WB20 In the diagram, AOC = 90° and BOC = q °.

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Presentation transcript:

WB20 In the diagram, AOC = 90° and BOC = q °. A particle at O is in equilibrium under the action of three coplanar forces. The three forces have magnitudes 8 N, 12 N and X N and act along OA, OB and OC respectively. Calculate (a) the value, to one decimal place, of θ (b) the value, to 2 decimal places, of X. Now try Ex 4A, Q1,4,14 then 7

Q1 Q4

Q14 Q7 Sub in (1)

WB21 A particle has mass 2 kg. It is attached at B to the ends of two light inextensible strings AB and BC. When the particle hangs in equilibrium, AB makes an angle of 30° with the vertical. The magnitude of the tension in BC is twice the magnitude of the tension in AB. (a) Find, in degrees to one decimal place, the size of the angle that BC makes with the vertical. (b) Hence find, to 3 significant figures, the magnitude of the tension in AB. Now try Ex 4B, Q1,2,6,5,4

Q1 Q2 Q6

Q5 Q4

WB23 A particle P of mass 2.5 kg rests in equilibrium on a rough plane under the action of a force of magnitude X newtons acting up a line of greatest slope of the plane, as shown in the diagram above. The plane is inclined at 20° to the horizontal. The coefficient of friction between P and the plane is 0.4. The particle is in limiting equilibrium and is on the point of moving up the plane. Calculate (a) the normal reaction of the plane on P, (b) the value of X. The force of magnitude X newtons is now removed. (c) Show that P remains in equilibrium on the plane. Now try Ex 4B, Q7,8,12,13

Q7 Q8

Q12 For A: A For B: B For A:

Q13 For 2kg mass: Q For Q: For Q:

WB22 Two small rings, A and B, each of mass 2m, are threaded on a rough horizontal pole. The coefficient of friction between each ring and the pole is m. The rings are attached to the ends of a light inextensible string. A smooth ring C, of mass 3m, is threaded on the string and hangs in equilibrium below the pole. The rings A and B are in limiting equilibrium on the pole, with BAC = ABC = θ, where , as shown in the diagram above. (a) Show that the tension in the string is (b) Find the value of μ. For B:

WB24 A parcel of mass 5 kg lies on a rough plane inclined at an angle a to the horizontal, where The parcel is held in equilibrium by the action of a horizontal force of magnitude 20 N, as shown in the diagram above. The force acts in a vertical plane through a line of greatest slope of the plane. The parcel is on the point of sliding down the plane. Find the coefficient of friction between the parcel and the plane.

WB25 A box of mass 1.5 kg is placed on a plane which is inclined at an angle of 30° to the horizontal. The coefficient of friction between the box and plane is The box is kept in equilibrium by a light string which lies in a vertical plane containing a line of greatest slope of the plane. The string makes an angle of 20° with the plane, as shown in the diagram above. The box is in limiting equilibrium and is about to move up the plane. The tension in the string is T newtons. The box is modelled as a particle. Find the value of T. Equating (3) and (4): Now try Ex 4C, Q8-12

Q8 Q For equilibrium, Q9 Q Sub in (1)

Q10 Q11a)

Q11b) Q12