In this paper numerical simulations of active vibration control for conical shell structure with dis-tributed piezoelectric actuators is presented.The dynamic equations of conical shell structure are derivedusing the ...In this paper numerical simulations of active vibration control for conical shell structure with dis-tributed piezoelectric actuators is presented.The dynamic equations of conical shell structure are derivedusing the finite element model (FEM) based on Mindlin's plate theory.The results of modal calculationswith FEM model are accurate enough for engineering applications in comparison with experiment results.The Electromechanical influence of distributed piezoelectric actuators is treated as a boundary conditionfor estimating the control force.The independent modal space control (IMSC) method is adopted and theoptimal linear quadratic state feedback control is implemented so that the best control performance withthe least control cost can be achieved.Optimal control effects are compared with controlled responses withother non-optimal control parameters.Numerical simulation results are given to demonstrate the effective-ness of the control scheme.展开更多
Despite Spain is a well-known worldwide developer of solar and wind energy, nowadays the wave energy is presented as an interesting alternative. Although depending on wind, marine energetic stability is higher than th...Despite Spain is a well-known worldwide developer of solar and wind energy, nowadays the wave energy is presented as an interesting alternative. Although depending on wind, marine energetic stability is higher than the one depending on air masses. For this reason, the use on isolated networks would bring a great benefit, as they have less perturbation than the other mentioned energies In addition to this, the subtropical weather is famous for its climatic stability and the lack of extreme conditions. For this paper, firstly, an initial analysis was carried out, comparing the most important wave converters in developing at the moment, in which the "Wave Dragon" device was chosen as the most promising. Secondly, the Gran Canaria's wave potential was studied using a numeric model based on data obtained from "Wana" points. Finally, the feasibility of implementing the "Wave Dragon" device in Gran Canaria was tested using simulations that were based in the previously obtained data, remarking the protection of the system against instabilities in the generation of renewable energies.展开更多
基金the National Defense Advanced Research Project(No.41320020302)
文摘In this paper numerical simulations of active vibration control for conical shell structure with dis-tributed piezoelectric actuators is presented.The dynamic equations of conical shell structure are derivedusing the finite element model (FEM) based on Mindlin's plate theory.The results of modal calculationswith FEM model are accurate enough for engineering applications in comparison with experiment results.The Electromechanical influence of distributed piezoelectric actuators is treated as a boundary conditionfor estimating the control force.The independent modal space control (IMSC) method is adopted and theoptimal linear quadratic state feedback control is implemented so that the best control performance withthe least control cost can be achieved.Optimal control effects are compared with controlled responses withother non-optimal control parameters.Numerical simulation results are given to demonstrate the effective-ness of the control scheme.
文摘Despite Spain is a well-known worldwide developer of solar and wind energy, nowadays the wave energy is presented as an interesting alternative. Although depending on wind, marine energetic stability is higher than the one depending on air masses. For this reason, the use on isolated networks would bring a great benefit, as they have less perturbation than the other mentioned energies In addition to this, the subtropical weather is famous for its climatic stability and the lack of extreme conditions. For this paper, firstly, an initial analysis was carried out, comparing the most important wave converters in developing at the moment, in which the "Wave Dragon" device was chosen as the most promising. Secondly, the Gran Canaria's wave potential was studied using a numeric model based on data obtained from "Wana" points. Finally, the feasibility of implementing the "Wave Dragon" device in Gran Canaria was tested using simulations that were based in the previously obtained data, remarking the protection of the system against instabilities in the generation of renewable energies.
