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Course Criteria
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3.00 Credits
Prerequisites: ECH 4504 and ECH 4604. Corequisite: ECH 4615. A systematic introduction to dynamic behavior and automatic control of industrial processes. Synthesis of feedback control loops for linear systems and synthesis of control structures.
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1.00 Credits
Prerequisites: ECH 4504 and ECH 4604. Corequisite: ECH 4615. This lab is comprised of experiments designed to illustrate and apply control theory, measurement techniques, calibration, tuning of controls, characterization of sensors, and control circuits.
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3.00 Credits
Prerequisites: ECH 3274L, ECH 3418, and ECH 4267. Corequisites: ECH 4504 and ECH 4604. This course involves preparing experimental plans and doing experimental work with unit operations equipment to meet specific objectives. Emphasis is on computer data analysis and on oral communication skills.
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3.00 Credits
Prerequisites: ECH 3274L, ECH 3418, and ECH 4267. This course covers the following topics: homogeneous and heterogeneous reaction kinetics; analysis of batch, mixed, plug, and recycle reactors; analysis of multiple reactions and multiple reactors; reactor temperature control; and catalytic reactor design.
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4.00 Credits
Prerequisites: ECH 3274L, ECH 3418, and ECH 4267. Corequisites: ECH 4404L, ECH 4504, and ECO 2023. This is the first course in a two-semester sequence on the analysis, synthesis, and design of chemical processes, preparing students for engineering practice. Students integrate knowledge from prior courses with process economics, computer-aided design, engineering standards, and realistic constraints to solve open-ended process problems.
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3.00 Credits
Prerequisites: ECH 4504 and ECH 4604. Corequisites: ECH 4323 and ECH 4323L. The second in a two-semester sequence on the analysis, synthesis, and design of chemical processes, this course prepares students for engineering practice. Students integrate knowledge from prior courses with process economics, computer-aided design, engineering standards, and realistic constraints to the design of chemical-process facilities.
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3.00 Credits
that are important for biotechnological applications. Extension of the chemical engineering principles of kinetics, reactor design, heat and mass transport, thermodynamics, process control, and separation processes to important problems in bioengineering.
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3.00 Credits
Prerequisites: ECH 3274L, ECH 3418, and ECH 4267. Corequisites: ECH 4404L, ECH 4504, and ECH 4604. Introduction to applications of environmental engineering from a chemical engineering perspective. Thermodynamics, stoichiometry, chemical kinetics, transport phenomena, and physical chemistry are utilized in addressing pollution control and prevention processes. Analysis of particle phenomena, including aerosols and colloids. Applications of fundamentals to analyze gas and liquid waste treatment processes.
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3.00 Credits
Prerequisites: Completion of sophomore-year academic requirements in chemical engineering, other engineering discipline, or in a related science; and instructor permission. This course involves the production of a distilled-spirit sample at a commercial facility, followed by an in-depth chemical analysis of the product through the use of sophisticated instrumentation located at a university chemistry laboratory in Scotland. This intensive course takes place over a two week period in which students are instructed in the operational procedure of the plant and given hands-on involvement in an actual production run. Lecture and laboratory sessions following the production run focus on a detailed chemical and physical analysis of the distilled spirit sample using spectroscopic, chromatographic, and NMR techniques.
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3.00 Credits
Prerequisites: ECH 3274L, ECH 3418, and ECH 4267. Corequisites: ECH 4404L, ECH 4504, and ECH 4604. This course offers an introduction to different types of polymers and their physical properties. Topics include major synthetic paths and reaction kinetics, properties of macromolecules in solution, methods of molecular weight determination, and the role of phase transitions in amorphous and crystalline polymers.
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