A wooden block mass 15kg has its core 10cm. find the density in both system.
Answers
Answer:
By the end of this section, you will be able to:
Use the work-energy theorem to analyze rotation to find the work done on a system when it is rotated about a fixed axis for a finite angular displacement
Solve for the angular velocity of a rotating rigid body using the work-energy theorem
Find the power delivered to a rotating rigid body given the applied torque and angular velocity
Summarize the rotational variables and equations and relate them to their translational counterparts
Thus far in the chapter, we have extensively addressed kinematics and dynamics for rotating rigid bodies around a fixed axis. In this final section, we define work and power within the context of rotation about a fixed axis, which has applications to both physics and engineering. The discussion of work and power makes our treatment of rotational motion almost complete, with the exception of rolling motion and angular momentum, which are discussed in Angular Momentum. We begin this section with a treatment of the work-energy theorem for rotation.
Work for Rotational Motion
Now that we have determined how to calculate kinetic energy for rotating rigid bodies, we can proceed with a discussion of the work done on a rigid body rotating about a fixed axis. (Figure) shows a rigid body that has rotated through an angle
\[d\theta\]
from A to B while under the influence of a force
\[\overset{\to }{F}\]
. The external force
\[\overset{\to }{F}\]
is applied to point P, whose position is
\[\overset{\to }{r}\]
, and the rigid body is constrained to rotate about a fixed axis that is perpendicular to the page and passes through O. The rotational axis is fixed, so the vector
\[\overset{\to }{r}\]
moves in a circle of radius r, and the vector
\[d\overset{\to }{s}\]
is perpendicular to
\[\overset{\to }{r}.\]
Figure shows the rigid body is constrained to rotate about a fixed axis that is perpendicular to the page and passes through a point labeled as O. The rotational axis is fixed, so the vector r moves in a circle of radius r, and the vector ds is perpendicular to vector r. An external force F is applied to point P and makes rigid body rotates through an angle dtheta.
Figure 10.39 A rigid body rotates through an angle
\[d\theta\]
from A to B by the action of an external force
\[\overset{\to }{F}\]
applied to point P.
From (Figure), we have
\[\overset{\to }{s}=\overset{\to }{\theta }\,×\,\overset{\to }{r}.\]
Thus,
\[d\overset{\to }{s}=d(\overset{\to }{\theta }\,×\,\overset{\to }{r})=d\overset{\to }{\theta }\,×\,\overset{\to }{r}+d\overset{\to }{r}\,×\,\overset{\to }{\theta }=d\overset{\to }{\theta }\,×\,\overset{\to }{r}.\]
Note that
\[d\overset{\to }{r}\]
is zero because
\[\overset{\to }{r}\]
is fixed on the rigid body from the origin O to point P. Using the definition of work, we obtain
\[W=\int \sum \overset{\to }{F}·d\overset{\to }{s}=\int \sum \overset{\to }{F}·(d\overset{\to }{\theta }\,×\,\overset{\to }{r})=\int d\overset{\to }{\theta }·(\overset{\to }{r}\,×\,\sum \overset{\to }{F})\]