Vector Mechanics for Engineers: Statics and Dynamics
Vector Mechanics for Engineers: Statics and Dynamics
11th Edition
ISBN: 9780073398242
Author: Ferdinand P. Beer, E. Russell Johnston Jr., David Mazurek, Phillip J. Cornwell, Brian Self
Publisher: McGraw-Hill Education
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Chapter 17.2, Problem 17.91P

A small 4-lb collar C can slide freely on a thin ring of weight 6 lb and radius 10 in. The ring is welded to a short vertical shaft, which can rotate freely in a fixed bearing. Initially, the ring has an angular velocity of 35 rad/s and the collar is at the top of the ring (θ = 0) when it is given a slight nudge. Neglecting the effect of friction, determine (a) the angular velocity of the ring as the collar passes through the position θ = 90°, (b) the corresponding velocity of the collar relative to the ring.

Chapter 17.2, Problem 17.91P, A small 4-lb collar C can slide freely on a thin ring of weight 6 lb and radius 10 in. The ring is

Fig. P17.91

(a)

Expert Solution
Check Mark
To determine

Find the angular velocity of the ring as the collar passes through the position θ=90°.

Answer to Problem 17.91P

The angular velocity of the ring as the collar passes through the position θ=90° is 15.00rad/s_.

Explanation of Solution

Given information:

The weight (WC) of collar C is 4 lb.

The weight (WR) of thin ring is 6 lb.

The initial angular velocity (ω1) of the ring is 35 rad/s.

Calculation:

Find the mass (mC) of the collar C using the equation:

mC=WCg

Substitute 4 lb for WC and 32.2ft/s2 for g.

mC=432.2=0.12422lbs2/ft

Find the mass (mC) of the ring using the equation:

mR=WRg

Substitute 6 lb for WC and 32.2ft/s2 for g.

mR=632.2=0.18634lbs2/ft

Sketch the component of velocity of the given system at initial position as shown in Figure (1).

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 17.2, Problem 17.91P , additional homework tip  1

Find the centroidal moment of inertia (I¯R) of the ring using the equation:

I¯R=12mRR2

Here, R is the radius of the ring.

The collar C is located at top of the ring at initial position. Therefore, the angle (θ) is zero at initial position.

Sketch the component of velocity of the given system at final position as shown in Figure (2).

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 17.2, Problem 17.91P , additional homework tip  2

Refer Figure (2).

Write the equation of the velocity (vC)y of the collar C in y-direction.

(vC)y=Rω2

Here, ω2 is the angular velocity of the system at final position.

Consider the conservation of angular momentum.

I¯Rω1=I¯Rω2+mC(vC)yR

Substitute 12mRR2 for I¯R, and Rω2 for (vC)y.

(12mRR2)ω1=(12mRR2)ω2+mC(Rω2)R12mRR2ω1=12mRR2ω2+mCR2ω212mRR2ω1=(mR+2mC)R22ω2

Simplify the Equation.

mRR2ω1=(mR+2mC)R2ω2ω2=mRR2(mR+2mC)R2ω1ω2=mR(mR+2mC)ω1

Substitute 6lb32.2ft/s for mR, 4lb32.2ft/s for mC, and 35rad/s for ω1.

ω2=6lb32.2ft/s6lb32.2ft/s+2(4lb32.2ft/s)(35rad/s)=614(35rad/s)=15rad/s

Thus, the angular velocity of the ring as the collar passes through the position θ=90° is 15.00rad/s_.

(b)

Expert Solution
Check Mark
To determine

Find the corresponding velocity of the collar relative to the ring.

Answer to Problem 17.91P

The corresponding velocity of the collar relative to the ring is 20.5ft/s_.

Explanation of Solution

Calculation:

Find the equation of the kinetic energy (T1) of the system at initial position.

T1=12I¯Rω12

Substitute 12mRR2 for I¯R.

T1=12(12mRR2)ω12=14mRR2ω12

Find the equation of the potential energy (V1) of the system at initial position.

V1=mCgR

Find the equation of the kinetic energy (T2) of the system at final position.

T2=12(12mRR2)ω22+12mC(vC)x2+12mC(vC)y2

Substitute 12mRR2 for I¯R, and Rω2 for (vC)x.

T2=12(12mRR2)ω22+12mC(Rω2)2+12mC(vC)y2=14mRR2ω22+12mCR2ω22+12mC(vC)y2

The potential energy of the system at final position (V2) is zero.

Consider the conservation of energy.

T1+V1=T2+V2

Substitute 14mRR2ω12 for T1, mCgR for V1, 14mRR2ω22+12mCR2ω22+12mC(vC)y2 for T2, and 0 for V2.

14mRR2ω12+mCgR=14mRR2ω22+12mCR2ω22+12mC(vC)y2+014mRR2ω12+mCgR=(14mR+12mC)R2ω22+12mC(vC)y2

Substitute 6lb32.2ft/s for mR, 10 in. for R, 4lb32.2ft/s for mC, 32.2ft/s for g, 35rad/s for ω1, and 15rad/s for ω2.

{14(6lb32.2ft/s2)(10in.)2(35rad/s)2+(4lb32.2ft/s2)(32.2ft/s2)(10in.)}={(14(6lb32.2ft/s2)+12(4lb32.2ft/s2))×(10in.)2(15rad/s)2+12(4lb32.2ft/s2)(vC)y2}{14(6lb32.2ft/s2)(1012ft)2(35rad/s)2+(4lb32.2ft/s2)(32.2ft/s2)(1012ft)}={(14(6lb32.2ft/s2)+12(4lb32.2ft/s2))×(1012ft)2(15rad/s)2+12(4lb32.2ft/s2)(vC)y2}39.6286+3.333=16.9836+0.0621(vC)y2

0.0621(vC)y2=42.961916.9836(vC)y2=25.97820.0621(vC)y=(418.25)0.5(vC)y=20.5ft/s

Thus, the corresponding velocity of the collar relative to the ring is 20.5ft/s_.

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Chapter 17 Solutions

Vector Mechanics for Engineers: Statics and Dynamics

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