Thematische Bibliographien / ENERGY HARVESTING APPLICATIONS

Inhaltsverzeichnis

  1. Zeitschriftenartikel
  2. Dissertationen
  3. Bücher
  4. Buchteile
  5. Konferenzberichte
  6. Berichte der Organisationen

Auswahl der wissenschaftlichen Literatur zum Thema „ENERGY HARVESTING APPLICATIONS“

Autor: Grafiati
Veröffentlicht am 21. Oktober 2023

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Zeitschriftenartikel zum Thema "ENERGY HARVESTING APPLICATIONS"

1

Pakrashi, Vikram, und Grzegorz Litak. „Energy harvesting and applications“. European Physical Journal Special Topics 228, Nr. 7 (August 2019): 1535–36. http://dx.doi.org/10.1140/epjst/e2019-900118-y.

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Gayakawad, Kavyashree C., Akshaykumar Gaonkar, B. Goutami und Vinayak P. Miskin. „Acoustic Energy Harvesting Using Piezoelectric Effect for Various Low Power Applications“. Bonfring International Journal of Research in Communication Engineering 6, Special Issue (30.11.2016): 24–29. http://dx.doi.org/10.9756/bijrce.8194.

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3

Elsheikh, Ammar. „Bistable Morphing Composites for Energy-Harvesting Applications“. Polymers 14, Nr. 9 (05.05.2022): 1893. http://dx.doi.org/10.3390/polym14091893.

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Bistable morphing composites have shown promising applications in energy harvesting due to their capabilities to change their shape and maintain two different states without any external loading. In this review article, the application of these composites in energy harvesting is discussed. Actuating techniques used to change the shape of a composite structure from one state to another is discussed. Mathematical modeling of the dynamic behavior of these composite structures is explained. Finally, the applications of artificial-intelligence techniques to optimize the design of bistable structures and to predict their response under different actuating schemes are discussed.
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Gordón, Carlos, Fabián Salazar, Cristina Gallardo und Julio Cuji. „Storage Systems for Energy Harvesting Applications“. IOP Conference Series: Earth and Environmental Science 1141, Nr. 1 (01.02.2023): 012009. http://dx.doi.org/10.1088/1755-1315/1141/1/012009.

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Abstract Currently, the use of energy from the environment to generate electricity has triggered applications like Energy Harvesting because it is an ecological and autonomous energy that can be used in countless applications, the disadvantage of these systems is the storage system so in this research, a literature review of the use of storage technologies for their implementation in energy Harvesting systems has been carried out. The main objective is to evaluate the performance of the soul-saving systems by making a comparison with existing batteries on the market, with an analysis of the modelling and simulation through Wolfram System Modeler where it allows to understand the behavior of the charging and unchanging processes from the results obtained in energy harvesting systems previously developed by students of the Technical University of Ambato obtaining parameters involved in them to test the Energy Harvesting system with different batteries and thus, achieve greater energy re-collection and storage. These results are very promising because it has been possible to demonstrate by simulation and measurement that the batteries contained in their composition are suitable for Energy Harvesting systems.
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Suzuki, Yuji. „Energy Harvesting“. Journal of The Institute of Image Information and Television Engineers 64, Nr. 2 (2010): 198–200. http://dx.doi.org/10.3169/itej.64.198.

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6

Roscow, J., Y. Zhang, J. Taylor und C. R. Bowen. „Porous ferroelectrics for energy harvesting applications“. European Physical Journal Special Topics 224, Nr. 14-15 (November 2015): 2949–66. http://dx.doi.org/10.1140/epjst/e2015-02600-y.

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Wang, Zhao, Xumin Pan, Yahua He, Yongming Hu, Haoshuang Gu und Yu Wang. „Piezoelectric Nanowires in Energy Harvesting Applications“. Advances in Materials Science and Engineering 2015 (2015): 1–21. http://dx.doi.org/10.1155/2015/165631.

