Fc = mV^2/r
(2000 kg)(25 m/s)^2/(80 m)
= 15625 Newtons
32meters
=(mv*v)/r =(2000*25*25)\80 =15625N
80 meters. Since the only force on the car is centripetal force then:Fc = macac = v2/rFc = (mv2)/rSolve for rr = (mv2)/Fcr = (1200)(20)2/(6000)r = 80m(See my work in the link below.)
Force is given by Newton's second law: F = ma where F is the force, m is the mass and a is the acceleration. F=2000kg x (25 m/s)2 / 80 meters 15,625n
If the speed is constant, the acceleration is toward the center of the circle.
15,625 N
32meters
15,625 N
=(mv*v)/r =(2000*25*25)\80 =15625N
Ferris wheel goes around in uniform circular motion. The wheel traverses in a circular path at a constant speed and distance of the body from the axis of rotation is fixed as constant at all times. While the speed is constant, its velocity is not constant but changing. It is an example of centripetal force constant in magnitude acting towards the axis of rotation.
The type of circular motion on a Ferris wheel without stopping is an example of uniform circular motion. In this type of motion, the speed of the object remains constant, but its direction changes continuously, moving in a circle at a consistent rate.
No, If a car moves around a circular race track with any constant speed, the acceleration is directed towards the centre. So it has a centripetal acceleration. The tangential acceleration would be irrelevant unless the car has an instantaneous tangential velocity of zero. Then the centripetal acceleration is zero. However, this would only exist for that small instant in time.
Velocity constantly changes as so does the direction around a circle...
Tangential velocity squared is GMs/r and velocity v =29814m/s and the centripetal acceleration is v2/r= 5.928 E-3 m/s2
80 meters. Since the only force on the car is centripetal force then:Fc = macac = v2/rFc = (mv2)/rSolve for rr = (mv2)/Fcr = (1200)(20)2/(6000)r = 80m(See my work in the link below.)
Uniform circular motion is commonly observed in everyday situations such as a car moving around a roundabout or a satellite orbiting around Earth. It is also used in various engineering applications, including the design of amusement park rides, centrifuges in laboratories, and the operation of flywheels in mechanical systems. Understanding the principles of uniform circular motion is essential in fields such as physics, engineering, and astronomy.
GRAVITY!A2. Centripetal force. The velocity of the satellite around the earth causes centripetal, force which balances with the gravity, holding it in a circular orbit around the earth.