Contactless and high-frequency optical hygrometry in LACIS-T

A narrow-band optical hygrometer FIRH (Fast Infrared Hygrometer, Nowak et al., 2016), based on absorption of laser light at wavelength &#955;=1364.6896 nm was used for contactless measurements of humidity inside the measurement volume of LACIS-T (turbulent Leipzig Aerosol Cloud Interaction Simulator, Niedermeier et al., 2020). LACIS-T is a multi-purpose moist-air wind tunnel for investigating atmospherically relevant interactions between turbulence and cloud microphysical processes under well-defined and reproducible laboratory conditions. Main goals of the experiment were:1) characterization and evaluation of the FIRH hygrometer in controlled conditions,2) characterization of fast turbulent humidity fluctuations inside LACIS-T.&#160;Collected results indicate, that FIRH can be used to characterize turbulent fluctuations of humidity in scales of tens of centimeters with the temporal resolution of 2 kHz and presumably more. Interestingly, scanning of LACIS-T measurement volume indicated existence of turbulence and wave-like features for the investigated measurement setup in its &#160;central part, where air streams of different thermodynamical properties, yet the same mean velocity mix intensively. , However, the setup for cloud measurements include an additional flow (i.e., an aerosol flow) in the central part strongly reducing the wave-like features. In other words, cloud process studies are most likely unaffected by these features.Finally, the experiments proved that contactless measurements of humidity conducted from outside the measurement volume of LACIS-T are useful, on condition of corrections of glass window transmission and interferences.&#160;Niedermeier, D., Voigtl&#228;nder, J., Schmalfu&#223;, S., Busch, D., Schumacher, J., Shaw, R. A., and Stratmann, F. (2020): Characterization and first results from LACIS-T: a moist-air wind tunnel to study aerosol&#8211;cloud&#8211;turbulence interactions, Atmos. Meas. Tech., 13, 2015-2033, doi:10.5194/amt-13-2015-2020.Nowak J., Magryta P., Stacewicz T., Kumala W., Malinowski S.P., 2016: Fast optoelectronic sensor of water concentration, Optica Applicata, vol. 46(4) , pp. 607-618 , doi: 10.5277/oa160408

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Characterization and first results from LACIS-T: a moist-air wind tunnel to study aerosol–cloud–turbulence interactions

Atmospheric Measurement Techniques ◽

10.5194/amt-13-2015-2020 ◽

2020 ◽

Vol 13 (4) ◽

pp. 2015-2033 ◽

Cited By ~ 3

Author(s):

Dennis Niedermeier ◽

Jens Voigtländer ◽

Silvio Schmalfuß ◽

Daniel Busch ◽

Jörg Schumacher ◽

...

Keyword(s):

Wind Tunnel ◽

Spatial Scales ◽

Experimental Studies ◽

Field Measurements ◽

Hygroscopic Growth ◽

Moist Air ◽

Aerosol Cloud ◽

Cloud Microphysical Processes ◽

First Results ◽

Microphysical Processes

Abstract. The interactions between turbulence and cloud microphysical processes have been investigated primarily through numerical simulation and field measurements over the last 10 years. However, only in the laboratory we can be confident in our knowledge of initial and boundary conditions and are able to measure under statistically stationary and repeatable conditions. In the scope of this paper, we present a unique turbulent moist-air wind tunnel, called the Turbulent Leipzig Aerosol Cloud Interaction Simulator (LACIS-T) which has been developed at TROPOS in order to study cloud physical processes in general and interactions between turbulence and cloud microphysical processes in particular. The investigations take place under well-defined and reproducible turbulent and thermodynamic conditions covering the temperature range of warm, mixed-phase and cold clouds (25∘C>T>-40∘C). The continuous-flow design of the facility allows for the investigation of processes occurring on small temporal (up to a few seconds) and spatial scales (micrometer to meter scale) and with a Lagrangian perspective. The here-presented experimental studies using LACIS-T are accompanied and complemented by computational fluid dynamics (CFD) simulations which help us to design experiments as well as to interpret experimental results. In this paper, we will present the fundamental operating principle of LACIS-T, the numerical model, and results concerning the thermodynamic and flow conditions prevailing inside the wind tunnel, combining both characterization measurements and numerical simulations. Finally, the first results are depicted from deliquescence and hygroscopic growth as well as droplet activation and growth experiments. We observe clear indications of the effect of turbulence on the investigated microphysical processes.

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Characterization and first results from LACIS-T: A moist-air wind tunnel to study aerosol-cloud-turbulence interactions

10.5194/amt-2019-343 ◽

2019 ◽

Author(s):

Dennis Niedermeier ◽

Jens Voigtländer ◽

Silvio Schmalfuß ◽

Daniel Busch ◽

Jörg Schumacher ◽

...

