RU127796U1 - ELECTRIC TRANSMISSION LONG-CARRYING STAND (OPTIONS) - Google Patents

Abstract

1. A long support column of the power line, containing two side faces with stiffeners each, made of bent metal sheets and forming an open triangular cross section, each side face is made in plan in the form of an irregular quadrangle, and the stiffener bent from each side face is tilted under obtuse or acute angle to the surface of the side face, and the ribs of the side faces are fastened to each other by elements of the lattice forming the surface of the third side face of the triangular cross-section of the rack in plan, characterized in that each side face with a stiffener is made of a single sheet having a height of the rack, or several sheets welded together, in which the stiffener is obtained by bending the edge part on one side of this sheet, two side the faces are connected to each other, with each side face made in the plan in the form of an irregular quadrangle or rectangle, and the stiffener bent from it is made in the form of an irregular quadrangle in the plan.2. The rack according to claim 1, characterized in that the lattice elements are welded to the stiffeners from their outer side. The rack according to claim 1, characterized in that it is provided with a pipe immersed in the ground, which is the foundation, and through holes are made in each side face at its base in the rack for attaching the base of the rack to the pipe with clamps or brackets covering the pipe, and the ends of which are missing through the indicated holes. 4. Long-length support pillar of the power line, which is a long-length design of a continuous V-shaped curved

Description

The utility model relates to construction, in particular, to long-length load-bearing structures such as a rack of a support of a power transmission line (transmission line).

A long-length support strut of a power transmission line is known, including side faces with stiffeners made of bent metal sheets sectionally connected to each other, making up its triangular cross section, the surfaces of two side faces and stiffeners of each section of the stand are made of a continuous V-shaped curved curved sheet strip with end bends forming three edges of the bends of the sheet rigid profiles of the corner belts of the supporting structure, two adjacent adjacent planes of equal size shackles in the form of trapezoids, 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 lattice elements forming the surface of the third side face in the form of an isosceles trapezoid of the supporting structure, while the stiffeners are located symmetrically from different sides of the latticed side face on the same plane with it (RU No. 2083785, publ. 07/10/1997).

This rack has good mechanical characteristics for the intermediate supports of power lines. However, for anchor-type supports, such a rack is not optimal, due to the fact that the cross-section of the rack decreases in height of the support, which determines the increased flexibility of the rack. The increased flexibility of the rack leads to the fact that when mechanical loads are applied to it, the top of the rack deviates significantly from the vertical. If this situation is quite acceptable for intermediate supports, then for anchor-type supports this can lead to an increase in the arrows of the wire sag, as a result of which the permissible clearance to the ground can be violated. In addition, the increased flexibility of the anchor type supports significantly complicates the installation of the wire, as the stand deviates from the vertical under the influence of the pulling force of the wires, as a result, it becomes difficult to provide the same sag arrows in the wires of all phases.

This utility model aims to increase the operational reliability of the rack structure and reduce the increased flexibility of the upper part of the anchor type supports.

The specified technical result for the first embodiment is achieved by the fact that the lengthy load-bearing strut of the power transmission 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 two side faces and stiffeners of each section of the rack 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 carrier structures, two adjacent equal planes between them, adjacent side faces in the form of irregular quadrangles, two flat end bends of a sheet of stiffener in the form of irregular quadrangles, oblique at an obtuse or acute angle to the planes of adjacent side faces and fastened to each other by lattice elements that form the surface of the third lateral face in the form of irregular quadrangles of the supporting structure, while the stiffeners are located symmetrically from different sides of the lattice laterally faces on a plane with her.

The specified technical result for the second embodiment is achieved by the fact that in a long support column of a power line containing two side faces with stiffeners each made of bent metal sheets and forming an open triangular cross section, each side face is made in plan in the form of an irregular quadrangle, and the stiffener bent from each side face is inclined at an obtuse or acute angle to the surface of the side face, and the stiffeners of the side faces are fastened to ug with other elements of the lattice, forming the surface of the third lateral face of the triangular cross-section of the rack in plan, each side face with a stiffening rib is made of a solid sheet having the height of the strut, or several sheets welded together, in which the stiffener is obtained by bending the edge part with one side of this sheet, two side faces are connected to each other, while each side face is made in plan in the form of an irregular quadrangle, the stiffener bent from it is made in the form Rectangle or triangle or trapezium in plan, and at the front in its upper part is fixed brace attachment element.

These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

This useful model is illustrated by specific examples of execution, which, however, are not the only possible ones, but clearly demonstrate the possibility of achieving the desired technical result.

Figure 1 presents a General view of a long bearing rack of power lines, a view from the side of the grill;

figure 2 - presents a General view of a long bearing rack of power lines, a view from the side of the side faces;

figure 3 is an example of the execution of the foundation for the power transmission lines of figure 1 and 2. View from the side of the lattice;

figure 4 is the same as in figure 3, a view from the back side;

figure 5 - the upper part of the rack of the power lines with an element of attachment strut;

Fig.6 is the same as in Fig.5, a view from the back;

Fig.7 - a long bearing rack of power lines with a strut;

Fig.8 is the same as in Fig.7, on the leader shows the attachment site with 2 clamps and 4 holes.

