R. Smith scite author profile

A new microfluidic product for measuring fluid density, specific gravity and chemical concentration has been developed. At the core of this lab-on-a-chip sensor is a vacuum-sealed resonating silicon microtube. Measurements can be made with under a microliter of sample fluid, which is over 1000x less than is conventionally required. Since the product is MEMS-based the overall system size is a fraction of conventional density meters and it weighs much less than the traditional desk-top, temperature controlled, density meters. The syringe or pipette loaded system includes a dynamic temperature control system that operates between 0 degree C and 90 degree C with an accuracy of less than 0.01 degree C. Density measurement accuracies of 4 to 5 digits have been observed with aqueous solutions. Measurement examples and applications will be discussed.

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Shortcut Design Method for Columns Separating Azeotropic Mixtures

Liu

Jobson

Smith

et al. 2004

Ind. Eng. Chem. Res.

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A shortcut method is proposed for the design of columns separating homogeneous azeotropic mixtures. Azeotropes are treated as pseudocomponents, and a C-component system with A azeotropes is treated as an enlarged (C + A)-component system. This enlarged system is divided into compartments, where each compartment behaves like a nonazeotropic distillation region formed by the singular points that appear in it. The compartment boundary is linearly approximated. A procedure is proposed for transforming vapor−liquid equilibrium behavior in terms of pure components into that in terms of singular points, allowing relative volatilities to be characterized in terms of singular points. The classical Fenske−Underwood−Gilliland method can then be used to design columns separating azeotropic mixtures. This method is extremely computationally efficient and can be applied to homogeneous azeotropic mixtures with any number of components. The results of the shortcut design method are useful for initializing rigorous simulations using commercial software.

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A MEMS-Based Coriolis Mass Flow Sensor for Industrial Applications

Smith

Sparks

Riley

et al. 2009

IEEE Trans. Ind. Electron.

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Design and Optimization of Fully Thermally Coupled Distillation Columns

Amminudin¹,

Smith²,

Thong³

et al. 2001

Chemical Engineering Research and Design

133

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R. Smith

Design and Optimization of Fully Thermally Coupled Distillation Columns

Measurement of density and chemical concentration using a microfluidic chip

Shortcut Design Method for Columns Separating Azeotropic Mixtures

A MEMS-Based Coriolis Mass Flow Sensor for Industrial Applications

Design and Optimization of Fully Thermally Coupled Distillation Columns

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