EA031238B1 - Space stay-cable truss - Google Patents

Abstract

The invention is related to civil engineering and can be used, in particular, in construction of hanging (suspended) structures for bridging over large spans. Summary of the invention: a space cable-stay truss comprises flexible stay cable chords joined by rigid polygon-shaped braces mounted along the truss length transversely to its longitudinal axis, the truss being designed so as to provide individual stress of each stay cable. At least two top stay cables form a stabilizing chord, and at least one bottom stay cable forms a load-bearing chord. The rigid braces are linked at their apexes to stay cables by means of a sliding joint, and their geometrical parameters provide a design biconvex asymmetric contour of the stabilizing and load-bearing chords in the conventional vertical longitudinal plane of symmetry, and a design biconvex symmetric contour of the stabilizing chord in plan. Perpendicularity of rigid braces to longitudinal axis of the truss is ensured by rigid ties of design length mounted pivotally-fixedly at brace apexes and disposed along stay cables, endmost of the rigid ties being secured pivotally-fixedly on one of the truss supports and secured pivotally-fixedly on another truss support. The technical result consists in provision of a multi-functional space stay-cable truss featuring higher reliability, wind resistance, and low labour intensity of erection.

Description

The invention relates to the construction and can be used, in particular, in the device hanging (suspended) structures for overlapping large spans. The inventive spatial cable farm includes flexible belt belts, interconnected established along the length of the farm perpendicular to its longitudinal axis with rigid spacers in the form of polygons, while the farm is made with ensuring individual voltage of each cable. At least two upper shrouds form a stabilizing belt, and at least one lower shroud forms a carrying belt. The rigid struts at the vertices are connected with the sliding-linking guys and are made with geometrical parameters that provide the calculated biconvex asymmetrical contour of the stabilizing and carrying belts in the conditional vertical longitudinal symmetry plane, and the computed biconvex symmetric contour of the stabilizing belt in the plan. In this case, the perpendicularity of the rigid struts of the longitudinal axis of the truss is ensured by fixed hinged and fixed at their tops and rigid ties of calculated length located along the cables, the outermost of which are fixed hingedly and movably on one of the trusses of the truss and hingedly fixed at the other truss support. The technical result consists in the creation of a multifunctional spatial cable truss with high reliability and wind resistance, as well as low installation complexity.

The invention relates to the construction and can be used, in particular, in the device hanging (suspended) structures for overlapping large spans.

Known spatial pre-stressed cable farm A.F. Tikhanov [1], including flexible belts located in planes intersecting in the center and convex to the center, and flexible puffs located along the distance from each other, decreasing in the middle of the span, and made in the form of closed polygonal elements and located along the contour of the farm, combining belts among themselves.

The disadvantage of this technical solution is the limited functional application.

The cable-rod system [2] is also known, which includes a cable-stayed system in the form of a carrying cable fixed at the ends in pivotally fixed supports and a stiffness beam connected to the cable, which uses a diagonal beam-type truss with polygonal belts consisting of racks located at the same distance from each other and ascending or descending from the supports to the middle of the truss brace. The heights of the trunks of the truss vary in proportion to the ordinates of the curve of bending moments built in a beam of the same span as the truss, from the action of a uniformly distributed load, while lifting the upper truss belt is determined from the condition of ensuring the minimum allowable slopes for the roof of a certain (specified) structure, and the distance from the nodes of the lower chord of the truss to the horizontal connecting its support nodes is determined by calculation. The carrier cable of the system is located on the lower belt of the truss and is connected pivotally with all its span nodes and hingedly fixed with the supporting nodes.

The lack of a constructive solution cable-rod system is the presence of the beam stiffness, which complicates the installation of a cable-stayed farm.

Closest to the claimed cable farm to the technical nature is an indiscriminate cable-stayed farm [3], including a stiffening beam, flexible belts connected to its ends, connected with each other by rigid elements installed along the length of the truss perpendicular to its longitudinal axis, and delays connecting the flexible belts with the beam stiffness, while the rigid elements have the shape of a triangle, the vertices of which are connected to the stiffening beam by flexible connections, moreover, the flexible connections and delays are connected to the stiffening beam by means of tensioning devices tv.

The disadvantage of this technical solution is also the use of beam stiffness, the presence of which complicates the process of mounting the truss in hard-to-reach and extensive landscape sections, as well as the large presence of mating elements, which also causes certain difficulties in installation.

The problem solved by the invention is the creation of a multifunctional spatial cable farm, which has increased reliability and wind resistance, as well as low labor-intensive installation.

