A student weighing 667N rides a steadily rotating Ferris wheel (student sits upright). At the highest point , the magnitude of the normal force `vec(N)` on the student from the seat is 556 N. The magnitude of `vec(N)`, if the wheel's speed is doubled is

A circular motion addict of mass 80 kg rides a Ferris wheel around in a vertical circle of radius 12 m at a constant speed of 5.5 m/s (a) What is the period of the motion? What is the magnitude of the normal force on the addict from the seat when bothh go through (b) the highest point of the circular path and (c) the lowest point?

Sum of magnitudes of the two forces acting at a point is 16 N if their resultant is normal to the smaller forces and has a magnitude 8N then the forces are .

The sum of two forces at a point is 16N. if their resultant is normal to the smaller force and has a magnitude of 8N, then two forces are

If vec(F) = (5hat(i)+2hat(j) - 4hat(k))N , the magnitude of force is

The centre in figure has dimensions m by h and the ramp is inclined at theta to the horizontal. Find the effective point of application of the normal force vec n .

Your are riding on a Ferris wheel that is rotating with a constant speed . The car in which you are riding always maintain its correct upward orientation , it does not invert. a. What is the direction of the normal force on you form the seat when you are at the top of the wheel ? i. upward ii. downward .iii. impossible to determine b. From the same choices, what is the direction of the net force on you when you are at the top of the wheel?

Figure shows a student, sitting on a stool that can rotate freely about a vertical axis. The student, initially at rest, is holding a bicycle wheel whose rim is loaded with lead and whose moment of inertia is I about its central axis. The wheel is rotating at an angular speed omega_i from an overead perspective, the rotation is counter clockwise. The axis of the wheel point vertical, and the angular momentum vecL_i of the wheel points vertically upward. The student now inverts the wheel, as a result, the student and stool rotate about the stool axis. With what angular speed and direction does the student then rotate? (The moment of inertia of the student+stool+wheel system about the stool axis is I_0 )

A constant horizontal force of 10 N is applied at the centre of a wheel of mass 10 kg and radius 0.30 m . The wheel rolls without slipping on the horizontal surface, and the acceleration of the centre of mass is 0.60 m//s^(2) . a. What are the magnitude and direction of the frictional force on the wheel? b. What is the rotational inertia of the wheel about an axis through its centre of mass and perpendicular to the plane of the wheel?

Figure 5-59 shows a box of mass m_(2)=1.0 kg on a friction-less plane inclined at angle theta=30^(@) . It is connected by a cord of negligible mass to a mass m_(1)=2.5 kg on a horizontal frictionless surface. The pulley is frictionless and massless. (a) If the magnitude of horizontal force vec(F) is 2.3 N, what is the tension in the connecting cord? (b) What is the largest value the magnitude of vec(F) may have without the cord becoming slack?