CN106024104A - Inner sheath for seafloor high-voltage power cable and manufacturing method for inner sheath - Google Patents
Inner sheath for seafloor high-voltage power cable and manufacturing method for inner sheath Download PDFInfo
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- CN106024104A CN106024104A CN201610361002.2A CN201610361002A CN106024104A CN 106024104 A CN106024104 A CN 106024104A CN 201610361002 A CN201610361002 A CN 201610361002A CN 106024104 A CN106024104 A CN 106024104A
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- H01B7/00—Insulated conductors or cables characterised by their form
- H01B7/17—Protection against damage caused by external factors, e.g. sheaths or armouring
- H01B7/18—Protection against damage caused by wear, mechanical force or pressure; Sheaths; Armouring
- H01B7/182—Protection against damage caused by wear, mechanical force or pressure; Sheaths; Armouring comprising synthetic filaments
- H01B7/183—Protection against damage caused by wear, mechanical force or pressure; Sheaths; Armouring comprising synthetic filaments forming part of an outer sheath
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Abstract
The invention belongs to the technical field of a cable, and particularly relates to an inner sheath for a seafloor high-voltage power cable. The inner sheath comprises conductive units, a metal shielding layer, a water-blocking layer and an inner sheath from inside to outside in sequence, wherein each conductive unit comprises a conductor, an insulating layer, an insulating shielding layer and a conductor protective layer; on any one cross section, the center of a circle of the conductor is overlapped with that of the corresponding insulating layer; the diameter of the insulating layer is 1.5-5 times of that of the conductor, and the minimum thickness of the insulating layer is 1.5mm; a filling rope group and a reinforcing part group are distributed on the exterior of the inner sheath alternately; the filling rope group and the reinforcing part group are both tightly attached to the inner sheath; an outer sheath protective layer is prepared from polyamide; and the insulating layer is prepared from organosilane crosslinked polyethylene or a special material. The invention also discloses a manufacturing method for the inner sheath. The inner sheath has the main beneficial effects of more appropriate mechanical performance redundancy quantity, capability of saving more resources, better wear-resisting property, better anti-seepage performance, higher seawater prevention, better shielding performance, and capability of transmitting high voltage with a better effect.
Description
The application is entitled: seabed high tension cable and manufacture method, filing date: on 09 15th, 2014, Application No.: the divisional application of the patent of invention of 201510049118.8;Application No.: the application of the patent of invention of 201510049118.8 require that entitled: seabed high tension cable and manufacture method, filing date: on 09 15th, 2014, Application No.: the divisional application of the patent of invention of 201410467691.6.
Technical field
The invention belongs to seabed cable technical field, especially relate to seabed high voltage power cable and manufacture method thereof and seabed high voltage power cable inner sheath and manufacture method thereof.
Background technology
Earth surface is divided into, by each big land, the vast waters communicated with each other and is referred to as ocean, and its gross area of the earth is about 3.6 hundred million square kilometres, and account for that earth surface is long-pending 71%, approximately equal to 2.5 times of land surface, world ocean is a huge treasure-house.It has a large amount of things necessary to the mankind and abundant industrial resources.Five main ocean of the earth are the Pacific Ocean, the Atlantic Ocean and the Indian Ocean, the Arctic Ocean, Antarctic Ocean, and major part is with land and sea-floor relief line as boundary.
Along with developing rapidly of industry, the exploration scale of Yu Haiyang is increased by people day by day, the value of ocean is also more paid attention to by people, for this, need to lay various submarine cable and be used as infrastructure, submarine cable is most commonly used that seabed high voltage power cable, submarine optical fiber cable, sea floor optoelectronic composite cable.
In prior art, people had carried out research for seabed high voltage power cable, as: publication No. is CN102290135A, entitled: rated voltage 220kV tri-core photoelectric composite submarine cable, outer layer is draped over one's shoulders including be sequentially distributed from outside to inside, armor and inner liner, three two biphase circumscribed electric units it are provided with in described inner liner, described electric unit and described inner liner surrounded three at gap be all filled with multiple filling unit, three described electric units and all of filling unit whole stranded formation one stock market main core segment of cable, it is surrounded with gluing strap outside the main core segment of extra large cable after stranded, in all of filling unit, at least one of which is light unit, remaining fills unit is gasket for packing, the rated voltage of this kind of cable has reached 220KV.
For another example: publication No. is CN101807450A, entitled: a kind of sea electric power cable; including the conductor (1) arranged from the inside to the outside, semi-conductive layer (2), insulating barrier (3), cushion (4), lead set (5), inner restrictive coating (6), armor (7) and armouring external protection (8); it is characterized in that: the mixed layer that described inner restrictive coating (6) is in series by two kinds of form head and the tail of semiconductive inner restrictive coating and insulation inner restrictive coating; the problem solving induced potential; and reduce loss, improve the purpose of current-carrying capacity.
Publication No. is CN101807453A, entitled: for the power cable in seabed; including the core (1) arranged from the inside to the outside, screen layer (2), insulation (3), insulator screen layer and sheath (4), armouring inner cushion layer (5), armor (6) and armouring external protection (7); it is characterized in that: described core (1) is made up of steel wire wire and aluminum conductor; described steel wire wire is positioned at the center of core (1), and steel wire wire is twisted into, with aluminum conductor, the core (1) that steel-cored aluminium strand structure is formed jointly.The core that it uses is made up of steel wire wire and aluminum conductor, and described steel wire wire is positioned at the center of core, and steel wire wire is twisted into, with aluminum conductor, the core that steel-cored aluminium strand structure is formed jointly.Be substituted for copper by aluminum, not only save cost, and electric conductivity is also fully consistent with standard, and steel wire therein twists the blend of aluminum, solves again the problem that aluminum conductor tensile strength is not enough.
But, applicant is after repetition test, think that seabed of the prior art high tension cable there is also the space that structure is improved, it is mainly manifested in (1) armor amount of redundancy excessive, mainly tensile strength aspect, primary concern is that the rounding of cable, therefore in prior art, the reinforcement that armor uses, far beyond the tensile strength of demand, causes the waste of resource;(2) anti-wear performance of external protection, water-impervious, anti-sea water performance are to be improved;(3) screen layer can improve further with the set-up mode of insulating barrier, preferably to improve cable performance;(4) material of insulating barrier needs to be researched and developed further so that it is can reach higher pressure grade or performance.
Summary of the invention
In order to solve the problems referred to above, it is an object of the invention to disclose seabed high voltage power cable and manufacture method thereof, and seabed high voltage power cable inner sheath and its manufacture method, they realize by the following technical solutions.
