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Convection in the boundary layer with uniform heat flux from a rectangular cavity’s side walls enclosed by porous lining

  • D. R. Sasi Rekha
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Applied Engineering Mathematics
This chapter is in the book Applied Engineering Mathematics

Abstract

In this study, buoyancy-drivenbuoyancy-driven convectionconvection in a rectangular enclosurerectangular enclosure occupied with liquid and confined by a porousporous lining is analyzed. The Beavers–JosephBeavers–Joseph (BJBJ) slip condition works on the porousporous liquid interface. Continuous heat flows through the verticalvertical side walls, causing heating and cooling. The boundary-layer boundary layer system was studied analytically that the boundary-layer system the boundary layer boundary layer thickness must be independent of altitude has no bearing on the boundary layer boundary layer, that the core be linearly stratified and immobile, and that the temperature temperature of the vertical vertical walls must unceasingly fluctuate with the same gradient as the core temperature temperature. Numerous applications include heat exchangers, insulation, solar-energy collection and storage, furnaces, and electronic heat management based on porous porous linings. Due to the decrease in surface friction, slip increases the flow rate. BJ-slip has the effect of speeding up heat transmission. A tightly bound porous membrane increases heat transferheat transfer. Consequently, the porous lining can be used as an efficient insulator.

Abstract

In this study, buoyancy-drivenbuoyancy-driven convectionconvection in a rectangular enclosurerectangular enclosure occupied with liquid and confined by a porousporous lining is analyzed. The Beavers–JosephBeavers–Joseph (BJBJ) slip condition works on the porousporous liquid interface. Continuous heat flows through the verticalvertical side walls, causing heating and cooling. The boundary-layer boundary layer system was studied analytically that the boundary-layer system the boundary layer boundary layer thickness must be independent of altitude has no bearing on the boundary layer boundary layer, that the core be linearly stratified and immobile, and that the temperature temperature of the vertical vertical walls must unceasingly fluctuate with the same gradient as the core temperature temperature. Numerous applications include heat exchangers, insulation, solar-energy collection and storage, furnaces, and electronic heat management based on porous porous linings. Due to the decrease in surface friction, slip increases the flow rate. BJ-slip has the effect of speeding up heat transmission. A tightly bound porous membrane increases heat transferheat transfer. Consequently, the porous lining can be used as an efficient insulator.

Chapters in this book

  1. Frontmatter I
  2. Preface V
  3. Contents VII
  4. Love wave propagation in layered piezoelectric structures for sensor-based applications 1
  5. A safe-ML model for assessing head loss in a subject-specific human femoral arterial network 11
  6. Fluid dynamics of transportation of viscoelastic fluids through inclined circular cylindrical tubes and its application in biological systems 31
  7. Numerical computation of Crane-type MHD Casson (blood type) stagnation point fluid flow past a stretching sheet 45
  8. Bioconvective MHD Casson fluid flow with motile microorganisms on a moving flat plate embedded in a porous medium 59
  9. Stability analysis of convection in rotating fluid layers with triple diffusion 73
  10. Groundwater contamination in heterogeneous semi-infinite aquifers for 1-D flow 85
  11. Convection in the boundary layer with uniform heat flux from a rectangular cavity’s side walls enclosed by porous lining 99
  12. Natural convection in a rectangular cavity bounded by porous lining 113
  13. Analysis of delayed mosquito life-cycle model 127
  14. Reflection and transmission of plane waves between two initially stressed rotating nonlocal orthotropic microstretch thermoelastic half-spaces with imperfect interface 137
  15. Nonlocal thermoelasticity of Klein–Gordon type: constitutive modelling in a piezoelectric microbeam resonator with memory effect 159
  16. Mathematical perspectives on biomechanical signal processing 179
  17. Numerical simulation of thermal performance in a hybrid nanofluid filled chamber with a heat producing element 221
  18. Non-Darcian flow of bioconvective viscoelastic fluid in a convectively heated elongating surface with variable heat source and energy activation 239
  19. Finite element analysis of biological systems 255
  20. Numerical analysis of free convective heat-transfer characteristics of a non-Newtonian (Casson) fluid in a heated permeable cavity under the effects of thermal radiation 279
  21. Graph-theoretical insights into resting-state EEG: a mathematical approach to psychiatric disorder analysis 289
  22. Index 317
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