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Aug 9, 2007 10/3/2007 Newer edition added to the collection. BL1900 .L3 B6 2/14/2008 Replaced by a newer textbook; not used since 1996 Engineering mechanics: statics. Hilbbeler, R.C. Hibbeler, Russell C. Prentice Hall?
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Mechanical Engineering Technology. Version 11/21/2014. 1 - P a g e PHYS 201 Statics / PHYS 320 Classical. Mechanics. 1.4 Credits. 3 1.9 Textbook. Russell C. Hibbeler, Mechanics of Materials. (9th Edition) Pearson Education stress concentrations, inelastic
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A spring is stretched 175 mm by an 8-kg block. If the block is displaced 100 mm downward from its equilibr ium position and given a downward downward velocity of 1.50 m > s, determine the differential equation which describes the motion. Assume that positive displacement is downward. Also, determine the position of the block when t = 0.22 s.
SO LUT ION + T Σ F = ma ; y
mg
k ( y y + y ) =
-
y
st
$
k
y +
Hence
p =
=
k
$
my
m
= mg st
y = 0
Where k =
Bm
where ky
8(9.81) = 448.46 N > m 0.175
448.46 = 7.487 B 8 $
$
y + (7.487)2 y = 0
6
y + 56.1 y = 0
Ans.
The solution of the above differen tial equatio equation n is of the form: y = A sin pt + B cos pt #
v = y = Ap cos pt
(1)
- Bp
sin pt
(2)
At t = 0, y = 0.1 m and v = v0 = 1.50 m > s From Eq. (1)
0 .1 =
A
sin 0 + B cos 0
v0 1.50 = = 0.2003 m p 7.487
From Eq. (2)
v0 = Ap cos 0
Hence
y = 0.2003 sin 7.487t + 0.1 cos 7.487t
At t = 0.22 s,
y = 0.2003 sin [7.487(0.22)] + 0.1 cos [7.487(0.22)]
= 0.192 m
-
0
B = 0.1 m A =
Ans.
Ans: $ y + 56.1 y = 0 y 0 t = 0.22 s = 0.192 m 1190
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22 – 2. 2.
A spring has a stiffness of 800 N > m. If a 2-kg block is br ium attached to the spring, pushed 50 mm above its equili br position, and released from rest, determine the equation that describes the block ’s motion. Assume that positive displacement is downward.
SO LUT ION k
p =
Am
=
800 = 20 A 2
x = A sin pt + B cos pt x =
- 0.05
- 0.05
m
when t = 0,
= 0 + B;
v = Ap cos pt
- Bp
B =
- 0.05
sin pt
v = 0 when t = 0, 0 = A(20)
-
0;
A
= 0
Thus, x =
- 0.05
cos (20t )
Ans.
Ans: x = - 0.05 cos (20t )
1191
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22 – 3. 3.
A spring is stretched 200 mm by a 15-kg block. If the block is displaced 100 mm downward from its it s equili br br ium position
and given a downward
velocity of 0.75 m> s,
determine the equation which describes the motion. What is the phase angle? Assume that positive displacement is downward.
SOLUTION k =
F
y
=
15(9.81) = 735.75 N> m 0.2
k vn =
Am
=
735.75 = 7.00 A 15
y = A sin v n t + B cos v n t y = 0.1 m when t = 0, 0.1 = 0 + B; v = A v n cos vn t
B = 0.1 -
Bvn sin vn t
v = 0.75 m> s when t = 0,
0.75 = A(7.00) A = 0.107 y = 0.107 sin (7.00t) + 0.100 ccos os (7.00 t) f
= tan - 1 a
B 0.100 b = tan - 1 a b = 43.0° A
Ans. Ans.
0.107
Ans: y = 0.107 sin (7.00 (7.00 t ) + 0.100 cos (7.00 t ) f
= 43.0°
1192
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*22 – 4. 4.
When a 20-lb weight weight is suspended from a spring, the spring spr ing is stretched a distance of 4 in. Determine the natural frequency and the period of vibrati vibration on for a 10-lb weigh t attached to the same spring.
