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Journal articles on the topic 'Energy cycle'

Author: Grafiati
Published: 4 June 2021
Last updated: 4 February 2022

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1

Han, Sung Bin, and Sung Il Hwang. "Experimental Study on the Cycle-to-Cycle Combustion Variations in a Spark Ignition Engine." Journal of Energy Engineering 22, no. 2 (June 30, 2013): 197–204. http://dx.doi.org/10.5855/energy.2013.22.2.197.

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2

Han, Sung Bin, and Sung Il Hwang. "Cycle-to-Cycle Fluctuations in a Spark Ignition Engine at Low Speed and Load." Journal of Energy Engineering 22, no. 2 (June 30, 2013): 205–10. http://dx.doi.org/10.5855/energy.2013.22.2.205.

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3

Noh, Taewan. "Technical Review on Thorium Breeding Cycle." Journal of Energy Engineering 25, no. 2 (June 30, 2016): 52–64. http://dx.doi.org/10.5855/energy.2016.25.2.052.

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4

Gotovsky, M., A. Gotovsky, V. Mikhailov, V. Lychakov, Y. Sukhorukov, and E. Sukhorukova. "Formate Cycle: The Third Way in Green Energy." International Journal of Chemical Engineering and Applications 10, no. 6 (December 2019): 189–94. http://dx.doi.org/10.18178/ijcea.2019.10.6.767.

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5

Shiwhae, Vichar. "Energy-Mass Cycle." International Journal of Scientific & Engineering Research 9, no. 6 (June 25, 2018): 1024–32. http://dx.doi.org/10.14299/ijser.2018.06.09.

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6

Eremeev, Igor P. "Electrophotonuclear energy cycle." Physics-Uspekhi 47, no. 12 (December 31, 2004): 1221–37. http://dx.doi.org/10.1070/pu2004v047n12abeh001941.

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7

Eremeev, Igor P. "Electrophotonuclear energy cycle." Uspekhi Fizicheskih Nauk 174, no. 12 (2004): 1319. http://dx.doi.org/10.3367/ufnr.0174.200412c.1319.

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8

Dixit, Manoj, S. C. Kaushik, and Akhilesh Arora. "Energy and Exergy Analysis of Solar Triple Effect Refrigeration Cycle." Journal of Clean Energy Technologies 5, no. 3 (May 2017): 222–27. http://dx.doi.org/10.18178/jocet.2017.5.3.373.

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9

Shin, Dong Gil. "Experimental Research on an Organic Rankine Cycle Using Engine Exhaust Gas." Journal of Energy Engineering 21, no. 4 (December 31, 2012): 393–97. http://dx.doi.org/10.5855/energy.2012.21.4.393.

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10

Cristina Zaro, Geovanna, Paulo Henrique Caramori, Cíntia Sorane Good Kitzberger, Fernanda Aparecida Sales, Sergio Luiz Colucci de Carvalho, and Cássio Egidio Cavenaghi Prete. "Phenological cycle and physicochemical characteristics of avocado cultivars in subtropical conditions." AIMS Energy 5, no. 3 (2017): 517–28. http://dx.doi.org/10.3934/energy.2017.3.517.

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11

Hung, T. C. "Triple Cycle: A Conceptual Arrangement of Multiple Cycle Toward Optimal Energy Conversion." Journal of Engineering for Gas Turbines and Power 124, no. 2 (March 26, 2002): 429–36. http://dx.doi.org/10.1115/1.1423639.

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The purpose of this study is to find a maximum work output from various combinations of thermodynamic cycles from a viewpoint of the cycle systems. Three systems were discussed in this study: a fundamental combined cycle and two other cycles evolved from the fundamental dual combined cycle: series-type and parallel-type triple cycles. In each system, parametric studies were carried out in order to find optimal configurations of the cycle combinations based on the influences of tested parameters on the systems. The study shows that the series-type triple cycle exhibits no significant difference as compared with the combined cycle. On the other hand, the efficiency of the parallel-type triple cycle can be raised, especially in the application of recovering low-enthalpy-content waste heat. Therefore, by properly combining with a steam Rankine cycle, the organic Rankine cycle is expected to efficiently utilize residual yet available energy to an optimal extent. The present study has pointed out a conceptual design in multiple-cycle energy conversion systems.
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12

Shin, Dong Gil. "Analysis of Efficiencies of Scroll Expander for Micro Scale Organic Rankine cycle." Journal of Energy Engineering 21, no. 4 (December 31, 2012): 398–401. http://dx.doi.org/10.5855/energy.2012.21.4.398.