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Recently, the nanogenerators which can convert the mechanical energy into electricity by using piezoelectric one-dimensional nanomaterials have exhibited great potential in microscale power supply and sensor systems. In this paper, we provided a comprehensive review of the research progress in the last eight years concerning the piezoelectric nanogenerators with different structures. The fundamental piezoelectric theory and typical piezoelectric materials are firstly reviewed. After that, the working mechanism, modeling, and structure design of piezoelectric nanogenerators were discussed. Then the recent progress of nanogenerators was reviewed in the structure point of views. Finally, we also discussed the potential application and future development of the piezoelectric nanogenerators.
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Horowitz, Stephen B., und Mark Sheplak. „Aeroacoustic applications of acoustic energy harvesting“. Journal of the Acoustical Society of America 134, Nr. 5 (November 2013): 4155. http://dx.doi.org/10.1121/1.4831230.

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Gladden, Josh R. „Elastic energy harvesting: Materials and applications“. Journal of the Acoustical Society of America 141, Nr. 5 (Mai 2017): 3689. http://dx.doi.org/10.1121/1.4988030.

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10

Chiriac, H., M. Ţibu, N. Lupu, I. Skorvanek und T. A. Óvári. „Nanocrystalline ribbons for energy harvesting applications“. Journal of Applied Physics 115, Nr. 17 (07.05.2014): 17A320. http://dx.doi.org/10.1063/1.4864437.

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Dissertationen zum Thema "ENERGY HARVESTING APPLICATIONS"

1

Martin, Benjamin Ryan. „Energy Harvesting Applications of Ionic Polymers“. Thesis, Virginia Tech, 2005. http://hdl.handle.net/10919/32024.

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The purpose of this thesis is the development and analysis of applications for ionic polymers as energy harvesting devices. The specific need is a self-contained energy harvester to supply renewable power harvested from ambient vibrations to a wireless sensor. Ionic polymers were investigated as mechanical to electrical energy transducers. An ionic polymer device was designed to harvest energy from vibrations and supply power for a wireless structural health monitoring sensor.The ionic polymer energy harvester is tested to ascertain whether the idea is feasible. Transfer functions are constructed for both the open-circuit voltage and the closed-circuit current. The impedance of the device is also quantified. Using the voltage transfer function and the current transfer function it is possible to calculate the power being produced by the device.Power generation is not the only energy harvesting application of ionic polymers, energy storage is another possibility. The ionic polymer device is tested to characterize its charge and discharge capabilities. It is charged with both DC and AC currents. An energy storage comparison is performed between the ionic polymers and capacitors. While the polymers performed well, the electrolytic capacitors are able to store more energy. However, the ionic polymers show potential as capacitors and have the possibility of improved performance as energy storage devices. Current is measured across resistive loads and the supplied power is calculated. Although the power is small, the ionic polymers are able to discharge energy across a load proving that they are capable of supplying power.
Master of Science
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2

Ersoy, Kurtulus. „Piezoelectric Energy Harvesting For Munitions Applications“. Master's thesis, METU, 2011. http://etd.lib.metu.edu.tr/upload/12613589/index.pdf.

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In recent years, vibration-based energy harvesting technologies have gained great importance because of reduced power requirement of small electronic components. External power source and maintenance requirement can be minimized by employment of mechanical vibration energy harvesters. Power sources that harvest energy from the environment have the main advantages of high safety, long shell life and low cost compared to chemical batteries. Electromagnetic, electrostatic and piezoelectric transduction mechanisms are the three main energy harvesting methods. In this thesis, it is aimed to apply the piezoelectric elements technology to develop means for energy storage in munitions launch. The practical problems encountered in the design of piezoelectric energy harvesters are investigated. The applicability of energy harvesting to high power needs are studied. The experience compiled in the study is to be exploited in designing piezoelectric energy harvesters for munitions applications. Piezoelectric energy harvesters for harmonic and mechanical shock loading conditions with different types of piezoelectric materials are designed and tested. The test results are compared with both responses from analytical models generated in MATLAB®
and ORCAD PSPICE®
, and finite element method models generated in ATILA®
. Optimum energy storage methods are considered.
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Sze, Ngok Man. „Switching converter techniques for energy harvesting applications /“. View abstract or full-text, 2007. http://library.ust.hk/cgi/db/thesis.pl?ECED%202007%20SZE.

