Thematische Bibliographien / Engineering, General|Energy / Zeitschriftenartikel

Zeitschriftenartikel zum Thema „Engineering, General|Energy“

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Autor: Grafiati
Veröffentlicht am 14. September 2021
Zuletzt aktualisiert am 2. Februar 2022

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1

TAKEDA, Kunihiko. „General Engineering Ethics and Multiple Stress of Atomic Energy Engineering.“ Journal of the Atomic Energy Society of Japan / Atomic Energy Society of Japan 41, Nr. 8 (1999): 875–80. http://dx.doi.org/10.3327/jaesj.41.875.

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2

Huang, Fu Chuan, Xing Zhong Tang und Man Rong Su. „The Development of Environment-Friendly and Energy-Saving Engineering Machinery General Oil“. Applied Mechanics and Materials 331 (Juli 2013): 321–25. http://dx.doi.org/10.4028/www.scientific.net/amm.331.321.

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This article combines with the engineering machinery of diesel engine, the hydraulic system, the gear system, the hydraulic transmission system using oil of performance requirements; in order to meet the need of engineering machinery actual using condition. Through the study of base oil, antioxidant and corrosion inhibitor, detergent and dispersant additive, extreme pressure and anti-wear agent, rust inhibitor, anti-emulsifier, anti-foam agent, etc composite additives. using Poly-α-olefin (PAO) and dioctyl sebacate composite act as the engineering machinery general oil of base oil, and by using the artificial neural network algorithm targeted to a variety of the functional additive of screening and prediction, and using the genetic algorithm optimists the selection of formula, develop the environment-friendly and energy-saving engineering machinery general oil.
3

Bezdenezhnukh, Tatiana, Andrey Kuritsyn und Irina Gimelshtein. „Energy efficiency in civil engineering: analyzing world experience“. MATEC Web of Conferences 212 (2018): 02009. http://dx.doi.org/10.1051/matecconf/201821202009.

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There are consistent trends in the development of energy-saving technologies in civil engineering in almost all countries of the world. The article considers the main approaches to ensuring energy efficiency in in civil engineering, analyzes the standards of energy-efficient construction in the world in general and in Russia in particular, and gives some recommendations on increasing energy efficiency in engineering.
4

Yu, Xiao Ping, und Xiao Feng Liao. „Study on the Multi-Target System of Building Energy Efficiency Engineering in China“. Advanced Materials Research 962-965 (Juni 2014): 1480–84. http://dx.doi.org/10.4028/www.scientific.net/amr.962-965.1480.

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From the systemic methodology for evaluating the multi-target system of Building Energy Efficient (BEE) engineering, this paper presents the social objectives, technical objectives, economic objectives, management and ecological objectives. BEE multi-target system evaluation is a comprehensive project appraisal. Based on the main body of generalization and conflict of the multi-target system, the BEE systems’ general objectives with engineering management, engineering technology, engineering economy, engineering social and ecological goals are analyzed, and BEE engineering system internal correlations properties are studied from time, space and energy dimension. Taking basic goals of BEE engineering as example, to evaluate the multi-target system is especially important to systemic analysis of the BEE engineering practice.
5

Cui, Zhanfeng, und Kyongbum Lee. „Biological engineering“. Current Opinion in Chemical Engineering 2, Nr. 1 (Februar 2013): 1–2. http://dx.doi.org/10.1016/j.coche.2013.01.006.

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6

Kiss, István Z. „Synchronization engineering“. Current Opinion in Chemical Engineering 21 (September 2018): 1–9. http://dx.doi.org/10.1016/j.coche.2018.02.006.

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7

Bashkatov, Yu L., und G. A. Shvetsov. „General energy relations for rail guns“. Journal of Applied Mechanics and Technical Physics 28, Nr. 2 (1987): 316–20. http://dx.doi.org/10.1007/bf00918741.

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8

Lapkin, Alexei A. „Editorial overview- Reaction engineering and Catalysis: Green chemical engineering“. Current Opinion in Chemical Engineering 26 (Dezember 2019): A3. http://dx.doi.org/10.1016/j.coche.2019.12.002.

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9

Bryukhovetsky, Kirill, und Ilya Livshitz. „An analysis of a General Data Protection Regulation impact on fuel and energy companies“. Energy Safety and Energy Economy 5 (November 2020): 55–63. http://dx.doi.org/10.18635/2071-2219-2020-5-55-63.