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13

Kim, Young Min, Dong Gil Shin, Chang Gi Kim, Se Jong Woo, and Byung Chul Choi. "Performance Analysis of Two-Loop Rankine Cycle for Engine Waste Heat Recovery." Journal of Energy Engineering 21, no. 4 (December 31, 2012): 402–10. http://dx.doi.org/10.5855/energy.2012.21.4.402.

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14

Shin, Dong Gil, and Young Min Kim. "Experimental Study of Vane Expander Prototype Applied to Micro Organic Rankine Cycle." Journal of Energy Engineering 23, no. 4 (December 31, 2014): 230–35. http://dx.doi.org/10.5855/energy.2014.23.4.230.

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15

Kim, Jeongbae, Kyu-Sun Lee, and Geunan Lee. "An Experimental Study on Performance of Vapor Compression Refrigeration Cycle with Al2O3nano-particle." Journal of Energy Engineering 24, no. 4 (December 31, 2015): 124–29. http://dx.doi.org/10.5855/energy.2015.24.4.124.

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16

Longo, Sonia, Maurizio Cellura, Francesco Guarino, Vincenzo La Rocca, Giuseppe Maniscalco, and Massimo Morale. "Embodied energy and environmental impacts of a biomass boiler: a life cycle approach." AIMS Energy 3, no. 2 (2015): 214–26. http://dx.doi.org/10.3934/energy.2015.2.214.

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17

Tadele, Debela, Poritosh Roy, Fantahun Defersha, Manjusri Misra, and Amar K. Mohanty. "Life Cycle Assessment of renewable filler material (biochar) produced from perennial grass (Miscanthus)." AIMS Energy 7, no. 4 (2019): 430–40. http://dx.doi.org/10.3934/energy.2019.4.430.

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18

Shmeleva, Elizaveta A., and Ivan A. Arkharov. "Selection of the optimal air liquefaction cycle for liquid air energy storage." MATEC Web of Conferences 324 (2020): 01007. http://dx.doi.org/10.1051/matecconf/202032401007.

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The report analyzes and selects the liquefaction cycle for Liquid Air Energy Storage. The specific liquefaction coefficient and the coefficient of thermodynamic perfection were calculated for the following cycles: the Linde-Hampson cycle, the Claude cycle, the Heylandt Cycle, the Collins cycle, and the cycle with two expanders. The criterion for optimizing cycles is the maximum value of the liquefaction coefficient. The Claude cycle was chosen as the optimal cycle for use in the Liquid Air Energy Storage. Its exergy efficiency was calculated.
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19

Palani, K., M. LalithaKumari, and L. Pandiselvi. "Total Energy of Cycle and Some Cycle Related Graphs." Journal of Physics: Conference Series 1947, no. 1 (June 1, 2021): 012007. http://dx.doi.org/10.1088/1742-6596/1947/1/012007.

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20

Stramigioli, Stefano, and Michel van Dijk. "Energy Conservative Limit Cycle Oscillations." IFAC Proceedings Volumes 41, no. 2 (2008): 15666–71. http://dx.doi.org/10.3182/20080706-5-kr-1001.02649.

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21

Trancik, Jessika E. "Clean energy enters virtuous cycle." Nature 528, no. 7582 (December 2015): 333. http://dx.doi.org/10.1038/528333d.

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22

Ohi, Jim. "Hydrogen energy cycle: An overview." Journal of Materials Research 20, no. 12 (December 1, 2005): 3180–87. http://dx.doi.org/10.1557/jmr.2005.0408.

