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PQE Vibration 09+Solution
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COLLEGE OF ENGINEERING
MECHANICAL ENGINEERING
Ph.D. Preliminary Qualifying Examination
Signature PageVibration Examination
January 26, 2009 (Monday)9:00 am – 12:00 noon
Room 2145 Engineering Building
For identification purposes, please fill out the following information in ink. Be sureto print and sign your name. This cover page is for attendance purposes only, andwill be separated from the rest of the exam before the exam is graded. Write yourstudent number on all exam pages. Do NOT write your name on any of the otherexam pages besides the cover page.
Name (print in INK)
Signature (in INK)
Student Number (in INK)
COLLEGE OF ENGINEERING
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MECHANICAL ENGINEERING
Ph.D. Preliminary Qualifying Examination
Cover Page
9:00 am – 12:00 noonRoom 2145 Engineering Building
GENERAL INSTRUCTIONS:
This examination contains five problems. You are required to select and solve fourof the five problems. Clearly indicate the problems you wish to be graded. If youattempt solving all of them without indicating which four of your choice, the four
problems with the worst grades will be considered. Note that Problem number 5 is mandatory.
Do all your work on the provided sheets of paper. If you need extra sheets, pleaserequest them from the proctor. When you are finished with the test, return theexam plus any additional sheets to the proctor.
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Mechanical Engineering Ph.D. Preliminary Qualifying ExaminationVibration – January 26, 2009
You are required to work four of the five problems, one of which is Problem No. 5. Clearlyindicate which problems you are choosing. Show all work on the exam sheets provided and write
your student personal identification (PID) number on each sheet. Do not write your name on anysheet.
Your PID number:____________________________
Question #1
A uniform bar of length L and weight W is suspended symmetrically by twounstrechable strings as shown in the figure. If the bar is given small initial rotation aboutthe vertical axis,
a. Draw the free body diagram of the bar during its free oscillation. b. Write down the equation of motion for small angular oscillation about axis O-O.c. Determine the period of the free oscillation of the bar.
O
O L
a
h
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You are required to work four of the five problems. Clearly indicate which problems you arechoosing. Show all work on the exam sheets provided and write your student personal
identification (PID) number on each sheet. Do not write your name on any sheet.
Your PID number:____________________________
Question #2The system shown in the figure is in its static equilibrium position (SEP). It consists of auniform rod of mass m and length L and is supported by spring of stiffness k anddashpot of coefficient c .
a. Draw the free body diagram of each system as it oscillates about the SEP. b. Derive the equation of motion of each system using Newton’s second law.
c. Determine the undamped natural frequency.d. Determine the damping ratio, the critical damping coefficient, and the dampednatural frequency.
O
ck
a
L
SEP O
ck
a
L
SEP
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You are required to work four of the five problems. Clearly indicate which problems you arechoosing. Show all work on the exam sheets provided and write your student personalidentification (PID) number on each sheet. Do not write your name on any sheet.
Your PID number:____________________________
Question #3The system shown consists of a cylinder of mass m with a piston, which impartsresistance proportional to the velocity of a linear viscous damping c , the cylinder isrestrained by a spring of stiffness k
(a) draw the free body diagram of the cylinder,
(b) write down the equation of motion using Newton’s second law, and
(c) determine the response amplitude and phase angle using Complex Algebra.
( ) sin y t Y t → = Ω( ) sin y t Y t → = Ω( ) sin y t Y t = Ω
( ) sin y t Y t → = Ω( ) sin y t Y t → = Ω( ) sin y t Y t = Ω
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You are required to work four of the five problems. Clearly indicate which problems you arechoosing. Show all work on the exam sheets provided and write your student personalidentification (PID) number on each sheet. Do not write your name on any sheet.
