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Course Criteria
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3.00 Credits
Prerequisites: CHM 2210, ECH 3023, MAC 2313, and PHY 2048C. Corequisites: ECH 3301 and PHY 2049C. This course is the second in a two-part series introducing the general concepts of chemical engineering. Applications of mass and energy balances are extended to include reactive systems, systems undergoing phase changes, and transient processes. MATLAB is used to demonstrate the use of a structured programming language for material and energy balances.
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3.00 Credits
Prerequisites: ECH 3023, ECH 3024, and ECH 3301, all with a grade of "C" or higher, as well as PHY 2049C. Corequisites: CHM 4410, ECH 3854, ECH 3266, and EGM 3512. This course exposes students to the basics of classical and solution thermodynamics, forming a link between the mass and energy balance courses and separations.
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3.00 Credits
Prerequisites: ECH 3023, ECH 3024, and ECH 3301, all with a grade of "C" or higher, as well as PHY 2049C. Corequisites: CHM 4410, ECH 3101, ECH 3854, and EGM 3512. This course examines integral balance equations for conservation of momentum, energy, and mass. Topics include: application to chemical processes involving fluid flow and heat and mass transfer; estimation of friction factors and of heat and mass transfer coefficients; pump selection and sizing; piping network analysis; and design of heat exchangers.
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3.00 Credits
Prerequisites: CHM 4410, ECH 3101, ECH 3266, and ECH 3854. Corequisites: ECH 3418 and ECH 4267. This course enables students to design and conduct experiments on fluid mechanics and heat transfer; analyze and interpret data; apply spreadsheets, statistical methods, and process models; as well as gain proficiency in operating basic chemical-engineering equipment and instruments. Emphasis is placed on safety, professionalism, teamwork, and oral/written communication.
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3.00 Credits
Prerequisite: MAC 2312. Corequisites: ECH 3023 and MAC 2313. This course examines the development and analysis of process models for systems that arise in chemical-engineering applications.
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3.00 Credits
Prerequisite: Completion of the academic requirements through the sophomore year in chemical engineering or in other engineering disciplines. This course covers ways to apply statistical process control and methods of planned experimentation to the design of products and processes, as well as to continuous quality improvement. Topics covered include control charts; process-capability studies; loss functions; acceptance sampling; design of experiments for screening studies and response-surface modeling; and analysis of variance. The course also introduces case studies in chemical processes, food engineering, and health care.
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3.00 Credits
Prerequisites: ECH 3101, ECH 3266, ECH 3854, and CHM 4410. Corequisites: ECH 3274L and ECH 4267. This course examines the principles of equilibrium and transport-controlled separations. Topics include analysis and design of stagewise and continuous separation processes, including distillation, absorption, extraction, filtration, and membrane separations.
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4.00 Credits
Prerequisites: PHY 2040C and a grade of "C-" or better in ECH 3023, ECH 3024, and ECH 3301. Corequisites: ECH 3101, ECH 3266, EGM 3512, and CHM 4410. This course covers structured programming techniques, solutions of ordinary differential equations, as well as numerical techniques useful in the solution of chemical engineering processes, as follows: root-finding techniques, direct and iterative approaches for solving linear systems, linear and nonlinear regression, interpolation, numerical differentiation and integration, and statistical analysis of data.
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0.00 Credits
(S/U grade only.)
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3.00 Credits
Prerequisites: CHM 4410, ECH 3101, ECH 3266, and ECH 3854. Corequisites: ECH 3274L and ECH 3418. This is the second in a two-semester sequence on transport phenomena. Emphasis is on critical analytical and mathematical skills for analyzing and applying fundamental concepts in transport phenomena (including fluid mechanics, heart transfer, and mass transfer), as well as on the analysis of similarities and differences among these three processes.
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