In the above problem normal reaction between ground and wedge will have magnitude equla to

In the figure if block A and wedge b will move with same acceleration, then the magnitude of normal reaction between the block and the wedge will be (There is no friction between block and the wedge and the wedge moves on horizontal surface as shown.)

In the above probllem, the normal force between the ball and the shell in position B is (m=mass of ball)

A block A of mass m which is placed a rough inclined face of a wedge of same mass being pulled through light string and with force F as shown in figure The coefficient of friction between inclined face and block A is mu while there is no friction between the ground and wedge it the whole system moves with same acceleration then find the value of F

A block of mass m slides down on a wedge of mass M as shown in figure .Let a_(1) be the asseleration of the acceleration of and a_(2) the the acceleration od block 1 N_(1) is the normal reaction between block and wedge and N_(2) the normal reaction between wedge and gound .frication is absent everwhere .Select the correct alternative(s)

A small wedge whose base is horizontal is fixed to a vertical rod as shown in fig . The sloping side of the weidgeis frictionless and the wedge is span with a constant angular speed omega about vertical axis as shown in the fig find the a. value of angular speed omega for which the block of mass m just does not slide down the wedge. b. normal reaction on the block by wedge when block does not slip relative to wedge.

A block of mass 1 kg is at rest relative to a smooth wedge moving leftwards with constant acceleration a = 5 m//s^(-2) .Let N be the normal reation between the block and the wedge . Then (g = 10 m//s^(-2))

Two blocks A and B of masses 2kg and 3kg respectively, are placed on a horizontal surface as shown (one on top of other). Find the ratio of magnitude of normal reaction between A and B to that between B and the surface, respectively

In the above problem, this horizontal distance between the two fragments when their position vectors are perpendicular to each other is

A constant horizontal force (F) is applied at the vertex A of an equilateral triangular wedge ABC of mass M and side length AB=BC=CA= l_(1) placed on a rough horizontal surface as shown in the figure. Even after the application of force F the wedge remains stationary. Calculate the torque of normal reaction acting between the wedge and the floor about the vertex B.

A rod can rotate in a horizontal plane about its one end. A bead which can move along the rod is placed at certain distance from the axis or rotation. The bead does not to friction. The rod has a constant angular acceleration A. the normal reaction on the bead will be constant h magnitude and direction both B. the magnitude of the normal reaction on the bead will be variable C. the magnitude of friction force on the bead will be constant D. the magnitude of friction force on the bead will be variable