Motion under gravity and forces

AI Thread Summary
A body falling under gravity experiences a downward force equal to its weight (mg). If an upward force equal to mg is applied, the net force becomes zero, and the body continues to fall. To freeze the body in midair, the applied force must equal mg, but once the body stops, the force must decrease to mg to maintain rest. An upward force greater than mg will cause the body to accelerate upwards, slowing down until it stops and then reverses direction. The magnitude of the applied force directly influences the body's acceleration and motion.
D. Wani
Messages
26
Reaction score
0
If a body is falling downward under the effect of gravity(=mg) and someone applies a force(=mg) in the opposite direction (upward), then the body will continue moving downwards as the net force is zero. What would be the magnitude of the force applied such that the body would freeze in midair(if possible) and what would be the magnitude of the force applied such that the body would start moving upwards?
 
Physics news on Phys.org
Those are not fixed force values. Force determines acceleration, not speed. If the acceleration is upwards, the body will get slower over time, stop, and then start moving upwards. The timescale depends on the force. To keep it at rest, the force has to drop to mg once the object stops.
 
Thank you
 

Thread '1:1 versus 2:1 Mechanical Advantage debate'

The rope is tied into the person (the load of 200 pounds) and the rope goes up from the person to a fixed pulley and back down to his hands. He hauls the rope to suspend himself in the air. What is the mechanical advantage of the system? The person will indeed only have to lift half of his body weight (roughly 100 pounds) because he now lessened the load by that same amount. This APPEARS to be a 2:1 because he can hold himself with half the force, but my question is: is that mechanical...
View full post »

Thread 'Newton's first law?'

Some physics textbook writer told me that Newton's first law applies only on bodies that feel no interactions at all. He said that if a body is on rest or moves in constant velocity, there is no external force acting on it. But I have heard another form of the law that says the net force acting on a body must be zero. This means there is interactions involved after all. So which one is correct?
View full post »
Thread 'Beam on an inclined plane'

Thread 'Beam on an inclined plane'

Hello! I have a question regarding a beam on an inclined plane. I was considering a beam resting on two supports attached to an inclined plane. I was almost sure that the lower support must be more loaded. My imagination about this problem is shown in the picture below. Here is how I wrote the condition of equilibrium forces: $$ \begin{cases} F_{g\parallel}=F_{t1}+F_{t2}, \\ F_{g\perp}=F_{r1}+F_{r2} \end{cases}. $$ On the other hand...
View full post »

Similar threads

B Why doesn't a body accelerate upward when a force is applied?
Replies
7
Views
1K
B Newton's Third Law in space
Replies
20
Views
2K
B Newton's 3rd Law interactions with 2nd and 1st Law Partners
Replies
8
Views
2K
Spring on a mass that is held back
Replies
1
Views
1K
I Why can centripetal force balance out gravity?
Replies
23
Views
3K
B Box being pulled up a slope with friction
Replies
3
Views
1K
B How do mechanical (weighing) scales work?
Replies
9
Views
3K
What is the free-body diagram for a massless pulley in free fall?
Replies
31
Views
4K
Laws of motion while climbing a Rope
Replies
8
Views
6K
B Confusion while trying to build intuition of centripetal force
Replies
15
Views
3K

Hot Threads

Recent Insights

Back
Top