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17 results on '"Thomas W. Grasser"'

2. kHz Rate Digital In-line Holography Applied to Quantify Secondary Droplets from the Aerodynamic Breakup of a Liquid Column in a Shock-Tube

Author

Paul E. Sojka, Joseph Olles, Yi Chen, Edward P. DeMauro, Justin L. Wagner, Daniel R. Guildenbecher, Paul Abraham Farias, and Thomas W. Grasser

Subjects
In line holography, Chemistry, business.industry, Holography, Mechanics, Aerodynamics, Breakup, 01 natural sciences, 010305 fluids & plasmas, law.invention, Physics::Fluid Dynamics, 010309 optics, Aerodynamic force, Water column, Optics, law, Position (vector), 0103 physical sciences, business, Shock tube
Abstract

The breakup of liquids due to aerodynamic forces has been widely studied. However, the literature contains limited quantified data on secondary droplet sizes, particularly as a function of time. Here, a column of liquid water is subjected to a step change in relative gas velocity using a shock tube. A unique digital in-line holography (DIH) configuration is proposed which quantifies the secondary droplets sizes, three-dimensional position, and three-component velocities at 100 kHz. Results quantify the detailed evolution of the characteristic mean diameters and droplet size-velocity correlations as a function of distance downstream from the initial location of the water column. Accuracy of the measurements is confirmed through mass balance. These data give unprecedented detail on the breakup process which will be useful for improved model development and validation.

Published
2016

3. Dual-Pump CARS Measurements of Temperature and Oxygen in a Turbulent Methanol-Fueled Pool Fire

Author

Kraig Frederickson, John C. Hewson, Anay Luketa, Sean P. Kearney, and Thomas W. Grasser

Subjects
Chemistry, Turbulence, General Chemical Engineering, Flame structure, Analytical chemistry, General Physics and Astronomy, Energy Engineering and Power Technology, General Chemistry, Combustion, Temperature measurement, Plume, symbols.namesake, Filter (large eddy simulation), Fuel Technology, Thermocouple, symbols, Atomic physics, Raman scattering
Abstract

We present broadband, dual-pump coherent anti-Stokes Raman scattering (CARS) measurements of N2 and O2 in 2 m diameter methanol pool fires. The design of the fiber-optically coupled CARS instrument for fire measurements is described. Single-shot temperatures and O2/N2 ratios were obtained simultaneously from a single measurement point at the center of the fire plume, and the measured temperature–oxygen statistics are compared to results of a time-domain-filtered Reynolds-averaged Navier-Stokes simulation. The measured and simulated mean fire temperatures agree to within 2–4%, with larger turbulent fluctuations observed in the measured temperatures. The behavior of the mean temperature conditioned on the O2/N2 ratio is similar for both simulation and experiment, but with simulated temperatures that are up to 10% lower than measured values for O2/N2 below 0.18. The uncertainty in the CARS measurements is described. A single-shot detection limit of O2/N2 = 0.06 was determined from the observed signal to nois...

Published
2010

4. Dual-pump coherent anti-Stokes Raman scattering thermometry in a sooting turbulent pool fire

Author

Kraig Frederickson, Sean P. Kearney, and Thomas W. Grasser

Subjects
Accuracy and precision, business.industry, Chemistry, Turbulence, Mechanical Engineering, General Chemical Engineering, Spectral line, Computational physics, Plume, symbols.namesake, Optics, Thermocouple, Fire protection, symbols, Physical and Theoretical Chemistry, business, Raman spectroscopy, Raman scattering
Abstract

We present a dual-pump coherent anti-Stokes Raman scattering (CARS) instrument, which has been constructed for the probing of temperature fluctuations in turbulent pool fires of meter-scale. The measurements were performed at the Fire Laboratory for Accreditation of Models and Experiments (FLAME) facility at Sandia National Laboratories, which provides a canonical fire plume in quiescent wind conditions, with well-characterized boundary conditions and access for modern laser-diagnostic probes. The details of the dual-pump CARS experimental facility for the fire-science application are presented, and single-laser-shot CARS spectra containing information from in-fire N2, O2, H2, and CO2 are provided. Single-shot temperatures are obtained from spectral fitting of the Raman Q-branch signature of N2, from which histograms that estimate the pdf of the enthalpy-averaged temperature fluctuations at the center of the fire plume are presented. Results from two different sooting fire experiments reveal excellent test-to-test repeatability of the fire plume provided by FLAME, as well as the CARS-measured temperatures. The accuracy and precision of the CARS temperatures is assessed from measurements in furnace-heated air, where the temperature can be accurately determined by a thermocouple. At temperatures in excess of 500 K, the furnace results show that the CARS measurements are accurate to within 2–3% and precise to within ±3–5% of the measured absolute temperature.

