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D. Gross • W. Hauger
J. Schröder • W.A. Wall
S. Govindjee
Engineering Mechanics 3
Dynamics
Solutions to
Supplementary
Problems
Gr
The numbers of the problems and the figures correspond
to the numbers in the textbook Gross et al., Engineering
Mechanics 3, Dynamics, 2nd Edition, Springer 2013
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Gr
Motion of a Point Mass
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Gr
Chapter 1
1
E1.17
1 Motion of a Point Mass
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2
A point P moves on a given path from A to B
(Fig. 1.42). Its velocity v decreases linearly with arc-length s from
a value v0 at A to zero at B.
How long does it take P to reach point B?
Example 1.17
s=l
B
v
v
v0
P
s
A
l
s
Fig. 1.42
Solution First we write down the velocity v as a linear function
of the arc-length s:
s
v(s) = v0 1 −
.
l
Separation of variables
ds
=v
dt
→
v0
ds
= dt
1 − sl
and indeterminate integration lead to
Z
Z
v0 t
ds
=
v
dt
→
s
=
l
1
−
C
exp
−
.
0
1 − sl
l
The integration constant C is determined from the initial condition:
v0 t
s(0) = 0 : 0 = 1 − C → s = l 1 − exp −
.
l
Point B is reached when s = l. This yields the corresponding time
tB :
Gr
s(tB ) = l
→
tB → ∞ .
3
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1 Motion of a Point Mass
Example 1.18 A radar screen tracks a rocket which rises vertically
with a constant acceleration
a (Fig. 1.43). The rocket is
launched at t = 0.
Determine the angular velocity ϕ̇ and the angular acceleration ϕ̈ of the radar screen.
Calculate the maximum angular velocity ϕ̇ and the corresponding angle ϕ.
ϕ
111111111111
000000000000
l
Fig. 1.43
Solution Since the acceleration
a is constant, the velocity v
and the position x of the rocket
are
x
v = at + v(0) ,
x = at2 /2 + v(0)t + x(0) .
Applying the initial conditions yields
v(0) = 0
→
x(0) = 0
→
v = at,
at2
x=
.
2
The angle ϕ of the radar screen follows as
2
x
at
tan ϕ =
→ ϕ(t) = arctan
.
l
2l
Differentiation leads to the angular velocity
"
2 2 #
at
at
ϕ̇(t) = / 1 +
l
2l
Gr
and the angular acceleration
"
2 2 #2
a 3a3 t4
at
ϕ̈(t) =
−
/ 1+
.
l
4l3
2l
ϕ
E1.18
1 Motion of a Point Mass
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4
The time t∗ of the maximum angular velocity ϕ̇max is obtained
from
2 1/4
4l
ϕ̈(t∗ ) = 0 → t∗ =
.
3a2
Thus,
ϕ̇max = ϕ̇(t∗ )
→
ϕ̇max
s √
3 3a
=
8l
and
Gr
√
ϕ(t∗ ) = arctan(1/ 3)
→
ϕ(t∗ ) = 30◦ .
5
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1 Motion of a Point Mass
Example 1.19 Two point masses P1 and P2 start at point A with
zero initial velocities and travel on a circular path. P1 moves with
a uniform tangential acceleration at1 and P2 moves with a given
uniform angular velocity ω2 .
a) What value must at1 have
in order for the two masses
P1
r
to meet at point B?
b) What is the angular velociB
A
ty of P1 at B?
c) What are the normal acceP2
lerations of the two masses
Fig. 1.44
at B?
Solution The velocity and position of P1 follow from at1 = const =
v̇ with the initial conditions s01 = 0 and v01 = 0 as
v1 = at1 t ,
s1 =
1
at1 t2 .
2
Similarly, for point P2 we obtain from at2 = 0 with s02 = 0 and
v02 = rω2 :
v2 = rω2 ,
s2 = rω2 t .
a) Both points meet at time tB at point B. Thus,
πr =
1
at1 t2B ,
2
πr = rω2 tB .
This leads to
Gr
tB =
π
ω2
→
at1 =
2πr
2rω22
.
=
2
tB
π
E1.19
1 Motion of a Point Mass
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6
b) The tangential acceleration at1 and the time tB are now known.
Hence, we can calculate the angular velocity of P1 at B:
v1 (tB ) = at1 tB = rω1 (tB )
→
ω1 (tB ) =
2rω22 π
at1 tB
=
= 2ω2 .
r
πrω2
c) The normal accelerations at B follow from an = rω 2 :
Gr
an1 = rω12 (tB ) = 4rω22 ,
an2 = rω22 .
7
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1 Motion of a Point Mass
Example 1.20 A child of mass m jumps up and down on a trampo-
line in a periodic manner. The child’s jumping velocity (upwards
upon leaving the trampoline) is v0 and during the contact time
∆t the contact force F (t) has a triangular form.
Find the necessary contact force amplitude F0 and the jumping period T0 .
F
F0
z
t
T0
∆t
Fig. 1.45
Solution The child is subjected
to its constant weight W = mg
and, during the contact with the
trampoline, to the contact force F (t). While the child is in the
air, the equation of motion is given by
F
F0
mg
F
0
t1
t2
t
T0
↑: mz̈ = −mg.
Integration between t = t0 = 0 (end of a contact) and t = t1
(beginning of a new contact) yields
mv1 − mv0 = −mgt1 ,
where v1 = v(t1 ) and v0 = v(0). Recall that the velocity at the
beginning of a vertical motion and the velocity at the end of a
free fall of a body are equal in magnitude: v1 = −v0 (note the
different signs). Therefore, we obtain
Gr
2v0 = gt1
→
t1 = 2
v0
.
g
E1.20
1 Motion of a Point Mass
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8
The jumping period T0 follows with ∆t = t2 − t1 as
T0 = t1 + ∆t
→
T0 =
2v0
+ ∆t .
g
We now apply the Impulse Law between time t0 and time t2 (see
the figure):
1
↑ : m v2 − m v0 = −mgT0 + F0 (t2 − t1 ) .
2
Gr
In order to have a periodic process, the velocities v2 and v0 have
to coincide: v2 = v0 . With this condition the Impulse Law yields
2v
2T0
1
0
mg = 2
+ 1 mg .
−mgT0 + F0 ∆t = 0 → F0 =
2
∆t
g∆t
9
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1 Motion of a Point Mass
Example 1.21 A car is travelling in a circular arc with radius R
s
and velocity v0 when it starts to brake.
v0
If the tangential deceleration is
at (v) = −(a0 + κv), where a0 and κ are
given constants, find the time to brake
tB , the stopping distance sB , and the
normal acceleration an during the braking.
R
Fig. 1.46
Solution The acceleration at is given as a function of the velocity:
at (v) = v̇ = −(a0 + κv) .
We separate the variables and integrate (initial condition: v(0) = v0 ):
Z v
1 a0 + κv0
dv̄
t(v) = −
= ln
.
a
+
κv̄
κ
a0 + κv
v0 0
The time tB when the car comes to a stop follows from the condition v = 0:
1 κv0 tB = t(v = 0) = ln 1 +
.
κ
a0
Now we determine the inverse function of t(v):
i
a0 + κv0
a0 h
κv0 −κt
eκt =
→ v(t) =
1+
e
−1 .
a0 + κv
κ
a0
Integration with the initial condition s(0) = 0 leads to the position
Z t
i
κv0 a0 h
s(t) =
v(t̄)dt̄ = 2 1 +
1 − e−κt − κt .
κ
a0
0
Gr
The stopping distance sB is obtained for t = tB :
"
!
#
a0 κv0 1
κv0 sB = s(tB ) = 2 1 +
1−
− ln 1 +
0
κ
a0
a0
1 + κv
a0
h
i
a0 κv0
κv0
= 2
− ln 1 +
.
κ a0
a0
E1.21
1 Motion of a Point Mass
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10
The normal acceleration an (t) during the breaking is found as
2
a20 v2
κv0 −κt
=
1+
e
−1 .
an =
R
Rκ2
a0
Gr
As a check on the correctness of the result we calculate an for
t = tB and obtain an = 0.
11
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1 Motion of a Point Mass
Example 1.22 A point P moves on
2
a parabola y = b(x/a) from A to
B. Its position as a function of the
time is given by the angle ϕ(t) =
arctan ω0 t (see Fig. 1.47).
Determine the magnitude of velocity v(t) of point P . How much
time elapses until P reaches point
B? Calculate its velocity at B.
E1.22
y
b
B
P
r
ϕ
A
a x
Fig. 1.47
Solution The parabola y = b(x/a)2 and the angle ϕ(t) = arctan ω0 t
are given. The angle ϕ can also be expressed as ϕ = arctan y/x.
Thus, y/x = ω0 t. Solving for x and y yields the position of
point P :
x(t) =
a2
ω0 t ,
b
y(t) =
a2
(ω0 t)2 .
b
To obtain the velocity of P , we differentiate:
ẋ(t) =
v=
p
a2
ω0 ,
b
ẋ2 + ẏ 2
a2 2
ω t,
b 0
a2 p
v(t) = ω0 1 + 4ω02 t2 .
b
ẏ(t) = 2
→
Point B is reached at time tB when x = a:
x(tB ) = a
→
tB =
b
.
aω0
Gr
Thus, the velocity at B is obtained as
s
a2
b2
vB = v(tB ) → vB = ω0 1 + 4 2 .
b
a
E1.23
1 Motion of a Point Mass
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12
Example 1.23 A rod with length l rota-
tes about support A with angular position given by ϕ(t) = κ t2 . A body
G slides along the rod with position
r(t) = l(1 − κ t2 ).
a) Find the magnitude of velocity and
acceleration of G when ϕ = 45◦ .
b) At what angle ϕ does G hit the support?
Given: l = 2 m, κ = 0.2 s−2 .
B
l
r
G
ϕ(t)
A
Fig. 1.48
Solution a) First we calculate the time t = t1 that it takes the
rod to reach the position ϕ = ϕ1 = 45◦ :
q
ϕ1 = π/4 = κt21
→
t1 = π/(4κ) = 1.98 s .
Then we determine the derivatives of the given functions r(t) and
ϕ(t):
r = l(1 − κt2 ) , ṙ = −2κlt ,
r̈ = −2κl ,
ϕ = κt2 ,
ϕ̈ = 2κ .
ϕ̇ = 2κt ,
vϕ
With t = t1 we obtain the velocity
vr = ṙ = −2κlt1 = −1.58 m/s ,
κt21 )2κt1
Gr
vϕ = rϕ̇ = l(1 −
= 0.34 m/s ,
q
v = vr2 + vϕ2 = 1.62 m/s
v
vr
π
4
13
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1 Motion of a Point Mass
and the acceleration
ar = r̈ − rϕ̇2 = −2κl − l(1 − κt21 )4κ2 t21
= −1.07 m/s2 ,
aϕ = rϕ̈ + 2ṙ ϕ̇ = l(1 − κt21 )2κ − 2 · 2κlt1 2κt1
2
= −2.34 m/s ,
q
a = a2r + a2ϕ = 2.57 m/s2 .
ar
π
4
b) Body G reaches the support (r = 0) at time tE :
q
r = 0 = l(1 − κt2E )
→
tE = 1/κ = 2.24 s .
This yields the corresponding angle ϕE :
Gr
ϕE = κt2E = 1
(=
b 57.3◦) .
aϕ
a
E1.24
1 Motion of a Point Mass
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14
Example 1.24 A mouse sits in a tower (with radius R) at point A
and a cat sits at the center 0.
If the mouse runs at a constant
velocity vM along the tower wall and
ϕ
r
the cat chases it in an Archimedian
0
spiral r(ϕ) = R ϕ/π, what must the H
A
R
cat’s constant velocity vC be in order
to catch the mouse just as the mouse reaches its escape hole H? At what
Fig. 1.49
time does it catch the mouse?
Solution We determine the components of the velocity of the cat
from the given equation r(ϕ) = Rϕ/π of the Archimedian spiral:
vr = ṙ =
dr dϕ
R
= ϕ̇
dϕ dt
π
and
vϕ = rϕ̇ =
R
ϕϕ̇ .
π
Thus, the constant velocity vC can be written as
q
R p
R dϕ p
1 + ϕ2 .
vC = vr2 + vϕ2 = ϕ̇ 1 + ϕ2 =
π
π dt
Separation of variables and integration lead to
vC
Zt
0
R
dt̄ = vC t =
π
Zϕ p
1 + ϕ̄2 dϕ̄ .
0
With the integral
Z p
i
1h p
1 + x2 dx =
x 1 + x2 + arsinh x
2
Gr
this results in
R p
vC t =
ϕ 1 + ϕ2 + arcsinh ϕ .
2π
15
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1 Motion of a Point Mass
The time T when both the cat and the mouse reach the hole
follows from the constant velocity vM of the mouse along the wall:
πR = vM T
→
T =
πR
.
vM
Gr
Introduction of T and ϕ(T ) = π into the expression for vC t yields
the velocity of the cat:
vM p
vC = 2 π 1 + π 2 + arcsinh π = 0.62 vM .
2π
E1.25
1 Motion of a Point Mass
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16
A soccer player kicks the ball (mass m) so that
it leaves the ground at an angle α0 with an initial velocity v0
(Fig. 1.50). The air exerts a drag force Fd = k v on the ball; it
acts in the direction opposite to the velocity.
Determine the velocity v(t) of the ball. Calculate the horizontal component vH of v when the ball reaches the teammate at a
distance l.
Example 1.25
x
z
v0
α0
l
Fig. 1.50
Solution The equations of motion are
mẍ = −Fd cos α ,
mz̈ = mg + Fd sin α .
We introduce the kinematic relations
ẍ =
dẋ
,
dt
z̈ =
x
v
dż
dt
α
Fd
z
mg
and the drag force Fd = kv. Noting that the components of the
velocity are given by
ẋ = v cos α ,
ż = −v sin α
we obtain
m
dẋ
= −k ẋ ,
dt
m
dż
= mg − k ż .
dt
Separation of variables gives
Gr
dẋ
k
= − dt ,
ẋ
m
dż
k
mg = − m dt
ż −
k
17
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1 Motion of a Point Mass
and integration yields
ẋ
k
ln
=− t,
C1
m
ln
mg
k =−kt.
C2
m
ż −
The constants of integration C1 and C2 can be determined from
the initial conditions. For t = 0 the left-hand sides of the equations
above have to be zero. Thus, the arguments of the ln-functions
have to be equal to one (numerator and denominator have to be
equal):
C1 = ẋ(0) = v0 cos α0 ,
C2 = ż(0) −
mg
mg
= −v0 sin α0 −
.
k
k
This leads to the components of the velocity:
mg mg
ẋ(t) = v0 cos α0 e−kt/m , ż(t) =
−
+ v0 sin α0 e−kt/m .
k
k
We now integrate the x-component to obtain the horizontal position of the ball:
m
x(t) = − v0 cos α0 e−kt/m + C .
k
Exploiting the initial condition
m
x(0) = 0 → C = v0 cos α0
k
yields
x(t) =
m
v0 cos α0 1 − e−kt/m .
k
The time t∗ when the ball reaches the teammate at the distance
l is found to be
m
mv0 cos α0
x(t∗ ) = l → t∗ =
ln
.
k
mv0 cos α0 − kl
This leads to the corresponding horizontal component of the velocity:
Gr
ẋ(t∗ ) = v0 cos α0 −
kl
.
m
E1.26
1 Motion of a Point Mass
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18
Example 1.26 A body with mass m
starts at a height h at time t = 0
with an initial horizontal velocity v0 .
If the wind resistance can be
approximated by a horizontal force
H = c0 m ẋ2 , at what time tB and
location xB does it hit the ground?
z
m
v0
h
B
x
Fig. 1.51
Solution The equations of
motion are given by
→ : mẍ = −mc0 ẋ2 ,
H
z
mg
↑ : mz̈ = −mg .
x
We integrate and apply the
initial conditions x(0) = 0, z(0) = h, ẋ(0) = v0 , ż(0) = 0 to obtain
Z ẋ
Z t
dx̄˙
1
,
=
−c
dt̄ → ẋ =
0
2
1
˙
v0 x̄
0
v0 + c0 t
Z x
Z t
1
1
dx̄ =
dt̄ → x =
ln(1 + c0 v0 t) ,
1
c0
0
0
v0 + c0 t̄
g
ż = −gt ,
z = − t2 + h .
2
The time tB when the body hits the ground follows from zB = 0:
s
2h
tB =
.
g
Thus, the location of point B is obtained as
s
!
2h
1
xB = x(t = tB ) =
ln 1 + c0 v0
.
c0
g
Gr
In the case of a vanishing wind resistance (c0 = 0) this result
reduces to
s
s
!
2h
2h
1
xB = lim
ln 1 + c0 v0
= v0
.
c0 →0 c0
g
g
19
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1 Motion of a Point Mass
Example 1.27 A mass m slides on a
E1.27
rotating frictionless and massless
rod S such that it is pressed against
a rough circular wall (coefficient of
friction µ).
If the mass starts in contact with
the wall at a velocity v0 , how many
rotations will it take for its velocity
to drop to v0 /10?
µ
r
S
m
g
Fig. 1.52
Solution If we express the accelera-
tion vector in terms of the SerretFrenet frame, then the equations of
motion are written as
տ : mat = −R ,
ւ : man = N .
at
an
N
R
Note that the weight of the mass does not influence the motion
since the motion takes place in a horizontal plane. If we use the kinematic relations at = v̇, an = v 2 /r, and the friction law R = µN
we can write the first equation of motion in the form
mv̇ = −µm
v2
.
r
Separation of variables and integration yield
Z v
Z t
dv̄
µ
v0
.
=
−
dt̄ → v(t) =
µv
2
1 + r0 t
v0 v̄
0 r
Gr
We integrate again to obtain the distance traveled:
Z t
Z s
dt̄
r
µv0
ds̄ = v0
v0 t̄ → s(t) = µ ln (1 + r t) .
1
+
µ
0
0
r
1 Motion of a Point Mass
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20
Now we calculate the time t1 that it takes for the velocity to drop
to v0 /10:
v0
v0
=
µv
10
1 + r 0 t1
→
t1 =
9r
.
µv0
The corresponding value s(t1 ) is found as
s1 = s(t1 ) =
r
µv0
r
ln (1 +
t1 ) =
ln 10 .
µ
r
µ
This yields the corresponding number of rotations:
Gr
n=
s1
ln 10
=
.
2πr
2πµ
21
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En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
1 Motion of a Point Mass
Example 1.28 A car (mass m) is traveling with constant velocity
v along a banked circular curve (radius r, angle of slope α), see
Fig. 1.53. The coefficient of static friction µ0 between the tires of
the car and the surface of the road is given.
r
0000000
1111111
0000000
1111111
0000000
1111111
1111111
0000000
0000000
1111111
m
µ0
α
Fig. 1.53
Determine the region of the allowable velocities so that sliding
(down or up the slope) does not take place.
Solution We model the car as a point mass and express the ac-
celeration vector in terms of the Serret-Frenet frame. Then the
equation of motion in the direction of the normal vector is (see
the free-body diagram)
man = N sin α + H cos α .
2.0
µ0 = 0.3
g
en et
r
1.5
v
v 2 /gr
M
1.0
0.5
mg
r
M
en
H
0
N
π/6
π/3
α
α
Since the car does not move in the vertical direction we can apply
the equilibrium condition
0 = N cos α − H sin α − mg .
Gr
↑:
E1.28
1 Motion of a Point Mass
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
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22
We now solve these two equations for the normal force N and the
force of static friction H:
H = man cos α − mg sin α ,
N = man sin α + mg cos α .
The car does not slide if the condition of static friction
|H| ≤ µ0 N
is satisfied. With an = v 2 /r this leads to the allowable region of
the velocity:
tan α + µ0
v2
tan α − µ0
≤
≤
.
1 + µ0 tan α
gr
1 − µ0 tan α
Gr
This is displayed for µ = 0.3 as a function of the angle α in the
figure.
23
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
1 Motion of a Point Mass
Example 1.29 A car (mass m) has a velocity v0 at the beginning of
a curve (Fig. 1.54). Then it slows down with constant tangential
acceleration at = −a0 . The coefficient of static friction between
the road and the tires is µ0 .
s
Calculate the velocity v
v0
of the car as a function of
the arc-length s. What is the
m
necessary radius of curvature
ρ(s)
ρ(s) of the road so that the
M
car does not slide?
Fig. 1.54
Solution We model the car as a point mass. Its velocity v can
be determined from the given constant tangential acceleration at
through integration (initial condition v(0) = v0 ):
v̇ = at = −a0
→
v(t) = v0 − a0 t .
The distance traveled follows from
ṡ = v
→
s(t) = s0 + v0 t − a0 t2 /2 .
With the initial condition s(0) = s0 = 0 we obtain
s(t) = v0 t − a0 t2 /2 .
Gr
Elimination of the time t yields the velocity as a function of the
arc-length:
q
v(s) = v02 − 2a0 s .
E1.29
1 Motion of a Point Mass
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
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24
In order to determine the necessary radius of curvature ρ(s) we
write down the equations of motion:
mat = Ht
→
man = Hn
→
0 = N − mg
→
Ht = −ma0 ,
v2
Hn = m ,
ρ
N = mg .
The static friction force H = (Ht2 +Hn2 )1/2 and the normal force N
have to satisfy the condition of static friction to avoid sliding of
the car:
|H| ≤ µ0 N
→
a20 +
v4
≤ µ20 g 2 .
ρ2
Solving for ρ yields
v 2 − 2a0 s
ρ(s) ≥ p0 2
.
µ0 g 2 − a20
This condition can not be satisfied if a0 > µ0 g.
mg
et
Ht
Hn
̺
Gr
en
M
N
25
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En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
1 Motion of a Point Mass
Example 1.30 A bowling ball (mass m) moves with constant ve-
locity v0 on the frictionless return of a bowling alley. It is lifted
on a circular path (radius r) to the height 2r at the end of the
return. The upper part of the circular path has a frictionless guide
of length r ϕG (Fig. 1.55).
Given the angle ϕG , determine the velocity v0 such that the
bowling ball reaches the upper level.
g
ϕG
r
v0
m
Fig. 1.55
Solution The velocity v0 has to be large enough so that the bow-
ling ball reaches the upper level (height 2r) with a velocity v ≥ 0.
It is convenient to use the Conservation of Energy Law to determine the relation between v0 and v. With T0 = mv02 /2, V0 = 0,
T1 = mv 2 /2 and V1 = 2mgr we obtain
T0 + V0 = T1 + V1
→
mv02 /2 + 0 = mv 2 /2 + 2mgr .
This yields a first requirement on v0 :
v02 = v 2 + 4gr
→
v02 ≥ 4gr .
In addition, the velocity v0 has to be large enough so that the
normal force between the bowling ball and the lower part of the
circular path does not become zero before the ball reaches the
guide of length rϕG . The necessary velocity v(ϕG ) follows from
the equation of motion in the normal direction (note that ϕ is
measured from the upper level):
Gr
ց:
m
v 2 (ϕ)
= N + mg cos ϕ .
r
E1.30
1 Motion of a Point Mass
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
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26
The condition N ≥ 0 for ϕ = ϕG leads to
v 2 (ϕG ) ≥ gr cos ϕG .
In order to calculate the corresponding velocity v0 we use the Conservation of Energy Law between the lower level and the beginning
of the guide:
T0 + V0 = T2 + V2
mv02 /2 + 0 = mv 2 (ϕG )/2 + mgr(1 + cos ϕG ) .
→
Thus, we obtain the second requirement
v02 ≥ (2 + 3 cos ϕG )gr .
Both requirements are plotted in the figure, which shows that
the minimum velocity v0 is obtained as
(
(2 + 3 cos ϕG )gr for ϕG < ϕ∗G = arccos 2/3 ,
2
v0 =
4gr
for ϕG > ϕ∗G .
8
ϕ
6
N
mg
4
v02 /gr
2+3 cos ϕG
2
ϕ∗G
0
0.2π
0.4π 0.6π 0.8π
Gr
ϕG
π
27
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
1 Motion of a Point Mass
Example 1.31 A point mass m is
E1.31
subjected to a central force
F = mk 2 r, where k is a constant
and r is the distance of the mass
from the origin 0. At time t = 0
the mass is located at P0 and has
velocity components vx = v0 and
vy = 0.
Find the trajectory of the
mass.
y
v0
P0
m
F
r0
r
α
0
x
Fig. 1.56
Solution The equations of motion in the directions x and y are
→: mẍ = −F cos α ,
↑ : mÿ = −F sin α .
With F = mk 2 r, x = r cos α and y = r sin α we obtain
ẍ + k 2 x = 0 ,
ÿ + k 2 y = 0 .
Both equations are equivalent to the differential equation that describes undamped free vibrations of a point mass (see Chapter 5).
The solutions are
x = A cos kt + B sin kt ,
y = C cos kt + D sin kt .
The constants of integration are calculated from the initial conditions:
→ A=0,
ẋ(0) = v0
→ B=
Gr
x(0) = 0
y(0) = r0
v0
, ẏ(0) = 0
k
→ C = r0 ,
→ D=0.
1 Motion of a Point Mass
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
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28
We now have a parametric representation of the curve describing
the motion:
v0
sin kt ,
y = r0 cos kt .
x=
k
To eliminate the time, these equations are squared and then added. Thus, we finally obtain
2 2
x
y
+
=1.
v0 /k
r0
Gr
The point mass moves along an ellipse which reduces to a circle
for k = v0 /r0 .
29
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
1 Motion of a Point Mass
Example 1.32 A centrifuge with radius r rotates with constant an-
gular velocity ω0 . A mass m is to be placed at rest in the centrifuge
and accelerated within a time t1 to the angular velocity ω0 .
What will be the needed (constant) moment M acting on the
mass? What is the power P of this
moment?
ω0
m
r
Fig. 1.57
Solution The centrifuge rotates with a
constant angular velocity. Thus, the
driving torque M needed to accelerate the point mass is equal to the moment of the friction force R which acts
between the mass and the cylinder:
at
R
N
N
R
M = rR .
The equation of motion in the tangential direction for the mass is
↑ : mat = R ,
where at = rω̇. Thus,
mr ω̇ =
M
r
→
ω̇ =
M
.
mr2
Integration with the initial condition ω(0) = 0 yields
M
t.
r2 m
Gr
ω=
E1.32
1 Motion of a Point Mass
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En s, Ha
gin ug
ee er,
rin
g M Schr
ö
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Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
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30
The condition ω(t1 ) = ω0 leads to the required moment:
M=
r2 mω0
.
t1
The corresponding power is
P = M · ω 0 = M ω0 =
r2 mω02
.
t1
Gr
Note that the moment M has to be reduced to zero after time t1 .
Otherwise the mass would be further accelerated.
31
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En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
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cs e
1 Motion of a Point Mass
Example 1.33 A skier (mass m) has the velocity vA = v0 at point
A of the cross country course (Fig. 1.58). Although he tries hard
not to lose velocity skiing uphill, he reaches point B with only a
velocity vB = 2 v0 /5. Skiing downhill between point B and the
finish C he again gains speed and reaches C with vC = 4 v0 .
Between B and C assume that a constant friction force acts due
to the soft snow in this region; the drag force from the air on the
skier can be neglected.
Calculate the work done by the skier on the path from A to B
(here the friction force is negligible). Determine the coefficient of
kinetic friction between B and C.
0000000000000000000000000
1111111111111111111111111
00000000000
11111111111
0000000000000000000000000
1111111111111111111111111
00000000000
11111111111
0000000000000000000000000
1111111111111111111111111
00000000000
11111111111
0000000000000000000000000
1111111111111111111111111
00000000000
11111111111
0000000000000000000000000
1111111111111111111111111
00000000000
11111111111
0000000000000000000000000
1111111111111111111111111
00000000000
11111111111
B
h
f inish
3h
A
C
10h
Fig. 1.58
Solution In order to calculate the work done by the skier on the
path from A to B we use the work-energy theorem:
TB + VB = TA + VA + U
→
Gr
→
2
2
mvB
/2 + mgh = mvA
/2 + 0 + U
U = m(gh − 21v02 /50) .
E1.33
1 Motion of a Point Mass
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En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
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32
Now we apply the work-energy theorem between points B and C,
where the work of the friction force is given by −RlBC :
TC + VC = TB + VB + U
→
2
2
mvC
/2 + 0 = mvB
/2 + 3mgh − RlBC .
With the normal force
N = mg cos α
→
N = mg
10h
lBC
mg
and the law of kinetic friction
R = µN
→
R = µmg
R
10h
lBC
N
α
we obtain
µ=
2
3
v 2 − vB
− C
10
20gh
→
µ≈
Gr
The result is valid only for µ ≥ 0.
4v 2
3
− 0 .
10 5gh
33
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En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
1 Motion of a Point Mass
Example 1.34 A circular disk (radius R)
rotates with the constant angular velocity Ω. A point P moves along a straight
guide; its distance from the center of
the disk is given by ξ = R sin ω t where ω = const (Fig. 1.59).
Determine the velocity and the acceleration of P .
E1.34
R
ξ
P
Ω
Fig. 1.59
Solution We use polar coordinates r, ϕ to
solve the problem. From Ω = const we find
ϕ̇ = Ω = const
→
ϕ = Ωt ,
ϕ̈ = 0 .
eϕ
P
er r
ϕ
The position vector is written as
r = ξ er
→
r = R sin ωt er .
Differentiation yields the velocity vector
v = ξ˙ er + ξ ϕ̇ eϕ
→
v = Rω cos ωt er + RΩ sin ωt eϕ
and the acceleration vector
a = (ξ¨ − ξ ϕ̇2 ) er + (ξ ϕ̈ + 2ξ̇ ϕ̇) eϕ
Gr
→
a = −R(ω 2 + Ω2 ) sin ωt er + 2RωΩ cos ωt eϕ .
1 Motion of a Point Mass
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
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cs e
34
Gr
The paths of point P are displayed for several values of Ω/ω in
the following figures.
Ω/ω = 0.25
Ω/ω = 0.5
Ω/ω = 1.0
Ω/ω = 2.0
35
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
1 Motion of a Point Mass
Example 1.35 A chain with length l and
mass m hangs over the edge of a frictionless table by an amount e.
If the chain starts with zero initial
velocity, find the position of the end of
the chain as a function of time.
000000
111111
000000
111111
000000
111111
000000
111111
000000
111111
E1.35
e
Fig. 1.60
Solution All the links of the chain have the same displacement,
velocity and acceleration. The corner only produces a change of
direction. We therefore consider the chain to be a single mass with
an applied force that depends on the length x of the overhanging
part. Thus, with a = ẍ, the equation of
motion is
g
x
ma = m g → ẍ − x = 0 .
x
l
l
x
0000000
1111111
0000000
1111111
0000000
1111111
0000000
1111111