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General Data Protection Regulation has been adopted in 2018 and establishes privacy and security protection for data gathered on anyone in the European Union. Russian power engineering companies have to potentially comply with GDPR in regards of processing and storing customer data. This paper contains an analysis of certain GDPR requirements and their meaning for power engineering companies and their departments for the purpose of compliance risk assessment. The results can help make decisions on compliance risk assessment initiatives to diminish data protection risks for international businesses, including power engineering companies.
10

Chiu, Loraine LY, und Milica Radisic. „Cardiac tissue engineering“. Current Opinion in Chemical Engineering 2, Nr. 1 (Februar 2013): 41–52. http://dx.doi.org/10.1016/j.coche.2013.01.002.

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11

Andrews, Ross N., Carlos C. Co und Chia-Chi Ho. „Engineering dynamic biointerfaces“. Current Opinion in Chemical Engineering 11 (Februar 2016): 28–33. http://dx.doi.org/10.1016/j.coche.2015.11.005.

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12

Saijo, Takashige. „Trends in Energy Conservation Technologies of Electric Railways. General Survey of Energy-seving Measures.“ IEEJ Transactions on Industry Applications 117, Nr. 1 (1997): 1–3. http://dx.doi.org/10.1541/ieejias.117.1.

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13

Yasmin, Musarat, Farhat Naseem und Malik Hassan Raza. „Adapting to Engineering Education Vision 2020“. Proceedings 2, Nr. 21 (29.10.2018): 1365. http://dx.doi.org/10.3390/proceedings2211365.

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Interdisciplinary energy research has become inevitable in the context of perceived energy break-point after 2050. Power and energy crisis is a matter of life or death for industry and human race on earth. Oil and natural gas peaking alarms started ringing by the start of the 21st century. Available energy reserves are emptying at of thousands of barrels per second and time to discover new energy sources is being wasted to convince and advocate disciplinarians going for interdisciplinary research approach. We will have to invent new ways of supplying 30% of the global energy demand by 2030 and 60% by 2050. It is not possible without putting the emerging bio, nano, and info technologies together in power and energy research laboratories under interdisciplinary and trans-disciplinary approaches. Electrical engineers badly need the supportive hand of energy scientists and technologists to overcome global power, energy, food, and water crises. Engineers and scientists often find it difficult to tolerate each other and usually end up with duplicate resources without any presentable output which requires motivation to develop teamwork spirit to succeed. This paper unveils the potential urgency for an interdisciplinary research approach concerning embedded energy research barriers and solutions in developing countries. Enhancing power and energy multidisciplinary research is a vital general formula that can be tailored to specific regional conditions to minimize the greenhorn blues to run local and global interdisciplinary research programs.
14

MIZUMA, TAKESHI. „Energy conservation of railway vehicles. 1 General remarks.“ Journal of the Institute of Electrical Engineers of Japan 123, Nr. 7 (2003): 402–5. http://dx.doi.org/10.1541/ieejjournal.123.402.

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15

Felgueiras, Manuel C., João S. Rocha und Nídia Caetano. „Engineering education towards sustainability“. Energy Procedia 136 (Oktober 2017): 414–17. http://dx.doi.org/10.1016/j.egypro.2017.10.266.

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16

Gerecht, Sharon, und Konstantinos Konstantopoulos. „Editorial overview: Biological engineering: engineering systems for cancer modeling, diagnostics and therapeutics“. Current Opinion in Chemical Engineering 11 (Februar 2016): iv—v. http://dx.doi.org/10.1016/j.coche.2016.02.004.

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17

Grady, P. L., G. N. Mock, G. A. Pai und K. W. Throneburg. „A General Purpose Textile Plant Energy Consumption Model“. Textile Research Journal 59, Nr. 3 (März 1989): 177–82. http://dx.doi.org/10.1177/004051758905900307.

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18

Shen, M., J. Zhang und K. Scott. „The General Rule of Power Converted from Chemical Energy to Electrical Energy“. Fuel Cells 4, Nr. 4 (Dezember 2004): 388–93. http://dx.doi.org/10.1002/fuce.200400031.

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19

Hsieh, C. K., und Chang-Yong Choi. „A General Analysis of Phase-Change Energy Storage for Solar Energy Applications“. Journal of Solar Energy Engineering 114, Nr. 4 (01.11.1992): 203–11. http://dx.doi.org/10.1115/1.2930007.

