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Transcript
Lecture 3 Newton’s laws Forces Friction NEWTON’S THIRD LAW If one object exerts a force on a second object, the second object exerts a force back on the first that is equal in magnitude and opposite in direction. “For every action there is an equal and opposite reaction” Freaction of the table object table Fweight object Faction Magnitude of force Fweight object = Freaction table Freaction Application: Newton’s 2nd Law Fa Define system and external force System 1 (trolley, patient, and attendant): External force provided by the floor: reaction to the force the attendant exerts on the floor. System 2 (trolley with patient): External force provided by the attendant. define the system and determine the external forces Application: system & external force Mass of patient = 50 kg Mass of trolley = 20 kg Mass of attendant=85 kg Fa Mass System 1 = 155 kg Mass System 2 = 70 kg 1/ If the attendant exerts a force of 100 N on the floor, what is the magnitude of acceleration of the trolley and of the attendant? System 1: F=ma 100 N = (Mass System 1)a a = 100N/155kg = 0.645 ms-2 Application: system & external force Mass System 2 = 70 kg Fa 2/ What force does the attendant then exert on the trolley? System 2: Fattn = (Mass System 2)*a = (70kg)(0.645ms-2) = 45.2 N 3/ Why is the force exerted by the attendant on the floor bigger than the force he exerts on the trolley? Because he also accelerates. Mass of attendant = 85 kg F=ma = 85kg.0.645ms-2=54.8N Adding Forces F is the Resultant force F1 F=F1+F2 “co-linear” F2 Length of arrow represents magnitude of force “perpendicular” F2 Magnitude Direction In general F q F1 F F12 F22 F2 tan q F1 * F2 q tan F1 1 we use vectors or graphical method to determine the resultant force Projection of a force Often need to split a force into two perpendicular components. Projection parallel to the plane a mgCosa a W=mg F2 Projection perpendicular to the plane Cosa = F1/mg a F1 w=mg Sina = F2/mg F1 = mgCosa F = mgSina 2 Example A gardener pushes a lawnmower with a force of 500N directed along its handle which makes an angle of 60º with the ground in order for it to move at a constant velocity. Determine (a). The component of this force which is directed horizontally H, in order to overcome the frictional forces and maintain a constant velocity, and, (b). the component of the force which is directed vertically downwards, V . Use method of components 500N V 600 H H = 500 cos600 = 250N V =500Sin600 = 433N Classes of Forces WEIGHT (w=mg) due to gravity w=mg N=w=mg NORMAL FORCE (N) normal to a plane w = mg FRICTION (f ) parallel to a plane f TENSION (T) is any force carried by a flexible string, rope etc. acts all along the string F T= w w Normal Force The normal force is the reaction by the plane to the perpendicular (or normal) component of force applied. N=mg W=mg a mgCosa Origin: Plane deforms under a W=mg load. The elastic force attempting to restore the plane to its original shape is the “normal force”. EXAMPLE A constant horizontal force F = 4N to the right, is applied to a box of mass 2kg resting on a level, frictionless surface. What is the acceleration of the box? Let the x axis (right) and y axis (up) be the positive directions. We assume the positive x axis is the direction of the force. Mark the forces acting on the box in the diagram. There are three forces acting on this box 1. The force F pulling the box 2. The weight (w) of the box 3. The normal reaction (N) (The third law says that if the box pushes down on the table, the table pushes up on the box) Exercise: Two children pull in opposite directions on a toy wagon of mass 8.0kg. One exerts a force of 30N, the other a force of 45N. Both pull horizontally and friction is negligible. What is the acceleration of the wagon? N=mg System: the toy wagon; x positive to the right Fext, net F2=45N F1=30N w=mg =F2 - F1 = 45N - 30N = 15N (right) a = Fext, net/m = (15/8)ms-2=1.875ms-2 to the right Biting Force Force between bottom and top teeth Bite-force estimation for Tyrannosaurus rex Nature 382, 706 - 708 (22 August 1996); 6,410 N to 13,400 N Muscles in the human jaw can provide a typical biting force of ≈ 600N muscle pivot force Biting Force Average maximum human biting force ≈ 750 N Biting force varies depending on region of mouth Molar region 400-850 N Premolar region 220-440 N Cuspid region 130-330 N Incisor region 90-110 N force Energy of a bite is absorbed by Food Teeth Periodontal ligament bone Tooth design is such that it can absorb large static and impact energies Applications of Newton’s Laws Friction is a force that always acts to oppose the motion of one object sliding on another. Friction is a contact force resulting from surface roughness Surfaces slide over each other, rough bits catch each other and impede the motion. Surfaces not perfectly