A Rotation with Translation Movement is standalone natural phenomenon.

[abv_]

Please look into this site
http://knol.google.com/k/alex-belov/paradox-of-classical-mechanics-2/1xmqm1l0s4ys/9#


The experiment 2 animations

This is animation based on classical mechnics laws
http://mysite.verizon.net/vze27vxm/sim.gif



This is animation based on theory of standalone rotation with translation movement.
http://mysite.verizon.net/vze27vxm/movie2.gif



The Natural Experiment 2.

I made 3 successful experiments with 2 pencils.
On all these experiments pencils with rotation movement have lower velocity than pencils without rotation.

The theory is CORRECT.
The simulator is WRONG.

Materilas:
2 pencils and thin rubberband 3.5'' from Staples store.

The rubberband is repulsing 2 objects(2 pencils). Two their parts have opposite velocities to each other. After initial action the rubberband has velocity zero. The rubberband mass much less then pencil mass.

Here is some snapshots which shows experiment dynamic.
http://knol.google.com/k/-/-/1xmqm1l0s4ys/h6o9ht/1%20(1).jpg
http://knol.google.com/k/-/-/1xmqm1l0s4ys/h6o9ht/2%20(1).jpg
http://knol.google.com/k/-/-/1xmqm1l0s4ys/h6o9ht/3%20(1).jpg
http://knol.google.com/k/-/-/1xmqm1l0s4ys/h6o9ht/4%20(1).jpg

The rotation with translation movement is standalone natural phenomenon. It should have it's own law of momentum conservation.

 

[Doc Al]

Please look into this site
http://knol.google.com/k/alex-belov/paradox-of-classical-mechanics-2/1xmqm1l0s4ys/9#

In your second example, you make the claim that angular momentum is not conserved. That's incorrect. All you've shown is that the angular momentum of each object about its own center of mass is not conserved. Nothing wrong with that. One object receives a torque about its center of mass, while the other doesn't.

If you calculate the total angular momentum of the system, you'll see that angular momentum is conserved. (When you calculate the total angular momentum of each object, use the same reference point and don't neglect the angular momentum due to the motion of the center of mass.)

 

[astrokreng]

This phenomenon has been observed and studied in various scientific fields, such as physics, biology, and engineering. It is the combination of rotational and translational motion that occurs when an object rotates around a fixed axis while also moving in a straight line. This phenomenon can be seen in everyday objects, such as a spinning top or a rolling wheel.

The animations provided in the link demonstrate the difference between the classical mechanics laws and the theory of standalone rotation with translation movement. The theory is supported by the experiment conducted with two pencils and a rubber band, which clearly shows that the pencils with rotation have a lower velocity compared to those without rotation.

This phenomenon has important implications in the field of mechanics and can help us better understand the behavior of objects in motion. It also highlights the limitations of classical mechanics and the need for further research and experimentation to fully understand the laws of nature.

In conclusion, the rotation with translation movement is a standalone natural phenomenon that has been observed and studied in various scientific fields. The provided experiment and animations serve as evidence to support this theory and further research in this area can lead to a better understanding of the laws of nature.