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Numerical Modeling of the Novel Cross-Flow Electrostatic PrecipitatorEboreime, Ohioma January 2019 (has links)
No description available.
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Design, Manufacturing, and Testing of a Pilot Wet Electrostatic PrecipitatorMannella, Nikolas E. 15 June 2017 (has links)
No description available.
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The Membrane Vibration and the Dust Removal Efficiency of the Membrane Based Electrostatic PrecipitatorLiao, Bo 30 June 2003 (has links)
No description available.
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Mechanical Behavior of Membranes in Electrostatic PrecipitatorsRamamoorthy, Thiagarajan 03 November 2005 (has links)
No description available.
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AEROSOL CALCULATION AND PRESSURE DROP SIMULATION FOR SIEVING ELECTROSTATIC PRECIPITATORSTelenta, Marijo 20 April 2007 (has links)
No description available.
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Experimental and theoretical study of sub-micron aerosol collection efficiency by Laminar Wet-Membrane electrostatic precipitatorLi, Ke January 2005 (has links)
No description available.
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Design Optimization and Experimental Study of a Wet Laminar Electrostatic Precipitator for Enhancing Collection Efficiency of AerosolsVijapur, Santosh H. 29 December 2008 (has links)
No description available.
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Dust Flow Separator Type Electrostatic Precipitator For A Control Of Particulate Matter Emissions From Natural Gas CombustionGuan, Lili 01 1900 (has links)
<p>Pollution problems have drawn worldwide awareness and become significantly
important now. Particulate matter (PM) emission is one of the key pollution issues.
Particulate matter has a significant impact on the environment and human health,
especially particle sizes that range below 10μm. Researches continuously work an
improvement of fine particulate matter collections emitted from all kinds of sources, such
as automobiles, industrial combustion, etc. Governments in many countries are planning
to regulate the PM emission from the existing PM_10 (particle diameter<10μm) to new
limits PM_2.5 (particle diameter<2.5μm) within the next few years. For this reason, present
PM control system needs to be improved.</p><p>The objective of this work is to develop a dust flow separator type electrostatic
precipitator (DFS-ESP) for the effective control of fine particulate matter emission from
natural gas combustions. The characteristic of PM emitted from natural gas combustion is
studied, and the performance of a DFS-ESP is evaluated by experiments and numerical
predictions.</p><p>An experiment was conducted for natural gas combustion exhaust flow rates from
2.5 to 9 Nm^3/h, ESP applied voltages from 0 to 30kV, and gas temperature from 80 to
160°C. A series of particle measurements were conducted at upstream, downstream and
middle of the DFS-ESP system by an optical particle counter for particle mass density,
and by condensation nucleate particle counter for particle size distributions and particle number density. Particle sampled from the natural gas combustion system was also
analyzed by an environmental scanning electron microscope (ESEM) technique. Flow
velocity profile and pressure drop of the DFS-ESP were measured by a Pitot tube and
diaphragm type pressure transducer, respectively.</p><p>The experimental results show that the particle size emitted from natural gas
combustion ranges from 17 to 300nm in diameter, and the volume density is
approximately from 5 x 10^8 #pt/m^3 to 5 x 10^9 #pt/m^3 depending on the combustion
conditions. The dust flow separator can concentrate 90% of fine particles in 1 to 3% of
the gas flow and divert it from the main flow to the ESP section where the particles can
be removed. In terms of overall particle collection efficiency, the DFS-ESP system can
remove up to 90% of the particles based on the number density. The pressure drop across
the DFS-ESP is observed to be lower than lPa for the present range of flow rate, which is
within acceptable limits for industrial applications.</p> / Thesis / Master of Applied Science (MASc)
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Dust Flow Separator Type Electrostatic Precipitator For A Control Of Particulate Matter Emissions From Natural Gas CombustionGuan, Lili 01 1900 (has links)
<p> Pollution problems have drawn worldwide awareness and become significantly
important now. Particulate matter (PM) emission is one of the key pollution issues.
