Mechanics
1. A car of mass 1000 kg travels along a horizontal straight road with its engine working at a constant rate of 20 kW. The resistance to motion of the car is 600 N. Find the acceleration of the car at an instant when its speed is 25 m s�1
2.
A man runs in a straight line. He passes through a fixed point A with constant velocity 7 m s�1 at time t � 0. At time ts his velocity is vm s�1
. The diagram shows the graph of v against t for the period 0 t 40.
(i) Show that the man runs more than 154 m in the first 24 s.
(ii) Given that the man runs 20 m in the interval 20 t 24, find how far he is from A when t � 40.
3.
A light inextensible string has its ends attached to two fixed points A and B, with A vertically above B. A smooth ring R, of mass 0.8 kg, is threaded on the string and is pulled by a horizontal force of magnitude X newtons. The sections AR and BR of the string make angles of 50Æ and 20Æ respectively
with the horizontal, as shown in the diagram. The ring rests in equilibrium with the string taut.
Find (i) the tension in the string, (ii) the value of X.
4. Two particles A and B are projected vertically upwards from horizontal ground at the same instant. The speeds of projection of A and B are 5 m s�1 and 8 m s�1 respectively. Find
(i) the difference in the heights of A and B when A is at its maximum height,
(ii) the height of A above the ground when B is 0.9 m above A.
5.
A force, whose direction is upwards parallel to a line of greatest slope of a plane inclined at 35Æ to the horizontal, acts on a box of mass 15 kg which is at rest on the plane. The normal component of the contact force on the box has magnitude R newtons (see Fig. 1).
(i) Show that R � 123, correct to 3 significant figures.
When the force parallel to the plane acting on the box has magnitude X newtons the box is about to move down the plane, and when this force has magnitude 5X newtons the box is about to move up the plane (see Fig. 2).
(ii) Find the value of X and the coefficient of friction between the box and the plane.
6. (i) A particle P of mass 1.2 kg is released from rest at the top of a slope and starts to move. The slope has length 4 m and is inclined at 25Æ to the horizontal. The coefficient of friction between P and the slope is 1
4 . Find
(a) the frictional component of the contact force on P,
(b) the acceleration of P,
(c) the speed with which P reaches the bottom of the slope.
(ii) After reaching the bottom of the slope, P moves freely under gravity and subsequently hits a horizontal floor which is 3 m below the bottom of the slope.
(a) Find the loss in gravitational potential energy of P during its motion from the bottom of the slope until it hits the floor.
(b) Find the speed with which P hits the floor.
7. A particle P starts to move from a point O and travels in a straight line. At time ts after P starts to move its velocity is vm s�1
, where v � 0.12t � 0.0006t 2.
(i) Verify that P comes to instantaneous rest when t 200, and find the acceleration with which it starts to return towards O.
(ii) Find the maximum speed of P for 0 t 200.
(iii) Find the displacement of P from O when t 200.
(iv) Find the value of t when P reaches O again.