RU178217U1 - POWER FLEXIBLE SHIELDED CABLE - Google Patents

Abstract

A flexible flexible shielded cable can be used to connect mobile shaft machines and mechanisms to the electric network for a rated AC voltage of up to 1140 V, frequencies up to 50 Hz on the main conductors and up to 220 V on the auxiliary conductors. The cable contains three main conductors made of copper wires with insulation made of ethylene propylene rubber and a shield of conductive rubber on top of the insulation. The main conductors are twisted around a profiled core of electrically conductive rubber. In the intervals between the main conductors, auxiliary conductors are made of copper wires, over which a braid of steel wires is applied. On top of the braid is rubber insulation. A split ground conductor is superimposed on the insulation of the auxiliary core by the method of winding from tinned copper wires. Outside, the cable has two sheaths: inner, two-layer, and outer, made of oil-resistant with high resistance to abrasion and laceration of hose rubber. The inner layer of the inner shell is made of electrically conductive rubber, and the outer layer is of an oil-resistant flame retardant hose rubber. Between the inner and outer shells there is armor made of strands twisted from steel and copper wires. When an external crushing load occurs, the metal armor and the ground conductor are shorted and an impulse is transmitted instantaneously to disconnect the electrical equipment through the internal electrically conductive rubber layer of the inner cable sheath. This ensures faster cable disconnection. The cable has an increased explosion hazard and high strength. 2 s.p. f-ly, 1 ill.

Description

The utility model relates to cable technology, and more specifically to the design of a power cable that can be used to connect mobile shaft machines and mechanisms to the mains for a rated voltage of alternating current up to 1140 V, frequencies up to 50 Hz on main cores and up to 220 V on auxiliary veins.

From information sources, the known design of a flexible shielded power cable according to the patent for utility model RU 75096, IPC НВВ 9/02, publ. 07/20/2008, intended for use in the mining industry for connecting mobile mechanisms or electrical installations to electrical networks. The cable according to EN 75096 contains three copper multi-wire main conductors, over each of which an inner shield of conductive rubber, rubber insulation and an outer shield of conductive rubber are laid. The cable also has one copper multi-wire non-insulated ground conductor twisted from right and left strands, and one copper multi-wire auxiliary conductor. A synthetic film and rubber insulation based on ethylene-propylene rubber with an ethylene content of more than 60% are superimposed on top of the auxiliary core. All cores are twisted together in a core. A synthetic film and an inner and outer rubber sheath are applied over the core. Increased resistance to mechanical stress is achieved through the use of strands of various directions and insulation of the auxiliary core with increased physical and mechanical properties.

Known power shielded cable according to the patent for utility model RU 144314, IPC НВВ 9/02, publ. 03/27/2014, which contains three main copper insulated conductors of increased flexibility with elastic electrically conductive screens twisted with a copper split insulated earth conductor located in the inter-core space of the main conductors. On top of twisted cores or between the inner and outer sheath is a conductive metal coating (metal shield) made of tinned copper wire and separated from the insulation and the inner and outer shells by a separation layer. The metal screen provides enhanced protection against external electrical noise. The outer sheath of the cable is made of heat-resistant rubber, which increases the operational capabilities of the cable.

Also known is a power flexible shielded mine cable according to the patent for utility model RU 145558, IPC НВВ 9/02, publ. 01/09/2014, which includes three main copper insulated conductors of increased flexibility with elastic electrically conductive screens twisted with three groups, each of which consists of a copper auxiliary conductor in rubber insulation and a copper ground conductor. Auxiliary conductors are located symmetrically to the main conductors. The grounding conductor is split and imposed by the winding method along the auxiliary cores. A conductive rubber shield is placed on top of the ground conductor. The inner sheath of the cable is made of rubber, the outer sheath of heat-resistant rubber. The outer sheath of the cable, made of heat-resistant rubber, ensures reliable operation of the cable in a wide temperature range. Cables according to patents RU 144314, RU 145558 are intended for connection to the electric networks of mobile mechanisms or electrical installations working in faces and treatment lavas. The presence of split ground conductors in the form of a winding on auxiliary conductors in these cables increases the mechanical strength of the cable and prevents its destruction during operation, especially when bending. However, the absence of a core in both cases reduces the tensile and tensile strength of the cable.

