hackhard said:
why shu[ol]d energy be conserved after all?
Because that's the Law for any isolated system.
If Energy is not conserved, then the system is not isolated.
Note: kinetic energy is not the only form of energy.
consider an inertial frame A
consider an isolated wheel rotating about an imaginary axis(axis is fixed wrt frame A) thru centre of mass .
now if rotational inertia is increased (somehow by causes internal to the wheel)
Somehow? ...
Sure - the energy stored in the spin is ##E=\frac{1}{2}I\omega^2## and angular momentum is ##L=I\omega## so ##E=\frac{1}{2}L\omega = L^2/2I##
If the wheel starts with ##I_0## and ends with ##I_1 > I_0##, "somehow" ...
Then the change in energy is ##E_1-E_0=\frac{1}{2}L^2\big(I_1^{-1} - I_0^{-1} \big)##
... since ##I_0<I_1## this is a net loss of energy. What happened to it? Where did it go?
[If the moment of inertia had
decreased "somehow", then you would get a net gain in energy ... if this did not come from anywhere then you could could use the effect to build a free-energy machine so: where would that energy come from?]
By the work-energy principle, the wheel has done some work on something...
http://hyperphysics.phy-astr.gsu.edu/hbase/rotwe.html
This would be the situation experienced by an ice-skater initially spinning fast with arms held close in, then opening her arms out.
If she wanted to pull her arms in, she would have to do work (comes from chemical energy in muscles).
So where does the energy go when she let's her arms out?
http://physics.stackexchange.com/qu...-figure-skaters-energy-go-when-she-slows-down
Note: what I was doing in post #7 was trying to figure out what you were talking about: so each section takes an interpretation of the description in post #1.