RU60099U1 - MILITARY MONOLITHIC REINFORCED CONCRETE FRAME OF MULTI-STOREY BUILDING - Google Patents

Abstract

The utility model relates to the field of construction, in particular to the construction of multi-storey residential and public buildings, as well as administrative buildings and structures. The technical result consists in the implementation of a more rigid and durable precast-monolithic reinforced concrete frame, which can withstand alternating loads, including those characteristic of seismic effects. An additional technical result is the possibility of designing and building free-space premises. Essence: The proposed precast-monolithic reinforced concrete frame consists of a precast reinforced concrete column (K) 1 with holes 2 dividing the body K1 into separate sections with a step to the floor; load-bearing crossbars 3 of rectangular cross section, which have releases of transverse reinforcement of loop-shaped outline 4 on the upper face and releases of longitudinal working reinforcement 5 at the ends; from connecting crossbars 6, which have cutouts 7 and outlets of longitudinal working reinforcement 8 at the ends; of hollow core slabs 9 made with voids 10, for example, round in shape and having horizontal non-pass through, on the upper flange, in sections facing the ends, grooves 11 limitedly extended in the direction of the longitudinal axis of the voids, each of which is placed in the region of a certain hollow and with a step corresponding to the step of the indicated voids. Moreover, the number of grooves corresponds to the number of voids. 1 N. p. f-ly; 5 s p. f-ly; 12 ill.

Description

The utility model relates to the field of construction, in particular to the construction of multi-storey residential and public buildings, as well as administrative buildings and structures.

Known precast-monolithic reinforced concrete frame of a multi-storey building (RF Patent No. 2250966, class E 04 B 1/20, 2003), including precast reinforced concrete columns with holes at the level of the floors, precast prestressed crossbars having horizontal end faces recesses of a triangular section, and floor slabs with a gap between their ends, which, together with the holes in the columns, are monolithic at the same time as the reinforced outlets from the prefabricated frame elements released into them, while the reinforced concrete columns are made for several floors, they have continuous longitudinal reinforcement with prestressed reinforcement, including within the openings at the level of ceilings, where the reinforcement is passed through thick-walled pipes having steel support plates and running into the column body for the length of the anchoring. The joint of the columns in height is made in monolithic concrete at the level of the floors, while the ends of the joined columns are wedge-shaped in two directions, and the tensile reinforcement of the joined columns, passed through thick-walled pipes and having an overlap, is concreted at the joint level. Prefabricated crossbars are made with additional prestressed reinforcement in the upper zone.

The disadvantage of this technical solution is the increased complexity and material consumption of installation work, is justified only in earthquake-prone areas. In other areas, this leads to inappropriate construction costs.

Also known is a precast-monolithic reinforced concrete frame of a multi-storey building (RF Patent No. 2182624, class E 04 B 1/20, 2001), which consists of prefabricated reinforced concrete columns with openings at the level of the floors, multi-hollow floor slabs made with round voids , or oval, or elliptical, or ovoidal crossbars made of prefabricated monolithic in the form of spatial bodies with a prefabricated lower broadened part and a monolithic narrowed relatively lower upper part in the form of an extended polyhedron with a cross section mainly in the form of a rectangle or trapezoid, with the formation, together with the prefabricated part, of a single bearing profile with local broadening in the form of protrusions located along the length of the crossbar with a step corresponding to the pitch of the voids of the floor slabs supported on the crossbar, and the protrusions are made extended in the directions of the axes voids have a length of at least 1/3 of the thickness of the respective plates, and are placed in the supporting and supporting zones of the voids of the plates.

The disadvantage of this invention is its complexity in the installation of hollow core slabs. This is due to the fact that the installation is carried out by supporting the floor slabs on the crossbars with the simultaneous introduction of the protrusions of the crossbar into the voids of the plate.

Closest to the claimed frame is a precast-monolithic reinforced concrete frame of a multi-storey building "Kazan-1000" (RF Patent No. 2184816, class E 04 B 1/20, 2001), including precast concrete columns with holes at the level of overlap, prefabricated pre-stressed load-bearing and coupling beams with reinforcement outlets at the ends and floor slabs with a gap between their ends, while the floor slabs are multi-hollow, the end surfaces of the plates resting on the crossbars are made inclined to the plane of the plate with an inclination angle of 25-30 °, crossbars are made of rectangular cross section, and on the end faces have a horizontal recess

triangular section, while the gaps between the ends of the plates and the holes in the columns are monolithic at the same time with the released reinforcing outlets from the prefabricated frame elements.

The disadvantage of this known frame are the following points:

- firstly, the prefabricated parts of the crossbars protruding from the plane of the floor slabs are located both in the bearing and in the connecting direction, which does not allow designing and building free-space premises or makes it necessary to use suspended ceilings that reduce the height of the room;

- secondly, the end surfaces of the floor slabs made at an angle of 25-30 ° do not allow creating high-quality keys of the monolithic part of the crossbar.

The technical result provided by the proposed utility model is to perform a more rigid and durable precast monolithic reinforced concrete frame, which can withstand alternating loads, including those characteristic of seismic effects.

An additional technical result is the possibility of designing and building free-space premises.

The specified technical result is achieved by the claimed precast-monolithic reinforced concrete frame of a multi-storey building, including precast reinforced concrete columns with holes at the floor level, prestressed prefabricated bearing and communication beams with reinforcement outlets at the ends and multi-hollow floor slabs installed with a gap between their ends, which together with holes in the columns are monolithic at the same time with the releases of reinforcement of the indicated crossbars released into them, while the new one is that

on the upper flange of said floor slabs in sections facing the ends, horizontal non-through, made limitedly extended in the direction of the longitudinal axes of voids, grooves located in the region of said voids are made, while the supporting crossbars are additionally equipped with reinforcing outlets on the upper face, and the connecting crossbars have cutouts at the ends by which they enter the aforementioned column openings.

