RU8715U1 - BRICK WALL ACCESS JUMPER - Google Patents

Abstract

The jumper of the wall opening of a brick building, including a reinforced concrete core, placed in a ceramic shell consisting of separate ceramic elements, characterized in that the ceramic shell is made in the form of a longitudinal row of identical ceramic elements joined by their end faces and interconnected by metal rods, each the ceramic shell element is made in the form of a parallelepiped with dimensions equal to the dimensions of the brick, has a central through longitudinal cavity, a longitudinal groove connected to it, made on the upper face of the parallelepiped along its entire length, and longitudinal through holes for pairing metal rods pairwise arranged relative to the symmetry axis of the element, and the reinforced concrete core is made in the form of a concrete cavity filler formed by combined central through cavities and longitudinal grooves of the joined ceramic shell elements.

Description

Jumper of a wall opening of a brick building

The proposed utility model relates to construction, namely, to long-length bearing bridges of the wall openings of buildings and can be used in industrial, civil and individual construction as a window or door lintel in the walls of brick buildings.

Known reinforced concrete lintel of the wall opening in the bearing walls of a brick building in the form of prefabricated reinforced concrete bars or beams with a cross section equal to or a multiple of the cross section of the brick, taking into account the mortar seam, based on the walls at least 120 mm / 1 /.

This reinforced concrete lintel from prefabricated reinforced concrete bars (with an opening width of less than 2.5 m) or from beams (with a width of more than 2.5 m) perceives the load of overlying brickwork and floors and provides the required bearing capacity, which prevents any subsidence of it over the opening.

However, such a reinforced concrete lintel, due to its high heat-conducting properties, is a cold bridge in the wall structures of masonry, which leads to a decrease in the thermal insulation properties of the building.

Also known is the ordinary jumper for the wall openings of a brick building, which consists of several rows of bricks and reinforcement in the form of steel flat or round rods, laying CL.MKI: - E04.C З / О; EB04 2/02

bricks on the bottom row (3-4 cm thick), and the ends of the 5 rods are simple: {and no less than 250 mm silt, BB ° -I - passed through vertical joints for anchoring / 2 /.

The specified jumper provides the required bearing capacity for wall openings with a width of 2m or less.

The disadvantage of an ordinary lintel is that such a lintel, on which beams or floor slabs above the openings rest, must have at least five rows of continuous brickwork laid on a cement-sand mortar to prevent it from sagging over the opening.

In addition, with an opening width of more than two meters or with heavy loads, this jumper will require additional reinforcements, for example, with a frame of steel rods embedded in vertical longitudinal masonry joints. All this leads to a complication and increase in the time of its installation and the material of the reinforcement, which narrows its operational capabilities.

Known arched window lintel in the form of an arch-shaped element made of formed by a diametric or chord cut part of a car tire attached to its tread by bolt connections of sector segments obtained by radial cuts of a car tire and concrete filling / 3 /.

However, this arch lintel for the window openings of the building, despite the scarcity of its material, due to the insufficient strength and rigidity of its structure, can only be used in the construction of light building structures, for example, homestead houses and similar structures, which also significantly reduces its functionality.

Also known for the structural embodiment and the achieved technical result to the claimed utility model is a facade lintel lined with ceramic elements, containing a reinforced concrete plaster with a reinforcing cage and piece

ceramic elements with dimensions that are multiples of the dimensions of the brick, placed with gaps on the core and provided with longitudinal dowels located on the inner side of the base and side walls / 4 /.

The well-known facade lintel of the wall opening of a brick building, due to the presence of a reinforced concrete core reinforced with a reinforcing cage, has a sufficiently high bearing capacity.

However, on the other hand, the introduction of a reinforcing cage into a reinforced concrete core, which in itself is a cold bridge, reduces the thermal insulation properties of the bridge. In this case, the presence of a ceramic shell of a reinforced concrete core formed by facing ceramic elements does not reduce this problem, since, basically, it carries a decorative load. In addition, the supply of reinforced concrete core with ceramic cladding elements and their implementation does not provide sufficient adhesion to the core, which reduces the reliability of the structure as a whole.

