Roller washer bearing and method

A linear roller washer bearing in a bolt interface assembly allows relative differential thermal expansion and contraction motion between a component plate and a base plate fastened together by a bolt without inducing large strains and stresses upon the bolt. The roller washer bearing functions as a thin spacer between the component and base plates enabling high preload tightening of the bolted assembly while enabling relative bidirectional motion of the plates. The roller washer bearing is a multiple roller assembly with thin rollers arranged unidirectionally and horizontally in parallel between the top and bottom washer plates. The rollers roll back and forth to enable relative back and forth alternating unidirectional motion of the component and base plates while the full strength of the bolt remains available to the support the component plate without creating high friction shear forces.

FIELD OF THE INVENTION 
The invention relates to the field of mechanical washers and linear 
bearings and mechanical assemblies subjected to thermal expansion stresses 
and differential motion during temperature variations. 
BACKGROUND OF THE INVENTION 
Changes in temperature can cause excessive thermal stresses at the 
attachment points between arbitrary parallel plates of a mechanical 
assembly, such as a top component plate and a bottom base, both rigidly 
fastened together. An example of such a mechanical assembly is a high 
precision optical instrument assembly or inertial guidance unit on a 
spacecraft. The unit has an aluminum housing bolted to a graphite-epoxy 
honeycomb support base structure. The instrument and/or the support base 
are subjected to large changes in orbital temperature with resulting 
differential expansions between the base structure and the instrument. The 
top component plate and the bottom base plate could be fastened together 
using conventional fastening bolts, nuts and washers, through aligned 
holes extending through the component and base plates. The top component 
plate and the bottom base plate may have substantially different 
coefficients of thermal expansion. The resulting unequal amounts of 
expansion or contraction, if constrained, can cause significant locally 
induced strains and stresses. During temperature variations, the top 
component plate may expand and contract at a different rate than the 
bottom base plate, thereby tending to misalign the base holes and placing 
stresses upon the bolts extending through the fastening holes, leading to 
stress and even eventual failure of the bolt. The differential in the 
thermal expansion can also lead to damage to the component plate and base 
plate, or may result in misalignment of precision mounted instruments. 
These and other disadvantages are eliminated or reduced using the 
invention. 
SUMMARY OF THE INVENTION 
An object of the invention is to provide a linear roller washer bearing 
which reduces stresses in an assembly having fastening bolts extending 
between a component plate and a base plate, both expanding and contracting 
at differing rates during temperature variations. 
Another object of the invention is to provide a method of rigidly fastening 
the component and base plates together using a linear roller washer 
bearing, thus enabling the component and base plates to expand and 
contract at differing rates during temperature variations without inducing 
excessive stresses in the component or base plate. 
The present invention is a linear roller washing bearing and method of use. 
The roller bearing comprises a plurality of parallel rollers extending 
between a top washer plate and a bottom washer plate. The rollers can roll 
back and forth between the top and bottom washer plates in the presence of 
horizontal forces upon the top washer plate relative to the bottom washer 
plate. 
In one aspect of the invention, the two roller washer bearings are disposed 
in alignment around a bolt hole having a larger diameter than a fastening 
bolt extending through the bolt hole in the top component plate and into 
the bottom base plate into which is rigidly fastened the bolt. The bolt 
fastens together the top component plate, the bottom base plates and the 
two roller washer bearings. In the preferred form, a bottom roller bearing 
is disposed between the bottom base plate and the top component plate and 
another top roller bearing is disposed between the bolt head the top 
component plate, with the bolt rigidly fastened into the bottom base 
plate. As the top component plate expands or contracts relative to the 
bottom base plate during temperature variations, the bottom washer plate 
of the bottom washer remains rigidly affixed to the bottom component plate 
and the top washer plate of the top roller washer bearing remains rigidly 
affixed to the bolt head, and the bottom washer plate of the top roller 
washer bearing and the top washer plate of the bottom washer bearing 
remain affixed to the top component plate, with the rollers of both roller 
washer bearings rolling slightly to enable the expansion and contraction 
of the top component plate relative to the base plate without placing 
stresses upon the bolt. As the top component plate expands or contracts, 
the rollers roll back and forth so that the hole in the top component 
plate moves in misalignment relative to the hole in the bottom base plate. 
At all times, the bolt remains in a rigid vertical and orthogonal position 
relative to the horizontally extending assembly. The hole in the component 
plate is larger than the bolt stem to create sufficient space for the 
relative movement without the top component plate inducing stresses in the 
fastening bolt. 
