RU212064U1 - FLEXIBLE POWER CABLE FOR NON-STATIONARY LAYING - Google Patents

Abstract

The utility model relates to cable technology, namely, to the designs of electrical flexible cables intended for non-stationary laying in ground and underground conditions, as well as indoors, for connecting mechanisms and equipment to electrical networks for a rated alternating voltage of 0.66 kV, frequency up to 400 Hz or constant rated voltage of 1 kV, as well as for a rated alternating voltage of 1 kV with a frequency of up to 400 Hz or a constant rated voltage of 1.5 kV, as well as to mobile sources of electrical energy, including power and auxiliary circuits. The technical objective of the utility model is to create a new power flexible cable with higher performance characteristics due to the execution of an aluminum alloy ground conductor of improved quality and reliability, with the ability to maintain electrical contact reliability for a long time. 5 z.p. f-ly, 1 ill.

Description

The utility model relates to cable engineering, namely, to the designs of electrical flexible cables intended for non-stationary laying in ground and underground conditions, as well as the connection of mobile machines, mechanisms and equipment to electrical networks for a rated alternating voltage of 0.66 kV, frequency up to 400 Hz or constant rated voltage of 1 kV, as well as for a rated alternating voltage of 1 kV with a frequency of up to 400 Hz or a constant rated voltage of 1.5 kV, as well as to mobile sources of electrical energy, including power and auxiliary circuits.

Known designs of electrical flexible cables put into operation according to TU 16.K73.05-93 and TU 16.K73.02-88, containing one or more copper conductors, core insulation made of rubber and an outer rubber sheath. The disadvantages of these designs of flexible cables are: low operating temperature of the cores, reduced electrical insulation resistance, reduced resistance to multiple kinks and abrasion, reduced frost resistance, increased flammability, low resistance to oils and fuels.

Currently, flexible cables with insulation of conductive cores, an outer sheath made of extruded thermoplastic materials are finding more and more widespread use. When using these materials, the complexity of manufacturing cables is significantly reduced, and their performance is also increased.

The closest in technical essence of the utility model and taken as a prototype is a flexible electric cable, according to the utility model patent RU No. 134691, IPC H01B 7/02, publ. November 20, 2013, bul. No. 32, containing one or more main conductive conductors, a neutral conductor or a ground conductor, or without them, core insulation from olefin thermoplastic elastomers, an outer polymeric sheath.

The technical problem and disadvantage of the prototype is the low service life.

The technical objective of the utility model is to create a new power flexible cable that is not inferior to the prototype in terms of basic characteristics, with high performance characteristics due to the execution of the ground conductor made of aluminum alloy, which has high quality and reliability, with the ability to maintain the reliability of electrical contact for a long time.

In order to improve the performance properties, a design of a power electric flexible cable used for non-stationary laying is proposed, in which the main multi-wire current-carrying conductors of the cable are made of flexible copper, and the ground conductor is made of flexible aluminum alloy, which allows for a long time to maintain the reliability of electrical contact, with than the core insulation and sheath are made of elastomeric materials.

The technical problem is solved due to the fact that the electric power cable is flexible, contains main flexible insulated current-carrying conductors of round shape, flexible conductive conductor zero conductor, flexible grounding conductor twisted around the core, one or more shells, according to the utility model, the main flexible conductive conductors and flexible the conductive neutral conductor is made of copper and is multi-wire, and the flexible ground conductor is made of aluminum alloy, while the insulation of the conductors and the sheath are made of elastomeric materials.

In addition, the main flexible current-carrying copper conductors are made of tin-plated tin or coated with a lead-tin alloy with a tin content of at least 40%.

In addition, the core insulation is made of a heat-resistant alkenediene elastomer, for example, ATEPng brand.

In addition, the core insulation is made of heat-resistant thermoplastic elastomer, for example, brand TEPi-70.

In addition, the core insulation is made of rubber, for example, type RTI-1.

In addition, the shell is made of rubber, for example, type RShT-2.

In FIG. 1 shows a cross section of a power flexible cable with insulated round cores.

The device contains the main flexible stranded current-carrying conductors (1) and a conductive flexible multi-wire neutral conductor (2) of round shape and made of copper, a flexible conductive grounding conductor made of aluminum alloy (3), while each of the conductors is insulated with polymer insulation (4) made of elastomeric materials, the insulated cores are twisted around the core (without position), one sheath (5) or several sheaths (6) of elastomeric materials is placed over the insulated cores.

