US3325325A - Method of making polyethylene insulated electrical conductors - Google Patents

Method of making polyethylene insulated electrical conductors Download PDF

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US3325325A
US3325325A US245947A US24594762A US3325325A US 3325325 A US3325325 A US 3325325A US 245947 A US245947 A US 245947A US 24594762 A US24594762 A US 24594762A US 3325325 A US3325325 A US 3325325A
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Robert A Ward
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General Electric Co
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01BCABLES; CONDUCTORS; INSULATORS; SELECTION OF MATERIALS FOR THEIR CONDUCTIVE, INSULATING OR DIELECTRIC PROPERTIES
    • H01B9/00Power cables
    • H01B9/02Power cables with screens or conductive layers, e.g. for avoiding large potential gradients
    • H01B9/027Power cables with screens or conductive layers, e.g. for avoiding large potential gradients composed of semi-conducting layers

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  • corona which is an electrical discharge occurring between two electrodes when a critical voltage is exceeded, causes localized high temperatures and chemical action from ions or radicals formed, thereby resulting in mechanical erosion and reduction in the efiiciency of the primary outer insulation.
  • corona discharge takes place in air spaces or gaps between the conductor and the ground insulation.
  • the conducting core which comprises the subject of the present invention may be any one of those normally used in the electrical arts, for instance, copper, aluminum, alloys of copper, alloys of aluminum, etc.
  • the polyethylene employed in the practice of the present invention is a solid, polymeric material formed by the polymerization of ethylene at various temperatures and pressures. Such material is described in US. Patent 2,153,553- Fawcett et al., and in Modern Plastics Encyclopedia, New York 1949, pages 268-271. Specific examples of commercially available polyethylene are the polyethylenes sold by E. I. du Pont de Nemours and Company, Inc., Wilmington, DeL, under the name of Alathon; those sold by Bakelite Company, such as DE2400, DYNH, etc.; polyethylene sold by Phillips Petroleum Company, such as Marlex 20, 50, etc. Other polyethylenes which are included in the practice of the presentinvention and which may be prepared by either high or low pressure polymerizations, are found described in recently issued United States Patents 2,816,883 and 2,882,357.
  • the outer insulation may be thermoplastic polyethylene which may be readily extruded over the metallic core and the intermediate semiconducting polyethylene layer.
  • the polyethylene may be wrapped around the latter two components in the form of a tape or sheet and thereafter subjected to a molding operation to eifect compacting of the outer insulation over the metallic core and intermediate layer of semiconducting polyethylene.
  • thermoplastic polyethylene as the outer insulation
  • an outer cross-linked polyethylene for instance, polyethylene which may be cross-linked to the substantially infusible and insoluble state, as, for instance, by irradiation with high energy electrons (for instance, with a dose of from 4X10 rep to 5 10 rep) as is more particularly disclosed and claimed in the copending application of Lawton and Bueche, Ser.
  • the polyethylene may be chemically cross-linked, usually in situ, by means of a specific class of organic peroxides (e. g., dicumyl peroxide in amounts ranging from 0.1 to 10 percent of the weight of the polyethylene) as is more particularly disclosed and claimed in U.S. 2,826,570 and in the copending application of Precopio and Gilbert, Ser. No. 509,388, filed May 18, 1955 (now Patent 3,079,370), both of the aforesaid applications being assigned to the same assignee as the present invention and by reference being made part of the discloures of the instant application.
  • organic peroxides e. g., dicumyl peroxide in amounts ranging from 0.1 to 10 percent of the weight of the polyethylene
  • the outer polyethylene insulation may be cross-linked, for instance, by chemical means or by irradi- :ation with high energy electrons and thereafter subjected to a milling operation and thereby made suitable for extrusion over the metallic core and over the intermediate semiconducting carbon-black filled, cross-linked polyethylene.
  • the use of such milling techniques to make crosslinked polyethylene extrudable is more particularly disclosed and claimed in the copending applications of Quin.-
  • the outer insulation of polyethylene when applied in 3 tape form preferably comprises a fiat stock material (e.g., tape) which has been oriented, i.e. stretched at least 10 percent up to 50 percent or more, in at least one direction, preferably in at least the lengthwise direction of the tape, and advantageously in both transverse and lengthwise directions.
  • This orientation generally comprises stretching the polyethylene either after, during, or before irradiation of the polyethylene with high energy electrons to crosslink the polyethylene.
