Resolving Forces, Inclined Planes & Friction (Edexcel A Level Maths: Mechanics): Exam Questions

Exam code: 9MA0

5 hours40 questions

Easy

Medium

Hard

Very Hard

1 mark

Diagram of a 5 kg object on a line, with a right-pointing 28 N force and a left-pointing force labelled F N. — **Figure 1**

A particle $P$ has mass 5 kg.

The particle is pulled along a rough horizontal plane by a horizontal force of magnitude 28 N.

The only resistance to motion is a frictional force of magnitude $F$ newtons, as shown in Figure 1.

Find the magnitude of the normal reaction of the plane on $P$ .

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2 marks

The particle is accelerating along the plane at 1.4 ms^–2.

Find the value of $F$ .

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1 mark

The coefficient of friction between $P$ and the plane is $μ$ .

Find the value of $μ$ , giving your answer to 2 significant figures.

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4 marks

The following force diagram shows three forces acting on a particle:

Diagram showing three forces at a point: 30 N at 50° pointing left-up, P N right, and Q N downward.

Given that the particle is in equilibrium, find the values of $P$ and $Q$ .

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6 marks

The following force diagram shows three forces acting on a particle:

Diagram showing three forces: 17 N left, 35 N right at 55° above, and 25 N down at 25° below, with dashed vertical line at origin.

Find the magnitude and direction of the resultant force.

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3 marks

The following force diagram shows three forces acting on a particle:

Diagram showing three forces acting on a point. Forces are 20 N at 30°, 20√3 N at 60°, and F N vertically downwards, with dashed lines for angles.

Given that the particle is in equilibrium, find the exact value of $F$ .

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2 marks

The following force diagram shows three forces acting on a particle:

Diagram showing forces: 40 N left, 26.5 N down, and force F at angle θ° above right horizontal.

Given that the particle is in equilibrium, find $F$ and $θ$ .

Give both your answers correct to 3 significant figures.

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4 marks

Figure 1 shows a particle of mass $m kg$ suspended by a light inextensible string, with the other end of the string attached to a fixed point $A$ .

With the string at an angle of $30 °$ to the vertical, equilibrium is maintained by a horizontal force of $P$ N which acts on the particle as shown in Figure 1.

Diagram showing a force triangle with a 30-degree angle at point A. Forces include P Newtons leftward and mg Newtons downward from a central point. — **Figure 1**

Given that the tension in the string is 16 N and that $g$ is the acceleration due to gravity, find the values of $P$ and $m$ .

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2 marks

A particle of mass 5 kg is sliding down a smooth slope that is angled at $30 °$ to the horizontal.

Calculate the acceleration of the particle down the slope.

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2 marks

Calculate the normal reaction force of the slope on the particle.

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2 marks

A particle of mass 10 kg is sliding down a smooth slope that is angled at $15 °$ to the horizontal.

Calculate the acceleration of the particle down the slope.

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2 marks

In each of the following situations, the object is initially at rest on a rough surface with coefficient of friction $μ$ .

Find the magnitude of the frictional force $F$ that will act upon the object in each case, and determine whether the object will remain at rest or begin to move.

Diagram of a 5 kg block with forces: 13 N right, F left, R upward, 5g N downward, and friction coefficient 0.3.

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2 marks

Diagram of a 3 kg block with forces: 12 N left, F right, 3g N down, R up. Friction coefficient is 0.4. Arrows indicate force directions.

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2 marks

Diagram of a 7 kg block on a surface with forces: 12 N and R up, 7g N down, 16 N right, F left. Friction coefficient is 0.2.

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2 marks

Diagram of a 10 kg block on a surface with friction coefficient 0.25. Forces include 25 N at 30° angle, vertical R, 10g N, and horizontal F.

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2 marks

A block of mass 2 kg rests on a rough horizontal surface.

A horizontal force of magnitude $P$ N acts on the block as shown in Figure 1.

The coefficient of friction between the block and the surface is 0.4.

Given that the block is on the point of sliding, calculate the magnitude of $P$ .

A block labelled 2 kg on a surface with friction coefficient 0.4, with a force P N applied horizontally to the right. — **Figure 1**

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11a

3 marks

A particle of mass 5 kg is held at rest on a rough plane which is inclined at $30 °$ to the horizontal. The coefficient of friction between the particle and the plane is 0.3.

The particle is then projected up the line of greatest slope of the plane, and moves up the plane until it comes to rest.

