RU79713U1 - CABLE FOR CONTROL, SIGNALING, INFORMATIZATION AND COMMUNICATION FOR EXPLOSIVE AREAS ON FLOATING DRILLING RIGS AND MARINE HOSPITAL PLATFORMS - Google Patents

Abstract

The utility model relates to control, signaling, information and communication cables for hazardous areas on floating drilling rigs and offshore stationary platforms.

The cable contains several copper stranded conductive conductors insulated with ethylene-propylene or silicone rubber and / or groups of two, three, or four conductors twisted together. The cores and / or groups are twisted into a core. The voids in the core are filled with a polymer aggregate based on polyvinyl chloride plasticate.

On top of the common screen, a moisture-proof sheath is made of oil-and-oil-resistant, sea-water and sea-fog resistant polyvinyl chloride plastic compound or polychloroprene rubber, or chlorosulfonated polyethylene.

A design is proposed in which on each one and / or several isolated cores and / or groups superimposed individual or, respectively, group screens that coincide in design with a common screen, and shells from materials approved for the manufacture of insulation and moisture-proof sheath in this utility model .

The thicknesses of the shells on top of the individual and / or group screens are selected so that they withstand a test of 500 V AC at a frequency of 50 Hz applied between any individual and / or group and / or common screens.

An armored cable design is proposed.

The constructions according to this utility model will ensure compliance with the requirements of the Rules for the classification, construction and equipment of floating drilling rigs and offshore fixed platforms for cables, including, on condition of movable laying.

Description

The utility model relates to cable technology and can be used in the construction of control cables, signaling, informatization and communication for laying in hazardous areas on floating drilling rigs and offshore stationary platforms.

Known cables brands KGVV; KUGVV; KUGVEV; KUGVVE (N.I. Belorussov, A.E. Saakyan; A.I. Yakovleva "Electric cables, wires and cords. Reference book", M., "Energoizdat", 1987). Cables have flexible conductors, insulation and sheath made of polyvinyl chloride (PVC) plastic compound. In the cable of the KUGVEV brand, insulated conductors have an individual screen in the form of a braid made of copper wire, however, there are no requirements for the screen and for isolation of the screens from each other, and there is also no common screen.

The cable of the KUGVVE brand has a common screen made in the form of a winding with an aluminum tape 0.15-0.20 mm thick with a copper wire or a copper multi-wire core laid under it. Such a screen degrades the flexibility of the cable, which is important when laying in compact rooms floating drilling rigs and offshore stationary platforms, as well as aluminum in the form of a tape is short-lived when operating in aggressive environments.

All of the above cables have another serious drawback: the cable core has air cavities through which explosive gaseous mixtures can be transferred from hazardous areas to non-hazardous areas, creating an emergency there.

The disadvantage of such a cable is that it cannot be used in conditions of multiple laying (in the general case: in conditions of movable installation), and this is necessary in some cases of operation.

As a prototype, choose a cable type KUGVEV.

The essence of the proposed utility model is expressed in the creation of a control cable, signaling, informatization and communication for hazardous areas on floating drilling rigs and offshore stationary platforms, preventing the spread of explosive gaseous mixtures along the core of the cable from hazardous areas to non-hazardous areas, providing the requirement for cable shields for intrinsically safe circuits on flexibility (“Rules for the classification, construction and equipment of floating drilling rigs and offshore stationary platforms”, 2006 ., p. 16.5.1) and density (“Rules for the classification, construction and equipment of floating drilling rigs and offshore stationary platforms, 2006, p. 16.5.1), requirements for external protective coatings for oil and oil resistance, resistance to sea water and sea fog. (“Rules for the classification, construction and equipment of floating drilling rigs and offshore fixed platforms”, 2006, clauses 2.3.2.1. And 16.8.1.5) and providing the ability to work in conditions of mobile installation.

The technical result is achieved by the fact that a control cable for signaling, informatization and communication is proposed for hazardous areas on floating drilling rigs and offshore stationary platforms, consisting of a core comprising several conductive wires twisted from several copper wires each, insulated with polymer, twisted together in a core, no less than one screen, and a polymer moisture-proof shell. In order to prevent the spread of explosive gaseous mixtures along the cable core, the air cavities in the cable core are filled with polymer aggregate.

