RU114981U1 - FRAME VARIABLE CONSTRUCTION - Google Patents

Abstract

1. A frame structure with variable-corrugated elements, consisting of a crossbar and posts, characterized in that the wall of the crossbar and / or posts is variable-corrugated or is a combination of smooth and corrugated (traditionally or variable) sections, while smooth sections are located as as a rule, in zones where bending moments in the element predominate, and corrugations with relatively higher rigidity are located, as a rule, in zones where shear forces and / or torques prevail, followed by a smooth or stepwise change in the parameters of the corrugations (pitch and / or height) in accordance with the change intensity of shear forces, bending and torques. ! 2. A frame structure according to claim 1, characterized in that the wall thickness of the crossbar and / or struts is variable in length. ! 3. Frame structure according to claim 1 or 2, characterized in that the height of the cross-section of the girder and / or the posts is variable. ! 4. The frame structure according to claim 3, characterized in that the elements of the crossbar and / or racks - belts, wall sections, interfaces - are made of materials with different physical and mechanical properties. ! 5. A frame structure according to claim 4, characterized in that perforation is provided in the wall of the crossbar and / or posts. ! 6. A frame structure according to claim 5, characterized in that the corrugation profile within the girder or post varies, and the profile of the girder wall of the girder may differ from the corrugation profile of the wall of the posts. ! 7. Frame structure according to claim 6, characterized in that the walls of the girder and / or struts are reinforced with stiffeners and / or braces.

Description

The invention relates to construction, to the supporting structures of the frame type used in buildings and structures of industrial and civil use.

The closest in technical essence and the achieved effect is the frame metal structure known from the prior art, in which the crossbar wall is corrugated in the transverse direction and the strut wall in the longitudinal direction (Metal structures. 3t. T.2. Steel structures of buildings and structures. ( Designer Handbook) / Under the general editorship of V.V. Kuznetsov - M .: DIA, 1998. - 512 p. S. 223.). Also known is a variant of this frame with transverse corrugation of the wall of the uprights. The main disadvantage of the known designs is the increased material consumption caused by the constant step and height of the corrugations of the walls.

The technical result from the application of the invention is to reduce the material consumption of the frame structure and increase its resistance to external power influences.

The specified technical result is a solution to the urgent task of saving material resources and is achieved due to the fact that the wall of the crossbar and / or racks is variable-corrugated or is a combination of smooth and corrugated (traditionally or alternately) sections. Variable corrugation of the wall consists in varying the parameters of the corrugations - step, and / or height, and / or profile along the length of the wall. The corrugations of the wall are mainly transversely directed to the longitudinal axis of the element. Corrugations with a relatively high height and / or small pitch, as a rule, it is rational to place them on the areas of prevalence of intense transverse forces and / or torques, followed by a smooth or stepwise decrease in height and / or increase in the step of the corrugations in accordance with a decrease in these forces. Thus, a change in the parameters of the corrugations (pitch and / or height) corresponds to a change in the intensity of the transverse forces, bending and torques. At the same time, wall sections with a relatively small height and / or a large step of the corrugations more actively resist bending moments acting in the plane of the wall, being included in the work of the structure for bending. Corrugation of the wall, in which the step, height and profile of the corrugations do not change along the length of the wall should be considered traditional. In the frame rods (crossbar and uprights) in the zones of intense bending moments, the device of smooth wall sections is effective.

The crossbar and / or racks along the length can consist of several compartments, within which not only the parameters of the corrugations of the wall, but also its thickness are changed, which is also aimed at achieving the presented technical result.

The essence of the invention is illustrated by drawings, which show:

- figure 1 is a transverse view of the frame structure with variable-corrugated elements - the walls of the crossbar and struts;

- figure 2 is a section aa in figure 1;

- figure 3 is a section bB in figure 1;

- figure 4 is a transverse view of one of the two symmetrical halves of the frame structure with variable-corrugated elements (design solution);

- figure 5 is a section aa in figure 4;

- figure 6 is a section bB in figure 4;

- figure 7 is a section bb in figure 4.

The frame with a variable-corrugated wall consists of a crossbar 1 and racks 2. A crossbar 1 consists of belts 3 and a wall 4. Racks 2 consist of belts 5 and a wall 6. Wall 4 of a crossbar 1 contains flat (smooth) sections 7, installed at least least in the ridge and cornice nodes. Under the cornice node refers to the interface of the bolt 1 with the rack 2.

A ridge assembly refers to a pair of symmetrical halves of the crossbar 1. The cornice assembly can be a separate element, vut, and the ridge assembly can be a ridge element, which allows designing collapsible frames with the possibility of interchangeability of the crossbar 1 and strut 2 elements.

