ME - Mechanical Engineering

Lecture session for Fluids Laboratory.

Lecture session for Fluids Laboratory.

Students work with faculty adviser to complete the first phase of a capstone project.

Students work with faculty adviser to complete the second phase of a capstone project.

Introduces graphical communication of engineering design using traditional sketches and drawings coupled with computer modeling. An introduction to engineering drawings, dimensioning, and tolerances. Three dimensional modeling introduced using commercial software. Visualization and manipulation of existing models will be performed by generating drawings, building assemblies, and creating engineering drawings. Fee: $25

Hands-on experience to gain familiarity with common manufacturing and assembly processes for mechanical devices. Fee: $130

Numerical methods applied to engineering problems: interpolation and curve fitting of experimental data, matrix analysis, and approximation methods in structural, thermal, and fluid systems.

Numerical methods applied to engineering problems: interpolation and curve fitting of experimental data, matrix analysis, numerical differentiation/integration, Fourier transforms and approximation methods in structural, thermal, and fluid systems.

Course builds on the concepts learned in strength of materials and introduces finite element analysis (FEA). Topics include elasticity, 3-dimensional Hooke’s law, and failure theories. FEA is introduced mathematically beginning with springs, trusses, and beams. A commercial FEA software package is used to model plane stress and three-dimensional geometry. Individual projects are used to introduce three dimensional analysis. Fee: $40

Course builds on EGR 322. Both analytical and numerical modeling of stresses in tensile, bending, and torsional members. Basics to the Finite Element method (linear static analysis) with and training in computer modeling software, integrated with classical failure theories (Tresca, von Mises, and maximum principle stresses).

An introduction to the modeling and control of mechanical systems in both the time and frequency domain. Fundamentals of vibration, free and forced vibration of (undamped/damped) single degree of freedom systems. Stability, analysis and design of PID, other forms of controllers in time and frequency domains. This course is the lecture portion to accompany the laboratory course ME377.

Application of fluid mechanics principles to laminar and turbulent duct flows; head losses through pipes including minor losses; compressible flows; measurement and turbomachinery.

Theoretical and practical aspects of the design of various machine components and simple systems. The design criteria are based on stress analysis, manufacturing issues, materials, and fatigue considerations.

Classical treatment emphasizing the first and second laws of thermodynamics and their application to open and closed systems undergoing steady and unsteady processes. Tabular and graphical data, as well as ideal gas properties, are used in analytical work.

Application of thermodynamic principles in analyzing power and refrigeration systems, non-reacting gas mixtures, psychrometrics, and combustion.

Fundamental course in the study of heat and mass transfer. Conduction, convection, radiation, and mass transfer are studied in context to real engineering systems involving multiple modes of heat and mass transfer. Numerical solutions are emphasized for the many problems for which analytical solutions cannot be easily obtained.

Theoretical and practical aspects of the design of various machine components and simple systems will be studied. Design criteria are based on stress analysis, manufacturing issues, materials, and fatigue considerations.

An introduction to control systems with an emphasis on industrial motion control. Theoretical and experimental studies will familiarize students with PID control, control system hardware and software, stepper motors, servo motors, sensors, simulation, and data acquisition systems. Fee: $50

Students will conduct a modest sized machine design project to produce solutions that meet specified needs with consideration of public health, safety, and welfare, as well as global, cultural, social, environmental, and economic factors. Students will use both analysis and experimentation to make engineering decisions. Fee: $50

Experimental analysis of fluid mechanics principles including pressure losses through pipes and fittings, pump turbine characteristics, drag force measurements, compressible flow, boundary layers etc. Fee: $50

Experimental analysis of fluid mechanics principles including pressure losses through pipes and fittings, pump turbine characteristics, drag force measurements, compressible flows, boundary layers, etc. Fee: $50

Experimental studies of thermal systems including compressors, steam turbine power cycles, refrigeration, air-conditioning, Otto engine cycle, evaporative cooling towers, and heat exchangers. Fee: $55

An introduction to control systems with an emphasis on industrial motion control. Experimental studies will familiarize students with PID control, control system hardware and software, sensors, actuators, simulation, and data acquisition systems. This course is the lab portion to accompany the lecture course ME 307. Fee: $55

Study of processes and knowledge used to create an engineered product. Topics include design for manufacturing and assembly, materials, and material selection, Lean Manufacturing, and Design of Experiments (DOE) for design and manufacturing.

Dimensional analysis and similitude; applications of fluid flow and thermodynamics to the study of turbomachinery. Characteristics and performance of different types of compressors, turbines, and pumps.

Methods to identify and prevent failures in design and manufacturing. Topics include: applied fracture mechanics, non-destructive testing, root cause analysis, and forensic engineering case studies.

Theory and application of the chemical and physical processes of high temperature chemical reactions. Includes combustion theory (equilibrium and chemical kinetics), fuel chemistry, operational combustion in engines, and environmental effects. 

Analysis and design necessary to plan and specify equipment for heating, refrigeration, and air conditioning systems. Includes heat transfer analysis of the structure, psychrometric analysis of inside and ventilating air, and thermodynamic and economic analysis of the necessary equipment.