This differential equation of second order
0000000
1111111
with constant coefficients has the solution
x(t) = A cosh
r
g
t + B sinh
l
r
m g
l
g
t.
l
We calculate the integration constants from the initial conditions:
)
r
ẋ(0) = 0 → B = 0
g
→ x(t) = e cosh
t.
l
x(0) = e → A = e
This solution is valid only for x ≤ l.
x−l
We may also solve the problem by
m
l
making an imaginary section cut at
the corner. Then the equations of
motion for each part of the chain are
d m m
d l−x m
ẋ = S ,
xẋ = xg − S .
dt
l
dt l
l
If we eliminate S we again obtain the
differential equation
Gr
g
ẍ − x = 0 .
l
S
S
m
x
l
x
E1.36
1 Motion of a Point Mass
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En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
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mi
cs e
36
x
Example 1.36 A rotating source of
1111111111
0000000000
light throws a beam of light onto a
screen (Fig. 1.61). Point P on the
screen should move with constant
velocity v0 .
Determine the required angular acceleration ϕ̈(ϕ) of the source
of light. Sketch ϕ̇(ϕ) and ϕ̈(ϕ).
P
v0
r0
ϕ
Fig. 1.61
Solution The position of point P is given by
x = r0 tan ϕ .
We write down the inverse function
x
ϕ = arctan
.
r0
Differentiation with ẋ = v = v0 = const yields
1
v0 r0
v0
v0
ẋ
= 2
=
cos2 ϕ ,
=
2
2
2
r0
r0 + x
r0
r0 (1 + tan ϕ)
x
1 + r0
v 2
v0
0
ϕ̈ = 2 cos ϕ(− sin ϕ)ϕ̇ = −2
sin ϕ cos3 ϕ .
r0
r0
ϕ̇ =
ϕ̇
v0
r
−
π
2
π
2
ϕ
ϕ̈
Gr
−
π
2
π
2
ϕ
37
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En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
1 Motion of a Point Mass
Gr
Note: the maximum value of ϕ̈, located at ϕ = ±30◦ , is obtained
as
3 √ v0 2
|ϕ̈max | =
3
.
8
r0
E1.37
1 Motion of a Point Mass
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
38
Example 1.37 A car travels with velocity v0 = 100 km/h. At time
t = 0, the driver fully applies the brakes. At that moment the car
starts sliding on a rough road (coefficient of kinetic friction µ).
Use the simplest model for the car (point mass) and calculate
the time t∗ and the distance x∗ until the car comes to a stop
a) on a dry road (µ = 0.8),
b) on a wet road (µ = 0.35).
Solution The equation of motion in the horizontal direction
← : ma = mẍ = −R ,
x
the equilibrium condition in the
vertical direction
mg
R
↑ : 0 = N − mg
N
and the law of friction
R = µN
lead to
a = −µg .
Integration with v(t = 0) = v0 and x(t = 0) = 0 yields
v(t) = v0 − µgt ,
x(t) = v0 t −
1
µgt2 .
2
The time t∗ follows from the condition v = 0:
v0
t∗ =
.
µg
This leads to
Gr
x∗ = x(t∗ ) =
v02
v2
v2
− 0 = 0 .
µg 2µg
2µg
39
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En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
1 Motion of a Point Mass
a) On a dry road (µ = 0.8) we obtain
100 · 1000
= 3.55 s ,
3600 · 0.8 · 9.81
1
100 2
= 49 m .
x∗ =
3.6
2 · 0.8 · 9.81
t∗ =
b) On a wet road (µ = 0.35) we are led to
100 · 1000
= 8.1 s ,
3600 · 0.35 · 9.81
100 2
1
x∗ =
= 112 m .
3.6 2 · 0.35 · 9.81
Gr
t∗ =
E1.38
1 Motion of a Point Mass
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
40
Example 1.38 In order to determine the
coefficient of restitution e experimentally, a ball is dropped from height h0 onto
a horizontal rigid surface (Fig. 1.62). After the ball has hit the surface 7 times, it
reaches only 20% of the original height
h0 .
Calculate the coefficient of restitution.
Solution With the positive direction of
the velocity taken as upwards, the velocity of the ball immediately before the
first impact is given by
p
v = − 2gh0 .
The definition
h0
h7 = 0.2h0
Fig. 1.62
h0
h1
h2
1111111
0000000
0000000
1111111
h7
v
v
of the coefficient of restitution in terms of the velocities yields the
velocity v̄ immediately after the impact:
p
v = −ev = e 2gh0 .
e=−
From the Conservation of Energy Law we obtain the height which
the body will reach:
1
mv 2 = mgh1
2
Similarly, we obtain
Gr
hi = e2 hi−1
→
h1 =
v2
= e 2 h0 .
2g
41
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ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
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1 Motion of a Point Mass
for the subsequent impacts. Thus,
h7 = e2 h6 = e4 h5 = . . . = e14 h0
and
Gr
e=
h7
h0
1/14
= 0.21/14 = 0.891 .
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
Gr
Dynamics of Systems of Point
Masses
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
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mi
cs e
Gr
Chapter 2
2
E2.10
2 Dynamics of Systems of Point Masses
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
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44
Example 2.10 Two vehicles (masses m1 and m2 , velocities v1 and
v2 ) crash head-on, see Fig. 2.20. After a plastic impact the vehicles
are entangled and slide with locked wheels a distance s to the right.
v1
v2
The coefficient of kinetic
friction between the wheels
m2
m1
and the road is µ.
Calculate v1 if v2 and s
Fig. 2.20
are known.
Solution The total momentum of the system remains unchanged
during the collision. We assume that positive velocities are directed to the right (note the direction of v2 ). We then obtain the
velocity v̄ of the vehicles after the impact:
1111111111111
0000000000000
m1 v1 − m2 v2 = (m1 + m2 )v̄
→
v̄ =
m1 v1 − m2 v2
.
m1 + m2
In order to relate the distance s to the velocity v̄ we apply the
work-energy theorem
T1 − T0 = U .
We insert the kinetic energies
T0 = (m1 + m2 )v̄ 2 /2 ,
T1 = 0 ,
the work of the friction force
U = −Rs
and Coulomb’s friction law
R = µN
→
R = µ(m1 + m2 )g .
Gr
We then obtain
1
− (m1 + m2 )v̄ 2 = −µ(m1 + m2 )gs
2
m2
m2 √
→ v1 =
v2 + 1 +
2µgs .
m1
m1
45
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2 Dynamics of Systems of Point Masses
Example 2.11 A block (mass m2 ) rests on a horizontal platform
(mass m1 ) which is also initially at rest (Fig. 2.21). A constant
force F accelerates the
l
platform (wheels rolling
µ
m2
without friction) which
F
m1
causes the block to slide
on the rough surface of
the platform (coefficient of
Fig. 2.21
kinetic friction µ).
11111111111
00000000000
Determine the time t∗ that it takes the block to fall off the
platform.
Solution We separate the
block and the platform and
introduce the coordinates
x1 and x2 as shown in the
free-body diagram. Then
the equations of motion for
the two bodies are
11
00
11
00
11
00
11
00
R
x1
N
1
① → : m1 ẍ1 = F − R ,
m2 g
2
x2
R
F
② → : m2 ẍ2 = R .
m1 g
With the friction law R =
µN = µm2 g, we obtain
F − µm2 g
,
ẍ2 = µg .
ẍ1 =
m1
A
B
Now, we integrate twice. Using the initial conditions x1 (0) =
x2 (0) = 0 and ẋ1 (0) = ẋ2 (0) = 0 we obtain
F − µm2 g
t,
m1
x1 =
F − µm2 g t2
,
m1
2
Gr
ẋ1 =
ẋ2 = µgt ,
x2 = µg
t2
.
2
E2.11
2 Dynamics of Systems of Point Masses
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46
The block falls off the platform if
x1 − x2 = l .
This yields
Gr
F − µm2 g (t∗ )2
(t∗ )2
− µg
=l
m1
2
2
→
∗
t =
s
2lm1
.
F − µg(m1 + m2 )
47
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2 Dynamics of Systems of Point Masses
A railroad wagon (mass m1 ) has a velocity v1
(Fig. 2.22). It collides with a wagon (mass m2 ) which is initially at rest. Both wagons roll without friction after the collision.
The second wagon is connected via a spring (spring constant k)
with a block (mass m3 ) that lies on a rough surface (coefficient of
static friction µ0 ).
Assume the impact to be plastic and determine the maximum
value of v1 so that the block stays at rest.
Example 2.12
v1
m1
Fig. 2.22
k
m2
m3
µ0
111111111111111111
000000000000000000
Solution The total momentum of the system remains unchanged
during the impact. This yields the velocity v̄ of the wagons after
the collision:
m1
m1 v1 = (m1 + m2 )v̄ → v̄ =
v1 .
m1 + m2
x
m1
m3 g
m2
11111111111111
00000000000000
00000000000000
11111111111111
m3
F
H
N
We assume that the block stays at rest. Then we can write down
the equilibrium conditions
Gr
→:
H=F ,
↑:
N = m3 g .
E2.12
2 Dynamics of Systems of Point Masses
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48
The force of static friction H and the normal force N have to
satisfy the condition of static friction:
H ≤ µ0 N
→
F ≤ µ0 m 3 g .
With
F = kx
→
x≤
µ0 m 3 g
k
we obtain the maximum compression of the spring:
µ0 m 3 g
.
xmax =
k
Gr
Now we apply the Conservation of Energy Law to determine v1max :
r
1
1 2
µ0 m 3 g m 1 + m 2
2
(m1 + m2 )v̄ = kxmax → v1max =
.
2
2
m1
k
49
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2 Dynamics of Systems of Point Masses
111
000
000
111
Example 2.13 A point mass m1 strikes a point mass m2 which is
suspended from a string (length l, negligible mass) as shown in Fig. 2.23. The
maximum force S ∗ that the string can
sustain is given.
Assume an elastic impact and determine the velocity v0 that causes the
string to break.
l
v0
m1
m2
Fig. 2.23
Solution First we formulate the con-
servation of linear momentum
m1 v0 = m1 v̄1 + m2 v̄2
111
000
and of energy (elastic impact!):
ϕ
m1 v02 /2 = m1 v̄12 /2 + m2 v̄22 /2 .
From these equations we can calculate the velocity v̄2 of mass m2 immediately after the impact:
2m1
v̄2 =
v0 .
m1 + m2
Now, we write down the equation of motion
տ:
m2 an = S − m2 g cos ϕ .
With an = v22 /l we obtain the force in the string:
Gr
S = m2 v22 /l + m2 g cos ϕ .
S
m2 g
E2.13
2 Dynamics of Systems of Point Masses
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50
The maximum force Smax in the string is found for ϕ = 0:
Smax = m2 (v̄22 /l + g) .
The string breaks if the maximum force Smax is larger than the
allowable force S ∗ :
Smax > S ∗ .
This yields
Gr
v0 >
m1 + m2 q ∗
l(S /m2 − g) .
2m1
51
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2 Dynamics of Systems of Point Masses
A ball ① (mass m1 ) hits a second ball ② (mass
m2 , velocity v2 = 0) with a velocity v1 as shown in Fig. 2.24.
Assume that the impact
m2
is partially elastic (coefficient of restitution e) and
2
r2
all surfaces are smooth.
m
1
1
Given: r2 = 3 r1 , m2 =
v1
r1
4 m1 .
Determine the velocities of the balls after the Fig. 2.24
collision.
Example 2.14
1111111111111
0000000000000
Solution We introduce the auxiliary angle α. Since the surfaces
are smooth, the linear impulse Fb acts in the direction of the line
of impact and the Impulse Laws are given by
①
②
→ : m1 (v 1 − v1 ) = −Fb cos α ,
m2 v 2 = Fb .
ր:
Note that the weights of
the balls can be neglected
during impact and that
ball ① moves only horizontally.
With the hypothesis
Fb
1
v1 , v1
e=−
v 1x − v 2x
v1x − v2x
and
v1x = v1 cos α ,
v2x = 0 ,
x
r
−r
2
1
α
r2
r1
11111111
00000000
2
v2
α
b
N
Fb
v 1x = v 1 cos α ,
α
v 2x = v 2
we obtain
Gr
v 1 = v1
m2
cos2 α
m1
,
m2
1+
cos2 α
m1
1−e
v 2 = v1
(1 + e) cos α
.
m2
1+
cos2 α
m1
E2.14
2 Dynamics of Systems of Point Masses
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52
Introduction of m2 = 4m1 and
r2 − r1
1
sin α =
=
r1 + r2
2
yields
Gr
1 − 3e
v1 ,
v1 =
4
→
cos α =
p
√
3
1 − sin α =
2
√
3
(1 + e) v1 .
v2 =
8
2
53
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2 Dynamics of Systems of Point Masses
A hunter (mass m1 ) sits in a boat (mass m2 =
2 m1 ) which can move in the water without resistance. The boat
is initially at rest.
a) Determine the velocity vB1 of the boat after the hunter fires a
bullet (mass m3 = m1 /1000) with a velocity v0 = 500 m/s.
b) Find the direction of the velocity of the boat after a second
shot is fired at an angle of 45◦ with respect to the first one.
Example 2.15
Solution a) We introduce a coordinate system and assume that
the bullet is fired in the direction of the negative x-axis. Since the
linear momentum before the firing of the bullet is zero, the total
linear momentum of the system after the firing (velocities positive
to the right) also has to be zero:
→:
(m1 + m2 − m3 )vB1 − m3 v0 = 0 .
This yields the velocity vB1 of the boat:
m3
vB1 =
v0 = m1 + m2 − m3
≈ 0.167
m
.
s
1
1000
1 1+2−
1000
500 =
500
2999
The algebraic sign shows that the boat moves in the direction of
the positive x-axis.
b) Now, we have to formulate the Impulse Laws in
the x- and y-direction:
m1 + m2
wB2
vB2
45◦
m3
v0
α
y
x
→ : (m1 + m2 − m3 )vB1 = (m1 + m2 − 2m3 )vB2 − m3 v0 cos 45◦ ,
Gr
↑:
0 = (m1 + m2 − 2m3 )wB2 − m3 v0 sin 45◦ .
E2.15
2 Dynamics of Systems of Point Masses
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54
They lead to
m1 + m2 − m3
m3
vB1 +
v0 cos 45◦
m1 + m2 − 2m3
m1 + m2 − 2m3
m
,
≈ 0.285
s
vB2 =
wB2 =
m3
m
,
v0 sin 45◦ ≈ 0.118
m1 + m2 − 2m3
s
Gr
→
tan α =
wB2
= 0.414
vB2
→
α = 22.5◦ .
55
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2 Dynamics of Systems of Point Masses
Example 2.16 A car ② goes into a skid on a wet road and co-
mes to a stop sideways across the road as shown in Fig. 2.25.
In spite of having fully applied the brakes
a distance s1 from car ②, a second car
① (sliding with the coefficient of kinetic
s2
2
friction µ) collides with car ②. This caum2
ses car ② to slide an additional distance
s2 . Assume a partially elastic central ims1
pact. Given: m1 = 2 m2 , µ = 1/3, e =
0.2, s1 = 50 m, s2 = 10 m.
1
Determine the velocity v0 of car ① bev0
m1
fore the brakes were applied.
Fig. 2.25
Solution The velocity v1 of car ① immediately before impact fol-
lows from the work-energy theorem:
1
1
m1 v12 − m1 v02 = −(µ m1 g)s1
2
2
→
v12 = v02 − 2µ gs1 .
The velocity v 2 of car ② immediately after impact can be determined from the conservation of linear momentum (note v2 = 0)
m1 v1 = m1 v 1 + m2 v 2
and the hypothesis
e=
v2 − v1
.
v1
We obtain
v2 =
1+e
m2 v1 .
1+
m1
Now we apply the work-energy theorem to the sliding of car ②:
Gr
1
− m2 v 22 = −(µ m2 g)s2
2
→
v 22 = 2µ gs2 .
E2.16
2 Dynamics of Systems of Point Masses
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56
If we eliminate v1 and v 2 we obtain
m2 ! 2
m1
2µ gs2 + 2µ gs1
1+e
1+
v02
=
=
or
1.5 2 2
2
· · 9.81 · 10 + · 9.81 · 50 = 429.19 m2/s2
1.2
3
3
v0 = 20.7 m/s
→
v0 = 74.6 km/h .
Gr
Note: the velocity of car ① at impact is v1 = 36.4 km/h.
57
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2 Dynamics of Systems of Point Masses
Example 2.17 Two cars (point masses m1 and m2 ) collide at an
intersection with velocities
v1 and v2 at an angle α
(Fig. 2.26). Assume a perfectly plastic collision.
Determine the magnitude and the direction of
the velocity immediately
after the impact. Calculate the loss of energy during
the collision.
β
v2
m2
Fig. 2.26
Solution Both cars have the
same velocity v after the
collision (plastic impact).
We write down the Impulse Laws in the x- and ydirections:
v1
α
m1
y
m1 +m2
m1 v
1
α
v
β
x
v2
m2
→ : m1 v1 + m2 v2 cos α = (m1 + m2 )v cos β ,
↑:
m2 v2 sin α = (m1 + m2 )v sin β .
If we square and then add these equations we obtain
q
1
v=
(m1 v1 )2 + 2m1 m2 v1 v2 cos α + (m2 v2 )2 ,
m1 + m2
whereas a division leads to
Gr
tan β =
m2 v2 sin α
.
m1 v1 + m2 v2 cos α
E2.17
2 Dynamics of Systems of Point Masses
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58
The loss of mechanical energy during impact is given by the difference ∆T of the kinetic energies before and after impact:
m1 v12
m2 v22
(m1 + m2 )v 2
+
−
2
2
2
m1 m2
2
2
(v + v2 − 2v1 v2 cos α).
=
2(m1 + m2 ) 1
∆T =
Gr
Note that the loss of energy is a maximum if the cars collide headon (α = π). The energy ∆T causes the deformation of the cars.
59
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2 Dynamics of Systems of Point Masses
Example 2.18 A bullet (mass m)
has a velocity v0 (Fig. 2.27). An
explosion causes the bullet to
break into two parts (point masses m1 and m2 ). The directions
α1 and α2 of the two parts and
the velocity v1 immediately after
the explosion are given.
Calculate m1 and v2 . Determine the trajectory of the center
of mass of the two parts.
E2.18
v1
m1
y
m
v0
α1 =
α2
m2
π
2
x
v2
Fig. 2.27
Solution Since no external forces are acting on the system, its
linear momentum does not change (linear momentum before the
explosion = linear momentum after the explosion). Componentwise, the principle of conservation of linear momentum gives
→ : mv0 = m2 v2 cos α2 ,
↑:
0 = m1 v1 − m2 v2 sin α2 .
Thus, we have two equations for the two unknowns m1 and v2 .
Solving with m = m1 + m2 yields
v0
v0
.
m1 = m
tan α2 , v2 =
v1
cos α2 − vv01 sin α2
We measure the time t from the moment of the explosion. Then,
with |yi | = vi t sin αi , the location of the center of mass is given by
yc =
=
1
(m1 y1 + m2 y2 )
m
(−v sin α )
o
1 n v0
v0
0
2
m
tan α2 v1 t + m − m
tan α2
t
v0
m
v1
v1
cos α2 − v1 sin α2
= 0.
Gr
The center of mass of the system continues to move on the original
straight line y = 0 (law of motion for the center of mass).
E2.19
2 Dynamics of Systems of Point Masses
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60
Example 2.19 A ball (point mass m1 ) is attached to a cable. It is
1111111
0000000
0000000
1111111
released from rest at a height h1 (Fig. 2.28). After falling to the
vertical position at A it collides with
a second ball (point mass m2 = 2 m1 )
which is also initially at rest. The com1
efficient of restitution is e = 0.8.
Determine the height h2 which the
A
h1
first ball can reach after the collision
m2
and the velocity of the second ball immediately after impact.
Fig. 2.28
1111
0000
Solution The velocities of the masses m1 and m2 before the impact
are
v1 =
p
2gh1 ,
v2 = 0 .
1
The Impulse Laws
①
②
→ : m1 (v 1 − v1 ) = −Fb ,
→:
and the hypothesis
e=−
v2
v1 , v1
m1
m2 v 2 = +Fb ,
Fb
Fb
m2
v1 − v2
v1
yield the velocities immediately after the impact:
p
m1 − e m2
1 − 1.6
v 1 = v1
= v1
= −0.2 2gh1 ,
m1 + m2
1+2
p
m1
1
v 2 = v1 (1 + e)
= v1 1.8
= 0.6 2gh1 .
m1 + m2
1+2
1111
0000
The height h2 follows from
the conservation of energy
1
m1 v 21 = m1 gh2
2
as
Gr
v2
h2 = 1 = 0.04 h1 .
2g
h2
v1
m1
m2 v2
2
11111111
00000000
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2 Dynamics of Systems of Point Masses
Example 2.20 The rigid rod (negli-
E2.20
gible mass) in Fig. 2.29 carries two
point masses. It is struck by an impulsive force Fb at a distance a from
the support A.
Determine the angular velocity of the rod immediately after the
impact and the impulsive reaction
at A. Calculate a so that the reaction force at A is zero.
A
l
a
m
Fb
l
m
Fig. 2.29
Solution We introduce a coordinate
system. The y-component of the velocity of the center of mass is zero
after the impact. Since the impulsive force Fb also has no y-component,
the impulsive reaction at A has only an x-component, i.e. Aby = 0. We
apply the principle of linear impulse
and momentum
→:
bx − Fb
2m(v̄c − vc ) = A
by
A
bx
A
y
x
3l/2
C
Fb
and the principle of angular impulse and momentum (compare
Chapter 3)
2
y
l
bx 3 l − Fb 3 l − a .
m(ω̄ − ω) = A
C: 2
2
2
2
Inserting the kinematic relation
v̄c = −3lω̄/2
and the velocities
Gr
v̄c = 0 ,
ω=0
2 Dynamics of Systems of Point Masses
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62
before the impact we obtain
Fb a
ω̄ = 2 ,
5l m
Abx =
3a b
1−
F .
5l
The reaction force at A is zero (Abx = 0) if the distance a is chosen
as
Gr
a = 5l/3 .
63
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2 Dynamics of Systems of Point Masses
Example 2.21 A wagon (weight W1 = m1 g) hits a buffer (spring
constant k) with velocity v. The
collision causes a block (weight
W2 = m2 g) to slide on the
rough surface (coefficient of static friction µ0 ) of the wagon
(Fig. 2.30).
Determine a lower bound for
the wagon’s speed before the
collision.
000000000000
111111111111
000000000000
111111111111
000000000000
111111111111
000000000000
111111111111
000000000000
111111111111
000000000000
111111111111
000000000000
111111111111
µ0
W2
k
v
W1
Fig. 2.30
Solution We separate the wagon and the block. The orientation
of the friction force H is assumed arbitrarily in the free-body
diagram. Both bodies have the same acceleration (ẍ1 = ẍ2 = ẍ) as
long as the block does not slim2 g
de. Therefore, the equations of
2
motion are
x
H
① ← : m1 ẍ = −H − F ,
② ← : m2 ẍ = H .
With F = k x we obtain
m2
H=−
kx .
m1 + m2
N
H
F
1
m1 g
1111111
0000000
0000000
1111111
is obtained at maximal com-
Gr
The maximum friction force Hmax
pression xmax of the spring which follows from the Conservation
of Energy Law:
r
1
1
m1 + m2
2
2
(m1 + m2 )v = k xmax
→
xmax =
v.
2
2
k
E2.21
2 Dynamics of Systems of Point Masses
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64
The block is on the verge of slipping if the condition of “limiting
friction”
|Hmax | = µ0 N = µ0 m2 g
→
k
xmax = µ0 g
m1 + m2
Gr
is satisfied. This yields the velocity that is necessary to cause
slippage of the block:
r
m1 + m2
v = µ0 g
.
k
65
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Dy ov
3
na idje
mi
cs e
2 Dynamics of Systems of Point Masses
Example 2.22 The system shown in Fig. 2.31 consists of two blocks
(masses m1 and m2 ), a spring (spring constant k), a massless rope
and two massless pulleys. Block 1 lies on a rough surface (coefficient of kinetic friction µ).
g
x1
At the beginning of the
motion (t = 0), the spring
k
m1
is unstretched and the position of block 1 is given
by x1 = 0.
µ
Determine the velocity
x2
m2
ẋ1 as a function of the position x1 .
11111111111
00000000000
11111111111
00000000000
11111111111
00000000000
11111111111
00000000000
11111111111
00000000000
11111111111
00000000000
11111111111
00000000000
11111111111
00000000000
Fig. 2.31
Solution Since we want to find the velocity as a function of the
position, we use the work-energy theorem
T1 − T0 = U .
In moving from the initial position to an arbitrary position, the
gravitational force, the force in the spring and the friction force
perform work:
1
Uk = − kx21 ,
2
UR = −Rx1 = −µN x1 = −µm1 gx1 .
UW = m2 gx2 ,
The kinetic energies are given by
T1 =
1
1
m1 ẋ21 + m2 ẋ22 ,
2
2
T0 = 0 .
With the kinematic relation
ẋ2 = 2ẋ1
the work-energy theorem yields
Gr
1
1
1
m1 ẋ21 + m2 4ẋ21 = m2 gx2 − kx21 − µm1 gx1
2
2
2
r
2
1 k 2
→ ẋ1 =
(2 − µ)gx1 −
x .
5
5m 1
E2.22
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En s, Ha
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g M Schr
ö
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Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
Gr
Dynamics of Rigid Bodies
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
Gr
Chapter 3
3
E3.24
3 Dynamics of Rigid Bodies
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
68
er
Example 3.24 Point A of the rod
in Fig. 3.47 moves with constant
velocity vA to the left.
Determine the velocity and
the acceleration of point B of the
rod (point of contact with the
step) as a function of the angle
ϕ. Find the path y(x) of the instantaneous center of rotation.
y
h
B
0000000
1111111
0000000
1111111
0000000
1111111
0000000
1111111
ϕ e
v
0000000
1111111
A
0000000
1111111
0000000 x
1111111
ϕ
A
Fig. 3.47
Solution We use the coordinate system with the basis vectors er
and eϕ as shown in the figure. Then, the velocity of point A is
er
given by
v A = vA cos ϕer − vA sin ϕeϕ .
The velocity v B of point B
points in the direction of the
rod (the rod does not lift off the
step). Thus,
v B = vB er .
arAB
vAB
1111111111
0000000000
1111111111
0000000000
1111111111
0000000000
1111111111
0000000000
1111111111
0000000000
1111111111
0000000000
1111111111
0000000000
vB
aϕAB
B
ϕ
vA
eϕ
A
With the kinematic relation
v B = v A + v AB
where v AB = aϕ̇eϕ
and with
a=
h
,
sin ϕ
we obtain
hϕ̇
eϕ
sin ϕ
vA
vB = vA cos ϕ and ϕ̇ =
sin2 ϕ .
h
vB er = vA cos ϕer − vA sin ϕeϕ +
Gr
→
a
69
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En s, Ha
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g M Schr
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Sp cha der,
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,G
r2
3,
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na idje
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cs e
3 Dynamics of Rigid Bodies
In order to determine the acceleration of point B we use the relation
aB = aA + arAB + aϕ
AB ,
where
aA = 0 ,
arAB = −aϕ̇2 er ,
aϕ
AB = aϕ̈eϕ .
The angular acceleration of the rod is found by differentiating its
angular velocity ϕ̇:
ϕ̈ =
vA
(sin2 ϕ)˙
h
→
ϕ̈ = 2
2
vA
sin3 ϕ cos ϕ .
h2
Hence, we obtain
aB =
2
vA
sin2 ϕ(− sin ϕer + 2 cos ϕeϕ ) .
h
The instantaneous center of rotation Π is given by the point of
intersection of two straight lines which are perpendicular to two
velocities. In the present example, the directions of the velocities
vA and vB are known. The2.0
refore, the instantaneous cenpath of Π
ter of rotation can easily be
1.5
constructed (see the figure).
Π
Point Π has the coordinates y/h
1.0
x = h cot ϕ ,
y = h + x cot ϕ .
Elimination of the angle ϕ
yields the path of Π:
x2
+h.
h
Gr
y=
0.5
11111
00000
11111
00000
11111
00000
11111
00000
11111
00000
0
-1.0
0.5
0
x/h
ϕ
0.5
1.0
E3.25
3 Dynamics of Rigid Bodies
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En s, Ha
gin ug
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rin
g M Schr
ö
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Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
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cs e
70
The wheel of a
crank drive rotates with
constant angular velocity ω
(Fig. 3.48).
Determine the velocity and
the acceleration of the piston P .
Example 3.25
Solution If we introduce the
auxiliary angle ψ, then the
position xP of the piston is
given by
xP = r cos ϕ + l cos ψ .
Now
we
differentiate and obtain (note
ϕ̇ = ω = const)
l
000
111
r
000
111
000
111
ϕ ψ
00000000
11111111
P
ω
111
000
000
111
Fig. 3.48
0
1
0
1
0
1
0
1
0
1
0
1
111111
000000
y
r
ϕ = ωt
x
ψ
l
ẋP = −rω sin ϕ − lψ̇ sin ψ ,
ẍP = −rω 2 cos ϕ − lψ̈ sin ψ − lψ̇ 2 cos ψ .
The quantities sin ψ, cos ψ, ψ̇ and ψ̈ are as yet unknown. They
follow from the condition that the piston can move only in the
horizontal direction. Therefore, its vertical displacement is zero:
yP = 0 = r sin ϕ − l sin ψ .
Differentiation yields
ẏP = 0 = rω cos ϕ − lψ̇ cos ψ ,
Gr
ÿP = 0 = −rω 2 sin ϕ − lψ̈ cos ψ + lψ̇ 2 sin ψ .
P
71
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g M Schr
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r2
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na idje
mi
cs e
3 Dynamics of Rigid Bodies
Thus,
r
sin ψ = sin ϕ ,
l
ψ̇ = ω
r cos ϕ
,
l cos ψ
cos ψ =
r
ψ̈ = −ω 2
1−
r
l
2
sin ϕ ,
r sin ϕ
sin ψ
+ ψ̇ 2
.
l cos ψ
cos ψ
Hence, we finally obtain
r sin ϕ cos ϕ
ẋP = −rω sin ϕ +
,
l
cos ψ
Gr
ẍP = −rω
2
(
"
#)
r sin2 ϕ cos2 ϕ
cos ϕ −
−
.
l cos ψ
cos3 ψ
E3.26
3 Dynamics of Rigid Bodies
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
72
Example 3.26 Link MA of the mechanism in Fig. 3.49 rotates with
angular velocity ϕ̇(t).
Determine the velocities of points B and C, the angular velocity ω and the angular acceleration ω̇ of the angled member ABC
at the instant shown.
l
r
ϕ
M
C
00
11
00
11
00
11
00
11
00
11
l
B
y
z
A
x
α
Fig. 3.49
Solution With the given x, y, z-coordinate system, the velocities
of points A and B at the instant shown can be written in the form




