Forces Forces • Shows all forces as vectors acting on an object • Push or pull on an object • Causes acceleration • Measured in Newtons N = Contact Forces Applied Force Frictional Force Tensional Force Normal Force Drag Force Spring Force Free Body Diagrams • Vectors always point away from object Kg m s2 • Used to help find net force Field Forces Gravitational Force Electrical Force Magnetic Force FN Fpull Ff Fg 1 Find the unknown forces!! Ex. 1 100 N Ex. 2 2 Newton’s First Law Law of Inertia – Resistance to change motion FA • Objects in motion stay in motion 75 N • Objects at rest stay at rest 50 N Fnet = ? Fnet = 10 N Downward Equilibrium – balanced forces, net force = 0 Fnet = 100N – 75 N Fnet = FA – 50 N = ‐10 N Net force – sum of all forces Fnet = 25 N Upward FA = 40 N 3 Newton’s Second Law Drag Force A net force will cause acceleration • “friction” force from a fluid (gases and liquids) mass Terminal Velocity – constant velocity of falling F = ma force Gravity force → 4 when Fdrag = Fg acceleration F = mg Mass and weight are not the same!!! 5 6 1 Forces Newton’s Third Law Solving Tips • Each action has an opposite and equal reaction FA on B = ‐ FB on A 1. Draw the problem and choose coordinates • Interaction Pair – action / reaction forces 2. Determine known and unknown forces. 3. Create a free‐body diagram showing the net force. 4. Use Newton’s laws to link acceleration and net force. 5. Solve equations for the unknowns 7 8 Combining Forces Normal Force +X FN = mg FN = mg + Fhand FN = mg ‐ Fstring 9 10 Friction Factor Friction Force • Always against motion • Two branches of friction (3 Types) – Kinetic (Moving) • Sliding • Rolling – Static (Stationary) • Friction of fluids is called viscosity Kinetic Friction Ff = k Fn = friction factor Fn = Normal Force Static Friction Ff,static ≤ s Fn 11 12 2 Forces Static Friction Fn Fn • The force of static friction is not constant! Static FFriction • The maximum static friction is equal q to sFn Ff,static,max ≥ Fapplied → stays still Ff,k Ff,s Kinetic FFriction • Static friction is equal to pulling force until the object begins to move Ff Ff = sFn, Ff,s,max Ff = kFn, Ff,static,max = Fapplied → constant speed, a=0 Ff,static,max ≤ Fapplied → accelerates FApplied 13 14 Static Friction and Motion Thrust from Friction What is the maximum acceleration a car can achieve if the tires/road friction coefficient is equal to 0.7? Fn (ignore drag) FDrag Fnet,x = Fthrust ‐ Fdrag = ma Fthrust Fg The h maximum thrust h cannot exceed d road d friction f Fthrust = Ff,s,max = sFn= s mg From Fnet,x ma = s mg a = s mg = (0.7)(9.8m/s2) = 6.9m/s2 15 16 Static Equilibrium Static Equilibrium The most important rule: ALWAYS FOLLOW THESE STEPS: F = 0 This means that: Fx = 0 and 1. Draw a labeled free body diagram 2. g forces into components p Break angled 3. Write net equations ( Fnet,x = … ) Fy = 0 Only use the components of angled forces!! Fnet,x = 0 and Fnet,y = 0 4. 17 Solve for unknowns one at a time 18 3 Forces Vector Direction ( 2 Common Ways) Working with Forces at an Angle • Labeled degrees north or south of x‐axis • Degrees from east direction (0°). 80° N of East 45° S of East O 80° Or 30° N of West O 315° Or O 150° Or When a force is at an angle: •break into x and y components –Do not use the original force again!! •Add x and y components separately •Find the new resultant force and its angle 80° 30° 45° O A = Tan‐1 F = Fx2+Fy2 Using the angle from the x‐axis: X‐Component y‐Component Fx = F cos Fy = F sin 19 SOH Right Triangle Help O A A = H Cos θ = angle Opposiite = Sin‐1 O = H Sin θ = Tan‐1 90° Adjacent 21 Forces at an Angle ‐ Breaking into components FPy m FN Find FP Components FPx = FP Cos FPy = FP Sin Use components for net equations Fnetx = FPx Fnety = FN + FPy ‐ Fg CAH TOA A O Cos θ = Tan θ = H A A O = Cos‐1 = Tan‐1 H A O Sin θ = H 90° ‐ You will typically want to work with the angle from the x‐axis. 20 O H Adjacent Opposite O = H Sin θ A = H Cos θ O = A Tan θ A= O = H2 ‐ A2 O Tan θ A = H2 ‐ O2 Hypotenuse O H= Sin θ A H= Cos θ H = A2+O2 22 Forces on a Ramp ‐ Breaking into components Find Fg Components Fgx = Fg Cos (90‐) Fgy = Fg Sin (90‐) FP FPx Or just use SOH CAH TOA Fgx = Fg Sin Fgy = Fg Cos Fg = mg FN should not equal Fg !! FN = Fg ‐ Fpy if ay = 0 23 Use components for net equations Fnetx = ‐Fgx Fnety = FN ‐ Fgy Fg = mg FN should not equal Fg !! Many cases, FN will equal Fgy 24 4 Forces Free Body Diagrams Tension Force Spring Force Drag Force 1