RU120449U1 - ELECTRIC TRANSMISSION SUPPORT STAND - Google Patents

Abstract

 1. A support tower for an overhead power transmission line, comprising a pyramid-shaped body of two segments, each of which is bent from sheet steel in the form of a half of the side surface of the pyramid, two opposite faces of which are formed by two pairs of extreme sections oriented towards each other, located at the base of the rack, at least two spaced apart along the length of the rack unit for mounting the rack on the pile, as well as two compensating pipes, segments of the body are rigidly connected to each other in areas from the top to the one that is closest to the top of the node for attaching the rack to the pile, and the pairs of extreme sections of the body segments are located at a distance from each other, at least in the locations of the nodes for mounting the rack on the pile and between them,! each of the nodes for mounting the rack on the cylindrical surface of the pile includes! two segments of rings rigidly fixed transversely at the same level as the interface in sections of the outer contour with the inner opposing surfaces of the segments of the housing and having internal parts in the form of parts of a circle for interfacing with the side surface of the pile,! two tie assemblies located at the level of the ring segments on opposite sides of the housing, each of which is made in the form of at least one pair of stops rigidly fixed to adjacent extreme sections of the housing segments, made with the possibility of pulling together threaded elements to each other,! each compensating pipe is made of a hexagonal cross section in the form of two opposite parallel faces, interconnected by sections with two faces, �

Description

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

Known rack support overhead power lines, which contains a housing of two segments, each of which is bent from sheet steel in the form of half of the side surface of the pyramid, two opposite faces of which are formed oriented towards each other by two pairs of extreme sections lying in the same plane. The housing segments are rigidly interconnected at a distance between the said pairs of extreme sections lying in the same plane using a set of straight steel elements, each welded on opposite sides to opposite extreme sections. Direct steel elements are welded on the outer surfaces of the extreme sections of the housing segments with the formation of welds, that is, extended welding sections for reliable joints and rigidity of the rack structure as a whole. At the top of the housing, the segments of the housing are rigidly connected by a plate conjugated with the ends (RU 113766 U1, IPC Е04Н 12 / 08.27.02.2012).

For installation on a cylindrical surface of a pile, the rack below the location of the direct steel elements at its base includes two spacers spaced apart by the distance along the length of the rack of the fastener. Each of these assemblies for fastening includes two segments of rings, rigidly fixed transversely at the same level with the interface in the sections of the outer contour with the inner opposite surfaces of the segments of the housing and having internal parts in the form of parts of a circle for interfacing with the side surface of the pile, and two tie nodes, located at the level of the segments of the rings on opposite sides of the body, each of which is made in the form of a pair of stops rigidly fixed on adjacent extreme sections of the segments of the body segments, nnyh contractably to each other by threaded elements.

To maintain the installed height of the rack at the installation height, the known rack is equipped with a thrust unit in the form of two thrust plates rigidly fixed in one geometric plane on the opposite internal surfaces of the body segments next to the node closer to the top of the rack for mounting the rack on the cylindrical surface of the pile from the side to the top of the rack from him. Thrust plates for abutment against the pile end face protrude into the housing at a distance to its axis, smaller than the radius from the axis of arrangement of the internal parts of the ring segments of nodes for mounting the rack on the cylindrical surface of the pile, due to which the thrust plates abut against the pile end, preventing the rack from dropping below.

To maintain the installed upright, it is equipped with two reinforcement units located on opposite sides of the body, each of which includes two crossbars and a brace, all of which are fixed at the opposite ends with threaded elements on the adjacent opposite extreme sections of the body segments, the cross members being located in zones the location of the nodes for mounting the rack on the cylindrical surface of the pile, and the strut is located obliquely from one cross member to another. As a rule, the strut of one gain node and the strut of the second gain node are located axisymmetrically relative to the axis of the housing.

The described nodes of the rack reinforcement of known design do not provide its stable vertical position during operation. This is due to the weakening of the threaded connecting nodes due to the dynamic effect on the wind column, which leads to breaking holes in the extreme sections of the housing segments, in which the bolt rods of these threaded connecting nodes are located, as well as to the deformation of the extreme sections of the housing segments in the zones of the location of the said threaded connecting nodes.

The technical result of this utility model is to expand the arsenal of racks for the construction of power line supports, moreover, the rack effectively resists the loads arising during operation, stably maintaining the installation vertical position on the pile.

This technical result is provided by a stand of an overhead power transmission line support, which comprises a pyramid-shaped body of two segments, each of which is bent from sheet steel in the form of half of the pyramid’s side surface, two opposite sides of which are formed by two pairs of extreme sections oriented towards each other, located at the base of the rack, at least two spaced apart along the length of the rack assembly for mounting the rack on the pile, as well as two compensating pipes.

