Axial magnetic bearing development for the BiVACOR rotary BiVAD/TAH

IEEE Transactions on Biomedical Engineering

Volumn 57, Issue 3, 2010, Pages 714-721

  Greatrex, Nicholas A ^a   Timms, Daniel L ^b   Kurita, Nobuyuki ^c   Palmer, Edward W ^a   Masuzawa, Toru ^d  

^a QUEENSLAND UNIVERSITY OF TECHNOLOGY   (Australia)

^b RWTH AACHEN UNIVERSITY   (Germany)

^c GUNMA UNIVERSITY   (Japan)

^d IBARAKI UNIVERSITY   (Japan)

Author keywords

Artificial biological organs; Blood pumps; Electromagnetic forces; Magnetic levitation

Indexed keywords

ARTIFICIAL HEART; ASSIST DEVICE; AXIAL DIRECTION; AXIAL MOVEMENT; BLOOD DAMAGE; BLOOD PUMP; DEVICE LIFETIME; ELECTROMAGNETIC FORCES; FLOW BALANCING; HYDRODYNAMIC BEARINGS; MAGNETIC BEARING SYSTEMS; MAGNETIC SUSPENSION SYSTEM; OPERATING POINTS; OPERATING SPEED; POWER CONSUMPTION; RADIAL DIRECTION; SEMI-OPEN CENTRIFUGAL IMPELLER; SUSPENSION SYSTEM;

ARTIFICIAL ORGANS; BEARING CAPACITY; BEARINGS (STRUCTURAL); BIOLOGICAL ORGANS; BLOOD; BLOWERS; CENTRIFUGATION; FLUID DYNAMICS; GLYCEROL; HYDRODYNAMICS; JOURNAL BEARINGS; MAGNETIC BEARINGS; MAGNETIC LEVITATION; MAGNETIC LEVITATION VEHICLES; MAGNETIC MATERIALS; MAGNETISM; PUMPS;

SUSPENSIONS (COMPONENTS);

GLYCEROL;

ARTICLE; ARTIFICIAL HEART; BLOOD PUMP; FORCE; HYDRODYNAMICS; IMPELLER; MAGNETIC FIELD; MOVEMENT PERCEPTION; SOLUTION AND SOLUBILITY; STEADY STATE; VELOCITY;

CENTRIFUGATION; COMPUTER SIMULATION; ELECTROMAGNETIC FIELDS; EQUIPMENT DESIGN; HEART-ASSIST DEVICES; MAGNETICS;

EID: 77649162846     PISSN: 00189294     EISSN: None     Source Type: Journal    
DOI: 10.1109/TBME.2009.2033389     Document Type: Article

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