The closest claimed cable in design and technical result achieved, which is adopted as a prototype, is a cable for coal combines TENAX-CT NSSHCGEOEU (http://www.media-prime.ru/produktsiya-draka-cables/underground-tunneling/armoured- coal-cutter-cable-for-chain / kabelj-tenax-ct-sshcgeoeu.html). The cable is designed to power mobile electrical equipment and machines in underground workings with high mechanical loads. It contains three main conductors made of thin copper wires insulated from heat-resistant ethylene-propylene rubber EPR-3G13. A semiconducting layer (screen) is applied on top of the insulation. The main conductors are twisted around a conductive core. Between the main veins are located double concentric elements. Each of the concentric elements consists of an auxiliary conductor, made in the form of a braiding of steel and copper and EPR-insulation, and a ground conductor around the insulation of the auxiliary conductor. The grounding conductor is made in the form of a binding of tinned wires wrapped in conductive tape. The inner sheath of the cable is made of a special rubber compound GM1b, and the outer one is made of 5GM5 rubber with increased resistance to abrasion and wear. The main and auxiliary veins have a distinctive color: blue, black, brown.

The use of ethylene propylene rubber as insulation increases the resistance of the cable to electrical and mechanical stress. The presence of a split ground conductor superimposed by a winding method on auxiliary conductors, as well as a central conductive core, increase the mechanical strength of the cable and prevent its destruction during operation, especially during bending. The prototype cable is highly flexible, reliable at high mechanical loads.

Due to the difficult operating conditions in underground mines, cables for various reasons receive mechanical damage leading to short circuits, which can cause electric shock and methane-air explosions. A shield layer of electrically conductive rubber in the prototype cable structure, applied over each insulated core, when subjected to mechanical action on the cable sheath, transmits an impulse to high-speed switching equipment to turn off the electrical equipment and prevent an accident. However, the presence of only such a protective element is insufficient in order to ensure that the cable is disconnected (relieved) ahead of the cable if the outer sheath of the cable is damaged before the insulation of the main conductors and a short circuit occurs.

The technical problem solved by the claimed utility model is to prevent accidents as much as possible by pre-empting (before damage to the insulation of the main cores and causing a short circuit) disconnecting the cable when exposed to a crushing external load, ensuring explosion safety and increasing the strength of the cable.

The technical result achieved by using the proposed cable design is to short the metal armor and the ground conductor through an internal electrically conductive rubber layer of the cable inner sheath and transmit an instant impulse to turn off the electrical equipment, as well as to increase the explosion safety and cable strength.

The technical result is achieved as follows.

The flexible flexible shielded cable, like the prototype, contains three main conductive cores made of copper wires, each of which is coated with ethylene-propylene rubber insulation. A shield is placed on top of the insulation of each main conductive core. Like the cable of the prototype, the inventive cable contains double concentric elements located in the gaps between the main cores. Each of the concentric elements consists of an auxiliary conductor made of copper wires and a steel wire braid, on top of which rubber insulation is applied, and a split ground conductor made in the form of a winding around the insulation of the auxiliary conductor. The insulation of the main and auxiliary cores is made in different colors. Common is the presence of a conductive core, inner and outer rubber shells.

Unlike the prototype, the inventive cable between the inner and outer shells is made of armor made of strands twisted from steel and copper wires. The inner shell of the inventive cable is made of two layers. The inner layer of the inner shell is made of electrically conductive rubber, and the outer layer of the inner shell is made of oil-resistant flame retardant hose rubber. The outer sheath of the cable is made of oil-resistant with high resistance to abrasion and tearing of rubber hose based on polychloroprene rubber. In addition, each grounding conductor in the inventive cable is made of copper strands, and the central core, unlike the prototype cable, is made of profiled conductive rubber.

In special cases of execution, the screen superimposed on the insulation of each of the main conductive cores can be made of electrically conductive rubber or in the form of a combined braid of copper wires and synthetic threads.

When the cable sheath (crushing load) is mechanically acted upon, the metal armor and the earth conductor are shorted through the internal conductive rubber layer, as well as the instantaneous transmission of the impulse through the internal layer of the conductive rubber sheath to high-speed switching equipment to prevent the electrical equipment from shutting down ahead of time. Thus, due to the use of a two-layer inner shell, consisting of a layer of electrically conductive rubber and a layer of hose rubber, an early disconnection of the cable is ensured under the influence of a crushing external load. In addition, depending on the value of the crushing load, in particular concrete cases of execution, it is possible to adjust the thickness of the electrically conductive layer at which shutdown occurs (stress relief).

