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Journal articles on the topic 'Energy conversion systems'

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Author: Grafiati
Published: 10 December 2022
Last updated: 6 September 2023

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1

Sówka, Izabela, Sławomir Pietrowicz, and Piotr Kolasiński. "Energy Processes, Systems and Equipment." Energies 14, no. 6 (March 18, 2021): 1701. http://dx.doi.org/10.3390/en14061701.

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The scientific and technical issues related to energy harvesting and conversion are inseparably bound to the issues of environmental protection. Energy conversion systems and devices that are applied for converting the chemical energy contained in different fuels into heat, electricity, and cold in industry and housing are sources of different gases and solid particle emissions. Thus, the development of different technologies for energy conversion and environmental protection that can be jointly applied to cover growing energy needs has become a crucial challenge for scientists and engineers around the world. Progress in the precise description, modeling, and optimization of physical and chemical phenomena related to these energy conversion systems is a key research and development field for the economy. Legal and social issues that are affecting key aspects and problems related to the energy conversion and power sector are also significant and worth investigating. The aim of Energy Processes, Systems and Equipment Special Issue is to publish selected high-quality papers from the XV Scientific Conference POL-EMIS 2020: Current Trends in Air and Climate Protection—Control Monitoring, Forecasting, and Reduction of Emissions (29–31 March 2021, Wrocław) and other papers related to the field of energy conversion.
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2

Papadopoulos, M. "Book Review: Wind Energy Conversion Systems." International Journal of Electrical Engineering & Education 29, no. 3 (July 1992): 264. http://dx.doi.org/10.1177/002072099202900309.

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3

Vocadlo, Jaro J., Brian Richards, and Michael King. "Hydraulic Kinetic Energy Conversion (HKEC) Systems." Journal of Energy Engineering 116, no. 1 (April 1990): 17–38. http://dx.doi.org/10.1061/(asce)0733-9402(1990)116:1(17).

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4

Yates, D. A. "Book Review: Wind Energy Conversion Systems." International Journal of Mechanical Engineering Education 22, no. 1 (January 1994): 76–77. http://dx.doi.org/10.1177/030641909402200112.

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5

Miguel, A. F., and M. Aydin. "Ocean exergy and energy conversion systems." International Journal of Exergy 10, no. 4 (2012): 454. http://dx.doi.org/10.1504/ijex.2012.047507.

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6

Demirbas, Ayhan. "Biofuel Based Cogenerative Energy Conversion Systems." Energy Sources, Part A: Recovery, Utilization, and Environmental Effects 28, no. 16 (December 2006): 1509–18. http://dx.doi.org/10.1080/009083190932187.

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7

Jansen, D., and M. Mozaffarian. "Advanced fuel cell energy conversion systems." Energy Conversion and Management 38, no. 10-13 (July 1997): 957–67. http://dx.doi.org/10.1016/s0196-8904(96)00126-4.

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8

Suda, S. "Energy Conversion Systems Using Metal Hydrides*." Zeitschrift für Physikalische Chemie 164, Part_2 (January 1989): 1463–74. http://dx.doi.org/10.1524/zpch.1989.164.part_2.1463.

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9

Deubener, J., G. Helsch, A. Moiseev, and H. Bornhöft. "Glasses for solar energy conversion systems." Journal of the European Ceramic Society 29, no. 7 (April 2009): 1203–10. http://dx.doi.org/10.1016/j.jeurceramsoc.2008.08.009.

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10

Subahan, G. M., G. Surendra Reddy, Y. Veera Reddy, G. Sudheer Reddy, G. Vishnu, and M. Srinivasulu. "PMSG Wind Energy Conversion Systems ZSI." International Journal for Research in Applied Science and Engineering Technology 11, no. 3 (March 31, 2023): 1708–17. http://dx.doi.org/10.22214/ijraset.2023.49534.