A kind of seabed high voltage power cable inner sheath, it is characterized in that it is to be made up of the metal screen layer set gradually from inside to outside, water blocking layer, tack coat, inner sheath, there is inside metal screen layer the conductive unit of three two biphase circumscribed settings, three conductive units and metal screen layer phase inscribe;Described conductive unit be coated on outside conductor by conductor, extrusion molding insulating barrier, be positioned at the insulation screen outside insulating barrier, conductor sheath that extrusion molding is coated on outside insulation screen is constituted, on arbitrary cross section, the center of circle of conductor coincides with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Described armor is made up of gasket for packing, reinforcement, reinforcement by stiffener, be coated on the plastic layer outside stiffener and constitute, gasket for packing is one group with two and is constituted gasket for packing group, gasket for packing group and reinforcement are alternately distributed outside inner sheath, and gasket for packing group and reinforcement are all close to inner sheath;Described insulating barrier is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;The material of described gasket for packing is linear low density polyethylene.
The manufacture method of a kind of seabed high voltage power cable inner sheath, it is characterised in that it is to comprise the steps of
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take insulating layer material again, described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Or described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 80 parts, ethylene-vinyl acetate copolymer: 15 parts, ethylene-tetrafluoroethylene copolymer: 12 parts, magnesium hydroxide: 13 parts, antioxidant 1010: 4 parts, strontium titanates: 3 parts, calcium titanate: 3 parts, bismuth titanates: 3 parts, magnesium titanate: 3 parts, silicon dioxide: 4 parts, zirconium dioxide: 4 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;
Second step: manufacture the step of metal screen layer: take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped and be coated with outside the conductive unit formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form the step of water blocking layer: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the water blocking layer outside formation inner sheath manufactured in the third step;Form seabed high voltage power cable inner sheath.
The manufacture method of a kind of seabed high voltage power cable inner sheath, it is characterised in that it is to comprise the steps of
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take insulating layer material again, described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Or described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 80 parts, ethylene-vinyl acetate copolymer: 15 parts, ethylene-tetrafluoroethylene copolymer: 12 parts, magnesium hydroxide: 13 parts, antioxidant 1010: 4 parts, strontium titanates: 3 parts, calcium titanate: 3 parts, bismuth titanates: 3 parts, magnesium titanate: 3 parts, silicon dioxide: 4 parts, zirconium dioxide: 4 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;Above-mentioned steps repeatedly, until forming three conductive units;
Second step: manufacture the step of metal screen layer: take three conductive units two manufactured in the first step biphase circumscribedly stranded or be placed in parallel, conductive unit intertwist body;Take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped again to be close to be coated with outside the conductive unit intertwist body formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form water blocking layer and the step of tack coat: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;Take polypropylene extrusion molding to be coated on outside water blocking layer and form tack coat;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the tack coat outside formation inner sheath manufactured in the third step;Form seabed high voltage power cable inner sheath.
The manufacture method of a kind of seabed high voltage power cable inner sheath, it is characterised in that it is to comprise the steps of
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take insulating layer material again, described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Or described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 80 parts, ethylene-vinyl acetate copolymer: 15 parts, ethylene-tetrafluoroethylene copolymer: 12 parts, magnesium hydroxide: 13 parts, antioxidant 1010: 4 parts, strontium titanates: 3 parts, calcium titanate: 3 parts, bismuth titanates: 3 parts, magnesium titanate: 3 parts, silicon dioxide: 4 parts, zirconium dioxide: 4 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;Above-mentioned steps repeatedly, until forming three conductive units;
Second step: manufacture the step of metal screen layer: take three conductive units two manufactured in the first step biphase circumscribedly stranded or be placed in parallel, conductive unit intertwist body;Take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped again to be close to be coated with outside the conductive unit intertwist body formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form water blocking layer and the step of tack coat: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;Take polypropylene extrusion molding to be coated on outside water blocking layer and form tack coat;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the tack coat outside formation inner sheath manufactured in the third step;Form seabed high voltage power cable inner sheath.
The manufacture method of a kind of seabed high voltage power cable inner sheath, it is characterised in that it is to comprise the steps of
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take insulating layer material again, described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Or described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 80 parts, ethylene-vinyl acetate copolymer: 15 parts, ethylene-tetrafluoroethylene copolymer: 12 parts, magnesium hydroxide: 13 parts, antioxidant 1010: 4 parts, strontium titanates: 3 parts, calcium titanate: 3 parts, bismuth titanates: 3 parts, magnesium titanate: 3 parts, silicon dioxide: 4 parts, zirconium dioxide: 4 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;Above-mentioned steps repeatedly, until forming three conductive units;
Second step: manufacture the step of metal screen layer: take three conductive units two manufactured in the first step biphase circumscribedly stranded or be placed in parallel, conductive unit intertwist body;Take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped again to be close to be coated with outside the conductive unit intertwist body formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form water blocking layer and the step of tack coat: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;Take polypropylene extrusion molding to be coated on outside water blocking layer and form tack coat;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the tack coat outside formation inner sheath manufactured in the third step;Form seabed high voltage power cable inner sheath.
In first embodiment of the present invention, seabed high voltage power cable, it is characterised in that it is to be made up of the conductive unit 1 set gradually from inside to outside, metal screen layer 2, water blocking layer 3, inner sheath 5, armor, oversheath 8, oversheath protective layer 9;Described conductive unit 1 be coated on outside conductor by conductor 11, extrusion molding insulating barrier 12, be positioned at the insulation screen 13 outside insulating barrier, conductor sheath 14 that extrusion molding is coated on outside insulation screen is constituted, on arbitrary cross section, the center of circle of conductor coincides with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Described armor is made up of gasket for packing 6, reinforcement 7, reinforcement 7 by stiffener 71, be coated on the plastic layer 72 outside stiffener and constitute, gasket for packing is one group with three and is constituted gasket for packing group, reinforcement is one group with three and is constituted reinforcement group, gasket for packing group and reinforcement group are alternately distributed outside inner sheath, and gasket for packing group and reinforcement group are all close to inner sheath;The material of described oversheath protective layer is polyamide;The material of described insulating barrier is organosilane crosslinked polyethylene or by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts.
In second embodiment of the present invention; seabed high voltage power cable; it is characterized in that it is to be made up of the metal screen layer 2 set gradually from inside to outside, water blocking layer 3, tack coat 4, inner sheath 5, armor, oversheath 8, oversheath protective layer 9; there is inside metal screen layer the conductive unit 1 of three two biphase circumscribed settings, three conductive units and metal screen layer phase inscribe;Described conductive unit 1 be coated on outside conductor by conductor 11, extrusion molding insulating barrier 12, be positioned at the insulation screen 13 outside insulating barrier, conductor sheath 14 that extrusion molding is coated on outside insulation screen is constituted, on arbitrary cross section, the center of circle of conductor coincides with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Described armor is made up of gasket for packing 6, reinforcement 7, reinforcement 7 by stiffener 71, be coated on the plastic layer 72 outside stiffener and constitute, gasket for packing is one group with two and is constituted gasket for packing group, gasket for packing group and reinforcement are alternately distributed outside inner sheath, and gasket for packing group and reinforcement are all close to inner sheath;The material of described oversheath protective layer is polyamide;The material of described insulating barrier is organosilane crosslinked polyethylene or by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts.
