Thermal entrance problem for blood flow inside an axisymmetric tube: The classical Graetz problem extended for Quemada’s bio-rheological fluid with axial conduction

Abstract

The heat-conducting nature of blood is critical in the human circulatory system and features also in important thermal regulation and blood processing systems in biomedicine. Motivated by these applications, in the present investigation, the classical Graetz problem in heat transfer is extended to the case of a bio-rheological fluid model. The Quemada bio-rheological fluid model is selected since it has been shown to be accurate in mimicking physiological flows (blood) at different shear rates and hematocrits. The steady two-dimensional energy equation without viscous dissipation in stationary regime is tackled via a separation of variables approach for the isothermal wall temperature case. Following the introduction of transformation variables, the ensuing dimensionless boundary value problem is solved numerically via MATLAB based algorithm known as bvp5c (a finite difference code that implements the four-stage Lobatto IIIa collocation formula). Numerical validation is also presented against two analytical approaches namely, series solutions and Kummer function techniques. Axial conduction in terms of Péclet number is also considered. Typical values of Reynolds number and Prandtl number are used to categorize the vascular regions. The graphical representation of mean temperature, temperature gradient, and Nusselt numbers along with detail discussions are presented for the effects of Quemada non-Newtonian parameters and Péclet number. The current analysis may also have potential applications for the development of microfluidic and biofluidic devices particularly which are used in the diagnosis of diseases in addition to blood oxygenation technologies.

Keywords

Graetz problem Quemada fluid Concentrated suspension S-L boundary value problem Péclet number Newton-Raphson method Simpson’s rule bvp5c

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References

Bureau

Healy

Bourgoin

, et al. Etude Experimentale In Vitro du Comportement Rheologie du Sang et Regime Transitoire a Faible Vitessed e Cisaillement, Rheol. Rheologica Acta 1978; 17:612–625.

Bureau

Healy

Bourgoin

, et al. Rheological hysteresis of blood at low shear rate1. Biorheology 1980; 17:191–203.

Burgreen

Antaki

, et al. Computational Fluid Dynamics as a development tool for rotary blood pumps. Artif Organs 2001; 25(5): 336–340.

Graetz

Uber die Warmeleitungsfahigheit von Flus- singkeiten, part 1. Annalen der Physik und Chemie 1883; 18:79–94. Part 2. 1885; 25: 337–357.

Nusselt

Die Abhangigkeit der Warmeubergangszahl von der Rohrlange (The Dependence of the Heat Transfer Coefficient on the Tube Length). Z ver Deut Ing 1910; 54:1154–1158.

Siegel

Sparrow

Hallman

TM.

Steady laminar heat transfer in a circular tube with prescribed wall heat flux. Appl Sci Res 1958; 7:386–392.

Hsu

CJ.

An exact mathematical solution for entrance region laminar heat transfer with axial conduction. Appl Sci Res 1967; 17:359.

Hsu

CJ.

Exact solution to entry-region laminar heat transfer with axial conduction and the boundary condition of the third kind. Chem Eng Sci 1968; 23:457–468.

Chia-Jung

Theoretical solutions for low-Péclét-number thermal-entry-region heat transfer in laminar flow through concentric annuli. Int J Heat Mass Transf 1970; 13:1907–1924.

10.

Shah

London

AL.

Laminar flow forced convection in ducts. 3rd ed. New York: Academic Press, 1978.

11.

Lahjomri

Oubarra

Analytical solution of the Graetz problem with axial conduction. J Heat Transf 1999; 121:1078–1083.

12.

Johnston

PR.

Axial conduction and the Graetz problem for a Bingham plastic in laminar tube flow. Int J Heat Mass Transf 1991; 34:1209–1217.

13.

Johnston

PR.

A solution method for the Graetz problem for Non-Newtonian fluids with Dirichlet and Neumann boundary conditions. Math Comput Model 1994; 19:1–19.

14.

Coelho

Pinho

Oliveira

PJ.

Thermal entry flow for a viscoelastic fluid, the Graetz problem for the PTT model. Int J Heat Mass Transf 2003; 46:3865–3880.

15.