  • This orientation of the polyethylene can also be exercised in connection with chemically crosslinked polyethylene referred to above.
  • the carbon-black filled, cross-linked polyethylene used as an intermediate layer in the above-described insulated conductor may contain from 10 to 300 percent, by weight, carbon-black, based on the weight of the cross-linked polyethylene. Stated alternatively, one can use from 0.1 to 3 parts carbon-black per part of polyethylene.
  • the types of finely divided carbon-blacks which can be employed in the practice of the instant invention are, for example, animal or vegetable, channel, furnace and thermal carbon-blacks, etc. A good description of the preparation of carbon-blacks is contained in the book Industrial Chemicals by Faith et al., pages 174-182, published by John Wiley & Sons, New York (1950).
  • suitable carbon-black are channel; channel, conducting; channel, hard processing; channel, medium processing; channel, easy processing; furnace, conducting; furnace, fine; furnace, high modulus; furnace, high elongation; furnace, reinforcing; furnace, semi-reinforcing; thermal fine; thermal medium; acetylene; lamp black, etc.
  • These carbon-blacks are of very fine particle size and may range in average particle size from about 1 to 100 millimicrons.
  • the manner whereby the carbon-black filled, crosslinked polyethylene may be prepared may be varied widely.
  • One method comprises incorporating the carbon-black in the polyethylene and thereafter irradiating the carbonblack filled polyethylene to cross-link the same with high energy electrons with a dose of from about 3X10 rep to 10 rep employing the method disclosed and claimed in the copending application of Gilbert and Precopio, Ser.
  • a chemical curing agent for the purpose of cross-linking the polyethylene, for instance, .an organic peroxide, such as di-alpha cumyl peroxide, more particularly disclosed and claimed in the copending application of Precopio and Gilbert, Ser. No. 509,387, filed May 18, 1955 (now Patent 2,888,424).
  • a chemical curing agent for the purpose of cross-linking the polyethylene, for instance, .an organic peroxide, such as di-alpha cumyl peroxide, more particularly disclosed and claimed in the copending application of Precopio and Gilbert, Ser. No. 509,387, filed May 18, 1955 (now Patent 2,888,424).
  • the peroxide, and the carbon-black in the polyethylene is heated at elevated temperatures of about 150 to 175 C. in order to elfect crosslinking (i.e., curing) of the carbon-black filled polyethylene.
  • this cross-linked, carbon-black filled polyethylene which is advantageously used in tape form, is then wound around the metallic core to form the intermediate semiconducting layer and thereafter the outer polyethylene insulation may be applied.
  • the application of the outer insulation may be in the form of a tape wrapped around the metallic core covered with the semiconducting layer of cross-linked, carbon-black filled polyethylene or the outer polyethylene insulating surface may be extruded over the latter two members of the conductor assembly.
  • the tape When employing tapes of either the semiconducting layer or of the outer layer of polyethylene, the tape is advantageously from one-half to siX inches or more wide and in thickness may range from about 0.5 to 50 or more mils, e.g., from 1 to 20 mils.
  • it may be desirable to employ more than one layer of both the cross-linked, carbon-black filled polyethylene and of the outer insulation of polyethylene.
  • Example 1 A copper stranded coil form about inch wide by 1 inch in height was wound with an irradiated semiconducting tape composed of carbon-black (Vulcan 9-super abrasion carbon manufactured by Godfrey L. Cabot Company) filled polyethylene (in which the carbon-black comprised about 30 percent, by weight, of the total weight of the polyethylene and the carbon-black) which had been irradiated with about 8X 10 rep (by means of electrons from a high voltage accelerating apparatus).
  • carbon-black Vulcan 9-super abrasion carbon manufactured by Godfrey L. Cabot Company
  • the semiconducting tape which was about 4 mils thick, was wrapped around the coil form with half laps until a thickness of about '6 to 8 mils of the carbon-black filled, crosslinked polyethylene was obtained on the insulated conductor.
  • Unfilled, oriented (40 to 50 percent orientation) polyethylene tape which had been irradiated with about 9 to 11 10 rep was then wrapped around the assembly comprising the metallic core and the carbon-black filled, crosslinked polyethylene to a thickness of about 40 mils.
  • the entire assembly (insulation being about 48 mils thick) comprising the outer irradiated polyethylene insulation, the intermediate layer of carbon-black filled, cross-linked polyethylene and themetallic core were heated at -115 C.