Your PID number:____________________________
Question #4
The system shown below consists of two rotors coupled by a discontinuous shaft of
modulus of rigidity is 6 211.5 10 / /G lb in rad = × :
• Draw the free-body diagram of each rotor,• Derive the equations of motion,• Determine the natural frequencies of free torsional oscillations and provide the
physical meaning of each value,• Draw the normal mode shape and evaluate the value of the twist at the junction of
the two shafts, i.e. 1/nθ θ or 2/nθ θ
1θ
2θ
nθ
1θ
2θ
nθ
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MANDATORY PROBLEM (EVERYONE IS REQUIRED TO SOLVE THIS PROBLEM)Your PID number:____________________________
Question #5
Consider a rigid body of mass m and mass moment of inertia J c with respect to center of gravityC g . Suppose that the body is supported by two springs of stiffness k that are attached at distances2l and l with respect to the center of gravity C g as shown in Figure 5a. Let m = 10 kg, J c = 5 kgm2
k = 100 N/m, and l = 1 m.
Part I:
(a) Derive the equations of motion for this body using coordinates x and θ .
(b) Determine the natural frequencies of the system.
(c) Draw the natural mode shapes of the system.
(5a) (5b)
Next, consider the same rigid body as shown in Figure 5b.
Part II:
(d) Derive the equations of motion for this body using coordinates x1 and x2.
(e) Determine the natural frequencies of the system.
(f) Draw the natural mode shapes of the system.
Part III:(g) State if there are differences in the equations of motion, natural frequencies and mode
shapes obtained in each case and explain why.
(h) What are the couplings in equations of motion, respectively, in these two cases?
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Problem 1
A uniform bar of length L and weight W is suspendedsymmetrically by two strings as shown in the figure. If the bar is given small initial rotation about the vertical axis,d. Draw the FBD of the bar during its free oscillation.e. Write down the equation of motion for small angular oscillation about axis O-O.f. Determine the period of the free oscillation of the bar.
Figure 5.Solution:
FBD
From the static equilibrium position we write
2T mg=
(1)Under free vibration of the bar and in an arbitrary position θ , the bar will be raised up
slightly, and will be displaced by a distance ( / 2)a θ from the its suspended string. The
string also be tilted by an angle ϕ from the vertical such that, ( / 2) ha θ = ϕ . This
geometric relation gives ( / 2h)aϕ = θ .
Now writing the equation of motion by taking moments about axis OO, gives
0I 2(Tsin )( / 2) T T2h
aa a a
θ = − ϕ ≈ − ϕ = − θ
&&
(2)Using equation (1), equation (2) takes the form
20 n
0
mg mgI 0 0 0
4h 4I h
2 2a aθ + θ = → θ + θ = → θ + ω θ =&& && &&
(3)
O
O L
a
h
T T
mg
SEP
0I θ
TT
θ
ϕϕ
a
( ) ha/2 θ = ϕ
h
Tsinϕ
Tsinϕ
T T
mg
SEP
0I θ
TT
θ
ϕϕ
a
( ) ha/2 θ = ϕ
h
Tsinϕ
Tsinϕ
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wheren 22
0
mg mg 3g
4I h hLL4 m h
12
2 2 2a a aω = = =
(4)
Problem 2
FBD
(b) From the free-body diagram, we write the equation of motion from the staticequilibrium position using Newton’s second law of moments about the hinge axis O
( ) ( )2
2 2
0 03
mL I cL L ka a cL kaθ θ θ θ θ θ = − − → + + =&& & && & (1)
(c) The undamped natural frequency is obtained by dividing both sides of the equation of
motion (1) by the coefficient of θ &, i.e.,
2 2
2 23 3 0 3 3n
c ka ka a k
m mL mL L m
θ θ θ ω + + = → = =&& & (2)
(d) The damping ratio is obtained by writing the equation of motion in the form22 0n nθ ζω θ ω θ + + =&& & (3)
Thus we can write km
3 3 32 3
2 2 32 3
n
n
c c c cL
m m a k kmam
L m
ζω ζ ω
= → = = =(4)
The critical damping coefficient is obtained from (4) as
3 2 3
32 3cr
cr
c cL kmac
c Lkmaζ = = → =
The damped natural frequency, nd ω , is written in terms of the undamped natural
frequency, nω , as
2 2 22
2
3 91 3 1 3 1
122 3nd n
a k cL a k c L
L m L m kmakmaω ω ζ
= − = − = −
L
a k
c
m
OSEP
0 I θ
R
O
kaθ cLθ
θ
L
a k
c
m
O
L
a k
c
m
OSEP
0 I θ
R
O
kaθ cLθ
θ
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Problem # 3
Using Newton’s second law and with the
help of the FBD, the equation of motion is
( )mx kx c y x= − + −&& & & (1)
Rearranging
mx cx kx cy+ + =&& & (1a)
But ( ) sin Im i t y t Y t Y e Ω= Ω = (2)
Also ( ) cos Im i t y t Y t i Y e Ω= Ω Ω = Ω& (3)
Note that one can write( ) ( ) ( ) ( )
/ 2 / 2 because cos / 2 sin / 2
i ii e e i i
π π π π = = + =
Thus one can write equation (1a) in the form
2Im Imi t
i t mx cx kx icY e cY eπ Ω + Ω + + = Ω = Ω&& &
(4)
The response must oscillate at the same frequency of the excitation in the steady state atamplitude and phase angle to be determined, thus one can write the response in the form
( ) wherei t i i t i x t X Ime X Ime X X Imeϕ ϕ Ω − Ω −= = = (5)
We need the first and second time derivatives of ( ) x t , i.e.
