RU225236U1 - POWER CABLE WITH FIBER OPTICAL MODULE FOR VOLTAGE 45-500 kV - Google Patents

Abstract

The utility model relates to cable technology. The technical result is to increase the reliability of the power cable. The power cable contains a conductive core, a core screen made of an electrically conductive cross-linked polymer composition, insulation made of a cross-linked polyethylene composition, an insulation screen made of an electrically conductive cross-linked polymer composition, a metal screen, a layer of electrically conductive tape, a metal wire screen and an outer sheath, wherein the cable contains fiber -optical modules laid between the wires of the screen, and the voids between the wires of the metal screen and the voids between the wires of the metal screen and the fiber optic modules are filled with polymer-based material. 3 salary f-ly, 2 ill.

Description

The utility model relates to cable technology, namely to the designs of power cables with cross-linked polyethylene insulation, used for the transmission and distribution of electrical energy in stationary installations with a rated alternating voltage of 45-500 kV.

To monitor the temperature in 45-500 kV power cables in order to detect critical places on the route, for example, areas of increased heating of the cable, fiber-optic modules built into the design of the metal screen are used.

A known power cable for voltages from 45 kV to 330 kV, containing one stranded current-carrying core with a nominal cross-section from 500 mm ² to 2500 mm ² , containing a first screen made of an electrically conductive cross-linked polyethylene composition, insulation made of cross-linked polyethylene, a second screen made of an electrically conductive cross-linked polyethylene composition, a metal screen made of copper wires wrapped with a spirally applied copper tape, a separating layer and an outer sheath, characterized in that an additional winding of electrically conductive polymer tape is applied along the conductive core (RF patent No. 161088, IPC H01B 9/02, published 04/10/2016).

The closest analogue (prototype) is a power cable containing one conductive core, a core screen made of an electrically conductive cross-linked polymer composition, insulation made of a cross-linked polyethylene composition, an insulation screen made of an electrically conductive cross-linked polymer composition, a layer of electrically conductive tape, a metal screen and an outer sheath, in this case, the cable contains fiber-optic modules laid between the screen wires with an attenuation coefficient of no more than 0.8 dB/km at a wavelength of 1300-1310 nm (RF patent No. 207041, IPC H01B 11/22, published 10/07/2021).

The disadvantage of the known solutions is the high risk of damage to the fiber-optic module during cable installation and operation, caused by bending loads.

The problem to be solved by the utility model is to increase the reliability of the operation of a power cable made with the use of fiber-optic modules in the design to control various parameters during cable operation, in particular, for a single-phase power cable with cross-linked polyethylene insulation for high voltage.

The technical result consists in increasing the reliability of the power cable and eliminating damage to the fiber-optic module during the installation and operation of the cable.

The technical result is achieved in that the power cable contains a conductive core, a core screen made of an electrically conductive cross-linked polymer composition, insulation made of a cross-linked polyethylene composition, an insulation screen made of an electrically conductive cross-linked polymer composition, a metal screen, a layer of electrically conductive tape, a metal wire screen and an outer sheath , wherein the cable contains fiber-optic modules laid between the wires of the screen, and the voids between the wires of the metal screen and the voids between the wires of the metal screen and the fiber-optic modules are filled with polymer-based material.

The utility model is illustrated by the following images:

Figure 1 shows the appearance of the cable (without the outer sheath), illustrating the consequences of applying bending loads;

Figure 2 shows a general cross-sectional view of the cable in one of the embodiments with filling the voids of the metal screen with a polymer bundle.

Experience with power cables for voltages of 45-500 kV with built-in fiber-optic modules shows that when laying the cable in a cable trench at the customer's site, damage to the optical fibers occurs due to bending of the wires of the metal cable screen and the fiber-optic module itself (Fig. 1) . The bends of the screen wires are the result of the action on the cable at each moment of time of mechanical forces of varying magnitude and direction, the formation of which during cable laying is influenced by the following main factors:

winter period of the year;

the presence of complex associated engineering and technical infrastructure when preparing the cable route (trench);

for a number of reasons, the actual state of the cable route (trench) does not correspond to the technical documentation.

Displacements and bends of the wires of the metal screen lead to deformation of the steel tube with the optical fiber and damage to the optical fiber; this becomes possible under the influence of the factors described above in the presence of voids between the wires.

The power cable according to this utility model contains a current-carrying core, insulation, a copper screen and an outer sheath. In this case, the voids between the wires of the metal screen are filled with a material based on polymers, fiberglass or carbon fiber.

The current-carrying core is made of multi-wire round or multi-sector made of aluminum or copper wires.

The insulation is made by extrusion from a cross-linked polyethylene composition and serves as the main electrical insulating element.

The metal screen is made of metal wires twisted in one direction, on top of which a metal tape (or a skein of metal wires) is applied by winding to ensure electrical contact; the wires and tape can be made of copper, or aluminum or an aluminum alloy.

Fiber optic modules are laid between the wires of the metal screen. The fiber optic module is a multimode optical fiber housed in a steel tube.

The placement of a module with optical fibers between the wires of the metal screen is carried out simultaneously with the placement of the wires of the metal screen. In this case, simultaneously with the wires of the screen and the fiber-optic module, carbon fiber, fiberglass or polymer bundles can be applied in the same direction, made by extrusion and filling the voids between the wires of the screen. Polymer bundles can be round and profile, reinforced with glass fibers. The application of the fiber-optic layer is carried out using a release device, which prevents exceeding the permissible traction force and longitudinal twisting of the fiber-optic module.