− sin ϕ
− cos α







v A = rϕ̇ 
 cos ϕ  , v B = vB  sin α  ,
0
0
where vB is as yet unknown (note that the direction of v B is
known). The angular velocity of the angled member ABC is represented by
 
0
 

ω = 0
 .
ω
We now use the kinematic relation
Gr
v B = v A + ω × rAB
73
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rin
g M Schr
ö
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Sp cha der,
rin
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,G
r2
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01
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na idje
mi
cs e
3 Dynamics of Rigid Bodies
which, with rAB = (0, −l, 0)T , in coordinates reads



  
− cos α
− sin ϕ
ωl



  
 = rϕ̇  cos ϕ  +  0  .
vB 
sin
α



  
0
0
0
Solving yields
vB = rϕ̇
cos ϕ
,
sin α
ω=
rϕ̇ cos ϕ sin ϕ −
.
l
tan α
In an analogous way we obtain the velocity of point C:


− sin ϕ

cos ϕ 

v C = v A + ω × r AC → v C = rϕ̇ 
sin ϕ + cos ϕ − tan α  .
0
In order to determine the angular acceleration ω̇ = (0, 0, ω̇)T of
the angled member, we first write down the relation
aB = aA + ω̇ × r AB + ω × (ω × rAB ) ,
which in coordinates reads





