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Unformatted text preview: ENU 4133 Syllabus, Spring 2011 – D. Schubring 1 Syllabus also serves ENU 6937 (graduate student version), differences as noted 1. Description Fundamentals of thermodynamics, fluid mechanics and heat transfer with application to design and safety of nuclear power plants. Thermal hydraulic characteristics of nuclear power plants, energy conversion cycles, applications of first and second law of thermodynamics, nuclear heat generation, fluid mechanics, conservation laws and governing equations for inviscid and viscous single-phase flow, conduction and convection heat transfer, and thermal design of fuel elements. 2. Prerequisite EML 3100 (Co-requisite: EML 4140) 3. Program Educational Objectives Supported by Course 1. Graduates will have successful careers in Nuclear Engineering or related disciplines. 2. Graduates will pursue advanced degrees or continuing education. 3. Graduates will communicate effectively and work collaboratively in Nuclear Engineering or related disciplines. 4. Professional Components Supported by Course 1. Provide students with the ability to apply advanced mathematics, computational skills, sci- ence and engineering science, including atomic and nuclear physics, to identify, formulate, analyze, and solve nuclear and radiological engineering problems. 4. Provide students with the skills needed to communicate effectively, work collaboratively, and understand their professional and ethical responsibilities and the impact of engineering solutions in a societal and economic context so they can pursue successful, productive careers in nuclear and radiological engineering. 5. Program Outcomes Supported by Course Outcome a: an ability to apply knowledge of mathematics, science, and engineering. Outcome b: an ability to design and conduct experiments as well as to analyze and interpret data Outcome c: an ability to design a system, component or process to meet desired needs within realistic constraints such as economic, environmental, social, political, ethical, health and safety, manufacturability, and sustainability Outcome e: an ability to identify, formulate, and solve engineering problems. Outcome g: an ability to communicate effectively Outcome k: an ability to use the techniques, skills, and modern engineering tools necessary for engineering practice Outcome l: an ability to apply advanced mathematics, science and engineering sciences, includ- ing atomic and nuclear physics, to nuclear and radiological systems and processes ENU 4133 Syllabus, Spring 2011 – D. Schubring 2 Outcome n: an ability to work professionally in on or more of the areas of: nuclear power sys- tems, nuclear instrumentation and measurement, radiation protection and shielding, and radiation sources and applications 6. Instructor DuWayne Schubring, Assistant Professor, Nuclear & Radiological Engineering 107A Nuclear Reactor Building 352-392-1401 x314 [email protected] http://victr.nre.ufl.edu/Teaching/Spring2011/ENU4133.html Office hours: M 1500-1630 (4192 student priority), F 1500-1630 (equal priority), MWF 1145-...
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This note was uploaded on 07/18/2011 for the course ENU 4133 taught by Professor Schubring during the Spring '11 term at University of Florida.
- Spring '11