A: It does not loose its strenght it just becomes less due to the resistances or impedance's along the way.
Power is basically voltage times current. The power lines have resistance and that causes a loss of some power in transmitting the power over long lines. When the power is sent at a higher voltage, the current is lower, which means that the power lost in the wires is less. A rule of thumb for power transmission is to use 1000 volt per kilometre so for a 33 km line you would use 33 kV.
This was due to the results of the War of the Currents between Edison, who supported DC and Tesla for AC power distribution. Although most electronics you find today run off DC power, the transmission of DC power over long distances is not very efficient and requires several substations between the power transmission source and where it is received. AC power after stepped up can be transmission over long distances with little energy loss. The energy loss occurs from heat generated from resistance within the transmission wire. At the introduction of Edison's system, there was no practical AC motor available. It was primary due to the introduction of the 3 phase AC motor did AC finally win over DC.
Step-up Transformers used in the transmission of electrical energy increase the voltage going over Transmission Lines (over 100,000 Volts). For a given amount of POWER to be Transmitted, the higher the Voltage, the LOWER the CURRENT. This reduces the amount of Power LOST to the Resistance of the Transmission Lines. Power Lost is calculated by the Formula: POWER Lost = I2 x R, where I=Current and R=Resistance So, the lower the Current (I), the lower the transmission line losses. At the end of the Transmission Path the Voltage is "Stepped Down" to a value usable for the Customer, usually (220 volts for Residential use in the USA).
The heating losses in a conductor of resistance R, with current I, are I2 x R. So if you are transmitting power, it is always best to keep the current as low as possible, and this is done by making the voltage high. To keep the size of the wires reasonable, both because of cost and weight, voltage is stepped up to hundreds of kilovolts. I'm not sure what US practice is, but in the UK long distance lines run at 400 KV. This requires large step up transformers at the power station and at the other end, to step voltage down to useable levels.
Step up Transformers. To transport the electricity from the power generating plant over long distances you step up the voltage using transformers to reduce line / cable losses. When you step up the voltage at the same time you lower the current for the same power. The line loss is due in major part to the cables resistance, more current the more heat generated and lost in the cable itself. It's all basic OHMS law.
Because wires are not perfect conductors, energy is released as heat. This is why electricity is transmitted at very high voltage and low current to reduce energy loss.
the signal goes out of sink due to refraction
Although N. Tesla invented many things, probably the most important invention was the alternating current (AC) motor. This allowed the world to use AC generating and transmission lines to transmit electricity over great distances with little power loss. Direct current cannot be generated or transmitted over long distances without great losses due to resistance.
AC voltages can be raise by transformers and transported over long distances without great power losses then converted back to lower household voltages by transfomers for our use.
The long distances and mud disrupting logistical resupply
Power is basically voltage times current. The power lines have resistance and that causes a loss of some power in transmitting the power over long lines. When the power is sent at a higher voltage, the current is lower, which means that the power lost in the wires is less. A rule of thumb for power transmission is to use 1000 volt per kilometre so for a 33 km line you would use 33 kV.
Yes it can. Large amounts of power are regularly transmitted by dc over long distances, or between adjacent countries like the UK and France whose grid systems are not synchronised with each other.
Electrical generators work at about 11,000 volts which is not enough to transmit power over long distances over about 5 miles. Therefore step-up Transformers are used to connect them to the local grid on 132 kV or the supergrid on 275 or 400 kV (in the UK)
Yes
DC current isn't used in homes because after being transmitted a couple miles by cable, it loses it's strength. AC current can travel 100's of miles without losing any or little strength. This is because alternating current power can be stepped up in voltage (to several hundred THOUSAND volts), and proportionally stepped down in current, by way of transformers, which results in minimal power losses over long distances (not to mention MUCH smaller cable size requirements!). Once the destination is reached, the power is transformed back to low voltage for commercial and residential use. DC power cannot be transformed in this manner, which means that the required voltage and current for homes and industries must be carried the full distance from the power plant/power station. Larger power losses are the result of the transmission of higher current power over those distances. Additionally, since transmission cables must be sized to carry the maximum
he did it for communication advances by transporting power long distances
Short distances Medium distances and Long distances