Determine the frictional force acting on the particle as it moves up the plane. State the magnitude and the direction of the force.

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11b

2 marks

Determine the acceleration of the particle while it is moving up the plane. State the magnitude and the direction of the acceleration.

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11c

1 mark

After coming momentarily to rest, the particle begins to slide back down the plane.

Determine the frictional force acting on the particle as it slides down the plane. State the magnitude and the direction of the force.

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11d

2 marks

Determine the acceleration of the particle while it is sliding down the plane. State the magnitude and the direction of the acceleration.

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6 marks

A 20kg block on a flat surface, with a 40N force acting diagonally at an angle α from the horizontal, indicated by an arrow. — **Figure 1**

A wooden crate of mass 20 kg is pulled in a straight line along a rough horizontal floor using a handle attached to the crate.

The handle is inclined at an angle $α$ to the floor, as shown in Figure 1, where $\tan α = \frac{3}{4}$ .

The tension in the handle is 40 N.

The coefficient of friction between the crate and the floor is 0.14.

The crate is modelled as a particle and the handle is modelled as a light rod.

Using the model, find the acceleration of the crate.

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1b2 marks

The crate is now pushed along the same floor using the handle. The handle is again inclined at the same angle $α$ to the floor, and the thrust in the handle is 40 N as shown in Figure 2 below.

Diagram showing a 20 kg block on a flat surface with a 40 N force applied at angle α to the horizontal. Dashed line indicates the angle. — **Figure 2**

Explain briefly why the acceleration of the crate would now be less than the acceleration of the crate found in part (a).

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4 marks

Figure 1 shows a particle of mass $m kg$ suspended by a light inextensible string, with the other end of the string attached to a fixed point $P$ .

With the string at an angle of $40 °$ to the vertical, equilibrium is maintained by a horizontal force of 12 N which acts on the particle as shown in Figure 1.

Diagram showing a mass m kg with a 12 N force leftward, a 40° angle to vertical, connected at point P on a dashed line. — **Figure 1**

Find

(i) the tension in the string,

(ii) and the value of $m$ .

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4 marks

A particle $P$ , of mass 7 kg, is pulled along a rough horizontal plane by a light horizontal string.

The string is inclined at 20° above the horizontal and the tension in the string is 45 N, as shown in Figure 2.

Ball on a flat surface with a 20-degree force vector angled upwards, labelled 45 N, illustrating applied force direction and magnitude. — **Figure 2**

The coefficient of friction between $P$ and the plane is 0.4.

Given that the particle is moving, find the magnitude of the acceleration of $P$ to two significant figures.

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3 marks

A block of mass 6 kg rests on a rough horizontal surface.

A force of magnitude $P$ N acts on the block as shown in Figure 2.

The coefficient of friction between the block and the surface is 0.3.

Given that the block is on the point of sliding, calculate the magnitude of $P$ .

Diagram of a 6 kg block on a surface with friction coefficient 0.3. A force P N acts at 40° to the horizontal on the block. — **Figure 2**

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5 marks

A particle of mass 0.70 kg rests on a rough plane that is inclined at an angle of 35° to the horizontal, as shown in Figure 1.

Ball on a 35-degree inclined plane; force P N shown with an arrow parallel to the slope. — **Figure 1**

A force of magnitude $P$ N acts up the line of greatest slope of the plane and keeps the particle in equilibrium, on the point of sliding up the plane.

The coefficient of friction between the particle and the plane is $μ = 0.35$ .

Determine the value of $P$ .

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6 marks

A particle of mass 3 kg rests on a fixed rough plane that is inclined at 15° to the horizontal.

The coefficient of friction between the particle and the plane is 0.2.

The particle is released from rest and slides down the line of greatest slope of the plane.

Taking $g = 9.8 {ms}^{- 2}$ , calculate the distance the particle travels down the plane in the first 3 seconds of its motion.

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6 marks

A particle of mass 3 kg is projected up a fixed rough plane that is inclined at 25° to the horizontal.

The particle is launched up the line of greatest slope with initial speed $u$ ms^-1.

After travelling 1.91 m up the plane it comes to instantaneous rest.

The coefficient of friction between the particle and the plane is 0.27.

Determine the value of $u$ .

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7 marks

Figure 1 shows a box $B$ of mass 5 kg resting on a rough horizontal table. It is connected by a light inextensible string to a sphere $A$ of mass 2 kg. The string passes over a smooth light fixed pulley at the edge of the table so that $A$ is hanging vertically downwards as shown in Figure 1.

