Device for axially conveying fluids

Information

  • Patent Grant
  • 7467929
  • Patent Number
    7,467,929
  • Date Filed
    Monday, February 18, 2002
    22 years ago
  • Date Issued
    Tuesday, December 23, 2008
    15 years ago
Abstract
A device for axially conveying fluids, wherein the conveyor part thereof is entirely magnetically borne and the radial bearing thereof is provided with sufficient rigidity and efficiently dampened, whereby problems encountered when passing through critical speeds and the disadvantageous effects of hydrodynamic and mechanical imbalance of the rotor are avoided. The magnetic bearing is combined with a hydrodynamic bearing.
Description
BACKGROUND

The invention relates to a device for axially conveying fluids.


In particular, less stable multiple-phase fluids which can undergo irreversible changes caused by an energy input, such as in the case of emulsions and dispersions, can run into unstable ranges in a disadvantageous manner when being conveyed in corresponding devices such as pumps.


Blood is a particularly sensitive fluid system. This opaque red body fluid of the vertebrates circulates in a self-enclosed vessel system where rhythmic contractions of the heart press the blood into various areas of the organism. In this case, the blood transports the respiratory gases oxygen and carbon dioxide as well as nutrients, metabolic products and endogenous active ingredients. The blood vessel system including the heart is hermetically isolated from the environment so that, in a healthy organism, the blood does not undergo any changes, except for the material exchange with the body cells, when it is pumped through the body by way of the heart.


It is known that, when blood comes into contact with non-endogenous materials or as a result of the effect of energy from an external source, it has a tendency to hemolysis and clot formation. Clot formation can be fatal for the organism because it can lead to blockage in the extensive branching profile of the vessel system. Hemolysis describes the condition where the red blood cells are destroyed within the body beyond the physiological dimension.


The causes for hemolysis can be of a mechanical or metabolic nature. Increased hemolysis causes multiple organ damage and can lead to a person's death.


On the other hand it is evident that it is possible in principle, under certain prerequisites with reference to constructive aspects, to support the pumping capacity of the heart or even to replace the natural heart with a synthetic one. However, a continuous operation of implanted heart supporting systems or synthetic hearts is presently only possible with certain limitations because the interactive effects of these artificial products with the blood and the entire organism still always lead to disadvantageous changes of the blood and the organism.


In the state of the art, axial blood pumps are known which mainly consist of a cylindrical tube in which a conveying part, which is executed as a rotor of an externally located motor stator, rotates. The rotor which is provided with a so-called blading, conveys the fluid in an axial direction after it has been made to rotate. The bearing of these so-called axial pumps represents a major problem. A purely mechanically bearing is disadvantageous with regard to blood damage and also the relatively high friction levels. And the magnet bearing variants as described up to the present have not, in particular, led to any satisfactory solution for the bearing conditions in axial pumps.


In the WO 00/64030 a device for the protective conveying of single- and multiple phase fluids is described whose conveying part is exclusively magnetically bearing-located. For this purpose, permanent magnetic bearing elements for the magnet bearing-location as well as permanent magnetic elements for the functionality as a motor rotor of an electromotor are preferentially integrated in the conveying part. The use of a magnet bearing for the conveying facility as described here makes it possible to waive bearing elements normally arranged in the flow current of the fluid to be conveyed which lead to dead water zones and vorticities of the fluid to be conveyed and, subsequently, have a negative influence on the current flow.


The magnetic bearing described here accommodates both the axial as well as the radial forces. The axial location of the conveying part is actively stabilised whereas the radial bearing of the conveying part is effected exclusively passive by means of the existing permanent magnets. However, the conveying facility as described has several disadvantages.


The passive magnetic radial bearing is characterised by relatively low rigidity and dampening where, during the pumping action, problems occur when passing through critical speeds of the rotor and/or the bearing. Possibly existing hydrodynamic and mechanical imbalance of the rotor has serious effects on the function of the pump, particularly when used as a blood-conveying facility.


SUMMARY

The invention is based on the task assignment of presenting a device for the axial conveying of fluids whose conveying part is completely magnetically borne and whose radial bearing has sufficient rigidity and effective dampening so that problems encountered when passing through critical speeds and the disadvantageous effects of hydrodynamic and mechanical imbalance of the rotor are avoided.


The solution for the task assignment is effected with a device for axially conveying fluids consisting of a tube-shaped hollow body which conducts the fluid in an essentially axial manner, in which a magnetically borne conveying part is arranged in axial alignment with a motor stator located outside of the hollow body capable of rotating said conveying part, where the one conveying part having a magnetic bearing has rotor blading, wherein the magnetic bearing is combined with a hydrodynamic bearing.