To enable the cable to work under conditions of mobile installation, the insulation and moisture-proof sheath must be made of elastomeric materials. One of the main representatives of elastomers is rubber ("Handbook of Electrotechnical Materials" edited by Yu.V. Koritsky, V.V. Pasynkov, B.N. Tareev, vol. 2, third edition, M., "Energoatomizdat", 1987 .) For isolation in this utility model, ethylene propylene and silicone rubber are used, for the shell - polychloroprene rubber. The main quality of rubbers is their elasticity, that is, the possibility of multiple stretching with a return to its original state within the elastic deformation. Chlorosulfonated polyethylene is also used for the moisture barrier. When polyethylene is modified with chlorine and sulfur dioxide, it acquires rubber-like properties. (Handbook of Electrotechnical Materials, edited by Yu.V. Koritsky, V.V. Pasynkov, B.N. Tareev, vol. 1, third edition, M., Energoatomizdat, 1987). Since there are no physical or chemical bonds between the insulation and the sheath in the cable during the stretching process, the insulation and sheath materials can be used in any combination.

According to the rules for constructing intrinsically safe circuits in hazardous areas, the cables used must have one or more shields for constructing ground circuits. The requirements for the screens are provided: in terms of flexibility - the screen is made in the form of a braid of copper wires, in density - the density of the braid is selected so that its mass is not less than 90% of the mass of a copper tube with the same inner diameter and thickness equal to the diameter of the braid wire.

At the request of oil and oil resistance, resistance to sea water and sea fog of the outer cover, the moisture barrier is made of oil and oil resistant, resistant to sea water and sea fog, polychloroprene rubber or chlorosulfonated polyethylene, each of which is an elastomer. The shell materials are superimposed by extrusion under pressure, which ensures the penetration of polymers into the gaps of the braid and reduces moisture permeability in the longitudinal direction.

Mostly, the screen is made in the form of a braid of soft copper wires. When using the cable in conditions of exposure to aggressive gases, in particular hydrogen sulfide, a shield made in the form of a braid of tinned copper wires is used to protect copper wires from corrosion.

The screen in the form of a braid satisfactorily works in the field of low frequencies and significant amplitudes of electric and magnetic fields (N. I. Belorusov, I. I. Grodnev “Radio-frequency cables”, Gosenergoizdat, ML, 1959). If there is a need to protect electrical equipment from high-frequency external influences, the screen is combined: from successive layers of metal-polymer tape with metal upward with overlapping and braids from tinned copper or copper wires. As a rule, the first layer is made either from an aluminum-polymer tape or from a copper-polymer tape.

In order to protect against corrosion, only a tinned copper braid is used in combination with the aluminum-polymer layer. Copper-polymer screen has more effective shielding properties, but it is much more expensive than aluminum-polymer, therefore it is used in economically determined cases. In combination with a copper-polymer screen, a braid of both soft copper and tinned copper wires can be equally used.

In connection with the peculiarity of the managed object or the principle of organizing the communication line, it is advisable to twist the cores into groups consisting of two, three, or four cores, which, in turn, are twisted into the core by midwire twisting.

By the type of elements on which the screen is superimposed, the screens are divided into:

individual, superimposed on individual insulated conductors, group, superimposed on groups, or general, superimposed on the cable core.

Individual or group screens are used to reduce electromagnetic effects between conductors and / or groups in the core and to organize ground circuits when using the type of protection "intrinsically safe electrical circuit i", the common screen is mainly used to protect the environment from electromagnetic radiation of the cable core and cable core from electromagnetic influences from the outside, as well as for the organization of grounding circuits.

A polymer shell must be applied on top of an individual or group screen, the thickness of which is selected based on the test conditions of a voltage of 500 V AC at a frequency of 50 Hz, applied between any individual screens and / or group screens, and / or a common screen (GOST R 51330.13-99 Sec. 12.2.2.1).

The shell on top of an individual or group screen can be made of any elastomeric material that guarantees the integrity of the dielectric layer between any screens during operation, which can withstand an electrical voltage of 500 V AC at a frequency of 50 Hz.

The dielectric layer between the screens can also be formed by overlapping individual or group screens with belt insulation by wrapping them with polymer tape with overlapping. By changing the pitch of the spiral when bending the cable, the tape can bend without damage. Therefore, the choice of tape material is determined only by its dielectric properties.

In order to protect against mechanical influences, it is advisable to apply armor in the form of a sheath made of galvanized steel or stainless steel wires to the moisture-proof sheath, and a moisture-proof hose made of oil and oil-resistant, resistant to sea water and sea fog polychloroprene rubber or chlorosulfonated polyethylene, each of which is an elastomer, over the armor . The shell materials are superimposed by extrusion under pressure, which ensures the penetration of polymers into the gaps of the braid and reduces moisture permeability in the longitudinal direction.