The wall 6 of the racks 2 contains flat (smooth) sections 7, at least in the cornice assembly and in the interface with the base structure. The wall thickness 4, 6 in the flat sections 7 of the ridge and / or cornice nodes, as a rule, is greater than the wall thickness 4, 6 in other sections. This circumstance is explained by the high intensity of bending moments in the cornice and ridge nodes from the action of the most likely combinations of external loads and effects.

If the crossbar 1 and / or the stand 2 consist of several enlarging elements, it is rational to arrange the flat sections 7 of the walls 4, 6 with a relatively large thickness (compared to other parts of the walls 4, 6) at the joints of such elements.

For additional material savings, as well as skipping communications within the height of the cross-sections (in order to maintain the optimal volume of the premises), perforation is provided in the wall 4, 6 of the crossbar 1 and / or the racks 2.

The frame structure with variable-corrugated elements is made of metal, mainly steel. A variant of the frame with pipe-concrete racks is possible 2. Belts 3, 5 can be made of sheet or shaped steel. The scope of the invention provides a variant of the frame, in which the elements of the crossbar 1 and / or racks 2 - belts 3, 5, wall sections 4, 6, interface units, etc. - are made of materials with different physical and mechanical properties. With the polymetallic (in particular, bistal) version of the frame, the belts 3, 5 are effectively made of metal with a comparatively higher calculated tensile resistance than the metal used for walls 4, 6.

The connections of the frame elements (crossbar 1 and strut 2 or symmetrical halves of the crossbar 1) in the cornice and ridge nodes are mainly flanged on high-strength bolts. It is recommended to make flanges from steel of increased strength group (C325 - C390 according to GOST 27772-88).

Belts 3, 5 are connected to the wall 4, 6 by welding. At the same time, the weld can be bilateral and one-sided, it is recommended to use a two-sided seam in the cornice assembly (wut).

The posts 2 and the crossbar 1 can have a constant or variable cross-sectional height. Racks 2 can mate with the foundation rigidly or articulated; be in vertical or inclined position. To perceive the thrust, a tightening device is possible at the level of the nodes of the interface of the racks 2 with the foundation or at the level of the cornice nodes.

The corrugations of the wall 4, 6 can be reinforced with ribs stamped on their faces (additional corrugations). Smooth-walled sections 7 can be reinforced with stiffeners or predominantly stamped irregular corrugations that prevent buckling of a smooth section 7 of the wall 4, 6 under load.

The wall 4 of the crossbar 1 and / or the wall 6 of the racks 2 can be reinforced with stiffeners and / or braces.

The profile of the corrugations can be different both within a specific element (crossbar 1, struts 2), and between elements, i.e. the profile of the corrugations within the crossbar 1 or strut 2 may vary, and the profile of the corrugations of the wall 4 of the crossbar 1 may differ from the profile of the corrugations of the wall 6 of the struts 2.

The cross section of the crossbar 1 and / or racks 2 can be I-beam, box-shaped or I-box (essentially box-shaped with overhangs of belts 3 or belts 5).

The scope of the invention provides a variant of the frame, in which the cross section of the crossbar 1 in the sections adjacent to the uprights 2 is box-shaped, and in the span section - I-beam. In this case, the cross section of the struts 2 can be box-shaped.

To produce the proposed frame structure, it is possible to resort to the technologies known from the prior art:

- corrugation of sheet blanks by rolling or stamping;

- automatic and manual welding of metal elements;

- cutting of smooth and shaped metal, etc.

The frame structure with variable-corrugated elements works as follows:

- when, for example, a vertical load is applied to the crossbar 1 in the plane of the wall 4, the crossbar 1 experiences a transverse bending. Bending moments (corresponding pairs of forces) in the crossbar 1 and in the struts 2 are almost completely perceived by the belts 3, 5, as well as by the smooth sections 7 (moreover, mainly by the part of the section 7 that is adjacent to the belts 3, 5);

- longitudinal forces (struts - in crossbar 1, vertical forces - in struts 2) are almost completely perceived by belts 3, 5, since corrugated walls 4, 6 have low rigidity across corrugations;

- lateral forces and torques are perceived mainly by corrugated walls 4, 6 and stiffeners (if provided);

- a complex stress-strain state occurs in the cornice node and in the node pair of the racks 2 with the foundation. In these places, the intensity and direction of efforts are most sensitive to external influences, which justifies the adoption of flat (smooth) or reinforced by a limited number of stiffeners (due to residual welding stresses) of sections 7 of the wall 4, 6;

- smooth thin-walled sections 7 can work in a supercritical (i.e., after loss of local stability) stage. On the one hand, this is a positive circumstance, since the material continues to work in the elastic - plastic stage, but on the other hand, the transition to the supercritical stage is accompanied by a loud bang, which, according to psychological requirements, is not permissible for all buildings. To eliminate this restriction, it is necessary that the thin-walled sections 7 of the walls 4, 6 go into the supercritical stage of operation even under constant loads, as provided for in the beams and frames with a flexible wall known from the prior art (Design of metal structures: Special course. Textbook. manual for universities / V.V. Biryulev, I.I. Koshin, I.I. Krylov, A.V. Silvestrov. - L .: Stroyizdat, 1990 - 432 pp., ill. S.20.