In 3rd embodiment of the present invention, seabed high voltage power cable, it is characterized in that it is to be made up of the metal screen layer 2 set gradually from inside to outside, water blocking layer 3, tack coat 4, inner sheath 5, armor, oversheath 8, there is inside metal screen layer the conductive unit 1 of three two biphase circumscribed settings, three conductive units and metal screen layer phase inscribe;Described conductive unit 1 be coated on outside conductor by conductor 11, extrusion molding insulating barrier 12, be positioned at the insulation screen 13 outside insulating barrier, conductor sheath 14 that extrusion molding is coated on outside insulation screen is constituted, on arbitrary cross section, the center of circle of conductor coincides with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Described armor is made up of gasket for packing 6, reinforcement 7, reinforcement 7 by stiffener 71, be coated on the plastic layer 72 outside stiffener and constitute, gasket for packing and reinforcement are alternately distributed outside inner sheath, and gasket for packing and reinforcement are all close to inner sheath;The material of described insulating barrier is organosilane crosslinked polyethylene or by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts.
In 4th embodiment of the present invention, seabed high voltage power cable, it is characterized in that it is to be made up of the metal screen layer 2 set gradually from inside to outside, water blocking layer 3, tack coat 4, inner sheath 5, armor, oversheath 8, there is inside metal screen layer the conductive unit 1 of three two biphase circumscribed settings, three conductive units and metal screen layer phase inscribe;Described conductive unit 1 be coated on outside conductor by conductor 11, extrusion molding insulating barrier 12, be positioned at the insulation screen 13 outside insulating barrier, conductor sheath 14 that extrusion molding is coated on outside insulation screen is constituted, on arbitrary cross section, the center of circle of conductor coincides with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Described armor is made up of gasket for packing 6, reinforcement 7, reinforcement 7 by stiffener 71, be coated on the plastic layer 72 outside stiffener and constitute, gasket for packing is one group with two and is constituted gasket for packing group, gasket for packing group and reinforcement are alternately distributed outside inner sheath, and gasket for packing group and reinforcement are all close to inner sheath;The material of described insulating barrier is organosilane crosslinked polyethylene or by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts.
Seabed high voltage power cable in the present invention the first embodiment, it by the following method step be fabricated by:
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take organosilane crosslinked polyethylene or by weight again, be made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;
Second step: manufacture the step of metal screen layer: take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped and be coated with outside the conductive unit formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form the step of water blocking layer: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the water blocking layer outside formation inner sheath manufactured in the third step;
5th step: manufacture the step of armor: take outside the inner sheath that pre-manufactured gasket for packing and reinforcement helical coated manufacture in the 4th step, wherein reinforcement by stiffener, be coated on the plastic layer outside stiffener and constitute, gasket for packing is one group with three and is constituted gasket for packing group, reinforcement is one group with three and is constituted reinforcement group, gasket for packing group and reinforcement group are alternately distributed outside inner sheath, and gasket for packing group and reinforcement group are all close to inner sheath;The material of stiffener is steel wire or fiberglass reinforced plastics or aramid yarn;The material of plastic layer is polypropylene or linear low density polyethylene or Low Density Polyethylene or high density polyethylene (HDPE);The diameter of gasket for packing is equal with the diameter of reinforcement;
6th step: manufacture the step of oversheath: be coated on outside the armor that the 5th step is formed by oversheath extruding machine by high density polyethylene (HDPE) or medium density polyethylene extrusion molding, form oversheath;
7th step: manufacture the step of oversheath protective layer: take polyamide and be coated in the 6th step outside the oversheath manufactured by its extrusion molding, forms seabed high voltage power cable finished product, and the thickness of described oversheath protective layer is 1.0~2.0mm.
Seabed high voltage power cable in the present invention the second embodiment, it by the following method step be fabricated by:
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take organosilane crosslinked polyethylene or by weight again, be made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;Above-mentioned steps repeatedly, until forming three conductive units;
Second step: manufacture the step of metal screen layer: take three conductive units two manufactured in the first step biphase circumscribedly stranded or be placed in parallel, conductive unit intertwist body;Take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped again to be close to be coated with outside the conductive unit intertwist body formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form water blocking layer and the step of tack coat: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;Take polypropylene extrusion molding to be coated on outside water blocking layer and form tack coat;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the tack coat outside formation inner sheath manufactured in the third step;
5th step: manufacture the step of armor: take outside the inner sheath that pre-manufactured gasket for packing and reinforcement helical coated manufacture in the 4th step, wherein reinforcement by stiffener, be coated on the plastic layer outside stiffener and constitute, gasket for packing is one group with two and is constituted gasket for packing group, gasket for packing group and reinforcement are alternately distributed outside inner sheath, and gasket for packing group and reinforcement are all close to inner sheath;The material of stiffener is steel wire or fiberglass reinforced plastics or aramid yarn;The material of plastic layer is polypropylene or linear low density polyethylene or Low Density Polyethylene or high density polyethylene (HDPE);The diameter of gasket for packing is equal with the diameter of reinforcement;
6th step: manufacture the step of oversheath: be coated on outside the armor that the 5th step is formed by oversheath extruding machine by high density polyethylene (HDPE) or medium density polyethylene extrusion molding, form oversheath;
7th step: manufacture the step of oversheath protective layer: take polyamide and be coated in the 6th step outside the oversheath manufactured by its extrusion molding, forms seabed high voltage power cable finished product, and the thickness of described oversheath protective layer is 1.0~2.0mm.
Seabed high voltage power cable in the present invention the 3rd embodiment, it by the following method step be fabricated by:
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take organosilane crosslinked polyethylene or by weight again, be made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;Above-mentioned steps repeatedly, until forming three conductive units;
Second step: manufacture the step of metal screen layer: take three conductive units two manufactured in the first step biphase circumscribedly stranded or be placed in parallel, conductive unit intertwist body;Take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped again to be close to be coated with outside the conductive unit intertwist body formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form water blocking layer and the step of tack coat: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;Take polypropylene extrusion molding to be coated on outside water blocking layer and form tack coat;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the tack coat outside formation inner sheath manufactured in the third step;
5th step: manufacture the step of armor: take outside the inner sheath that pre-manufactured gasket for packing and reinforcement helical coated manufacture in the 4th step, wherein reinforcement by stiffener, be coated on the plastic layer outside stiffener and constitute, gasket for packing and reinforcement are alternately distributed outside inner sheath, and gasket for packing and reinforcement are all close to inner sheath;The material of stiffener is steel wire or fiberglass reinforced plastics or aramid yarn;The material of plastic layer is polypropylene or linear low density polyethylene or Low Density Polyethylene or high density polyethylene (HDPE);The diameter of gasket for packing is equal with the diameter of reinforcement;
6th step: manufacture the step of oversheath: be coated on outside the armor that the 5th step is formed by oversheath extruding machine by high density polyethylene (HDPE) or medium density polyethylene extrusion molding, form oversheath;Complete the manufacture of seabed high voltage power cable finished product.