S O LUT IO N k =
20 12
vn =
t
=
4
= 60 lb> ft
60 k = 13.90 rad > s = 10 A 32.2 Am
Ans.
2p = 0.452 s vn
Ans.
Ans: vn = 13.90 rad > s t = 0.452 s
1193
22 – 5. 5.
When a 3-kg block is suspended from a spring, the spring is of 60 mm. Determine the natural stretched a distance frequency and the period of vibratio n for a 0.2-kg block attached to the same spring.
S O LUT IO N k =
vn =
f
=
t
=
3(9.81) F = = 490.5 N> m ¢x 0.060
490.5 k = 49.52 = 49.5 rad > s = m A A 0.2
Ans.
vn 49.52 = 7.88 Hz = 2p 2p 1 f
=
1 = 0.127 s 7.88
Ans.
Ans: vn = 49.5 rad > s t = 0.127 s
1194
22 – 6. 6.
An 8-kg block is suspen suspended ded from a spring having h aving a stiffness k = 80 N> m. If the block is given an upward velocity of 0.4 m> s when when it is 90 mm above its equilibrium position, motion and the determine the equation which describes the motion maximum upward displacement of the block measured from the equilibriu m position. Assume that positive displacement is measured downward.
S O LUT IO N vn =
80 k = A 8 = 3.162 rad > s Am 0.4 m> s,
x
y =
- 0.09
m at t
= = 0 -
Ans: vn = 19.7 rad > s C = 1 in. y = (0.0833 cos 19.7t ) f t
*22 – 8. 8.
A 6-lb weight weight is suspended from a spring having a stiffness b> in. If the weight is given an upward k = 3 l b upward velocity of 20 ft> s when it is 2 in. above its equilibrium position, determine the equation which describes the motion and the maximum upward displacement of the weight, measured from the equilibrium position. Assume positive displacement is downward.
S O LUT IO N k = 3(12) = 36 lb> ft 36 k vn = = 13.90 rad > s = 6 A Am 32.2
t = 0,
y =
- 20
ft> s,
y = -
1 ft 6
From Eq. 22 – 3, 3, -
1 = 0 + B 6
B =
- 0.167
From Eq. 22 – 4, 4, - 20
= A(13.90) + 0
A =
- 1.44
Thus,
y = [ - 1.44 sin (13.9t)
-
0.167 cos (13.9t)] ft
Ans.
From Eq. 22 – 10, 10, C =
2
2A
+ B2 =
2
2 (1.44)
+ ( - 0.167)2 = 1.45 ft
Ans.
Ans: y = [ - 1.44 sin (13.9t ) C = 1.45 f t 1197
-
0.167 cos (13.9 t )] )] f t
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22 – 9. 9.
A 3-kg block is suspend ed from a spring having a stiffn ess of k = 200 N> m. If the block is pushed 50 mm upward from its equilibriu m position posit ion and then released from rest, determine the equation that describes the motion. What are the amplitude and the frequency of the vibration? Assume that positive displacement is downward.
SOLUTIO N vn =
k
200 = 8.16 rad >s A 3
=
Am
Ans.
x = A sin v n t + B cos vn t x =
- 0.05
m when t = 0,
- 0.05
= 0 + B; v = Ap cos vn t
B = - 0.05 - Bv n sin vn t
v = 0 when t = 0,
0 = A(8.165)
-
0;
A = 0
Hence,
x = C =
2
2A
+ B2 =
- 0.05 2
2 (0)
cos (8.16 t)
Ans.
+ ( - 0.05) = 0.05 m = 50 mm
Ans.
Ans: vn = 8.16 rad > s x = - 0.05 cos (8.16t ) C = 50 mm 1198
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22 – 10. 10.
The uniform rod of mass m is supported by a pin at A and a spring at B. If B is given a small sideward displacement and released, determine the natural period of vibr ation. ation.
A
L
Solution Equation of Motio n. The mass moment of inertia of the rod about A is I A =
a + Σ M A
However;
= I a ;
- mg
A
a
sin u b
-
mL 2.