The task is solved due to the fact that the spatial cable truss, including flexible belts, combined with each other installed along the length of the truss perpendicular to its longitudinal axis with rigid spacers in the form of polygons, according to the invention, is made with ensuring individual tension of each cable, at least the two upper shrouds form a stabilizing belt, and at least one lower shroud forms a carrying belt; rigid struts at the vertices are connected with the sliding joint guys and are made with geometrical parameters that provide the calculated biconvex asymmetrical contour of the stabilizing and supporting belts in the conditional vertical longitudinal symmetry plane, and the computed biconcave symmetric contour of the stabilizing belt in the plan, while the rigid struts of the longitudinal symmetrical contour are in the plan; It is provided with fixed hinged and motionless in their tops and hard links located along the cables liny, the end of which is pivotally-mounted movably on one of the legs and truss hinge-fixed on the other support truss.

In addition, rigid struts can be made in the form of rectangles.

In addition, rigid struts can be made in the form of triangles.

The cable-stayed farm can also be made with the location of an overpass on it or in it.

The claimed spatial cable farm is illustrated by the following drawings.

FIG. 1 shows an unloaded cable farm with rectangular rigid struts, axonometry; FIG. 2 is a cable farm in FIG. 1, side view; FIG. 3 shows section A-A in FIG. 2; FIG. 4 shows a cable farm in FIG. 1, top view; FIG. 5 - unloaded cable farm with triangular rigid struts, axonometry; FIG. 6 - cable farm in FIG. 5, side view; FIG. 7 is a section BB in FIG. 6; FIG. 8 cable farm in FIG. 5, top view; FIG. 9 - unloaded cable farm in axonometry under the action of lateral (wind) load W; FIG. 10 is a cable farm in FIG. 1 under the load of a vehicle traveling along an overpass arranged on a stabilizing belt; FIG. 11 is a cable farm in FIG. 5 under load placed in her pipeline.

Spatial cable farm includes flexible belts 1, 2 guys, interconnected established along the length of the farm perpendicular to its longitudinal axis 3 rigid struts 4 or 5 in

- 1 031238 form of closed polygons (for example, a rectangle (Fig. 1-4, 10) or an isosceles triangle (Fig. 5-9, 11), respectively), with the two upper shrouds 6 forming a stabilizing belt 1, and the two lower shrouds 7 (Fig. 1-4, 9, 12) or one lower guy 7 (Fig. 5-9, 11) form the carrier belt 2. The ends of the cables 6, 7 are installed in the anchor seats of two supports (not shown in the figures) with the possibility of individual tension N ^k , where k - the number of guys. The rigid struts 4 (5) at the vertices are connected with the cables 6, 7 by a sliding joint 8 and are made with geometrical parameters that provide the calculated biconvex asymmetrical contour 9.10 of stabilizing 1 and supporting 2 belts in the conditional vertical longitudinal plane of symmetry (FIG. 2, 6), and in the plan - calculated biconvex symmetrical about the longitudinal axis 3 contour 11 of the stabilizing belt 1 (Fig. 4, 8). A contour 11 in the form of a so-called biconvex lens is preferred. This is achieved through the use of a central rigid strut 4 (5) with a maximum height h of the spacer and a length l of the horizontal side of the strut, and symmetrically located from the central strut to the periphery of the strut truss, with parameters h and l decreasing to the periphery of the span. This is due to the fact that the length of the horizontal side of rigid struts is selected depending on the size of the horizontal wind loads W (Fig. 9), and the height of the rigid struts depends on the vertical operating loads F _n (Figs. 10, 11). At the same time, the perpendicularity of the rigid struts 4 (5) of the longitudinal axis 3 of the truss is ensured by fixed hinges non-moving at their tops and rigid ties 12 of the calculated length located along the cables, the outermost of which are fixed hinge-movably on the truss 13 and hinged-fixed on the truss 14. To impart geometrical immutability, rectangular struts 4 can be provided with diagonal braces 15. In the case of laying the pipeline inside the cable truss, triangular rigid braces 5 can be used, equipped in particular with braces 16 connected to the vertices of the triangle, joined by a central ring 17 through which the pipeline passes 18, which together provides for the maintenance of the pipeline vertically and the redistribution of the load by transferring the load to the nodes of a triangular rigid strut 5. ovokupnost interconnected elements 4 (5), 8, 12-17 farm form its support frame. The optimal ratio of the weight of the support frame (and, hence, its geometric parameters), determining the stability of the truss under the action of wind loads W, and the permissible load F on the cable belts, determining its reliability, is determined by calculation.

Spatial cable farm is mounted as follows.