The technical result of the proposed utility model is to increase the performance of the lintel of the wall opening of a brick building by improving its heat-insulating properties and increasing the reliability of operation, as well as expanding its technological capabilities.

The technical result is achieved by the fact that in the lintel of the wall opening of a brick building, including a reinforced concrete core, housed in a ceramic shell consisting of separate ceramic elements, according to a utility model, the ceramic shell is made in the form of a longitudinal row of identical ceramic elements joined by their tor-face faces and interconnected by metal rods, with each ceramic shell element made in the form of a parallelepiped with dimensions equal to the dimensions of a brick, has a central through longitudinal cavity, a longitudinal groove connected to it, made on the top face of the parallelepiped along its entire length, and longitudinal through holes for passing metal rods pairwise arranged relative to the axis of symmetry of the element, and the reinforced concrete core is made in the form of a concrete core filler formed by combined central through cavities and longitudinal grooves of joined ceramic shell elements.

The specified implementation of the ceramic shell of the core provides a higher bearing capacity and strength compared to the prototype. In addition, the placement of the concrete core in such a ceramic shell in the form of its filler will increase the thermal insulation properties of the bridge due to the presence of a large proportion of ceramics in it and the absence of reinforcement in the core compared to the prototype.

The execution of individual ceramic shell elements of identical shape allows you to unify the building elements that make up the jumper, to get a kind of modular element, easy to manufacture and install with wide technological capabilities. At the same time, the presence of a through cavity and a groove in the ceramic elements ensures easy filling of the core material with the simultaneous compression and compaction of the core concrete, which increases its crack resistance and strength, and, consequently, the reliability of the bridge in operation. The presence of metal rods, which are simultaneously reinforcement for the bridge and connecting ceramic elements, helps to increase the strength of the connection between each other and increase the reliability of the bridge in comparison with the prototype.

Thus, a comparative analysis of the proposed utility model showed that it differs from the prototype by the above features and meets the criterion of novelty.

The use of this utility model in the field of industrial, civil and individual construction as window, door and other lintels of wall openings of the Kirillich Adany makes it possible to conclude that it meets the criterion of industrial applicability.

The proposed jumper is shown in the drawing, where FIGL shows a General view of the jumper with a reinforced concrete core in a ceramic shell (in plan); in FIG. 2 - the same section along AA;

in FIG. 3 is a general view of a hollow ceramic element (in a perspective view); in FIG. 4 - the process of assembling a ceramic shell from ceramic

Elements of the proposed ons structure (in Alignometry); in FIG. 5 - the process of laying the jumper over the window opening of the wall

brick building (in perspective view); in FIG. 6 - view of the jumper supported on the piers of the window opening with

laid on top of it with masonry (in plan). The proposed jumper contains a core 1, placed in a ceramic shell, consisting of separate ceramic elements 2 with dimensions i, h, b, equal to the size of the brick, and metal rods 3. Ceramic elements 2 are made identical, in the form of a parallelepiped, has a central through cavity 4, a groove 5 connected to it, made on the upper face 6 of the element 2, along its entire length i and pairwise arranged relative to the axis of symmetry of the element, with its end faces 7 through longitudinal holes 8 for passing metal erasers 3 it (sm.fig.3).

The ceramic shell is made in the form of a longitudinal row of length 1 of ceramic elements 2 which are joined together by end faces 7 and are connected by metal rods 3 located in the combined holes 8 of the joined ceramic elements 2. Moreover, in the cavity of the ceramic shell formed by combined through cavities 4 and the grooves 5 of the joined ceramic elements 2 are the core 1, made in the form of its filler 9, for example from a concrete mass of class B 25 (see figure 2

and figure 4).

The dimensions of the ceramic element are determined to be equal to the dimensions of the brick for combining the latter with the brickwork of the wall (see Fig. 5/) and are: length i –250 mm, height h –65 mm, width b –120 mm. The diameter of the round metal rod is set depending on the load and is 8.10 or 12mm, cavity size 4 (nhv) -45khbomm The length L of the assembled lintel depends on the length of the opening C and is from 1 to 3 meters and, as a rule, exceeds the size of the opening C by the value of the backfill d see fig. 6). The size of the embedment with the edges of the support is at least 120 mm.

