US2195998A - High tension electric cable and method of making the same - Google Patents

High tension electric cable and method of making the same Download PDF

Info

Publication number
US2195998A
US2195998A US194568A US19456838A US2195998A US 2195998 A US2195998 A US 2195998A US 194568 A US194568 A US 194568A US 19456838 A US19456838 A US 19456838A US 2195998 A US2195998 A US 2195998A
Authority
US
United States
Prior art keywords
paper
cable
insulation
spaces
strands
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US194568A
Inventor
Hubert H Race
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
General Electric Co
Original Assignee
General Electric Co
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by General Electric Co filed Critical General Electric Co
Priority to US194568A priority Critical patent/US2195998A/en
Application granted granted Critical
Publication of US2195998A publication Critical patent/US2195998A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01BCABLES; CONDUCTORS; INSULATORS; SELECTION OF MATERIALS FOR THEIR CONDUCTIVE, INSULATING OR DIELECTRIC PROPERTIES
    • H01B13/00Apparatus or processes specially adapted for manufacturing conductors or cables

Definitions

  • Patented Apr. 2, 1940 PATENT OFFICE HIGH TENSION ELECTRIC CABLE AND METHOD OF THE SAME Hubert 11. Race, Schenectady, N. Y., assignor to General Electric Company, a corporation of New York Application March 8, 1938, Serial No. 194,568
  • My invention has for its object the method or process of manufacturing high potential cables whereby ionization and corona duepto the presence of oil orcompound as such in the strand spaces of the outer layer of the conductor underneath the surrounding insulation, is prevented.
  • Fig. 1 indicates a short 7 thickness for the voltage of the cable.
  • FIG. 2 is a diagrammatic view illustrating the usual construction of paper insulated cable
  • Fig. 3 is a cross-section of my improved cable on an enlarged scale showing the external strand spaces filled with compressed fibrous insulation
  • Fig. 4 illustrates the application of moist paper to fill the strand spaces and also the application of insulating material
  • Fig. 5 is a perspective view of a strand space filler made of fibrous material
  • Fig. 6 shows a length of sheathed cable with a vacuum pump for removing moisture and air therefrom
  • Fig. 7 is a greatly enlarged view showing how the compacted moist material completely fills the strand space.
  • each strand space is defined by the peripheral surfaces of the two adjacent strands and the overlying body of insulation. It is in these V-shaped strand spaces that ionization of the oil or compound takes place with the ultimate result of causing corona effect which in turn causes deterioration of the insulation. If the effect is pronounced, it will in time result in cable failure.
  • V-shaoed strand spaces instead of being empty or filled only with oil or compound are filled with hard packed fibrous insulation, such as paper, for example, which in the subsequent process of manufacture of the cable are fully impregnated with oil or compound.
  • hard packed fibrous insulation such as paper, for example, which in the subsequent process of manufacture of the cable are fully impregnated with oil or compound. It is well recognized that impregnated paperhas a higher dielectric strength than oil or compound alone or paper alone. It
  • the tapes While the tapes are moist and well softened by water or other vapor, they are subjected to relatively heavy external compression pressure which has the effect of forcing or squeezing the moist paper into the V-shaped strand spaces and completely filling them. After the moist paper tapes are forced into the strand spaces, the insulation for the conductor, whether it be paper or equivalent material, may be applied in the usual way.
  • Fig. 3 is shown a section of a part of a cable wherein 4 indicates the outer layer of strands of conducting material, such as copper. Inside of these strands are other strands 'l of which as many may be provided as desired to carry the current for which the cable is intended. 8 indicates the triangular-shaped portions of the moist paper which have been forced into the outer strand spaces by external pressure. Over the numerous strips or portions 8 is wound the necessary customary insulation, and the latter is enclosed in an impervious lead or equivalent sheath 9.
  • 4 indicates the outer layer of strands of conducting material, such as copper. Inside of these strands are other strands 'l of which as many may be provided as desired to carry the current for which the cable is intended.
