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474 results on '"Massoudi, Mehrdad"'

101. Using CO 2 as a Cooling Fluid for Power Plants: A Novel Approach for CO 2 Storage and Utilization.

Author

Phuoc, Tran X. and Massoudi, Mehrdad

Subjects
GAS power plants, CARBON dioxide, POWER plants, STEAM power plants, JOULE-Thomson effect, HEAT transfer, HEAT transfer fluids, SURFACE area
Abstract

To our knowledge, the potential use of CO2 as a heat-transmitting fluid for cooling applications in power plants has not been explored very extensively. In this paper, we conduct a theoretical analysis to explore the use of CO2 as the heat transmission fluid. We evaluate and compare the thermophysical properties of both dry air and CO2 and perform a simple analysis on a steam-condensing device where steam flows through one of the flow paths and the cooling fluid (CO2 or air) is expanded from a high-pressure container and flows through the other. Sample calculations are carried out for a saturated-vapor steam at 0.008 MPa and 41.5 °C with the mass flow rate of 0.01 kg/s. The pressure of the storage container ranges from 1 to 5 MPa, and its temperature is kept at 35 °C. The pressure of the cooling fluid (CO2 or dry air) is set at 0.1 MPa. With air as the heat-removing fluid, the steam exits the condensing device as a vapor-liquid steam of 53% to 10% vapor for the container pressure of 1 to 5 MPa. With CO2 as the heat-removing fluid, the steam exits the device still containing 44% and 7% vapor for the container pressure of 1 MPa and 2 MPa, respectively. For the container pressure of 3 MPa and higher, the steam exits the device as a single-phase saturated liquid. Thus, due to its excellent Joule–Thomson cooling effect and heat capacity, CO2 is a better fluid for power plant cooling applications. The condensing surface area is also estimated, and the results show that when CO2 is used, the condensing surface is 50% to 60% less than that when dry air is used. This leads to significant reductions in the condenser size and the capital costs. A rough estimate of the amount of CO2 that can be stored and utilized is also carried out for a steam power plant which operates with steam with a temperature of 540 °C (813 K) and a pressure of 10 MPa at the turbine inlet and saturated-vapor steam at 0.008 MPa at the turbine outlet. The results indicate that if CO2 is used as a cooling fluid, CO2 emitted from a 1000 MW power plant during a period of 250 days could be stored and utilized. [ABSTRACT FROM AUTHOR]

Published
2021
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103. Removal of malaria-infected red blood cells using magnetic cell separators: A computational study

Author

Jeongho Kim, Massoudi, Mehrdad, Antaki, James, and Gandini, Alberto

Subjects
90399 Biomedical Engineering not elsewhere classified, FOS: Medical engineering
Abstract

High gradient magnetic field separators have been widely used in a variety of biological applications. Recently, the use of magnetic separators to remove malaria-infected red blood cells (pRBCs) from blood circulation in patients with severe malaria has been proposed in a dialysis-like treatment. The capture efficiency of this process depends on many interrelated design variables and constraints such as magnetic pole array pitch, chamber height, and flow rate. In this paper, we model the malaria-infected RBCs (pRBCs) as paramagnetic particles suspended in a Newtonian fluid. Trajectories of the infected cells are numerically calculated inside a micro-channel exposed to a periodic magnetic field gradient. First-order stiff ordinary differential equations (ODEs) governing the trajectory of particles under periodic magnetic fields due to an array of wires are solved numerically using the 1(st) -5(th) order adaptive step Runge-Kutta solver. The numerical experiments show that in order to achieve a capture efficiency of 99% for the pRBCs it is required to have a longer length than 80 mm; this implies that in principle, using optimization techniques the length could be adjusted, i.e., shortened to achieve 99% capture efficiency of the pRBCs.

