Electrical generator or motor structure – Dynamoelectric – Rotary
Reexamination Certificate
2001-01-10
2004-03-23
Le, Dang (Department: 2834)
Electrical generator or motor structure
Dynamoelectric
Rotary
C310S272000, C310S036000, C384S049000, C384S208000, C384S492000
Reexamination Certificate
active
06710487
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Technical Field of the Invention
This invention relates to high precision rotary components with matched expansion ceramic bearings for use in electronic devices, and in particular, to partial rotation torque motors with matched expansion ceramic bearings for use in galvanometer scanners and like devices.
2. Background Art
Modem galvanometer scanners, which are essentially high precision partial-rotation torque motors with position feedback, are intrinsically long-life devices with no wearing parts other than their bearings. The bearings, however, have relatively short life because of the requirement that they exhibit high geometrical precision, low operating torque, high stiffness, and low electromagnetic noise. All of these attributes are adversely affected by wear. The process of bearing renewal requires that the galvanometer be removed from the equipment in which it is used, sent back to the factory, and finally reinstalled and realigned. This process is costly in terms of the repair work itself, commonly about two thirds the cost of a new galvanometer scanner, and also in terms of the down-time of the end use equipment.
The art in galvanometer design has not discovered a bearing which fulfills the technical requirements as well or better than conventional, instrument quality, rolling element bearings, specifically ball bearings. However, conventional ball bearings are not well adapted to reciprocating motion for the reasons described below, and suffer a reduction in useful life of about a factor of five when compared with equivalent loading in applications in which the bearing can rotate completely around.
If a ball bearing is constructed with two rings, an inner ring mounted to a shaft and an outer ring mounted to a housing, and these rings are separated by a compliment of bearing balls, relative rotation of the rings results in rolling of the balls along tracks on each ring. If this bearing is preloaded axially, so that all the internal clearance between the parts is removed, the balls are constrained against “skidding” on the tracks in normal operation; that is, the initial relationship between the ball surface and the track surfaces is fixed. If this bearing is rotated over a small angle in reciprocation, a definite small portion of each ball rolls over a definite small portion of the track on each ring, and is constrained to move over these same small areas forever.
After even a few minutes of reciprocating, limited rotation operation, the grease or other lubricant present in a reciprocated ball bearing is squeezed out of the high pressure region between the ball poles and the races, and forms a small hill at the boundary between the edge of each ball and the race at both extremes of travel. There is no mechanism to return this lubricant to the high pressure area where it is needed. This “parking” phenomenon is at the root of bearing failure in reciprocating bearings, since unless the bearing can rotate completely around, the lubricant is effectively lost to the replenishment process. This is why failed bearings often seem to have plenty of lubricant left in them. The lubricant is in fact there, but it is not available to the high pressure area where it is needed.
As the squeezing-out process continues, the lubricant layer between the parts becomes thinner and thinner, and eventually the asperities remaining on even the most highly polished surfaces begin to break through the lubricant film, which is now thinner than the height dimension of the asperities. Where the asperities contact each other, they attempt to carry the entire load exerted on the ring-ball interface. Because their area is very small, even though the absolute load may be only a few pounds, the specific load is enormous; in fact, it is way above the compressive strength of steel. This is a problem best known to phonograph record stylus designers, and which lead eventually to the use of diamond for the stylus material.
If the materials of the balls and the rings are the same, or similar, then welding takes place temporarily at these contact points due to the pressure. The weld is immediately broken by the relative motion, leaving behind an even greater number of asperities available for welding. This process is a chain reaction which quickly destroys the bearing. It is a cruel paradox of nature that the highly-finished surfaces which initially provide low-noise precision operation are precisely those which suffer most from welding and so-called “fret corrosion” or false brinelling during boundary lubrication conditions.
This bearing life problem, and the underlying causes, have been understood for some time. The load carrying capacity required of bearings of suitable size is so high that only the highest strength, or more precisely, the highest fatigue limit, materials are suitable. As a result, bearings have generally been made of steel. In particular, the availability of high performance solid lubricants has led to ball bearings in which the rings and balls are made of steel, but either or both are coated with a soft metal film, such as silver or gold, which acts as a lubricant. Unfortunately, such films tend to flow and to wear, building up at the ends of the current ball track, just as liquid or semi-liquid conventional lubricants do. If a larger motion is attempted, the balls must “bump” over these small hills, destroying the geometrical accuracy and noise performance in that region of motion at least.
Another approach has been to coat the balls with a hard film, such as titanium nitride. While the wearing properties of this film are good, and the surface will not normally weld to the steel rings, the film is brittle, so that the deformation of the balls into ellipsoids in service causes micro cracking of the film, leading to sharp abrasive edges and the eventual destruction of the bearing. Hybrid bearings, in which the rings are steel but the balls are ceramic, have been used. However, these bearings have a load rating of only about 70% of the load rating of a similar sized all-steel bearing, because the very high modulus of elasticity of the ceramic ball material resists the deformation of the contact area on the ball into an ellipsoid. As a result, the rings are subjected to a higher compressive stress, leading to fatigue failure of the rings. All other things being equal, the life of a ball bearing in a particular application is related directly to its intrinsic load carrying capacity, so hybrid bearings have failed to demonstrate long life in galvanometer applications in spite of the ability of the ball material to resist micro welding to the races.
In general, the prior art, in the context of the requirements of torque motors for galvanometer scanners, has had as its purpose two distinct goals. The first has been the design of a bearing for extremely high temperature, high-speed, continuous rotation use, where conventional lubricants are unsuitable, and where the high temperature resistance and the great resistance to wear of non-lubricated ceramic materials, makes them attractive. U.S. Pat. Nos. 5,775,816, 5,052,828 and 5,197,808 are in this category. The second goal has been the design of low friction, very high speed, continuous rotation bearings for moderate (room temperature) use, where air is the lubricant. The non-lubricated wear capabilities of ceramics are important here because of the lack of an effective lubricating film during startup and stopping. U.S. Pat. Nos. 5,532,729, 5,596,443, 5,900,903, 5,373,391 and PCT WO99/43927 are examples.
All of these applications are, or can be made to be, tolerant of a certain amount of “springiness”, that is, dynamic uncertainty in the position of the axis of rotation with respect to external coordinates. This tolerance is taken advantage of in the design and mounting of the bearing surfaces in the prior art, in allowing parts to take up small clearances during heating, or by providing springs which deflect in response to changes in dimension, or by allowing an axial or radial unconstrained motion, as is the cas
Aguirrechea J.
GSI Lumonics Corporation
Maine & Asmus
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