For armored cables laid in rooms that may be flooded, it is advisable to lay a water blocking layer under the armor.

Under the condition of a limited number of gaskets, mainly no more than three, to ensure increased fire safety requirements, it is necessary that the filler, sheath, moisture protection sheath and moisture protection hose be made of polyvinyl chloride plastic compound or special polyvinyl chloride plastic compound with reduced smoke emission and an oxygen index of at least 28 or halogen-free a polymer composition with an oxygen index of at least 30, and materials for a moisture-proof shell and a moisture-proof hose are made Lebanon neftemaslobenzostoykih from materials that are resistant to sea water and sea spray.

In this case, a specific of the listed materials is selected in accordance with fire safety requirements: the oxygen index and the norm for smoke emission or toxicity of the gases emitted. The oxygen index of ordinary polyvinyl chloride plastic compound is determined by a particular brand, but in general is in the range (19-24).

The filler can be made of any polymer material approved for use in cable designs for hazardous areas on floating drilling rigs and offshore stationary platforms: polyvinyl chloride plastic compound or ethylene propylene, or organosilicon, or polychloroprene rubber, or chlorosulfonated polyethylene. It does not require longitudinal integrity. During cable deformation, it may crack. The main task,

which he performs consists in displacing air from free cavities in the core, additional - easy scraping off the insulation when cutting the cable.

In the future, the proposed utility model is illustrated by a specific implementation example and the attached drawing, which shows a cross-section of an armored control cable, signaling, informatization and communication with individually shielded cores for hazardous areas on floating drilling rigs and offshore stationary platforms, consisting of a core comprising several copper stranded conductive conductors 1, insulated with ethylene-propylene or silicone rubber 2, with individual screen 3 in the form of a braid of copper wires with a density such that the mass of the braid is not less than 90% of the mass of a copper tube with the same inner diameter and thickness equal to the diameter of the braid wire, with sheaths 4 of ethylene propylene rubber, or silicone rubber, or polychloroprene rubber, or chlorosulfonated polyethylene superimposed on top of individual screens 3, twisted together by a twisting twist, filling the air cavities 5 in the core with a polymer filler, a common screen 6 in the form of a braid made of copper dies with a density such that the braid mass is not less than 90% of the mass of the copper tube with the same inner diameter and thickness equal to the diameter of the braid wire overlaid with a moisture-proof sheath 7 made of oil-oil-resistant, seawater and sea fog polychloroprene rubber, or chlorosulfonated polyethylene, armor 8 in the form of a braid of galvanized steel wires and a moisture protection hose 9 of oil and petrol resistant to sea water and sea fog polychloroprene rubber, or chlorosul corrugated polyethylene.

Cable manufacturing technology according to the claimed utility model includes the following operations.

Copper wires for conductive conductors 1 are made of copper wire "wire rod" mainly with a diameter of 8 mm by drawing. Depending on the diameter of the finished wire, either only coarse or coarse and medium drawing is used. After that, the wire is annealed either in special annealing furnaces or in passage annealing devices built into medium drawing machines.

Conductor 1 is twisted from separate wires on cigar-type machines.

Insulation 2 of ethylene-propylene rubber is superimposed on special extrusion lines, of silicone - on continuous vulcanization aggregates.

Shell 4, polymer aggregate 5, moisture barrier 7 and moisture barrier hose 9 are applied to extrusion lines or continuous vulcanization units by compression (pressure) method.

Screens 3 and 6 in the form of braids made of soft copper wires are imposed on braiding machines. The density of the braid is chosen so that its mass is not less than 90% of the mass of the copper tube with the same inner diameter and thickness equal to the diameter of the braid wire.

The braiding wire is made in the same way as the wire for the conductive core, introducing another technological operation - fine drawing. To ensure the required density on reed machines, bundles of several wires are prepared. Armor 8 made of galvanized steel or stainless steel wires is also imposed on braiding machines. The wire is purchased ready. If necessary, bundles of several wires on reed machines are also reed.

