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Course Criteria
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3.00 Credits
Preparation of a report based on personal research, design, or experiment. Prerequisite: consent of the department. One course credit. Please see departmental website for specific details. Prerequisites Permission of instructor. This course is offered during the following semesters: Spring Semester
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3.00 Credits
A mentored professional experience in chemical engineering at an off-site organization. The internship must conform to all the requirements of the School of Engineering Internship Program. The department will grant course credit for internships if all of the following conditions are met: 1) The project is approved in advance by the department, 2) a faculty mentor has supervisory and technical control of any work that receives credit, and 3) a written report is submitted that is evaluated by the faculty adviser and the outside institutional supervisor. Please see departmental website for specific details. Prerequisites Junior or senior standing. This course is offered during the following semesters: Fall Semester Spring Semester
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3.00 Credits
Application of numerical methods and digital computers to the solution of mathematical problems in chemical engineering. Subjects include interpolation and approximation, roots of algebraic equations, numerical integration, and solution to ordinary and partial differential equations. Prerequisites For juniors, seniors, and graduate students. This course is offered during the following semesters: Fall Semester
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3.00 Credits
Treatment of chemical reaction equilibrium and kinetic fundamentals and application of them to the design of reactors. Topics include interpretation of reaction-rate data, establishment of reaction mechanism and rate-controlling steps, sizing, and optimization of reactors. Use of personal computer software is encouraged. This course is offered during the following semesters: Spring Semester
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3.00 Credits
Applied chemical kinetics, reaction rate theories, complex kinetics, chain reactions, reactor stability and sensitivity to operating parameters. Mass and energy transfer limitations in heterogeneous noncatalytic and catalytic reactor design. Prerequisites Chemical and Biological Engineering 102. This course is offered during the following semesters: Fall Semester
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3.00 Credits
Material on mass-transfer separation processes beyond that covered by the undergraduate unit operations course. Computational techniques employing digital computers are emphasized. Prerequisites CHBE 45
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3.00 Credits
Fundamentals of liquid/solid, liquid mixture, and gas mixture separations using synthetic membranes. Processes include microfiltration, ultrafiltration, reverse osmosis, electrodialysis, and gas permeation, with applications to industrial process streams, bioprocessing, water purification, and hazardous waste control; also novel membrane reactors and membrane extraction. Emphasis on application of mass transfer and fluid flow principles; also process configuration selection, to design and scale-up. Prerequisites CHBE 45.
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3.00 Credits
Mathematical modeling of chemical processes with ordinary differential equations. Feedback, feedforward, and environmental control. Block diagrams. Laplace transformation. Linearization techniques. Frequency response. Laboratory exposure to instrumentation. Prerequisites Chemical and Biological Engineering 21 and 22, or permission of instructor. This course is offered during the following semesters: Fall Semester
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3.00 Credits
Intorduction to fundamental method of optimization with application to problems related to chemical and biological systems and processes; nature of optimization problem; one-dimensional and multivaribale unconstrianed optimization; linear programming; non-linear programming with constriants; mixed-integer programming; selected applications. This course is offered during the following semesters: Spring Semester
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3.00 Credits
(Cross-listed as Mechanical Engineering 112). Multi-dimensional conduction. Transient conduction including moving boundary problems. External forced and natural convection. Internal forced and natural convection. Developing flows and transition to turbulence. Condensation and boiling heat transfer. Radiation and conjugate heat transfer involving radiation. Temperature and heat flux measurements. Numerical techniques. Prerequisites ME111 Thermal-Fluid Transport I or equivalent.
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