RU2600227C1 - Multi-cavity concrete slab with high anchor - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to production of building structures, specifically to production of hollow core reinforced concrete slabs by bench non-shutter forming. In body of slab 1 there are cavities 4, and prestressed effective reinforcements 2 and 3 located near lower face and upper face of body 1 of slab respectively. Cavities 4 and effective reinforcements 2 and 3 are oriented along flight of body 1 of slab. External surfaces of effective reinforcement 2 and 3 in support sections 5 of body 1 of slab are attached to it by closed external elements, made of flexible metal plates 6 and 7 in form of bands, and are shifted relative to each other in opposite directions, and at end of their connection are fixed overlapping each other. Plates 6 and 7 are rigidly connected with effective reinforcements 2 and 3 by welding and are placed in body of fibre concrete 8. Middle part of slab body 1 with effective reinforcements 2 and 3 is additionally equipped with framed reinforcement made of ribbed high-strength wire 10 and 11 in form of closed sinusoid in plan view, there are also at least two elements, which are shifted relative to each other in opposite directions, rigidly coupled with effective reinforcements 2 and 3 by welding and arranged in body of steel fibre concrete 12. Vibration moulding of all sections in said slab is performed simultaneously.

EFFECT: technical result is providing carrying capacity of slab with broader technological capabilities of manufacture, specifically possibility of continuous moulding, high crack resistance at erection.

1 cl, 2 dwg

Description

The invention relates to the production of building structures, namely the production of multi-hollow reinforced concrete floor slabs by the method of bench formless formation.

A multi-hollow building slab is known, comprising a reinforcing cage with longitudinal working and transverse reinforcement, longitudinal vertical hollow elements, mounting loops and monolithic concrete, the longitudinal vertical frame elements are made in the form of loop clamps welded to the longitudinal working reinforcement in the supporting sections of the plate, while the longitudinal working reinforcement equipped with clamps made in the form of hinges welded to it with a step equal to 0.2-0.5 lengths of the plate (patent RU No. 2161230, E04C 2/06, E04C 5/06 from 12/27/2000).

The disadvantage of this constructive solution is that the supporting sections of the plates are anchored with reinforcement from many loops and the presence of a trough-like mesh in them, this leads to a heavier weight of the plate and an overestimation of material consumption due to the irrational placement of the use of the trough-like mesh. Another disadvantage is that with a long span, the weight of the plate increases sharply, and sawing plates of any length at the request of the customer complicates the planning tasks when deciding to create the other end in the form of a support section of the body of the plate, which leads to an increase in crack resistance of the product. This can be especially noticeable on the formation of cracks in the slab concrete with uneven loads on the slab; uneven rise of the plate, partial support on the linings, dynamic effects during transportation, etc., i.e. the stress in concrete exceeds the tensile strength of concrete, and with such stresses cracks form in the upper part of the shelf, in the rib, the lower part of the shelf of the plate. Thus, it is necessary to find new options for reinforcing designs with the coordination of modern concrete laying technologies (for example, technological equipment of the Spanish company Tekhnospan, a line that operates at the concrete products factory, Ryazan; the plant can produce BOF formless slabs of different lengths within 12 m with the production line, the width of the plates: 1; 1.2; 1.5 m with a bearing capacity of 300-1600 kg / cm ³ .

A multi-hollow prestressed expanded clay concrete slab with increased anchoring is known, in which the middle part of the concrete body of the slab is made of expanded clay concrete. Inside the concrete body there are voids oriented along the body of the slab. The supporting sections of the slab are made of heavy concrete and are anchors for reinforcement made of high-strength prestressed wire installed in the body of the slab. The middle part is made of expanded clay concrete. The length of the supporting sections is selected from condition 186 SNiP 2.03.01.-84 * "Concrete and reinforced concrete structures" (PM, patent RU No. 115379, IPC, EV 5/02 dated 10/13/2011).