To confirm the technical result, three cable samples were made according to this utility model with three pairs of cores with insulation from

ethylene-propylene rubber, with group screens and sheaths of ethylene-propylene rubber, overlaid on each pair, with a polymer core core based on polyvinyl chloride plastic compound, a common screen and a moisture-proof sheath made of polychloroprene rubber and three cable images according to this utility model with three pairs of conductive cores with silicone rubber insulation, with group screens and silicone rubber shells on them, superimposed on each pair, with a polymer core core on based on polyvinyl chloride plastic compound, common screen and moisture-proof sheath made of chlorosulfonated polyethylene. Three cable samples with the prototype construction were also made: with three pairs of cores with insulation made of PVC compound, with group screens and a sheath of PVC compound over them, superimposed on each pair, with a polymer core filling based on PVC compound, a common screen and a moisture-proof sheath made of PVC compound.

The cables were tested with an alternating voltage of 2.5 kV at a frequency of 50 Hz applied between conductive conductors and between conductive conductors and group screens and an alternating voltage of 500 V at a frequency of 50 Hz applied between group screens, between group screens and a common screen. Before electrical tests, they rewound the cables tenfold from drum to drum, simulating tenfold cable routing under operating conditions.

All cable samples for this utility model have passed the listed tests. One sample cable prototype voltage test between the cores could not stand.

Test results confirm the achievement of the technical result.

Claims (11)

1. A control, signaling, informatization and communication cable for explosive areas on floating drilling rigs and offshore stationary platforms, consisting of a core comprising several conductive wires twisted from several copper wires each, insulated with polymer, twisted together in a core of at least one screen, and a moisture-proof polymer shell, characterized in that the insulation of the conductive wires is made of ethylene-propylene or silicone rubber, air gaps in the core filled with polymer aggregate, the screen is made in the form of a braid of copper wires, and the density of the braid is selected so that its mass is not less than 90% of the mass of the copper tube with the same inner diameter and thickness equal to the diameter of the braid wire, and the said moisture-proof sheath is made of oil and oil-resistant resistant to sea water and sea fog of polychloroprene rubber or chlorosulfonated polyethylene, applied under pressure. 2. The cable according to claim 1, characterized in that the insulated conductive conductors are twisted into groups of two, or three, or four conductors, which, in turn, are twisted into a core, and the polymer aggregate is additionally inserted into the air cavities in the groups. 3. A cable according to any one of claims 1 or 2, characterized in that the screen is made individual, superimposed on a separate insulated conductive core, and / or group, superimposed on a separate group, and / or common, superimposed on the core, and on top of each individual and / or group screens, a sheath made of ethylene-propylene, or silicone, or polychloroprene rubber, or chlorosulfonated polyethylene, or waist insulation in the form of a winding with a polymer tape with at least one layer with an overlap. 4. The cable according to claim 3, characterized in that the thickness of the sheath or waist insulation over an individual or group screen is selected so that it can withstand a test of at least 500 V AC at a frequency of 50 Hz applied between any individual and / or group, and / or common screens. 5. Cable according to any one of claims 1 or 2, characterized in that the screen is made in the form of a braid of tinned copper wires. 6. A cable according to any one of claims 1 or 2, characterized in that the screen is made up of metal with a combined top layer of metal-polymer tape upward with overlapping and braided from tinned copper or copper wires. 7. A cable according to any one of claims 1 or 2, characterized in that the armor in the form of a braid of steel galvanized or stainless steel wires and a moisture protection hose of oil-oil-resistant, resistant to sea water and sea fog polychloroprene rubber or chlorosulfonated polyethylene are applied over the said moisture-proof sheath. superimposed under pressure. 8. The cable according to claim 7, characterized in that a water blocking layer is laid under the armor. 9. The cable according to any one of paragraphs 1 or 2, characterized in that the filler, the sheaths and the moisture barrier are made of oil and oil-resistant, sea-water and sea fog resistant polyvinyl chloride plastic compound or special polyvinyl chloride plastic compound with reduced smoke and gas emission and an oxygen index of at least 28, or halogen-free polymer composition with an oxygen index of at least 30, superimposed under pressure. 10. The cable according to claim 9, characterized in that the armor in the form of a braid made of galvanized steel or stainless steel wires and a moisture protection hose made of oil and oil resistant to sea water and sea fog polyvinyl chloride plastic compound or special polyvinyl chloride plastic compound with reduced smoke and gas are overlaid and an oxygen index of at least 28, or a halogen free polymer composition with an oxygen index of at least 30, superimposed under pressure. 11. The cable according to claim 10, characterized in that a water blocking layer is laid under the armor.