Deterministic and band-limited stochastic energy harvesting from uniaxial excitation of a multilayer piezoelectric stack

Zhao, Siyu; Ertürk, Alper

doi:10.1016/j.sna.2014.04.019

Cited by 77 publications

(47 citation statements)

References 51 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Zhao and Erturk accounted for higher vibration modes of the harvester in broadband random excitation using a distributed‐parameter electromechanical modeling framework and presented analytical and numerical solutions with experimental validations. In another work, the same authors also explored random excitation of first‐order energy harvesters, specifically a piezoelectric stack under compressive axial loading, along with analytical and numerical solutions validated by experiments. Aridogan et al .…”

Section: Introductionmentioning

confidence: 99%

“…tion of bistable inductive energy harvesting was studied by Daqaq [33] using theoretical methods.Z hao and Erturk [34] accounted for higher vibration modes of the harvester in broadbandr andom excitation using ad istributed-parameter electromechanical modeling framework and presented analytical and numerical solutionsw ith experimental validations. In another work, [35] the same authors also explored random excitation of first-order energy harvesters,s pecifically ap iezoelectric stack under compressive axial loading, along with analyticala nd numerical solutionsv alidatedb ye xperiments. Aridogan et al [36] explored random excitation of a2 Ds tructure (mainly at hin Kirchhoff plate with clamped edges) that hosts multiple structurally integrated piezoelectric patches as energy harvesters.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Soft and Hard Piezoelectric Ceramics and Single Crystals for Random Vibration Energy Harvesting

2018

View full text Add to dashboard Cite

Vibration‐based energy harvesting for enabling next‐generation self‐powered devices is a rapidly growing research area. In real‐world applications, the ambient vibrational energy is often available in non‐deterministic forms rather than the extensively studied deterministic scenarios, such as simple harmonic excitation. It is of interest to choose the best piezoelectric material for a given random excitation. Here, performance comparisons of various soft and hard piezoelectric ceramics and single crystals are presented for electrical power generation under band‐limited off‐resonance and wideband random vibration energy‐harvesting scenarios. For low‐frequency off‐resonance excitation, it is found that soft piezoelectric ceramics based upon lead zirconate titanate (e.g., PZT‐5H and PZT‐5A) outperform their hard counterparts (e.g., PZT‐4 and PZT‐8), and likewise soft single crystals based upon lead magnesium niobate and lead titanate as well as PZT (e.g., PMN‐PT and PMN‐PZT) outperform the relatively hard ones (e.g., manganese‐doped PMN‐PZT‐Mn). Overall, for such off‐resonance random vibrations, PMN‐PT is the most suitable choice among the materials studied. For wideband random excitation with a bandwidth covering the fundamental resonance of the harvester, hard piezoelectric ceramics offer larger power output compared to soft ceramics, and likewise hard single crystals produce larger power compared to their soft counterparts. Remarkably, a hard piezoelectric ceramic (e.g., PZT‐8) can outperform a soft single crystal (e.g., PMN‐PT) for wideband random vibration energy harvesting.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Soft and Hard Piezoelectric Ceramics and Single Crystals for Random Vibration Energy Harvesting

2018

View full text Add to dashboard Cite

show abstract

“…Rectangular beams are favored because they have lower resonance frequencies and higher strain for a given force input, but trapezoidal cantilever beams produce more power per unit area because the distribution of strain is uniform (Muthalif, et al, 2015). Some researchers are investigating stacked configurations (Zhao, et al, 2014), shells, spirals and zigzags (Muthalif, et al, 2015). For greater energy requirements, multiple sources of piezoelectric energy harvesting may be required, and three harvesting interface circuits have been proposed to enable the use of multiple sources (Xia, et al, 2014).…”

Section: Additive Manufacturing (3d Printing Roll To Roll Plastic Prmentioning

confidence: 99%

Here there be dragons, a pre-roadmap construct for IoT service infrastructure

Islam

Marinakis

Majadillas

et al. 2020

Technological Forecasting and Social Change

View full text Add to dashboard Cite

The major challenges facing the 21 st century world demands disruptive technology based solutions. One of the most promising exponential technology set to address world challenges is the Internet of Things (IoT) based Trillion Sensor System (TSS). The IoT supports many revolutionary commercial and societal solutions including wearable or unobtrusive medical sensors, Industry 4.0, power and water grids, smart cities, food production, education, transportation and roadway infrastructure needs. However, to support these solutions the current IoT infrastructure needs improved spectrum and the use of between one to ten Trillion Sensors (TS). The development of a robust IoT based TSS infrastructure would create an addition to world GDP equal to that of the U.S. GDP to double the worlds GDP. This new IoT based TSS would create a high paying job base that will form a new vibrant world middle class and an abundant economy. Yet while much is written about the ability of the IoT to transform society little effort is focused on its infrastructure. If this is true there is cause for concern. We add to the literature by developing a precursor road mapping construct which focuses on the service sector and supports 3 rd generation road mapping techniques. We utilize the emerging IoT TSS technology base as our case study. We utilize the best thoughts of hundreds of experts from three organizations focused on accelerating IoT TSS road mapping efforts.

show abstract

“…The electrical power of 12 mW was obtained when a pre-stress of 1.2 N was applied on the harvester at 113 Hz under 1 g [39]. Multilayer stack structure for an energy harvesting using 33 mode achieved enhancing of the mechanical to the electrical energy conversion efficiency [40,41]. Xu et al obtained significantly higher electrical power than a similar size cantilever type piezoelectric energy harvester in both resonance and off-resonance modes.…”

Section: Various Types Of Bulk Piezoelectric Energy Harvestersmentioning

confidence: 99%

Recent Progress on PZT Based Piezoelectric Energy Harvesting Technologies

et al. 2016

View full text Add to dashboard Cite

Abstract:Energy harvesting is the most effective way to respond to the energy shortage and to produce sustainable power sources from the surrounding environment. The energy harvesting technology enables scavenging electrical energy from wasted energy sources, which always exist everywhere, such as in heat, fluids, vibrations, etc. In particular, piezoelectric energy harvesting, which uses a direct energy conversion from vibrations and mechanical deformation to the electrical energy, is a promising technique to supply power sources in unattended electronic devices, wireless sensor nodes, micro-electronic devices, etc., since it has higher energy conversion efficiency and a simple structure. Up to now, various technologies, such as advanced materials, micro-and macro-mechanics, and electric circuit design, have been investigated and emerged to improve performance and conversion efficiency of the piezoelectric energy harvesters. In this paper, we focus on recent progress of piezoelectric energy harvesting technologies based on PbZr x Ti 1´x O 3 (PZT) materials, which have the most outstanding piezoelectric properties. The advanced piezoelectric energy harvesting technologies included materials, fabrications, unique designs, and properties are introduced to understand current technical levels and suggest the future directions of piezoelectric energy harvesting.

show abstract

Deterministic and band-limited stochastic energy harvesting from uniaxial excitation of a multilayer piezoelectric stack

Cited by 77 publications

References 51 publications

Soft and Hard Piezoelectric Ceramics and Single Crystals for Random Vibration Energy Harvesting

Soft and Hard Piezoelectric Ceramics and Single Crystals for Random Vibration Energy Harvesting

Here there be dragons, a pre-roadmap construct for IoT service infrastructure

Recent Progress on PZT Based Piezoelectric Energy Harvesting Technologies

Contact Info

Product

Resources

About