Loose Leaf for Vector Mechanics for Engineers: Statics and Dynamics
Loose Leaf for Vector Mechanics for Engineers: Statics and Dynamics
12th Edition
ISBN: 9781259977206
Author: BEER, Ferdinand P., Johnston Jr., E. Russell, Mazurek, David, Cornwell, Phillip J., SELF, Brian
Publisher: McGraw-Hill Education
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Chapter 19.1, Problem 19.15P

A 5-kg collar C is released from rest in the position shown and slides without friction on a vertical rod until it hits a spring with a constant of k = 720 N/m that it compresses. The velocity of the collar is reduced to zero, and the collar reverses the direction of its motion and returns to its initial position. The cycle is then repeated. Determine (a) the period of the motion of the collar, (b) the velocity of the collar 0.4 s after it was released. (Note: This is a periodic motion, but it is not simple harmonic motion.)

Chapter 19.1, Problem 19.15P, A 5-kg collar C is released from rest in the position shown and slides without friction on a

Fig. P19.15

(a)

Expert Solution
Check Mark
To determine

The period (τn) of the motion of the collar.

Answer to Problem 19.15P

The period (τn) of the motion of the collar is 0.943sec_.

Explanation of Solution

Given Information:

The mass (m) of the collar C is 5 kg.

The spring constant (k) is 720N/m.

The value of acceleration due to gravity (g) is 9.81m/s2.

The vertical distance (h) between the collar and the spring is 0.5 m.

Calculation:

Calculate the natural circular frequency (ωn) using the relation:

ωn=km

Substitute 720N/m for k and 5 kg for m.

ωn=720N/m5=144=12rad/s

Calculate the initial velocity (v0) using the relation:

v0=2gh

Substitute 9.81m/s2 for g and 0.5 m for h.

v0=2×9.81×0.5=3.132m/s

Calculate the free fall time (t1) using the relation:

t1=2hg

Substitute 9.81m/s2 for g and 0.5 m for h.

t1=2(0.5)9.81=0.3193sec

Measure the displacement (x) from the position of static displacement of the spring.

Calculate the weight (W) of the collar C using the relation:

W=mg

Substitute 5kg for m and 9.81m/s2 for g:

W=5×9.81=49.05kgft/s2

Calculate the static displacement (δst) using the relation:

δst=Wk

Substitute 49.05kgft/s2 for W and 720N/m for k.

δst=49.05720=0.068125m

Show the displacement of the collar and spring while impact as in Figure (1).

Loose Leaf for Vector Mechanics for Engineers: Statics and Dynamics, Chapter 19.1, Problem 19.15P

Write the equation of motion for simple harmonic motion as below:

mx¨+kx=0

Substitute 5 kg for m and 720N/m for k.

5x¨+(720)k=0

Write the expression for displacement (x):

x=xmsin(ωnt+ϕ) (1)

Differentiate the above equation.

x˙=xmωncos(ωnt+ϕ) (2)

When time (t) is 0 the displacement (x) is equal to δst and the velocity (x˙) is 3.132m/s.

Substitute 0 for t and 0.068125m for x in equation (1).

0.068125=xmsin(ωn(0)+ϕ)0.068125=xmsin(ϕ)

Rewrite the above equation,

0.068125=xmsin(ϕ)xm=0.068125sin(ϕ) (3)

Substitute 0 for t, 3.132m/s for x˙, and 12rad/s for ωn in Equation (2).

3.132=xm(12)cos(ωn(0)+ϕ)3.132=12xmcos(ϕ) (4)

Calculate the phase angle (ϕ):

Substitute 0.068125sin(ϕ) for xm in equation (4).

3.132=12×0.068125sin(ϕ)×cos(ϕ)3.132=12×(0.068125sec(ϕ))3.13212=(0.068125sec(ϕ)) (secϕ=1tanϕ)

0.2610.068125=1tanϕtanϕ=13.831ϕ=tan1(0.261)ϕ=0.25531rad

Calculate the amplitude (xm):

Substitute 0.25531rad for ϕ in Equation (3).

xm=0.068125sin(0.25531)=0.26975m

Hence, from time of impact, the ‘time of flight’ is the time necessary for the collar to come to rest on its downward motion. The time required for collar to rest return is (t2).

At time (t2) the velocity (x˙) is zero.

Calculate the time (t2):

Substitute 0 for x˙ in equation (2).

0=xmωncos(ωnt2+ϕ)0=cos(ωnt2+ϕ)ωnt2+ϕ=cos1(0)ωnt2+ϕ=π2

Substitute 12rad/s for ωn and 0.25531rad for ϕ.

12t2+(0.25531)=π212t2=π2+0.25531t2=1.82612t2=0.15217sec

Calculate the period of motion (τn) using the relation:

τn=2(t1+t2)

Substitute 0.15217sec for t2 and 0.3193sec for t1.

τn=2(0.3193+0.15217)=0.9429=0.943sec

Therefore, the period (τn) of the motion of the collar is 0.943sec_.

(b)

Expert Solution
Check Mark
To determine

The velocity (x˙) of the collar 0.4 s after it was released.

Answer to Problem 19.15P

The velocity (x˙) of the collar 0.4 s after it was released is 2.45m/s()_.

Explanation of Solution

Given Information:

The mass (m) of the collar C is 5 kg.

The spring constant (k) is 720N/m.

The value of acceleration due to gravity (g) is 9.81m/s2.

The vertical distance (h) between the collar and the spring is 0.5 m.

Calculation:

Calculate the velocity (x˙) 0.4 sec after it was released.

Rewrite equation (2).

x˙=xmωncos(ωn(0.4t1)+ϕ)

Substitute 0.26975m for xm, 12rad/s for ωn, 0.25531rad for ϕ, and 0.3193sec for t1.

x˙(0.4)=(0.26975)(12)(cos((12(0.40.3193))+(0.25531)))=2.4483m/s=2.45m/s()

Therefore, the velocity (x˙) of the collar 0.4 s after it was released is 2.45m/s()_.

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Chapter 19 Solutions

Loose Leaf for Vector Mechanics for Engineers: Statics and Dynamics

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