Diagram of a pulley system with a 5 kg block on a surface connected to a 2 kg hanging weight over a pulley. — **Figure 1**

The string between $B$ and the pulley is horizontal, and the coefficient of friction between $B$ and the table is 0.35.

The system is released from rest with the string taut.

As $A$ descends, calculate

(i) the initial acceleration of the two objects

(ii) the tension in the string.

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5 marks

Figure 1 shows a particle of mass $m$ kg hanging in equilibrium, suspended by two light inextensible strings. The strings are inclined at 25° and 70° to the horizontal, as shown.

Diagram of a force triangle with angles 25 and 70 degrees, dashed horizontal line, and mass "m kg" at the lower right corner. — **Figure 1**

Given that the tension in the string angled at 70° to the horizontal is 56 N, find the value of $m$ .

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10a

3 marks

Figure 1 shows a particle of mass 12 kg being pushed up a smooth slope by a force of 50 N that acts horizontally. The slope is inclined at $20 °$ to the horizontal.

Block on a 20-degree inclined plane with a 50 N force horizontal. — **Figure 1**

Calculate the acceleration of the particle up the slope.

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10b

2 marks

Calculate the normal reaction force of the slope on the particle.

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5 marks

A particle of mass 15 kg is sliding down a rough slope that is angled 25° to the horizontal.

The coefficient of friction between the particle and the slope is 0.3.

Calculate the acceleration of the particle down the slope.

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12a

3 marks

Figure 1 shows a particle being pulled up a smooth slope by a force of 60 N that acts at an angle of $15 °$ to the slope. The slope is inclined at $25 °$ to the horizontal, as shown.

Block on a 25-degree inclined plane with a force of 60 N at 15 degrees to the plane. — **Figure 1**

The particle experiences an acceleration of $0.3 m s^{- 2}$ up the slope.

Calculate the mass of the particle.

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12b

3 marks

Calculate the normal reaction force of the slope on the particle.

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13a

2 marks

Figure 1 shows two identical light cables attached symmetrically to a load of weight $W$ N.
Each cable is under the same tension $T$ N and meets the vertical at an angle $θ$ .

Diagram of forces on a hanging object with two tension forces, T, at angle θ from vertical, and weight, W, directed downwards. — **Figure 1**

The load is initially at rest. No forces other than its weight and the tensions in the two cables act on the system.

Write down an inequality for $W$ in terms of $T$ and $θ$ that must be satisfied if the cables are to start lifting the load.

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13b

2 marks

Using your result from part (a), or otherwise, show that when the cables are in a position such that $θ = 45$ , the upward acceleration of the load is still positive only if

$T > \frac{\sqrt{2}}{2} W$

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1a2 marks

A rough plane is inclined to the horizontal at an angle $α$ , where $\tan α = \frac{3}{4}$ .

A brick $P$ of mass $m$ is placed on the plane.

The coefficient of friction between $P$ and the plane is $μ$ .

Brick $P$ is in equilibrium and on the point of sliding down the plane.

Brick $P$ is modelled as a particle.

Using the model, find, in terms of $m$ and $g$ , the magnitude of the normal reaction of the plane on brick $P$ .

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1b4 marks

Show that $μ = \frac{3}{4}$ .

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1c1 mark

For parts (c) and (d), you are not required to do any further calculations.

Brick $P$ is now removed from the plane and a much heavier brick $Q$ is placed on the plane.

The coefficient of friction between $Q$ and the plane is also $\frac{3}{4}$ .

Explain briefly why brick Q will remain at rest on the plane.

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1d2 marks

Brick $Q$ is now projected with speed 0.5 ms⁻¹ down a line of greatest slope of the plane.

Brick $Q$ is modelled as a particle.

Using the model, describe the motion of brick $Q$ , giving a reason for your answer.

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4 marks

Diagram of an inclined plane with an angle labelled "α" and a block labelled "B". Arrow "XN" indicates horizontal force on the block, towards the slope. — **Figure 1**

A rough plane is inclined to the horizontal at an angle $α$ , where $\tan α = \frac{3}{4}$ .

A small block $B$ of mass 5 kg is held in equilibrium on the plane by a horizontal force of magnitude $X$ newtons, as shown in Figure 1.

The force acts in a vertical plane which contains a line of greatest slope of the inclined plane.

