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Two particles A and B, of mass 7 kg and 3 kg respectively, are attached to the ends of a light inextensible string - Edexcel - A-Level Maths Mechanics - Question 7 - 2011 - Paper 1

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Two particles A and B, of mass 7 kg and 3 kg respectively, are attached to the ends of a light inextensible string. Initially B is held at rest on a rough fixed plan... show full transcript

Worked Solution & Example Answer:Two particles A and B, of mass 7 kg and 3 kg respectively, are attached to the ends of a light inextensible string - Edexcel - A-Level Maths Mechanics - Question 7 - 2011 - Paper 1

Step 1

Find the magnitude of the acceleration of B immediately after release.

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Answer

To analyze the forces acting on particles A and B, we use Newton's second law. For particle A (mass 7 kg):

extWeight=7g ext{Weight} = 7g

For particle B (mass 3 kg), we consider:

  • The tension in the string, T.
  • The frictional force acting against the motion, which is given by: F = rac{2}{3} R = rac{2}{3} (3g rac{5}{13})

Setting up the equations: For A: 7gT=7a7g - T = 7a For B (considering forces parallel to the incline): T - F - 3g rac{5}{12} = 3a

Eliminating T from the equations:

  1. Rearranging for T in the first equation gives: T=7g7aT = 7g - 7a
  2. Substituting for T in the second equation, we have: (7g - 7a) - rac{2}{3} (3g rac{5}{12}) - 3g rac{5}{12} = 3a

This leads us to calculate the acceleration a, yielding: a = rac{2g}{5} Approximately, this results in: aextis3.9extm/s2extor3.92extm/s2.a ext{ is } 3.9 ext{ m/s}^2 ext{ or } 3.92 ext{ m/s}^2.

Step 2

Find the speed of B when it has moved 1 m up the plane.

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Answer

Using the kinematic equation:

v2=u2+2asv^2 = u^2 + 2as

where:

  • Initial speed, u=0u = 0 (since it starts from rest),
  • a = rac{2g}{5} ext{ (from previous calculation)}, and the distance moved, s=1ms = 1 m.

Substituting the values: v^2 = 0 + 2 imes rac{2g}{5} imes 1 Calculating gives: v=extapproximately2.8extm/s.v = ext{ approximately } 2.8 ext{ m/s}.

Step 3

When B has moved 1 m up the plane the string breaks. Given that in the subsequent motion B does not reach P, find the time between the instants when the string breaks and when B comes to instantaneous rest.

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Answer

After the string breaks, the force acting on B is:

(-(F + 3g rac{5}{12}) = 3a

Therefore:

- rac{2}{3} (3g rac{5}{12}) - 3g rac{5}{12} = -3a Resulting in: a=ga = -g From here, we calculate time, using:

t = rac{v}{g} where v=2.8extm/sv = 2.8 ext{ m/s}. Thus: t = rac{2 ext{ m/s} }{7} ext{ yielding approximately } 0.286 ext{ seconds.}

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