The manufacturing technology of the cable according to the utility model is implemented as follows.

The main and zero current-carrying cores are made of copper wires by twisting the wires into a strand, the strands into a core. The conductors of cables intended for operation in areas with a tropical climate are made of copper wire tinned with tin or coated with a lead-tin alloy with a tin content of at least 40%.

Copper stranded main (1) and zero (2) conductors, grounding conductor (3) made of aluminum alloy of a five-core cable is insulated (4) from alkendien elastomer, or heat-resistant thermoplastic elastomer, or rubber. The insulation may be applied, for example, in one or two layers. The insulation must fit snugly against the conductive core, but can be easily separated without damaging the insulation itself. On the surface of the insulation there should be no defects that bring its thickness beyond the limit deviations. Insulated cable cores must be marked with a distinctive color or digital marking. Marking with colors or numbers must be permanent, legible and durable. When marking with a color, each insulated core must be of the same color, except for the two-color grounding core. When applying two-layer insulation, only the outer layer is allowed to be colored.

The insulated cable cores must be twisted. Insulated cable cores are twisted around a round or profiled core (without position) of extruded materials. A sheath (5) is applied over the twisted cable cores, for example, thermoplastic elastomer of the brand TEPO-70 (TEPi-70 is allowed), or rubber type RSHT-2, with filling the inter-core space (with compression), without winding along the general twist.

In multi-core cables, the use of a two-layer sheath (6) is allowed. The thickness of the outer layer of the shell is at least 50% of the total thickness of the shell.

In view of the fact that the electrical flexible cable is intended for non-stationary laying in ground and underground conditions, as well as indoors, for connecting mechanisms and equipment to electrical networks for a rated alternating voltage of 0.66 kV with a frequency of up to 400 Hz or a constant rated voltage of 1 kV, and also for a rated alternating voltage of 1 kV with a frequency of up to 400 Hz or a constant rated voltage of 1.5 kV, as well as for mobile sources of electrical energy, including power and auxiliary circuits, must have conductive resistance to regular deformation processes and repeated bending, resistance to stretching and compression, the possibility of use on an industrial and household machine, high conductor flexibility. Moreover, a cable with insulation made of alkendiene elastomer and thermoplastic elastomer of the brand, for example, TEPi-70, must be resistant to the effects of a long-term allowable temperature on conductive cores up to 90°C, and cables with rubber insulation - up to 75°C. The cables must be resistant to changes in ambient temperature from -60°C to +50°C and resistant to crushing loads of at least 8 kN.

In order to verify the compliance of the cables with the established requirements for the design, technology and materials used, the manufacturer carried out comprehensive tests of the power flexible electric cable in normal climatic conditions. All tests were successful, a positive result was achieved. The service life of such cables is at least 5 years, subject to the conditions of transportation, storage, laying (installation), and the operation of cables is not limited by the service life, but is determined by their technical condition.

The technical result of the claimed utility model is the creation of a new power flexible cable for non-stationary laying, with higher performance characteristics, due to the execution of an aluminum alloy ground conductor of increased quality and reliability, with the ability to maintain electrical contact reliability for a long time.

Thus, the claimed power flexible cable for non-stationary laying with the above distinctive features in combination with known features is new, industrially applicable and subject to legal protection as a utility model.

Claims (6)

1. A flexible power cable containing main flexible insulated current-carrying conductors of round shape, a flexible conductive neutral conductor, a flexible grounding conductor twisted around the core, one or more sheaths, characterized in that the main flexible current-carrying conductors and the flexible conductive neutral conductor are made of copper and are multi-wire, and the flexible grounding conductor is made of aluminum alloy, while the insulation of the conductors and the sheath are made of elastomeric materials. 2. Power flexible cable according to claim 1, characterized in that the main flexible current-carrying copper conductors are made of tin-plated tin or coated with a lead-tin alloy with a tin content of at least 40%. 3. Power flexible cable according to claim 1, characterized in that the insulation of the cores is made of heat-resistant alkenediene elastomer, for example, brand ATEPng. 4. Power flexible cable according to claim 1, characterized in that the core insulation is made of heat-resistant thermoplastic elastomer, for example, brand TEPi-70. 5. Flexible power cable according to claim 1, characterized in that the core insulation is made of rubber, for example, type RTI-1. 6. Power flexible cable according to claim 1, characterized in that the sheath is made of rubber, for example, type RSHT-2.

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