
Concept explainers
Solve Prob. 17.11, assuming that the 6 N

(a)
Number of revolutions of gear C.
Answer to Problem 17.12P
Number of revolutions of gear C is
Explanation of Solution
Given information:
Mass of the gear A (mA) = 10kg.
Radius of gyration of the gear A (kA) = 190mm.
Mass of the gear B (mB) = 10kg.
Radius of gyration of the gear B (kB) = 190mm.
Mass of the gear C (mC) = 2.5kg.
Radius of gyration of the gear C (kC) = 80mm.
Initial angular velocity of gear C (Nc)1 = 450rpm
Final angular velocity of gear C (NC)1 = 1800rpm
A couple at gear C (M) = 6N-m.
Radius of gear A (rA) = 250mm
Radius of gear B (rB) = 250mm
Radius of gear C (rC) = 100mm
Calculation:
Moment of inertia of gear A
Moment of inertia of gear B
Moment of inertia of gear C
For Initial condition; angular velocity is 450 rpm
Angular velocity of the gear C,
Gear C mess with Gear A. So angular velocity ration is given as
Gear C mess with gear B
Initial kinetic energy
For final condition; Angular velocity of the gear C is 1800rpm
Gear C mess with Gear A. So angular velocity ration is given as
Gear C mess with gear B
Final kinetic energy
Work done by the gear C
Substitute the value of E1, E2 and W in work energy equation

(b)
Tangential force on gear A.
Answer to Problem 17.12P
Tangential force on gear A is
Explanation of Solution
Given information:
Mass of the gear A (mA) = 10kg.
Radius of gyration of the gear A (kA) = 190mm.
Mass of the gear B (mB) = 10kg.
Radius of gyration of the gear B (kB) = 190mm.
Mass of the gear C (mC) = 2.5kg.
Radius of gyration of the gear C (kC) = 80mm.
Initial angular velocity of gear C (Nc)1 = 450rpm
Final angular velocity of gear C (NC)1 = 1800rpm
A couple at gear C (M) = 6N-m.
Radius of gear A (rA) = 250mm
Radius of gear B (rB) = 250mm
Radius of gear C (rC) = 100mm
Calculation:
Angle of rotation for gear A
Substitute the value of E1, E2 and W in work energy equation for gear A
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Chapter 17 Solutions
VECTOR MECH...,DYNAMICS(LOOSE)-W/ACCESS
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