RU2197586C1 - Bearing structure of electric power line - Google Patents

Abstract

FIELD: construction industry. SUBSTANCE: invention refers specifically to bearing structures in the form of space truss of high-voltage electric power line. Technical result of invention consists in reduced usage of steel for manufacture of chords and in optimization of forms of chords over height of truss in correspondence with loads acting on truss over its height to raise mechanical strength of space truss to take bending moments without any growth of thickness of metal sheet of chords and any expansion of truss base. Bearing structure of electric power line presents space truss of polygonal cross-section carrying at least three shaped chords arranged at some distance one from another and interconnected by means of members of grates with formation of closed cross- sectional circuit. Base of each shaped cord has faces made of continuous steel sheet bent in transversal plane over entire height of bearing structure with making of specified geometric form of central surface and of bent surfaces arranged at preset angle to it and forming stiffening ribs of chord of specified shape. Members of grates are made fast to extreme stiffening ribs of adjacent cords. Ends of members of grates of adjacent side faces of truss are attached to common units on its chords. Pentahedral base of each shaped chord forms five surfaces. First surface is central, two other side surfaces adjacent to central surface are arranged along its sides at right angle with reference to it, two extreme surfaces bordering on side surfaces are arranged at obtuse angle to side surfaces. Central surface of cord has shape of isosceles triangle or right- angled-triangle or trapezium. EFFECT: raised mechanical strength of truss. 5 cl, 13 dwg

Description

 The invention relates to the construction, in particular, to supporting structures in the form of a spatial truss for a high voltage power line (power transmission line).

 For the most frequently used and more reliable free-standing supports (without guy wires), the forces in the strut belts are determined mainly by bending moments from the loads, which in normal conditions are directed perpendicular to the axis of the high voltage line, and in emergency modes, they are directed along the axis of the high voltage line. Since the bending moments in the upper sections are less, and in the lower sections more, the sections are performed with inclined belts in order to possibly bring together the forces in the belts of the upper and lower panels of each section. With the equality of these efforts, it is possible to fully use the strength of the material of the belts over the entire height of the section, which minimizes the cost of steel on the belts. However, the large slope of the belts leads to an expansion of the struts of the supports in the lower part, an increase in the mass of the grate and the need to install supports on three or four foundations.

 To reduce the area occupied by the support structure for power lines, the number of foundations and the mass of the lattice, narrow-base supports are now used that are attached to one foundation. When performing the construction of the struts of these supports, similarly to the construction of wide-base ones, the forces in the belts increase due to a decrease in the width of the strut, and due to a decrease in the slope of the belts, the forces in the belts of the upper and lower panels of each section differ significantly. Therefore, the strength of the belts selected for maximum efforts (in the lower panels) in the remaining panels of the sections is not fully used. For these reasons, the steel consumption for belts in narrow-base supports increases significantly.

 The noted drawbacks of narrow-base supports made as broad-base are partially eliminated by the use of narrow-base polyhedral racks from a bent sheet with a continuous cross section in the form of a regular polygon. The dimensions of the cross-section of a multifaceted rack in order to save material usually decrease from the maximum in the lower part to the minimum in the upper part, in accordance with the reduction of bending moments. Similar constructions have found application as typical supports for 110 and 220 kV overhead lines (see the Handbook of High Voltage Electrical Installations, M .: Energoatomizdat, 1989, pp. 425-426, as well as the Manual on the Design of Overhead Stations and Outdoor Switchgear Supports with voltage higher than 1 kV ", M .: Central Institute of Typical Design, 1989, p. 58-59).

 The disadvantage of the support with a rack of continuous multifaceted section remains a relatively large consumption of material. Since during bending, the stress in the fibers located in the region of the neutral axis of the cross section is much lower than the permissible, i.e. the strength of the material in these fibers is not fully used.

