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Common copper wire sizes and resistance
Resistance of other materials compared
to copper
Voltage drop on long cables. The length of our cable from the supply ( windmill ) to the load ( batteries ) can have a big impact on the power generated. All wire has a resistance, and any resistance is a loss, so we need to reduce this loss to a minium. But just how much is lost?
Say our windmill is supplying 20 amps of power, and we have a 12 volt battery under charge. We have a power cable from our windmill to our battery of 100 meters, and the cable size is 6 AWG. Using the cable cross reference here, we know that 6 AWG wire ( 4.1mm or 0.16inches diameter ) has a resistance of 1.3 ohms per 1km, or 0.13 ohm for our 100m length. Now there are two wires + and -, so we double that to get 0.26 ohms. So if the windmill is supplying 20 amps, using ohms law ( here ) we calcualte 20 amps over our 0.26 ohm cable equals 5.2 volts lost in the cable. To work out how many watts is lost in the cable, we use watts = volts * amps, so 5.2 volts * 20 amps = 104 watts. As our battery is 12 volts, its using 12 volts * 20 amps = 240 watts. So our windmill is making 104watts + 240watts = 344 watts, 104 watts of which is wasted in the cable. If we increase our wire size to 4 AWG, our total cable resistance drops to 0.16 ohms (0.83 ohms per 100m, times 2). This works out to 3.2 volts lost in the cable, or 64 watts wasted. |
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per 1000' **