'First, let's figure out how much power does a 747 needs to takeoff:
Assume:
Engine thrust = 284 kN Takeoff speed = 170 knots
Takeoff power = 90% max power

Using P=Fv
, converting the variables to SI units, we get
Power=88,948,800W
Or, in other words, around 90MW'

That's just to get off the ground

The Chair, Those Tesla figures are are a bit misleading, they claim a range of 120 miles but that's with new batteries (£5,000 each)older Teslas are getting much less and cars developed in California where the sun always shines will not stand up to the British winters, try heating them from the battery and see what effect it has on the range

'Let us take this a step further and evaluate the total energy needed for a flight. Assume all required energy comes from onboard energy storage (i.e. no solar panels / windmills). Let's also assume a full power climb to cruise altitude of 15 minutes, 50% power cruise for 4 hours, and a completely idle descent which does not consume any power at all.

Using E=∫Pdt
, we get the total energy needed for a flight is
720,485,280,000J

.

With that amount of energy, you can pull a 735 kiloton object up 100m. If all those weights are water, that's close to 300 Olympic swimming pools.

If you power the whole plane with batteries, you'd need 47 million AA batteries.'

I don't vouch for the stats, I just quote them :0) What do you say jim?

NJ. It would be easy if one had a long dangling lead to an electric source on the ground, but an aircraft would need to store it's electricity on board in the form of batteries. Everyone keeps hoping for a major breakthrough but considering battery powered vehicles have been around since the 18 hundreds it really isn't happening.

What is worrying is that governments are starting to formulate legislation for the future, on the assumption the science will find an answer.