Article: Simulation of fly ash particulates separation in cyclone separator Journal: International Journal of Environmental Technology and Management (IJETM) 2016 Vol.19 No.3/4 pp.288 - 300 Abstract: The response surface Box-Behnken design is used to study the dependence and interactions of particle size, load of fly ash and pressure drop inside the cyclone separator for collection efficiency of fly ash. The maximum collection efficiency of fly ash obtained was 95% in the cyclone separator studied. The Barth model is used to evaluate the axial and tangential velocities of cyclone separator studied. The static pressure contour plots at different inlet velocities of 41 m/s and 104 m/s at top and bottom horizontal planes of cyclone separator were developed using computational fluid dynamics software Fluent. The contour regions of axial, radial and tangential velocity fields in the cyclone separator were analysed using Fluent finite volume code for flow analysis inside the cyclone separator for fly ash collection. It was observed that the radial velocity increases rapidly towards the vortex core and the tangential velocity is dependent on the geometrical design of cyclone separator, wall friction and particle loading of fly ash. Inderscience Publishers - linking academia, business and industry through research

Title: Simulation of fly ash particulates separation in cyclone separator

Authors: P. Sabareesh Sankar; R. Krishna Prasad

Addresses: Department of Chemical Engineering and Materials Science, Center of Excellence in Advanced Materials and Green Technology, School of Engineering – Coimbatore, Amrita Vishwa Vidyapeetham, Amrita University, Ettimadai, Coimbatore 641-112, India ' Department of Chemical Engineering and Materials Science, Center of Excellence in Advanced Materials and Green Technology, School of Engineering – Coimbatore, Amrita Vishwa Vidyapeetham, Amrita University, Ettimadai, Coimbatore 641-112, India

Abstract: The response surface Box-Behnken design is used to study the dependence and interactions of particle size, load of fly ash and pressure drop inside the cyclone separator for collection efficiency of fly ash. The maximum collection efficiency of fly ash obtained was 95% in the cyclone separator studied. The Barth model is used to evaluate the axial and tangential velocities of cyclone separator studied. The static pressure contour plots at different inlet velocities of 41 m/s and 104 m/s at top and bottom horizontal planes of cyclone separator were developed using computational fluid dynamics software Fluent. The contour regions of axial, radial and tangential velocity fields in the cyclone separator were analysed using Fluent finite volume code for flow analysis inside the cyclone separator for fly ash collection. It was observed that the radial velocity increases rapidly towards the vortex core and the tangential velocity is dependent on the geometrical design of cyclone separator, wall friction and particle loading of fly ash.

Keywords: cyclone separators; simulation; fly ash particulates; particulate separation; Box-Behnken design; computational fluid dynamics; CFD; Fluent; particle size; fly ash load; pressure drop; axial velocity; tangential velocity; radial velocity; fly ash collection; geometrical design.

DOI: 10.1504/IJETM.2016.082255

International Journal of Environmental Technology and Management, 2016 Vol.19 No.3/4, pp.288 - 300

Accepted: 20 Nov 2016
Published online: 13 Feb 2017 *

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Title: Simulation of fly ash particulates separation in cyclone separator

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