Published
2009

5. Temperature, Oxygen, and Soot-Volume-Fraction Measurements in a Turbulent C2H4-Fueled Jet Flame

Author

Caroline Winters, Thomas W. Grasser, Sean P. Kearney, John C. Hewson, Daniel R. Guildenbecher, and Paul Abraham Farias

Subjects
Jet (fluid), Chemistry, Turbulence, Diffusion flame, Analytical chemistry, Reynolds number, medicine.disease_cause, Soot, Computational physics, Physics::Fluid Dynamics, symbols.namesake, Volume fraction, Incandescence, medicine, symbols, Physics::Chemical Physics, Raman scattering
Abstract

We present a detailed set of measurements from a piloted, sooting, turbulent C 2 H 4 - fueled diffusion flame. Hybrid femtosecond/picosecond coherent anti-Stokes Raman scattering (CARS) is used to monitor temperature and oxygen, while laser-induced incandescence (LII) is applied for imaging of the soot volume fraction in the challenging jet-flame environment at Reynolds number, Re = 20,000. Single-laser shot results are used to map the mean and rms statistics, as well as probability densities. LII data from the soot-growth region of the flame are used to benchmark the soot source term for one-dimensional turbulence (ODT) modeling of this turbulent flame. The ODT code is then used to predict temperature and oxygen fluctuations higher in the soot oxidation region higher in the flame.

Published
2015

6. Quantitative Laser-Induced Incandescence Measurements of Soot in Turbulent Pool Fires

Author

Sean P. Kearney, Thomas W. Grasser, and Kraig Frederickson

Subjects
chemistry.chemical_compound, chemistry, Synthetic fuel, Laser-induced incandescence, Diffusion flame, Incandescence, Analytical chemistry, medicine, Laminar flow, Diffusion (business), medicine.disease_cause, Toluene, Soot
Abstract

Laser-induced incandescence measurements have recently been obtained from 10% and 30% toluene in methanol blended fuel pool fires of 2-m diameter. Calibration of the instrument was performed using an ethylene/air laminar diffusion flame produced by a Santoro-type burner which allowed the extraction of absolute soot-volume-fractions from these images. Performance of the optical probe was characterized using the laminar diffusion flame and corrections were implemented for signal dependence upon detector gain, flat field, and location within the probe laser sheet when processing the images. Probability density functions of the soot-volume fraction were constructed for the blended fuels used in this study and the mean values were determined to be 0.0077 and 0.028 ppm for the 10% and 30% blended fuels, respectively. Signal trapping was estimated for the two types of blended fuel and it was determined to be negligible for the 10% toluene/methanol blend and require {approx}10% correction for the 30% toluene/methanol blend.

Published
2010

7. Diagnostic development for determining the joint temperature/soot statistics in hydrocarbon-fueled pool fires : LDRD final report

Author

Anay Luketa, Sean P. Kearney, Kraig Frederickson, Jaime N. Casteneda, Thomas W. Grasser, and John C. Hewson

Subjects
Chemistry, Nuclear engineering, Analytical chemistry, Probability density function, medicine.disease_cause, Combustion, Laser, Temperature measurement, Soot, law.invention, symbols.namesake, Thermocouple, law, Incandescence, symbols, medicine, Raman scattering
Abstract

A joint temperature/soot laser-based optical diagnostic was developed for the determination of the joint temperature/soot probability density function (PDF) for hydrocarbon-fueled meter-scale turbulent pool fires. This Laboratory Directed Research and Development (LDRD) effort was in support of the Advanced Simulation and Computing (ASC) program which seeks to produce computational models for the simulation of fire environments for risk assessment and analysis. The development of this laser-based optical diagnostic is motivated by the need for highly-resolved spatio-temporal information for which traditional diagnostic probes, such as thermocouples, are ill-suited. The in-flame gas temperature is determined from the shape of the nitrogen Coherent Anti-Stokes Raman Scattering (CARS) signature and the soot volume fraction is extracted from the intensity of the Laser-Induced Incandescence (LII) image of the CARS probed region. The current state of the diagnostic will be discussed including the uncertainty and physical limits of the measurements as well as the future applications of this probe.