 A support structure is known in the form of a spatial truss of a polygonal cross section for power lines, including shaped belts made of sheet material that forms a rigid profile when bent, and lattice elements attached to them, while the lateral belts of the spatial truss are trihedral of separate solid metal sheets, curved along the entire height of the supporting structure, and includes planes located at an obtuse angle to each other in the form of isosceles triangles in the middle and adjacent to them along the two lateral sides of the rectangles forming the stiffening ribs of the belts, and the planes of the triangle and the rectangles are inclined to the vertical axis of the spatial truss, and the lattice elements are rigidly attached to the extreme stiffening ribs of the adjacent lateral belts and placed with them in the same plane of each side face of the spatial truss while the rectangular stiffeners of adjacent belts are parallel to each other, the ends of the lattice elements of adjacent side faces of the truss are attached to common nodes and its zones, the support structure in the cross section at the base nodes and connections made octagonal sectioned, and the top of the support structure is formed in a quadrangular plane (RU, Application 94020592, E 04 H 12/00, publ. 1996).

 This design of the transmission line support is adopted as a prototype.

The supporting structure according to this solution has high mechanical strength due to the choice of a rational configuration of the cross section, variable along the entire length of the frameless spatial truss. However, with increasing loads acting on the support, for example, for increased transitional supports, when using large cross-section wires or in areas with high wind speeds, bending moments affecting the lower part of the support increase, and, starting with a certain value of the bending moments, the solution proposed in the prototype, it is not possible to provide the required mechanical strength without increasing the base of the farm, which will translate the proposed design into the category of broad-base supports. This is determined by the fact that increasing the mechanical strength of the proposed design to the perception of bending moments can be achieved only in two ways:
- an increase in the thickness of the metal sheet used for the manufacture of trihedral belts, and for this method there is a limit on the technological capabilities of the equipment of the manufacturer and the optimal ratio of the sheet thickness and the shape of the belt;
- an increase in the base (the distance between the opposite side faces of the farm).

 In this regard, it is advisable to develop ways to increase the mechanical strength of the truss to the effects of bending moments without increasing the thickness of the metal sheet used for the manufacture of belts, and without increasing the base of the truss.

 The present invention is aimed at solving the technical problem of increasing the mechanical strength of a spatial truss to the perception of bending moments without increasing the thickness of the metal sheet of the belts and without expanding the base of the truss.

 The technical result achieved in this case is to reduce the steel consumption in the manufacture of belts and to optimize the shape of the belts according to the height of the truss in accordance with the loads acting on the height of the truss to increase the mechanical strength of the spatial truss to the perception of bending moments without increasing the thickness of the metal sheet of the belts and without expanding the base of the truss.

 The specified technical result is achieved by the fact that in the supporting structure for the power line, which is a spatial truss of a polygonal cross section, containing at least three figured belts located at a distance from each other and interconnected by lattice elements with the formation of a closed transverse contour, each shaped belt at the base is made with faces of a continuous metal sheet, curved in the transverse plane along the entire height of the supporting structure with the formation of of the given geometric shape of the central surface and the bent surfaces located at a given angle to it, forming the stiffening ribs of the belt and made of the given geometric shape, the planes of these belt surfaces are inclined to the vertical axis of the spatial truss, and the lattice elements are rigidly attached to the extreme stiffening ribs of adjacent belts and placed with them in the same plane of each side face of the spatial truss, while the stiffeners of adjacent belts are parallel to each other gu, the ends of the lattice elements of adjacent lateral faces of the truss are attached to common nodes on its belts, each figured belt at the base is made pentagonal with the formation of five planes located, the first of which is central, the other two side surfaces adjacent to the central surface are located on two side its sides at right angles to it, the two extreme surfaces adjacent to the side surfaces are oblique to the side surfaces, and the central surface of the belt is made in the form of an isosceles triangle, or rectangle, or trapezoid.

 Moreover, each lateral surface adjacent to the central surface of the belt along its lateral side, as well as each extreme surface adjacent to the lateral surface of the belt, is made in the form of a rectangle or triangle, or trapezoid with the location of the base of each triangle or larger base of each trapezoid in the base of the farm.

 In the cross section at the base of the truss, it can be made hexagonal, and the top of the supporting structure in plan can be made quadrangular or octagonal or hexagonal.