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Oliva, Alexander. „Multi-source energy harvesting for lightweight applications“. Thesis, Massachusetts Institute of Technology, 2018. http://hdl.handle.net/1721.1/119580.

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Thesis: M. Eng., Massachusetts Institute of Technology, Department of Electrical Engineering and Computer Science, 2018.
This electronic version was submitted by the student author. The certified thesis is available in the Institute Archives and Special Collections.
Cataloged from student-submitted PDF version of thesis.
Includes bibliographical references (pages 193-197).
This thesis analyzes, designs and tests circuit topologies for simultaneous energy harvesting from solar and 915-MHz RF energy sources. An important design objective is to minimize system weight while maximizing output power and operating time for applications in the sub-170-mg and single-mW ranges. The resulting energy harvesting system uses a unique approach of categorizing the harvesters as primary and auxiliary harvesters due to the power levels of each in relation to the high load demand. This work results in a 162-mg supercapacitor-powered system capable of powering a 2-V load at up to approximately 2-3 mW and a 150-mg battery-powered system capable of powering a 2-V load at up to 6 mW. The auxiliary RF harvester uses a fully-integrated charge pump to impedance-match to a rectenna with greater than 94% matching. The parasitic models developed for the RF harvester show errors less than 1.4% in the measured system.
by Alexander Oliva.
M. Eng.
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Smilek, Jan. „Energy Harvesting Power Supply for MEMS Applications“. Doctoral thesis, Vysoké učení technické v Brně. Fakulta strojního inženýrství, 2018. http://www.nusl.cz/ntk/nusl-386765.

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Tato práce se zabývá vývojem nezávislého elektrického zdroje pro moderní nízkopříkonové elektrické aplikace. Protože tradiční řešení napájení drobných spotřebičů s využitím baterií či akumulátorů snižuje uživatelský komfort kvůli potřebě pravidelné údržby, navrhovaný zdroj využívá principu energy harvesting. Tento princip spočívá v získávání energie přímo z okolního prostředí napájené aplikace a její přeměně na energii elektrickou, která je dále využita pro na-pájení moderních MEMS (mikroelektromechanických) zařízení. Potenciální aplikací vyvíjeného zdroje je především moderní nositelná elektronika a biomedicínské senzory. Tato oblast využití ovšem klade zvýšené nároky na parametry generátoru, který musí zajistit dostatečný generovaný výkon z energie, dostupné v okolí lidského těla, a to při zachování prakticky využitelné velikosti a hmotnosti. Po stanovení předběžných požadavků a provedení analýz vhodnosti dostupných zdrojů energie ke konverzi byla k využití vybrána kinetická energie lidských aktivit. Byla provedena série měření zrychlení na lidském těle, především v místě předpokládaného umístění generátoru, aby bylo možno analyzovat a generalizovat hodnoty energie dostupné ke konverzi v daném umístění. V návaznosti na tato měření a analýzy byl vyvinut inovativní kinetický energy harvester, který byl následně vyroben jako funkční vzorek. Tento vzorek byl pak testován v reálných podmínkách pro verifikaci simulačního modelu a vyhodnocení reálné použitelnosti takového zařízení. Kromě samotného vývoje generátoru je v práci popsán i originální způsob zvýšení generovaného výkonu pro kinetické energy harvestery a jsou prezentována statistická data a modely pro predikci využitelnosti kinetických harvesterů pro získávání energie z lidské aktivity.
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6

Wang, X., S. Dong, Ashraf F. Ashour und B. Han. „Energy-harvesting concrete for smart and sustainable infrastructures“. A Springer Nature Publication, 2021. http://hdl.handle.net/10454/18553.

