RU211710U1 - Power cable - Google Patents

Abstract

The utility model relates to the field of electrical engineering, in particular to power cables with insulation made of polypropylene composition (PPC) and intended for the transmission of electrical energy in networks with an alternating voltage of 6-35 kV and a frequency of 50 Hz. EFFECT: increased operating temperature and improved electrical characteristics. The power cable contains a single-core or three-core conductive core 1 of aluminum or copper conductors with insulation. The insulation of the conductors of the core 1 is made of consecutively superimposed shielding 2 layers of extrudable semi-conductive polypropylene composition, 3 insulating layers of polypropylene composition, 4 insulating shielding layer of extruded semi-conductive polypropylene composition, the first separating 5 layer. Next, a shielding metal layer 6 is laid, then a second separating layer 7, on top of which an outer shell 8 is made of extruded polyethylene. 6 w.p. f-ly, 6 figs.

Description

The utility model relates to the field of electrical engineering, in particular to power cables with polypropylene composition (PPC) insulation, intended for the transmission and distribution of electrical energy in industrial networks with an alternating voltage of 6-35 kV and a frequency of 50 Hz.

Polypropylene, as a polymeric material with low conductivity, along with polyethylene, is currently widely used for the manufacture of insulation in power cables, in particular in cables with medium voltage up to 35 kV. The necessary electrical properties of PPC, namely, low conductivity, are due to the presence of nanosized catalyst fragments, the source of which is the solid catalytic system of the polypropylene composition. The great advantage of polypropylene is the possibility of recycling the insulation material, low CO ₂ emissions during production, as well as the absence of requirements for cross-linking the core insulation.

Known power cable, including polypropylene with nanosized fragments of the catalyst [RU No. 2570793 C2, 10.12.2015]. The cable comprises a conductor surrounded by at least one layer (L) of polypropylene (PP), where the polypropylene includes catalyst fragments (F) in the form of a solid catalytic system (SCS) with an average particle size d50 of less than 1 μm, measured by a Coulter LS200 counter at room temperature. temperature with n-heptane as medium. Polypropylene (PP) is uncrosslinked and is a propylene homopolymer (H-PP) or propylene random copolymer (R-PP) or a heterophasic propylene copolymer (HECO) with a polymer matrix (M) of said propylene homopolymer (H-PP) and /or said random propylene copolymer (R-PP) and an elastomeric propylene copolymer (E). The power cable includes a conductor surrounded by an inner semiconductor layer, an insulating layer, and an outer semiconductor layer, in such an order where at least the insulating layer represents layer (L) and is a high voltage direct current (HVDC) power cable.

Known cable layer containing propylene homopolymer [EA No. 019563 B1, 30.04.2014]. The cable includes a non-crosslinked propylene homopolymer with a mesopentad concentration of more than 91% according to NMR and a branching index g' of less than 1.00, while the propylene homopolymer contains a crystalline fraction that crystallizes in the range of 200-105°C. The crystalline fraction contains a portion which, upon subsequent melting at a melting rate of 10°C/min, melts at a temperature less than or equal to 140°C, and this portion constitutes at least 20% by weight of the crystalline fraction. Said propylene homopolymer is used in the cable as an insulating or semi-conductive layer, the cable comprising one or more such layers.

The patent [RU No. 149965 U1, 01/27/2015] describes a power cable for a voltage of 6-35 kV. The cable contains three sector-shaped conductive aluminum or copper conductors, on top of each of which the first screen of an electrically conductive polymer composition with a radius of curvature (r) in the range of 2.5 to 3.6 mm is sequentially superimposed by extrusion, insulation and a second screen of an electrically conductive polymer compositions. The insulated cores are twisted into a core, on top of which a fastening layer, a metal screen made of copper wires connected by a spirally applied copper tape, a separating layer and an extruded outer sheath are successively located, and the insulation is made of ethylene-propylene rubber, which is a tracking-resistant ethylene-propylene rubber.

The disadvantages of the known analogues are the high crystallinity of the propylene homopolymer, which increases the melting point and processing temperature of such material, and also reduces its plasticity and thus the flexibility of the final product. Cable insulation made of ethylene propylene rubber has insufficient thermal, moisture and tracking resistance, which worsens the performance of the cable and limits its use.

