RU193916U1 - TWO-CHAINED INTERMEDIATE INTERMEDIATE MULTI-DIMENSIONAL SUPPORT OF ELECTRIC TRANSMISSION LINES - Google Patents

Abstract

The utility model relates to the construction of electric power facilities, in particular to the supports of overhead power transmission lines combined with a fiber-optic communication line, namely, to a double-circuit intermediate increased multifaceted support with a single-row arrangement of wires of transmission lines 110-220 kV. The two-chain intermediate increased multifaceted support with a single-row arrangement of 110-220 kV power line wires contains a multifaceted rack mounted on the foundation and consisting of five sections, while two multifaceted traverses are mounted to the upper section at an angle to the support for suspension of phase wires with the formation of Y- shaped support, and sections of the rack and traverse for hanging the phase wires are connected by means of a bolt connection through a telescope on the flanges, and the said cross-arms are horizontal mi and inclined cables. The technical result of the patented solution is to reduce the material consumption of a two-chain high-rise support while maintaining the necessary rigidity and strength of its structure.

Description

The utility model relates to the construction of electric power facilities, in particular, to the supports of overhead power lines combined with a fiber-optic communication line, namely, to a double-circuit increased intermediate multifaceted support with a single-row arrangement of 110-220 kV shot glass wires.

Today, the relevance of the use of power transmission towers (power lines) on a multifaceted bent rack (MGS) is growing every day. In particular, supports with an increased arrangement of wires. Supports with an increased arrangement of wires make it possible to preserve the forest. The size to the ground exceeds the forest. The main disadvantage of supports of this kind is their heavy weight. But, despite this, the power transmission towers on the MGS have high reliability, durability and vandal resistance, as well as a good economic effect.

The following support structures are known in the art.

So, from the description of the patent of the Russian Federation No. 13214 (published on 09/10/2013), a single-chain intermediate support is known, the trunk of which consists of an upper section and a lower section, the lower beam with consoles and the upper beam with consoles are fixed on the barrel, while the beam is fixed to the sections, the consoles are designed for fastening the phase wires of overhead power lines, and the console is for attaching an optical cable, the shaft of the steel support can have a closed multifaceted section or a closed oval section, can be made lattice with a diagonal or gingham grille.

The closest analogue to the patented solution is the design of an intermediate two-chain steel support of a three-phase overhead power transmission line containing a barrel made of multi-faceted racks and multi-faceted traverses for hanging phase wires and a lightning protection cable, while the barrel racks and traverse are connected by means of flanges (RF patent No. 73905 published on 06/10/2008).

The disadvantages of the known design are the presence of additional traverse, an increase in the height of the support and, as a consequence, its metal consumption, the complexity of the installation of the support and operation of overhead power lines. The use of the specified combined connection “telescope on the flanges” of the traverse leads to a decrease in metal consumption (reducing the thickness of the flanges, the absence of the need for additional ribs) compared to a conventional flange connection, by increasing the cross-sectional area of the shell, due to the extension of the upper shell to the lower one to a depth of half the diameter and as a result, the forces in the flanges are reduced. The bending forces of the shell surface during bending significantly reduce the longitudinal forces in the shell and the bending forces in the flanges. There is no need for thick flanges and additional stability ribs. The technical problem to be solved by the claimed utility model is the creation of two chain increased intermediate multifaceted supports with a single-row arrangement of wires of a three-phase overhead line 110-220 kV, which allows to reduce material consumption while maintaining the necessary rigidity and strength of the structure, simplify the installation of the support, reduce the weight of the foundation and size its deepening.

The technical result of the patented solution is to reduce the material consumption of two chain high support while maintaining the necessary rigidity and strength of its structure.

The claimed technical result is achieved due to the two chain increased intermediate multifaceted supports with a single-row arrangement of wires of the power line 110-220 kV, which contains a multifaceted rack, mounted on the foundation and consisting of five sections, while two multifaceted cantilever mounted on the upper section at an angle to the support traverses for suspension of two chains of phase wires with the formation of a Y-shaped support, moreover, the barrel sections and cantilever traverses are connected via bolt connections through a telescope to flanges, and the mentioned traverses are fastened with a cable both vertically and horizontally to the trunk, which significantly increase the rigidity of the support.

