RU113532U1 - ELECTRIC TRANSMISSION SUPPORT STAND - Google Patents

Abstract

1. An overhead power transmission line support, comprising a body in the form of a pyramid surface segment bent from sheet steel, having seven faces, from the edges of the outermost of which sections bent towards each other are made along the body, the edges are located at a distance from each other and in the cross section of the body along a generatrix parallel to a similar generatrix of the middle face of the body, from which in both directions to the sections bent towards each other there are sequentially faces whose planes are conjugate at angles, respectively, α, β, γ from the inner side of the body, and the sections bent towards each other lie in the plane conjugate to the planes with the faces adjacent to them at an angle δ from the inner side of the body, while the values of these angles are related by the inequality γ> α> β> δ, and the sections bent towards each other are rigidly connected to each other by a set of straight steel elements welded each opposite sides to opposite sides bent towards each other friend sites. ! 2. The post according to claim 1, characterized in that it is provided with two fastening nodes located at the base of the post spaced along the length of the body for mounting the post on the cylindrical surface of the pile, each of the nodes for attaching the post on the cylindrical surface of the pile includes a ring segment, rigidly fixed transversely with mating in sections of the outer contour with the inner surface of the body and having an inner part located opposite to the sections bent towards each other in the form of a half circle for mating with the lateral surface of the pile, which continues in the direction�

Description

The utility model relates to the field of electrical equipment, and specifically to a stand of an overhead power line support, which is intended for the construction of mainly intermediate supports of overhead power lines with a voltage of 6-20 kV in areas with normal construction conditions with a seismicity of up to 9 points.

Known stand support overhead power lines, containing a housing made of sheet steel in the form of a hexagonal pyramid with equal internal angles, one face of which is made with a slot with the formation of facing towards each other edges, departing from its preceding faces and parallel to the face located opposite the slot on the other side corps. The said edges facing each other are rigidly connected by a set of transverse slats or braces (RU 2347049 C1, IPC E04H 12/08, 2009).

The stand of this known construction is not optimal to counter the load applied in the direction from the cut to the edge on the other side of the body, which corresponds to the direction of passage of the overhead power line when the known stand is used to construct an intermediate support of the power line. This is due to the fact that the transverse dimension of the face of the body located on the side opposite to the section is due not so much to considerations of optimal structural strength as to the manufacturing technology of the body, which provides for the flexible body as a whole or its individual transverse components. In addition, the known rack does not have reliable means for installation on a pile with a cylindrical lateral surface, effectively counteracting axial, bending and torque loading.

The technical result of this utility model is to expand the arsenal of means in the form of racks for the construction of intermediate supports of power lines, and the rack effectively resists the torsional and compressive loads that arise during its operation as an element of the intermediate support of an overhead power line, as well as bending loads applied in various directions with minimal material consumption and manufacturability of the design.

The indicated technical results are provided by the stable support of the overhead power line, which contains a casing in the form of a segment of a pyramid surface curved from sheet steel, having seven faces, from the edges of the extreme of which there are sections bent towards each other, located at the same distance from each other and a cross-section of the housing along a generatrix parallel to a similar generatrix of the middle face of the housing, from which on both sides to sections bent towards each other in series FLS faces are conjugate planes are at angles, respectively, α, β, γ from the interior of the housing, and bent towards each other portions lie in a plane conjugate to the planes of faces adjacent thereto at an angle δ with the inner side of the housing. The values of the mentioned angles are related by the inequality γ> α> β> δ. The sections bent towards each other are rigidly interconnected by a set of straight steel elements, each welded on opposite sides to opposite sections bent towards each other,

The rack also contains located at the base of two spaced apart along the length of the housing of the mount for mounting the rack on the cylindrical surface of the pile.

Each of the nodes for fastening the rack on the cylindrical surface of the pile includes a ring segment, rigidly transversely fixed to the interface in the sections of the outer contour with the inner surface of the housing and having an opposite half-circle opposite side bent towards each other to interface with the side surface of the pile, which continues in the direction of the sections bent towards each other by straight sections located at distances from the axis of the inner part, the value of which is not m less than the radius of the inner part, and the screed assembly, located at the level of the ring segment, which is made in the form of a lining installed transversely outside the housing between the body sections bent towards each other with the possibility of attraction to the body by threaded elements passing through the holes in the sections bent towards each other and faces opposite them through the hull. The overlay on the side facing the cavity of the body is made with a sample along the radius corresponding to the radius of the inner part in the form of half the circumference of a ring segment for interfacing with a pile.

In a preferred embodiment of the utility model, the strut comprises a strut secured by opposite ends with threaded elements of both overlays of the coupler assemblies on opposite sections of the housing bent towards each other.

