US1956199A - Electric cable - Google Patents

Electric cable Download PDF

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Publication number
US1956199A
US1956199A US250576A US25057628A US1956199A US 1956199 A US1956199 A US 1956199A US 250576 A US250576 A US 250576A US 25057628 A US25057628 A US 25057628A US 1956199 A US1956199 A US 1956199A
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cable
oil
pressure
compound
gas
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US250576A
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Thomas F Peterson
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01BCABLES; CONDUCTORS; INSULATORS; SELECTION OF MATERIALS FOR THEIR CONDUCTIVE, INSULATING OR DIELECTRIC PROPERTIES
    • H01B9/00Power cables
    • H01B9/06Gas-pressure cables; Oil-pressure cables; Cables for use in conduits under fluid pressure
    • H01B9/0611Oil-pressure cables

Definitions

  • Patentd Apr. 24, 1934 UNI-TED STATESv PATENT OFFICE This invention relates to improvements in the construction of cable used for the transmission of electrical energy at What are commonly classed as high voltages, namely, greater than 20,000
  • Cable of this class is usuallymade up of one or more conductors insulated with paper and heated, evacuated, then saturated with compound and finally encased in a lead or lead alloy sheath. Though attempts are made to remove all gas before saturation some invariably remains or is occluded With the compound or oil forming bubbles or lrns, and these bubbles or lms of gas when subjected to sufficiently high electrical stresses become ionized, breakdown and serve as l5 starting points for complete cable failure. On
  • the present invention comprises the inclusion within the cable of volumetric change-compensating means which also function to oiier resist- 'ance to flow or migration of oil longitudinally of the cable. It is based on the principle of securing pressure stabilization slightly above atmospheric by means of a gas or compressible medium that is not within an electric eld and not in contact with oil or compound; air or gas, if not so confined, may migrate to parts of cable under electrical stress or be absorbed by the oil. In the embodiments illustrated and hereinafter described it takes the form of air or gas filled sealed iiexible reservoir units or cells placed at intervals along the cable length.
  • FIG. 1 is a longitudinal section of a cable showing one type of unit
  • Fig. 2 is a transverse section on the line 2-2 of Fig. 1; ⁇ Fig. 3 is a side view of another type of unit; Fig. 4 is a transverse section on the line 4-4 oi' Fig. 3;
  • Fig. 5 is a longitudinal section of a modifica.- tion of the unit shown in Fig. 1;
  • Fig. 6 is a transverse section of a three-conductor cable.
  • the cable shown in longitudinal section in Fig.. 1 comprises a hol1ow ⁇ core conductor 10 which can be formed from a plurality ol.' helically twisted strands 11.
  • a hol1ow ⁇ core conductor 10 which can be formed from a plurality ol.' helically twisted strands 11.
  • About the conductor is the usual oil or compound impregnated insulation l2 consisting of layers of paper or other suitable material or fabric. The insulation in turn is enclosed within a lead sheath 13.
  • Fig. 3 Within the hollow core of the conductor are disposed at suitable intervals pressure-compensating unit is shown in Fig. 3.
  • eating units 15 which are preferably lled with a gas or air and sealed. They may, however, be spring tted, as shown in Fig. 5, and sealed under vacuum. Inside the corrugated metallic cylinder 17 is a spring 22 tending to expand the unit, such expansion being limited by the Wire or bond 19 connecting the ends 18 in order to prevent over-expansion or bursting.
  • Gas fillectunits of flexible material should preferably be sealed so that, when in their normal condition as regards expansion and contraction, internal pressure is somewhat above atmospheric.
  • the core space between the units is preferably lled with some material 16 such as jute or rope, to further impede longitudinal flow of oil or compound along the cable.
  • the pressure-compensating units or cells can be constructed in a number of Ways.- As illustrated in Fig. 1, a unit comprises a flexible bellows or a circumferentially corrugated metal cylinder 17 with ends 18 secured thereto. Since the cable after construction is subject to evacuation,
  • the unit 20 is provided with longitudinal corrugations 21.
  • a phosphor bronze strip or equivalent material is corrugated, bent into cylindrical form and soldered.
  • the ends 22 may be capped as in the rst embodiment or they can be drawn into conical form and then sealed. This type of unit expands and contracts transversely and there is therefore no longitudinal displacement.
  • the corrugations can be helical in which case movement of the walls of the unit due to changes in pressure will be both longitudinal and transverse, the extent of movement in each direction being governed by the pitch of the helix.
  • Suchfibrous material Suchfibrous material.
  • the conductor as to compensate for a change in Volume of the compound within the cable, measured by the distance between the centers of the units, that is caused by the changes in temperature to which the cable is subject in use preferably Without a variation in pressure materially in excess of one atmosphere.
  • pressure is preferably applied before sealing the ends for shipment so that the units will be compressed and thus keep cable completely filled With oil and prevent formation of voids or spaces due to reeling and installation or loss of oil or compound during splicing. Any contraction of compound caused by a drop of temperature is likewise compensated b y the application of an initial pressure.
  • a slight pressure can be applied to the cable system by means of reservoirs at the joints. Since. the core is blocked by the units and other lling, the static head of oil will not develop excessive pressure but will create very slow migration; it can be taken care of, if necessary, by the reservoirs at the joints. Development of pressures due to temperature changes resulting from cable operation will be compensated by the movement or the units Within the core.
  • the invention is not limited to single conductor cables but can be applied to multiple conductor cables of the shielded type in which case it is prefable to place units in unstressed interstices. Such a construction is shown in Fig. 6, the conductorsI are inserted the pressure compensating units 15.
  • a high-tension cable including the combination of a hollow conductor, oil impregnated insulation covering said conductor, the latter being constructed to permit the passage of oil forced from said insulation, at least one expansible device in said hollow conductor and means for applying expansive forces to said device, said hollow conductor having all internal space not occupied by said expansibe device, lled with a THOMAS F. PETERSON.

