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cable,originally wire cordage of great strength or heavy metal chain used for hauling, towing, supporting the roadway of a suspension bridge, or securing a large ship to its anchor or mooring. Today a cable often refers to a line used for the transmission of electrical signals. One type of electric cable consists of a core protected by twisted wire strands and suitably insulated, especially when it is used to cross oceans undersea; a message transmitted by cable is known as a cablegram or cable. France and England were first successfully connected by submarine telegraphic cable in 1845. The first permanent transatlantic cable was laid in 1866 by Cyrus West FieldField, Cyrus West,
1819–92, American merchant, promoter of the first Atlantic cable, b. Stockbridge, Mass.; brother of David Dudley Field and Stephen J. Field. As head of a paper business, he accumulated a modest fortune, and in 1853 he retired.
..... Click the link for more information. , although demonstrations of its possibility had been made in 1858. The first telephone message was transmitted from New York to Philadelphia in 1936; the first transatlantic telephone cable was laid in 1956.
The coaxial cable, which is virtually immune to external interference, consists of two concentric conductors separated by an insulator; the current in the inner conductor draws the current in the outer conductor toward the center rather than letting it dissipate outwards. Because they can carry a large number of signals simultaneously, coaxial cables are also used in cable televisioncable television,
the transmission of televised images to viewers by means of coaxial cables. Cable systems receive the television signal, which is sent out over cables to individual subscribers, by a common antenna (CATV) or satellite dish.
..... Click the link for more information. systems. The newest form of cable is the fiber-opticfiber optics,
transmission of digitized messages or information by light pulses along hair-thin glass or plastic fibers. Each fiber is surrounded by a cladding having a high index of refractance so that the light is internally reflected and travels the length of the fiber
..... Click the link for more information. cable, developed in the 1970s. Instead of a copper conductor, a silica glass fiber carries digitized signals as pulses of light.
The insulated wire that conducts electricity from generator to consumer is also called a cable; it often contains multiple conductors and must be of sufficient gauge to carry large currents. Its insulation must withstand high voltages.
(or rope), a flexible article manufactured from steel wire, filaments, yarn (hemp yarn), or vegetable, synthetic, or mineral fibers. Cables can be subdivided by their method of manufacture into twisted, nontwisted, and braided types.
Metal (steel) cables are manufactured from uncoated (bright), zinc-coated, or aluminum-coated wire of circular or shaped cross section, with tensile strength δv = 900–3, 500 meganewtons per sq m (MN/m2), or 90-350 kilograms-force per sq mm (kgf/ mm2). The cross section of steel cables may be round, hexagonal, rectangular, or square. Twisted round cables may have various lays—for example, a single spiral lay, which may be open, semi-sheathed, or sheathed; double lay (hawser lay), made up of three to eight strands, which may be circular or shaped (trihedral or oval); or triple lay (cable lay), made up of hawser-laid cables (strands). According to the arrangement of wires in the strand layers, cables may have linear, point, or combination contact between the wires. Depending on the lay of the strands, cables may be of the untwisting, nonuntwisting, or low-twist types (there may be 18-31 strands, with opposite directions of lay in individual layers). The direction of lay for the strands of a cable can be right-hand (designation Z) and left-hand (designation 5); the combination of directions of lay for the individual elements and for the cable as a whole can be crossed right-hand (SZ), crossed left-hand (ZS), one-way right-hand (ZZ), and one-way left-hand (SS). Twisted circular cables have a diameter of up to 100 mm. Combined twisted cables are made of hemp and steel. In this case the steel strands are covered by a layer of hemp yarn or plastic. Nontwisted cables consist of tightly packed groups of steel wires or spiral cables compressed from the outside by a spiral wrapping or by clamps. Such cables are usually assembled at the place of use; their diameter may be up to 1.5 m. The breaking load of nontwisted cables depends on their diameter and can be as high as 1,000 MN. Braided cables are produced by braiding an even number of strands (usually four), half of which have a right-hand braid and the other half a left-hand braid. Such cables have a square cross section. Flat cables consist of an even number of strands (four to twelve), with an alternating (right-hand and left-hand) lay, fastened together (stitched) with strands or pins; such cables have a rectangular cross section, and they are up to 250 mm wide.
