A tube holder (105) for use with a peristaltic pump includes a housing having a recess (165) for receipt of a pump rotor and a tube race around the recess. The tube race has a first race part and a second race part, a first tube inlet (167a) into the first race part and a first tube outlet (167b) fr
A tube holder (105) for use with a peristaltic pump includes a housing having a recess (165) for receipt of a pump rotor and a tube race around the recess. The tube race has a first race part and a second race part, a first tube inlet (167a) into the first race part and a first tube outlet (167b) from the first race part, a second tube inlet (167c) into the second race part and a second tube outlet (167d) from the second race part. The tube is insertable in the tube race by movement in a substantially orthogonal direction relative to the tube race so that it extends in through the first tube inlet (167a), around the first race part, out through the first tube outlet (167b), in through the second tube inlet (167c), around the second race part, and out through the second tube outlet (167d).
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The invention claimed is: 1. A tube holder for use with a peristaltic pump, the tube holder comprising: a housing having a recess for receipt of a pump rotor, a tube race for receipt of a tube around the recess and having a first race part around one part of the recess and a second race part around
The invention claimed is: 1. A tube holder for use with a peristaltic pump, the tube holder comprising: a housing having a recess for receipt of a pump rotor, a tube race for receipt of a tube around the recess and having a first race part around one part of the recess and a second race part around another part of the recess, a first tube inlet into the first race part and a first tube outlet from the first race part, a second tube inlet into the second race part and a second tube outlet from the second race part, the first race part extending between the first tube inlet and first tube outlet and comprising an occluding surface against which part of a tube can be compressed in use by a pump rotor, and the second race part extending between the second tube inlet and second tube outlet and comprising an occluding surface against which part of a tube can be compressed in use by the pump rotor; the tube being insertable in the tube race by movement in a substantially orthogonal direction relative to the tube race so that it extends in through the first tube inlet, around the first race part, out through the first tube outlet, in through the second tube inlet, around the second race part, and out through the second tube outlet, and such that a portion of the tube between the first tube outlet and second tube inlet is external of the tube race. 2. A tube holder as claimed in claim 1, wherein the first tube outlet and second tube inlet are configured such that the tube can exit the housing between the first outlet and second inlet. 3. A tube holder as claimed in claim 1, wherein the first tube outlet and second tube inlet are in communication with a recess or groove which is separate to the tube race, but which is located within the housing. 4. A tube holder as claimed in claim 1, wherein the housing comprises a lip or projection between the first outlet and the second inlet, behind which the tube can be located to maintain the tube in position within the tube race. 5. A tube holder as claimed in claim 1, wherein the recess is tapered for receipt of a tapered pump rotor. 6. A tube holder as claimed in claim 5, wherein each tube race part is defined by a channel or groove extending inwardly from a respective tube inlet and tube outlet. 7. A tube holder as claimed in claim 6, wherein the grooves extend part way around the recess. 8. A tube holder as claimed in claim 1, wherein the tube holder is a one-piece article. 9. The combination of a tube holder as claimed in claim 1 and a pump head having a tapered rotor which is received in the recess of the tube holder, such that actuation of the pump head causes fluid to be pumped through a tube in the tube holder by occlusion of the tube. 10. The combination as claimed in claim 9, wherein the tube is resiliently flexible so that it returns substantially to its original shape following occlusion, to thereby suck fluid through the tube. 11. The combination as claimed in claim 9, wherein the rotor is axially biased towards its tapered end, such that the pump rotor and tube race are self-adjusting, to maintain a desired pressure on a tube in the tube race during pumping. 12. The combination as claimed in claim 11, wherein the rotor is axially biased by a compression spring. 13. The combination as claimed in claim 11, including a stop to limit the axial movement of the rotor relative to the housing. 14. The combination as claimed in claim 13, wherein the stop is in the form of an annular lip on the rotor. 15. The combination as claimed in claim 12, wherein the pump head comprises a transmission mechanism to transmit motive power from a power source to the rotor, and wherein the base of the tapered rotor comprises a plurality of gear teeth which engage with a gear of the transmission mechanism, and wherein the gear teeth of the rotor and the teeth of the gear of the transmission mechanism are of sufficient length to remain engaged during axial movement of the rotor. 