If it is 0.6m (long?) then how can it be 2 m high? Also, if friction is involved, this will affect the amount of force.
Divide the height of the ramp by the length of the ramp (rise over run).
At the bottom of the ramp, the higher the ramp the faster the speed, ignoring frictionl forces The speed varies as the square root of the height
The long ramp.
-- angle the ramp makes with the ground -- weight of the piano -- height above ground at the top of the ramp -- horizontal distance between the beginning and end of the ramp If the question included any one of these pieces of information, an answer could be calculated. But with only the information given, it can't be.
Changing the slope of the ramp will affect the speed of the vehicle going down it.
More force will be required to push an object along the ramp.
The input force would increase as the height of the ramp increased. It wouldn't matter the distance. Ask me another one.
The input force would increase as the height of the ramp increased. It wouldn't matter the distance. Ask me another one.
The height.=====================Answer #2:The mechanical advantage.
Centripetal force is always changing as it is a direct result as a change in velocity. This can be experienced when you drive in your car and go on an off or on ramp. You feel as though you are being pushed sideways.
The input force would increase as the height of the ramp increased. It wouldn't matter the distance. Ask me another one.
It depends on the mass of the box, the force exerted, the total displacement and the height the box was moved.
The effort needed would increase.
You would need to know the length and height of the ramp.
No. Mechanical advantage of a ramp is the ratio of base to height. That is fixed. Using a ramp on the Moon would result in less force being required in that same ratio, although the total force would be about 0.165 that of Earth because of the Moon's smaller gravity. Explained another way... If you have a 10:1 ramp that allows you to only need 10 N of force to lift a 100 N load on Earth, then that same ramp and same load on the Moon would require 1.65 N, but the object would also be only 16.5 N to start with.
how does increasing the height of a ramp affect how far a ball rolls down the ramp
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