However, the use of two types of concrete: lightweight (expanded clay concrete) and heavy concrete are anchors for reinforcement made of high-strength prestressed wire installed in the body of the slab only for supporting sections, although it is selected from condition 186 SNiP 2.03.01-84 * Concrete and reinforced concrete structure ”, has, under certain operating conditions, low bending strength and compressive strength for floor slabs of large length, which should correspond to standardized and calculated values, and Such plates should not be inferior to structures with integral prestressed reinforcement in the form of a mesh along the entire length of the plate body. Another disadvantage is that the body of the plate is limited by the release of the flow line of the formless formation plates of large length, i.e. more than 6 m with a large bearing capacity. Proceeding from this, there is a large rejection of them when cutting the slab, especially at different angles, which is associated with the sawing of slabs of any possible length according to the customer’s request for the consolidated design of the building space when creating complex planning decisions, and this in turn significantly increases the construction time and costs construction work. Thus, the known technical solution does not allow to expand the production technology for the manufacture of such plates during the commissioning of the technological production line for the production of reinforced concrete products using a non-formwork method with high productivity and to satisfy the buyer’s need for plant products even during periods of most active demand when sawing plates is necessary. including at any angle in the construction of facilities.

The closest design to the proposed one is a multi-hollow expanded clay concrete slab with increased anchor reinforcement containing the body of the slab, in which internal voids are made oriented along it, and the working reinforcement of high-tensile prestressed wire, supporting sections of the slab body are made of expanded clay with the addition of metal fiber or fiber from composite materials, while the length of the supporting sections is determined by the calculation formula, taking into account the expanded ability of expanded clay concrete with fiber (patent PM "No. 133548, E04B 5/02 of 05/14/2013).

However, the body of the floor slab is limited by the release of the production line of large formwork formless slabs, i.e. no more than 6 m with a big bearing ability. Another disadvantage is that the quality of the plates decreases, they are discarded when sawing the slab, especially at different angles, which is associated with sawing slabs of any possible length at the request of the customer for the free design of the building space when creating complex planning decisions, and this in turn is significantly increases the construction time and construction costs. Thus, the known technical solution does not allow to expand the production technology for the manufacture of such plates during the commissioning of the production line for the production of reinforced concrete products using a non-formwork method with high productivity and to satisfy the buyer’s need for plant products even during periods of most active demand when sawing plates is a necessity. including at any angle in the construction of the facility. This results in low bending strength and low compressive strength, as well as low impact resistance.

The technical problem is to expand the technological capabilities of production through the use of waste non-dimensional sections of the rods and increase the crack resistance of the floor slab.

The technical problem is solved in such a way that a multi-hollow fiber-reinforced concrete floor slab with increased anchoring, containing the body of the slab, in which the internal voids are oriented along it, and the working reinforcement of the strained wire, the longitudinal reinforcement on top of the frame in the supporting sections of the body of the slab is made of bordering closed elements, made of flexible metal plates in the form of tapes, the ends of which are overlapped to each other, and at least two with an offset of one relative to the other, placed in barely fiber-reinforced concrete and each rigidly connected to the working reinforcement, while the working reinforcement in the middle part of the plate is made of a reinforced element in the form of a ribbed high-strength wire in the form of a closed sinusoid in plan and at least two elements with an offset of one relative to the other, placed in the body of steel fiber reinforced concrete and rigidly connected with working fittings by welding.

The essence of the invention lies in the fact that the design of a multi-hollow fiber-reinforced concrete floor slab with increased anchoring and with longitudinal working reinforcement allows to reduce optimally simpler means using available materials, significantly expand the range of products and saw a flow plate (of any length), at the request of the customer, including and at an angle, with the possibility of implementing complex planning decisions. Since the working reinforcement in the body of the plate has only longitudinally strained wire along the entire length of the plate, it is taken into account only when calculating the stiffness and crack resistance, and they are not taken into account in terms of strength, if necessary, increase the strength, according to the proposed solution, the supporting sections with working reinforcement are made of bordering closed elements made of flexible metal strips in the form of tapes overlapping each other with a displacement of one relative to another, placed in the body of fiber-reinforced concrete and rigidly connected with working reinforcement oh, while the middle part of the plate with the working reinforcement is made of a reinforced element in the form of a ribbed high-strength wire in the form of a closed sinusoid placed in the body of steel fiber concrete and rigidly connected to the working reinforcement by welding, and also increase the reliability of fixing the reinforcement in places that can withstand large loads in the slab. All this represents a single whole with cast concrete, which increases the strength of the plate even with the possibility of cutting it of any length and at an angle. The proposed design does not have distortions and deformations, and the supporting sections of the plate body reduce crack resistance from impacts, etc., i.e. no cracking. Therefore, increases the strength of the plate.

