SU962548A1 - Method of erecting high-rise buildings with rigidity core by the method of floor-lifting - Google Patents

Description

The invention relates to cTpoHTenb ^J property, in particular, to methods for erecting multi-story buildings with a core of rigidity by the method of lifting floors.

A known method of construction by lifting the floors of a building with a reinforced concrete core of rigidity, including the installation of columns, the manufacture of a package of floor slabs with their subsequent lifting 'to the design elevators [1]. *

There is also known a method of erecting a multi-storey building with a stiffness core by the method of · raising floors, including installing columns of the building, making floor slabs and stiffness cores with their elevators lifting them up by the floor, installing the slabs in the design position, followed by concreting the stiffness core [2].

A disadvantage of the known methods is that the stability of the building during the lifting and mounting period is ensured by the steel frame, which is erected from the foundation to the top of the building, and the vertical elements of the steel frame are e-monolithic together with the stiffness core, which leads to unjustified cost overrun of steel.

The purpose of the invention is the reduction of labor = the intensity of the erection process and the reduction of metal consumption.

This goal is achieved by the fact that according to the method of erecting a multi-storey building with a core of rigidity by the method of lifting floors, including the installation of columns of the building, ego-. 1Q the production of floor slabs and stiffening core with their hoist lifting by floors, installing the slabs in the design position, followed by floor-level concreting of the stiffening core after raising all the slabs 15 ku above the level of the first design elevation, fix the lower slab at the level of the first design elevation and install there are mounting links under it, attaching them to the columns, then after the elevators are rearranged along the height of the columns, the remaining plates are subsequently lifted with the next lower plate fixed to the second design second mark, and then set it under the optional mounting connection, attaching them to the columns of the floor, then concreted core stiffness to the height level of the first design mark, and after nabo30 Dr. concrete strength mounting svya3 communication ground floor dismantle and za-. the cycle is repeated until the construction of the building as a whole.

Figure 1 shows the installed columns, made a package of floor slabs and installed, lifts; 5 in figure 2 - the rise of floor slabs, when the bottom plate is fixed at the level of the first design elevation, and within the first floor they install mounting ties; on fig.Z - further-upward rise with fixing the next plate at the second design level, with installation within! the second floor of additional mounting ties and concreting of the stiffness core to the highest level of the first floor; in Fig. 4, further lifting with fastening, the next slab at the third design mark with installation within the third floor of the installation ties, dismantled — 2q bathrooms from the second floor, and concreting the stiffness core within the second floor; figure 5 - further construction of the building with such a cycle; figure 6 is the final position. buildings erected by the proposed method; 7 is a building in plan.

The method of erecting a multi-storey building with a core of rigidity by the method of lifting floors is carried out by an image.

After installing the columns' 1 of the building and manufacturing the package of floor slabs 2 on the columns ¹ , the elevators 3 are installed to the height necessary 35 to ensure the stability of the building and to raise all the slabs to the elevation above the level of the first design elevation. Next, lift the floor slabs, and after raising all plates 40 to the mark above the design level of the first bottom plate 4 zakrep- lyayut ¹ at first the design level 'and set underneath mounting connection 5, attaching them to kolon- 45 us. Then, after the elevators 3 are rearranged to a height at which stability of the building is ensured only by columns, the subsequent lifting of the remaining plates is carried out with the next lower plate 6 being fixed at the second design elevation. Next, additional mounting connections 7 are installed under it, fixing them to the columns of this floor. After that, the core 8 of rigidity is concreted to a height of the level of the first design mark. And after the concrete has gained strength, the mounting ties of the first floor are dismantled and installed within the third floor.

In this sequence, the cycle is repeated until the construction of the building as a whole.

The proposed method can significantly reduce the consumption of steel, since the stability of the building in the lifting and installation period is provided by the columns of the frame at the initial stage, two sets of mounting connections, as well as the subsequent phased concreting of the stiffness core along the height of the building from the bottom up.

At the same time, the stiffeners in the installation stage are the columns and slabs of the building with the inclusion of mounting links between them. In addition, the proposed method also reduces the complexity of the work, because this method does not require the installation of special equipment for the construction of the core of the stiffness core and the working sites for concreting the core are floor slabs.

