L. Danielle Koch scite author profile

L. Danielle Koch

5Publications

33Citation Statements Received

18Citation Statements Given

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Affiliations

Glenn Research Center, Goethe University Frankfurt, General Motors (India)

Publications

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Flow field comparisons from three Navier-Stokes solvers for an axisymmetric separate flow jet

Koch

Bridges²,

Khavaran

2002

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To meet new noise reduction goals, many concepts to enhance mixing in the exhaust jets of turbofan engines are being studied. Accurate steady state flowfield predictions from state-of-the-art computational fluid dynamics (CFD) solvers are needed as input to the latest noise prediction codes. The main intent of this paper was to ascertain that similar Navier-Stokes solvers run at different sites would yield comparable results for an axisymmetric two-stream nozzle case. Predictions from the WIND and the NPARC codes are compared to previously reported experimental data and results from the CRAFT Navier-Stokes solver. Similar k-epsilon turbulence models were employed in each solver, and identical computational grids were used. Agreement between experimental data and predictions from each code was generally good for mean values. All three codes underpredict the maximum value of turbulent kinetic energy. The predicted locations of the maximum turbulent kinetic energy were farther downstream than seen in the data. A grid study was conducted using the WIND code, and comments about convergence criteria and grid requirements for CFD solutions to be used as input for noise prediction computations are given. Additionally, noise predictions from the MGBK code, using the CFD results from the CRAFT code, NPARC, and WIND as input are compared to data.

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Mean Flow and Noise Prediction for a Separate Flow Jet with Chevron Mixers

Koch

Bridges

Khavaran

2004

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Experimental and analytical determination of the geometric far field for round jets

et al. 2005

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An introduction to NASA’s broadband acoustic absorbers that resemble natural reeds

Koch

Jones

Bonacuse

et al. 2021

International Journal of Aeroacoustics

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Thin, lightweight, and durable broadband acoustic absorbers capable of absorbing sounds over a wide frequency range, especially below 1000 Hz, while also surviving harsh operational conditions such as exposure to sprays of liquid and solid debris and high temperatures are desired for many noise control applications. While today’s commercially available broadband acoustic liners are impressive, such as melamine foam and perforate-over-honeycomb structures, each style has its limitations. Motivated by the need to reduce aircraft engine noise pollution NASA has recently patented a broadband acoustic absorber that claims some benefit over existing acoustic liners. Inspired by nature, these structures resemble the geometry and acoustic absorption of bundles of natural reeds, slender grasses that grow in wetlands across the world. Proof-of-concept experiments have begun at NASA. This report summarizes the design, fabrication, and normal incidence impedance tube tests performed for assemblies of natural reeds and additively-manufactured plastic prototypes that resemble the irregular geometry of bundles of natural reeds. Some synthetic prototypes were tested with and without perforated face sheets. Results indicate that there are a number of synthetic designs that exhibit substantial acoustic absorption in the frequency range of 500 Hz to 3000 Hz, and especially below 1000 Hz, as compared to baseline acoustic absorbers of similar thicknesses and weights. Many of these prototypes have an average acoustic absorption coefficient greater than 0.6. Additionally, an annular prototype was designed and printed but not yet subjected to tests. This annular prototype of a multifunctional structure designed to transfer heat and absorb sound was developed to fit inside the NASA Glenn Research Center’s DGEN Aeropropulsion Research Turbofan engine testbed. This invention can be considered and developed for a variety of aerospace, automotive, industrial, and architectural noise control applications.

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An Experimental Study of Fan Inflow Distortion Tone Noise

Koch

2009

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L. Danielle Koch

Flow field comparisons from three Navier-Stokes solvers for an axisymmetric separate flow jet

Mean Flow and Noise Prediction for a Separate Flow Jet with Chevron Mixers

Experimental and analytical determination of the geometric far field for round jets

An introduction to NASA’s broadband acoustic absorbers that resemble natural reeds

An Experimental Study of Fan Inflow Distortion Tone Noise

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