Bibliografías temáticas / Thermoelectric, Cu2SnS3, thermoelectric generators

Literatura académica sobre el tema "Thermoelectric, Cu2SnS3, thermoelectric generators"

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Publicado: 11 de marzo de 2023

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Artículos de revistas sobre el tema "Thermoelectric, Cu2SnS3, thermoelectric generators"

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Cortel, Adolf. "Thermoelectric generators". Physics Education 42, n.º 1 (21 de diciembre de 2006): 88–92. http://dx.doi.org/10.1088/0031-9120/42/1/012.

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Snyder, G. Jeffrey. "Small Thermoelectric Generators". Electrochemical Society Interface 17, n.º 3 (1 de septiembre de 2008): 54–56. http://dx.doi.org/10.1149/2.f06083if.

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Beretta, D., M. Massetti, G. Lanzani y M. Caironi. "Thermoelectric characterization of flexible micro-thermoelectric generators". Review of Scientific Instruments 88, n.º 1 (enero de 2017): 015103. http://dx.doi.org/10.1063/1.4973417.

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Paul, D. J., A. Samarelli, L. Ferre Llin, Y. Zhang, J. M. R. Weaver, P. S. Dobson, S. Cecchi et al. "Si/SiGe Thermoelectric Generators". ECS Transactions 50, n.º 9 (15 de marzo de 2013): 959–63. http://dx.doi.org/10.1149/05009.0959ecst.

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Li, Shan y Qian Zhang. "Ionic Gelatin Thermoelectric Generators". Joule 4, n.º 8 (agosto de 2020): 1628–29. http://dx.doi.org/10.1016/j.joule.2020.07.020.

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Baranowski, Lauryn L., G. Jeffrey Snyder y Eric S. Toberer. "Concentrated solar thermoelectric generators". Energy & Environmental Science 5, n.º 10 (2012): 9055. http://dx.doi.org/10.1039/c2ee22248e.

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Töpfer, Jörg, Timmy Reimann, Thomas Schulz, Arne Bochmann, Beate Capraro, Stefan Barth, Andy Vogel y Steffen Teichert. "Oxide multilayer thermoelectric generators". International Journal of Applied Ceramic Technology 15, n.º 3 (6 de noviembre de 2017): 716–22. http://dx.doi.org/10.1111/ijac.12822.

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Noudem, J. G., S. Lemonnier, M. Prevel, E. S. Reddy, E. Guilmeau y C. Goupil. "Thermoelectric ceramics for generators". Journal of the European Ceramic Society 28, n.º 1 (enero de 2008): 41–48. http://dx.doi.org/10.1016/j.jeurceramsoc.2007.05.012.

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Cheong, K. W. y J. H. Lim. "Numerical simulation of segmented ratio in bismuth telluride and skutterudites for waste heat recovery". Journal of Physics: Conference Series 2120, n.º 1 (1 de diciembre de 2021): 012007. http://dx.doi.org/10.1088/1742-6596/2120/1/012007.

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Abstract The thermoelectric performance of the segmented annular thermoelectric generators with the bismuth telluride and skutterudites has been investigated. The effect of the length ratio of the hot-segment leg to total length leg on the thermoelectric performance of the segmented annular thermoelectric generators is analysed and discussed and the optimization design of the annular thermoelectric generator with bismuth telluride and skutterudites as the materials with high thermoelectric performance is obtained. The result of the thermoelectric performance with the manipulated variable of the increase of length ratio, the output power, output voltage and efficiency of the segmented annular thermoelectric generators increase at the beginning then decrease afterwards. Additionally, to compare with the single bismuth telluride and skutterudites annular thermoelectric generators, the output voltage, output power and the conversion efficiency of the segmented annular thermoelectric generators can be improved twice. Lastly, the thermoelectric performance of the segmented annular thermoelectric generators operating in the changes of the temperature. The result has proved that as the temperature increase, the thermoelectric performance of the annular thermoelectric generator will also increase. Hence, the acquired results may be given some useful applications of the bismuth telluride and skutterudites on the segmented annular thermoelectric generators for waste heat recovery.
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Zhang, Yujie, Chaogang Lou, Xiaojian Li y Xin Li. "Thin film thermoelectric generators with semi-metal thermoelectric legs". AIP Advances 9, n.º 5 (mayo de 2019): 055027. http://dx.doi.org/10.1063/1.5090131.

