A 42.0 kg block lies on a smooth(friction less) inclined plane tilted at an angle of...

A block of mass M2 = 8.45 kg on a plane inclined moving down at angle...

A block of mass M2 = 8.45 kg on a plane inclined moving down at angle θ = 50° is connected by a cord over a massless, frictionless pulley to a second block of mass M1 = 5.36 kg on a horizontal surface. The coefficient of kinetic friction between M1, M2 and the surface is μk = 0.150, the Force F1 = 11.3 N is acting downward on M1, and the Force F2 = 21.8 N is acting on M2...

A block lies on an inclined plane with an angle of elevation theta. The inclined plane...

A block lies on an inclined plane with an angle of elevation theta. The inclined plane is frictionless, and the plane is accelerated to the left such that the block's height remains constant. What is the net force on the block?

If a block of mass 10 kg slides down an inclined plane having an angle of...

If a block of mass 10 kg slides down an inclined plane having an angle of 30 degrees above the horizon,at the end of the inclined plane there is a frictionless surface on the end of it lies a spring having spring constant 500N/m.There is friction on the inclined plane,Find the coefficient of kinetic friction of the inclined plane. when the block reaches the spring,it compresses it by 0.40m Let the block start from rest and the height be 20...

A 1 kg block, starting from rest, slides down a 22 degree inclined plane that is...

A 1 kg block, starting from rest, slides down a 22 degree inclined plane that is .55m tall. At the bottom, the 1 kg block collides with a 3 kg block. The two blocks stick together and slide .52 m on a friction less horizontal surface for .52 sec. What is the speed of the 1kg block before it collides with the 3 kg block? What is the acceleration of the 1kg block as it travels down the inclined plane?...

A 3.00 kg block slides down a 37.0 degree inclined plane. If the acceleration of the...

A 3.00 kg block slides down a 37.0 degree inclined plane. If the acceleration of the block is 1.52 m/s2, a) the force of kinetic friction on the block. b) the normal force on the block. c) the coefficient of kinetic friction on the block. d) the angle needed to make the block slide down the incline at a constant speed.

In the figure, a 5.40 kg block is sent sliding up a plane inclined at θ...

In the figure, a 5.40 kg block is sent sliding up a plane inclined at θ = 37.0° while a horizontal force   of magnitude 50.0 N acts on it. The coefficient of kinetic friction between block and plane is 0.330. What are the (a) magnitude and (b) direction (up or down the plane) of the block's acceleration? The block's initial speed is 4.30 m/s. (c) How far up the plane does the block go? (d) When it reaches its highest...

an 11 kg block slides down a surface with friction that is inclined at an angle...

an 11 kg block slides down a surface with friction that is inclined at an angle of 38 degrees. how much work does the friction force do after the block has gone .75 m down the incline? .275 friction

A block of mass 4.8 kg slides 24 m from rest down an inclined plane making...

A block of mass 4.8 kg slides 24 m from rest down an inclined plane making an angle of 24 o with the horizontal. If the block takes 10 s to slide down the plane, what is the retarding force due to friction?

A 4.00kg block slides on the surface of an inclined table, which makes an angle of...

A 4.00kg block slides on the surface of an inclined table, which makes an angle of 15.0∘ with the horizontal. The block is connected through cords over two pulleys to a 7.26kg bowling ball on the upper side of the table, and a 3.00kg ball on the lower side. The pulleys are massless and frictionless, while the coefficient of kinetic friction between the block and the table's surface is 0.470. Draw a free-body diagram for each moving object. Determine the...

A 9.31 kg block is placed at the top of a frictionless inclined plane angled at...

A 9.31 kg block is placed at the top of a frictionless inclined plane angled at 14.9 degrees relative to the horizontal. When released (from rest), the block slides down the full 2.77 meter length of the incline. Calculate the speed (magnitude of the velocity) of the block at the bottom of the incline. [Start by drawing a free-body diagram for the block.] Note that all the information provided may not be necessary to solve the problem.