  • the insulated conductors of the present invention have a firm bond between the outer insulation and the conductor core through the medium of the intermediate semiconducting layer and eliminates difiiculties upon flexing, bending or vibration, where conventional nonbonding semiconducting tapes become embrit-tled and discontinuous and pull away from the insulation with resultant void formation. Because of the compatibility of the outer insulation with the intermediate layers of carbonblack filled, cross-linked polyethylene, there is a homogeneous structure obtained which is able to obviate the difficulties heretofore encountered when using non-compatible layer systems. This means that voids will not develop in the composite insulation structure due to thermal working, i.e., expansion and contraction of the insulation system due to temperature cycling.

Description

June 13, 1967 R. A. WARD 3,325,325
METHOD 0 AKING POLYETHYLENE INSULATED EGTRICAL CONDUCTORS Original Filed May 21. 1958 CARBON BLAC/fF LED CROSS-LINK PULYETHYLE/VE Inventor": Robert, A. Ward,
His Attorney.
United States Patent 3,325,325 METHOD OF MAKING POLYETHYLENE INSU- LATED ELECTRICAL CONDUCTORS Robert A. Ward, Scotia, N.Y., assignor to General Electric Company, a corporation of New York Original application May 21, 1958, Ser. No. 736,760. Divided and this application Dec. 17, 1962, Ser. No.
2 Claims. (Cl. 156-56) present a means for eliminating or minimizing electrical breakdown of equipment due to high voltage discharges (corona damage). In order to effect this desired result, the use of semiconducting layers between the metallic core and the outer polyethylene insulation for the purpose of distributing high voltage stress gradients have been found to be an essential feature of such insulated conductors. However, heretofore, any semiconducting layer used in an insulating system has not been satisfactory in combination with polyethylene insulated conductors.
This is due to the fact that when corona, which is an electrical discharge occurring between two electrodes when a critical voltage is exceeded, causes localized high temperatures and chemical action from ions or radicals formed, thereby resulting in mechanical erosion and reduction in the efiiciency of the primary outer insulation. In
the usual cases, corona discharge takes place in air spaces or gaps between the conductor and the ground insulation.
Where corona discharges take place in the air spaces or gaps between the conductors and the ground insulation, usually such gaps are present because of the porosity of the cotton strand insulation and the crevice formed by the radius of curvature of the individual strands. Normal procedure for high voltage insulation entails compounding by vacuum and pressure processing. This fills in voids in the basic structure and also compresses the insulation into any gaps next to the conductor. However, this procedure 'is both time consuming and costly and even when used does not produce a satisfactory insulated conductor which is as free of corona discharge as is desired.
It is, therefore, one of the objects ofthis invention to prevent corona attack of a polyethylene insulated conductor.
It is another object of the invention to employ a semiconducting layer in combination with polyethylene insulated conductors which is compatible with the polyethylene.
It is still a further object of the invention to prepare an insulated conductor Whose primary insulation is based on polyethylene in which the insulation will expand and contract with temperature changes without the appearance of voids in any substructure underneath the outer polyethylene insulation.
It is an additional object of the invention to obtain polyethylene insulated conductors which are free of moisture sensitivity and which have high thermal stability at temperatures as high as 150 C.
Other objects of the invention will become apparent from the description thereof which follows.
All the foregoing objects of the invention are obviated 3,325,325 Patented. June 13, 1 967 by employing an insulated conductor in which the outer insulation is polyethylene and there is present between the outer insulation and the metallic conducting core an intermediate layer of insulation comprising a cross-linked,
carbon-black filled polyethylene.
The conducting core which comprises the subject of the present invention may be any one of those normally used in the electrical arts, for instance, copper, aluminum, alloys of copper, alloys of aluminum, etc.
The polyethylene employed in the practice of the present invention is a solid, polymeric material formed by the polymerization of ethylene at various temperatures and pressures. Such material is described in US. Patent 2,153,553- Fawcett et al., and in Modern Plastics Encyclopedia, New York 1949, pages 268-271. Specific examples of commercially available polyethylene are the polyethylenes sold by E. I. du Pont de Nemours and Company, Inc., Wilmington, DeL, under the name of Alathon; those sold by Bakelite Company, such as DE2400, DYNH, etc.; polyethylene sold by Phillips Petroleum Company, such as Marlex 20, 50, etc. Other polyethylenes which are included in the practice of the presentinvention and which may be prepared by either high or low pressure polymerizations, are found described in recently issued United States Patents 2,816,883 and 2,882,357.
