A spring loaded launcher sits at the bottom of the hill, which has an angle of...

A small spring-loaded launcher is designed to fire steel ball bearings with masses of 0.3 kg...

A small spring-loaded launcher is designed to fire steel ball bearings with masses of 0.3 kg . When setting the launcher, you compress the spring a distance of 13 cm . You then fire the launcher straight up and find that the projectiles reach a maximum height of 0.9 m above the point that they leave the launcher. You load another ball bearing, compress the spring a distance of 17 cm , and place it horizontally at the edge of...

An earthball with a mass of 125 kg and a radius of 1.5 m rolls down...

An earthball with a mass of 125 kg and a radius of 1.5 m rolls down a regular hill. The hill is 60 meters high and inclined at 15 degrees to the vertical. How fast is the ball moving at the bottom of the hill? At the bottom of the hill is an ice covered ramp. The ball begins to go up the frictionless ice ramp. What is the maximum height up the ramp that the ball reaches?

An earthball with a mass of 120 kg and a radius of 1.5 m rolls down...

An earthball with a mass of 120 kg and a radius of 1.5 m rolls down a regular hill. The hill is 60 meters high and inclined at 15 degrees to the vertical. a) How fast is the ball moving at the bottom of the hill? b) At the bottom of the hill is an ice covered ramp. The ball begins to go up the frictionless ice ramp. What is the maximum height up the ramp that the ball reaches?

In a spring gun system, a spring with a spring force constant 370 N/m  , is compressed...

In a spring gun system, a spring with a spring force constant 370 N/m  , is compressed 0.13 m . When fired, 79.1% of the elastic potential energy stored in the spring is eventually converted into kinetic energy of a 5.50×10−2 kg uniform ball that is rolling without slipping at the base of a ramp. The ball continues to roll without slipping up the ramp with 90.3 % of the kinetic energy at the bottom converted into an increase in gravitational...

In a spring gun system, a spring with a spring force constant 430 N/mN/m  , is compressed...

In a spring gun system, a spring with a spring force constant 430 N/mN/m  , is compressed 0.11 mm . When fired, 80.7 %% of the elastic potential energy stored in the spring is eventually converted into kinetic energy of a 6.50×10−2 kgkg uniform ball that is rolling without slipping at the base of a ramp. The ball continues to roll without slipping up the ramp with 89.6 %% of the kinetic energy at the bottom converted into an increase in...

A spring-loaded toy gun is used to shoot a ball of mass m=1.50kg straight up in...

A spring-loaded toy gun is used to shoot a ball of mass m=1.50kg straight up in the air. The spring has spring constant k=667 N/m. If the spring is compressed a distance of 19.0 cm from its equilibrium position y=0 and then released, the ball reaches a maximum height hmax (measured from the equilibrium position of the spring). There is no air resistance, and the ball never touches the inside of the gun. Assume that all movement occurs in a...

In a spring gun system, a spring with a spring force constant 350 N/mN/m  , is compressed...

In a spring gun system, a spring with a spring force constant 350 N/mN/m  , is compressed 0.11 mm . When fired, 81.0 %% of the elastic potential energy stored in the spring is eventually converted into kinetic energy of a 6.40×10−2 kgkg uniform ball that is rolling without slipping at the base of a ramp. The ball continues to roll without slipping up the ramp with 90.0 %% of the kinetic energy at the bottom converted into an increase in...

A 1100-kg car sits at rest at the bottom of a 15 degree hill. The driver...

A 1100-kg car sits at rest at the bottom of a 15 degree hill. The driver initiates the accelerator and the engine pushes it up a 15 degree hill with a net force of 4500 N parallel to the hill. There is an effective 0.1 coefficient of kinetic friction. Use energy concepts to calculate the speed of the car after it has moved 40 m along the hill’s surface.

A 1100-kg car sits at rest at the bottom of a 15 degree hill. The driver...

A 1100-kg car sits at rest at the bottom of a 15 degree hill. The driver initiates the accelerator and the engine pushes it up a 15 degree hill with a net force of 4500 N parallel to the hill. There is an effective 0.1 coefficient of kinetic friction. Use energy concepts to calculate the speed of the car after it has moved 40 m along the hill’s surface.

A hollow ball of mass 6.00 kg and radius 0.180 m is rolled up a hill...

A hollow ball of mass 6.00 kg and radius 0.180 m is rolled up a hill without slipping. If it starts off at the bottom with a linear speed of 7.00 m/s, what vertical height (in m) will it reach?