RU75778U1 - 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 cables for signaling, informatization and communication for hazardous areas on floating drilling rigs and offshore fixed platforms.

Stranded copper conductive conductors insulated with polyvinyl chloride plastic compound are twisted into a core by a twisted twist with the filling of voids with a polymer filler based on polyvinyl chloride plastic compound.

A common screen is superimposed on top of the core either in the form of a braid of tinned copper or copper strands, or a combination of successive layers of metal-polymer tape with metal upward overlapping and braids of tinned copper or copper tins. In this case, 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.

A moisture-proof sheath made of oil and oil-resistant, resistant to sea water and sea fog polyvinyl chloride plasticate is applied on top of the common screen.

A design is proposed in which individual shields superimposed on one or more insulated conductive conductors coincide in design with a common screen and a sheath made of PVC compound.

The thicknesses of the shells on top of the individual screens and the moisture barrier on top of the common screen are selected so that they can withstand a test of at least 500 V AC at a frequency of 50 Hz, applied between any individual screens, between any individual and common screens, between a common screen and water.

Designs of armored cables and cables that meet increased fire hazard requirements are also proposed.

The designs proposed in this utility model will ensure that the cable requirements established in the Rules for the Classification, Construction and Equipment of Floating Drilling Rigs and Offshore Fixed Platforms are met.

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 provided that floating drilling rigs and offshore stationary platforms are laid in compact rooms, and aluminum is also short-lived when used 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.

As a prototype, we choose a cable type KGVV.

The technical task of the proposed utility model is to create 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 m ", 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) and 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 stationary platforms”, 2006, clauses 2.3.2.1. And 16.8.1.5).

The technical problem is solved by the fact that it is proposed a control cable for signaling, information and communication 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 PVC compound, twisted together into a core twisted twist, and moisture-proof sheath made of PVC compound. In order to prevent the spread of explosive gaseous mixtures along the cable core, the air cavities in the cable core are filled with a polymer filler based on polyvinyl chloride plasticate. To meet the requirements for intrinsically safe circuit screens: in terms of flexibility - the screen is made in the form of a braid of tinned copper or copper tinned wires or a combination of successive layers

a metal-polymer tape with metal overlapping upwards and a braid of tinned copper or copper wires, the density-density of the braid is chosen 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 covers, the moisture-proof sheath is made of oil and oil resistance, PVC compound, resistant to sea water and sea fog.

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.

In order to reduce the electromagnetic effects between the cores or groups in the core, it is advisable to impose an individual or, respectively, group screen on one or more cores or groups of cores that meets the same requirements as the common screen.

A polymer shell must be applied over an individual or group screen, the thickness of which is selected on the basis of a test condition of 500 V AC at a frequency of 50 Hz applied between any individual screens, between any individual and common screens, between a common screen and water (GOST R 51330.13- 99 p. 12.2.2.1).

In order to protect against mechanical influences, it is advisable to put armor in the form of a braid of steel galvanized steel or stainless steel wires on the moisture-proof shell, and a moisture-proof hose made of oil and oil-resistant, resistant to sea water and sea fog PVC compound, over the armor.

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

To ensure increased fire safety requirements, it is necessary that the insulation, core, sheath, moisture barrier and moisture hose are made of special PVC compound with reduced smoke emission and an oxygen index of at least 30 or a halogen-free polymer composition with an oxygen index of at least 35, and the materials for a moisture-proof sheath and a moisture-proof hose are made of oil-and-oil-resistant materials resistant to sea water and sea fog.

The proposed utility model is illustrated by a specific implementation example and the attached drawing, in which Fig. 1 shows a cross section of an armored control cable, signaling, information and communication with individually shielded cores for hazardous areas on floating drilling rigs and offshore stationary platforms.

Control cable for signaling, informatization and communication with individually shielded cores for hazardous areas on floating drilling rigs and offshore fixed platforms 1 (Fig. 1) consisting of a core including several copper multi-wire conductive cores 2, insulated with PVC plastic 3, with individual shields 4 in the form of a braid of copper wires, with sheaths 5, superimposed on top of individual shields 4, twisted together by a twist, with filling the air cavities 6 in the core with polymer filler, a common screen 7 in the form of a braid of copper wires, laid on top of the core, a moisture-proof sheath 8 of oil-and-oil-resistant, resistant to sea water and sea fog PVC compound, armor 9 in the form of a braid of steel galvanized wires and a moisture-proof hose 10 of oil and oil-resistant, resistant to sea water and sea fog of PVC compound.

