MECHANICAL ENGINEERING TECHNOLOGY (ETME)

ETME 1101. Manufacturing Processes. (3) This course surveys and introduces common manufacturing processes and design for manufacture considerations. Student will be introduced to methods and equipment used to transform materials, and to the interdependency between geometry (form), materials properties, and processes and their effects on functionality of the manufactured artifact. Coverage will include processing of polymers, metals, and ceramics. The purpose of this course is to provide the students the conceptual understanding of materials processes.

ETME 2101. Applied Materials. (3) Prerequisite: MATH 1103. This course introduces the student to materials and to the concept that materials are designed to provide the desired properties in the same way that the parts themselves are designed. The students will learn to understand that the processes we use to change materials into the geometries we want for also change the properties of the materials. The course intends to approach materials from a design and manufacturing perspective.

ETME 2102. Mechanisms. (3) Prerequisites: ETGR 1103, PHYS 1101. This course covers plane motion and devices used to generate plane motion. Topics include analysis of displacement, velocity, acceleration, gears, cams and other mechanical systems. (Spring)

ETME 2156. Machine Shop Practices. (2) Prerequisite: ETGR 1103. This course introduces students to machine shop techniques and designing for machining with a combination of lectures and projects. Students will learn design for machining guidelines, about specification of machining operations, and about shop measurement instruments and techniques. (Spring)

ETME 2156L Machine Shop Practices Lab. (1) See ETME 2156. (Spring)

ETME 2202. Introduction to Mechanical Design. (2) Prerequisites: ETGR 1104, ETGR 1201. This course introduces mechanical design techniques using computer based parametric modeling tools such as Autodesk Inventor. Topics include feature based solid modeling, design constraints, assemblies, mechanisms, animations, and design documentation via technical drawings. Proficiency is demonstrated by an end-of-term design project. (Fall)

ETME 3113. Dynamics. (3) Prerequisites: MATH 1121, ETGR 2101, and ETME 2102. The dynamic behavior of particles; translation, rotation and plane motion of a rigid body, the principles of conservation of energy and momentum.

ETME 3123. Strength of Materials. (3) Prerequisites: ETGR 2101 with a C or better. Corequisite: MATH 1121. Stress strain relationships resulting from direct loads, torsional loads and bending loads, and the results obtained from applying more than one of these loads simultaneously. Beam deflection and column loading.

ETME 3133. Fluid Mechanics. (3) Prerequisite: ETGR 2101. Fundamental principles of fluid mechanics. Topics include manometry, buoyancy, forces on submerged bodies, boundary layers, flow over surfaces, Bernoulli's equation with applications, orifices, pipe losses and an introduction to hydrodynamics.

ETME 3143. Thermodynamics. (3) Prerequisites: MATH 1121. Fundamentals of thermodynamics including work and heat; classical approach to first and second laws of thermodynamics; ideal gas, entropy, reversibility, irreversibility, and study of various processes and cycles.

ETME 3151. Fluid Mechanics Laboratory. (1) (W) Prerequisite or corequisite: ETME 3133. Flow through conduits and in open channels, the experimental determination of fluid specific weights, viscosity and flash and fire points. Flow measuring devices such as orifices, venturi tubes, anemometers and pitot tubes. Laminar turbulent flow and stability.

ETME 3152. Stress Analysis Laboratory. (1) (W) Prerequisite or corequisite: ETME 3123. Experiments illustrating stress strain relationships in engineering materials and the use of brittle coating, photoelasticity and electrical resistance strain gages.

ETME 3163. Instrumentation and Controls. (3) Prerequisite: ETGR 2106. Introduction to instrumentation for measurement and control of physical variables, with emphasis on electronic systems. Review of basic circuit analysis, electrical instruments, sensors and measurement principles and a survey of automatic controls from a systems point of view.

ETME 3213. Machine Design I. (3) Prerequisite: ETME 2101, ETME 3123. Analysis and design of clutches, brakes, belts and roller chain. Indeterminate normal loading, superposition of stresses and deflections, compound stresses, columns and fatigue. Theories of failure. Shaft design, deflections of shafts with nonuniform moments of inertia involving computer verification. Antifriction bearings, engineering materials, helical compression springs. Small mechanical component and system designs.

ETME 3223. Machine Design II. (3) Prerequisite: ETME 3213. A continuation of ETME 3213 with emphasis on new methods of problem solving and opportunities to integrate previously attained skills and knowledge into the design and optimization of small machine systems. (On demand)

ETME 3232. Senior Design Project I. (2) (W) Prerequisites: ETME 3113, 3133, and 3143. Corequisite or prerequisite: ETME 3213 or permission. First of a two-semester course sequence in which each student proposes and implements a senior-level design project which demonstrates abilities as developed by the coursework taken thus far. Each student uses project planning techniques to complete a project proposal and plans and makes substantial progress toward implementation in the first semester and completes the project, including design evaluation during the second semester. One class hour and three lab hours per week.

ETME 3242. Senior Design Project II. (2) Prerequisite: ETME 3232. Pre- or corequisite: ETME 3163. Second of a two-semester course sequence in which each student proposes and implements a senior-level design project which demonstrates abilities as developed by the coursework taken thus far. Each student uses project planning techniques to complete a project proposal and plans and makes substantial progress toward implementation in the first semester and completes the project, including design evaluation during the second semester. One class hour and three lab hours per week.

ETME 3244. Applied Heat Transfer. (3) Prerequisites: ETME 3133. Basic principles of heat transfer. Theory and applications of conduction, free and forced convection and radiation heat transfer. Heat exchangers and heat transfer measurement. (Fall)

ETME 3251. Instrumentation Laboratory. (1) (W) Prerequisite or corequisite: ETME 3163. Practice in the use of the various instrumentation devices studied in ETME 3163.

ETME 3252. Thermodynamics and Heat Transfer Laboratory. (1) (W) Prerequisite or corequisite: ETME 3143. Experimentation involving the fundamental principles of thermodynamics and heat transfer, as applied to internal combustion engines, steam engines, engine dynamometers, refrigeration and heat pumps, solar energy systems, and heat exchangers. Three laboratory hours per week.

ETME 3263. Fluid Power. (3) Prerequisite: ETME 3133. Mechanical and fluid power and the conversion of one to the other. Components and system efficiencies including those consisting of cascaded components. Performance evaluation of such hydraulic components as pumps, motors, valves and metering devices. Viscosity, bulk modulus, noise, optimum performance and system design will be considered. (On demand)

ETME 3273. Air Conditioning Systems. (3) Prerequisite: ETME 3143. Functions and operating characteristics of the major components of refrigerating machines, heat pumps, boilers, furnaces, solar collectors, heat exchangers, fans and pumps. Emphasis on sizing, economics and performance characteristics. Includes coverage of psychometric principles and fan and pump laws. (On demand)

ETME 3283. Modern Techniques in Energy Conservation and Utilization. (3) Prerequisite: ETME 3143 or permission of the instructor. Survey of current topics that may include solar energy, basic nuclear reactor technology, ammonia based Rankine cycle, absorption refrigeration cycle, heat pump cycle, techniques for energy conservation in new construction and techniques for retrofitting existing energy utilization systems. (On demand)