wire sizing issues

BB. wrote: »

Shawn, I will give it a shot--But this is something you may need to talk with a well person/licensed electrician (familiar with well installations) about.

First, the needs of the motor. AC power is actually quite complex in its application to induction motors (vector math, inductors/capacitors, etc.). But the basics work out like this.

• 2 HP * ~746 Watts per HP = 1,492 Watts of power

You have said that it actually takes ~2,000 Watts (at full power) to run the pump. Or, its electrical efficiency is:

• 1,492 Watts / 2,000 Watts = 0.746 ~ 75% efficiency (seems reasonable).

So, you need more power/current to run the pump due to motor losses.

Next, is another set of "losses". With AC power, the Voltage Sine Wave is not always "in phase" with the Current Sine Wave... For induction motors, the current wave "lags" the voltage sine wave... The end result is that the motor "Takes more current" to run than you would expect from the "simple" power equation:

• 2,000 Watts / 240 VAC = 8.33 Amps (@ 240 VAC).

In reality, because the current lags the voltage wave form, the motor needs more current to operated at rated output power (this is sort of like pulling a car with a rope--You stand in front, all of your pull moves the car forward. Stand 45 degress to the side, and only ~71% of your "pulling force" is moving the car forward, the rest is trying to pull the car sideways).

For induction motors, this can be talked about as VA (Volt Amps) -- The amount of current and voltage needed to make the motor run at full output power--And you need to size the wiring, transformers, AC inverter, etc. to this required current flow.

For a typical induction motor, roughly the Cos (phase angle) = ~0.70 (~70% of the current is used to turn the motor, the other 30% is "wasted" doing nothing other than pulling more current in the wiring).

If you motor is a 2,000 Watt input, then its "VA" rating would be (roughly):

• 2,000 Watts / 0.70 = 2,857 VA

And the current draw would be:

• 2,857 VA / 240 VAC = 11.9 Amps

So--All the wiring/breakers would need to be sized to supply 11.9 amps continuously (more complicated than that, there is starting surge of 7,500 Watts -- Really probably 7,500 VA).

Now, lets say you want a 3% maximum voltage drop (240 VAC * 3% = 7.2 volt drop) when running (you may need to run 5% drop--We will see what the math looks like):

• 7.2 volt drop, 11.9 amps, 650 feet
• http://www.calculator.net/voltage-drop-calculator.html

6 AWG:
Voltage drop: 6.11
Voltage drop percentage: 2.55%
Voltage at the end: 233.89

So, a 650 foot 6 AWG copper cable wire run would seem to be a good starting point.

If you cannot fit 6 AWG down to the pump, perhaps you use a smaller AWG in the well, and a larger AWG from the house to the well.

In your cause 300 feet of 8 AWG in well:

Voltage drop: 4.49
Voltage drop percentage: 1.87%
Voltage at the end: 235.51

and that leaves 7.2 volts - 4.5 volt 8 awg drop = 2.7 volt drop for the 350 foot run:

4 AWG (350 foot from inverter to well):
Voltage drop: 2.07
Voltage drop percentage: 0.86%
Voltage at the end: 237.93

I have to go right now--But that is where I would start.

-Bill