Seabed high voltage power cable in the present invention the 4th embodiment, it by the following method step be fabricated by:
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take organosilane crosslinked polyethylene or by weight again, be made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;Above-mentioned steps repeatedly, until forming three conductive units;
Second step: manufacture the step of metal screen layer: take three conductive units two manufactured in the first step biphase circumscribedly stranded or be placed in parallel, conductive unit intertwist body;Take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped again to be close to be coated with outside the conductive unit intertwist body formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form water blocking layer and the step of tack coat: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;Take polypropylene extrusion molding to be coated on outside water blocking layer and form tack coat;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the tack coat outside formation inner sheath manufactured in the third step;
5th step: manufacture the step of armor: take outside the inner sheath that pre-manufactured gasket for packing and reinforcement helical coated manufacture in the 4th step, wherein reinforcement by stiffener, be coated on the plastic layer outside stiffener and constitute, gasket for packing is one group with two and is constituted gasket for packing group, gasket for packing group and reinforcement are alternately distributed outside inner sheath, and gasket for packing group and reinforcement are all close to inner sheath;The material of stiffener is steel wire or fiberglass reinforced plastics or aramid yarn;The material of plastic layer is polypropylene or linear low density polyethylene or Low Density Polyethylene or high density polyethylene (HDPE);The diameter of gasket for packing is equal with the diameter of reinforcement;
6th step: manufacture the step of oversheath: be coated on outside the armor that the 5th step is formed by oversheath extruding machine by high density polyethylene (HDPE) or medium density polyethylene extrusion molding, form oversheath;Complete the manufacture of seabed high voltage power cable finished product.
In the present invention, due to reinforcement by stiffener, be coated on the plastic layer outside stiffener and constitute, therefore, the size of stiffener can carry out appropriate design according to mechanical property requirements, and its outside plastic layer achieves tangent, the technology of rounding, i.e. armor amount of redundancy can be transferred to properly, coordinates gasket for packing to order and makes resource more save.
In the present invention, oversheath and presumable oversheath protective layer, make product be provided with the anti-wear performance more excellent than prior art, water-impervious, anti-sea water performance.
In the present invention, screen layer is different with of the prior art from the set-up mode of insulating barrier, and in prior art, screen layer is close to conductor, is actually difficulty with the effect of shielding;Therefore, the present invention makes the shielding properties of cable be substantially improved, not only achieve the eliminating of external disturbance, considerably reduce the impact that conductor self radiation is external simultaneously.
In the present invention, owing to have employed special insulating layer material, and suitably thickness proportion and concentricity, the insulating properties making cable are greatly increased, and through test, the present invention is for the electric power of transmission 500~1000KV, 1000 meters, 30,000 hours, any punch-through is not had to occur.
Simply, easily grasp, the production equipment using cable production firm conventional i.e. can produce the cable making method of the present invention, and therefore, equipment investment is few, more economically practical, makes utilization rate of equipment and installations higher.
Therefore, the present invention has a following main beneficial effect: cable machinery performance redundancy amount is more suitable, resource is more saved, more anti-wear performance, more can water-impervious, more anti-sea water, shielding properties more preferably, more can transmit high voltage.
Accompanying drawing explanation
Fig. 1 is the perspective view after one section of stripping of embodiment 1 of the present invention.
Fig. 2 is the cross-sectional structure schematic diagram after Fig. 1 amplifies.
Fig. 3 is the perspective view after one section of stripping of embodiment 2 of the present invention.
Fig. 4 is the cross-sectional structure schematic diagram after Fig. 3 amplifies.
Fig. 5 is the perspective view after one section of stripping of embodiment 3 of the present invention.
Fig. 6 is the cross-sectional structure schematic diagram after Fig. 5 amplifies.
Fig. 7 is the perspective view after one section of stripping of embodiment 4 of the present invention.
Fig. 8 is the cross-sectional structure schematic diagram after Fig. 7 amplifies.
Detailed description of the invention
Embodiment
1
Ask for an interview Fig. 1 and Fig. 2, seabed high voltage power cable, it is characterised in that it is to be made up of the conductive unit 1 set gradually from inside to outside, metal screen layer 2, water blocking layer 3, inner sheath 5, armor, oversheath 8, oversheath protective layer 9;Described conductive unit 1 be coated on outside conductor by conductor 11, extrusion molding insulating barrier 12, be positioned at the insulation screen 13 outside insulating barrier, conductor sheath 14 that extrusion molding is coated on outside insulation screen is constituted, on arbitrary cross section, the center of circle of conductor coincides with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Described armor is made up of gasket for packing 6, reinforcement 7, reinforcement 7 by stiffener 71, be coated on the plastic layer 72 outside stiffener and constitute, gasket for packing is one group with three and is constituted gasket for packing group, reinforcement is one group with three and is constituted reinforcement group, gasket for packing group and reinforcement group are alternately distributed outside inner sheath, and gasket for packing group and reinforcement group are all close to inner sheath;The material of described oversheath protective layer is polyamide;The material of described insulating barrier is organosilane crosslinked polyethylene or by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts.
The mode that seabed high voltage power cable described above, it is characterised in that the material of described metal screen layer is steel band or aluminium strip or copper strips is in the way of longitudinally cladding or spiral is wrapped is coated on outside conductive unit;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm.
Embodiment
2
Ask for an interview Fig. 3 and Fig. 4; seabed high voltage power cable; it is characterized in that it is to be made up of the metal screen layer 2 set gradually from inside to outside, water blocking layer 3, tack coat 4, inner sheath 5, armor, oversheath 8, oversheath protective layer 9; there is inside metal screen layer the conductive unit 1 of three two biphase circumscribed settings, three conductive units and metal screen layer phase inscribe;Described conductive unit 1 be coated on outside conductor by conductor 11, extrusion molding insulating barrier 12, be positioned at the insulation screen 13 outside insulating barrier, conductor sheath 14 that extrusion molding is coated on outside insulation screen is constituted, on arbitrary cross section, the center of circle of conductor coincides with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Described armor is made up of gasket for packing 6, reinforcement 7, reinforcement 7 by stiffener 71, be coated on the plastic layer 72 outside stiffener and constitute, gasket for packing is one group with two and is constituted gasket for packing group, gasket for packing group and reinforcement are alternately distributed outside inner sheath, and gasket for packing group and reinforcement are all close to inner sheath;The material of described oversheath protective layer is polyamide;The material of described insulating barrier is organosilane crosslinked polyethylene or by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts.
