RU127243U1 - MOUNTING CABLE - Google Patents

Abstract

The utility model relates to mounting cables, namely, cable designs intended for movable or stationary inside instrument and inter-instrument mounting of electrical devices and output ends of electronic equipment mainly in aggressive environments in the presence of gasoline and petroleum oils.

The technical problem, which the claimed model is aimed at, is to develop an assembly cable design that meets the requirements for oil and gas resistance (GOST 25018-81), and at the same time does not emit halogens in fire conditions while maintaining a high degree of non-proliferation of combustion when laying in bundles.

The technical result provided by the claimed utility model is to create an assembly cable design that meets the requirements for oil and gas resistance (GOST 25018-81), and at the same time does not emit halogens in fire conditions while maintaining a high degree of non-proliferation of combustion when laying in bundles.

The cable contains multi-wire tinned copper conductors insulated with a silane-cross-linked halogen-free polymer composition resistant to oil and gasoline. Isolated cores are twisted together in a core. Over the core, the cable sequentially contains a winding and a protective sheath. The protective shell is made of a halogen-free polymer composition resistant to oil and gasoline. The cable may further comprise a shield in the form of a braid of tinned copper or tinned copper wires under the protective sheath.

Description

The utility model relates to mounting cables, namely, cable designs intended for movable or stationary inside instrument and inter-instrument mounting of electrical devices and output ends of electronic equipment mainly in aggressive environments in the presence of gasoline and petroleum oils.

Currently, the closest analogue of the claimed cable for the totality of features is an installation cable (patent No. 106025 RU from 02.11.2011). The cable contains at least two stranded copper tinned conductive conductors coated with polymer insulation and twisted together. Over twisted insulated cores, a winding and a protective sheath of a polymer composition are sequentially applied. The insulation is made of a halogen-free polyolefin composition with a maximum optical smoke density during combustion and decay of Dmax no more than 180 or of low fire hazard polyvinyl chloride plastic compound with a maximum optical smoke density during combustion of Dmax no more than 220 and with smoldering Dmax no more than 150 and protective the shell is made of a halogen-free polyolefin composition with a maximum optical density of smoke during combustion and decay of Dmax of not more than 180 or of low polyvinyl chloride plastic compound fire hazard with a maximum optical density of smoke during combustion and smoldering Dmax no more than 150. Also, the cable may contain conductive conductors insulated with a polyolefin composition that does not contain halogens of the Vintes 1110 grade (TU U 24.1-30989828-012-2007) or from low fire polyvinyl chloride plastic compound hazards of the PPI 30-30T brand (TU U 24.1-30989828-002-2001). The cable may contain a protective sheath made of a polyolefin composition that does not contain halogens of the Vintes 2010 brand (TU U 24.1-30989828-012-2007) or of low fire hazard PVC compound of the PPO 20-35T grade (TU U 24.1-30989828-002-2001 ) The cable may contain a common screen in the form of a braid of tinned copper wires, located under the protective sheath.

The disadvantages of this cable include the lack of requirements for oil and petrol resistance.

The technical problem, which the claimed model is aimed at, is to develop an assembly cable design that meets the oil and gas resistance requirements in accordance with GOST 25018-81 (2003) “Cables, wires and cords. Methods for determining the mechanical properties of insulation and shell ”, and at the same time not emitting halogens in fire conditions while maintaining a high degree of non-proliferation of combustion when laying in bundles.

The technical solution is aimed at eliminating these shortcomings and is achieved due to the fact that the installation cable contains multi-wire tinned copper conductors, insulated with a silanol-crosslinkable halogen-free self-extinguishing, oil-resistant composition, twisted together. A winding of polymer tape and a protective sheath of a halogen-free self-extinguishing, oil and petrol resistant composition are sequentially applied over twisted cores. The cable may also contain a common screen in the form of a braid of copper or tinned copper wires, located under the protective sheath. The technical result provided by the claimed utility model is to create an assembly cable design that meets the oil and gas resistance requirements (GOST 25018-81 (2003) "Cables, Wires and Cords. Methods for Determining the Mechanical Indices of Insulation and Sheath"), and at the same time not emitting halogens in fire conditions while maintaining a high degree of non-proliferation of combustion when laying in bundles. The utility model is illustrated by the drawing. Figure 1 shows a cable in cross section (according to claim 1 of the formula) Figure 2 shows a cable in cross section (according to claim 2 and claim 3 of the formula)

The inventive cable contains:

conductive conductors made of tinned copper wires 1, insulation made of silanol-crosslinkable, gas-free self-extinguishing, oil and petrol resistant composition 2, a winding of polymer tape 3 superimposed with overlapping, and a protective sheath 5 made of non-hardened self-extinguishing, oil and petrol resistant composition.

Also, the cable may additionally contain: a shield 4, made in the form of a braid of tinned copper or copper wires, located under the protective sheath.

The following is evidence of the industrial applicability of the utility model.

A layer of tin is applied to the wire by electrolytic method. From tinned wires, by drawing method, wires are made for twisting conductive wires. Stranded conductors 1 of individual wires are twisted into bundles on a frame type machine.

The imposition of insulation 2 and shell 5 is carried out by extrusion. The winding 3 is applied on a winding machine.

The screen 4 of soft copper or tinned copper wires is placed on a braiding machine.

As a result of the use of new materials, the cable product ensures the achievement of the technical result indicated by the applicant. The use of these materials allows to ensure a low level of emission of toxic combustion products and smoke, while meeting the requirements for oil and gas resistance according to GOST 25018-81 (2003) “Cables, Wires and cords. Methods for determining the mechanical properties of insulation and shell. "

Claims (3)

1. An assembly cable, consisting of multi-wire tinned copper conductors, characterized in that each core is insulated with a halogen-free silica cross-linked polymer composition that is resistant to oil and gasoline, while the wires are twisted together into a core over which a winding and protective conductor are sequentially applied the shell, the protective shell is made of a halogen-free polymer composition that is resistant to oil and gasoline. 2. The cable according to claim 1, characterized in that it further comprises a shield in the form of a braid of copper wires under the protective sheath. 3. The cable according to claim 1, characterized in that it further comprises a shield under the protective sheath in the form of a braid of tinned copper wires.

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