    
− cos α
− sin ϕ
cos ϕ
ω̇l
0





    
2








aB  sin α  = rϕ̈  cos ϕ  − rϕ̇  sin ϕ  +  0  + ω 2 l
 .
0
0
0
0
0
Solving for aB and ω̇ yields
1
(rϕ̈ cos ϕ − rϕ̇2 sin ϕ + lω 2 ) ,
sin α
1
1
ω̇ =
rϕ̈ sin ϕ + rϕ̇2 cos ϕ −
(rϕ̈ cos ϕ − rϕ̇2 sin ϕ + lω 2 ) .
l
tan α
Gr
aB =
E3.27
3 Dynamics of Rigid Bodies
00
11
111111111111
000000000000
00Ω
11
111111111111
000000000000
R
111111111111
000000000000
P r
111111111111
000000000000
111111111111
000000000000
111111111111
000000000000
ϕ
111111111111
000000000000
111111111111
000000000000
os
En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
74
Example 3.27 Wheel ① rolls in
a gear mechanism without slip
along circle ②. The mechanism
is driven with a constant angular velocity Ω (Fig. 3.50).
Determine the magnitudes
of the velocity and the acceleration of point P on the wheel.
1
2
Fig. 3.50
Solution The motion of P is composed of the rotation of B about
A with
vB = RΩ
(vB ⊥ AB) ,
aB = RΩ2
(aB k AB)
and the rotation of P about B. In order to determine the angular
velocity ω of wheel ① we consider two positions of the wheel. The
figure shows that the relation
00
11
111111111111
000000000000
00
11
111111111111
000000000000
→ Rα = rβ
111111111111
000000000000
for the arclengths holds. Diffe- 000000000000
111111111111
000000000000
rentiating and using α̇ = Ω and 111111111111
111111111111
000000000000
β̇ = ω yields
111111111111
000000000000
R
000000000000
RΩ = rω → ω = Ω
. 111111111111
r
(R + r)α = r(β + α)
A
α
R
C′
r B
C
β
B′
α
Gr
Note that Ω is positive counterclockwise, whereas ω is positive
clockwise.
75
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En s, Ha
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g M Schr
ö
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Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
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3
na idje
mi
cs e
3 Dynamics of Rigid Bodies
We can now construct the velocity
diagram and the acceleration diagram. Since the velocity diagram
is represented by an isosceles triangle, we obtain
vP = 2ΩR sin
ϕ
.
2
vP
vB = RΩ
Gr
Finally, the law of cosines yields
2 2 2
Ω R
a2P = (Ω2 R)2 +
r
2 2
aB = RΩ2
Ω
R
cos(π − ϕ) ,
−2Ω2 R
r
s
2
R
R
+ 2 cos ϕ .
a P = Ω2 R 1 +
r
r
ϕ
ϕ
aP
vP B = rω
= Rω
anP B = rω 2
Ω2 R2
=
r
E3.28
3 Dynamics of Rigid Bodies
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En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
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cs e
76
Example 3.28 A disk
(mass m, radius r1 ) rests in a frictionless
support (ω0 = 0). A second disk
r2
2 (mass m, radius r2 ) rotates
ω2
m
with the angular velocity ω2 . It
m
2
is placed on disk 1 as shown in
1
Fig. 3.51. Due to friction, both
disks eventually rotate with the
r1
same angular velocity ω̄.
Determine ω̄. Calculate the
Fig. 3.51
change ∆T of the kinetic energy.
1
111111
000000
000000
111111
111111111
000000000
0000
1111
0000
1111
Solution Since there is no moment of external forces acting on the
system, the angular momentum is conserved during the process:
Θ2 ω2 = (Θ1 + Θ2 )ω̄ .
With the mass moments of inertia
Θ1 = mr12 /2 ,
Θ2 = mr22 /2
we obtain the resulting angular velocity ω̄:
ω̄ =
r22
ω2 .
r12 + r22
The change ∆T of the kinetic energy follows as
Gr
∆T =
1
1
(Θ1 + Θ2 )ω̄ 2 − Θ2 ω22
2
2
→
r2 r2
1
∆T = − mω22 2 1 2 2 .
4
r1 + r2
77
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En s, Ha
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g M Schr
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Sp cha der,
rin
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,G
r2
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01
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3
na idje
mi
cs e
3 Dynamics of Rigid Bodies
Example 3.29 The door (mass m, moment
E3.29
of inertia ΘA ) of a car is open (Fig. 3.52).
Its center of mass C has a distance b from
the frictionless hinges. The car starts to
move with the constant acceleration a0 .
Determine the angular velocity of the
door when it slams shut.
a0
C
A
m
b
Fig. 3.52
Solution First, we write down
the acceleration of the center
of mass C:
aC = aA +
arAC
+
aϕ
AC
An
A
ϕ
C
At
,
where the magnitudes of the
individual terms are given by
aA = a0 ,
arAC = bϕ̇2 ,
aϕ
AC = bϕ̈ .
We then formulate the principle of linear momentum (in the tdirection, see the free-body diagram)
ւ:
m(bϕ̈ − a0 cos ϕ) = At
and the principle of angular momentum (about the center of mass
C):
y
C:
ΘC ϕ̈ = −At b .
The mass moment of inertia ΘC follows from the parallel-axis
theorem:
Gr
ΘC = ΘA − mb2 .
3 Dynamics of Rigid Bodies
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En s, Ha
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g M Schr
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r2
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78
Eliminating the force At yields
ϕ̈ =
ma0 b
cos ϕ .
ΘA
The angular velocity of the door can be obtained through integration:
1 2
ma0 b
ϕ̇ (ϕ) =
sin ϕ .
2
ΘA
Gr
Thus, for ϕ = π/2 (closed door) we find
s
2ma0 b
ϕ̇(π/2) =
.
ΘA
79
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En s, Ha
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g M Schr
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,G
r2
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na idje
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cs e
3 Dynamics of Rigid Bodies
Example 3.30 A child (mass m) runs along the rim of a circular
platform (mass M , radius r) starting from point A (Fig. 3.53).
The platform is initially at rest; its support is frictionless.
Determine the angle
of rotation of the platM
0
m
form when the child arr
rives again at point A.
A
Fig. 3.53
Solution We apply the principle of angular momentum: the time
rate of change of the angular momentum is equal to the moment of
the applied forces. Since there are no external applied forces acting
in the present example, the angular momentum is constant:
dL(0)
=0
dt
→
L(0) = const
with
L(0) = Θ0 ω + mr2 (ω + ωrel ) .
Here,
Θ0 = M r2 /2
is the mass moment of inertia of the platform, ω is the angular
velocity of the platform and ωrel is the angular velocity of the child
relative to the platform. Integration of the principle of angular
momentum with the initial condition
L(0) (0) = 0
yields
Z t
L(0) dt̄ = 0
Gr
0
L(0) ≡ 0
→
→
Θ0 ϕ + mr2 (ϕ + ϕrel ) = 0 .
E3.30
3 Dynamics of Rigid Bodies
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En s, Ha
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rin
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r2
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80
The child arrives again at
point A when the relative angle attains the value
ϕrel = 2π. Solving for ϕ
yields
ϕ=−
2π
.
M
+1
2m
2π
ϕrel = 2π
ϕ
|ϕ|
ϕchild = ϕ+ϕrel
π
0
Gr
The result is displayed in
a diagram.
2
4
M/m
6
8
10
81
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En s, Ha
gin ug
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rin
g M Schr
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Sp cha der,
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,G
r2
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Dy ov
3
na idje
mi
cs e
3 Dynamics of Rigid Bodies
A homogeneous
triangular plate of weight W =
mg is suspended from three
strings with negligible mass.
Determine the acceleration of
the plate and the forces in the
strings just after string 3 is cut.
Example 3.31
111111111
000000000
1
E3.31
1010
1010
2
α
α
3
W
l
2l
Fig. 3.54
Solution The motion of the plate is a translation after string 3 is
cut. Therefore, all the points of the plate have the same acceleration (and the same velocity). We choose point A which rotates
about a fixed point to represent the motion of the plate. Its acceleration can be written in the Serret-Frenet frame as
a = aA = v̇et +
v2
en .
ρA
Its velocity is zero at the moment of the cut:
v=0
→
a = v̇et .
The principles of linear and angular momentum are then given
by (see the free-body diagram)
en
S1
et
2
l
3
S2
A
C
α
1
l
3
mg
ւ : mv̇ = mg sin α ,
0 = S1 + S2 − mg cos α ,
y
C :
0=
Gr
տ:
2
l
l
4
lS1 cos α − S1 sin α − S2 sin α − S2 cos α .
3
3
3
3
3 Dynamics of Rigid Bodies
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En s, Ha
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rin
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82
Solving these equations yields
v̇ = g sin α,
S1 =
mg
(sin α + 4 cos α),
6
S2 =
mg
(− sin α + 2 cos α) .
6
Gr
Note that S2 = 0 for sin α = 2 cos α (i.e., for tan α = 2 →
α = 63.4◦). In this case the line of action of S1 passes through the
center of mass C.
83
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g M Schr
ö
e
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rin
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,G
r2
3,
01
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3
na idje
mi
cs e
3 Dynamics of Rigid Bodies
Example 3.32 A sphere (mass
E3.32
m1 , radius r) and a cylindrical
wheel (mass m2 , radius r) are
connected by two bars (mass
of each bar m3 /2, length l).
They roll down a rough inclined plane (with angle α) without slipping (Fig. 3.55).
Find the acceleration of the
bars.
ϕ
x
r
m1
m3
m2
r
l
α
Fig. 3.55
Solution The only external forces that act on the system are the
weights of the individual parts. Therefore, conservation of energy
T + V = const
leads to the solution. The kinetic energy is given by
T = (m1 + m2 + m3 )ẋ2 /2 + (Θ1 + Θ2 )ϕ̇2 /2
and the potential energy is
V = −(m1 + m2 + m3 )gx sin α .
With the kinematic relation (rolling without slipping)
ẋ = rϕ̇
and the mass moments of inertia
Gr
Θ1 = 2m1 r2 /5 ,
Θ2 = m2 r2 /2
3 Dynamics of Rigid Bodies
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En s, Ha
gin ug
ee er,
rin
g M Schr
ö
e
Sp cha der,
rin
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,G
r2
3,
01
Dy ov
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84
we obtain
(7m1 /10 + 3m2 /4 + m3 /2)ẋ2 − (m1 + m2 + m3 )gx sin α = const .
Differentiation finally yields the acceleration of the bars:
2(7m1 /10 + 3m2 /4 + m3 /2)ẋẍ − (m1 + m2 + m3 )g ẋ sin α = 0
Gr
→
a = ẍ =
(m1 + m2 + m3 ) sin α
g.
7m1 /5 + 3m2 /2 + m3
85
os
En s, Ha
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rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
cs e
3 Dynamics of Rigid Bodies
Example 3.33 The cylindrical
E3.33
z
y
shaft shown in Fig. 3.56 has
x
an inhomogeneous mass density given by ρ = ρ0 (1 + αr).
l
Find the moments of inerFig. 3.56
tia Θx and Θy .
Solution We determine the
z
mass moment of inertia
Θx from
r
dr
Z
Z
Θx = (y 2 + z 2 )dm = r2 dm .
r
y
R
y
R
With
dm = ρ 2πr dr dx = 2πρ0 (r + αr2 )dr dx
we obtain
R4
Rl RR 3
R5 (r + αr4 )dr dx = 2πρ0 l
+α
4
5
0 0
π
4
= ρ0 lR4 1 + αR .
2
5
Θx = 2πρ0
The mass moment of inertia Θy = Θz (symmetry) follows from
Z
Θy = (z 2 + x2 )dm
with
rdϕ
z
dm = ρr dϕ dr dx
dr
dϕ r
r sin ϕ
2
= ρ0 (r + αr ) dϕ dr dx ,
Gr
z = r sin ϕ .
ϕ
y
3 Dynamics of Rigid Bodies
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86
Using the symmetry we obtain
π/2
Zl ZR Z
Θy = 4ρ0
(r2 sin2 ϕ + x2 )(r + αr2 )dϕ dr dx
0
0
0
Z l ZR
= πρ0
(r2 + 2x2 )(r + αr2 )dr dx
0
0
3
l2
2 2
R2
R
= πρ0 R l
+ +α
+ Rl
.
4
3
5
9
2
Note: For α = 0 the results reduce with m = ρ0 πR2 l to the mass
moments of inertia of a homogeneous cylindrical shaft (note the
term due to the parallel-axis theorem):
Gr
Θx =
1
mR2 ,
2
Θy =
1
m 3R2 + 4l2 .
12
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3 Dynamics of Rigid Bodies
Determine the
moment of inertia Θa of a homogeneous torus with a circular
cross section and mass m.
Example 3.34
a
E3.34
R
c
a
Fig. 3.57
Solution The mass moment of inertia Θa is determined from
Z
Θa =
r2 dm .
We can determine the geometrical relations
dr
a
R
c
ϕ
r = R + c sin ϕ ,
c sin ϕ
dm = ρ 2πr2c cos ϕ dr
from the figure. With
r
a
dr = c cos ϕ dϕ
we obtain
dm = 4πρc2 (R + c sin ϕ) cos2 ϕ dϕ .
Thus,
Θa = 4πρc
2
+π/2
Z
(R + c sin ϕ)3 cos2 ϕdϕ
−π/2
= 4πρc
2
+π/2
Z
−π/2
R3 cos2 ϕ + 3R2 c sin ϕ cos2 ϕ
+ 3Rc2 sin2 ϕ cos2 ϕ + c3 sin3 ϕ cos2 ϕ]dϕ
Gr
= 4πρc
2
π 3 3π
R +
Rc2
2
8
3 2
2
= 2π ρc R R + c
.
4
2
2
2c cos ϕ
3 Dynamics of Rigid Bodies
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88
Note that the integrals of the odd functions over the even interval
are zero. Using m = 2π 2 ρc2 R we finally get
3 Θ a = m R 2 + c2 .
4
Gr
This result reduces to Θa = mR2 in the case of a thin ring
(c ≪ R).
89
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3 Dynamics of Rigid Bodies
Example 3.35 A rope drum on a
E3.35
rough surface is set into motion
by pulling the rope with a constant force F0 .
Determine the acceleration of
point C assuming that the drum
rolls (no slipping). What coefficient of static friction µ0 is necessary to ensure rolling?
m, Θc
r2
C
r1
F0
α
111111111
000000000
µ0
Fig. 3.58
Solution The free-body diagram shows the forces that act on the
drum. We apply the principles of linear and angular momentum:
→:
mac = F0 cos α − H ,
↑ :
0 = N − mg + F0 sin α ,
vc
y
C : Θc ω̇ = r1 H − r2 F0 .
ω
r1
r2
mg
F0
C
α
In addition we have the kinematic relation
H
vc = r1 ω
→
v̇c = ac = r1 ω̇
N
between the velocity and the angular velocity (rolling without
slip). We solve these four equations to obtain the acceleration and
the forces:
r2
cos α −
F0
r1
ac =
,
Θc
m
1+ 2
r1 m
Gr
Θc cos α r2
+
r12 m
r1
H = F0
,
Θc
1+ 2
r1 m
N = mg − F0 sin α .
3 Dynamics of Rigid Bodies
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90
In order to ensure rolling, the condition of static friction H ≤ µ0 N
has to be satisfied. This leads to
Θc cos α r2
+
r12 m
r1
.
µ0 ≥
mg
Θc
1+ 2
− sin α
F0
r1 m
Gr
Note: For cos α > r2 /r1 we have ac > 0 (motion to the right),
whereas for cos α < r2 /r1 we obtain ac < 0 (motion to the left).
In the case of F0 sin α > mg the drum lifts off the ground.
91
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3 Dynamics of Rigid Bodies
Example 3.36 A homogeneous beam (mass M , length l) is initially
in vertical position ① (Fig. 3.59). A small disturbance causes the
beam to rotate about the frictionless
support A (initial velocity equal to zero). In position ② it strikes a small
sphere (mass m, radius r ≪ l). Assume the impact to be elastic (e = 1).
Determine the angular velocities of
the beam immediately before and after the impact and the velocity of the
sphere after the impact.
① M
l
A
②
m
Fig. 3.59
Solution The angular velocity ω immediately before the impact
follows from the conservation of energy (ΘA = M l2 /3):
q
M gl/2 = ΘA ω 2 /2 − M gl/2 → ω = 6g/l .
Since the impact is assumed to be elastic, the conservation of the
angular momentum
ΘA ω = ΘA ω̄ + mlv̄
as well as the conservation of energy
ΘA ω 2 /2 = ΘA ω̄ 2 /2 + mv̄ 2 /2
hold. Solving these two equations yields
M − 3m
ω,
M + 3m
Gr
ω̄ =
v̄ =
2lM
ω.
M + 3m
E3.36
E3.37
3 Dynamics of Rigid Bodies
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92
A thin half-cylindrical shell of weight W = mg
rolls without sliding on a flat surface (Fig. 3.60).
Determine the angular velocity
as a function of ϕ when the initial
condition ϕ̇(ϕ = 0) = 0 is given.
Example 3.37
W
ϕ
R
11111111
00000000
Fig. 3.60
Solution The position of the center of mass and the mass moment
of inertia are given by
Z π
1
2R
(R sin α)Rdα =
,
c =
Rπ 0
π
4
Θc = Θ0 − mc2 = mR2 − 2 mR2
π
4
= mR2 (1 − 2 ) .
π
Thus,
xc = Rϕ + c cos ϕ = R(ϕ +
2R
sin ϕ ,
π
2
ẋc = Rϕ̇(1 − sin ϕ) ,
π
2R
ẏc =
ϕ̇ cos ϕ .
π
R sin α
0
α
c
C
2
cos ϕ) ,
π
R
R dα
Rϕ c cos ϕ
c
yc = c sin ϕ =
y
ϕ yc
C
x
11111111
00000000
Since we want to find the angular velocity as a function of the
angle we apply the conservation of energy:
T + V = T0 + V0 .
With
T0 = 0 ,
Gr
T =
V0 = 0 ,
1
1
1
4
4
m(ẋ2c + ẏc2 ) + Θc ϕ̇2 = mR2 ϕ̇2 1 − sin ϕ + 2 sin2 ϕ
2
2
2
π
π
1
4
4 2
+ 2 cos2 ϕ + mR2 ϕ̇2 1 − 2 = mR2 ϕ̇2 1 − sin ϕ ,
π
2
π
π
2
V = −mgyc = − mgR sin ϕ
π
93
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3 Dynamics of Rigid Bodies
we obtain
mR2 ϕ̇2 (1 −
→
2
2
sin ϕ) − mgr sin ϕ = 0
π
π
s
2g sin ϕ
ϕ̇(ϕ) =
.
R(π − 2 sin ϕ)
Gr
Note that the angular velocity attains its maximum for ϕ = 90◦
(lowest position of the center of mass):
q
ϕ̇max = 2g/R(π − 2) .
E3.38
3 Dynamics of Rigid Bodies
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94
An elevator consists of a cabin (weight W = mg)
which is connected through a rope (of negligible mass) with a rope drum and a band brake (coefficient of dynamic friction µ).
Determine the necessary braking force F such that a cabin
travelling downwards with velocity v0 stops after a distance h.
Example 3.38
l
r2
0
r1
µ
F
Θ0
v0
W
Fig. 3.61
Solution First we determine the
r2
brake momentum MB that acts
on the drum. To this end we separate the drum and the lever.
Equilibrium at the lever
y
A:
ω0
S1
0 = −2r2 S2 + lF
→
S2 =
Fl
2r2
Gr
S2
A
2r2
l
Fl
.
2
Now we apply the work-energy theorem
T1 − T0 = U .
S2
S1
and the formula S1 = S2 e−µπ
for belt friction (see Volume 1,
Chapter 9) lead to
MB = r2 S2 − r2 S1 = (1 − e−µπ )
W
F
95
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3 Dynamics of Rigid Bodies
With the kinematic relations (constraints imposed by the rope)
v0 = r1 ω0 ,
h = r1 ϕh
the kinetic energies and the work are given by
v2 Θ0 1
1
T1 = 0 ,
T0 = mv02 + Θ0 ω02 = 0 m + 2 ,
2
2
2
r1
Z ϕh
F lh
U = mgh −
MB dϕ = mgh − (1 − e−µπ )
.
2r1
0
Thus, we obtain
Θ0 v2 F lh
− 0 m + 2 = mgh − (1 − e−µπ )
.
2
r1
2r1
Gr
Solving for the force F yields
r1 v02 m 2gh Θ0
F =
+
.
1
+
lh(1 − e−µπ )
mr12
v02
E3.39
3 Dynamics of Rigid Bodies
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96
Example 3.39 A homogeneous beam (mass m, length l) rotates
about frictionless support A (Fig. 3.62) until it hits support B.
The motion starts with zero
initial velocity in the vertical
l
position. The coefficient of restitution e is given.
m
Calculate the impulsive
forces at A and B. DetermiA
B
ne the distance a so that the
impulsive force at A vanishes.
a
Calculate the change of the
Fig. 3.62
kinetic energy.
Solution First we calculate the angular velocity of the beam im-
mediately before the impact with the aid of the conservation of
energy (ΘA = ml2 /3):
mgl/2 = ΘA ϕ̇2 /2
ϕ
y
x
→
ϕ̇2 = 3g/l .
bH
A
bV
A
C
a
b
B
We then apply the principles of impulse and momentum:
→:
↑:
Gr
y
A:
¯C − ẋC ) = AbH ,
m(ẋ
b,
m(ẏ¯C − ẏC ) = AbV + B
b .
ΘA (ϕ̇¯ − ϕ̇) = −Ba
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3 Dynamics of Rigid Bodies
Here, the velocity of the center of mass and the angular velocity
before the impact are given by
q
p
ẋC = 0 , ẏC = − 3gl/2 , ϕ̇ = 3g/l .
In order to obtain the velocities immediately after the impact we
use the hypothesis
e=−
ẏ¯B
ẏB
→
ϕ̇¯ = −eϕ̇ ,
which leads to
¯C = 0 ,
ẋ
p
ẏ¯C = e 3gl/2 ,
q
ϕ̇¯ = −e 3g/l .
Solving for the impulsive reactions yields
bV = (1 + e)(3a − 2l)m √3gl ,