Thanks to the implementation of the support Y-shaped, containing a multi-faceted stand, consisting of five sections, and two multi-faceted traverses cantilever mounted at an angle to the support for hanging two chains of phase wires, it is possible to suspend three wires on one traverse, thereby reducing the number of traverses, reducing the height racks and, accordingly, the metal consumption of the support, while the transmitted electrical load remains the same. The connection of the barrel sections and cantilever traverses by means of a bolt connection through a telescope on the flanges allows to ensure reliability of the strength and rigidity of the support structure by inserting shells into each other by half the diameter, which reduce the longitudinal forces of separation of the shells from each other due to the friction forces of the shell inlet. The flanges are welded with a slight gap to the shells in the conductor when two shells are inserted into each other, which is further necessary for couplers of sections to be mounted. A telescope of half diameter in collaboration with the flange significantly reduces the bending forces in the flanges, and as a result there is no need for additional ribs and thick flanges, and the unfastening of the cantilever traverses with a horizontal cable reduces the forces in the attachment points arising from the weight of the traverses with wires. Thus, the necessary rigidity and strength of the support structure are provided, that is, its ability to withstand the loads acting on the support. Unfastening the same traverse with inclined cables allows to reduce horizontal and vertical deviations of the traverse and the support as a whole.

In the particular case of implementation, cable traverses of a multifaceted section for attaching a ground wire or fiber optic communication cable (FOCL) are attached to traverses for suspending phase wires by means of a bolt connection through a telescope on the flanges.

Traverses for suspension of phase wires and cable traverses can be made in the form of hollow truncated pyramids of oval or round cross-section from a steel sheet.

In particular, on each traverse for hanging two chains of phase wires, one straight insulator is suspended for attaching the wires, and six straight garlands suspended under two wires in a V-shape way, through a rigid beam connecting all three garlands in the lower part. This solution is necessary in order to ensure a safe distance to live parts (inclined cable) by limiting the deviation of V-shaped strings, and one insulator for attaching a ground wire or fiber optic cable is suspended on the cable traverses.

The essence of the proposed technical solution is illustrated by reference to the figures, which represent the following.

In figure 1 is a General view of the support in front.

In figure 2 is a General view of the support in isometry.

In Figure 3 - mounting bracket traverse for hanging phase wires to the rack.

In figure 4 - the attachment point of the traverse of the ground wire to the traverse for suspension of phase wires. Wire suspension.

In figure 5 - the site of attachment of the support pillars to the foundation.

In figure 6 - the node mounting sections of the racks.

In figure 7 - the attachment section of the wire cross-section.

In figure 8 - the attachment point of the inclined cable to the barrel section.

In figure 9 - the attachment of the horizontal cable to the lightning-proof. Ground wire suspension.

The support stand is made of steel, has a closed circular multifaceted section and consists of five polyhedral sections 2, 3, 4, 6 and 7, connected by a telescope on flanges 23 with a rigid ring 22, and tightened by bolts, while the bolts are oriented perpendicular to the plane of the flanges 23 The lower section 2 is bolted through the direct support flange 1. The direct support flange 1 is attached to the mating support flange of the foundation embedded part (not shown in the figure) through the studs.

On the trunk of the upper section 7, at the angle to the support, two multifaceted traverses are fixed, each of which consists of two sections 24, 8 for suspension of two chains of phase wires 16, the free ends of which are oriented upwards, while the traverses are located opposite each other, with the formation of Y- shaped support. Section 24 and 8 are bolted through the telescope to the flanges 14. To reduce the efforts in the attachment points arising from the weight of the wires, the traverses for suspending the phase wires in their middle part are connected by a steel cable 9 to the upper section 7. One cable is fixed on each traverse 8 traverse 21. To reduce the efforts in the attachment points arising from the weight of the cable, the traverses 21 for suspension of the cable in their upper part are connected by a cable 12, 13. Sections 2, 3, 4, 6 and 7, traverses 8 for suspension of phase wires 16 and cable traverses 21 for a suspension of a cable 17 They are filled with the multifaceted method of bending in the form of hollow truncated pyramids of oval or round section from a steel sheet. Traverses 8 for suspension of phase conductors 17 are fixed, on the upper section 7, through vertical plates 26, by means of bolt connections through flanges 19 located in the middle of the upper section 7, and cable traverses 21 are mounted on traverses 8 for suspension of cable 17 by means of bolted connections through the flanges 20. Inclined traverses 8 to the shell section of the barrel 4 are secured with inclined cables 5.

