RU91583U1 - VARIABLE CORFORED WALL - Google Patents

Abstract

1. A beam of I-beams cross section, containing a compressed and stretched belt connected by a transverse corrugated wall, characterized in that the corrugation is variable along the length of the beam with a decrease in the step of the corrugations and / or an increase in their height in the areas of action of relatively intense transverse forces, followed by a smooth or stepwise a decrease in height and / or an increase in the step of the corrugations in accordance with a decrease in the intensity of transverse forces and an increase in the intensity of bending moments with the achievement of a minimum height and / or poppy the maximum step of the corrugations in the area with the maximum bending moment and minimal transverse forces, and a single corrugation remains a constant section along the height of the wall. ! 2. The beam according to claim 1, characterized in that the compressed and stretched belts are not parallel to each other, while the outline of the belts is a trapezoidal, polygonal, segmented or triangular shape with the greatest divergence of the belts in the areas of maximum bending moments. ! 3. The beam according to any one of claims 1 and 2, characterized in that along the length of the beam, one-sided or two-sided transverse stiffeners and / or end ribs are provided. ! 4. The beam according to claim 3, characterized in that in areas with a relatively low intensity of transverse forces, perforation is provided in the wall. ! 5. The beam according to claim 4, characterized in that in the area with a relatively low intensity of transverse forces and a relatively high intensity of bending moments, the wall is made of a smooth sheet. ! 6. The beam according to claim 5, characterized in that the compressed and stretched belts are made with different cross-sections. ! 7.

Description

The utility model relates to construction and can be used as a supporting structure of industrial and civil buildings and structures.

In the prior art, an I-beam of N.P. Selivanov (Patent for invention RU 2029039 C1) is known, in which the wall is corrugated by a profile having a decrease in amplitude to the lower zone. The disadvantage of this solution is the decrease in the overall stability of the wall and the local stability of an individual corrugation, which (due to a change in its cross section along the height of the wall) ceases to work as a transverse stiffener, which especially affects the supporting sections of the beam. In addition, in places where bending moments predominate, the compressed wall section (above the neutral axis) cannot fully engage in bending, due to the low rigidity across the corrugations.

The closest analogue of the proposed utility model in terms of technical nature and the achieved effect is a metal beam of I-section with a corrugated wall, the pitch and height of the transverse corrugations of which remain constant along the length of the beam (Metal structures. 3 vol. T.1. Structural elements: Textbook for building Universities / V.V. Gorev, B.Yu. Uvarov, V.V. Filippov et al .; Edited by V.V. Gorev - 3rd ed., Sr. - Moscow: Higher School, 2004 - 551 p. S. 294-298, fig. 5.60). The disadvantage of this design solution is the exclusion from the work of bending the span of the wall at its substantial height, i.e. the formation of a zone of undervoltage, which reduces the reliability of the structure, due to the low stiffness of the wall across the corrugations, and also increases the consumption of material, in view of the ongoing corrugation of the wall in areas where bending moments predominate.

The technical result of this utility model is to reduce the material consumption of beams and increase their bearing capacity. The presented technical result is a solution to the urgent and significant task for the construction industry of the efficient use of material in load-bearing structures. The specified technical result is achieved due to the fact that the transverse corrugations, constant along the height of the wall of the section, are concentrated on those parts of the wall where intense transverse forces act (as a rule, support sections), followed by a smooth or stepwise decrease in the height of the corrugations and / or increase in their pitch ("Attenuation") in accordance with a decrease in the intensity of transverse forces and an increase in the intensity of bending moments. Significantly important is the constancy of the cross-sectional height of the wall section of a single corrugation to ensure its local stability, as a kind of transverse stiffener. In this case, the wall is a structurally orthotropic plate, the stiffness (including bending-torsional) characteristics of which vary in length generally nonlinearly, due to the different intensities of the “attenuation” of the corrugation along the length of the wall.

In the drawings, revealing the essence of this utility model, it is shown: in Fig. 1, a beam with a variable-corrugated wall, the lower belt of the beam has an asymmetric section compared to the upper;

figure 2 is a side view of the beam in figure 1;

figure 3 is a longitudinal section aa in figure 2;

figure 4 - beam with a variable-corrugated wall and symmetrical belts;

figure 5 is a beam with a variable-corrugated wall, reinforced with bilateral end and additional transverse stiffeners;

Fig.6 is a beam with a variable-corrugated wall having a flat section in the span;

7 is a beam with a variable-corrugated wall having a flat section with perforation, as well as transverse stiffeners;

Fig.8 is a beam of a trapezoidal shape having a variable-corrugated wall;

figure 9 is a beam of a trapezoidal shape having a variable-corrugated wall with a flat fragment;

figure 10 - beam of a trapezoidal shape, the wall of which is alternately corrugated with various profiles;

figure 11 is a side view of the beam in figure 10;

in Fig.12 is a longitudinal section aa of the beam of Fig.11;

in Fig.13 - beam polygonal shape with a variable-corrugated wall;

on Fig - beam with a variable-corrugated wall made of two explicit compartments, the span of which is flat.