The outer insulation may be thermoplastic polyethylene which may be readily extruded over the metallic core and the intermediate semiconducting polyethylene layer. Alternatively, the polyethylene may be wrapped around the latter two components in the form of a tape or sheet and thereafter subjected to a molding operation to eifect compacting of the outer insulation over the metallic core and intermediate layer of semiconducting polyethylene.
In addition to employing thermoplastic polyethylene as the outer insulation, it is also intended to include within the scope of the invention the use of an outer cross-linked polyethylene, for instance, polyethylene which may be cross-linked to the substantially infusible and insoluble state, as, for instance, by irradiation with high energy electrons (for instance, with a dose of from 4X10 rep to 5 10 rep) as is more particularly disclosed and claimed in the copending application of Lawton and Bueche, Ser.
No. 324,552, filed Dec. 6, 1952 (now abandoned). In addition, the polyethylene may be chemically cross-linked, usually in situ, by means of a specific class of organic peroxides (e. g., dicumyl peroxide in amounts ranging from 0.1 to 10 percent of the weight of the polyethylene) as is more particularly disclosed and claimed in U.S. 2,826,570 and in the copending application of Precopio and Gilbert, Ser. No. 509,388, filed May 18, 1955 (now Patent 3,079,370), both of the aforesaid applications being assigned to the same assignee as the present invention and by reference being made part of the discloures of the instant application.
Alternatively, the outer polyethylene insulation may be cross-linked, for instance, by chemical means or by irradi- :ation with high energy electrons and thereafter subjected to a milling operation and thereby made suitable for extrusion over the metallic core and over the intermediate semiconducting carbon-black filled, cross-linked polyethylene. The use of such milling techniques to make crosslinked polyethylene extrudable is more particularly disclosed and claimed in the copending applications of Quin.-
tin P. Cole, Ser. No. 561,937, filed Ian. 27, 1956 (now .Patent 2,919,475), and Ser. No. 437,477, filed June 17, 1954 (now Patent 2,919,473), both applications being assigned to the same assignee of the present invention and .by reference being incorporated as part of the instant application.
The outer insulation of polyethylene when applied in 3 tape form preferably comprises a fiat stock material (e.g., tape) which has been oriented, i.e. stretched at least 10 percent up to 50 percent or more, in at least one direction, preferably in at least the lengthwise direction of the tape, and advantageously in both transverse and lengthwise directions. This orientation generally comprises stretching the polyethylene either after, during, or before irradiation of the polyethylene with high energy electrons to crosslink the polyethylene. This orientation of the polyethylene can also be exercised in connection with chemically crosslinked polyethylene referred to above. Thereafter, when the oriented or stretched polyethylene is applied to the metallic core and the intermediate semiconducting crosslinked polyethylene layer, and subjected to heat, the heat causes the oriented polyethylene to shrink into a tight, void-free structure around the intermediate layer of semiconducting, cross-linked polyethylene and around the metallic core. By means of this void-free structure, the possibility of corona discharge taking place in air spaces or gaps between the conductor and the ground insulation is materially eliminated. The heat shrinking of oriented polyethylene is more particularly disclosed and claimed in Stirrat et a1. application, Ser. No. 518,403, filed June 27, 1955 (now abandoned) and assigned to the assignee of the present invention.
The carbon-black filled, cross-linked polyethylene used as an intermediate layer in the above-described insulated conductor may contain from 10 to 300 percent, by weight, carbon-black, based on the weight of the cross-linked polyethylene. Stated alternatively, one can use from 0.1 to 3 parts carbon-black per part of polyethylene. Among the types of finely divided carbon-blacks which can be employed in the practice of the instant invention are, for example, animal or vegetable, channel, furnace and thermal carbon-blacks, etc. A good description of the preparation of carbon-blacks is contained in the book Industrial Chemicals by Faith et al., pages 174-182, published by John Wiley & Sons, New York (1950). Among the various grades of suitable carbon-black are channel; channel, conducting; channel, hard processing; channel, medium processing; channel, easy processing; furnace, conducting; furnace, fine; furnace, high modulus; furnace, high elongation; furnace, reinforcing; furnace, semi-reinforcing; thermal fine; thermal medium; acetylene; lamp black, etc. These carbon-blacks are of very fine particle size and may range in average particle size from about 1 to 100 millimicrons.
