A particle of mass 3 kg is connected to a particle of mass 5 kg by a taut, light, inextensible string which passes over a smooth light pulley at the edge of a rough horizontal table - Leaving Cert Applied Maths - Question 4 - 2011

To find the acceleration, we can set up the following equations:

For the 3 kg mass: [ 5g - T - F_{friction} = 5a ] [ 5g - T - 2g = 5a ] [ 3g - T = 5a \quad ext{(1)} ]

For the 5 kg mass: [ T - 5g = -5a \quad ext{(2)} ]

From equation (1): [ T = 3g - 5a ] Substituting into equation (2): [ (3g - 5a) - 5g = -5a ] [ 3g - 10a = 0 ] [ a = \frac{3g}{10} ] [ g \approx 9.8 \Rightarrow a \approx 2.94 \ \text{ms}^{-2} ]

Using equation (1): [ T = 3g - 5a = 3(9.8) - 5(2.94) ] [ T \approx 29.4 - 14.7 = 14.7 \ N ]

For the 8 kg mass: [ R - T = 2a \quad ext{(1)} ]

For the 2 kg mass: [ 2g - T = 2a \quad ext{(2)} ]

From equation (1): [ T = R - 2a ] From equation (2): [ T = 2g - 2a ] Setting these equal gives: [ R - 2a = 2g - 2a ] [ R = 2g \Rightarrow R = 2(9.8) \Rightarrow R = 19.6 \ N ]

From here, we can find the acceleration: [ 20 - 2a = 10a \Rightarrow 20 = 12a \Rightarrow a = \frac{5}{3} \approx 1.67 \ ms^{-2} ]

Using the derived values: [ T = 2g + 2a = 2(9.8) + 2(1.67) ] [ T = 19.6 + 3.34 = 22.94 \ N ]