Also in a preferred embodiment of the utility model, holes lying in the same geometric plane in the sections bent towards each other and opposite sides through the case for installing threaded fasteners for the lining from the base of the housing are located along the length of the housing at a distance from the ring segment of this assembly towards the base of the housing , and the holes lying in the same geometric plane in the sections bent towards each other and the faces opposite them through the case for installation and threaded fastening elements lining on the housing top arranged along the length of the housing in the region of the node ring segment toward the top of the housing.

In the best embodiment of the utility model, the angles γ, α, β, δ are, respectively, 150, 147, 138, 105 degrees. Straight steel elements in a preferred embodiment of the utility model are welded onto the outer surfaces of the sections bent towards each other to form welds.

The feasibility of the utility model is confirmed by a specific example of the construction of a stand of a support of an overhead power line, which is illustrated by drawings.

Figure 1 shows the rack of the intermediate support of an overhead power line mounted on a pile, a side view from the side of the location of the housing sections bent towards each other.

Figure 2 and figure 3 (rotated relative to figure 2 by 180 degrees) shows the cross-section of the housing, respectively, at the top and base of the rack.

Figure 4 shows the base of the rack, paired with a pile, a side view of the area of the nodes for mounting the rack on the cylindrical surface of the pile.

Figure 5 shows a longitudinal section of the base of the rack, paired with a pile, a view of the zone of location of the nodes for mounting the rack on the cylindrical surface of the pile from the side of the location of the sections of the body bent towards each other.

FIG. 6 shows a plan view of a segment of a ring of a node for fastening a stand on a cylindrical surface of a pile.

7 shows a cross section with a view of the node for mounting the rack on the cylindrical surface of the pile.

The support of the overhead power transmission line, the construction of which is shown in the drawings, comprises a housing 1 (Fig. 1) in the form of a pyramid surface segment curved from sheet steel having seven faces 2, 3, 4, 5 (Figs. 2, 3) from edges 6 extreme (3) of which along the housing 1 are made bent towards each other sections 7 and 8, located by the edges 9 at a distance from each other and in the cross section of the housing 1 along a generatrix parallel to a similar generatrix of the middle edge 2 of the housing 1, from which on both sides to the section bent towards each other At points 7 and 8, faces 3, 4, and 5 go sequentially, the planes of which are conjugated at angles, respectively, α, β, γ from the inside of the housing 1, and sections 7 and 8 bent towards each other lie in a plane conjugate with the planes adjacent to them faces 5 at an angle δ from the inside of the housing 1. The values of the mentioned angles γ, α, β, δ in this particular example are 150, 147, 138, 105 degrees, respectively, which corresponds to the inequality γ> α> β> δ, which should be performed at possible other specific angles other than the specified dimensions .

The sections 7 and 8 bent towards each other are rigidly connected to each other by a set of straight steel elements 10 (Fig. 1), each welded by opposite sides 11 and 12 to the outer surfaces of the opposite sections 7 and 8 bent towards each other. The straight steel elements 10 are made in the form corners and welded by the edges 13, 14 of the shelves with the orientation of the inner cavity to sections 7 and 8 bent towards each other with the formation of extended welds along the edges 13, 14. Straight steel elements 10 can be located transversely relative to about the housing 1, as shown in figure 1, but can be arranged as struts at an angle with a change in angle from one straight steel element 10 to the next in the form of a zigzag or in any combination of an inclined and transverse arrangement.

At the base of the rack are two spaced apart along the length of the housing 1 of the attachment node for mounting the rack on the cylindrical surface of the pile 15 (Figs. 1, 4, 5, 6, 7). Each of the nodes for fastening the rack on the cylindrical surface of the pile 15 includes a segment of the ring 16 (Fig.5, 6, 7), rigidly mounted transversely with the interface in the sections of the outer contour 17 (Fig.6, 7) with the inner surface of the housing and having located opposite bent toward each other sections 7 and 8, the inner part 18 in the form of a half circle to mate with the side surface of the pile 15, which continues in the direction of bent towards each other sections 7 and 8 straight sections 19 located at distances from the axis of the inside enney portion 18, the value of which is not less than the radius of the inner part 18.

In addition, each of the nodes for mounting the rack on the cylindrical surface of the pile 15 includes a tie assembly (Figs. 1, 4, 7) located at the level of the ring segment 16, which is made in the form of a lining 20 mounted transversely from the outside of the housing 1 between each other bent towards each other to each other by sections 7 and 8 of the housing 1 with the possibility of pulling to the housing 1 by threaded elements in the form of bolts 21 passing through the holes in sections 7 and 8 bent towards each other (not visible in the drawings) and through the holes 22 (Fig. 5) on opposite to them facets 3 through the corpus and 1, and nuts 23. The cover plate 20 on the side facing to the cavity body 1, provided with a recess 24 (Figure 7) along the radius corresponding to the radius of the inner part 18 in the shape of half a circle segment ring 16 for coupling with the pile 15.