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  • Gas Or Oil Filled Cable Accessories (AREA)
  • Cable Accessories (AREA)

Description

Patentd Apr. 24, 1934 UNI-TED STATESv PATENT OFFICE This invention relates to improvements in the construction of cable used for the transmission of electrical energy at What are commonly classed as high voltages, namely, greater than 20,000
volts. Cable of this class is usuallymade up of one or more conductors insulated with paper and heated, evacuated, then saturated with compound and finally encased in a lead or lead alloy sheath. Though attempts are made to remove all gas before saturation some invariably remains or is occluded With the compound or oil forming bubbles or lrns, and these bubbles or lms of gas when subjected to sufficiently high electrical stresses become ionized, breakdown and serve as l5 starting points for complete cable failure. On
account of this tendency the percentage of residual gas remaining in the cable must be kept below a very small amount, that is, less than one per cent by volume. `Though bubbles ,or lms of gas are a source of cable failure, they are on 'the other hand useful as serving to cushion volumetric changes in the cable and the contained compound which take place with temperature changes; but, since the percentage of allowable residual gas is so small, a slight expansion of compound creates a large increase of pressure which is apt to stretch the inelastic lead sheath. Upon contraction of the compound and release of pressure, voids are then developed Within the cable, and to eliminate voids so formed or that may otherwise exist in the cable, recent practice provides the use of oil reservoirs at joints. (This subject is more fully treated in my paper published in the November ,19, 1927 issue of the Electrical World). Even ,35 with oil reservoirs, however, the cycle of expansion and construction with distension of the sheath and formation of voids may occur or be repeated due to the large resistance to oil flow within the paper-insulated cable. The use of hollow cores or open-stranded conductors, slotted sheath or the like, providing a continuous channel for oil to flow longitudinally of the cable improves the distribution and tends to equalize pressures resulting from expansion; but this construction as practised necessitates the use of reservoirs, pressure tanks, towers and stop joints at intervals suciently near to avoid the building up of localized excessive pressures within the cable. The installation of cable with continuous oil channels furthermore requires elaborate eld work to insure evacuation of gas and impregnation with oil, and the cost of this forms a. very appreciable part of the total.
According to the present invention internal pressures are maintained at all times within prescribed limits, volumetric changes due to the temperatures change are compensated and wide pressure variations are substantially eliminated while voids within the cable are quickly filled with compound. Furthermore these objects are accomplished Without the need of expensive tower tanks, pressure tanks or stop joints, reinforced sheaths etc. Furthermore, expansible oil reservoirs of the character described in the paper aforesaid can be used at cable joints without the danger of cumulative additions of oil to localized parts of the cable. In other words, by the present invention pressure stabilization with very short time lag, complete filling with oil at all times after leading of the cable and minimization of difficulties arising from oil migration are made possible.
The present invention comprises the inclusion within the cable of volumetric change-compensating means which also function to oiier resist- 'ance to flow or migration of oil longitudinally of the cable. It is based on the principle of securing pressure stabilization slightly above atmospheric by means of a gas or compressible medium that is not within an electric eld and not in contact with oil or compound; air or gas, if not so confined, may migrate to parts of cable under electrical stress or be absorbed by the oil. In the embodiments illustrated and hereinafter described it takes the form of air or gas filled sealed iiexible reservoir units or cells placed at intervals along the cable length.
In the accompanying drawing Fig. 1 is a longitudinal section of a cable showing one type of unit;
Fig. 2 is a transverse section on the line 2-2 of Fig. 1;` Fig. 3 is a side view of another type of unit; Fig. 4 is a transverse section on the line 4-4 oi' Fig. 3;
Fig. 5 is a longitudinal section of a modifica.- tion of the unit shown in Fig. 1; and
Fig. 6 is a transverse section of a three-conductor cable. l
The cable shown in longitudinal section in Fig.. 1 comprises a hol1ow^`core conductor 10 which can be formed from a plurality ol.' helically twisted strands 11. About the conductor is the usual oil or compound impregnated insulation l2 consisting of layers of paper or other suitable material or fabric. The insulation in turn is enclosed within a lead sheath 13.
