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Type: Double Date: ______________ Objective: Statics and Dynamics Homework: Assignment (1-20) Do PROBS Ch. 4 #’s (82) Ch. 4 + Do AP 1986 #1, 1988 #1 (handouts) AP Physics “B” Mr. Mirro Date: ________ Statics and Dynamics I Two masses suspended over a pulley by a cable, as shown is sometimes referred to generically as an Atwood’s machine. Consider the real-life application of an “elevator” (m1) and its “counterweight” (m2). To minimize the work done by the motor to raise and lower the elevator safely, m1 and m2 are similar in mass. We leave the motor out of the system for this calculation, and assume the cable’s mass is negligible and the pulley is frictionless and massless, which assures that the “tension” in the cord has the same magnitude on both sides of the pulley. Let the mass of the counterweight be m2 = 1000 kg. Assume the mass of the empty elevator is 850 kg, and its mass when carrying four passengers is m1 = 1150 kg. For the latter case (m1 = 1150 kg), we can determine: a. the acceleration (a) of the elevator motion b. the tension in the cable (T) adown = negative FIRST – The Analysis of the Elevator (m1): ∑ FE = mE adown aup = positive mE = m1 +T - mE g = mE (-a) SECOND – The Analysis of the Counterweight (m2): ∑ FCW = mCW aup mCW = m2 +T - mCW g = mCW (+a) Finally, solving the system of equation by either addition or substitution we can obtain an expression for the acceleration (a). Method #1: Solving systems of equations by using the addition method. +T - mE g = mE (-a) Eq. 1 +T - mCW g = mCW (+a) Eq. 2 Multiply Eq. 1 through by (-1) to switch the signs of each term to create a new version of Eq 1 called Eq. 3. -T + mE g = mE (a) ADD Eq. 3 Now we can add Eq. 2 and the new version of Eq. 1, which now is Eq. 3 together to eliminate the tension (T) and then isolate the acceleration (a). +T - mCW g = mCW (a) Eq. 2 -T + mE g = mE (a) Eq. 3 + mE g - mCW g = mCW (a) + mE (a) mE g - mCW g = a (mCW + mE ) a = mE g - mCW g mCW + mE Method #2: Solving systems of equations by using the substitution method. Since, +T - mE g = mE (-a) then: T1 = mE g - mE a Since, +T - mCW g = mCW (+a) then: T2 = mCW a + mCW g Let T1 = T2 mE g - mE a = mCW a + mCW g By substitution of T1 and T2 mE g - mCW g = mCW a + mE a Same as previous ! mE g - mCW g = a (mCW + mE) Same as previous ! a = mE g - mCW g mCW + mE Same as previous ! AP Physics “B” Mr. Mirro Date: ________ Statics and Dynamics I Ex 1: As shown in the diagram, two guiderails for an elevator each exert a constant friction force of 95.0 Newtons on the elevator car when it is moving upward with an acceleration of 1.0 m/s2 . The pulley has negligible mass and friction; assume g = 10.0 m/s2 . a) What is the direction of the net force on the elevator car? 500 kg Elevator Guide Rails b) On the diagram below, sketch and clearly label all the forces acting on the elevator car. M Counterweight c) Calculate the tension in the cable when it is accelerating upward as described. d) Calculate the mass M the counterweight must have in order to raise the elevator car with the acceleration as described. Ex 2: A helicopter holding a 50-kilogram package suspended from a rope 10.0 meters long accelerates upward at a rate of 6 m/s2. Neglect air resistance on the package. a. On the diagram below, draw and label all of the forces acting on the package. b. Determine the tension in the rope. c. When the upward velocity of the helicopter is 20 meters per second, the rope is cut and the helicopter continues to accelerate upward at 6 m/s2. Determine the distance between the helicopter and the package 2.0 seconds after the rope is cut. AP Physics “B” Mr. Mirro Date: ________ Statics and Dynamics II Ex: A crate of dilled pickles with mass m1 = 14 kg moves along a plane that makes an angle of θ = 30° with the horizontal. That crate is connected to a crate of pickled dills with mass m2 = 14 kg by a taut, massless cord that runs around a frictionless, massless pulley. The hanging crate of dills descends with constant velocity. [Halliday6.4] a. What are the magnitude and direction of the frictional force exerted on m1 by the plane ? m2 m1 b. Compute the value for the coefficient of kinetic friction between the crate and the plane.