3
Referring to the FBD. of the rod, Fig. a, L
1
B
1
k
(kx cos u)( L L) = a mL 2 b a
2
3
x = L sin u. Then - mg L
sin u
2
-
1 2 mL a 3
kL 2 sin u cos u =
Using the trigonometry identity sin 2u = 2 sin u cos u, 2
- mg L
sin u
2
1
KL -
2
sin 2u =
3
2
mL a
$ Here since u is small sin u equation becomes
u and sin 2u
mg L 1 2 $ mL u + a + 3 2
2u. Also a = u . Then the above
2
kL b u
= 0
$ L 3mg + 6k u + u = 0 2m L Comparing to that of the Standard form, vn =
t
=
2p vn
= 2 p
L 3mg + 6k . Then 2m L A
2m L A 3mg + 6kL
Ans.
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Ans:
2m L t
= 2 p
L A 3mg + 6k
1199
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22 – 11. 11. While standing in an elevator, the man holds a pen pendu dulum which consists of an 18-in. cord cord and a 0.5-lb bob. bob. If the elevator is descending with an an acceleration a = 4 f t> s2, determine the natural period of vibration for small amplitudes of swing. a
4 f t/s2
S O LUT IO N Since the acceleration of the pendulum is (32.2
-
4) = 28.2 ft> s2
Using the result of Example 22 – 1, 1, We have vn =
t
=
g Al 2p vn
=
=
28.2 = 4.336 rad > s A 18 > 12 2p = 1.45 s 4.336
Ans.
Ans: t = 1.45 s 1200
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*22 – 12. 12. Determine the natural period of vibration of the uniform bar of mass m when it is displaced downward slightly and released.
O
k L —
L —
2
2
Solution Equation of Motion . The mass moment of inertia of the bar about O is I 0 =
1 mL 2. 12
Referring to the FBD of the rod, Fig. a, a + Σ M 0
= I a ;
- ky
L
1
2
12
cos u a
0
However, y =
L
2
b = a
sin u. Then L
-k
mL 2 b a
a
2
1
L
sin u b cos u a
2
b =
12
2
mL a
Using the trigonometry identity sin 2u = 2 sin u cos u, we obtain 1 mL2a + 12
2
L k
8
sin 2u = 0
Here since u is small, sin 2u 12 12
2u. Also, a = u . Then the above equ ation becomes
$kL 2
mL u +
4
u = 0
$ 3k u + u = 0 m Comparing to that of the Standard form, vn =
t
=
2p vn
= 2 p
m A 3k
3k . Then Am Ans.
Ans: t
= 2 p
m A 3 k
1201
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22 – 13. 13.
The body of arbitrary shape has a mass m, mass center at G, and a radius of gyration about G of k G. If it is displaced a slight amount u from its equilibriu m position and released, determine the natural period of vibration.
O
d u G
SOLUTION a +
©M O = IO a;
- mgd
$ u +
$ 2 2 + md Du sin u = C mk G gd 2
2
k
G
sin u = 0
+ d
However, for small rotation sin u L u. Hence $ gd u + 2 u = 0 2 k G + d gd
From the above differential equation, vn = t
=
2p vn
=
2p gd
B k 2G + d 2
= 2 p
.
2 k G + d 2 C gd
Ans.
A k G2 + d 2
Ans: t
= 2 p C
k 2G + d 2 gd
1202
22 – 14. 14.
The 20-lb rectangul ar plate has a natural period of vibration t = 0.3 s, as it oscillates around the axis of rod AB. ad, Determine the torsional stiffness k , measured in lb ft > r ad, of the rod. Neglect the mass of the rod.
A
k B
Solution T =
k u
1 Σ M z
= I za ;
- k u
=
20
2
4 ft
$
a b (2) u 12 32.2
$ u + k (4.83)u (4.83)u = 0 2 ft t
=
2p 2k (4.83 )
= 0.3
k = 90.8 lb # ft > rad
Ans.