Further advantageous embodiments are stated in the Subclaims.


The bearing of the conveying part has an actively stabilising magnetic axial bearing, a passive magnetic radial bearing and a hydrodynamic radial bearing. The hydrodynamic radial bearing is executed in a further embodiment of the invention as a hollow-cylindrical, rotation-symmetrical back-up ring which is joined to the conveying part.


On the conveying part, at least one back-up ring is arranged, where the back-up rings are arranged at the beginning of the motor rotor and/or at the end of the motor rotor or between these said positions.


In a further embodiment of the invention, the axial dimension of the back-up ring corresponds, at the maximum, to the axial length of the conveying part, and the axial dimension of the running surface of the back-up ring is smaller than one internal surface of the back-up ring.


The back-up ring has the same radial dimension as the rotor blading and is joined to it.


Furthermore as an embodiment, the back-up ring has such a radial dimension (thickness) that it can be provided with a radial profile which services the purpose of conditioning the inflow into the rotor blading of the conveying part.


In a further embodiment, a back-up ring is provided with such an axial reach that the blading over its entire length is restricted radially from the back-up ring. The running surface of the back-up ring which points against internal side of the tube-shaped hollow body, has in an advantageous manner a surface coating with emergency run characteristics and this coating is, moreover, bio-compatible.


The internal surface of the back-up ring has, in one execution, a profile which can favourably influence the current flow properties.


The execution of the running surface of the back-up ring as one running line leads to particularly favourable friction values.


The major rigidity and dampening of the radial bearing of the conveying part is achieved in such a way that, in addition to a magnetic bearing of the conveying part, a hydrodynamic bearing is envisaged. The hydrodynamic bearing is achieved by at least one hollow-cylindrical, rotation-symmetrical back-up ring which is solidly joined to the conveying part. With a suitable execution of the back-up ring, the rotor receives major tilting rigidity. Advantageously, this effect is obtained by a particularly large axial reach of the back-up ring or by the arrangement of at least two back-up rings at one rotor.


With a large axial reach of the back-up ring and/or extensive or complete encapsulation of the blading by means of such a back-up ring, damaging effects of the radial gap occurring at the blade ends are advantageously avoided.


The invention is explained in greater detail based on a drawing:





BRIEF DESCRIPTION OF THE FIGURES

The Figures show the following:



FIG. 1: a schematic illustration of an axial section of an axial blood pump with back-up ring;



FIG. 2: a schematic illustration of an arrangement of a back-up ring on the rotor;



FIG. 3: a schematic illustration of an arrangement of two back-up rings on the rotor;



FIG. 4: a schematic illustration of an arrangement of a back-up ring with profiled internal surface;



FIG. 5: a schematic illustration of a back-up ring reaching over the entire rotor, and



FIG. 6: a schematic illustration of a back-up ring on the rotor with a running line on the running surface.





DESCRIPTION OF PREFERRED EMBODIMENT

In an exemplary manner, FIG. 1 shows in an axial sectional illustration the construction of a category-related axial pump with the bearing, according to the invention, of a conveying part 4. In its main parts, the axial pump consists of a tube-shaped hollow body 1 and a pump casing 3 that includes a motor stator 7 and axial stabilisers 6. The pump casing 3 lies immediately and rotation-symmetrical on the tube-shaped hollow body 1. In the interior of the tube-shaped hollow body 1, a fluid inlet guide facility 5 and a fluid outlet guide facility 5′ are envisaged, between which the conveying part 4, which is rotated by the motor stator 7, is arranged.


The conveying part 4 has a magnetic bearing where permanent magnetic bearing elements 9 and 9′ are arranged in the motor rotor 8 and permanent magnetic bearing elements 10 and 10′ are arranged in the fluid inlet- and fluid outlet guide facilities 5 and 5′. On the motor rotor 8 of the conveying part 4, a rotor blading 11 is envisaged which is combined with a back-up ring. The magnetically bearing-located conveying part 4 is rotated by way of the motor stator 7 where, by means of the oppositely located permanent magnetic bearing elements 9, 9′ and 10, 10′ in combination with the axial stabilisers 6, the conveying part is kept in a floating state and the back-up ring provides for an additional hydrodynamic bearing-location of the rotating conveying part 4.



FIG. 2 shows in a schematic illustration the motor rotor 8 with the rotor blading 11 in a cut-open tube-shaped hollow body 1. In accordance with the invention, the back-up ring here is arranged in the end zone of the motor stator 8. The fluid to be conveyed is moved between an internal surface 16 of the back-up ring 13 and the motor rotor 8. A running surface 14 of the back-up ring 13 is moved with a minimum clearance to an internal wall 2 of the tube-shaped hollow body 1.



