Thin disks falling in air

Tinklenberg, Amy; Guala, Michele; Coletti, Filippo

doi:10.1017/jfm.2023.209

Cited by 7 publications

(2 citation statements)

References 99 publications

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“…The same circular disks were also utilized by Tinklenberg et al. (2023) to study the settling of thin plates. Consistent to the established procedures outlined in Section 2.2 for the density measurement, we first detect and segment the particles, followed by a measurement of their region properties.…”

Section: System Assessmentmentioning

confidence: 99%

“…These thin disks, composed of polyethylene terephthalate (PET, ρ PET = 1,380 kg/m 3 ), are individually dropped into the snow particle analyzer. The same circular disks were also utilized by Tinklenberg et al (2023) to study the settling of thin plates. Consistent to the established procedures outlined in Section 2.2 for the density measurement, we first detect and segment the particles, followed by a measurement of their region properties.…”

Section: Table 1 Classification and Corresponding Volume Estimation O...mentioning

confidence: 99%

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Snow Particle Analyzer for Simultaneous Measurements of Snow Density and Morphology

Li,

Guala,

Hong

2023

JGR Atmospheres

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The detailed characterization of snow particles is critical for understanding the snow settling behavior and modeling the ground snow accumulation for various applications such as prevention of avalanches and snowmelt‐caused floods, etc. In this study, we present a snow particle analyzer for simultaneous measurements of various properties of fresh falling snow, including their size, shape, type, and density. The analyzer consists of a digital inline holography module for imaging falling snow particles in a sample volume of 88 cm3 and a high‐precision scale to measure the weight of the same particles in a synchronized fashion. The holographic images are processed in real‐time using a machine learning model and post‐processing to determine snow particle size, shape, and type. Such information is used to obtain the estimated volume, which is subsequently correlated with the weight of snow particles to estimate their density. The performance of the analyzer is assessed using monodispersed spherical glass and foam beads, irregular salt crystals, and thin disks with various shapes with known density, which shows <10% density measurement errors. In addition, the analyzer was tested in a number of field deployments under different snow and wind conditions. The system is able to achieve measurements of various snow properties at single particle resolution and statistical robustness. The analyzer was also deployed for four hours of operation during a snow event with changing snow and wind conditions, demonstrating its potential for long‐term and real‐time monitoring of the time‐varying snow properties in the field.

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Section: System Assessmentmentioning

confidence: 99%

Section: Table 1 Classification and Corresponding Volume Estimation O...mentioning

confidence: 99%

Snow Particle Analyzer for Simultaneous Measurements of Snow Density and Morphology

Li,

Guala,

Hong

2023

JGR Atmospheres

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Unveiling the Dynamics of Snow Settling in Atmospheric Turbulence: A Review of Nearly a Decade of Field Research at EOLOS, MN

Li,

Hong

2023

IUTAM Bookseries

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Laboratory generation of zero-mean-flow homogeneous isotropic turbulence: non-grid approaches

Ghazi Nezami,

Byron,

Johnson

2023

Flow

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Over the years, many facilities have been developed to study turbulent flow in the laboratory. Homogeneous isotropic turbulence (HIT) with zero mean flow provides a unique environment for investigating fundamental aspects and specific applications of turbulent flow. We provide an extensive overview of laboratory facilities that generate incompressible zero-mean-flow HIT using different types of actuators and configurations. Reviewed facilities cover a variety of geometries and sizes, as well as forcing style (e.g. symmetric versus asymmetric and unsteady versus steady). We divide facilities into four categories, highlighting links between their geometries and the statistics of the flows they generate. We then compare published data to uncover similarities and differences among various turbulence-generation mechanisms. We also compare the decay of turbulence in zero-mean-flow facilities with that observed in wind and water tunnels, and we analyse the connections between flow characteristics and physical aspects of the facilities. Our results emphasize the importance of considering facility geometry and size together with the strength and type of actuators when studying zero-mean-flow HIT. Overall, we provide insight into how to optimally design and build laboratory facilities that generate zero-mean-flow HIT.

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Thin disks falling in air

Cited by 7 publications

References 99 publications

Snow Particle Analyzer for Simultaneous Measurements of Snow Density and Morphology

Snow Particle Analyzer for Simultaneous Measurements of Snow Density and Morphology

Unveiling the Dynamics of Snow Settling in Atmospheric Turbulence: A Review of Nearly a Decade of Field Research at EOLOS, MN

Laboratory generation of zero-mean-flow homogeneous isotropic turbulence: non-grid approaches

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