Unit 5
Capacitance of Transmission Line
- Explain the electric potential of single charged conductor?
Consider long straight cylindrical conductor A of radius r metres. Let the conductor operate at such a potential (VA) that charge QA coulombs per metre exists on the conductor. It is desired to find the expression for VA. The electric intensity E at a distance x from the centre of the conductor in air is given by:
E = QA/ 2π x volts/m
QA= charge per metre length
= permittivity of free space
As x approaches infinity, the value of E approaches zero. Therefore, the potential difference between conductor A and infinity distant neutral plane is given by :
VA = / 2π x dx = QA/ / 2π
2. Explain Potential at conductor in a group of charged conductors?
Consider a group of long straight conductors A, B, C etc. operating at potentials such that charges QA, QB, Qc etc. coulomb per metre length exist on the respective conductors
Let us find the potential at A VA in this arrangement.
Potential at A due to, its own charge (i.e. QA)
= A/ 2π x dx ---------------------------------(i)
Potential at conductor A due to charge QB
B/ 2π x dx ---------------------------------------(ii)
Potential at conductor A due to charge Qc.
/ 2π x dx --------------------------------------(iii)
Overall potential difference between conductor A and infinite neutral plane is
VA = (i) +(ii) +(iii)
= A/ 2π x dx + B/ 2π x dx + / 2π x dx
= 1/ 2π [ QA( log e ∞ - log e r) + QB( log e ∞ - log e d1) + Qc(log e ∞ - log e d2) +………………………]
= 1/ 2π [ QA log e 1/r + QB log e1/d1 + Qc log e 1/d2+ log e (QA+QB+QC) +……..]
3. Explain capacitance of single phase ?
Consider the single-phase line consisting of two round conductors as shown in Figure. The separation between the conductors is D .
Let us assume that conductor 1 carries a charge of q1 C/m while conductor 2 carries a charge q2 C/m. The presence of the second conductor and the ground will disturb field of the first conductor. However we assume that the distance of separation between the conductors is much larger compared to the radius of the conductor and the height of the conductor is much larger than D for the ground to disturb the flux.
Therefore, the distortion is small and the charge is uniformly distributed on the surface of the conductor.
Assuming that the conductor 1 alone has the charge q1 , the voltage between the conductors is
V12(q1) = q1/ 2 π o ln D / r1 ---------------------------------------------------------(1)
Similarly if the conductor 2 alone has the charge q2 , the voltage between the conductors is
V21(q2) = q2/ 2 π o ln D / r2
The above equation implies that
V12 (q2) = q2/ / 2 π o ln r2/D --------------------------------------------------(2)
From the principle of superposition we can write
V12 = V12(q1)+V12(q2) = q1/ 2 π o ln D / r1 + q2/ / 2 π o ln r2/D ------------(3)
For a single-phase line let us assume that q1 (= -q2 ) is equal to q . We therefore have
V12 = q/ 2 π o ln D / r1 - q/ / 2 π o ln r2/D = q/ 2 π o ln D 2 / r1 r2 -------------(4)
Assuming r1 = r2= r3, we can rewrite (4) as
V12 = = q/ π o ln D / r ----------------------------------------------------(5)
Therefore the capacitance between the conductors is given by
C12 = π o ln D / r F/m -----------------------------------------------------(6)
The above equation gives the capacitance between two conductors.
For the purpose of transmission line modeling, the capacitance is defined between the conductor and neutral. This is shown in Figure. Therefore, the value of the capacitance is given from Figure as
C=2C12 =2 π o/ ln (D / r) F/m ------------------------------------------------(7)
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Fig (a) Capacitance between two conductors (b) Equivalent capacitance to ground
4. Explain the Capacitance of single phase line with effect of earth’s surface on electric field .
Assume conductors A’ and B’ as image conductors of conductors A and B respectively, as shown in Figure. Let the height of conductors be h metres above the earth and charge of +q coulombs per metre length and -q coulombs per metre length on the conductors A and B respectively.