|Table 1. Characteristics of various types of cable|
|Diameter (mm)||Breaking load (KN)2|
|1Data for breaking load are based on total strength of wire 21 kN = 1,000 kgf|
|Spiral open ...............||0.65–34.4||0.44–965.0|
|Hawser–laid (LC), with core|
Nonmetallic (fiber) cables for ropes are spun from long bast fibers of Russian (soft), manila, and sisal (stiff) hemp, from seed fibers of coconut and cotton, and from synthetic fibers (polypropylene, capron, nylon, perlon, and others) and asbestos fibers. Short fibers (hemp and cotton) are used in the manufacture of cord, binder twine, and other articles. Nonmetallic cables are made in stranded lays (three- and four-strand), with right-hand hawser cable lay (three-strand), as ordinary braided round cables (halyards), or as high-flexibility (nautical) cables. The diameter of fiber cables made from tarred or untarred Russian hemp, manila hemp, or sisal hemp is 6.7-111.5 mm. Cables made from stiff hemp, as compared with those made of soft hemp, have the advantage of greater strength, better wear resistance, and lower weight. Cables made from synthetic fibers exhibit high-strength properties. The strength characteristics of various kinds of cables are given in Table 1.
|Table 2. Uses of various types of cable|
|Spiral open..............||Guy ropes, reinforcement of structural members and engineering products, and lightning-protection cables of high-voltage power lines|
|Spiral sheathed..............||Cableways and mine hoists|
|Hawser type, crossed lay..............||Hoisting and transportation mechanisms and machines, boring equipment, timber procurement|
|Hawser type, shaped strands..............||Funicular cableways and inclined mine hoists|
|Cable-laid, multiStrand..............||Maritime and river transport (mooring and towing)|
|Nontwisted..............||Reinforcement of structural members and suspension bridges|
|Flat..............||Mine hoists (cage hoists), shaft-sinking equipment (hoists)|
|Braided..............||Load hoisting equipment (prevents rotation of the load)|
|Hawser type, untarred..............||Ship's tackle, binding of packaging material|
|Hawser type, tarred..............||Tackle and others (primarily for maritime and river transportation)|
|Cable-laid..............||Mooring and towing|
|Braided (halyards)..............||Rigging for sailing ships, equipment for towing a nautical log|
M. A. BUKSHTEIN
electrical, one or more insulated wires enclosed in hermetic sheathing. As a rule, the sheathing is covered by protective coatings. Cables are used in the transmission of electric power or signals (high-voltage power lines; power supply for industrial enterprises and transportation and municipal institutions; communications trunk lines; urban telephone networks; radio and television communications links; power supply for mobile operating machines, such as excavators and coal-cutting and peat-digging machines, and electrical equipment of ships and aircraft). The design of a cable depends essentially on the operating conditions in the cable run (underground; in water, air, or chemically active mediums; at low or high temperatures; or under conditions of high humidity).
Cables of all types have some common design components: current-carrying strands, insulation, and sheathing. Current-carrying strands are made of copper or aluminum, which, with the exception of silver, have the lowest electrical resistance (the specific resistivity p of electrolytic copper is 1.7 × 10-8 ohm ⋅ m; that of aluminum, 2.9 × 10-8 ohm ⋅ m). Depending on operating conditions the current-carrying strands may have various degrees of flexibility and may consist of a single wire or many wires twisted together. In power cables the current-carrying strands have standard cross sections. The choice of cross section depends on the power to be transmitted. In the USSR the most commonly used cross sections are 10, 16, 25, 35, 50, 70, 95, 120, and 150 sq mm. In communications cables the current-carrying strands have standard diameters.
Cable insulation consists of a one-piece, laminated or frame-and-air dielectric separating the current-carrying strands from one another and from the sheath. In multistrand cables the twisted, insulated strands are covered with additional insulation (belted); as a rule, its material is the same as that of the primary insulation. The belted insulation serves as a binding that imparts a circular shape to the cable. Insulation materials must have high electrical resistance and provide the electrical strength needed for particular operating conditions, while maintaining minimum insulation thickness; dielectric losses (tan **) must be low; and the dielectric constant (e) must be minimized. The materials must have high resistance to aging. For certain operating conditions additional requirements may apply to insulation, such as incombustibility and increased flexibility and wet strength. The heat resistance of insulation—that is, the ability to withstand high temperatures without a significant reduction in operational reliability—is of particular importance, since an increase in the upper limit of operating temperatures makes possible a reduction in overall dimensions and weight of the cable. Materials most widely used as insulation are cable paper and telephone paper, rubbers based on natural and synthetic latex, and plastics (polyethylene in various modifications, polyvinyl chloride, and polystyrene). Mineral oils, oil-rosin compounds, and certain inert gases under pressure can also be used as components of insulating materials.
