RU2442868C1 - Method for constructing building addition - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: the invention relates to construction, in particular, to method for constructing building addition. Bearing vertical supports are built with the height at least equal to the height of the original building, furthermore, the supports are built on the exterior of the original building along its longitudinal exterior walls. After the bearing supports are built, a multi-layer carcass is constructed on their heads layer-by-layer. Each carcass layer is made from exterior and interior truss walls with parallel girths where the distance between them is equal to the addition floor corresponding to the said layer. Exterior truss walls are positioned along the axes of exterior addition walls, while interior truss walls are positioned along the axes of interior bearing longitudinal walls and along the central longitudinal axis of the building. All truss walls are assembled from tightly fixed modules. After building the addition carcass intermediate floor is installed on each layers at the level of lower girth of truss walls of the installed carcass layer. All intermediate floors are composite.

EFFECT: improved bearing frame of the addition, high torsional stiffness.

3 cl, 3 dwg

Description

The invention relates to construction, and in particular to methods of reconstruction of existing buildings with a superstructure of additional floors without stopping the operation of an existing building, in particular without resettling residents, and in urban areas.

From the achieved level of technology, a method for building superstructure is known, including erection of supporting vertical supports and structures on them near the walls of the base (reconstructed) building, while bored piles are made along the perimeter of the base building outside the compressible thickness of the base soil of the base of the base building, on top of which tape is arranged monolithic reinforced concrete grillage, on which load-bearing vertical supports are erected from monolithic reinforced concrete with a simultaneous installation in the levels of overlap of the base buildings of additional floors with cantilevered protrusions in the direction of the base building, and the erection of the outer walls of the building. After erecting the vertical supports to the level of the roofing of the base building, the cover is dismantled, and in its place a continuous monolithic reinforced concrete safety slab resting on the walls of the base building is arranged. Next, on the heads of the supporting vertical supports, the mounting trusses are mounted on which the superstructure is being erected (see patent RU-C1-No.2036291, 1995).

The main disadvantage of this method is that it cannot be used in the construction of an add-in with a sufficiently large number of floors (for example, 8-10 or more), since the construction of an add-in on load-bearing farms, which, in turn, are supported by bearing heads vertical supports, will lead to the fact that the superstructure will simply be a load on the supporting trusses, and the bearing capacity of the external and internal walls of the superstructure, as well as its floors, is practically not used. In addition, the installation of a continuous safety slab resting on the walls of the base building will certainly lead to an increase in the load on its walls and foundation (the weight of the slab is greater than the weight of the roofing). Therefore, the known method can be used only in the presence of reserves of the bearing capacity of the walls and foundations of the base building. It should also be noted here that the placement of supporting 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 devices moving along the walls of the base building and outside the building 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.

There is also a known method of building superstructure, taken as a prototype and including the construction of an additional foundation, on which load-bearing vertical supports are erected with a height not less than the height of the base (reconstructed) building, while load-bearing vertical supports are erected on the outside of the base building along its longitudinal outer walls, and on the bearing vertical supports, the device is installed continuous over the entire area of the superstructure of the floor floors. The superstructure is performed 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 prototype allows you to abandon the use of hoisting machines moving along the base building, since the bearing vertical supports erect from the outside of the base building, but only along its longitudinal outer walls (see patent RU-C1 No. 2156841, 2000). As a result, a superstructure of the base building is provided without stopping its operation, in particular, without resettling residents.

The disadvantage of the prototype is that it does not provide high torsional rigidity and the bearing capacity of the superstructure, since the walls of the superstructure are essentially only a load on the solid disks of the floor floors. In other words, the prototype cannot be used to build a superstructure with a sufficiently large number of floors, for example, 8-10 and above.

The present invention is aimed at solving the technical problem of creating a method for building superstructure, which provides both an increase in the superstructure's bearing capacity and high torsional rigidity, while increasing the degree of industrialization of work, reducing labor intensity and simplifying the construction work.