16. The combination as claimed in claim 15, wherein the gear teeth of the rotor are elongate and longer than the teeth of the gear of the transmission mechanism. 17. The combination as claimed claim 9, wherein part of the rotor is substantially conical or frustoconical, and has a plurality of rollers rotatably mounted thereon which are configured to occlude the tube in use. 18. The combination as claimed in claim 17, wherein the rollers are substantially frustoconical in configuration, with their tapered ends directed towards the tapered end of the rotor. 19. The combination as claimed in claim 18, wherein the rollers are mounted for rotation with axes which taper toward the tapered end of the rotor. 20. The combination as claimed in claim 17, wherein the rotor comprises a main body part and a head part, with the rollers mounted for rotation in a recess or recesses between the main body part and the head part. 21. The combination as claimed in claim 9, wherein the tube holder and pump head are fully separable from an operable configuration in which the rotor is located in the recess of the tube holder and configured to pump fluid through a tube to a loading configuration in which the tube may be loaded into the tube race. 22. A method of loading a tube into a tube holder comprising: providing a tube holder having a housing having a recess for receipt of a pump rotor, a tube race for receipt of a tube around the recess and having a first race part around one part of the recess and a second race part around another part of the recess, a first tube inlet into the first race part and a first tube outlet from the first race part, a second tube inlet into the second race part and a second tube outlet from the second race part, the first race part extending between the first tube inlet and first tube outlet and comprising an occluding surface against which part of a tube can be compressed in use by a pump rotor, and the second race part extending between the second tube inlet and second tube outlet and comprising an occluding surface against which part of a tube can be compressed in use by the pump rotor; providing a tube; and moving the tube in a substantially orthogonal direction relative to the tube race such that it extends in through the first tube inlet, around the first race part, out through the first tube outlet, in through the second tube inlet, around the second race part, and out through the second tube outlet, and such that a portion of the tube between the first tube outlet and second tube inlet is external of the tube race. 23. A method as claimed in claim 22, wherein the tube holder comprises a retainer which is in the form of a projection or lip between the first outlet and the second inlet, and wherein the method further comprises pulling the installed tube in a direction away from the projection or lip so that the tube is maintained in position within the tube race with part of the tube located behind the projection or lip. 24. A method as claimed in claim 22, wherein the method comprises bringing the tube holder into engagement with a pump head to provide the combination of a tube holder and a pump head, and so that the rotor is located in the recess in the tube holder. 25. A method as claimed in claim 24, wherein the pump head comprises a tapered rotor which is received in the recess of the tube holder, such that actuation of the pump head causes fluid to be pumped through a tube in the tube holder by occlusion of the tube against the occluding surfaces of the tube race. 26. The combination of a peristaltic pump head having a tapered pump rotor which is rotatable about an axis of rotation, and a tube holder having a recess for receipt of the tapered end of the rotor, the tube holder having a tube race configured for receipt of a tube for pumping of a fluid by movement of the rotor, the tube race comprising a first race part around one part of the recess and a second race part around another part of the recess, a first tube inlet into the first race part and a first tube outlet from the first race part, a second tube inlet into the second race part and a second tube outlet from the second race part, the first race part extending between the first tube inlet and first tube outlet and comprising an occluding surface against which part of a tube can be compressed in use by the tapered pump rotor, and the second race part extending between the second tube inlet and second tube outlet and comprising an occluding surface against which part of a tube can be compressed in use by the tapered pump rotor, wherein a tube can be inserted into the tube race so that it extends in through the first tube inlet, around the first race part, out through the first tube outlet, in through the second tube inlet, around the second race part, and out through the second tube outlet, such that the tube exits and re-enters the tube race, and such that a portion of the tube between the first tube outlet and second tube inlet is external of the tube race. 27. The combination as claimed in claim 26, wherein the tube is insertable into the tube race without separating the tube holder from the pump head. 28. The combination as claimed in claim 26, wherein the tube holder and pump head are movable from an operable configuration in which the rotor is located in the recess of the tube holder and configured to pump fluid through a tube to a loading configuration in which the tube may be loaded into the tube race. 29. The combination as claimed in claim 28, wherein the tube holder and pump head are fully separable. 