smooth. Schematic showing the nature of forces on a very small (atomic) scale. Surface roughness results in frictional forces Applications of Newton’s Laws The normal reaction force, N, is described by Newton’s third law. The third law says that for every force there is an equal but opposite force. Friction and Normal reaction force are two types of contact forces If one object is sliding on another, the frictional force, F, always acts in the direction opposed to the motion, the normal force always acts in a direction perpendicular to the surface. Applications of Newton’s Laws Imagine an object lying on a frictional surface and a very small horizontal force, A, acts on it. The force diagram is drawn as follows. N A F W The forces acting on the object are its weight w, the normal force N, the frictional force F and the applied force A. Applications of Newton’s Laws To a good approximation the frictional force (F) of an object on a surface is proportional to the normal force of the surface on the object F N F = µN where the constant of proportionality is known as the Coefficient of friction µ. The most familiar thing about friction is that the heavier an object the greater the friction. It is more difficult to slide a full box than an empty one. Large force required to move heavy object N=mfg Wf=mfg Small force required to move light object N=meg We=meg Kinetic Friction Kinetic friction is the force that opposes motion due to physical contact between substances, and is parallel to the contact surfaces. It is proportional to the normal force: F= kN k is the coefficient of kinetic friction (between moving substances) N=mg F= kN A w=mg Const. speed: (A=F) Acceleration: (A>F) Deceleration: (A<F) Static Friction Static friction is the force that prevents motion due to physical contact between substances, and which is parallel to the contact surface. F=A A It behaves like the normal force: F=A up to a maximum of sN s is the coefficient of static friction (between immobile substances) If A< sN: static friction prevents motion If A> sN: static friction isn’t strong enough motion kinetic friction. Generally k < s Applications of Newton’s Laws Friction– Graphical representation F Fs,max = sN F = kN A Static Kinetic Values of coefficients of friction s and k depend on the nature of the surfaces Typically 0<k<s<1 Typical values for coefficient of static friction s of some substances Rubber on concrete s = 1 Synovial joints s ≈0.016 EXAMPLE You press a book flat against a vertical wall. In what direction is the frictional force exerted by the wall on the book? F (a)downward (b) upward (c) into the wall H N (d) out of the wall w EXAMPLE A crate is sitting in the centre of a flatbed truck. The truck accelerates eastwards, and the crate moves with it (not sliding on the bed of the truck). In what direction is the frictional force exerted by the bed of the truck on the crate? (a)to the west (b) to the east (c) there is no frictional force because the crate does not slid Friction Dental considerations Abrasion Abrasion or wear due to surface roughness Dental restorations and appliances should have smooth surfaces Abrasive resistance of material depends on Hardness Surface roughness Example Excessive wear of tooth enamel by opposing ceramic crown caused by High biting force Rough ceramic surface Remedy Adjust occlusion•broader contact areas---reduces stresses Polish ceramic to reduce abrading surface Friction Lubrication in the mouth is provided by saliva Saliva greatly reduces the frictional force and helps prevent excessive wear of teeth Saliva reduces friction force by up to a factor of 20. Lubricating properties of saliva are maintained over the range of jaw biting forces (0→600N) muscle pivot force Reduced friction→ reduces wear ensures good contact between opposite teeth is not impaired and surfaces used for chewing are maintained. Saliva, also protects the tongue and other soft tissues inside the mouth EXAMPLE A crate slides at constant velocity down a plane inclined at an angle a to the horizontal. If the coefficient of kinetic friction between the surfaces of the crate and the plane is 0.6, determine the angle a. a mgCosa a W=mg F k N k mgCosa F k N mgSina Constant velocity mgSina k Tana k mgCosa mgSina mgCosa a tan 1 k tan 1 0.6 310 EXAMPLE You need to move an object across a horizontal surface by pushing it. Its mass is 50kg and the coefficients of friction are µs=0.5 and µk=0.4. How much force A do you have apply horizontally to a) get it moving? b) To keep it moving? When the object is stationary the friction that impedes motion is determined by µs. The forces on the box are outlined below N = mg Fmax = sN A w=mg The object will start to move when the applied force A becomes very slightly greater than the maximum frictional force Fmax=µsN. For our purposes we will say this happens when A=Fmax