His primary scientific interests are in Control theory, Nonlinear system, Reactive distillation, Simulated moving bed and Chromatography. His Control theory research is multidisciplinary, relying on both Distillation, Fractionating column, Process control and Mechanics. His Nonlinear system research is multidisciplinary, incorporating elements of Fluidized bed, Measure, Control theory and Granulation.
The study incorporates disciplines such as Rate equation, Chemical kinetics and Chemical engineering, Chemical process in addition to Reactive distillation. His studies deal with areas such as Separation process and Analytical chemistry as well as Simulated moving bed. His Chromatography study combines topics in areas such as Dispersion and Ester hydrolysis.
His scientific interests lie mostly in Nonlinear system, Control theory, Chromatography, Reactive distillation and Mechanics. Achim Kienle interconnects Separator, Continuous stirred-tank reactor, Distillation and Applied mathematics in the investigation of issues within Nonlinear system. His study explores the link between Control theory and topics such as Fluidized bed that cross with problems in Spray Granulation.
The concepts of his Chromatography study are interwoven with issues in Simulated moving bed and Enantiomer. The Reactive distillation study combines topics in areas such as Dynamic simulation, Chemical engineering, Process engineering and Fractionating column. His work carried out in the field of Mechanics brings together such families of science as Low-density polyethylene, Work and Granulation.
His main research concerns Fluidized bed, Global optimization, Mechanics, Granulation and Layering. His Fluidized bed research incorporates themes from Economies of agglomeration, Process control and Lyapunov function. His Global optimization research integrates issues from Distillation, Catalysis and Process engineering.
Achim Kienle studies Mass transfer which is a part of Mechanics. Achim Kienle combines subjects such as Chromatography and Simulated moving bed, Adsorption with his study of Numerical stability. His Applied mathematics research is multidisciplinary, incorporating perspectives in Triangle theory, Viral replication and Nonlinear system.
His primary areas of investigation include Mathematical optimization, Fluidized bed, Global optimization, Mechanics and Work. Mathematical optimization is closely attributed to Distillation in his research. The Fluidized bed study combines topics in areas such as State space, Control theory, Sieve, Lyapunov function and Parametrization.
Achim Kienle regularly ties together related areas like Granulation in his Mechanics studies. His study in Granulation is interdisciplinary in nature, drawing from both Chromatography, Volumetric flow rate, Volume and Instability. His Thermodynamics study combines topics from a wide range of disciplines, such as Organic chemistry, Methanol and Catalysis.
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Production of Butyl Acetate by Catalytic Distillation: Process Design Studies
Jignesh Gangadwala;Achim Kienle;Achim Kienle;Erik Stein;Sanjay Mahajani.
Industrial & Engineering Chemistry Research (2004)
Reactive distillation : status and future directions
Kai Sundmacher;Kai Sundmacher;A. Kienle;A. Kienle.
Esterification of acetic acid with butanol in the presence of ion-exchange resins as catalysts
Jignesh Gangadwala;Surendra Mankar;Sanjay Mahajani;Achim Kienle;Achim Kienle.
Industrial & Engineering Chemistry Research (2003)
Simulated moving bed process with cyclic modulation of the feed concentration.
Henning Schramm;Malte Kaspereit;Achim Kienle;Achim Kienle;Andreas Seidel-Morgenstern;Andreas Seidel-Morgenstern.
Journal of Chromatography A (2003)
Steady-state multiplicities in reactive distillation columns for the production of fuel ethers MTBE and TAME: theoretical analysis and experimental verification
Klaus-Dieter Mohl;Achim Kienle;Ernst-Dieter Gilles;Patrick Rapmund.
Chemical Engineering Science (1999)
Nonlinear computation in DIVA — methods and applications
M. Mangold;A. Kienle;E.D. Gilles;E.D. Gilles;K.D. Mohl.
Chemical Engineering Science (2000)
Low-order dynamic models for ideal multicomponent distillation processes using nonlinear wave propagation theory
Achim Kienle;Achim Kienle.
Chemical Engineering Science (2000)
Improved operation of simulated moving bed processes through cyclic modulation of feed flow and feed concentration
H. Schramm;A. Kienle;A. Kienle;M. Kaspereit;A. Seidel-Morgenstern;A. Seidel-Morgenstern.
Chemical Engineering Science (2003)
Real-Time Optimization for Large Scale Processes: Nonlinear Model Predictive Control of a High Purity Distillation Column
M. Diehl;I. Uslu;R. Findeisen;S. Schwarzkopf.
Integrated chemical processes : synthesis, operation, analysis, and control
Kai Sundmacher;Kai Sundmacher;Achim Kienle;Achim Kienle;Andreas Seidel-Morgenstern;Andreas Seidel-Morgenstern.
Published in <b>2005</b> in Weinheim by Wiley-VCH (2005)
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