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Abstract

This paper is primarily concerned with the feasibility of modelling the flow of electro-structured fluids (ESFs) by the use of computational fluid dynamics (CFD). The non-steady performance of specimen devices in which power, force, or torque is transmitted via an ESF is predicted. This is achieved by incorporating a Bingham plastic type model into a commercial CFD package. Adequately describing the rheology of these fluids requires the use of several parameters. The presence of plug flow and unsteady terms in the equations of motion adds a certain complexity, and a future view of including heat transfer, field distributions, and electrical conductance adds even more difficulty. For enabling practical device development/ optimization studies that incorporate these features, an approach utilizing a well-endowed CFD package for this purpose is near essential. The results are verified by experiments that represent a wide range of flow situations. For experimentation, an electrorheological (ER) fluid is used as the test medium on the grounds of convenience owing to the current availability of a reliable fluid with some characterization. However, the CFD procedures apply both to ER and to magnetorheological (MR) fluids.

Keywords

electrostructured fluid electrorheological fluid magnetorheological fluid smart fluid unsteady flow computational fluid dynamics

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Modelling the flow of an electrostructured fluid in transient operation

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