The block $B$ is modelled as a particle.

The magnitude of the normal reaction of the plane on $B$ is 68.6 N.

Using the model,

(i) find the magnitude of the frictional force acting on $B$ ,

(ii) state the direction of the frictional force acting on $B$ .

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6 marks

The horizontal force of magnitude $X$ newtons is now removed and $B$ moves down the plane.

Given that the coefficient of friction between $B$ and the plane is 0.5,

find the acceleration of $B$ down the plane.

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3a2 marks

Diagram of two masses, A (3m) on an inclined plane at angle α, and B (m) hanging vertically from pulley P. — **Figure 1**

A small stone $A$ of mass $3 m$ is attached to one end of a string.

A small stone $B$ of mass $m$ is attached to the other end of the string.

Initially $A$ is held at rest on a fixed rough plane.

The plane is inclined to the horizontal at an angle $α$ , where $\tan α = \frac{3}{4}$ .

The string passes over a pulley $P$ that is fixed at the top of the plane.

The part of the string from $A$ to $P$ is parallel to a line of greatest slope of the plane.

Stone $B$ hangs freely below $P$ , as shown in Figure 1.

The coefficient of friction between $A$ and the plane is $\frac{1}{6}$ .

Stone $A$ is released from rest and begins to move down the plane.

The stones are modelled as particles.

The pulley is modelled as being small and smooth.

The string is modelled as being light and inextensible.

Using the model for the motion of the system before $B$ reaches the pulley, write down an equation of motion for $A$ .

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7 marks

Using the model for the motion of the system before $B$ reaches the pulley, show that the acceleration of $A$ is $\frac{1}{10} g$ .

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3c2 marks

Using the model for the motion of the system before $B$ reaches the pulley, sketch a velocity-time graph for the motion of $B$ , from the instant when $A$ is released from rest to the instant just before $B$ reaches the pulley, explaining your answer.

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3d1 mark

In reality, the string is not light.

State how this would affect the working in part (b).

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7 marks

Figure 1 shows two particles $A$ and $B$ , of masses 4 kg and 3 kg respectively, connected by a light inextensible string.

Particle $A$ is held motionless on a rough fixed plane inclined at $35 °$ to the horizontal. The string passes over a smooth light pulley fixed at the top of the plane so that $B$ is hanging vertically downwards as shown in Figure 1.

Diagram of two points, A and B, connected by lines with angles. A is on a slope at 35 degrees; B hangs vertically. — **Figure 1**

The string between $A$ and the pulley lies along a line of greatest slope of the plane, and $B$ hangs freely from the pulley.

The coefficient of friction between particle $A$ and the plane is $0.15$ .

The system is released from rest with the string taut.

Calculate

(i) the initial acceleration of the two objects,

(ii) the tension in the string as $B$ descends.

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10 marks

After descending for 3.2 seconds, particle $B$ strikes the ground and immediately comes to rest. Particle $A$ continues to move up the slope until the forces of gravity and friction cause it to come momentarily to rest.

Find the total distance travelled by particle $A$ between the time that the system is first released from rest and the time that particle $A$ comes momentarily to rest again after $B$ has struck the ground.

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6 marks

Figure 1 shows a particle of mass 0.9 kg on a rough horizontal plane. A force of magnitude $P$ N is acting on the particle at an angle of 40° to the horizontal as shown.

Diagram showing a force vector P N at a 40-degree angle, acting on a sphere resting on a horizontal line, with dashed lines indicating components. — **Figure 1**

Given that the coefficient of friction between the plane and the particle is 0.3, and that the particle is on the point of sliding to the right under the influence of the force, find the value of $P$ .

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67 marks

A particle of mass $m$ kg is held at rest on a rough plane inclined at angle $θ °$ to the horizontal, where $45 ° < θ < 90 °$ .

The coefficient of friction between the particle and the plane is $μ$ .

The particle is then released.

Given that the particle remains motionless after it is released, show that $μ > 1$ .

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7 marks

A particle of mass 2 kg is projected up a rough plane which is inclined at an angle of 20° to the horizontal.

It is projected up the line of greatest slope with an initial velocity of $u m s^{- 1}$ , and it comes to instantaneous rest after moving a distance of 4.85 m up the slope.

The coefficient of friction between the particle and the slope is 0.2.

Find the value of $u$ .