Fig. Single phase transmission lines
The equation for the voltage drop VAB as determined by two charged conductors A and B and their images A’ and B’ may be written as follows:
VAB = 1/ 2π [ qa log e d/r + qb log e r/d + qa’ log e √4h2 + d2 / 2h + qb’ log e 2h/ √4h2 + d2 ] ----------------------------------------------------(8)
Substituting qA = q’B = + q and q’A = qB = -q we have,
VAB = q/ π log e 2hd/ r √ 4h2 + d2
Capacitance between conductors A and B,
CAB = q/VAB = π / log e d/ r√ 1+ d2/4h2 -----------------------(9)
The above expression for capacitance reveals that the presence of earth modifies the radius of conductor r to r √ ( 1 + d2 / 4 h2 )
The effect of earth on the capacitance of the system is to increase it. However, normally the distance of separation between the conductors is much smaller than the height of the conductor from the ground, therefore, r √ ( 1 + d2 / 4 h2 ) ≈ r and for all practical purposes the effect of earth on line capacitance can be neglected.
5. Explain the concept of GMD?
Let us assume two composite conductors used in Transmission Line as shown in figure below.
Figure . Composite conductors
As shown in the figure above, one conductor is Go and another is Return for current for single phase line. The current is assumed to be equally divided among all the strands of a conductor.
Therefore,
Current carried by each strand in Go conductor = I/n
Current carried by each strand in Return conductor = -I/m
Here I is the total current carried by each conductor.
To calculate the GMD and GMR for the configuration of the conductors shown in figure above.
For getting the GMD, first we need to calculate the distance between the strands of Go and Return conductors.
Let,
D11 = Distance between the 1ststrand of Go and Return conductor
D12 = Distance between the 1ststrand of Go and 2nd strand of Return conductor
D21 = Distance between the 2nd strand of Go and 1st strand of Return conductor
Dmn = Distance between the mthstrand of Go and nth strand of Return conductor
Thus, the geometrical mean of above distances that is GMD
= mn √ (D11D12…….D1m)(D21 D22….D2m) (D31 D32….D3m) …..(Dn1Dn2…Dnm)
6. Explain the concept of GMR?
Geometrical Mean Radius of a solid conductor or a strand of radius R is defined as the factious radius R’ having no internal flux linkage but having the same inductance as the original conductor of radius R.
R ‘ = 0.7788R
Method for Calculating GMR of a Composite Conductor :
For calculating GMR, first we find the distance between the individual strands. Thus, if there are n strands in a composite conductor then obviously there will be n2 distances between the strands.
Thus GMR of Go conductor
= n2 √ (R’ D12 D13…..D1n) (R’D21 D22 D23 ….D2n) …..(R’Dn1Dn2….D(n-1)n)
7. Explain GMR with example?
As shown in figure below, go conductor contain three strands of radius 2.5 mm while the return conductor contains two of radius 5mm.
Figure. Conductor strands
GMR of individual strands in Go conductor R’ = 0.7788xR
= 0.7788×2.5
= 1.947mm
GMR of Go Conductor
= [(1.947x6x12)(1.947x6x6)(1.947x6x12)]1/9
= 0.4809m
Similarly,
GMR of individual strands in Return conductor R’ = 0.7788xR
= 0.7788×5 mm
= 0.003894 m
Hence, GMR of Return Conductor
= [(0.003894×6)(0.003894×6)]1/4
= 0.1528 m
Now, distance between strand a and e Dae = [92+62]1/2
= 10.81 m
Distance between strand c and d, Dcd = [92+122]1/2
= 15 m
Therefore,
GMD for the configuration,
= [9×10.81×10.81x9x15x10.81]1/6
= 10.74 m
8. Explain the Capacitance of three phase line unsymmetrical spacing with transposition?
Figure shows the three identical conductors of radius r of Capacitance of Three Phase Line Unsymmetrical Spacing.
It is assumed that the line is fully transposed. As the conductors are rotated cyclically in the three sections of the transposition cycle, correspondingly three expressions can be written for Vab. These expressions are:
For the first section of the transposition cycle
Vab = 1/ 2 πk (qa1 ln D12/r + qb1 ln r/ D12 + qc1 ln D23/ D31 )--------(a)
Figure. Cross section of three phase line with asymmetrical spacing (fully transposed)
For the second section of the transposition cycle
Vab = 1/ 2πk (qa2 ln D23/r + qb2 ln r/D23 + qc2 ln D31/D12) -----------(b)
For the third section of the transposition cycle
Vab = 1/ 2 πk (qa3 ln D1/r + qb3 ln r/ D31 + qc3 ln D12/D23) -----------------(c)
If the voltage drop along the line is neglected, Vab is the same in each transposition cycle. On similar lines three such equations can be written for Vbc = Vab ∠ –120°. Three more equations can be written equating to zero the summation of all line charges in each section of the transposition cycle.