The closest in technical essence to the proposed utility model is the design of a power cable with polypropylene (PP) insulation for medium voltage 26/35kV and below, chosen as a prototype [CN No. 107705881 A, 02/16/2018]. The power cable with polypropylene insulation contains single-core or three-core insulated cores. The outer conductor of each insulated core is extruded from inside to outside in turn using polypropylene (PP) insulation. The insulating layer and the insulating shielding layer are made using a modified formula of polypropylene (PP) material developed by Jiaotong University. The core of a single-core insulated wire is wrapped with a shielding layer and a lining layer of copper tape, and the outer side of the lining layer is extruded into the outer sheath. The three-core insulated wire core is formed into a cable, and the core of the three-core insulated wire has a gasket and a sheath on the outside. The modified polypropylene (PP) insulation material is made without changing the extrusion structure of the cable, while the wire extrusion materials and shielding materials are compatible with the insulating material. The maximum temperature of the cable core during normal operation is 100°C.

The cable, according to the prototype, has a characteristic drawback, which consists in the high crystallinity of the polypropylene composition (PP), which causes an increased melting temperature and processing temperature, as well as poor flexibility at low temperature exposure.

The objective of the utility model is to eliminate these shortcomings and improve the consumer qualities of the power cable.

The technical result of the utility model is to increase the operational temperature and improve the electrical characteristics.

The technical result is achieved by the fact that in a power cable containing a single-core or three-core conductive core of aluminum or copper conductors, a semi-conductive shielding layer, an insulating layer and an insulating semi-conductive shielding layer made of modified polypropylene, and a shielding metal layer are applied over each conductor, according to the useful model, the conductive core (1) contains the first separating (5) insulation layer, on top of which a shielding metal (6) layer is laid, and then the second separating (7) layer, on which the outer sheath (8) of extruded polyethylene is applied, while the modified polypropylene for the shielding (2) layer and the insulating shielding (4) layer is an extrudable semi-conductive composition of polypropylene, and for the insulating (3) layer, the modified polypropylene is a composition of polypropylene, which is characterized by a specific volumetric electrical resistance fluctuation not less than 10 ¹² Ohm⋅cm at 90°С; dielectric loss tangent 0.8⋅10 ^-4 at 30°С, dielectric loss tangent 1.3⋅10 ^-4 at 90°С and dielectric loss tangent 5.6⋅10 ^-4 at 130°С .

Conductive three-core core made of aluminum or copper conductors is made with a sector or round core.

A conductive single-core core made of aluminum or copper conductors is made with a sector or round core.

The shielding metal layer is made of copper wires, which are fastened with a copper tape.

The shielding layer and the insulating shielding layer are made of a semi-conductive composition of homopolymer type polypropylene characterized by partial crystallization in the solid state.

The insulating layer of the polypropylene composition has a molecular structure with an isotactic fraction content of 93-95% and is characterized by a density of 0.90-0.91 g/cm ³ .

The outer sheath is made of an extruded polymer composition that does not contain halogens or PVC compound of reduced fire hazard.

The essence of the utility model is illustrated by the drawings in Fig. 1-6.

In FIG. 1 shows a cross-sectional view of a three-core power cable with a sector multi-wire conductive core.

In FIG. 2 - a view of a three-core power cable in cross section with a round multi-wire conductive core.

In FIG. 3 - a view of a three-core power cable in cross section with a sector single-wire conductive core.

In FIG. 4 - view of a single-core power cable in cross section with a round multi-wire conductive core.

In FIG. 5 - a view of a single-core power cable in cross section with a sector single-wire conductive core.

In FIG. 6 - a view of a three-core power cable in cross section with a round single-wire conductive core.

The power cable includes a single-core or three-core conductive core 1 made of aluminum or copper conductors, a semi-conductive shielding layer 2 of an extrudable semi-conductive polypropylene composition is applied over each conductor, an insulating layer 3 of a polypropylene composition and an insulating semi-conductive shielding layer 4 of an extrudable semi-conductive polypropylene composition, made of modified polypropylene; the first separation layer 5, on top of which the shielding metal layer 6 and the second separation layer 7 are laid, on top of which the outer shell 8 is made of extruded polyethylene; the polypropylene composition of the insulating layer 3 is characterized by a specific volumetric electrical resistance of at least 10 ¹² Ohm⋅cm at 90°C, a dielectric loss tangent of 0.8⋅10 ^-4 at a temperature of 30°C, a dielectric loss tangent of 1.3⋅10 ^-4 at a temperature of 90°C and a dielectric loss tangent of 5.6⋅10 ^-4 at a temperature of 130°C.

Implementation of the utility model

In accordance with the utility model, the production technology provides for the manufacture of power cables with a single-core (see Fig. 4, 5) conductive core 1 or a three-core (see Fig. 1, 2, 3, 6) conductive core 1, which is made of aluminum or copper conductors. The conductive core 1 can be made with a sector 11 stranded core (see Fig. 1) or a round stranded core 12 (see Fig. 2), or with a sector single-wire core 13, 15 (see Fig. 3, 5) or round 14, 16 single-wire core (see Fig. 4, 6).

