become clear from the further discussion.

In the future, the utility model is illustrated by a specific example, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the above-mentioned technical results with a patentable combination of essential features.

Figure 1 schematically shows the reconstructed building, side view, partial section; figure 2 is a section along aa of figure 1; figure 3 is a section along BB of figure 2.

The reconstructed building (Figs. 1 and 2) contains the reconstructed base building 1, for example, a five-story building, which includes at least the outer 2 and inner 3 walls installed on the foundation 4, the floors 5 and the roof 6, as well as a superstructure in the form of floors lying above the roof 6 of the base building 1, with a roof. The construction of the base building 1 includes vertical supports, which, in the preferred embodiment of the utility model, are made in the form of monolithic reinforced concrete columns 7 (pylons), the height of which is not less than the height of the base building 1, while the columns 7 are erected from the outside of the base building 1, along it longitudinal external walls or, as described in patent RU-C1-No.2116417, 1998, on a generally independent foundation 4 of the base building 1 and a deeper foundation compared to it, which is made in the form of bored piles with reinforced concrete tape grill ohm in the preferred embodiment of the utility model, on each column 7, a deeper (as compared to the foundation 4) foundation 8, each foundation 8 is made in the form of a group, for example, of three bored piles 9 with local reinforced concrete (in other words, having an area necessary to support on it only one column corresponding to it 7) grillage 10.

The superstructure includes a steel frame made of tiers 11 rigidly interconnected (by welding or threaded fasteners), the number of which is equal to the number of floors located above the roof 6 of the base building 1. The superstructure frame is supported on the heads of the vertical supports, namely, column 7, and rigidly fixed on them.

Each tier 11 of the superstructure frame is made of external truss walls 12 rigidly interconnected (by welding or threaded fasteners), as well as internal, namely transverse truss walls 13 and at least one longitudinal, middle (central) truss wall 14, while all the above-mentioned truss walls are made with parallel upper 15 and lower 16 belts, the distance - H between which corresponds to the height of the superstructure floor to which this frame tier corresponds. It should be noted here that in most practically important cases the floors of the superstructure of the reconstructed building have different heights. In particular, the height of technical floors differs from the height of floors intended for residential premises, offices, industrial premises, halls, etc.

The external truss walls 12 are located along the axes 121, 122, 123 and 124 of the outer walls of the superstructure, the inner transverse truss walls 13 are located along the axes 131, 132, 133, 134, and 135, at least of the supporting internal transverse walls of the superstructure, and the inner longitudinal middle truss wall 14 is located on the central axis 141 of the building. All the above-mentioned truss walls are made of rigidly connected (by means of welding or threaded fasteners) lightweight assembly units, namely, modules (not shown in the drawings), which are a series of several typical fragments of truss walls providing including the formation of openings 17 in the relevant places of the project located windows and doors.

In addition, the superstructure contains interfloor ceilings 18, which are located at the level of the lower zones 16 of the truss walls 12-14 of each tier 11 of the frame, supported by metal supporting elements, which are either rigidly fixed to the lower girdle 16 of the truss walls corresponding to each interfloor overlap 18 , or made in one piece with the lower belts 16 of these truss walls, with each interfloor overlap formed in one piece with its construction and monolithic along its entire contour with the lower belts bordering it 16 corresponding e mu farm walls simultaneously with its device.

In a preferred embodiment of the utility model, the metal supporting elements are made in the form of beams 19 in the form of rods, strips, and the like, arranged for example in the longitudinal direction of the superstructure and fixed at their lower belts 16 of truss walls located opposite each other, for example, internal transverse truss walls 13 (figure 2). However, horizontally arranged elements of the metal profile, from which the lower belts 16 of the truss walls are made, can also be used as metal supporting elements. Thus, in this case, the metal supporting elements are made integrally with the lower belts 16 of the truss walls.