Oliveira

Coelho

Pinho

FT.

The Graetz problem with viscous dissipation for FENE-P fluids. J Non-Newton Fluid Mech 2004; 121:69–72.

16.

Filali

Khezzar

Siginer

, et al. Graetz problem with non-linear viscoelastic fluids in non-circular tubes. Int J Therm Sci 2012; 61:50–60.

17.

Ali

Khan

MW.

The Graetz problem for the Ellis fluid model. Zeitschrift für Naturforschung A (ZNA) 2019; 74:15–24.

18.

Khan

MWS

Ali

. Theoretical analysis of thermal entrance problem for blood flow: an extension of classical Graetz problem for Casson fluid model using generalized orthogonality relations. Int Commun Heat Mass Transf 2019; 109:104314.

19.

Khan

MWS

Ali

Asghar

Thermal and rheological effects in a classical Graetz problem using a nonlinear Robertson-Stiff fluid model. Heat Transf 2021; 50:2321–2338.

20.

Quemada

. Rheology of concentrated disperse systems II. A model for non-Newtonian shear viscosity in steady flows. Rheologica Acta 1978; 17:632–642.

21.

Das

Enden

Popel

AS.

Stratified multiphase model for blood flow in a venular bifurcation. Ann Biomed Eng 1997; 25(1): 135–153.

22.

Naeofytou

Comparison of blood rheological models for physiological flow simulation. Biorheology 2004; 41(6): 693–714.

23.

Marcinkowska-Gapińska

Gapinski

Elikowski

, et al. Comparison of three rheological models of shear flow behavior studied on blood samples from post-infarction patients. Med Biol Eng Comput 2007; 45:837–844.

24.

Postelnicu

Florea

Pecurariu

. Steady flow in the Willis circle using a Quemada model. PAMM Proc Appl Math Mech 2007; 7: 4020021–4020022.

25.

Sriram

Intaglietta

Tartakovsky

DM.

Non-Newtonian flow of blood in arterioles: consequences for wall shear stress measurements. Microcirculation 2014; 21(7): 628–639.

26.

Easthope

Brooks

DE.

A comparison of rheological constitutive functions for whole human blood. Biorheology 1981; 18:267–268.

27.

Popel

Enden

An analytical solution for steady flow of a Quemada fluid in a circular tube. Rheologica Acta 1993; 32:422–426.

28.

Kreyzig

Advanced Engineering Mathematics. 9th ed. New York: Wiley, 2006.

29.

Haji-Sheikh

Beck

Amos

DE.

Axial heat conduction effects in the entrance region of parallel plate ducts. Int J Heat Mass Transf 2008; 51:5811–5822.

30.

Lahjomri

Oubarra

Alemany

Heat transfer by laminar Hartmann flow in thermal entrance region with a step change in wall temperatures: the Graetz problem extended. Int J Heat Mass Transf 2002; 45:1127–1148.

31.

Mikhailov

Cotta

RM.

Eigenvalues for the Graetz problem in slip-flow. Int Commun Heat Mass Transf 1997; 24:449–451.

32.

Hemadri

Biradar

Shah

, et al. Experimental study of heat transfer in rarefied gas flow in a circular tube with constant wall temperature. Exp Therm Fluid Sci 2018; 93:326–333.

33.

Victor

Shah

VL.

Steady state heat transfer to blood flowing in the entrance region of a tube. Int J Heat Mass Transf 1976; 19:777–783.

34.

Shitzer

Eberhart

RC.

(eds). Heat transfer in medicine and biology. New York: Plenum Press, 1985.

35.

Mashour

Boock

RJ.

Effects of shear stress on nitric oxide levels of human cerebral endothelial cells cultured in an artificial capillary system. Brain Res 1999; 842(1): 233–238.

36.

Quemada

Blood theology and its implications in flow of blood. In: Rodkiewicz

(ed.) Arteries and arterial blood flow. Biological and physiological aspects. New York: Springer Verlag, 1983, pp.1–127.

37.

Popel

Johnson

PC.

Microcirculation and hemorheology. Annu Rev Fluid Mech 2005; 37:43–69.