RU2450110C2 - Tower body of overhead transmission line - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: tower body of overhead transmission line is made of metal formed section which cross-section looks like half of polygon. Width of side edges of the latter is decreased with height and outermost side edges have flat end bends located in one plane and connected by array elements forming surface of additional edge. Number n of side edges is selected on found out dependency.

EFFECT: reduction in metal consumption by tower bodies due to optimal number of edges and simplification of tower bodies maintenance during operation without special attachments or hoisters due to selected form and location of array elements.

2 cl, 3 dwg

Description

The technical solution relates to the construction, namely the construction of power lines, in particular to long bearing structures, for example, uprights of towers of an overhead power line.

A mast is known, including a shell with a cross section in the form of an equilateral polygon, made with the number of faces determined by the established relationship (see USSR author's certificate No. 1414956, Е04Н 12/08, publ. 07.08.1988).

A section in the form of an equilateral polygon has equal moments of resistance along the axes of the Cartesian coordinates. But the loads on the struts of supports along the air line are greater than the loads across the line, therefore, the moments of resistance of the struts of supports along and across the air line should be different. Failure to take this circumstance into account in a well-known solution leads to excessive metal consumption.

Also known is the support pole of the power line (see certificate of the Russian Federation for utility model No. 34192, ЕНН 12/00, published on November 27, 2003), made of two bent sheet profiles and having a variable cross-sectional height. The profiles are interconnected, and the cross section has the shape of an elongated hexagon formed from two halves of a regular hexagon, divided in the middle of its opposite sides, which are interconnected by slats or braces. The distance in the light between the halves of the regular hexagon is selected from the condition that the ratio of the moments of resistance of the cross section of the composite rod of the rack along the axes of the Cartesian coordinates are within 1.2 ÷ 2.0.

The design of such a rack of a power line can reduce metal consumption, but it is difficult to manufacture.

The closest in technical essence and the totality of technical features is a lengthy load-bearing structure such as a rack of a support for a power line, including side faces with stiffeners, made of bent metal sheets sectionally connected to each other, making up its triangular cross section. The surfaces of the two lateral faces and stiffeners of each section of the rack are made of a continuous V-shaped curved curved sheet strip with end bends, forming three profiles of bends of the sheet rigid profiles of the corner belts of the supporting structure, two adjacent equal sides in the form of trapezoidal planes, two flat end bends of the sheet stiffeners in the form of parallelograms, inclined at an obtuse angle to the planes of adjacent side faces and fastened to each other by etki forming surface of the third side face in the form of an equilateral trapezoid supporting structure. Stiffening ribs are located symmetrically on different sides of the latticed side face on the same plane with it (see RF patent for invention No. 2083785, Е04Н 12/00, publ. 07/10/1997).

The disadvantage of such a lengthy supporting structure is its increased metal consumption, since for a given metal thickness, the width of the side face is limited by local stability. The presence of only two side faces in this design leads to an inevitable increase in the width of these faces, and, consequently, to the need to increase the thickness of the sheet of metal according to local stability. In addition, this design has a large area for wind load due to the increased elongation of this structure along the axis of the overhead line, which leads to an increase in the load on the support, and therefore, to increase the metal consumption of the support.

The technical task is to reduce the metal consumption of the supports by choosing the optimal number of its side faces.

An additional advantage is the simplification of maintenance of supports during operation without devices or lifting mechanisms due to the selected shape and location of the spacers.

The problem is achieved in that in the rack of the support of an overhead power line made of a bent metal profile, the cross section of which looks like half a polyhedron, while the width of the side faces of the latter decreases in height, and the extreme side faces have flat end bends located in the same plane and interconnected by lattice elements forming the surface of an additional face, according to the technical solution, the number n of side faces is selected from the condition of providing local th stability at the minimum possible thickness t of the metal according to the formula:

,

,

where M ^p is the calculated value of the bending moment in the lower section of the support strut,

- произведение наибольшей условной гибкости

на эффективность

использования металла,

- the product of the greatest conditional flexibility

on efficiency

use of metal

W is the moment of resistance of the lower section of the support strut,

S is the lower cross-sectional area of the support strut,

E is the modulus of elasticity of the metal,

R _y is the design resistance of the metal.

It is known that the size of the side h _{ef of the} cross section of a polyhedron under local stability conditions should be no more than

If the cross-sectional side of the polyhedron exceeds this value, it is necessary to increase the thickness t of the metal. But from the point of view of saving metal, it is more efficient to increase the number of sides of a polyhedron, rather than the thickness t of the metal. This position is implemented in the proposed technical solution.

