Vector Mechanics For Engineers
Vector Mechanics For Engineers
12th Edition
ISBN: 9781259977305
Author: BEER, Ferdinand P. (ferdinand Pierre), Johnston, E. Russell (elwood Russell), Cornwell, Phillip J., SELF, Brian P.
Publisher: Mcgraw-hill Education,
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Chapter 16.1, Problem 16.37P

Gear A weighs 1 lb and has a radius of gyration of 1.3 in.; gear B weighs 6 lb and has a radius of gyration of 3 in.; gear C weighs 9 lb and has a radius of gyration of 4.3 in. Knowing a couple M of constant magnitude of 40 lb in. is applied to gear A, determine (a) the angular acceleration of gear C, (b) the tangential force that gear B exerts on gear C.

Expert Solution
Check Mark
To determine

i.

The angular acceleration of gear C.

Answer to Problem 16.37P

Angular acceleration of gear C = 129.99 rad/s2

Explanation of Solution

Given:

weight of Gear A, wa = 1 lb radius of gyration of gear A, ka¯ = 1.3 in. = 1.3/12 ft

radius of gear A = 2 in.

weight of gear B, wb = 6 lb

radius of gyration of gear B, kb¯ = 3 in. = 0.25 ft

radius of gear B, r1 = 4 in.; r2 = 2 in.

weight of Gear C, wc = 9 lb

radius of gyration of gear C, kc¯ = 4.3 in. = 4.3/12 ft

radius of gear C = 6 in.

Magnitude of Couple applied on gear A, M = 40lb-in. = 40/12 lb-ft = 3.333 lb-ft

Concept used:

Mass moment of acceleration is given by-

I = mk2¯, where k¯ is the radius of gyration 

The tangential force acting on a gear will provide the angular acceleration to the gear. Therefore,

Summation of moments applied on it = Mass Moment of inertia × angular accelerationΣM = Iα 

The free body diagram of the three gears is as following-

Vector Mechanics For Engineers, Chapter 16.1, Problem 16.37P , additional homework tip  1

Calculation:

Mass of gear A =  1lb32.2ft/s2  = 0.03106 lb-s2/ft

Mass of gear B =  6lb32.2ft/s2  = 0.18634 lb-s2/ft

Mass of gear C =  9lb32.2ft/s2  = 0.2795 lb-s2/ft

Mass moment of inertia of gear A =  mAkA2 = (0.03106 lb-s2/ft)×(1.312)2 = 3.6448×10-4lb×s2ft

Mass moment of inertia of gear B =  mBkB2 = (0.18634 lb-s2/ft)×(.25)2 = 0.01165 lb×s2ft

Mass moment of inertia of gear A =  mCkC2 = (0.2795 lb-s2/ft)×(4.312)2 = 0.3589 lb×s2ft

At the point of contact between A and B

tangential acceleration of gear A is equal to the tangential acceleration of gear BThe relation between acceleration and angular accelerationa = rαTherefore, at = rAαA = rBαBA = 4αBαA = 2αB

At the point of contact between B and C

tangential acceleration of gear B is equal to the tangential acceleration of gear CThe relation between acceleration and angular accelerationa = rαTherefore, at = r2αB = rCαCB = 6αCαB = 3αC Therefore, αA = 2αB = 6αC

For gear A,

ΣMB = IBαBM-FAB×rA= IAαAFAB×(2/12 ft) = 3.333lb×ft - (3.6448×10-4) lb×ft×s2 × (6αC)FAB= 20lb - 0.01312αC lb

For gear B,

ΣMB = IBαBFAB×r1 - FBC×r2= IBαBFBC×(2/12 ft) = FAB×(4/12 ft) -  (0.01165) lb×ft×s2 × (3αC)FBC = ((20lb - 0.01312αC lb)×(4/12 ft) -  (0.01165) lb×ft×s2 × (3αC))×12/12FBC = 40lb - 0.23594αC

For gear C,

ΣMC = ICαCFBC×rC= IcαC(40lb - 0.23594αC)×(6/12 ft) =   (0.03589) lb×ft×s2 × (αC)20lb =  0.15386αC αC = 129.99 rad/s2

Conclusion:

Angular acceleration of gear C = 129.99 rad/s2

Expert Solution
Check Mark
To determine

ii.