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Tesis sobre el tema "Thermoelectric, Cu2SnS3, thermoelectric generators"

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Lohani, Ketan. "Development of Cu2SnS3 based thermoelectric materials and devices". Doctoral thesis, Università degli studi di Trento, 2022. http://hdl.handle.net/11572/344345.

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Commercially available high-performance thermoelectric materials are often rare or toxic and therefore unsustainable. The present thesis work makes a case for eco-friendly, earth-abundant, and non-toxic p-type ceramic Cu2SnS3 (CTS, hereafter) and, in general, the use of disordered materials for thermoelectric applications. The detailed study of polymorphism, synthesis conditions, porosity, grain size, and doping provides a systematic and in-depth experimental and computational analysis of thermoelectric properties and stability of CTS. These results can be generalized for numerous thermoelectric materials and other applications. Moreover, a case for functioning thermoelectric generators using non-toxic and cost-effective materials is also presented. The thesis begins with a brief introduction to thermoelectricity, followed by a literature review and justification of the choice of the subject. The second chapter puts forward a novel approach to stabilize a disordered CTS polymorph without any chemical alteration through high-energy reactive ball milling. The third chapter deals with the stability of disordered samples under different synthesis and sintering conditions, highlighting the effect of synthesis environment, microstructure, and porosity. The fourth chapter employed a novel, facile, and cost-effective two-step synthesis method (high-energy ball milling combined with spark plasma sintering) to synthesize CTS bulk samples. The two-step synthesis method was able to constrain the CTS grain growth in the nanometric range, revealing the conductive nature of the CTS surfaces. The next chapter explores combining the two-step synthesis method with Ag substitution at the Sn lattice site to improve CTS's thermoelectric performance further. In the final stages of the thesis work, thin film thermoelectric generators were fabricated using CTS and similar chalcogenides, demonstrating power output comparable to existing thermoelectric materials used in the medium temperature range. The final chapter summarizes outlooks and future perspectives stemming from this research work.
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Alothman, Abdulmohsen Abdulrahman. "Modeling and Applications of Thermoelectric Generators". Diss., Virginia Tech, 2016. http://hdl.handle.net/10919/79846.

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We develop a simplified one-dimensional numerical model that simulates the performance of thermoelectric generators (TEG). The model is based on the energy and electrical potential field equations. The Seebeck coefficient, thermal conductivity, electrical resistivity and Thomson coefficient of the TEG material are used to predict the harvested power. Bismuth-telluride is used as semiconductors materials of the TEG, which is the most commonly used material by industry. Experiments on three TEG modules were performed to validate the numerical model. A comparison with predicted levels of harvested energy based on the TEG specifications is also performed. The results show differences between the experimental and numerical values on one hand and the predicted ones on the other hand. The reason for these differences are discussed. A procedure to estimate the sensitivity of the harvested power to different inputs and TEG parameters is detailed. In the second part of the dissertation, we integrate a thermoelectric generator with an organic storage device. The performance of the integrated system for different values of load resistances and temperature gradients is determined. Finally, we demonstrate that power generated from a TEG is related to the flow rate in a pipe and can, thus, be used as a flow meter. Particularly, a dimensionless relation between the TEG's peak power and Reynolds number is determined.
Ph. D.
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3

Glatz, Wulf. "Development of flexible micro thermoelectric generators". Tönning Lübeck Marburg Der Andere Verl, 2008. http://d-nb.info/989530639/04.

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Twaha, Ssennoga. "Regulation of power generated from thermoelectric generators". Thesis, University of Nottingham, 2018. http://eprints.nottingham.ac.uk/49544/.

