* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Forces & the Laws of Motion
Survey
Document related concepts
Transcript
QOD What is force? Forces & the Laws of Motion Physics I Mr. Padilla Aristotle (~400 B.C.) Divided motion into 2 types Natural Violent Natural – Straight up or straight down. Objects seek their “natural” resting place Clouds – Up Rocks – Down Heavens – Perfect Circles around Earth Violent – imposed motion A result of forces that pushed or pulled. Had an external cause. These ideas held for about 2000 years. Copernicus (1473-1534) Nicholas Copernicus was the first to reason that the Earth & planets moved around the sun. Heavily persecuted for his ideas and worked in secret to hide them. His work was published for the first time on the day he died. Galileo Believed Copernicus and so was placed under house arrest Force – any push or pull Friction – any force that acts between materials as they move past each other Only when friction is present is a force needed to keep an object in motion Discredited Aristotle’s ideas of motion Changes in Motion Forces can act through contact or at a distance Contact forces – result from the physical contact between 2 objects. Ex: Jordan pushes Kevin Field forces – does not involve physical contact. Ex: Gravity, electric fields Field forces were developed to explain how an object can exert force on another without touching. Newton Newton’s 1st Law of Motion Every object continues in a state of rest, or of motion in a straight line at a constant speed, unless it is compelled to change that state by forces exerted upon it. An object in motion stays in motion, an object at rest stays at rest. AKA law of inertia Inertia in Action Inertia: the reluctance of any body to a change in the state of motion. Book on a table Air hockey table Table cloth & dishes Where would they go? Ball thrown in outer space Car without a driving force Planets without the sun’s gravity Mass vs. Weight The inertia of an object depends on its mass How much material is in the object The more mass = more inertia Mass is a measure of the inertia of an object. Mass is not weight. Weight – force of gravity of an object Weight can change in different environments: mass, and therefore inertia, remain constant. Mass & Weight are proportional. Weight Weight can be calculated by taking an objects mass times gravity The SI unit for weight is W = mg kg (x) m/s2 = kgm/s2 or Newtons (N) A mass of 1kg has a weight of 9.8N, or 2.2lbs Mass Example Felicia, the ballet dancer, has a mass of 45.0 kg. a) What is Felicia’s weight on Earth? b) What is Felicia’s mass on Jupiter, where acceleration due to gravity is 25.0 m/s2? c) What is Felicia’s weight on Jupiter? Net force Force is a vector quantity. Has magnitude and direction. Net force – When considering Newton’s 1st Law, you must think of net forces not just forces. Net Force – combination of all forces acting on an object. All individual forces can be added and treated as a single (net) force FBD A free body diagram can be drawn to represent the forces acting on an object. A FBD shows vectors for forces acting on a single object Equilibrium What forces act on a book at rest on a table? If the net force acting on an object is zero, it is in equilibrium. At least 2 – weight and a support (normal) force No change in state of motion. Normal force – always acts at a right angle to the surface. QOD Determine your weight, in Newtons, on the other planets in our solar system. Mercury 3.59 m/s2 Venus 8.87 m/s2 Mars 3.77 m/s2 Jupiter 25.0 m/s2 Saturn 11.08 m/s2 Uranus 10.67 m/s2 Neptune 14.07 m/s2 Acceleration So far: a = ΔV/t This is the definition of a The cause of acceleration is force. Applying a force (or net force) to an object causes it to accelerate More force causes more acceleration (direct) Mass resists the acceleration more mass causes less acceleration (inversely) 2nd Law Acceleration produced by a net force on an object is directly proportional to the magnitude of the net force, is in the same direction as the net force, and is inversely proportional to the mass of the object. Or a ~ (net force)/mass Better yet… Fnet = ma a = F/m Examples A force of 30.N is applied to a 12kg mass, how fast does it accelerate? How much force is needed to accelerate a 700.kg vehicle at a rate of 4.0m/s2? F = ma 30.N = 12kg(a) a = 30N/12kg a = 2.5 m/s2 F = ma F = (700.kg)(4.0m/s2) F = 2800N More Great Examples Ben and Sam push on opposite sides of Chris. Ben pushes with 400.N of force, Sam with 200.N. What is the net force on Chris? If Chris has a mass of 75kg, what will his acceleration be? A constant force exerted on an object, will result in what kind of motion? Fnet = ΣF acting on Chris F = ma Fnet = 400.N – 200.N Fnet = 200.N 200N = (75kg)a a = 200N/75kg a = 2.7 m/s2 Constant force produces constant acceleration. Free Fallin’ In a vacuum all things fall at the same rate due to gravity. In reality, air resistance provides friction and causes some things to slow down. All objects reach a point where the force of