Keyword(s):

Wind Tunnel ◽

Spatial Scales ◽

Experimental Studies ◽

Small Time ◽

Hygroscopic Growth ◽

Moist Air ◽

Aerosol Cloud ◽

Cloud Microphysical Processes ◽

First Results ◽

Microphysical Processes

Abstract. The interactions between turbulence and cloud microphysical processes have been investigated primarily through numerical simulation and field measurements over the last ten years. However, only in the laboratory we can be confident in our knowledge of initial and boundary conditions, and are able to measure under statistically stationary and repeatable conditions. In the scope of this paper, we present an unique turbulent moist-air wind tunnel, called the Turbulent Leipzig Aerosol Cloud Interaction Simulator (LACIS-T) which has been developed at TROPOS in order to study cloud physical processes in general and interactions between turbulence and cloud microphysical processes in particular. The investigations take place under well-defined and reproducible turbulent and thermodynamic conditions covering the temperature range of warm, mixed-phase and cold clouds (25 °C > T > −40 °C). The continuous-flow design of the facility allows for the investigation of processes occurring on small time (up to a few seconds) and spatial scales (micrometer to meter scale) and with a Lagrangian perspective. The experimental studies using LACIS-T are accompanied and complemented by Computational Fluid Dynamics (CFD) simulations which help us to design experiments as well as to interpret experimental results. In this paper, we will present the fundamental operating principle of LACIS-T, the numerical model as well as results concerning the thermodynamic and flow conditions prevailing inside the wind tunnel combining both characterization measurements and numerical simulations. Finally, first results are depicted from deliquescence/hygroscopic growth as well as droplet activation and growth experiments. We observe clear indications of the effect of turbulence on the investigated microphysical processes.

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Review of “Characterization and first results from LACIS-T: A moist-air wind tunnel to study aerosol-cloud-turbulence interactions” by Niedermeier et al.

10.5194/amt-2019-343-rc1 ◽

2019 ◽

Author(s):

Anonymous

Keyword(s):

Wind Tunnel ◽

Moist Air ◽

Aerosol Cloud ◽

First Results

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A wind tunnel simulation of the mean velocity fields behind upright porous fences

Agricultural and Forest Meteorology ◽

10.1016/j.agrformet.2007.05.009 ◽

2007 ◽

Vol 146 (1-2) ◽

pp. 82-93 ◽

Cited By ~ 82

Author(s):

Zhibao Dong ◽

Wanyin Luo ◽

Guangqiang Qian ◽

Hongtao Wang

Keyword(s):

Wind Tunnel ◽

Velocity Fields ◽

Mean Velocity ◽

Wind Tunnel Simulation ◽

The Mean

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Blind test comparison of the performance and wake flow between two in-line wind turbines exposed to different atmospheric inflow conditions

10.5194/wes-2016-31 ◽

2016 ◽

Cited By ~ 1

Author(s):

Jan Bartl ◽

Lars Sætran

Keyword(s):

Wind Tunnel ◽

Wind Turbines ◽

Turbulence Intensity ◽

Wake Flow ◽

Detached Eddy Simulation ◽

Mean Velocity ◽

Blind Test ◽

The Mean ◽

Inlet Conditions ◽

Inflow Conditions

Abstract. This is a summary of the results of the fourth Blind test workshop which was held in Trondheim in October 2015. Herein, computational predictions on the performance of two in-line model wind turbines as well as the mean and turbulent wake flow are compared to experimental data measured at NTNU's wind tunnel. A detailed description of the model geometry, the wind tunnel boundary conditions and the test case specifications was published before the workshop. Expert groups within Computational Fluid Dynamics (CFD) were invited to submit predictions on wind turbine performance and wake flow without knowing the experimental results at the outset. The focus of this blind test comparison is to examine the model turbines' performance and wake development up until 9 rotor diameters downstream at three different atmospheric inflow conditions. Besides a spatially uniform inflow field of very low turbulence intensity (TI = 0.23 %) as well as high turbulence intensity (TI = 10.0 %), the turbines are exposed to a grid-generated atmospheric shear flow (TI = 10.1 %). Five different research groups contributed with their predictions using a variety of simulation models, ranging from fully resolved Reynolds Averaged Navier Stokes (RANS) models to Large Eddy Simulations (LES). For the three inlet conditions the power and the thrust force of the upstream turbine is predicted fairly well by most models, while the predictions of the downstream turbine's performance show a significantly higher scatter. Comparing the mean velocity profiles in the wake, most models approximate the mean velocity deficit level sufficiently well. However, larger variations between the models for higher downstream positions are observed. The prediction of the turbulence kinetic energy in the wake is observed to be very challenging. Both the LES model and the IDDES (Improved Delayed Detached Eddy Simulation) model, however, are consistently managing to provide fairly accurate predictions of the wake turbulence.