The manner whereby the carbon-black filled, crosslinked polyethylene may be prepared may be varied widely. One method comprises incorporating the carbon-black in the polyethylene and thereafter irradiating the carbonblack filled polyethylene to cross-link the same with high energy electrons with a dose of from about 3X10 rep to 10 rep employing the method disclosed and claimed in the copending application of Gilbert and Precopio, Ser.
'No. 488,304, filed Feb. '15, 1955 (now Patent No. 3,084,-
114). Alternatively, one can incorporate a chemical curing agent for the purpose of cross-linking the polyethylene, for instance, .an organic peroxide, such as di-alpha cumyl peroxide, more particularly disclosed and claimed in the copending application of Precopio and Gilbert, Ser. No. 509,387, filed May 18, 1955 (now Patent 2,888,424). After incorporation of the peroxide, and the carbon-black in the polyethylene, the latter is heated at elevated temperatures of about 150 to 175 C. in order to elfect crosslinking (i.e., curing) of the carbon-black filled polyethylene. Generally, this cross-linked, carbon-black filled polyethylene which is advantageously used in tape form, is then wound around the metallic core to form the intermediate semiconducting layer and thereafter the outer polyethylene insulation may be applied. The application of the outer insulation may be in the form of a tape wrapped around the metallic core covered with the semiconducting layer of cross-linked, carbon-black filled polyethylene or the outer polyethylene insulating surface may be extruded over the latter two members of the conductor assembly.
When employing tapes of either the semiconducting layer or of the outer layer of polyethylene, the tape is advantageously from one-half to siX inches or more wide and in thickness may range from about 0.5 to 50 or more mils, e.g., from 1 to 20 mils. When making the insulated conductor, it may be desirable to employ more than one layer of both the cross-linked, carbon-black filled polyethylene and of the outer insulation of polyethylene.
The drawing accompanying this description shows a preferred embodiment of the claimed invention. In the single figure, there is shown a metallic conducting core 1, for instance, copper, surrounded by a semi-conducting layer of cross-linked, carbon-black filled polyethylene 2, and an outer insulation of polyethylene 3 which may be either thermoplastic or itself may be in the cross-linked,
substantially infusible and insoluble state.
In order that those skilled in the art may better understand how the present invention may be practiced, and in order to show the marked advantages derived from the Example 1 A copper stranded coil form about inch wide by 1 inch in height Was wound with an irradiated semiconducting tape composed of carbon-black (Vulcan 9-super abrasion carbon manufactured by Godfrey L. Cabot Company) filled polyethylene (in which the carbon-black comprised about 30 percent, by weight, of the total weight of the polyethylene and the carbon-black) which had been irradiated with about 8X 10 rep (by means of electrons from a high voltage accelerating apparatus). The semiconducting tape, which was about 4 mils thick, was wrapped around the coil form with half laps until a thickness of about '6 to 8 mils of the carbon-black filled, crosslinked polyethylene was obtained on the insulated conductor. Unfilled, oriented (40 to 50 percent orientation) polyethylene tape which had been irradiated with about 9 to 11 10 rep was then wrapped around the assembly comprising the metallic core and the carbon-black filled, crosslinked polyethylene to a thickness of about 40 mils. The entire assembly (insulation being about 48 mils thick) comprising the outer irradiated polyethylene insulation, the intermediate layer of carbon-black filled, cross-linked polyethylene and themetallic core were heated at -115 C.
for one hour to shrink the outer polyethylene layer, and then at C. for 15 minutes to effect a tight seal be- 0W661l all the layers of polyethylene. This procedure gave a smooth, dimensionally reproducible insulation which was essentially void-free. The 150 C. treatment was sufficient to effect a seal between the semi-conducting layers and the outer insulating, unfilled, irradiated polyethylene.
'mil. If only the unfilled, irradiated polyethylene insulation was considered, the stress was 200 volts per mil.
As the result of these tests (average of five tests on each type of insulation assembly) it Was found that the insulated conductor which did not contain the intermediate layer of carbon-black filled, cross-linked polyethylene took an average of about 6 hours under dielectric stress to breakdown, whereas the insulated conductor which had the intermediate layer of carbon-black filled, cross-linked polyethylene took an average of about 67 hours before it broke down.
