Numerical computations of magnetohydrodynamic mixed convective flow of Casson nanofluid in an open-ended cavity formed by earthquake-induced faults

doi:10.1007/s10483-024-3190-9

摘要/Abstract

Abstract:

The numerical computations for the magnetohydrodynamic (MHD) mixed convective flow of a non-Newtonian Casson nanofluid (Cu/H$_2$O) within an open-ended cavity formed by earthquake-induced faults are analyzed, aiming to investigate the fluid dynamics and convection processes of geothermal systems. Such cavities, typically found in energy reservoirs, are primarily caused by tensional fault zones formed due to the accumulated energy from the disintegration of radioactive materials. These cavities play a crucial role in energy transmission, particularly in the form of heat. The focus of this paper is on the laminar, steady, and incompressible fluid flow. An inclined magnetic field is applied with an angle of inclination $z=30^{\circ}$. Additionally, a heated material with two vertical corrugated walls is placed at the center of the cavity. The governing nonlinear partial differential equations (PDEs) are transformed into the equations with a non-dimensional form. The Galerkin finite element method (FEM) is implemented to solve the dimensionless equations. The impacts of key variables, including the Reynolds number $Re$, the volume fraction $(0.01\leqslant \phi_{\rm p}\leqslant 0.05)$, the Hartmann number $Ha$, and the Casson parameter $(0.5\leqslant \gamma\leqslant 1.0)$, on the velocity and temperature distributions are studied. The analysis of the fluid flow and the heat transfer rate is conducted. The results indicate that the velocity increases as the volume fraction and the Reynolds number increase. Similarly, the heat transfer rate rises with the Reynolds number and the volume fraction, while decreases with the higher Hartmann number. The Nusselt number increases with the volume fraction and the Reynolds number but decreases with the Hartmann number.

Key words: nanofluid, magnetohydrodynamic (MHD), Casson fluid, mixed convection, finite element method (FEM)

中图分类号:

74S05
76A05

. [J]. Applied Mathematics and Mechanics (English Edition), 2024, 45(12): 2215-2230.

M. IBTESAM, S. NADEEM, J. ALZABUT. Numerical computations of magnetohydrodynamic mixed convective flow of Casson nanofluid in an open-ended cavity formed by earthquake-induced faults[J]. Applied Mathematics and Mechanics (English Edition), 2024, 45(12): 2215-2230.

