DE00939518T1 - BLOOD PUMP WITH MAGNETIC STORAGE - Google Patents

Abstract

Blood pump for driving blood through the pump, with:
a pump housing having a pump axis and having an inlet opening and an outlet opening at opposite axial ends of the pump housing;
a rotor having a rotor axis and having opposite rotor axial ends;
a magnetic suspension device within the pump housing at the rotor axial ends for magnetic suspension of the rotor without physical contact with the housing and in order to form fluid gaps between the rotor axial ends and the magnetic suspension device and to essentially maintain the radial stability of the rotor so that the rotor axis is essentially equally extending during operation remains to the pump axis;
control means for maintaining the axial stability of the rotor so that the rotor can absorb external axial forces to maintain the fluid gaps and the axial distance between the rotor and the pump housing;
Blowing agents on the rotor, which are effective for drawing blood into the inlet opening and for dispensing the blood through the outlet opening during the rotation of the ...

Claims (44)

Blood pump for driving blood through the pump, With: a pump housing, which has a pump axis and an inlet opening and an outlet opening opposite Axial ends of the pump housing having; a rotor that has a rotor axis and opposite Has rotor axial ends; a magnetic suspension device inside the pump housing at the rotor axial ends for magnetic suspension of the rotor without physical contact of the housing and fluid gaps between the rotor axial ends and the magnetic suspension to form and the radial stability of the rotor essentially to keep up with that during the operation of the rotor axis essentially in the same direction the pump axis remains; a control device for maintenance the axial stability of the rotor so that the rotor absorbs external axial forces can help maintain fluid gaps and axial clearance between the rotor and the pump housing; Propellant on the Rotors that are effective for drawing blood into the inlet opening and for dispensing blood through the outlet opening while the rotor is rotating; one Drive device for driving the rotor and the propellant to pump the blood; and a blood rinsing device during Rotation of the rotor continuously draws blood through the fluid gaps drive to prevent blood clotting in the fluid gaps. The blood pump of claim 1, wherein the rotor is cylindrical rotor housing which is formed by a cylindrical wall which is coaxial to the rotor axis and non-magnetic circular cross walls to each Has axial end. The blood pump of claim 2, wherein the cylindrical Wall and the transverse walls are tightly attached to each other to seal the interior of the rotor housing. The blood pump of claim 1, wherein the magnetic suspension magnetic field generating means for building axially directed fields through the fluid column at each axial end of the Rotor. The blood pump of claim 4, wherein the hanger has a support member at each axial end of the rotor, the Support parts along the pump axis and essentially centrally in the pump housing and at predetermined axial distances are arranged around the rotor, at each axial end of the rotor, to form the fluid gaps that are between the pump axis and the radially extreme Extend the area of the rotor. The blood pump of claim 5, wherein the support members are inlet and have readout panels designed around one streamlined To create an outline and to reduce flow turbulence and separation the inlet opening or the readout opening. The blood pump of claim 5, wherein each support member has one active bearing coil includes at least one component of the generate axially directed fields and a permanent magnet within each axial end of the rotor is provided around a second component to generate the axially directed fields through the column. The blood pump of claim 7, wherein each active bearing coil is associated with a magnetizable yoke through which the axially directed fields flow, with each yoke arranged in this way is so that the axially directed fields extend through the fluid gaps in alignment with the peripheral peripheries of the rotor axial ends. The blood pump of claim 8, wherein pole pieces on each Axial end of the rotor are provided, which are associated with an Permanent magnet cooperate to the second components of the axially directed fields adjacent to the peripheries of the rotor axial ends to judge. Blood pump according to claim 9, wherein the pole pieces and the yokes are magnetizable parts that have associated fluid gaps are axially spaced from each other, the magnetizable parts shaped as radially spaced, essentially central edge rings are, which have cross-sectional areas in radial planes, which are smaller are than the cross-sectional areas the permanent magnet around the magnetic flux density through the fluid gaps between associated, radially opposite edge rings strengthen. The blood pump of claim 