The above example illustrates the ability to use a conducting layer to distribute voltage stress and eliminate ionization. The corona damage in the insulation and on the conductor has been greatly reduced, if not completely eliminated, and this same principle can be applied to other similar situations where the insulation is separated from high voltage or from ground by voids. The invention herein described avoids the necessity for using vacuum-pressure compounding techniques and can be used in the encapsulation of various electrical conductors and coils.
The insulated conductors of the present invention have a firm bond between the outer insulation and the conductor core through the medium of the intermediate semiconducting layer and eliminates difiiculties upon flexing, bending or vibration, where conventional nonbonding semiconducting tapes become embrit-tled and discontinuous and pull away from the insulation with resultant void formation. Because of the compatibility of the outer insulation with the intermediate layers of carbonblack filled, cross-linked polyethylene, there is a homogeneous structure obtained which is able to obviate the difficulties heretofore encountered when using non-compatible layer systems. This means that voids will not develop in the composite insulation structure due to thermal working, i.e., expansion and contraction of the insulation system due to temperature cycling. Because the intermediate layer is non-melting, it can withstand extrusion temperatures when, for instance, thermoplastic polyethylene, or milled, cross-linked polyethylene (referred to in the above-mentioned two Cole applications) is extruded over the carbon-black filled, cross-linked polyethylene and the metallic core.
It will, of course, be apparent to those skilled in the art that other carbon-blacks may be employed, many examples of which have been given above, without departing from the scope of the invention. In addition, instead of using irradiated polyethylene both for the outer insulation and for the intermediate carbon-black filled, crosslinked polyethylene, one can also use chemically crossl'inked polyethylene employing, for instance, dicumyl peroxide as the curing agent as is recited in the abovedescribed Precopio and Gilbert aplications, Ser. No. 509,- 387 (now Patent 2,888,424) and Ser. No. 509,388 (now Patent 3,079,370).
What I claim as new and desire to secure by Letters Patent of the United States is:
l. The process for forming an insulated electrical c-onductor of improved corona resistance which comprises (1) forming a coating of carbon-black filled cross-linked polyethylene on the surface of an electrical conductor, (2) wrapping a stretched, cross-linked polyethylene tape in overlapping fashion about said coating and (3) heating the resulting assembly above the temperature at which said tape tends to shrink, whereby the shrinkage of said tape compresses said coating between said conductor and said tape to form an insulated electrical conductor having a substantially void-free semiconducting layer in contact with said conductor and a substantially void-free outer insulating layer surrounding and in contact with said semiconducting layer.
2. The process for forming an insulated electrical conductor which comprises (1) forming a coating of carbon black filled cross-linked polyethylene on the surface of an electrical conductor, (2) wrapping a stretched, crosslinked polyethylene tape in overlapping fashion about said coating, (3) heating the resulting assembly at a temperature of about to C. for a sufiicient time to shrink said outer polyethylene layer, and (4) then heating said entire assembly at a temperature of about C. to effect a seal between said inner coating and said outer coating, whereby an insulated electrical conductor is produced which is substantially free of voids and which has improved corona resistance.
References Cited UNITED STATES PATENTS 2,635,975 4/1953 Peters. 2,808,357 10/1957 Lamphier et al. 15685 2,919,473 1/1960 Cole 264-22 3,033,727 5/1962 Cram et a1 156-55 X FOREIGN PATENTS 546,419 7/1942 Great Britain.
EARL M. BERGERT, Primary Examiner.
P. R. WY DIE, T. R. SAVOIE, Assistant Examiners.

Claims (1)

1. THE PROCESS FOR FORMING AN INSULATED ELECTRICAL CONDUCTOR OF IMPROVED CORONA RESISTANCE WHICH COMPRISES (1) FORMING A COATING OF CARBON-BLACK FILLED CROSS-LINKED POLYETHYLENE ON THE SURFACE OF AN ELECTRICAL CONDUCTOR, (2) WRAPPING A STRETCHED, CROSS-LINKED POLYETHYLENE TAPE IN OVERLAPPING FASHION ABOUT SAID COATING AND (3) HEATING THE RESULTING ASSEMBLY ABOVE THE TEMPERATURE AT WHICH SAID TAPE TENDS TO SHRINK, WHEREBY THE SHRINKAGE OF SAID TAPE COMPRESSES SAID COATING BETWEEN SAID CONDUCTOR AND SAID TAPE TO FORM AN INSULATED ELECTRICAL CONDUCTOR HAVING A SUBSTANTIALLY VOID-FREE SEMICONDUCTING LAYER IN CONTACT WITH SAID CONDUCTOR AND A SUBSTNATIALLY VOID-FREE OUTER INSULATING LAYER SURROUNDING AND IN CONTACT WITH SAID SEMICONDUCTING LAYER.
