Circular motion, vertical surface with kinetic friction: A small block of mass 2.0 kg slides on...
A small block of mass 0.150 kg slides in a horizontal circular trajectory of radius 0.400 m at constant speed along the inside of a frictionless bowl (cross-section shown). The bowl’s surface makes an angle of 25.0° with the horizontal. 5. Find the magnitude of the normal force acting on the block. 6. Find the block’s speed. please explain (numbers 5-6) A small block of mass 0.150 kg slides in a horizontal circular trajectory of radius 0.400 m at constant...
A block of mass m = 78 kg slides along a horizontal surface. The coefficient of friction between the block and the surface is μk = 0.29. The block has an initial speed of v0 = 29 m/s in the positive x-direction as shown. a. Write an expression for the x-component of the frictional force the block experiences, Ff, in terms of the given variables and variables available in the palette. b. What is the magnitude of the frictional force in N? c....
A block of mass m = 63 kg slides along a horizontal surface. The coefficient of friction between the block and the surface is μk= 0.41. The block has an initial speed of v0 = 16 m/s in the positive x-direction as shown. Part (a) Write an expression for the x-component of the frictional force the block experiences, Ff in terms of the given variables and variables available in the palette.Part (b) What is the magnitude of the frictional force in...
A block of mass m = 67 kg slides along a horizontal surface. The coefficient of friction between the block and the surface is μk = 0.22. The block has an initial speed of v0= 16 m/s in the positive x-direction as shown.Part (a) Write an expression for the x-component of the frictional force the block experiences, Ff, in terms of the given variables and variables available in the palette. Part (b) What is the magnitude of the frictional force in...
take r ro be 1.0 m 1. A small block of mass 0.5 kg compresses a spring (K 500 N/m) a distance of x 0.50 m. The block is released from rest and travels along a frictionless, horizontal surface until it reaches point A. After point A is moves along the circular path while experiencing an frictional force of magnitude 6.0 N. a) Calculate the speed when it reaches the top of the circular path. (Use work-energy methods to solve...
Question 12 of 14 > Final position A small block of mass m slides to the left on a frictionless, horizontal surface with speed u. Then, the block slides up a rough ramp that has an incline angle of 8. The coefficient of kinetic friction between the ramp and box is p. The acceleration due to gravity is g. Rough surface Initial position What is the height h of the block when its speed up the ramp equals nu, where...
A 2.0-kg block slides along a rough horizontal surface. A force(P=6.0N) is applied to the block at a 30degree angle. What is the horizontal acceleration of the block? ASSUME NO FRICTIONAL FORCE
6. A 2.0 kg block slides to the right across a horizontal surface. Let's define a coordinate system where the +x-direction is to the right. At x=0, the block's velocity is +5.0 m / s (to the right). The magnitude of the kinetic friction force between the block and surface is 10N.a. Draw a force diagram of the block. Which forces expert zero work on the block? Explain why.c. What is the work that the kinetic friction force exerts on...
(S points) A o.5 kg block slides along a horizontal frictionless surface at 2.0 m/s. It is brought to rest by compressing a ve 16. sed long spring of spring constant 800 N/m. How far does the spring get compressed (in cm)? 17. (5 points) A block is released from rest at point P. h2 50 m high, and slides along the frictionless track shown. What is its speed at pointō匹=40 m high? h1 h2 ground level
Problem 4 A block of mass m slides at velocity vo across a horizontal frictionless surface toward a large curved movable ramp n and has a smooth circular frictionless face up which the block can easily slide. When the block slides up the ramp, it momentarily reaches a maximum height a shown in Figure II, and then slides back down the frictionless surface as shown in Figure III. face to the horizontal (a) Find the velocity of the ramp at...