How Do You Calculate the Electric Field from a Powerline?

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SUMMARY

This discussion focuses on calculating the electric field around a current-carrying wire with an AC voltage, represented as V = |V| e^{i ω t}. The electric field is radial from the wire, but ground effects must be considered for realistic calculations. The capacitance of high voltage power lines is not the primary source of losses; resistance is. The method of images is recommended for calculating electric fields, utilizing the formula Pij = (1/2πE0) ln(dij/Hij) and charge distribution Q = [P^-1]V to determine the field at any point.

PREREQUISITES
  • Understanding of AC voltage representation and angular frequency
  • Familiarity with electric field concepts and charge distribution
  • Knowledge of the method of images in electrostatics
  • Basic principles of power line resistance and capacitance
NEXT STEPS
  • Study the method of images in electrostatics for electric field calculations
  • Learn about the impact of resistance and capacitance in high voltage power lines
  • Explore the mathematical derivation of electric fields from voltage and charge distributions
  • Investigate real-world measurements of electric fields around power lines
USEFUL FOR

Electrical engineers, physicists, and students studying electromagnetism, particularly those interested in power line design and electric field calculations.

Nick89
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Hi,

How can I calculate the electric field from a powerline?

I need to calculate the electric field around a current carrying wire with an AC voltage. I don't know the current, I only know the voltage that is on the wire. For example, the voltage could be V = |V| e^{i \omega t} where \omega is ofcourse the angular frequency of the AC voltage.

Am I right that the direction will always be radial to the wire, regardless of the change in voltage over time?

Thanks.
 
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In simple terms the field is just radial form the wire.
If you need a more realistic answer you have to take into account the ground underneath the wire. The field will look like a capacitor between the ire and the ground below and a simple field extending into space everywhere else.

Capcitance losses to the ground are the major source of loss in high V transmission lines and is one of the reason for using high towers rather than burying cables.
 
I know the ground will disturb the field rather much, however I was trying to calculate the field in empty space first, and then try to compare it with measurements from real powerlines and explain the differences.

My question is still open, I still didn't figure out how to actually calculate the electric field on a wire if the only thing I know is the voltage. If I knew some sort of charge distribution it would be trivial but afaik this can't be derived from voltage only, right?

Come to think of it, I don't even know how to calculate it if the voltage is just constant...
 
Apologies but I have just seen this thread, being a newcomer to the forum

mgb_phys is in error-or, at least oversimplifying. the capacitance of a high voltage power line is definitely not the major source of losses. Resistance is. A line may be inductive or capacitive depending on its length and loading. Lines are high to reduce ground level fields and to give greater clearance at higher voltages.

As to calculation of the electric fields -given the voltages, positions and radii of the conductors it is a simple process to determine the charges and then the field. The method of images is used and while this is not exact as the ground is not a perfect conducting plane but the errors are negligible.

Matrix P has elements (see any power system (engineering) text.
Pij= (1/2piE0)*ln dij/Hij where dij is the distance between conductors i and j and Hij is the distance between conductor i and the image of conductor j
Q =[P^-1]V
Now given Q the field at any point can be found from the sum of fields due to individual line and image charges.
 

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