Quieting a Rib-Framed Honeycomb Core Sandwich Panel for a Rotorcraft Roof

Hambric, Stephen A.; Shepherd, Micah R.; Schiller, Noah H.; Snider, Royce; May, Carl

doi:10.4050/jahs.62.012009

Cited by 9 publications

(4 citation statements)

References 7 publications

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“…In general, these forces can change from repulsion to attraction with small changes in these parameters [ 13 , 14 ], making them unpredictable and, consequently, potentially leading to erratic behaviors. The ground and wall effect combination [ 15 ], as well as the tilt angle of the UAV [ 16 ], increase the effect of this phenomenon.…”

Section: Introductionmentioning

confidence: 99%

Towards Precise Positioning and Movement of UAVs for Near-Wall Tasks in GNSS-Denied Environments

Orjales

Losada-Pita

Deibe

2021

Sensors

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UAVs often perform tasks that require flying close to walls or structures and in environments where a satellite-based location is not possible. Flying close to solid bodies implies a higher risk of collisions, thus requiring an increase in the precision of the measurement and control of the UAV’s position. The aerodynamic distortions generated by nearby walls or other objects are also relevant, making the control more complex and further placing demands on the positioning system. Performing wall-related tasks implies flying very close to the wall and, in some cases, even touching it. This work presents a Near-Wall Positioning System (NWPS) based on the combination of an Ultra-wideband (UWB) solution and LIDAR-based range finders. This NWPS has been developed and tested to allow precise positioning and orientation of a multirotor UAV relative to a wall when performing tasks near it. Specific position and orientation control hardware based on horizontal thrusters has also been designed, allowing the UAV to move smoothly and safely near walls.

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Section: Introductionmentioning

confidence: 99%

Towards Precise Positioning and Movement of UAVs for Near-Wall Tasks in GNSS-Denied Environments

Orjales

Losada-Pita

Deibe

2021

Sensors

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“…Adel and Steven minimized the single-objective function and multi-objective functions for foam sandwich plates with hybrid composite face sheets subjected to bending and torsional stiffness constraints [ 33 ]. Some articles discussed experimental and computational analysis to assess foam-formed materials’ sound insulation capabilities and applied the gray relational analysis method and multi-objective particle swarm optimization algorithm to develop the acoustic performances of foam composites [ 34 , 35 , 36 ]. Khan et al described the improvement models of the smallest cell for quantifying the deformation and failure modes for a core structure under static loadings [ 37 ].…”

Section: Introductionmentioning

confidence: 99%

“…Some articles discussed experimental and computational analysis to assess foamformed materials' sound insulation capabilities and applied the gray relational analysis method and multi-objective particle swarm optimization algorithm to develop the acoustic performances of foam composites [34][35][36]. Khan et al described the improvement models of the smallest cell for quantifying the deformation and failure modes for a core structure under static loadings [37].…”

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confidence: 99%

Optimization of a Totally Fiber-Reinforced Plastic Composite Sandwich Construction of Helicopter Floor for Weight Saving, Fuel Saving and Higher Safety

2021

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The application of fiber-reinforced plastic (FRP) composites as structural elements of air vehicles provides weight saving, which results in a reduction in fuel consumption, fuel cost, and air pollution, and a higher speed. The goal of this research was to elaborate a new optimization method for a totally FRP composite construction for helicopter floors. During the optimization, 46 different layer combinations of 4 different FRP layers (woven glass fibers with phenolic resin; woven glass fibers with epoxy resin; woven carbon fibers with epoxy resin; hybrid composite) and FRP honeycomb core structural elements were investigated. The face sheets were composed of a different number of layers with cross-ply, angle-ply, and multidirectional fiber orientations. During the optimization, nine design constraints were considered: deflection; face sheet stress (bending load, end loading); stiffness; buckling; core shear stress; skin wrinkling; intracell buckling; and shear crimping. The single-objective weight optimization was solved by applying the Interior Point Algorithm of the Matlab software, the Generalized Reduced Gradient (GRG) Nonlinear Algorithm of the Excel Solver software, and the Laminator software. The Digimat-HC software solved the numerical models for the optimum sandwich plates of helicopter floors. The main contribution is developing a new method for optimizing a totally FRP composite sandwich structure—due to its material constituents and construction—that is more advantageous than traditional helicopter floors. A case study validated this fact.

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“…The applications that are considered include aerospace, and marine and naval engineering. A redesign of a rotorcraft sandwich roof minimizing structure-borne sound and optimizing the sound power transmission loss was investigated by Hambric et al. (2017).…”

Section: Introductionmentioning

confidence: 99%

Analysis of sandwich Timoshenko porous beam with temperature-dependent material properties: Magneto-electro-elastic vibration and buckling solution

Bamdad

Mohammadimehr

Alambeigi

2019

Journal of Vibration and Control

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Vibration and buckling analysis of a magneto-electro-elastic sandwich Timoshenko beam with a porous core and poly-vinylidene fluoride (PVDF) matrix reinforced by carbon nanotubes (CNTs) is considered as face layers and material properties of CNTs and PVDF are assumed to be temperature-dependent. Different CNT distribution patterns including uniform distribution, AV (which top and bottom face sheets have functionally graded-A (FG-A) and functionally graded-V (FG-V) CNT distribution patterns, respectively) and VA patterns are employed. The governing equations of motion are derived based on Timoshenko beam theory, and Navier's solution is used to solve these equations. The sandwich beam resting on a Pasternak foundation and face layers are subjected to electric and magnetic potentials. The effect of different parameters such as porosity coefficient, electric and magnetic potential, parameters of foundation, and geometrical parameters are investigated on vibration and buckling behavior of the sandwich beam. Numerical results of this paper show that porosity distribution has a significant effect on the stiffness of the sandwich beam. The results can be used for future analysis of magneto-electro-mechanical sandwich systems as actuators and sensors.

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Quieting a Rib-Framed Honeycomb Core Sandwich Panel for a Rotorcraft Roof

Cited by 9 publications

References 7 publications

Towards Precise Positioning and Movement of UAVs for Near-Wall Tasks in GNSS-Denied Environments

Towards Precise Positioning and Movement of UAVs for Near-Wall Tasks in GNSS-Denied Environments

Optimization of a Totally Fiber-Reinforced Plastic Composite Sandwich Construction of Helicopter Floor for Weight Saving, Fuel Saving and Higher Safety

Analysis of sandwich Timoshenko porous beam with temperature-dependent material properties: Magneto-electro-elastic vibration and buckling solution

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