1, wherein the fluid column dimensioned essentially the same at both axial ends of the rotor are for an essentially equal blood flow and flush both axial ends of the rotor. The blood pump of claim 7, wherein the permanent magnets determine a magnetic axis at each axial end of the rotor, which is essentially the same extension to the pump axis and the rotor axis. The blood pump of claim 7, wherein each permanent magnet is radial at each axial end of the rotor is magnetized. The blood pump of claim 5, wherein each of the support members encloses an active bearing coil to produce a component the axially directed fields and a permanent magnet to generate one second component of the axially directed fields, one being magnetizable Yoke is attached to each axial end of the rotor around a return path for the axially directed one To create fields in the rotor. The blood pump of claim 1, wherein the flushing device to rinse of the fluid gap at the inlet opening has an axial inlet hole substantially along the Pump axis arranged, open at one axial end in the direction of the inlet opening, and at the other axial end in fluid flow communication with an associated one Fluid gap is thus at least some of the blood flowing into the inlet opening passed through the axial inlet hole and the associated fluid gap becomes. The blood pump of claim 1, wherein the flushing device to rinse of the fluid gap at the outlet end has an axial outlet hole having an axial end that is in fluid flow communication with a fluid gap is at the outlet end and in the direction of the outlet opening on other axial end is open; and has deflection means by at least some of the propellant driven through the pump housing To divert blood into the associated fluid gap so blood can flow through the fluid gap at the outlet opening flows and flows through the other axial end into the outlet opening. The blood pump of claim 1, wherein the blood rinsing device has at least one projection which is attached to the rotor and protrudes into the fluid gap, the protrusion being the centrifugal flow of the Blood increases with the rotor speed. The blood pump of claim 17, wherein the at least a projection in the form of at least one radial rib is. The blood pump of claim 18, wherein a plurality of radial ribs are provided on the rotor, which are in the fluid gap at the inlet opening extend, and wherein the radial ribs around the rotor axis in one Are spaced apart from each other. The blood pump of claim 1, wherein the rotor is an im Has essentially cylindrical rotor housing with a cylindrical Wall that has an axis that is parallel to the Rotor axis is and an outer, cylindrical surface has the, with the pump housing, forms a ring channel for the blood flow from the inlet opening to the outlet opening, and the propellants include a plurality of axially aligned helical blades have, which is provided on at least one axial length of the outer cylindrical surface are, the blades being at substantially the same angle are spaced from each other about the rotor axis and the helical blades an incline and a length so that they are at least in the direction of view along the rotor axis partly overlap in the circumferential direction the back leakage to minimize. The blood pump of claim 20, wherein three helical blades are provided and each blade is at an angle of 130 degrees the rotor axis extends for a 10 degree overlap with adjacent, helical blades. The blood pump of claim 1, wherein the control device has effective storage coils, which are part of the magnetic suspension device are and are arranged to deviate the axial positions of the Determine rotor, as well as means for creating an attacking rotor Differential pressure due to the deviations. The blood pump of claim 22, wherein the control device a feedback control circuit with virtual zero power (VZP) for axial stabilization of the rotor based on the determined axial speed of the rotor and the coil current. The blood pump of claim 1, wherein the pump housing and the propellants are arranged around the blood axially between the inlet opening and the outlet opening to pump. The blood pump of claim 1, wherein the pump housing and the propellants are designed centrifugally around the blood in a radial direction to drive. The blood pump of claim 1, wherein the control device Has means for creating a desired, cyclical, differential pressure change on the rotor to achieve pulsating blood flow through the pump. The blood pump of claim 26, wherein the control device Has means for adjusting the frequency of the pulsating flow and a feedback loop has to compare the selected, set frequency and differential pressure with the in function the axial position of the piston. The blood pump of claim 1, wherein the pump housing and propellants are configured for axial blood flow, and further tan potential-to-axial flow alignment means to align the tangential blood flow at the outlet end caused by rotation of the