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This overview will describe briefly key segments of the hydrogen energy cycle from production using various feedstocks to its end use in fuel cells to generate electrical and thermal energy. The paper will also discuss the larger societal context, the so-called “hydrogen economy,” in which such production and use of hydrogen may take place. Although most of the public attention on hydrogen has been focused on its potential as an alternative energy source to petroleum and other fossil fuels, a hydrogen economy will encompass much more than a substitution of one energy source by another. Widespread use of hydrogen as an energy carrier can transform our society in much the same way that personal computing technologies have. This transforming power arises from the unique capability of hydrogen to link renewable energy resources and zero-emission energy conversion technologies. Hydrogen can be produced from locally available renewable resources, such as solar, wind, biomass, and water, and converted to electricity or fuel at or near the point of use with only heat and water vapor as “emissions.” Hydrogen also lies at the confluence of two emerging trends that will shape our energy future during the first quarter of this century: greater reliance on renewable energy sources and the shift from large, centralized power plants to smaller, decentralized facilities located at or near the point of use. This paper describes these emerging trends and the role of hydrogen in linking them in a way that could transform our society.
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23

Shin, Dong Gil. "Analysis of Performance of Organic Rankine Cycle for Inlet Condition of Displacement Type Expander." Journal of Energy Engineering 26, no. 1 (March 31, 2017): 23–27. http://dx.doi.org/10.5855/energy.2017.26.1.023.

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24

Al Badwawi, Rashid, Mohammad Abusara, and Tapas Mallick. "Speed control of synchronous machine by changing duty cycle of DC/DC buck converter." AIMS Energy 3, no. 4 (2015): 728–39. http://dx.doi.org/10.3934/energy.2015.4.728.

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25

Yang, Xiuwen, and Ligong Wang. "Ordering of bicyclic signed digraphs by energy." Filomat 34, no. 13 (2020): 4297–309. http://dx.doi.org/10.2298/fil2013297y.

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Let Sn be the class of bicyclic signed digraphs with n vertices whose two signed directed even cycles are vertex-disjoint. In this paper, we characterize the ordering of bicyclic signed digraphs in Sn by energy with two positive or negative directed even cycles (resp., one positive directed even cycle and one negative directed even cycle). Furthermore, we determine extremal energy in Sn by the two orderings.
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26

Ayisi, Emmanuel Nyarko, and Karel Fraňa. "The Design and Test for Degradation of Energy Density of a Silica Gel-Based Energy Storage System Using Low Grade Heat for Desorption Phase." Energies 13, no. 17 (September 1, 2020): 4513. http://dx.doi.org/10.3390/en13174513.

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This paper presents the design and a short cycle repeatability test of a silica gel-based thermal energy storage system using low grade heat for the desorption phase. The system was designed to test the degradation in the energy storage density of the adsorbent material for a 2 h working period in a short number of cycles (5 cycles). Low grade heat of 70 °C is used for regeneration during the desorption phase in each cycle. It was found that a reduction of 1.6 W/kg per each cycle of energy storage was observed, up to 5 cycles. The maximal heat storage density was 292 kJ/kg at the first cycle and reduced to 225 kJ/kg at the fifth cycle. Furthermore, the total amount of water vapor adsorbed in the silica gel was observed as well. The test of energy storage was performed under a short time period (maximal approx. 165 min).
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27

Collares, Fabrício Mezzomo, Carmen Beatriz Borges Fortes, Vicente Castelo Branco Leitune, Stefani Becker Rodrigues, Susana Maria Werner Samuel, César Petzhold, and Vater Stefani. "Influence of polymerization cycle in properties of acrylic resin polymerized by microwave energy." Revista Odonto Ciência 31, no. 3 (December 31, 2016): 105. http://dx.doi.org/10.15448/1980-6523.2016.3.21693.

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Objective: The purpose of this study was to evaluate the physicochemical properties of acrylic resin polymerized by microwave energy in short cycle of polymerization.Methods: Two brands (Classico and VIPI) and two cycles were evaluated (manufacturer cycle and short cycle). The characteristics and properties as degree of conversion, glass transition temperature, impact strength-Izod, Knoop hardness, swelling degree, soluble fraction, specific mass, water sorption and solubility were evaluated.Results: Glass transition temperature, hardness, specific mass, soluble fraction and solubility were statistically significant between cycles and brands (p<0.05). Water sorption showed no difference between cycles (p>0.05) and impact strength presented difference between brands in short cycle (p<0.05). Acrylic resin polymerized by microwave energy with manufacturer cycle presented no difference in physicochemical properties between evaluated brands. Conclusion: The short cycle of polymerization showed reduced properties in microwave acrylic resin when compared to manufacturer cycle. Manufacturer cycle of polymerization should be used to acrylic resin devices production.
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28

She, Chen, Rui Jia, Bei-Ning Hu, Ze-Kun Zheng, Yi-Peng Xu, and Dragan Rodriguez. "Life cycle cost and life cycle energy in zero-energy building by multi-objective optimization." Energy Reports 7 (November 2021): 5612–26. http://dx.doi.org/10.1016/j.egyr.2021.08.198.

