SU1131984A1 - Prefabricated multivoid floor panel - Google Patents

Abstract

COMBINED MULTIPLE PANEL OF COVERINGS, made with a thicker upper shelf, characterized in that, in order to reduce the consumption of steel and labor costs for installing floors in the dimensions of the top shelf, the panels are formed with open grooves along its entire perimeter and closed through channels extending into them, placed at an angle of 45-60 ° to the longitudinal axis of the panel and at a distance from each other, exceeding the horizontal projection of the channel to the longitudinal axis of the panel. §

Description

The invention relates to the industrial construction of multi-storey civil and industrial buildings, in particular to the construction of floors.

A known type of panel design is for the construction of floors and floorings of buildings with a length of 3-9 m with a cross-section height of 220 mm and symmetrically arranged circular voids with a diameter of 159 mm.

The drawbacks of the known construction are the relatively low overall stiffness and strength of the support sections and the thin upper flange above the voids, which requires additional reinforcement of the panel. In addition, due to the high hollowness, the own weight of the panel is insufficient to provide the required sound insulation and it is necessary to arrange special supports for the floors, usually monolithic concrete, within the limits of which electrical and low-current networks are also placed. . The closest technical solution to the present invention is a precast hollow core floor panel, made with a thicker upper shelf 2.

The disadvantages of the known construction are the need to reconstruct the standard equipment and the forming equipment (replacement of the beads and punches) in connection with the change of the diameter and position of the round longitudinal voids, the impossibility of free placement of electrical and other communications without making monolithic preparations on the ceilings.

The purpose of the invention is to reduce the consumption of steel and labor costs for the installation of floors.

This goal is achieved by the fact that in the composite hollow-core floor panel, made with a thicker upper shelf, in the dimensions of the upper shelf of the panel, open grooves are formed along its entire perimeter and closed through channels extending therein at an angle of 45-60 ° to the longitudinal axis of the panel and at a distance from each other, exceeding the horizontal projection of the channel to the longitudinal axis of the panel.

FIG. 1 shows a composite hollow core panel; in fig. 2 is a section A-A in FIG. G, FIG. 3 - formwork for a panel (cross section).

The composite hollow-core panel 1 of the ceiling is made with the upper shelf 2 thickened 1JO compared to the lower shelf 3. In the dimensions of the upper shelf 2 of the panel 1, open grooves 4 are formed, located along its entire perimeter. In the grooves 4 exit closed through channels 5, placed at an angle of 45-60 ° to the longitudinal

the axes of the panel 1 and at a distance from each other, exceeding the horizontal projection of the channels 5 onto the longitudinal axis of the panel 1.

5 This arrangement of channels 5 does not weaken the cross section of the compressed zone of concrete and does not reduce the strength and rigidity of the panel, since any cross section intersects only one channel 5.

Making the overlap panel 1 with a thickened shelf 2 with an increased section height (260 mm) and making voids 6 with a diameter of 159 mm makes it possible to significantly reduce the consumption of steel for the reinforcement of panel 1 and reduce the labor intensity of the floor slab, since the use of such panels eliminates the labor-intensive work on the installation of monolithic preparations under the floor.

At the same time at the device of overlappings

 open grooves 4 with closed canals 5 extending therein enable both laying utilities and removing them during repair without destroying the base of the floor and

5 panel designs 1.

The laying of communications can be carried out simultaneously in two directions: along and across panels 1 and output them along closed channels 5 to different points of the floors, while reducing the length

0 closed areas and simplifies the laying of communications at smaller angles of inflection and adjoining the latter.

Panel I overlap with standardly located, relative to the lower and side faces, voids 6 with a diameter of 159 mm are made in a standard formwork including a pallet 7, longitudinal and end boards 8- For this, the corners 9 are fixed on the sides of the formwork 8 so that when the product is formed along the contour

its upper flange 2 has grooves 4 of a given size. In the holes provided in the corners 9, inventory-holding rods 10 are passed through with plastic pipes II attached to them, which are non-removable channel-formers. After the concrete has been laid and compacted, the panel is calibrated in height, the latching rods 10 are removed and the board equipment is removed - the panel is dismounted.

0 Installation of panels 1 in the slabs is carried out in the usual way, communications are placed in the slots 4 and channels 5, then the joints between the panels 1 and the slots 4 are sealed with concrete or mortar. According to the surface thus obtained

 overlapping floors without preparation device.

The invention makes it possible to reduce the consumption of steel for the reinforcement of the panels and, consequently, the overlap in general, and also to reduce the labor costs for the installation of the overlap by eliminating the device

podgotovrki under the floors and simplify the laying of utilities.

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Claims (1)

COMBINED MULTI-EMBEDDED OVERLAPPING PANEL, made with a thickened upper shelf, characterized in that, in order to reduce steel consumption and labor costs for the device of the overlap, open grooves are formed in the dimensions of the upper shelf of the panel along its entire perimeter and closed through channels extending into them are placed at an angle 45-60 ° to the longitudinal axis of the panel and at a distance from each other exceeding the horizontal projection of the channel onto the longitudinal axis of the panel.