图/表 21

参考文献 29

1	OHNAKA, M. The Physics of Rock Failure and Earthquakes, Cambridge University Press, Cambridge 148 (2013)
2	PARK, R. G. Foundation of Structural Geology, Routledge, Oxfordshire (1997)
3	PEACOCK, D. C. P., KNIPE, R. J., and SANDERSON, D. J. Glossary of normal faults. Journal of Structural Geology, 22, 291- 305 (2000)
4	HONGSEN, X., WEI, W., WENGE, Z., HAIFEI, Z., GENLI, S., and WEIGUO, Z. Materials Science of the Earth's Interior, Terra Sci. Publ. Company, Tokyo (2000)
5	NADEEM, S., AKBER, R., ALMUTAIRI, S., GHAZWANI, H. A., and MAHMOUD, O. Numerical analysis of hydrothermal flow and heat transfer inside a cavity formed due to faults causing earthquakes. Frontiers in Physics, 10, 959168 (2022)
6	HUSSIEN, A. A., AL-KOUZ, W., EL HASSAN, M., JANVEKAR, A. A., and CHAMKHA, A. J. A review of flow and heat transfer in cavities and their applications. The European Physical Journal Plus, 136 (4), 353 (2021)
7	SAHA, G., AL-WAALY, A. A., PAUL, M. C., and SAHA, S. C. Heat transfer in cavities: configurative systematic review. Energies, 16 (5),2338 (2023)
8	VALENCIA, A., and FREDERICK, R. L. Heat transfer in square cavities with partially active vertical walls. International Journal of Heat and Mass Transfer, 32 (8), 1567- 1574 (1989)
9	CHAMKHA, A. J., HUSSAIN, S. H., and ABD-AMER, Q. R. Mixed convection heat transfer of air inside a square vented cavity with a heated horizontal square cylinder. Numerical Heat Transfer, Part A: Applications, 59 (1), 58- 79 (2011)
10	AKRAM, B., ULLAH, N., NADEEM, S., and ELDIN, S. M. Simulations for MHD mixed convection in a partially heated lid-driven chamfered enclosure. Numerical Heat Transfer, Part A: Applications, (2023) doi: 10.1080/10407782.2023.2242581
11	ALSABERY, A. I., ISMAEL, M. A., CHAMKHA, A. J., and HASHIM, I. Mixed convection of Al₂O₃-water nanofluid in a double lid-driven square cavity with a solid inner insert using Buongiorno's two-phase model. International Journal of Heat and Mass Transfer, 119, 939- 961 (2018)
12	SIDDIKI, M. N. A. A., ISLAM, S., AHMMED, M. U., and MOLLA, M. M. Numerical simulation of a non-Newtonian nanofluid on mixed convection in a rectangular enclosure with two rotating cylinders. International Journal of Ambient Energy, 45 (1), 2332525 (2024)
13	CHAMKHA, A. J., and AL-NASER, H. Double-diffusive convection in an inclined porous enclosure with opposing temperature and concentration gradients. International Journal of Thermal Sciences, 40 (3), 227- 244 (2001)
14	SELIMEFENDIGIL, F., OZTOP, H. F., SHEREMET, M. A., and ABU-HAMDEH, N. Forced convection of Fe₃O₄-water nanofluid in a bifurcating channel under the effect of variable magnetic field. Energies, 12 (4), 666 (2019)
15	CASSON, N. Flow equation for pigment-oil suspensions of the printing ink-type. Rheology of Disperse Systems, Pergamon Press, New York, 84–104 (1959)
16	SRIVASTAVA, N. The Casson fluid model for blood flow through an inclined tapered artery of an accelerated body in the presence of magnetic field. International Journal of Biomedical Engineering and Technology, 15 (3), 198- 210 (2014)
17	PRIYADHARSHINI, S., and PONALAGUSAMY, R. Mathematical modelling for pulsatile flow of Casson fluid along with magnetic nanoparticles in a stenosed artery under external magnetic field and body acceleration. Neural Computing and Applications, 31, 813- 826 (2019)
18	SHAHZAD, H., WANG, X., GHAFFARI, A., IQBAL, K., HAFEEZ, M. B., KRAWCZUK, M., and WOJNICZ, W. Fluid structure interaction study of non-Newtonian Casson fluid in a bifurcated channel having stenosis with elastic walls. Scientific Reports, 12 (1), 12219 (2022)
19	ALHADHRAMI, A., VISHALAKSHI, C. S., PRASANNA, B. M., SREENIVASA, B. R., ALZAHRANI, H. A., GOWDA, R. P., and KUMAR, R. N. Numerical simulation of local thermal non-equilibrium effects on the flow and heat transfer of non-Newtonian Casson fluid in a porous media. Case Studies in Thermal Engineering, 28, 101483 (2021)
20	CHOI, S. U. and EASTMAN, J. A. Enhancing Thermal Conductivity of Fluids with Nanoparticles, Argonne National Lab., Lemont (1995)
21	NADEEM, S., ULLAH, N., and KHAN, A. U. Finite element simulations for natural convective flow of nanofluid in a rectangular cavity having corrugated heated rods. Journal of Thermal Analysis and Calorimetry, 143, 4169- 4181 (2021)
22	CHO, C. C., YAU, H. T., and CHEN, C. K. Enhancement of natural convection heat transfer in a U-shaped cavity filled with Al₂O₃-water nanofluid. Thermal Science, 16 (5), 1317- 1323 (2012)
23	ASMADI, M. S., KASMANI, R. M., SIRI, Z., and SALEH, H. Thermal enhancement effects of buoyancy-driven heat transfer of hybrid nanofluid confined in a tilted U-shaped cavity. Journal of Applied Fluid Mechanics, 15 (2), 337- 348 (2022)
24	ULLAH, N., NADEEM, S., and SALEEM, A. Finite element analysis of convective nanofluid equipped in enclosure having both inlet and outlet zones. Journal of the Taiwan Institute of Chemical Engineers, 113, 428- 441 (2020)
25	SHEIKHOLESLAMI, M., and VAJRAVELU, K. J. A. M. Nanofluid flow and heat transfer in a cavity with variable magnetic field. Applied Mathematics and Computation, 298, 272- 282 (2017)
26	GHASEMI, B., and AMINOSSADATI, S. Magnetic field effect on convection in a nanofluid-filled square enclosure. International Journal of Thermal Sciences, 50, 1748- 1756 (2011)
27	SHEIKHOLESLAMI, M., BANDPY, M. G., ELLAHI, R., and ZEESHAN, A. Simulation of MHD CuO-water nanofluid flow and convective heat transfer considering Lorentz forces. Journal of Magnetism and Magnetic Materials, 369, 69- 80 (2014)
28	NADEEM, S., SALMA, R., ULLAH, N., ALZABUT, J., and GHAZWANI, H. A. Numerical solutions for MHD mixed convection flow in a square wavy cavity inside heated corrugated rods. International Communications in Heat and Mass Transfer, 149, 107136 (2023)
29	LIAO, C. C., LI, W. K., and CHU, C. C. Analysis of heat transfer transition of thermally driven flow within a square enclosure under effects of inclined magnetic field. International Communications in Heat and Mass Transfer, 130, 105817 (2022)

