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12 results on '"O. WITSCHGER"'

1. Simplified method for testing personal inhalable aerosol samplers

Author

Paul A. Baron, J. Smith, O. Witschger, V. Aizenberg, Sergey A. Grinshpun, and Klaus Willeke

Subjects
Fluid Flow and Transfer Processes, Atmospheric Science, Environmental Engineering, Meteorology, Mechanical Engineering, Airflow, Sampling (statistics), Test method, Torso, Pollution, Wind speed, Aerosol, medicine.anatomical_structure, Flow velocity, medicine, Environmental science, Wind tunnel, Marine engineering
Abstract

The presently available protocol for evaluating the performance of personal aerosol samplers according to the inhalable convention is difficult to satisfy as it requires a large cross-section wind tunnel. The present study was initiated to simplify and reduce the cost of the test method by mounting the test samplers on a small, stationary torso instead of a full-size rotating manikin. The simplified torso consisted of a rectangular three-dimensional body (33 cm wide, 21 cm deep, 21 cm high). Replicates of the personal inhalable aerosol sampler under consideration were attached in the center of each vertical face of the simplified torso representing the three principal sampling orientations (facing the wind, turned 90°, and turned 180° to the wind). When the samplers were mounted on a full-size manikin, the air flow in the vicinity of the manikin was found to depend on the sampler location, symmetry of the manikin, and position of the manikin’s arms. On the simplified torso, the magnitude and direction of the air flow near the samplers were found to be comparable to that of the manikin. When subjected to nearly monodisperse aerosol flows (particle size of 70 μm, wind velocity of 50 and 200 cm s-1), both methods yielded aerosol sampling efficiencies that were statistically not different at three major sampling orientations. The advantages of the simplified torso are that fewer measurements need to be made; a smaller, less expensive wind tunnel can be used for the testing; and interlaboratory variability of personal inhalable samplers’ performance may be decreased.

Published
1998
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2. A new experimental wind tunnel facility for aerosol sampling investigations

Author

O. Witschger, A. Renoux, J.F. Fabries, P. Görner, and Richard Wrobel

Subjects
Fluid Flow and Transfer Processes, Atmospheric Science, Environmental Engineering, Particle number, Turbulence, Mechanical Engineering, Airflow, Analytical chemistry, Sampling (statistics), Mechanics, Pollution, Aerosol, Range (statistics), Environmental science, Particle, Wind tunnel
Abstract

A new experimental wind tunnel facility for aerosol sampling investigations has been built and its performance evaluated. Subsequently, an experimental methodology using a polydisperse test aerosol of glass beads to measure entry, transmission and overall sampling efficiencies has been developed and tested. The new facility is composed of a horizontal cylindrical pipe of 5 m long and 30 cm in diameter. The measurement zone is located just at the exit, allowing to take benefit of the whole cross-sectional area inside a stabilised aerosol flow. The working air velocity range is 0.5–4.5 m s−1 Air velocity and turbulence profiles are uniform within 10%. Turbulence in the working section is controlled with a square mesh grid. The test aerosol is generated by a fluidized-bed generator and dispersed into the clean air flow upstream of the horizontal part. Generated particles are within a size interval extending from a few μm to about 80 μm in aerodynamic diameter. Tests of time and space stability of the test aerosol in the working section were carried out. They have shown a reasonably uniform spatial distribution and time stability considering the size range of generated particles. The experimental method allows to obtain, simultaneously with the same technique entry, transmission, and overall sampling efficiencies of samplers from several μm up to 70 μm in particle aerodynamic diameter with a good accuracy. It is based on the measurement of the distribution of particle number concentration vs particle aerodynamic diameter of deposited and sampled aerosols in a reference probe and in the test sampler. To evaluate both the new wind tunnel facility and the methodology, measurements of the different efficiencies were achieved using a cylindrical sharp-edged thin-walled probe as a test sampler. This evaluation was performed in three steps. At first, the reproducibility of transmission efficiency measurements of the probe working in isokinetic conditions was determined. It appears fairly good between 10 and 70 μm in particle aerodynamic diameter. Then, the methodology was applied to the assessment of the aspiration efficiency of a probe working in subisokinetic conditions. Finally, a consistency test of the data was proposed and applied to our data; it consists in comparing the mass fractions of collected samples (deposited on the internal sampler walls, collected onto filters) calculated from the efficiency data and the distributions of particle concentrations, with those which are directly recovered after each experiment and weighed. This test yields an indicator of the quality of the whole efficiency data set.

Published
1997
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8. An experimental facility for powder reentrainment studies

Author

L. Alloul, J. Monnatte, O. Witschger, D. Le Dur, and A. Renoux

Subjects
Fluid Flow and Transfer Processes, Atmospheric Science, Range (particle radiation), Environmental Engineering, Materials science, Turbulence, Mechanical Engineering, Airflow, Surface finish, Mechanics, Pollution, Acceleration, Particle, Particle size, Two-phase flow
Abstract

Particle reentrainment from surfaces to turbulent air flow is an important subject in many different fields like nuclear safety, environmental air pollution, sediment transport by wind, surface contamination in semiconductor operations. Theoretical and experimental studies have been numerous and cover different aspects of the phenomena (Ziskind et al., 1995). Although a number of theoretical works have been devoted for describing the mechanisms of detachment of primary spherical particles from flat smooth surfaces in a turbulent flow, experimental data are still needed in order to comparison. Moreover, the knowledge of the effect of parameters related to the deposit (monolayer, multilayer, conelike pile), the powder particles (particle-size distribution, adhesive properties), the surface (roughness . . . . ), the airflow (velocity, acceleration, turbulence) or the environment (humidity . . . . ) is still in an elementary stage. The main objective of our work is to contribute to the understanding and quantification of the relevant parameters that govern the particle reentrainment from a powder deposit (particle size in the range I to approximately 120 I.tm) in an horizontal airflow (air velocity up to 10 m/s). Therefore, a new experimental facility has been designed and built in our laboratory.

10. Simplified test method to evaluate personal aerosol samplers

Author

V. Aizenberg, Paul A. Baron, O. Witschger, Klaus Willeke, J. Smith, and Sergey A. Grinshpun

Subjects
Fluid Flow and Transfer Processes, Atmospheric Science, Environmental Engineering, Meteorology, Mechanical Engineering, Environmental science, Test method, Pollution, Aerosol, Wind tunnel

11. Particle entry efficiency of an annular slot aerosol sampler

Author

O. Witschger, P. Görner, and J.F. Fabries

Subjects
Fluid Flow and Transfer Processes, Atmospheric Science, Semi empirical model, Environmental Engineering, Meteorology, Mechanical Engineering, Environmental science, Particle, Mechanics, Pollution, Wind tunnel, Aerosol

12. Development of a novel calibration tool for workplace aerosol samplers - Review of progress of EU project

Author

O. Witschger, Robert Aitken, G. Beaumont, Hans Kromhout, Göran Lidén, W. Koch, C Chalmers, D. Mark, and Publica

Subjects
Fluid Flow and Transfer Processes, Atmospheric Science, Environmental Engineering, Calibration (statistics), Mechanical Engineering, Pollution, Aerosol, Occupational hygiene, Environmental science, media_common.cataloged_instance, Occupational exposure, European union, Environmental planning, Instrument evaluation, media_common

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