Numerical Assessment of Impeller Features of Centrifugal Blood Pump Based on Fast Hemolysis Approximation Model_Journal of Biomedical Engineering

Authors：

 SHOUChen ^1,2 , GUOYongjun ¹ , SULei ¹ , LIYongqian ¹

1. Shanxi Key Lab of MEMS/NEMS, Northwestern Polytechnical University, Xi'an 710072, China;
2. Xijin Medical Application Company, Xi'an 710077, China;

Corresponding author：

SHOUChen, Email: shouxile@163.com

Keywords：

centrifugal blood pump; impeller profile; computational fluid dynamics; scalar shear stress; hemolysis approximation

DOI：

10.7507/1001-5515.20140239

Video：

Export PDF Favorites Scan Get Citation

Abstract Full text Figures/Tables Video References Cited by

The impeller profile, which is one of the most important factors, determines the creation of shear stress which leads to blood hemolysis in the internal flow of centrifugal blood pump. The investigation of the internal flow field in centrifugal blood pump and the estimation of the hemolysis within different impeller profiles will provide information to improve the performance of centrifugal blood pump. The SST κ-ω with low Reynolds correction was used in our laboratory to study the internal flow fields for four kinds of impellers of centrifugal blood pump. The flow fields included distributions of pressure field, velocity field and shear stress field. In addition, a fast numerical hemolysis approximation was adopted to calculate the normalized index of hemolysis (NIH). The results indicated that the pressure field distribution in all kinds of blood pump were reasonable, but for the log spiral impeller pump, the vortex and backflow were much lower than those of the other pumps, and the high shear stress zone was just about 0.004%, and the NIH was 0.0089.

Citation： SHOUChen, GUOYongjun, SULei, LIYongqian. Numerical Assessment of Impeller Features of Centrifugal Blood Pump Based on Fast Hemolysis Approximation Model. Journal of Biomedical Engineering, 2014, 31(6): 1260-1264. doi: 10.7507/1001-5515.20140239 Copy

1.	张天逸,胡兆燕.心脏辅助与替代装置中的血泵[J].中国组织工程研究,2012,16(40):7544-7552.
2.	程云章,骆宾海,吴文权,等.基于CFD技术的无叶片离心血泵内部流动特性分析研究[J].生物医学工程学杂志,2010,27(5):1133-1137.
3.	胡兆燕,潘友联,陈正龙,等.血液灌注量和破坏指标约束下的无叶片离心血泵结构优选方法的研究[J].生物医学工程学杂志,2012,29(6):1201-1206.
4.	MIZUNUMA H, NAKAJIMA R. Experimental study on shear stress distributions in a centrifugal blood pump[J]. Artif Organs, 2007, 31(7):550-559.
5.	FLUENT 14.0 User's Guide. Lebanon (NH),Fluent Inc,2011.
6.	王芳群,封志刚,曾培,等.基于CFD的离心式人工心脏泵的溶血预测方法[J].中国生物医学工程学报,2006,25(3):338-341,345.
7.	朱来来,张锡文.流线型轴流血泵内部流场与溶血分析[J].应用力学学报,2009,26(4):647-650.
8.	阮晓东,陈松松,钱伟,等.基于溶血性能的离心式旋转血泵设计[J].中国生物医学工程学报,2011,30(3):411-415.
9.	GARON A, FARINAS M I. Fast three-dimensional numerical hemolysis approximation[J]. Artif Organs, 2004, 28(11):1016-1025.
10.	SMITH WA, ALLAIRE P, ANTAKI J, et al. Collected nondimensional performance of rotary dynamic blood pumps[J]. ASAIO J, 2004, 50(1):25-32.
11.	BLUDSZUWEIT C. Three-dimensional numerical prediction of stress loading of blood particles in a centrifugal pump[J]. Artif Organs, 1995, 19(7):590-596.
12.	GIERSIEPEN M, WURZINGER L J, OPITZ R, et al. Estimation of shear stress-related blood damage in heart valve prostheses——in vitro comparison of 25 aortic valves[J]. Int J Artif Organs, 1990, 13(5):300-306.
13.	SONG G, CHUA L P, LIM T M. Numerical study of a bio-centrifugal blood pump with straight impeller blade profiles[J]. Artif Organs, 2010, 34(2):98-104.
14.	APEL J, PAUL R, KLAUS S, et al. Assessment of hemolysis related quantities in a microaxial blood pump by computational fluid dynamics[J]. Artif Organs, 2001, 25(5):341-347.
15.	SONG G, CHUA L P, LIM T M. Numerical study of a centrifugal blood pump with different impeller profiles[J]. ASAIO J, 2010, 56(1):24-29.

1. 张天逸,胡兆燕.心脏辅助与替代装置中的血泵[J].中国组织工程研究,2012,16(40):7544-7552.
2. 程云章,骆宾海,吴文权,等.基于CFD技术的无叶片离心血泵内部流动特性分析研究[J].生物医学工程学杂志,2010,27(5):1133-1137.
3. 胡兆燕,潘友联,陈正龙,等.血液灌注量和破坏指标约束下的无叶片离心血泵结构优选方法的研究[J].生物医学工程学杂志,2012,29(6):1201-1206.
4. MIZUNUMA H, NAKAJIMA R. Experimental study on shear stress distributions in a centrifugal blood pump[J]. Artif Organs, 2007, 31(7):550-559.
5. FLUENT 14.0 User's Guide. Lebanon (NH),Fluent Inc,2011.
6. 王芳群,封志刚,曾培,等.基于CFD的离心式人工心脏泵的溶血预测方法[J].中国生物医学工程学报,2006,25(3):338-341,345.
7. 朱来来,张锡文.流线型轴流血泵内部流场与溶血分析[J].应用力学学报,2009,26(4):647-650.
8. 阮晓东,陈松松,钱伟,等.基于溶血性能的离心式旋转血泵设计[J].中国生物医学工程学报,2011,30(3):411-415.
9. GARON A, FARINAS M I. Fast three-dimensional numerical hemolysis approximation[J]. Artif Organs, 2004, 28(11):1016-1025.
10. SMITH WA, ALLAIRE P, ANTAKI J, et al. Collected nondimensional performance of rotary dynamic blood pumps[J]. ASAIO J, 2004, 50(1):25-32.
11. BLUDSZUWEIT C. Three-dimensional numerical prediction of stress loading of blood particles in a centrifugal pump[J]. Artif Organs, 1995, 19(7):590-596.
12. GIERSIEPEN M, WURZINGER L J, OPITZ R, et al. Estimation of shear stress-related blood damage in heart valve prostheses——in vitro comparison of 25 aortic valves[J]. Int J Artif Organs, 1990, 13(5):300-306.
13. SONG G, CHUA L P, LIM T M. Numerical study of a bio-centrifugal blood pump with straight impeller blade profiles[J]. Artif Organs, 2010, 34(2):98-104.
14. APEL J, PAUL R, KLAUS S, et al. Assessment of hemolysis related quantities in a microaxial blood pump by computational fluid dynamics[J]. Artif Organs, 2001, 25(5):341-347.
15. SONG G, CHUA L P, LIM T M. Numerical study of a centrifugal blood pump with different impeller profiles[J]. ASAIO J, 2010, 56(1):24-29.

Journal of Biomedical Engineering

Numerical Assessment of Impeller Features of Centrifugal Blood Pump Based on Fast Hemolysis Approximation Model

Abstract Full text Figures/Tables Video References Cited by

Previous Article

Next Article

Format

Content