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Course Criteria
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3.00 Credits
Application of principles of chemical engineering to small chemical systems. Topics include: conservation-of-species equation, linear multi-state chemical systems, unit micro-operations, rate and diffusion control, multiphase catalysis, chromatography, phase-transfer catalysis, facilitated diffusion. Pre: 3184. (3H,3 Credits).
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2.00 Credits
Mathematical modeling of chemical processes, application of numerical techniques to the solution of equations, use of a programming language to write programs for calling numerical subroutines, numerical solutions of problems resulting in partial differential equations. Pre: 2124, 3114. Co: 3184, 3044. (2H,2 Credits).
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3.00 Credits
Business strategies and industrial marketing concepts, and their application in the chemical, pharmaceutical and related process industries. The course is designed for engineers and other students planning a career in the process industries. Junior standing required. (3H,3 Credits).
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4.00 Credits
Chemical process synthesis and plant design, economic analysis of alternative processes, process equipment design and specifications, computer-aided process design and simulation, design case studies, application of scientific and engineering knowledge to practical design problems. Grade of C- or better in all CHE prefix courses and in-major GPA of 2.0 or better is required. Pre: 3144, 3134, 3184, 3044 for 4185; 4185 for 4186. (4H,4 Credits).
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3.00 Credits
Basics of polymeric materials including description and categorization of macromolecules; characterization; mechanical properties; rubbery, glassy, crystalline, and viscous flow behavior. Pre: CHEM 2536, CHE 2164. (3H,3 Credits).
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3.00 Credits
Basic principles of momentum and heat transfer applied to the analysis of polymer processing operations. Introduction to polymer rheology. Pre: 3144, 3044. (3H,3 Credits).
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3.00 Credits
Concepts, principles and applications of various unit operations used in protein separations. Properties of biological materials, such as cells and proteins, and their influences on process design. Design of processes for protein purification based on the impurities to be eliminated. Concepts and principles of scale-up of unit operations. Case studies in practical protein recovery and purification issues, with a focus on enhanced protein purification by genetic engineering. Protein purification process simulation and optimization using process simulation software. Pre: BSE 3504 or CHE 3144. (3H,3 Credits).
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3.00 Credits
Variable credit course.
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3.00 Credits
Variable credit course.
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3.00 Credits
Variable credit course.
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