long line modeling issues rev. 2.1 tss meeting january 20, 2011 r. peter mackin, p.e. draft
TRANSCRIPT
Long Line Modeling IssuesRev. 2.1
TSS Meeting
January 20, 2011
R. Peter Mackin, P.E.
DRAFT
• Basic Transmission Line Models • (from Stevenson, Elements of Power System
Analysis, 4th Edition)
• Short Transmission Line:– Up to 50 miles
Background
Z = R + jX
• Medium-length Transmission Line:– 50 miles to 150 miles
Background
Z = R + jXY2
Y2
• Long Transmission Line:– Greater than 150 miles– Lumped parameters cannot be used
accurately to represent these lines– Accurate representation requires the use of
hyperbolic functions
Background
Y tanh(γl/2)2 γl/2
Y’2
=
sinh(γl) γl
Z’ = ZY’2
The Issue
• For long transmission lines (greater than say 150 miles), using the per mile impedance times the line length in miles can result in an inaccurate representation of the transmission line.
• For these long lines, it is better to use the “long line” equations that involve hyperbolic functions to calculate the line impedance.
• A couple of examples that illustrate the problem are given below.
Example #1
• Assume a new 500 kV line with the following parameters– 200 miles long– Horizontal conductor configuration
• 32’ phase spacing, 35’ minimum clearance to ground
• 3 – 1780 ACSR 84/19 “Chukar” conductors per phase
• 18” triangular bundle
Example #1• The table below shows the impedances for this line calculated using either
the PowerWorld Transmission Line Parameter Calculator (TLPC) ver. 1.0 or Aspen Line Constants.
• The PowerWorld TLPC uses “Long Line” equations to calculate more accurate values of impedance and admittance for longer lines.
• Aspen Line Constants calculates a “per mile” impedance and then multiplies this value by the line length in miles to determine the line impedance and admittance.
Source Line Length (mi.) Calculation R (p.u.) X (p.u.) B (p.u.) Comment
PowerWorld TLPC 1.0 200 Long Line Parameters 0.001540 0.041579 3.953540Aspen Line Constants 200 Per Mile Line Parameters 0.001468 0.042723 4.082248
PowerWorld TLPC 1.0 120 Long Line Parameters 0.000958 0.025397 2.350851PowerWorld TLPC 1.0 80 Long Line Parameters 0.000646 0.017026 1.562865
Total 0.001604 0.042423 3.913716Totals are NOT equal to 200 mile long line above
Aspen Line Constants 120 Per Mile Line Parameters 0.000881 0.025634 2.449349Aspen Line Constants 80 Per Mile Line Parameters 0.000587 0.017089 1.632899
Total 0.001468 0.042723 4.082248Totals are equal to 200 mile long line above
Example #1• The example below shows the effects of the different impedance
assumptions on the flow on this hypothetical line.• The first power flow plot shows the flows on the line when using the
“long line” impedance and admittance.• The second power flow plot shows the flows on the line in the first
plot when a new bus is added 60% of the total line distance from TESTBUS1.
• The third power flow plot shows the flows on the line when using inaccurate “per mile” impedance and admittance method used by Aspen Line Constants.
• The fourth power flow plot shows the flows on the line in the third plot when a new bus is added 60% of the total line distance from TESTBUS1.
Example #1
• This power flow plot shows the flows on the line when using the “long line” impedance and admittance.
Long Line Parameters
• This power flow plot shows the flows on the line in the first plot when a new bus is added 60% of the total line distance from TESTBUS1.
Long Line Parameters
Example #1
Per Mile Line Parameters
• This power flow plot shows the flows on the line when using inaccurate “per mile” impedance and admittance method used by Aspen Line Constants.
Example #1
• This power flow plot shows the flows on the line in the third plot when a new bus is added 60% of the total line distance from TESTBUS1.
Per Mile Line Parameters
Example #1
Example #1 Conclusions
• As shown, “long line” impedance and admittance values provide the most accurate results for long lines. This conclusion can be observed by noting that the line flows before and after adding an intermediate bus to a line are almost exactly the same.
• Using “per mile” impedance and admittance values are not as accurate. This fact is demonstrated by the addition of an intermediate bus to the line using these parameters. As shown in the third and fourth power flow plots, the flow on the line is not the same in both cases (even though it should be).
Example #2• The first power flow plot shows the line flows on a 200 mile long 500 kV
line that is modeled as 5 series pi sections of 40 miles each.• The second power flow plot shows the line flows on a 200 mile long 500
kV line that is correctly modeled as 1 long line compensated segment (i.e., using PowerWorld Transcalc).
• The third power flow plot shows the line flows on a 200 mile long 500 kV line modeled as 1 Pi segment (incorrectly modeled using per mile impedances times line length in miles).
• The fourth power flow plot shows the line flows on a 200 mile long 500 kV line that was originally modeled using long line compensated impedances (Example #2, Plot #2), but is now split into two equal segments without recalculating the segment impedances. (This example is different than Example #1 in that the long line compensated impedances were simply divided in half. In example #1 the long line impedances were recalculated when adding the intermediate bus.)
200 Miles of 500 kV line modeled as 5
series Pi sections of 40 Miles each
The first power flow plot shows the line flows on a 200 mile long 500 kV line that is modeled as 5 series pi sections of 40 miles each.
200 Miles of 500 kV line modeled as 1
long-line compensated
segment
The second power flow plot shows the line flows on a 200 mile long 500 kV line that is correctly modeled as 1 long line compensated segment (i.e., using PowerWorld Transcalc).
200 Miles of 500 kV line modeled as 1 Pi segment (Incorrectly
Modeled)
The third power flow plot shows the line flows on a 200 mile long 500 kV line modeled as 1 Pi segment (incorrectly modeled using per mile impedances times line length in miles).
200 Miles of 500 kV line split into two segments without
recalculating the long line impedances
The fourth power flow plot shows the line flows on a 200 mile long 500 kV line that was originally modeled using long line compensated impedances (Example #2, Plot #2), but is now split into two equal segments without recalculating the segment impedances. (This example is different than Example #1 in that the long line compensated impedances were simply divided in half. In example #1 the long line impedances were recalculated when adding the intermediate bus.)
Example #2 Conclusions• GE PSLF properly corrects impedances for long lines if the line is
split into multiple short segments (compare Plots #1 and #2).• Incorrectly modeling a long line using per mile impedances times
line length in miles results in slightly different (and incorrect) flows on the modeled line.
• If you add an intermediate bus to a long line, you must recalculate the new line impedances. You cannot just multiply the impedances by the ratio of the distance to the next bus divided by the total line length. This conclusion applies whether the original impedance was calculated using long line compensated impedances or “per mile” impedances.