Roller pump

A roller pump in which one or more hoses is compressed against an arcuate stator bearing surface by a plurality of rollers carried by a rotating rotor. A shim is provided in generally opposing relation to the stator bearing surface to impart a hose compression offset force to the rotor. In this manner, the forces imparted to the rotor remain substantially constant throughout its rotation. In a preferred embodiment, a liner, which may be unitary with the shim, overlies the hoses to be compressed by the rotor to compensate for dimensional variations between the rotor rollers and for variations in the bearing surface and the hoses themselves. The thickness of the shim, at its region of greatest thickness, approximates the combined thickness of the hose, when fully compressed, and the compensating liner. Tabs are provided to extend from the shim to assist in maintaining the shim and liner in proper orientation relative to the hoses to be compressed.

BACKGROUND OF PRIOR ART 
Roller pumps are known to the prior art and have wide application in the 
medical field. A typical application for such a pump is as a blood pump 
during hemodialysis, for example. Other applications are well known. The 
simplicity and reliability of roller pumps has resulted in their wide 
acceptance within the medical community. 
Typically, medical roller pumps employ a stator having a bearing surface 
against which one or more hoses is compressed by a rotating rotor, the 
rotor engaging the hoses with two or more rollers. On rotation of the 
rotor, the fluid medium in the hose or hoses is transported in the 
direction of the rotor rotation. Alternatively, the fluid may be presented 
to the pump under pressure such that rotation of the rotor causes the pump 
to serve as a measuring valve. In either instance, knowledge of the inner 
diameter of the hose or hoses and the rotational speed of the rotor 
provides a knowledge of the amount of fluid passed through the hose or 
hoses, which amount can be regulated by regulating the speed of the rotor. 
Among the problems encountered in prior art roller pumps are dimensional 
variations in the rotor rollers as well as variations in the stator 
bearing surface and the hoses themselves. In addition, the rotor rollers 
have not always rolled over the hoses but, instead, have a tendency to 
"scuff" the hoses. Hose flutter is also known. Each of these phenomena, if 
prolonged, may result in mechanical failure of the hoses. Also, because 
the hose is not compressed against the stator bearing surface throughout 
the full 360.degree. rotation of the rotor, the forces imparted to the 
rotor are not uniform throughout its rotation. In larger pumps, this can 
be countered by increases in the size of the driving shaft. However, in 
smaller units, this solution may not be practical. In all cases, this 
results in significant variations in the torque required to rotate the 
rotor through 360.degree.. 
BRIEF SUMMARY OF THE INVENTION 
The present invention provides an improved roller pump by employing a shim 
in opposing relation to the stator bearing surface. The shim imparts a 
hose compression counterbalancing or offset force to the rotor thereby 
equalizing the forces imparted to the rotor throughout its 360.degree. 
rotation. Additionally, a liner may extend from the shim to overlie each 
hose in the stator bearing surface region to compensate for dimensional 
variations between the rotor rollers as well as variations in the bearing 
surface and the hoses themselves. In a preferred embodiment, the thickness 
of the shim, in its region of greatest thickness, approximates the 
combined thickness of the hose, when fully compressed, and the 
compensating liner. Tabs may be provided to cooperate with the stator 
structure to assist in maintaining the shim/liner structure in the desired 
position.

