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200 10$aReactive distillation$b[electronic resource] $estatus and future directions /$fKai Sundmacher and Achim Kienle (eds.)
210   $aWeinheim $cWiley-VCH$dc2003
215   $a1 online resource (309 p.)
300   $aDescription based upon print version of record.
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320   $aIncludes bibliographical references and index.
327   $aReactive Distillation Status and Future Directions; Contents; Preface; List of Contributors; Part I Industrial Applications; 1 Industrial Applications of Reactive Distillation; 1.1 Introduction; 1.2 Etherification: MTBE, ETBE, and TAME; 1.3 Dimerization, Oligomerization, and Condensation; 1.4 Esterification: Methyl Acetate and Other Esters; 1.5 Hydrolysis of Esters; 1.6 Hydration; 1.7 Hydrogenation/Hydrodesulfurization/Hydrocracking; 1.7.1 Benzene to Cyclohexane; 1.7.2 Selective Hydrogenation of C(4) Stream; 1.7.3 Hydrogenation of Pentadiene; 1.7.4 C(4) Acetylene Conversion
327   $a1.7.5 Hydrodesulfurization, Hydrodenitrogenation, and Hydrocracking1.7.6 Miscellaneous Hydrogenations; 1.8 Chlorination; 1.9 Acetalization/Ketalization; 1.10 Recovery and Purification of Chemicals; 1.11 Difficult Separations; 1.12 Chemical Heat Pumps; 1.13 RD with Supercritical Fluids; 1.14 Conclusions; 2 Reactive Distillation Process Development in the Chemical Process Industries; 2.1 Introduction; 2.2 Process Synthesis; 2.3 Process Design and Optimization; 2.4 Limitations of the Methods for Synthesis and Design: the Scale-Up Problem; 2.5 Choice of Equipment
327   $a2.6 Some Remarks on the Role of Catalysis2.7 Conclusions; 2.8 Acknowledgments; 2.9 Notation; 3 Application of Reactive Distillation and Strategies in Process Design; 3.1 Introduction; 3.2 Challenges in Process Design for Reactive Distillation; 3.2.1 Feasibility Analysis; 3.2.2 Catalyst and Hardware Selection; 3.2.3 Column Scale-Up; 3.3 MTBE Decomposition via Reactive Distillation; 3.3.1 Conceptual Design; 3.3.2 Model Development; 3.3.2.1 Catalyst Selection and Reaction Kinetics; 3.3.2.2 Phase Equilibrium Model; 3.3.2.3 Steady-State Simulation; 3.3.3 Lab-Scale Experiments
327   $a3.3.4 Pilot-Plant Experiments3.4 Conclusions; Part II Physicochemical Fundamentals; 4 Thermodynamics of Reactive Separations; 4.1 Introduction; 4.2 Process Models for Reactive Distillation; 4.2.1 Outline; 4.2.2 Case Study: Methyl Acetate; 4.3 Equilibrium Thermodynamics of Reacting Multiphase Mixtures; 4.4 Fluid Property Models for Reactive Distillation; 4.4.1 Outline; 4.4.2 Examples; 4.4.2.1 Hexyl Acetate: Sensitivity Analysis; 4.4.2.2 Methyl Acetate: Prediction of Polynary Vapor-Liquid Equilibria; 4.4.2.3 Butyl Acetate: Thermodynamic Consistency
327   $a4.4.2.4 Ethyl Acetate: Consequences of Inconsistency4.4.2.5 Formaldehyde + Water + Methanol: Intrinsically Reactive Complex Mixture; 4.5 Experimental Studies of Phase Equilibria in Reacting Systems; 4.5.1 Outline; 4.5.2 Reactive Vapor-Liquid Equilibria; 4.5.2.1 Batch Experiments; 4.5.2.2 Flow Experiments; 4.5.2.3 Recirculation Experiments; 4.6 Conclusions; 4.7 Acknowledgments; 4.8 Notation; 5 Importance of Reaction Kinetics for Catalytic Distillation Processes; 5.1 Introduction; 5.2 Reactive Ideal Binary Mixtures; 5.2.1 Reaction-Distillation Process with External Recycling
327   $a5.2.1.1 (,)-Analysis
330   $aIn a reactive distillation column, both the chemical conversion and the distillative separation of the product mixture are carried out simultaneously. Through this integrative strategy, chemical equilibrium limitations can be overcome, higher selectivities can be achieved and heat of reaction can be directly used for distillation. Increased process efficiency and reduction of investments and operational costs are the direct results of this approach.Highly renowned international experts from both industry and academia review the state-of-the-art and the future directions in application,
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200 10$aBaukonstruktion im Klimawandel /$fvon Bernhard Weller, Marc-Steffen Fahrion, Sebastian Horn, Thomas Naumann, Johannes Nikolowski
205   $a1st ed. 2016.
210  1$aWiesbaden :$cSpringer Fachmedien Wiesbaden :$cImprint: Springer Vieweg,$d2016.
215   $a1 online resource (X, 333 S. 173 Abb., 131 Abb. in Farbe.) 
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320   $aIncludes bibliographical references.
330   $aDas vorliegende Buch zeigt baukonstruktive Lösungen für eine zukunftsfähige Gebäudeertüchtigung vor dem Hintergrund des Klimawandels. Behandelt werden die klimatischen Einwirkungen Sommerhitze, Überflutung, Starkregen, Hagel, Wind und Schnee. Deren Veränderungen infolge des Klimawandels beeinflussen die Verletzbarkeit bestehender Wohngebäude und Nichtwohngebäude. Auf Grundlage objektiver Analysemethoden werden die Auswirkungen des Klimawandels auf Bestandsgebäude beschrieben und detaillierte baukonstruktive Anpassungsmaßnahmen erläutert. Der Inhalt Klimawandel und Klimaanpassung von Gebäuden als aktuelle Herausforderung ? Bestandsanalyse und baukonstruktive Anpassung von neun Wohn- und Nichtwohngebäuden der Baujahre von 1890 bis 1995 ? Gebäudeertüchtigung im Detail für die Einwirkungen aus Sommerhitze, Überflutung, Starkregen, Hagel, Wind und Schnee - Wirtschaftlichkeit von Anpassungsmaßnahmen Die Zielgruppe Architekten, Ingenieure, Denkmalpfleger Immobilienwirtschaft Die Autoren Prof. Dr.-Ing Bernhard Weller ist Direktor des Instituts für Baukonstruktion an der Technischen Universität Dresden. Dr.-Ing. Marc-Steffen Fahrion war Leiter der Forschungsgruppe ?Energieeffizienz und Nachhaltigkeit? am Institut für Baukonstruktion an der Technischen Universität Dresden. Dipl.-Ing. Sebastian Horn ist Leiter der Forschungsgruppe ?Energieeffizienz und Nachhaltigkeit? am Institut für Baukonstruktion an der Technischen Universität Dresden. Prof. Dr.-Ing. Thomas Naumann ist Leiter des Forschungsbereichs "Umweltrisiken in der Stadt- und Regionalentwicklung" am Leibniz-Institut für ökologische Raumentwicklung e.V. in Dresden. Dr.-Ing. Johannes Nikolowski ist Mitarbeiter im Büro GB1 Ingenieure mit den Tätigkeitsschwerpunkten Schadensanalyse, Sanierungsplanung und Qualitätssicherung.
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