Claims (2)

The invention relates to the construction, in particular, to methods of erecting multi-storey buildings with a reinforced concrete stiffness method. There is a known method of erection by the method of lifting floors of a building with a reinforced concrete core, including the installation of columns, the manufacture of a package of floor slabs with their subsequent lifting of design elevators 1. There is also known a method of erecting a multi-storey building with a core stiffness method, lifting floors, including installing building columns, making floor slabs and stiffening them with floor-by-floor lifting, installing plates in a design position, followed by concreting the stiffening core 2. A disadvantage of known methods is the fact that the stability of the building during the lifting and installation period is ensured by the steel frame, which is erected from the foundation to the top of the building, with the vertical elements of steel th frame zamonolichivayuts with the core stiffness, which leads to unnecessary overspending steel. The purpose of the invention is to reduce tr5G before the construction process and reduce the metal consumption. This goal is achieved by the fact that according to the method of erection of a multi-storey building with a core of rigidity by the method of lifting floors, including the installation of building columns / derelict. the manufacture of floor slabs and stiffeners with their lifting with elevators, installation of slabs in the design position with subsequent concreting of the stiffener after floor raising of all plates to the mark above the first design elevation, the lower slab is fixed at the level of the first design elevation and mounting is installed below it connection, attached them to the columns, then after shifting the lifts along the height of the columns, they carry out the subsequent raising of the remaining plates with the fixing of the next lower plate to the second design The first mark, after which additional mounting brackets are installed under it, attached them to the columns of this floor, then concrete blocks are stiffened to the height of the first design elevation level, and after the concrete gains strength, the mounting connections of the lower floor are dismantled, and then the cycle is repeated until construction here or in general. In Fig. 1, installed columns, a pack of recipe plates and installed, are invented; the lifts in Fig. 2 raise the floor slabs when the bottom plate is fixed at the level of the first design elevation, and I install wiring connections within the first 3Ta3ka; Fig. 3 shows a further ascent with fixing the next PITA at the second design mark, with installation of additional assembly connections for concreting the stiffener core to the level of the first floor within the second floor; in Fig. 4, a further ascent with fastening of the next plate on the third design label with installation of assembly connections within the third floor, dismantled from the second floor, and concreting of the core, rigidity within the second floor; in FIG. 3, the further construction of a building with such a cycle; figb is the final position of the building erected by the proposed method; 7 - building in the plan. The method of erecting a multi-building building with a stiffening core by the method of lifting floors is carried out in the following manner. After installing columns 1 of the building and making a package of floor slabs 2 on the columns, lift 3 lifts up to the height necessary to ensure the stability of the building to lift all the slabs to the leveling above the first design mark. Next, the floor slabs are lifted of all the plates on the level of the LEADER of the level of the first project mark, the bottom plate 4 is fixed at the level of the first design mark and the installation links 5 are installed below it, attached to the columns. Then, after the elevators 3 are moved to a height at which the building is only stable by columns, the next plates are lifted further with the next lower plate 6 fixed to the second design mark. Further, additional installation links 7 are installed under it, fastened them to the columns of this floor. After that, concreting core 8 is concreted to the height of the first design elevation level. And after the concrete has gained strength, the mounting connections 5 of the first floor are dismantled and installed within the third floor. In this sequence, the cycle is repeated until the building as a whole is erected. The proposed method allows to significantly reduce steel consumption, since the stability of the building during the lifting and mounting period is provided by the frame columns at the initial stage, with two sets of assembly links, as well as the subsequent step-by-step concreting of the stiffener along the building height from bottom to top. At the same time, the rigidity elements in the installation stage are columns and slabs of the building, with interconnecting connections between them. In addition, the proposed method also reduces the laboriousness of the work, because this method does not require the installation of special tooling for the construction of stiffeners and the concrete concreting sites are floor slabs. Claims of Invention A method of erecting a multi-storey building with a core of stiffness using the method of lifting floors, including installing columns of a building, manufacturing floor slabs and a stiffener core with floor-by-floor lifting with elevators, installing plates into the design position with subsequent floor concreting of a stiffener core, the laboriousness of the erection process and the reduction of metal consumption, after lifting all the plates to a level above the level of the first design elevation, the bottom plate is fixed at the level of Then, after installation of the elevators pe to the height of the columns, the remaining plates are subsequently raised with the next lower plate fixed to the second design mark, after which additional assembly links are installed. attached them to the columns of this floor, then concreted core stiffness to the height of the first design elevation level, and after dialing with a concrete strength, the assembly connections of the lower floor are dismantled, then the cycle is repeated construction of the building as a whole. Sources of information taken into account in the examination 1.Shakhnazar and S.Kh. and others. Construction of buildings by the method of lifting floors. M., stroiizdat, 1974, p.98-104. 2. USSR author's certificate according to the application No. 2781201 / 29-33, cl. E 04 G 21/14, 1979 (prototype). F fug / Fig. TG TT gg tt tg - / /