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A unified approach is developed for the analysis of one, two, or three-phase melting or solidification of a semi-infinite medium with or without subcooling or superheating and imposed with constant, monotonic, or cyclic temperature or flux conditions. A source and sink method is presented in which a sink front is used to characterize a melt front while a source front is used to characterize a freeze front. An integrodifferential equation is then derived for the interface position which is linearized locally for numerical solution. This position is, in turn, used as input for the determination of the temperature distribution and energy storage and release in different phases of the medium. The numerical solution presented in this paper has shown to be unique, convergent, stable, and accurate. The analysis has been applied to the study of phase change in a subcooled paraffin wax imposed with a cyclic temperature condition. Test results yield some interesting phenomena related to the merging of phase-change fronts and hysteresis of energy storage and release, among others, which have not previously been reported in the literature. Their relations to the energy storage and release are particularly stressed in the paper.
20

de Pozo, Pablo Mulás, David Nieva Gómez und F. A. Holland. „Developments in geothermal energy in Mexico—Part one: General considerations“. Journal of Heat Recovery Systems 5, Nr. 4 (Januar 1985): 277–83. http://dx.doi.org/10.1016/0198-7593(85)90002-5.

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21

Koseki, Takafumi. „Technologies for Saving Energy in Railway Operation: General Discussion on Energy Issues Concerning Railway Technology“. IEEJ Transactions on Electrical and Electronic Engineering 5, Nr. 3 (Mai 2010): 285–90. http://dx.doi.org/10.1002/tee.20531.

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22

Angenent, Largus T. „Energy biotechnology: beyond the general lignocellulose-to-ethanol pathway“. Current Opinion in Biotechnology 18, Nr. 3 (Juni 2007): 191–92. http://dx.doi.org/10.1016/j.copbio.2007.05.003.

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23

Tien, Joe. „Microfluidic approaches for engineering vasculature“. Current Opinion in Chemical Engineering 3 (Februar 2014): 36–41. http://dx.doi.org/10.1016/j.coche.2013.10.006.

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24

Qian Wang und Dian-Wu Yue. „A General Parameterization Quantifying Performance in Energy Detection“. IEEE Signal Processing Letters 16, Nr. 8 (August 2009): 699–702. http://dx.doi.org/10.1109/lsp.2009.2022196.

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25

Yang, Min Xia, Da Xie, Yu Jian Jia, Jun Qi Feng, Yu Cheng Lou und Yu Zhang. „Periodic Control of General Energy Flowing in Charging-Discharging-Storage Integrated Station“. Advanced Materials Research 860-863 (Dezember 2013): 1110–19. http://dx.doi.org/10.4028/www.scientific.net/amr.860-863.1110.

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A novel scheme of charging-discharging-storage integrated station is put forward. In order to control energy/power flowing in the integrated station effectively, a new definition of general energy is fully discussed and its periodic characteristic is analyzed. General energy includes three parts: general energy of battery supply system, general energy of battery echelon utilization system and general energy of EVs, all of which is almost periodic. After analyzing steady operation curves of the three parts of general energy, their interrelation is discussed. On this basis, a periodic control strategy for general energy is proposed. Taking typical bus operation in Shanghai as a case, general energy curves of battery systems and EVs are described and analyzed under periodic control strategy, which obviously shows that the integrated station can maintain stable and economic operation by periodic control of general energy flowing in the integrated station.
26

Yiming Liu, Geng Tian, Yong Wang, Junhong Lin, Qiming Zhang und Heath F. Hofmann. „Active Piezoelectric Energy Harvesting: General Principle and Experimental Demonstration“. Journal of Intelligent Material Systems and Structures 20, Nr. 5 (28.11.2008): 575–85. http://dx.doi.org/10.1177/1045389x08098195.

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In piezoelectric energy harvesting systems, the energy harvesting circuit is the interface between a piezoelectric device and an electrical load. A conventional view of this interface is based on impedance matching concepts. In fact, an energy harvesting circuit can also apply electrical boundary conditions, such as voltage and charge, to the piezoelectric device for each energy conversion cycle. An optimized electrical boundary condition can therefore increase the mechanical energy flow into the device and the energy conversion efficiency of the device. We present a study of active energy harvesting, a type of energy harvesting approach which uses switch-mode power electronics to control the voltage and/or charge on a piezoelectric device relative to the mechanical input for optimized energy conversion. Under quasi-static assumptions, a model based on the electromechanical boundary conditions is established. Some practical limiting factors of active energy harvesting, due to device limitations and the efficiency of the power electronic circuitry, are discussed. In the experimental part of the article, active energy harvesting is demonstrated with a multilayer PVDF polymer device. In these experiments, the active energy harvesting approach increased the harvested energy by a factor of five for the same mechanical displacement compared to an optimized diode rectifier-based circuit.
27