  • 8 indicates the triangular-shaped portions of the moist paper which have been forced into the outer strand spaces by external pressure. Over the numerous strips or portions 8 is wound the necessary customary insulation, and the latter is enclosed in an impervious lead or equivalent sheath 9.
  • l0 indicates the stranded conductor which may be hollow or solid depending upon its ultimate use.
  • II and I2 indicate paper tapes which are applied directly over the bare strands. The tapes may be applied by the same machine which applies the final insulation, all that is required is to have the necessary number of paper carrying bobbins for the purpose on the revolving head of the machine. These bobbins may and usually would be duplicates of those used in applying the main insulation. For the tapes, whether for the strand spaces or the main insulation, it is desirable to use paper which has been carefully washed to remove impurities as completely as possible.
  • moist paper tape is notso strong as the usual type of dry paper tape, a convenient way is to apply it in a dry state and subsequently to moisten it to the neces- The excess moissary extent. This may be done by means of a nozzle or equivalent device l3 which discharges water, steam or other vapor over the paper tapes H and I! after application in sufficient amount to render them soft and pliable. Desirably the nozzle should be so shaped as to cause the water or vapor to act on the entire circumference of the tapes to facilitate moistening.
  • roller dies H and I5 which are so shaped and positioned and under such pressure as to force the moist paper into the V-shaped strand spaces.
  • the inner or sharp end of the squeezed-in fibrous material should fully extend into that part of the conductor where each two of the strands are in sidewise contact throughout their respective lengths.
  • the paper tapes may be forced into the strand spaces, leaving only the high spots of the strands slightly exposed.
  • the moistened tapes may appear as a very thin, nearly transparent covering for the strands with the remainder filling the strandspaces.
  • the dies may be cold or they may be heated to some extent in which case they will aid in removing a limited amount of the moisture. The mere fact that they act to compress the paper tapes may result in heating the dies to some extent.
  • the insulation in the form of tapes is applied, of which l6 and I! may be regarded as examples. The number of tapes will be governed by the voltage under which the cable is to operate.
  • the insulating tapes are applied before the moist tapes are fully dried since by so doing they act as binding means therefor and also compress it and smooth out any slight irregularities that otherwise might exist.
  • the insulation as such may be of paper or other suitable material, following in this particular established cable practice.
  • Fig. 7 is shown on a greatly enlarged scale round copper conductors 4 arranged in side-byside contact with a filling 8 of paper in the V- shaped spaces between them.
  • the filling is arranged to terminate in a thin edge adjacent the highest part of each of the conductors.
  • Fig. 6 is shown by way of example means employed in removing air and moisture from a sheathedcable.
  • I8 indicates a sheathed cable having sealing caps l 9 at its ends, one of which is connected to a vacuum pump 20 of any suitable construction. If it be desired to evacuate the cable before applying the sheath, it may be done. in accordance with the usual methods.
  • the method of making high potential stranded electric conductor which comprises assembling it to substantially fill the strand spaces of the outer layer of strands, applying insulation over the strands and body under sufllcient tension to hold the moistened body in place, removing moisture from the body and the insulation, impregnating the fibrous'body and the insulation, and enclosing the insulation in an impervious sheath.
  • the method of making stranded electric cables which comprises spirally applying over the bare strands of the conductor a body of fibrous paper, moistening the paper so applied to soften it, passing the so covered conductor through dies to force a portion 01' the paper into the strand spaces and also reduce the thickness of the paper overlying the outer surfaces of the conductor strands, applying insulation over the so compressed paper, and applying a sheath over the insulation.