Also, in a particular case, these voids between the wires of the metal screen and the fiber optic module can be filled with an extruded polymer layer.

Filling the voids between the metal screen wires and the fiber optic module with bundles allows you to create a shock-absorbing gap between the screen wires and the fiber optic module. Experiments have confirmed that this cable design provides reliable protection of the fiber-optic module from mechanical damage under difficult installation conditions.

Examples of the polymer material from which the tow is made for filling voids: composition of low-density polyethylene Metalen PE-11K (form. "Metaklay"), composition of low-density polyethylene 711 KM (form. "Polygran")

The outer sheath of the cable, depending on the conditions of use, can be made of polyethylene, polyvinyl chloride, polyvinyl chloride of reduced flammability, polyvinyl chloride of reduced flammability in a cold-resistant design, polyvinyl chloride of reduced fire hazard, polyvinyl chloride of reduced fire hazard with low smoke emission in a cold-resistant design, a polymer composition that does not contain halogens, a polymer composition , halogen-free and cold-resistant. The outer shell can also be made in a reinforced two-layer design.

In a particular case of execution, a winding of electrically conductive polymer tape or electrically conductive water-blocking tape can be additionally applied over the conductive core.

An internal screen made of an electrically conductive cross-linked polymer composition is applied to the conductor using an extrusion method, which serves to uniformly distribute the electric field strength at the boundary of the conductor and the insulation layer.

An outer screen made of an electrically conductive cross-linked polymer composition is applied over the insulation by extrusion, which serves to uniformly distribute the tension between the insulation and the metal screen.

A layer of electrically conductive paper tape or electrically conductive polymer tape, or electrically conductive fabric, or electrically conductive water-blocking tape is applied on top of the outer screen made of an electrically conductive cross-linked polymer composition, which serves as protection against mechanical damage to the second electrically conductive screen, as well as to equalize the electric field in the cable.

A separating layer of electrically conductive water-blocking tapes can be applied over the metal screen using the winding method.

On top of the metal screen or on top of the separating layer of electrically conductive water-blocking tapes, a separating layer in the form of a winding with fire-retardant tape can be applied using the winding method, which is necessary to prevent the sheath material from flowing between the screen wires during the manufacturing process.

In a particular embodiment, an inner shell can be applied over the separating layer.

On top of the inner sheath, in a particular version, the cable may contain a thermal barrier made of copper or aluminum tape, or fire retardant tape.

The power cable can also have armor made of metal wires and/or tapes (aluminum or aluminum alloy) and serves as protection against mechanical and tensile influences. It is allowed to lay polymer tape or fire retardant tape over the armor and under it.

On top of the separating layer or on top of the thermal barrier, or on top of the applied armor, an outer shell is applied by extrusion.

The power cable can be made in the “g” design and contain on top of the second electrically conductive screen, on top of the metal screen and on top of the inner sheath a layer of electrically conductive water-blocking tape, and on top of the separating layer contain a water-blocking tape, which allows you to protect the cable from the spread of moisture.

The power cable can be made in the “gzh” design and, in addition to the “g” design, contain a sealed current-carrying core by introducing water-blocking threads during the twisting process.

The cable can be made in the “2g” and “2gzh” versions and, in addition to the “g” or “gzh” design, contain an overlapping winding made of laminated aluminum-polymer tape on top of the separating layer.

Figure 2 shows one example of the implementation of a utility model.

Copper segmented conductor (RMS) 1 consists of five insulated and twisted segments with a cross-section of 1400 mm ² . On top of the conductive core 1, an internal screen 2 made of an electrically conductive cross-linked polymer composition is applied by extrusion, on top of which insulation 3 and on top of it an outer screen 4 made of an electrically conductive cross-linked polymer composition are extruded. On top of the outer screen 4 made of an electrically conductive cross-linked polymer composition, a separating layer 5 of electrically conductive water-blocking tapes is applied by winding, onto which metal screen wires 6, steel tubes with a fiber-optic module 7 and polymer bundles 8 are simultaneously applied by winding. On top of the metal screen layer by winding a separating layer 9 of electrically conductive water-blocking tapes and electrically conductive nylon tapes is applied. An aluminum polymer tape 10 and, using the coextrusion method, an outer shell 11 made of low-density polyethylene and a semiconducting layer 12 made of a cross-linked polymer composition are simultaneously applied on top of the separating layer.

The design of the claimed utility model was successfully tested in the conditions of production and cable laying at energy facilities and made it possible to maintain the functionality of fiber-optic modules of the power cable under bending loads and thereby increase the reliability of the power cable, providing the ability to control areas of overheating of the cable insulation.

Claims (4)

1. A power cable containing a conductive core, a core screen made of an electrically conductive cross-linked polymer composition, insulation made of a cross-linked polyethylene composition, an insulation screen made of an electrically conductive cross-linked polymer composition, a metal screen, a layer of electrically conductive tape, a metal wire screen and an outer sheath, wherein the cable contains fiber-optic modules laid between the wires of the screen, characterized in that the voids between the wires of the metal screen and the voids between the wires of the metal screen and the fiber-optic modules are filled with a polymer-based material. 2. Power cable according to claim 1, characterized in that the material for filling the voids contains filler in the form of glass or carbon fiber. 3. Power cable according to claim 1 or 2, characterized in that the material for filling the voids is made in the form of a polymer bundle. 4. Power cable according to claim 1, characterized in that the polymer material for filling voids is applied by polymer extrusion.