In another aspect of the invention, one roller washer bearing is disposed 
between the top component plate and the bottom base plate with the top 
washer plate being rigidly fastened to the top component plate and with 
the bottom washer plate being rigidly fastened to the bottom base plate, 
again with an alignment hole larger than the diameter of the bolt stem 
around which is disposed a pair of rocker washers, one rocker washer 
disposed between the bolt head and the top component plate and the other 
rocker washer disposed between the bottom base plate and a bottom 
fastening nut. As the top component plate expands or contracts, the 
rollers roll back and forth so that the hole in the top component plate 
moves in misalignment relative to the hole in the bottom base plate, 
causing the bolt to cock, that is, rotate within the alignment hole as the 
rocker washers rock upon the respective component and base plates. At all 
times, the bolt remains in a rigid position affixed to the bottom base 
plate. The hole in the component plate being larger than the bolt stem to 
create sufficient space for the relative rotation of the bolt stem within 
the alignment hole inducing stresses in the fastening bolt. 
In a third aspect of the invention, the rollers within the roller washer 
bearing are slanted at an angle to enable relative motion along only one 
direction relative to the plane of the roller washer bearing. 
The invention releases interface stresses by allowing relative differential 
motion between the component plate and base plate fastened by a bolt. The 
full strength of the bolt is available to support the component plate. The 
strength of the bolted assembly is not compromised in the presence of 
relative thermal expansion and contraction. The rollers within the roller 
washer avoid friction shear forces. The roller washer bearings function as 
a thin spacer between the component and base plates, thus enabling high 
preload tightening of the bolted assembly. These and other advantages will 
become more apparent from the following detailed description of the 
preferred embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
An embodiment of the invention is described with reference to the figures 
using reference designations as shown in the figures. Referring to FIG. 1, 
a roller washer bearing 10 preferably comprises a plurality of long and 
short rods 16 and 17 extending horizontally and unidirectionally and are 
disposed between a top washer plate 12 and a bottom washer plate 14. In 
the preferred form, rods 16 are long rollers and rods 17 are short 
rollers. The roller washer bearing 10 including a circular insert 13 
having an outer confinement surface 15 and a center circular aperture 21. 
The bottom washer plate 14 includes opposing vertically extending 
retention flanges 18a and 18b, and top washer plate 12 includes opposing 
vertically extending retention flanges 20a and 20b. The rollers 16 and 17 
are undirectionally aligned in a horizonal position and are retained 
within the bearing 10. 
As shown, the ends of the long rollers 16 are confined by flanges 20a and 
20b, the ends of the short rollers 17 are confined by flanges 20a and 20b, 
and the confinement surface 15. The confinement of the rollers 16 and 17 
of the roller bearing 10 resists relative bidirectional movement of the 
top and bottom plates 12 and 14 along the length of the rollers 16 and 17. 
However, distances between the flanges 18a and 18b, and the distances 
between the confinement surface 15 and the flanges 18a and 18b, are 
greater than the accumulative thickness of the rollers 16 and 17 
therebetween, so as to provide a small amount of space between the flanges 
18a and 18b, and between the surface 15 and flags 18a and 18b, in which 
the respective rollers 16 and 17 may in unison roll back and forth in an 
alternating unidirectional cyclic rolling movement, to provide a single 
degree of relative motion between the top washer plate 12 and the bottom 
washer plate 14 rolling on the rods 16 and 17. 
The roller washer bearing 10 is a multiple roller assembly including a 
parallel collection of roller rods 16 and 17 disposed between a top plate 
12 and a bottom plate 14. The washer aperture 21 is disposed preferably in 
the center of the roller washer bearing 10. The roller rods 16 and 17 can 
roll back and forth in an alternating unidirectional movement so that the 
top washer plate 12 and bottom washer plate 14 can horizontally move small 
distances relative to each other while rolling on the rods 16 and 17. The 
roller rods 16 and 17, insert 13 and washer plates 12 and 14 can be 
machined from high strength alloys of steel, or other suitable materials. 