In a preferred embodiment of the utility model, each interfloor overlap 18 is prefabricated-monolithic and includes a metal profiled (e.g. corrugated) sheet 20 and a covering 21 located over its entire surface with a flat upper surface 22, which is the upper surface of the interfloor overlap 18, while the sheet 20 is supported on metal load-bearing elements (beams 19), and the cover 21 is made of monolithic concrete or reinforced concrete and monolithically when it is installed along the entire contour of the floor 18 with an eye mlyayuschimi its lower belts 16 its corresponding wall-farms. Patented execution of interfloor ceilings 18 can significantly reduce the complexity of their installation due to the simplification of their design, and therefore, accelerates the pace of construction and reduce its cost.

It should be noted that for the device of interfloor ceilings 18, reinforced concrete, preferably multi-hollow, slabs can also be used. In this case, each interfloor overlap 18 includes the above-mentioned reinforced concrete slabs laid in a row and supported on metal supporting elements (for example, as in the example described above, on beams 19), while by means of concrete joints and in a single cycle, reinforced concrete slabs are joined between into a single interfloor overlap 18, which is monolithic along its entire contour with 16 corresponding truss walls bordering its lower belts. Of course, the use of reinforced concrete slabs when installing flooring 18 does not fully ensure (as in the example described above) the achievement of the above results.

Thus, in both examples described above, all prefabricated-monolithic interfloor ceilings 18 of each tier of the superstructure framework are monolithic along the contour corresponding to each of them with the lower belts 16 of the corresponding truss walls bordering them. Therefore, in the patented reconstructed building, inside the superstructure framework and at the level of the lower girdle 16 of the truss walls of each of its tiers, a substantially continuous floor disk is formed, and the outer 12 and inner 13 and 14 truss walls are tiered rigidly joined by interfloor ceilings 18 located adjacent to the level of the lower zone of the truss walls of the corresponding tier of the frame. As a result, the patented superstructure framework, in the form of a high-strength, spatial, multi-tiered truss structure, together with the patented interfloor ceilings 18 form an integral geometrically unchanged spatial system that perceives external (wind, temperature) effects and is characterized by an additional high torsional rigidity, as well as a high bearing ability, due not only to the high load-bearing capacity of the truss walls, but also the load-bearing capacity of floors between floors 18. Traces viem the above is the use of patent-pending utility model for reconstruction with the superstructure even more, for example ten to fifteen floors.

To ensure the maximum possible useful use of the height of the reconstructed building, the floor floors 18 corresponding to the lower tier of the superstructure frame are placed with a minimum clearance relative to the roof 6 of the base building 1, which ensures that the load from the superstructure is transferred only to the vertical supports even in case of possible local contact between the floor floors 18 of the base roof buildings 1, for example, as a result of unequal precipitation of the old and new parts of the building after reconstruction.

The reconstruction of the base building 1 is carried out without resettlement of residents and without stopping its operation in cases where it is industrial, office or public, etc., in the following sequence.

In a preferred embodiment of the utility model, in the immediate vicinity of the base building 1 along its longitudinal outer walls and outside the area of compressible thickness of the soil, the foundations 4 of the base building 1 are constructed with deeper foundations 8, arranged in accordance with the project with variable and constant or periodically varying pitch. For each foundation 8, a group of bored piles 9 is made, after which a local grillage 10 is erected on top of each group of bored piles 9, while there is no violation of the bearing capacity of the compressible thickness of the soil under the foundation 4, since the bored piles 9 are based on the underlying soil layers. Then, on each foundation 8, vertical supports are erected, in the considered example (Fig. 1), columns 7, the height of which is not less than the height of the base building 1 (with a roof 6). It should be noted here that the construction may also include various structural elements known from the prior art. In particular, when performing vertical supports in the form of pylons, in each row they can be combined (monolithically interconnected) with ceilings located horizontally and at the level of the floors of the base building 1 and including the function of ceilings and floors of loggias for the floors of the base buildings 1. Next, on the column heads 7, a multi-tier steel frame of the superstructure is mounted, while the column heads 7 are rigidly connected to the corresponding section of the lower zone of the truss walls 12 of the lower tier.

The construction of the superstructure framework is carried out in tiers, while the installation of truss walls 12-14 of each tier is carried out element-wise, namely, from lightweight assembly units-modules, which are a series of several typical fragments of truss walls 12-14, by lifting the modules to the mounting level (for example, using a mast hoist, a self-propelled crane, winches and cradles) moving them horizontally (manually, by means of a cable system and traction winches), with their subsequent installation in the design position and securing them welding or threaded fasteners.