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In recent years, the efficiency of thermoelectric devices has improved greatly due thermoelectric material and device geometrical improvements. However, the efficiency of TEG is still low, being a subject of further research for more improvement. Hence, the main objective of the research carried out in this thesis is to analyse the performance of dc-dc converters with or without MPPT in conditioning the power generated from TEG. In light of this objective, the following case studies have been carried out. The initial study has analysed the performance of a TEG/dc-dc boost converter system. Results indicate that the converter is able to stabilise and boost the voltage and higher efficiencies are achieved at different hot side temperatures. The next study proposes the use of MPPT algorithm to harvest maximum power from TEG system. Hence, the analysis of the performance of TEG/dc-dc converter with MPPT enabled by Incremental conductance (IC) method is done. The results indicate that the IC based MPPT approach is able to track the maximum power point but with relatively lower efficiencies than the Perturb and Observe (P&O) based MPPT method. method. Another study has analysed the parameters for the performance of TEG/dc-dc converter system in different modes with a variable load. The TEG system is subjected to different hot side temperatures, including increasing step, increasing random and constant cold side temperature profiles. The study has demonstrated how the proper selection of converter components is a necessity to avoid converter losses as well interferences on the load connected to TEG/dc-dc converter system. Furthermore, another study compares the performance of extremum seeking control (ESC) and P&O MPPT algorithms applied to TEG system. The TEG model is validated with results from multiphysics (COMSOL) modelling software. To assess the effect of temperature dependency of TEG parameters, two TEG materials have been chosen; bismuth telluride (Bi2Te3) with temperature dependent Seebeck effect (S), electrical conductivity (σ) and thermal conductivity (k); and lead telluride (PbTe) with non-temperature dependent S, σ and k. Results indicate that ESC MPPT method outperforms the P&O technique in terms extracting maximum power and the simulation speed. Results also indicate that ESC outperforms the IC technique in terms of extracting maximum power and the speed of computation. ESC method is faster than the IC method. In the final study, the application of the concept and the design of a distributed dc-dc converter architecture (DCA) on TEG system is deliberated. The distributed or cascaded converter architecture involves the use of non-isolated per-TEG dc-dc converter connected to the load. Alternatively, for some specific loads, especially in automotive applications, soft-switched, isolated bi-directional dc-dc converters can be used instead of non-isolated converters because these integrated converters enable bi-directional power flow control capability. Simulations and experimental studies have been carried out to demonstrate and prove the necessity of the DCA design application on TEG systems. In addition, some of the factors affecting the performance of TEG systems are correspondingly analysed.
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Montecucco, Andrea. "Efficiently maximising power generation from thermoelectric generators". Thesis, University of Glasgow, 2014. http://theses.gla.ac.uk/5213/.

