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Course Criteria
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4.00 Credits
Quantitative laboratory studies of operations such as fluid flow, filtration, heat transfer, mass transfer and fluidization which illustrate the fundamentals of momentum, heat and mass transfer. Laboratory safety, technical writing, and oral presentation skills are emphasized. Four hours of laboratory, field trips. Fall Prerequisites: CHML 208, 305, 306. (Cr. 2)
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5.00 Credits
A continuation of the topics in CHML 403. Experimental topics include distillation, drying, fluidization, reaction kinetics, membrane processes, and computer-controlled processes. Laboratory safety, technical writing, and oral presentation skills are emphasized. Five hours of laboratory, field trips. Spring. Prerequisites: CHML 306, 321, 423. Corequisite: CHML 439 (Cr. 2)
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1.00 - 2.00 Credits
Application of the principles of chemical engineering to the design of chemical processes. The sequence of design methods and economic evaluations utilized in the evolution of a chemical process design, from initial process research to preliminary equipment design, is developed. Students work in three-person groups on a comprehensive plant design. Technical writing required. Two lectures and one two-hour problem period. Fall. Prerequisites: CHML 208, 305, 306, 321. Corequisite: CHML 423 (Cr. 3)
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1.00 - 2.00 Credits
Continuation of the design projects from CHML 405. Application of safety constraints, loss prevention, hazards evaluation, and engineering ethics to design of chemical processes and plants. Computer simulation software used for process design. Industrial review of design projects. Written and oral reports required. Two lectures and one two-hour problem period. Spring. Prerequisites: CHML 316, 405, 423. Corequisite: CHML 439. (Cr. 3)
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3.00 Credits
A study of the unsteady state behavior of processes as it relates to design of control systems. Applications in reactor control, level control, and control of distillation columns. Three lectures. Fall. Prerequisites: CHML 306, 321, MATH 203. (Cr. 3)
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3.00 Credits
An independent investigation, including literature, theoretical and/or experimental studies of a chemical engineering project under the supervision of a faculty advisor. (For students of superior ability.) Written and oral reports required. Fall and Spring. Prerequisite: Permission of Department Chair. (Cr. 2-3)
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3.00 Credits
Design of equipment and systems for separation processes based on rate-controlled mass transfer. Applications in liquid extraction, absorption, drying, crystallization, and membrane separation. Three lectures. Spring. Prerequisite: CHML 306. (Cr. 3)
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3.00 Credits
Development of the mass, energy and momentum transport equations. Use of these equations in solving chemical engineering problems. Three lectures. Spring. Prerequisites: CHML 208, 305, 306, MATH 203. (Cr. 3)
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3.00 Credits
Application of engineering principles to biological processes. Topics include enzyme-catalyzed reactions, kinetics of cell growth and product formation; aeration, agitation and oxygen transfer; bioreactor design and scale-up; biological waste treatment, and fermentation laboratory experiments. Three lectures. Prerequisites: CHML 306, 321 (Cr. 3)
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3.00 Credits
Emphasis on particulate control. Industrial sources and regulatory codes for particulate emissions; review of fine particle technology; development of performance equations and design procedures for gravity settlers, cyclone-electrostatic precipitators, baghouse and venturi scrubbers; atmospheric dispersion and stack design; overview of gaseous control equipment. (Cr. 3)
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