The present utility model contemplates the construction of a lengthy load-bearing strut of a transmission line support. To solve the problem of limiting the flexibility of the struts of anchor-type supports, it is proposed to perform a cross-section of the rack constant over its entire height.

The lengthy load-bearing pillar of the power transmission line includes lateral faces with stiffeners made of bent metal sheets sectionally connected to each other, making up its triangular cross section. The surfaces of 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 and welded together with the formation of three ribs in the places of bending of the sheets. These bends form rigid profiles of the corner belts of the supporting structure. Adjacent lateral faces in the form of parallelograms form two equally large planes, two flat end bends are made in the form of irregular quadrangles, inclined at an obtuse or acute angle to the planes of adjacent side faces and fastened to each other by lattice elements, which forms the surface of the third side face in the form of an irregular quadrangle supporting structure. These stiffeners are located symmetrically on different sides of the lattice side face on the same plane with it.

The following is a specific example of a rack.

The lengthy load-bearing structure of the power transmission column support (Figs. 1-3) includes two side faces 1 and 2, each of which is made with a stiffener 3. Each side face 1 and 2, having a stiffener 3, is made of a solid sheet having the height of the rack, in which the stiffener 3 is obtained by bending the edge part on one side of this sheet. The stiffener 3 bent from each side face is inclined at an obtuse or acute angle to the surface of the side face. Two side faces 1 and 2 are connected (adjacent) to each other by edge parts 4 on the other side and are welded by intermittent or continuous weld along the height of the rack.

Thus, the rack is made of two parts, each of which is cut out of the sheet and exposed at one edge along the long side of the bend of this edge. Thus, it is possible to obtain a single piece without additional welds. You can make part of the workpiece from two or three sheets, which are welded along the length of the part of the workpiece to each other.

Two such blanks are placed at an angle to each other along the planes of the side faces and welded to each other so that an open profile of a triangular shape is formed (an open triangular cross section is formed). This design of workpieces simplifies the technology of producing the rack, as it allows you to weld the rack from two blanks and transport it assembled from the factory (where cutting and bending is performed) to the field site to where the rack is installed on the foundation 6. Improving manufacturability, among other things, leads to to simplify the design and the ability to significantly accelerate the process of mounting racks for power lines while reducing transport operations.

The use of an intermittent weld provides sufficient strength at a high height (along the length of the strut) and eliminates the possibility of warpage of the strut during welding, which can be observed when welding with a continuous weld. But this does not limit the connection of the rack parts to a continuous weld.

Each side face is made in the plan in the form of an irregular quadrangle, and the stiffener bent from it is also made in the form of an irregular quadrangle in the plan and is inclined at an obtuse or acute angle to the surface of the side face. In terms of the cross section, the stiffeners 3 are directed in different directions, and their outer 7 surfaces lie in the same plane. It is possible that the stiffeners can be bent towards each other, that is, at an acute angle to the surface of the side face. In cross section, these stiffeners will be directed inward and towards each other. This example is not shown illustratively.

An embodiment of a lengthy load-bearing pillar in the form of a structure of a continuous V-shaped curved curved sheet strip forming an open triangular cross section in plan and containing two side faces with stiffeners each is possible. Each side face is made in plan in the form of an irregular quadrangle, and the stiffener bent from each side face is inclined at an obtuse or acute angle to the surface of the side face. Also, each side face is made in the plan in the form of an irregular quadrangle of the rectangle, and the stiffener bent from it is made in the form of an irregular quadrangle in the plan.

The stiffening ribs of the side faces are fastened to each other by the lattice elements 8 (braces in the form of corners, plates, pipes, rods and other profile elements of standard rolled products, etc.), which forms the surface of the third side face of an already closed triangular cross-section in a plan shape ( figure 3 or 4). Such a lattice provides the rigidity of the rack and allows you to use it as a ladder to lift the installer to the top when servicing the electrical part of the transmission line support.

The lattice elements 8 are located on the same plane with the stiffeners 3 and, together with the opposite belts 1, form a third side face that determines the rigidity of the supporting structure of the rack. The plane of the third side face can be made in the form of an isosceles trapezoid or rectangle depending on the shape of the stiffener. The lattice elements 8 can be welded to the stiffeners from their outer side (Fig. 1).

The supporting strut with a cross-section in the form of a triangle is highly stable in the direction of the longitudinal axis of the power line, and stability in the transverse direction is ensured by the planes of the stiffeners. Lateral faces 1 and 2 of a solid metal sheet and lattice elements welded to stiffeners 3 enhance the mechanical strength of the supporting structure to bending loads and axial rotation in normal and emergency conditions.