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

Copper wires for conductive conductors 2 are made, as a rule, from copper wire "wire rod" mainly with a diameter of 8 mm by drawing method. 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 2 is twisted from separate wires on cigar-type machines.

Insulation 3, shell 5, moisture barrier 8, moisture barrier 10 are applied to the extrusion lines. Moreover, in all cases, the extrusion of polymeric materials is carried out by a compression method (under pressure).

Screens 5 and 7 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. To ensure the required density on reed machines, bundles of several wires are prepared. Armor 9 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.

The water-blocking layer is imposed by winding in a spiral with water-blocking tapes on a tape-wrapping machine or longitudinally under armor for braiding operations.

To confirm the technical result, three cable samples were made with four individually shielded conductors with sheaths along the screens, core filling, common screen and moisture-proof sheath.

A test was conducted with a voltage of 500 V AC at a frequency of 50 Hz applied between individual screens, between individual screens and a common screen, between a common screen and water. All samples were voltage tested.

Claims (15)

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 PVC compound, twisted together in a core by twisted twist, and moisture-proof sheath made of polyvinyl chloride plasticate, characterized in that the air gaps in the core are filled with a polymeric vinyl-based polymer aggregate Of the plastic compound, a common screen is applied over the core under the moisture-proof sheath, either in the form of a braid made of copper or copper tinned wires, or combined from successive layers of metal-polymer tape with the metal upward overlapping and braids made of copper or copper tinned wires, and the density of the braid is chosen so that its mass was 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 was made of oil and oil-resistant, resistant to sea water and sea fog, polyvinyl chloride plasticate, or 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, three or four conductors, which, in turn, are twisted into a core. 3. 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 and oil resistant to sea water and sea fog polyvinyl chloride plastic compound or polychloroprene are applied over the said moisture-proof sheath. rubber, or chlorosulfonated polyethylene, superimposed under pressure. 4. The cable according to claim 3, characterized in that a water blocking layer is laid under the armor. 5. Cable according to any one of claims 1 or 2, characterized in that the insulation, filler, sheaths and moisture protection sheath are made of oil and oil-resistant, special PVC compound with low smoke emission and oxygen index of at least 30 or of halogen-free, resistant to sea water and sea fog polymer composition with an oxygen index of at least 35, superimposed under pressure. 6. The cable according to claim 5, 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 special PVC compound with reduced smoke emission and an oxygen index at least 30 or from a halogen-free polymer composition with an oxygen index of at least 35, superimposed by pressure. 7. The cable according to claim 6, characterized in that a water blocking layer is laid under the armor. 8. Cable according to any one of claims 1 or 2, characterized in that on each one or more insulated conductive wires or groups individual or group screens are superimposed, either in the form of a braid of tinned copper or copper wires, or combined from successive layers of metal-polymer metal strips upward with overlapping and braids from tinned copper or copper wires, and the density of the braid is chosen 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 ru braid wire, and sheath made of PVC compound, imposed under pressure. 9. The cable according to claim 8, characterized in that the shell thicknesses are selected so that they withstand a test of at least 500 V AC at a frequency of 50 Hz applied between any individual or group screens, between any individual or group and common screens. 10. The cable according to claim 8, 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 polychloroprene rubber, or chlorosulfonated are applied over the said moisture-proof sheath. polyethylene superimposed by pressure. 11. The cable according to claim 10, characterized in that a water blocking layer is laid under the armor. 12. The cable according to claim 8, characterized in that the insulation, filler, sheaths and moisture protection sheath are made of oil and oil resistant to sea water and sea fog special PVC compound with reduced smoke emission and an oxygen index of at least 30 or from a halogen-free polymer composition with oxygen index of at least 35 superimposed under pressure. 13. The cable according to claim 12, characterized in that the shell thicknesses are selected so that they withstand a test of at least 500 V AC at a frequency of 50 Hz applied between any individual or group screens, between any individual or group screens and a common screen. 14. The cable according to claim 12, characterized in that the armor in the form of a braid of steel galvanized or stainless steel wires and a moisture-proof hose under pressure of oil and oil resistant to sea water and sea fog special polyvinyl chloride plastic compound with reduced smoke and an oxygen index of at least 30 or a halogen-free polymer composition with an oxygen index of at least 35, superimposed by pressure. 15. The cable according to 14, characterized in that a water blocking layer is laid under the armor.