Sheaths in the form of continuous tubes covering the current-carrying strands protect the strands from mechanical damage and the effects of moisture, light, and chemicals. For cables with easily moistened (hygroscopic) insulation the preferred sheath materials are lead or aluminum (materials with a near-zero diffusion constant). Lead sheaths are easily molded at relatively low temperatures (180°-220°C). In spite of several disadvantages—high density (11.4 g/cm3), danger to workers’ health, and low vibration resistance and mechanical strength—lead sheaths are widely used in the manufacture of cables. Aluminum is more promising for this purpose, since its strength is 2.0-2.5 times that of lead, it is lighter by a factor of 3.3, its vibration resistance is higher, and it is in better supply than lead. However, the molding of aluminum requires more complicated equipment, because plastic deformation of aluminum requires considerable force even at temperatures of 450°-500°C. To increase flexibility, aluminum sheaths for large-diameter cables are corrugated. Cables with continuous plastic insulation usually have sheaths consisting of various polyvinyl chlorides and polyethylene pigmented with 1-2 percent carbon black (the moisture permeability of polyvinyl chlorides is 10 times higher than that of polyethylene). Cables with rubber insulation usually have a sheath made of materials with a synthetic latex base, which imparts to the insulation oil and gasoline resistance, noncom-bustibility, and high cold resistance, flexibility, and mechanical strength.
To protect cable sheaths against mechanical damage and corrosion, protective coverings, most of which contain an armored layer (armor), are applied to the sheaths. In most cases the armor consists of two steel strips 0.3-0.8 mm thick, sometimes galvanized or asphalt-covered. The strips protect the cable from damage during underground laying, as well as within buildings and in channels, blocks, and tunnels. To protect a cable from the effect of considerable tension forces, it is enclosed in an armor made from round (less frequently flat) galvanized steel wires with a diameter of 1.4-6.0 mm (such protection is mandatory for cables laid on the bottom of bodies of water and in boreholes). Soft covers or fillers consisting of several layers of asphalt-impregnated paper strips or of cable braid (jute) are placed above and below the armor. Cables laid in highly corrosive environments or in the ground where stray currents are present, as well as all cables with an aluminum sheath (independent of operating conditions), are protected by reinforced cover layers that contain layers of plastic, either in strips or continuous. Cables laid in mines or in buildings exposed to fire hazard are protected by noncombustible coverings, such as glass braid or coal-tar pitch. Protection of cables against minor mechanical damage is provided by armor shielding made from galvanized steel wires with a diameter up to 0.3 mm or by braiding with fibrous materials impregnated with nondecaying substances.
The USSR produces more than 1,000 types of cables, whose brands, types, usage, design, and characteristics are given in corresponding standards. A detailed classification of cables by groups, taking into account common technological processes, has been adopted for manufacturing planning and organization and is the basis for specialization of cable-producing factories
|Table 1. Main types of cable produced in the USSR|
|Design features||Areas of use|
|KShVGL 3 × 95 + 3 × 10 highly flexible (jacketed) high-voltage cable||Combination power cable (3 strands of 95 sq mm cross section and 3 grounding strands of 10 sq mm cross section) with rubber insulation in a double rubber sheath (jacket). Outside diameter, 69 mm; manufacturing length, 200 m.||For supplying power to earthmoving and mining machinery (excavators; spreaders, and others) under all weather conditions|
|MNSA and MSSA oil-filled cables with central channel||Single-strand with paper insulation in a lead sheath, reinforced by copper strips, with a corrosion-proof covering; channel consists of a spirally wound stainless-steel wire of 150-800 sq mm cross section. Voltage, 110-220 kV.||For connecting step-up transformers of large power plants to outside distribution equipment and for laying across water obstacles and in built-up areas; laid in trenches and tunnels and on the bottom of bodies of water (wire armor up to 6 mm thick is mandatory)|
|MVDT (high-pressure) oil-filled cable in steel tubing||Three-strand with paper insulation; laid in a steel tube with a diameter of up to 219 mm, filled with oil under pressure; enclosed in a corrosion-proof covering. Voltage, 220-500 kV; tubing is welded at the actual location of the cable run.|
