Vector Mechanics for Engineers: Statics and Dynamics
Vector Mechanics for Engineers: Statics and Dynamics
12th Edition
ISBN: 9781259638091
Author: Ferdinand P. Beer, E. Russell Johnston Jr., David Mazurek, Phillip J. Cornwell, Brian Self
Publisher: McGraw-Hill Education
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Chapter 3.4, Problem 3.120P

Two 150-mm-diameter pulleys are mounted on line shaft AD. The belts at B and C lie in vertical planes parallel to the yz plane. Replace the belt forces shown with an equivalent force-couple system at A.

Chapter 3.4, Problem 3.120P, Two 150-mm-diameter pulleys are mounted on line shaft AD. The belts at B and C lie in vertical

Expert Solution & Answer
Check Mark
To determine

Replace the given system with its equivalent force-couple system at POINT A.

Answer to Problem 3.120P

The equivalent force is (420N)j^(339N)k and resultant moment of couple about point A is (1.125Nm)i^+(163.9Nm)j^(109.9Nm)k^.

Explanation of Solution

Refer Fig P3.120. Its vector diagrams showing equivalent force-couple is given below.

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 3.4, Problem 3.120P

Write the formula to calculate the resultant force pulley B.

RB=FB1+FB2 (I)

Here, RB is the resultant force on pulley B, FB1 and FB2 are the forces acting on pulley B.

Write the formula to calculate the net moment of couple on pulley B.

MB=rb(FB1+FB2)i^ (II)

Here, MB is moment of resultant couple about pulley B, FB1 and FB2 are the magnitudes of forces on pulley B, and rb is the radius of pulley B.

Write the formula to calculate the resultant force pulley C.

RC=FC1+FC2 (III)

Here, RC is the resultant force on pulley C, FC1 and FC2 are the forces acting on pulley C.

Write the formula to calculate the net moment of couple on pulley B.

MC=rc(FC2FC1)i^ (IV)

Here, MC is moment of resultant couple about pulley C, FC1 and FC2 are the magnitudes of forces on pulley B, and rc is the radius of pulley C.

Write the expression to calculate the net force on pulley.

R=RB+RC (V)

Here, R is the resultant force vector of whole system.

Write the expression to calculate the resultant moment of couple about point A.

MA=MB+MC+(rB/A×RB)+(rC/A×RC) (VI)

Here, MA is the net moment of couple of system about point A, rB/A is the distance between end A to pulley B, and rC/A is the distance between pulley C and end A.

Write the determinant form to calculate r×F.

r×F=|ijkrirjrkFiFjFk| (VII)

Here, ri is the component of r in x-direction, rj is the component of r in y-direction, rk is the is the component of r in z-direction, Fi is the component of F in x-direction, Fj is the component of F in y-direction, and Fk is the component of F in z-direction.

Conclusion:

Substitute (145N)[cos20°+sin20°k]j^ for FB1, (215N)j^ for FB2 in equation (I) to find RB.

RB=(145N)[cos20°j^+sin20°k]+(215N)j^=(351.26N)j^+(49.59N)k

Substitute 215N for FB2, 145N for FB1, and 75mm for rb in equation (II) to find MB.

MB=(75mm(1m103mm))(215N+145N)i^=(5.25Nm)i^

Substitute (155N)[sin10°j^cos10°k] for FC1 and (240N)[sin10°j^cos10°k] for FC2 in equation (III) to find RC.

RC=(155N)[sin10°j^cos10°k]+(240N)[sin10°j^cos10°k]=(68.59N)j^(389.00N)k^

Substitute 240N for FC2, 155N for FC1, and 75mm for rc in equation (IV) to find MC.

MC=(75mm(1m103mm))(240N155N)i^=(6.375Nm)i^

Substitute (351.26N)j^+(49.59N)k for RB and (68.59N)j^(389.00N)k^ for RC in equation (V) to find R.

R=[(351.26N)j^+(49.59N)k^]+[(68.59N)j^(389.00N)k^]=(420N)j^(339N)k^

Substitute (5.25Nm)i^ for MB, (6.375Nm)i^ for MC, (225mm)i^ for rB/A, (351.26N)j^+(49.59N)k for RB, (450mm)i^ for rC/A, (68.59N)j^(389.00N)k^ for RC in equation (VI) to find MA.

MA={(5.25Nm)i^+(6.375Nm)i^+((225mm)i^×[(351.26N)j^+(49.59N)k^])+((450mm)i^×[(68.59N)j^(389.00N)k^])} (IIX)

Calculate (225mm)i^×[(351.26N)j^+(49.59N)k^] using equation (VII).

(225mm)i^×[(351.26N)j^+(49.59N)k^]=|i^j^k^225mm(1m103mm)0m0m0N351.26N49.59N|=(11.16Nm)j^(79.03Nm)k^ (IX)

Calculate (450mm)i^×[(68.59N)j^(389.00N)k^] using equation (VII).

(450mm)i^×[(68.59N)j^(389.00N)k^]=|i^j^k^450mm(1m103mm)0m0m0N68.59N389.00N|=(175.05Nm)j^ (X)

Rewrite equation (IIX) by substituting equations (IX) and (X).

MA=(5.25Nm)i^+(6.375Nm)i^+[(11.16Nm)j^(79.03Nm)k^]+(175.05Nm)j^=(1.125Nm)i^+(163.9Nm)j^(109.9Nm)k^

Therefore, the equivalent force is (420N)j^(339N)k and resultant moment of couple about point A is (1.125Nm)i^+(163.9Nm)j^(109.9Nm)k^.

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Chapter 3 Solutions

Vector Mechanics for Engineers: Statics and Dynamics

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