Chapter 24 : Laws of Motion 489
Here we shall discuss the following two cases as shown in Fig. 24.1 (a) and (b) :- When the lift is moving upwards.
- When the lift if moving downwards.
- When the lift is moving upwards
Fig. 24.1. Motion of a lift.
We know that downward force due to mass of the lift
=mgand net upward force on lift, F=R – mg ...(i)
We also know that this force = Mass × Acceleration = m.a ...(ii)
From equations (i) and (ii),
R – mg=ma
∴ R=ma + mg = m (a + g)- When the lift is moving downwards
In this case, the net downward force, which is responsible for the motion of the lift.
=mg – R ...(iii)
From equations (ii) and (iii),
ma=mg – R
∴ R=mg – ma = m (g – a)
Note. In the above cases, we have taken mass carried by the lift only. We have assumed that it
includes mass of the lift also. But sometimes the example contains mass of the lift and mass carried by
the lift separately.
In such a case, the mass carried by the lift (or mass of the operator etc.) will exert a pressure on
the floor of the lift. Whereas tension in the cable will be given by the algebraic sum of the masses of
the lift and mass carried by the lift. Mathematically. (When the lift is moving upwards), then the
pressure exerted by the mass carried by the lift on its floor
= m 2 (g + a)
and tension in the cable = (m 1 + m 2 ) (g + a)
where m 1 = Mass of the lift and
m 2 = Mass carried by the lift.