Performance comparison of PZT and PMN–PT piezoceramics for vibration energy harvesting using standard or nonlinear approach

Rakbamrung, Prissana; Lallart, Mickaël; Guyomar, Daniel; Muensit, Nantakan; Thanachayanont, Chanchana; Lucat, Claude; Guiffard, Benoît; Petit, Lionel; Sukwisut, Pisan

doi:10.1016/j.sna.2010.08.028

Cited by 47 publications

(24 citation statements)

References 32 publications

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“…Although the effect of the nonlinear SSHI circuit on a PMN-PT energy harvester has been discussed in Ref. [19], the PMN-PT therein is not a single crystal but a polycrystalline plate, and the SSHI circuit is not self-sustained but powered by an external power source. This paper, by contrast, documents a systematic comparison between the PZT ceramic energy harvester and the PMN-PT and PZN-PT single crystal energy harvesters using a selfpowered SSHI circuit.…”

Section: Introductionmentioning

confidence: 99%

Comparison of PZN-PT, PMN-PT single crystals and PZT ceramic for vibration energy harvesting

Yang

2016

Energy Conversion and Management

154

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Section: Introductionmentioning

confidence: 99%

Comparison of PZN-PT, PMN-PT single crystals and PZT ceramic for vibration energy harvesting

Yang

2016

Energy Conversion and Management

154

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“…ME interactions are already discussed, but the energy harvesting response of asymmetric MFC/Ni bilayer is two to three times more than that of trilayer Ni/MFC/Ni symmetric structure. This is what expected from the Ni/ MFC structure as the flexural strain (bending strain/vibration) is associated with the asymmetric structure (Xing et al 2009) which results into the larger thickness shear deformation; by using piezo-material featuring high coupling coefficient along the flexural mode (Rakbamrung et al 2010) can generate high voltage/power output under lower excitation frequencies and load resistances than symmetric. Thus, it can be predicted that our designed Ni-MFC laminate structures can be suitable candidates for possible applications in self-biased magnetic field sensors with in-plane mode and as well as potential energy harvesters with asymmetric (unimorph) mode in future.…”

Section: Me Harvestermentioning

confidence: 69%

Magneto-Mechano-Electric (MME) Energy Harvesting Properties of Piezoelectric Macro-fiber Composite/Ni Magnetoelectric Generator

Kambale¹,

Kang²,

Yoon

et al. 2014

Energy Harvesting and Systems

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Asymmetric and symmetric magnetoelectric (ME) laminates structures of piezoelectric macro-fiber composite (MFC)/nickel (Ni) were fabricated and investigated their ME and magneto-mechano-electric (MME) energy harvesting responses to an applied magnetic/ mechanical stimulations. Both the structures strongly revealed the dependence of ME voltage coefficient (α ME ) on applied magnetic field directions with an important feature of a zero-bias field ME response. This is much more beneficial for designing the magnetic field sensors. The fabricated MFC/Ni structures exhibited good energy harvesting response to applied simultaneous magnetic/ mechanical vibrations of lab magnetic stirrer. The electric power was successfully harnessed from magnetomechanical stimulations; the resulting potential and power were up to ,20 V p-p and ,6 μW respectively, which are quite enough power to light a commercial red LED with traditional rectifier circuit and capacitor. Hence, the present MFC/Ni ME generators provide their future feasibility having self-biasing feature for designing the magnetic field sensors as well as for powering small consumer electronic devices and wireless sensor network systems by exploiting mechanical/magnetic stimulations from surrounding.

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“…Rakbamrung et al 49 attempted performance comparison between two common piezoelectric compositions, PZT + 1 mol% Mn and PMN-25PT, obtained from sintering piezoelectric powders. The PMN-PT showed higher coupling coefficient than the PZTbased sample, making such a composition a better choice for energy harvesting purposes at a first glance.…”

Section: Single Crystalmentioning

confidence: 99%

A review of piezoelectric energy harvesting based on vibration

Kim

2011

Int. J. Precis. Eng. Manuf.

952

444

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This paper reviews energy harvesting technology from mechanical vibration. Recent advances on ultralow power portable electronic devices and wireless sensor network require limitless battery life for better performance. People searched for permanent portable power sources for advanced electronic devices. Energy is everywhere around us and the most important part in energy harvesting is energy transducer. Piezoelectric materials have high energy conversion ability from mechanical vibration. A great amount of researches have been conducted to develop simple and efficient energy harvesting devices from vibration by using piezoelectric materials. Representative piezoelectric materials can be categorized into piezoceramics and piezopolymers. This paper reviews key ideas and performances of the reported piezoelectric energy harvesting from vibration. Various types of vibration devices, piezoelectric materials and mathematical modeling of vibrational energy harvestings are reviewed.

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Performance comparison of PZT and PMN–PT piezoceramics for vibration energy harvesting using standard or nonlinear approach

Cited by 47 publications

References 32 publications

Comparison of PZN-PT, PMN-PT single crystals and PZT ceramic for vibration energy harvesting

Comparison of PZN-PT, PMN-PT single crystals and PZT ceramic for vibration energy harvesting

Magneto-Mechano-Electric (MME) Energy Harvesting Properties of Piezoelectric Macro-fiber Composite/Ni Magnetoelectric Generator

A review of piezoelectric energy harvesting based on vibration

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