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6 marks

A smooth bead $B$ of mass $m$ grams is threaded on a light, inextensible string.
The ends of the string are fixed at two points $A$ and $C$ , with $A$ vertically above $C .$

The section $A B$ of the string makes an angle of 35° with the vertical.

The section $B C$ of the string makes an angle of 55° with the vertical.

The bead is held in equilibrium by a horizontal force of 3 N acting towards the left, as shown in Figure 1.

Diagram with point B having a 3N force leftward. Angles ABC and BAC are 55° and 35° respectively. Line AC is vertical. — **Figure 1**

The only forces on the bead are its weight and the tensions in $A B$ and $B C$ .

Taking $g$ = 9.8 ms^-2, find the value of $m$ .

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7 marks

A particle of mass 0.8 kg is released from rest on a rough plane that is inclined at an angle $θ$ to the horizontal, where $\tan θ = \frac{2}{7}$ .

After 4 s the speed of the particle is 1.35 m s^-1.

Determine the coefficient of friction, $μ$ , between the particle and the plane.

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8 marks

Diagram of an inclined plane at angle α with block A (2m) on it. Block B (3m) is suspended by a pulley at point P. — **Figure 1**

Two blocks, $A$ and $B$ , of masses $2 m$ and $3 m$ respectively, are attached to the ends of a light string.

Initially $A$ is held at rest on a fixed rough plane.

The plane is included at angle $α$ to the horizontal ground, where $\tan α = \frac{5}{12}$ .

The string passes over a small smooth pulley, $P$ , fixed at the top of the plane.

The part of the string from $A$ to $P$ is parallel to a line of greatest slope of the plane.

Block $B$ hangs freely below $P$ , as shown in Figure 1.

The coefficient of friction between $A$ and the plane is $\frac{2}{3}$ .

The blocks are released from rest with the string taught and $A$ moves up the plane.

The tension in the string immediately after the blocks are released is $T$ .

The blocks are modelled as particles and the string is modelled as being inextensible.

Show that $T = \frac{12 m g}{5}$ .

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2 marks

After $B$ reaches the ground, $A$ continues to move up the plane until it comes to rest before reaching $P$ .

Determine whether $A$ will remain at rest, carefully justifying your answer.

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1c2 marks

Suggest two refinements to the model that would make it more realistic.

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10 marks

Two small particles $A$ and $B$ , of masses 2.7 kg and 2.2 kg respectively, are joined by a light inextensible string.

Particle $A$ is initially held at rest on a fixed rough plane that is inclined at 25° to the horizontal.

The string passes over a small smooth pulley at the top of the plane so that particle $B$ hangs freely and vertically below the pulley, as shown in Figure 1.

Diagram showing an incline at 25 degrees with a pulley at the top; mass A on the slope, connected to mass B hanging vertically. — **Figure 1**

The section of the string parallel with the plane lies along the line of greatest slope of the plane.

The coefficient of friction between particle $A$ and the plane is $μ$ .

The system is released from rest with the string taut.

Given that particle $B$ descends 1.82 m in the first 3 s after it is released, find the value of $μ$ .

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38 marks

A small particle is placed on a rough plane that can be set at different angles to the horizontal.

The plane is first inclined at an angle $θ_{1}$ where $0 ° < θ_{1} < 90 °$ . The particle is released from rest and remains at rest on the plane.

The angle of the plane is then increased to angle $θ_{2}$ where $θ_{1} < θ_{2} < 90 °$ . The particle is again released from rest, and this time it begins to slide down the line of greatest slope of the plane.

The coefficient of friction between the particle and the plane is $μ$ .

Show that

$\tan θ_{1} \leq μ < \tan θ_{2}$

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9 marks

A particle of mass 0.5 kg rests on a fixed rough plane that is inclined at 35° to the horizontal as shown in Figure 1.

Diagram of a ball on an inclined plane. A 6N force acts on the ball. The incline forms a 35° angle with the horizontal. An unknown angle θ is shown between the slope and the 6 N force. — **Figure 1**

A force of 6 N acts on the particle in the same vertical plane as the line of greatest slope of the plane.

The line of action of the force makes an acute angle $θ$ with the plane, as shown.

The coefficient of friction between the particle and the plane is 0.4.

The particle is on the point of sliding up the plane.

Calculate the value of $θ$ .

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10 marks

A particle of mass $m$ kg is projected up a rough plane which is inclined at an angle of $θ °$ to the horizontal.

It is projected up the line of greatest slope with an initial velocity of $u$ metres per second, and it comes to instantaneous rest in $t_{1}$ seconds after moving a distance of $s$ metres up the slope.