On each traverse 8 suspended on 7 insulators. The insulators 10 are straight elongated, three insulators 11 in a group are suspended in a V-shape to limit deviation during wind exposure. The insulators 10 and 11 are suspended taking into account the equal distance from each other of the suspension points of the wires 16 through the holder 27 for mounting the wires 16, in turn, the holders 27 of the V-shaped garlands are attached to additional traverses-beams 15 made of channel, which in turn are attached to traverse 8 and unfasten the corners, and at the free end of each cable traverse 21 is suspended one insulator through the holder 28, for attaching a ground wire 17 or fiber optic cable.

Installation of the proposed support power lines is as follows.

A reinforced concrete foundation is installed with a embedded part (not shown in the figures). The lower section 2 is lifted by a truck crane and bolted through a straight support flange 1 to the counter flange of the foundation embedded part. Subsequent sections 2, 3, 4, 6, 7 are raised to each other in ascending order by means of a truck crane and secured by bolting through a telescope to flange 23. Using an adapter pad or a hoist, the installer tightens the joints with bolts. The wire traverse section 24 is lifted by a truck crane and secured with a bolt joint, then the phase wire suspension section 8 is bolted through a telescope on the flanges 14 to section 24. The inclined sections 8 are pulled through the steel cable 9 through the lanyard to the top of section 7. The cable traverses 21 are lifted by a truck crane and bolted through the flange 20 to section 8 of the inclined yoke. The steel cable 12 through the lanyard pull inclined traverse 21 between themselves. The steel cable 13 pulls the yoke 21 of the cable to section 8 of the inclined yoke. The steel cable 5 through the lanyard pull the inclined sections 8 to the section 4. The installation of the support is completed and after suspension on the sections of the crosshead 8 insulators 10 to the holders 27 with wires 16, to the beam beams insulators 11 to the holders 27 in a V-shaped manner with wires 16, and on the console 21 insulators 18 to the holders 28 with a ground wire 17 or fiber optic cable, the power line is ready for operation.

Thus, increasing the length of the traverse for hanging three wires allows you to reduce the number of traverses to two, while reducing the height of the barrel and, accordingly, the metal consumption of the support, while due to this design provides the necessary rigidity and strength of the support.

Claims (6)

1. A two-chain intermediate increased multi-faceted support with a single-row arrangement of wires of a 110-220 kV power line, characterized in that it contains a multi-faceted rack mounted on a foundation and consisting of five sections, while two multi-faceted traverses are mounted on the upper section at an angle to the support for suspension of phase wires with the formation of a Y-shaped support, and sections of the rack and traverse for suspension of phase wires are connected by means of a bolt connection through a telescope on the flanges, and the aforementioned grass the races are unfastened by a cable. 2. The support according to claim 1, characterized in that polyhedral cable traverses are attached to the traverses for hanging the phase conductors by means of a bolt connection through a telescope on the flanges for attaching a ground wire or cable of fiber-optic communication lines. 3. The support according to claim 1, characterized in that the telescopes on the flanges are made with the upper section inserted into the lower half by half the diameter and bolted through the flanges. 4. Support according to claim 1, characterized in that the traverses for hanging phase wires and cable traverses can be made in the form of hollow truncated pyramids of oval or round cross section from a steel sheet. 5. The support according to claim 1, characterized in that the traverses for the suspension of wires are unfastened through the upper rack with a horizontal cable and through the middle section with an inclined cable, and the traverses for the suspension of cables are unfastened with a horizontal cable. 6. The support according to claim 1, characterized in that on each traverse for suspending 3-phase wires, seven insulators are suspended for attaching the wires, of which one is a straight insulator, and six insulators of three in a group are V-shaped, and one insulator is suspended on cable traverses for attaching a ground wire or cable for fiber-optic communication lines.

Images