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Thermoelectric generators (TEGs) convert the thermal energy flowing through them into DC electrical energy in a quantity dependant on the temperature difference across them and the electrical load applied, with a conversion efficiency of typically 5%. Nonetheless, they can be successfully employed to recover energy from waste heat and their use has increased rapidly in recent years, with applications ranging from microwatts to kilowatts, due to energy policy legislations and increasing energy cost determined by climate change, environmental issues and availability of energy sources. The performance of TEGs, subject to thermal and electrical effects, can vary considerably depending on the operating conditions, therefore it is necessary to measure and characterise their performance, and to understand their dynamic behaviour and interaction with the other parts of the system. Based on this knowledge it is then desired to develop an effective electronic system able to control these devices so as to maximise the power generated and increase the overall efficiency of the system. Several TEGs can be electrically connected in series and/or parallel (forming an array) to provide the required voltage and/or current. However, TEGs are usually employed in environments with time-varying temperatures, thermal powers and electrical loads. As a consequence in most TEG systems the individual thermoelectric devices can be subject to temperature mismatch due to operating conditions. Therefore it is of relevant importance to accurately simulate the evolution of thermoelectric systems during thermal and electrical transients. At the same time accurate experimental performance data are necessary to permit precise simulations. Unfortunately, there is still no standardised method to test the electrical and thermal performance of TEGs. This thesis tackles these key challenges and contributes to the pool of existing knowledge about TEGs dealing with four main topics: testing of thermoelectric generators, simulation of thermoelectric generating systems, design and production of power electronic converters for thermoelectric generators, and physical applications of thermoelectric generators. After an introduction to the physical phenomena underlying the operation of TEGs, this thesis describes the innovative test system built at the University of Glasgow to assess the performance of TEG devices in the ”real-world”. The fixture allows a single TEG device to be tested with thermal input power up to 1 kW and hot temperature up to 800◦C with minimal thermal losses and thermal shock; the mechanical clamping force can be adjusted up to 5 kN, and the temperatures are sensed by thermocouples placed directly on the TEGs surfaces. A computer program controls all the instruments in order to minimise errors and to aid accurate measurement and test repeatability. The test rig can measure four TEGs simultaneously, each one individually controlled and heated. This allows testing the performance of TEG arrays under mismatched conditions, e.g., dimensions, clamping force, temperature, etc. Under these circumstances experimental results and a mathematical analysis show that when in operation each TEG in the array will have a different electrical operating point at which maximum energy can be extracted and problems of decreased power output arise. This thesis provides the transient solution to the one-dimensional heat conduction equation with internal heat generation that describes the transfer and generation of heat throughout a thermoelectric device with dynamic exchange of heat through the hot and cold sides. This solution is then included in a model in which the Peltier effect, the thermal masses and the electrical behaviour of the system are also considered. The resulting model is created in Simulink and the comparison with experimental results from a TEG system confirms the accuracy of the simulation tool to predict the evolution of the thermoelectric system both in steady-state and during thermal or electrical transients. This thesis presents an investigation of the optimum electrical operating load to maximise the power produced by a TEG. Both fixed temperature difference and fixed thermal input power conditions are considered. Power electronic converters controlled by a Maximum Power Point Tracking (MPPT) algorithm are used to maximise the power transfer from the TEG to the load. The MPPT method based on the open-circuit voltage is arguably the most suitable for the almost linear electrical characteristic of TEGs. An innovative way to perform the open-circuit voltage measurement during the pseudo-normal operation of the power converter is presented. This MPPT technique is supported by theoretical analysis and used to control an efficient synchronous Buck-Boost converter capable of interfacing TEGs over a wide range of temperatures. The prototype MPPT converter is controlled by an inexpensive microcontroller, and a lead-acid battery is used to accumulate the harvested energy. Experimental results using commercial TEG devices demonstrate the ability of the MPPT converter to accurately track the maximum power point during steady-state and thermal transients. This thesis also presents two practical applications of TEGs. The first application exploits the thermal energy generated by a stove to concurrently produce electrical energy and heat water, while the second application recovers the heat energy rejected to ambient by a car’s exhaust gas system to generate electrical energy for battery charging.
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Naylor, Andrew J. "Towards highly-efficient thermoelectric power harvesting generators". Thesis, University of Southampton, 2014. https://eprints.soton.ac.uk/366984/.