The coefficient of friction between the particle and the slope is $μ$ .

Show that:

(i) $t_{1} = \frac{u}{g (\sin θ + μ \cos θ)}$

(ii) $s = \frac{u^{2}}{2 g (\sin θ + μ \cos θ)}$

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7 marks

After coming to instantaneous rest, the particle begins to slide back down the slope, and after $t_{2}$ seconds it has returned to its starting point.

Find an expression for $t_{2}$ in terms of $u, g, μ and θ$ .

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6a13 marks

A group of scientists have landed on the planet Hephaestia, where the gravitational constant of acceleration $g$ has a different value than it does on Earth.

Their spaceship contains a device which may be used to find the value of $g$ on any planet.

In this device a particle $A$ with mass $m_{A}$ kg is connected by a light inextensible string to a light scale-pan.

A force meter $C$ with mass $m_{C}$ kg is placed in the scale-pan, and a small block $B$ with mass $m_{B}$ kg is placed on top of $C$ .

$A$ is held in place on a rough plane angled at $θ °$ to the horizontal.

The coefficient of friction between $A$ and the plane is $μ$ .

The string passes over a smooth light pulley fixed at the top of the plane so that the scale-pan is hanging vertically below as shown in Figure 1 below.

Inclined plane with angle θ, a ball labelled A on it, and a pulley system with a lift containing blocks B and C where B is stacked on top of C — **Figure 1**

With the string between $A$ and the pulley lying in the line of greatest slope of the plane, $A$ is projected down the plane with a velocity of $v m s^{- 1}$ parallel to the string.

After a time of $t$ seconds the system comes momentarily to rest, and then the scale-pan begins to descend under the force of gravity, pulling mass $A$ up the slope behind it.

When the scale-pan is initially moving upwards, the force exerted by $B$ on $C$ is denoted by $F_{B C ↑}$ .

When the scale-pan begins to descend, the force exerted by $B$ on $C$ is denoted by $F_{B C ↓}$ .

The force meter $C$ is only able to record the difference, $Δ F$ , between these two values, where $Δ F = F_{B C ↓} - F_{B C ↑}$ .

Use the above information to show that

$Δ F = (\frac{2 m_{A} m_{B}}{m_{A} + m_{B} + m_{C}}) g μ \cos θ$

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2 marks

For the scientists' ship’s device the following values apply.

$\begin{array}{rcl} m_{A} & = & 3 \\ m_{B} & = & 1 \\ m_{C} & = & 2 \\ θ & = & 30 \\ µ & = & 0.4 \end{array}$

Find the value of $g$ on Hephaestia (the planet they are visiting), given that the value recorded for $Δ F$ is 1.286 N. Give your answer to 4 significant figures.

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15 marks

Two particles $A$ and $B$ , of identical mass, are connected by means of a light inextensible string.

Particle $A$ is held motionless on a rough fixed plane inclined at 30° to the horizontal. This plane is connected at its top to another rough fixed plane which is inclined at 70° to the horizontal.

The string passes over a smooth light pulley fixed at the top of the two planes so that $B$ is hanging downwards in contact with the second plane. This situation is shown in Figure 1.

Diagram of two connected rods forming angles of 30 and 70 degrees with the ground, showing points A and B. Particle B is 0.75 metres above ground level. — **Figure 1**

The parts of the string between $A$ and the pulley and between $B$ and the pulley each lie along a line of greatest slope of the respective planes.

The coefficient of friction between the particles and the planes is 0.15 in both cases.

The system is released from rest with the string taut, and with particle $B$ a vertical distance of 0.75 m from the ground.

Particle $B$ descends down the slope until it reaches the ground, at which point it immediately comes to rest. Particle $A$ continues to move up the slope until the forces of gravity and friction cause it to come momentarily to rest.

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Resolving Forces, Inclined Planes & Friction (Edexcel A Level Maths: Mechanics): Exam Questions

Quantities & Units in Mechanics

Quantities, Units & Modelling

Working with Vectors

Kinematics

Graphs in Kinematics

Variable Acceleration in 1D

Constant Acceleration in 1D

Variable Acceleration in 2D

Constant Acceleration in 2D

Projectiles

Forces & Newton's Laws

Forces & Equilibrium

Newton's Second Law (F=ma)

Resolving Forces, Inclined Planes & Friction

Moments

Moments