The top plate 12 and bottom plate 14 are configured to confine the rods in 
one direction while enabling rolling along the relative alternating 
unidirection movements of the plates 12 and 14 during alternating thermal 
expansion of the component plate relative to the base plate. The roller 
rods 16 and 17 may be lubricated for reducing friction and may be equally 
spaced using a filler material, not shown, such as RTV medium used to 
equally space the rods enabling repetitively back and forth rolling yet 
retain equal spacing even after many rolling cycles. As shown, the 
preferred roller rods 16 and 17 are confined in alignment. The rods 16 and 
17 should be thick and strong enough to prevent collapse of the washer 
under expected loads. The roller bearing 10 is shown generally in the 
shape of a square, but other shapes, such as a circle, could be used as 
well, with suitably varying length rods. The long rods 17 may be 0.9 
inches long, and the short rods may be 0.29 inches long, both with a 3/64 
diameter. The top and bottom plates 12 and 14 may be 0.05 inches thick 
with 0.07 inch extending flanges 18 and 20. The center aperture may have a 
0.252 inch diameters with the insert 13 having an a square confinement 
surface 15 of 0.282 inches for confining the rods 16 and 17 within the 
assembly 10. 
Referring to FIGS. 1 and 2, and more particularly to FIG. 2, two roller 
washer bearings 10a and 10b comprise roller rods 16 and 17, only a few of 
which are shown for clarity without the confining insert 13. The bearings 
10a and 10b further comprise top washer plates 12a and 12b, and bottom 
washer plates 14a and 14b, and are used to enable relative horizontal 
motion between a top component plate 22 and a bottom base plate 24. The 
roller rods 16 and 17 are arranged in a plane parallel to the plates 22 
and 24 and extend orthogonal to relative thermal expansion and contraction 
motion of the top component plate 22 relative to the bottom base plate 24. 
The roller rods 16 and 17 and the shape of the bearings 10 constrain all 
other translatory and rotational motion of the component plate 22 relative 
to the base plate 24. A bolt 26 comprising a threaded stem 26 and bolt 
head 28 extends vertically through the plates 22 and 24, through a bore 
hole 32 in the top component plate 22 and a threaded hole 34 in the bottom 
base plate 24. Here, the top plate 12a is shown to have a bevel edge for 
transfer of the load from the bolt 26 to the roller rods 16 and 17 and for 
proper orientation of the roller washer bearing, whereas the bottom plate 
14b remains substantially flat for buttress against the base plate 24. The 
holes 32 and 34 are in initial alignment when the top and bottom plates 22 
and 24 are initially fastened together. The base plate 24 could be a 
honeycomb structure having a low coefficient of thermal expansion, whereas 
the component plate 22 may be an aluminum mounting plate having a high 
thermal coefficient of expansion. The relative movement between the plates 
22 and 34 may be, for example, 0.004 inches over a wide temperature range. 
The roller washer bearings 10a and 10b may further respectively comprise 
pilot registrations 36a and 36b for centering the bearings 10a and 10b 
into the hole 32. The registrations 36a and 36b are optional circular 
vertically extending flanges initially centered within bolt hole 32 to 
align the bearings 10a and 10b to the bolt hole 32. As shown, the hole 32 
is larger than the diameter of the registrations 36a and 36b, and much 
larger than the diameter of the bolt stem 30, so that the top component 
plate 22 can move horizontally relative to the bottom base plate 24 while 
the bolt 36 remains in a vertical position while rigidly affixed to, 
preferably screwed into, the bottom base plate 24. 
The two roller washer bearings 10a and 10b are disposed in alignment around 
a bolt hole 32 having a larger diameter than the fastening bolt stem 30 
extending through the bolt hole 32 in the top component plate 22 and into 
the bottom base plate 24 into which the bolt 26 is rigidly fastened. The 
bolt 28 fastens together the top component plate 22, the bottom base plate 
24 and the two roller washer bearings 10a and 10b. The bottom roller 
bearing 10b is disposed between the bottom base plate 24 and the top 
component plate 22, and the top roller bearing 10a is disposed between the 
bolt head 28 and the top component plate 22. As the top component plate 22 
expands or contracts back and forth in slight horizontal alternating 
unidirectional movement relative to the bottom base plate 24 during 
temperature variations, the bottom washer plate 14b of the bottom washer 
10b remains rigidly affixed to the bottom component plate 24, and, the top 
washer plate 12a of the top washer bearing 10a remains rigidly affixed to 
the bolt head 28, as the bottom washer plate 14a of the top washer 10a and 
the top washer plate 12b of the bottom washer bearing 10b remain affixed 
to the top component plate 22. The rollers 16 and 17 of both bearings 10a 
and 10b roll back and forth providing the top and bottom washer plates 12 
and 14 with relative movement equal to the differential motion caused by 
expansion and contraction of the top component plate 22 relative to the 
base plate 24 without placing stresses upon the bolt 26. As the top 
component plate 22 moves back and forth, the rollers 16 and 17 roll back 
and forth so that the hole 32 in the top component plate 22 moves in 
misalignment relative to the thread hole 34 in the bottom base plate 24. 
