Your search keyword '"Shearing PR"' showing total 3 results

1. Packed bed compression visualisation and flow simulation using an erosion-dilation approach.

Author

Johnson TF, Iacoviello F, Hayden DJ, Welsh JH, Levison PR, Shearing PR, and Bracewell DG

Subjects

Cellulose chemistry, Porosity, Pressure, Computer Simulation, Rheology methods

Abstract

X-ray computed tomography has been demonstrated to be capable of imaging 1 mL (5 mm diameter, 50 mm height) chromatography packed beds under compression, visualising the 3D structure and measuring changes to geometry of the packing. 1 mL pre-packed columns did not exhibit any structural changes at vendor specified flow rate limits, however cellulose beds did compress at higher flow rates that were imaged before, during and after flow. This was used to visualise and quantitate changes to porosity, tortuosity and permeability based on simulation of flow through the packed bed structure using the imaging data. When using a high flow rate it was found that a decrease in porosity could be measured during compression before reverting after flow had ceased, with corresponding changes to tortuosity and permeability also occurring. X-ray CT imaging of packed beds and individual beads exposed to foulant-rich process streams resulted in considerable image quality loss, associated with residual biological material. In order to address this, digital processing using an erosion-dilation method was applied at bead and bed scales to computationally alter the porosity by adding or removing material from the existing surface to calculate the impact upon tortuosity factor. The eroded and dilated bead volumes of agarose, cellulose and ceramic materials were used to simulate diffusivity whilst mimicking internal bead pore constriction and blocking mechanisms., (Copyright © 2019. Published by Elsevier B.V.)

Published

2020

2. Three dimensional characterisation of chromatography bead internal structure using X-ray computed tomography and focused ion beam microscopy.

Author

Johnson TF, Bailey JJ, Iacoviello F, Welsh JH, Levison PR, Shearing PR, and Bracewell DG

Subjects

Chromatography instrumentation, Imaging, Three-Dimensional, Porosity, Software, Microscopy, Tomography, X-Ray Computed

Abstract

X-ray computed tomography (CT) and focused ion beam (FIB) microscopy were used to generate three dimensional representations of chromatography beads for quantitative analysis of important physical characteristics including tortuosity factor. Critical-point dried agarose, cellulose and ceramic beads were examined using both methods before digital reconstruction and geometry based analysis for comparison between techniques and materials examined. X-ray 'nano' CT attained a pixel size of 63 nm and 32 nm for respective large field of view and high resolution modes. FIB improved upon this to a 15 nm pixel size for the more rigid ceramic beads but required compromises for the softer agarose and cellulose materials, especially during physical sectioning that was not required for X-ray CT. Digital processing of raw slices was performed using software to produce 3D representations of bead geometry. Porosity, tortuosity factor, surface area to volume ratio and pore diameter were evaluated for each technique and material, with overall averaged simulated tortuosity factors of 1.36, 1.37 and 1.51 for agarose, cellulose and ceramic volumes respectively. Results were compared to existing literature values acquired using established imaging and non-imaging techniques to demonstrate the capability of tomographic approaches used here., (Copyright © 2018 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2018

3. X-ray computed tomography of packed bed chromatography columns for three dimensional imaging and analysis.

Author

Johnson TF, Levison PR, Shearing PR, and Bracewell DG

Subjects

Particle Size, Porosity, Chemistry Techniques, Analytical instrumentation, Chemistry Techniques, Analytical methods, Chromatography, Liquid instrumentation, Imaging, Three-Dimensional methods, Tomography, X-Ray Computed

Abstract

Physical characteristics critical to chromatography including geometric porosity and tortuosity within the packed column were analysed based upon three dimensional reconstructions of bed structure in-situ. Image acquisition was performed using two X-ray computed tomography systems, with optimisation of column imaging performed for each sample in order to produce three dimensional representations of packed beds at 3μm resolution. Two bead materials, cellulose and ceramic, were studied using the same optimisation strategy but resulted in differing parameters required for X-ray computed tomography image generation. After image reconstruction and processing into a digital three dimensional format, physical characteristics of each packed bed were analysed, including geometric porosity, tortuosity, surface area to volume ratio as well as inter-bead void diameters. Average porosities of 34.0% and 36.1% were found for ceramic and cellulose samples and average tortuosity readings at 1.40 and 1.79 respectively, with greater porosity and reduced tortuosity overall values at the centre compared to the column edges found in each case. X-ray computed tomography is demonstrated to be a viable method for three dimensional imaging of packed bed chromatography systems, enabling geometry based analysis of column axial and radial heterogeneity that is not feasible using traditional techniques for packing quality which provide an ensemble measure., (Crown Copyright © 2017. Published by Elsevier B.V. All rights reserved.)

Published

2017