ELEC 1104

Lecture 6: OhdlidOverhead lines and underground cables Power Syyystem Layout Transmission lines Distribution lines Transmission and Distribution Lines

ƒ Transmission lines are hung from steel towers through insulator strings, and they may be sin gl e cir cui t or doubl e cir cui t lin es. ƒ There are usually one or two earthed wires at the top of tower for lightning protection . ƒ Distribution lines are usually supported on iltiinsulator pins mount on wood en or concret e poles. Saggp and Span

Earth wire

Sag

Conductor tower Minimum clearance

Span Earth Wires

ƒ Overhead lines are Earth wire usually protected from lightning by installing one or two overhead earth wires positioned to Line give suitable shielding conductor Shield angle over the line conductors. ƒ These earth wires are electrically connected to the earthed towers. Insulators Overhead lines

ƒ Bare conductors stranded of several wires for greater flexibility and mechanical str engt h. ƒ Standard number of strands are in either one of the series: (a) 1, 7, 19 …….. (b) 3, 12, 27 ……. Overhead lines Conductors

Material Hard drawn Hard drawn Heat treated CiCopper wire Alumi ni um Alumi ni um wire alloy Specific gravity 8.89 2.7 2.70 Breaking stress 23-30 10-12 19.2 (tons/sq in) Conductivity at 20oC 97.4 61 53.5 (% of ICAS) Resistivity at 20oC 1.774 2.826 3.22 (Ω-m x 10-8) Coefficient of linear 0.000017 0.000023 0.000023 expansion (oC-1) Resistivity of International Annealed Copper Standard (IACS) at 20oC = 1.7241 x 10-8 ohm-meter. Copper vs Aluminium

ƒ Aluminium is liggyhter but its conductivity is lower. ƒ For equal conductivity, aluminium conductor has 1.64 times the cross section of copper, but its weight is only about half of that of the copper conductor. ƒ Aluminium has low tensile strength and high coefficient of expansion. ƒ Cost of aluminium is lower and more stable. ASCR

ƒ Aluminium conductors are often reinforced by steel for greater mechanical strength and are known as ACSR (Aluminium Conductor, Steel Reinforced). ƒ In ACSR the central strands of the conductor are madflde of galvani idzed steel lf for strength hh whereas th e peripheral strands are made of aluminium for electrical conductivity .

6 aluminium 6 aluminium 1 steel 7 steel Bundle conductors

ƒ Bundle conductors composed of two, three or four stranded conductors are used for ver y hi gh vol tages. ƒ Lower voltage gradient at conductor surface ƒ BttBetter h eat tdii dissipati on and dh hence b bttetter current rating.

A bundle of 2 A bundle of 3 A bundle of 4 Corona

ƒ A corona is a luminous ppgartial electrical discharge due to ionization of the air surrounding a conductor. ƒ The breakdown stress, i.e. the critical field intensity, of air would depend on the atmospheric conditi ons. ƒ For a given voltage, the maximum field intensity occurs attht the con duc tor sur face an ddd decreases as the conductor radius is increased. Corona Corona

ƒ There is a certain definite loss associated with corona. ƒ The ionization current associated with corona flows in pulses only during the voltage peaks and is therefore rich in harmonics. ƒ Ozone is produced in corona and would cause deterioration to any organic materials nearby. ƒ Audible noise is produced in corona and hence is a source of noise pollution. Electrical Parameters

ƒ These are distributed parameters by nature:

» Series resistance r Ωm » Series inductance l H/m » Shunt capacitance c F/m » Shunt conductance g S/m

For overhead lines, shunt conductance represents leakage through insulators or corona loss and is usuallyyg ignored. Transmission Line Model Transmission line as a two-port

ƒ VS = sending end voltage

ƒ IS = sending end current

ƒ VR = receiiiving end volt age

ƒ IR = receiving end current

IS IR

VS Line VR Transmission parameters

VS = AVR + BIR

IS = CVR + DIR

IS IR

VS A, B, C, D VR Line Model

ƒ Nominal π representation (Medium line)

