Inlet Diameter and Flow Volume Effects on Separation and Energy Efficiency of Hydrocyclones

This study investigates hydrocyclone performance of an oil injected screw compressor. Especially, the oil separation efficiency of a screw compressor plays a significant role for air quality and non-stop working hour of compressors has become an important issue when the efficiency in energy is consi...

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Bibliographic Details
Published inIOP conference series. Materials Science and Engineering Vol. 90; no. 1; pp. 12074 - 12083
Main Authors Erikli, Okay, A B
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 01.01.2015
Subjects
Aerodynamics
Air quality
Breakup
Centrifugal force
Compressors
Computational fluid dynamics
Cyclones
Efficiency
Energy management
Hydrocyclones
Inlets
Mathematical models
Outdoor air quality
Parameters
Reservoirs
Reynolds stress
Screws
Separation
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Summary:This study investigates hydrocyclone performance of an oil injected screw compressor. Especially, the oil separation efficiency of a screw compressor plays a significant role for air quality and non-stop working hour of compressors has become an important issue when the efficiency in energy is considered. In this study, two separation efficiency parameters were selected to be hydrocyclone inlet diameter and flow volume height between oil reservoir surface and top of the hydrocyclone. Nine different cases were studied in which cyclone inlet diameter and flow volume height between oil reservoir surface and top were investigated in regards to separation and energy performance aspects and the effect of the parameters on the general performance appears to be causing powerful influence. Flow inside the hydrocyclone geometry was modelled by Reynolds Stress Model (RSM) and hydro particles were tracked by Discrete Phase Model (DPM). Besides, particle break up was modelled by the Taylor Analogy Breakup (TAB) model. The reversed vortex generation was observed at different planes. The upper limit of the inlet diameter of the cyclone yields the centrifugal force on particles to decrease while the flow becomes slower; and the larger diameter implies slower flow. On the contrary, the lower limit is increment in speed causes breakup problems that the particle diameters become smaller; consequently, it is harder to separate them from gas.
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ISSN:1757-8981
1757-899X
1757-899X
DOI:10.1088/1757-899X/90/1/012074