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Yes
Concrete with smart and functional properties (e.g., self-sensing, self-healing, and energy-harvesting) represents a transformative direction in the field of construction materials. Energy-harvesting concrete has the capability to store or convert the ambient energy (e.g., light, thermal, and mechanical energy) for feasible uses, alleviating global energy and pollution problems as well as reducing carbon footprint. The employment of energy-harvesting concrete can endow infrastructures (e.g., buildings, railways, and highways) with energy self-sufficiency, effectively promoting sustainable infrastructure development. This paper provides a systematic overview on the principles, fabrication, properties, and applications of energy-harvesting concrete (including light-emitting, thermal-storing, thermoelectric, pyroelectric, and piezoelectric concretes). The paper concludes with an outline of some future challenges and opportunities in the application of energy-harvesting concrete in sustainable infrastructures.
The full-text of this article will be released for public view at the end of the publisher embargo on 19 Jul 2022.
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Constantinou, Peter. „A magnetically sprung generator for energy harvesting applications“. Thesis, University of Bristol, 2009. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.508049.

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Simone, Dominic J. „Modeling a linear generator for energy harvesting applications“. Thesis, Monterey, California: Naval Postgraduate School, 2014. http://hdl.handle.net/10945/44669.

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Approved for public release; distribution is unlimited
The intent of this research is to draw attention to linear generators and their potential uses. A flexible model of a linear generator created in MATLAB Simulink is presented. The model is a three-phase, 12-pole, non-salient, synchronous permanent magnet linear generator with a non-sinusoidal back electromotive force (EMF) but could easily be adapted to fit any number of poles or any back EMF waveform. The emerging technologies related to linear generators such as wave energy converters and free-piston engines are explained. A selection of these technologies is generically modeled and their results are discussed and contrasted against one another. The model clearly demonstrates the challenges of using linear generators in different scenarios. It also proves itself a useful tool in analyzing and improving the performance of linear generators under a variety of circumstances.
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Choi, Yeonsik. „Novel functional polymeric nanomaterials for energy harvesting applications“. Thesis, University of Cambridge, 2019. https://www.repository.cam.ac.uk/handle/1810/282877.

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Polymer-based piezoelectric and triboelectric generators form the basis of well-known energy harvesting methods that are capable of transforming ambient vibrational energy into electrical energy via electrical polarization changes in a material and contact electrification, respectively. However, the low energy conversion efficiency and limited thermal stability of polymeric materials hinder practical application. While nanostructured polymers and polymer-based nanocomposites have been widely studied to overcome these limitations, the performance improvement has not been satisfactory due to limitations pertaining to long-standing problems associated with polymeric materials; such as low crystallinity of nanostructured polymers, and in the case of nanocomposites, poor dispersion and distribution of nanoparticles in the polymer matrix. In this thesis, novel functional polymeric nanomaterials, for stable and physically robust energy harvesting applications, are proposed by developing advanced nanofabrication methods. The focus is on ferroelectric polymeric nanomaterials, as this class of materials is particularly well-suited for both piezoelectric and triboelectric energy harvesting. The thesis is broadly divided into two parts. The first part focuses on Nylon-11 nanowires grown by a template-wetting method. Nylon-11 was chosen due to its reasonably good ferroelectric properties and high thermal stability, relative to more commonly studied ferroelectric polymers such as polyvinylidene fluoride (PVDF) and polyvinylidene fluoride-trifluoroethylene (P(VDF-TrFE)). However, limitations in thin-film fabrication of Nylon-11 have led to poor control over crystallinity, and thus investigation of this material for practical applications had been mostly discontinued, and its energy harvesting potential never fully realised. The work in this thesis shows that these problems can be overcome by adopting nanoporous template-wetting as a versatile tool to grow Nylon-11 nanowires with controlled crystallinity. Since the template-grown Nylon-11 nanowires exhibit a polarisation without any additional electrical poling process by exploiting the nanoconfinement effect, they have been directly incorporated into nano-piezoelectric generators, exhibiting high temperature stability and excellent fatigue performance. To further enhance the energy harvesting capability of Nylon-11 nanowires, a gas -flow assisted nano-template (GANT) infiltration method has been developed, whereby rapid crystallisation induced by gas-flow leads to the formation of the ferroelectric δʹ-phase. The well-defined crystallisation conditions resulting from the GANT method not only lead to self-polarization but also increases average crystallinity from 29 % to 38 %. δʹ-phase Nylon-11 nanowires introduced into a prototype triboelectric generator are shown to give rise to a six-fold increase in output power density as observed relative to the δʹ-phase film-based device. Interestingly, based on the accumulated understanding of the template-wetting method, Nylon-11, and energy harvesting devices, it was found that thermodynamically stable α-phase Nylon-11 nanowires are most suitable for triboelectric energy generators, but not piezoelectric generators. Notably, definitive dipole alignment of α-phase nanowires is shown to have been achieved for the first time via a novel thermally assisted nano-template infiltration (TANI) method, resulting in exceptionally strong and thermally stable spontaneous polarization, as confirmed by molecular structure simulations. The output power density of a triboelectric generator based on α-phase nanowires is shown to be enhanced by 328 % compared to a δʹ-phase nanowire-based device under the same mechanical excitation. The second part of the thesis presents recent progress on polymer-based multi-layered nanocomposites for energy harvesting applications. To solve the existing issues related to poor dispersion and distribution of nanoparticles in the polymer matrix, a dual aerosol-jet printing method has been developed and applied. As a result, outstanding dispersion and distribution. Furthermore, this method allows precise control of the various physical properties of interest, including the dielectric permittivity. The resulting nanocomposite contributes to an overall enhancement of the device capacitance, which also leads to high-performance triboelectric generators. This thesis therefore presents advances in novel functional polymeric nanomaterials for energy harvesting applications, with improved performance and thermal stability. It further offers insight regarding the long-standing issues in the field of Nylon-11, template-wetting, and polymer-based nanocomposites.
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Thompson, Nicholas John. „Singlet exciton fission : applications to solar energy harvesting“. Thesis, Massachusetts Institute of Technology, 2014. http://hdl.handle.net/1721.1/89959.

