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Show Technology Engineering ENGINEERING TECHNOLOGY CORE PROGRAM Engineering Technology Programs prepare individuals for occupations working with both engineers and craftsmen, designers and producers. Engineering Technologists are essentially "hands on" engineers. They apply established engineering principles and rules and direct production of machines, structures, and products which engineers have designed. This "hands on" approach is in contrast to the Engineer (who may also begin his training in the Pre-Engineering program with the School of Technology) who concentrates on design and on development of new engineering principles and procedures: and who requires, therefore, more extensive training in mathematics and science than does the Engineering Technologist. Core: Total Core credit hours required (min.) AET; EET 88; MET 91. Students receiving a bachelor of science degree in any of the Engineering Technology majors must satisfy the following minimum core requirements: 1. Mathematics, 20 credit hours minimum total; Math PS 105 (5) or Related Technical Education 114 (5), Math 106 (5) or Related Technical Education 115 (5), Math PS 107 (5) or Related Technical Education 117 (5), Math PS 211 (5) or Related Technical Education 118 (5). 2. Physics: 10 credit hrs. min. AET: PS 111, 114 (5) or PS 261, 264 (5) & PS 113, 116 (5) or PS 263, 266 (5), EET: PS 112, 115 (5) or PS 262, 265 (5) & PS 113, 116 (5) or PS 263, 266 (5), MET: PS 111, 114 (5) or PS 261, 264 (5) & PS 112, 115 (5) or PS 262, 265 (5). 3. Chemistry, 5 credit hours minimum total; PS 101 (5) or PS 121 (5). 4. Communications 102 or 105 (3) and 3-5 credit hours of Gen. Ed. courses in Humanities, Soc. Science or Communication. 5. Mechanics & Strengths: AET & MET: 8 credit hrs. min., ENGTL 330 (5) & 331 (4) or Pre-engineering 350 (4), 352 (4), EET: 4 credit hrs. min., ENGTL 330 (5) or ENGIN 350 (4). 6. Materials and Processes: 5 credit hours minimum total: Engineering Technology 236 (5). 7. Electronics, 12 credit hours minimum total: Electronics Technology 124 (5), 136 (5), 137 (2). 8. Computer Applications, 9 credit hours minimum total; Data Processing 260 (3), Engineering Technology 345 (3) and 355 (3). 9. Engineering Graphics, 7 credit hours minimum total; Engineering Technology 142 (4), 244 (3). 10. Supervision, 3 credit hours minimum total; Engineering Technology 456 (3). 11. Senior Project, 6 credit hours minimum total; Engineering Technology 461 (2), 462 (2), 463 (2). ENGINEERING TECHNOLOGY COURSES 142. Technical Drawing (4) Basic drafting Includes lettering, geometric constructions, use of drafting machines, sketching, multiview drawings, sectional views, auxiliary views, dimensional theory and practice One hour lecture and three 3-hour labs a week. A W 236. Materials & Processes (5) Survey of industrially important materials; the principles of materials behavior; the processes used to change materials shape and condition for industrial use. Four lectures and one laboratory per week. A W 244. Descriptive Geometry (3) Theory of basic drafting is applied to solution of engineering problems more advanced than those encountered in basic drafting courses. Deals with view relationships, spatial visualization and problems relating to points, lines and planes. Prerequisite: Engineering Technology 142 or equivalent One hour lecture and two 3-hour labs a week. W S 319. Advanced Topics in Mathematics Applied to Engineering Technology (5) The analysis of mechanical and electrical systems using differential equations and transform methods. S domain interpretation of the system, forced and transient response, and pole-zero interpretation. Prerequisites: Electronic Technology 130, Related Technical Education 11S or Math 211. Five one-hour lectures per week. 330. Introduction to Applied Mechanics (5) The principles of statistics and dynamics as used in industrial equipment and structures. Development of analytical skills and techniques. Prerequisite: Related Technical Education 115 or equivalent. Four 1-hour lecture periods and one 3-hour laboratory period each week. A 331. Strength of Materials (4) Relation of physical properties of matter to geometric properties of form, stress and strain. Beams, columns, welded and riveted joints, combined loading. Prerequisite: ENGTG 330. Four Lectures. W 248 Technology Pre-Engineering 332. Machine Design (3) Application of engineering fundamentals to machine design with emphasis for stress and deflection analysis, and techniques involved in designing and selecting individual machine parts. Prerequisites: Related Technical Education 118 and Engineering Technology 236 and 331. Three one-hour lectures per week. S 334. Applied Fluid Power (3) Principles of fluid mechanics and component operation as they apply to the design of hydraulic and pneumatic systems. Prerequisites: ENGTC 331 (may be taken concurrently). Three lectures. 345. Computer-Aided Graphics and Applications (3) An introduction to the use of computers in technical graphics. Prerequisites: Related Tech. nical Education 114 or Math 106. Engineering Technology 142. Two lectures and one 3-hour laboratory. 355. Introduction to Micro-Processors (3) Introduction to micro-processors and their appli- cations in controls systems. Prerequisite: Electronic Technology 124. Two lectures, one 3-hour lab. 456. Supervision Principles (3) Understanding of basic company, supervisor and operator objective! and responsibilities, and their relationships to each other; case problem approach. Three lectures. 461, 462, 463. Senior Projects (2-2-2) An engineering problem for each program will be selected for team solution. Problems will require analysis, evaluation, design, planning, development, production and testing. Prerequisite: Permission of instructor. 472. Thermodynamic Systems (3) Application of the laws, concepts, and procedures of thermodynamics, heat transfer, and gas dynamics to industrial situations. Prerequisites: Related Technical Education 118; Physics 113 or 263. Chemistry 121. Three lectures. PRE-ENGINEERING PROGRAM W. Lee Dickson, Coordinator Program: Pre-Engineering Program (Associate of Science Degree Optional) I. General Requirements: A. The Pre-engineering program offers the first two years of the professional engineering curricula for chemical, civil, electrical, mechanical, aeronautical, mining, metallurgical, and geological engineering. B. These two-year curricula are designed to prepare the engineering student to transfer to the junior year of engineering at the senior colleges of engineering in the state of Utah and also to many other professional engineering colleges and universities. C. In planning his program it is important for a student to be aware of certain prerequisites to, and scheduling of, key courses. If the student becomes irregular in his program, he should consult his adviser since improper scheduling of courses can cause some delay in his graduation. D. A grade of C or better is required. II. Specific Requirements: A. Pre-engineering courses required (15 credit hours): Pre-engineering 140 (1), 141 (1), 221 (5), 350 (4), 352 (4). B. Support courses required: Mathematics 107 (5), 211 (5), 212 (5), 213 (5), 320 (5), 371 (4); Chemistry 121 (5), 122 (5). 123 (5); Physics 261 (4), 262 (4), 263 (4), 264 (1), 265 (1), 266 (1); Data Processing 260 (3). PRE-ENGINEERING COURSES 124. Introduction to Digital Electronics (5) A combined lecture-laboratory class which introduces the fundamentals from digital electronics e.g. number systems, codes, combinational logic sequential logic, etc. Prerequisite: Related Technical Education 113 or equivalent (may be taken concurrently). Three hour lectures, two 8-hour labs per week. 140. Engineering Orientation (1) A W S (1) 141. Slide Rule (1) Operation and use of the slide rule. May be taken on an accelerated schedule. Prerequisite: Trigonometry in high school or college. (May be taken concurrently.) AWS 249 |