High fluid velocity passes the ball at the top. This creates low pressure at the top of the ball. Since there's higher pressure at the bottom than at the top of the ball, the ball levitates.
@dawance88 actually the high pressure is at the bottom, the air on the top is also at a slight higher pressure than atmosphere, but much less than at the bottom, so the ball lifts
@airlinerdude12 yea and in fact, if my understanding is good, the ball should be very slightly compressed around the rotation axis since the extra pressure is absent on the sides. But on the other hand the centrifugal force acts in the opposite direction. I wonder which is stronger
Does anybody know the song title ?
harry2harry2harry 1 year ago
sound name pls
d1fference1 1 year ago
Cool !
RockTheOcean4me 1 year ago
It's good to see female students participating in physics. Good role models
BuildingIntlBridges 2 years ago
Ok great job now can u tell us what it is?????
Darkwagz 2 years ago 2
High fluid velocity passes the ball at the top. This creates low pressure at the top of the ball. Since there's higher pressure at the bottom than at the top of the ball, the ball levitates.
dawance88 2 years ago
@dawance88 actually the high pressure is at the bottom, the air on the top is also at a slight higher pressure than atmosphere, but much less than at the bottom, so the ball lifts
Mendelevium146 1 year ago
@Mendelevium146
precisely
airlinerdude12 1 year ago
@airlinerdude12 yea and in fact, if my understanding is good, the ball should be very slightly compressed around the rotation axis since the extra pressure is absent on the sides. But on the other hand the centrifugal force acts in the opposite direction. I wonder which is stronger
Mendelevium146 1 year ago
@Mendelevium146
hey could you explain the magnus effect to me in plain english?
i need to know the exact effect on flying bullets
USMCM249gunner 11 months ago