FIG. 3 shows in schematic illustration an arrangement of two back-up rings 13 and 13′ at the ends of a motor rotor 8. The illustration of the tube-shaped hollow body 1 has been left out here.



FIG. 4 shows a further embodiment, according to the invention, of the back-up ring 13. The internal surface 16 of the back-up ring 13 shows a profile 15. As can be seen in the sectional illustration of the back-up ring 13, the profile 15 is executed here in a bearing-surface similar form. In this case also, the illustration of the tube-shaped hollow body has been waived.


In a further embodiment of the invention, as shown in FIG. 5, a back-up ring 13 is arranged without an illustration of the tube-shaped hollow body 1, and this back-up ring covers the entire axial length of the motor rotor 8 with its blading 11. The conveying of the fluid is also effected here between the internal surface 16 of the back-up ring 13 and the motor rotor 8.


In a further embodiment of the invention, a back-up ring is shown in FIG. 6 whose running surface 14 has a raised running line 17 which facilitates a minimum clearance combined with a minimum friction opposite the internal wall 2 of the tube-shaped hollow body 1.


REFERENCED PARTS LIST




  • 1 Tube-shaped hollow body


  • 2 Internal wall


  • 3 Pump casing


  • 4 conveying part


  • 5 Fluid inlet guide facility


  • 5′ Fluid outlet guide facility


  • 6 Axial stabiliser


  • 7 Motor stator


  • 8 Motor rotor


  • 9 Permanent magnetic bearing element


  • 9′ Permanent magnetic bearing element


  • 10 Permanent magnetic bearing element


  • 10′ Permanent magnetic bearing element


  • 11 Rotor blading


  • 12 Fluid guide blading


  • 12′ Fluid guide blading


  • 13 Back-up ring


  • 13′ Back-up ring


  • 14 Running surface


  • 15 Profile


  • 16 Internal surface


  • 17 Running line


Claims
  • 1. A device for axially conveying fluids, comprising: a tube-shaped hollow body having a constant internal diameter for conducting fluid in an essentially axial manner, a motor stator located outside of the hollow body, a conveying part responsive to the motor stator and arranged within the hollow body in axial alignment with the hollow body, the conveying part including a central motor rotor having a continuous outer surface extending between a first end and a second end, blading fixed to the continuous outer surface for conveying fluid within the hollow body upon rotation of the conveying part by the motor stator, at least one hollow ring fixed to a radial outer portion of the blading defining a hydrodynamic radial bearing, the hollow ring defining the hydrodynamic radial bearing having an inner surface that is radially inwardly bowed toward the central rotor continuous outer surface for conditioning the fluid inflow into the rotor blading of the conveying part, an actively stabilizing magnetic axial bearing, and a passive magnetic radial bearing located within the hollow body, the bearings maintaining the conveying part within the tube-shaped hollow body in proximity to the motor stator.
  • 2. A device according to claim 1, further comprising a fluid inlet guide facility and a fluid outlet guide facility, both of the guide facilities being situated in axial alignment within the tube-shaped hollow body and spaced from opposite ends of the conveying part, a permanent magnet being situated in each of the guide facilities adjacent the conveying part.
  • 3. A device according to claim 1 or claim 2, wherein the blading fixed to the continuous outer surface of the central rotor extends from the first end to the second end, and another permanent magnet is situated in each of the ends of the rotor confronting the guide facilities.
  • 4. A device according to claim 1 or claim 2, wherein the at least one ring defining the hydrodynamic radial bearing comprises at least one hollow, rotationally-symmetrical ring joined to the conveying part.
  • 5. A device according to claim 4, wherein the at least one hollow, rotationally-symmetrical ring defining the hydrodynamic radial bearing is joined circumferentially to the blading at the first end.
  • 6. A device according to claim 5, wherein a second hollow, rotationally-symmetrical ring is joined circumferentially to the blading at the second end.