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Abstract: Recently Permanent Magnet Synchronous Generator are mostly used in the Wind Energy Conversion System applications This work is clearly deal with the study of Wind Energy Conversion System WECS by way of Permanent Magnet Synchronous Generator PMSG with Z Source Inverters. The PMSGs and wind turbines are gradually entered in the field of power generation huge wind farms are used at constant voltage and frequency to increase capacity power supply Particularly Permanent Magnet Synchronous Generators is used in this machinery due to special characteristics such as low weight volume and high. PMSG never required the power supply at the starting time of power production PMSGs run at synchronous speed. These type of inverter are classified has Z-Source Inverter ZSI, Quasi Z Source Inverter QZSI, Trans Z Source Trans ZSI and Cascaded Multi Cell Z Source Inverter CMCTZSI etc. This inverter is operated such as shoot through state and on shoot through state previously to convert DC supply to AC supply where the DC supply side have been boosted up to required AC supply level are executed. The above mention shoot through state is not applicable to implementing in the conventional Voltage Source Inverter VSI and Current Source Inverter CSI. The PMSG and types of Z Source inverter systems are simulated in MATLAB Simulation platform.
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11

Mojumdar, Md Rejwanur Rashid, Mohammad Sakhawat Hossain Himel, Md Salman Rahman, and Sheikh Jakir Hossain. "Electric Machines & Their Comparative Study for Wind Energy Conversion Systems (WECSs)." Journal of Clean Energy Technologies 4, no. 4 (2015): 290–94. http://dx.doi.org/10.7763/jocet.2016.v4.299.

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12

Sheikh, Aabid Hussain, and Dr O. P. Malik. "Maximum Power Extraction Strategy for Wind Energy Conversion Systems using Intelligent Controllers." International Journal of Trend in Scientific Research and Development Volume-1, Issue-4 (June 30, 2017): 580–84. http://dx.doi.org/10.31142/ijtsrd2213.

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13

Szałek, Andrzej. "Energy conversion in motor vehicles." Combustion Engines 183, no. 4 (December 15, 2020): 50–57. http://dx.doi.org/10.19206/ce-2020-408.

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The portfolio of the automotive market appears more and more low-emission and zero-emission propulsions in vehicles. This is the result of measures taken to limit or even eliminate the emission of harmful substances into the atmosphere generated by vehicles. The article covers issues related to energy conversion in automotive drive systems currently offered by automotive manufacturers. Standard, hybrid, hybrid plug-in, electric and fuel cells drive system were analyzed. Attention was drawn to the chain of energy transformations related to each of the analyzed drive systems. The efficiency of the presented vehicle drive systems was analyzed. General conclusions were formulated regarding the method of analyzing energy changes related to the operation of automotive propulsion systems. The article reviews selected author's own works on hybrid and hydrogen propulsions.
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14

Wagner, Hermann-Josef. "Introduction to wind energy systems(*)." EPJ Web of Conferences 246 (2020): 00004. http://dx.doi.org/10.1051/epjconf/202024600004.

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This article presents the basic concepts of wind energy and deals with the physics and mechanics of operation. It describes the conversion of wind energy into rotation of turbine, and the critical parameters governing the efficiency of this conversion. After that it presents an overview of various parts and components of windmills. The connection to the electrical grid, the world status of wind energy use for electricity production, the cost situation and research and development needs are further aspects which will be considered.
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15

Bagdanavicius, Audrius. "Energy and Exergy Analysis of Renewable Energy Conversion Systems." Energies 15, no. 15 (July 29, 2022): 5528. http://dx.doi.org/10.3390/en15155528.

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16

Chalamala, Babu R., Ross Guttromson, and Ralph D. Masiello. "Energy Storage—Part I: Batteries and Energy Conversion Systems." Proceedings of the IEEE 102, no. 6 (June 2014): 936–38. http://dx.doi.org/10.1109/jproc.2014.2321031.

