RU2241808C1 - Reinforced concrete structure - Google Patents

Abstract

FIELD: building units, particularly reinforced concrete panels.

SUBSTANCE: structure has strapping orifices. Inserted in strapping orifices are reinforcement rods performing strapping and having cross-sections calculated by the following expression

where A_s is rod cross-section, cm²; P is designed force applied to reinforcement rod, kgf; ς_ul is designed maximum permissible stress in reinforcement rod, kgf/cm² and δ is designed percent elongation of reinforcement rod, %. Strapping orifices are spaced a distance equal to or exceeding anchoring depth from reinforced concrete structure ends extending perpendicular to reinforcement rods.

EFFECT: reduced metal consumption.

2 cl, 4 dwg

Description

The invention relates to building structures, in particular, to reinforced concrete slabs for various purposes.

Reinforced concrete structures are known, for example, floor panels, in which sling loops are monolithic in the concrete body of the panel (see "Typical structures, products and units of buildings and structures." Series 1.141-1 "Multi-hollow reinforced concrete floor panels. Issue 66." Preliminary stressed panels with round voids 6280, 5980, 5680, 5080 and 4780 mm long, 1790, 1490, 1190 and 990 mm wide reinforced with high-strength reinforcing wire of class Bp-II ". Designed by TsNIIEP" Housing "with the participation of NIIIZhB, approved and entered into action from 04.15.86. Order No. 93 dated 03/18/86, drawing 1.141-1.66.102). Similar sling loops are provided not only with reinforced concrete structures, but, for example, with concrete blocks for basement walls (see GOST 13579-78, p.14).

Reinforced concrete slabs equipped with closed sling loops covering reinforcing elements placed in a reinforced concrete slab (see "Typical building structures, products and units". Series 3.400-7 "Unified mounting loops for lifting precast concrete and reinforced concrete products" were selected as the prototype. 1/87, developed by PI No. 1 and NIIIZhB and approved by the State Construction Committee of the USSR on 01.07.88, protocol dated 03.03.88 No. ACh-9, drafts 3.400-7.1 / 87-SM7, 3.400-7.1 / 87-SM6).

The main disadvantage of the described structures is the significant metal consumption for the device of the sling loops. So, for example, only in one 10-story 40-apartment block section (83 series) the consumption of class A-1 reinforcement for closed sling loops in floor and cover slabs is 1560 kg. For open loops (see the above analogue), the consumption of the same reinforcement is 2420 kg.

An object of the invention is to save metal.

The essence of the invention lies in the fact that the reinforced concrete structure, including the concrete body and the reinforcement placed in it, is provided with sling holes, through each of which a rod of working reinforcement with a cross-sectional area passes

where And _s is the cross-sectional area of the rod of the working reinforcement, for which the sling is made, cm ² ;

P is the calculated force acting on the rod of the working reinforcement, for which the sling is made, kgf;

σ _ul - the calculated maximum allowable stress in the rod of the working reinforcement, for which the sling is performed, kgf / cm ² ;

δ is the calculated allowable relative elongation of the rod of the working reinforcement, for which the sling is made,%;

When this sling holes are placed from the ends of the reinforced concrete structure, perpendicular to the bars of the working reinforcement, at a distance equal to or greater than the length of the anchoring zone.

In addition, the surface of each sling hole is made at an angle to its longitudinal axis equal to or greater than 45 ° C.

The proposed reinforced concrete structure lacks sling loops, which significantly saves metal.

The invention is illustrated by drawings, where in Fig.1 shows a side view of a reinforced concrete structure with a partial section, in Fig.2 is a top view of a reinforced concrete structure, in Fig.3, 4 are embodiments of a sling hole in a reinforced concrete structure.

The reinforced concrete structure includes a concrete body 1, reinforcement 2 placed therein and sling holes 3, through each of which passes the core of the working reinforcement 2, for which the sling is made. The number of sling holes 3 is determined depending on the geometric parameters of the reinforced concrete structure and the conditions of the sling. The configuration of the sling holes 3 is chosen by the manufacturer and can be any: round, oval, rectangular, etc. In order to reduce the wear of the sling cables (not shown in the drawing) of the lifting device by reducing the friction of the edge of the sling holes 3, the surface of each sling hole 3 made at an angle to its longitudinal axis α ≥ 45 °. The dimensions of the sling holes 3 are selected based on the size of the sling element (not shown in the drawing) of the lifting mechanism.

To ensure reliable operation and anchoring of the rods of the working reinforcement 2, for which the sling is made, the sling holes 3 are placed from the ends of the reinforced concrete structure perpendicular to the rods of the working reinforcement 2, at a distance l≥ l _an , where l _an is the length of the anchoring zone, determined empirically or , for example, according to SNiP 2.03.01-84 "Concrete and reinforced concrete structures", paragraph 5.14, formula 186.

The cross-sectional area of the opening of the working reinforcement 2 passing through the sling hole 3 is equal to:

where And _s is the cross-sectional area of the rod of the working reinforcement, for which the sling is made, cm ² ;

P is the calculated force acting on the rod of the working reinforcement, for which the sling is made, kgf;

σ _ul - the calculated maximum allowable stress in the rod of the working reinforcement, for which the sling is performed, kgf / cm ² ;

δ is the calculated allowable relative elongation of the rod of the working reinforcement, for which the sling is made,%;

Moreover, σ _ul ≥ σ _0.02 , where σ _0.02 is the conditional limit of elasticity of the rod of the working reinforcement, determined empirically or according to GOST 12004-81 "Reinforcing steel. Tensile test methods".

The estimated allowable relative elongation of the rod δ of the working reinforcement for which the sling is performed should be within the range of δ _y ≤ δ ≤ δ _s , where δ _s is the value of the relative elongation of the rod of the working reinforcement at break, determined empirically according to, for example, GOST 12004-81 , a

where E _n - the initial modulus of elasticity of the rod of the working reinforcement, determined empirically according to, for example, GOST 12004-81.

Slinging and installation of the proposed reinforced concrete structure is as follows.

The lifting elements of the lifting device, for example, hooks, are inserted into the lifting holes 3 and capture the rods of the working reinforcement 2. After this, the reinforced concrete structure is lifted, transported and laid in the position provided by the project. Then, the sling elements are removed from the sling holes 3, which, after the installation of the reinforced concrete structure is completed, are monolithic (at the installation site) with concrete or mortar.

Claims (2)

1. Reinforced concrete structure, comprising a concrete body and reinforcement placed in it, characterized in that it is equipped with sling holes, through each of which a rod of working reinforcement with a cross-sectional area passes

where And _s is the cross-sectional area of the rod of the working reinforcement, for which the sling is made, cm ² ; P is the calculated force acting on the rod of the working armature, for which the sling is made, kgf;

- the calculated maximum allowable voltage in the rod of the working reinforcement, for which the sling is performed, kgf / cm ² ;

- the estimated allowable relative elongation of the rod of the working reinforcement, for which the sling is made,%; while the sling holes are placed from the ends of the reinforced concrete structure perpendicular to the bars of the working reinforcement at a distance equal to or greater than the length of the anchoring zone. 2. The reinforced concrete structure according to claim 1, characterized in that the surfaces of each sling hole are made at an angle to its longitudinal axis equal to or greater than 45 °.

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