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Power harvesting from thermoelectric generators is considered as a viable route towards sustainable energy generation by the conversion of thermal gradients occuring naturally or from waste heat sources into useful electrical energy. This thesis investigates the electrodeposition of n-type binary, ternary and doped thermoelectric materials, with the aim of demonstrating that electrodeposition can be used as a cost-effective and simple technique to fabricate highly-efficient thermoelectric materials. In order to achieve this, the thermoelectric and electrical properties of such materials must be related to their microstructural properties. Therefore, a detailed and systematic study of their microstructural properties, including morphology, crystal structure, composition and crystallite size, is undertaken whilst also measuring the electrical and thermoelectric properties. It is found that the potential of the working electrode, employed as the substrate during the electrodeposition of bismuth telluride, is one of the most effective variables in the fabrication process. More anodic potentials such as 0 V vs. SCE offer the best microstructural and thermoelectric properties. The addition of a surfactant, sodium lignosulphonate, to the electrolyte further improves the microstructural properties of bismuth telluride thin films, by levelling the deposits and inducing greater crystallographic orientation in growth planes perpendicular to the substrate. This is believed to be preferential for improving thermoelectric properties. The electrodeposition of the ternary thermoelectric material bismuth tellurium selenide shows that the microstructural and hence the thermoelectric and electrical properties of the thin films can be optimised by use of more positive electrode potentials. The thin films fabricated exhibit a thermoelectric efficiency of up to two orders of magnitude greater than similar materials prepared by electrodeposition previously and equal efficiency to those prepared by methods which are more costly and difficult to undertake. Doping these materials with copper, by electrochemical means, further improves the thermoelectric efficiency by over another order of magnitude.
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Smith, Kevin D. "An investigation into the viability of heat sources for thermoelectric power generation systems /". Online version of thesis, 2009. http://hdl.handle.net/1850/8266.

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Weinstein, Lee A. (Lee Adragon). "Improvements to solar thermoelectric generators through device design". Thesis, Massachusetts Institute of Technology, 2013. http://hdl.handle.net/1721.1/85471.

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Thesis: S.M., Massachusetts Institute of Technology, Department of Mechanical Engineering, 2013.
Cataloged from PDF version of thesis.
Includes bibliographical references (pages 145-150).
A solar thermoelectric generator (STEG) is a device which converts sunlight into electricity through the thermoelectric effect. A STEG is nominally formed when a thermoelectric generator (TEG), a type of solid state heat engine, is placed between a solar absorber and a heat sink. When the solar absorber is illuminated by sunlight, it heats up and the TEG is subjected to a temperature gradient. Heat flows through the TEG, some of which is converted to electricity. Recent advancements have improved STEG efficiency considerably, however more work is required before STEGs will be able to compete commercially with other solar to electricity conversion technologies. This thesis explores two device level improvements to STEG systems. First, thin-film STEGs are explored as a method to potentially reduce the manufacturing costs of STEG systems. It is shown through modeling that thin-film STEGs have only a slight degradation in performance compared to bulk STEGs when identical materials properties are used. Two parameters are found which can guide device design for thin-film STEGs regardless of system size. Second, an optical cavity is investigated which can improve opto-thermal efficiency for STEGs or any other solar-thermal system. The cavity improves performance by specularly reflecting radiation from the absorber back to itself, reducing radiative losses. It is shown through modeling and with some preliminary experimental results that such a cavity has the potential to significantly improve the opto-thermal efficiency of solar-thermal systems and operate efficiently at high absorber temperatures without the use of extremely high optical concentration ratios.
by Lee A. Weinstein.
S.M.
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Sandoz-Rosado, Emil Jose. "Investigation and development of advanced models of thermoelectric generators for power generation applications /". Online version of thesis, 2009. http://hdl.handle.net/1850/10795.

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McEnaney, Kenneth. "Modeling of solar thermal selective surfaces and thermoelectric generators". Thesis, Massachusetts Institute of Technology, 2010. http://hdl.handle.net/1721.1/65308.

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Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Mechanical Engineering, 2010.
Cataloged from PDF version of thesis.
Includes bibliographical references (p. 101-107).
A thermoelectric generator is a solid-state device that converts a heat flux into electrical power via the Seebeck effect. When a thermoelectric generator is inserted between a solar-absorbing surface and a heat sink, a solar thermoelectric generator is created which converts sunlight into electrical power. This thesis describes the design and optimization of solar thermoelectric generators, with a focus on systems with high optical concentration which utilize multiple material systems to maximize efficiency over a large temperature difference. Both single-stage and cascaded (multi-stage) generators are considered, over an optical concentration range of 0.1 to 1000X. It is shown that for high-concentration Bi₂Te₃/skutterudite solar thermoelectric generators, conversion efficiencies of 13% are possible with current thermoelectric materials and selective surfaces. Better selective surfaces are needed to improve the efficiency of solar thermoelectric generators. In this thesis, ideal selective surfaces for solar thermoelectric generators are characterized. Non-ideal selective surfaces are also characterized, with emphasis on how the non-idealities affect the solar thernoelectric gencrator performance. Finally. the efficiency limit for solar thermoclectric generators with non-directional absorbers is presented.
by Kenneth McEnaney.
S.M.
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Libros sobre el tema "Thermoelectric, Cu2SnS3, thermoelectric generators"

