It depends on the value of voltage being applied to the wire in normal use. Voltages up to 750 volts can be used on wires reading as low as .5 meg ohms. Engineers like to see 5 meg ohms on conductor readings.
The resistance of a conductor is directly proportional to the resistivity of the conductor. since the resistivity of a conductor is decreases with decrease in temperature hence the resistance.
The resistance of a conductor is directly proportional to its length, hence increasing the length twice will increase the resistance twice as well. Therefore the resistance will be 2*10 = 20 Ohms
Purely additive. 2+3+4+5+6=20.
I = V/R 5 volts / 2600 ohms = .00192 or round to .002.
It depends on the value of voltage being applied to the wire in normal use. Voltages up to 750 volts can be used on wires reading as low as .5 meg ohms. Engineers like to see 5 meg ohms on conductor readings.
V/I = R --> R = 2 ohms.
The resistance of a conductor is directly proportional to the resistivity of the conductor. since the resistivity of a conductor is decreases with decrease in temperature hence the resistance.
4
This depends, you have amperage which is how much pressure of electricity is being pushed through the conductor. Next is what kind of conductor, the matters because of ohms, which is how much resistance is caused by the conductor
5 ohms
The resistance of a conductor is directly proportional to its length, hence increasing the length twice will increase the resistance twice as well. Therefore the resistance will be 2*10 = 20 Ohms
red = 2violet = 7silver = 0.01gold = 5%The value is 27 * 0.01 ohms 5% or 0.27 ohms 5%
Purely additive. 2+3+4+5+6=20.
Purely additive. 2+3+4+5+6=20.
5 ohms
0.0547 ohms/km - maximum DC resistance at 20'C. Britsh Standards.