In the process of manufacturing a power cable, insulation from modified polypropylene is applied to each conductor of the conductive core 1 by extrusion, while first a semi-conductive shielding 2 layer is applied to the conductive core 1, then an insulating 3 layer. The 3rd insulating layer is made of a polypropylene composition having a molecular structure containing an isotactic fraction of 93-95% with a density of 0.90-0.91 g/cm ³ , while such a polypropylene composition of the insulating layer (3) is characterized by the required electrical properties, namely : specific volume electrical resistance not less than 10 ¹² Ohm⋅cm at 90°C, as well as a dielectric loss tangent of 0.8⋅10 ^-4 at a temperature of 30°C, a dielectric loss tangent of 1.3⋅10 ^-4 at a temperature of 90 °C and dielectric loss tangent of 5.6⋅10 ^-4 at a temperature of 130°C.

Further, on top of the insulating layer 3, an insulating semi-conductive shielding layer 4 is laid, which, like the shielding layer 2, is made of a semi-conductive composition of polypropylene of a homopolymer type, characterized by partial crystallization in the solid state. Then, on top of the insulating semi-conductive shielding layer 4, the first separating layer 5 is applied, on which the shielding metal 6 layer is laid. The shielding metal 6 layer is made of copper wires, which are fastened with a copper tape (not shown in the drawing), and a second separating 7 layer is applied on top of the shielding metal 6 layer.

Then, on the separating layer 7, an outer shell 8 of polyethylene is applied, which is made of an extruded polymer composition that does not contain halogens or PVC compound of reduced fire hazard.

The resulting power cable with a semi-conductive screening layer 2 of an extrudable semi-conductive polypropylene composition, an insulating 3 layer of a polypropylene composition, an insulating semi-conductive shielding layer 4 of an extrudable semi-conductive polypropylene composition (PPC) and a protective outer sheath 8 of polyethylene in the form of a polymer composition that does not contain halogens or polyvinylchloride compound of reduced fire hazard, is characterized by an increased operating temperature - up to 110 ° C and improved electrical performance - specific volumetric electrical resistance, a lower value of the dielectric loss tangent, and also withstands higher impulse voltage and has high values of permissible load currents at equal cross sections of conductive wires compared with the prototype.

The production process for cables with polypropylene composition (PPC) insulation does not require cross-linking of core insulation and is characterized by low CO ₂ emissions. An important techno-economic advantage of the production of such a power cable is the possibility of recycling the insulation material from the PPC composition.

The combination of PPC polypropylene compound insulation and a protective outer sheath 8 of polyethylene in the form of a halogen-free polymer composition provides additional advantages to the new cable over the prototype. Such cables can be installed in XLPE-insulated networks using the same fittings used with XLPE-insulated cables.

Claims (7)

1. Power cable containing a single-core or three-core conductive core (1) of aluminum or copper conductors, a semi-conductive shielding (2) layer, an insulating (3) layer and an insulating semi-conductive shielding (4) layer, made of modified polypropylene, are applied over each conductor, and a shielding metal layer (6), characterized in that the conductive core (1) contains the first separating (5) insulation layer, on top of which the shielding metal (6) layer is laid, and then the second separating (7) layer, on which the outer sheath is superimposed (8) from extruded polyethylene, while the modified polypropylene for the shielding (2) layer and the insulating shielding (4) layer is an extrudable semi-conductive composition of polypropylene, and for the insulating (3) layer, the modified polypropylene is represented by a composition of polypropylene, which is characterized by specific volumetric electrical resistance not less than 10 ¹² Ohm ⋅cm at 90°C; dielectric loss tangent 0.8⋅10 ^-4 at 30°С, dielectric loss tangent 1.3⋅10 ^-4 at 90°С and dielectric loss tangent 5.6⋅10 ^-4 at 130°С . 2. Power cable according to claim. 1, characterized in that the conductive three-core core (1) of aluminum or copper conductors is made with a sector (11) or round (12) core. 3. Power cable according to claim 1, characterized in that the conductive single-core core (1) of aluminum or copper conductors is made with a sector (13) or round (14) core. 4. Power cable according to claim 1, characterized in that the shielding metal (6) layer is made of copper wires, which are fastened with copper tape. 5. Power cable according to claim 1, characterized in that the shielding (2) layer and the insulating shielding (4) layer are made of a semi-conductive composition of homopolymer type polypropylene, characterized by partial crystallization in the solid state. 6. Power cable according to claim 1, characterized in that the insulating (3) layer of the polypropylene composition has a molecular structure with an isotactic fraction content of 93-95% and is characterized by a density of 0.90-0.91 g/cm ³ . 7. Power cable according to claim. 1, characterized in that the outer sheath (8) is made of an extruded polymer composition that does not contain halogens or PVC compound of reduced fire hazard.

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