Best Isolation HRS? SRA? Zoethecus? Symposium?

j-badov - The heavy mass used in Vibraplane is employed to lower the resonant freq. of the "mass on spring" system and has nothing whatsoever to do with inertia, as you suggested. System resonant frequency is a (strict) function of the Sq. Root of spring rate over the mass.

Thus, if vibraplane employed an even heavier mass, all things being equal, it would be an even better isolator. But not because of the reason you gave.

~ cheers

Something to keep in mind here are self induced internal resonaces generated by the electronics themselves as well as airborne resonance generated by the speakers and regenerated by the room. How is that isolated? Tom

Years ago I tried many shelves and stands. The Manas proved superior to all others. I did later find the Neuance shelves on the Mana stands were superior to the glass top shelf provided. Later I found the Acapella shelves to be better yet. Then came the Halcyonic active isolators. Under the universal player and my turntable, there is nothing even close. They are too expensive for me to use elsewhere, however. I will not even try them under my amp as I am afraid I would go broke.

theaudiotweak: in the case of our Promethean & Nimbus, we use selective frequency damping of the top plate to remove residual vibration due to seismic type, component-induced or airborne type. We also prefer the extremely hard dh (diamond hardness) cones for lightning-fast energy transfer between component & plate/damper.

Geoff Kait, Machina Dynamica

Geoffkait

Nice to know that four course on vibration I took in university can be boiled down to one easy sentence Geoff. It is far more complex in study than what you have stated. It has everything to do with inertia.

"The heavy mass used in Vibraplane is employed to lower the resonant freq. of the "mass on spring" system and has nothing whatsoever to do with inertia, as you suggested. System resonant frequency is a (strict) function of the Sq. Root of spring rate over the mass."

What you talk of is a simple machine, a text book example not a real world application. What you talk of is a single degree of freedom spring and mass system. It does not particularly apply. Yes, additonal mass will lower the resonant frequency of the platform but is not the sole or most important reason for the mass. You could simply damp, clamp and change the resonant frequency with out the mass. You have completely ignored Newton and Kinetics all in one foul swoop. How about your transmission ratios, harmonic ground motion, forced periodic motion etc.?

"Thus, if vibraplane employed an even heavier mass, all things being equal, it would be an even better isolator. But not because of the reason you gave."

Beg to differ here sir. A larger mass requires larger surface areas and will not necessarily translate to better isolation. It introduces another set of issues. It is a large reason as to why it operates the way it does. Mass limits movement the isolators decouple from the source of the vibration. It is similar in operation to an inertia base under large rotating pieces of equipment, conversly though they are trying to limit the vibration transmitted into a building. Mass is key in keeping things in place and limiting both movement and transmission of vibration.