Details
Models of Thermochemical Heat Storage
SpringerBriefs in Energy
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CHF 59.00 |
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| Verlag: | Springer |
| Format: | |
| Veröffentl.: | 23.01.2018 |
| ISBN/EAN: | 9783319715230 |
| Sprache: | englisch |
Dieses eBook enthält ein Wasserzeichen.
Beschreibungen
Thermochemical gas-solid reactions, as well as adsorption processes, are currently of significant interest for the design of heat storage systems. This book provides detailed models of these reactions and processes that account for heat and mass transport, chemical and physical reactions, and possible local thermal non-equilibrium. The underlying scientific theory behind the models is explained, laboratory tests are simulated, and methods for high-performance computing are discussed. Applications ranging from seasonal domestic heat storage to diurnally operating systems in concentrating solar power facilities are considered in these models, which are not available through any other sources. Finally, an outlook on future developments highlights emerging technologies.
Introduction.- THC Processes in a Packed Adsorbent Bed.- The FEM Simulation Software OpenGeoSys 6.- Laboratory-Scale Adsorption Chamber Simulation.- Extensions.- Closing Remarks.
<p><b>Christoph Lehmann </b>obtained his Bachelor’s degree in Physics from the Martin Luther University Halle-Wittenberg in 2011 and his Master’s in Physics from the University of Leipzig in 2013. He’s been working as a software developer at pwp-systems developing tools for traffic data analysis from 2011-2015. After working on scientific visualisation at the Institute of Computer Science at Leipzig University, he joined the UFZ in 2015 to work on the numerical simulation of thermochemical energy storage (TCES), especially systems based on water adsorption to zeolite. His research interests are the numerical assessment of the energy efficiency of those storage systems and the examination of the sortion kinetics of novel composite adsorbents, in particular zeolite granules impregnated with hygroscopic salts for the enhancement of the heat storage density.</p><p><b>Olaf Kolditz </b>is the head of the Department of Environmental Informatics at the Helmholtz Center for Environmental Research (UFZ). He holds a Chair in Applied Environmental System Analysis at the Technische Universität in Dresden. His research interests are related to environmental fluid mechanics, numerical methods and software engineering with applications in geotechnics, hydrology and energy storage. Prof. Kolditz is the lead scientist of the OpenGeoSys project, an open-source scientific software platform for the numerical simulation of thermo-hydro-mechanical-chemical processes in porous media, in use worldwide. He studied theoretical mechanics and applied mathematics at the University of Kharkov, got a PhD in natural sciences from the Academy of Science of the GDR (in 1990) and earned his habilitation in engineering sciences from Hannover University (in 1996), where he became group leader at the Institute of Fluid Mechanics. Until 2001 he was full professor for Geohydrology and Hydroinformatics at Tübingen University and director of the international Master course in Applied Environmental Geosciences. Since 2007 he is the speaker of the Helmholtz graduate school for environmental research HIGRADE. Prof. Kolditz is Editor-in-Chief of two international journals <i>Geothermal Energy </i>(open access) and <i>Environmental Earth Sciences </i>(ISI). Prof. Kolditz is a leading scientist in numerous Sino-German research networks.<br/></p><p><b>Thomas Nagel </b>is heading the groups “Computational Energy Systems” at the Helmholtz Centre for Environmental Research—UFZ, as well as “Environmental Geotechnics: Multi-physics simulation for geotechnical system analysis”, a joint work group between the UFZ and the Federal Institute for Geosciences and Natural Resources (BGR). He holds an Adjunct Professorship at Trinity College Dublin, Ireland. During his master’s studies of Mechanical Engineering/Applied Mechanics at Chemnitz University of Technology he worked on coupled problems in biomechanics and biomedical technology at Rush University Medical Center in Chicago and Eindhoven University ofTechnology, the Netherlands. In 2012 he was awarded his PhD from Trinity College Dublin for a dissertation in mechanobiology. Since then he has been working at the UFZ as part of a team of scientists developing the numerical simulation framework OpenGeoSys for coupled multiphysical problems. His particular foci are thermochemical and sensible heat storage in porous media as well as geotechnical applications in the context of energy supply, storage and waste management.<br/></p><p></p>
Focuses on the thermochemical gas-solid reactions for the design of heat storage systems Provides detailed models of the reactions that account for heat and mass transport, chemical and physical reactions, and possible local thermal non-equilibrium Covers the full spectrum of the modeling process, from underlying scientific theory, to practical applications
<p>Focuses on the thermochemical gas-solid reactions for the design of heat storage systems <br/><br/>Provides detailed models of the reactions that account for heat and mass transport, chemical and physical reactions, and possible local thermal non-equilibrium</p><p>Covers the full spectrum of the modeling process, from underlying scientific theory, to practical applications</p>
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