Dear Kirkus, I know that these were not your motivations - I just wanted to set some points clear as the turntable sure looks like a "mammoth" in the picture and thus the above mentioned suspect might easily arise. But - thank you.
As for the string - just briefly and preliminary, as I have to leave the computer soon:
The basic idea / principle is to have a homogenous mass put into constant rotation and then let the inertia do the job. The string in its kind of "slip-coupling" (which is kind of tricky to set-up and needs a calbrated spring gauge to ensure the perfect "non-grip") does have only one job (after bringing the platter on constant speed once):
- prevent the platter from getting slower.
All I can say - and this time I just plain ask you to take my words for granted - is: it works extremely well. We made long period measurements in MTU in 1992 and the derivation from 33 1/3 was (short-period as well as long-period derivation measurements) as close to zero as possible (measurements were taken with laser beam and calibrated circular stroboscope foil).
And - yes, the measurements were made while stylus was in the groove.
This is a huge inertia (the platter is 326 mm in total diameter - 108 lbs) in motion.
Once in motion on the desired speed, there are no derivations. The air resistance, the bearing friction (...the stylus drag..) these are all constants and thus the rotation stays constant.
It however takes about 2:35 minutes to reach constant speed........
The string just have to be dyneema or kevlar derivate and the coupling has to be precise.
But it works marvelous and watching it work, you get a certain "feel" of "completeness" and "natural move".
Audio phrases......
Time to get off.
Good night for now.
As for the string - just briefly and preliminary, as I have to leave the computer soon:
The basic idea / principle is to have a homogenous mass put into constant rotation and then let the inertia do the job. The string in its kind of "slip-coupling" (which is kind of tricky to set-up and needs a calbrated spring gauge to ensure the perfect "non-grip") does have only one job (after bringing the platter on constant speed once):
- prevent the platter from getting slower.
All I can say - and this time I just plain ask you to take my words for granted - is: it works extremely well. We made long period measurements in MTU in 1992 and the derivation from 33 1/3 was (short-period as well as long-period derivation measurements) as close to zero as possible (measurements were taken with laser beam and calibrated circular stroboscope foil).
And - yes, the measurements were made while stylus was in the groove.
This is a huge inertia (the platter is 326 mm in total diameter - 108 lbs) in motion.
Once in motion on the desired speed, there are no derivations. The air resistance, the bearing friction (...the stylus drag..) these are all constants and thus the rotation stays constant.
It however takes about 2:35 minutes to reach constant speed........
The string just have to be dyneema or kevlar derivate and the coupling has to be precise.
But it works marvelous and watching it work, you get a certain "feel" of "completeness" and "natural move".
Audio phrases......
Time to get off.
Good night for now.
