RU2137886C1 - Method for erection of multistory framework building - Google Patents

Abstract

FIELD: construction engineering. SUBSTANCE: method can be used for erection of monolithic buildings and structures. According to method, columns and coverings are concreted in shuttering of each story with creation in coverings of open passages in mutually perpendicular directions for location of prestressed reinforcement by installing hollow-core forming mandrels in shuttering. Open passages in coverings are made of varying depth with incline towards center of each framework span to value equal to depth of covering. Upon hardening of concrete, shuttering is removed and hollow-core forming mandrels are taken away and then installed for concreting next story of framework. Installed in open passages along faces of columns in compliance with epure of bending moments is prestressed reinforcement. Reinforcement is tensioned by hydraulic jacks and fixed on end-faces of coverings over perimeter of building framework. After that, open passages in covering are concreted. Application of aforesaid method cuts labour input in manufacturing of framework, cuts erection period and improves quality of construction operations. EFFECT: higher efficiency. 2 dwg

Description

 The invention relates to the field of construction and is intended for monolithic construction of buildings and structures.

 A known method of erecting buildings frame system IMS, including the installation of columns, the installation of floor slabs, laying between the floor slabs of prestressed reinforcement in two mutually perpendicular directions with the passage of reinforcement into the holes made in the columns at the level of overlap, the tension of the reinforcement and subsequent monolithic joints between the plates and holes concrete (1).

 The disadvantage of this method is the restriction of the use of monolithic concrete elements of the frame due to the complexity of the transverse holes in the columns and the significant installation time.

 Closest to the proposed one is a method of erecting a multi-storey prestressed frame building, including floor-by-floor erection of columns, production of ceilings, placement of tensioned reinforcement in mutually perpendicular directions at the level of ceilings and its tension with subsequent monolithic seams between plates and holes. The erection of columns is made from prefabricated elements with holes for the passage of prestressing reinforcement, the package of floors is concreted and mounted by lifting and connecting to the column of prestressing reinforcement (2).

 The disadvantages of this method is the complexity of the construction of the frame due to the need for accurate installation of the columns to ensure alignment of the holes made for the passage of prestressed reinforcement, the passage of reinforcement through these holes and subsequent injection of solution into them after tensioning the reinforcement, as well as the long production time of the frame due to the sequential floor installation and the need for preliminary concreting of the floor package.

 The technical problem is to reduce the complexity of manufacturing the frame, reducing the time of its construction and improving the quality of construction work with monolithic concreting by eliminating the opening of holes in the columns, skipping prestressed reinforcement in them, injecting the solution into the holes after tensioning the reinforcement and monoling the joints of the columns with ceilings, and also due to the possibility of floor-level concreting of columns and ceilings, regardless of the installation of prestressed reinforcement, its tension and subsequent homologation.

 The problem is solved in such a way that in the method of erecting a multi-story frame building, including floor-by-floor erection of columns, production of ceilings, placement at the level of ceilings of prestressed reinforcement in mutually perpendicular directions and tensioning it with subsequent monolithic elements of the frame, according to the invention, columns and ceilings are concreted in the formwork each floor, while the floors are concreted with open channels for prestressed reinforcement with a variable depth with a slope to the center at each span of the carcass, equal in the middle of the span to the thickness of the floor, the prestressed reinforcement is placed in the open channels of the floor along the faces of the columns in accordance with the diagram of bending moments, followed by tension and fixing the reinforcement at the ends of the floor along the perimeter of the building frame.

 The proposed method differs from the known one in that the columns and floors are concreted in the formwork of each floor, while the floors are concreted with open channels for prestressed reinforcement with a variable depth with a slope to the center of each span of the frame, equal to the thickness of the ceiling in the middle of the span, the tensioned reinforcement is placed in open channels of overlap along the faces of the columns in accordance with the diagram of bending moments with subsequent tension and fixing of reinforcement at the ends of the overlap along the perimeter of the frame and I.

 The location of the prestressed reinforcement along the faces of the columns in the channels made in a monolithic overlap allows you to abandon the laborious operations of arranging holes in the columns with the location in the body of the concrete when concreting the columns of the formative tubes with the great accuracy of their location, as well as the need to pass prestressed reinforcement through the holes, and after tension monopolize the holes, and, in addition, avoid weakening the cross section of the column and reduce the bearing capacity of the column structure, i.e. the need to strengthen it. The implementation of channels of variable depth in the cross-section of the overlap makes it possible to locate the tensioned reinforcement in the stretched zones, and in the compressed conventional working reinforcement, while providing the possibility of the tensioned reinforcement to fix the cross-section in accordance with the diagram of bending moments and make full use of its properties. Floor-level concreting of columns and floors reduces the time frame is erected, since the reinforcement is tensioned independently and fixed at the ends of the floor around the perimeter of the building frame after hardening the concrete and removing the formwork.

 The method is illustrated in the drawing, where in FIG. 1 shows the frame of a multi-story building (section); in FIG. 2 - AA of FIG. 1.

 The method is implemented as follows.

 On the erected foundation, the reinforcing cage of column 1 is mounted on one, two or more floors. First, the formwork of the columns is installed to the height of the floor, then the horizontal formwork of the ceiling 2, in which the channel formers are placed, for the device of open channels for prestressed reinforcement and reinforcing frames of the ceiling. The channel formers are placed in such a way that they run along the faces of the columns in mutually perpendicular directions and have a height equal to kd at the faces of the columns, where k is the thickness of the concrete protective layer, d is the diameter of the reinforced reinforcement, and in the middle of each span of the frame is equal to the ceiling height and width - knd, where n is the number of reinforcing bars. Then make concreting columns 1 and floors 2 floors. After the hardening of concrete, channel formers are removed, the formwork of the floor and columns is dismantled, leaving temporary supports in the spans of the floor, mounted on the next floor and concreted on the next floor of the frame, etc. Into the formed open channels 3 in the floor 2 along the faces of the columns 1 in mutually perpendicular in the directions, lay the prestressing reinforcement 4 and fix it with the help of elements 5 in the places of the inflection of the reinforcement in accordance with the diagram of bending moments. Then the reinforcement is tensioned with hydraulic jacks to the calculated magnitude of the tension force and its fixation at the ends of the floor using anchor devices. As a prestressing reinforcement, use wire rope with a diameter of 9,12,15 mm GOST 13840-68 or wire reinforcement with a diameter of 3 - 10 mm GOST 7348-81. Then concreting open channels is carried out. Concreting of columns and floor overlapping and reinforcement tension are carried out autonomously in a continuous cycle and can significantly reduce the construction time of a multi-story frame building.

Sources of information:
1. St. B. Koprivitsa "Application of the IMS frame system for the construction of residential and public buildings", g. "Housing", N 1, M., 1984, p. 30-32.

 2. SU Copyright certificate N981547, cl. E 04 G 21/14, BI N 46, 1982 (prototype).

Claims (1)

 A method of erecting a multi-storey frame building, including floor-by-floor erection of columns, production of ceilings, placement at the level of ceilings of prestressing reinforcement in mutually perpendicular directions and its tension with subsequent monolithic elements of the frame, characterized in that the columns and ceilings are concreted in the formwork of each floor, while the floors are concreted with open channels for prestressed reinforcement with a variable depth with a slope to the center of each span of the frame, equal to the middle span slab thickness, tendons placed in open channels along the overlapping edges of columns in accordance with the bending moment and tension, followed by fixing the fittings at the ends overlapping on the perimeter of the building framework.

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