Metal constructions. In 3t. T.2. Construction of buildings: Textbook. for builds. universities / V.V. Gorev, B.Yu. Uvarov, V.V. Filippov, and others; under the editorship of V.V. Goreva - 3rd ed., Erased. - M .: Higher. school, 2004 - 528 p., pp. 208-209);

- the horizontal reaction from the struts 2 is perceived by the construction of the foundation or puff;

- sections of the wall 4, 6 with corrugations of relatively low stiffness (i.e., with a large pitch and / or lower height) are more effectively included in the work of the corresponding element in bending than sections of the wall 4, 6 with corrugations of relatively greater stiffness.

- in the work of the proposed design, the following principle of power resistance is observed: the distribution of internal forces between the elements depends on the ratio of their linear stiffnesses;

- under the effect of horizontal (wind) load on the rack 2, as well as a combination of horizontal and vertical (symmetric or asymmetric) loads, respectively, on the rack 2 and crossbar 1, the described features of the proposed design are saved.

The rational corrugation locations with the greatest stiffness (i.e., with a smaller pitch and / or higher height) are: in the crossbar 1 - supporting sections of the wall 4 starting immediately after the cornice node, in the racks 2 - sections of the wall 6 adjacent to the cornice node and the interface to the base.

Smooth thin-walled sections 7 are effectively located in the crossbar 1 - in the span zone, in the racks 2 - in the mid-height zone.

The described arrangement of corrugated sections and smooth thin-walled sections 7 of the wall 4, 6 of the crossbar 1 and the struts 2 is optimal for the overwhelming number of combinations of vertical (symmetric and asymmetric) and horizontal loads on the frame structure.

Under certain conditions and appropriate justification, a different arrangement of corrugated sections and smooth sections 7 is possible, while the principle of their power resistance described above is preserved.

According to the static scheme, the proposed frame is mainly double-hinged or hinge-free. The hinges are located in the nodes of the junction of the racks 2 to the foundation. Three-hinged version of the frame is possible in exceptional cases with appropriate justification.

By varying the stiffness of the wall 4, 6 by means of variable corrugation, it becomes possible to maintain or slightly change the shape (cross-sectional height) of the crossbar 1 and / or struts 2 with an effective distribution of the material. This circumstance can significantly reduce the cost of manufacturing the frame, rationally distribute the stiffness of the elements in terms of material consumption, and also provides the ability to organize automated production of such structures.

A multi-span frame design solution with variable-corrugated elements is possible.

The direction of the corrugations of the wall 4, 6 is mainly transverse, i.e. perpendicular to the longitudinal axis of the element (crossbar 1 or rack 2).

Due to the fact that the frame structure with variable-corrugated elements has a number of specific features; distribution and redistribution of efforts, supercritical work, cross-section deployment, variable stiffness, influence of loading regime, local and general stability of elements, etc., it is recommended to calculate strength and stability by numerical methods of elasticity theory in a computer implementation, for example, by the finite element method (FEM) , solving the problem in a spatial setting and modeling the frame elements by shell finite elements.

Claims (7)

1. The frame structure with variable-corrugated elements, consisting of a crossbar and racks, characterized in that the wall of the crossbar and / or rack is variable-corrugated or is a combination of smooth and corrugated (traditionally or alternately) sections, while smooth sections are arranged as as a rule, in zones of prevalence of bending moments in the element, and corrugations with relatively greater rigidity are located, as a rule, in zones of prevalence of transverse forces and / or torques with subsequent smooth or step change corrugation parameters (step and / or height) in accordance with a change in the intensity of transverse forces, bending and torque. 2. The frame structure according to claim 1, characterized in that the wall thickness of the crossbar and / or racks is variable in length. 3. The frame structure according to claim 1 or 2, characterized in that the cross-sectional height of the crossbar and / or racks is variable. 4. The frame structure according to claim 3, characterized in that the crossbar and / or strut elements — belts, wall sections, interface units — are made of materials with different physical and mechanical properties. 5. The frame structure according to claim 4, characterized in that perforation is provided in the wall of the crossbar and / or racks. 6. The frame structure according to claim 5, characterized in that the profile of the corrugations within the crossbar or strut changes, and the profile of the corrugations of the wall of the crossbar may differ from the profile of the corrugations of the wall of the struts. 7. The frame structure according to claim 6, characterized in that the walls of the crossbar and / or struts are reinforced with stiffeners and / or braces.