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17

Xie, Kaigui, and Roy Billinton. "Energy and reliability benefits of wind energy conversion systems." Renewable Energy 36, no. 7 (July 2011): 1983–88. http://dx.doi.org/10.1016/j.renene.2010.12.011.

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18

Wagner, Hermann-Josef. "Introduction to wind energy systems." EPJ Web of Conferences 189 (2018): 00005. http://dx.doi.org/10.1051/epjconf/201818900005.

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This article presents the basic concepts of wind energy and deals with the physics and mechanics of operation. It describes the conversion of wind energy into the rotation of a turbine, and the critical parameters governing the efficiency of this conversion. After that it presents an overview of the various parts and component of windmills. The connection to the electrical grid, the world status of wind energy use for electricity production, the cost situation and research and development needs are further aspects which will be considered.
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19

Kozuma, Ichiro. "Frequency conversion technology for new energy systems." IEEJ Transactions on Industry Applications 109, no. 2 (1989): 73–77. http://dx.doi.org/10.1541/ieejias.109.73.

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20

Alhmoud, Lina, and Hussein Al-Zoubi. "IoT Applications in Wind Energy Conversion Systems." Open Engineering 9, no. 1 (November 2, 2019): 490–99. http://dx.doi.org/10.1515/eng-2019-0061.

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AbstractRenewable energy reliability has been the main agenda nowadays, where the internet of things (IoT) is a crucial research direction with a lot of opportunities for improvement and challenging work. Data obtained from IoT is converted into actionable information to improve wind turbine performance, driving wind energy cost down and reducing risk. However, the implementation in IoT is a challenging task because the wind turbine system level and component level need real-time control. So, this paper is dedicated to investigating wind resource assessment and lifetime estimation of wind power modules using IoT. To illustrate this issue, a model is built with sub-models of an aerodynamic rotor connected directly to a multi-pole variable speed permanent magnet synchronous generator (PMSG) with variable speed control, pitch angle control and full-scale converter connected to the grid. Besides, a large number of various sensors for measurement of wind parameters are integrated with IoT. Simulations are constructed with Matlab/Simulink and IoT ’Thingspeak’ Mathworks web service. IoT has proved to increase the reliability of measurement strategies, monitoring accuracy, and quality assurance.
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21

Chen, Gang. "Thermoelectric Energy Conversion: Materials, Devices, and Systems." Journal of Physics: Conference Series 660 (December 10, 2015): 012066. http://dx.doi.org/10.1088/1742-6596/660/1/012066.

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22

Freitas, Walmir, Ahmed Faheem Zobaa, Jose C. M. Vieira, and James S. McConnach. "Issues related to wind energy conversion systems." International Journal of Energy Technology and Policy 3, no. 4 (2005): 313. http://dx.doi.org/10.1504/ijetp.2005.008397.

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23

Dabiri, A. E. "Energy Conversion Systems Design for Fusion Reactors." Fusion Technology 15, no. 2P2B (March 1989): 1275–80. http://dx.doi.org/10.13182/fst89-a39865.

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24

Han, Ying Hua. "Grid Integration of Wind Energy Conversion Systems." Renewable Energy 21, no. 3-4 (November 2000): 607–8. http://dx.doi.org/10.1016/s0960-1481(00)00042-2.

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25

El Marjani, A., F. Castro Ruiz, M. A. Rodriguez, and M. T. Parra Santos. "Numerical modelling in wave energy conversion systems." Energy 33, no. 8 (August 2008): 1246–53. http://dx.doi.org/10.1016/j.energy.2008.02.018.

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26

Chen, Zhe. "Special Issue on “Wind Energy Conversion Systems”." Applied Sciences 9, no. 16 (August 9, 2019): 3258. http://dx.doi.org/10.3390/app9163258.