Embodiment
3
Ask for an interview Fig. 5 and Fig. 6, seabed high voltage power cable, it is characterized in that it is to be made up of the metal screen layer 2 set gradually from inside to outside, water blocking layer 3, tack coat 4, inner sheath 5, armor, oversheath 8, there is inside metal screen layer the conductive unit 1 of three two biphase circumscribed settings, three conductive units and metal screen layer phase inscribe;Described conductive unit 1 be coated on outside conductor by conductor 11, extrusion molding insulating barrier 12, be positioned at the insulation screen 13 outside insulating barrier, conductor sheath 14 that extrusion molding is coated on outside insulation screen is constituted, on arbitrary cross section, the center of circle of conductor coincides with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Described armor is made up of gasket for packing 6, reinforcement 7, reinforcement 7 by stiffener 71, be coated on the plastic layer 72 outside stiffener and constitute, gasket for packing and reinforcement are alternately distributed outside inner sheath, and gasket for packing and reinforcement are all close to inner sheath;The material of described insulating barrier is organosilane crosslinked polyethylene or by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts.
Embodiment
4
Ask for an interview Fig. 7 and Fig. 8, seabed high voltage power cable, it is characterized in that it is to be made up of the metal screen layer 2 set gradually from inside to outside, water blocking layer 3, tack coat 4, inner sheath 5, armor, oversheath 8, there is inside metal screen layer the conductive unit 1 of three two biphase circumscribed settings, three conductive units and metal screen layer phase inscribe;Described conductive unit 1 be coated on outside conductor by conductor 11, extrusion molding insulating barrier 12, be positioned at the insulation screen 13 outside insulating barrier, conductor sheath 14 that extrusion molding is coated on outside insulation screen is constituted, on arbitrary cross section, the center of circle of conductor coincides with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Described armor is made up of gasket for packing 6, reinforcement 7, reinforcement 7 by stiffener 71, be coated on the plastic layer 72 outside stiffener and constitute, gasket for packing is one group with two and is constituted gasket for packing group, gasket for packing group and reinforcement are alternately distributed outside inner sheath, and gasket for packing group and reinforcement are all close to inner sheath;The material of described insulating barrier is organosilane crosslinked polyethylene or by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts.
Seabed high voltage power cable described in arbitrary embodiment in above-mentioned embodiment 2-4, it is characterized in that the material of described metal screen layer is steel band or aluminium strip or copper strips, be in the way of longitudinally cladding or the wrapped mode of spiral is coated on the outside that three conductive units are overall;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm.
Seabed high voltage power cable described in arbitrary embodiment in above-mentioned embodiment 2-4, it is characterised in that the material of described tack coat is polypropylene.
Seabed high voltage power cable described in any of the above-described embodiment, it is characterised in that described water blocking layer is waterstop or non-woven fabrics or polyester band or aluminium-plastic tape.
Seabed high voltage power cable described in any of the above-described embodiment, it is characterised in that described insulation screen is conductive plastics.
Seabed high voltage power cable described in any of the above-described embodiment, it is characterised in that the material of described protective cover of conductor is high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene.
Seabed high voltage power cable described in any of the above-described embodiment, it is characterised in that the material of main part of described inner sheath is polyethylene or polrvinyl chloride.
Seabed high voltage power cable described in any of the above-described embodiment, it is characterised in that the material of described oversheath is high density polyethylene (HDPE) or medium density polyethylene.
Seabed high voltage power cable described in any of the above-described embodiment, it is characterised in that the material of described gasket for packing is polypropylene or linear low density polyethylene or Low Density Polyethylene.
Seabed high voltage power cable described in any of the above-described embodiment, it is characterised in that the material of described stiffener is steel wire or fiberglass reinforced plastics or aramid yarn.
Seabed high voltage power cable described in any of the above-described embodiment, it is characterised in that the material of described plastic layer is polypropylene or linear low density polyethylene or Low Density Polyethylene or high density polyethylene (HDPE).
Seabed high voltage power cable in embodiment 1 of the present invention, it by the following method step be fabricated by:
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take organosilane crosslinked polyethylene or by weight again, be made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;
Second step: manufacture the step of metal screen layer: take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped and be coated with outside the conductive unit formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form the step of water blocking layer: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the water blocking layer outside formation inner sheath manufactured in the third step;
5th step: manufacture the step of armor: take outside the inner sheath that pre-manufactured gasket for packing and reinforcement helical coated manufacture in the 4th step, wherein reinforcement by stiffener, be coated on the plastic layer outside stiffener and constitute, gasket for packing is one group with three and is constituted gasket for packing group, reinforcement is one group with three and is constituted reinforcement group, gasket for packing group and reinforcement group are alternately distributed outside inner sheath, and gasket for packing group and reinforcement group are all close to inner sheath;The material of stiffener is steel wire or fiberglass reinforced plastics or aramid yarn;The material of plastic layer is polypropylene or linear low density polyethylene or Low Density Polyethylene or high density polyethylene (HDPE);The diameter of gasket for packing is equal with the diameter of reinforcement;
6th step: manufacture the step of oversheath: be coated on outside the armor that the 5th step is formed by oversheath extruding machine by high density polyethylene (HDPE) or medium density polyethylene extrusion molding, form oversheath;
7th step: manufacture the step of oversheath protective layer: take polyamide and be coated in the 6th step outside the oversheath manufactured by its extrusion molding, forms seabed high voltage power cable finished product, and the thickness of described oversheath protective layer is 1.0~2.0mm.
Seabed high voltage power cable in embodiment 2 of the present invention, it by the following method step be fabricated by:
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take organosilane crosslinked polyethylene or by weight again, be made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;Above-mentioned steps repeatedly, until forming three conductive units;
Second step: manufacture the step of metal screen layer: take three conductive units two manufactured in the first step biphase circumscribedly stranded or be placed in parallel, conductive unit intertwist body;Take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped again to be close to be coated with outside the conductive unit intertwist body formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form water blocking layer and the step of tack coat: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;Take polypropylene extrusion molding to be coated on outside water blocking layer and form tack coat;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the tack coat outside formation inner sheath manufactured in the third step;
5th step: manufacture the step of armor: take outside the inner sheath that pre-manufactured gasket for packing and reinforcement helical coated manufacture in the 4th step, wherein reinforcement by stiffener, be coated on the plastic layer outside stiffener and constitute, gasket for packing is one group with two and is constituted gasket for packing group, gasket for packing group and reinforcement are alternately distributed outside inner sheath, and gasket for packing group and reinforcement are all close to inner sheath;The material of stiffener is steel wire or fiberglass reinforced plastics or aramid yarn;The material of plastic layer is polypropylene or linear low density polyethylene or Low Density Polyethylene or high density polyethylene (HDPE);The diameter of gasket for packing is equal with the diameter of reinforcement;
6th step: manufacture the step of oversheath: be coated on outside the armor that the 5th step is formed by oversheath extruding machine by high density polyethylene (HDPE) or medium density polyethylene extrusion molding, form oversheath;
7th step: manufacture the step of oversheath protective layer: take polyamide and be coated in the 6th step outside the oversheath manufactured by its extrusion molding, forms seabed high voltage power cable finished product, and the thickness of described oversheath protective layer is 1.0~2.0mm.