A
6a
AbH = 0 ,
b = (1 + e)ml √3gl .
B
3a
The impulsive force at A vanishes if
AbV = 0
→
a = 2l/3 .
The change of the kinetic energy is the difference ∆T = T1 − T0
of the energies before and after impact:
Gr
∆T =
1
1
ΘA ϕ̄˙ 2 − ΘA ϕ̇2
2
2
→
∆T = −(1 − e2 )mgl/2 .
E3.40
3 Dynamics of Rigid Bodies
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98
A homogeneous circular disk of weight W = mg is suspended from a pin-supported bar (of
negligible mass). Initially the disk
rotates with the angular velocity ω0 .
a) Determine the amplitude of oscillation of the pendulum, if the
bar suddenly prevents the disk
from rotating.
b) Calculate the energy loss ∆E.
Example 3.40
l
ϕ
m
ω0
r
Fig. 3.63
Solution a) First we determine the angular velocity ω of the bar
immediately after the rotation of the disk is prevented (note that
the bar is still in the vertical position). Since there are no external
moments acting with respect to A,
the angular momentum is conserA
ved. With
ω
ΘB =
1 2
mr ,
2
ΘA =
1 2
1
mr + ml2 = m(r2 + 2l2 )
2
2
Disk
blocked
we obtain
Θ B ω0 = Θ A ω
→
ω=
B
ΘB
r2
ω0 = 2
ω0 .
ΘA
r + 2l2
The maximum value ϕ1 of the angle
ϕ (= amplitude of the oscillation)
can be calculated from the conservation of energy:
ϕ1
T1 +V1 = T0 +V0 .
If we choose the potential energy V0
(initial position) to be equal to zero,
we can write
T1 = 0 ,
position 1
l(1 − cos ϕ1 )
position 0
Gr
V1 = mgl(1 − cos ϕ1 ) ,
T0 =
1
mr2 ω02
r2
ΘA ω 2 =
,
2
4
r2 + 2l2
V0 = 0 .
99
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3 Dynamics of Rigid Bodies
Then, conservation of energy leads to
cos ϕ1 = 1 −
r2 ω02
r2
.
2
4gl r + 2l2
b) The loss of energy ∆E is given by the difference ∆T of the
kinetic energies before and after the blocking:
∆E =
Gr
=
ΘB ω02
ΘA ω 2
mr2 ω02
m
r4 ω02
−
=
− (r2 + 2l2 ) 2
2
2
4
4
(r + 2l2 )2
mr2 ω02
l2
.
2
r2 + 2l2
E3.41
3 Dynamics of Rigid Bodies
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100
M
11
00
0
1
00 10
11
A homogeneous angled bar of mass m is attached to a
shaft with negligible mass. The rotation of the system is driven by the
moment M0 .
Determine the angular acceleration and the support reactions.
Example 3.41
0
2l
m
ξ
2l
2l
111
000
The following moments
Solution
and products of inertia with respect
to the body-fixed coordinate system
ξ, η, ζ are needed:
Fig. 3.64
M0
Aη
Aξ
(2l)2
m
2
20
Θζ = m
+
(2l)2 =
ml2 ,
3
3
3
9
l
1
m
Θξζ = − 2l = − ml2 ,
3
2
3
ω, ω̇
η
ζ
C
ξc
ξ
Bη
Bξ
Θηζ = 0 .
l
η
With the moments
Mξ = 2lBη − 2lAη ,
Mη = 2lAξ − 2lBξ ,
Mζ = M0
the principle of angular momentum in component form yields
y
ξ :
y
η :
Gr
y
ζ :
ml2
3
ml2
2l(Aξ − Bξ ) = −ω 2
3
20
M0 =
ml2 ω̇
9
2l(Bη − Aη ) = −ω̇
mlω̇
,
6
mlω 2
Aξ − Bξ = −
,
6
9M0
.
ω̇ =
20ml2
→ Bη − Aη = −
→
→
101
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3 Dynamics of Rigid Bodies
In order to be able to calculate the support reactions, we now
have to formulate the principle of linear momentum. The center
of mass moves on a circle. With the distance ξc = 4l/3 from the
axis of rotation, we obtain the components of its acceleration as
acξ = −ξc ω 2 and acη = ξc ω̇. Thus,
−m ξc ω 2 = Aξ + Bξ ,
m ξc ω̇ = Aη + Bη
which leads to
3
Aξ = − mlω 2 ,
4
Aη =
27 M0
,
80 l
7
mlω 2 ,
12
Bη =
21 M0
.
80 l
Gr
Bξ = −
E3.42
3 Dynamics of Rigid Bodies
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102
A shaft (principal moments of inertia Θ1 , Θ2 , Θ3 )
rotates with constant angular velocity ω0 about its longitudinal
axis. This axis undergoes a rotation
α(t) about the z-axis of the fixed in
1
y
space system x, y, z.
2
ω0
Calculate the moment which is
3,
z
exerted by the bearings on the shaft
x
α(t)
for
a) uniform rotation α = Ωt,
Fig. 3.65
b) harmonic rotation α = α0 sin Ωt.
Example 3.42
Solution We solve the problem with the aid of Euler’s equations
Θ1 ω̇1 − (Θ2 − Θ3 )ω2 ω3 = M1 ,
Θ2 ω̇2 − (Θ3 − Θ1 )ω3 ω1 = M2 ,
Θ3 ω̇3 − (Θ1 − Θ2 )ω1 ω2 = M3 .
With
ω1 = ω0 ,
ω̇1 = 0 ,
ω2 = ω̇2 = 0 ,
ω3 = α̇ ,
ω̇3 = α̈
we obtain
M1 = 0 ,
M2 = −(Θ3 − Θ1 )ω0 α̇ ,
M3 = Θ3 α̈
where α(t) represents an arbitrary rotation¡.
a) In the special case of a uniform rotation α = Ωt we get
α̇ = Ω ,
α̈ = 0 .
Thus,
Gr
M1 = M3 = 0 ,
M2 = (Θ1 − Θ3 )ω0 Ω .
103
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3 Dynamics of Rigid Bodies
b) In the case of a harmonic rotation α = α0 sin Ωt we find
α̇ = α0 Ω cos Ωt ,
α̈ = −α0 Ω2 sin Ωt
and
M1 = 0 ,
M2 = (Θ1 − Θ3 )ω0 Ω α0 cos Ωt ,
M3 = −Θ3 Ω2 α0 sin Ωt .
Gr
Note: Only a moment about the 2-axis acts in case a). It is caused
by two opposite support reactions of equal magnitude (= couple)
in the 3- and z-directions, respectively.
E3.43
3 Dynamics of Rigid Bodies
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104
Example 3.43 A pin-supported rigid beam
(mass m, length l) is initially at rest. At
time t0 = 0 it starts to rotate due to an
applied constant moment M0 .
Determine the stress resultants (inter- M0
nal forces and moments) as functions of x
for t > t0 . Neglect gravitational effects.
l
x
ϕ
A
Fig. 3.66
Solution First we determine the angular acceleration and the an-
gular velocity of the beam. The principle of angular momentum
with respect to A yields
x
A:
ΘA ϕ̈ = M0
→
ϕ̈ =
M0
.
ΘA
Integration with the initial condition ϕ̇(0) = 0 gives
ϕ̇(t) =
M0
t.
ΘA
Now we cut the beam at an arbitrary position and introduce the
bending moment M and the shear force V into the free-body diagram (the normal force N will be considered later). The principle
of angular momentum (with respect to the center of mass C̄) and
the principle of linear momentum (in the y-direction) yield
x
C̄ :
տ:
Θ̄C̄ ϕ̈ = −M (x) − V (x)
l−x
,
2
m̄ ÿC̄ = V (x) .
The acceleration ÿC̄ follows from the kinematics (circular motion):
m̄, Θ̄C̄
V
M
y
C̄
1
(l
2
− x)
x
rC̄ = 12 (l + x)
l+x
ϕ̈ .
2
x
m l2
Thus, with m̄ = (1 − ) m and ΘA =
we obtain the shear
l
3
force:
x 2 l+x
l + x M0
3 M0
V (x) = m̄
ϕ̈ = m̄
=
1−
.
2
2 ΘA
2 l
l
Gr
ÿC̄ = rC̄ ϕ̈ =
105
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3 Dynamics of Rigid Bodies
1
m̄ (l − x)2 leads
Introduction of the moment of inertia Θ̄C̄ =
12
to the bending moment:
l−x
− Θ̄C̄ ϕ̈
2
x 2 3
1+
= − M0 1 −
4
l x 2
1
1+
= −M0 1 −
l
2
M (x) = −V
x 3 M0
x m l2 −
1−
l
12
l
ΘA
x
.
l
The normal force can be determined from the equation of motion
in the x-direction:
m̄
ր:
m̄ ẍC̄ = −N (x)
2
where ẍC̄ = −rC̄ ϕ̇ is the centripetal
acceleration. This leads to
N
y
C̄
x
rC̄ = 12 (l + x)
2
N (x) = m̄ rC̄ ϕ̇
x x+l
= m (1 − )
l
2
9 M02 t2
=
2 m l3
1−
M0
t
ΘA
x 2 l
2
.
Note that the normal force increases with time t in contrast to
the bending moment and the shear force.
The stress resultant diagrams are presented below.
M(x)
V (x)
+
3 M0
2 l
M0
Gr
N(x)
+
9 M02 t2
2 ml3
E3.44
3 Dynamics of Rigid Bodies
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106
Example 3.44 The angled member
A
(weight W = mg) in Fig. 3.67 consists of two homogeneous bars.
Derive the equation of motion
for the member’s center of mass.
g
2l
l
Fig. 3.67
Solution First, we locate the center
of mass of the angled member. With
the coordinate system as shown in
the figure we obtain
m l
l
xc = 3 2 = ,
m
6
m
2m
2l +
l
3 = 4l.
yc = 3
m
3
x
C
xc
A
a
√
q
65
yc2 + x2c =
l.
6
y
ϕ
1
m
3
C
Thus, the distance of the center of
mass from point A is given by
a=
yc
a
2
m
3
mg
a sin ϕ
The member rotates about a fixed axis that passes through A. We
introduce the angle ϕ and apply the principle of angular momentum:
Gr
ΘA ϕ̈ = MA .
107
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3 Dynamics of Rigid Bodies
We measure ϕ from the position of equilibrium (C is vertically
below A). With the mass moment of inertia
(
"
2 #)
(2l)2
7
m l2
l
2
2
ΘA =
+ (2l) +
+ m
= ml2
3 12
2
3
3
3
we obtain
x
A:
7
ml2 ϕ̈ = −mga sin ϕ
3
→
ϕ̈ +
√
65 g
sin ϕ = 0 .
14 l
Note: In the case of small oscillations (ϕ ≪ 1, sin ϕ ≈ ϕ) the
equation of motion reduces to the differential equation
√
65 g
ϕ̈ +
ϕ=0
14 l
Gr
for harmonic vibrations.
E3.45
3 Dynamics of Rigid Bodies
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108
Example 3.45 A bowling ball (mass m) is placed on a rough surface
(coefficient of kinetic friction
µ = 0.3) with velocity v0 = 5 m/s
(Fig. 3.68). Initially, the ball does
not rotate.
What is the position xr of the
ball when it stops sliding? Calculate
the corresponding velocity vr .
v0
11111111
00000000
µ
Fig. 3.68
Solution When the ball is placed on the rough surface it slides.
ω
C
r
mg
x
R
N
The friction force R is opposed to the direction of the motion.
Thus, the equations of motion are given by
→:
↑ :
y
C :
mẍ = −R ,
0 = N − mg
→
N = mg ,
Θc ω̇ = rR .
With Θc = 2mr2 /5 and the law of friction R = µN = µmg, the
first and the third equation lead to (initial conditions v(t = 0) =
v0 , x(t = 0) = 0, ω(t = 0) = 0)
Gr
v = ẋ = v0 − µgt ,
x = v0 t −
1
µg t2 ,
2
ω=
5µg
t.
2r
109
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3 Dynamics of Rigid Bodies
The ball rolls without sliding if the velocity of its center of mass
is given by
v = rω .
This condition leads to the corresponding time tr :
v0 − µgtr =
5
µ g tr
2
→
Thus,
12v02
= 2.08 m ,
49µg
vr = v(tr ) =
5
m
v0 = 3.57
.
7
s
Gr
xr = x(tr ) =
tr =
2v0
= 0.49 s .
7µg
E3.46
3 Dynamics of Rigid Bodies
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110
Example 3.46 The double pendulum in
Fig. 3.69 consists of two identical homogeneous bars (each mass m, length
l). It is struck by a linear impulse Fb at
point D.
Determine the distance d of point D
from the lower end of the pendulum so
that the angular velocity ω2 of the lower
bar is zero immediately after the impact. Calculate the impulsive forces at
A and B.
A
g
l
l
B
D
Fb
d
Fig. 3.69
Solution We separate the two bars and
draw the free-body diagram. Note that
there is no linear impulse in the vertical
direction. The bars are at rest before the
impact. The principles of linear and angular impulse and momentum are given
by
①
x
A:
②
→:
x
C2 :
where
ΘA =
b,
ΘA ω 1 = l B
b,
m v 2 = Fb − B
l b lb
ΘC2 ω 2 = B
− d−
F
2
2
1 2
ml ,
3
ΘC2 =
A
ω1
①
l
b
B
1
l
2
d−
Fb
1
l
2
b
B
v2
C2
ω2
②
1
ml2 .
12
We desire the motion of bar ② to be a translation. Therefore,
Gr
ω2 = 0 ,
v2 = l ω1 .
111
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3 Dynamics of Rigid Bodies
This leads to
3 Fb
ω1 =
,
4 ml
Fb
Fb
b=
B
2 = 4 ,
ml
1+
ΘA
ml2
l
5
ΘA
d=
= l.
2
8
ml2
1+
ΘA
2+
The impulsive force at A follows from the principle of linear im1
l ω1 :
2
pulse for bar ① with the kinematic relation v 1 =
→:
b+B
b
m v1 = A
→
b
b= F .
A
8
b
A
Gr
b
B
ω1
v1
C1
1
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Gr
Principles of Mechanics
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Gr
Chapter 4
4
E4.8
4 Principles of Mechanics
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114
Example 4.8 A homogeneous disk (mass m, radius r) rolls without
slipping on a rough surface (Fig. 4.9). Its center of mass C is
connected with the wall by a spring (spring constant k).
Derive the equation of motion
ϕ
using
r
a) Newton’s 2nd Law,
b) dynamic equilibrium conditions.
k
m C
A
Fig. 4.9
Solution a) The free-body diagram shows the forces that act on
the disk.
x
ϕ
W
F
C
H
N
We use the coordinates x and ϕ. Then the principles of linear
and angular momentum yield
←:
↑:
x
C:
mẍc = −F − H ,
0=N −W
→
ΘC ϕ̈ = rH
N =W ,
where ΘC = mr2 /2 .
In addition, we have the kinematic relation
xc = rϕ
→
ẍc = rϕ̈ ,
and the relation
Gr
F = kxc
→
F = krϕ
115
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4 Principles of Mechanics
for the force F in the spring. Solving these equations for the angle
ϕ yields
ϕ̈ + ω 2 ϕ = 0
where ω 2 =
2k
.
3m
b) If we apply the dynamic equilibrium conditions, the inertial
force mẍc and the pseudo moment ΘC ϕ̈ (both acting in the negative coordinate directions) have to be drawn into the free-body
diagram.
ΘC ϕ̈
W
mẍc
F
C
B
H
N
Dynamic moment equilibrium about point B then yields
y
B:
ΘC ϕ̈ + rmẍc + rF = 0 .
If we introduce the kinematic relation (see a)), the force F = krϕ
and ΘC = mr2 /2 we again obtain
ϕ̈ + ω 2 ϕ = 0 ,
ω2 =
2c
.
3m
Gr
Note that we may choose point B to be the reference point for
the moment equilibrium. This is advantageous since then the lever
arm of the unknown force of static friction H is zero. The mass
moment of inertia must be ΘC (not ΘB !).
E4.9
4 Principles of Mechanics
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116
Example 4.9 A cylinder (mass
m, radius r) rolls without slipping on a circular path (radius
R); see Fig. 4.10.
Derive the equation of motion using dynamic equilibrium
conditions.
11111111111111
00000000000000
00000000000000
11111111111111
00000000000000
11111111111111
ϕ
00000000000000
11111111111111
00000000000000
11111111111111
00000000000000
11111111111111
00000000000000
11111111111111
m
R
00000000000000
11111111111111
00000000000000
11111111111111
r
00000000000000
11111111111111
00000000000000
11111111111111
00000000000000
11111111111111
00000000000000
11111111111111
Fig. 4.10
Solution We isolate the cylinder and introduce the coordinates
ϕ and ψ (angle of rotation of the cylinder). With the tangential
acceleration at = (R − r)ϕ̈ (in the positive ϕ-direction) of the
center of mass C and the normal acceleration an = (R − r)ϕ̇2
(directed towards the center of the circular path), the inertial
forces mat (opposite to at ) and man (opposite to an ) can be drawn
on the free-body diagram.
ΘC ψ̈
ϕ
ψ
m(R − r)ϕ̇2
C
B
H
ϕ
m(R − r)ϕ̈
N
mg
The pseudo moment ΘC ψ̈ acts in the negative ψ-direction. Moment equilibrium about point B yields the equation of motion:
y
B : ΘC ψ̈ + m(R − r)ϕ̈ + mgr sin ϕ = 0
where ΘC = mr2 /2 .
The system has one degree of freedom. Therefore a relation exists
between the two coordinates:
vC = (R − r)ϕ̇ = rψ̇
→
ψ̈ = (R/r − 1)ϕ̈ .
This leads to
2g
ϕ̈ +
sin ϕ = 0 .
3(R − r)
Gr
Note that the moment equilibrium may be established with respect to point B. This is advantageous since the lever arms of
the unknown force of static friction H and of the inertial force
m(R − r)ϕ̇2 are zero. The mass moment of inertia, however, has
to be taken with respect to the center of mass C.
117
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4 Principles of Mechanics
Example 4.10 Two blocks of weights
W1 = m1 g and W2 = m2 g are
suspended by a pin-supported rope drum (moment of inertia ΘA ) as
shown in Fig. 4.11.
Determine the angular acceleration of the drum and the force in rope ① using dynamic equilibrium conditions. Neglect the mass of the ropes.
We first introduce the coordinates x1 and x2 describing the
motion of the blocks. The inertial forces −mi ẍi point in the negative xi -directions (see the freebody diagram). In addition, we have to consider the pseudo moment
−ΘA ϕ̈ which acts in the negative ϕdirection. Moment equilibrium about
point A then yields
E4.10
ϕ
A
2
Fig. 4.11
ϕ
ΘA ϕ̈
A
x2
x1
m1 g
m2 g
m1 x¨1
m2 x¨2
−r1 m1 (g + ẍ1 ) + r2 m2 (g − ẍ2 ) − ΘA ϕ̈ = 0 .
x1 = r1 ϕ
→
ẍ1 = r1 ϕ̈ ,
x2 = r2 ϕ
→
ẍ2 = r2 ϕ̈
we obtain the angular acceleration of the drum:
Gr
r2 m2 − r1 m1
g.
r12 m1 + r22 m2 + ΘA
m2
m1
Using the kinematic relations
ϕ̈ =
r1
1
Solution
y
A:
ΘA
r2
4 Principles of Mechanics
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118
In order to determine the force in rope ① we cut the rope. Force
equilibrium (see the free-body diagram) yields
S1
↑:
S1 − m1 g − m1 ẍ1 = 0
or
r2 (r1 + r2 )m2 + ΘA
S1 = m1 (g + r1 ϕ̈) = m1 g 2
.
r1 m1 + r22 m2 + ΘA
x1
m1 g
m1 x¨1
Gr
Note: For r2 m2 > r1 m1 the drum rotates clockwise, for r2 m2 <
r1 m1 it rotates counterclockwise. In the special case r2 m2 = r1 m1
the system is in static equilibrium (ϕ̈ = 0).
119
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4 Principles of Mechanics
Example 4.11 An angled arm (mass
E4.11
b
m) rotates with constant angular velocity Ω about point 0 (Fig. 4.12).
Calculate the bending moment,
shear force and normal force as functions of position using dynamic equilibrium conditions.
Ω
a
0
Fig. 4.12
Solution We introduce two coordinate systems xi , zi . Then, we
make a cut at the arbitrary position x1 . The acceleration of the
mass element dm at the position s (distance from the left end of
the arm) is given by an = rΩ2 (pointing towards point 0; note
that at = 0). Therefore, this element is subjected to the inertial
force dmrΩ2 (see the free-body diagram).
N(x2 = 0)
x1
z1
ds
dm(a − s)Ω2
ds
N
V
s
M(x1 = b)
M
N(x1 = b)
ϕ
x2
V
V (x1 = b)
r
N
Ω
z2
V (x2 = 0)
s
dmrΩ2
M(x2 = 0)
M
Ω
With
dm =
m
ds = µds ,
a+b
where µ = m/(a + b) is the mass per unit length, and with the
geometrical relations
cos ϕ = (b − s)/r ,
sin ϕ = a/r
Gr
we can determine the stress resultants through integration (note
that M ′ = V ).
Normal force (0 ≤ x1 ≤ b):
Z
Z x1
N (x1 ) = rΩ2 cos ϕdm =
Ω2 (b − s)µds
0
= µΩ2 [bs − s2 /2]|x0 1
Shear force (0 ≤ x1 ≤ b):
Z
Z
V (x1 ) = rΩ2 sin ϕdm =
→
x1
0
N (x1 ) = µΩ2 (bx1 − x21 /2) .
Ω2 aµds
→
V (x1 ) = µΩ2 ax1 .
4 Principles of Mechanics
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120
Bending moment (0 ≤ x1 ≤ b):
Z x1
M (x1 ) =
V (s)ds → M (x1 ) = µΩ2 ax21 /2 .
0
The matching conditions at the corner (x1 = b, x2 = 0) are given
by
N0 = N (x2 = 0) = V (x1 = b) = µΩ2 ab ,
V0 = V (x2 = 0) = −N (x1 = b) = −µΩ2 b2 /2 ,
M0 = M (x2 = 0) = M (x1 = b) = µΩ2 ab2 /2 .
Now we make a cut at the position x2 . The mass element dm at
the position s is subjected to the inertial force dm(a − s)Ω2 . This
leads to the following stress resultants:
Normal force, shear force, bending moment (0 ≤ x2 ≤ a):
Rx
N (x2 ) = N0 + 0 2 µΩ2 (a − s)ds
→
N (x2 ) = µΩ2 (ab + ax2 − x22 /2) ,
V (x2 ) = V0
→
V (x2 ) = −µΩ2 b2 /2 ,
M (x2 ) = M0 + x2 V0
N
+
| V0 |
N0
→
M (x2 ) = µΩ2 b2 (a − x2 )/2 .
V
+
N0
V0
M
M0
+
+
Gr
+
−
121
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4 Principles of Mechanics
Example 4.12 A wheel (weight W1 = m1 g, moment of inertia ΘA )
on an inclined plane is connected to a
block (weight W2 = m2 g) by a rope
which is guided over an ideal pulley
(Fig. 4.13). The wheel rolls on the plane without slipping.
Determine the acceleration of the
block applying d’Alembert’s principle.
Neglect the masses of the rope and the
pulley.
m1 , ΘA
r
A
m2
α
Fig. 4.13
Since the constraint forces (force in the rope, static
friction force) need not be determined, it is advantageous to apply
d’Alembert’s principle. The motion
is described by the coordinates xi
and ϕ. The inertial forces mi ẍi and
ϕ
x1
the pseudo moment ΘA ϕ̈ (acting in
ΘA ϕ̈
x2
the directions opposite to the chosen
A
α
positive coordinate directions) are
m1 x¨1
m2 g
shown in the figure. D’Alembert’s
m1 g
principle (principle of virtual work)
m2 x¨2
requires that the virtual work of all
forces vanishes:
Solution
δU + δUI = 0
→ −m1 ẍ1 δx1 − m1 g sin αδx1 − ΘA ϕ̈δϕ + m2 gδx2 − m2 ẍ2 δx2 = 0 .
With the kinematic relations
x1 = x2 = rϕ = x
→


