Being and 'old wife' is really nothing to be ashamed of. I have been one myself on numerous occasions. But as with alcoholism I tell myself, admission is the first step to recovery! So anyway, back to CN versus C3 debate and what is the basis of my brazen statements .....
1)Deep groove / Conrad type ball brgs made by good manufacturers generally have bore and OD tolerances at the middle of the tolerance band (+/- a couple of microns). There is a little more 'spread' on the RIC but even this wont reach anywhere near 'catalogue' limits.
2)The processes used to make shafts and housings are by no means as well controlled as brgs, but the likelihood of a single machine taken in for repair having both shaft and housing features on a 'max metal' condition is quite remote.
3)normal surface quality on shafts and particularly housings means that, during the brg fitting process, significant amounts of the theoretical interference is lost.
4)Machines which have been in service will often exhibit additional wear/smoothing of the seating surfaces.
5)Even in a brg that is 'theoretically tight' after installation, normal elastic characteristics mean that when an external load is applied, a clearance zone is re-created within the brg.
6)In my experience, assumed shaft~hsg temperature differentials of often exagerated for safety due to the difficulty in attempting to predict or measure them.
Ok these are just general points which may or may not be applicable in every case. But certainly not taking into account the 'real' dimensions of the parts when doing fit calcs can be misleading.
The one issue I haven't addressed yet is the conditions required for 'thermal runaway' and my statement that 'a few microns' will not cause trouble. This is probably because I dont really understand the situation myself!!! But it is the case that 'moderate' speeds and 'moderate' negative clearances in ball brgs can and do work successfully. If they didn't, lots of other things wouldnt work either. Take machine tool spindles. These are often fitted up with pairs of angular contact brgs clamped together in an axially preloaded condition. From the rolling elements point of view, they cant tell the difference between an axial or radial preload, a zero or 15 deg contact angle. All they know is that they are trapped tightly between raceways. After startup, temperature differentials develop across the brg and things, theoretically at least, should go from bad to worse....except that it doesnt !
In the automotive world, there are lots of applications where conventional theory has been ignored without disasterous consequences. Some alternators for example, incorporate C2 clearance brgs(ie less than normal) heavily interference fitted into aluminium housings (to make sure that they dont become loose at 100 degs C). According to the theory, this arrangement shouldn't work either, but is does do, even when you freeze them down to -40C !
Im not suggesting that 'thermal runaways' never happen, just that they dont happen as frequently as the world would generally predict. I remain convinced that provided nothing dodgy happens on the lubrication side, Smaty will get away with fitting a CN. He'll probably also find that his pump becomes smoother and quieter than its ever been!
Gerry
