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Show Technology Technology Department of Industrial and Manufacturing Engineering Technology A. Kent Randall, Chairman Professor, A. Kent Randall; Associate Professors, Dale S. Cowgill, Clifton B. Larson; Assistant Professor, Robert Wal- lentine; Instructors, Newell S. Crookston, Kent Robertson, C. Austin Seager. INDUSTRIAL ENGINEERING TECHNOLOGY The Industrial Engineering Technology program prepares the student for industrial employment in the areas of methods improvement, work measurement, plant engineering, materials handling, estimating, and production and quality control. He will use industrial engineering techniques, statistics and applied mathematics, and the computer to aid in the development, control, and reduction of production costs so as to insure a successful and profitable operation of manufacturing companies. The curriculum provides the essential engineering, scientific and technical knowledge to perform in the above described job classifications. Department Major—In addition to the general requirements for graduation from Weber State College the following courses, passed with a grade of "C" or better, are required for the department major. Bachelor of Science Degree—Engineering 1, 2, 41; Industrial Drafting 51; Physics 61, 62, 63, 64, 65, 66; Mathematics 18, 21, 51, 52, 54, 121; Chemistry 24, 25; Journalism 126; Manufacturing Engineering Technology 21, 66, 70, 170, 171, 172, 173, 176, 177, 191; Industrial Engineering Technology 130, 131, 132, 134, 142, 144, 160, 181, 182; Welding 165; Electronics 141, 142, 143; Management 172; Data Processing 67, 75. Courses of Instruction Students wishing to major in Industrial Engineering Technology may complete the lower division requirements by completing the engineering curriculum offered by the Department of Engineering. Lower Division courses for this curriculum may be selected from the Engineering Department and are not listed here. 130. Applied Mechanics—Statics—Analytical study of bodies at rest, force systems, components, resultants; centroids equilibrium; force analysis of structures; friction; moment of inertia. Prerequisite: Technical Education 18 or equivalent, Physics 51, 54. Three lectures. A (3) Wallentine 131. Applied Mechanics—Dynamics—Analytical study of the geometry of motion and the forces required to produce or change motion, kinematics, kinetics, displacements, velocity, acceleration, work and energy, impulse and momentum, mechanical vibrations—causes and effects. Prerequisite: Industrial Engineering Technology 130. Three lectures. W (3) Wallentine 132. Strength of Materials—Relation of physical properties of matter of geometric properties of form, stress and strain, beams, columns, welded and riveted joints, combined loadings. Prerequisite: Industrial Engineering Technology 131. Three lectures. S (3) Wallentine 134. Applied Hydraulics and Pneumatics—Principles of fluid mechanics as they apply to hydraulic and pneumatic design. Designing systems" for liquids and gases. Prerequisites: Technical Education 17, Physics 53, 56. Three lectures. S (3) Wallentine 142. Methods Engineering—Fundamental principles, procedures and techniques used in the design and measurement of work methods. Three lectures. Prerequisite: Technical Education 17. W (3) Randall 144. Plant Planning and Materials Handling—Arrangement and layout of equipment and processes in an industrial plant for the most economic production. Prerequisite: Technical Education 17. Two lectures. S (2) Robertson 160. Reliability—Principles and practices of management, design, control, and statistical demonstration. Prerequisite: Technical Education 17. Three lectures. A (3) Randall 181. Kinematics—Applied analysis of displacement, velocity and acceleration in mechanisms by graphical and analytical methods; velocity and acceleration polygons and diagrams; kinematic design of cams, belts, gearing, gear trains and miscellaneous mechanisms. Prerequisite: Industrial Engineering Technology 131. Three lectures. W (3) Wallentine 182. Thermodynamic Systems—Application of the laws, concepts, and procedures of thermodynamics, heat transfer, and gas dynamics to the basic engine cycles, including: piston and turbine engines, expanders and compressors, and other apparatus. Both analytical and experimental approaches. Three lectures. Prerequisites: Technical Education 17, Physics 53, 56, Chemistry 5. S (3) Wallentine 286 287 |