Within the hollow core of the conductor are disposed at suitable intervals pressure-compensating unit is shown in Fig. 3.
eating units 15 which are preferably lled with a gas or air and sealed. They may, however, be spring tted, as shown in Fig. 5, and sealed under vacuum. Inside the corrugated metallic cylinder 17 is a spring 22 tending to expand the unit, such expansion being limited by the Wire or bond 19 connecting the ends 18 in order to prevent over-expansion or bursting.
Gas fillectunits of flexible material should preferably be sealed so that, when in their normal condition as regards expansion and contraction, internal pressure is somewhat above atmospheric. The core space between the units is preferably lled with some material 16 such as jute or rope, to further impede longitudinal flow of oil or compound along the cable.
The pressure-compensating units or cells can be constructed in a number of Ways.- As illustrated in Fig. 1, a unit comprises a flexible bellows or a circumferentially corrugated metal cylinder 17 with ends 18 secured thereto. Since the cable after construction is subject to evacuation,
it may be necessary to include some means suchl as a loosely-stretched wire or bond 19 connecting the ends 18, so that rupture of the unit will not occur due to the pressure Within it. With this type of unit the tendency is to expand or contract longitudinally as the external pressure upon it is less or` greater than the gas pressure within.
Another embodiment of the pressure-compen- In this form the unit 20 is provided with longitudinal corrugations 21. In the manufacture of this unit a phosphor bronze strip or equivalent material is corrugated, bent into cylindrical form and soldered. The ends 22 may be capped as in the rst embodiment or they can be drawn into conical form and then sealed. This type of unit expands and contracts transversely and there is therefore no longitudinal displacement.
Other forms of unitscan be used, for example,-
the corrugations can be helical in which case movement of the walls of the unit due to changes in pressure will be both longitudinal and transverse, the extent of movement in each direction being governed by the pitch of the helix. Suchfibrous material.
the conductor as to compensate for a change in Volume of the compound within the cable, measured by the distance between the centers of the units, that is caused by the changes in temperature to which the cable is subject in use preferably Without a variation in pressure materially in excess of one atmosphere.
After the cable is constructed and impregnated, pressure is preferably applied before sealing the ends for shipment so that the units will be compressed and thus keep cable completely filled With oil and prevent formation of voids or spaces due to reeling and installation or loss of oil or compound during splicing. Any contraction of compound caused by a drop of temperature is likewise compensated b y the application of an initial pressure. After the installation a slight pressure can be applied to the cable system by means of reservoirs at the joints. Since. the core is blocked by the units and other lling, the static head of oil will not develop excessive pressure but will create very slow migration; it can be taken care of, if necessary, by the reservoirs at the joints. Development of pressures due to temperature changes resulting from cable operation will be compensated by the movement or the units Within the core.
The invention is not limited to single conductor cables but can be applied to multiple conductor cables of the shielded type in which case it is prefable to place units in unstressed interstices. Such a construction is shown in Fig. 6, the conductorsI are inserted the pressure compensating units 15.
Since the cores or interstices of the multiple conductors are thereby filled to block longitudinal movement of compound, stop joints and expensive towers to develop pressure to balance that Within the cable are not required.
I claim:
A high-tension cable including the combination of a hollow conductor, oil impregnated insulation covering said conductor, the latter being constructed to permit the passage of oil forced from said insulation, at least one expansible device in said hollow conductor and means for applying expansive forces to said device, said hollow conductor having all internal space not occupied by said expansibe device, lled with a THOMAS F. PETERSON.
US250576A 1928-01-30 1928-01-30 Electric cable Expired - Lifetime US1956199A (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20050037656A1 (en) * 2003-08-26 2005-02-17 Cairns James L. Dry mate connector

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20050037656A1 (en) * 2003-08-26 2005-02-17 Cairns James L. Dry mate connector
US6910910B2 (en) * 2003-08-26 2005-06-28 Ocean Design, Inc. Dry mate connector

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