RU2303112C1 - Power transmission tower structure - Google Patents

Abstract

FIELD: towers, masts, poles and similar structures, methods of erecting such structures.

SUBSTANCE: tower structure is made as three-dimensional truss, which comprises figured belts spaced a distance one from another and connected with each other through grid members so that closed transversal profile is created. Each figured belt has faces made of solid metal sheet curved in transversal plane for the full tower structure height to impart predetermined shape to central surface and bent surfaces extending therefrom at obtuse angles. The central surface is made as two isosceles triangles or rectangles or trapezes. The bent surfaces define stiffening ribs of the belt and have predetermined shapes. Above belt surface planes are inclined to vertical three-dimensional truss axis. Grid members are fixedly secured to extreme stiffening ribs of adjacent belts. Grid members and stiffening ribs are in single plane with each side face of three-dimensional truss. Stiffening ribs of adjacent belts are parallel to each other. Ends of grid members in adjacent side truss faces are fastened to common joints of truss belts. Each profiled belt has hexahedral base and define six planes. The first two planes are inclined one to another along the full tower structure height and define central surface. Two other side surfaces adjacent to central surface are connected to two sides thereof and extend at obtuse angles to adjacent central surface plane. Two extreme surfaces adjoining side ones are at obtuse angle to side surfaces.

EFFECT: increased strength of three-dimensional truss taking bending moments without increase of metal sheet thickness used for belt forming and without truss base widening.

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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).

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 metal continuous 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, the planes of the triangle and the rectangles being 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 lateral face of the spatial truss while 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).

The supporting structure for 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 wide-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 thickness of the sheet and the shape of the belt;

- an increase in the base (the distance between the opposite side faces of the farm).

A support structure for a power line is known, 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 to form a closed transverse contour, each figured 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 surface, and bent surfaces located at a given angle to it, forming stiffeners of the belt and made of a given geometric shape, the planes of these surfaces of the 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 one plane of 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 adjacent lateral g trusses 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 its two lateral sides at right angles 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 rectangle, or apecia (RU, Pat. No. 2197586, ЕНН 12/10, publ. 01/27/2003).

The disadvantage of this design is that to ensure sufficient bending stiffness of the Central surface of the figured belt when it is flat, you must either increase the thickness of the sheet or increase the length of the base, which leads to increased consumption of metal.

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

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 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 made of curly belts located at a distance from each other and interconnected by connecting elements with the formation of a closed transverse contour, each curly belt is made curved in the transverse plane along the entire height of the supporting structure with the formation of a given geometric shape of the Central surface, made in the form located under a blunt scrap to one another of two isosceles triangles, or rectangles, or trapezoids, and bent surfaces located at an obtuse angle to it, forming the stiffening ribs of the belt and made of a given geometric shape, and the connecting elements are attached to the extreme stiffening ribs of the adjacent belts and placed with them in one the plane of each side face of the spatial truss, each figured belt at the base is made of hexagonal from a continuous metal sheet bent in the transverse plane or from welded between battle along the height of the truss of individual metal sheets, with the formation of six planes located obliquely to the vertical axis of the spatial truss or parallel to the latter, the first two of which are located at an obtuse angle to each other over the entire height of the supporting structure and form a central surface, two other side surfaces adjacent to the central surface are located on its two lateral sides at an obtuse angle to the adjacent plane of the central surface, and the two extreme surfaces, approximately Sticking to the side surfaces are located at an obtuse angle to the side surfaces.

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 with increased stability and mechanical strength in normal and emergency conditions.

The invention is illustrated in the drawing, which shows a General view of the spatial truss of the supporting structure with a hexagonal belt.

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 connecting elements attached to them, for example, lattices 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 shaped belts located at a distance from each other and interconnected by braces to form a closed transverse contour.

Each figured belt is made of a continuous metal sheet bent in cross section along the entire height of the supporting structure, or from individual metal sheets welded together along the height of the truss with the formation of surfaces located at predetermined angles to each other, the first of which, being central, can be made in the form in the form of two given geometry of figures (for example, isosceles triangles or trapezoids, or rectangles), the other two adjacent to the central one on its two lateral sides, are which are lateral, are also made in shape in the form of a given geometric figure (for example, an isosceles or right triangle or trapezoid, or rectangle), 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 figure ( for example, an isosceles or right triangle or trapezoid, or rectangle). 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 hexagonal with the formation of six planes located, the first two of which are located at an obtuse angle to each other over the entire height of the supporting structure and form a central surface, two other side surfaces adjacent to the central surface are located on its two lateral sides at an obtuse angle to an adjacent plane of the central surface, and the two extreme surfaces adjacent to the side surfaces are located at an obtuse angle to the side surfaces.

The planes of the surfaces of the hexagonal belt are inclined to the vertical axis of the spatial truss or parallel to the latter, 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 her belts.

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

The support structure for the power transmission line (drawing) is made in the form of a spatial truss, which includes curly corner belts 1 with a central, for example, triangular in plan plan face, formed from two height-high supporting structures at an angle to each other of connected planes 2, two, for example, made side-shaped triangular faces 3 and two rectangular shaped, extreme edges 4, as well as lattice elements in the form of braces 5.

The spatial truss of the support structure of the power transmission line (drawing) is formed by four curly belts interconnected by lattice elements. Each farm belt 1 is made of hexagon from a continuous sheet of thickened rolled metal of a curved cut, curved into six flat geometric shapes in the shape 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 side faces 3 of belt 1, and the latter abut against the central face at an obtuse angle to adjacent planes forming a central surface and perform the function of 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 lapped 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.

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 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 working mode loads and twisting loads of emergency high voltage power transmission 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 (1)

The support structure for the power line, which is a spatial truss made of figured belts located at a distance from each other and interconnected by connecting elements to form a closed transverse contour, each figured belt is made curved in the transverse plane along the entire height of the supporting structure to form a predetermined the geometric shape of the central surface, made in the form of two isosceles triangles, or rectangles, or trapezoids, and is located bent surfaces at an obtuse angle to it, forming the stiffening ribs of the belt and made of a given geometric shape, and the connecting elements are attached to the extreme stiffening ribs of the adjacent belts and placed with them in the same plane of each side face of the spatial truss, characterized in that each figured belt in the base is made of hexagonal from a continuous metal sheet bent in the transverse plane or from individual metal sheets welded together along the height of the truss with the formation of six flat bones located obliquely to the vertical axis of the spatial truss or parallel to the latter, the first two of which are located at an obtuse angle to each other over the entire height of the supporting structure and form a central surface, two other lateral surfaces adjacent to the central surface are located on its two lateral sides at an obtuse angle to an adjacent plane of the central surface, and the two extreme surfaces adjacent to the side surfaces are located at an obtuse angle to the side surfaces.