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A single paragraph of about 200 words maximum. For research articles, abstracts should give a pertinent overview of the work. We strongly encourage authors to use the following style of structured abstracts, but without headings: (1) Background: place the question addressed in a broad context and highlight the purpose of the study; (2) Methods: describe briefly the main methods or treatments applied; (3) Results: summarize the article’s main findings; and (4) Conclusions: indicate the main conclusions or interpretations. The abstract should be an objective representation of the article; it must not contain results that are not presented and substantiated in the main text and should not exaggerate the main conclusions.
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27

Palacios, Rodrigo E., Stephanie L. Gould, Christian Herrero, Michael Hambourger, Alicia Brune, Gerdenis Kodis, Paul A. Liddell, et al. "Bioinspired energy conversion." Pure and Applied Chemistry 77, no. 6 (January 1, 2005): 1001–8. http://dx.doi.org/10.1351/pac200577061001.

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Artificial photosynthetic antenna systems have been synthesized based on carotenoid polyenes and polymer-polyenes covalently attached to tetrapyrroles. Absorption of light in the blue/green region of the spectra excites the polyenes to their S2 state, and ultrafast singlet energy transfer to the tetrapyrroles occurs when the chromophores are in partial conjugation. The additional participation of other excited states of the polyene in the energy-transfer process is a requirement for perfect antenna function. Analogs of photosynthetic reaction centers consisting of tetrapyrrole chromophores covalently linked to electron acceptors and donors have been prepared. Excitation of these constructs results in a cascade of energy transfer/electron transfer which, in selected cases, forms a final charge-separated state characterized by a giant dipole moment (>150 D), a quantum yield approaching unity, a significant fraction of the photon energy stored as chemical potential, and a lifetime sufficient for reaction with secondary electron donors and acceptors. A new antenna-reaction center complex is described in which a carotenoid moiety is located in partial conjugation with the tetrapyrrole π-system allowing fast energy transfer (<100 fs) between the chromophores. In this assembly, the energy transduction process can be initiated by light absorbed by the polyene.
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28

Schlögl, Robert. "Sustainable Energy Systems: The Strategic Role of Chemical Energy Conversion." Topics in Catalysis 59, no. 8-9 (April 13, 2016): 772–86. http://dx.doi.org/10.1007/s11244-016-0551-9.

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29

Dai, Quanqi, Inhyuk Park, and Ryan L. Harne. "Impulsive energy conversion with magnetically coupled nonlinear energy harvesting systems." Journal of Intelligent Material Systems and Structures 29, no. 11 (April 23, 2018): 2374–91. http://dx.doi.org/10.1177/1045389x18770860.

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Magnets have received broad attention for vibration energy harvesting due to noncontact, nonlinear forces that may be leveraged among harvesting system elements. Yet, opportunities to integrate multi-directional coupling among a nonlinear energy harvesting system subjected to impulsive excitations have not been scrutinized, despite widespread prevalence of such excitations. To characterize these potentials, this research investigates an energy harvesting system with magnetically induced nonlinearities and coupling effects under impulsive excitations. A system model is formulated and validated with experimental efforts to reconstruct static and dynamic properties of the system via simulations. Then, the model is harnessed to scrutinize dynamic response of the system when subjected to impulse conditions. This research reveals the clear impulse strength dependence and influence of asymmetries on total electrical energy capture and energy conversion efficiency that are tailored by magnetic force coupling. Asymmetry is found to promote greater impulse-to-electrical energy conversion when compared to the symmetric counterpart system and a benchmark nonlinear energy harvester. The roles of initial conditions exemplify how stored energy in an asymmetric energy harvesting system may be released during nonlinear impulsive response. These results provide insights about opportunities and challenges to incorporate magnetic coupling effects in nonlinear energy harvesting systems subjected to impulses.
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30

Pilipenko, A. V., and S. P. Petrov. "Analysis of Energy Efficiency of Energy Conversion in Cogeneration Systems." IOP Conference Series: Earth and Environmental Science 224 (February 5, 2019): 012006. http://dx.doi.org/10.1088/1755-1315/224/1/012006.