DETAILED DESCRIPTION OF THE INVENTION 
FIGS. 1 and 2 illustrate a typical prior art roller pump having a stator 10 
which provides a bearing surface for one or more hoses 11. A rotor 12 is 
rotatable through 360.degree. and carries a plurality of rollers 13 which 
engage the hose or hoses 11 and compress them against the stator 10 
bearing surface to regulate the flow of fluid through the hoses 11. 
Typically, the rollers 13 are carried on biased levers 14 which maintain 
uniform compressing pressure on the hoses 11. The roller pump of FIGS. 1 
and 2 is that disclosed in U.S. Pat. No. 4,108,575 issued Aug. 22, 1978, 
to Schal for OBTAINING DESIRED FLOW RATE FROM THE ROLLER PUMP DESPITE 
VARYING THE HOSE MEANS, which patent is hereby incorporated by reference. 
The rotor 12 of the roller pump of FIGS. 1 and 2 is driven by a rotor shaft 
15 which, itself, is driven by a suitable motor. When in the position 
illustrated in FIG. 1, the compression of the hose 11 by the uppermost 
roller 13 imparts a force to rotor 12 which is not counterbalanced or 
offset by a corresponding force applied to the lowermost roller 13 
inasmuch as the lowermost roller 13 is not in engagement with the hose 11. 
In smaller units, requiring a relatively small rotor shaft 15, this could 
have a tendency to deflect the rotor shaft 15 to result in a less than 
complete compression of the hose 11 against the bearing surface of the 
stator 10. This could result in a leakage past the uppermost rotor 13 and 
an inaccuracy in the assumed amount of fluid flow through the hose 11. 
This is especially true when the fluid is supplied to the hose under 
pressure and may be critical when that fluid is a medication to be 
dispensed with the roller pump serving to regulate the amount of 
medication dispensed. 
The present invention provides means for imparting a compensating or 
offsetting force to the rotor when one of the rotor rollers is not in 
compressing relation to the roller pump hose or hoses. This is illustrated 
diagramatically in FIG. 3 which illustrates a stator 20 having a generally 
cylindrical bearing surface 21 with a hose 22 extending from a stator hose 
inlet 23 to a stator hose outlet 24 and overlying the arcuate stator 
bearing surfce 21. A rotor 25 carries a plurality of rolles 26 (two shown) 
which rotate about a central axis 27, in known manner, to compress the 
hose 22 against the stator bearing surface 21. Preferably the compression 
is complete, as illustrated in cutaway at 28 to eliminate leakage. Of 
course, the rollers 26 can be carried by levers or be otherwise spring 
biased to regulate the amount of compressing force applied to the hose 22, 
the particular design of the rotor 25 and rollers 26 forming no part of 
the present invention. 
With a fluid supply entering the hose 22 as indicated by the arrow 29, and 
with the rotor 25 rotating in the direction indicated by the arrow 30, the 
fluid will be moved through the tube 22 to exit from the tube 22 as 
indicated by the arrow 31. However, and as indicated with reference to the 
discussion of FIGS. 1 and 2, as the rotor approaches the position 
illustrated in phantom in FIG. 3, the disengagement of the lowermost 
roller from the hose 22 will result in a force being imparted to the 
uppermost roller by the compressed hose without a counterbalancing or 
offsetting force on the lowermost roller. This force has a tendency to 
cause a deflection of the rotor assembly to result in less than a complete 
compression of the hose 22 and, accordingly, a leakage past the uppermost 
roller 26. In the present invention, this force is countered or offset by 
a shim member 32 which engages the lowermost phantom roller 26 to impart a 
force thereto which compensates or offsets for the force imparted by the 
compressed hose 22 to the uppermost phantom roller 26. The shim 32 is 
supported by a backing member 33 and tapers from its region of greatest 
thickness (overlying the backing member 33) in accordance with the 
configuration of the bearing surface 21 and the amount of compressing of 
the hose 22 that it overlies, in a manner which is easily determinable by 
one of ordinary skill in the art. In addition to minimizing leakage, the 
shim of the present invention also provides a more uniform torque 
requirement for the motor driving the rotor 25. 
Tabs 35 extend from the shim 32 and into the hose inlet and outlet ports 23 
and 24 to help maintain the shim 32 in position against rotation of the 
rotor 25, and the rollers 26 which contact it, as well as helping to 
properly position the hose 22 within the inlet and outlet ports 23 and 24. 
Also extending from the shim 32 is a liner 36 which is preferably unitary 
with the shim 32 to overlie the hose 22 intermediate the hose 22 and the 
rollers 26. The linear 36 compensates for dimensional variations between 
the rotor rollers 26 as well as dimensional variations in the bearing 
surface 21 and the hose 22, itself. Alternatively, the linear 36 may be 
formed separately of the shim 32 to overlie both the shim 32 and hose 22 
to provide the stated functions. In addition to compensating for 
dimensional variations, the linear 36 also prevents a scuffing of the hose 
32 by the rollers 26 while the entire structure formed of shim 32, tabs 35 
and liner 36 reduce hose flutter which, like a scuffing of the hose 22 by 
rollers 26, could result in premature hose failure. In the preferred 
embodiment illustrated in FIG. 3, including the liner 36, the thickness of 
the shim in its region of greatest thickness (the thickness at arrow 34, 
for example) approximates the combined thickness of the hose, when fully 
compressed, and the liner 36, the backing member providing an arcuate 
surface that constitutes an extension of the generally cylindrical bearing 
surfce 21. The shim 32 and liner 36 may be made of any suitable material, 
silicone, for example. 
Obviously, many modifications and variations of the present invention are 
possible in light of the above teachings. One such modification is 
illustrated in FIGS. 4 and 5, FIG. 4 illustrating a unitary structure 
formed of shim 32, tabs 35 and liner 36 while FIG. 5 illustrates a unitary 
structure formed of shim 32 and tabs 35. The structure of FIG. 5 may be 
employed with or without a separate liner structure, dependent on the 
desired application and the problems encountered, without departing from 
the scope of the present invention. Also, while disclosed in terms of a 
roller "pump," it is contemplated that the improvement disclosed herein 
may be employed with a roller pump structure in which the fluid entering 
the hose 22, as indicated at arrow 29, is under pressure with the rotation 
of the rotor 25 serving to regulate the amount of fluid allowed to pass 
through the hose 22 within the stator 20. Indeed, it is contemplated that 
preferred embodiments of the present invention will be employed within a 
drug dispensing mechanism with the drug to be dispensed being maintained 
in a reservoir under pressure and supplied to the hose 22 as at the arrow 
29. The roller pump may thus serve a medical purpose in dispensing the 
drug in an amount established by the inner diameter of the hose 22 and the 
speed of the rotor 25. It is therefore to be understood that, within the 
scope of the appended claims, the invention may be practiced otherwise 
than as specifically described.