At all times, the bolt 26 remains in a rigid vertical and orthogonal 
position relative to the horizontally extending plates 22 and 24. The hole 
32 in the component plate 22 is larger than bolt stem 30 to create 
sufficient circumferential space around the stem 30 for the relative 
movement of the top component plate 22 without the top component plate 22 
inducing stresses in by contact with the fastening bolt 26. 
Referring to FIG. 3, a single roller washer bearing 10, including the 
roller rods 16 and 17, a top washer plate 12 and bottom washer plate 14 
are disposed between the top component plate 22 and bottom base plate 24. 
The bolt 26 extends through the bolt hole 32 and is fastened using a nut 
36. Two rocker washers 38a and 36b are disposed so as to juxtapose the 
bolt head 28 and nut 36 at the end of bolt stem 30. During relative 
horizontal movement of the top component plate 22 relative to the bottom 
base plate 24, the top washer plate 22 remains affixed to the bottom of 
the top component plate 22, the bottom washer plate 14 remains affixed to 
the top of the bottom base plate 24, the roller rods 16 and 17 roll back 
and forth in alternating unidirectional motion in the same direction of 
the relative movement, the bolt 26 rotates and is cocked to an angle 
relative to the bolt hole, and the rocker washers 38, each having a curved 
surface buttressing the plates 12 and 24, rotate as the bolt 26 rotates to 
its cocked position. During relative movement, the bolt 26 no longer 
remains in vertical upright position, but cocks back and forth, as the 
head 28 pivots on rocker washer 38a, as the end of the stem 30 pivots on 
rocker washer 38b, as the top component plate 22 moves back and forth, 
during temperature cycling. 
In both assemblies of FIGS. 2 and 3, the roller rods 16 extend horizontally 
and unidirectionally and roll back and forth in a horizontal plane 
orientation so as to enable relative horizontal movement along one 
direction, for example, a left and right orientation of the view of the 
FIGS. 2 and 3, so as to resist movement other than this in this left and 
right direction. In many applications, such as with the use of large 
circular component and base plates, the expansion and contraction is 
radial in direction extending from the center of the circular component 
plate to each of a plurality of mounting bolts 26. The roller washer 
bearings 10 can be disposed to align the rolling direction of the roller 
rods 16 and 17 to this radial relative movement, with rods 16 and 17 being 
orthogonally disposed to the radial expansion and contraction, and as 
such, the rods 16 and 17 enable radially alternating unidirectional 
relative movement, while resisting circumferential relative movement 
between the component and base plates 22 and 24. Thus, the roller washer 
bearings 10 provide a single degree of freedom of movement of alternating 
unidirectional relative motion of the plates 22 and 24 in the radial 
direction. 
The circular pilot registrations 36 are used for centering the roller 
washer bearing 10 around the bolt hole 32, but do not orient the washer 
bearing 10 in the direction of relative radial motion in the circular 
radial expansion and contraction application. Hence, the washer bearing 10 
could be easily modified to have radial orientation means, such as a pin 
and hole registration for aligning the rollers 16 and 17 orthogonal to the 
radial expansion and contraction. 
Referring to FIG. 4, a slanted roller washer bearing 40 comprises a top 
washer plate 42 with an aperture 46a and confinement flanges 47a and 47b, 
a bottom washer plate 44 with an aperture 46b, and rolling rods 48 which 
are slanted at an angle relative to the horizontal plane. The slanted 
configuration of this roller washer bearing enables the top and bottom to 
move back and forth in alternating unidirectional horizontal movement with 
added restraint against translatory movement. 
The exemplary assemblies of FIGS. 2 to 4 enable movement in one direction 
by restraining relative motion in other translatory and rotational 
directions. However, the assemblies could be modified to include secondary 
washer bearings having roller alignment orthogonal to the primary washer 
bearings, with the secondary washer bearing enabling movement in another 
orthogonal direction. 
The roller washer bearing 10 is an assembly used as a load bearing 
mechanism for disposition between two mounting plates having relative 
movement, which may be caused, for example, by thermal cycling. The 
rollers avoid interface friction shear forces. The full strength of the 
bolt with normal preloads can be maintained to support components on the 
component plate. Those skilled in the art can make enhancements, 
improvements and modifications to the invention. However, those 
enhancements, improvements and modifications may nonetheless fall within 
the spirit and scope of the following claims.