Z = R + jX IS I IR

VS YC/2 YC/2 VR Line Model

I = IR + VRY/2

VS = VR + ZI

= (()1+ZY/2)VR + ZIR

IS = I + VSY/2

= Y(1+ZY/4)V R + (1+ZY/2)I R Hence A = D = (1+ZY/2), B = Z, C = Y(()1+ZY/4) Line Model

ƒ Nominal T representation (Medium line)

(R + jX)/2 (R + jX)/2 IS V IR

VS YC VR Line Model

V = VR + IR Z/2

I = YV = YVR + IR YZ/2

IS = IR +I+ I = YV R +(1+YZ/2)I+ (1+YZ/2)IR

VS = V + ISZ/2

= (1+YZ/2)VR + Z(1+YZ/4)IR Hence A = D = (1+ZY/2), B = Y(1+ZY/4), CYC = Y. Line Model

ƒ Series impedance (Short line)

» VS = VR + ZIR;IS = IR

R + jX IS IR

VS VR Example

ƒ Given a 3 -phase, 132 kV line 350 km long with parameters r = 0 .108 ohm/km; l = 1 .37 mH/km; g = 0 siemens/km; c = 0.0085 μF/km. ƒ Load: 50 MVA at 0.8 power factor lagging.

ƒ To determine sending-end voltage, current and power factor. Example

ƒ Z = ((j0.108+j2π×50×1.37×10-3) × 350 =155.27∠75.91o Ω ƒ Y = (j2π×50×0.0085×10-6) × 350 = 934.6 ×10-6∠90o Siemens

ƒ VR = 132/√3 = 76.21 kV (phase) 3 ƒ IR = 50×10 /√3×132 = 218. 7 A ƒ θ = cos-1 0.8 = 36.87o (lagging) Example

Using short line representation

o ƒ IS = IR = 218.7∠-36.87 A

ƒ VS = VR + ZIR = 76.21+155.27∠75.91o × 0.2187∠-36.87o kV = 76.21+33.96 ∠39.04o = 104.8 ∠11.78o kV ƒ Input power factor = cos (11.78o + 36.87o ) = 0.66 (lagging) Example

Using nominal -π representation ƒ A = D =1+YZ/2 = 1 + 0 .0726 ∠165.91 o = 0.9297+j0.0176 = 0.9298 ∠1.08o ƒ B = Z = 155 .27 ∠75. 91o Ω ƒ C = Y(1+YZ/4) = j 934 .6 ×10-6(1 + 0 .0263 ∠165.91 o) = 910.8 ×10-6 ∠90.38o Example

ƒ VS = AVR + BIR = 0.9298 ∠1.08o × 76.21 ∠0o + 155.27∠75.91o × 0.2187∠-36.87o kV = 99.95 ∠13.15 o kV

ƒ IS = CVR + DIR = 910.8 ×10-6 ∠90.38 o × 76210 ∠0o + 0.9298 ∠1.08o × 218.7∠-36.87o = 171.78 ∠-16.75 o A ƒ Input power factor = cos (13.1 5o + 16.75o )086(li)) = 0.867 (lagging) Underground Cables

ƒ Cables contain one or more conductors within a protective sheath. ƒ The conductors are separated from each other and from the sheath by solid insulating material. ƒ The protective sheath is an impervious coveriiltidillfing over insulation and is usually of lead. Its main function is to prevent the ingress of moisture to the ins ulation . Underground Cables

ƒ They may be single-core cables with one cable per phase or three-core cables with one co mmo n lead s heat h. ƒ In single-core cables the stranded conductor is always of round cross-section. ƒ In multi-core cables so-called sector shaped strand s are al so used t o b ett er utili ze th e space within the sheath. Cable Insulations

Common insulating materials used in cables are: ƒ Oil-impregnated paper ƒ Vulcanised rubber ƒ synthetic polymeric dielectrics such as » polyethylene (PE), » propylene (PP), » polyvinyl chloride (PVC) Solid Cables

Single Core Three core

Hessian fillers servings Lead sheaths

Paper insulation

Stranded Fabraic conductors Belt tapes insulation Solid Cables

ƒ Single Conductor, paper -insulated power cable. Solid Cables

ƒ Three-conductor, belted, compact -sector, paper-insulated cable. Solid Cables

ƒ Three-conductor, shielded (H -type), compact-sector , paper-insulated cable. Solid Cables

