Investigation of Cut-Off Sizes and Collection Efficiencies of Portable Microbial Samplers

The CIP 10-M personal sampler measures worker exposure to airborne particles by collecting particles in a rotating metal cup containing a few milliliters of a collection fluid. This device is mainly used to sample microorganisms or microbial components to measure bioaerosol concentrations in various occupational environments. Aqueous liquids are generally used, but their rapid evaporation limits the duration of sampling; alternative collection fluids could alleviate this problem. Indeed, the particle-collection efficiency of the rotating cup has not been extensively studied, and the only data available relate to a discontinued model. This study aimed to measure the collection efficiency of the current rotating cup model containing an aqueous (water) or viscous (ViaTrap mineral oil) collection fluid. The kinetics of evaporation confirmed that ViaTrap does not evaporate, making 8-h sampling campaigns in constant volumes feasible. Particles with a wide range of aerodynamic diameters (between around 0.1 and 10 mm) were produced using various test rigs and mono-or polydisperse test aerosols. Both new and older cup models performed similarly, with a collection efficiency of >80% for larger particles (aerodynamic diameters >2.8 mm), progressively decreasing to around 50% for aerodynamic diameters of 2.1 mm; with aerodynamic diameters of <1 mm, the collection efficiency was generally <10%. In physical terms, collection efficiency was unaffected by the type (aqueous or viscous) or volume (between 0 and 3 mL) of collection fluid used. Bias maps indicated that the inhalable fraction may be underestimated in occupational settings, particularly with aerosols mainly composed of particles with aerodynamic diameters of less than around 3 mm. EDITORTiina Reponen

Section: 33mentioning

confidence: 63%

Physical performances and kinetics of evaporation of the CIP 10-M personal sampler's rotating cup containing aqueous or viscous collection fluid

Simon

Bau

Boivin

et al. 2016

“…The particle collection efficiency was found to be influenced by the cross flow (Fang et al 1991) and nozzle arrangement (Kwon et al 2002). Moreover, the effect of the S/W ratio on the cutoff characteristics of the multinozzle impactors (i.e., micro-orifice impactors) has been studied (Gudmundsson et al 1995;Kwon et al 2002;Yao and Mainelis 2006). In Gudmundsson et al (1995), when S/W > 1:8, (Stk 50 ) 1/2 increased with an increasing S/W but decreased with an increasing Re at a fixed porosity (Po) which is defined as the total cross-sectional area of nozzles divided by the area of nozzle plate.…”

Section: Introductionmentioning

confidence: 99%

“…Increasing the S/W ratio from 1.75 to 2.25 was shown to decrease particle collection efficiency by more than 10%. Yao and Mainelis (2006) investigated the effect of the S/W ratio on the physical collection efficiency of the multinozzle bioaerosol impactors. Results showed that the d pa50 decreased when the S/W ratio was decreased over the range from 2.7 to 9.…”

Section: Introductionmentioning

confidence: 99%

Design and Testing of the NCTU Micro-Orifice Cascade Impactor (NMCI) for the Measurement of Nanoparticle Size Distributions

Chien

Tien

Liu

et al. 2015

The NCTU micro-orifice cascade impactor (NMCI) was redesigned and tested to enable the measurement and adjustment of the jet-to-plate distance (S) of the impactors by using a micrometer. Each stage of the NMCI contains an impaction plate and a nozzle plate which are separated. The bottom casing for impaction plate assembly and the nozzle plate holder of each stage are separated. Calibration results show that the cutoff aerodynamic diameter (d pa50 ) of the three lower stages (d pa50 D 180, 100, and 56 nm) are close to the nominal values given in Marple et al. (1991). In addition, the S/W (W: nozzle diameter) effects on the d pa50 for the three lower stages were investigated and an empirical equation was developed to facilitate the prediction of d pa50 when the nozzle diameters may change slightly from one batch to another. The relationship between the nozzle diameter and pressure drop of the micro-orifice impactors at the fixed operational flow rate of 30 L/min was also established so that the nozzle diameters can be predicted from the pressure drop measurement. An empirical equation was proposed to express the correlation between the dimensionless cutoff size and the S/W ratio when considering isentropic flow to facilitate the design of microorifice impactors for S/W > 4. It is expected that the present NMCI could improve the accuracy of size classification of submicron particles below 180 nm, especially for nanoparticles.

“…While staying within the recommended S/W range of about one to five (Marple and Olson 2011), Yao and Mainelis (2006a) have demonstrated improved physical collection efficiency in multinozzle portable agar impactors by increasing agar plate volume and thus decreasing S/W. However, in addition to physical collection of particles, biological collection efficiency also needs to be considered when collecting culturable samples with different agar volumes.…”

Section: Introductionmentioning

confidence: 99%

Effect of Agar Plate Volume on Accuracy of Culturable Bioaerosol Impactors

Therkorn

Mainelis

2013

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