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CfE Higher Physics

CfE Higher Physics. Unit 1 Our Dynamic Universe Newton’s Laws. Learning Intentions. To analyse the motion of an object using free body diagrams and Newton’s first and second laws. To be able to carry out calculations using Newton’s second law (F=ma) in one direction only. Newton I.

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CfE Higher Physics

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  1. CfE Higher Physics Unit 1 Our Dynamic Universe Newton’s Laws

  2. Learning Intentions • To analyse the motion of an object using free body diagrams and Newton’s first and second laws. • To be able to carry out calculations using Newton’s second law (F=ma) in one direction only.

  3. Newton I “An object remains at rest or continues to move at constant speed in the same direction unless acted upon by an unbalanced force.” Newton II F = ma

  4. Newton II and

  5. F a = m Newton II(continued) Since the unit of force, the newton, is defined as the force that will accelerate a mass of 1 kg at 1 ms-2 we can write: or, more commonly: F = ma

  6. Common Forces There are many different names used for different forces. These are some examples: Thrust, Th - force from an engine or rocket Weight, W - downward force due to gravity (W=mg) Friction, Fr - force opposing motion Tension, T - pulling force of string, rope, cable or chain Buoyancy, B - upward force due to floatation Lift, L - upward force generated by wings or rotors Reaction, R - force of contact from a surface (always at right angles to the surface)

  7. Friction • Friction is a force that opposes motion. • It always acts in the opposite direction of an action. • If you want to find the resultant force (the direction and force the block will move) then you simply take away the friction from the pull force: Resultant = 6N – 2N = 4N right Friction 2N Pull force 6N

  8. Air resistance (drag) Terminal Velocity In free-fall – unbalanced forces Weight > drag • Terminal velocity is when an object is in free-fall and reaches its maximum velocity. • Before, the object in free-fall would be accelerating constantly due to gravity (-9.8 ms-2). The forces are unbalanced. • Eventually, the object reaches it’s maximum velocity. This is known as its terminal velocity. • During terminal velocity, the forces acting on the object are balanced. Weight Air resistance (drag) Terminal velocity – balanced forces Weight = drag Weight

  9. R R T Th Fr Fr W W Resolving Forces • From National 5, you would have been able to use Newton’s second law linearly and vertically. • It is important in higher that you use free body diagrams for ALL forces problems. This will help you visualise the problem and the forces! For example: A car driving along a road A skier on a ski tow

  10. Resolving Forces Linearly • Linearly, the forces acting on an object would be: • Friction • The Unbalanced force • Any other external force applied to the object • Example: • A block moving with a constant acceleration of 1 ms-2 Pull force Friction a= 1 ms-2 Unbalanced force = pull force – force of friction

  11. Reaction Weight Resolving Forces vertically - lift Once a free body diagram has been drawn the forces acting in a particular direction can be ‘resolved’. For example: A person in a lift Resolving upwards: R - W = ma The rest of the problem can then be solved numerically.

  12. Resolving Forces Vertically - Rocket Thrust Weight

  13. Example Weight = mass x gravity Thrust

  14. Example

  15. Success Criteria • I can analyse the motion of an object using free body diagrams and Newton’s first and second laws. • I can carry out calculations using Newton’s second law (F=ma) in one direction only.

  16. Learning Intentions • To be able to work out resultant forces for objects that are tied together and in contact.

  17. Objects tied together • Below the tractor and the trailer are moving at a constant velocity. • This means that the forces of the tractor and the trailer are balanced. • This means that the Thrust produced by the engine of the tractor, is equal and opposite to the frictional forces.

  18. Objects tied together The forces on the tractor and trailer are balanced because the thrust and frictional forces are equal and opposite.

  19. Objects tied together • The tractor is now accelerating at a constant rate. • Because the tractor is accelerating, the thrust of the tractor’s engine and the frictional forces are now unbalanced. There is an unbalanced force acting on the tractor and the trailer.

  20. Objects tied together • IF we assume the frictional forces are the same, we can work out that the unbalanced force is equal to the thrust minus the friction.

  21. Objects tied together • The trailer in this example is held by a coupling. The trailer is attached to the tractor, so it must have the same acceleration as the tractor. • There is an unbalanced force acting on the trailer through the tow bar. • The total force exerted through the tow bar is also known as the TENSION, and in this case, the tension is greater than the frictional forces acting on the trailer. • In general: Unbalanced force = Tension – Friction Tension = unbalanced force + friction

  22. Example Problem 1 Two blocks, connected by a string, are being pulled along a horizontal surface. Their motion is uniform acceleration. The force applied to the right hand 10kg block is 10 N and the frictional force acting on each block is 2 N. • What is the acceleration of the two blocks? • What is the tension in the string?

