Aeroservoelastic analysis of the blade-sailing phenomenon in the helicopter-ship dynamic interface.

Roberto Luiz da Cunha Barroso Ramos

02 May 2007

This thesis proposes a Rotary-Wing Aeroservoelasticity approach to the modeling, analysis and control of the blade-sailing phenomenon in the helicopter-ship dynamic interface (DI), based on the identification, response evaluation and control of flow and ship motion induced loads, during the engagement/disengagement flight regimes, in order to establish some principles for the design and safe operation of shipboard rotorcraft systems. The nonlinear aeroelastic analysis revealed that the nonlinearity due to large flapping deflections and to the centrifugal forces is not relevant for normal operating conditions, whereas the nonlinear effects due to the flapping stops in articulated rotors influence significantly the blade-sailing vibrations. These nonlinear effects related to the stops can be tackled with approximate stiffness functions. The nonlinear analysis confirmed that hingeless rotor blade-sailing vibrations are lower than that of the articulated rotor, however, the differences are small for rotors with similar structural/geometric characteristics. The blade-sailing phenomenon in the DI and the flapping response during engagement/disengagement shipboard operations can be analyzed trough an oscillator system with nonlinear stiffness related to the droop and flap stops and time-varying coefficients related to the undisturbed flow velocity and to the parameters of the proposed active proportional-derivative individual blade control (PD-IBC). The aeroelastic analysis also showed that blade sailing is a cooperative phenomenon. Though the mean flow vertical velocity gradient across the rotor be the single most important factor, the combination of horizontal wind velocities, fluctuating flow vertical velocities, gravity and ship motion effects may give rise to excessive flapping vibrations. The proposed active proportional-derivative state feedback individual blade control (PD-IBC) can obtain blade-sailing flapping vibration reduction of 30% for shipboard articulated rotors at moderate wind-over-deck (WOD) conditions/advance ratios, without monitoring the DI environment, and a reduction greater than 40% if combined with shipboard rotor plant modifications, involving an increase of the blade flapwise stiffness and an aerodynamic design of the ship flight deck, considering the current blade pitch input limits of the actuators. Therefore, the implementation of active feedback aeroelastic control methods may be one of the most important measures for blade-sailing mitigation in the DI.

Helicópteros

Aeroservoelasticidade

Lâminas de rotores (turbomáquinas)

Embarcações

Porta-aviões

Controle automático de vôo

Mecânica de vôo

Engenharia aeronáutica

Projeto e análise de desempenho de uma turbina axial utilizada em uma unidade de turbobomba de um motor foguete a propelente líquido na faixa de 55 kN de empuxo

Juraci de Sousa Araujo Filho

11 August 2009

As características de um motor foguete a propelente líquido podem levar a turbina a operar em ciclo aberto ou em ciclo fechado. No caso de um motor que opera em ciclo térmico aberto, a turbina é supersônica, de ação e de admissão parcial. Já para o caso de um motor que opera em ciclo fechado, a turbina é sônica, de reação e admissão total. O uso da admissão parcial leva a turbina a ter altura de pá maior do que no caso da admissão total. Esta característica faz com que o desempenho aumente consideravelmente, pois caso a turbina operasse em admissão total, as perdas por vazamento e secundárias seriam excessivamente altas.

Turbinas axiais

Escoamento supersônico

Bombas de turbinas

Lâminas de rotores (turbomáquinas)

Motores foguetes a propelente líquido

Engenharia mecânica

Engenharia aeroespacial