Number of triangular mesh elements	$Nu_{\rm A}$
Number of triangular mesh elements	$Re=200$	$Re=400$
7 052	18.671 6	19.382 3
9 244	18.672 4	19.382 9
14 144	18.673 1	19.383 7
23 000	18.673 9	19.384 5
49 612	18.674 3	19.384 8
65 132	18.674 4	19.384 9

Number of triangular elements	$Nu_{\rm A}$
Number of triangular elements	Ref. [5]	Present
1 236	2.859 0	2.864 3
2 348	2.863 9	2.872 9
2 879	2.865 5	2.875 7
3 001	2.866 1	2.876 6
3 930	2.866 4	2.877 1

Characteristic	Cu	H$_2$O
Thermal expansion	$1.67\times 10^{-5}$	$2.1\times 10^{-4}$
Thermal resistivity/$({\rm W}\cdot {\rm m}^{-1}\cdot {\rm K}^{-1})$	401	0.62
Density/$({\rm kg}\cdot {\rm m}^{-3})$	8 933.0	997.0
Electrical conductivity/$({\rm S}\cdot {\rm m}^{-1})$	$5.96\times 10^7$	0.050
Specific heat capacity/$({\rm J}\cdot {\rm kg}^{-1}\cdot {\rm K}^{-1})$	385	4 179

[1]	. [J]. Applied Mathematics and Mechanics (English Edition), 2024, 45(12): 2147-2164.
[2]	. [J]. Applied Mathematics and Mechanics (English Edition), 2024, 45(6): 947-962.
[3]	. [J]. Applied Mathematics and Mechanics (English Edition), 2024, 45(5): 747-762.
[4]	Feiyang HE, Zhiyu SHI, Denghui QIAN, Y. K. LU, Yujia XIANG, Xuelei FENG. Flexural wave bandgap properties of phononic crystal beams with interval parameters[J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(2): 173-188.
[5]	Zheng GONG, Yinxiao ZHANG, Ernian PAN, Chao ZHANG. Three-dimensional general magneto-electro-elastic finite element model for multiphysics nonlinear analysis of layered composites[J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(1): 53-72.
[6]	Xiaokang DU, Yuanzhao CHEN, Jing ZHANG, Xian GUO, Liang LI, Dingguo ZHANG. Nonlinear coupling modeling and dynamics analysis of rotating flexible beams with stretching deformation effect[J]. Applied Mathematics and Mechanics (English Edition), 2023, 44(1): 125-140.
[7]	Dong WU, Yixing HUANG, Ming LEI, Zeang ZHAO, Xiaogang GUO, Daining FANG. Stiffness and toughness of soft/stiff suture joints in biological composites[J]. Applied Mathematics and Mechanics (English Edition), 2022, 43(10): 1469-1484.
[8]	Junning ZHANG, Shaopu YANG, Shaohua LI, Yongjie LU, Hu DING. Influence of vehicle-road coupled vibration on tire adhesion based on nonlinear foundation[J]. Applied Mathematics and Mechanics (English Edition), 2021, 42(5): 607-624.
[9]	Zixuan LU, Liang GUO, Hongyu ZHAO. Mechanics of nonbuckling interconnects with prestrain for stretchable electronics[J]. Applied Mathematics and Mechanics (English Edition), 2021, 42(5): 689-702.
[10]	Yingli SHI, Junyun JI, Yafei YIN, Yuhang LI, Yufeng XING. Analytical transient phase change heat transfer model of wearable electronics with a thermal protection substrate[J]. Applied Mathematics and Mechanics (English Edition), 2020, 41(11): 1599-1610.
[11]	Dongxing CAO, Wei XIA, Wenhua HU. Low-frequency and broadband vibration energy harvester driven by mechanical impact based on layer-separated piezoelectric beam[J]. Applied Mathematics and Mechanics (English Edition), 2019, 40(12): 1777-1790.
[12]	Jin ZENG, Hui MA, Kun YU, Zhitao XU, Bangchun WEN. Coupled flapwise-chordwise-axial-torsional dynamic responses of rotating pre-twisted and inclined cantilever beams subject to the base excitation[J]. Applied Mathematics and Mechanics (English Edition), 2019, 40(8): 1053-1082.
[13]	Yun CUI, Yafei YIN, Chengjun WANG, K. SIM, Yuhang LI, Cunjiang YU, Jizhou SONG. Transient thermo-mechanical analysis for bimorph soft robot based on thermally responsive liquid crystal elastomers[J]. Applied Mathematics and Mechanics (English Edition), 2019, 40(7): 943-952.
[14]	Dongxing CAO, Yanhui GAO. Free vibration of non-uniform axially functionally graded beams using the asymptotic development method[J]. Applied Mathematics and Mechanics (English Edition), 2019, 40(1): 85-96.
[15]	Si YUAN, Yue WU, Qinyan XING. Recursive super-convergence computation for multi-dimensional problems via one-dimensional element energy projection technique[J]. Applied Mathematics and Mechanics (English Edition), 2018, 39(7): 1031-1044.