A block of mass m=1.2 kg is held at rest against a spring with a force constant k=730N/m. Initially the spring is compressed a distance d. When the block is released, it slides across a surface that is frictionless except for a rough patch of width? x = 5.0 cm that has coefficient of kinetic friction µk = 0.44 Find a general expression of d such that the block's speed after crossing the rough patch is Vf = 2.3 m/s. Also calculate the value of d. How does the friction effect the d to reach the same Vf?

Question

Physics

Guest

3 January, 15:34

A block of mass m=1.2 kg is held at rest against a spring with a force constant k=730N/m. Initially the spring is compressed a distance d. When the block is released, it slides across a surface that is frictionless except for a rough patch of width? x = 5.0 cm that has coefficient of kinetic friction µk = 0.44 Find a general expression of d such that the block's speed after crossing the rough patch is Vf = 2.3 m/s. Also calculate the value of d. How does the friction effect the d to reach the same Vf?

+3

Answers (1)

Know the Answer?

Ismael Mcbride · Answer 1

potential energy of compressed spring

= 1/2 k d²

= 1/2 x 730 d²

= 365 d²

This energy will be given to block of mass of 1.2 kg in the form of kinetic energy.

Kinetic energy after crossing the rough patch

= 1/2 x 1.2 x 2.3²

= 3.174 J

Loss of energy

= 365 d² - 3.174

This loss is due to negative work done by frictional force

work done by friction = friction force x width of patch

= μmg d, μ = coefficient of friction, m is mass of block, d is width of patch

=.44 x 1.2 x 9.8 x. 05

=.2587 J

365 d² - 3.174 =.2587

365 d² = 3.4327

d² = 3.4327 / 365

=.0094

d =.097 m

= 9.7 cm

If friction increases, loss of energy increases. so to achieve same kinetic energy, d will have to be increased so that initial energy increases so compensate increased loss.