VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS
VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS
12th Edition
ISBN: 9781260265453
Author: BEER
Publisher: MCG
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Textbook Question
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Chapter 15.5, Problem 15.154P

Pin P is attached to the wheel shown and slides in a slot cut in bar BD. The wheel rolls to the right without slipping with a constant angular velocity of 20 rad/s. Knowing that x = 480 mm when θ = 0, determine the angular velocity of the bar and the relative velocity of pin P with respect to the rod when (a) θ = 0, (b) θ = 90°.

Chapter 15.5, Problem 15.154P, Pin P is attached to the wheel shown and slides in a slot cut in bar BD. The wheel rolls to the

Fig. P15.154

(a)

Expert Solution
Check Mark
To determine

Find the angular velocity of the bar when θ=0°.

Find the relative velocity of the pin P with respect to the rod when θ=0°.

Answer to Problem 15.154P

The angular velocity of the bar when θ=0° is ωBD=3.81rad/s(Clockwise)_.

The relative velocity of the pin P with respect to the rod when θ=0° is 6.53m/s(16.26°)_.

Explanation of Solution

Given information:

The constant angular velocity of the wheel is ωAC=20rad/s.

The distance BA is (xA)0=480mm.

The distance AP is e=140mm.

The radius of the wheel is r=200mm.

Consider the relative velocity of the pin P with respect to the rod is denoted by u.

Calculation:

Show the wheel and the rod arrangement as shown in Figure 1.

VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS, Chapter 15.5, Problem 15.154P

Refer Figure 1.

Consider the coordinates of the point A, B, C, and P are (xA,yA),(xB,yB),(xC,yC) and (xP,yP) respectively.

Calculate the value of the distance xA,yA,xB,yB,xC,yC,xP,yP as follows:

xA=(xA)0+rθyA=r

xB=0yB=r

xC=xA=(xA)0+rθyC=0

xP=xA+esinθyP=r+ecosθ

Consider the angular velocity of the wheel AC is ωAC=ωAC(Clockwise).

Consider the angular velocity of the rod BD is ωBD=ωBD(Clockwise).

Consider the velocity of the point P with respect to point A is denoted by (vP/A).

Show the velocity at point P (vP) as follows:

vP=(vA)+[vP/A]=[rωAC()]+[eωAC(Acting at θclockwise below the horizontal)]=rωAC()+eωAC(Acting at θclockwise below the horizontal) (1)

Consider the velocity of the point P with respect to point F is denoted by (vP/F).

Show the velocity at point P (vP) as follows:

vP=(vP)+[vP/F]=[xpωBD()+ecosθωBD()]+[ucosβ()+usinβ()]=xpωBD()+ecosθωBD()+ucosβ()+usinβ() (2)

Equate Equation (1) and (2).

rωAC()+eωAC(Acting at θclockwise below the horizontal)=xpωBD()+ucosβ()+usinβ() (3)

Equate the horizontal component of the Equation (3) as follows:

Take the direction towards right as positive.

rωAC+eωACcosθ=ecosθωBD+ucosβ(r+ecosθ)ωAC=ecosθωBD+ucosβ (4)

Equate the vertical component of the Equation (3) as follows:

Take the direction towards downward as positive.

eωACsinθ=xpωBDusinβeωACsinθ={[(xA)0+rθ]+esinθ}ωBDusinβ (5)

Calculate the value of the angle θ using the relation:

tanβ=ecosθxptanβ=ecosθxp=ecosθxA+esinθ=ecosθ[(xA)0+rθ]+esinθ

Substitute 0° for θ, 480mm for (xA)0, 140mm for e, and 200mm for r.

tanβ=140cos(0°)480+200×0+140sin(0°)tanβ=140480β=tan1(140480)β=16.26°

Modify Equation (4) as follows:

Substitute 0° for θ, 16.26° for β, 480mm for (xA)0, 140mm for e, and 200mm for r, and 20rad/s for ωAC in Equation (4).

[200+140cos(0°)]×20=140cos(0°)ωBD+ucos(16.26°)6800=140ωBD+0.96uu=6800140ωBD0.96 (6)

Modify Equation (5) as follows:

Substitute 0° for θ, 16.26° for β, 140mm for e, and 200mm for r, and 20rad/s for ωAC in Equation (5).

140×20sin(0°)=[480+200×0+140sin(0°)]ωBDusin(16.26°)0=480ωBD+0.28u

Substitute 6800140ωBD0.96 for u in above Equation.

0=480ωBD0.28(6800140ωBD0.96)0=480ωBD1983.33+40.83ωBD520.83ωBD=1983.33ωBD=1983.33520.83

ωBD=3.81rad/s(Clockwise)

Thus, the angular velocity of the bar when θ=0° is ωBD=3.81rad/s(Clockwise)_.

Calculate the relative velocity of the pin P with respect to the rod when θ=0° as follows:

Substitute 3.81rad/s for ωBD in Equation (5).

u=6800140×3.810.96=6530mm/s×(1m1000mm)=6.53m/s(16.26°)

Thus, the relative velocity of the pin P with respect to the rod when θ=0° is 6.53m/s(16.26°)_.

(b)

Expert Solution
Check Mark
To determine

Find the angular velocity of the bar when θ=90°.

Find the relative velocity of the pin P with respect to the rod when θ=90°.

Answer to Problem 15.154P

The angular velocity of the bar when θ=90° is 3rad/s(Clockwise)_.

The relative velocity of the pin P with respect to the rod when θ=90° is 4m/s()_.

Explanation of Solution

Given information:

Calculation:

Consider the value of the angle θ=90°.

Refer to Part (a).

Calculate the value of the angle θ using the relation:

tanβ=ecosθxp=ecosθxA+esinθ=ecosθ[(xA)0+rθ]+esinθ

Substitute 90° for θ, 480mm for (xA)0, 140mm for e, and 200mm for r.

tanβ=140cos(90°)480+200×(90°×π180°)+140sin(90°)tanβ=0β=tan1(0)β=0°

Modify Equation (4) as follows:

Substitute 90° for θ, 0° for β, 480mm for (xA)0, 140mm for e, and 200mm for r, and 20rad/s for ωAC in Equation (4).

[200+140cos(90°)]×20=140cos(90°)ωBD+ucos(0°)4000=uu=4000mm/s×(1m1000mm)u=4m/s()

Thus, the relative velocity of the pin P with respect to the rod when θ=90° is 4m/s()_.

Modify Equation (5) as follows:

Substitute 90° for θ, 0° for β, 140mm for e, and 200mm for r, and 20rad/s for ωAC in Equation (5).

140×20sin(90°)=[480+200×(90°×π180°)+140sin(90°)]ωBDusin(0°)2800=(480+100π+140)ωBDωBD=2800(480+100π+140)ωBD=3rad/s(Clockwise)

Thus, the angular velocity of the bar when θ=90° is 3rad/s(Clockwise)_.

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Chapter 15 Solutions

VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS

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