Published
2009

8. Dual-Pump Cars Probing of Meter-Scale Turbulent Pool Fires

Author

Sean P. Kearney, Thomas W. Grasser, and Kraig Frederickson

Subjects
Accuracy and precision, Optics, Scale (ratio), business.industry, Chemistry, Thermocouple, Turbulence, Analytical chemistry, Metre, business, Temperature measurement, Order of magnitude
Abstract

Presented here are broadband, dual-pump CARS measurements which were performed in a 2-meter diameter methanol pool fire. Single-shot temperature and relative mole fractions were obtained simultaneously. The temperatures were compared to traditional thermocouple measurements in the pool fire. It was found that the CARS mean temperatures agree to within 4% of the thermocouple measurements, while the RMS temperatures were an order of magnitude less for the thermocouple. The accuracy and precision of the single-shot temperature measurements were characterized by comparison to a laboratory standard. It was determined that between 500-1400 K the CARS instrument was accurate to better than 4% and the measurements were reproducible to within 6%.

Published
2008

9. Mechanical properties of anodized coatings over molten aluminum alloy

Author

Ted B. Parson, Anne Grillet, Thomas W. Grasser, S. M. Trujillo, V. Carter Hodges, Richard P. Grant, and Allen D. Gorby

Subjects
Inert, Controlled atmosphere, Materials science, Anodizing, Alloy, Metallurgy, chemistry.chemical_element, Surface finish, engineering.material, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Biomaterials, Colloid and Surface Chemistry, chemistry, Coating, Aluminium, engineering, Inert gas
Abstract

A method to measure interfacial mechanical properties at high temperatures and in a controlled atmosphere has been developed to study anodized aluminum surface coatings at temperatures where the interior aluminum alloy is molten. This is the first time that the coating strength has been studied under these conditions. We have investigated the effects of ambient atmosphere, temperature, and surface finish on coating strength for samples of aluminum alloy 7075. Surprisingly, the effective Young's modulus or strength of the coating when tested in air was twice as high as when samples were tested in an inert nitrogen or argon atmosphere. Additionally, the effective Young's modulus of the anodized coating increased with temperature in an air atmosphere but was independent of temperature in an inert atmosphere. The effect of surface finish was also examined. Sandblasting the surface prior to anodization was found to increase the strength of the anodized coating with the greatest enhancement noted for a nitrogen atmosphere. Machining marks were not found to significantly affect the strength.

Published
2007

11. Measurements of thermal accommodation coefficients

Author

Jaime N. Castaneda, Daniel J. Rader, John Robert Torczynski, Wayne M. Trott, and Thomas W. Grasser

Subjects
Materials science, Argon, fungi, Metallurgy, technology, industry, and agriculture, chemistry.chemical_element, Surface finish, Experimental uncertainty analysis, chemistry, Heat flux, Thermal, Surface roughness, Composite material, Thermal analysis, Helium
Abstract

A previously-developed experimental facility has been used to determine gas-surface thermal accommodation coefficients from the pressure dependence of the heat flux between parallel plates of similar material but different surface finish. Heat flux between the plates is inferred from measurements of temperature drop between the plate surface and an adjacent temperature-controlled water bath. Thermal accommodation measurements were determined from the pressure dependence of the heat flux for a fixed plate separation. Measurements of argon and nitrogen in contact with standard machined (lathed) or polished 304 stainless steel plates are indistinguishable within experimental uncertainty. Thus, the accommodation coefficient of 304 stainless steel with nitrogen and argon is estimated to be 0.80 {+-} 0.02 and 0.87 {+-} 0.02, respectively, independent of the surface roughness within the range likely to be encountered in engineering practice. Measurements of the accommodation of helium showed a slight variation with 304 stainless steel surface roughness: 0.36 {+-} 0.02 for a standard machine finish and 0.40 {+-} 0.02 for a polished finish. Planned tests with carbon-nanotube-coated plates will be performed when 304 stainless-steel blanks have been successfully coated.