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US3436287A (en) * 1965-07-02 1969-04-01 Bell Telephone Labor Inc Coaxial cable manufacturing method
US3441660A (en) * 1966-07-12 1969-04-29 Gen Cable Corp Solid aluminum conductor insulated with cross-linked polyethylene
US3455752A (en) * 1961-10-12 1969-07-15 Alvin N Gray Method of manufacturing electric wires covered with plastics
US3475245A (en) * 1963-10-14 1969-10-28 Phillips Petroleum Co Method of forming wrapped tubing from oriented polymer film while maintaining orientation
US3502542A (en) * 1965-06-14 1970-03-24 Uniroyal Inc Methods of improving adhesion
US3524768A (en) * 1964-05-29 1970-08-18 Hitachi Chemical Co Ltd Method of treating plastic film for electric insulation
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US3572499A (en) * 1967-01-19 1971-03-30 Custom Materials Inc Conductive packaging material and container for explosives
US3712222A (en) * 1970-03-12 1973-01-23 Brunswick Corp Pyrotechnic fuse
US3861972A (en) * 1970-08-24 1975-01-21 Johnson & Johnson Intravenous catheter
US4317001A (en) * 1979-02-23 1982-02-23 Pirelli Cable Corp. Irradiation cross-linked polymeric insulated electric cable
US4384944A (en) * 1980-09-18 1983-05-24 Pirelli Cable Corporation Carbon filled irradiation cross-linked polymeric insulation for electric cable
US5243876A (en) * 1990-08-15 1993-09-14 Markel Corporation Cable assemblies and methods of producing same
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US2635975A (en) * 1937-10-02 1953-04-21 Bell Telephone Labor Inc Method of bonding polyethylene to vulcanized rubber and article produced thereby
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Publication number Priority date Publication date Assignee Title
US3455752A (en) * 1961-10-12 1969-07-15 Alvin N Gray Method of manufacturing electric wires covered with plastics
US3475245A (en) * 1963-10-14 1969-10-28 Phillips Petroleum Co Method of forming wrapped tubing from oriented polymer film while maintaining orientation
US3524768A (en) * 1964-05-29 1970-08-18 Hitachi Chemical Co Ltd Method of treating plastic film for electric insulation
US3502542A (en) * 1965-06-14 1970-03-24 Uniroyal Inc Methods of improving adhesion
US3436287A (en) * 1965-07-02 1969-04-01 Bell Telephone Labor Inc Coaxial cable manufacturing method
US3413167A (en) * 1965-07-09 1968-11-26 Phelps Dodge Copper Prod Manufacture of plastic-insulated electrical cable
US3389200A (en) * 1966-03-30 1968-06-18 Dow Chemical Co Process for producing compressed vermicular graphite structures
US3441660A (en) * 1966-07-12 1969-04-29 Gen Cable Corp Solid aluminum conductor insulated with cross-linked polyethylene
US3572499A (en) * 1967-01-19 1971-03-30 Custom Materials Inc Conductive packaging material and container for explosives
US3541228A (en) * 1967-05-23 1970-11-17 Pirelli Medium voltage cables
US3712222A (en) * 1970-03-12 1973-01-23 Brunswick Corp Pyrotechnic fuse
US3861972A (en) * 1970-08-24 1975-01-21 Johnson & Johnson Intravenous catheter
US4317001A (en) * 1979-02-23 1982-02-23 Pirelli Cable Corp. Irradiation cross-linked polymeric insulated electric cable
US4384944A (en) * 1980-09-18 1983-05-24 Pirelli Cable Corporation Carbon filled irradiation cross-linked polymeric insulation for electric cable
US5243876A (en) * 1990-08-15 1993-09-14 Markel Corporation Cable assemblies and methods of producing same
WO1993023681A1 (en) * 1992-05-15 1993-11-25 Markel Corporation Cable assemblies and methods of producing same
WO2015005857A1 (en) * 2013-07-09 2015-01-15 Habia Cable Ab Medium/high-voltage cable comprising fluoropolymer layers

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