2( ) , ( )i t i t x t i X Ime x t X ImeΩ Ω= Ω = −Ω& && (6)
Substituting expressions (5) and (6) into equation (4), gives
2 22 2i t
i t i t i t n n n X Ime i X Ime X Ime Y Ime
π
ζω ω ζω
Ω + Ω Ω Ω + Ω + = Ω (7)
Canceling out i t Ime Ω from both sides of equation (7) and rearranging, gives
2 2 2 22 2 2 , wherei i
n n n n X i X X Y Ime Y Y Y Ime
π π
ζω ω ζω ζω −Ω + Ω + = Ω = Ω = (8)
Rearranging
( )2 2
2
2
n
n n
X
Y i
ζω
ω ζω
Ω=
− Ω + Ω (9)
Multiplying and dividing by the conjugate of the denominator, gives
( )( )( )
2 2
2 2 2 2
22
2 2
n nn
n n n n
i X
Y i i
ω ζω ζω
ω ζω ω ζω
− Ω − ΩΩ= ×
− Ω + Ω − Ω − Ω
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( ) ( )
( )2 2
2 22 2
22
2
nn n
n n
iζω
ω ζω ω ζω
Ω = − Ω − Ω − Ω + Ω
(10)
Dividing the numerator and denominator by2nω , and setting / nr ω = Ω , equation (10)
takes the form
( ) ( )( )2
2 22
21 2
1 2
X r r i r
Y r r
ζ ζ
ζ
= − − − +(11)
Multiplying and dividing each expression by ( ) ( )2 22
1 2r r ζ − + gives
( ) ( )
( )( )
( )
( ) ( ) ( ) ( )
2 22 2
2 2 2 22 2 22 2
2 1 2 1 2
1 21 2 1 2
r r r r X r i
Y r r r r r r
ζ ζ ζ
ζ ζ ζ
− + − = −
− +− + − +
(12)
With the help of the shown triangle equation (12)may be written in the form
( ) ( )
[ ]2 22
2cos sin
1 2
X r i
Y r r
ζ ψ ψ
ζ
= −
− +(13)
Expressing X and Y in terms of their original
Definitions (5) and (8), gives
( ) ( )[ ]/ 2 2 22
2
cos sin1 2
i
i
X Ime r
iY Imer r
ϕ
π
ζ
ψ ψ ζ
−
= −− +
( ) ( )[ ]
( ) ( )
/ 2
2 22 22 2
2 2cos sin
1 2 1 2
i ii X Ime r r
i IM eY
r r r r
ϕ π ψ ζ ζ
ψ ψ
ζ ζ
− −−= − =
− + − +, thus
( ) ( )
1
22 22
2 2, and / 2 or / 2 tan / 2
11 2
r r X i i i
r r r
ζ ζ ϕ π ψ ϕ ψ π ϕ π
ζ
−= − − = − = − → = −−− +
ψ 2 r ζ
2(1 )r −
2 2 2(1 ) (2 )r r ζ − +
2
2tan
1
r
r
ζ ψ =
−
ψ 2 r ζ
2(1 )r −
2 2 2(1 ) (2 )r r ζ − +
2
2tan
1
r
r
ζ ψ =
−
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Problem 4
Insert a virtual disk at the shaft discontinuity of moment of inertia 0n
J = , the
corresponding twist angle is nθ . The equations of motion of the three degrees of freedom
are
1 1 1 1( )n J K θ θ θ = −&& , 1 1 2 2( ) ( ) 0n n n n J K K θ θ θ θ θ = − − + − =&& , 2 2 2 2( )n J K θ θ θ = − −&&
from the second equation we have:6 6 61
1 2 1 22 2 2
( ) 0.1536 10 0.0941 10 ( 0.5979) 0.0596 10n n K K K K θ θ θ
θ θ θ + = + → × = × − + ×
Thus2
0.021
1
nθ
θ = −
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Problem 5Solution to Problem 5:Part I:The equations of motion can be derived as follows:
∑ = xm F → ( ) ( )θ θ l xk l xk xm +−−−= 2
θ C C J M ∑ = → ( ) ( )θ θ θ l xkl l xkl J C
+−−= 22
which leads to the following matrix equations
=
−
−+
0
0
5
2
0
02
θ θ
x
kl kl
kl k x
J
m
C
(1)
Assume t X x ω sin= and t ω θ sinΘ= , and substitute the assumed form solutions intoEq. (1).
=
Θ
−−
−−
0
0
5
222
2 X
J kl kl
kl mk
C ω
ω , (2)
The natural frequencies can be determined by setting the determinant of Eq. (2) to zero
05
2det
22
2
=
−−−−
ω
ω
C J kl kl
kl mk , which yields
( ( 052 22222 =−−− l k J kl mk C ω ω (3)
Equation (3) is the characteristic equation of the system. Substitute J C = 0.5ml 2 into (3)
01812 2242 =+− k mk m ω ω , (4)
Therefore, the natural frequencies are
( ) 2.42361=−= mk ω (rad/sec) and ( ) 1.102362
=+= mk ω (rad/sec). (5)
Substituting the natural frequencies into the homogeneous part of Eq. (2) gives thenatural modes of the system:
( )
( ) 1.4234
1
2 2
1
1
1
=+−
=−
=Θ ω mk
k
l
X and
( )
( )1.0
234
1
2 2
2
2
2
−=−−
=−
=Θ ω mk
k
l
X . (6)
1st mode shape 2nd mode shape
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Part II:
The equations of motion can be derived as follows:
∑ = xm F → 2121
3
2
3kxkx
x xm −−=
+
θ C C J M ∑ = → 21
12 233
klxklxl
xl
x J C −=
−
which leads to the following matrix equations, after substituting J C = 0.5ml 2
=
−
+
− 0
0
612
332
2
1
2
1
x
x
k k
k k
x
x
mm
mm
(7)
Assume t X x ω sin11
= and t X x ω sin22
= , and substitute the assumed form solutions
into Eq. (1).
=
−+−
−−
0
0
612
233
2
1
22
22
X
X
mk mk
mk mk
ω ω
ω ω
, (8)
The natural frequencies can be determined by setting the determinant of Eq. (8) to zero
0612
233det
22
22
=
−+−
−−
ω ω
ω ω
mk mk
mk mk , which yields
( )( ) ( )( ) 0122363 2222 =−−+−− ω ω ω ω mk mk mk mk (9)
Equation (9) can be simplified to
01812 2242 =+− k mk m ω ω , (10)
Therefore the natural frequencies remain the same as before. However, the natural modesof the system:
( )
( )
( )( )
4.02363
23623
3
232
1
2
1
1
2
1
1 =−−
−−=
−−
=ω
ω
mk
mk
X
X and
( )
( )
( )( )
4.22363
23623
3
232
2
2
2
2
2
2
1 −=+−
+−=
−−
=ω
ω
mk
mk
X
X . (11)
1st mode shape 2nd mode shape
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Part III: Natural frequencies remain the same, but equations of motion and mode shapesare different. The first case is static coupling and the second is both dynamic and staticcoupling.