Landscapes

  • Engineering & Computer Science (AREA)
  • Manufacturing & Machinery (AREA)
  • Manufacturing Of Electric Cables (AREA)

Description

April 2, 1940. H, RACE 2,195,998
HIGH TENSION ELECTRIC CABLE AND METHOD OF MAKING .THE SAME Filed March 8, 1938 Fig.1.
Fig.2
4 miiw a ce, by i sfi/ ttorney.
Patented Apr. 2, 1940 PATENT OFFICE HIGH TENSION ELECTRIC CABLE AND METHOD OF THE SAME Hubert 11. Race, Schenectady, N. Y., assignor to General Electric Company, a corporation of New York Application March 8, 1938, Serial No. 194,568
2 Claims.
It has long been known that high tension stranded cables insulated with fibrous material are subject to ionization and corona effects which manifest themselves at diflerent places in the cable and specifically in the region of the outermost layer of the strands. This, I have ascertained by elaborate investigation and tests, is due to the fact that the insulation which is wrapped around the conductor does not fill the outermost strand spaces but on the other hand with the strands defines approximately V-shaped spirally disposed spaces extending lengthwise of the cable. Upon dissecting cables as ordinarily constructed, it will be found that in many cases the paper has turned darker in the region where it contacts with the peripheral surface of the strands. Such a darkening of the paper is evidence of the fact that ionization and corona has taken place to a greater or less degree. This trouble is initiated by ionization of the oil or compound contained in the V-shaped spaces which are the regions of maximum electrical stress.
It has been proposed to prevent ionization and corona in the region of the V-shaped spaces above mentioned by applying a smooth exterior metal coveringfor the strands and in electrical contact therewith, such for example as thin metal-tapes applied in overlapping relation. It has also been proposed for the same purpose to use tapes made of fibrous material and to so metalize them before application to the conductor as render them conducting or at least semiconducting. Irrespective of the kind of covering so applied, the V-shaped strand spaces exist and should a fault occur in the covering, the oil or compound in any of the spaces so formed is subject to ionization and later the cause of corona effects. Such coverings have the effect of somewhat increasing the diameter of the cable, and are a source of added expense both initially and in the manufacture of the cable.
My invention has for its object the method or process of manufacturing high potential cables whereby ionization and corona duepto the presence of oil orcompound as such in the strand spaces of the outer layer of the conductor underneath the surrounding insulation, is prevented.
For a consideration of what I believe to be novel and my invention, attention is directed to the accompanying description and the claims appended thereto.
In the accompanying drawing which is illustrative oi my invention, Fig. 1 indicates a short 7 thickness for the voltage of the cable.
piece of stranded cable; Fig. 2 is a diagrammatic view illustrating the usual construction of paper insulated cable; Fig. 3 is a cross-section of my improved cable on an enlarged scale showing the external strand spaces filled with compressed fibrous insulation; Fig. 4 illustrates the application of moist paper to fill the strand spaces and also the application of insulating material; Fig. 5 is a perspective view of a strand space filler made of fibrous material; Fig. 6 shows a length of sheathed cable with a vacuum pump for removing moisture and air therefrom, and Fig. 7 is a greatly enlarged view showing how the compacted moist material completely fills the strand space.
Referring first to Fig. 2, 4 indicates the conductors of a stranded cable of which there may 'be any desired number of strands and of layers cable may result in one or more pockets or dry spots being formed in the strand spaces and thereby increases the danger of failure. The insulation 6 is applied layer by layer to the desired It will be observed that the insulation does not and under the circumstances cannot fill the said strand spaces but on the contrary rests on the peripheral surfaces of the strands. Thus it will be seen that each strand space is defined by the peripheral surfaces of the two adjacent strands and the overlying body of insulation. It is in these V-shaped strand spaces that ionization of the oil or compound takes place with the ultimate result of causing corona effect which in turn causes deterioration of the insulation. If the effect is pronounced, it will in time result in cable failure. I
According to my invention, these V-shaoed strand spaces instead of being empty or filled only with oil or compound are filled with hard packed fibrous insulation, such as paper, for example, which in the subsequent process of manufacture of the cable are fully impregnated with oil or compound. It is well recognized that impregnated paperhas a higher dielectric strength than oil or compound alone or paper alone. It
A failure in a -manufacturing operation or during use of the will thus be seen that my improved cable embodies the best engineering practice in this particular. As previously indicated in connection with Fig. 2, paper applied in the usual condition of dryness will not fill the spaces no matter how tightly it is wrapped around the conductor. I depart radically from the established practice of using dry paper tape and use paper tape which contains a large percentage of water vapor or moisture to make it soft and workable. I may use one or more such layers, desirably at least two with overlapping joints so as to ensure a complete covering without any intervening spaces between turns. While the tapes are moist and well softened by water or other vapor, they are subjected to relatively heavy external compression pressure which has the effect of forcing or squeezing the moist paper into the V-shaped strand spaces and completely filling them. After the moist paper tapes are forced into the strand spaces, the insulation for the conductor, whether it be paper or equivalent material, may be applied in the usual way.