The housing segments are rigidly interconnected in areas from the top to the node closest to the top for attaching the rack to the pile, and the pairs of extreme sections of the housing segments are spaced from each other, at least in the locations of the nodes for attaching the rack to the pile and between them .

Each of the nodes for fastening the stand on the cylindrical surface of the pile includes two segments of rings, rigidly fixed transversely at the same level as pairing on sections of the outer contour with inner opposite surfaces of the segments of the housing and having internal parts in the form of parts of a circle for pairing with the side surface of the pile, two screed assembly located at the level of ring segments on opposite sides of the housing, each of which is made in the form of at least one pair of rigidly fixed n and adjacent extreme sections of the segments of the body of the stops made with the possibility of pulling together threaded elements.

Each compensating pipe is made of a hexagonal cross-section in the form of two opposite parallel faces, interconnected by sections with two faces, while the compensating pipes are located on opposite sides of the casing with the mating at the ends of opposite parallel faces with stops of the coupler nodes.

It is possible that each stop of the coupler assembly is made in the form of a corner piece welded to the extreme portion of the housing segment with the perpendicular arrangement of one of the shelves to this extreme portion in which a hole is made through which the corresponding threaded element of the tie assembly passes.

It is also possible that each coupler assembly includes two pairs of stops, while each emphasis of the coupler assembly is made in the form of a corner piece welded to the extreme portion of the housing segment with the perpendicular arrangement of one of the shelves to this extreme portion in which the hole through which passes corresponding threaded element of the coupler assembly.

In the best embodiment, in parallel faces at the ends of each compensating pipe, holes are made through which the threaded elements of the coupler nodes pass. Each compensating pipe can be made of two longitudinal parts welded together by longitudinal sections.

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 a cross-section of the rack of the power line support with a plane lying between the attachment points for mounting the rack on the cylindrical surface of the pile, view towards the base of the rack.

Figure 2 shows the lower part of the rack of the support of the power line with a local longitudinal section.

Figure 3 shows a compensating pipe, three-dimensional view.

The support of the overhead power transmission line comprises a pyramid-shaped body of two segments 1 and 2, each of which is bent from sheet steel in the form of half of the side surface of the twelve-sided pyramid, two opposite faces of which are formed by two pairs of extreme sections lying in the same plane facing each other 3 , four.

At the base of the rack there are two spacers spaced at a distance along the length of the rack for mounting the rack on the cylindrical surface of the pile (not shown in the drawings), each of which includes two segments of rings 5 and 6, rigidly fixed transversely at the same level with the pair in the outer contour sections 7 (FIGS. 1, 2) with opposing inner surfaces 8 (FIGS. 2, 3) of the housing segments 1 and 2 and having inner parts 9 in the form of circumferential parts for. pairing with the side surface of the piles, as well as two nodes of the coupler (figure 2) located at the level of segments of the rings 5 and 6 on opposite sides of the housing, each of which is made in the form of two pairs of rigidly fixed on adjacent extreme sections 3, 4 of segments 1, 2 housing stops 10, 11 (figure 1, 2). Each stop 10, 11 is made in the form of a piece of corner, each with one shelf 12 (Fig. 1) is welded from the outside to the outer surface of the corresponding extreme section 3 or 4 of segment 1 or 2 of the body, and a hole is made in the second shelf 13 (not visible in the drawings) to enable the stops 10, 11 to be pulled together by threaded elements in the form of a bolt 14, passed through the holes in the shelves 13 of both stops 10, 11, and nuts (not visible in the drawings). The rack may include only one pair of stops 10, 11 on each node of the screed. A variant is possible when a pair of stops of the coupler units are connected by one threaded element, and possibly a larger number of parallel threaded elements in the form of bolts or studs.

Segments 1, 2 of the housing in areas from the top to the node closest to the top for attaching the rack to the pile are rigidly interconnected at a distance between the said pairs of extreme sections 3, 4 lying in the same plane using a set of straight steel elements (not shown in the drawings), welded each opposite side to the opposite extreme sections 3, 4. Direct steel elements are made in the form of corners and welded by the edges of the shelves with the orientation of the internal cavity to segments 1 and 2 of the housing on the outer surfaces of the extreme sections 3, 4 segments 1, 2 of the body with the formation of extended welds. Straight steel elements are usually located transversely to segments 1 and 2 of the body, and can be arranged as struts at an angle with a change in angle from one steel element to the next in the form of a zigzag or in any combination of an inclined and transverse arrangement. Pairs of extreme sections of segments 1, 2 of the body can be located at a distance from each other only in areas of the nodes for mounting the rack on the pile and between them, that is, in the lower part of the rack. In sections from the top to the node closest to the top for mounting the stand on a pile, the housing segments 1, 2 can be welded directly to each other, that is, in these opposite zones, pairs of extreme sections 3, 4 lying in the same plane can contact without being located at a distance from each other from friend.

