a device shoots a toy car by compressing a springwith spring constant 150n/m a distance of...

A 880·kg car strikes a huge spring at a speed of 16·m/s, compressing it 11.0·m. (a)...

A 880·kg car strikes a huge spring at a speed of 16·m/s, compressing it 11.0·m. (a) What is the spring constant of the spring? N/m (b) How long does the spring take to stop the car? s

The toy gun in the figure below consists of a spring with spring constant k. It...

The toy gun in the figure below consists of a spring with spring constant k. It is loaded with a projectile of mass m and the spring is compressed of a distance d. The toy gun is fired horizontally and the bullet travels a total distance of L within the toy gun before it is released. A) Neglecting all resistive forces, determine the speed of the projectile v0 once it exits the toy gun (i.e, express v0 in terms of...

A remote controlled, battery operated toy car starts at t = 0 and travels 6.0 m...

A remote controlled, battery operated toy car starts at t = 0 and travels 6.0 m at constant speed of 0.23 m/s. It now accelerates at 0.15m/s2 for another 6.0m and then maintains a constant speed for another 6.0m. The care now slows at 0.10m/s2 for 6.0m coming to a stop. How long did it take the car to travel the 24.0m?

A new car, car 1, has a spring loaded rear bumper with a force constant of...

A new car, car 1, has a spring loaded rear bumper with a force constant of 8.4x105 N/m. While car 1 is parked, a second vehicle, car 2 (with mass of 1.5x103 kg), travels at a constant speed of 18 km/h, hitting car 1 in the rear bumper.             a)        Calculate the kinetic energy of car 2. b)        Calculate the distance that car 1’s bumper will compress if car 2 comes to a complete stop after striking it.

A toy gun shoots spherical plastic projectiles by means of a spring. A typical projectile has...

A toy gun shoots spherical plastic projectiles by means of a spring. A typical projectile has a mass of m = 25 g. The spring used has a spring constant of k = 18.6 N/m, and when put under load, it is displaced 10 cm, as shown in Figure P6.92. The barrel of the gun exerts a slight frictional force, Ffriction= -0.1512 N, on the pellet as it moves down the barrel from its starting point over a total length...

The toy gun in the figure below consists of a spring with spring constant k. Itis...

The toy gun in the figure below consists of a spring with spring constant k. Itis loaded with a projectile of mass mand the spring is compressed a distance d. The toy gun is fired horizontally and the bullet travels a total distance Lwithin the toy gunbefore it is released. A) Neglecting all resistive forces, determine the speed of the projectile v0once it exits the toy gun(i.e., expressv0 in terms of the known quantities k, m, L, d).B) Suppose now...

A 172 g block is launched by compressing a spring of constant k=200N/m a distance of...

A 172 g block is launched by compressing a spring of constant k=200N/m a distance of 15 cm. The spring is mounted horizontally, and the surface directly under it is frictionless. But beyond the equilibrium position of the spring end, the surface has coefficient of friction μ=0.27. This frictional surface extends 85 cm, followed by a frictionless curved rise, as shown in the figure After launch, where does the block finally come to rest? Measure from the left end of...

A toy gun uses a spring with a force constant of 300N/m to propel a 15.0...

A toy gun uses a spring with a force constant of 300N/m to propel a 15.0 g steel ball. If the spring is compressed 6.00 cm and friction is negligible: a) how much force is needed to compress the spring? b) what is the maxium height that the ball can reach? c) If the gun is fired at an angle of 7.50 degrees above the horizontal, what is the maxium distance the ball will travel on level ground?

A car traveling 74 km/hkm/h slows down at a constant 0.54 m/s2m/s2 just by "letting up...

A car traveling 74 km/hkm/h slows down at a constant 0.54 m/s2m/s2 just by "letting up on the gas." (a) Calculate the distance the car coasts before it stops. (b) Calculate the time it takes to stop. (c)Calculate the distance it travels during the first second. (d) Calculate the distance it travels during the fifth second.

Another block, another spring. This time around, the block (m = 1.18 kg) is compressing a...

Another block, another spring. This time around, the block (m = 1.18 kg) is compressing a spring with spring constant k = 273 N/m by 36.3 cm. It is released from rest so it then slides along the horizontal surface shown. This time, there is friction on the horizontal surface, with a coefficient of friction between the block and surface of μk = 0.11. In addition, there is a steady wind blowing to the right, exerting a constant 6.7 N...