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Show Technology Welding WELDING COURSES 101. Oxyacetylene Proceses (5) Skill in welding, cutting, hard-facing, surface-bonding, testing, and inspection of sheet and plate steel welding as applied to the American welding standards. Five 2-hour labs a week. A 102. Principles of Gas Welding (5) Oxyacetylene processes, including fusion of mild steels, surface bonding of the non-ferrous alloys, cutting techniques, and the safety factors with respect to gas welding. Five lectures. A 103. Electric Welding Processes (5) Structural joint designs, hard surfacing, testing, and inspection of arc welding. Five 2-hour labs a week. W 104. Principles of Arc Welding (5) Electric arc welding processes; fusion of steels, hard-facing of ferrous and non-ferrous alloys, fundamentals of electrode design, and safety factors involved in the arc welding process. Five lectures. W 105. Inert Welding Processes (5) Inert gas welding of nonferrous metals such as stainless steel and aluminum alloys emphasizing testing and inspection requirements of the American Welding Standards. Five 2-hour labs a week. S 106. Principles of Inert Welding (5) Non-ferrous alloys and their weldability; construction and maintenance of the inert welding machine. Five lectures. S 115. Welding Blueprint Reading (2) Interpretation and application of blueprint reading; estimation and cost of materials and structural design as it applied to welding in industry. For majors. One lecture and one 3-hour lab a week. S 165. Welding Processes (2) Principles and practices in the fundamentals of arc and acetylene welding for those students in related fields; fusion welding of sheet and plate ferrous metals. Two 3-hour labs a week. A W S 251. Gas Fusion Processes (5) Non-ferrous alloys and the newer developments in weld metals and their fluxes. Testing and inspection as required by American welding standards. Prerequisites: Welding 101 and 102. Five 3-hour labs a week. A 252. Principles of Gas Fusion (5) Current developments in the oxyacetylene welding process; research and experimental work involved in a new industrial technique. Five lectures. A 253. Advanced Arc Welding Processes (5) Principles and applications of advanced arc welding; weldability of ferrous and the non-ferrous metals, design, and cost estimating; inspection and testing. Field trips to Utah's leading industrial areas. Prerequisites: Welding 103-104. Five 3-hour labs a week. W 255. Testing and Inspection (5) Industrial tests and inspection required to meet industrial standards. Prerequisite: Manufacturing Engineering Technology 236. Two lectures and three 3-hour labs a week. S 292. Short Courses, Workshops, Institutes and Special Programs (1-6) In order to provide flexibility and to meet many different needs, a number of specific offerings are possible using this catalog number. When the number is used it will be accompanied by a brief and specific descriptive title. The specific title with the credit authorized for the particular offering will appear on the student transcript. A W S Su 360. Welding Manufacturing Processes (3) Welding process selection, production planning, tooling and quality control. One lecture and two labs. 365. Advanced Welding Processes (2) A composite of arc and acetylene welding for students in related fields. Two research papers on advanced fabrication and design are required. Two 3-hour labs a week. A W S MANUFACTURING ENGINEERING TECHNOLOGY PROGRAM This curriculum is designed to give the student fundamental comprehension of, and basic skill in, the planning and selection of the methods of manufacturing, the design of tooling and equipment for manufacturing, the selection and treatment of materials used in manufacturing, and in the use of computers in manufacturing. In application, development of process sheets, equipment specification and installation, tool design, value analysis, production and quality control, and a coordination with the design and production functions. A Manufacturing Engineering Technology degree with emphasis in the Industrial Engineering area is also offered by the department. The objective is to train students to perform successfully the industrial engineering functions such as methods analysis, work simplification, time standards development, plant layout, materials handling equipment design and selection, cost analysis, and cost reduction. 272 Technology Manufacturing Engineering Technology- Program: Manufacturing Engineering Technology Bachelor Degree I. General Requirements: A. Specific course requirements of the college (see index). B. Bachelor Degree General Education requirements (see index). C. A minor is not required. D. Manufacturing Engineering Technology majors must have a C or better in major courses. E. An overall G. P. A. of 2.00 or C. F. A total of 202 hours are required. G. Sixty of the 202 hours must be upper division (courses numbered 300 and above). II. Specific Requirements: A. Engineering Technology Core Requirements (93 credit hours). B. Manufacturing Engineering Technology courses required (26 credit hours): Manufacturing Engineering Technology 123 (3), 132 (3), 231 (2), 232 (2), 244 (3), 301 (3), 302 (3), 331 (3), 452 (2), 499 (2). C. Technical courses required (35 credit hours): Machine Tool 100 (1), 101 (2), 102 (1), 103 (2), 202 (1), 203 (2); Engineering Graphics 245 (3); Welding 360 (3); Industrial Engineering Technology 142 (3), 350 (2), 351 (3), 401 (3); Automotive Engineering Technology 420 (3); Engineering Technology 314 (3), 334 (3). D. Support course required (5 credit hours). Economics 101 (5). E. Electives (select 6 credit hours): Manufacturing Engineering Technology 246 (3); Industrial Engineering 331 (3), 342 (3), 360 (3), 458 (3); Engineering Technology 472 (3). MANUFACTURING ENGINEERING TECHNOLOGY COURSES 123. Machine Tool Performance (3) Determining cutting tool forces and efficiency through proper selection and application of tool material, tool geometry and coolants. Prerequisites: Machine Tool 103. Related Technical Education 115. One lecture and two 3-hour labs. 132. Inspection and Testing (3) Basic principles and applications of inspection and testing methods and equipment to determine dimensional, physical and chemical properties of materials and fabricated parts. Two lectures and one three hour lab. 189. Cooperative Work Experience (1-9) Open to all first year students in Manufacturing Engineering Technology. The course objectives for each student will be developed between the student, the department and a suitable employer providing the opportunity for on-the-job experience. Evaluation of course participants will be shared between the employer, student and the department. A W S Su 231. Metal Forming: Manufacturing Processes (2) Metal forming process selection, production planning, tooling and quality control. One lecture and one lab. 232. Casting Manufacturing Processes (2) Casting Process Selection, production planning, tooling and quality control. One lecture, one lab. 244. Numerical Control in Manufacturing (3) N/C advantages, costs, applications, manual programming. Prerequisite: Machining experience. Related Technical Education 115. Two lectures, one lab. A 246. Numerical Control Programming (3) Computer Programming for numerically controlled machines using AD-APT language. Prerequisite: Manufacturing Engineering Technology 244. Three lectures. W S 247. Numerical Control Programming (3) Computer Programming or numerically controlled machines using APT (Automatic Programmed Tools) language. Prerequisites: Manufacturing Engineering Technology 246, Related Technical Education 117. Three lectures. W S 289. Cooperative Work Experience. (1-9) Open to all second year students in Manufacturing Engineering Technology. A continuation of Manufacturing Engineering Technology 189. A W S Su 273 |
