LT5685B - Beam and it's production method - Google Patents

Abstract

The present invention relates essentially to the construction industry, specifically to the production of the reinforced concrete beam of increased load-carrying capacity and enhanced resistance to the impact of various external factors. The frame of the beam, which consists of frame, reinforcement and concrete, is built out of stay-in-place metal formworks and internal stiffening metal strips. The external metal formworks may be the stay-in-place metal formworks or the external metal formworksmay be the removable metal formworks. For the production of the beam, formworks and stiffening metal strips are used. For the production of the frame, removable and/or stay-in-place external metal formworks and internal stiffening strips are assembled, the reinforcement is embedded, concrete mix is poured, and, after concrete has cured to a required strength, the removable metal formworks are stripped, and the stay-in-place external metal formworks and internal stiffening strips are left in place.

Description

The invention relates to the construction industry, in particular to the production of reinforced concrete with increased load-bearing capacity and resistance to various external influences.

It uses reinforcement and concrete to produce well-known reinforced concrete beams. Known reinforced concrete beams use wooden formwork or molds of various materials to mold them (SU1765327,1990-11-12).

When the beam is a complex form, the disadvantage of the classic reinforced concrete beam method is that it takes a long time to form the formwork, and the standard molds are usually straight molds, which results in high labor costs. Wood formwork is used to achieve a sleek and sleek beam shape, making a correct shape virtually impossible (very high material and labor costs). When making wooden beams using space formwork, the outer part of the beam is more or less angular and loses its correct geometric shape. The load-bearing capacity of known reinforced concrete beams has two components: concrete and reinforcement. As a result, bulky beams have a very large cross-section and a high specific gravity. When the cross-section and length of the beam are very large, the structure is very heavy and visually very large. Such a beam loses its gracefulness and carries heavy loads to the base. Known standard, classic reinforced concrete beams generally have straight elements and, depending on the load and length of the beam, have a large cross-section. When classical reinforced concrete beams are used for the production of elements protruding from the building (balconies, terraces, protruding parts of the building and other similar purposes), the biggest disadvantage of them depending on the length of the protruding part is its large cross-section and heavy weight.

It is an object of the invention to provide a beam having a higher load-bearing capacity, a smaller cross-section, and protection against any external influence, in any shape. Produce a beam with cheap materials and low labor costs. Shorten the production and installation process. Reduce the cross-section of the beam and the weight of its own construction. Produce lightweight, sleek, sleek and regular beam geometry and spatiality at low labor cost. Increase the load-bearing capacity of the beam without increasing its cross-sectional and structural weight.

Customized beam construction for any application: supporting beams, lintels, support beams, balconies protruding from the building, staircases, stairways and other elements. Operate the beam in any difficult and aggressive operating conditions. Protect the beam from weathering, heat or cold, fire, chemical, earthquake, external physical and shock effects. Achieve maximum beam durability during operation.

The essence of the invention is that the beams consisting of a frame, reinforcement and concrete, the frame consists of outer metal formwork and inner metal stiffeners. The outer metal formwork may be a permanent metal formwork or the outer metal formwork may be a removable metal formwork.

The beams use formwork and metal stiffeners for their production. For the production of the frame, removable and / or removable outer metal formwork and inner stiffeners are added, reinforced, filled with concrete mixture, the concrete hardens to the required strength, removable metal formwork removable, leaving the remainder of the outer metal formwork and internal stiffeners.

