Venturi pump-critical orifice as an online and robust nanoparticle dilution probe for in situ powder stream characterization

The study of aerosol dynamics in nanomaterial synthesis and powder processing requires real time, fast, automatic and reliable characterization of particle size distribution and concentration. Online characterization techniques, such as the scanning mobility particle sizer (SMPS) allow these measure...

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Vydané v:Powder technology Ročník 412; s. 117974
Hlavný autor: Vazquez-Pufleau, Miguel
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Elsevier B.V 01.11.2022
Predmet:
Aerosol sampling in adverse conditions
aerosols
Dilution factor
Dilution probes
ethanol
latex
nanoparticles
Online powder characterization
particle size distribution
polystyrenes
silane
streams
toxicity
Venturi pump
Dilution probes
Venturi pump
Aerosol sampling in adverse conditions
Online powder characterization
Dilution factor
ISSN:0032-5910
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Abstract The study of aerosol dynamics in nanomaterial synthesis and powder processing requires real time, fast, automatic and reliable characterization of particle size distribution and concentration. Online characterization techniques, such as the scanning mobility particle sizer (SMPS) allow these measurements for aerosol systems. Unfortunately, the SMPS was developed and optimized primarily for atmospheric sampling. However, reactors for the purposeful synthesis of nanoparticles operate in highly dynamic conditions with high concentrations, various pressures and even flammable, pyrophoric or toxic gases, demanding fast and reliable quenching, diluting and transporting the aerosols towards characterization. In the present work, a sampling and dilution probe based on the Venturi principle with different orifice sizes was characterized using polystyrene latex beads and salt. The obtained dilution rates were compared vs state of the art equations and precursor dilution from a silane reactor showing good agreement. The smallest orifices could clog but ethanol and pressurized gas allow their regeneration. [Display omitted] •Study compares dilution probe capabilities on PSL beads, salt and silane vs models.•Probes useful for characterizing & monitoring aerosol reactors and generators.•Particularly attractive in systems with toxic, explosive or pyrophoric atmospheres.•Cheap, operational at different pressures, allows quenching fast aerosol dynamics.•Experiments agree with predictions PSL standard shows advantages over salt.
AbstractList The study of aerosol dynamics in nanomaterial synthesis and powder processing requires real time, fast, automatic and reliable characterization of particle size distribution and concentration. Online characterization techniques, such as the scanning mobility particle sizer (SMPS) allow these measurements for aerosol systems. Unfortunately, the SMPS was developed and optimized primarily for atmospheric sampling. However, reactors for the purposeful synthesis of nanoparticles operate in highly dynamic conditions with high concentrations, various pressures and even flammable, pyrophoric or toxic gases, demanding fast and reliable quenching, diluting and transporting the aerosols towards characterization. In the present work, a sampling and dilution probe based on the Venturi principle with different orifice sizes was characterized using polystyrene latex beads and salt. The obtained dilution rates were compared vs state of the art equations and precursor dilution from a silane reactor showing good agreement. The smallest orifices could clog but ethanol and pressurized gas allow their regeneration.
The study of aerosol dynamics in nanomaterial synthesis and powder processing requires real time, fast, automatic and reliable characterization of particle size distribution and concentration. Online characterization techniques, such as the scanning mobility particle sizer (SMPS) allow these measurements for aerosol systems. Unfortunately, the SMPS was developed and optimized primarily for atmospheric sampling. However, reactors for the purposeful synthesis of nanoparticles operate in highly dynamic conditions with high concentrations, various pressures and even flammable, pyrophoric or toxic gases, demanding fast and reliable quenching, diluting and transporting the aerosols towards characterization. In the present work, a sampling and dilution probe based on the Venturi principle with different orifice sizes was characterized using polystyrene latex beads and salt. The obtained dilution rates were compared vs state of the art equations and precursor dilution from a silane reactor showing good agreement. The smallest orifices could clog but ethanol and pressurized gas allow their regeneration. [Display omitted] •Study compares dilution probe capabilities on PSL beads, salt and silane vs models.•Probes useful for characterizing & monitoring aerosol reactors and generators.•Particularly attractive in systems with toxic, explosive or pyrophoric atmospheres.•Cheap, operational at different pressures, allows quenching fast aerosol dynamics.•Experiments agree with predictions PSL standard shows advantages over salt.
ArticleNumber 117974
Author Vazquez-Pufleau, Miguel
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CitedBy_id crossref_primary_10_1016_j_matchemphys_2023_128684
crossref_primary_10_1039_D2NR06016G
crossref_primary_10_1016_j_chemosphere_2023_139443
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Keywords Dilution probes
Venturi pump
Aerosol sampling in adverse conditions
Online powder characterization
Dilution factor
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SubjectTerms Aerosol sampling in adverse conditions
aerosols
Dilution factor
Dilution probes
ethanol
latex
nanoparticles
Online powder characterization
particle size distribution
polystyrenes
silane
streams
toxicity
Venturi pump
Title Venturi pump-critical orifice as an online and robust nanoparticle dilution probe for in situ powder stream characterization
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