From these nine (independent) equations, it is possible to determine the nine unknown charges.
With the usual spacing of conductor’s sufficient accuracy is obtained by assuming
Qa1 =qa2=qa3=qa; qb1=qb2=qb3=qb; qc1=qc2=qc3=qc
This assumption of equal charge/unit length of a line in the three sections of the transposition cycle requires, on the other hand, three different values of Vab designated as Vab1, Vab2 and Vab3 in the three sections. The solution can be considerably simplified by taking Vab as the average of these three voltages, i.e.
Vab (avg) = 1/3 (Vab1 + Vab2 + Vab3)
Vab = 1/ 6πk[ qa ln (D12 D23 D31/ r3 ) + qb ln ( r3 / D12 D23 D31) + qc ln ( D12 D23 D31/ D12 D23 D31)]
= ½ πk(qa ln Deq/r + qb ln r/ Deq) ------------------------------------(1)
Deq = (D12D23D31) 1/3
Vac = 1/ 2 π k ( qa ln Deq/r + qc ln r/ Deq) -----------------------------(2)
Adding Eqs. (1) and (2), we get
Vab + Vac = 1/ 2 π k ( qa ln Deq/r + (qb+qc) ln r/ Deq)-------------(3)
For balanced three-phase voltages
Vab + Vac = 3 Van
(qb +qc) = -qa
Use of these relationships in Eq. (3) leads to
Van = qa / 2 π k ln Deq/r -------------------------------------------------------(4)
The capacitance of line to neutral of the transposed line is then given by
Cn = qa / Van = 2 π k/ ln (Deq/r)------------------------------- (4a)
For air medium (kr = 1)
Cn = 0.0242 / log (Deq/r) μ F/km to neutral
It is obvious that for equilateral spacing Deq = D, the above (approximate) formula gives the exact result .
The line charging current for a three-phase line in phasor form is
Ia (line charging) = jw Cn Van A/km
9. Explain the Need for transposition for capacitance solutions?
The basic definition for transposition of transmission line is to rotate the conductors which result in the conductor or a phase being moved to next physical location in a regular sequence. In electrical power transmission lines, the conductor arranges unequal space. So, the voltage drops are not same as one place to another.
To eliminate this effect, we can simply do by interchange the conductor position which is known as transposition. The transposition arrangement is necessary when there is a capacitance between the power conductor.
10. Explain the double circuit asymmetrical spacing?
Consider the arrangement shown in figure. It consists of three phase double circuit. The radius of each conductor r. The voltage between the phases a and b can be calculated in order to calculate capacitance. One complete cycle of transposition is shown in figure.
Figure 11. Double circuit
Vab1 = 1/ 2 π { qa ( ln D/r + ln m/n) + qb(ln r/D + ln h/m) + qc ( ln D/2D + ln m/h)}
Vab2 = 1/ 2 π { qa ( ln D/r + ln m/n) + qb(ln r/D + ln h/m) + qc ( ln D/2D + ln m/h)}
Vab3 = 1/ 2 π { qa ( ln 2D/r + ln h/n) + qb(ln r/2D + ln n/h) + qc ( ln D/D + ln m/m)}
Vab = 1/3 { Vab1 + Vab2 + Vab3}
= 1/6π{ qa(ln 2D3 / r3 + ln m2h/n2h ) + qb(ln r3 / 2D3 + ln n2h / m2 h) + qc( ln 2D3/2D3 + ln m2h/m2h)}
Vab = 1/6π{ qa(ln 2D3 m2/ r3 n2+ ln m2h/n2h ) + qb(ln r3 n2/ 2D3m2 )
Similiarly we have
Vab1 = 1/ 2 π { qa (ln D/
Vac = 1/6 { qa ln 2 D3 m 2 / r3 n2 + qc ln r3 n3 / 2 D 3 m 2 }
We have Vab Vac= 3 Van
3 Van = 1/6 π{ 3 qa ln 2 D3 m2 / r3 n2 }
Van = 1/6 {qa ln 2 D3 m2 / r3 n2 }
Can = qa/Van = 6 / ln 2D3 m2 / r n2
Can = 2π / ln { 2 1/3 (D/r) (m/n) 2/3 }