Published
2005

12. Microscale rarefied gas dynamics and surface interactions for EUVL and MEMS applications

Author

Thomas W. Grasser, Wayne M. Trott, Jaime N. Castaneda, John Robert Torczynski, Daniel J. Rader, and Michail A. Gallis

Subjects
Work (thermodynamics), Monatomic ion, Argon, Materials science, chemistry, Heat flux, Thermal, Analytical chemistry, chemistry.chemical_element, Mechanics, Diatomic molecule, Helium, Microscale chemistry
Abstract

A combined experimental/modeling study was conducted to better understand the critical role of gas-surface interactions in rarefied gas flows. An experimental chamber and supporting diagnostics were designed and assembled to allow simultaneous measurements of gas heat flux and inter-plate gas density profiles in an axisymmetric, parallel-plate geometry. Measurements of gas density profiles and heat flux are made under identical conditions, eliminating an important limitation of earlier studies. The use of in situ, electron-beam fluorescence is demonstrated as a means to measure gas density profiles although additional work is required to improve the accuracy of this technique. Heat flux is inferred from temperature-drop measurements using precision thermistors. The system can be operated with a variety of gases (monatomic, diatomic, polyatomic, mixtures) and carefully controlled, well-characterized surfaces of different types (metals, ceramics) and conditions (smooth, rough). The measurements reported here are for 304 stainless steel plates with a standard machined surface coupled with argon, helium, and nitrogen. The resulting heat-flux and gas-density-profile data are analyzed using analytic and computational models to show that a simple Maxwell gas-surface interaction model is adequate to represent all of the observations. Based on this analysis, thermal accommodation coefficients for 304 stainless steel coupled with argon, nitrogen, and helium are determined to be 0.88, 0.80, and 0.38, respectively, with an estimated uncertainty of {+-}0.02.

Published
2004

13. Filtered Rayleigh scattering diagnostic for multi-parameter thermal-fluids measurements : LDRD final report

Author

Steven J. Beresh, Sean P. Kearney, Thomas W. Grasser, and Robert W. Schefer

Subjects
Premixed flame, Jet (fluid), symbols.namesake, Mach number, Chemistry, Diffusion flame, symbols, Analytical chemistry, Hypersonic wind tunnel, Rayleigh scattering, Combustion, Light scattering, Computational physics
Abstract

Simulation-based life-cycle-engineering and the ASCI program have resulted in models of unprecedented size and fidelity. The validation of these models requires high-resolution, multi-parameter diagnostics. Within the thermal-fluids disciplines, the need for detailed, high-fidelity measurements exceeds the limits of current engineering sciences capabilities and severely tests the state of the art. The focus of this LDRD is the development and application of filtered Rayleigh scattering (FRS) for high-resolution, nonintrusive measurement of gas-phase velocity and temperature. With FRS, the flow is laser-illuminated and Rayleigh scattering from naturally occurring sources is detected through a molecular filter. The filtered transmission may be interpreted to yield point or planar measurements of three-component velocities and/or thermodynamic state. Different experimental configurations may be employed to obtain compromises between spatial resolution, time resolution, and the quantity of simultaneously measured flow variables. In this report, we present the results of a three-year LDRD-funded effort to develop FRS combustion thermometry and Aerosciences velocity measurement systems. The working principles and details of our FRS opto-electronic system are presented in detail. For combustion thermometry we present 2-D, spatially correlated FRS results from nonsooting premixed and diffusion flames and from a sooting premixed flame. The FRS-measured temperatures are accurate to within {+-}50 Kmore » (3%) in a premixed CH4-air flame and within {+-}100 K for a vortex-strained diluted CH4-air diffusion flame where the FRS technique is severely tested by large variation in scattering cross section. In the diffusion flame work, FRS has been combined with Raman imaging of the CH4 fuel molecule to correct for the local light scattering properties of the combustion gases. To our knowledge, this is the first extension of FRS to nonpremixed combustion and the first use of joint FRS-Raman imaging. FRS has been applied to a sooting C2H4-air flame and combined with LII to assess the upper sooting limit where FRS may be utilized. The results from this sooting flame show FRS temperatures has potential for quantitative temperature imaging for soot volume fractions of order 0.1 ppm. FRS velocity measurements have been performed in a Mach 3.7 overexpanded nitrogen jet. The FRS results are in good agreement with expected velocities as predicted by inviscid analysis of the jet flowfield. We have constructed a second FRS opto-electronic system for measurements at Sandia's hypersonic wind tunnel. The details of this second FRS system are provided here. This facility is currently being used for velocity characterization of these production hypersonic facilities.« less

Published
2004

14. Filtered Rayleigh Scattering Thermometry in a Premixed Sooting Flame

Author

Steven J. Beresh, Sean P. Kearney, and Thomas W. Grasser

Subjects
Elastic scattering, Scattering, business.industry, Chemistry, Analytical chemistry, Context (language use), medicine.disease_cause, Laser, Soot, law.invention, symbols.namesake, Optics, law, Incandescence, Volume fraction, medicine, symbols, Rayleigh scattering, business
Abstract