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Thesis: Ph. D., Massachusetts Institute of Technology, Department of Materials Science and Engineering, 2014.
Cataloged from PDF version of thesis.
Includes bibliographical references (pages 141-147).
Singlet exciton fission transforms a single molecular excited state into two excited states of half the energy. When used in solar cells it can double the photocurrent from high energy photons increasing the maximum theoretical power efficiency to greater than 40%. The steady state singlet fission rate can be perturbed under an external magnetic field. I utilize this effect to monitor the yield of singlet fission within operating solar cells. Singlet fission approaches unity efficiency in the organic semiconductor pentacene for layers more than 5 nm thick. Using organic solar cells as a model system for extracting photocurrent from singlet fission, I exceed the convention limit of 1 electron per photon, realizing 1.26 electrons per incident photon. One device architecture proposed for high power efficiency singlet fission solar cells coats a conventional inorganic semiconducting solar with a singlet fission molecule. This design requires energy transfer from the non-emissive triplet exciton to the semiconducting material, a process which has not been demonstrated. I prove that colloidal nanocrystals accept triplet excitons from the singlet fission molecule tetracene. This enables future devices where the combine singlet fission material and nanocrystal system energy transfer triplet excitons produced by singlet fission to a silicon solar cell.
by Nicholas J. Thompson.
Ph. D.
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Bücher zum Thema "ENERGY HARVESTING APPLICATIONS"

1

Kaźmierski, Tom J. Energy Harvesting Systems: Principles, Modeling and Applications. New York, NY: Springer Science+Business Media, LLC, 2011.

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Ikram, Muhammad, Ali Raza und Salamat Ali. 2D-Materials for Energy Harvesting and Storage Applications. Cham: Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-030-96021-6.

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Innovative materials and systems for energy harvesting applications. Hershey, PA: Engineering Science Reference, 2015.

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Álvarez-Carulla, Albert, Jordi Colomer-Farrarons und Pere Lluís Miribel Català. Self-powered Energy Harvesting Systems for Health Supervising Applications. Singapore: Springer Nature Singapore, 2022. http://dx.doi.org/10.1007/978-981-19-5619-5.

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Kyung, Chong-Min, Hrsg. Nano Devices and Circuit Techniques for Low-Energy Applications and Energy Harvesting. Dordrecht: Springer Netherlands, 2016. http://dx.doi.org/10.1007/978-94-017-9990-4.