The tangential force that gear B exerts on gear C.

Answer to Problem 16.37P

Force exerted by gear B on gear C = 9.33 lb

Explanation of Solution

Given:

weight of Gear A, wa = 1 lb radius of gyration of gear A, ka¯ = 1.3 in. = 1.3/12 ft

radius of gear A = 2 in.

weight of gear B, wb = 6 lb

radius of gyration of gear B, kb¯ = 3 in. = 0.25 ft

radius of gear B, r1 = 4 in.; r2 = 2 in.

weight of Gear C, wc = 9 lb

radius of gyration of gear C, kc¯ = 4.3 in. = 4.3/12 ft

radius of gear C = 6 in.

Magnitude of Couple applied on gear A, M = 40lb-in. = 40/12 lb-ft = 3.333 lb-ft

Angular acceleration of gear C = 129.99 rad/s2

Concept used:

Mass moment of acceleration is given by-

I = mk2¯, where k¯ is the radius of gyration 

The tangential force acting on a gear will provide the angular acceleration to the gear. Therefore,

Summation of moments applied on it = Mass Moment of inertia × angular accelerationΣM = Iα 

The free body diagram of the three gears is as following-

Vector Mechanics For Engineers, Chapter 16.1, Problem 16.37P , additional homework tip  2

Calculation:

Mass of gear A =  1lb32.2ft/s2  = 0.03106 lb-s2/ft

Mass of gear B =  6lb32.2ft/s2  = 0.18634 lb-s2/ft

Mass of gear C =  9lb32.2ft/s2  = 0.2795 lb-s2/ft

Mass moment of inertia of gear A =  mAkA2 = (0.03106 lb-s2/ft)×(1.312)2 = 3.6448×10-4lb×s2ft

Mass moment of inertia of gear B =  mBkB2 = (0.18634 lb-s2/ft)×(.25)2 = 0.01165 lb×s2ft

Mass moment of inertia of gear A =  mCkC2 = (0.2795 lb-s2/ft)×(4.312)2 = 0.3589 lb×s2ft

At the point of contact between A and B

tangential acceleration of gear A is equal to the tangential acceleration of gear BThe relation between acceleration and angular accelerationa = rαTherefore, at = rAαA = rBαBA = 4αBαA = 2αB

At the point of contact between B and C

tangential acceleration of gear B is equal to the tangential acceleration of gear CThe relation between acceleration and angular accelerationa = rαTherefore, at = r2αB = rCαCB = 6αCαB = 3αC Therefore, αA = 2αB = 6αC

For gear A,

ΣMB = IBαBM-FAB×rA= IAαAFAB×(2/12 ft) = 3.333lb×ft - (3.6448×10-4) lb×ft×s2 × (6αC)FAB= 20lb - 0.01312αC lb

For gear B,

ΣMB = IBαBFAB×r1 - FBC×r2= IBαBFBC×(2/12 ft) = FAB×(4/12 ft) -  (0.01165) lb×ft×s2 × (3αC)FBC = ((20lb - 0.01312αC lb)×(4/12 ft) -  (0.01165) lb×ft×s2 × (3αC))×12/12FBC = 40lb - 0.23594αC

As found in part I,

Angular acceleration of gear C = 129.99 rad/s2

Tangential force of gear B, on gear C-

FBC = 40lb - 0.23594αC FBC = 40lb - 0.23594(129.9rad/s2)FAC= 9.33 lb

Conclusion:

Angular acceleration of gear C = 129.99 rad/s2

Force exerted by gear B on gear C = 9.33 lb

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Chapter 16 Solutions

Vector Mechanics For Engineers

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