A particle is acted upon by a force of constant magnitude which is always perpendicular to the velocity of the particle, the motion of the particle takes place in a plane. It follows that
its velocity is constant
its acceleration is constant
its kinetic energy is constant
its kinetic energy is constant
Two masses m1 = 5 kg and m2 = 10 kg, connected by an inextensible string over a frictionless pulley, are moving as shown in the figure. The coefficient of friction of the horizontal surface is 0.15. The minimum weight m that should be put on top of m2 to stop the motion is :
10.3 kg
18.3 kg
27.3 kg
43.3 kg
C.
27.3 kg
Given: m1 = 5kg;
m2 = 10 kg
μ = 0.15
For m1, m1g -T =m1a
= 50-T = 5 x a
and T - 0.15 (m+10) g = (10 + m)a
For rest a = 0
or 50 = 0.15 (m +10) 10
The minimum value from the options, satisfying the above condition is, m = 27.3 kg
In a collinear collision, a particle with an initial speed v0 strikes a stationary particle of the same mass. If the final total kinetic energy is 50% greater than the original kinetic energy, the magnitude of the relative velocity between the two particles, after the collision, is:
vo/4
v0/2
From the ground, a projectile is fired at an angle of 60 degrees to the horizontal with a speed of 20 m/s. Take, acceleration due to gravity as 10 m/s2 . The horizontal range of the projectile is
20 m
A ball falls from a table top with initial horizontal speed V0. In the absence of air resistance,which of the following statement is correct.
The vertical component of the acceleration changes with time
The horizontal component of the velocity does not change with time
The horizontal component to the acceleration is non zero and finite
The time taken by the ball to touch the ground depends on V0
A man of mass 60 kg climbed down using an elevator.The elevator had an acceleration 4 ms-2. If the acceleration due to gravity is 10 ms-2, the man's apparent weight on his way down is
60 N
240 N
360 N
840 N
A uniform rod of length of 1 m arid mass of 2 kg is attached to a side support at O as shown in the figure. The rod is at equilibrium due to upward force T acting at P. Assume the acceleration due to gravity as 10 m/s2 . The value of T is
0
2 N
5 N
10 N
An aeroplane is flying with a uniform speed of 150 km h-1 along the circumference of a circle. The change in its velocity in half the revolution (in km h-1) is
150
100
200
300
In uniform circular motion, the centripetal acceleration is
towards the centre of the circular path and perpendicular to the instantaneous velocity
a constant acceleration
away from the centre of the circular path and perpendicular to the instantaneous velocity
a variable acceleration making 45° with the instantaneous velocity
A body is thrown up with a speed u, at an angle of projection θ. If the speed of the projectile becomes on reaching the maximum height, then the maximum vertical height attained by the projectile is