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Zaman, Noor, Vasaki Ponnusamy, Tang Jung Low und Anang Hudaya Muhamad Amin. Biologically-inspired energy harvesting through wireless sensor technologies. Hershey, PA: Information Science Reference, 2016.

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Shalan, Ahmed Esmail, Abdel Salam Hamdy Makhlouf und Senentxu Lanceros‐Méndez, Hrsg. Advances in Nanocomposite Materials for Environmental and Energy Harvesting Applications. Cham: Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-030-94319-6.

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Ferreira Carvalho, Carlos Manuel, und Nuno Filipe Silva Veríssimo Paulino. CMOS Indoor Light Energy Harvesting System for Wireless Sensing Applications. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-21617-1.

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Dhar, Nibir K., und Achyut K. Dutta. Energy harvesting and storage: Materials, devices,and applications : 5-6 April 2010, Orlando, Florida, United States. Herausgegeben von Wijewarnasuriya Priyalal S und SPIE (Society). Bellingham, Wash: SPIE, 2010.

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Dhar, Nibir K., Achyut K. Dutta und Priyalal S. Wijewarnasuriya. Energy harvesting and storage: Materials, devices,and applications II : 25-28 April 2011, Orlando, Florida, United States. Bellingham, Wash: SPIE, 2011.

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Buchteile zum Thema "ENERGY HARVESTING APPLICATIONS"

1

Dauksevicius, Rolanas, und Danick Briand. „Energy Harvesting“. In Material-Integrated Intelligent Systems - Technology and Applications, 479–528. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2017. http://dx.doi.org/10.1002/9783527679249.ch21.

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Lata, Sonam, und Shabana Mehfuz. „Efficient Ambient Energy-Harvesting Sources with Potential for IoT and Wireless Sensor Network Applications“. In Energy Harvesting, 19–63. Boca Raton: Chapman and Hall/CRC, 2022. http://dx.doi.org/10.1201/9781003218760-2.

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Di Paolo Emilio, Maurizio. „Applications of Energy Harvesting“. In Microelectronic Circuit Design for Energy Harvesting Systems, 155–65. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-47587-5_11.

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Doğan, Mustafa, Sıtkı Çağdaş İnam und Ö. Orkun Sürel. „Efficient Energy Harvesting Systems for Vibration and Wireless Sensor Applications“. In Energy Harvesting and Energy Efficiency, 87–106. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-49875-1_4.

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Ylli, Klevis, und Yiannos Manoli. „Industrial Applications“. In Energy Harvesting for Wearable Sensor Systems, 95–113. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-33-4448-8_7.

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Patil, Sneha, Mahesh Goudar und Ravindra Kharadkar. „Exploration of Indoor Energy Harvesting“. In Digital Technologies and Applications, 584–91. Cham: Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-031-01942-5_58.

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Parida, Kaushik, und Ramaraju Bendi. „Piezoelectric Energy Harvesting and Piezocatalysis“. In Nano-catalysts for Energy Applications, 171–89. Boca Raton: CRC Press, 2021. http://dx.doi.org/10.1201/9781003082729-10.

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Ferreira Carvalho, Carlos Manuel, und Nuno Filipe Silva Veríssimo Paulino. „Energy Harvesting Electronic Systems“. In CMOS Indoor Light Energy Harvesting System for Wireless Sensing Applications, 7–42. Cham: Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-21617-1_2.

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Ferreira Carvalho, Carlos Manuel, und Nuno Filipe Silva Veríssimo Paulino. „Proposed Energy Harvesting System“. In CMOS Indoor Light Energy Harvesting System for Wireless Sensing Applications, 117–56. Cham: Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-21617-1_5.

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Raju Thoutam, Laxman, und Sammaiah Pulla. „Piezoelectric Materials for Energy Harvesting Applications“. In Energy Harvesting and Storage Devices, 1–24. New York: CRC Press, 2023. http://dx.doi.org/10.1201/9781003340539-1.