The rack includes two compensating pipes 15, each of which has six faces, two faces 16 of which are parallel, two between them on one side 17 (Figs. 1, 4) are protruding outward, and two opposite on the other side 18 are concave into the cavity compensating pipe 15. Due to this embodiment of the compensating pipe 15, it is possible to displace parallel, faces 16 towards each other or vice versa.

Compensating pipes 15 are located on opposite sides of the housing with mating at the ends with opposite parallel faces 16 with stops 10, 11 of the coupler nodes. In parallel faces 16 at the ends of each compensating pipe 15, holes 19 are made (Fig. 4), through which threaded elements pass in the form of bolts 14 of the coupler nodes. Each compensating pipe 15 is made of two longitudinal U-shaped parts 20, 21, welded together by longitudinal sections 22, 23.

On opposing inner surfaces of 8 segments 1, 2 of the housing next to a node located closer to the top of the rack for mounting the rack on the cylindrical surface of the pile from the side to the top of the rack from it, two thrust plates 24 of the thrust node are rigidly fixed opposite each other (figure 2, 3 ) The thrust plates 24 for stopping against the pile end face protrude into the housing at a distance to its axis that is smaller than the radius from the axis of the internal parts 9 of the ring segments 5, 6, which facilitates the installation of the rack at a predetermined distance relative to the pile against the stop in its end face of the thrust plates 24.

Prepared for installation, the rack is mounted on a pre-installed pile, which is located between the segments of the rings 5 and 6 until the end of the pile rests in the thrust plates 24, after which the pairs of segments of the rings 5 and 6 of both fastening nodes are pulled together by threaded elements (21), so the rack is rigidly fixed on the pile. When the segments of the rings 5 and 6 are pulled together, the stops 10 and 11 become closer, and the compensating tube 15 located between them is compressed, since its parallel faces 16 are brought together. Since each compensating pipe 15 is connected with threaded elements (14) of the tie-rods located at a distance from each other of the fastener for installing the stand on the cylindrical surface of the pile, it prevents the possibility of longitudinal displacement relative to each other of the strained stops 10, 11 of the tie rods, what prevents the angular displacement of segments 1 and 2 of the housing relative to each other and the axis of installation of the rack on the pile.

All details of the utility model made in accordance with patent claims are made of steel using known technologies. The example of the implementation of the utility model is not exhaustive. As noted above, other options are possible corresponding to the scope of patent claims, the implementation of the corresponding utility model of a power transmission tower support.

Claims (5)

1. A support tower of an overhead power transmission line, comprising a pyramid-shaped body of two segments, each of which is bent from sheet steel in the form of a half of the side surface of the pyramid, two opposite faces of which are formed by two pairs of extreme sections oriented towards each other, located at the base of the rack, at least two spaced apart along the length of the rack assembly for mounting the rack on the pile, as well as two compensating pipes, segments of the body are rigidly interconnected in areas from the top to leaning to the top of the node for mounting the rack on the pile, and the pairs of extreme sections of the segments of the housing are located at a distance from each other, at least in areas of the nodes for mounting the rack on the pile and between them, each of the nodes for mounting the rack on the cylindrical surface of the pile includes two segments of rings, rigidly fixed transversely at the same level with the mate on the sections of the outer contour with the inner opposite surfaces of the segments of the housing and having internal parts in the form of parts of a circle for interfacing with the side surface of the pile, two tie assemblies located at the level of the ring segments on opposite sides of the housing, each of which is made in the form of at least one pair of stops rigidly fixed to adjacent extreme sections of the housing segments, made with the possibility of pulling together threaded elements to each other, each compensating pipe is made of a hexagonal cross-section in the form of two opposite parallel faces, interconnected by sections with two faces, while the compensating pipes are located on opposite sides of the casing with the mating at the ends of opposite parallel faces with stops of the coupler nodes. 2. The rack according to claim 1, characterized in that each stop of the coupler assembly is made in the form of a corner piece welded to the extreme portion of the housing segment with the perpendicular arrangement of one of the shelves to this extreme portion in which a hole is made through which the corresponding threaded element passes node screed. 3. The rack according to claim 1, characterized in that each coupler assembly includes two pairs of stops, while each emphasis of the coupler unit is made in the form of a corner section welded to the extreme section of the housing segment with the perpendicular arrangement of one of the shelves to this extreme section, in which made a hole through which the corresponding threaded element of the screed assembly passes. 4. Rack according to any one of claims 1 to 3, characterized in that in parallel faces at the ends of each compensating pipe holes are made through which the threaded elements of the coupler nodes pass. 5. Stand according to claim 4, characterized in that each compensating pipe is made of two longitudinal parts welded together by longitudinal sections.