SU960402A1 - Wall girder - Google Patents

Description

(54) BEAM

The invention relates to the field of construction and can be used in the construction of agricultural production buildings in livestock complex.

A panel is known, comprising vertical supporting ribs from the protrusion and in the lower part and bordered by horizontal edges ,. and in the upper part of which window openings-fl are formed.

The disadvantage of this design is the presence of large zones of cold bridges, which limits the scope of their application.

The closest in technical essence to the present invention is a beam-wall, comprising a shell reinforced with outer and inner with bearing ribs with insulators located between them, combined by flexible connections 2 J.

A disadvantage of the known construction is the high consumption of materials, the low tightness of the butt joint, as well as the presence of cold kustik.

The aim of the invention is to reduce the material consumption and increase the tightness of the butt joint.

This goal is achieved by the fact that in the beam-wall, which includes an armor. The outer shell and the inner shell with supporting ribs with a heater located between them, combined by flexible connections, are not coated with the contour ribs of the shell made of X-shaped form with overlapping recesses in the rib insulation

10 panels, the ribs are reinforced with V-shaped frames with three carriers: longitudinal rods, and the flexible connections are formed by releases of the working reinforcement of the shell.

15, .1 schematically shows a wall of beams-walls, a general view; figure 2 - section aa in figure 1; in Fig. 3, a vertical connecting JOINT} in Fig. 4, an intermediate vertical edge; figure 5 - frame bearing ribs; Fig. 6 is a working mesh with flexible connections; Fig.7 is a diagram of armor11 and; in fig. 8 - installation of the rolls of the wall in the glass fun25 Dament.

The beam wall of aglopo rite porous concrete is a rectangular panel including the outer plate 1, insulation 2, insulated from moisture penetration.

the material 3, the inner shell with the carrying ribs 4, framed along the contour by the horizontal rib 5 and the rib 6 in the form of a thrust ledge and vertical ribs 7 and 8, divided by the middle intermediate rib 9. In the upper part of the panel there are window openings 10 and 11 filled with profiled glass 12 in factory conditions. The bearing reinforcement cages of 13 vertical and horizontal ribs, having a .V-shape, consist of three longitudinal rods 14 connected by transverse rods 15.

The working rebar is 16 soyoit from working longitudinal 17 and 18 transverse rods, the outlets of which о. form flexible connections 19. Hermetic-. The vertical cavity of the vertical joint 2 is filled with an insulating matvrial in the form of a warming liner 21, and the outer 22 and inner 23 seams are sealed with a hydrophobic solution 24 to form air layers 25. The outer plate is reinforced with reinforcing mesh 26. The supporting contour edges of the shell 7 are made L-shaped with overlapping recesses in the edge of the insulation panel.

The construction of flexible connections implies the use of precisely soft insulation (mineral wool plates on a phenolic binder, phenol resistive foam, expanded polystyrene of different grades), which completely eliminates the effect of temperature deformations on the inner carrier layer due to the fact that the reinforcement bar is not flexible. coated with concrete and the compound is malleable (not hard).

The design of the flexible links 19 also allows the assembly and operational integrity of the product to be maintained, since the outer plate 1 and the inner shell 4 work as pinched elements due to a rigid paddle in the lower horizontal rib 6.

The integrity of the product and non-displace plates 1 and the shells 4 relative to each other are provided by mounting protrusions. For the entire thickness of the panel that the suit is, there are cold bridges due to the fact that the lower horizontal edge b is below the floor when the building is erected.

The beam-wall works as a solid monolithic structure, all elements of which are included, both from vertical and horizontal loads, into operation simultaneously.

Thermally, both bulkhead and butt joints

They do not have a direct cold bridge, since the insulation of the panel 2 and the insulating liner 21 are offset from each other by not less than 3/4 of the width of the sealed cavity 20, which ensures good thermal performance characteristics.

In the cavity of the vertical joint, a heat insulation insert is placed in the installation process. Before installing the adjacent panel, the insulation is used with a sealing mastic.

It is possible to fill the vertical joint with foaming phenol-molding foam (foam foam PL, which fill the cavity in a foamy state. To avoid leakage of foam foam, two-sided jointing of the seams is made with cement mortar.

The presence of V-shaped reinforcement cages in horizontal and vertical fins creates structural rigidity and provides high bearing capacity from transport. assembly and operational loads. The V-shaped framework also determines a reduction in the specific consumption of reinforcement compared to the well-known rectangular spatial frameworks. At the same time, this also makes it possible to completely mechanize the process of manufacturing reinforcing cages and to avoid manual welding.

The transverse rods 15 of the V-shaped frame are formed by the usual bending to form an angle in the range of 60-65. This angle, according to the test results, provides the maximum pt) available rigidity.

The length of the flexible connections should be such as to enable them to be anchored to the reinforcing mesh 26.

The thrust protrusion 6 of the beam-wall is made over the entire width of the panel, which ensures the integrity of the product and the non-displaceability of the inner shell and the outer panel relative to each other.

The X-shaped vertical iieeep 7 and 8 reduces the area of adhesion to the formwork in the manufacture of beams-walls and reduces the concentration of stresses and avoids chipping during transportation of the structure from the manufacturer to the construction site.

The use of the proposed racks will reduce the cost of construction, reduce construction time, while increasing the degree of prefabrication of the structure.

Claims (2)

1. Sakhnovsky K.V. and others. Prefabricated thin-walled spatial and long-span designs. Leningrad, Stroyizdat, 1969, p. 334 2. Authors certificate of the USSR 547506, cl. E 04 C 2/38, 1977 (prototype). ba on the wall S  I . 2 ig. 22 25 16  IS kink oCiSO tfg./ Fie.7 1 tiustk9 0.10 fi.l / s // vrA X / VI -030 AV / XNX / XVVy PU9.8 5-5 roll - wall 0.00 one P9L