Published
2018
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132. Flow of granular materials with slip boundary condition

Author

Zhao, Xinran and Massoudi, Mehrdad

Abstract

2014 , Purdue University, West Lafayette, IN, October 1‑3, 2014. We study the steady fully developed flow of granular materials between two horizontal flat plates, subject to slip at the walls. The constitutive equation used in our study is a model proposed by Rajagopal et al. [1], and the material properties such as viscosity and the normal stress coefficients are derived using the kinetic theory approximation proposed by Boyle and Massoudi [2] which includes the effect of the gradient of volume fraction. The slip boundary condition is based on the particle dynamics simulation results of Rosato and Kim [3]. The governing equations are nondimensionalized, and the resulting system of nonlinear differential equations is solved numerically. The results for the velocity profiles and the volume fraction profiles are presented. REFERENCES [1] Rajagopal, K.R., Massoudi, M., Wineman, A.S. Flow of granular materials between rotating disks. Mechanics Research Communications. 1994, 21, 629–634. [2] Boyle, E.J., Massoudi, M. A theory for granular materials exhibiting normal stress effects based on Enskog’s dense gas theory. Int. J. Engng. Sci. 1990,28(12), 1261–1275. [3] Rosato, A.D., Kim, H. Particle dynamics calculations of wall stresses and slip velocities for Couette flow of smooth inelastic spheres. Continuum Mech. Thermodyn. 1994, 6, 1‑20.

Published
2014

133. Vertical flow of a multiphase mixture in a channel

Author

Massoudi Mehrdad and Rao C. Lakshmana

Subjects
Physics::Fluid Dynamics, Multiphase flow, Granular materials, Mixture theory, Continuum mechanics, Interaction force, lcsh:TA1-2040, lcsh:Mathematics, lcsh:Engineering (General). Civil engineering (General), lcsh:QA1-939
Abstract

The flow of a multiphase mixture consisting of a viscous fluid and solid particles between two vertical plates is studied. The theory of interacting continua or mixture theory is used. Constitutive relations for the stress tensor of the granular materials and the interaction force are presented and discussed. The flow of interest is an ideal one where we assume the flow to be steady and fully developed; the mixture is flowing between two long vertical plates. The non-linear boundary value problem is solved numerically, and the results are presented for the dimensionless velocity profiles and the volume fraction as functions of various dimensionless numbers.

Published
2000

141. Entropy Analysis for a Nonlinear Fluid with a Nonlinear Heat Flux Vector.

Author

Hyunjin Yang, Massoudi, Mehrdad, and Kirwan, A. D.

Subjects
*NONLINEAR analysis, *MATHEMATICAL analysis, *FLUIDS, *FLUID mechanics, *HEAT flux
Abstract

Flowing media in both industrial and natural processes are often characterized as assemblages of densely packed granular materials. Typically, the constitutive relations for the stress tensor and heat flux vector are fundamentally nonlinear. Moreover, these equations are coupled through the Clausius-Duhem inequality. However, the consequences of this coupling are rarely studied. Here we address this issue by obtaining constraints imposed by the Clausius-Duhem inequality on the constitutive relations for both the stress tensor and the heat flux vector in which the volume fraction gradient plays an important role. A crucial result of the analysis is the restriction on the dependency of phenomenological coefficients appearing in the constitutive equations on the model objective functions. [ABSTRACT FROM AUTHOR]

Published
2017
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142. Heat Transfer in Complex Fluids

Author

Massoudi, Mehrdad

Subjects
Computers / Computer Simulation
Abstract

Heat Transfer in Complex Fluids

Published
2011

147. An Anisotropic Constitutive Equation for the Stress Tensor of Blood Based on Mixture Theory

Author

Massoudi, Mehrdad and Antaki, James F.

Subjects
Physics::Fluid Dynamics, Article Subject, Physics::Medical Physics, Quantitative Biology::Cell Behavior
Abstract

Based on ideas proposed by Massoudi and Rajagopal (M-R), we develop a model for blood using the theory of interacting continua, that is, the mixture theory. We first provide a brief review of mixture theory, and then discuss certain issues in constitutive modeling of a two-component mixture. In the present formulation, we ignore the biochemistry of blood and assume that blood is composed of red blood cells (RBCs) suspended in plasma, where the plasma behaves as a linearly viscous fluid and the RBCs are modeled as an anisotropic nonlinear density-gradient-type fluid. We obtain a constitutive relation for blood, based on the simplified constitutive relations derived for plasma and RBCs. A simple shear flow is discussed, and an exact solution is obtained for a very special case; for more general cases, it is necessary to solve the nonlinear coupled equations numerically.