The presence of any appreciable amount of moisture within a cable is, of course, highly detrimental for operating conditions and cable manufacturers definitely limit it to the smallest amount consistent with satisfactory making operations. In fact, the best practice calls for applying the paper in a room where the percentage of moisture is accurately controlled and limited to a determined small amount. ture in my case can be removed by the usual technique of drying before impregnation. It is customary in the manufacture of paper insulated cable to subject it to the effects of vacuum, or to both vacuum and heat, to remove moisture and air contained in the insulation and strand spaces as fully as possible prior to impregnation, and such treatment will likewise remove the excess moisture contained in the paper that has been compressed into the strand spaces. Thus it will appear that the removal of the excess moisture does not require an extra operation in the manufacture of the cable.
In Fig. 3 is shown a section of a part of a cable wherein 4 indicates the outer layer of strands of conducting material, such as copper. Inside of these strands are other strands 'l of which as many may be provided as desired to carry the current for which the cable is intended. 8 indicates the triangular-shaped portions of the moist paper which have been forced into the outer strand spaces by external pressure. Over the numerous strips or portions 8 is wound the necessary customary insulation, and the latter is enclosed in an impervious lead or equivalent sheath 9.
Referring to Fig. 4, l0 indicates the stranded conductor which may be hollow or solid depending upon its ultimate use. II and I2 indicate paper tapes which are applied directly over the bare strands. The tapes may be applied by the same machine which applies the final insulation, all that is required is to have the necessary number of paper carrying bobbins for the purpose on the revolving head of the machine. These bobbins may and usually would be duplicates of those used in applying the main insulation. For the tapes, whether for the strand spaces or the main insulation, it is desirable to use paper which has been carefully washed to remove impurities as completely as possible. Because moist paper tape is notso strong as the usual type of dry paper tape, a convenient way is to apply it in a dry state and subsequently to moisten it to the neces- The excess moissary extent. This may be done by means of a nozzle or equivalent device l3 which discharges water, steam or other vapor over the paper tapes H and I! after application in sufficient amount to render them soft and pliable. Desirably the nozzle should be so shaped as to cause the water or vapor to act on the entire circumference of the tapes to facilitate moistening. As the conductor is pulled through the machine in the customary manner by a capstan, it is passed through roller dies H and I5 which are so shaped and positioned and under such pressure as to force the moist paper into the V-shaped strand spaces. Assuming that the strands are in contact, which should be the case in a well constructed cable, the inner or sharp end of the squeezed-in fibrous material should fully extend into that part of the conductor where each two of the strands are in sidewise contact throughout their respective lengths. Depending upon the compression pressure exerted by the dies, the paper tapes may be forced into the strand spaces, leaving only the high spots of the strands slightly exposed. If a lesser pressure is used, the moistened tapes may appear as a very thin, nearly transparent covering for the strands with the remainder filling the strandspaces. The dies may be cold or they may be heated to some extent in which case they will aid in removing a limited amount of the moisture. The mere fact that they act to compress the paper tapes may result in heating the dies to some extent. After the moist paper is applied and ironed into place by the dies, the insulation in the form of tapes is applied, of which l6 and I! may be regarded as examples. The number of tapes will be governed by the voltage under which the cable is to operate. Desirably the insulating tapes are applied before the moist tapes are fully dried since by so doing they act as binding means therefor and also compress it and smooth out any slight irregularities that otherwise might exist. As will be apparent, the insulation as such may be of paper or other suitable material, following in this particular established cable practice.
In Fig. 7 is shown on a greatly enlarged scale round copper conductors 4 arranged in side-byside contact with a filling 8 of paper in the V- shaped spaces between them. In this figure, the filling is arranged to terminate in a thin edge adjacent the highest part of each of the conductors.
As shown, especially in Fig. 4, the tapes 1 I and I2 are spirally wrapped around the conductor yet after the die or ironing operation, it is noticeable that the bodies of the tapes in each strand space form practically a unitary structure. In Fig. 6 is shown by way of example means employed in removing air and moisture from a sheathedcable. In this figure, I8 indicates a sheathed cable having sealing caps l 9 at its ends, one of which is connected to a vacuum pump 20 of any suitable construction. If it be desired to evacuate the cable before applying the sheath, it may be done. in accordance with the usual methods.
What I claim as new and desire to secure by Letters Patent of the United States is:
1. The method of making high potential stranded electric conductor which comprises assembling it to substantially fill the strand spaces of the outer layer of strands, applying insulation over the strands and body under sufllcient tension to hold the moistened body in place, removing moisture from the body and the insulation, impregnating the fibrous'body and the insulation, and enclosing the insulation in an impervious sheath.
2. The method of making stranded electric cables which comprises spirally applying over the bare strands of the conductor a body of fibrous paper, moistening the paper so applied to soften it, passing the so covered conductor through dies to force a portion 01' the paper into the strand spaces and also reduce the thickness of the paper overlying the outer surfaces of the conductor strands, applying insulation over the so compressed paper, and applying a sheath over the insulation.
HUBERT H. RACE.
US194568A 1938-03-08 1938-03-08 High tension electric cable and method of making the same Expired - Lifetime US2195998A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US194568A US2195998A (en) 1938-03-08 1938-03-08 High tension electric cable and method of making the same