Seabed high voltage power cable in embodiment 3 of the present invention, it by the following method step be fabricated by:
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take organosilane crosslinked polyethylene or by weight again, be made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;Above-mentioned steps repeatedly, until forming three conductive units;
Second step: manufacture the step of metal screen layer: take three conductive units two manufactured in the first step biphase circumscribedly stranded or be placed in parallel, conductive unit intertwist body;Take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped again to be close to be coated with outside the conductive unit intertwist body formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form water blocking layer and the step of tack coat: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;Take polypropylene extrusion molding to be coated on outside water blocking layer and form tack coat;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the tack coat outside formation inner sheath manufactured in the third step;
5th step: manufacture the step of armor: take outside the inner sheath that pre-manufactured gasket for packing and reinforcement helical coated manufacture in the 4th step, wherein reinforcement by stiffener, be coated on the plastic layer outside stiffener and constitute, gasket for packing and reinforcement are alternately distributed outside inner sheath, and gasket for packing and reinforcement are all close to inner sheath;The material of stiffener is steel wire or fiberglass reinforced plastics or aramid yarn;The material of plastic layer is polypropylene or linear low density polyethylene or Low Density Polyethylene or high density polyethylene (HDPE);The diameter of gasket for packing is equal with the diameter of reinforcement;
6th step: manufacture the step of oversheath: be coated on outside the armor that the 5th step is formed by oversheath extruding machine by high density polyethylene (HDPE) or medium density polyethylene extrusion molding, form oversheath;Complete the manufacture of seabed high voltage power cable finished product.
Seabed high voltage power cable in embodiment 4 of the present invention, it by the following method step be fabricated by:
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take organosilane crosslinked polyethylene or by weight again, be made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;Above-mentioned steps repeatedly, until forming three conductive units;
Second step: manufacture the step of metal screen layer: take three conductive units two manufactured in the first step biphase circumscribedly stranded or be placed in parallel, conductive unit intertwist body;Take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped again to be close to be coated with outside the conductive unit intertwist body formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form water blocking layer and the step of tack coat: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;Take polypropylene extrusion molding to be coated on outside water blocking layer and form tack coat;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the tack coat outside formation inner sheath manufactured in the third step;
5th step: manufacture the step of armor: take outside the inner sheath that pre-manufactured gasket for packing and reinforcement helical coated manufacture in the 4th step, wherein reinforcement by stiffener, be coated on the plastic layer outside stiffener and constitute, gasket for packing is one group with two and is constituted gasket for packing group, gasket for packing group and reinforcement are alternately distributed outside inner sheath, and gasket for packing group and reinforcement are all close to inner sheath;The material of stiffener is steel wire or fiberglass reinforced plastics or aramid yarn;The material of plastic layer is polypropylene or linear low density polyethylene or Low Density Polyethylene or high density polyethylene (HDPE);The diameter of gasket for packing is equal with the diameter of reinforcement;
6th step: manufacture the step of oversheath: be coated on outside the armor that the 5th step is formed by oversheath extruding machine by high density polyethylene (HDPE) or medium density polyethylene extrusion molding, form oversheath;Complete the manufacture of seabed high voltage power cable finished product.
In the present invention, due to reinforcement by stiffener, be coated on the plastic layer outside stiffener and constitute, therefore, the size of stiffener can carry out appropriate design according to mechanical property requirements, and its outside plastic layer achieves tangent, the technology of rounding, i.e. armor amount of redundancy can be transferred to properly, coordinates gasket for packing to order and makes resource more save.
In the present invention, oversheath and presumable oversheath protective layer, make product be provided with the anti-wear performance more excellent than prior art, water-impervious, anti-sea water performance.
In the present invention, screen layer is different with of the prior art from the set-up mode of insulating barrier, and in prior art, screen layer is close to conductor, is actually difficulty with the effect of shielding;Therefore, the present invention makes the shielding properties of cable be substantially improved, not only achieve the eliminating of external disturbance, considerably reduce the impact that conductor self radiation is external simultaneously.
In the present invention, owing to have employed special insulating layer material, and suitably thickness proportion and concentricity, the insulating properties making cable are greatly increased, and through test, the present invention is for the electric power of transmission 500~1000KV, 1000 meters, 30,000 hours, any punch-through is not had to occur.
Through applicant's repeated tests, the optimization formula of discovery insulating barrier is: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 80 parts, ethylene-vinyl acetate copolymer: 15 parts, ethylene-tetrafluoroethylene copolymer: 12 parts, magnesium hydroxide: 13 parts, antioxidant 1010: 4 parts, strontium titanates: 3 parts, calcium titanate: 3 parts, bismuth titanates: 3 parts, magnesium titanate: 3 parts, silicon dioxide: 4 parts, zirconium dioxide: 4 parts.
In the application, insulating barrier is through test, and its major parameter is as follows: melt flows mass rate :≤1.8g/10min;Density≤1.06g/cm3;Hot strength >=21MPa;Break-draw strain >=550%;Resisting environmental stress and cracking F0/h≥130h;Dielectric strength >=75kV/mm;Specific insulation >=5 × 1015ρv/Ω·m;Dielectric strength εr≤2.8。
Optimization formula is through test, and its major parameter is as follows: melt flows mass rate: 1.5g/10min;Density≤1.01g/cm3;Hot strength: 25MPa;Break-draw strains: 580%;Resisting environmental stress and cracking F0/ h:160h;Dielectric strength: 82kV/mm;Specific insulation: 5.9 × 1015ρv/Ω·m;Dielectric strength εr: 2.6.
Above-mentioned parameter ensure that it has excellent insulating properties and extrusion processing performance, enables the cable of the present invention to transmit 500~1000
The electric power of kV.
Simply, easily grasp, the production equipment using cable production firm conventional i.e. can produce the cable making method of the present invention, and therefore, equipment investment is few, more economically practical, makes utilization rate of equipment and installations higher.
Therefore, the present invention has a following main beneficial effect: cable machinery performance redundancy amount is more suitable, resource is more saved, more anti-wear performance, more can water-impervious, more anti-sea water, shielding properties more preferably, more can transmit high voltage.