30. The combination as claimed in claim 26, wherein the tube holder has a housing, the first race part around one part of the recess defined by a first tube inlet aperture and a first tube outlet aperture, the second race part around another part of the recess defined by a second tube inlet aperture and a second tube outlet aperture, such that movement of a tube threaded therethrough in the axial direction of the rotor is minimized or prevented by the apertures. 31. The combination as claimed in claim 28, wherein the tube holder comprises: a housing having a recess for receipt of a pump rotor, the tube race for receipt of a tube around the recess and having the first race part around one part of the recess and the second race part around another part of the recess, the first tube inlet into the first race part and the first tube outlet from the first race part, the second tube inlet into the second race part and the second tube outlet from the second race part; the tube being insertable in the tube race by movement in a substantially orthogonal direction relative to the tube race so that it extends in through the first tube inlet, around the first race part, out through the first tube outlet, in through the second tube inlet, around the second race part, and out through the second tube outlet. 32. The combination as claimed in claim 31, wherein the tube is resiliently flexible so that it returns substantially to its original shape following occlusion, to thereby suck fluid through the tube. 33. The combination as claimed in claim 31, wherein the rotor is axially biased towards its tapered end, such that the pump rotor and tube race are self-adjusting, to maintain a desired pressure on a tube in the tube race during pumping. 34. The combination as claimed in claim 33, wherein the rotor is axially biased by a compression spring. 35. The combination as claimed in claim 33, comprising a stop to limit the axial movement of the rotor relative to the housing. 36. The combination as claimed in claim 35, wherein the stop is in the form of an annular lip on the rotor. 37. The combination as claimed in claim 34, wherein the pump head comprises a transmission mechanism to transmit motive power from a power source to the rotor, and wherein the base of the tapered rotor comprises a plurality of gear teeth which engage with a gear of the transmission mechanism, and wherein the gear teeth of the rotor and the teeth of the gear of the transmission mechanism are of sufficient length to remain engaged during axial movement of the rotor. 38. The combination as claimed in claim 37, wherein the gear teeth of the rotor are elongate and longer than the teeth of the gear of the transmission mechanism. 39. The combination as claimed in claim 26, wherein the tapered part of the rotor is substantially conical or frustoconical, and has a plurality of rollers rotatably mounted thereon which are configured to occlude the tube in use. 40. The combination as claimed in claim 39, wherein the rollers are substantially frustoconical in configuration, with their tapered ends directed towards the tapered end of the rotor. 41. The combination as claimed in claim 40, wherein the rollers are mounted for rotation with axes which taper toward the tapered end of the rotor. 42. The combination as claimed in claim 39, wherein the rotor comprises a main body part and a head part, with the rollers mounted for rotation in a recess or recesses between the main body part and the head part.
Terman David S. (Houston TX) Sulliva Michael (Buffalo Grove IL) Cullis Herbert M. (Silver Spring MD), Apparatus for the extracorporeal treatment of disease.
Gimple James J. (Oregon OH) Hamilton David L. (Belleville MI) Hughey Daniel C. (Indianapolis IN) Jamison Chris M. (Indianapolis IN) Seitz David M. (Temperance MI), Automatic coating using conductive coating materials.
Reese Robert J. (St. Charles MO) Podgorny Gerald J. (St. Louis MO) Newkirk Franklin D. (Florissant MO) Schmitz Mark S. (St. Charles MO) Fink George R. (St. Louis MO), Hot beverage brewing apparatus.
Schneider Philip H. (2939A Cowley Way San Diego CA 92117) Weber William J. (520 W. Ellis Ave. Inglewood CA 90302) Massaro Thomas A. (1339 Hill Top Rd. Charlottesville VA 22903), Insulin infusion pump.
Giesler Richard C. ; Miles Myra P. ; Lovelace Susan L. ; Patno Timothy J. ; West Richard L., Peristaltic pump tube holder with pump tube shield and cover.
Giesler Richard C. ; Miles Myra P. ; Lovelace Susan L. ; Patno Timothy J. ; West Richard L., Peristaltic pump tube holder with pump tube shield and cover.
Morrick Joseph Q. (1634 West County Rd. B Roseville MN 55113), Peristaltic pump with spring means to urge slide members and attached rollers radially outward on a rotor.
Pieronne Alain (18 Rue Francois de Badts 59110 La Madeleine FRX) Soots Georges (17 Rue Bazinghien 59000 Lille FRX) Logier Rgis (19 Rue des Liliums 59134 Herlies FRX) Delecroix Michel (2 rue d\Haubour, Pump regulation device.
Afflerbaugh Richard L. (Libertyville IL) West Richard L. (Lake Villa IL) Patno Timothy J. (Mundelein IL) Chapman Arthur S. (Solvang CA), Self loading peristaltic pump tube cassette.
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