Guerra, J. A., L. M. Montañez, K. Tucto, J. Angulo, J. A. Töfflinger, A. Winnaker und R. Weingärtner. „Bandgap Engineering of Amorphous Hydrogenated Silicon Carbide“. MRS Advances 1, Nr. 43 (2016): 2929–34. http://dx.doi.org/10.1557/adv.2016.422.

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ABSTRACTA simple model to describe the fundamental absorption of amorphous hydrogenated silicon carbide thin films based on band fluctuations is presented. It provides a general equation describing both the Urbach and Tauc regions in the absorption spectrum. In principle, our model is applicable to any amorphous material and it allows the determination of the bandgap. Here we focus on the bandgap engineering of amorphous hydrogenated silicon carbide layers. Emphasis is given on the role of hydrogen dilution during the deposition process and post deposition annealing treatments. Using the conventional Urbach and Tauc equations, it was found that an increase/decrease of the Urbach energy produces a shrink/enhancement of the Tauc-gap. On the contrary, the here proposed model provides a bandgap energy which behaves independently of the Urbach energy.
28

Tenti, Paolo, und Tommaso Caldognetto. „A General Approach to Select Location and Ratings of Energy Storage Systems in Local Area Energy Networks“. IEEE Transactions on Industry Applications 55, Nr. 6 (November 2019): 6203–10. http://dx.doi.org/10.1109/tia.2019.2932679.

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29

Yagi, Toshiharu. „Trial Calculation of Energy Saving on General Lighting(Residential Lighting Aiming at Energy Saving and Amenity)“. JOURNAL OF THE ILLUMINATING ENGINEERING INSTITUTE OF JAPAN 94, Nr. 10 (01.10.2010): 687–92. http://dx.doi.org/10.2150/jieij.94.687.

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30

Nasedkin, A. V. „General theorems on energy transport by homogeneous waves“. Journal of Applied Mathematics and Mechanics 57, Nr. 5 (Januar 1993): 861–69. http://dx.doi.org/10.1016/0021-8928(93)90152-c.

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31

Durrans, Bryn, Jonathan Whale und Martina Calais. „Benchmarking a Sustainable Energy Engineering Undergraduate Degree against Curriculum Frameworks and Pedagogy Standards from Industry and Academia“. Energies 13, Nr. 4 (13.02.2020): 822. http://dx.doi.org/10.3390/en13040822.

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There is an urgent need for educational institutions to produce graduates with appropriate skills to meet the growing global demand for professionals in the sustainable energy industry. For universities to stay at the forefront of meeting this global demand from industry, universities need to ensure their curricula and pedagogies stay relevant. The use of benchmarking is a key means of achieving this and ensuring any gap between university curricula and the practical needs of industry is minimized. The aim of this paper is to present an approach to benchmarking a sustainable energy engineering undergraduate degree with respect to curriculum frameworks recommended by industry and pedagogy standards required and recommended by academia and education research. The method uses the Murdoch University renewable energy engineering degree major as a case study. The results show that the learning outcomes of the renewable energy engineering units, in general, align well with the recommended learning outcomes for a complete sustainable energy degree, as prescribed by the Australian Government Office for Learning and Teaching. In addition, assessment task and marking criteria for the capstone unit of the major were at Australian Universities’ standard. A similar approach to benchmarking can be adopted by developers of new or existing sustainable energy engineering degrees in order to align with curriculum frameworks and pedagogy standards required by industry and academic peers.
32

Koshevyi, Oleksandr, Dmytro Levkivskyi, Victoria Kosheva und Andrii Mozharovskyi. „Сomputer modeling and optimization of energy efficiency potentials in civil engineering“. Strength of Materials and Theory of Structures, Nr. 106 (24.05.2021): 274–81. http://dx.doi.org/10.32347/2410-2547.2021.106.274-281.