propellant into an axial flow to prevent turbulence and stall at the outlet end. The blood pump of claim 28, wherein the flow alignment means a variety of curved Have blades at the outlet end, with successive, curved blades different axial lengths have additional peripheral space to create which is necessary is to achieve a desired one Flow cross-sectional area to Flow rate adjustment at the inlet to the alignment device. The blood pump of claim 1, wherein the drive device has a permanent magnet that is essentially axial, central in the rotor is arranged to determine a center of gravity of the rotor, and stator coils on the pump housing, which are essentially axially aligned with the center of gravity, thus equal radial forces on the magnetically suspended Axial ends exercised can be. The blood pump of claim 1, wherein the blood rinsing device Has active around the blood through the fluid gaps during the agent Drive rotation of the rotor. The blood pump of claim 31, wherein the blood flushing device has at least one Archimedean screw to deflect blood at the pump inlet opening and the licked blood through the fluid gap at the inlet port float. The blood pump of claim 31, wherein the blood flushing device has at least one Archimedean screw around blood actively to aspirate the fluid gap at the pump outlet opening and the aspirated Blood to the pump outlet to lead. The blood pump of claim 15, further comprising means to prevent blood stagnation in the axial inlet hole. The blood pump of claim 34, wherein the means for change the blood stagnation has at least one element that differs from The rotor extends at least partially into the axial inlet hole to move the blood in the hole as the rotor rotates. The blood pump of claim 35, wherein the element is eccentric is arranged with respect to the rotor axis. The blood pump of claim 16, further comprising means to prevent blood stagnation in the axial outlet hole. The blood pump of claim 37, wherein the means for Prevention of blood stagnation has an element that differs from The rotor extends at least partially into the axial outlet hole to move the blood in the hole as the rotor rotates. The blood pump of claim 38, wherein the element is eccentric is arranged with respect to the rotor axis. Blood pump for driving blood through the pump, With: a pump housing, that has a pump axis and an inlet opening and an outlet opening in the pump housing having; a rotor that has a rotor axis and opposite Has rotor axial ends; a suspension device within the pump housing on the rotor axial ends for hanging of the rotor for rotation in the housing and around fluid gaps between the rotor axial ends and the suspension device to form and the radial stability of the rotor essentially to keep up with that during the operation of the rotor axis essentially in the same direction the pump axis remains; a control device for maintenance the axial stability of the rotor so that the rotor absorbs external axial forces can be used to maintain fluid gaps and axial spacing between the rotor and the pump housing; Propellant on the Rotors that are effective for drawing blood into the inlet opening and for dispensing blood through the outlet opening while the rotor is rotating; one Drive device for driving the rotor and the propellant to pump the blood; and a blood rinsing device during Rotation of the rotor continuously blood actively through the fluid column to drive to prevent blood clotting in the fluid gaps. A blood pump for driving blood through the pump, comprising: a pump housing having a pump axis and having an inlet opening and an outlet opening in the pump housing; a rotor having a rotor axis and having opposite rotor axial ends; a suspension device within the pump housing at the rotor axial ends for suspending the rotor for rotation in the housing and to form fluid gaps between the rotor axial ends and the suspension device and to substantially maintain the radial stability of the rotor so that during operation the rotor axis is essentially the same extent as the pump axis remains; a permanent magnet device for generating strong axial fields over the fluid gaps to ensure the radial rigidity and stability of the rotor during operation of the pump; control means for maintaining the axial stability of the rotor so that the rotor can absorb external axial forces to maintain the fluid gaps and the axial distance between the rotor and the pump housing; Propellants on the rotor which are effective for drawing blood into the inlet opening and for dispensing the blood through the outlet opening during the rotation of the rotor; drive means for driving the rotor and propellants to pump the blood; and a blood rinsing device for continuously driving blood through the fluid gaps during the rotation of the rotor in order to prevent blood clotting in the fluid gaps. Blood pump for driving blood through the pump, With: a pump housing, that has a pump axis and an inlet opening