 These distinguishing features are new in comparison with the known analogues and, together, are necessary to achieve a new technical result, which consists in creating a lightweight quick-mount support structure for a high voltage power line, which has increased stability and mechanical strength in normal and emergency conditions.

The essential features of this supporting structure in the form of a spatial truss are:
- pentahedral design of the spatial truss belts with solid planes in the form of geometric figures from a seamless sheet metal sheet;
- inclined placement to the vertical axis of the spatial truss;
- placement of stiffening ribs of the belts in the form of lateral and extreme planes as parts of its surface;
- the location of the planes of the belt at predetermined angles with respect to each other;
- the execution of the surface of the belt in the form of an isosceles triangle or trapezoid or rectangle.

The invention is illustrated by drawings, where
figure 1 shows a General view of the spatial truss of the supporting structure with a quadrangular upper belt, the first embodiment, the central plane is a triangle, the lateral planes are a triangle, the extreme planes are a rectangle;
in FIG. 2 - the same as in figure 1, the second example of execution, the central plane is a triangle, the lateral planes are a triangle, the extreme planes are a trapezoid;
figure 3 is a General view of the spatial truss of the supporting structure with an octagonal upper belt, the first embodiment, the central plane is a trapezoid, the lateral planes are a triangle, the extreme planes are a trapezoid;
in FIG. 4 - the same as in Fig. 3, the second embodiment, the central plane is a rectangle, the lateral planes are a triangle, the extreme planes are a trapezoid;
in FIG. 5 is the same as in FIG. 3, the third embodiment, the central plane is a trapezoid, the lateral planes are a triangle, the extreme planes are a trapezoid;
in Fig.6 - the same as in Fig.3, the fourth embodiment, the central plane is a rectangle, the lateral planes are a triangle, the extreme planes are a rectangle;
Fig.7 is a General view of the spatial truss of the supporting structure with a hexagonal top belt, the first embodiment, the central plane is a trapezoid, the side planes are a rectangle, the extreme planes are a trapezoid;
in FIG. 8 - the same as in Fig. 7, a second embodiment, the central plane is a trapezoid, the lateral planes are a trapezoid, and the extreme planes are a trapezoid;
in FIG. 9 - the same as in Fig. 7, a third embodiment, the central plane is a rectangle, the lateral planes are a trapezoid, and the extreme planes are a rectangle;
in FIG. 10 - the same as in Fig. 7, a fourth embodiment, the central plane is a rectangle, the lateral planes are a trapezoid, and the extreme planes are a trapezoid;
in FIG. 11 is the same as in FIG. 7, a fifth embodiment, the central plane is a trapezoid, the lateral planes are a rectangle, and the extreme planes are a rectangle;
in FIG. 12 is the same as in FIG. 7, a sixth embodiment, the central plane is a trapezoid, the lateral planes are a trapezoid, and the extreme planes are a rectangle;
in Fig.13 is the same as in Fig.7, the seventh embodiment, the central plane is a rectangle, the lateral planes are a rectangle, the extreme planes are a trapezoid.

 According to the present invention, the support structure is a spatial truss of a polygonal cross-section for power lines, including figured belts made of curved in the transverse plane of the sheet material and lattice elements attached to them in the form of braces, by means of which these belts are interconnected. The supporting structure of the lattice spatial form with belts of variable cross-sectional length contains at least three curly belts, preferably four, spaced apart from each other and interconnected by braces to form a closed transverse contour.

 Each curly belt is made of a continuous metal sheet bent over the entire height of the supporting structure to form planes located at predetermined angles to each other, the first of which being central, can be shaped in the form of a given geometric figure (for example, an isosceles triangle or trapezoid , or rectangle, Figs. 1, 3, 4), the other two adjacent to the central one on its two lateral sides, which are lateral, are also made in shape in the form of a given geometric shape (for example , isosceles or right triangle or trapezoid, or rectangle, 6, 7, 9), and two planes located on the sides of the sides of the lateral planes, which are extreme can also be made in the form of a given geometric shape (for example, an isosceles or right triangle or trapezoid (Fig. 5), or rectangle (Fig. 6.) The planes adjacent to the central along its two lateral sides form the stiffening ribs of the belt.