The following are examples of beam construction which are described in the drawings, in which

FIG. 1 (a-b) - a beam with a frame consisting of remnant metal formwork: a) - cross section; b) - longitudinal section A;

FIG. l (c-d) - beam with frame made of removable metal formwork and inner metal stiffeners:

(c) - cross-section; d) - longitudinal section B;

FIG. 1 (e-f) - beam with frame made of residual metal formwork and inner metal stiffeners:

(e) - cross-section; f) - longitudinal section C;

FIG. 2 (a-b) - a beam having a frame made of residual metal formwork: a) - cross section; b) - longitudinal section A;

FIG. 2 (c-d) - beam with frame made of removable metal formwork and inner metal stiffeners:

(c) - cross-section; d) - longitudinal section B;

FIG. 2 (e-f) - beam with frame consisting of remnant metal formwork and inner metal stiffeners:

(e) - cross-section; f) - longitudinal section C;

FIG. 3 (a-b) - beam having a frame made of residual metal formwork: (a) - cross-section; b) - longitudinal section A;

FIG. 3 (c-d) - beam with removable metal decking and inner metal stiffeners:

(c) - cross-section; d) - longitudinal section B;

FIG. 3 (e-f) - a beam with a frame consisting of remnant metal decking and inner metal stiffeners:

(e) - cross-section; f) - longitudinal section C;

FIG. 4 (a-c) - Several of the many possible shapes of beams are given: a) - elliptical in plane; b) - arch in the plane; c) - curved in space;

FIG. 1 - FIG. Figure 3 (a-b) shows beams with a frame made of residual metal formwork. Only remnant metal formwork is produced and installed in this structure. In the manufacture of this type of beam by the installation of formwork (1), according to the purpose, length and cross-section of the beam structure Fig. 1 - FIG. 3 (a), (c), (e) and other effects, reinforcement (3) or metal bars (3) of appropriate geometrical characteristics and class shall be installed. After laying the formwork (1) and reinforcement (3), the structure is filled with concrete of appropriate density, structure and class, if necessary, and of the environmental class (2). The load-bearing capacity of this beam depends on the residual metal formwork (1), reinforcement (3) and concrete (2) of the three load-bearing components. The advantage of this type of construction is that, without increasing the cross-section of the beam and its own weight, depending on the thickness of the residual metal formwork (1) used, a sufficiently high load-bearing capacity is achieved. At low cost of material and labor, any lightweight beam is obtained in Figs. 4 (a-c) and, if necessary, a light, graceful spatial shape of Fig. 4c. This type of structure is much more resistant than the classical reinforced concrete structure to physical impacts (impact, vibration, earthquake, etc.). The beam of this construction, with metal residual formwork of appropriate thickness and type of metal, additionally covered with fire-retardant materials and plaster-coated, is highly fire-resistant, since the beam reinforcement and concrete are protected from open flame by sheet metal, in this case residual metal plaster, fire-retardant .

FIG. 1 - Fig. 3 (cd) illustrate beams having a frame made of removable metal formwork with internal stiffening metal strips. In this construction, manufactures and installs permanent metal formwork and internal rigid metal strips. Fabrication and installation of this type of construction beams compared to Figs. 1 - FIG. Type 3 (ab) beams are more complex. The production of this type is fitted to the formwork girder (1) is mounted internal stiffening metal strips (L ¹⁾ based on the beam purpose, length and cross-section Fig. 1 - FIG. 3 (a), (c), (e) and installs reinforcement (3) or metal bars (3) of appropriate geometrical characteristics and class. Mounting barns (1) of the web-strips (l ¹⁾ and the valve (3) is poured on the design of appropriate density, structure and class where necessary and exposure class concrete (2). FIG. 1 - FIG. For the manufacture of type 3 (cd) beams, metal formwork (1) is used only to obtain the form of the beam, thin and of low geometrical characteristics and low grade, because when the concrete (2) is completely hardened, the metal formwork (1) is removed from the beam. The curing time of the concrete mix (2) of the beam depends on the density, structure and grade of the concrete (2). FIG. 1 - FIG. The load-bearing capacity of the structure 3 (cd) beams is the same as that of Figs. L - Fig.3 (ab) beams from the three components of the load-bearing capacity: internal metal stiffeners (l ¹ ), reinforcement (3) and concrete (2). . The construction of this beam is more complicated than that of Figs. 1 - FIG. 3 (ab) beams due to the manufacture, installation and internal stiffening of metal bands (l ¹ ) and the removal of the beams (1) after the concrete (2) has hardened. For the beam shape of FIG. 4 (ab) obtain the same possibilities as in Figs. 1 - FIG. 3 (ab) or FIG. 1 - FIG. 3 (ef) (bulky, graceful, light spatial shape). The metal formwork (1) is removed from the beam when exposed to direct atmospheric conditions (rain, sun, cold, etc. atmospheric effects) The sheet metal (1) in this case is exposed to corrosion so that the formwork does not have to be made of precious metal or protected from expensive corrosion. materials, removes the formwork (1) and leaves only metal bands of internal stiffness due to the load-bearing capacity (l ¹ ) · However, if the beam requires special strength using weatherproof formwork (1), such as stainless steel formwork of appropriate geometry and grade ( 1) leaves the formwork (1). By leaving the stainless steel formwork (1), the structure becomes, FIG. 1 - FIG. 3 (ef).

