RU2686837C1 - Non-insulated wire with function of monitoring technical parameters in current time mode (versions) - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to the field of electrical equipment, namely to non-insulated wires intended for transmission of electric energy via overhead power line of 35 kV overhead line and above, with constant monitoring of requirements for technical parameters of non-insulated wires, with simultaneous preservation of monitoring during long operating life of overhead line. Invention is aimed at creation of non-insulated wire in various design, with constant monitoring in current mode of technical characteristics of non-insulated wire, such as tensile strength, eolian vibration, galloping (dancing) in mode of intermittent load, durability of sealing in tension and connecting terminals heating temperature along conductor length, resistance and current. Results of measured parameters from electronic sensors tuned to control of technical parameters are transmitted to reading measuring device.EFFECT: this will significantly increase efficiency during long-term operation of overhead line.4 cl, 3 dwg

Description

The invention relates to the field of electrical engineering, in particular to uninsulated wires intended for the transmission of electrical energy over an overhead power line of 35 kV overhead lines and above, with constant monitoring of the requirements imposed on the technical parameters of uninsulated wires, while maintaining monitoring over the long life of the overhead lines.

Known optical cable (Patent for a useful model RU №168350, H01B 11/22, published. 01/30/2017). The invention relates to the field of electrical engineering and can be used in communication systems and information transfer.

The proposed device does not resolve issues related to the transmission of electrical energy through an overhead power line of 35 kV and above. It is difficult to link the diameter of the optical fiber with a protective polymer coating, with a given amount and wire diameter for one layer, in order to increase resistance to repeated bends.

Known wire for overhead power lines. The wire contains a conductive core placed on a supporting core, made in the form of a long rod made of composite material. At least one fiber-optic cable is placed in the carrier core along the entire length, and an insulating material is laid between the core and the conductive core (Utility Model Patent RU No. 119927, H01B 5/08, published 27.08.2012).

The disadvantages of this wire are low electrical conductivity, due to the low electrical conductivity of the composite core, rather high complexity associated with the manufacture of the carrier core, made in the form of a long rod made of composite material, in which the fiber-optic cable is placed along the entire length, and as a result, high costs for its manufacture .

Known electro-optical cable for overhead power lines. (Patent for utility model RU No. 159553, H01B 11/22, published on 02/10/2016). The invention relates to the cable industry and can be used primarily for cables used for suspension on power transmission towers.

The disadvantages of this design include the complexity, it is almost impossible to manufacture a fiber-optic core made in the form of twisted preformed steel wires, forming a channel in which optical fibers are chosen as the central wire.

Known self-supporting wire isolated and protected for overhead power lines. (Patent for utility model RU No. 136913, H01B 7/02, published on 01/20/2013). The utility model relates to electrical engineering, in particular, to the design of combined self-supporting insulated wires for a rated voltage of 0.6 / 1 kV and combined self-supporting protected wires for a nominal voltage of 20 and 35 kV. The wire contains a conductive core with a central power element, the cable or module with optical fibers is placed outside the outer polymer sheath of the wire and connected to it by a twist around an insulated conductor.

The disadvantages of the device are the complexity of the design, the inability to achieve maximum strength of the wire using for the manufacture of plastically compressed core galvanized steel wire, made according to GOST 9850-72. This design, as well as the previous ones, are not intended for transmitting and reading wire parameters, and monitoring mechanical and electrical parameters, in the current time mode modulo optical fibers.

The aim of the invention is the creation of uninsulated wires in various versions, with constant monitoring in the current time mode, the technical characteristics of the uninsulated wire, such as tensile strength, aeolian vibration, galloping (dancing) in the mode of pulsating load, seal strength in tension and connecting clamps, temperature heating along the length of the conductor, resistance and current. The results of measured parameters from electronic sensors that are configured to control technical parameters are transmitted to a readout measuring device, which will significantly increase the efficiency over the long life of the OHL.

Four variants of uninsulated wire are offered, with monitoring of technical parameters in the current time mode, modulo with embedded optical fibers in uninsulated wire, the wire is plastically deformed over the cross-sectional area.

The essence of the claimed invention is to use non-insulated wire for simultaneous transmission of electrical energy through an overhead transmission line (OHTL) of 35 kV and above and monitoring technical parameters, the results of measured parameters from electronic sensors are transmitted to the readout measuring device from electronic sensors for tracking HV line, in the current time mode modular with optical fibers embedded in uninsulated wire, in four versions.

Option 1.

Uninsulated high strength wire,

monitoring the technical parameters of the wire modulated with optical fibers in the current time mode. The wire consists of a galvanized steel core made of galvanized high-strength steel wires, conductive layers of aluminum wires are located around the core. Galvanized steel core, contains module 1 with optical fibers 2, the module is made of stainless steel grade with a hydrophobic filler to protect the organic substances from moisture. The module is covered with layers of 3 galvanized steel wire. The number of layers of galvanized steel wire varies from one to three. The conductive part of the wire may contain from one to two layers of 4 aluminum wires, or from an alloy based on aluminum. The design of the galvanized steel core, the number of conductive layers of non-insulated steel-aluminum wire is selected depending on the nominal section size aluminum / steel uninsulated wire. The nominal aluminum / steel section varies in the range of 49 / 6-1250 / 101.8 mm ² . The core is plastically deformed with a degree of reduction over the cross-sectional area with a degree of 2 ÷ 4.5%. The core and wire layers are made with the same stripe pitch, in the same direction and with a linear touch of the wires. The outer surfaces of the upper layer wires are plastically deformed with a degree of compression of the cross-sectional area of the wire of 3 ÷ 5%.

The invention is illustrated in the drawing, where in FIG. 1 shows a cross section of uninsulated wire.