  23. Worked Answer

  24. Worked Answer

  25. R Th Frtrailer Frtractor W Worked Example 2 A 2,000 kg tractor is towing a trailer of mass 1,200 kg. The tractor can generate an engine force of 6,500 N and the frictional forces on the tractor and trailer are 800 N and 600 N respectively. a) Calculate the maximum acceleration of the tractor and trailer? Resolving horizontally: Th - Frtractor - Frtrailer = ma 6,500 - 800 - 600 = (2,000 + 1,200) a 5,100 = 3,200 a a = 1.59 ms-2

  26. R T Frtrailer W Worked Example 2(continued) b) Calculate the tension in the coupling between the tractor and trailer? Trailer only Resolving horizontally: T - Frtrailer = ma T - 600 = 1,200(1.59) T = 1,908 + 600 T = 2,508 N

  27. Objects in contact • For two blocks in contact, a similar approach is used. • There are only two acting on the 8 kg block, but 3 acting on the 4 kg block. • Determine the force exerted BY the 4 kg block on the 8 kg block. • Find the acceleration of the whole system. • Consider the forces acting on the 8 kg block ONLY.

  28. Objects in Contact example (a) Find the force exerted by the 4 kg block on the 8 kg block. (b) Find the acceleration of the blocks. (a)On 8 kg block, the forces are: • Friction total = 3N • Force of 4 kg on 8 kg = push force – force of friction = 6N

  29. Objects in Contact example

  30. Objects in Contact tips • Always consider the forces on the mass that is furthest away from the push or pull force. This is because there are only two forces acting on it – The force of friction and the pull or push force. • For the other block, there are three forces acting on it – the force of friction, the push force and the unbalanced force of the other mass on it. • Always get the total mass of the system when finding the acceleration. • Always take away friction from the push or pull force to get the resultant.

  31. Success Criteria • I am able to work out resultant forces for objects that are tied together and in contact.

  32. Resultant Forces at an angle • When objects are pulled at an angle, like below, they can be resolved into horizontal and vertical components – just like projectiles:

  33. Resultant Forces at an angle • If the whole pull force was to act in the horizontal direction, there would be no vertical force. i.e. if you decrease the angle horizontally, the horizontal component of force would equal the pull force.

  34. Resultant Forces at an angle • If the whole pull force was to act in the vertical direction, there would be no horizontal force. i.e. if you increase the angle vertically, the vertical component of force would equal the pull force.

  35. Resultant Forces at an angle • But what do the horizontal and vertical forces depend on? • The angle – theta, which is the angle to the horizontal. • For example, below we have made theta = 30 degrees and the force being pulled 100N: • Resolve the vector from tip to tail!

  36. Resultant Forces at and angle

  37. Resultant Force at an Angle The bigger the angle, the smaller the horizontal force, but the bigger the vertical force.

  38. Resultant Force at an Angle The bigger the angle, the smaller the horizontal force, but the bigger the vertical force.

  39. Learning Intentions To be able to: • Resolve the forces for a lift at rest, accelerating and decelerating • Resolve the forces for people in a lift that is at rest, accelerating and decelerating. • Resolve the forces for a person in a lift on newton scales that is at rest, accelerating and decelerating.

  40. Forces on a Lift • When a lift is or isn’t in operation, there are two forces that act on it: Tension in the cable Weight

  41. Forces on a Lift • When the lift is at rest or travelling at a constant velocity, the forces of the tension and weight are balanced: Tension in the cable Tension = weight Weight

  42. Forces on a Lift • When the lift is accelerating upwards or decelerating down, you can simply treat the lift as if it is a rocket (the unbalanced force must overcome gravity so must be bigger): Tension in the cable Weight

  43. Forces on a Lift • When the lift is accelerating down or decelerating up, you can simply treat the lift as if it is a rocket (the unbalanced force is small because it is going in the same direction as gravity): Tension in the cable Weight

  44. Forces on a Lift • Going UP: The unbalanced force must be greater than the tension and the weight as it is going against gravity. • Going DOWN: The unbalanced force is smaller, because it is going down with gravity. Tension in the cable Weight

  45. Forces on a Lift – person in lift • When the lift has a person or object in it and is at rest or travelling at a constant velocity, the forces of the tension and weight of both the person and lift are balanced: Tension in the cable Tension = weight of lift + weight of person in lift Weight

  46. Forces on a Lift – person in lift • When the lift is accelerating upwards/decelerating down: Tension in the cable Tension > weight of lift + weight of person in lift Weight

  47. Forces on a Lift – person in lift • When the lift is accelerating down/decelerating up: Tension in the cable Tension < weight of lift + weight of person in lift Weight

  48. Forces on a Lift – person in lift on scales • When the lift is at a constant velocity or not moving, the reading on the scale: Weight of person = Reaction force Reaction Weight

  49. Forces on a Lift – person in lift on Newton scales • When the lift is accelerating up or decelerating down: Reaction force > Weight Reading on scales is smaller Reaction Weight

  50. Forces on a Lift – person in lift on Newton scales • When the lift is accelerating down or decelerating up: Reaction force < Weight Reading on scales is bigger Reaction Weight

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