Floor slabs are made with voids of a round, or oval, or elliptical, or ovoidal shape in cross section.

The grooves are placed with a step corresponding to the step of the voids.

Prefabricated crossbars made of rectangular cross section.

Bearing crossbars are equipped with outlets of transverse reinforcement of a loop-like outline on the upper face and with outlets of longitudinal working reinforcement at the ends

Crossbars and floor slabs can have different orientations in one building - longitudinal and transverse.

The problem is solved by the following.

Due to the fact that on the upper shelf of the said floor slabs in sections facing the ends, horizontal non-through, made limited to the longitudinal axis of voids, grooves are made, it is possible to clearly establish reinforcing frames and qualitatively fill voids, thereby achieving additional rigidity of the frame.

The fact that the grooves are located in the region of the voids mentioned above works for the same purpose.

Due to the fact that the supporting crossbars are additionally equipped with reinforcing outlets on the upper face, the reinforcement of the upper zone of the supporting crossbars and the grids of the floor slabs are connected. continuous configuration of the monolithic part of the supporting crossbar.

The supply of connecting crossbars with cutouts at the ends, through which they enter the aforementioned column openings, provides an additional element of communication with the column during monolithic.

Due to the fact that the crossbars and floor slabs can have different orientations in the same building - longitudinal and transverse, it is possible to increase the spans of the building.

Due to the rigid connection of the joints of all frame elements and their monolithic frame has high rigidity.

The proposed utility model is illustrated by drawings, where:

figure 1 - shows the connection node of the floor slabs, beams and columns in a perspective view with a partial cutaway;

figure 2 is a sectional view of the reinforcement of a bearing precast-monolithic crossbar;

figure 3 is a sectional view of the reinforcement of the node connecting the columns with the bearing bolt;

figure 4 is a sectional view of the reinforcement of the node supporting the floor slab on the bearing beam;

figure 5 is a sectional view of the reinforcement of the node connecting the column with a connecting crossbar;

figure 6 is a shuttering drawing of a bearing beam;

Fig.7 is a sectional drawing of a bearing beam in section;

on Fig - shuttering drawing of the column;

figure 9 is a shuttering drawing of a tie bolt;

figure 10 is a shuttering drawing of a tie bolt in a section;

figure 11 is a top view of the floor slab;

Fig. 12 is a top view of the coupling beam.

The proposed precast-monolithic reinforced concrete frame of a multi-story building consists of a precast reinforced concrete column 1 with holes 2 dividing the body of the column 1 into separate sections with a step to the floor; load-bearing crossbars 3 of rectangular cross section, which have releases of transverse reinforcement of loop-shaped outline 4 on

upper face and releases of longitudinal working reinforcement 5 at the ends; from connecting crossbars 6, which have cutouts 7 and outlets of longitudinal working reinforcement 8 at the ends; from hollow core slabs 9, made with voids 10, for example, round in shape, and having horizontal through holes on the upper shelf, in sections facing the ends, horizontally extended in the direction of the longitudinal axis of voids, for example, to a length of 350 mm, grooves 11, each of which is placed in the region of a certain void and with a step corresponding to the step of the indicated voids. Moreover, the number of grooves corresponds to the number of voids.

Installation of structural elements of the inventive frame is as follows.

The bearing crossbar 3 and the connecting crossbar 6 are paired with the column 1. The longitudinal working reinforcement 5 of the supporting crossbar 3 is brought into the hole 2 of the column 1. Further, the longitudinal working reinforcement 8 of the connecting crossbar 6 is inserted into the same hole 2, leaving a gap between the ends communication crossbars. The releases of the fittings 5 and 8 are connected with the stacked supporting working fittings and the hole 2 of the column 1 is monolithic. The floor slabs 9 are laid on the supporting crossbars 3, also leaving a gap at the ends of the plates 9, reinforcing frames are installed in the grooves 11 and the channel formed by the gap between the ends of the plates 9 and grooves 11.

The proposed precast-monolithic reinforced concrete frame of a multi-storey building is characterized by the following indicators:

- reduced floor thickness - 14.2 cm;

- steel consumption per 1 m ^{2 of} overlap - 8.6 kg / m ² ;

- the proportion of cast concrete in the floor - up to 7%,

Claims (6)

1. The precast-monolithic reinforced concrete frame of a multi-storey building, including precast reinforced concrete columns with openings at the level of the floors, prestressed prefabricated bearing and connecting crossbars with reinforcement outlets at the ends and multi-hollow floor slabs installed with a gap between their ends, which together with the openings in the columns are monolithic at the same time with the releases of reinforcement of the indicated crossbars released in them, characterized in that on the upper shelf of the said floor slabs in the sections facing the ends are made horizontal non-through, limitedly extended in the direction of the longitudinal axes of voids, grooves located in the region of the said voids, while the bearing crossbars are additionally equipped with reinforcing outlets on the upper face, and the connecting crossbars have cutouts at the ends by which they enter the aforementioned column openings. 2. The frame according to claim 1, characterized in that the floor slabs are made with voids of a round, or oval, or elliptical, or ovoid shape in cross section. 3. The frame according to claim 1, characterized in that the grooves are placed with a step corresponding to the step of the voids. 4. The frame according to claim 1, characterized in that the prefabricated crossbars are made of rectangular cross-section. 5. The frame according to claim 1, characterized in that the supporting crossbars are equipped with outlets of the transverse reinforcement of a loop-like outline on the upper face and with outlets of the longitudinal working reinforcement at the ends. 6. The frame according to claim 1, characterized in that the crossbars and floor slabs can have different orientations in the same building - longitudinal and transverse.