δx1 = δx2 = rδϕ = δx

ẍ = ẍ = rϕ̈ = ẍ
1
2
we obtain
ΘA
−m1 ẍ − m1 g sin α − 2 ẍ + m2 g − m2 ẍ δx = 0 .
r
Gr
Since δx 6= 0, the expression in the brackets must vanish. Thus,
ẍ = ẍ2 = g
m2 − m1 sin α
.
ΘA
m1 + m2 + 2
r
Note that ẍ < 0 for m1 sin α > m2 . In this case, the wheel rolls
down the inclined plane.
E4.12
E4.13
4 Principles of Mechanics
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122
Example 4.13 Two drums are connected by a rope and carry blocks
of weights m1 g and m2 g
(Fig. 4.14). Drum ① is driven by the moment M0 .
Determine the acceleration of block ② using
d’Alembert’s
principle.
Neglect the mass of the
ropes.
ΘA
ΘB
r2
M0
1
r1
A
r2
B
m2
m1
2
Fig. 4.14
We introduce the
inertial forces mi ẍi and
the pseudo moments ΘA ϕ̈1 ,
ΘB ϕ̈2 . They act in the
directions opposite to the
chosen positive coordinate directions. D’Alembert’s
x1
principle requires
Solution
δU + δUI = 0 ,
ϕ1
ΘA ϕ¨1
M0
A
ΘB ϕ¨2
B
x2
m1 g
m2 g
m1 x¨1
m2 x¨2
which leads to
−m1 (g + ẍ1 )δx1 + m2 (g − ẍ2 )δx2
+M0 δϕ1 − ΘA ϕ̈1 δϕ1 − ΘB ϕ̈2 δϕ2 = 0 .
With the kinematic relations