The present invention is not limited to above-mentioned preferred forms, it will be appreciated that the design of the present invention can be implemented to use by other various forms, and they also fall within protection scope of the present invention.
Claims (10)
1. a seabed high voltage power cable inner sheath, it is characterized in that it is to be made up of the metal screen layer set gradually from inside to outside, water blocking layer, tack coat, inner sheath, there is inside metal screen layer the conductive unit of three two biphase circumscribed settings, three conductive units and metal screen layer phase inscribe;Described conductive unit be coated on outside conductor by conductor, extrusion molding insulating barrier, be positioned at the insulation screen outside insulating barrier, conductor sheath that extrusion molding is coated on outside insulation screen is constituted, on arbitrary cross section, the center of circle of conductor coincides with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Described armor is made up of gasket for packing, reinforcement, reinforcement by stiffener, be coated on the plastic layer outside stiffener and constitute, gasket for packing is one group with two and is constituted gasket for packing group, gasket for packing group and reinforcement are alternately distributed outside inner sheath, and gasket for packing group and reinforcement are all close to inner sheath;Described insulating barrier is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;The material of described gasket for packing is linear low density polyethylene.
A kind of seabed the most according to claim 1 high voltage power cable inner sheath, it is characterised in that described water blocking layer is waterstop or non-woven fabrics or polyester band or aluminium-plastic tape.
3. according to a kind of seabed high voltage power cable inner sheath described in claim 1 or claim 2, it is characterised in that described insulation screen is conductive plastics.
A kind of seabed the most according to claim 3 high voltage power cable inner sheath, it is characterised in that the material of described conductor sheath is high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene.
A kind of seabed the most according to claim 4 high voltage power cable inner sheath, it is characterised in that the material of main part of described inner sheath is polyethylene or polrvinyl chloride.
A kind of seabed the most according to claim 5 high voltage power cable inner sheath, it is characterised in that the material of described stiffener is steel wire or fiberglass reinforced plastics or aramid yarn;The material of described plastic layer is polypropylene or Low Density Polyethylene or high density polyethylene (HDPE).
7. the manufacture method of a seabed high voltage power cable inner sheath, it is characterised in that it is to comprise the steps of
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take insulating layer material again, described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Or described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 80 parts, ethylene-vinyl acetate copolymer: 15 parts, ethylene-tetrafluoroethylene copolymer: 12 parts, magnesium hydroxide: 13 parts, antioxidant 1010: 4 parts, strontium titanates: 3 parts, calcium titanate: 3 parts, bismuth titanates: 3 parts, magnesium titanate: 3 parts, silicon dioxide: 4 parts, zirconium dioxide: 4 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;
Second step: manufacture the step of metal screen layer: take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped and be coated with outside the conductive unit formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form the step of water blocking layer: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the water blocking layer outside formation inner sheath manufactured in the third step;Form seabed high voltage power cable inner sheath.
8. the manufacture method of a seabed high voltage power cable inner sheath, it is characterised in that it is to comprise the steps of
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take insulating layer material again, described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Or described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 80 parts, ethylene-vinyl acetate copolymer: 15 parts, ethylene-tetrafluoroethylene copolymer: 12 parts, magnesium hydroxide: 13 parts, antioxidant 1010: 4 parts, strontium titanates: 3 parts, calcium titanate: 3 parts, bismuth titanates: 3 parts, magnesium titanate: 3 parts, silicon dioxide: 4 parts, zirconium dioxide: 4 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;Above-mentioned steps repeatedly, until forming three conductive units;
Second step: manufacture the step of metal screen layer: take three conductive units two manufactured in the first step biphase circumscribedly stranded or be placed in parallel, conductive unit intertwist body;Take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped again to be close to be coated with outside the conductive unit intertwist body formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form water blocking layer and the step of tack coat: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;Take polypropylene extrusion molding to be coated on outside water blocking layer and form tack coat;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the tack coat outside formation inner sheath manufactured in the third step;Form seabed high voltage power cable inner sheath.
9. the manufacture method of a seabed high voltage power cable inner sheath, it is characterised in that it is to comprise the steps of
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take insulating layer material again, described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Or described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 80 parts, ethylene-vinyl acetate copolymer: 15 parts, ethylene-tetrafluoroethylene copolymer: 12 parts, magnesium hydroxide: 13 parts, antioxidant 1010: 4 parts, strontium titanates: 3 parts, calcium titanate: 3 parts, bismuth titanates: 3 parts, magnesium titanate: 3 parts, silicon dioxide: 4 parts, zirconium dioxide: 4 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;Above-mentioned steps repeatedly, until forming three conductive units;
Second step: manufacture the step of metal screen layer: take three conductive units two manufactured in the first step biphase circumscribedly stranded or be placed in parallel, conductive unit intertwist body;Take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped again to be close to be coated with outside the conductive unit intertwist body formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form water blocking layer and the step of tack coat: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;Take polypropylene extrusion molding to be coated on outside water blocking layer and form tack coat;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the tack coat outside formation inner sheath manufactured in the third step;Form seabed high voltage power cable inner sheath.
10. the manufacture method of a seabed high voltage power cable inner sheath, it is characterised in that it is to comprise the steps of
The first step: manufacture the step of conductive unit: first take many copper wires or aluminium wire or many copper wires carry out stranded with multiple aluminium wire, forms the conductor of required sectional area;Take insulating layer material again, described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 70~85 parts, ethylene-vinyl acetate copolymer: 10~20 parts, ethylene-tetrafluoroethylene copolymer: 8~16 parts, magnesium hydroxide: 10~15 parts, antioxidant 1010: 3~5 parts, strontium titanates: 2~4 parts, calcium titanate: 2~4 parts, bismuth titanates: 2~4 parts, magnesium titanate: 2~4 parts, silicon dioxide: 3~5 parts, zirconium dioxide: 3~5 parts;Or described insulating layer material is by weight, it is made up of following raw material: insulating layer material by weight, is made up of following raw material: high density polyethylene (HDPE): 80 parts, ethylene-vinyl acetate copolymer: 15 parts, ethylene-tetrafluoroethylene copolymer: 12 parts, magnesium hydroxide: 13 parts, antioxidant 1010: 4 parts, strontium titanates: 3 parts, calcium titanate: 3 parts, bismuth titanates: 3 parts, magnesium titanate: 3 parts, silicon dioxide: 4 parts, zirconium dioxide: 4 parts;Put in insulating barrier extruding machine, at the outer plastic extruding insulated layer of conductor, make the center of circle of conductor coincide with the center of circle of insulating barrier, and the diameter of insulating barrier is 1.5~5 times of conductor diameter and thickness of insulating layer minima is 1.5mm;Then insulation screen is formed outside conductive plastics extrusion molding is coated on insulating barrier;Then conductor sheath is formed outside high density polyethylene (HDPE) or medium density polyethylene or polrvinyl chloride or Low Density Polyethylene extrusion molding being coated on insulation screen;Above-mentioned steps repeatedly, until forming three conductive units;
Second step: manufacture the step of metal screen layer: take three conductive units two manufactured in the first step biphase circumscribedly stranded or be placed in parallel, conductive unit intertwist body;Take the mode that steel band or aluminium strip or copper strips are in the way of longitudinally cladding or spiral is wrapped again to be close to be coated with outside the conductive unit intertwist body formed in the first step;Longitudinally during cladding, having overlapping overlap joint, lap width is 2~5mm, and lap-joint's PUR bonds, and the peel strength minima between lap-joint's steel band or between aluminium strip or between copper strips is 1.6N/mm;When spiral is wrapped, front and back having overlapping overlap joint between spiral, lap width is 1~3mm;
3rd step: form water blocking layer and the step of tack coat: take water blocking layer and be waterstop or non-woven fabrics or polyester band or aluminium-plastic tape is longitudinally coated on outside the metal screen layer manufactured in second step, form water blocking layer;Take polypropylene extrusion molding to be coated on outside water blocking layer and form tack coat;
4th step: manufacture the step of inner sheath: take polyethylene or polrvinyl chloride extrusion molding is coated with the tack coat outside formation inner sheath manufactured in the third step;Form seabed high voltage power cable inner sheath.
