Use a mass of 10,000 kg of steel in pile driving. To make the pile into...

A 2,200-kg pile driver is used to drive a steel I-beam into the ground. The pile...

A 2,200-kg pile driver is used to drive a steel I-beam into the ground. The pile driver falls 4.60 m before coming into contact with the top of the beam, and it drives the beam 15.8 cm farther into the ground as it comes to rest. Using energy considerations, calculate the average force the beam exerts on the pile driver while the pile driver is brought to rest.

A 1,710 kg pile driver is used to drive a steel beam into the ground. The...

A 1,710 kg pile driver is used to drive a steel beam into the ground. The pile driver falls 9 m before contacting the beam, and it drives the beam 13 cm into the ground before coming to rest. Using energy considerations, calculate the amplitude of the average force (in N) the beam exerts on the pile driver while the pile driver is brought to rest.

Calculate the change in kinetic energy in J, when the mass is 56 kg, the initial...

Calculate the change in kinetic energy in J, when the mass is 56 kg, the initial velocity is 45 m/s and the final velocity is 90 m/s. Calculate the mass of the vehicle in kg, if the grade resistance is 82 N, the road grade is 1.1. Find the rolling resistance (in N) when: the rolling coef. is 0.014, the effective mass is 81 kg. Find F(aero) (in N) if the total tractive effort is 73 kN, the rolling resistance...

You drop a ball with a diameter of 7.5 cm and a mass of 150 g...

You drop a ball with a diameter of 7.5 cm and a mass of 150 g off of the top of a tall building. Use C = 0.5 and Pair = 1.225 kg/m^3. If the height of the building is 100 m, how long will it take the ball to hit the ground? What will the ball’s velocity be when it hits the ground?

1. Assuming that the acceleration of the driving mass was constant, calculate the speed and the...

1. Assuming that the acceleration of the driving mass was constant, calculate the speed and the translational kinetic energy of the driving mass just as it strikes the ground. Use the average of the three measured times. 2. Using conservation of energy, calculate the rotational kinetic energy of the system just as the driving mass strikes the ground. 3. Calculate the angular velocity of the system just as the driving mass strikes the ground. 4. Using the rotational kinetic energy...

Mass of glider= 0.385 kg is placed at rest on an air track that has an...

Mass of glider= 0.385 kg is placed at rest on an air track that has an angle of inclination = 10°. The height = 30 cm of the glider above the table. The glider is released traveling 3.05 m down along the track. When the glider is at 20 cm above the height of the table, the velocity = 1.5m/s. Find the frictional force acting on the glider?

A ball, mass is 8 kg, is thrown from the top of a 30 m cliff...

A ball, mass is 8 kg, is thrown from the top of a 30 m cliff with a velocity of 20 m/s straight up. The ball misses the cliff on the way down. Ignore air resistance. Use work and conservation of energy to find the following values. a. what is the work done by gravity while the ball is in the air? b. what is the maximum height of the ball? c. what is the magnitude of the velocity just...

A ball with mass 1/9.8 kg is thrown upward with initial velocity 20 m/s from the...

A ball with mass 1/9.8 kg is thrown upward with initial velocity 20 m/s from the roof of a building 30 m high. Assume that the force of air resistance (drag force) is (v^2)/1225. Find the maximum height above the ground that the ball reaches. (Hint: find the velocity v(t) first, then find the height x(t).)

An object of mass 5 kg is released from rest 24525 m above the ground and...

An object of mass 5 kg is released from rest 24525 m above the ground and allowed to fall under the influence of gravity. Assume the gravitational force is constant, with g=9.8 m/sec2 , and the force due to air resistance is proportional to the velocity of the object with proportionality constant k= 1 kg/sec. Approximate when (in seconds) the object will strike the ground.

Two blocks with masses 0.443 kg (A) and 0.769 kg (B) sit on a frictionless surface....

Two blocks with masses 0.443 kg (A) and 0.769 kg (B) sit on a frictionless surface. Between them is a spring with spring constant 26 N/m, which is not attached to either block The two blocks are pushed together, compressing the spring by 0.338 meter, after which the system is released from rest. What is the final speed of the block A? (Hint: you will need to use both conservation of energy and conservation of momentum to solve this problem)....