The problem is solved in that in the method of building superstructure, including the construction of vertical supporting pillars with a height not less than the height of the base building with a roof, the installation of floor floors and superstructure walls, as well as the installation of the roof, while the vertical supporting pillars are erected along the outer side of the base building along of its longitudinal external walls, according to the invention, after the erection of the bearing vertical supports on their heads, a steel multi-tier frame is erected, the number of tiers of which is equal to the number of floors of the superstructure, frame they are parted in tiers to ensure a rigid connection of the elements of adjacent tiers contacting each other, while each tier of the frame is made of external and internal truss walls with parallel upper and lower belts, the distance between which is equal to the height of the superstructure floor corresponding to this tier, and the outer truss walls are placed along the axes of the external walls of the superstructure, the internal truss walls are placed at least along the axes of the internal supporting transverse walls of the superstructure and along the central axis of the building and are rigidly connected to each other d, all the above-mentioned wall trusses are mounted on the mounting level corresponding to each tier from lightweight assembly units-modules, which are rigidly interconnected to form openings in the locations of windows and doors corresponding to the project, after the superstructure frame is erected to the design height of each tier, the device interfloor ceilings at the level of the lower zone of the farm walls of the next mounted tier of the frame; all interfloor ceilings are prefabricated and monolithic and interacting, etc. respectfully supported, with metal load-bearing elements that are fixed, for example, rigidly on the lower girdle of the truss walls corresponding to each interfloor overlap, or are made integrally with the lower belts of these truss walls, wherein each interfloor overlap is integral with it device with simultaneous monoling it along the entire circuit with the lower belts of the corresponding truss walls bordering it.

In addition, in the patented method, the metal supporting elements are made in the form of beams, the ends of which are fixed on the lower belts of the truss walls opposite each other, and when the precast-monolithic floor is installed, the metal profiled sheet is laid on the above-mentioned beams, the dimensions of which correspond to the dimensions arranged interfloor overlap, and then concreting is carried out over its entire upper surface with the formation of a flat upper surface of the concrete coating, yuscheysya upper surface of the resulting intermediate floor, and with simultaneous embedment of it around its contour bordering with its lower belts its corresponding wall-farms.

In addition, in the patented method, before the concreting operation, reinforcing elements are placed from the side of the upper surface of the metal profiled sheet.

The advantage of the patented method of building add-on compared to the prototype is that the above patentable combination of features related to the construction of a steel multi-tier frame, as well as to the device of floor floors, provides the construction of the superstructure frame in the form of a high-strength spatial, multi-tiered truss structure, which together with interfloor ceilings, arranged according to the patented method, form an integral, geometrically unchanged spatial system a subject perceiving external influences and characterized by high torsional rigidity and high load-bearing capacity, due not only to the high load-bearing capacity of truss walls, but also to the load-bearing capacity of floors. Patented installation of truss walls from modules (lightweight assembly units) provides, on the one hand, an increase in the degree of industrialization of construction works (due to the ability to use a limited number of types of prefabricated modules manufactured at specialized enterprises for truss walls), and therefore, the pace acceleration construction and reducing its cost, and on the other hand, simplifying the construction work, reducing the complexity of mounting the frame, as well as the ability to carry out the construction of construction without the use of lifting machines moving along the building. The latter circumstance is very important, as it allows the reconstruction of the base building without stopping its operation, in particular without resettlement of residents.

Other technical results achieved using the patented invention will become apparent from the following.

The invention is further 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 base building with an erected superstructure frame, 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, which includes at least the external 2 and internal 3 walls, the foundation 4, the floors 5 and the roof 6, bearing vertical supports, for example columns 7, whose height is not less than the height of the base building with a roof 6. Columns 7 are erected from the outside of the base building 1 along its longitudinal outer walls on an additional foundation, which is made deeper than the foundation 4. An additional foundation can be made directly contact with the foundation 4 (as in the prototype) or in the form of an independent foundation of bored piles with reinforced concrete tape grillage (see patent RU-C1-No.2116417, 1998). Columns 7 can also be erected on the foundation 8 corresponding to each column 7, which is deeper than the foundation 4. 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 the area required for supporting only one column corresponding to it 7) grillage 10.

On the heads of the bearing vertical supports, in the considered example of columns 7, a steel multi-tier superstructure frame was erected, the number of tiers 11 of which is equal to the number of floors of the superstructure. In other words, the number of floors located above the roof level 6 of the base building 1. The superstructure frame is supported on the heads of columns 7 and is rigidly fixed to them. It should be noted that the bearing vertical supports can also be made in the form of pylons.

Each tier 11 of the superstructure frame is made of external truss walls 12, as well as internal, namely transverse truss walls 13, and at least one longitudinal, middle (central) rigidly interconnected (by welding or threaded fasteners) ) truss walls 14, while all of the above truss walls 12-14 are made with parallel upper 15 and lower 16 belts, the distance H between which is equal to the height of the superstructure floor corresponding to this tier. All of the above-mentioned truss walls 12-14 are made of rigidly interconnected lightweight assembly units, namely modules (not shown), which are a series of several typical fragments of truss walls, which provide, inter alia, the formation of openings 17 in the corresponding project locations of windows and doors.

