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Page 1: MHD Electrolyte Flow within an Inter-electrode Gap Driven ... · machining (PECM) allows micro-scale geometries with excellent finishes for high performance materials. Magnetic fields

Value Units

Anode 7075 Al

Electrolyte NaNO3 20%

IEG 390 μm

B-Field0.053-

935mT

E-Field

Frequency

0.25-

250kHz

MHD Electrolyte Flow within an Inter-electrode Gap Driven by a

Sinusoidal Electric Field and Constant Magnetic FieldC. Bradley1, J. Samuel2

1. U.S. Army RDECOM-ARDEC, Benét Laboratories, Watervliet, NY, USA

2. Department of Mechanical, Aerospace, & Nuclear Engineering, Rensselaer Polytechnic Institute, Troy, NY, USA

Introduction: Pulsed electrochemical

machining (PECM) allows micro-scale

geometries with excellent finishes for high

performance materials. Magnetic fields

assist electrolyte flow in the inter-electrode

gap (IEG), creating a complex

magnetohydrodynamic (MHD) flow [1].

Computational Methods: First the E-field is

solved, then the Lorentz force and fluid

velocity are solved simultaneously using the

Navier-Stokes equations for incompressible

laminar flow [2],

, ,

Fig. 2 shows a COMSOL 5.2™ simulation of

flow cell IEG.

Results: Electrochemical impedance

spectroscopy (EIS) measures conductance

as a function of B-field magnitude and E-

field frequency in Fig. 3. MHD simulation

results in Fig. 4 show |u| also as a function

of B-field magnitude and E-field frequency.

Conclusions: The EIS results suggest

operating at a high frequency to maximize

conductivity. The MHD suggests minimizing

frequency and maximizing the magnetic

field to maximize electrolyte |u|. Combining

EIS with MHD suggests an optimum E-field

frequency to maximize electrolyte |u|.

Figure 2. IEG MHD flow velocity magnitude |u|

Figure 3. EIS |Y| Figure 4. MHD |u|

Table 1. EIS Conditions

Figure 5. EIS |Y| Combined with MHD |u|

Figure 1. EIS Flow cell w/ magnets

The velocity results from the EIS

combined with the MHD in Fig. 5.

Tool

Workpiece

References:1. O. Lioubashevski, Magnetic field effects on electrochemical

processes: a theoretical hydrodynamic model, J. Phys.

Chem. B, 108, (2004) 5778-5784

2. L. Aoki, An MHD Study of the Behavior of an Electrolyte

Solution using3D Numerical Simulation and Experimental

results, Proceeding of COMSOL conference. Boston,

Volume, (2013)

Excerpt from the Proceedings of the 2017 COMSOL Conference in Boston

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