The analysis of the prior art, including a search by patent and scientific and technical sources of information, and the identification of sources containing information about analogues of the claimed invention, allow us to establish that the applicant has not found technical solutions characterized by features identical to all the essential features of the claimed invention. The definition from the list of identified analogues of the prototype made it possible to identify a set of essential (with respect to the technical result perceived by the applicant) distinctive features in the claimed object set forth in the claims.

Therefore, the claimed invention meets the requirement of "novelty" under the current law.

Information about the fame of the distinguishing features in the totality of the characteristics of the known technical solutions with the achievement of the same as the claimed device, there is no positive effect. Based on this, it was concluded that the proposed technical solution meets the criterion of "inventive step".

In FIG. 1 shows a general view of a multi-hollow fiber-reinforced concrete floor slab with increased anchoring; in FIG. Figure 2 shows a top view of the isopole of stresses when resting on the gaskets (warehousing) of the plate, the self-weight load of eight plates.

Multi-hollow fiber-reinforced concrete floor slab with increased anchoring contains the body of 1 slab. Prestressed working fittings 2 and 3. The voids 4 can be round, oval or other shape. The external surfaces of the working reinforcement 2 and 3 in the supporting sections 5 of the body 1 of the plate are formed by closed external elements fixed to them, made of fringing flexible metal plates 6 and 7 in the form of tapes, with a displacement of one relative to another, at the end of which are overlapped, rigidly connected with working reinforcement 2 and 3 by welding and placed in the body of fiber concrete 8.

In the middle part 9 of the body 1, the slabs to the working reinforcement 2 and 3 are additionally equipped with a frame of reinforcement made of high-strength ribbed wire 10 and 11 in the form of a closed sinusoid in terms of at least two elements, offset one relative to the other, placed in the body of reinforced concrete 12 and rigidly associated with working fittings by welding. At the same time, vibroforming of the entire length of the slab is carried out at the same time, this provides increased resistance and the absence of cracking from the condition of reliable anchoring of prestressed working reinforcement as a whole of the body parts of the slab, both in design and in conjunction with concrete laying technology. Plates are formed using a combine on a thermostat.

The use in the middle part of the body of a plate of ribbed high-strength wire 10 and 11 placed in steel fiber reinforced concrete provides increased strength and fracture stiffness, and increased strength of supporting sections 5, bordering metal plates 6 and 7 placed in fiber concrete, increases their strength, stiffness and crack resistance, in addition, increase the reliability of fixation of the working reinforcement in the most arising places at high loads of the floor slab. The physico-mechanical parameters of the fiber-reinforced concrete of the supporting sections of the slabs (with and without water activation) correspond to GOST.

Structurally known and the proposed slabs differ, according to their length, in such a way that the fringed flexible metal plates in the form of ribbons and ribbed high-strength wire are placed in the body of fiber-reinforced concrete, respectively, the length of its minimum linear size with respect to the length of the slab. With this approach to the formation of the cross-sectional diagram of the proposed plate, there is no need to calculate its elements, since the calculations will be identical to the results of the calculation of all elements of the prototype plate. In this regard, the main task of the designer is the rational choice of a flexible metal plate and ribbed high-strength reinforcement. After hardening, sawing is carried out at the ends of the body of the plates. The length of the supporting sections and the middle part of the body of the slabs made of fiber-reinforced concrete with the proposed structural elements is not more than 0.2 L _pl with the offset of the proposed elements from each other to achieve the required level of strength and reduce the deformability of the metal in the zone of possible crack of the supporting sections and deflection of the middle part floor slabs. All parameters of the proposed elements are determined experimentally on a test bench, the strength, stiffness and crack resistance of which must correspond to the standardized and calculated values. In terms of strength, such structures are equally strong structures with integral prestressed reinforcement in the form of a mesh along the entire length of the bodies of the plate.