1

Kalandarishvili, A. G. Istochniki rabochego tela dli͡a︡ termoėmissionnykh preobrazovateleĭ ėnergii. Moskva: Ėnergoatomizdat, 1986.

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Sini͡avskiĭ, V. V. Metody opredelenii͡a kharakteristik termoėmissionnykh tvėlov. Moskva: Ėnergoatomizdat, 1990.

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Buri͡ak, Anatoliĭ Andreevich. Ocherki razvitii͡a termoėlektrichestva. Kiev: Nauk. dumka, 1988.

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Thermoelectric power generation: Symposium held November 26-29, 2007, Boston, Massachusetts, U.S.A. Warrendale, Pa: Materials Research Society, 2008.

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Skipidarov, Sergey y Mikhail Nikitin, eds. Thin Film and Flexible Thermoelectric Generators, Devices and Sensors. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-45862-1.

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Sarkisov, A. A. Termoėlektricheskie generatory s i͡a︡dernymi istochnikami teploty. Moskva: Ėnergoatomizdat, 1987.

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Kukharkin, N. E. Kosmicheskai︠a︡ i︠a︡dernai︠a︡ ėnergetika (i︠a︡dernye reaktory s termoėlektricheskim i termoėmissionnym preobrazovaniem--"Romashka" i "Eniseĭ"). Moskva: IzdAt, 2012.

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Baranov, A. P. Sudovye sistemy ėlektrodvizhenii͡a︡ s generatorami pri͡a︡mogo preobrazovanii͡a︡ teploty: Rezhimy raboty i ikh modelirovanie. Leningrad: "Sudostroenie", 1991.

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M, Tritt Terry, ed. Thermoelectric materials, 1998--the next generation materials for small-scale refrigeration and power generation applications: Symposium held November 30-December 3, 1998, Boston, Massachusetts, U.S.A. Warrendale, PA: Materials Research Society, 1999.

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M, Tritt Terry, ed. Thermoelectric materials 2000: The next generation materials for small-scale refrigeration and power generation applications : symposium held April 24-27, 2000, San Francisco, Calif., U.S.A. Warrendale, Pa: Materials Research Society, 2001.

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Capítulos de libros sobre el tema "Thermoelectric, Cu2SnS3, thermoelectric generators"

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Narducci, Dario, Peter Bermel, Bruno Lorenzi, Ning Wang y Kazuaki Yazawa. "Solar Thermoelectric Generators". En Hybrid and Fully Thermoelectric Solar Harvesting, 45–61. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-76427-6_3.

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Stark, Ingo. "Micro Thermoelectric Generators". En Micro Energy Harvesting, 245–69. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2015. http://dx.doi.org/10.1002/9783527672943.ch12.

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Lan, Yucheng y Zhifeng Ren. "Solar Thermoelectric Power Generators". En Advanced Thermoelectrics, 735–68. Boca Raton, FL : CRC Press, Taylor & Francis Group, [2017] | Series: Series in materials science and engineering: CRC Press, 2017. http://dx.doi.org/10.1201/9781315153766-22.

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Narducci, Dario, Peter Bermel, Bruno Lorenzi, Ning Wang y Kazuaki Yazawa. "A Primer on Thermoelectric Generators". En Hybrid and Fully Thermoelectric Solar Harvesting, 11–43. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-76427-6_2.

