RU1791573C - Floor - Google Patents

Abstract

Usage: as a ceiling or coating. SUMMARY OF THE INVENTION; the overlap contains prefabricated reinforced concrete panels combined into a single disk with monolithic seams made in the longitudinal channels formed by the side faces of the panels and transverse monolithic distribution poles located at the ends of the panels. Through channels and shelves there is placed through prestressed reinforcement with anchors. The monolithic distribution along the end walls has a plan-shaped shape and is placed above the end walls and corner sections of the longitudinal walls, and above the intermediate transverse walls and adjacent sections of the outer longitudinal walls, an I-shaped in plan. The bar at the end sections is equipped with vertical flat reinforcing cages. The coating disk over the lateral edges of the extreme panels has expansion joints at the depth of their embedment into the side wall. The number of through prestressed reinforcement in the channels increases in the direction to the longitudinal axis of the overlap and is determined by the formula given in the description. 5 s n, f-ly, 9 ill. Ј

Description

The invention relates to construction, and in particular to frameless residential and public buildings.

Prefabricated reinforced concrete slabs or coatings are known, including slabs with sloping faces and a pole with monolithic joints.

Under the influence of vertical loads in the known overlap, a complete redistribution of forces between the supporting elements is not ensured, with relatively low force effects at the seams between adjacent plates, breakdown and shutdown of the bonds are observed, since their quality depends only on the quality of work performed on the construction site. For this reason, the known overlap is not economical and reliable.

Overlapping is known, including prefabricated reinforced concrete panels connected to each other by monolithic seams, and in adjacent parts between adjacent flights, by one-piece reinforcing elements.

The known coating is laborious during the construction, as it requires careful manual execution of assembly and assembly work. It is unreliable and does not provide flexible space-planning solutions, since it requires the placement of additional columns.

Closest to the proposed one is a ceiling including precast reinforced concrete panels combined into a single disc with monolithic seams made in channels formed by the side faces of the panels and transverse distribution by themselves, through prestressed reinforcement placed in the channels, passed along the building and equipped anchors.

The use of such a ceiling in practice is associated with increased labor and material costs; it does not provide improved space-planning solutions. The reasons for this are that the prefabricated plates are not rigidly jammed in a single floor disk, high consumption of high-strength main prestressed reinforcement is noted, the floor does not provide a large step of the bearing walls.

The purpose of the invention is to reduce material consumption and improve space-planning decisions of the building.

This goal is achieved by the fact that in the ceiling, including precast concrete panels supported on the walls of the building, combined into a single disk with monolithic seams made in channels formed by the side faces of the panels and transverse monolithic distribution poles located at the ends of the panels, a through pre-stressed - 5 maturah with anchors located in channels and poles, monolithic distribution poles at the end walls are C-shaped in plan and placed above the end walls with angled sections ol

0 walls. Above the intermediate transverse walls and adjacent sections of the outer longitudinal walls, the rails have an I-shaped in plan view, and at the end sections they are equipped with vertical flat reinforcing cages. The number of through prestressed reinforcement in the channels increases in the direction to the longitudinal axis of the overlap and is determined by the formula (see

0 claims).

Through-through fittings are freely let through in the channels. It can be installed in channels curvilinearly along the diagram of moments in the zone of its positive 5 values, freely passed in channels, in zones of minimum negative moments it is equipped with intermediate internal anchors; monolithic seams within the entire zone of negative moments

0 are made two-layer. The transverse distribution lines along the contact with the ends of the floor panels are equipped with concrete keys placed in the voids of the panels, and expansion joints

5 are made in the form of an air gap or provided with elastic gaskets.

In FIG. 1 shows the proposed overlap in plan, general view; in FIG. 2 is the same, section AA in FIG. 1; in FIG. 3 0 distribution of forces in the section of the overlap along section AA in FIG. 2; in FIG. 4 - overlap, section BB in FIG. 1; in FIG. 5 is the same, section BB in FIG. 1; in FIG. 6 is the same, section GG in FIG. 1; in FIG. 7 is the same

5 a section DD in FIG. 1; in FIG. 8 is the same, node I in FIG. 2; in FIG. 9 - node II in FIG. 1.

