List of the Top 10 convection in porous media you can buy in 2019

When you want to find convection in porous media, you may need to consider between many choices. Finding the best convection in porous media is not an easy task. In this post, we create a very short list about top 10 the best convection in porous media for you. You can check detail product features, product specifications and also our voting for each product. Let’s start with following top 10 convection in porous media:

Best convection in porous media

Product	Features	Go to site
	Convection in Porous Media	Go to amazon.com
	Convection in Porous Media	Go to amazon.com
	Principles of Heat Transfer in Porous Media (Mechanical Engineering Series)	Go to amazon.com
	Convection in Porous Media	Go to amazon.com
	Modeling Approaches to Natural Convection in Porous Media (SpringerBriefs in Applied Sciences and Technology)	Go to amazon.com
	Essentials of Heat and Fluid Flow in Porous Media	Go to amazon.com
	Long time behavior of convection in porous media: Convection in porous media	Go to amazon.com
	Mixed Convection in Porous Media With Heat Source/Sink: With Boundary condition of Third Kind	Go to amazon.com
	Natural Convection in Porous Media: CO2 Sequestration and CO2-Vapex	Go to amazon.com
	Convection in Channels and Porous Media: Analysis, Optimization, and Constructal Design	Go to amazon.com

Related posts:

1. Convection in Porous Media

Description

This new edition includes nearly 1000 new references.

2. Convection in Porous Media

Description

3. Principles of Heat Transfer in Porous Media (Mechanical Engineering Series)

Description

Convective heat tranfer is the result of fluid flowing between objects of different temperatures. Thus it may be the objective of a process (as in refrigeration) or it may be an incidental aspect of other processes. This monograph reviews in a concise and unified manner recent contributions to the principles of convective heat transfer for single- and multi-phase systems: It summarizes the role of the fundamental mechanism, discusses the governing differential equations, describes approximation schemes and phenomenological models, and examines their solutions and applications. After a review of the basic physics and thermodynamics, the book divides the subject into three parts. Part 1 deals with single-medium transfer, specifically with intraphase transfers in single-phase flows and with intramedium transfers in two-phase flows. Part 2 deals with fluid-solid transfer processes, both in cases where the interface is small and in cases where it is large, as well as liquid-liquid transfer processes. Part 3 considers three media, addressing both liquid-solid-solid and gas-liquid-solid systems.

4. Convection in Porous Media

Description

Convection in Porous Media, 4th Edition, provides a user-friendly introduction to the subject, covering a wide range of topics, such as fibrous insulation, geological strata, and catalytic reactors. The presentation is self-contained, requiring only routine mathematics and the basic elements of fluid mechanics and heat transfer. The book will be of use not only to researchers and practicing engineers as a review and reference, but also to graduate students and others entering the field. The new edition features approximately 1,750 new references and covers current research in nanofluids, cellular porous materials, strong heterogeneity, pulsating flow, and more.

5. Modeling Approaches to Natural Convection in Porous Media (SpringerBriefs in Applied Sciences and Technology)

Description

This book provides an overview of the field of flow and heat transfer in porous medium and focuses on presentation of a generalized approach to predict drag and convective heat transfer within porous medium of arbitrary microscopic geometry, including reticulated foams and packed beds. Practical numerical methods to solve natural convection problems in porous media will be presented with illustrative applications for filtrations, thermal storage and solar receivers.

6. Essentials of Heat and Fluid Flow in Porous Media

Feature

Used Book in Good Condition

Description

Knowledge of heat and fluid flow through porous media finds extensive applications in several engineering devices spanning four major divisions: mechanical, civil, chemical, and bioengineering. This textbook fills the knowledge-gap between available research monographs in porous media and basic thermo-fluids courses required to understand such monographs. Coverage includes fluid flow, conduction, convection, and radiation in porous media as well as porous medium aspects of biological systems. The book includes end-of-chapter problems and an appendix of useful convection correlations.

7. Long time behavior of convection in porous media: Convection in porous media

Feature

Long Time Behavior of Convection in Porous Media

Description

This book investigates asymptotic behaviour of convection in a fluid saturated porous medium. We analyse the Darcy-Boussinesq system under perturbation of the Darcy-Prandtl number parameter. In very tightly packed media this parameter is of very large order and can be driven to innity to yield the innite Darcy-Prandtl number model. We show convergence of global attractors and invariant measures of the Darcy-Boussinesq system to that of the innite Darcy-Prandtl number model with respect to perturbation of the Darcy- Prandtl number.

8. Mixed Convection in Porous Media With Heat Source/Sink: With Boundary condition of Third Kind

Description

A numerical study of mixed convection in a vertical channel filled with a porous medium,including the effects of inertia forces, is studied by taking into account the effects of viscous and Darcy dissipations with heat source or sink. The flowis modeled using the Brinkman Forchheimerextended Darcy equations.The plate exchanges heat with an external fluid. Both conditions of equal and of different reference temperatures of the external fluid are considered. The governing equations are solved using RungeKutta fourth-order method with shooting technique for extended Darcy model and analytically using the perturbation series method for the Darcy model. The velocity and temperature fields are obtained for various porous parameters, inertia effect, and perturbation parameters for equal and unequal Biot numbers and are shown graphically. It is also found that both analytical and numerical solutions agree to a great extent with the small values of the perturbation parameter in the absence of inertial forces.

9. Natural Convection in Porous Media: CO2 Sequestration and CO2-Vapex

Description

Natural convection in porous media has been researched for a long time. In this study, the focus is on natural convection in two processes in porous media: CO2-sequestration in deep saline aquifers and CO2-Vapex processes. For the natural convection in saline aquifers, the onset of convection and pattern of instabilities are analyzed for an inclined layer and are compared with a horizontal layer. Then, the effect of thermal instability is added to the problem and a double-diffusion (thermohaline) convection is studied. In the second part the effect of instabilities, if present, is studied in the CO2-Vapex process. The analysis is based on a model for the boundary layer in the interface of CO2 chamber/heavy oil. The effect of dispersion and variation of viscosity in the boundary layer are considered in the analysis.

10. Convection in Channels and Porous Media: Analysis, Optimization, and Constructal Design

Description

Convection in porous media has a large field of application. Firstly, this book presents an analytical and numerical study of the generation and flow of methane gas through a layer of porous medium impregnated with solid clathrate hydrates. Later, design with constructal theory is addressed. We start studying the fundamental problem of maximizing the thermal contact between an entire heat-generating volume and a pulsating stream of coolant that bathes the volume. A series of examples in which the global performance of flow systems is optimized subject to global constraints is also presented. The text continues describing a hierarchical strategy to developing the optimal internal structure of a round heat-generating body cooled at its center with the help of optimally distributed inserts of high-conductivity material. Finally, it considers the fundamental problem of squeezing into a fixed volume the highest heat transfer rate that can be made to occur between two streams at different initial temperatures.

Conclusion

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