 Each shaped belt at the base is made pentahedral with the formation of five planes located, the first of which is central, the other two side surfaces adjacent to the central surface are located on its two lateral sides at right angles to it, the two extreme surfaces adjacent to the side surfaces, located at an obtuse angle to the side surfaces. In this case, the base of each triangle or the larger base of each trapezoid should be located at the base of the truss.

 The planes of the surfaces of the pentagonal belt are inclined to the vertical axis of the spatial truss, and the lattice elements are rigidly attached to the extreme stiffeners of adjacent belts and placed with them in the same plane of each extreme face of the spatial truss, the ends of the lattice elements of adjacent lateral edges of the truss are attached to common nodes on its belts .

 In cross section at the base of the farm is made hexagonal, and the top of the supporting structure in plan is made quadrangular or octagonal, or hexagonal, depending on the magnitude of the loads acting on the farm.

 The surfaces of two adjacent pentahedral belts by combining adjacent adjacent extreme surfaces can be made combined from one continuous sheet material of a curved profile (illustrative example is not given).

 The following is an example of a specific embodiment of the invention.

 The support structure for the power transmission line of FIG. 1 is made in the form of a spatial truss, which includes curly corner belts 1 with a central, for example, triangular face 2, two, for example, triangular shaped side faces 3, two rectangular shaped, extreme edges 4 and lattice elements in the form of braces 5.

 The spatial truss of the supporting structure of the power transmission line in figure 1 is formed by four curly belts interconnected by lattice elements. Each truss belt 1 is made five-sided from a continuous sheet of thickened rolled metal of a curved cut, curved into five flat geometric shapes in the form of an isosceles triangle forming the middle central face 2 of belt 1, in the form of triangles forming side faces 3, and in the form of rectangles forming two extreme edges 4 of this farm belt.

 The two extreme flat faces 4 adjoin at an obtuse angle to the flat lateral faces 3 of belt 1, and the latter adjoin the central face at a right angle and act as stiffeners.

 One extreme face 4 of each neighboring belt 1 is placed in the plane adjacent to them at the extreme edge of the farm, and is at the same time an integral part of this side face along its entire height.

 The lattice elements in the form of braces 5 are rigidly overlapped to the inner surfaces of the extreme edges 4 of the adjacent belts 1 and are placed along the entire height of the side edges, and the braces of the 5 adjacent lateral edges of the truss are joined in the common attachment points of the adjacent belt 1. The lattice elements can be made of corner or round profile.

 Thus, the supporting structure is a spatial truss with at least three trihedral belts and three lattice faces. The cross section of each belt continuously decreases from the lower end to the upper end due to a change in the width of the central and lateral faces. Lattice elements can be made from a rolled or bent corner, as well as from a round profile or pipe; fastening to the extreme edges of the belts is possible by welding or bolts.

 The inclination of the axes of the belts and the angle between their faces are selected so that the width of the lattice faces is constant in height of the structure, which is convenient for unification of the elements of the lattice.

 In FIG. Figure 2 shows an example of a truss with a quadrangular upper belt, in which the central plane is a triangle, the lateral planes are a triangle, and the extreme planes are a trapezoid.

 Figure 3 shows a general view of the spatial truss of the supporting structure with an octagonal upper girdle, in which the central plane is a trapezoid, the lateral planes are a triangle, and the extreme planes are a trapezoid.

 In FIG. 4 shows an example of a truss with an octagonal upper girdle, in which the central plane is a rectangle, the lateral planes are a triangle, and the extreme planes are a trapezoid.

 In FIG. Figure 5 shows an example of a truss with an octagonal upper girdle, in which the central plane is a trapezoid, the lateral planes are a triangle, and the extreme planes are a trapezoid.

 In FIG. Figure 6 shows an example of a truss with an octagonal upper girdle, in which the central plane is a rectangle, the lateral planes are a triangle, and the extreme planes are a rectangle.