Particulate matter has a significant impact on the environment and human health,
especially particle sizes that range below lOJJ.m. Researches continuously work an
improvement of fine particulate matter collections emitted from all kinds of sources, such as automobiles, industrial combustion, etc. Governments in many countries are planning to regulate the PM emission from the existing PM10 (particle diameter<10μm) to new limits PM2.5 (particle diameter<2.5μm) within the next few years. For this reason, present PM control system needs to be improved. </p> <p> The objective of this work is to develop a dust flow separator type electrostatic precipitator (DFS-ESP) for the effective control of fine particulate matter emission from natural gas combustions. The characteristic of PM emitted from natural gas combustion is studied, and the performance of a DFS-ESP is evaluated by experiments and numerical predictions. </p> <p> An experiment was conducted for natural gas combustion exhaust flow rates from 2.5 to 9 Nm^3/h, ESP applied voltages from 0 to 30kV, and gas temperature from 80 to 160°C. A series of particle measurements were conducted at upstream, downstream and middle of the DFS-ESP system by an optical particle counter for particle mass density, and by condensation nucleate particle counter for particle size distributions and particle number density. Particle sampled from the natural gas combustion system was also analyzed by an environmental scanning electron microscope (ESEM) technique. Flow velocity profile and pressure drop of the DFS-ESP were measured by a Pitot tube and diaphragm type pressure transducer, respectively. </p> <p> The experimental results show that the particle size emitted from natural gas combustion ranges from 17 to 300nm in diameter, and the volume density is approximately from 5 x 10^8 #pt/m^3 to 5 x 109 #pt/m^3 depending on the combustion conditions. The dust flow separator can concentrate 90% of fine particles in 1 to 3% of the gas flow and divert it from the main flow to the ESP section where the particles can be removed. In terms of overall particle collection efficiency, the DFS-ESP system can remove up to 90% of the particles based on the number density. The pressure drop across the DFS-ESP is observed to be lower than lPa for the present range of flow rate, which is within acceptable limits for industrial applications. </p> / Thesis / Master of Applied Science (MASc)
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A Dust Flow Separator Type Electrostatic Precipitator for Diesel Engine Particulate Matter ControlColenbrander, John W. 08 1900 (has links)
<p> Increasingly stringent legislation governing the emissions of diesel engine particulate matter (DPM) has required the development of technological improvements to diesel engines, fuels and exhaust treatments. A main focus of diesel particulate matter abatement is on exhaust after treatment, that consists of the removal of particulate matter from the exhaust gas after it exits the engine. This is currently accomplished with regenerative diesel particulate traps that are effective at removing DPM, but are costly and introduce a significant pressure drop in the exhaust flow.</p> <p> The objective of this study was to evaluate the potential of a novel particulate removal system consisting of a particulate flow separator combined with electrostatic precipitators (ESPs). Previous application of this system to natural gas emissions resulted in collection efficiencies larger than 90% with negligible pressure drop.</p> <p> The ESPs used in the proposed flow separator-ESP were characterized and have collection efficiencies of up to 99% at the flow rates studied. The flow separator-ESP was characterized with a straight inlet section and an expanding inlet section. The collection efficiency of the flow separator-ESP configured with the expanding inlet section was up to 60% for a flow rate of 2.5 kg/hr, that corresponded to laminar flow with Reynolds number of 1100. Collection efficiencies on the order of 20% were obtained for exhaust flow rates of 3.75 kg/hr (Re = 1500) and 5.0 kg/hr (Re = 2100) for both inlet configurations, and 2.5 kg/hr with the straight inlet. The effectiveness of the current design is limited by exhaust flow rate.</p> <p> The diesel exhaust gas was sampled using a partial flow dilution tunnel developed specifically for this study. The dilution ratio for this system can be estimated to within ±10% using volumetric flow measurements. It was found that changes in the dilution and sampling velocity ratios for diesel exhaust have some effect on measured particulate matter mass concentrations.</p> / Thesis / Master of Applied Science (MASc)
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