FIG. 1 - FIG. Fig. 3 (ef) depicts beams with a frame made of residual metal formwork with internal stiffening metal strips. In this construction, manufactures and installs permanent metal formwork and internal rigid metal strips. Fabrication and installation of this type of construction beams compared to Figs. 1 - FIG. The beams of type 3 (cd) are simpler since the metal formwork (1) does not have to be removed, but more complicated than the construction of the beams of Fig. 3 (ab) because they have to be manufactured and installed as in Figs. 1 - FIG. 3 (cd) type beams internal stiffeners (l ¹ ). However, FIG. 1 - FIG. 3 (ef) type construction beams outside FIG. 1 - FIG. Type 3 (ab) and (cd) beams have significantly higher load-bearing capacities. In the manufacture of FIG. 1 - FIG. When installing formwork 3 (ef) beams (1), install metal strips of internal stiffness (l ¹ ). With regard to the purpose, length and cross-section of the beam structure, FIG. 1 - FIG. 3 (a), (c), (e), loads and other effects, installs reinforcement (3) or metal rods (3) of appropriate geometrical characteristics and class. When the metal formwork (1), the metal stiffeners (l ¹ ) and the beam reinforcement (3) or the metal bars (3) are installed, the structure is filled with concrete of appropriate density, structure and class, if necessary also from the environmental class. I - FIG. 3 (ef) type beams, in contrast to FIG. I - FIG. 3 (cd), the formwork (l) of this construction is of a residual nature and is not only used in the form of the beam. 4 (ac) receive but also holding! power, and protection against various external influences to perform the function. Depending on the purpose of the beam and its effects, the metal formwork (l) shall be made of sheet metal of appropriate thickness and geometrical composition and class. FIG. I - FIG. The load-bearing capacity of a beam type 3 (ef) depends on four load-bearing components: residual formwork (l), metal stiffeners (l ¹ ), reinforcement (3) and concrete (2). The construction of this beam is more complicated than that of Figs. I - FIG. 3 (ab), because of the manufacture and installation of an internal stiffness metal strip (l ¹ ), but simpler depending on the cross-section of the beam. 1 - FIG. 3 (a), (c), (e) for Figs. 1 - FIG. Type 3 (cd) beams because there is no need to remove the metal formwork (1). To obtain the shape of the beam Fig. 4 (ac) same as Figs. 1 - FIG. 3 (ab) or (cd) type (bulky, sleek and light in any shape). If the beam of this structure is used outdoors under direct weathering (rain, sun, cold, etc. atmospheric effects), the metal sheet (1) in this case is exposed to corrosion. When FIG. 1 - FIG. 3 (ef) type structure is affected by direct atmospheric action and design requirements small cross-section. 2 (e) light weight of its own construction, for the production of formwork (1) using weather-resistant metal sheets of the appropriate geometric structure and class, in this case formwork (1), for example: stainless steel. Compared to the manufacturing method of FIG. 1, FIG. 3 (cd) type structure, without direct atmospheric action and without the need to use stainless steel formwork (1), Figs. 1 - FIG. 3 (ef) type beam is cheaper and more customizable for use than FIG. 1 - FIG. 3 (cd) beam, because metal formwork (1) does not need to be removed. This form of construction of Figs. 4 (ac) is obtained in a light, graceful and, if necessary, spatial arrangement of FIG. 4 (c) as easily as Figs. 1 - FIG. 3 (ab) or (cd) type. The use of appropriate materials in the manufacture of this type of beam is as resistant as in FIGS. 1 - FIG. 3 type (ab) or (cd) for direct atmospheric, chemical and fire effects. FIG.