gravity pulling them down is equal to the force of air resistance pushing back on them. This is called terminal velocity. Humans = 150-200 km/h in free fall 15-20 km/h with a parachute. Forces Forces are not a thing by themselves, but part of an interaction. Forces always occur in pairs. One force is called the action force, the other is called the reaction force. Newton’s Third Law Whenever one object exerts a force on a second object, the second object exerts an equal and opposite force on the first object. To every action, there is an equal and opposite reaction. Action/Reaction Pairs When a hammer hits a nail, which is the action and which is the reaction force? Identify the action/reaction forces when you walk. Action: Object A exerts force on object B Reaction: Object B exerts force on object A Different Masses Forces objects exert on each other are always equal in strength and in opposite directions. Newton’s second law (F=ma) still applies. If the masses are greatly different, then the object with the smaller mass will undergo greater acceleration. A gun with a mass of 20kg shoots out a .04kg bullet. The gun kicks back at .2m/s2, at what rate does the bullet accelerate? F=F ma = ma (20kg)(.2m/s2) = (.04kg)a 4N = (.04kg)a 100m/s2 = a Examples Calculate the kick of a 50kg cannon that shoots a 3kg cannonball out with an acceleration of 12m/s2. Action - Reaction A car accelerates along a road. Strictly speaking, what is the force that moves the car? We know that Earth pulls on the moon. Does the moon also pull on the Earth? If so, which pull is stronger? Can you identify the action and reaction forces of an object falling in the vacuum of outer space? Cancellation Do action/reaction forces cancel each other out? Create a system to determine net force on an object. Ex: Boy on a skateboard, pulling against a girl standing on the ground. Draw systems, identify action reaction forces. Friction Friction is a force that affects motion. It acts when materials are in contact with one another and always opposes motion. Friction is due to the irregularities in the two surfaces. Constant speed = no net force so friction = driving force Different surfaces have different amounts of friction between them (μ) Friction is not restricted to solids , it also occurs in fluids This can be felt even at slow speeds Air resistance is friction acting on something moving through air. Friction Two types of Friction Static friction (Fs) Restrictive Fs force when object is not in motion = -Fa Kinetic friction (Fk) Restrictive force when object is in motion Net external force acting on an object is equal to the difference between applied force and force of kinetic friction F - Fk Kinetic friction is less than static friction. Friction The force of friction is proportional to the normal force. Easier to push a chair across the floor at a constant speed than to push a heavy desk at the same speed. Coefficient of Friction is a Ratio of Forces Defined as the ratio between the normal force and the force of friction between two surfaces. Coefficient of Kinetic Friction μk = Fk Fn Coefficient of Static Friction μs = Fs,max Fn If the value of μ and the normal force on the object are known, then the magnitude of the force of friction can be calculated directly. Ff = μFn Coefficients of Friction Material steel on steel Aluminum on steel Rubber on dry concrete Rubber on wet concrete Wood on wood Glass on glass Waxed wood on wet snow Waxed wood on dry snow Metal on metal (lubricated) Ice on ice Teflon on teflon Synovial joints in humans μs 0.74 0.61 1.0 ----0.4 0.9 0.14 ----0.15 0.1 0.04 0.01 μk 0.57 0.47 0.8 0.5 0.2 0.4 0.1 0.04 0.06 0.03 0.04 0.003 Air Resistance is a form on friction Whenever an object moves through a fluid medium (air or water), that fluid provides a resistance to the object’s motion. Car at low speed = FR is roughly proportional to the car’s speed in the opposite direction Car at higher speed = FR is roughly proportional to the square of the car’s speed in the opposite direction When the magnitude of FR equals the magnitude of the force moving the car forward, the net force is zero and the car moves at a constant speed. Examples A 24 kg crate initially at rest on a horizontal floor requires 75 N horizontal force to set it in motion. Find the coefficient of static friction between the crate and the floor. A student moves a box of books by attaching a rope to the box and pulling with a force of 90.0 N at an angle of 30.0o. The box of books has a mass of 20.0 kg, and the coefficient of kinetic friction between the bottom of the box and the sidewalk is 0.50. Find the acceleration of the box. Ch. 4 Mixed Review Answers 45. 55 N to the right 47. 13 N down the incline 49. a. 2.00 N b. 6.04 N 51. a. 0 b. 33.9 N 53. 50. m 55. a. 1.78 m/s2 b. 0.367 c. 9.36 N d. 2.67 m/s 57. 510 N 59. 32.2 N 61. 1.41o 63. a. 20. m/s2 to the rt. b. F1 = 40. N F2 = 60. N F3 = 80. N c. m2 by m1 = 140 N m1 by m2 = -140 N m3 by m2 = 80. N m2 by m3 = -80. N 65. a. between the bottom block and the table. b. 0.47