The calculation of the jumper load from the aforementioned brickwork 1; 5 is carried out according to the graphs that allow you to set a uniformly distributed load from the length of the jumper L. For example, at negative temperatures, the load from the above-laid masonry is determined: a) from the masonry layer with a height equal to the length of the opening C, that is, 1.14 -2.24 m; b) from the masonry layer with a height equal to 1/3 of the opening of the lintel C, that is, 0.38-0.74 m. Moreover, in each case, the average density of the masonry of r.KN / m (kgf / m) is taken into account, depending on the selected material. For load-bearing jumpers, the load from overlying floors (not shown in the drawing) based on masonry should also be taken into account if these floors are located at a height not exceeding the opening length C. 1 | and the proposed bridge is made as follows.

Installation of the bridge is carried out simultaneously with the masonry (zen. Initially, the ceramic shell is assembled. To do this, use four metal round bars Z, for example, from reinforcing steel of class A-Sh of a given length and diameter and join ceramic elements 2 with end faces 7, and then thread the metal rods through pairwise located through holes 8 of the ceramic elements 2, connecting them together.

Concrete mixture, for example, class B 25, is poured into a ceramic shell assembled from ceramic elements 2 through a groove 5, in a dosed volume corresponding to the volume of the through cavity formed by the combined through cavities 4 and grooves 5 of the joined ceramic elements 2. After setting and solidification of the aggregate 9, and thus forming from this core core jumper, the latter is ready for use. From figure 5 it is seen that the laying of the jumper is carried out in longitudinal rows 10. which are placed on the supporting surfaces 1.4 of the aperture AND by the embedment value a (see Fig. 5.6), on which cement mortar is preliminarily applied. The number of rows of the jumper depends on the thickness of the opening of the opening (window) (see, 5).

After laying the lintel, the latter is propped up with a temporary mounting lintel, strut 12 (for example, with a cross-section support) to exclude various deformations that may occur when laying the lintel after its assembly.

After laying the lintels over the opening, the upper levels 13 of the brickwork of the wall are immediately produced. In this case, the upper surface of the lintel is cleaned and moistened until the masonry continues. The front surface of the lintel is plastered together with the masonry without preliminary tightening with a metal mesh, due to the presence of its ceramic shell.

- 7 apertures of a brick building allows to provide high-mashushchuschs ability and reliability in operation while reducing weight, and increase its heat-insulating properties due to (reduction of cold bridges and increase the proportion of ceramics. All this improves its performance compared to the prototype.

In addition, this jumper is easy to manufacture and install.This is due to the unification of its elements, and also provides high installation performance, reduction of materials and fittings, and is perfectly combined with brick masonry, which expands its technological capabilities compared to the prototype. 1. 2. 3. 4. Sources of information: M. Tupolev and other constructions of civil buildings. M., Stroyizdat, 1973 (2nd edition), pp. 35-36, Fig. SH.6: d, e, and, k; Sh.6: f. Tupolev M.S. Civil and industrial buildings. Moscow, Gosstroyizdat, part 1, 1962, p. 93, fig. 70. RF Patent No. 2047710, Е04С 3/02, 1995, BI 31. RF Certificate No. 2997, Е04С 33/02, 1996, Bulletin Utility Models and Industrial Designs No. 10. - Prototype.

Claims (1)

The jumper of the wall opening of a brick building, including a reinforced concrete core, placed in a ceramic shell consisting of separate ceramic elements, characterized in that the ceramic shell is made in the form of a longitudinal row of identical ceramic elements joined by their end faces and interconnected by metal rods, each the ceramic shell element is made in the form of a parallelepiped with dimensions equal to the dimensions of the brick, has a central through longitudinal cavity, a longitudinal groove connected to it, made on the upper face of the parallelepiped along its entire length, and longitudinal through holes for pairing metal rods pairwise arranged relative to the symmetry axis of the element, and the reinforced concrete core is made in the form of a concrete cavity filler formed by combined central through cavities and longitudinal grooves of the joined ceramic shell elements.