VECTOR MECH. FOR EGR: STATS & DYNAM (LL
VECTOR MECH. FOR EGR: STATS & DYNAM (LL
12th Edition
ISBN: 9781260663778
Author: BEER
Publisher: MCG
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Chapter 15.1, Problem 15.35P

Two friction disks A and B are brought into contact when the angular velocity of disk A is 240 rpm counterclockwise and disk B is at rest. A period of slipping follows and disk B makes two revolutions before reaching its final angular velocity. Assuming that the angular acceleration of each disk is constant and inversely proportional to the cube of its radius, determine (a) the angular acceleration of each disk, (b) the time during which the disks slip.

Chapter 15.1, Problem 15.35P, Two friction disks A and B are brought into contact when the angular velocity of disk A is 240 rpm

Fig. P15.34 and P15.35

(a)

Expert Solution
Check Mark
To determine

Find the angular acceleration of disk A and B.

Answer to Problem 15.35P

The angular acceleration of disk A and B are 4.34rad/s2(Clockwise)_ and 1.832rad/s2(Clockwise)_.

Explanation of Solution

Given information:

Consider the initial and final angular velocity of disk A are as follows:(ωA)0=240rpm(Counterclockwise) and (ωA)1.

Consider the initial and final angular velocity of disk B are (ωB)0=0rpm and (ωB)1.

Consider the angular acceleration of the disk A and B are denoted by αA and αB.

Consider the angular displacement of the disk B is denoted by θB(Clockwise).

Show the value of the angular displacement θB(Clockwise) as follows:

θB=2rev×(2πradians1rev)=4πradians

The angular acceleration of disk A and B are constant.

The radius of the disk A and B are rA=150mm and rB=200mm.

The angular acceleration of disk A and B are inversely proportional to cube of their radius.

(αBαA)=(rArB)3 (1)

Calculation:

Calculate the final angular velocity of disk A using the relation:

(ωA)1=(ωA)0αAt1

Substitute 240rpm for (ωA)0.

(ωA)1=240rpm×(2πrad/s60rpm)αAt1=8παAt1

Calculate the angular displacement of the disk B using the relation:

θB=(ωB)0t1+12αBt12

Modify above Equation using Equation (1).

θB=(ωB)0t1+12αA(rArB)3t12

Substitute 0 for (ωB)0, 150mm for rA, 200mm for rB, and 4πradians for θB

4π=0+12αA(150200)3t128π=0.421875t12αAt12=8π0.421875αAt12=59.574radians (2)

Calculate the final angular velocity of the disk B using the relation:

(ωB)1=(ωB)0+αBt1

Modify above Equation using Equation (1).

(ωB)1=(ωB)0+αA(rArB)3t1

Substitute 0 for (ωB)0, 150mm for rA, and 200mm for rB.

(ωB)1=0+αA(150200)3t1(ωB)1=0.421875αAt1

Consider the contact point between the disk A and B are denoted by C.

Calculate the velocity at point C using the relation:

vC=rAωA

Substitute 150mm for rA and (8παAt1) for ωA.

vC=150×(8παAt1) (3)

Calculate the velocity at point C using the relation:

vC=rBωB

Substitute 200mm for rB and 0.421875αAt1 for ωB.

vC=200×(0.421875αAt1)=84.375αAt1 (4)

Equate Equation (3) and (4).

150×(8παAt1)=84.375αAt18παAt1=0.5625αAt11.5625αAt1=8παAt1=(8π1.5625)

αAt1=(8π1.5625)αAt1=16.0850rad/s (5)

Divide Equation (1) by (5).

t1=3.7037s (6)

Calculate the angular acceleration of disk A as follows:

Substitute 150mm for rA, 200mm for rB,

αA×(3.7037s)=16.0850rad/sαA=16.0850rad/s3.7037s=4.34rad/s2(Clockwise)

Thus, the angular acceleration of the disk A is 4.34rad/s2(Clockwise)_.

Calculate the angular acceleration of disk B as follows:

Substitute 150mm for rA, 200mm for rB, and 4.34rad/s for αA.

(αB4.34rad/s)=(150200)3αB=4.34(150200)3αB1.832rad/s2

Thus, the angular acceleration of the disk B is 1.832rad/s2(Clockwise)_.

(b)

Expert Solution
Check Mark
To determine

Find the time at which the disk slip.

Answer to Problem 15.35P

The disk slip at time t1=3.70s_.

Explanation of Solution

Given information:

Calculation:

Refer to Part (a).

Refer Equation (6).

The time at which the disk slip is at t1=3.70s.

Thus, the time at which the disk slip is at t1=3.70s_.

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Chapter 15 Solutions

VECTOR MECH. FOR EGR: STATS & DYNAM (LL

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