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29

Hu, Jianjun, Zhihua Hu, Xiyuan Niu, and Qin Bai. "Research on energy management strategy considering battery life for plug-in hybrid electric vehicle." Advances in Mechanical Engineering 10, no. 9 (September 2018): 168781401879776. http://dx.doi.org/10.1177/1687814018797766.

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To improve the fuel efficiency and battery life-span of plug-in hybrid electric vehicle, the energy management strategy considering battery life decay is proposed. This strategy is optimized by genetic algorithm, aiming to reduce the fuel consumption and battery life decay of plug-in hybrid electric vehicle. Besides, to acquire better drive-cycle adaptability, driving patterns are recognized with probabilistic neural network. The standard driving cycles are divided into urban congestion cycle, highway cycle, and urban suburban cycle; the optimized energy management strategies in three representative driving cycles are established; meanwhile, a comprehensive test driving cycle is constructed to verify the proposed strategies. The results show that adopting the optimized control strategies, fuel consumption, and battery’s life decay drop by 1.9% and 3.2%, respectively. While using the drive-cycle recognition, the features of different driving cycles can be identified, and based on it, the vehicle can choose appropriate control strategy in different driving conditions. In the comprehensive test driving cycle, after recognizing driving cycles, fuel consumption and battery’s life decay drop by 8.6% and 0.3%, respectively.
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30

Meyers, Jonathan, and Michael Sevener. "Hydrologic Cycle Energy Flux and the Water-Energy Nexus." Proceedings of the Water Environment Federation 2009, no. 15 (January 1, 2009): 2046–50. http://dx.doi.org/10.2175/193864709793954510.

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31

Himpe, Eline, Leen Trappers, Wim Debacker, Marc Delghust, Jelle Laverge, Arnold Janssens, Jan Moens, and Marlies Van Holm. "Life cycle energy analysis of a zero-energy house." Building Research & Information 41, no. 4 (August 2013): 435–49. http://dx.doi.org/10.1080/09613218.2013.777329.

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32

Park, Sung-Hwan, Min-Hyug Park, and Jung-Gu Park. "A Study on The Virtuous Cycle of The Value Chain and Value System in Korean Photovoltaic Industry." Journal of Energy Engineering 23, no. 1 (March 31, 2014): 21–32. http://dx.doi.org/10.5855/energy.2014.23.1.021.

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33

Lim, Seul-Ye, Hyo-Yeon Choi, and Seung-Hoon Yoo. "Measurement of the Benefits from Safeguarding Energy Security through Building the Integrated Gasification Combined Cycle Power Plant." Journal of Energy Engineering 24, no. 3 (September 30, 2015): 40–47. http://dx.doi.org/10.5855/energy.2015.24.3.040.

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34

Andersen, Otto, Geoffrey Gilpin, and Anders S.G. Andrae. "Cradle-to-gate life cycle assessment of the dry etching step in the manufacturing of photovoltaic cells." AIMS Energy 2, no. 4 (2014): 410–23. http://dx.doi.org/10.3934/energy.2014.4.410.

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35

Liu, Yu, Kunqi Ma, Hanzhengnan Yu, Jingyuan Li, and Xiaopan An. "Influence of Test Cycles on Energy Consumption Test of Electric Vehicles." E3S Web of Conferences 241 (2021): 02004. http://dx.doi.org/10.1051/e3sconf/202124102004.

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In order to verify the necessity of the application of China Automotive Test Cycle which is constructed through actual driving data in china of more than 55 million kilometers in the energy consumption test of electric vehicles in China, this paper compares the characteristics of New European Test Cycle (NEDC), World-wide harmonized Light duty Test Cycle (WLTC) and China light-duty vehicle test cycle for passenger car(CLTC-P), and analyzes the differences of vehicle energy demand under different test cycles from theoretical and simulation point, simulation results show that the endurance mileage is longest and the energy recovery strategy is more effective under CLTC-P cycle. Finally, four types of vehicles are selected to carry out the endurance mileage test under these three test cycles. The test results are consistent with the simulation results. Therefore, in order to make the test results of electric vehicle energy consumption closer to the actual use of our country, CLTC-P should be selected to replace NEDC and WLTC cycle.
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36

YABE, Takashi, and Shigeaki UCHIDA. "Laser Propulsion and New Energy Cycle." Review of Laser Engineering 34, no. 6 (2006): 408–13. http://dx.doi.org/10.2184/lsj.34.408.

