Magnetically suspended and rotated rotor
First Claim
1. An artificial heart for implantation in the body of a human subject comprising:
- a first pump comprising a housing having an inlet passage fluidly connectable to the subject'"'"'s left atrium and an outlet passage fluidly connectable to the subject'"'"'s aorta; and
a second pump comprising a housing having an inlet passage connectable to at least one of the subject'"'"'s superior vena cava and inferior vena cava and an outlet passage fluidly connectable to the subject'"'"'s pulmonary artery;
wherein the housing of each of said pumps has an impellor chamber disposed between the housing inlet passage and the housing outlet passage; and
wherein each of said pumps further comprises;
an impellor disposed in the housing impellor chamber and rotatable therein about an impellor rotation axis for drawing blood into the housing inlet passage and discharging blood from the housing outlet passage;
magnetic suspension means disposed partially on the impellor and partially on the housing for magnetically suspending the impellor in said impellor chamber out of contact with the walls of the impellor chamber comprising;
permanent magnet impellor support means comprising an assembly and on the housing for exerting forces on the impellor tending to align the rotation axis of the impellor with a selector support axis of the housing while tending to drive the impellor axially away from a selected null position on said support axis at such times that the impellor is axially displaced from the null position;
an electromagnet mounted on the housing and positioned thereon to exert a force directed along the support axis on portions of the permanent magnet impellor support means disposed on the impellor at such times that an electric current is passed through the electromagnet, the electromagnet thereby exerting an axial force on the impellor; and
electromagnetic control means mounted on the housing for detecting a displacement of the impellor from a control position of the impellor on the support axis and passing a current through the electromagnetic to drive the impellor toward the control position, wherein the electromagnet control means is characterized as comprising means for selecting the control position in a displaced relation to the null position along said support axis, whereby the permanent magnet impellor support means will exert a force on the impellor at such times that the impellor is in the control position, thereby enabling the permanent magnets of the permanent magnet impellor support means to balance a static force exerted axially on the impellor;
impellor drive means disposed partially on the impellor and partially on the housing for turning the impellor about said rotation axis, wherein portions of the impellor drive means disposed on the impellor are coupled solely magnetically to portions of the impellor drive means disposed on the housing; and
wherein the combined center of gravity of the impellor and portions of the impellor drive means and permanent magnet impellor support means disposed thereon of each of the first and second pumps is positioned at the center of buoyancy of the impellor, and wherein a cavity is formed in the impellor to match the average specific gravity of the impellor and portions of the drive means and the permanent magnet impellor support means thereon to the specific gravity of blood.
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Accused Products
Abstract
The impellor of a blood pump is supported by permanent magnets on the impellor and pump housing and stabilized by an electromagnet on the housing. A control circuit supplies current to the electromagnet to maintain the axial position of the impellor at a control position in which the impellor is in mechanical equilibrium under permanent magnet forces and static axial forces on the impellor to minimize energy consumption in the support of the impellor. The impellor is rotated magnetically and stator coils in the housing are supplied with electric currents having a frequency and amplitude adjusted in relation to blood pressure at the pump inlet to match the flow characteristics of the pump to physiological characteristics of the natural heart. A cavity is formed in the impellor to match the average specific gravity of the impellor and portions of the suspension and drive systems thereon to the specific gravity of blood to further minimize power consumption by the pump. A valve member can be formed on the impellor to mate with a restriction in the pump inlet for pumps used to assist the pumping action of the natural heart.
152 Citations
2 Claims
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1. An artificial heart for implantation in the body of a human subject comprising:
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a first pump comprising a housing having an inlet passage fluidly connectable to the subject'"'"'s left atrium and an outlet passage fluidly connectable to the subject'"'"'s aorta; and a second pump comprising a housing having an inlet passage connectable to at least one of the subject'"'"'s superior vena cava and inferior vena cava and an outlet passage fluidly connectable to the subject'"'"'s pulmonary artery; wherein the housing of each of said pumps has an impellor chamber disposed between the housing inlet passage and the housing outlet passage; and
wherein each of said pumps further comprises;an impellor disposed in the housing impellor chamber and rotatable therein about an impellor rotation axis for drawing blood into the housing inlet passage and discharging blood from the housing outlet passage; magnetic suspension means disposed partially on the impellor and partially on the housing for magnetically suspending the impellor in said impellor chamber out of contact with the walls of the impellor chamber comprising; permanent magnet impellor support means comprising an assembly and on the housing for exerting forces on the impellor tending to align the rotation axis of the impellor with a selector support axis of the housing while tending to drive the impellor axially away from a selected null position on said support axis at such times that the impellor is axially displaced from the null position; an electromagnet mounted on the housing and positioned thereon to exert a force directed along the support axis on portions of the permanent magnet impellor support means disposed on the impellor at such times that an electric current is passed through the electromagnet, the electromagnet thereby exerting an axial force on the impellor; and electromagnetic control means mounted on the housing for detecting a displacement of the impellor from a control position of the impellor on the support axis and passing a current through the electromagnetic to drive the impellor toward the control position, wherein the electromagnet control means is characterized as comprising means for selecting the control position in a displaced relation to the null position along said support axis, whereby the permanent magnet impellor support means will exert a force on the impellor at such times that the impellor is in the control position, thereby enabling the permanent magnets of the permanent magnet impellor support means to balance a static force exerted axially on the impellor; impellor drive means disposed partially on the impellor and partially on the housing for turning the impellor about said rotation axis, wherein portions of the impellor drive means disposed on the impellor are coupled solely magnetically to portions of the impellor drive means disposed on the housing; and wherein the combined center of gravity of the impellor and portions of the impellor drive means and permanent magnet impellor support means disposed thereon of each of the first and second pumps is positioned at the center of buoyancy of the impellor, and wherein a cavity is formed in the impellor to match the average specific gravity of the impellor and portions of the drive means and the permanent magnet impellor support means thereon to the specific gravity of blood. - View Dependent Claims (2)
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Specification