|
|
|
|
|
|
by yboris
2162 days ago
|
|
|
Thank you for the response. My thought is that the weight of the flywheel matters. To be able to absorb / release a tremendous amount of power, I imagine this flywheel would need to be very heavy. If so, wouldn't it non-linearly differ in efficiency from the near vacuum & magnetic bearing designs we've built before? Perhaps the proposal is to build a large array of smaller flywheels that don't have to deal with the problem I imagine? I'm not familiar with any part of engineering here -- just a curious soul -- sincerely asking! |
|
|
With flywheels, I don't see the bearings as difficult. I mean it's sure a challenge to keep a few tons afloat, but nothing unsolved. I'd assume (but don't know) that you can scale magnetic bearings a few orders of magnitude with their properties staying the same.
On the other hand, the faster you spin flywheels, the more energy they store. And here comes the limitation: The material they're made of has to sustain all tearing force. So at some point you'll add mass instead of spinning faster.