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31

VISA, ION, and ANCA DUTA. "The role of solar energy in the future energy scenario." Journal of Engineering Sciences and Innovation 3, no. 3 (September 16, 2018): 215–26. http://dx.doi.org/10.56958/jesi.2018.3.3.215.

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The future energy scenario of each country needs to be developed based on key issues that are outlined and examples of innovative solutions for implementing solar energy conversion systems in the built environment are presented. Additionally, sustainability features of the implemented systems are presented and the emergent solar energy conversion processes – as photocatalysis – are discussed.
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32

Batko, Kornelia M., Izabella Ślęzak-Prochazka, Andrzej Ślęzak, Wioletta M. Bajdur, and Maria Włodarczyk-Makuła. "Management of Energy Conversion Processes in Membrane Systems." Energies 15, no. 5 (February 23, 2022): 1661. http://dx.doi.org/10.3390/en15051661.

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The internal energy (U-energy) conversion to free energy (F-energy) and energy dissipation (S-energy) is a basic process that enables the continuity of life on Earth. Here, we present a novel method of evaluating F-energy in a membrane system containing ternary solutions of non-electrolytes based on the Kr version of the Kedem–Katchalsky–Peusner (K–K–P) formalism for concentration polarization conditions. The use of this formalism allows the determination of F-energy based on the production of S-energy and coefficient of the energy conversion efficiency. The K–K–P formalism requires the calculation of the Peusner coefficients Kijr and Kdetr (i, j ∈ {1, 2, 3}, r = A, B), which are necessary to calculate S-energy, the degree of coupling and coefficients of energy conversion efficiency. In turn, the equations for S-energy and coefficients of energy conversion efficiency are used in the F-energy calculations. The Kr form of the Kedem–Katchalsky–Peusner model equations, containing the Peusner coefficients Kijr and Kdetr, enables the analysis of energy conversion in membrane systems and is a useful tool for studying the transport properties of membranes. We showed that osmotic pressure dependences of indicated Peusner coefficients, energy conversion efficiency coefficient, entropy and energy production are nonlinear. These nonlinearities were caused by pseudophase transitions from non-convective to convective states or vice versa. The method presented in the paper can be used to assess F-energy resources. The results can be adapted to various membrane systems used in chemical engineering, environmental engineering or medical applications. It can be used in designing new technologies as a part of process management.
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33

CIUCUR, VIOLETA-VALI. "INCREASING THE EFFICIENCY OF MARINE ENERGY CONVERSION." Journal of marine Technology and Environment 2021, no. 2 (October 1, 2021): 7–10. http://dx.doi.org/10.53464/jmte.02.2021.01.

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New approaches need to be taken into account in adopting the configuration of residual heat recovery systems, design, operation and control and to consider equipment and the energy conversion process in the perspective of integrated systems in order to increase measurable energy efficiency in existing marine energy systems as well as other new systems.
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34

Gursoy, Mehmetcan, Guangping Zhuo, Andy G. Lozowski, and Xin Wang. "Photovoltaic Energy Conversion Systems with Sliding Mode Control." Energies 14, no. 19 (September 24, 2021): 6071. http://dx.doi.org/10.3390/en14196071.

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A new sliding-mode-control-based power conversion scheme is proposed for photovoltaic energy conversion systems. The perturbation and observation (P&O) maximum power-point tracking (MPPT) approach is adopted for optimizing the power generation capabilities from solar panels. Due to the inherent nonlinear dynamics of power converters, we need to adopt a nonlinear control approach to optimize the energy conversion efficiency and tolerate the fluctuations and changes of load and sunlight irradiance. In this manuscript, novel first-and higher-order sliding mode control approaches are proposed, aiming to provide a systematic approach for the robust and optimal control of solar energy conversion, which guarantees Lyapunov stability and consistent performance in the face of external perturbations and disturbances. Moreover, to eliminate the chattering phenomenon inherent in the first-order approach, super-twisting second-order sliding mode control is developed for the buck-boost converter. Furthermore, the output of DC–DC converter supplies a voltage-oriented-control (VOC)-based space-vector pulse-width-modulated inverter to generate three-phase AC power to the grid. To demonstrate the robustness and effectiveness of the proposed scheme, computer simulations and dSPACE hardware-in-the-loop platform have been carried on for examining the proposed sliding-mode-control-based solar energy conversion system.
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35

