RU2610951C1 - Structure of strengthening of reinforced concrete hollow-core slabs - Google Patents

Abstract

FIELD: building.

SUBSTANCE: invention relates to the construction and, in particular, to structures of strengthening of reinforced concrete hollow-core slabs, the access to which is not possible from above, for example, floor slabs, mainly used in buildings with a roof combined. The invention is that the structure of strengthening reinforced concrete slabs has protrusions formed below the lower face of slab plane, where in the zone of slab hollows additional reinforcement is put and built-in along slab zone in above mentioned protrusions. Additional built in armature is provided with, at least, two built-in anchors, where additional built in armature has bent ends passing through openings formed in the bottom of the slab. The bent ends of the additional reinforcement are placed and built-in in slab hollows. Concrete dowels are made close to slab openings in slab hollows.

EFFECT: invention allows increasing the carrying capacity, stiffness and fracturing resistance of a plate, reducing labor costs and material consumption, and weight reducing after plates strengthening.

3 cl, 3 dwg

Description

The invention relates to the construction, in particular, to reinforcement structures for reinforced concrete multi-hollow floor slabs, access to which is not possible from above, for example, floor slabs used mainly in buildings with combined roofing.

A known reinforcement design, including puffs on the outside of the plate, located at its stretched surface, the fastening elements of the puffs are made in the form of a strand. The weight is placed in a vertical hole, between the upper and lower shelves of the plate. The connection of the puff with the bands is carried out by means of an anchor device. (Malganov A.I., Plevkov B.C., Polishchuk A.I. Restoration and strengthening of building structures of emergency and reconstructed buildings (Atlas of diagrams and drawings. Tomsk: Tomsk Interindustry TSNTI, 1990. sheet 61, upper right figure).

The main disadvantage of this reinforcement design is the insufficiently reliable fastening of the puffs to the plate and, consequently, the inability to use this reinforcement under heavy loads and significant efforts in the puff. In addition, since the cord is attached to the upper face of the plate, this reinforcement cannot be used in plates that cannot be accessed from above.

The closest analogue is the reinforcement structure of a reinforced concrete multi-hollow floor slab, including additional reinforcement, which is placed and monolithic in grooves made in the stretched zone of the slab, and connected to the voids of the slab, the additional monolithic reinforcement is equipped with at least two monolithic anchors that are installed in holes made in the locations of the indicated anchors, below the grooves and holes made protrusions connected to the specified grooves and holes (see patent RU №154148, IPC E04G 23/02, publ. 08.20.2015).

Although this reinforcement is possible to use in slabs that cannot be accessed from above, the use of this design leads to a significant increase in the dead weight of the structure (due to the fact that the slab is completely filled with concrete) and the longitudinal reinforcements are overused in comparison with the previous analogue. Its implementation requires large labor costs due to the need to break through the groove along the entire length of the additional reinforcement.

The objective of the invention is to develop a reinforcement structure for a multi-hollow reinforced concrete slab, access to which is not possible from above, and at the same time allows to increase the load-bearing capacity, rigidity and crack resistance of the slab, reduces material consumption and labor costs, and also significantly reduces the weight of the slab after reinforcement.

The essence of the invention lies in the fact that in the reinforcement structure of a reinforced concrete multi-hollow floor slab, including protrusions made below the plane of the lower face of the slab in the zone of voids of the slab, additional reinforcement, which is placed and monolithic in the stretched zone of the slab in the above protrusions, additional monolithic reinforcement is provided at least two monolithic anchors, while the additional monolithic reinforcement has bent ends passing through openings made in the lower ke plate bent ends and placed additional reinforcement plate is hardwired into the void, close to the holes in the hollow slab made of concrete dowel.

The lower edge of the protrusion has a curved shape and is located at a distance not less than a from additional reinforcement, where a is the value of the protective layer of concrete of additional reinforcement.

In the place of bending of the additional reinforcement in the hole at the bent ends, a stop is installed, while the stop width b _{s is} selected from the condition:

где

Where

N is the force acting on the stop;

ψ is the coefficient taken depending on the nature of the load distribution;

R _b is the calculated concrete resistance.

