Coupling of experimentally validated electroelastic dynamics and mixing rules formulation for macro-fiber composite piezoelectric structures

Shahab, Shima; Ertürk, Alper

doi:10.1177/1045389x16672732

Cited by 35 publications

(38 citation statements)

References 62 publications

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“…However, conventional PZT ceramics are rigid and brittle, making their application in structures with uneven surface unfeasible. To overcome this drawback, more recently, macrofiber composite (MFC) transducers were proposed as an alternative (Brunner et al, 2009;Shahab and Erturk, 2016). These devices are low-profile, flexible, and durable, making their use in many types of structures feasible.…”

Section: Introductionmentioning

confidence: 99%

Performance of three transducer mounting methods in impedance-based structural health monitoring applications

Silveira

Campeiro

Baptista

2017

Journal of Intelligent Material Systems and Structures

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Piezoelectric transducers are widely used in many nondestructive methods for damage detection in structural health monitoring applications. Among the various methods for detecting damage, the electromechanical impedance technique is known for using thin and small piezoelectric ceramics operating simultaneously as actuators and sensors. The basic method of installing these piezoelectric ceramics in the host structure is using a high-stiffness adhesive such as epoxy or cyanoacrylate glue. However, some studies have proposed alternative methods of transducer mounting, therein aiming to reuse the transducer or allowing for the monitoring of structures under adverse conditions under which the direct installation of the sensor would not be possible. Thus, the objective of this study is to analyze and compare the performance of three main mounting methods for metal structures for applications based on the electromechanical impedance technique: magnetic mounting, metal-wire-based mounting, and conventional mounting using adhesives. Tests were conducted on aluminum beams, and the performances of the three transducer mounting methods were compared using basic damage indices and the pencil-lead-break test. The experimental results indicate that the mounting method has a significant effect on the frequency response and sensitivity for damage detection.

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Section: Introductionmentioning

confidence: 99%

Performance of three transducer mounting methods in impedance-based structural health monitoring applications

Silveira

Campeiro

Baptista

2017

Journal of Intelligent Material Systems and Structures

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“…The alternative piezoelectric sensors used in this study were the MFCs sensors [17], [26], which are low-profile, durable and flexible devices composed of rectangular piezoceramic rods inserted between layers of adhesive, electrodes and polyimide film as shown Fig. 1 (b) and (c).…”

Section: Piezoelectricity and Mfc Sensorsmentioning

confidence: 99%

“…These devices are as a thin, surface−conformable sheet and can be applied to various types of structures or embedded in composite structures [17], [26].…”

Section: Piezoelectricity and Mfc Sensorsmentioning

confidence: 99%

Assessment of Macro Fiber Composite Sensors for Measurement of Acoustic Partial Discharge Signals in Power Transformers

et al. 2017

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This paper presents a performance assessment of macro fiber composite (MFC) sensors for measuring acoustic emission (AE) signals from partial discharges (PD) in power transformers filled with mineral oil. MFC sensors are low-profile and flexible, allowing them to be attached to uneven surfaces, such as a transformer wall. Two types of MFC sensors were assessed: P1 (d33 effect) and P2 (d31 effect), which are optimized for different deformations in the structure, such as elongation and contraction, respectively. In addition, a conventional AE sensor, R15I-AST model from Physical Acoustics South America, was also used as a reference for comparative analysis. Four metrics were applied to the signals: root mean square, energy criterion, Akaike criterion, power spectral density, and correlation. The experimental results indicate a high similarity between the MFC sensors and the conventional AE sensor, which expands the research field in acoustic PD measurement in power transformers by using low-cost and flexible sensors.

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“…Thus, MFCs are suitable for large deformation and curved surface applications. In recent years, MFCs have been wildly used in morphing wings (Bilgen et al, 2010a; Gamble and Inman 2018; Kochersberger et al, 2017; Pankonien et al, 2015), energy harvesting (Shahab et al, 2016; Upadrashta et al, 2015; Yang et al, 2016), and active vibration control for the plates and shells (Li et al, 2016; Sohn et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

“…Thus, some researchers have considered the piezoelectric material nonlinear tensile stiffness in the dynamic models of MFC structures to obtain more accurate dynamic response (Tan et al, 2017; Yang and Upadrashta, 2016). In addition, MFC is composed of active and inactive parts, when the inactive area is relatively small, the whole MFC piece can be approximated to the active part (Shahab and Erturk, 2016; Yang and Upadrashta, 2016); if the inactive part area is near to or even larger than the area of active part, the influence of the inactive part cannot be neglected, such as M-4005-P1, M-4010-P1 etc. Since the sizes and material properties of the inactive and active parts are remarkably different and their structures are closely bonded together, the analytical model cannot be exactly established in the case of considering the inactive part, so finite element method (FEM) should be applied.…”

Section: Introductionmentioning

confidence: 99%

Large deformation mechanical modeling with bilinear stiffness for Macro-Fiber Composite bimorph based on extending mixing rules

2020

Journal of Intelligent Material Systems and Structures

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Macro-Fiber Composite bimorph is a kind of piezoelectric actuator that allow large bending deformation. However, macro-fiber composites exhibit strong stiffness nonlinearity in their operation range, so it is difficult to accurately estimate their large deformation behavior based on a linear constitutive model. In addition, the macro-fiber composites have active and inactive parts, that significantly differ in their material sizes and properties, so it is not reasonable to consider them as uniform material. Thus, it is necessary develop an accurate modeling and analysis method for the large deformation macro-fiber composite structures. First, the mixing rules are extended to derive the three-dimensional homogenized mechanical and electrical parameters of the macro-fiber composite active part; based on these parameters, the actuation results of linear finite element model is in good agreement with the official data. Then a finite element model of the axially compressed macro-fiber composite bimorph is established, the bilinear tensile stiffness of macro-fiber composite is realized by secondary development in ANSYS. Comparison with the experimental results reveals high accuracy of the established finite element model. Thus, the developed method can be effectively used for the performance evaluation and design of the macro-fiber composite devices with large deformation.

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Coupling of experimentally validated electroelastic dynamics and mixing rules formulation for macro-fiber composite piezoelectric structures

Cited by 35 publications

References 62 publications

Performance of three transducer mounting methods in impedance-based structural health monitoring applications

Performance of three transducer mounting methods in impedance-based structural health monitoring applications

Assessment of Macro Fiber Composite Sensors for Measurement of Acoustic Partial Discharge Signals in Power Transformers

Large deformation mechanical modeling with bilinear stiffness for Macro-Fiber Composite bimorph based on extending mixing rules

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