ẍ2
r1
x1 = r1 ϕ1 


ϕ̈1 = ϕ̈2 =
,
ẍ1 = ẍ2 ,

r2
r2
x2 = r2 ϕ2  →
r
δx
2
1


, δx1 = δx2
δϕ1 = δϕ2 =

r2
r2
ϕ1 = ϕ2
Gr
ϕ2
123
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4 Principles of Mechanics
we obtain
r1 r1
−m1 g + ẍ2
+ m2 (g − ẍ2 )
r2
r2
ΘB
ΘA
M0
− 2 ẍ2 − 2 ẍ2 δx2 = 0 .
+
r2
r2
r2
Since δx2 =
6 0, the expression in the curly brackets must vanish.
Thus, the acceleration of block ② is
Gr
m1 r1
M0
1−
+
m2 r2
r2 m2 g
ẍ2 = g
.
ΘA
ΘB
m1 r1 2
+
+
1+
m2 r2
m2 r22
m2 r22
E4.14
4 Principles of Mechanics
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124
Example 4.14 The system shown in Fig. 4.15 consists of a block
(mass M ), a homogeneous disk (mass m, radius r) and two springs
(spring constant k). The block moves on a frictionless surface; the
m
disk rolls without slipping
k
on the block. A force F (t)
r
k
F (t)
acts on the block.
M
Derive the equations of motion using Lagrange’s forno friction
malism.
Fig. 4.15
Solution The system has
x
two degrees of freedom. We
00000000000000
11111111111111
ϕ
00000000000000
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00000000000000
11111111111111
choose the displacement x
C
00000000000000
11111111111111
F (t)
00000000000000
11111111111111
of the block and the angle
00000000000000
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00000000000000
11111111111111
of rotation ϕ of the disk to
00000000000000
11111111111111
be the generalized coordinates.
The two springs are unstressed for x = 0 and ϕ = 0. The kinetic
energy and the potential energy of the springs, respectively, are
2
T = M ẋ2 /2 + ΘC ϕ̇2 /2 + mvC
/2 ,
V = kx2 /2 + k(rϕ)2 /2 .
With ΘC = mr2 /2 and the kinematic relation
vC = ẋ − ϕ̇
we obtain the Lagrangian
L =T −V
→ L = M ẋ2 /2 + mr2 ϕ̇2 /4 + m(ẋ − rϕ̇)2 /2 − kx2 /2 − kr2 ϕ2 /2 .
Since the force F (t) is not given from a potential, we have to apply
the Lagrangian equations in the form
d ∂L
∂L
d ∂L
∂L
−
= Qx ,
−
= Qϕ .
dt ∂ ẋ
∂x
dt ∂ ϕ̇
∂ϕ
Gr
The generalized forces Qx and Qϕ follow from the virtual work
δU of the force F (t):
δU = Qx δx + Qϕ δϕ = F (t)δx
→
Qx = F (t) ,
Qϕ = 0 .
125
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To set up the equations of motion, the following derivatives
have to be calculated:
∂L
= M ẋ + m(ẋ − rϕ̇) ,
∂ ẋ
d ∂L
= M ẍ + m(ẍ − rϕ̈) ,
dt ∂ ẋ
∂L
= mr2 ϕ̇/2 − mr(ẋ − rϕ̇) ,
∂ ϕ̇
d ∂L
= mr2 ϕ̈/2 − mr(ẍ − rϕ̈) ,
dt ∂ ϕ̇
∂L
∂L
= −kx ,
= −kr2 ϕ .
∂x
∂ϕ
Thus, we obtain
(M + m)ẍ − mrϕ̈ + kx = F (t) ,
Gr
3
−mẍ + mrϕ̈ + krϕ = 0 .
2
E4.15
4 Principles of Mechanics
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126
Fig. 4.16 shows two blocks of mass m1 and m2
which can glide on a frictionless surface. They are coupled by springs (stiffnesses
k1
k3
k2
m1
m2
k1 , k2 , k3 ).
Derive the equations of
Fig. 4.16
motion using the Lagrange
formalism.
Solution The system is conservative; it has two degrees of freedom.
We introduce the two coordinates x1 and x2 which describe the
positions of the two blocks.
They are measured from the
x1
x2
equilibrium positions of the
k1
k3
k2
blocks. The kinetic and the
m1
m2
potential energy, respectively, are given by
1
1
T = m1 ẋ21 + m2 ẋ22 ,
2
2
1
1
1
2
V = k1 x1 + k2 x22 + k3 (x2 − x1 )2 .
2
2
2
Example 4.15
Thus, the Lagrangian of the system is
L=T −V =
1
1
1
1
1
m1 ẋ21 + m2 ẋ22 − k1 x21 − k2 x22 − k3 (x2 − x1 )2 .
2
2
2
2
2
To set up the Lagrange equations
d ∂L ∂L
d ∂L ∂L
−
=0,
−
=0
dt ∂ ẋ1
∂x1
dt ∂ ẋ2
∂x2
Gr
the following derivatives must be calculated:
∂L
d ∂L ∂L
= m1 ẋ1 ,
= m1 ẍ1 ,
= −k1 x1 + k3 (x2 − x1 ) ,
∂ ẋ1
dt ∂ ẋ1
∂x1
∂L
d ∂L ∂L
= m2 ẋ2 ,
= m2 ẍ2 ,
= −k2 x2 − k3 (x2 − x1 ) .
∂ ẋ2
dt ∂ ẋ2
∂x2
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4 Principles of Mechanics
Hence, we obtain
m1 ẍ1 + k1 x1 − k3 (x2 − x1 ) = 0
→
m1 ẍ1 + (k1 + k3 )x1 − k3 x2 = 0 ,
m2 ẍ2 + k2 x2 + k3 (x2 − x1 ) = 0
→
m2 ẍ2 + (k2 + k3 )x2 − k3 x1 = 0 .
Gr
Note: The two coupled differential equations describe the coupled
free vibrations of the two blocks. In the special case of k3 = 0 the
system is decoupled and we obtain two independent equations of
motion for two systems, each with one degree of freedom.
E4.16
4 Principles of Mechanics
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128
Example 4.16 Two simple pen-
dulums (each mass m, length
l) are connected by a spring
(spring constant k, unstretched
length b) as shown in Fig. 4.17.
Derive the equations of motion using the Lagrange formalism.
l
g
k
m
l
m
Fig. 4.17
Solution The system has two
degrees of freedom. We choose
the generalized coordinates ϕ1
and ϕ2 as shown in the figure.
With the kinetic and the potential energy, respectively,
0
ϕ1
ϕ2
k
m
T = ml2 (ϕ̇1 − ϕ̇2 )2 /2 + ml2 (ϕ̇1 + ϕ̇2 )2 /2
→
T = ml2 (ϕ̇21 + ϕ̇22 ) ,
m
2l sin ϕ2
V = −mgl cos(ϕ1 − ϕ2 ) − mgl cos(ϕ1 + ϕ2 ) + k(2l sin ϕ2 − b)2 /2
→
V = −2mgl cos ϕ1 cos ϕ2 + k(2l sin ϕ2 − b)2 /2
(zero level: point 0 and unstressed spring) the Lagrangian becomes
L=T −V
→ L = ml2 (ϕ̇21 + ϕ̇22 ) + 2mgl cos ϕ1 cos ϕ2 − k(2l sin ϕ2 − b)2 /2 .
Gr
To set up the Lagrange equations
d
∂L
∂L
d
∂L
∂L
−
=0,
−
=0
dt ∂ ϕ̇1
∂ϕ1
dt ∂ ϕ̇2
∂ϕ2
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4 Principles of Mechanics
the following derivatives are needed:
∂L
d
∂L
= 2ml2 ϕ¨1 ,
= 2ml2 ϕ̇1 ,
∂ ϕ̇1
dt ∂ ϕ̇1
∂L
= −2mgl sin ϕ1 cos ϕ2 ,
∂ϕ1
∂L
d
∂L
2
= 2ml2 ϕ¨2 ,
= 2ml ϕ˙2 ,
∂ ϕ̇2
dt ∂ ϕ̇2
∂L
= −2mgl cos ϕ1 sin ϕ2 − k(2l sin ϕ2 − b)2l cos ϕ2 .
∂ϕ2
This leads to the equations of motion:
lϕ¨1 + g sin ϕ1 cos ϕ2 = 0 ,
Gr
mlϕ¨2 + mg cos ϕ1 sin ϕ2 + k(2l sin ϕ2 − b) cos ϕ2 = 0 .
E4.17
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130
A disk (weight m2 g,
moment of inertia Θ2 ) glides along
a frictionless homogeneous bar of
weight m1 g (Fig. 4.18).
Find the equations of motion
using the Lagrange formalism.
Example 4.17
x
l
m2 , Θ2
ϕ
m1
Fig. 4.18
Solution The system is conservative;
x
it has two degrees of freedom. Its po0
sition is uniquely determined by the
x cos ϕ l
C1
cos ϕ
distance x of point C1 from pin 0 and
2
by the angle ϕ (generalized coordinaC2
ϕ
tes). With the kinetic and the potential energy, respectively,
o
1 m1 l 2 2 n 1
1
T =
ϕ̇ +
m2 [(xϕ̇)2 + ẋ2 ] + Θ2 ϕ̇22
2
3
2
2
i
1 h m1 l 2
1
=
+ m2 x2 + Θ2 ϕ̇2 + m2 ẋ2 ,
2 3
2
h
i
l
l
V = −m1 g cos ϕ − m2 gx cos ϕ = − m1 + m2 x g cos ϕ
2
2
(zero level at 0) and the Lagrangian L = T − V , we can write
down the Lagrange equations
d ∂L ∂L
d ∂L ∂L
=0,
=0.
−
−
dt ∂ ϕ̇
∂ϕ
dt ∂ ẋ
∂x
Gr
To this end, the following derivatives are needed:
∂L m1 l2
∂L
l
=
+ m2 x2 + Θ2 ϕ̇ ,
= − m1 + m2 x g sin ϕ ,
∂ ϕ̇
3
∂ϕ
2
2
d ∂L
m1 l
∂L
=
+ m2 x2 + Θ2 ϕ̈ + 2m2 xẋϕ̇ ,
= m2 ẋ ,
dt ∂ ϕ̇
3
∂ ẋ
d ∂L ∂L
= m2 ẍ ,
= m2 xϕ̇2 + m2 g cos ϕ .
dt ∂ ẋ
∂x
This leads to the coupled equations of motion:
m l2
l
1
+ m2 x2 + Θ2 ϕ̈ + 2m2 xẋϕ̇ + m1 + m2 x g sin ϕ = 0 ,
3
2
m2 ẍ − m2 xϕ̇2 − m2 g cos ϕ = 0
→
ẍ − xϕ̇2 − g cos ϕ = 0 .
131
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A thin half-cylindrical shell of weight W = mg rolls
without sliding on a flat surface
(Fig. 4.19).
Derive the equation of motion
using the Lagrange formalism.
Solution The system is conservative;
it has one degree of freedom. We introduce the coordinate ϕ as shown
in the figure. With the distance a =
2r/π of the center of mass C from
the center M of the shell we have
Example 4.18
E4.18
r
m
Fig. 4.19
Θ C = Θ M − a2 m = r 2 m − a2 m
rϕ
M
a
x
ϕ
C
y
= (1 − 4/π 2 )mr2 ,
xc = rϕ − a sin ϕ
yc = a cos ϕ
→
→
ẋc = rϕ̇ − aϕ̇ cos ϕ ,
ẏc = −aϕ̇ sin ϕ .
Thus, the potential energy V , the kinetic energy T , the Lagrangian
and the pertinent derivatives are
2
mgr(1 − cos ϕ) ,
π
h
2
1
1
1
2
T = m(ẋ2c + ẏc2 ) + ΘC ϕ̇2 = mr2 ϕ̇2 1 − cos ϕ
2
2
2
π
2
2 i
4
2
+
sin ϕ + 1 − 2 = mr2 ϕ̇2 1 − cos ϕ ,
π
π
π
h
i
2
2
L = T − V = mr rϕ̇2 1 − cos ϕ − g(1 − cos ϕ) ,
π
π
h
i
∂L
2
= mr 2rϕ̇ 1 − cos ϕ ,
∂ ϕ̇
π
V = mga(1 − cos ϕ) =
Gr
h
4
i
d ∂L 2
= mr 2rϕ̈ 1 − cos ϕ + rϕ̇2 sin ϕ ,
dt ∂ ϕ̇
π
π
h2
i
2
∂L
= mr rϕ̇2 sin ϕ − g sin ϕ .
∂ϕ
π
π
4 Principles of Mechanics
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132
Introduction into
d ∂L ∂L
−
=0
dt ∂ ϕ̇
∂ϕ
yields the equation of motion:
Gr
ϕ̈(π − 2 cos ϕ) + ϕ̇2 sin ϕ +
g
sin ϕ = 0 .
r
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A block (mass m1 )
can move horizontally on a smooth
surface (Fig. 4.20). A simple pendulum (mass m2 ) is connected to the
block by a pin.
Find the equations of motion
using the Lagrange formalism.
Example 4.19
E4.19
m1
g
l
m2
Fig. 4.20
Solution The system is conserva-
tive; it has two degrees of freedom. We use the generalized coordinates x and ϕ as shown in the
figure. With the zero-level of the
potential of the force m2 g chosen
at the height of the mass m1 , we
have
x
x
m1
y
l cos ϕ
ϕ
m2
l sin ϕ
V = −m2 gl cos ϕ ,
1
1
T = m1 ẋ2 + m2 [(ẋ + lϕ̇ cos ϕ)2 + (lϕ̇ sin ϕ)2 ] ,
2
2
1
1
L = T − V = (m1 + m2 )ẋ2 + m2 lẋϕ̇ cos ϕ + m2 l2 ϕ̇2 + m2 gl cos ϕ .
2
2
Introduction of the derivatives
∂L
= m2 lẋ cos ϕ + m2 l2 ϕ̇ ,
∂ ϕ̇
∂L
= −m2 lẋϕ̇ sin ϕ − m2 gl sin ϕ ,
∂ϕ
d ∂L = m2 lẍ cos ϕ − m2 lẋϕ̇ sin ϕ + m2 l2 ϕ̈ ,
dt ∂ ϕ̇
Gr
∂L
∂L
= (m1 + m2 )ẋ + m2 lϕ̇ cos ϕ ,
=0,
∂ ẋ
∂x
d ∂L = (m1 + m2 )ẍ + m2 lϕ̈ cos ϕ − m2 lϕ̇2 sin ϕ
dt ∂ ẋ
4 Principles of Mechanics
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134
into the Lagrange equations
d ∂L ∂L
−
=0,
dt ∂ ϕ̇
∂ϕ
d ∂L ∂L
−
=0
dt ∂ ẋ
∂x
yields the coupled equations of motion
ẍ cos ϕ + lϕ̈ + g sin ϕ = 0 ,
Gr
(m1 + m2 )ẍ + m2 lϕ̈ cos ϕ − m2 lϕ̇2 sin ϕ = 0 .
Vibrations
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Chapter 5
5
E5.11
5 Vibrations
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136
Example 5.11 The system in Fig 5.30
consists of three bars and a beam
(with negligible masses) and a block
(mass m).
Determine the circular frequency
of the free vertical vibrations.
EA
EA
l
EA
EI
m
l
l
Fig. 5.30
Solution The system consisting of
the truss and the beam is equivalent to a system consisting of two
springs in parallel (both springs
undergo the same elongation when
the block is displaced). To determine the spring constant kB of the
beam, we subject the beam to the
force FB = 1 which acts at the
location of the block. This force
produces the deflection (see Engineering Mechanics 2: Mechanics of
Materials, Table 4.3)
wB =
1 · (2l)3
.
48EI
FB = 1
wB
③
②
①
wT
FT = 1
Thus, the spring constant is given by
kB =
1
48 EI
6 EI
=
= 3 .
3
wB
(2l)
l
In order to find the spring constant kT of the truss, we apply the
force FT = 1 at bar ①. This force causes the displacement (see
Engineering Mechanics 2: Mechanics of Materials, Section 6.3)
Gr
wT =
X S̄ 2 li
i
.
EA
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With
S̄1 = 1 ,
S̄2 = S̄3 = −
1√
2,
2
l1 = l ,
l2 = l3 =
√
2l
we obtain
√2 2 √ i
√
1 h 2
l
wT =
1 ·l+2·
2 l = (1 + 2)
EA
2
EA
→
kT =
1
EA
√
=
.
wT
(1 + 2)l
Now, we replace the two springs in parallel by an equivalent single
spring. Its spring constant k ∗ is given by
k ∗ = kB + kT =
6 EI
EA
√
+
.
l3
(1 + 2)l
Gr
Thus, the eigenfrequency is
s
r
k∗
1 EAl2 1
√ .
=
6 EI +
ω=
m
l ml
1+ 2
E5.12
5 Vibrations
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138
Example 5.12 The system in Fig. 5.31 consists
r
of a homogeneous drum (mass M , radius r), a
block (mass m), a spring (spring constant k)
and a string (with negligible mass). The support of the drum is frictionless. Assume that
there is no slip between the string and the
drum.
Determine the natural frequency of the sys- k
tem.
M
m
Fig. 5.31
Solution We first draw the free-body dia-
gram. The position of the block is given by
the coordinate x, measured from the position with an unstrechted spring. Next, we
write down the equations of motion for the
block
↓:
mẍ = mg − S1
and for the drum
y
2
B : M r ϕ̈/2 = S1 r − S2 r .
In addition, we need the kinematic relation
ϕ
B
S2
S1
S2
S1
x
mg
ẋ = rϕ̇
and the equation
S2 = kx
for the restoring force in the spring. Solving yields the differential
equation for harmonic oscillations:
ẍ +
2k
2mg
x=
.
M + 2m
M + 2m
Gr
Thus, the natural frequency is
r
2k
ω=
.
M + 2m
139
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5 Vibrations
Example 5.13 Two drums rotate in opposite directions as shown in
Fig. 5.32. They support a homogeneous board of weight W (mass
m). The coefficient of kinetic
friction between the drums
x
W
and the board is µ.
Show that the board unµ
dergoes a harmonic vibratiΩ
Ω
on and determine the natural
frequency.
a
Fig. 5.32
Solution We separate the various parts of the system. The freebody diagram shows the forces acting if the board is displaced by
an amount x (the friction forces act on the drums in the opposite
directions of the rotations).
x
R2
W
N2
R1
N1
R2
a/2
R1
a/2
Thus, the equation of motion in the x-direction of the board is
given by
mẍ = R2 − R1 .
The normal forces follow from force equilibrium in the vertical
direction and from moment equilibrium:
a
a
+x
−x
N1 = W 2
,
N2 = W 2
.
a
a
With the law of kinetic friction R = µN , we obtain
Gr
R2 − R1 = µ(N2 − N1 ) = −µmg
2x
.
a
E5.13
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140
The equation of motion
mẍ = −µmg
2x
a
thus leads to the differential equation for harmonic vibrations:
g
ẍ + 2µ x = 0 .
a
The natural frequency is given by
r
g
ω = 2µ .
a
Gr
Note that the natural frequency does not depend on the angular
velocity Ω of the drums.
141
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5 Vibrations
Example 5.14 A homogeneous bar (weight W = mg, length l) is
submerged in a viscous fluid and undergoes vibrations about point
A (Fig. 5.33). The drag force Fd acting
A
on every point of the bar is proportional to the local velocity (proportionality factor β).
ϕ
l
a) Derive the equation of motion.
Assume small amplitudes and neglect
the buoyancy. b) Calculate the value
Fig. 5.33
β = β ∗ for critical damping.
Solution a) We consider an arbitrary
element of length dx of the bar. It is
A
x
subjected to the drag force
dFd = β v(x) dx = βxϕ̇ dx .
ϕ
We restrict ourselves to small amplitudes (sin ϕ ≈ ϕ). In this case the principle of angular momentum yields
l
ΘA ϕ̈ = −mg ϕ −
2
x
A:
Zl
dx
mg
dFd
l
lϕ
sin ϕ ≈
2
2
βx2 ϕ̇dx .
0
Evaluation of the integral and introduction of ΘA = ml2 /3 lead
to the equation of motion
ϕ̈ +
βl
3 g
ϕ̇ +
ϕ=0
m
2 l
→
where
βl
,
2m
Gr
ξ=
ω2 =
3g
.
2l
ϕ̈ + 2ξ ϕ̇ + ω 2 ϕ = 0
E5.14
5 Vibrations
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142
b) Critical damping is characterized by
ξ=ω
or
ζ=1.
Thus,
Gr
β∗l
=
2m
r
3g
2l
→
m
β =
l
∗
r
6
g
.
l
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rin
ge nics Wall
,G
r2
3,
01
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5 Vibrations
Example 5.15 The pendulum of a clock consists of a homogeneous
rod (mass m, length l) and a homogeneous disk (mass M , radius r) whose
center is located at a distance a from
point A (Fig. 5.34). Assume small amplitudes and determine the natural frequency of the corresponding oscillations. Choose m = M and r ≪ a and
calculate the ratio a/l which yields the
maximum eigenfrequency.
11
00
A
a
l
M
m
2r
Fig. 5.34
Solution We introduce the angle ϕ
as shown and apply the principle
of angular momentum:
x
A:
A
ΘA ϕ̈ = − mgl/2 sin ϕ − M ga sin ϕ
where
ΘA = ml2 /3 + M (r2 + 2a2 )/2 .
ϕ
mg
Mg
If we assume small amplitudes (sin ϕ ≈ ϕ), we can linearize the
equation of motion:
ϕ̈ +
(ml + 2M a)g
ϕ=0.
2ΘA
Hence, the eigenfrequency is obtained as
s
(ml + 2M a)g
ω=
.
2ΘA
In the special case of m = M and r ≪ a the natural frequency
simplifies to
r
3l + 6a
ω=
g.
2l2 + 6a2
Gr
The ratio a/l which yields the maximum eigenfrequency is found
by setting the derivative dω/da equal to zero:
!
r
dω
1
7
= 0 → a/l =
−1 .
da
2
3
E5.15
E5.16
5 Vibrations
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rin
g M Schr
ö
e
Sp cha der,
rin
ge nics Wall
,G
r2
3,
01
Dy ov
3
na idje
mi
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144
111
000
000
111
Example 5.16 The system in Fig 5.35
consists of a homogeneous pulley
(mass M , radius r), a block (mass m)
and a spring (spring constant k).
Determine the equation of motion
for the block and its solution for the
initial conditions x(0) = 0, v(0) = v0 .
Neglect the mass of the string and
any lateral motion.
k
r
M
A
111
000
m
Fig. 5.35
Solution We separate the pulley and
the block and measure the displacements x of the block and xA of point A
from the position of equilibrium. With
this choice, we do not have to consider
the weights M g and mg in the freebody diagram. Thus, the equations of
motion are
①
↓ :
②
↓ : M ẍA = S1 + S2 − kxA ,
x
A : ΘA ϕ̈ = rS1 − rS2 .
mẍ = −S1 ,
ϕ
S1
x
,
2
2rϕ = x
→
ẍA =
ẍ
,
2
kxA
S2
x
1
xA
If we use the kinematic relations (Π=:
b
instantaneous center of rotation, see
the figure)
xA =
2
xA
Π
x
ϕ̈ =
ẍ
2r
Gr
and ΘA = M r2 /2 we can solve the equations of motion for x and
obtain
v
u
k
k
ẍ +
x=0
→
ω=u
.
t
3
3
4m + M
4m + M
2
2
145
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5 Vibrations
The general solution of this differential equation is given by
x(t) = A cos ωt + B sin ωt .
The initial conditions
x(0) = 0
→
A=0,
lead to
Gr
x(t) =
v0
sin ωt .
ω
ẋ(0) = v0
→
B=
v0
ω
E5.17
5 Vibrations
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rin
g M Schr
ö
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Sp cha der,
rin
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,G
r2
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01
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146
Example 5.17 A wheel (mass m, radius r) rolls without slipping
on a circular path (Fig. 5.36). The mass of the rod (length l) can
be neglected; the joints are
g
frictionless.
Derive the equation of
l
motion and determine the
natural frequency of small
A
ϕ
oscillations.
m
r
Fig. 5.36
Solution We apply conserva-
tion of energy
T + V = const
ϕ
to derive the equation of motion. The kinetic energy of
the rolling wheel is given by
(see the figure)
vc
C
ψ
T = mvc2 /2 + ΘC ψ̇ 2 /2 ,
the potential energy is (zero-level at the height of point A)
V = −mgl cos ϕ .
With the mass moment of inertia ΘC = mr2 /2 and the kinematic
relations
vc = lϕ̇ ,
vc = rψ̇
→
lϕ̇ = rψ̇
the kinetic energy can be written as
T = 3ml2 ϕ̇2 /4 .
Introduction into the expression for conservation of energy gives
3lϕ̇2 /4 − g cos ϕ = const .
Gr
Differentiation yields
3
lϕ̇ϕ̈ + g ϕ̇ sin ϕ = 0
2
→
ϕ̈ +
2g
sin ϕ = 0 .
3l
147
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5 Vibrations
If we restrict ourselves to small amplitudes (sin ϕ ≈ ϕ) this equation reduces to
2g
ϕ̈ + ϕ = 0 .
3l
Gr
Thus, the natural frequency is obtained as
r
2g
ω=
.
3l
E5.18
5 Vibrations
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rin
g M Schr
ö
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Sp cha der,
rin
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,G
r2
3,
01
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148
Example 5.18 The simple pendulum in Fig. 5.37 is attached to a
spring (spring constant k) and a dashpot (damping coefficient d).
a) Determine the maximum value of
the damping coefficient d so that
the system undergoes vibrations.
a
Assume small amplitudes.
b) Find the damping ratio ζ so that
d
the amplitude is reduced to 1/10
a
of its initial value after 10 full cyk
cles. Calculate the corresponding
m
period Td .
1010
10
1010
01
Fig. 5.37
Solution a) The equation of motion
A
follows from the principle of angular
momentum (rotation about point A;
small amplitudes: sin ϕ ≈ ϕ, cos ϕ ≈ 1):
x
A:
ϕ
Fd
Fk
ΘA ϕ̈ = −Fd a − Fk 2a − mg2aϕ .
With
mg
ΘA = m (2a)2 ,
Fd = da ϕ̇ ,
Fk = k2a ϕ
we obtain
ϕ̈ +
where
Gr
ξ=
k
d
g ϕ̇ +
+
ϕ=0
4m
m 2a
d
,
8m
ω2 =
k
g
+
.
m 2a
→
ϕ̈ + 2ξ ϕ̇ + ω 2 ϕ = 0 ,
149
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5 Vibrations
In order to have oscillations, the system must be underdamped:
r
k
g
d
<
+
ζ <1 → ξ<ω →
8m
m 2a
r
gm2
.
→ d < 8 km +
2a
b) The necessary damping ratio follows with xn+10 = xn /10 from
the logarithmic decrement:
2πζ
xn
10 p
= ln 10
= ln
xn+10
1 − ζ2
v
u
1
→ ζ=u
= 0.037 .
t 20π 2
+1
ln 10
This leads to the period
Gr
2π
2π
Td = p
≈
= 2π
2
ω
ω 1−ζ
s
2am
.
2ak + gm
E5.19
5 Vibrations
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rin
g M Schr
ö
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rin
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,G
r2
3,
01
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150
Example 5.19 The structure in Fig. 5.38 consists of an elastic beam
(flexural rigidity EI, axial rigidity EA → ∞, negligible mass) and
three rigid bars (with negligible masses). The block (mass m) is
suspended from a spring (spring constant k).
Determine the eigenfrequency of the vertical oscillations of
the block.
1010
1010
010
1
a
a
a
a
k
m
Fig. 5.38
Solution We reduce the structure to an
equivalent system of a spring (spring
constant k ∗ , see the figure) and a mass.
To this end we first replace the beam
and the bars by a spring with the spring
constant kB . We can determine kB if we
subject the beam to a force F which acts
at the free end. This force produces the
deflection
w=
1111
0000
k∗
m
F a3
EI
(see Engineering Mechanics 2: Mechanics of Materials, Example
6.22). The spring constant is obtained from
kB =
F
w
→
kB =
EI
.
a3
Gr
The displacement of the block is the sum of the elongations of the
springs with spring constants k and kB . Therefore, the beam/bars
and the given spring act as springs in series. Thus, the spring
constant k ∗ of the equivalent system follows from
1
1
1
=
+
k∗
kB
k
→
k∗ =
kEI
.
ka3 + EI
This yields the eigenfrequency
s
r
k∗
kEI
ω=
→ ω=
.
m
(ka3 + EI)m
151
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rin
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,G
r2
3,
01
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na idje
mi
cs e
5 Vibrations
Example 5.20 A rod (length l, with negligible mass) is elastically
supported at point A (Fig. 5.39). The rotational spring (spring
constant kT ) is unstretched for ϕ = 0. The rod carries a point
mass m at its free end.
A
kT
Derive the equation of motion.
g
Determine the spring constant so
ϕ
that ϕ = π/6 is an equilibrium posim
tion. Calculate the natural frequenl
cy of small oscillations about this
Fig. 5.39
equilibrium position.
Solution To derive the equation of
motion we apply the principle of angular momentum:
y
A:
0110
MA
ϕ
ΘA ϕ̈ = mgl cos ϕ − MA .
mg
With the mass moment of inertia
ΘA = ml2 and the restoring moment MA = kT ϕ we obtain
ϕ̈ =
g
kT
cos ϕ −
ϕ.
l
ml2
Since ϕ = ϕ0 = π/6 is a position of equilibrium, the condition ϕ̈(π/6) =
√ 0 leads to the required spring constant (note that
cos(π/6) = 3/2):
√
√
3 g π kT
3 3
−
= 0 → kT =
mgl .
2 l
6 ml2
π
Now we consider small oscillations about this position of equilibrium. We assume that
ϕ = ϕ0 + ψ
with |ψ| ≪ 1 .
Introduction into the equation of motion yields
ψ̈ =
g
kT
cos(ϕ0 + ψ) −
(ϕ0 + ψ) .
l
ml2
Gr
We use the trigonometric relation
cos(ϕ0 + ψ) = cos ϕ0 cos
√ ψ − sin ϕ0 sin ψ
3
1
→ cos(ϕ0 + ψ) =
cos ψ − sin ψ
2
2
E5.20
5 Vibrations
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152
and linearize (cos ψ ≈ 1, sin ψ ≈ ψ) to obtain
√
kT
3 g π kT
1g
ψ+
−
ψ̈ = − ψ −
2l
ml2
2 l
6 ml2
√ !
1 3 3 g
→ ψ̈ +
+
ψ=0.
2
π
l
Gr
Thus, the natural frequency is given by
v
√ !
u
u 1
3 3 g
t
+
.
ω=
2
π
l
153
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,G
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na idje
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5 Vibrations
Example 5.21 A single story frame
E5.21
consists of two rigid columns (with
m
negligible masses), a rigid beam of
mass m and a spring-dashpot sysd
tem as shown in Fig. 5.40. The
ground is forced to vibration by an
k
earthquake; the acceleration üE =
45◦
b0 cos Ωt is known from measurements.
üE
Determine the maximum ampliFig. 5.40
tude of the steady state vibrations.
Assume that the system is underdamped and that the vibrations
have small amplitudes.
00000
11111
1111
0000
00000
0000 11111
1111
Solution We assume that the
amplitudes of the vibrations
are small. Then the elongation of the diagonal is obtained
as
√
2
∆=
(x − uE ) .
2
The elongation produces the
force
x − uE
m
x
F
∆
45◦
uE
1111111111
0000000000
˙
F = k∆+ d∆
in the spring-dashpot system (see the figure). The equation of
motion of the beam is given by
√
2
→: mẍ = −F
2
d
k
→ mẍ + (ẋ − u̇E ) + (x − uE ) = 0 .
2
2
Thus, the relative displacement y = x − uE is described by
d
k
ẏ + y = m b0 cos Ωt
2
2
2ζ
1
→
ÿ +
ẏ + y = y0 cos Ωt ,
ω2
ω
Gr
mÿ +
where
ω2 =
k
,
2m
ζ=
d
2
r
1
,
2k m
y0 =
2m b0
.
k
5 Vibrations
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g M Schr
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r2
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154
Gr
The maximum amplitude A is obtained for η = Ω/ω ≈ 1 (resonance!). In the case of small damping (ζ ≪ 1) we obtain
s
√ b 0 m3
y0
A = y0 Vmax ≈
=2 2
.
2ζ
d
k
155
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,G
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5 Vibrations
The undamped system in Fig. 5.41 consists of a
block (mass m = 4 kg) and a spring (spring constant k = 1
N/m). The block is subjected to a force F (t). The initial conditions
x(0) = x0 = 1 m, ẋ(0) = 0 and the response
t
t−T
ht − T i0
x(t) = x0 cos
+ 20 1 − cos
2t0
2t0
Example 5.22
x(t)
to the excitation are given. Here,
t0 = 1 s, T = 5 s and ht − T i0 = 0
for t < T and ht − T i0 = 1 for
t > T.
Calculate the force F (t).
k
m
F (t)
Fig. 5.41
Solution First we calculate the force F for t < T . Then ht−T i0 = 0
and the response is given by
x(t) = x0 cos
t
.
2t0
The unknown force follows from the equation of motion:
F = mẍ + kx .
With
ẋ = −
x0
t
sin
2t0
2t0
and ẍ = −
x0
t
cos
2
4t0
2t0
we obtain
mx0
t
F (t) = − 2 + kx0 cos
.
4t0
2t0
Inserting the given numerical values of the parameters leads to
Gr
F (t) ≡ 0 for
t<T .
E5.22
5 Vibrations
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156
Now we consider the case t > T . Then ht − T i0 = 1 and the
response follows as
t−T
t
+ 20 1 − cos
x(t) = x0 cos
2t0
2t0
x0
t
t−T
→ ẋ =
− sin
+ 20 sin
2t0
2t0
2t0
x0
t
t−T
.
→ ẍ = 2 − cos
+ 20 cos
4t0
2t0
2t0
Introduction into the equation of motion yields
mx0
t
F (t) = − 2 + kx0 cos
4t0
2t0
20mx0
t−T
+
−
20kx
+ 20kx0
0 cos
4t20
2t0
→
F (t) ≡ 20 N
for t > T .
F (t) [N]
30
20
10
Gr
5
10
t[s]
157
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5 Vibrations
Example 5.23 A simplified model of a car (mass m) is given by
a spring-mass system (Fig. 5.42). The car drives with constant
velocity v0 over an uneven surface in the form of a sine function
(amplitude U0 , wavelength L).
v0
a) Derive the equation of motion and determine the forcing
m
x
U0
frequency Ω.
c
b) Find the amplitude of the vertical vibrations as a function
of the velocity v0 .
L
c) Calculate the critical velocity
Fig. 5.42
vc (resonance!).
Solution a) We denote the verti-
cal displacement of the car by x,
the uneven surface is described
by u. Then Newton’s law reads
↑:
m
x
u
mẍ = −k (x − u) .
With the position of the car, s =
v0 t, in the horizontal direction
we obtain
u = U0 cos
u
L
U0
s
2πs
2πv0 t
= U0 cos
= U0 cos Ωt .
L
L
Thus,
m ẍ + k x = k U0 cos Ωt
with
Ω=
2πv0
.
L
b) We assume the solution of the equation of motion to be of
the form of the right-hand side: x = x0 cos Ωt. This leads to the
amplitude of the steady state vibrations:
x0 =
U0
U0
=
Ω2
4π 2 v02 m
1− 2
1−
ω
L2 k
Gr
where ω 2 = k/m.
c) Resonance occurs for Ω = ω:
4π 2 vc2 m
=1
L2 k
→
L
vc =
2π
r
k
.
m
E5.23
E5.24
5 Vibrations
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rin
g M Schr
ö
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Sp cha der,
rin
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,G
r2
3,
01
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158
Example 5.24 A homogeneous wheel (mass m) is attached to a
spring (spring constant k). The
x
wheel rolls without slipping on
m
a rough surface which moves
k
C
r
according to the function u =
µ0
u
u0 cosΩt (Fig. 5.43).
a) Determine the amplitude of
Fig. 5.43
the steady state vibrations.
b) Calculate the coefficient µ0 of static friction which is necessary
to prevent slipping.
00
11
00
11
00
11
00
11
Solution The equations of mo-
tion for the wheel are given by
x
↑
:
→:
y
C :
0 = N − mg ,
(a)
m ẍ = −k x + H ,
(b)
ΘC ϕ̈ = −r H .
mg
kx
C
(c)
ϕ
H
N
With the kinematic relation
ẍ = ü + rϕ̈ = −u0 Ω2 cos Ωt + rϕ̈
→
x = u + rϕ
r
and ΘC = mr2 /2 we obtain from (b) and (c) the differential equation for forced vibrations:
ẍ +
2 k
1
x = − u0 Ω2 cos Ωt .
3 m
3
a) We assume the solution to be of the form of the right-hand
side: x = x0 cos Ωt. This leads to the amplitude of the steady state
vibrations:
u0
|x0 | =
.
2 k
3
−
1
3 m Ω2
b) The condition |H|max ≤ µ0 N for static friction and (a), (b)
yield the required coefficient of static friction:
Gr
|H|max
µ0 ≥
=
N
→
ẍ +
µ0 ≥
k
x
m
g
u 0 Ω2
3g
max
=
−x0 Ω2 +
k
−1
m Ω2
.
2 k
−
1
3 m Ω2
g
k
x0
m
159
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r2
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01
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5 Vibrations
Example 5.25 A small homogeneous disk (mass m, radius r) is at-
tached to a large homogeneous disk (mass M , radius R) as shown
in Fig. 5.44. The torsion spring
(spring constant kT ) is unstretg
M A R
ched in the position shown.
kT
Determine the eigenfrequency
a
r
of the oscillations. Assume small
amplitudes.
m
Fig. 5.44
Solution We apply the principle
of angular momentum to derive
the equation of motion:
x
A:
kT ϕ
ΘA ϕ̈ = −kT ϕ − mga sin ϕ .
In the case of small amplitudes
(sin ϕ ≈ ϕ) this equation reduces
to
ϕ̈ + ω 2 ϕ = 0
with
ω2 =
A
ϕ
mg
kT + mga
.
ΘA
Inserting the mass moment of inertia
M R2
mr2
2
ΘA =
+
+ ma
2
2
we can write the eigenfrequency in the form
v
u
kT + mga
u
ω=u
.
t1
r2
M R2 + m( + a2 )
2
2
Note that the problem can also be solved with the aid of the
conservation of energy (we choose V = 0 for ϕ = 0):
T + V = const →
1
1
ΘA ϕ̇2 + kT ϕ2 + mga(1 − cos ϕ) = const.
2
2
Differentiation yields
Gr
ΘA ϕ̇ϕ̈ + kT ϕϕ̇ + mga sin ϕ ϕ̇ = 0 .
With sin ϕ ≈ ϕ and ϕ̇ 6= 0 we obtain the same result as above.
E5.25
E5.26
5 Vibrations
1111
0000
000011
1111
00
00
11
00
11
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ö
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,G
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160
Example 5.26 The systems ➀
and ➁ in Fig. 5.45 consist of
two beams (negligible masses,
flexural rigidity EI), a spring
(spring constant k) and a box
(mass m).
Determine the spring constants k ∗ of the equivalent
springs for the two systems.
Solution We reduce both sys-
tems to the equivalent simple systems of a mass and a
spring.
00
11
00
11
00
11
00
11
00
11
00
11
EI
k
EI
1
m
a
EI
2a
EI
k
m
11
00
00
11
2
Fig. 5.45
11
00
00
11
1
l , EI
w
In system ①, the three “springs” are attached to the mass. Therefore, they undergo the same deflection when the box is displaced:
they act as springs in parallel. The equivalent spring constant k ∗
is the sum of the individual spring constants:
X
k∗ =
ki .
We obtain the spring constants kL and kR of the right and the
left beam, respectively, if we subject the cantilevers to a force 1
at their free ends. The corresponding deflections are
w=
1 · l3
3EI
Gr
(see Engineering Mechanics 2: Mechanics of Materials, Section
4.5) which leads to
161
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5 Vibrations
kL =
1
3EI
,
=
wL
(2a)3
kR =
1
3EI
= 3 .
wR
a
Thus,
k ∗ = kL + kR + k =
27 EI
27EI + 8ka3
+
k
=
.
8 a3
8a3
0000
1111
111
000
111
0000
111 000
000000
111
0001111
111
kL
k∗
k̄
kR
k
k
m
m
m
Now we consider system ②. Here, the two beams act as springs
in parallel with equivalent spring constant k̄. This then acts in
series with given spring (spring constant k). Hence,
27 EI
,
8 a3
1
1
8a3
1
1
+
=
=
+
k∗
27EI
k
k̄ k
k̄ = kL + kR =
→ k∗ =
27EIk
=
27EI + 8ka3
27EI
8a3 + 27
EI
k
.
Gr
Note that the stiffness of system ② is smaller than the one of
system ①. Therefore it vibrates with a smaller frequency.
E5.27
5 Vibrations
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162
Example 5.27 A homogeneous wheel (mass m, moment of inertia
ΘC , radius r) rolls without slipping on a rough beam (mass M ).
m, ΘC
The beam moves without
k
C
friction on roller supports
r
(Fig. 5.46).
Determine the natural freM
quency of the system.
1010
1010
111
000
Solution We separate the wheel
and the beam and introduce the
coordinates x1 , x2 and ϕ (see
the figure). The coordinates are
measured from the position of
equilibrium. Then the equations of motion are
①
→:
y
C :
②
Fig. 5.46
x1
mg
1
kx1
C
r
ϕ
H
m ẍ1 = −kx1 − H ,
ΘC ϕ̈ = r H ,
11
00
00
11
N
H
x2
A
→ : M ẍ2 = H .
2
If we use the kinematic relation
x1 = x2 + rϕ
→
ẋ1 = ẋ2 + rϕ̇
and solve for x1 we obtain
k
ẍ1 +
m+
M
1 + M r2 /ΘC
x1 = 0 .
Gr
Thus, the natural frequency is given by
v
u
k
u
.
ω=u
M
t
m+
1 + M r2 /ΘC
→
ẍ1 = ẍ2 + rϕ̈
B
Non-Inertial Reference Frames
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Gr
Chapter 6
6
E6.5
6 Non-Inertial Reference Frames
1111111
0000000
0000000
1111111
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164
Example 6.5 Point A of the simple
pendulum (mass m, length l) in
Fig. 6.8 moves with a constant acceleration a0 to the right.
Derive the equation of motion.
a0
A
g
ϕ
l
m
Fig. 6.8
Solution We introduce the ξ, η-co-
ordinate system as shown in the figure. It is a translating coordinate
system with point A as the origin.
The equation of motion in the moving system is
η
eη
A
eξ
ξ
ϕ
mar = F + Ff .
S
The (real) force F acting at the
mass is given by
m
W = mg
F = − S sin ϕ eξ + (S cos ϕ − mg)eη
and the fictitious force Ff is
Ff = − maf = − ma0 eξ .
Note that the Coriolis force is zero since ω = 0.
The components of the relative acceleration ar follow from the
coordinates of the point mass in the moving system through differentiation:
ξ = l sin ϕ,
η = − l cos ϕ,
η̇ = lϕ̇ sin ϕ,
ξ¨ = lϕ̈ cos ϕ − lϕ̇2 sin ϕ,
η̈ = lϕ̈ sin ϕ + lϕ̇2 cos ϕ .
Gr
ξ˙ = lϕ̇ cos ϕ,
165
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6 Non-Inertial Reference Frames
This yields the relative acceleration
ar = ξ¨ eξ + η̈ eη = (lϕ̈ cos ϕ − lϕ̇2 sin ϕ)eξ
+(lϕ̈ sin ϕ + lϕ̇2 cos ϕ)eη .
Introduction into the equation of motion leads to the components
of the equation of motion in the direction of the axes ξ and η:
m (lϕ̈ cos ϕ − lϕ̇2 sin ϕ) = −S sin ϕ − ma0 ,
m (lϕ̈ sin ϕ + lϕ̇2 cos ϕ) = S cos ϕ − mg.
These are two equations for the unknowns ϕ and S. Solving for ϕ
yields the equation of motion
lϕ̈ + g sin ϕ + a0 cos ϕ = 0 .
Gr
Note that the position ϕ0 = − arctan a0 /g is obtained for ϕ̈ = 0.
The pendulum oscillates about this position for ϕ̈ 6= 0.
E6.6
6 Non-Inertial Reference Frames
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166
Example 6.6 The two disks in
11
00
1010
00
11
Fig. 6.9 rotate with constant
angular velocities Ω and ω
about their respective axes.
Determine the absolute acceleration of point P at the instant shown.
P
ϕ
r
ω
z
y
x
101010
101010
Ω
Solution We describe the mo-
a
Fig. 6.9
tion of point P in a coordinate system x, y, z which is fixed
to the large disk. The absolute
acceleration of P is
P
r
ϕ
z
aP = af + ar + ac ,
where the acceleration of the
reference frame and the relative acceleration are given by

