Evaluation of piezoelectric energy harvester under dynamic bending by means of hybrid mathematical/isogeometric analysis

Akbar, Mahesa; Curiel-Sosa, J.L.

doi:10.1007/s10999-017-9395-0

Cited by 9 publications

(5 citation statements)

References 44 publications

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“…Akbar and Curiel-Sosa [25] proposed the hybrid analytical/numerical scheme for dynamic bending condition which implemented in a cruise scenario. The extension of the hybrid scheme can be seen in [26]. Advance numerical method, i.e., isogeometric analysis, is coupled with the scheme and provides better shear locking resistance.…”

Section: Introductionmentioning

confidence: 99%

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Implementation of multiphase piezoelectric composites energy harvester on aircraft wingbox structure with fuel saving evaluation

Akbar¹,

Curiel-Sosa²

2018

Composite Structures

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The multiphase composite with active structural fiber (ASF) has proven able to provide better optimization between actuating and load bearing capability compared to a pure piezoelectric material. In this paper, the multiphase composite application is further extended for energy harvesting purpose. The Double-Inclusion model combined with Mori-Tanaka method is implemented in a computational code to estimate the effective electro-elastic properties of the multiphase composite. The effective composite properties obtained via the present code are in good agreement with the analytical, experimental and finite element results. The multiphase composite with different composition is applied to a typical jet aircraft wingbox with 14.5 m halfspan. The energy harvesting evaluation by means of hybrid FEM/analytical piezoelectric energy harvester model is presented. A new procedure to investigate the trade-off between the aircraft weight, the fuel saving and the energy harvested is developed. The results pointed out that the equivalent fuel saved from the power generated by the wingbox is more than enough for 1 hour Auxiliary Power Unit (APU) operation.

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Section: Introductionmentioning

confidence: 99%

“…Shear locking itself commonly occurs in thin shells and leads to a poor accuracy [27,28]. The hybrid scheme also shows faster computational time compared to a full electromechanical finite element model [26]. Hence, it is considered a good alternative in the early design stage.…”

Section: Introductionmentioning

confidence: 99%

Implementation of multiphase piezoelectric composites energy harvester on aircraft wingbox structure with fuel saving evaluation

Akbar¹,

Curiel-Sosa²

2018

Composite Structures

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“…Implementation of plate and shell theories for advanced piezoelectric composite has also been proposed in various studies, from the classical plate theory to a higher-order shear deformation theory [34], as well as for static and dynamic analyses [35,36]. Moreover, new piezoelectric finite element concepts for energy harvesting have also been discussed in a few articles [37,38].…”

Section: Introductionmentioning

confidence: 99%

Evaluation of Piezoelectric-based Composite for Actuator Application via FEM with Thermal Analogy

Kevin,

Akbar,

Gunawan

et al. 2023

TECM

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In the present work, a new study on the piezoelectric-based structure by means of Finite Element Method (FEM) is conducted. Currently, the piezoelectric model in the FEM-based commercial software is only applicable via 2D plane stress and 3D solid elements. However, piezoelectric structures are usually manufactured as thin-walled structures, i.e., plates and disks. Therefore, it is more convenient to model a piezoelectric-based structure with 2D shell elements. In this study, FEM with a thermal analogy approach is implemented. Thermal coupling characteristics are utilised as the equivalent of electromechanical properties. Thermal analysis is much more established in FEM-based software; thus, applications with various types of elements are enabled. Therefore, the evaluation of piezoelectric structure via shell element with a thermal analogy approach could be performed. Static and dynamic analyses are conducted with experimental and numerical validations. As depicted in some details in this paper, the shell model with thermal analogy shows an excellent agreement with the 3D solid piezoelectric elements with insignificant variances, less than 0.3%.

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“…This hybrid scheme was implemented to evaluate energy harvesting potential from a wingbox of a civil jet transport aircraft. Further discussed in [40], a faster computational time was benefitted from this hybrid scheme compared to the full electromechanically coupled FEM of [16]. The hybrid scheme was further elaborated in [39].…”

Section: Introductionmentioning

confidence: 99%

“…Despite the fact that the models built in [13,14,[34][35][36][37] provided the platforms to evaluate the energy harvesting potential from the lifting structure under cruise/gust loads, to the authors ′ knowledge, comparison with other methods have not yet been conducted. Only the hybrid scheme in [38,40] has been validated with analytical and FEM solutions, although the approach was only compared to the base excitation problem of [41]. Therefore, in the present work, a novel computational method to evaluate the energy harvesting on the lifting structure is developed.…”

Section: Introductionmentioning

confidence: 99%

An iterative finite element method for piezoelectric energy harvesting composite with implementation to lifting structures under Gust Load Conditions

Akbar

Curiel-Sosa

2019

Composite Structures

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In this paper, a novel iterative finite element method (FEM) for energy harvesting purpose is presented. The new iterative FEM is implemented to solve the dynamic problems of piezoelectric-based energy harvester in the frequency and time domains. The validation against other methods from the literature shows the robustness and capabilities of the iterative FEM. Implementation to a transport aircraft wingbox with 14.5 m half span and an embedded piezoelectric layer is shown in some details. The energy harvesting potential of the wingbox due to the cruise and the 1-cosine gust loads is investigated. In addition, for the first time, stress and failure analyses of the structure with an active energy harvesting layer are performed. The results pointed out that the wingbox is still in a safe condition even when it is subjected to a 30 m/s gust amplitude while harvesting 51 kW power.

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Evaluation of piezoelectric energy harvester under dynamic bending by means of hybrid mathematical/isogeometric analysis

Cited by 9 publications

References 44 publications

Implementation of multiphase piezoelectric composites energy harvester on aircraft wingbox structure with fuel saving evaluation

Implementation of multiphase piezoelectric composites energy harvester on aircraft wingbox structure with fuel saving evaluation

Evaluation of Piezoelectric-based Composite for Actuator Application via FEM with Thermal Analogy

An iterative finite element method for piezoelectric energy harvesting composite with implementation to lifting structures under Gust Load Conditions

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