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The paper presents the results of creating a software package for optimizing the calculation of potentials of alternative energy sources in the regions of Ukraine based on BIM technologies (AutoCAD, ArchiCAD, Revit), which are combined using the IFC format. The software package uses mathematical and graph-analytical models of climate and energy zoning in the regions of Ukraine, and with the help of MS Excel visualizes the research process and automates, accelerates optimal decision in design, reconstruction and construction. The process of forming a database for traditional energy sources (electricity, oil products, natural gas, coal, firewood) and a database of energy potentials of alternative energy sources (solar energy, wind energy, geothermal energy, hydropower of small rivers, potentials of livestock and crop biomass potential of excess pressure of natural gas, potentials of heat of soil, ground and sewage, potentials of energy of peat and forest waste) for all regions of Ukraine. The structure of the software package and a block diagram has been developed, all indicators are reduced to a single unit of measurement (MW*h / year per 1000 people). To analyze and make optimal decisions, informative-illustrative bar and sector pie charts are built in MS Excel on five main areas of energy consumption, taking into account alternative energy sources for each region of Ukraine. The general analysis of energy consumption and optimization calculations are carried out with the help of informative-illustrative diagram SANKEY, which is created with the help of "SankeyDiagramGenerator", and visualizes the whole process of graph-analytical modeling of energy consumption in Ukraine.
33

Stanton, Robert V., Steven L. Dixon und Kenneth M. Merz. „General Formulation for a Quantum Free Energy Perturbation Study“. Journal of Physical Chemistry 99, Nr. 27 (Juli 1995): 10701–4. http://dx.doi.org/10.1021/j100027a004.

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34

Soares, Isabel, Paula Ferreira und Henrik Lund. „Energy transition: The economics & engineering nexus“. Energy 166 (Januar 2019): 961–62. http://dx.doi.org/10.1016/j.energy.2018.10.021.

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35

Boon-Kong, TAN. „Engineering Geology of Limestone in Malaysia“. Acta Geologica Sinica - English Edition 75, Nr. 3 (07.09.2010): 316–24. http://dx.doi.org/10.1111/j.1755-6724.2001.tb00538.x.

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36

Hunter, K. C., und C. Balnaves. „DEVELOPMENT AND ENGINEERING HIGHLIGHTS OF 1995“. APPEA Journal 36, Nr. 2 (1996): 95. http://dx.doi.org/10.1071/aj95068.

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37

Caetano, Nídia S., Rafael R. Carvalho, Francisco R. Franco, Carlos A. R. Afonso und Carlos Felgueiras. „Sustainable engineering labs - A Portuguese perspective“. Energy Procedia 153 (Oktober 2018): 455–60. http://dx.doi.org/10.1016/j.egypro.2018.10.077.

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38

Blackstock, Daniel, Miso Park, Qing Sun, Shen-Long Tsai und Wilfred Chen. „Engineering protein modules for diagnostic applications“. Current Opinion in Chemical Engineering 2, Nr. 4 (November 2013): 416–24. http://dx.doi.org/10.1016/j.coche.2013.08.001.

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39

Papoutsakis, Eleftherios Terry, und Nigel Titchener-Hooker. „Editorial overview: Biotechnology and bioprocess engineering“. Current Opinion in Chemical Engineering 14 (November 2016): iv—v. http://dx.doi.org/10.1016/j.coche.2016.10.002.

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40

Titchener-Hooker, Nigel. „Editorial overview: Biotechnology and bioprocess engineering“. Current Opinion in Chemical Engineering 18 (November 2017): i—ii. http://dx.doi.org/10.1016/j.coche.2017.11.004.

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41

Boris, Khusid. „Editorial overview: Microfluidics in chemical engineering“. Current Opinion in Chemical Engineering 29 (September 2020): A3—A4. http://dx.doi.org/10.1016/j.coche.2020.06.002.

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42

Ramkrishna, Doraiswami, und Jamey D. Young. „Editorial overview: Biotechnology and bioprocess engineering“. Current Opinion in Chemical Engineering 32 (Juni 2021): 100686. http://dx.doi.org/10.1016/j.coche.2021.100686.

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43

Höller, Raphael, Valerie Smejkal, Florian Libisch und Christian Hellmich. „Energy landscapes of graphene under general deformations: DFT-to-hyperelasticity upscaling“. International Journal of Engineering Science 154 (September 2020): 103342. http://dx.doi.org/10.1016/j.ijengsci.2020.103342.

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44

Zhao, Yuehao, Ke Peng, Bingyin Xu, Yuquan Liu, Wen Xiong und Yu Han. „Applied engineering programs of energy blockchain in US“. Energy Procedia 158 (Februar 2019): 2787–93. http://dx.doi.org/10.1016/j.egypro.2019.02.039.

