Development of a blood flow model including hypergravity and validation against an analytical model

M.H.A. Geel, van; C.G. Giannopapa; B.J. Linden, van der; J.M.B. Kroot

Development of a blood flow model including hypergravity and validation against an analytical model

M.H.A. Geel, van, C.G. Giannopapa, B.J. Linden, van der, J.M.B. Kroot

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

Abstract

Fluid structure interaction (FSI) appears in many areas of engineering, e.g. biomechanics, aerospace, medicine and other areas and is often motivated by the need to understand arterial blood flow. FSI plays a crucial role and cannot be neglected when the deformation of a solid boundary affects the fluid behavior and vice versa. This interaction plays an important role in the wave propagation in liquid filled flexible vessels. Additionally, the effect of hyper gravity under certain circumstances should be taken into account, since such exposure can cause alterations in the wave propagation underexposed. Typical examples in which hyper gravity occurs are rollercoaster rides and aircraft or spacecraft flights. This paper presents the development of an arterial blood flow model including hyper gravity. This model has been developed using the finite element method along with the ALE method. This method is used to couple the fluid and structure. In this paper straight and tapered aortic analogues are included. The obtained computational data for the pressure is compared with analytical data available.

Original language	English
Title of host publication	Proceedings of the ASME 2010 Pressure Vessels and Piping Division/K-PVP Conference (PVP2010, Bellevue WA, USA, July 18-22, 2010)
Publisher	American Society of Mechanical Engineers
Pages	109-115
ISBN (Print)	978-079184923-1
Publication status	Published - 2010

Cite this

Geel, van, M. H. A., Giannopapa, C. G., Linden, van der, B. J., & Kroot, J. M. B. (2010). Development of a blood flow model including hypergravity and validation against an analytical model. In Proceedings of the ASME 2010 Pressure Vessels and Piping Division/K-PVP Conference (PVP2010, Bellevue WA, USA, July 18-22, 2010) (pp. 109-115). American Society of Mechanical Engineers.

@inproceedings{7dcee0fc303148efafcc485e5c41d696,

title = "Development of a blood flow model including hypergravity and validation against an analytical model",

abstract = "Fluid structure interaction (FSI) appears in many areas of engineering, e.g. biomechanics, aerospace, medicine and other areas and is often motivated by the need to understand arterial blood flow. FSI plays a crucial role and cannot be neglected when the deformation of a solid boundary affects the fluid behavior and vice versa. This interaction plays an important role in the wave propagation in liquid filled flexible vessels. Additionally, the effect of hyper gravity under certain circumstances should be taken into account, since such exposure can cause alterations in the wave propagation underexposed. Typical examples in which hyper gravity occurs are rollercoaster rides and aircraft or spacecraft flights. This paper presents the development of an arterial blood flow model including hyper gravity. This model has been developed using the finite element method along with the ALE method. This method is used to couple the fluid and structure. In this paper straight and tapered aortic analogues are included. The obtained computational data for the pressure is compared with analytical data available.",

author = "\{Geel, van\}, M.H.A. and C.G. Giannopapa and \{Linden, van der\}, B.J. and J.M.B. Kroot",

year = "2010",

language = "English",

isbn = "978-079184923-1",

pages = "109--115",

booktitle = "Proceedings of the ASME 2010 Pressure Vessels and Piping Division/K-PVP Conference (PVP2010, Bellevue WA, USA, July 18-22, 2010)",

publisher = "American Society of Mechanical Engineers",

address = "United States",

}

Development of a blood flow model including hypergravity and validation against an analytical model. / Geel, van, M.H.A.; Giannopapa, C.G.; Linden, van der, B.J. et al.
Proceedings of the ASME 2010 Pressure Vessels and Piping Division/K-PVP Conference (PVP2010, Bellevue WA, USA, July 18-22, 2010). American Society of Mechanical Engineers, 2010. p. 109-115.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

TY - GEN

T1 - Development of a blood flow model including hypergravity and validation against an analytical model

AU - Geel, van, M.H.A.

AU - Giannopapa, C.G.

AU - Linden, van der, B.J.

AU - Kroot, J.M.B.

PY - 2010

Y1 - 2010

N2 - Fluid structure interaction (FSI) appears in many areas of engineering, e.g. biomechanics, aerospace, medicine and other areas and is often motivated by the need to understand arterial blood flow. FSI plays a crucial role and cannot be neglected when the deformation of a solid boundary affects the fluid behavior and vice versa. This interaction plays an important role in the wave propagation in liquid filled flexible vessels. Additionally, the effect of hyper gravity under certain circumstances should be taken into account, since such exposure can cause alterations in the wave propagation underexposed. Typical examples in which hyper gravity occurs are rollercoaster rides and aircraft or spacecraft flights. This paper presents the development of an arterial blood flow model including hyper gravity. This model has been developed using the finite element method along with the ALE method. This method is used to couple the fluid and structure. In this paper straight and tapered aortic analogues are included. The obtained computational data for the pressure is compared with analytical data available.

AB - Fluid structure interaction (FSI) appears in many areas of engineering, e.g. biomechanics, aerospace, medicine and other areas and is often motivated by the need to understand arterial blood flow. FSI plays a crucial role and cannot be neglected when the deformation of a solid boundary affects the fluid behavior and vice versa. This interaction plays an important role in the wave propagation in liquid filled flexible vessels. Additionally, the effect of hyper gravity under certain circumstances should be taken into account, since such exposure can cause alterations in the wave propagation underexposed. Typical examples in which hyper gravity occurs are rollercoaster rides and aircraft or spacecraft flights. This paper presents the development of an arterial blood flow model including hyper gravity. This model has been developed using the finite element method along with the ALE method. This method is used to couple the fluid and structure. In this paper straight and tapered aortic analogues are included. The obtained computational data for the pressure is compared with analytical data available.

M3 - Conference contribution

SN - 978-079184923-1

SP - 109

EP - 115

BT - Proceedings of the ASME 2010 Pressure Vessels and Piping Division/K-PVP Conference (PVP2010, Bellevue WA, USA, July 18-22, 2010)

PB - American Society of Mechanical Engineers

ER -

Development of a blood flow model including hypergravity and validation against an analytical model

Abstract

Fingerprint

Cite this