and an outlet opening in the pump housing having; a rotor that has a rotor axis and opposite Has rotor axial ends; a suspension device within the pump housing on the rotor axial ends for hanging of the rotor for rotation in the housing and around fluid gaps between the rotor axial ends and the suspension device to form and the radial stability of the rotor essentially to keep up with that during the operation of the rotor axis essentially in the same direction the pump axis remains; a control device for maintenance the axial stability of the rotor so that the rotor absorbs external axial forces can help maintain fluid gaps and axial clearance between the rotor and the pump housing;  Propellant on the Rotors that are effective for drawing blood into the inlet opening and for dispensing blood through the outlet opening while the rotor is rotating; one Drive device for driving the rotor and the propellant to pump the blood; and a blood rinsing device during Rotation of the rotor continuously draws blood through the fluid gaps drive to prevent blood clotting in the fluid gaps, wherein the rotor has a substantially cylindrical rotor housing with a cylindrical wall that has an axis that is straight with the rotor axis and an outer, cylindrical surface has the, with the pump housing, forms a ring channel for the blood flow from the inlet opening to the outlet opening, and the propellants include a plurality of axially aligned helical blades have, which is provided on at least one axial length of the outer cylindrical surface are, the blades being at substantially the same angle are spaced apart from one another about the rotor axis and the helical blade is one Slope and a length have so that they are at least in the direction of view along the rotor axis Overlap part in the circumferential direction about the back leakage to minimize. Blood pump for driving blood through the pump, With: a pump housing, that has a pump axis and is an inlet opening and an outlet opening the pump housing having; a rotor that has a rotor axis and opposite Has rotor axial ends; a suspension device within the pump housing at the rotor axial ends for magnetic suspension of the rotor for rotation in the housing and around fluid gaps between the rotor axial ends and the suspension device to form and the radial stability of the rotor essentially to keep up with that during the operation of the rotor axis essentially in the same direction the pump axis remains; a control device for maintenance the axial stability of the rotor so that the rotor absorbs external axial forces can help maintain fluid gaps and axial clearance between the rotor and the pump housing; Propellant on the Rotors that are effective for drawing blood into the inlet opening and for dispensing blood through the outlet opening while the rotor is rotating; one Drive device for driving the rotor and the propellant to pump the blood; and a blood rinsing device during Rotation of the rotor continuously draws blood through the fluid gaps drive to prevent blood clotting in the fluid gaps, being the pump housing and the propellants are designed for axial blood flow, and furthermore with tangential-to-axial flow alignment means around the tangential blood flow caused by rotation of the propellant at Outlet end in an axial flow to align to create turbulence and stall at the outlet end to prevent. A blood pump for driving blood through the pump, comprising: a pump housing having a pump axis and having an inlet opening and an outlet opening in the pump housing; a rotor having a rotor axis and having opposite rotor axial ends; a suspension device within the pump housing at the rotor axial ends for suspending the rotor for rotation in the housing and for flu to form a gap between the rotor axial ends and the suspension device and to substantially maintain the radial stability of the rotor so that during operation the rotor axis remains essentially the same extent as the pump axis; a control device for maintaining the axial stability of the rotor so that the rotor can absorb external axial forces to maintain the fluid gaps and the axial distance between the rotor and the pump housing; Propellants on the rotor which are effective for drawing blood into the inlet opening and for dispensing the blood through the outlet opening during the rotation of the rotor; drive means for driving the rotor and propellants to pump the blood; and a blood rinsing device for continuously driving blood through the fluid gaps during the rotation of the rotor to prevent blood clotting in the fluid gaps, the control device comprising means which are arranged for detecting the axial speed of the rotor and means for building up on the rotor differential pressure due to changes in speed to provide physiological control of the pump in response to a patient's heartbeat rhythm, which is substantially proportional to mean differential pressures between systolic and diastolic blood pressure.