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US194568A US2195998A (en) 1938-03-08 1938-03-08 High tension electric cable and method of making the same

Publications (1)

Publication Number Publication Date
US2195998A true US2195998A (en) 1940-04-02

Family

ID=22718085

Family Applications (1)

Application Number Title Priority Date Filing Date
US194568A Expired - Lifetime US2195998A (en) 1938-03-08 1938-03-08 High tension electric cable and method of making the same

Country Status (1)

Country Link
US (1) US2195998A (en)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3194871A (en) * 1961-06-09 1965-07-13 Gen Cable Corp Graded initial moisture content paper cable
US3238280A (en) * 1962-07-02 1966-03-01 Gen Electric Porous coatings for electrical conductors and method of forming

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3194871A (en) * 1961-06-09 1965-07-13 Gen Cable Corp Graded initial moisture content paper cable
US3238280A (en) * 1962-07-02 1966-03-01 Gen Electric Porous coatings for electrical conductors and method of forming

Similar Documents

Publication Publication Date Title
US2915808A (en) Methods of making electrical capacitors
US2591794A (en) Gas-filled power cable with embossed tape
US1697134A (en) Bakelized armature coil
US2195998A (en) High tension electric cable and method of making the same
US3621119A (en) Insulated conductor for communication cable
US2112322A (en) Cable
US2309992A (en) Electric power cable
US1740076A (en) Electric cable
US2300910A (en) Transformer
US2320796A (en) Method of making high tension electric cable
US2429635A (en) Application of insulating material to electric cables
US2234353A (en) Electrical insulating material
US2067169A (en) Electric cable
US2264439A (en) Nonmetallic sheathed cable
US2290706A (en) Cable joint and method of making the same
US1892663A (en) Method of and apparatus for improving the electrical properties of cables
US2318367A (en) Insulated electric conductor
US2120095A (en) Insulated electrical cable
US2536885A (en) Method of making multiconductor cables
US2379756A (en) Insulating sheath on electrical conductor strands
US1935532A (en) Insulation of high voltage conductors
US2093445A (en) Electric cable
DE1803161A1 (en) Method for supporting and distancing the insulated conductors of a high-voltage winding
US2043702A (en) Insulated wire
US1940511A (en) High voltage conductor