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Turbulence Intensity as Influenced by Surface Roughness and Mean Velocity in a Wind-Tunnel Boundary Layer

Transactions of the ASAE ◽

10.13031/2013.38277 ◽

1971 ◽

Vol 14 (2) ◽

pp. 0285-0289 ◽

Cited By ~ 10

Author(s):

Leon Lyles ◽

Lowell A. Disrud ◽

and R. K. Krauss

Keyword(s):

Boundary Layer ◽

Surface Roughness ◽

Wind Tunnel ◽

Turbulence Intensity ◽

Mean Velocity

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Combined effects of flow curvature and rotation on uniformly sheared turbulence

Journal of Fluid Mechanics ◽

10.1017/s0022112009006296 ◽

2009 ◽

Vol 628 ◽

pp. 371-394 ◽

Cited By ~ 1

Author(s):

D. C. ROACH ◽

A. G. L. HOLLOWAY

Keyword(s):

Shear Stress ◽

Wind Tunnel ◽

Model Development ◽

Three Dimensional ◽

Simple Shear Flow ◽

Test Case ◽

Mean Velocity ◽

Tunnel Section ◽

Flow Curvature ◽

The Mean

This paper describes an experiment in which a uniformly sheared turbulence was subjected to simultaneous streamwise flow curvature and rotation about the streamwise axis. The distortion of the turbulence is complex but well defined and may serve as a test case for turbulence model development. The uniformly sheared turbulence was developed in a straight wind tunnel and then passed into a curved tunnel section. At the start of the curved section the plane of the mean shear was normal to the plane of curvature so as to create a three-dimensional or ‘out of plane’ curvature configuration. On entering the curved tunnel, the flow developed a streamwise mean vorticity that rotated the mean shear about the tunnel centreline through approximately 70°, so that the shear was nearly in the plane of curvature and oriented so as to have a stabilizing effect on the turbulence. Hot wire measurements of the mean velocity, mean vorticity, mean rate of strain and Reynolds stress anisotropy development along the wind tunnel centreline are reported. The observed effect of the mean shear rotation on the turbulence was to diminish the shear stress in the plane normal to the plane of curvature while generating non-zero values of the shear stress in the plane of curvature. A rotating frame was identified for which the measured mean velocity field took the form of a simple shear flow. The turbulence anisotropy was transformed to this frame to estimate the effects of frame rotation on the structure of sheared turbulence.

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Angular Bias Errors in Three-Component Laser Velocimeter Measurements

Journal of Fluids Engineering ◽

10.1115/1.2817794 ◽

1996 ◽

Vol 118 (3) ◽

pp. 555-561 ◽

Cited By ~ 1

Author(s):

Chao-Yi Chen ◽

P. J. Kim ◽

D. T. Walker

Keyword(s):

Velocity Vector ◽

Sampled Data ◽

Mean Velocity ◽

Measurement Volume ◽

Significant Bias ◽

Specific Configuration ◽

The Mean ◽

Flow Directions ◽

Vector Magnitude ◽

Angular Bias

For three-component laser velocimeter systems, the change in projected area of the coincident measurement volume for different flow directions will introduce an “angular” bias in naturally sampled data. In this study, the effect of turbulence level and orientation of the measurement volumes on angular bias errors was examined. The operation of a typical three-component laser velocimeter was simulated using a Monte Carlo technique. Results for the specific configuration examined show that for turbulence levels less than 10 percent no significant bias errors in the mean velocities will occur and errors in the root-mean-square (r.m.s.) velocities will be less than 3 percent for all orientations. For turbulence levels less than 30 percent, component mean velocity bias errors less than 5 percent of the mean velocity vector magnitude can be attained with proper orientation of the measurement volume; however, the r.m.s. velocities may be in error as much as 10 percent. For turbulence levels above 50 percent, there is no orientation which will yield accurate estimates of all three mean velocities; component mean velocity errors as large as 15 percent of the mean velocity vector magnitude may be encountered.

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Prediction of the hub vortex instability in a wind turbine wake: stability analysis with eddy-viscosity models calibrated on wind tunnel data

Journal of Fluid Mechanics ◽

10.1017/jfm.2014.263 ◽

2014 ◽

Vol 750 ◽

Cited By ~ 52

Author(s):

F. Viola ◽

G. V. Iungo ◽

S. Camarri ◽

F. Porté-Agel ◽

F. Gallaire

Keyword(s):

Stability Analysis ◽

Wind Tunnel ◽

Wind Turbine ◽

Eddy Viscosity ◽

General Interest ◽

Mean Velocity ◽

Vortex Instability ◽

Viscosity Models ◽

Wind Tunnel Data ◽

The Stability

AbstractThe instability of the hub vortex observed in wind turbine wakes has recently been studied by Iungo et al. (J. Fluid Mech., vol. 737, 2013, pp. 499–526) via local stability analysis of the mean velocity field measured through wind tunnel experiments. This analysis was carried out by neglecting the effect of turbulent fluctuations on the development of the coherent perturbations. In the present paper, we perform a stability analysis taking into account the Reynolds stresses modelled by eddy-viscosity models, which are calibrated on the wind tunnel data. This new formulation for the stability analysis leads to the identification of one clear dominant mode associated with the hub vortex instability, which is the one with the largest overall downstream amplification. Moreover, this analysis also predicts accurately the frequency of the hub vortex instability observed experimentally. The proposed formulation is of general interest for the stability analysis of swirling turbulent flows.

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