5. In the figure, two masses, M = m = 12.8.0 kg, are connected to a very light rigid bar and are attached to an ideal massless spring of spring constant 100 N/m. The system is set into 16 kg and %3D

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2
4TC
m
Hence,
r- -
2n,
3
3 V k
INTEXT EXERCISE: 3
al masses are suspended
f spring constants k, and
ate with equal maximum
Mand N are in the ratio
k mg
k m2g
(b)
m2
k
my
k
k
k(m, + m2) mg
(c)
V m + m2
(d)
k
2m, m2
k
Aiw, - AnWz
WL5. In the figure, two masses, M = 16 kg and
WI JRim = 12.8.0 kg, are connected to a very light rigid
%3D
tely from two springs
.. Their time periods
pectively. If the same
vo springs connected
combination will be
bar and are attached to an ideal massless spring of
spring constant 100 N/m. The system is set into
oscillation with an amplitude of 78 cm. At the instant
when the acceleration is at its maximum, the 16 kg
+T2
mass separates from the 12.8.0 kg mass, which then
remains attached to the spring and continues to
oscillate. What will be the amplitude of oscillation
+T;
25
of the 12.8.0 kg mass?
table is connected
th spring constants
e fixed to walls, as
(а) 78 cm
(b) 62 cm
(c) 35 cm
(d) 98 cm
gular frequency of
dk, 5.0 N/m?
6. A 2.00 kg object is attached to an ideal massless
%3D
Transcribed Image Text:2 4TC m Hence, r- - 2n, 3 3 V k INTEXT EXERCISE: 3 al masses are suspended f spring constants k, and ate with equal maximum Mand N are in the ratio k mg k m2g (b) m2 k my k k k(m, + m2) mg (c) V m + m2 (d) k 2m, m2 k Aiw, - AnWz WL5. In the figure, two masses, M = 16 kg and WI JRim = 12.8.0 kg, are connected to a very light rigid %3D tely from two springs .. Their time periods pectively. If the same vo springs connected combination will be bar and are attached to an ideal massless spring of spring constant 100 N/m. The system is set into oscillation with an amplitude of 78 cm. At the instant when the acceleration is at its maximum, the 16 kg +T2 mass separates from the 12.8.0 kg mass, which then remains attached to the spring and continues to oscillate. What will be the amplitude of oscillation +T; 25 of the 12.8.0 kg mass? table is connected th spring constants e fixed to walls, as (а) 78 cm (b) 62 cm (c) 35 cm (d) 98 cm gular frequency of dk, 5.0 N/m? 6. A 2.00 kg object is attached to an ideal massless %3D
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