In the anchor nests of two opposite trusses of the truss (not shown in Fig. 1), the ends of each pre-stressed (weakened) guy are fixed at a calculated distance from each other, determined by geometrical parameters h and l, first to the strut of the rigid strut 4 (5). The shrouds 4 (5) are strung on the cables 6, 7 due to the sliding connection 8, while a strut with maximum geometrical parameters is located in the center of the span of the truss, and relative to it with decreasing values of h and l to the periphery on both sides of the span of the truss are arranged symmetrically equal rigid struts 4 (5). The struts are interconnected by rigid connections 12 by installing rigid connections 12 along each cable and hingedly fixed at the vertices of the struts. Formed as a result of the assembly, the spatial structure attached to the cables 6, 7 is connected by rigid couplings 12 hingedly and motionless to the support 14 and hingedly and movably to the support 13. Individually tension each cable 6, 7 with force N, which leads to a decrease in the length of the cables, and therefore to stabilization and rigidity of the support frame due to its tension. The stabilizing 1 and carrying 2 belts acquire in the conditional vertical longitudinal plane of symmetry of the truss a calculated biconvex contour 9-10, asymmetrical with respect to the axis 3. In this case, the outer contour 11 of the stabilizing belt 1 in the plan takes the form of a so-called biconvex lens, which ensures the stability of the truss under the action of wind loads.

Thus, the spatial farm mounting technology described above is not labor-intensive, it is possible without the involvement of expensive equipment in hard-to-reach places.

The inventive spatial cable-stayed truss can be applied for at least two variants of loads on farm belts: 1st variant - with the upper vertical load F ₁ ... F _n , (for example, the weight of a passing vehicle 19 (Fig. 10); Option 2 - with axial load F ₁ ... F _n , for example, based on the weight of the pipeline 18, laid along the longitudinal axis 3 of the truss through the rings 17) (Fig. 11), where F, n is the value and number, respectively, of local loads on the stabilizing belt 1 truss or ring 17 spacers 5.

In the first variant, the initial value of the deflection of the stabilizing belt 1 (curve 9) is calculated from the condition that when the belt is loaded, it should tend to take a horizontal position (line 20) for passing train trains and traffic flow through it. In the second variant, the amount of deflection of two belts 1 and 2 is calculated from the condition of preserving the straightness of the geometric location of the lower points of the ring 17 when laying a water, gas or oil pipeline inside the truss (through the rings 17). During the deflection of the belts, the extreme rigid connections fixed on the support 13 will have the opportunity not only of angular but also linear movement, which will ensure horizontal stability of the upper stabilizing belt 1 and invariance of the perpendicularity of the rigid struts 4 (5)

- 2 031238 dolna axis 3 trusses.

The implementation of the spatial farm due to the use of at least two cables in the stabilizing belt, and at least one cable in the carrier, and the use of hinge joints between struts and rigid connections in the support frame of the truss allows reducing the effect of atmospheric or local (vertical) loads and wind (side) loads, which ensures the stability and rigidity of the cable-stayed farm. Reducing the effect of wind load can increase the span of the farm and increase its reliability.

Thus, both during construction and maintenance, the spatial cable farm of the claimed invention is convenient, reliable, and the technical and economic indicators are higher compared with the known analogues.

Information sources.

1. SU 903509, IPC E04B 7/14, publ. 1982.02.07.

2. RU 2288332, IPC E04B 7/14, publ. 2006.11.27.

3. SU 434163, IPC E04C 3/10, publ. 1974.06.30.

Claims (5)

CLAIM 1. Spatial cable farm, including flexible guy belts, interconnected by fixed lengthwise trusses in the form of polygons mounted along the length of the truss perpendicular to its longitudinal axis, characterized in that it is made with ensuring individual tension of each cable, while at least two upper cables form a stabilizing belt, and at least one lower guy forms a carrier belt; rigid struts at the vertices are connected with the sliding joint guys and are made with geometrical parameters that provide the calculated biconvex asymmetrical contour of the stabilizing and supporting belts in the conditional vertical longitudinal symmetry plane, and the computed biconcave symmetric contour of the stabilizing belt in the plan, while the rigid struts of the longitudinal symmetrical contour are in the plan; It is provided with fixed hinged and motionless in their tops and hard links located along the cables liny, the end of which is pivotally-mounted movably on one of the legs and truss hinge-fixed on the other support truss. 2. Cable-stay farm according to claim 1, characterized in that the rigid struts are made in the form of rectangles. - 3 031238 FIG. 3 3. Cable-stay farm according to claim 1, characterized in that the rigid struts are made in the form of triangles. - 4 031238 FIG. 7 FIG. eight 4. A cable-stayed farm according to claim 1, characterized in that it is made by providing for the location of an overpass on it or in it. FIG. one - 5 031238 FIG. eleven