The I-beam cross section consists of a compressed 1 and 2 extended belts connected by a variable-corrugated wall 3, the corrugations of which are perpendicular to the longitudinal axis of the beam, and a single corrugation does not change its cross section along the height of the wall 3. Change step 4 and / or height 5 of the wall corrugations 3 along the length of the beam allows you to vary the stiffness and bending-torsional characteristics of both the wall 3 and the beam as a whole, which best fits the diagrams of transverse forces and bending moments.

A variant of the beam is possible in which the wall 3 in the area with relatively intense bending moments and relatively small transverse forces is made of a smooth sheet.

The greatest economic effect from the application of this utility model can be achieved by loading the beam with the formation of a clean bending zone. In this case, the alternating corrugated wall 3 perceives transverse forces in the supporting sections, and is more involved in the work of belts 1 and 2 for bending in the span (in the zone of pure bending).

Based on the principle of concentration and “attenuation” of the corrugations described above, by varying their pitch 4 and / or height 5, it is possible, depending on the given conditions and the desire of the designer, to reduce material consumption while ensuring equal stability of the shape and position of the beam in comparison with the closest analogue , or with the same material consumption, increase the stability margin of the shape and position of the structure, or get a design option that will have both better stability and reduced material consumption.

This circumstance is explained by the nature of the work of the beam with a variable-corrugated wall 3, which consists in the following: when one of the zones 1 and 2 is exposed to external load in the plane of the wall 3, the beam is transversely bent. In this case, the forces caused by the bending moment are predominantly perceived by the belts 1 and 2 and the span section of the wall 3, which has greater stiffness across the corrugations than the reference sections, in view of their relatively low height 5 and / or large step 4 or the span is smooth-walled. The transverse forces, which, as a rule, have the highest intensity in the supporting sections, are almost completely perceived by the corrugated wall 3, in these sections it is advisable to provide corrugations with a relatively small pitch 4 and / or high height 5.

A gradual increase in step 4 and / or a decrease in the height of the 5 corrugations ensures the stability of the wall 3 and increase the moment of resistance to bending of the beam cross section in the span - where bending moments have a dominant effect.

In the case of a device for variable corrugation of the wall 3 due to the docking of the compartments with various parameters of the corrugations, the effectiveness of such a design solution depends on the degree of discretization (breakdown frequency) of the wall 3 by such compartments.

The profile of the corrugations can be different: wavy (sinusoidal, parabolic, ellipsoidal, etc.), triangular, trapezoidal (in the particular case, rectangular).

The volume of the utility model also provides beam options, the variability of the corrugation of the wall 3 of which is carried out by changing only one of the parameters of the corrugations - step 4 or height 5, i.e. only step 4 of the corrugations is changed (in accordance with the described principle) with their constant height 5 or only height 5 of the corrugations with their constant step 4.

The wall 3 may have a perforation, which is preferably provided in the span, where the intensity of the transverse forces, as a rule, is small, and the intensity of the bending moments reaches its maximum. The perforation device allows in some cases to further reduce the consumption of materials and expand the scope of such structures, for example, by laying through communications openings.

A variant of the beam is possible, in which the wall 3 consists of compartments (explicit or conditional) with a different profile of corrugations. Explicit compartments are understood to mean fragments of the wall 3, combined into a single whole with the help of welds 6 or flange joints. In the case of conditional compartments, it is assumed that the wall 3 is made of a single sheet, and the division into compartments is due to either stiffening ribs 7, or a change in the corrugation profile, or other constructive solution.

Corrugations can be one-sided and two-sided. The device of the latter is preferable due to their symmetry relative to the median plane of the wall 3.

Belts 1 and 2 can be either parallel or not parallel to each other. In the latter case, the outlines of belts 1 and 2 are trapezoidal, polygonal, segmented or triangular in order to better match the diagram of bending moments. It is possible to carry out belts 1 and 2 with different cross sections.