The proposed overlap (Fig. 1, 2, 4-9) includes precast concrete panels 1, combined with each other

0 monolithic seams 2, made in the channels 4 formed by the lateral faces of 3 panels 1. In the channels 4, a pre-stressed reinforcement of 5 s is placed through the entire length of the building (or sections of the building)

5 anchors 6 at the ends. In the same channels 4, flat reinforcing frames 7 are placed. Reinforced concrete panels 1 are supported with ends 1 on the intermediate 8 and end 9 load-bearing walls of the building. At the ends of the panels 1 there are transverse distribution poles. Moreover, the strip 10 is placed above the end 9 and corner sections of the side walls 11 of the building, forming a planar shape in plan. The transverse lines 12 are placed above the intermediate load-bearing walls 8 and above the side walls 11 and each form an I-beam in plan view. The strips 10 and 12 above the transverse walls are reinforced with vertical flat reinforcing frames 13. Moreover, above the intermediate supporting walls 8, the flat frames 14 can be made with a length exceeding the width of the end plates 1 by the length of the anchoring zone of the working reinforcement of the frame 14. To ensure the enckering of the frames 13 and 14 their working reinforcement above the side walls 11 is made in the form of a loop through which flat welded mesh 15 is passed across.

In addition to making transverse distribution poles 10 and 12 in a figurative and I-shaped form in plan, for reliable fixation of the hollow panels 1 on the lateral surfaces along the poles 10 and 12 at the same time, concrete dowels 16 are placed in contact with the ends of the panels 1, placed in the cavities panels 1. For this purpose, hollow lattice thin-walled elements 17 are pre-installed on the ends of the panels 1 in their cavities, providing a given shape of the dowels 16 when concreting transverse rails 10 and 12.

Through tensile reinforcement 5, either along the entire length, or only in the zone of positive moments from the influence of the working load, is freely passed in the channels 4 and has a coating 18. In the zones of minimum negative moments, at transverse load-bearing walls, the reinforcement 5 can be equipped with additional internal anchors 19 and longitudinal seams 2 in all zones of negative moments can be made two-layer, and the upper layer 20 of monolithic concrete is laid after tensioning the reinforcement 5.

In order to prevent longitudinal cracks from forming in the extreme panels 1 on top of the side walls 11 from the influence of the work load and to ensure free angular movements of the upper panels on the top of their embedment depth in the walls 11, the overlap is provided with expansion joints 21. Moreover, the expansion joints 21 can be made with an air gap or can be equipped with plastic gaskets (rubber, roofing gaskets, etc.).

The overlap is constructed in the following order. The panels 1 are laid in the design position on the supporting transverse walls 8 and 9. In the channels 4 are placed in the design

the position of the through tensile reinforcement 5 and the flat frames 7, and between the ends of the panel 1 above the walls 8, 9 and 11 are placed flat welded frames 13, 14 and 15. Then

at the same time, the longitudinal joints 2 and the transverse distribution joints 10 and 12 are concreted if the longitudinal tensile reinforcement 5 is freely passed in the channels 4 along the entire length of the building. After the concrete strength has been set to the required strength, the through tensile reinforcement 5 is tensioned and fixed at the ends in the anchors 6 in the distribution supports 10. In the event that the longitudinal through 5 tensioned reinforcement 5 is freely passed in the channels 4 only in the zones of positive moment, the seams 2 in the areas of operation during the operation of negative moments are made in two layers, and the upper layer 20

0 joints 2 are concreted after tensioning the through reinforcement 5. Concreting of the upper layer 20 is carried out simultaneously with finishing work. 3 of both cases during concrete aging

5 monopolizing further work on. the erection of walls 8, 9 and 11 is not suspended. For scaffolding, formwork and tooling are not required. The proposed design of the ceiling

0 in comparison with the known one allows to cover spans of a greater length with the same thickness, which not only leads to a reduction in material consumption, but also due to an increase in the pitch of the load-bearing walls, it can significantly expand the possibilities of space-planning solutions in the building premises.

The implementation of through valves 5 freely passed in the channels 4 will allow for

In comparison with the prototype, to obtain additional technological advantages, expressed in increasing the pace of construction and installation works. In this case, hardening and curing

5 with concrete, joints 2 and distribution joints 10 and 12 occur without stopping the work, and the reinforcement 5 is subsequently tensioned at a convenient time.

