Liquid Consumption of Wetted Wall Bioaerosol Sampling Cyclones: Characterization and Control

Advances in microfluidic, lab on chip, and other near-real-time biological identification technologies have driven the desire to concentrate bioaerosols into hydrosol sample volumes on the order of tens of microliters (μL). However, typical wet biological aerosol collector outputs are an order or tw...

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Bibliographic Details
Published in:Aerosol science and technology 2011-02, Vol.45 (2), p.172-182
Main Authors: Hubbard, J. A., Haglund, J. S., Ezekoye, O. A., McFarland, A. R.
Format: Article
Language:English
Subjects:
Accumulators
Aerosols
Atmospheric aerosols
Bioaerosols
Biological
Chemistry
Collectors
Colloidal gels. Colloidal sols
Colloidal state and disperse state
Correlation analysis
Cyclones
Droplets
Environmental conditions
Environmental testing
Exact sciences and technology
General and physical chemistry
Liquids
Sampling
Surface physical chemistry
Walls
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Summary:Advances in microfluidic, lab on chip, and other near-real-time biological identification technologies have driven the desire to concentrate bioaerosols into hydrosol sample volumes on the order of tens of microliters (μL). However, typical wet biological aerosol collector outputs are an order or two of magnitude above this goal. The ultimate success of bioaerosol collectors and biological identifiers requires an effective coupling at the macro-to-micro interface. Liquid collection performance was studied experimentally for a family of dynamically scaled wetted wall bioaerosol sampling cyclones (WWC's). Steady-state liquid collection rates and system response times were measured for a range of environmental conditions (temperatures from 10°C to 50°C and relative humidities from 10% to 90%), liquid input rates, and WWC airflow configurations. A critical liquid input rate parameter was discovered that collapsed all experimental data to self-similar empirical performance correlations. A system algorithm was then developed from empirical correlations to provide control over the liquid output rate and resulting concentration factor for a cyclone with an airflow rate of 100 L/min. Desired liquid output rates of 25 to 50 μL/min were maintained while sampling outdoor air over diurnal ranges of environmental conditions. These flow rates are associated with concentration factors on the order of 1,000,000 to 2,000,000 and liquid outputs that are a steady stream of 10 to 30 drops/min of 7 to 10 μL droplets. These developments should allow wetted wall cyclones to be effectively coupled to advanced biological identification systems.
ISSN:0278-6826
1521-7388
DOI:10.1080/02786826.2010.528806