In addition, the superstructure contains interfloor ceilings 18, which are located at the level of the lower belts 16 of the truss racks 12-14 of each tier of the frame, interacting, preferably supported, with metal load-bearing elements that are either fixed, for example, rigidly to the lower girdle 16 of the truss walls corresponding to each interfloor overlap 18, or made integrally with the lower belts 16 of these truss walls.

In a preferred embodiment of the invention, the metal supporting elements are made in the form of beams 19 in the form of rods, strips and the like, located, for example, in the longitudinal direction of the superstructure and secured with their ends on the lower belts 16 of opposite truss walls, 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 supporting elements are made in one piece with the lower belts 16 of the truss walls.

In a preferred embodiment of the invention, each prefabricated monolithic floor overlap includes a metal profiled (e.g. corrugated) sheet 20 and a concrete or reinforced concrete coating 21 located along its entire upper surface with a flat surface 22, which is the upper surface of the floor 18, while the sheet 20 is supported on metal supporting elements (beams 19).

The method of building superstructure is as follows, without stopping the operation of the base building 1 and in urban areas. First, in the immediate vicinity of the base building 1, along its longitudinal outer walls (preferably outside the zone of compressible soil thickness of the foundation foundation 4 of the base building 1), deeper foundations 8 are constructed, arranged in accordance with the project with variable, constant or periodically varying pitch. For each foundation 8, a group of bored piles 9 is made, a local grillage 10 is built. Then, on each foundation 8, a corresponding vertical support is erected, in this example, a column 7, not less than the height of the base building 1 with a roof 6.

Next, on the heads of the vertical supports (columns 7), a steel multi-tier frame is erected, the number of tiers 11 of which is equal to the number of floors of the superstructure, while the heads of the columns 7 are rigidly connected to each section of the lower girder of the truss walls 12 of the lower tier of the superstructure.

The superstructure framework is erected in tiers to provide a rigid connection of the upper and lower trusses of the truss walls of adjacent tiers 11, in other words, in other words, the upper truss truss wall of each tier 11 is rigidly connected to the corresponding lower truss truss wall of the next tier of the superstructure framework. The installation of truss walls 12-14 of each tier 11 is carried out elementwise, namely, from lightweight assembly units of modules, which are a series of several typical fragments of truss walls 12-14, by lifting the modules to the mounting level of the corresponding tier (for example, using the mast hoist, self-propelled crane, winches and cradles), moving them in the horizontal direction (for example, manually, by means of a cable system and traction winches), with their subsequent installation in the design position and fixing by welding or zbovyh fasteners. The modules are rigidly interconnected with the formation of openings 17.

Each tier 11 of the superstructure frame is made of external 12 and internal 13, 14 truss walls, while the external truss walls 12 are placed along the axes 121, 122, 123 and 124 of the outer walls of the superstructure, the inner transverse truss walls 13 are placed along the axes 132, 132, 133, 134 and 135 of at least the internal load-bearing transverse walls of the superstructure, and the internal longitudinal middle truss wall 14 is placed along the central longitudinal axis 141 of the building. All the mentioned truss walls are rigidly interconnected.

After the superstructure frame is erected at the design height of each tier 11 (in other words, at the height of each superstructure floor), interfloor ceilings 18 are installed at the level of the lower girdle of the truss walls 12-14 of the mounted next tier of the carcass. All interfloor ceilings are prefabricated-monolithic and, preferably, supported on metal supporting elements, which are either rigidly fixed to the lower girdle of the truss walls corresponding to each interfloor overlap, or are made integrally with the lower girdle of these truss walls. Each interfloor overlap is formed in one piece when it is constructed, while at the same time monoling it along its entire contour with its lower belts 16 corresponding to the truss walls.

In a preferred embodiment of the invention, the metal supporting elements are in the form of beams 19, the ends of which are fixed on the lower belts 16 of the opposite truss walls. To do this, the beams 19 are placed, for example, in the longitudinal direction (Fig. 2) 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 of the floor (arranged) on them 18. After that, the metal profiled sheet 20 is laid on the beams 19, the dimensions of which correspond to the dimensions of the prefabricated monolithic flooring 18, then the coating 21 is formed by concreting the entire upper second surface of the sheet 20 to form a flat upper surface 22, which is the upper surface of the resultant intermediate floor 18, and secured at the coating embedment device 21 around the entire periphery formed with intermediate floor 18 bordering its lower belts 16, respective truss-walls. Coating 21 may be made of reinforced concrete. In this case, before the concreting operation, the reinforcing elements of the design according to the design are placed on the side of the upper surface of the sheet 20.