Four holes are made in the lower part of the rack (at its base) (FIGS. 3 and 4), two in each belt - only in the lower part of the rack and are used to fix it on the foundation from a steel pipe 9 using steel brackets or clamps 10. These holes are made in those racks that are attached to the foundation with clamps. For racks of the same design that are attached to the foundation through a flange, these racks do not have such holes. Figure 3 shows the rack mount with two clamps and four holes.

Thus, the rack can be made with a foundation, which is a steel pipe immersed in the ground, and through holes are made in each side face at its base in the rack for attaching the base of the rack to the pipe with clamps or brackets covering the pipe and the ends of which are passed through these holes .

For accurate non-biased positioning of the stand on the pipe 9, two corners 11 of the profile are fixed vertically so that when the stand is mounted on the pipe, the latter is laid with the corners resting and cannot be displaced in the transverse direction (see the callout in FIG. 8). In addition, in the corner zone of the rack, a stop 12 is fixed to support the bottom of the rack and fix the rack from movement when tightening the clamps with bolts.

If the strength of the strut of the anchor-type supports is insufficient, it is proposed to reinforce it by strut 13 (Figs. 7 and 8). At the same time, the strut mount assembly 14 is fixed (welded by welding) to the strut of the support, and the strut and strut are attached to the foundation of the steel pipe with clamps, made by analogy with the foundation for the supporting strut. That is, the strut is supplied with a pipe immersed in the ground, which is its foundation, and through holes are made in the side walls at the base of the strut to attach the strut base to the pipe with clamps or brackets covering the pipe and the ends of which are passed through these holes.

In the upper part of the rack is equipped with a node 15, on which is fixed the system 16 for mounting wires.

This utility model is industrially applicable and allows the manufacture of load-bearing racks with a high degree of resistance to bending of its upper part, on which the wire fastening system is fixed.

Claims (8)

1. A long support column of the power line, containing two side faces with stiffeners each, made of bent metal sheets and forming an open triangular cross section, each side face is made in plan in the form of an irregular quadrangle, and the stiffener bent from each side face is tilted under obtuse or acute angle to the surface of the side face, and the ribs of the side faces are fastened to each other by elements of the lattice forming the surface of the third side face of the triangular cross-section of the rack in plan, characterized in that each side face with a stiffener is made of a solid sheet having a height of the rack, or several sheets welded together, in which the stiffener is obtained by bending the edge part on one side of this sheet, two side the faces are connected to each other, with each side face made in the plan in the form of an irregular quadrangle or rectangle, and the stiffener bent from it is made in the form of an irregular quadrangle in the plan. 2. The rack according to claim 1, characterized in that the lattice elements are welded to the stiffeners from their outer side. 3. The rack according to claim 1, characterized in that it is provided with a pipe immersed in the ground, which is the foundation, and through holes are made in each side face at its base in the rack for attaching the base of the rack to the pipe with clamps or brackets covering the pipe, and the ends which are passed through the indicated holes. 4. A lengthy load-bearing pillar of the power line, which is a long-length structure of a continuous V-shaped curved curved sheet strip, forming an open triangular cross section in plan and containing two side faces with stiffeners each, each side face is made in the plan in the form of an irregular quadrangle, and the stiffener bent from each side face is inclined at an obtuse or acute angle to the surface of the side face, and the stiffeners of the side faces are fastened to each other by ntami lattice forming the surface of the third lateral edge of the triangular cross section rack in plan, characterized in that each lateral face is formed in terms of a shape of an irregular quadrilateral or rectangular and is folded away from it a stiffening rib formed in the shape of irregular quadrangle in plan view. 5. A long support column of the power line, containing two side faces with stiffeners each, made of bent metal sheets and forming an open triangular cross section, each side face is made in the plan in the form of an irregular quadrangle, and the stiffener bent from each side face is tilted under obtuse or acute angle to the surface of the side face, and the ribs of the side faces are fastened to each other by elements of the lattice forming the surface of the third side face of the triangular cross-section of the rack in plan, characterized in that each side face with a stiffener is made of a solid sheet having a height of the rack, or several sheets welded together, in which the stiffener is obtained by bending the edge part on one side of this sheet, two side the faces are connected to each other, with each side face made in the plan in the form of an irregular quadrangle, the stiffener bent from it is made in the form of an irregular quadrangle or triangle in the plan, and on the stand in hney part of the strut mount. 6. The rack according to claim 5, characterized in that the lattice elements are welded to the stiffeners from their outer side. 7. The stand according to claim 5, characterized in that the stand is equipped with a pipe immersed in the ground, which is its foundation, and through holes are made in each side face at its base in the rack for attaching the base of the rack to the pipe with clamps or brackets covering the pipe and ends which are passed through the indicated holes. 8. The stand according to claim 5, characterized in that the strut is provided with a pipe immersed in the ground, which is its foundation, and through holes are made in the side walls at the base of the strut for attaching the base of the strut to the pipe with clamps or brackets covering the pipe and the ends of which are passed through indicated holes.

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