Priority Applications (1)
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CN201610361002.2A CN106024104A (en) | 2014-09-15 | 2014-09-15 | Inner sheath for seafloor high-voltage power cable and manufacturing method for inner sheath |
Applications Claiming Priority (2)
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CN201410467691.6A CN104376904B (en) | 2014-09-15 | 2014-09-15 | Submarine high voltage cable and manufacturing method thereof |
CN201610361002.2A CN106024104A (en) | 2014-09-15 | 2014-09-15 | Inner sheath for seafloor high-voltage power cable and manufacturing method for inner sheath |
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CN201410467691.6A Division CN104376904B (en) | 2014-09-15 | 2014-09-15 | Submarine high voltage cable and manufacturing method thereof |
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Family Applications (9)
Application Number | Title | Priority Date | Filing Date |
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CN201610361002.2A Pending CN106024104A (en) | 2014-09-15 | 2014-09-15 | Inner sheath for seafloor high-voltage power cable and manufacturing method for inner sheath |
CN201610398242.XA Withdrawn CN105957589A (en) | 2014-09-15 | 2014-09-15 | Watertight submarine high-voltage cable with good shielding performance |
CN201410467691.6A Active CN104376904B (en) | 2014-09-15 | 2014-09-15 | Submarine high voltage cable and manufacturing method thereof |
CN201610398243.4A Withdrawn CN105957607A (en) | 2014-09-15 | 2014-09-15 | Submarine high-voltage cable |
CN201610361003.7A Pending CN106098168A (en) | 2014-09-15 | 2014-09-15 | One seabed high voltage power cable armouring cable core and manufacture method thereof |
CN201610397407.1A Withdrawn CN106098170A (en) | 2014-09-15 | 2014-09-15 | A kind of seabed high tension cable of water-impervious |
CN201610254161.2A Pending CN105976912A (en) | 2014-09-15 | 2014-09-15 | Undersea high-voltage cable, undersea high-voltage cable manufacturing method and insulation layer material for high-voltage cables |
CN201610398241.5A Withdrawn CN105913907A (en) | 2014-09-15 | 2014-09-15 | Submarine high-voltage cable |
CN201610397375.5A Withdrawn CN105931745A (en) | 2014-09-15 | 2014-09-15 | Submarine high-voltage cable with relatively good shielding performance |
Family Applications After (8)
Application Number | Title | Priority Date | Filing Date |
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CN201610398242.XA Withdrawn CN105957589A (en) | 2014-09-15 | 2014-09-15 | Watertight submarine high-voltage cable with good shielding performance |
CN201410467691.6A Active CN104376904B (en) | 2014-09-15 | 2014-09-15 | Submarine high voltage cable and manufacturing method thereof |
CN201610398243.4A Withdrawn CN105957607A (en) | 2014-09-15 | 2014-09-15 | Submarine high-voltage cable |
CN201610361003.7A Pending CN106098168A (en) | 2014-09-15 | 2014-09-15 | One seabed high voltage power cable armouring cable core and manufacture method thereof |
CN201610397407.1A Withdrawn CN106098170A (en) | 2014-09-15 | 2014-09-15 | A kind of seabed high tension cable of water-impervious |
CN201610254161.2A Pending CN105976912A (en) | 2014-09-15 | 2014-09-15 | Undersea high-voltage cable, undersea high-voltage cable manufacturing method and insulation layer material for high-voltage cables |
CN201610398241.5A Withdrawn CN105913907A (en) | 2014-09-15 | 2014-09-15 | Submarine high-voltage cable |
CN201610397375.5A Withdrawn CN105931745A (en) | 2014-09-15 | 2014-09-15 | Submarine high-voltage cable with relatively good shielding performance |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN107099092A (en) * | 2017-04-07 | 2017-08-29 | 安徽省无为县经纬电缆附件有限公司 | A kind of power-frequency electromagnetic fields |
RU221823U1 (en) * | 2023-04-04 | 2023-11-23 | Общество с ограниченной ответственностью "Камский кабель" | Power cable with combined armor |
Families Citing this family (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN105885465A (en) * | 2016-05-18 | 2016-08-24 | 无为县金华电缆材料有限公司 | Formula of ultraviolet-resistant waterproof cable armored layer |
CN106531300B (en) * | 2016-10-27 | 2018-06-29 | 国网江苏省电力有限公司宿迁供电分公司 | A kind of power equipment |
CN115985569B (en) * | 2017-06-13 | 2023-12-05 | 中天科技海缆股份有限公司 | Umbilical cable |
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- 2014-09-15 CN CN201610398243.4A patent/CN105957607A/en not_active Withdrawn
- 2014-09-15 CN CN201610361003.7A patent/CN106098168A/en active Pending
- 2014-09-15 CN CN201610397407.1A patent/CN106098170A/en not_active Withdrawn
- 2014-09-15 CN CN201610254161.2A patent/CN105976912A/en active Pending
- 2014-09-15 CN CN201610398241.5A patent/CN105913907A/en not_active Withdrawn
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Also Published As
Publication number | Publication date |
---|---|
CN106098170A (en) | 2016-11-09 |
CN106098168A (en) | 2016-11-09 |
CN105913907A (en) | 2016-08-31 |
CN105957607A (en) | 2016-09-21 |
CN105957589A (en) | 2016-09-21 |
CN104376904B (en) | 2017-02-22 |
CN105976912A (en) | 2016-09-28 |
CN105931745A (en) | 2016-09-07 |
CN104376904A (en) | 2015-02-25 |
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