Download November 18

Notes
• Schedule this week:
– Office hours on Monday, 4-6pm, Tues, 2-5pm
• Normal Help Sessions this week
• Exam(s): Will cover up to and including Section 10.6
– Tuesday morning for those in Calc III:
• DBRT 126, 7:45 am start
• Review Session Tonight, 7-9pm, Hayes-Healy 127
– Thursday morning for everyone else:
• Hesburgh Library Auditorium, 7:45 am start
• Review Session Wed, 7:15-9:15pm, Hayes-Healy 128
A wheel has eight spokes and a radius of 30 cm. It is mounted on
a fixed axle and is spinning at 2.5 rev/s. You want to shoot a 24cm arrow parallel to this axle and through the wheel without
hitting any of the spokes.
spokes Assume that the arrow and the spokes
are very thin.
(a) What minimum speed must the arrow have to pass through
without contact?
(b) Does
oes itt matter
atte w
where
e e you aaim tthee aarrow
ow betwee
between tthee aaxlee and
a d
the rim? If so, where is the best location? Why?
At some point during its motion, a certain wheel turns through 90
rev in 15 s; its angular speed is 10 rev/s at the end of this period.
(a) What was the angular speed of the wheel at the beginning of
th 15 s time
the
ti interval,
i t
l assuming
i constant
t t angular
l acceleration?
l ti ?
(b) How much time had elapsed between the time the wheel was
at rest and the beginning of the 15 s interval?
A gyroscope flywheel of radius 2.83 cm is accelerated from rest
at 14.2 rad/s2 until its angular speed is 2760 rev/min.
(a) What is the tangential acceleration of a point on the rim of the
fl h l?
flywheel?
(b) What is the radial acceleration of this point when the wheel is
spinning at full speed?
(c) Through what distance does a point on the rim move during
the acceleration?
A force F is applied to a dumbbell for a time interval t,
first as in (a) and then as in (b). In which case does the
dumbbell acquire the greater center-of-mass speed?
1. (a)
2. (b)
3. no difference
4. The answer depends
on the rotational inertia
of the dumbbell.
Calculating Moments of Inertia:
A set of four atoms are bound into a square with sides of length a.
If a constant torque is applied to one of the masses so that the
system will rotate about the axes shown, which of the following
configurations will have the largest angular acceleration?
A constant tangential force is applied to one of atoms in
configurations a) and b), below, forcing the square to spin about
the axes shown.
The angular acceleration of square b) is
1.) half
2.) the same as
3.) twice
4.) four times
that of square a).
Calculate the moment of inertia of a hoop of radius R
and mass M about an axis passing through the center of
the hoop and perpendicular to the plane of the hoop.
R
Calculate the moment of inertia of a disk of radius R
and mass M about an axis passing through the center of
the disk and perpendicular to the plane of the disk.
R
Two identical solid spheres of mass M and radius R are joined
together, and the combination is rotated about an axis tangent to
one sphere and perpendicular to the line connecting them. What
is the moment of inertia of the combination? (Inertia Table says
Isphere = 2/5MR2 about any diameter.)
Now, onto Dynamics:
A constant force F pulls a string attached to the rim of a disk of
radius R and mass M which is free to spin on an axis through its
center. Find the angular acceleration, velocity, and position as a
function of time, assuming the disk starts from rest.
A cylinder of radius R and mass M has a string wrapped around
it. It is released from rest, and the string is pulled upward so that
the center of mass of the cylinder does not move. Find a) the
tension in the string and b) the angular acceleration of the
cylinder.
T
R
Same problem, except that now the string is held fixed and the
cylinder falls. Find the tension in the string and the linear
acceleration of the center of mass.
T
R