Harvesting energy from the vibration of a passing train using a single-degree-of-freedom oscillator

Gatti, Gianluca; Brennan, M.J.; Tehrani, Maryam Ghandchi; Thompson, D.J.

doi:10.1016/j.ymssp.2015.06.026

Cited by 104 publications

(43 citation statements)

References 20 publications

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“…As mentioned in the principles and basics of the analytical design of the model [2,[17][18][19], Figure 2, it is possible to describe electromagnetic field more generally with the FEM numerical model (1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11). The electromechanical vibrating harvester (34) works in special modes using resonances; its model includes nonlinearities and material nonlinearities depending on the temperature etc.…”

Section: Fem Numerical Modelmentioning

confidence: 99%

“…The extraction of residual energy (harvesting) has been a subject of scientific research in the latest decade. In many projects and publications [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19], the arrangement of a system generating electric power is sought as a suitable or optimized solution of design proposals. A very satisfactory tool of basic research is numerical modeling [2][3][4]8,[17][18][19].…”

Section: Introductionmentioning

confidence: 99%

“…One of the prerequisites for the design of the electromechanical system is a correct way of grasping the physical principle for maximum description of phenomena and processes; it is fundamental in harvesting extraction, as cases in the theses and works [17][18][19]. When comparing the majority of experimental methods and approaches [9,20], including hybrid design methods [6][7][8] with numerically modeled coupled tasks, the realized design using finite element methods (FEM) [2] is difficult to process but it leads to results with significant parameters relative to other quick approaches, as reported in work [19], Table 1, column "Effective power density [W/m 3 ]".…”

Section: Introductionmentioning

confidence: 99%

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Coupled Numerical Model of Vibration-Based Harvester

et al. 2020

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Herein, the authors publish the complex design of a numerical coupled model of a vibration-based harvester that transforms mechanical vibrations into electric energy. A numerical model is based on usage of the finite element method, connecting analysis of the damped mechanical oscillation, electromagnetic field and electrical circuit. The model was demonstrated on the design of a microgenerator (MG), and then experimentally tested. The numerical model allows us to execute optimization of the design with many degrees of freedom. The transformation of the wave spreading in the form of mechanical vibrations was solved in the area of resonance of the electromechanical system.

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Section: Fem Numerical Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Coupled Numerical Model of Vibration-Based Harvester

et al. 2020

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“…Its main drawback is the complexity of the design and, as a result, performance degradation with decreasing of the turbine size [5]. Autonomous power generators based on the piezoelectric effect can satisfy strength requirements, operate effectively in a wide temperature range and presence of moisture, withstand vibration and mechanical shock arising during the motion of the train [6][7][8][9].…”

mentioning

confidence: 99%

“…Ветрогенератор пре-образует энергию потока воздуха в электроэнергию, но при малых размерах турбины характеризуется сложностью конструкции и низкой производительно-стью [5]. Автономные генераторы тока на основе пьезо-электрического эффекта отвечают прочностным тре-бованиям и способны эффективно работать в широ-ких диапазонах температур и влажности, а также выдерживать вибрации и механические удары, воз-никающие при движении поезда [6][7][8][9].…”

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Development of a piezoelectric energy harvester for navigation support of railway transport