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37

Jermyn, Adam S., Shashikumar M. Chitre, and Christopher A. Tout. "Energy Budget of the Solar Cycle." Research Notes of the AAS 3, no. 9 (September 3, 2019): 124. http://dx.doi.org/10.3847/2515-5172/ab3fae.

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38

Wilson, Michael. "Embodied Energy in the Water Cycle." Proceedings of the Water Environment Federation 2009, no. 10 (January 1, 2009): 5515–28. http://dx.doi.org/10.2175/193864709793952729.

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39

Kucher, Oleg, and Alexander Kurov. "Business cycle, storage, and energy prices." Review of Financial Economics 23, no. 4 (November 2014): 217–26. http://dx.doi.org/10.1016/j.rfe.2014.09.001.

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40

Wang, Haochuan, Ayman Alismail, Gaia Barbiero, Raja Naeem Ahmad, and Hanieh Fattahi. "High Energy, Sub-Cycle, Field Synthesizers." IEEE Journal of Selected Topics in Quantum Electronics 25, no. 4 (July 2019): 1–12. http://dx.doi.org/10.1109/jstqe.2019.2924151.

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41

Mueller, K. G., A. W. Court, and C. B. Besant. "Energy life cycle design: A method." Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture 213, no. 4 (April 1999): 415–19. http://dx.doi.org/10.1243/0954405991516877.

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42

HATANO, Hiroyuki. "Efficient Energy Utilization by Chemical Cycle." Journal of the Society of Mechanical Engineers 105, no. 1006 (2002): 596–97. http://dx.doi.org/10.1299/jsmemag.105.1006_596.

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43

Gutman, Ivan. "Cycle energy and its size dependence." Discrete Applied Mathematics 284 (September 2020): 534–37. http://dx.doi.org/10.1016/j.dam.2020.04.015.

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44

Boer, G. J., and S. Lambert. "The energy cycle in atmospheric models." Climate Dynamics 30, no. 4 (October 26, 2007): 371–90. http://dx.doi.org/10.1007/s00382-007-0303-4.

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45

Johnson, William G., Sheila A. Corrigan, Christian R. Lemmon, Kimberly B. Bergeron, and April H. Crusco. "Energy regulation over the menstrual cycle." Physiology & Behavior 56, no. 3 (September 1994): 523–27. http://dx.doi.org/10.1016/0031-9384(94)90296-8.

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46

McKinley, Ian M., Felix Y. Lee, and Laurent Pilon. "A novel thermomechanical energy conversion cycle." Applied Energy 126 (August 2014): 78–89. http://dx.doi.org/10.1016/j.apenergy.2014.03.069.

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47

Pelino, Vinicio, Filippo Maimone, and Antonello Pasini. "Energy cycle for the Lorenz attractor." Chaos, Solitons & Fractals 64 (July 2014): 67–77. http://dx.doi.org/10.1016/j.chaos.2013.09.005.

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48

Wakeel, Muhammad, and Bin Chen. "Energy Consumption in Urban Water Cycle." Energy Procedia 104 (December 2016): 123–28. http://dx.doi.org/10.1016/j.egypro.2016.12.022.

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49

Cho, Sung Ju, and Chang Joo Hah. "Determination of Optimum Batch Size and Fuel Enrichment for OPR1000 NPP Based on Nuclear Fuel Cycle Cost Analysis." Journal of Energy Engineering 23, no. 4 (December 31, 2014): 256–62. http://dx.doi.org/10.5855/energy.2014.23.4.256.

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50

Yang, Hac Jin, Seong Kun Kim, and Kwang Hee Choi. "A Study of the Feature Classification and the Predictive Model of Main Feed-Water Flow for Turbine Cycle." Journal of Energy Engineering 23, no. 4 (December 31, 2014): 263–71. http://dx.doi.org/10.5855/energy.2014.23.4.263.

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