Sage Journals: Discover world-class research

Abstract

This paper presents a comparison of manufacturing techniques used in the development of an axial blood pump impeller. In this development process the impeller was designed and its performance was evaluated with the aid of computational fluid dynamics (CFD). Prototypes of those designs where the CFD results show promise were needed in sufficient quantities at a low cost for experimental validation of the CFD results. As the impeller is less than 16 mm in diameter with a maximum blade thickness of about 1.5 mm, innovative manufacturing techniques are explored in this paper to determine the best process for quick fabrication of prototypes that are dimensionally accurate, structurally robust and low in cost. Four rapid prototyping techniques were explored. The completed parts were compared on the basis of manufacturing time, quality and strength of parts obtained, manufacturing cost and also in vitro performances. Based on these studies, it was concluded that selective laser sintering (SLS) is the most appropriate method for the quick production of prototype parts for evaluation of pump performance.

Keywords

computational fluid dynamics rapid prototyping selective laser sintering axial blood pump impeller

Get full access to this article

View all access options for this article.

References

Frazier

O. H.

Myers

T. J.

Jarvik

R. K.

Westaby

Pigott

D. W.

Gregoric

I. D.

Tehreen

Khan

Tamez

D. W.

Conger

J. L.

Macris

M. P.

Research and development of an implantable, axial-flow left ventricular assist device: The Jarvik 2000 Heart. Ann. Thoracic Surgery, 2001, 71 (3), S125–132.

Wieselthaler

G. M.

Schima

Dworschak

Quittan

Nuhr

Czerny

Seebacher

Huber

Grimm

Wolner

First experiences with outpatient care of patients with implanted axial flow pumps. Artif. Organs, 2001, 25 (5), 331–335.

Burgreen

G. W.

Antaki

J. F.

Z. J.

Holmes

A. J.

Computational fluid dynamics as a development tool for rotary blood pumps. Artif. Organs, 2001, 25 (5), 336–340.

Nakamura

Yano

Computational simulation of flows in an entire centrifugal heart pump. Artif. Organs, 1999, 23 (6), 572–575.

Apel

Neudel

Reul

Computational fluid dynamics and experimental validation of a microaxial blood pump. Artif. Organs, September-October 2001, 47 (5), 552–558.

Curtas

A. R.

Wood

H. G.

Allaire

P. E.

McDaniel

J. C.

Day

S. W.

Olsen

D. B.

Computational fluid dynamics modeling of impeller designs for the HeartQuest left ventricular assist device. Artif. Organs, September-October 2002, 48 (5), 552–561.

Wurzinger

L. J.

Opitz

Eckstein

Mechanical blood trauma—an overview. Angeiologie, 1986, 38, 81–97.

Giersiepen

Wurzinger

L. J.

Opitz

Reul

Estimation of shear stress-related blood damage in heart valve prosthesis—in vitro comparison of 25 aortic valves. Int. J. Artif. Organs, 1990, 13 (5), 300–306.

Bludszuweit

Model for a general blood damage prediction. Artif. Organs, 1995, 19, 583–589.

10.

Papantonis

Croba

Numerical calculation of the performances and shear stresses developed on centrifugal blood pumps. In Proceedings of the International Workshop on

Rotary Blood Pumps, Vienna, 1988, pp. 53–60.

11.

Pinotti

Rosa

E. S.

Computational prediction of hemolysis in a centrifugal ventricular assist device. Artif. Organs, 1995, 19 (3), 267–272.

12.

Chan

W. K.

Wong

Y. W.

Ding

Chua

L. P.

S. C. M.

Numerical investigation of the effect of blade geometry on blood trauma in a centrifugal blood pump. Artif. Organs, 2002, 26 (9), 734–742.

13.

H. D.

Chan

W. K.

Inverse design and CFD investigation of blood pump impeller. Crit. Rev. Biomed. Engng, 2000, 28 (1), 75–80.

14.

Beaman

J. J.

Laser

J. R.

Sintering for desktop manufacturing. Machine Des., March 1990, 26, 65–66.

15.

Thakker

Sheahan

Frawley

Khaleeq

H. B.

Innovative manufacture of impulse turbine blades for wave energy power conversion. J. Engng Mf., 2002, 216-B, 1053–1059.

Rapid manufacturing techniques in the development of an axial blood pump impeller

Abstract

Abstract

Keywords

Get full access to this article

References