  • 7. A device according to claim 5, wherein the hollow, rotationally-symmetrical ring defining the hydrodynamic radial bearing extends entirely between the first end and the second end.
  • 8. A device according to claim 4, wherein the at least one hollow, rotationally-symmetrical ring defining the hydrodynamic radial bearing has a cylindrical outer surface spaced from an inner surface of the tube-shaped hollow body.
  • 9. A device according to claim 1, wherein the cylindrical outer surface of the hydrodynamic radial bearing includes an outwardly extending circumferential running line facilitating a minimum clearance and a minimum friction with the internal surface of the tube-shaped hollow body.
  • 10. A device according to claim 1 or claim 2 wherein the at least one hollow ring is non-magnetic.
  • 11. A device for axially conveying fluids, comprising: a tube-shaped hollow body having a constant internal diameter for conducting fluid in an essentially axial manner from a first end to a second end, a motor stator located outside of the hollow body, a conveying part responsive to the motor stator and arranged within the hollow body in axial alignment with the hollow body, the conveying part including a central rotor having a continuous outer surface extending between the first end and the second end, blading fixed to the continuous outer surface for conveying fluid within the hollow body upon rotation of the conveying part by the motor stator, a hollow non-magnetic ring fixed to a radial outer portion of the blading at the first end defining a hydrodynamic radial bearing, the hollow non-magnetic ring defining the hydrodynamic radial bearing having an inner surface that is radially inwardly bowed toward the central rotor continuous outer surface for conditioning the fluid inflow into the rotor blading of the conveying part, an actively stabilizing magnetic axial bearing, and a passive magnetic radial bearing, the bearings maintaining the conveying part within the tube-shaped hollow body in proximity to the motor stator.
Priority Claims (1)
Number Date Country Kind
101 08 810 Feb 2001 DE national
PCT Information
Filing Document Filing Date Country Kind 371c Date
PCT/EP02/01740 2/18/2002 WO 00 2/5/2004
Publishing Document Publishing Date Country Kind
WO02/066837 8/29/2002 WO A
US Referenced Citations (49)
Number Name Date Kind
3139832 Saunders Jul 1964 A
3608088 Dorman et al. Sep 1971 A
4763032 Bramm et al. Aug 1988 A
4779614 Moise Oct 1988 A
4898518 Hubbard et al. Feb 1990 A
4944748 Bramm et al. Jul 1990 A
4957504 Chardack Sep 1990 A
5049134 Golding et al. Sep 1991 A
5078741 Bramm et al. Jan 1992 A
5112200 Isaacson et al. May 1992 A
5126610 Fremerey Jun 1992 A
5147187 Ito et al. Sep 1992 A
5211546 Isaacson et al. May 1993 A
5316440 Kijima et al. May 1994 A
5324177 Golding et al. Jun 1994 A
5326344 Bramm et al. Jul 1994 A
5360317 Clausen et al. Nov 1994 A
5370509 Golding et al. Dec 1994 A
5385581 Bramm et al. Jan 1995 A
5393207 Maher et al. Feb 1995 A
5399074 Nosé et al. Mar 1995 A
5405251 Sipin Apr 1995 A
5507629 Jarvik Apr 1996 A
5575630 Nakazawa et al. Nov 1996 A
5588812 Taylor et al. Dec 1996 A
5601418 Ohara et al. Feb 1997 A
5683231 Nakazawa et al. Nov 1997 A
5686772 Delamare et al. Nov 1997 A
5695471 Wampler Dec 1997 A
5707218 Maher et al. Jan 1998 A
5725357 Nakazeki et al. Mar 1998 A
5729065 Fremery et al. Mar 1998 A
5746575 Westphal et al. May 1998 A
5803720 Ohara et al. Sep 1998 A
5863179 Westphal et al. Jan 1999 A
5947703 Nojiri et al. Sep 1999 A
5951263 Taylor et al. Sep 1999 A
6053705 Schob et al. Apr 2000 A
6080133 Wampler Jun 2000 A
6100618 Schoeb et al. Aug 2000 A
6135729 Aber Oct 2000 A
6234772 Wampler et al. May 2001 B1
6234998 Wampler May 2001 B1
6368075 Fremerey Apr 2002 B1
6368083 Wampler Apr 2002 B1
6688861 Wampler Feb 2004 B2
20020094281 Khanwilkar et al. Jul 2002 A1
20020102169 Wampler Aug 2002 A1
20040234397 Wampler Nov 2004 A1
Foreign Referenced Citations (15)
Number Date Country
3935502 May 1991 DE
583781 Feb 1994 EP
03286775 Dec 1991 JP
05-071492 Mar 1993 JP
06218043 Aug 1994 JP
WO 9307388 Apr 1993 WO
WO 9409274 Apr 1994 WO
WO 9413955 Jun 1994 WO
WO 9500185 Jan 1995 WO
WO 9749440 Dec 1997 WO
WO 9811650 Mar 1998 WO
WO 9811650 Mar 1998 WO
WO 0064030 Oct 2000 WO
WO 0064031 Oct 2000 WO
WO 0064508 Nov 2000 WO
Related Publications (1)
Number Date Country
20040115038 A1 Jun 2004 US