 Module 1 with optical fibers 2, layers of high-strength steel wire 3 and conductive layers 4 are located around the module.

Option 2

The uninsulated high-temperature wire of increased strength, which monitors the technical parameters of the wire modulated with optical fibers in the current-time mode. The wire consists of a galvanized steel core made of galvanized high-strength steel wires. Galvanized steel core, contains module 1 with optical fibers 2, the module is made of stainless steel grade with a hydrophobic filler to protect the organic substances from moisture. The module is covered with 4 layers of galvanized steel wire. The number of layers of galvanized steel wire varies from one to three. The core is covered with a layer of grease 3 with a thickness of up to 1 mm, resistant to high temperatures. On top of the core there are conductive wire layers made of an aluminum-based alloy, including zirconium 0.20 ÷ 0.40 wt.%. The conductive part of the wire 5 may contain from one to two layers of wires. The design of the galvanized steel core, the number of conductive layers of non-insulated steel-aluminum wire is selected depending on the nominal section size aluminum / steel uninsulated wire. The nominal section of aluminum / steel varies in the range of 49/6 - 1250 / 101.8 mm ² . The core is plastically deformed with a degree of reduction over the cross-sectional area with a degree of 2 ÷ 4.5%. The core and wire layers are made with the same stripe pitch, in the same direction with the linear touch of the wires. The outer surfaces of the upper layer wires are plastically deformed with a degree of compression of the cross-sectional area of the wire of 3 ÷ 5%.

The invention is illustrated in the drawing, where in FIG. 2 shows a cross section of uninsulated wire. Module 1 with optical fibers 2, layers of high-strength steel wire 4, layer of lubricant 3 and conductive layers 5 are located around the module.

Option 3

The uninsulated wire, which monitors the technical parameters of the wire modulated with optical fibers in the current-time mode, contains in the center a module 1 with optical fibers 2, the module is made of heat-shielding and high-strength composite material with a hydrophobic filler to protect the moisture from moisture. Around the module there are layers of conducting wires made of aluminum or of an aluminum-based alloy, with the wires touching linearly with each other, with the same pitch of the layers, the outer surfaces of the wires 3 are plastically deformed with a reduction degree of 3-5% of the cross-sectional area of the wire. The number of layers in the wire varies from one to three. The number of layers and the number of wires in the wire is determined by the nominal cross section of the wire. The nominal cross-section of the wire varies in the range of 10,700 mm ² . All conductive wires are made of aluminum or aluminum-based alloy.

The invention is illustrated in the drawing, where in FIG. 3 shows a cross section of uninsulated wire. Module 1 with optical fibers 2, conductive aluminum layers of wire 3 are located around the module.

Option 4

Uninsulated wire, which monitors the technical parameters of the wire modulated with optical fibers in the current-time mode, differs from uninsulated wire, made according to option 3, the chemical composition of the wire for

 conductive part of the wire. The wires of the conductive part of the wire are made of an alloy based on aluminum, the mass fraction of the remaining chemical elements,%: aluminum - base, silicon 0.38-0.42, iron 0.33-0.37, copper ≤0.10, magnesium 0, 43-0.46, zinc ≤0.10, titanium, vanadium, manganese chromium, ≤0.015, boron ≤0.06, others ≤0.03.

This allows non-insulated wire made in all four variants to continuously monitor, in the current time mode, the technical characteristics of the non-insulated wire made in various versions, such as the voltage in the wire when exposed to loads of aeolian vibration, galloping (dancing) in the pulsating load mode, tension in tension and connecting clips, heating temperature along the conductor length, resistance and current, which will significantly increase the efficiency and safety operation of the proposed wire, completely eliminate the possibility of its failure during the long life of the OHL.

Claims (4)

1. Uninsulated high-strength wire, monitoring the technical parameters of the wire modulated with optical fibers in the current-time mode, the wire consists of a galvanized steel core made of galvanized steel high-strength wires, with a stainless steel grade module with a hydrophobic filler and optical fiber embedded in the core the fibers in it, the conductive layers of the wire made of aluminum wires, or an alloy based on aluminum, the number of layers of steel galvanized oh wire varies from one to three, the conductive part of the wire may contain from one to two layers of aluminum wires, or from an alloy based on aluminum, the core is plastically deformed with a degree of reduction in cross-sectional area with a degree of 2 ÷ 4.5%, the core layers and the wires are made with the same twist pitch, in the same direction and with a linear touch of the wires; the outer surfaces of the wires of the upper layer are plastically deformed with a degree of reduction of the cross-sectional area of the wire 3–5%. 2. Non-insulated high-temperature wire of increased strength, monitoring the technical parameters of the wire according to claim 1, characterized in that the core is coated with a lubricant up to 1 mm thick that is resistant to high temperatures, the conductive wire layers are made of an aluminum-based alloy including zirconium 0 , 20 ÷ 0.40 weight. % 3. Uninsulated wire, monitoring the technical parameters of the wire modulated with optical fibers in the current-time mode, containing in the center a module with optical fibers, the module is made of heat-shielding and high-strength composite material with a hydrophobic filler, layers of conductive aluminum wires are located around the module, or from an alloy based on aluminum, made with a linear touch of the wires between themselves, with the same pitch of layering, the outer surfaces of the wires are plastic defo ized with a reduction rate of 3-5% of the cross section of the wire, the number of layers of wires varies from one to three. 4. Uninsulated wire, monitoring the technical parameters of the wire according to claim 3, characterized in that the conductive wire layers are made of an aluminum-based alloy, the mass fraction of the remaining chemical elements,%: aluminum - base, silicon 0.38-0.42, iron 0.33-0.37, copper ≤0.10, magnesium 0.43-0.46, zinc ≤0.10, titanium, vanadium, manganese chromium, ≤0.015, boron ≤0.06, others ≤0, 03

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