Published
2008
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148. Heat Transfer in a Drilling Fluid with Geothermal Applications.

Author

Wei-Tao Wu, Aubry, Nadine, Antaki, James F., McKoy, Mark L., and Massoudi, Mehrdad

Subjects
HEAT transfer, DRILLING fluids, GEOTHERMAL resources, FLUID flow, SHEAR (Mechanics), NON-Newtonian fluids, THERMAL diffusivity
Abstract

The effects of various conditions on the fluid flow, particle migration and heat transfer in non-linear fluids encountered in drilling and geothermal applications are studied. We assume that the drilling fluid is a suspension composed of various substances, behaving as a non-linear complex fluid, where the effects of particle volume fraction, shear rate, and temperature on the viscosity and thermal diffusivity are considered. The motion of the particles is described using a concentration flux equation. Two problems are studied: flow in a vertical pipe and flow between two (eccentric) cylinders where the inner cylinder is rotating. We consider effects of earth temperature, the rotational speed of the inner cylinder, and the bulk volume fraction on the flow and heat transfer. [ABSTRACT FROM AUTHOR]

Published
2017
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149. Numerical Simulation of Red Blood Cell-Induced Platelet Transport in Saccular Aneurysms.

Author

Wei-Tao Wu, Yubai Li, Aubry, Nadine, Massoudi, Mehrdad, and Antaki, James F.

Subjects
ERYTHROCYTES, ANEURYSMS, COMPUTER simulation
Abstract

We present a numerical simulation of blood flow in two aneurysmal vessels. Using a multicomponent continuum approach, called mixture theory, the velocity fields and spatial distribution of the red blood cells (RBCs) and the plasma are predicted. Platelet migration is described by a convection-diffusion equation, coupled to the RBC concentration field. The model is applied to study a two-dimensional straight vessel and multiple two-dimensional aneurysm vessels with different neck sizes. The model accurately predicts the enrichment of the platelets near the wall in the straight vessel, agreeing with the experimental measurement quantitatively. The numerical results also show that the near-wall enrichment of the platelets in the parent vessel highly influences the platelet concentration within the aneurysm. The results also indicate that the platelet concentration within the aneurysm increases with Reynolds number and decreases with a smaller neck size. This might have significance on the formation of thrombus (blood clot) within the aneurysm, which in turn may have a protective effect on preventing ruptures. Based on the success with the problems studied, we believe the current model can be a useful tool for analyzing the blood flow and platelets transport within patient specific aneurysms in the future. [ABSTRACT FROM AUTHOR]

Published
2017
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150. Heat Transfer and Flow of Nanofluids in a Y-Type Intersection Channel with Multiple Pulsations: A Numerical Study.

Author

Wei-Tao Wu, Massoudi, Mehrdad, and Hongbin Yan

Subjects
*NANOFLUIDS, *HEAT transfer, *PULSATION (Electronics), *PULSE frequency modulation, *PULSE amplitude modulation, *NUSSELT number, *NUMERICAL analysis
Abstract

In this paper, we study pulsed flow and heat transfer in water-Al2O3 nanofluids in a Y-type intersection channel with two inlets and one outlet. At the two inlets, two sinusoidal velocities with a phase difference of π are applied. We assume that the shear viscosity and the thermal conductivity of the nanofluids depend on the nanoparticles concentration. The motion of the nanoparticles is modeled by a convention-diffusion equation, where the effects of the Brownian motion, thermophoretic diffusion, etc., are included. The effects of pulse frequency, pulse amplitude and nanoparticles concentration on the heat transfer are explored numerically at various Reynolds numbers. The results show that the application of the pulsed flow improves the heat transfer efficiency (Nusselt number) for most of the cases studied. Amongst the four factors considered, the effect of the frequency seems to be the most important. [ABSTRACT FROM AUTHOR]

Published
2017
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