- FIG. Type 3 (e-f) construction is extremely resistant to physical impacts (shocks, vibrations, earthquakes, etc.).

Beams. metal formwork can be made of sheet metal and in the workshop and on the construction site where it will be installed. Because the metal sheet is easy to roll, the formwork produces low-cost, streamlined geometry and spacious formwork at low cost. If the beam manufactured is of complex or spatial shape, metal formwork can be produced both in the workshop and on site, but if the beam is bulky, the beam is mounted on the site. The technology for installing metal formwork is very simple (the slip principle). Each formwork part shall be numbered consecutively from 1 to n numbers during manufacture and only the numbering sequence shall be followed during installation. When installing internal stiffeners, metal strips and metal formwork are close to one another and join to each other, depending on the shape of the beam, by dots, continuous seams or other welding or joining. The principle of beam installation is not declared - installation can be done taking into account the favorable situation for installation from 1-n or n-1. Depending on the cross-sectional composition of the structure, the metal formwork is used to install metal stiffeners, reinforcement or metal bars, and finally the structure is filled with concrete of appropriate density, structure and class, if necessary. If the beam produced is straightforward (straight, curved in plane) but bulky, then the metal formwork and, if necessary, the internal metal stiffeners and beam reinforcement are produced in the workshop, but to avoid the heavy labor costs of transporting the beam, the concrete mixture is filled. If the beam is independent of shape and size, the beam can be fully fabricated in the workshop. In this case, the metal formwork optionally finishes the beam as needed. Depending on the technology, concrete is bonded with metal binding agents, putty or plaster with a simple construction putty or plaster, and painted with ordinary (wall or ceiling) paint, or putty with metal putty and paint for metal painting. The beam can also be covered with building finishes (drywall, decorative wood panels and other materials), taking into account the external influences acting on the beam. After removing the metal formwork from the beam, the beam shall be filled or plastered with building mortar or plaster and painted with appropriate paint according to the conditions of use. If the structure has high fire resistance requirements, the beams are covered with special fire-resistant materials for additional fire protection and then trimmed if necessary.

The new beam structure is superior to the classical reinforced concrete beam structure in that the load-bearing capacity is significantly increased without increasing the beam cross-section and its own weight, depending on the thickness of the residual formwork and the internal metal stiffness bars 7. At low cost of materials and labor, any lightweight shape is obtained and, when needed, a lightweight, grid-shaped beam. The new construction of the beam is more resistant to chemical and fire effects and more resistant to physical effects (shocks, vibrations, earthquakes, etc.).

Claims (3)

DEFINITION OF INVENTION 1. A beam consisting of a frame, reinforcement and concrete, characterized in that the frame 5 consists of outer metal decking and inner metal stiffeners. 2. A beam as claimed in claim 1, wherein the outer metal formwork is a residual metal formwork. 3. A beam according to claim 1, characterized in that the outer metal formwork is removable metal formwork. 10 4. The method of manufacturing the beam using formwork, which consists of installing removable and / or removable outer metal formwork and inner stiffeners to produce the frame, filling the reinforcement with a concrete mix, removing the removable metal formwork once the concrete has hardened. outer metal decking and inner stiffening strips.