Ans: k = 90.8 lb # ft > rad
Engineering Mechanics Statics and Dynamics 14th Edition Hibbeler
SOLUTIONS MANUAL Full download: https://testbanklive.com/download/engineering-m https://testbanklive.com/d ownload/engineering-mechanics-statics-andechanics-statics-anddynamics14th-edition-hibbeler-solutions-manual/ People also search: engineering mechanics statics & dynamics (14th edition) pdf engineering mechanics statics and dynamics 14th edition solutions statics and dynamics 13th edition statics and dynamics 14th edition chegg engineering mechanics: statics & dynamics pdf statics and dynamics hibbeler pdf engineering mechanics statics and dynamics hibbeler pdf engineering mechanics statics and dynamics 14th edition pdf free download
SOLUTIONS MANUAL People also search: https://testbanklive.com/do https://testbankliv e.com/download/engineering-m wnload/engineering-mechanics-statics-and-dynam echanics-statics-and-dynamicsics14th-edition-hibbeler-solutions-manual/ 22 – 1. 1.
A spring is stretched 175 mm by an 8-kg block. If the block is displaced 100 mm downward from its equilibr ium position and given a downward downward velocity of 1.50 m > s, determine the differential equation which describes the motion. Assume that positive displacement is downward. Also, determine the position of the block when t = 0.22 s.
SO LUT ION + T Σ F = ma ; y
mg
k ( y y + y ) =
-
y
st
$
k
y +
Hence
p =
=
k
$
my
m
= mg st
y = 0
Where k =
Bm
where ky
8(9.81) = 448.46 N > m 0.175
448.46 = 7.487 B 8 $
$
y + (7.487)2 y = 0
6
y + 56.1 y = 0
Ans.
The solution of the above differen tial equatio equation n is of the form: y = A sin pt + B cos pt #
v = y = Ap cos pt
(1)
- Bp
sin pt
(2)
At t = 0, y = 0.1 m and v = v0 = 1.50 m > s From Eq. (1)
0 .1 =
A
sin 0 + B cos 0
v0 1.50 = = 0.2003 m p 7.487
From Eq. (2)
v0 = Ap cos 0
Hence
y = 0.2003 sin 7.487t + 0.1 cos 7.487t
At t = 0.22 s,
y = 0.2003 sin [7.487(0.22)] + 0.1 cos [7.487(0.22)]
= 0.192 m
-
0
B = 0.1 m A =
Ans.
Ans: $ y + 56.1 y = 0 y 0 t = 0.22 s = 0.192 m 1190
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22 – 2. 2.
A spring has a stiffness of 800 N > m. If a 2-kg block is br ium attached to the spring, pushed 50 mm above its equili br position, and released from rest, determine the equation that describes the block ’s motion. Assume that positive displacement is downward.
SO LUT ION k
p =
Am
=
800 = 20 A 2
x = A sin pt + B cos pt x =
- 0.05
- 0.05
m
when t = 0,
= 0 + B;
v = Ap cos pt
- Bp
B =
- 0.05
sin pt
v = 0 when t = 0, 0 = A(20)
-
0;
A
= 0
Thus, x =
- 0.05
cos (20t )
Ans.
Ans: x = - 0.05 cos (20t )
1191
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22 – 3. 3.
A spring is stretched 200 mm by a 15-kg block. If the block is displaced 100 mm downward from its it s equili br br ium position
and given a downward
velocity of 0.75 m> s,
determine the equation which describes the motion. What is the phase angle? Assume that positive displacement is downward.
SOLUTION k =
F
y
=
15(9.81) = 735.75 N> m 0.2
k vn =
Am
=
735.75 = 7.00 A 15
y = A sin v n t + B cos v n t y = 0.1 m when t = 0, 0.1 = 0 + B; v = A v n cos vn t
B = 0.1 -
Bvn sin vn t
v = 0.75 m> s when t = 0,
0.75 = A(7.00) A = 0.107 y = 0.107 sin (7.00t) + 0.100 ccos os (7.00 t) f
= tan - 1 a
B 0.100 b = tan - 1 a b = 43.0° A
Ans. Ans.
0.107
Ans: y = 0.107 sin (7.00 (7.00 t ) + 0.100 cos (7.00 t ) f
= 43.0°
1192
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*22 – 4. 4.