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Narducci, Dario, Peter Bermel, Bruno Lorenzi, Ning Wang y Kazuaki Yazawa. "Hybrid Photovoltaic–Thermoelectric Generators: Materials Issues". En Hybrid and Fully Thermoelectric Solar Harvesting, 103–16. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-76427-6_6.

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Dani, Ines, Aljoscha Roch, Lukas Stepien, Christoph Leyens, Moritz Greifzu y Marian von Lukowicz. "Energy Turnaround: Printing of Thermoelectric Generators". En IFIP Advances in Information and Communication Technology, 181–84. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013. http://dx.doi.org/10.1007/978-3-642-41329-2_19.

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Novikov, S. V., E. Z. Parparov y M. I. Fedorov. "Reliable Thermoelectric Generators for Space Missions". En Proceedings of the 11th European Conference on Thermoelectrics, 109–16. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-07332-3_13.

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Narducci, Dario, Peter Bermel, Bruno Lorenzi, Ning Wang y Kazuaki Yazawa. "A Primer on Photovoltaic Generators". En Hybrid and Fully Thermoelectric Solar Harvesting, 63–90. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-76427-6_4.

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Narducci, Dario, Peter Bermel, Bruno Lorenzi, Ning Wang y Kazuaki Yazawa. "Hybrid Photovoltaic–Thermoelectric Generators: Theory of Operation". En Hybrid and Fully Thermoelectric Solar Harvesting, 91–102. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-76427-6_5.

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Nonoguchi, Yoshiyuki. "Materials Design for Flexible Thermoelectric Power Generators". En Flexible and Stretchable Medical Devices, 139–60. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2018. http://dx.doi.org/10.1002/9783527804856.ch6.

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Actas de conferencias sobre el tema "Thermoelectric, Cu2SnS3, thermoelectric generators"

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"Thermoelectric generators". En IECON 2012 - 38th Annual Conference of IEEE Industrial Electronics. IEEE, 2012. http://dx.doi.org/10.1109/iecon.2012.6389125.

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Caillat, Thierry, Jean-Pierre Fleurial y Alex Borshchevsky. "Development of high efficiency thermoelectric generators using advanced thermoelectric materials". En Space technology and applications international forum - 1998. AIP, 1998. http://dx.doi.org/10.1063/1.54794.

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Dalala, Zakariya M. "Energy harvesting using thermoelectric generators". En 2016 IEEE International Energy Conference (ENERGYCON). IEEE, 2016. http://dx.doi.org/10.1109/energycon.2016.7514088.

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Paul, D. J., A. Samarelli, L. Ferre Llin, J. R. Watling, Y. Zhang, J. M. R. Weaver, P. S. Dobson et al. "Prospects for SiGe thermoelectric generators". En 2013 14th International Conference on Ultimate Integration on Silicon (ULIS 2013). IEEE, 2013. http://dx.doi.org/10.1109/ulis.2013.6523478.

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Miodushevsky, Pavel. "High Energy Density Thermoelectric Generators". En 6th International Energy Conversion Engineering Conference (IECEC). Reston, Virigina: American Institute of Aeronautics and Astronautics, 2008. http://dx.doi.org/10.2514/6.2008-5688.

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Massetti, Matteo. "3D printed Organic Thermoelectric Generators". En nanoGe Fall Meeting 2021. València: Fundació Scito, 2021. http://dx.doi.org/10.29363/nanoge.nfm.2021.145.

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Salvador, Catherine S., Angela Caliwag, Nathaniel Aldivar, Vince Angeles y Mark Bernabe. "Modeling of Roof-Mountable Thermoelectric Generators". En 2017 25th International Conference on Systems Engineering (ICSEng). IEEE, 2017. http://dx.doi.org/10.1109/icseng.2017.75.

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Xu, Xiaoqiang, Yongjia Wu, Lei Zuo y Shikui Chen. "Multimaterial Topology Optimization of Thermoelectric Generators". En ASME 2019 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. American Society of Mechanical Engineers, 2019. http://dx.doi.org/10.1115/detc2019-97934.