Kadırgan, F. "Electrochemical nano-coating processes in solar energy systems." International Journal of Photoenergy 2006 (2006): 1–5. http://dx.doi.org/10.1155/ijp/2006/84891.

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The efficiencies of electrochemically prepared nano-thick CdS and black nickel coatings were investigated as a function of their preparation conditions in the application field of energy; such as, solar-electricity conversion, solar cells, and solar-thermal conversion, spectrally selective solar collectors.
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36

Haseli, Yousef. "Interpretation of Entropy Calculations in Energy Conversion Systems." Energies 14, no. 21 (October 27, 2021): 7022. http://dx.doi.org/10.3390/en14217022.

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Often, second law-based studies present merely entropy calculations without demonstrating how and whether such calculations may be beneficial. Entropy generation is commonly viewed as lost work or sometimes a source of thermodynamic losses. Recent literature reveals that minimizing the irreversibility of a heat engine may correspond to maximizing thermal efficiency subject to certain design constraints. The objective of this article is to show how entropy calculations need to be interpreted in thermal processes, specifically, where heat-to-work conversion is not a primary goal. We will study four exemplary energy conversion processes: (1) a biomass torrefaction process where torrefied solid fuel is produced by first drying and then torrefying raw feedstock, (2) a cryogenic air separation system that splits ambient air into oxygen and nitrogen while consuming electrical energy, (3) a cogeneration process whose desirable outcome is to produce both electrical and thermal energy, and (4) a thermochemical hydrogen production system. These systems are thermodynamically analyzed by applying the first and second laws. In each case, the relation between the total entropy production and the performance indicator is examined, and the conditions at which minimization of irreversibility leads to improved performance are identified. The discussion and analyses presented here are expected to provide clear guidelines on the correct application of entropy-based analyses and accurate interpretation of entropy calculations.
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37

Ioinovici, Adrian. "Special Issue “Renewable and Sustainable Energy Conversion Systems”." Applied Sciences 12, no. 8 (April 13, 2022): 3905. http://dx.doi.org/10.3390/app12083905.

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38

Guo, Bingyong, Siming Zheng, John Ringwood, João Henriques, and Dahai Zhang. "Guest Editorial: Advances in Wave Energy Conversion Systems." IET Renewable Power Generation 15, no. 14 (October 2021): 3039–44. http://dx.doi.org/10.1049/rpg2.12303.

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39

Rodrigues, Leao. "Wave power conversion systems for electrical energy production." Renewable Energy and Power Quality Journal 1, no. 06 (March 2008): 601–7. http://dx.doi.org/10.24084/repqj06.380.

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40

Karaki, S. H., R. B. Chedid, and R. Ramadan. "Probabilistic performance assessment of wind energy conversion systems." IEEE Transactions on Energy Conversion 14, no. 2 (June 1999): 217–24. http://dx.doi.org/10.1109/60.766986.

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41

Stanley, Cameron, Ahmad Mojiri, and Gary Rosengarten. "Spectral light management for solar energy conversion systems." Nanophotonics 5, no. 1 (June 1, 2016): 161–79. http://dx.doi.org/10.1515/nanoph-2016-0035.