0



2
af = 
−(a + r cos ϕ)Ω  ,
0
y
x

0




2
ar = 
−rω cos ϕ .
−rω 2 sin ϕ
We also write the angular velocity of the reference frame and the
relative velocity as column vectors:
 


0
0
 





Ω=
 0  , v r = −rω sin ϕ
Gr
Ω
rω cos ϕ
167
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6 Non-Inertial Reference Frames
and we calculate the Coriolis acceleration:


2rωΩ sin ϕ


 .
ac = 2Ω × v r → ac = 
0


0
Combining yields

2rωΩ sin ϕ

Gr



2
2
aP = 
−(a + r cos ϕ)Ω − rω cos ϕ .
−rω 2 sin ϕ
E6.7
6 Non-Inertial Reference Frames
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168
Example 6.7 A horizontal circular platform (radius r) rotates with
constant angular velocity Ω (Fig. 6.10). A block (mass m) is locked
in a frictionless slot at a distance a
from the center of the platform. At
r
a
time t = 0 the block is released.
Determine the velocity vr of the
m
block relative to the platform when
it reaches the rim of the platform.
Ω
Fig. 6.10
Solution We describe the motion of
the block in a coordinate system x, y
which is fixed to the platform. The
absolute acceleration of the block is
given by
x
y
a
aB = af + ar + ac .
Here, the acceleration of the reference frame, the relative acceleration and the Coriolis acceleration are
"
#
" #
"
#
−xΩ2
ẍ
0
af =
, ar =
, ac =
.
0
0
2Ωẋ
Thus, the absolute acceleration becomes
"
#
ẍ − Ω2 x
aB =
.
2Ωẋ
The equation of motion for the block is
Gr
maB = F ,
169
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6 Non-Inertial Reference Frames
where the force F (which is exerted from the slot on the block) is
" #
0
F =
.
Fy
We now write down the x-component of the equation of motion:
m(ẍ − Ω2 x) = 0
→
ẍ − Ω2 x = 0 .
The general solution of this differential equation is given by
x(t) = A cosh Ωt + B sinh Ωt .
With the initial conditions
x(0) = a
ẋ(0) = 0
→
→
A=a,
B=0
we obtain
x(t) = a cosh Ωt .
When the block reaches the rim of the platform, the condition
x(tR ) = r
→
cosh ΩtR = r/a
Gr
is satisfied. Thus the relative velocity is (note that cosh2 x −
sinh2 x = 1)
p
ẋ(tR ) = aΩ sinh ΩtR → ẋ(tR ) = Ω r2 − a2 .
E6.8
6 Non-Inertial Reference Frames
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170
Example 6.8 A simple pendulum is
attached to point 0 of a circular disk
(Fig. 6.11). The disk rotates with
a constant angular velocity Ω; the
pendulum oscillates in the horizontal plane.
Determine the circular frequency
of the oscillations. Assume small
amplitudes and neglect the weight
of the mass.
Ω
r
m
l
0
00000
11111
00000
11111
00000
11111
Fig. 6.11
Solution We introduce a rotating ξ, η, ζ-coordinate system. Then
Ω = Ωeζ ,
Ω̇ = 0 ,
a0 = r̈ 0 = −rΩ2 eξ ,
r 0P = l cos ϕ eξ + l sin ϕ eη .
The relative velocity can be expressed by the relative angular velocity ϕ∗ (∗ : time derivative relative to the moving frame):
vr = lϕ∗
→
Ω
vr
η
ϕ
r
0
v r = −lϕ∗ sin ϕ eξ + lϕ∗ cos ϕ eη .
Thus, the fictitious forces F f and F c are
F f = − ma0 − mΩ × (Ω × r 0P ) = m(rΩ2 + lΩ2 cos ϕ)eξ
+ mΩ2 l sin ϕ eη ,
F c = − 2mΩ × v r = 2mΩlϕ∗ (eξ cos ϕ + eη sin ϕ) .
Gr
P
r0P
ξ
171
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6 Non-Inertial Reference Frames
With the tangential relative acceleration art = lϕ∗∗ the equation of motion in the tangential direction is obtained as
տ: mlϕ∗∗ = m(lΩ2 + 2lϕ∗ Ω) sin ϕ cos ϕ
− m[rΩ2 + (lΩ2 + 2lϕ∗ Ω) cos ϕ] sin ϕ
mΩ2 l sin ϕ
= − mrΩ2 sin ϕ .
We assume small amplitudes
(sin ϕ ≈ ϕ). This yields
rΩ2
ϕ∗∗ +
ϕ=0.
l
art
η
S
2mlϕ∗ Ω sin ϕ
m(rΩ2 +lΩ2 cos ϕ)
m
ϕ 2mlϕ∗ Ω cos ϕ
ξ
Gr
Hence, the circular frequency of the oscillations is
q
ω = r/l Ω .
E6.9
6 Non-Inertial Reference Frames
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172
Example 6.9 A drum rotates with
angular velocity ω about point B
(Fig. 6.12). Pin C is fixed to the
drum; it moves in the slot of link
AD.
Determine the angular velocity
A
ωAD of link AD and the velocity
vr of the pin relative to the link at
the instant shown.
D
C
3l
B
4l
111111111
000000000
ω
Fig. 6.12
Solution We use the rotating co-
ordinate system x, y as shown in
the figure. The (absolute) velocity
of pin C is given by
"
#
cos β
.
v C = 3lω
y
− sin β
x
C
a
3ℓ
β
A
With the geometrical relations
p
a = 16l2 + 9l2 = 5l , sin β = 3/5 ,
4ℓ
cos β = 4/5
we can write
" #
3lω 4
vC =
.
5 −3
The velocity of the reference frame at point C and the velocity of
pin C relative to the moving frame are
" #
" #
0
1
v f = β̇l
, v r = vr
.
5
0
With
vC = vf + vr
→
" #
" #
" #
3lω 4
0
1
= β̇l
+ vr
,
5 −3
5
0
Gr
we finally obtain
ωAD
9ω
= β̇ = −
,
25
" #
12
1
vr =
ωl
.
5
0
173
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6 Non-Inertial Reference Frames
Example 6.10 A point P moves along a circular path (radius r)
on a platform with a constant relative velocity vr (Fig. 6.13). The
platform rotates with a convr
stant angular velocity ω about
P
point A. The eccentricity e is giω
r
ven.
A e
0
Determine the relative, fixed
frame-, Coriolis, and absolute
accelerations of P .
Fig. 6.13
Solution We introduce the coor-
dinate system ξ, η, ζ as shown in
the figure. Its origin is located at
the center 0 of the platform; it
rotates with the platform. Thus
point P undergoes a circular
motion relative to this system.
With the magnitude ar = vr2 /r
of the relative acceleration and
its direction (from P to 0) we
can write
v2
ar = − r (eξ cos ϕ + eη sin ϕ) .
r
η
vr
ω
A
r 0P
e 0
P
ϕ
ξ
With
ω = ωeζ ,
ω̇ = 0 ,
r0P = eξ r cos ϕ + eη r sin ϕ ,
v r = vr (−eξ sin ϕ + eη cos ϕ) ,
r̈ 0 = a0 = −e ω 2 eξ
we obtain
af = a0 + ω × (ω × r0P )
= −e ω 2 eξ + rω 2 [eζ × (eζ × eξ cos ϕ) + eζ × (eζ × eη sin ϕ)]
= −(e + r cos ϕ)ω 2 eξ − rω 2 sin ϕeη ,
Gr
ac = 2ω × v r = 2ωvr [eζ × (−eξ sin ϕ) + eζ × eη cos ϕ]
= −2ωvr (eξ cos ϕ + eη sin ϕ) .
E6.10
6 Non-Inertial Reference Frames
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174
Thus, the absolute acceleration is found as
a = af + ar + ac
vr2
v2
+ 2ωvr ) cos ϕ]eξ − [rω 2 + r + 2ωvr ] sin ϕ eη
r
r
vr 2
vr 2
2
= −[eω + r(ω + ) cos ϕ]eξ − r(ω + ) sin ϕ eη .
r
r
Gr
= −[eω 2 + (rω 2 +
175
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6 Non-Inertial Reference Frames
Example 6.11 A circular ring (ra-
dius r) rotates with constant angular velocity Ω about the xaxis (Fig. 6.14). A point mass m
moves without friction inside the
ring.
Derive the equations of motion and determine the equilibrium
positions of the point mass relative to the ring.
E6.11
Ω
01101010
m
ϕ x
z
y
g
r
11
00
01
Fig. 6.14
Solution We describe the motion of the point mass in the x, y, zcoordinate system (see the figure) which rotates with the ring.
The absolute acceleration a of the point mass is given by
a = af + ar + ac ,
where the acceleration of the reference frame and the relative acceleration are




0
−rϕ̇2 cos ϕ − rϕ̈ sin ϕ







2
2
af = 
−rΩ sin ϕ , ar = −rϕ̇ sin ϕ + rϕ̈ cos ϕ .
0
0
With the angular velocity of the ring and the relative velocity
 


Ω
−rϕ̇ sin ϕ
 





Ω=
 0  , v r =  rϕ̇ cos ϕ 
0
0
we can calculate the Coriolis acceleration


0


 .
ac = 2Ω × v r → ac = 
0


2rΩϕ̇ cos ϕ
Gr
The equation of motion is given by
ma = W + N ,
6 Non-Inertial Reference Frames
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176
where


−mg



W =
 0 
0
is the weight of the point mass and
 
N
 x

N =
Ny  with Ny /Nx = tan ϕ
Nz
is the force exerted from the ring on the point mass. Now, we can
write down the components of the equation of motion:
−m(rϕ̇2 cos ϕ + rϕ̈ sin ϕ) = −mg + Nx ,
−m(rϕ̇2 sin ϕ − rϕ̈ cos ϕ + rΩ2 sin ϕ) = Nx tan ϕ ,
2mrΩϕ̇ cos ϕ = Nz .
Positions of equilibrium relative to the ring are characterized by
g
ϕ̇ = 0 , ϕ̈ = 0 →
rΩ2 +
sin ϕ = 0 .
cos ϕ
This yields
ϕ1 = 0 ,
ϕ2 = π ,
ϕ3,4 = π ± arccos
Gr
The positions ϕ3,4 exist only for Ω2 > g/r.
g
.
rΩ2
177
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Example 6.12 A point P moves
on a square plate along a circular path (radius r) with a
constant relative velocity vr .
The plate moves horizontally
with the constant acceleration
a0 (Fig. 6.15).
Determine the magnitude of
the absolute acceleration of P .
11111111111
00000000000
vr
P
r
a0
1111111111
0000000000
0000000000
1111111111
Fig. 6.15
Solution The components of the
relative velocity in the moving
reference frame ξ, η are
η
vr
P
y
fixed
x
vrξ = ξ ∗ = −vr sin ϕ ,
E6.12
r
0
ϕ
ξ
vrη = η ∗ = vr cos ϕ
(∗: time derivative relative to the moving frame). Differentiation
with respect to the moving frame leads to the components of the
relative acceleration (note: rϕ∗ = vr ):
vr2
cos ϕ ,
r
v2
= −vr ϕ∗ sin ϕ = − r sin ϕ .
r
arξ = ξ ∗∗ = −vr ϕ∗ cos ϕ = −
arη = η ∗∗
Since the reference frame undergoes a translation, the absolute
acceleration is given by
ax = a0 + arξ = a0 −
ay = arη = −
vr2
sin ϕ .
r
It has the magnitude
r
q
Gr
a=
vr2
cos ϕ ,
r
a2x + a2y =
a20 +
vr4
vr2
−
2a
cos ϕ .
0
r2
r
E6.13
6 Non-Inertial Reference Frames
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ö
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r2
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178
Example 6.13 A crane starts to move from rest with a constant
acceleration b0 along a straight track. At the same time, the jib
begins to rotate with constant angubc
0
lar velocity ω, and the trolley on the
jib begins to move towards point 0
with constant relative acceleration bc
ω
(Fig. 6.16). The initial positions of the
b0
jib and of the trolley are given by ϕ0
and s0 .
bc
s
Determine the absolute velocity and
the absolute acceleration of the trolley
ϕ
as functions of the time t.
b0
1111111
0000000
Fig. 6.16
Solution We use the fixed coordinate system x, y, z, where the
x-axis coincides with the track. In addition, we introduce the rotating coor- y
dinate system ξ, η, ζ, where the ξ-axis
rotates with the jib. Then, the general equations for the absolute velocity z
and the absolute acceleration are
η
ω
0
P
r 0P
ξ
ϕ
ζ
x
v = v 0 + ω × r0P + v r ,
a = a0 + ω̇ × r 0P + ω × (ω × r 0P ) + 2 ω × v r + ar .
We measure the time t from the beginning of the motion. Then,
making use of the given accelerations, angular velocity and initial
conditions, we obtain
a 0 = b 0 ex
ω = ωeζ ,
ar = −bc eξ
→
v 0 = b 0 t ex ,
ω̇ = 0 ,
→
v r = −bc t eξ
→
r 0P = (− 21 bc t2 + s0 )eξ ,
and
ω × r 0P = ω(− 21 bc t2 + s0 )eη ,
Gr
ω × (ω × r0P ) = −ω
2
(− 12 bc t2
2 ω × v r = −2 ω bc t eη ,
+ s0 )eξ .
179
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mi
cs e
6 Non-Inertial Reference Frames
With the relation ex = eξ cos ϕ − eη sin ϕ, where ϕ = ϕ0 + ω t, we
finally obtain
v = [b0 t cos ϕ − bc t]eξ + [−b0 t sin ϕ + ω(− 21 bc t2 + s0 )]eη ,
Gr
a = [b0 cos ϕ − ω 2 (− 12 bc t2 + s0 ) − bc ]eξ − [b0 sin ϕ + 2 ω bc t]eη .