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Abstract Over 50% of the energy from power plants, vehicles, oil refining, and steel or glass making process is released to the atmosphere as waste heat. As an attempt to deal with the growing energy crisis, the solid-state thermoelectric generator (TEG), which converts the waste heat into electricity using Seebeck phenomenon, has gained increasing popularity. Since the figures of merit of the thermoelectric materials are temperature dependent, it is not feasible to achieve high efficiency of the thermoelectric conversion using only one single thermoelectric material in a wide temperature range. To address this challenge, this paper proposes a method based on topology optimization to optimize the layouts of functional graded TEGs consisting of multiple materials. The objective of the optimization problem is to maximize the output power and conversion efficiency as well. The proposed method is implemented using the Solid Isotropic Material with Penalization (SIMP) method. The proposed method can make the most of the potential of different thermoelectric materials by distributing each material into its optimal working temperature interval. Instead of dummy materials, both the P and N-type electric conductors are optimally distributed with two different practical thermoelectric materials, namely Bi2Te3 & PbTe for P-type, and Bi2Te3 & CoSb3 for N-type respectively, with the yielding conversion efficiency around 12.5% in the temperature range Tc = 25°C and Th = 400°C. In the 2.5D computational simulation, however, the conversion efficiency shows a significant drop. This could be attributed to the mismatch of the external load and internal TEG resistance as well as the grey region from the topology optimization results as discussed in this paper.
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Chan, Walker R., Christopher M. Waits, John D. Joannopoulos y Ivan Celanovic. "Thermophotovoltaic and thermoelectric portable power generators". En SPIE Defense + Security, editado por Thomas George, M. Saif Islam y Achyut K. Dutta. SPIE, 2014. http://dx.doi.org/10.1117/12.2054173.

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Ledesma, Edward M., Shervin Sammak y Matthew M. Barry. "MODELING BRIDGMAN HEATING IN THERMOELECTRIC GENERATORS". En 5-6th Thermal and Fluids Engineering Conference (TFEC). Connecticut: Begellhouse, 2021. http://dx.doi.org/10.1615/tfec2021.cmd.036778.

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Informes sobre el tema "Thermoelectric, Cu2SnS3, thermoelectric generators"

1

Gomez, Alessandro. Development of Optimized Combustors and Thermoelectric Generators for Palm Power Generation. Fort Belvoir, VA: Defense Technical Information Center, octubre de 2004. http://dx.doi.org/10.21236/ada427416.

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Weiss, H. V. y J. F. Vogt. Radioisotope Thermoelectric Generators Emplaced in the Deep Ocean, Recover or Dispose in Situ. Fort Belvoir, VA: Defense Technical Information Center, marzo de 1986. http://dx.doi.org/10.21236/ada168027.

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Salvador, James. Development of Cost-Competitive Advanced Thermoelectric Generators for Direct Conversion of Vehicle Waste Heat into Useful Electrical Power. Office of Scientific and Technical Information (OSTI), diciembre de 2017. http://dx.doi.org/10.2172/1414341.

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Shott, Gregory y Dawn Reed. UNREVIEWED DISPOSAL QUESTION EVALUATION: Disposal of the Lawrence Livermore National Laboratory French Radioisotope Thermoelectric Generators at the Area 5 Radioactive Waste Management Site, Nevada National Security Site, Nye County, Nevada. Office of Scientific and Technical Information (OSTI), enero de 2020. http://dx.doi.org/10.2172/1601280.

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[Radioisotope thermoelectric generators and ancillary activities]. Monthly technical progress report, 1 April--28 April 1996. Office of Scientific and Technical Information (OSTI), junio de 1996. http://dx.doi.org/10.2172/233289.

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(Design, fabricate, and provide engineering support for radiosotope thermoelectric generators for NASA's CRHF AND CASSINI missions). Office of Scientific and Technical Information (OSTI), enero de 1991. http://dx.doi.org/10.2172/5772917.

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