The use of a central profiled core increases the tensile and tensile strength of the cable, allows you to create a damping layer between the conductive conductors, which avoids a short circuit between the conductors with increased mechanical stress on the cable. Using a central profiled core allows you to completely fill the space between the cores, which prevents the possibility of "pumping" or involving moisture and gases potentially causing an explosion inside the cable structure. The presence of the specified core also creates convenience during installation.

Hose rubber has high tensile strength, elasticity, moisture resistance and heat resistance. The execution of strands also increases the strength of the cable.

The cable design in the proposed combination of essential features in known sources of information has not been identified, which confirms its novelty.

The drawing shows a cross section of a power flexible shielded cable.

The cable contains three main conductors 1 of copper wire with insulation 2 made of ethylene propylene rubber. On top of the insulation 2, an individual screen 3 is imposed, which can be made of electrically conductive rubber or as a combined braid of copper wires and synthetic threads. Insulated conductive conductors 1 are twisted around a profiled core 4 of conductive rubber. In the intervals between the main conductors 1 are three auxiliary conductors 5 made of copper wires, on top of which a braid 6 of steel wires is applied. A rubber insulation 7 is made on top of the braid 6. Concentrated to each auxiliary conductor 5 is a split ground conductor 8. A ground conductor 8 is superimposed on the insulation 7 of the auxiliary conductor 5 by winding from tinned copper wires. The inner sheath of the cable is two-layer. The inner layer 9 is made of electrically conductive rubber. The outer layer 10 of the inner sheath of the cable is made of oil-resistant flame retardant hose rubber. On the outer layer 10 is applied armor 11 of strands twisted from steel and copper wires. The outer sheath of the cable 12 is made of oil-resistant with high resistance to abrasion and tearing of rubber hose based on polychloroprene rubber.

The inventive power flexible shielded cable meets the criterion of "industrial applicability", since it can be repeatedly produced and used for its intended purpose with the achievement of the specified technical result. Cable manufacture does not cause difficulties for cable industry specialists. All materials used in the construction of the cable are known and commercially available by the industry. Cable manufacture is based on well-known cable equipment and standard technologies. The manufacturing process includes operations such as drawing copper wire, twisting conductive wires, applying rubber insulation, manufacturing a profiled core, general twisting of the main shielded and auxiliary conductors, applying sheaths and armor, as well as conducting electrical tests of the finished wires and cable in finished form. For these purposes the following are used: drawing machines, braiding machines, twisting machines for twisting current-carrying conductors and general twisting, equipment for applying by the method of winding armor, aggregates of continuous vulcanization, testing equipment.

Power flexible shielded cable is used at ambient temperatures from minus 30 ° С to plus 50 ° С, does not spread combustion. Long-term permissible operating temperature on the conductive conductors of the cable - no more than 90 ° С. The minimum bending radius of the cable during installation and operation corresponds to 5 cable diameters. The cable resistance to bending at an angle of ± πrad is at least 10,000 cycles.

Claims (3)

1. Power flexible shielded cable containing three main conductive cores of copper wires, each of which is coated with ethylene-propylene rubber insulation, and a shield is placed on top of the insulation; double concentric elements located in the gaps between the main cores, each of the concentric elements consisting of an auxiliary core made of copper wires and a steel wire braid with rubber insulation on top of it and a split ground wire made in the form of a winding around the auxiliary insulation veins; while the insulation of the main and auxiliary cores has a different color; comprising an electrically conductive core, inner and outer rubber sheaths, characterized in that the cable between the inner and outer sheaths further comprises armor made of strands twisted from steel and copper wires, wherein the inner sheath of the cable is made of two layers, its inner layer is made of electrically conductive rubber, and outer - from oil-resistant flame retardant hose rubber, and the outer sheath of the cable is made of oil-resistant with high resistance to abrasion and laceration zines based on polychloroprene rubber, except that each earth wire strands made of copper, and an electrically conductive core made of profiled semi-conductive rubber. 2. The cable according to claim 1, characterized in that the screen overlaid on the insulation of each main conductive core is made of electrically conductive rubber. 3. The cable according to claim 1, characterized in that the screen superimposed on the insulation of each main conductive core is made in the form of a combined braid of copper wires and synthetic threads.

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