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Abstract Due to the inherent broadband nature of the solar radiation, combined with the narrow spectral sensitivity range of direct solar to electricity devices, there is a massive opportunity to manipulate the solar spectrum to increase the functionality and efficiency of solar energy conversion devices. Spectral splitting or manipulation facilitates the efficient combination of both high-temperature solar thermal systems, which can absorb over the entire solar spectrum to create heat, and photovoltaic cells, which only convert a range of wavelengths to electricity. It has only recently been possible, with the development of nanofabrication techniques, to integrate micro- and nano-photonic structures as spectrum splitters/manipulators into solar energy conversion devices. In this paper, we summarize the recent developments in beam splitting techniques, and highlight some relevant applications including combined PV-thermal collectors and efficient algae production, and suggest paths for future development in this field.
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42

Dulley, T. A. C. "A Guide to Small Wind Energy Conversion Systems." IEE Review 35, no. 1 (1989): 36. http://dx.doi.org/10.1049/ir:19890016.

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43

Gago, Aldo S., Aurelien Habrioux, and Nicolas Alonso-Vante. "Tailoring nanostructured catalysts for electrochemical energy conversion systems." Nanotechnology Reviews 1, no. 5 (October 1, 2012): 427–53. http://dx.doi.org/10.1515/ntrev-2012-0013.

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AbstractThis review covers topics related to the synthesis of nanoparticles, the anodic and cathodic electrochemical reactions and low temperature electrochemical energy devices. The thermodynamic aspects of nucleation and growth of nanoparticles are discussed. Different methods of chemical synthesis such as w/o microemulsion, Bönnemann, polyol and carbonyl are presented. How the electrochemical reactions take place on the surface of the catalytic nanoparticles and the importance of the substrate is put in evidence. The use of nanomaterials in low temperature energy devices such as H2/O2 polymer electrolyte or proton exchange membrane fuel cell (PEMFC) and micro-direct methanol fuel cell (μDMFC), as well as recent progress and durability, is discussed. Special attention is given to the novel laminar flow fuel cell (LFFC). This review starts with the genesis of catalytic nanoparticles, continues with the surface electrochemical reactions that occur on them, and finally it discusses their application in electrochemical energy devices such as low temperature fuel cells or Li-air batteries.
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44

Visa, I., A. Cotorcea, M. Neagoe, and M. Moldovan. "Adaptability of solar energy conversion systems on ships." IOP Conference Series: Materials Science and Engineering 147 (August 2016): 012070. http://dx.doi.org/10.1088/1757-899x/147/1/012070.

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45

Dabiri, Ali E. "Thermal Energy Conversion Systems Overview for Fusion Reactors." Fusion Technology 16, no. 2 (September 1989): 211–24. http://dx.doi.org/10.13182/fst89-a29149.

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46

Hodges, Laurent. "A guide to small wind energy conversion systems." Physics Teacher 26, no. 7 (October 1988): 481. http://dx.doi.org/10.1119/1.2342587.

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47

St. Pierre, George R. "Advanced materials and coatings for energy conversion systems." Energy Conversion and Management 38, no. 10-13 (July 1997): 1035–41. http://dx.doi.org/10.1016/s0196-8904(96)00133-1.

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48

Hishida, M., M. Fumizawa, Y. Inaba, M. Aritomi, S. Nomura, S. Kosaka, S. Yamada, and K. Ogata. "Nuclear energy conversion systems for arresting global warming." Energy Conversion and Management 38, no. 10-13 (July 1997): 1365–75. http://dx.doi.org/10.1016/s0196-8904(96)00166-5.

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49

Yuce, M. Ishak, and Abdullah Muratoglu. "Hydrokinetic energy conversion systems: A technology status review." Renewable and Sustainable Energy Reviews 43 (March 2015): 72–82. http://dx.doi.org/10.1016/j.rser.2014.10.037.

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Steele, B. C. H. "Materials for electrochemical energy conversion and storage systems." Ceramics International 19, no. 4 (1993): 269–77. http://dx.doi.org/10.1016/0272-8842(93)90059-z.

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