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45

Langley, R. S. „A general mass law for broadband energy harvesting“. Journal of Sound and Vibration 333, Nr. 3 (Februar 2014): 927–36. http://dx.doi.org/10.1016/j.jsv.2013.09.036.

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46

Götze, Jens, Jonte Dancker und Martin Wolter. „A general MILP based optimization framework to design Energy Hubs“. at - Automatisierungstechnik 67, Nr. 11 (26.11.2019): 958–71. http://dx.doi.org/10.1515/auto-2019-0059.

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Abstract To optimally design integrated energy systems a widely used approach is the Energy Hub. The conversion, storage and transfer of different energy vectors is represented by a coupling matrix. Yet, the coupling matrix restricts the configuration of the Energy Hub and the constraints, that can be included. This paper proposes a MILP based optimization framework, which allows a high variability and adaptability and is based on energy flows. The functionality of the developed framework is tested on four use cases depicting different system sizes and Energy Hub configurations. It is shown that the framework is able to simplify the design process of an Energy Hub.
47

Gu, Shuang, Bingjun Xu und Yushan Yan. „Electrochemical Energy Engineering: A New Frontier of Chemical Engineering Innovation“. Annual Review of Chemical and Biomolecular Engineering 5, Nr. 1 (07.06.2014): 429–54. http://dx.doi.org/10.1146/annurev-chembioeng-060713-040114.

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48

Foppa-Pedretti, Ester, Giovanni Riva, Giuseppe Toscano und Daniele Duca. „CONSIDERATIONS ON RENEWABLE ENERGY SOURCES AND THEIR RELATED PERSPECTIVES OFAGRICULTURAL ENGINEERING“. Journal of Agricultural Engineering 41, Nr. 2 (30.06.2010): 35. http://dx.doi.org/10.4081/jae.2010.2.35.

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This paper discusses some considerations and advances a number of proposals about the potential of Agricultural Engineering to contribute to the field of renewable energy, with an emphasis on biomass. Several areas for action are identified. First, general education and teaching of students who will go on to become technicians and professionals in the sector of renewable energies, even though the characteristics of the sectors are still fuzzy. Diffusion of the energy culture, a too often neglected aspect that is however indispensable to sustain the overdue penetration of renewable energies in Italy, is an additional area for action. Another critical area, energy planning, is currently viewed mainly as involving the assessment on more or less wide areas of energy consumption and for the scope of replacing fossil resources with renewables to meet some energy requirements. A more complex, overarching issue is energy efficiency, especially of buildings, which should be a mainstay of the planning process but is in fact not so clearly addressed in development plans for renewables. At this same level, all interactions among production sectors should be assessed, to enhance the role of agriculture, one of the new potential energy-producing sectors and one of the possible prospective suppliers of renewable energy for different final users, from households to the service sector and industry. Agricultural Engineering has the skills needed to implement all these different actions. A role for it in advanced research, i.e. biotechnologies, can and should also be envisaged. Its work in the renewable energy sector should closely involve microbiological, genetic, chemical, agronomic, and animal research to define the goals to be pursued and to implement intuitions. In this way, Agricultural Engineering would increasingly be characterized as Biosystems Engineering.
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Carini, A., und O. De Donato. „A Comprehensive Energy Formulation for General Nonlinear Material Continua“. Journal of Applied Mechanics 64, Nr. 2 (01.06.1997): 353–60. http://dx.doi.org/10.1115/1.2787314.

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By specialization to the continuum problem of a general formulation of the initial/boundary value problem for every nonpotential operator (Tonti, 1984) and by virtue of a suitable choice of the “integrating operator,” a comprehensive energy formulation is established. Referring to the small strain and displacement case in the presence of any inelastic generally nonlinear constitutive law, provided that it is differentiable, this formulation allows us to derive extensions of well-known principles of elasticity (Hu-Washizu, Hellinger-Reissner, total potential energy, and complementary energy). An illustrative example is given. Peculiar properties of the formulation are the energy characterization of the functional and the use of Green functions of the same problem in the elastic range for every inelastic, generally nonlinear material considered.
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McCartney, L. N. „Energy-based prediction of failure in general symmetric laminates“. Engineering Fracture Mechanics 72, Nr. 6 (April 2005): 909–30. http://dx.doi.org/10.1016/j.engfracmech.2004.09.003.

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