A beam with a variable-corrugated wall 3 may have transverse stiffening ribs 7 and / or end ribs 8. The arrangement of ribs 7 and 8 is effective in the case of reinforcing wall 3 in the zones of action of concentrated forces. The transverse ribs 7 can be bilateral or one-sided relative to the median plane of the wall 3.

Thus, a beam with a variable-corrugated wall 3 combines the advantages of both constant corrugation in terms of increasing the stability of the wall and increasing the bending-torsional characteristics of the cross section, as well as a smooth-walled solution in terms of increasing the moment of resistance to transverse bending.

When bending the closest analogue - beams with a constantly corrugated wall - in the span of the wall, a zone is formed in which the normal and tangential stresses are close to zero (undervoltage zone), i.e. the wall material in this zone does not participate in the work of the structure, increasing its material consumption and reducing the bearing capacity. In a beam with a variable-corrugated wall 3, this zone is significantly smaller in area due to the greater stiffness of the wall 3 across the corrugations. Thus, the material of the wall 3 is actively included in the work and is rationally used along the entire length of the structure, starting from the supporting sections, where the maximum transverse forces are perceived by concentrated corrugations, and ending with the span section, where corrugations with a small height of 5 and / or an extended step of 4 or, even, a smooth fragment of the wall 3 actively participates in the work of belts 1 and 2 for bending with, as a rule, a low intensity of transverse forces.

The listed features of a beam with a variable-corrugated wall 3 make it possible to reasonably reduce its structural height, which, as applied to buildings for various purposes, reduces the area of enclosing structures, operating costs for heating, ventilation, etc.

A beam with a variable-corrugated wall 3 can be made of basic building materials used for supporting structures of the beam type: metals, wood. In the case of manufacturing a metal beam, the alternating corrugated wall 3 is connected to the belts 1 and 2 using a continuous, mainly one-sided weld, which must be taken into account when choosing specific materials according to the criteria of weldability and operating conditions. In the case of the manufacture of wood beams, the edges of the alternating corrugated wall 3 are glued into the corresponding grooves of the belts 1 and 2.

Giving the sheet blank a variable-corrugated shape is possible using stamping; bending using a rotating matrix with a set of different grooves-calibres corresponding to the step and height of the corrugations; profiling on mills with changing rolls.

For the production of beams with a variable-corrugated wall 3 at existing production facilities for the automated production of the closest analogue - beams with constant corrugation of the wall - the following is proposed: two halves - the workpieces are connected by a vertical weld 6 or flange connection, and each half of wall 3 is corrugated only on some part - the reference section, and on the other part - has a flat shape (Fig).

The proposed utility model can be used in structural systems of load-bearing elements of buildings and structures for civil and industrial purposes, intended for use in various snow and wind regions of the Russian Federation, as well as in areas with seismicity up to 9 points. A beam with a variable-corrugated wall can be used to perform both load-bearing and enclosing functions, for example, in the sheathing of transport galleries, end elements of unheated buildings.

Claims (9)

1. A beam of I-beams cross section, containing a compressed and stretched belt connected by a transverse corrugated wall, characterized in that the corrugation is variable along the length of the beam with a decrease in the step of the corrugations and / or an increase in their height in the areas of action of relatively intense transverse forces, followed by a smooth or stepwise a decrease in height and / or an increase in the step of the corrugations in accordance with a decrease in the intensity of transverse forces and an increase in the intensity of bending moments with the achievement of a minimum height and / or poppy the maximum step of the corrugations in the area with the maximum bending moment and minimal transverse forces, and a single corrugation remains a constant section along the height of the wall. 2. The beam according to claim 1, characterized in that the compressed and stretched belts are not parallel to each other, while the outline of the belts is a trapezoidal, polygonal, segmented or triangular shape with the greatest divergence of the belts in the areas of maximum bending moments. 3. A beam according to any one of claims 1 and 2, characterized in that along the length of the beam, one-sided or two-sided transverse stiffeners and / or end ribs are provided. 4. The beam according to claim 3, characterized in that in areas with a relatively low intensity of transverse forces, perforation is provided in the wall. 5. The beam according to claim 4, characterized in that in the area with a relatively low intensity of transverse forces and a relatively high intensity of bending moments, the wall is made of a smooth sheet. 6. The beam according to claim 5, characterized in that the compressed and stretched belts are made with different cross-sections. 7. The beam according to claim 6, characterized in that the profile of the corrugations of the wall changes along the length of the beam. 8. The beam according to claim 7, characterized in that the height of the corrugations of the wall does not change along the length of the beam. 9. The beam according to claim 7, characterized in that the step of the corrugations of the wall does not change along the length of the beam.