ƒ Three-conductor solid-type cable with protective steel armour. Cable Parameters

ƒ Cables have the same distributed electrical parameters as the overhead lines but » Capacitance is much higher due to closer proximity of the conductors. » Sh unt l oss i s n o l on ger n egli gi bl e. th e sh unt loss in the dielectric include – leakage – dielectric hysteresis Dielectric loss angle

ƒ The dielectric loss is usually measured by the dielectric power factor dielectric p .f . = cos φ I ƒ The dielectric loss angle is δ = 90 – power flfactor angle φ δ ƒ Since δ is small φ δ≈sin δ = cos φ = dielectric p.f. V Cable Ratings

ƒ The current rating of a cable is limited by the maximum permissible temperature of its insulat io ns. ƒ Depending on the expected loading, we have the following ratings: » Continuous rating » Short time rating » Cyclic rating Cable Rating

The steady loading that results in a final temperature equal to the maximum permissible value is know n as the cont inuous rating. temp T current max T

Continuous rating I

time Cable Rating

If the loading is applied for a short duration only, say 1 hour, then the loading without the maximu m te mpe ratu re be ing e xceeded is known as the (1 hour) short-time rating. temp T current max

Short-time rating I T

time Cable Rating

For a given cyclic pattern, the maximum load that can be supplied without the maximum tempe ratu re be ing e xceeded is know n as t he cyclic rating. temp T current max T cyclic rating I

time Thermal equation

ƒ Heat Balance Equation Heat generated = heat dissipated +h+ heat ab sorb ed . Heat generated depends on power loss P in the cable (I 2RlR loss an ddild dielect tiric l oss) Heat dissipated depends on the surface area, method of cooling and temperature difference . Heat absorbed results in temperature increase depending on the specific heat . Thermal equation

Let P = power loss in cable λ = emissivity (watt/m 2/oC) A = surface area for heat dissipation (m2) θ = temperature rise above ambient ( oC) M = mass (kg) o Cp = specific heat (joule/kg/ C) Thermal equation

Then with temperature rise d θ in the time period dt, Heat generated =Pdt= P dt Heat dissipated = λAθ dt

Heat absorbed = MCp dθ Hence

MCp dθ + λAθ dt = P dt Thermal equation

This can be written in the form

τ(dθ/dt) + θ = θ∞ where τ = MCp/λA is the heating time constant.

θ∞ =P/= P/λA is the steady state temperature rise . The solution is -t/ τ θ(t) = θ∞ -(θ∞ - θ0)e where θ0 is the initial temperature rise above ambient at t = 0. Example

ƒ Heat run test of a transformer from cold » Temperature rise after 1 hr – 15o C » Temperature rise after 2 hr – 27o C

ƒ DtDeterm ine » Final temperature rise if run continuously » Heating time constant of transformer Example

From thermal heating equation -1/τ θ∞(1 – e ) = 15 (1) -2/τ θ∞(1 – e )27) = 27 (2) Dividing (2) by (1) (1 + e-1/τ) = 27/15 = 1.8 e-1/τ = 1.8 – 1 = 0.8 -1/τ ∴θ∞ = 15/(1 – e ) = 75 τ = -1/ln(0.8) = 4 .48 Overhead line vs Underground cables

ƒ Cost » Underground cables cost, on average, 8~15 times more than overhead lines. ƒ Operation » Charging current for underground cables is much higher than that of overhead lines and can use up a ltlot of fth the current carryi ng capacit y. The situation gets worse as the voltage increases. Overhead line vs Underground cables

ƒ Reliability » Overhead lines have more outages than underggpg,round cables per unit length, but the outages are usually shorter in duration. ƒ Flex ibilitibility » Overhead lines can be upgraded to higher voltages if necessary. U nd erground cabl es cannot be easily upgraded. Overhead line vs Underground cables

ƒ Safety » Underground cables are more safe and are alwayyypps used in densely populated areas for this reason alone. ƒ Envvoironme nt » Overhead Line Towers (aesthetic problem) » EM Field under overhead lines (effect on human beings) » Corona (radio interference, noise pollution etc)