To strengthen in order to prevent bending, the rack is equipped with a strut 25 (Figs. 1, 4), fixed by opposite ends 26 and 27 with threaded elements in the form of bolts 21 and nuts 22 of both plates 20. The heads 28 (Fig. 7) of the bolts 21 are supported on supporting segments corners 29, facing the cavities to the housing 1 and resting on the edges 30 and 31 of the shelves outside the housing 1 on its edges 3 and 4.

Holes 22 lying in the same geometric plane in sections 7 and 8 bent towards each other and opposite faces 3 through the body 1 for installing threaded elements in the form of bolts 21 for fastening the cover 20 from the base of the body 1 are located along the length of the body 1 at a distance from the ring segment 16 of this assembly towards the base of the body, and the holes 22 lying in the same geometric plane in the sections 7 and 8 bent towards each other and the opposite faces 3 through them through the body 1 for installing threaded elements in the form screws 21 mounting plates 20 from the side of the top 32 (figure 1) of the housing 1 are located along the length of the housing 1 at a distance from the segment of the ring 16 of this node in the direction of the top 32 of the housing 1. The segments of the rings 16 to further strengthen the structure are additionally connected to the housing with gussets 33 (Fig. .5).

The rack prepared for installation is mounted on a pre-installed pile 15, which is located between the inner parts 18 of the ring segments 16 and the samples 24 of the corresponding plates 20, which, after setting the rack position in height, are attracted by 2 G bolts and nuts 22 to the housing 1, so the rack is rigidly fixed on pile 15. After installing the rack on its top 32, the necessary head and / or beam, several travers (not shown in the drawings) are mounted, the choice of designs of which depends on the design features stey would cut overhead power line.

The stand made in accordance with this utility model withstands significant torsional and compressive loads, as well as complex bending loads applied both in the direction between sections 7 and 8 bent towards each other, and orthogonal to it, which is achieved due to the relative relative positioning of the faces 2, 3, 4, 5, 8 of the housing 1, and additionally due to the presence of a strut 25. In this case, the housing can be easily made flexible from a sheet blank using known technologies, as well as other parts made in responsible with the patent claims of technical solutions.

The example of the implementation of the utility model is not exhaustive. There may be other options for the implementation of the rack air support power lines corresponding to the volume of patent claims.

Claims (6)

1. A support tower of an overhead power line, comprising a body in the form of a pyramid surface segment curved from sheet steel, having seven faces, from the edges of the extreme of which sections along the body are made bent towards each other, located at a distance from each other and in a cross section of the body along a generatrix parallel to a similar generatrix of the middle face of the body, from which on both sides to the sections bent towards each other there are successively faces whose planes are conjugated at angles corresponding to respectively, α, β, γ from the inner side of the housing, and the sections bent towards each other lie in the plane conjugated with the planes adjacent their faces at an angle δ from the inner side of the housing, while the values of the mentioned angles are related by the inequality γ> α> β> δ, and the sections bent towards each other are rigidly connected to each other by a set of straight steel elements, each welded on opposite sides to the opposite sections bent towards each other. 2. The rack according to claim 1, characterized in that it is equipped with two fastening nodes spaced at the base of the rack for mounting the rack on the cylindrical surface of the pile, each of the nodes for mounting the rack on the cylindrical surface of the pile includes a ring segment, rigidly fixed transversally with mating on the sections of the outer contour with the inner surface of the housing and having opposite to the opposite bent towards each other sections the inner part in the form of a half circle for tension from the side surface of the pile, which continues in the direction of the sections bent towards each other by straight sections located at distances from the axis of the inner part, the size of which is not less than the radius of the inner part, and the tie assembly located at the level of the ring segment, which is made in the form of a lining, mounted transversely on the outside of the casing between sections of the casing bent towards each other with the possibility of attraction to the casing by threaded elements passing through openings in the bent towards each other from the other parts and the opposite sides through the case, the overlay on the side facing the cavity of the body is made with a sample according to the radius corresponding to the radius of the inner part in the form of a half circle of a ring segment for interfacing with a pile. 3. The rack according to claim 2, characterized in that it is equipped with a strut fixed at opposite ends by threaded elements of both overlays of the coupler nodes on opposite sections of the housing bent towards each other. 4. The rack according to claim 2, characterized in that the holes lying in the same geometric plane in the sections bent towards each other and the edges opposite them through the body for installing threaded fasteners on the base of the body are located along the length of the body at a distance from the ring segment of this node to the side of the base of the body, and the holes lying in the same geometric plane in the bent towards each other sections and the opposite sides through the body to install the threaded elements The pads on the top of the body are located along the length of the body at a distance from the ring segment of this assembly towards the top of the body. 5. Stand according to any one of claims 1 to 4, characterized in that the angles γ, α, β, δ are respectively 150, 147, 138, 105 °. 6. A stand according to any one of claims 1 to 4, characterized in that the straight steel elements are welded on the outer surfaces of the sections bent towards each other with the formation of welds.