Liquid Propellant Mass Measurement in Microgravity

AbstractThe Modal Propellant Gauging (MPG) experiment has demonstrated sub-1% gauging accuracy under laboratory conditions on both flight hardware and subscale tanks. Recently, MPG was adapted for flight on Blue Origin's New Shepard vehicle and has flown twice, achieving equilibrated, zero-g surface configurations of propellant simulant at three different fill fractions. Flight data from MPG missions on New Shepard P7 and P9 show agreement between known and measured propellant levels of 0.3% for the fill fractions investigated in the present study. Two approaches for estimating zero-g propellant mass are described here. Both approaches rely on measuring shifts in modal frequencies of a tank excited by acoustic surface waves and subject to fluid mass loading by the propellant. In the first approach, shifts in the lowest mode frequency (LMF) are measured and associated with liquid fill-level changes. In the second approach, 1-g modal spectra at a range of known fill levels are used in a cross-correlation calculation to predict fill levels associated with a zero-g modal spectrum. Flight data for both approaches are consistent with finite element predictions using a simple fluid–structure interaction model. In both settled and unsettled microgravity environments, MPG meets or exceeds NASA Roadmap goals for in-space propellant mass gauging.

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One-way fluid-structure interaction model to study the influence of the fluid velocity and coolant channel thickness on the stability of nuclear fuel plates

10.26678/abcm.cobem2017.cob17-0121 ◽

2017 ◽

Author(s):

Javier González Mantecón ◽

Miguel Mattar Neto

Keyword(s):

Nuclear Fuel ◽

Fluid Velocity ◽

Fluid Structure Interaction ◽

Interaction Model ◽

Fluid Structure ◽

Structure Interaction ◽

Channel Thickness ◽

The Stability

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CFD Investigation of Trout-Like Configuration Holding Station near an Obstruction

Fluids ◽

10.3390/fluids6060204 ◽

2021 ◽

Vol 6 (6) ◽

pp. 204

Author(s):

Kamran Fouladi ◽

David J. Coughlin

Keyword(s):

Fluid Dynamics ◽

Computational Fluid Dynamics ◽

Laboratory Experiment ◽

Numerical Models ◽

Interaction Model ◽

Underwater Vehicle ◽

Water Stream ◽

Hydrodynamic Analysis ◽

Structure Interaction ◽

Vehicle Systems

This report presents the development of a fluid-structure interaction model using commercial Computational fluid dynamics software and in-house developed User Defined Function to simulate the motion of a trout Department of Mechanical Engineering, Widener University holding station in a moving water stream. The oscillation model used in this study is based on the observations of trout swimming in a respirometry tank in a laboratory experiment. The numerical simulations showed results that are consistent with laboratory observations of a trout holding station in the tank without obstruction and trout entrained to the side of the cylindrical obstruction. This paper will be helpful in the development of numerical models for the hydrodynamic analysis of bioinspired unmanned underwater vehicle systems.

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Running safety evaluation of a 350 km/h high-speed freight train negotiating a curve based on the arbitrary Lagrangian-Eulerian method

Proceedings of the Institution of Mechanical Engineers Part F Journal of Rail and Rapid Transit ◽

10.1177/0954409720986283 ◽

2021 ◽

pp. 095440972098628

Author(s):

Gongxun Deng ◽

Yong Peng ◽

Chunguang Yan ◽

Boge Wen

Keyword(s):

High Speed ◽

Safety Evaluation ◽

Interaction Model ◽

Arbitrary Lagrangian Eulerian ◽

Railway Transportation ◽

Freight Train ◽

Fluid Structure ◽

Running Safety ◽

Study Results ◽

Fill Level

To adapt to the rapid growth of the logistics market and further improve the competitiveness of railway transportation, the high-speed freight train with a design speed of 350 km/h is being developed in China. The safety of the train under great axle load of 17 t and dynamic load is unknown. This paper is aimed to study the running safety of the high-speed freight train coupled with various cargo loading conditions negotiating a sharp curve at high velocity. A numerical model integrated a fluid-structure coupled container model and the nonlinear high-speed freight train was set up by the software of LS-DYNA. The fluid-structure interaction model between the container and fluid cargo was established using the Arbitrary Lagrangian-Eulerian (ALE) method. Two influencing parameters, including the cargo state in the container and the fill level, were selected. The study results showed that the wheelset unloading ratio and overturning coefficient could be significantly affected by the liquid sloshing, while the influence of sloshing on the risk of derailment was slight. In general, increasing the cargo filling rate would contribute to vehicle operation safety. In conclusion, this study would provide theoretical help for the running safety of the newly designed high-speed freight train.

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Fully coupled fluid-structure interaction model of reed valves in a multi-cylinder reciprocating piston compressor

IOP Conference Series Materials Science and Engineering ◽

10.1088/1757-899x/232/1/012030 ◽

2017 ◽

Vol 232 ◽

pp. 012030

Author(s):

F Xie ◽

J Nieter ◽

A Lifson ◽

R Reba ◽

V Sishtla

Keyword(s):

Fluid Structure Interaction ◽

Interaction Model ◽

Piston Compressor ◽

Fluid Structure ◽

Structure Interaction ◽

Fully Coupled

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Specification Document for OC6 Phase II: Verification of an Advanced Soil-Structure Interaction Model for Offshore Wind Turbines

10.2172/1811648 ◽

2021 ◽

Author(s):

Roger Bergua ◽

Amy Robertson ◽

Jason Jonkman ◽

Andy Platt

Keyword(s):

Phase Ii ◽

Wind Turbines ◽

Soil Structure ◽

Interaction Model ◽

Offshore Wind ◽

Soil Structure Interaction ◽

Offshore Wind Turbines ◽

Structure Interaction ◽

Specification Document

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An Investigation of the Aerodynamic and Vibration Behavior of a Helicopter Rotor Blade

Volume 4: Advances in Aerospace Technology ◽

10.1115/imece2020-23668 ◽

2020 ◽

Author(s):

Mohammad Khairul Habib Pulok ◽

Uttam K. Chakravarty

Keyword(s):

Rotor Blade ◽

Fluid Structure Interaction ◽

Interaction Model ◽

Scale Model ◽

Helicopter Rotor ◽

Small Scale ◽

Fluid Structure ◽

Structure Interaction ◽

Aerodynamic Analysis ◽

Helicopter Rotor Blade

Abstract Rotary-wing aircrafts are the best-suited option in many cases for its vertical take-off and landing capacity, especially in any congested area, where a fixed-wing aircraft cannot perform. Rotor aerodynamic loading is the major reason behind helicopter vibration, therefore, determining the aerodynamic loadings are important. Coupling among aerodynamics and structural dynamics is involved in rotor blade design where the unsteady aerodynamic analysis is also imperative. In this study, a Bo 105 helicopter rotor blade is considered for computational aerodynamic analysis. A fluid-structure interaction model of the rotor blade with surrounding air is considered where the finite element model of the blade is coupled with the computational fluid dynamics model of the surrounding air. Aerodynamic coefficients, velocity profiles, and pressure profiles are analyzed from the fluid-structure interaction model. The resonance frequencies and mode shapes are also obtained by the computational method. A small-scale model of the rotor blade is manufactured, and experimental analysis of similar contemplation is conducted for the validation of the numerical results. Wind tunnel and vibration testing arrangements are used for the experimental validation of the aerodynamic and vibration characteristics by the small-scale rotor blade. The computational results show that the aerodynamic properties of the rotor blade vary with the change of angle of attack and natural frequency changes with mode number.

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