Filtered Rayleigh Scattering (FRS) is demonstrated in a premixed, sooting ethylene-air flame. In sooting flames, traditional laser-based temperature-imaging techniques such linear (unfiltered) Rayleigh scatting (LRS) and planar laser-induced fluorescence (PLIF) are rendered intractable due to intense elastic scattering interferences from in-flame soot. FRS partially overcomes this limitation by utilizing a molecular iodine filter in conjunction with an injection-seeded Nd:YAG laser, where the seeded laser output is tuned to line center of a strong iodine absorption transition. A significant portion of the Doppler-broadened molecular Rayleigh signal is then passed while intense soot scattering at the laser line is strongly absorbed. In this paper, we demonstrate the feasibility of FRS for sooting flame thermometry using a premixed, ethylene-air flat flame. We present filtered and unfiltered laser light-scattering images, FRS temperature data, and laser-induced incandescence (LII) measurements of soot volume fraction for fuel-air equivalence ratios of φ = 2.19 and 2.24. FRS-measured product temperatures for these flames are nominally 1500 K. The FRS temperature and image data are discussed in the context of the soot LII results and a preliminary estimate of the upper sooting limit for our FRS system of order 0.1 ppm volume fraction is obtained.

Published
2004

16. Temperature Imaging of Vortex-Flame Interaction by Filtered Rayleigh Scattering

Author

Steven J. Beresh, Sean P. Kearney, Robert W. Schefer, and Thomas W. Grasser

Subjects
Scattering, business.industry, Chemistry, Diffusion flame, Laminar flow, Combustion, Temperature measurement, Vortex, symbols.namesake, Optics, symbols, Rayleigh scattering, Diffusion (business), business
Abstract

This paper describes the application of a filtered-Rayleigh-scattering (FRS) instrument for nonintrusive temperature imaging in a vortex-driven diffusion flame. The FRS technique provides quantitative, spatially correlated temperature data without the flow intrusion or time lag associated with physical probes. Use of a molecular iodine filter relaxes the requirement for clean, particulate-free flowfields and offers the potential for imaging near walls, test section windows and in sooty flames, all of which are preculded in conventional Rayleigh imaging, where background interference from these sources typically overwhelms the weak molecular scattering signal. For combustion applications, FRS allows for full-field temperature imaging without chemical seeding of the flowfield, which makes FRS an attractive alternative to other laser-based imaging methods such as planar laser-induced fluorescencs (PLIF). In this work, the details of our FRS imaging system are presented and temperature measurements from an acoustically forced diffusion flame are provided. The local Rayleigh crosssection is corrected using Raman imaging measurements of the methane fuel molecule, which are then correlated to other major species using a laminar flamelet approach. To our knowledge, this is the first report of joint Raman/FRS imaging for nonpremixed combustion. Measurements are presented from flames driven at 7.5 Hz, where a single vortex stretches the flame, and at 90 Hz, where two consecutive vortices interact to cause a repeatable strain-induced flame-quenching event.

Published
2003

17. A Combined PLIF/PIV System for Simultaneous Gas-Phase Temperature/Velocity Imaging

Author

Sean P. Kearney, Thomas W. Grasser, and Christopher Jay Bourdon

Subjects
Convection, Chemistry, business.industry, Turbulence, Instrumentation, Analytical chemistry, Laminar flow, Laser, Temperature measurement, law.invention, Physics::Fluid Dynamics, Optics, Particle image velocimetry, law, Heat transfer, business
Abstract

This paper reports non-intrusive temperature and velocity imaging measurements in gas-phase flows using acetone planar laser-induced fluorescence (PLIF) thermometry and particle image velocimetry (PIV). The details of the combined PLIF/PIV instrument and the demonstration flow facilities are provided and results are presented from a turbulent Rayleigh-Benard convection flow (PLIF only) and from an unsteady laminar impinging jet flow (combined PLIF/PIV). The data show that PLIF temperature imaging at laboratory scales is most effective for characteristic temperature differences on the order of 100 K of more. Simultaneous gas-phase temperature-velocity images are presented which show that PLIF-PIV holds promise for detailed laboratory scale measurements for gas-phase convective heat-transfer applications at high temperature differences.Copyright © 2002 by ASME

Published
2002

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