Study of renewable energy systems including photovoltaic, wind, geothermal systems, biofuels, and tidal energy. Overview of renewable energy credits, sustainability definitions, life cycle assessment, and exergy assessment techniques.

Systems approach to engineering with application to measurement. Time and frequency analysis of first and second order systems. Calibration, data acquisition, analog to digital conversion, filtering, and modulation will be addressed in both theory and experiment.

Introduction to the operation, analysis, and design of air-breathing and space propulsion engines and systems. Application of thermodynamics, compressible fluid flow and combustion fundamentals to the design of gas turbine and rocket engines and components, including turbomachines, combustors, nozzles and diffusers.

Analysis of the motion of aircraft. Topics include aerodynamics, equations of motion, dynamic and static stability, handling qualities and automatic control for aircraft. Simulation and analysis of aircraft will be performed using Matlab and Simulink.

Analysis and prediction of the dynamic behavior and response of mechanical systems. Various types of oscillations and physical properties such as damping and stiffness are explained.

Industrial application of noise control criteria, measurements, materials, and design. Vibration control is comprised of source identification, system isolation, and testing. Extensive laboratory program also includes spectral and signal analysis. Fee: $50

A major design experience based on the knowledge and skills acquired in earlier course work and incorporating appropriate standards and multiple realistic constraints. Projects have some combination of the following characteristics: realism, communication, exposure, teamwork, learning, and related opportunities.

Continuation of a major design experience based on the knowledge and skills acquired in earlier course work and incorporating appropriate standards and multiple realistic constraints. Projects have some combination of the following characteristics: realism, communication, exposure, teamwork, learning, and related opportunities.

Selected study or project in mechanical engineering for upper-division students. Must be arranged between the student and an individual faculty member and subsequently approved by the dean of engineering. No more than three hours of directed study taken at the University may be used for elective credits to satisfy degree requirements.

Credit arranged.

Credit arranged.

Faculty-directed student research. Before enrolling, a student must consult with a faculty member to define the project. May be repeated for credit.

Study of processes and knowledge used to create an engineered product. Topics include design for manufacturing and assembly, materials, and material selection, Lean Manufacturing, and Design of Experiments (DOE) for design and manufacturing. Special project to be completed.

Advanced dimensional analysis and similitude; advanced applications of fluid flow and thermodynamics to the study of turbomachinery. Characteristics and performance of different types of compressors, turbines, and pumps. Special project required. Knowledge of fundamental fluid mechanics required.

Study of failures in design and manufacturing with methods to identify and prevent them. Topics include: applied fracture mechanics, non-destructive testing, root cause analysis, and forensic engineering case studies. Knowledge of metallurgy or materials science, and fundamental stress analysis is required. Special project required.

Theory and application of the chemical and physical processes of high temperature chemical reactions. Advanced topics in combustion theory (equilibrium and chemical kinetics), fuel chemistry, operational combustion in engines, and environmental effects. Basic knowledge thermodynamics and chemistry is required.

Analysis and design necessary to plan and specify equipment for heating, refrigeration, and air conditioning systems. Includes heat transfer analysis of the structure, psychrometric analysis of inside and ventilating air, and thermodynamic and economic analysis of the necessary equipment.  Applied knowledge of thermodynamics required, including thermodynamics properties and psychrometrics.

Advanced study of renewable energy systems including photovoltaic, wind, geothermal systems, biofuels, and tidal energy. Study of renewable energy credits, sustainability definitions, life cycle assessment, and energy assessment techniques. Applied knowledge of physics and thermodynamics required, including thermodynamics properties, entropy, and exergy.

Systems approach to engineering with application to measurement. Time and frequency analysis of first and second order systems. Calibration, data acquisition, analog to digital conversion, filtering, and modulation will be addressed in both theory and experiment. Students will complete a project on advanced topics. Knowledge of engineering dynamics required.

Introduction to the operation, analysis, and design of air-breathing and space propulsion engines and systems. Application of thermodynamics, compressible fluid flow and combustion fundamentals to the design of gas turbine and rocket engines and components, including turbomachines, combustors, nozzles and diffusers. Includes a propulsion system design project. Prior knowledge of fluid mechanics, thermodynamics required.

Analysis of aircraft motion. Topics incl. aerodynamics, equations of motion, dynamic and static stability, handling qualities and automatic control for aircraft. Simulation and analysis of aircraft will be performed using Matlab/Simulink. Grad level students must research a topic related to aircraft independently and present in a lecture to the class. Prior knowledge in dynamics, numerical methods and mechanical systems required.

Analysis and prediction of the dynamic behavior and response of mechanical systems. Various types of oscillations and physical properties such as damping and stiffness are explained. Students will work a project on advanced topics. Knowledge of engineering dynamics and differential equations required.

Industrial application of noise control criteria, measurements, materials, and design. Vibration control is comprised of source identification, system isolation, and testing. Extensive laboratory program also includes spectral and signal analysis. Students will work on a project on advanced topics. Knowledge of engineering dynamics and differential equations required. Fee: $50

Credit arranged.

Credit arranged.

Credit arranged.

Faculty-directed student research. Before enrolling, a student must consult with a faculty member to define the project. May be repeated for credit.

Credit arranged.