Vasiliev¹,

Chuprin²

2016

NanoRus

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Исследованы параметры колебаний разных типов грузовых вагонов. Предложено несколько конструкций пьезогенераторов для эффективного преобразования механических колебаний в электроэнергию. На основе экспериментальных данных проведено сравнение разных типов и конструкций пьезогенераторов. Оценено количество энергии, необходимое для работы устройства приема-передачи информации. Полученные данные могут быть использованы для разработки пьезоэлектрического генератора тока, предназначенного для обеспечения автономным питанием грузовых вагонов и платформ. Investigation of vibration parameters of the freight cars is presented. Several designs of piezoelectric energy harvester are proposed for the efficient conversion of mechanical vibrations into electrical power. Based on experimental studies a comparison of different types and designs of energy harvester is performed. The amount of energy required for wireless transceiver for monitoring location of a vehicle is evaluated. Obtained data can be used for development of production technology of the piezoelectric energy harvester to provide autonomous power supply for freight cars. в целях оптимизации работы системы железно-дорожного транспорта актуальна задача созда-ния единой информационной системы, кото-рая обеспечит следующие преимущества:• реализацию в полном объеме функции автома-тизированного контроля состава поездов, а также уменьшение штата сотрудников, контролирую-щих составы поездов; • внедрение безбума ж ных информационных технологий; • повышение достоверности и оперативности отчетно-сти о состоянии вагонных и локомотивных парков; • высокий уровень информационного сервиса во внутренних и транзитных международных перевозках.Для этого необходимо оснастить каждую подвиж-ную единицу железнодорожного транспорта набором датчиков, которые способны отслеживать ее параме-тры и отправлять полученные сведения в центр обра-ботки данных. Основной проблемой при реализации такой идеи является отсутствие системы электропи-тания на грузовых вагонах. Применение электриче-ских кабелей или гальванических элементов -слож-ное и дорогостоящее решение [1], поэтому одним из перспективных направлений является исполь-зование солнечной, ветряной, тепловой или меха-нической энергии [2]. Основным критерием выбора системы, применяемой в качестве автономного источника энергии, является возможность работы в условиях эксплуатации железнодорожного транс-Нанотехнологии. МЭМС * НПЦ "СпецЭлектронСистемы" / SpecElectronSystems RPC.

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High‐Efficiency Energy Management Circuit Combining Synchronized Switch Harvesting on Inductor Rectifier and Impedance Matching for Impact‐Type Piezoelectric Energy Harvester

2022

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Today, in internet of things applications, ambient-energy harvesting (EH) self-powered systems have gained considerable attention as a promising replacement for batteries. [1,2] The piezoelectric energy harvesters (PEHs) can convert mechanical energy into electrical energy. However, the PEHs suffer from the inherent capacitance C p and varying load resistance. Furthermore, they generate an AC output. Therefore, an energy management circuit connecting the PEHs and energy storage devices is necessary to achieve AC to DC conversion and extract maximum output power. [3] Studies have proposed four kinds of switch-based energy management circuit techniques to improve the output power and EH efficiency: synchronized switch harvesting (SSH), [4] impedance matching, [5] synchronous electrical charge extraction (SECE), [6] and maximum power point tracking (MPPT). [7] Recent studies have combined the abovementioned EH techniques [8][9][10][11][12][13][14][15] to further improve the EH efficiency and the output power. A combination of a synchronized switch harvesting on inductor (SSHI) rectifier and a MPPT technique yields an improvement in the harvesting efficiency and the output power (1.7 times) of vibration-type PEHs as compared to the use of only a full-bridge rectifier (FBR). [8] A series SSHI rectifier and a MPPT circuit implemented by an analog circuit were used, [9] and an output power equivalent to 2.68 times that of the FBR circuit was achieved. In ref.[13], a SSHI rectifier and a SECE technique were alternately used in every half-cycle, which improved the working bandwidth and the output power (2.3 times) compared to the FBR circuit. The above studies show that combining the SSHI with other techniques can effectively improve the output power of the periodic vibration-type PEH.Compared with the periodic vibration-type PEHs, the impact-type piezoelectric energy harvesters (IPEHs) excited by impact or shock generate intermittent decaying electrical energy, which is more common in people's life, such as the road EH system, [16][17][18][19][20][21] the rain EH system, [22][23][24][25] and the human motion EH system. [26][27][28] In our previous study, [30] an alternative impedance matching technique for the microwind IPEH was proposed, and it reached an efficiency of 73.4% at a wind speed of 1.53 m s À1 . In ref. [19], an adaptive impedance matching technique for bridge IPEH was proposed; it reached an efficiency of 80%. In ref. [31], an integrated parallel-SSHI circuit was proposed for IPEH and achieved 2.69 times enhancement. However, these existing energy management circuits [16,19,22,[29][30][31] for IPEHs still

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Harvesting energy from the vibration of a passing train using a single-degree-of-freedom oscillator

Cited by 104 publications

References 20 publications

Coupled Numerical Model of Vibration-Based Harvester

Coupled Numerical Model of Vibration-Based Harvester

Development of a piezoelectric energy harvester for navigation support of railway transport

High‐Efficiency Energy Management Circuit Combining Synchronized Switch Harvesting on Inductor Rectifier and Impedance Matching for Impact‐Type Piezoelectric Energy Harvester

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