|SB, ASB, AB, and AAB armored power cables; SBG, ASBG, and AABG cables without protective, covers||Three-strand, with paper insulation in a lead or aluminum sheath; protected by armor consisting of steel strips (2 layers) and by jute and asphalt coatings. Cross section, 25-240 sq mm; voltage, 1-10 kV; limiting temperature, 80°C; manufacturing length, more than 200 m.||For power and light installations; laid underground (in trenches) or along walls of buildings|
|KLShV-6 jacketed elevator cable with bearer cable||Highly flexible 6-strand cable; copper strands with rubber insulation; strands are twisted around a rubber-sheathed steel cable (breaking stress, 200 kgf or 2 kN); enclosed in a common rubber sheath. Outside diameter, 14 mm.||For elevator installations with a lift height of up to 40 m; free-hanging|
|GESK armored cable, filled with gas under pressure||Three-strand, with paper insulation, shielded with a metallized paper strip and a copper strip; gas is fed between strands. Cross section, 70-150 sq mm; voltage, 60-138 kV; limiting temperature, 70°C.||For high-voltage transmission lines. No limit on difference in laying levels.|
|KBM 8/6 armored communications trunk cable||Combination of 8 main and 6 small coaxial pairs, 1 quadruple, 8 paired, and 6 single conductors for service traffic and signaling; air insulation, lead sheath, steel-strip armor||For long-distance lines and for communication among points along cable run|
|TPP 100 × 2 × 0.5 telephone cable||Multipair cable (100 pairs of copper strands 0.5 mm in diameter) with polyethylene insulation in polyethylene sheathing; shielded by a smooth or corrugated aluminum strip. Electric resistance, 90 ohms/km; temperature, from -50° to 50°C; manufacturing length, 200-350 m.||For distribution and connecting telephone lines in city networks|
|KVRG 19 × 1.5 control cable||MultiStrand cable (19 strands of solid wires, cross section 1.5 sq mm), with rubber insulation in polyvinyl chloride sheath. Voltage, up to 2 kV; temperature, from ?40° to 50°C; manufacturing length, not less than 100 m.||For connecting electrical instruments and control, protective, and communications devices|
|KOBD-4 armored borehole cable||Single-strand (steel-copper) with rubber insulation (heat-resistant up to 80°C), in an oil- and gasoline-resistant rubber hose; armor consists of two braids of steel wire; manufacturing length, 3.0-3.5 km.||For electrical prospecting (core sampling) of petroleum, ore, and coal deposits and in sinking deep boreholes|
|RK-75-7-16 high-power, radio-frequency coaxial cable||Single-strand with solid polyethylene insulation in metal braiding; polyvinyl chloride sheath. Characteristic impedance, 75 ohms; diameter across insulation, 7 mm; temperature, 40°-70°C; manufacturing length, not less than 50 m.||For electric power supply to transmitting antennas and from receiving antennas in radio installations|
|KPT-41 television camera cable||Combination of three coaxial pairs, three quadruple and 19 single wires, one paired and five odd wires; with polyethylene insulation in a polyvinyl chloride sheath. Characteristic impedance, 75 ohms; manufacturing length, 50 m.||For connecting mobile television cameras to power sources and transmitting equipment|
and workshops. Cables usually have a letter designation, with an indication of the number and cross section or diameter of the current-carrying strands (see Table 1). For some cables the value of the most important characteristic is also given (operating voltage or rated characteristic impedance), or a characteristic design feature is indicated (type and number of coaxial pairs, double or quadruple twist, and so on). The letters usually denote the metal of the conductor, sheath, and insulation, as well as the presence and type of protective covering and armor and frequently the area of usage (control, shipboard, signaling and block signaling, or installation work). For example, ASK 3 × 95-6 is a power cable that has three aluminum strands with a cross section of 95 sq mm enclosed in a lead sheath and an armor made of circular steel wires, with a reinforced protective covering on the outside, for a rated voltage of 6 kilovolts (kV); TPVBG 100 × 2 × 0.5 is a telephone cable with polyethylene insulation in a polyvinyl chloride sheath, armored with 100 pairs of steel strips with corrosion-proof coating; the diameter of the copper strands is 0.5 mm.
Data on the cables that are most widely used in various areas of technology are given in Table 1, along with an indication of the main brands for each type and a description of design characteristics, main parameters, cable-laying conditions, operating conditions, and main areas of use.
REFERENCESBragin, S. M. Elektricheskii i teplovoi raschet kabelia. Moscow-Leningrad, 1960.
Bachelis, D. S., N. I. Belorussov, and A. E. Saakian. Elektricheskie kabeli, provoda i shnury, 2nd ed. Moscow-Leningrad, 1963. (Handbook.)
Kabeli i provoda, vols. 1-3. Moscow-Leningrad, 1959-64.
Osnovy kabeVnoi tekhniki.Moscow-Leningrad, 1967.
Privezentsev, V. A., and E. T. Larina. Silovye kabeli i vysokovol’tnye kabe’nye linii. Moscow, 1970.
V. M. TRET’IAKOV