Moreover, b _s ≤h _s , where

h _s is the conditional height of the stop.

The proposed design allows to increase the bearing capacity, rigidity and crack resistance of the reinforced plate more efficiently than the closest analogue, while reducing the dead weight of the plate, material consumption and labor.

The invention is illustrated by drawings, where in FIG. 1 shows a cross-sectional reinforcement structure of a reinforced concrete multi-hollow floor slab, in FIG. 2 is a section along AA, in FIG. 3 - a section along BB.

The reinforcement structure of a reinforced concrete multi-hollow floor slab 1, including protrusions 2 made below the plane of the lower face of the slab in the void zone of the slab 3, additional reinforcement 4, which is placed and monolithic in the stretched zone of the slab in the above protrusions 2, the additional monolithic reinforcement 4 is provided with at least , two monolithic anchors 5, additional monolithic reinforcement 4 has bent ends 6 passing through holes 7 made in the lower shelf of the plate 1, bent ends 6 of additional reinforcement 4 is placed and monolithic in the void of the slab 3, concrete dowels are made near the holes 7 in the void of the slab 3. The lower edge of the protrusion 2 has a curved shape and is located at a distance of at least a from the additional reinforcement 4, where a is the value of the additional protective concrete layer reinforcement (selected in accordance with SP 63.13330.2012 "Concrete and reinforced concrete structures. Basic provisions"). In the place of the bend of the additional reinforcement 4 in the hole 7 at the bent ends 6, a stop 9 is installed, while the stop width bs is selected from the condition:

где

Where

N is the force acting on the stop;

ψ is the coefficient taken depending on the nature of the load distribution (selected according to SP 63.13330.2012 "Concrete and reinforced concrete structures. Basic provisions");

R _b is the calculated concrete resistance.

Moreover, b _s ≤h _s , where

h _s is the conditional height of the stop.

To carry out the reinforcement design, holes 7 connecting with the void 3 are punched from the stretched zone from the side of the stretched zone 1. The keys are concreted 8. Bends are made - the ends 6 of the additional reinforcement 4 are bent, anchors 5 and stops are joined 9. The resulting structure is installed in the design position. The formwork is mounted on the bottom surface of the plate. A hole is left in the formwork for the nozzle of the concrete pump. The nozzle of the concrete pump is installed in the hole left and the protrusion 2 and part of the void 3 are concreted, where the anchors 5 are located. The protrusion 2 can be made by plastering additional reinforcement 4 on a plaster grid.

For example, if it is necessary to strengthen the PC 59-10 slab, manufactured according to the series II 03-02, Al.5 (1957), reinforced with two rods with a diameter of 12 mm and four rods with a diameter of 10 mm of class A-III, concrete class B15. The plate is reinforced with a reinforcing bar with a diameter of 14 mm, class A500. In this case, the force acting on the stop is not more than R _b = 4500 kgf, the calculated concrete resistance is R _b = 85 kgf / cm ² , ψ = 0.75.

Then:

h _s ≥b _s ≥7.13 cm.

Claims (9)

1. The reinforcement design of a reinforced concrete multi-hollow floor slab, including protrusions made below the plane of the lower face of the slab in the zone of the voids of the slab, additional reinforcement that is placed and monolithic in the stretched zone of the slab in the above protrusions, the additional monolithic reinforcement is equipped with at least two monolithic anchors characterized in that the additional monolithic reinforcement has bent ends passing through openings made in the lower shelf of the plate, bent ends additionally tional valve hardwired and placed in a vacuum plate near the holes formed in the vacuum plate concrete dowel. 2. The construction according to claim 1, characterized in that the lower edge of the protrusion has a curved shape and is located at a distance not less than a from additional reinforcement, where a is the value of the protective layer of concrete of additional reinforcement. 3. The construction according to p. 1 and 2, characterized in that at the bend of the additional reinforcement in the hole at the bent ends, a stop is installed, while the stop width b _{s is} selected from the condition:

where N is the force acting on the stop; Ψ - coefficient taken depending on the nature of the load distribution; R _b is the calculated concrete resistance. Moreover, b _s ≤h _s , where h _s is the conditional height of the stop.

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