When a 20-lb weight weight is suspended from a spring, the spring spr ing is stretched a distance of 4 in. Determine the natural frequency and the period of vibrati vibration on for a 10-lb weigh t attached to the same spring.
S O LUT IO N k =
20 12
vn =
t
=
4
= 60 lb> ft
60 k = 13.90 rad > s = 10 A 32.2 Am
Ans.
2p = 0.452 s vn
Ans.
Ans: vn = 13.90 rad > s t = 0.452 s
1193
22 – 5. 5.
When a 3-kg block is suspended from a spring, the spring is of 60 mm. Determine the natural stretched a distance frequency and the period of vibratio n for a 0.2-kg block attached to the same spring.
S O LUT IO N k =
vn =
f
=
t
=
3(9.81) F = = 490.5 N> m ¢x 0.060
490.5 k = 49.52 = 49.5 rad > s = m A A 0.2
Ans.
vn 49.52 = 7.88 Hz = 2p 2p 1 f
=
1 = 0.127 s 7.88
Ans.
Ans: vn = 49.5 rad > s t = 0.127 s
1194
22 – 6. 6.
An 8-kg block is suspen suspended ded from a spring having h aving a stiffness k = 80 N> m. If the block is given an upward velocity of 0.4 m> s when when it is 90 mm above its equilibrium position, motion and the determine the equation which describes the motion maximum upward displacement of the block measured from the equilibriu m position. Assume that positive displacement is measured downward.
S O LUT IO N vn =
80 k = A 8 = 3.162 rad > s Am 0.4 m> s,
x
y =
- 0.09
m at t
= = 0 -
Ans: vn = 19.7 rad > s C = 1 in. y = (0.0833 cos 19.7t ) f t
*22 – 8. 8.
A 6-lb weight weight is suspended from a spring having a stiffness b> in. If the weight is given an upward k = 3 l b upward velocity of 20 ft> s when it is 2 in. above its equilibrium position, determine the equation which describes the motion and the maximum upward displacement of the weight, measured from the equilibrium position. Assume positive displacement is downward.
S O LUT IO N k = 3(12) = 36 lb> ft 36 k vn = = 13.90 rad > s = 6 A Am 32.2
t = 0,
y =
- 20
ft> s,
y = -
1 ft 6
From Eq. 22 – 3, 3, -
1 = 0 + B 6
B =
- 0.167
From Eq. 22 – 4, 4, - 20
= A(13.90) + 0
A =
- 1.44
Thus,
y = [ - 1.44 sin (13.9t)
-
0.167 cos (13.9t)] ft
Ans.
From Eq. 22 – 10, 10, C =
2
2A
+ B2 =
2
2 (1.44)
+ ( - 0.167)2 = 1.45 ft
Ans.
Ans: y = [ - 1.44 sin (13.9t ) C = 1.45 f t 1197
-
0.167 cos (13.9 t )] )] f t
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22 – 9. 9.
A 3-kg block is suspend ed from a spring having a stiffn ess of k = 200 N> m. If the block is pushed 50 mm upward from its equilibriu m position posit ion and then released from rest, determine the equation that describes the motion. What are the amplitude and the frequency of the vibration? Assume that positive displacement is downward.
SOLUTIO N vn =
k
200 = 8.16 rad >s A 3
=
Am
Ans.
x = A sin v n t + B cos vn t x =
- 0.05
m when t = 0,
- 0.05
= 0 + B; v = Ap cos vn t
B = - 0.05 - Bv n sin vn t
v = 0 when t = 0,
0 = A(8.165)
-
0;
A = 0
Hence,
x = C =
2
2A
+ B2 =
- 0.05 2
2 (0)
cos (8.16 t)
Ans.
+ ( - 0.05) = 0.05 m = 50 mm
Ans.
Ans: vn = 8.16 rad > s x = - 0.05 cos (8.16t ) C = 50 mm 1198
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22 – 10. 10.
The uniform rod of mass m is supported by a pin at A and a spring at B. If B is given a small sideward displacement and released, determine the natural period of vibr ation. ation.
A
L
Solution Equation of Motio n. The mass moment of inertia of the rod about A is I A =
a + Σ M A
However;
= I a ;
- mg
A
a
sin u b
-
mL 2.
