I've been having a bit of trouble understanding the High-Voltage powerlines. If I was sending power from $A \rightarrow B$, we have:
Ohm's law $V = IR$
Power lost in the form of heat $P = I^2 R$
Power delivered to $B$ is $P = VI$
But using Ohm's law on the power lost formula, we get $P = V I$ also.
Does this mean that the total amount of power $A$ loses is $P_A = 2 VI$, and the total amount of power delivered to $B$ is just $P_B = VI$? Will transferring energy always result in half of it being lost?
Answer
The difficulty is that there are three voltages involved.
The voltage at the power station end $V_S$, the total voltage drop across the cables $V_L$ and the voltage at the consumer end $V_C$.
The voltages are related as follows.
$V_S=V_L+V_C$
So you have power supplied by power station is equal to the power lost in the transmission cables plus the power used by the customer.
$V_SI = V_L I+ V_CI$
So the power loss in the cables is $V_LI = RI\cdot I = I^2R$ where $R$ is the total resistance of the transmitting cables.
The reason for transmitting the power at high voltage is that then the current through the cables $I$ is less and so the ohmic loss $I^2R$ in the cables is considerably smaller.
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