It should be noted that the patented implementation of the flooring 18 allows to significantly reduce the complexity of their installation due to the simplicity of their device, and therefore, accelerates the pace of construction and reduce its cost.

Instead of sheet 20 and cover 21, reinforced concrete, preferably multi-hollow, slabs can be used for prefabricated-monolithic floors. In this case, when the device is installed on the beams 19, reinforced concrete slabs (not shown) are laid in a row on the beams 19. After that, in a single cycle, the formation of concrete joints between reinforced concrete slabs, as well as joints between reinforced concrete slabs and the lower belts 16 of the corresponding truss walls bordering them, are carried out. In other words, in this case, the device of the interfloor ceilings is carried out by forming inter-tile seams with the simultaneous monolithic interfloor overlap throughout the circuit.

Thus, in both examples described above, all prefabricated-monolithic floor floors 18 of each tier 11 of the superstructure framework are monolithic along the respective contour with the lower belts 16 of the corresponding truss walls bordering them. Therefore, inside the superstructure framework and at the level of the lower zone 16 of the truss walls of each of its tiers 11, 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 belt truss walls of the corresponding tier of the frame. As a result, the superstructure framework together with the interfloor ceilings 18 form an integral, geometrically unchanged spatial system characterized by (as noted above) high torsional rigidity and high load-bearing capacity. A consequence of the foregoing is the possibility of using the patented method in the reconstruction of base buildings with a superstructure of high storeys, for example, from ten to fifteen floors.

In a preferred embodiment of the invention, the 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. This makes it possible to use the height of the reconstructed building as much as possible.

After the superstructure frame is erected to the design height, the roof is mounted. In the process of the superstructure of the base building 1, external fencing is carried out, as well as the installation of the enclosing structures of the internal walls of the superstructure.

The industrial applicability of the invention is also confirmed by the possibility of its implementation using known from the prior art means and materials.

Claims (3)

1. The method of building superstructure, including the erection of vertical bearing pillars with a height not less than the height of the base building with a roof, the installation of floor floors and superstructure walls, as well as the installation of the roof, while the vertical bearing pillars are erected from the outside of the base building along its longitudinal outer walls, characterized in that after the erection of the bearing vertical supports on their heads, a steel multi-tier frame is erected, the number of tiers of which is equal to the number of floors of the superstructure, the frame is erected in a tiered manner with a rigid connection of elements of adjacent tiers that are in contact, each tier of the frame is made of external and internal truss walls with parallel upper and lower belts, the distance between which is equal to the height of the superstructure floor corresponding to this tier, and the outer truss walls are placed along the axes of the outer walls of the superstructure , the inner wall trusses are placed at least along the axes of the internal supporting transverse walls of the superstructure and along the central axis of the building and are rigidly interconnected, all the above truss walls mon they are installed at the mounting level corresponding to each tier from lightweight assembly units-modules, which are rigidly connected to each other with the formation of openings in the locations of windows and doors corresponding to the project, after the superstructure frame is erected to the design height of each tier, interfloor ceilings are installed at the level of the lower truss the walls of the mounted next tier of the frame, all interfloor ceilings are prefabricated-monolithic and interacting, preferably supported, with metallic with supporting elements, which are fastened, for example, rigidly, on the lower girdle of truss walls corresponding to each interfloor overlap, or are made integrally with the lower girdles of these truss walls, while each interfloor overlap is formed as a whole when it is installed with the same along the entire contour with the lower belts bordering it on the truss walls corresponding to it. 2. The method according to claim 1, characterized in that the metal supporting elements are in the form of beams, the ends of which are fixed to the outer belts of the farm walls located opposite each other, and when the prefabricated-monolithic floor is first installed, the profiled metal is laid on the above-mentioned beams a sheet whose dimensions correspond to the dimensions of the arranged interfloor overlap, and then concreted along its entire upper surface to form a flat upper surface of the concrete coating, i the upper surface of the resulting interfloor overlapping, and at the same time monoling it along its entire contour with the lower belts of the corresponding truss walls bordering it. 3. The method according to claim 2, characterized in that before the concreting operation, reinforcing elements are placed from the side of the upper surface of the metal profiled sheet.

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