0 Through-through reinforcement 5, placed in channels 4 curvilinearly along the trajectory according to the diagram of moments, in the zones of their positive values can be performed without adhesion to concrete, and in zones

5 minimum negative moments are provided with intermediate internal anchors 19. In this case, the seams 2 in the zones of negative moments (for transverse distribution poles 10 and 12) are made in two layers. Moreover, the top layer of the seam

2, in which the through-tensioning reinforcement 5 is placed, are concreted after tensioning the reinforcement. In the case under consideration, with the same technological advantages compared with the prototype, there is no reduction in metal saving, because by ensuring the adhesion of the reinforcement 5 in the support zones of the ceiling and supplying it with internal anchors 19, the efficiency of using through reinforcement 5 increases significantly. On the whole, the placement of the through tensile reinforcement 5 along the trajectory in accordance with the diagram of the moments makes it possible to create in the floors under the supporting intermediate transverse walls 8 the continuity and, accordingly, the negative supporting bending moments, thereby reducing the value of the passage moments acting in the section of the panels 1 The aforementioned allows, without increasing the cross-section and, accordingly, the material-capacity of the floor, to increase the pitch of the bearing walls 8 in the building, providing flexible space-planning solutions for the premises, and reduce th building material consumption.

The presence of concrete dowels 16 on supports 10 and 12, located in the voids of panels 1, allows rigid jamming of panels 1 at the ends above the supporting walls, thereby ensuring a complete redistribution of forces between panels 1 under load and facilitating the rational placement and use of concrete and overlap working reinforcement.

In order to further reduce the consumption of armature for overlapping in the intermediate transverse distribution poles 12, the vertical flat frames 13 may not be the entire width of the building, but only for a length that ensures their reliable anchoring in the poles 12, sufficient to fix the position of the panels 1 12 themselves, taking into account the vertical reducing stresses generated by the upstream parts of the intermediate bearing walls 8 of the building.

Expansion joints 21 under the lateral edges of the extreme panels can be made in the form of an air gap. This embodiment of the seams 21 is the simplest in execution and allows unobstructed rotation of the side faces of the extreme panels 1 above the side walls 11. To prevent solids from entering the air gaps. capable of obstructing the free rotation of the edges of the panels 1, the expansion joints 21 may be provided with elastic gaskets. Compared with analogs, the presence of the proposed expansion joints 21 can improve the reliability of the overlap disk.

Reducing labor costs is achieved by eliminating the need for traditional additional devices to fix the position of the hollow panels 1, as well as due to the possibility of laying monolithic concrete joints 2 in the channels 4 and transverse distribution

for sah without formwork.

Claims (6)

The proposed flooring is universal and can be used in residential, public and administrative buildings. Compared with standard ones, it allows reducing the specific consumption of reinforced concrete by 25 ... 28%, metal to 35%. SUMMARY OF THE INVENTION 1. Overlap, including precast reinforced concrete panels supported on the walls of a building, joined into a single disk by monolithic seams made in the longitudinal channels formed by the side faces of the panels and transverse monolithic distribution poles placed at the ends of the panels, through prestressed reinforcement with anchors placed in channels in basins, characterized in that, in order to reduce material consumption, monolithic 0 distribution along the ca at the end walls are {shaped in plan and placed above the end walls and corner sections of the longitudinal walls, and above the intermediate transverse walls and 5 adjacent sections of the outer longitudinal walls - I-shaped in plan view, and, at the end sections, they are equipped with vertical flat reinforcing cages, and the number of through 0 prestressed reinforcement in the channels increases in the direction of the longitudinal axis of the overlap and is determined by the formula 5 Ap 4MiX, (B-X,). | lB2Ri h where Mi is the largest value of the bending moment in the middle of the span of the overlap; Xr is the distance from the lateral face of the ceiling to the channel in question; B is the width of the overlap between its side faces; Ј |. Ј2 - empirical coefficients equal to 0.65 and 0.95, respectively; 5 R-I - design resistance of through-through prestressed reinforcement; h is the total height of the cross section of the ceiling; Api is the number of reinforcing bars, the amount coming to the design section of adjacent plates, adjacent to the channel, sufficient for their safe transportation and installation, while the entire coating disk; over the lateral edges of the extreme panels to the depth of their embedment in the side wall of the building has expansion joints, -. 2. Overlap pop, 1, characterized in that the through-through prestressed reinforcement is freely passed in the channels. 3. Overlap according to claim, characterized in that the through prestressed reinforcement in the channels is installed curvilinearly along the diagram of moments in the zone of its positive values, freely passed in the channels, in zones of minimal negative 5 of salient moments it is equipped with intermediate internal anchors, and monolithic seams within the entire zone of negative moments are made of two-layer ones. 4. Overlapping according to Claims 1–3, characterized in that the transverse distribution poles in contact with the ends of the floor panels are equipped with concrete dowels located in the voids of the panels. 5. The overlap according to p. 1-4, characterized in that the expansion joints are made in the form of an air gap, 6. The overlap according to claim 5, with the exception that the expansion joints above the lateral edges of the extreme panels are provided with elastic gaskets, 5-5 FS.6 H