использования металла в предлагаемом техническом решении примерно на 20% выше, чем у прототипа. Т.е. момент W сопротивления в предлагаемом техническом решении на 20% выше, чем у прототипа при равных площадях S сечений. Или вес стойки опоры у предлагаемого решения примерно на 20% меньше, чем у прототипа, при равных моментах W сопротивления.Calculations show that by increasing the number of n side faces, the efficiency

the use of metal in the proposed technical solution is approximately 20% higher than that of the prototype. Those. the moment W of resistance in the proposed technical solution is 20% higher than that of the prototype with equal cross-sectional areas S. Or the weight of the support strut of the proposed solution is about 20% less than that of the prototype, with equal moments of resistance W.

In addition, when the support is installed in a position where the plane of the end bends of the extreme lateral faces is perpendicular to the axis of the air line, and this is how the supports are installed for the prototype, and in the proposed solution, increasing the number of n faces reduces the projection area of the support structure when the wind is angled both 90 ° and 45 ° to the axis of the overhead line. And this leads to a decrease in wind loads on the support in normal conditions and, therefore, to reduce the metal consumption of the support.

It is advisable for servicing the supports during operation without attachments or lifting mechanisms, so that the lattice elements connecting the flat end bends of the extreme side faces are made in the form of horizontally spaced metal spacers with the orientation of the cavity corners in the direction of the cavity of the support strut.

To reduce flexibility, these horizontal spacers are made of metal corners with a vertical step that allows a person to safely lift onto a support. To be able to use hot-dip galvanizing as an anti-corrosion coating, horizontal spacers are welded to the flat bends of the extreme edges with a "house", i.e. with the orientation of the cavity of the corners in the direction of the cavity of the strut support.

The essence of the technical solution is illustrated by an example of a specific embodiment and by drawings, where it is shown: in Fig. 1 is a general view of a strut of a support of an overhead power line, in Fig. 2 is a section A-A in Fig. 1, in Fig. 3 is a view B in Fig. 1 (fragment).

The support of the overhead power transmission line consists of a bent metal profile 1 (Fig. 1), the cross-section of which looks like half a polyhedron with two flat end bends 2 of the extreme side faces (Figs. 1, 2). Flat end bends of 2 extreme faces are located in the same plane and are interconnected by welding with lattice elements. The lattice elements are horizontally spaced struts 3 made of metal corners (figure 1), forming the surface of an additional face. The width of the side faces 4 (figure 2) decreases in height. The thickness of the sheet bent metal profile is t (figure 2). The number n of side faces 4 (figure 2) is selected from the condition of ensuring local stability at the minimum possible thickness t of the metal according to the formula:

where M ^p is the calculated value of the bending moment in the lower section of the support strut,

- произведение наибольшей условной гибкости

на эффективность

использования металла,

- the product of the greatest conditional flexibility

on efficiency

use of metal

W is the moment of resistance of the lower section of the support strut,

S is the lower cross-sectional area of the support strut,

E is the modulus of elasticity of the metal,

R is the calculated metal resistance.

The horizontally located spacers 3 (Fig. 1) are made with a step h, which allows a safe lifting of a person on a support. To be able to use hot dip galvanizing as a corrosion-resistant coating, horizontally placed spacers 3 (Fig. 3) are welded to the flat end bends of the extreme edges with a "house", i.e. with the orientation of the cavity of the corners in the direction of the cavity of the strut support.

Claims (2)

1. The support of the overhead power line, made of a bent metal profile, the cross-section of which looks like half a polyhedron, while the width of the side faces of the latter decreases in height, and the extreme side faces have flat end bends located in the same plane and interconnected by elements lattices forming the surface of an additional face, characterized in that the number n of lateral faces is selected from the condition of ensuring local stability at the minimum possible thickness t Ferrous materials of formula

where M ^p - the estimated value of the bending moment in the lower section of the support strut;

- the product of the greatest conditional flexibility

on efficiency

use of metal;
W is the moment of resistance of the lower section of the support strut;
S is the lower cross-sectional area of the support strut;
E is the modulus of elasticity of the metal;
R _y is the design resistance of the metal. 2. The support of the overhead power transmission line according to claim 1, characterized in that the said lattice elements are horizontally spaced struts made of metal corners with the orientation of the cavity of the corners in the direction of the cavity of the support strut.

Images