Electronic – High voltage three phase transmission lines

Any help would be appreciated

You can measure phase-neutral voltage and if the supply and load are balanced then you can infer line voltage by: -

line volts = phase volts\$\times\sqrt3\$

This should be one of the easier measurements yet you say you can calculate "real power, reactive power and apparent with ease". This does make me think that you have used one of these measurements, and the RMS measurement of current and back-calculated phase/line voltage and that's when you are seeing a discrepency.

If this is so then I suspect your current measurement may be at fault either through incorrect use of a current transformer or some ratio being incorrect. Or, it could be the \$\sqrt3\$ thing mentioned above.

If you need any further help with this you should consider detailing how you make the other measurements and why you believe voltage to be incorrectly calculated/measured.

As the generator gives balanced 3-phase, you can use three large same resistors witch give you the neutral point and then find the frequency from neutral point and one of phases.

^{simulate this circuit – Schematic created using CircuitLab}

In the previous schematic we divided the \$100M\Omega\$ resistor into \$3M\Omega\$ and \$97M\Omega\$ to reduce the output voltage. By the generator's peak voltage (\$150V\$) the output on \$3M\Omega\$ voltage will have less than \$5V\$ peak and can be determined easily by an Op-Amp.

Another way:

Of course it is possible to find out frequency of generator from voltage of one line to another. For example from \$R\$ to \$S\$.

The waveform of \$R-S\$ voltage is like this:

This is the plot of \$f = Sin(x)-Sin(x-2 \pi / 3)\$ (Plotted by Fooplot). The period of f witch can be found by finding the \$f(x)=f(x + T)\$ is same as \$Sin(x)\$. So The frequency of generator is also can be determined by \$l-l\$ voltage. And a simple zero crossing detector can help to find the frequency.