The installation of truss walls from modules (lightweight assembly units weighing, for example, up to 150 kg.) Provides, on the one hand, an increase in the degree of industrialization of work (due to the possibility of using a limited number of types of finished modules manufactured at specialized enterprises for truss walls), and therefore, accelerating the pace of construction and reducing its cost, and on the other hand, simplifying the production of construction work, reducing the complexity of mounting the frame, as well as the ability to carry out construction work triples without the use of lifting machines moving along the building. The latter circumstance is very important, as it allows reconstruction of the base building without stopping its operation, in particular, without resettling residents.

In the aforementioned preferred embodiment of the utility model, first, the metal supporting elements in the form of beams 19 are placed, for example, in the longitudinal direction and fixed at the ends on the lower belts 16 of the opposite transverse truss walls 13. The number of beams 19 is selected based on the weight they have an interfloor overlap 18. After that, a profiled metal sheet 20 is laid on the beams 19, the dimensions of which correspond to the dimensions of a prefabricated monolithic interfloor floors 18. Then the coating 21 is formed by concreting the entire upper surface of the sheet 20 with the formation of a flat upper surface 22, which is the upper surface of the resulting flooring 18, and ensuring that when the device is coated 21, it is monolithic along the entire contour of the formed flooring 18 with its lower edges belts 16 corresponding truss walls.

It should be noted here that the coating 21 can be made of reinforced concrete. In this case, before the concreting operation, placement of reinforcing elements corresponding to the design from the upper surface of the sheet 20 is carried out.

After the frame is erected, the superstructure to the design height above which the roof is mounted, external fencing is performed in accordance with the heat engineering calculations, depending on the location of the reconstructed building according to building codes, as well as the installation of the enclosing structures of the internal walls. If there is no elevator in the base building 1, then attached attached elevators are installed outside the reconstructed building with exits to the stairwells, including the base building.

The industrial applicability of the patented technical solution is also confirmed by the possibility of implementing it using means and materials known from the prior art.

Claims (2)

1. A reconstructed building containing a reconstructed base building with a roof, vertical supports erected from the outside of the base building along its longitudinal walls and having a height that is not less than the height of the base building with a roof, as well as a superstructure with floors, walls and roof, characterized the fact that the superstructure contains a steel frame supported on the heads of vertical supports and rigidly connected to them from rigidly interconnected tiers, the number of which is equal to the number of floors of the superstructure, each the frame mustache is made of rigidly connected outer truss walls, internal transverse truss walls and at least one internal longitudinal, middle truss wall, all truss walls mentioned above are made with parallel upper and lower belts, the distance between which is equal to the height corresponding to this tier of the floor of the superstructure, while the outer truss walls are located on the axes of the outer walls of the superstructure, the inner transverse truss walls are located on the axes of at least the internal transverse walls of the superstructure rooks, and the inner longitudinal middle truss wall is located on the central longitudinal axis of the building, all the truss walls mentioned above are made of lightweight assembly units-modules rigidly interconnected, which are a series of several typical fragments of truss walls providing openings in the location of windows and doors corresponding to the project, the outer and inner truss walls are tiered rigidly joined by interfloor ceilings, which are adjacent adjacent to the level of the lower truss walls of the corresponding tier of the frame, and interfloor ceilings are supported by metal load-bearing elements that are either rigidly fixed to the lower zone of the truss walls corresponding to each interfloor overlap, or are made integrally with the lower belts of these truss walls, and each interfloor overlap is formed into one the whole at its construction and monolithic along its entire contour with the lower belts bordering it corresponding to each interfloor overlapping of truss walls simultaneously with its construction. 2. The building according to claim 1, characterized in that each floor is made precast and includes a profiled metal sheet and a coating with a flat upper surface located on its entire upper surface, which is the upper surface of the floor, while the sheet is supported on metal load-bearing elements, and the coating is made of concrete or reinforced concrete and monolithic when it is installed along the entire contour of the floor with the lower belts bordering it with the corresponding truss walls .