How Long Must a Day Be for Weightlessness at the Equator?

AI Thread Summary
To achieve weightlessness at the equator, calculations indicate that a day would need to last approximately 84 minutes, based on the balance of gravitational and centrifugal forces. The formula used involves equating gravitational force to centrifugal force, leading to a velocity of 7920 m/s and a period of 5077 seconds. Participants in the discussion agree on this 84-minute figure, questioning the teacher's assertion of a five-minute duration. The apparent strength of gravity at the equator is expressed as g_a = g - rω² cos² φ, which confirms the longer duration needed for weightlessness. The conversation highlights a discrepancy in calculations and invites further clarification from the teacher.
madis
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Hello, this is my first post here :)
The question I'm having problem with follows: how long would one day have to be so that there would be weightlessness on the equator? (the teacher said that the correct anwser would be roughly 5 minutes)

Solving this by myself I couldn't reach any other conclusion than:
gravitational force = centrifugal force => mg=mvv/r => g=vv/r => vv=gr
(v-velocity of any point on the equator, r- radius of the Earth, 6,4 million meters)
which means that: v=7920m/s => T=2*pi*r/v=5077s=84 minutes

What did I leave out of the account?
 
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Welcome madis.

An equation of the apparent strength of gravity is:
g_a = g - r\omega^2 \cos^2 \phi
Where \phi is latitude (which would be zero at equator) and g_a is apparent force of gravity, which in your case would be zero. I can show the derivation if you like.
 
Thanks! Using this equation I still got 84 minutes for the solution so I guess this is the real right anwser...
 
Yes, I get around 85 mintues also. I would be interested in seeing how your teacher calculated the five minutes, if you could post it here please:biggrin:
 

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