3
Referring to the FBD. of the rod, Fig. a, L
1
B
1
k
(kx cos u)( L L) = a mL 2 b a
2
3
x = L sin u. Then - mg L
sin u
2
-
1 2 mL a 3
kL 2 sin u cos u =
Using the trigonometry identity sin 2u = 2 sin u cos u, 2
- mg L
sin u
2
1
KL -
2
sin 2u =
3
2
mL a
$ Here since u is small sin u equation becomes
u and sin 2u
mg L 1 2 $ mL u + a + 3 2
2u. Also a = u . Then the above
2
kL b u
= 0
$ L 3mg + 6k u + u = 0 2m L Comparing to that of the Standard form, vn =
t
=
2p vn
= 2 p
L 3mg + 6k . Then 2m L A
2m L A 3mg + 6kL
Ans.
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Ans:
2m L t
= 2 p
L A 3mg + 6k
1199
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22 – 11. 11. While standing in an elevator, the man holds a pen pendu dulum which consists of an 18-in. cord cord and a 0.5-lb bob. bob. If the elevator is descending with an an acceleration a = 4 f t> s2, determine the natural period of vibration for small amplitudes of swing. a
4 f t/s2
S O LUT IO N Since the acceleration of the pendulum is (32.2
-
4) = 28.2 ft> s2
Using the result of Example 22 – 1, 1, We have vn =
t
=
g Al 2p vn
=
=
28.2 = 4.336 rad > s A 18 > 12 2p = 1.45 s 4.336
Ans.
Ans: t = 1.45 s 1200
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*22 – 12. 12. Determine the natural period of vibration of the uniform bar of mass m when it is displaced downward slightly and released.
O
k L —
L —
2
2
Solution Equation of Motion . The mass moment of inertia of the bar about O is I 0 =
1 mL 2. 12
Referring to the FBD of the rod, Fig. a, a + Σ M 0
= I a ;
- ky
L
1
2
12
cos u a
0
However, y =
L
2
b = a
sin u. Then L
-k
mL 2 b a
a
2
1
L
sin u b cos u a
2
b =
12
2
mL a
Using the trigonometry identity sin 2u = 2 sin u cos u, we obtain 1 mL2a + 12
2
L k
8
sin 2u = 0
Here since u is small, sin 2u 12 12
2u. Also, a = u . Then the above equ ation becomes
$kL 2
mL u +
4
u = 0
$ 3k u + u = 0 m Comparing to that of the Standard form, vn =
t
=
2p vn
= 2 p
m A 3k
3k . Then Am Ans.
Ans: t
= 2 p
m A 3 k
1201
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22 – 13. 13.
The body of arbitrary shape has a mass m, mass center at G, and a radius of gyration about G of k G. If it is displaced a slight amount u from its equilibriu m position and released, determine the natural period of vibration.
O
d u G
SOLUTION a +
©M O = IO a;
- mgd
$ u +
$ 2 2 + md Du sin u = C mk G gd 2
2
k
G
sin u = 0
+ d
However, for small rotation sin u L u. Hence $ gd u + 2 u = 0 2 k G + d gd
From the above differential equation, vn = t
=
2p vn
=
2p gd
B k 2G + d 2
= 2 p
.
2 k G + d 2 C gd
Ans.
A k G2 + d 2
Ans: t
= 2 p C
k 2G + d 2 gd
1202
22 – 14. 14.
The 20-lb rectangul ar plate has a natural period of vibration t = 0.3 s, as it oscillates around the axis of rod AB. ad, Determine the torsional stiffness k , measured in lb ft > r ad, of the rod. Neglect the mass of the rod.
A
k B
Solution T =
k u
1 Σ M z
= I za ;
- k u
=
20
2
4 ft
$
a b (2) u 12 32.2
$ u + k (4.83)u (4.83)u = 0 2 ft t
=
2p 2k (4.83 )
= 0.3
k = 90.8 lb # ft > rad
Ans.
Ans: k = 90.8 lb # ft > rad
Engineering Mechanics Statics and Dynamics 14th Edition Hibbeler
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