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Konferenzberichte zum Thema "ENERGY HARVESTING APPLICATIONS"

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Ruchi, Ruchi, Akshat Savant, Abdul Kalam, Yugal Khurana, Prachi Prachi und Samir Kumar. „Energy Harvesting For IoT Applications“. In 2022 3rd International Conference on Electronics and Sustainable Communication Systems (ICESC). IEEE, 2022. http://dx.doi.org/10.1109/icesc54411.2022.9885464.

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Jain, Akash, Bharat Bansal und Meghna Hada. „Energy Harvesting for Portable Applications“. In 2014 Texas Instruments India Educators' Conference (TIIEC). IEEE, 2014. http://dx.doi.org/10.1109/tiiec.2014.027.

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Monroe, J. G., Erick S. Vasquez, Zachary S. Aspin, John D. Fairley, Keisha B. Walters, Matthew J. Berg und Scott M. Thompson. „Energy harvesting via ferrofluidic induction“. In SPIE Sensing Technology + Applications, herausgegeben von Nibir K. Dhar und Achyut K. Dutta. SPIE, 2015. http://dx.doi.org/10.1117/12.2178419.

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Patil, Akshay, Mayur Jadhav, Shreyas Joshi, Elton Britto und Apurva Vasaikar. „Energy harvesting using piezoelectricity“. In 2015 International Conference on Energy Systems and Applications. IEEE, 2015. http://dx.doi.org/10.1109/icesa.2015.7503403.

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Weddell, Alex S., und Michele Magno. „Energy Harvesting for Smart City Applications“. In 2018 International Symposium on Power Electronics, Electrical Drives, Automation and Motion (SPEEDAM). IEEE, 2018. http://dx.doi.org/10.1109/speedam.2018.8445323.

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Karakaya, Emrullah, Cenk Mulazimoglu, Sultan Can, A. Egemen Yilmaz und Baris Akaoglu. „Metamaterial design for energy harvesting applications“. In 2016 24th Signal Processing and Communication Application Conference (SIU). IEEE, 2016. http://dx.doi.org/10.1109/siu.2016.7495789.

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Lahoti, Suyash, und Mandar D. Kulkarni. „Shape Optimization for Energy Harvesting Applications“. In AIAA Scitech 2020 Forum. Reston, Virginia: American Institute of Aeronautics and Astronautics, 2020. http://dx.doi.org/10.2514/6.2020-2262.

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DeLong, B., C. C. Chen und J. L. Volakis. „Wireless energy harvesting for medical applications“. In 2015 IEEE International Symposium on Antennas and Propagation & USNC/URSI National Radio Science Meeting. IEEE, 2015. http://dx.doi.org/10.1109/aps.2015.7304995.

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Bierschenk, Jim. „Optimized thermoelectrics for energy harvesting applications“. In 2008 17th IEEE International Symposium on the Applications of Ferroelectrics (ISAF). IEEE, 2008. http://dx.doi.org/10.1109/isaf.2008.4693950.

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Suslowicz, Charles, Archanaa S. Krishnan und Patrick Schaumont. „Optimizing Cryptography in Energy Harvesting Applications“. In CCS '17: 2017 ACM SIGSAC Conference on Computer and Communications Security. New York, NY, USA: ACM, 2017. http://dx.doi.org/10.1145/3139324.3139329.

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Berichte der Organisationen zum Thema "ENERGY HARVESTING APPLICATIONS"

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Shtein, Max, Kevin Pipe und Peter Peumans. Solar and Thermal Energy Harvesting Textile Composites for Aerospace Applications. Fort Belvoir, VA: Defense Technical Information Center, Juni 2012. http://dx.doi.org/10.21236/ada563065.

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Brumer, Paul, und Gregory Scholes. Photoinduced Electronic Energy Transfer: Theoretical and Experimental Issues for Light Harvesting Applications. Fort Belvoir, VA: Defense Technical Information Center, Oktober 2013. http://dx.doi.org/10.21236/ada591816.

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Prezhdo, Oleg. Atomistic Time-Domain Simulations of Light-Harvesting and Charge-Transfer Dynamics in Novel Nanoscale Materials for Solar Energy Applications. Office of Scientific and Technical Information (OSTI), Mai 2015. http://dx.doi.org/10.2172/1179082.

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