Transient rotating electromagnetohydrodynamic micropumps between two infinite microparallel plates

Jian, Yongjun; Si, Dongqing; Chang, Long; Liu, Quansheng

doi:10.1016/j.ces.2015.04.036

Cited by 45 publications

(24 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Further studies include Homsy et al [11] for direct current high density micropumps, Vaibhayetal. [12] who also studied electro-osmotic effects, Zhao et al [13] for alternating current MHD micropumps, Pal et al [14] for ferrofluid thermo-magnetic micropumps, Kabbani et al [15] for both DC and AC systems, Jian [16] for rotating EM micro-pumps. These works have generally neglected Hall current effects.…”

Section: U Sir Is a DI Git Al C Oll E C Tio N Of T H E R E S E A R C mentioning

confidence: 99%

Slip and Hall Current Effects on Jeffrey Fluid Suspension Flow in a Peristaltic Hydromagnetic Blood Micropump

Ramesh

Tripathi

Bég

et al. 2018

Iran J Sci Technol Trans Mech Eng

View full text Add to dashboard Cite

show abstract

Section: U Sir Is a DI Git Al C Oll E C Tio N Of T H E R E S E A R C mentioning

confidence: 99%

Slip and Hall Current Effects on Jeffrey Fluid Suspension Flow in a Peristaltic Hydromagnetic Blood Micropump

Ramesh

Tripathi

Bég

et al. 2018

Iran J Sci Technol Trans Mech Eng

View full text Add to dashboard Cite

show abstract

“…1,2 Because of the numerous applications of microflow in a rotating channel, many researchers have investigated several aspects of the underlying transport features of rotational microfluidics considering both the Newtonian and non-Newtonian fluids in recent years. [3][4][5][6][7] Although the flow of nanofluids in a rotating microfluidic platform is of vital importance for several reasons, the underlying effect is not well explored to date. We would like to mention here a few important motivating factors for the present analysis: first, to explore the physics involved with the flow dynamics of nanofluids in a rotating narrow fluidic pathway under influence of electro-magnetic forcing, while the second one is essentially from the perspective of its huge applications, typically in controlling the microflows, micro-mixing, reduction in clogging and essentially for system miniaturization.…”

Section: Introductionmentioning

confidence: 99%

Magneto-hydrodynamic (MHD) micropump of nanofluids in a rotating microchannel under electrical double-layer effect

Mondal

2020

Proceedings of the Institution of Mechanical Engineers, Part E:

View full text Add to dashboard Cite

We investigate the electroosmosis of nanofluid in a rotating microfluidic channel under the influence of an applied magnetic field. We bring out the rotation-induced complex flow dynamics in the channel as modulated by the nanoparticle driven modifications in the viscous drag. In particular, we observe the flow reversal at the center of the channel, emerging from an intricate competition among different forcings under consideration. We identify the critical rotation Reynolds number, signifying the critical strength of channel rotation relative to the viscous resistance to the flow, for which the flow reversal at the channel center sets in. We demonstrate that the strength of the flow reversal for higher rotation Reynolds number decreases, since higher rotation Reynolds number breaks the interparticle interactions, leading to an enhancement in the effective viscosity of the fluid. Finally, we explain the consequential effects of colloidal suspensions of nanoparticle as realized through the particle concentration and agglomeration size on the alterations in the volume transport rates in the channel.

show abstract

“…For a natural convection stream, the conversation of mass, momentum, transfer of heat, and mass under the impact of body force, electrically conductive, electroosmotic flow, chemically reactive, and thermal heat‐absorbing fluid in a porous medium are given by 1–3,24,25,33–35

\begin{matrix} left \\ \frac{\partial u'}{\partial t'} = ν (1 + \frac{1}{γ}) \frac{\partial^{2} u'}{\partial y'^{2}} + g β' (T' - T_{\infty}^{true'}) + g β^{*} (C' - C_{\infty}^{true'}) + \frac{ρ_{e} E_{x}}{ρ} - \frac{μ u'}{ρ k'} - \frac{σ * B_{0}^{2} u'}{ρ}, \end{matrix}

ρ c_{p} \frac{\partial T'}{\partial t'} - K \frac{\partial^{2} T'}{\partial y'^{2}} + Q_{0} (T' - T_{\infty}^{'}) = 0,

\frac{\partial C'}{\partial t'} - D \frac{\partial^{2} C'}{\partial {y'}^{2}} + α' (C' - C_{\infty}^{'}) = 0 .

and the boundary conditions for the above fluid flow are assumed by

\begin{matrix} left \\ (\begin{matrix} left \\ u' = 0 \\ T' = T_{\infty}^{true'} \\ C' = C_{\infty}^{true'} \end{matrix}\} for t' \leq 0 and y' \geq 0<...> \end{matrix}

…”

Section: Mathematical Analysismentioning

confidence: 99%

“…There are special benefits to the combined application of electric and magnetic fields, which cannot be separately recognized in any field. Jian et al 33 used experimental techniques to explore the unstable electromagnetohydrodynamics (EMHD) movement of an electrically conductive, incompressible, and Newtonian fluid among twofold slit microparallel plates in the presence of an external electric current applied and a magnetic field. Owing to the large rise in flow velocity, the supporting component of the Lorentz force was slightly greater than the inhibiting factor for a broad range of magnetic field operations relative to the electric field in the axial and lateral directions.…”

Section: Introductionmentioning

confidence: 99%

Impact of electroosmotic flow on a Casson fluid driven by chemical reaction and convective boundary conditions

Vijayaragavan

Bharathi²,

Prakash³

2021

Heat Trans

View full text Add to dashboard Cite

A numerical and theoretical review of the electroosmosis flow effect on a transient state Casson fluid by natural convection stream past an exponentially accelerated plate is provided in this report. Additionally, porous medium, thermal radiation, magnetic field, electric field, ramped wall temperature and isothermal concentration are taken into consideration. The equation of Poisson–Boltzmann is used to depict the electrical potential profile within the fluid medium linearized by the Debye–Hückel implementation. Using the Laplace transform technique, the analytical solutions of momentum, energy, and concentration equations are determined. The obtained solutions of axial velocity, fluid temperature, and concentration expressions are diagrammatically revealed, and numerical results for the number of Nusselt are also obtained for critical related flow parameters. The natural convection of ramped wall temperature was also compared to the isothermal system. With the increase in Joule heating parameter, mass Grashof number, Prandtl number, and chemical reaction parameter, the velocity has been reduced for both the case of ramped and isothermal wall temperatures (RIWT). The uses of the RIWT are applicable to clean nuclear plant wastewater, food manufacturing, drilling operations, and bioengineering operations.

show abstract

Transient rotating electromagnetohydrodynamic micropumps between two infinite microparallel plates

Cited by 45 publications

References 43 publications

Slip and Hall Current Effects on Jeffrey Fluid Suspension Flow in a Peristaltic Hydromagnetic Blood Micropump

Slip and Hall Current Effects on Jeffrey Fluid Suspension Flow in a Peristaltic Hydromagnetic Blood Micropump

Magneto-hydrodynamic (MHD) micropump of nanofluids in a rotating microchannel under electrical double-layer effect

Impact of electroosmotic flow on a Casson fluid driven by chemical reaction and convective boundary conditions

Contact Info

Product

Resources

About