The thermostat (not shown) is a concrete field 90 m long. The product fully complies with GOST 9561-91 “Multi-hollow reinforced concrete floor slabs for buildings and structures. Technological conditions. "

The well-known technological line of the company Tekhnospan Reinforced Concrete Products, Ryazan, is a field with a sheet metal coating (not shown in the drawing for simplicity), and it is here that the concrete mixture is supplied. The entire area of continuous formation is divided into seven tracks with a given width with rails along which the equipment needed in the process moves. The production is equipped with a heating system. In production, reinforcement is performed by high-strength wire. Anchors or stops provide wire fastening. However, the production of existing floor slabs also showed that the defects that occur during the manufacture and delivery of them to the object can be divided into two groups: formation defects and mechanical defects. These types of defects are the result of many reasons caused by the technological parameters of the formation of plates. Particularly noteworthy are mechanical defects that occur after cutting the plates and transporting them to the storage location and causing cracks in the upper and lower zones of the plate passing through the reinforcement; the length of the cracks was 55 cm from the edge of the plate and was at a distance of 430 ... 480 mm, which is unacceptable for the construction of buildings. Production can easily be reoriented to the production of another type of product, for example, the present invention. Of particular note is the dynamic dynamic effects on the slab, starting from storage, transportation and lifting of the slab, which is also associated with the uneven distribution of the load from the weight of the stacking slabs on top of the lower slabs. The concrete composition is used brand M-400.

Compared with the prototype, the solidity of the body of the entire plate is achieved with its optimal weight by simpler means using available materials that eliminate crack resistance not only along the lengths of the supporting sections, but also in the middle part of the plate of any length at the request of the customer, including at a shear angle, which is an opportunity for the free design of the internal space of buildings, the embodiment of complex planning decisions.

Since longitudinal working reinforcement is laid in the body of the slab, the design with the proposed elements placed in the body of fiber-reinforced concrete for each of its sections of the slab and its composition of fiber-reinforced concrete expands the technological capabilities of the bench formwork formation. The concrete class used for multi-hollow prestressed floor slabs together with the addition of flexible metal plates in the form of ring-shaped tapes connected at the end to overlap and connected to the working reinforcement by welding, as well as ribbed high-strength wire in the form of a sinusoid in the middle part of the floor slab and placed in the body of fiber-reinforced concrete, provide in the aggregate the bearing capacity of the structure, which can be reliably sawed to a given length and at an angle or with a load capacity 300-1600 kg / m ³ and for longer spans BOP plates, and this reduces the number of supports, creating a free layout space. Given that a large consumption of concrete is spent on one slab up to 12 m long, the total volume of concrete can achieve concrete savings of up to 40% in the proposed slab. The lower weight of the BOF boards allows saving on construction and foundation elements, reduces the cost of delivering products to the construction site.

Thus, the technical result of the claimed invention is achieved due to the rational choice of the forms of available metal elements and fiber concrete aggregate with fixed working reinforcement in different areas in the plate body.

Claims (1)

A multi-hollow fiber-reinforced concrete floor slab with increased anchoring, containing the body of the slab, in which the internal voids are oriented along it, and the working reinforcement of the strained wire, characterized in that the longitudinal reinforcement on top of the frame in the supporting sections of the slab body is made of bordering closed elements made of flexible metal plates in the form of at least two tapes, the ends of which overlap with each other, with a displacement of one relative to the other, placed in the body of fiber concrete and rigidly each knitted with working reinforcement, while the working reinforcement in the middle part of the plate is made of a reinforced element in the form of a ribbed high-strength wire in the form of a closed sinusoid in plan, at least two elements are made with an offset of one relative to the other, placed in the body of steel fiber concrete and rigidly connected to the working reinforcement by welding.

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