 Fig. 7 shows a general view of a spatial truss of a supporting structure with a hexagonal top belt, in which the central plane is a trapezoid, the lateral planes are a rectangle, and the extreme planes are a trapezoid.

 In FIG. Figure 8 shows a general view of the spatial truss of the supporting structure with a hexagonal upper belt, in which the central plane is a trapezoid, the lateral planes are a trapezoid, and the extreme planes are a trapezoid.

 In FIG. Figure 9 shows a general view of a spatial truss of a supporting structure with a hexagonal top belt, in which the central plane is a rectangle, the lateral planes are a trapezoid, and the extreme planes are a rectangle.

 In FIG. 10 shows a general view of the spatial truss of the supporting structure with a hexagonal upper belt, in which the central plane is a rectangle, the lateral planes are a trapezoid, and the extreme planes are a trapezoid.

 In FIG. 11 is a general view of the spatial truss of the supporting structure with a hexagonal upper belt, in which the central plane is a trapezoid, the lateral planes are a rectangle, and the extreme planes are a rectangle.

 In FIG. 12 is a general view of the spatial truss of the supporting structure with a hexagonal top belt, in which the central plane is a trapezoid, the lateral planes are a trapezoid, and the extreme planes are a rectangle.

 in Fig.13 is a General view of the spatial truss of the supporting structure with a hexagonal upper belt, in which the central plane is a rectangle, the lateral planes are a rectangle, and the extreme planes are a trapezoid.

 The long support structure can be made for ease of transportation and installation sectionally from composite figuratively bent along the edge of sheet metal strips attached to each other by upper and lower edges, for example, using flange joints built from the inside of them, made of a corner or flat profile and by welding.

 Such a construction of a spatial truss from solid figuredly bent metal sheets with a larger cross-sectional area at the base of the supporting structure than the cross-sectional area at the top of the support has high mechanical strength to bending and operating conditions and torsional loads of emergency modes of high voltage power lines.

 The present invention is industrially applicable, since its implementation does not require special technology other than that currently used in the manufacture of truss structures.

Claims (6)

 1. The support structure for the power line, which is a spatial truss of a polygonal cross section, containing at least three curly belts located at a distance from each other and interconnected by lattice elements to form a closed transverse contour, each curly belt at the base is made with faces of a continuous metal sheet bent in the transverse plane along the entire height of the supporting structure with the formation of a given geometric shape of the central surface and bent surfaces located at a given angle to it, forming the stiffening ribs of the belt and made of a given geometric shape, the planes of these belt surfaces are inclined to the vertical axis of the spatial truss, and the lattice elements are rigidly attached to the extreme stiffening ribs of adjacent belts and placed with them in the same plane each side face of the spatial truss, while the stiffeners of adjacent belts are parallel to each other, the ends of the lattice elements of the adjacent side faces of the fe we are attached to common nodes on its belts, characterized in that each figured belt at the base is made pentagonal with the formation of five planes located, the first of which is central, the other two side surfaces adjacent to the central surface are located on its two lateral sides under the straight angle to it, two extreme surfaces adjacent to the side surfaces are located at an obtuse angle to the side surfaces, the central surface of the belt is made in the form of an isosceles triangle, or right flax, or trapezoid.  2. The supporting structure according to claim 1, characterized in that each side surface adjacent to the central surface of the belt along its lateral side is shaped in the form of a rectangle, or a triangle, or a trapezoid.  3. The supporting structure according to claim 1, characterized in that each extreme surface adjacent to the side surface of the belt is shaped in the form of a rectangle, or a triangle, or a trapezoid.  4. The supporting structure according to claim 1, characterized in that in the cross section at the base of the truss is made hexagonal, and the top of the supporting structure in plan is made quadrangular, or octagonal, or hexagonal.  5. The supporting structure according to claim 1, characterized in that the base of each triangle or the larger base of each trapezoid is located at the base of the truss.  6. The supporting structure according to claim 2 or 3, characterized in that the base of each triangle or the larger base of each trapezoid is located at the base of the truss.

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