ME - Mechanical Engineering
Lecture session for Fluids Laboratory.
0
Corequisites
ME 374
Lecture session for Thermodynamics Laboratory.
0
Corequisites
ME 376
This course introduces graphical communication of engineering design using traditional sketches and drawings coupled with computer modeling. An introduction to engineering drawings, dimensioning, and tolerances will be provided. Three dimensional modeling will be introduced using commercial software. Visualization and manipulation of existing models will be performed by generating drawings, building assemblies, and creating engineering drawings.
2
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. First offering in spring 2015, replaces
ME 111.
2
Numerical methods applied to engineering problems: interpolation and curve fitting of experimental data, matrix analysis, and approximation methods in structural, thermal, and fluid systems.
2
Prerequisites
CS 201 or
EGR 111.
This course builds on the concepts learned in strength of materials and introduces finite element analysis (FEA). 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.
3
Prerequisites
EGR 322,
ME 111
Basic properties of a fluid, problems in hydrostatics. The general equations of fluid motion. Boundary layer concepts. Application to a variety of laminar and turbulent incompressible flow situations. The technique of dimensional analysis is introduced.
3
Prerequisites
EGR 212 or
EGR 213
Application of fluid mechanics principles to laminar and turbulent duct flows; head losses through pipes including minor losses; compressible flows; measurement and turbomachinery.
2
Prerequisites
ME 311 or
EGR 311.
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. First offering in spring 2016, replaces
ME 401.
4
Prerequisites
EGR 221,
EGR 322.
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.
3
Prerequisites
MTH 202
Application of thermodynamic principles in analyzing power and refrigeration systems, non-reacting gas mixtures, psychrometrics, and combustion.
2
Prerequisites
CHM 207,
ME 331
Conduction, convection, and radiation heat transfer are studied in detail. Real engineering problems and systems involving more than one of these modes are analyzed. Numerical solutions are emphasized for the many problems for which analytical solutions cannot be found.
3
Prerequisites
ME 331
Manufacturing properties of engineering materials. Casting, forging, forming, and joining processes. Conventional and non-conventional material removal processes. Powder metallurgy and coatings. An introduction to the concept of intelligent processing of materials.
3
Prerequisites
EGR 221,
EGR 322
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.
2
Prerequisites
EGR 212,
MTH 321 or corequisite.
Corequisites
MTH 321 or prerequisite.
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: $40.
1
Corequisites
ME 312,
ME 074.
Experimental studies of thermal systems including compressors, steam turbine power cycles, refrigeration, air-conditioning, Otto engine cycle, evaporative cooling towers, and heat exchangers. Fee: $40.
1
Prerequisites
ME 332
Corequisites
ME 076
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.
4
Prerequisites
EGR 221,
EGR 322
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.
3
Prerequisites
Upper division standing.
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.
3
Prerequisites
ME 311 or
EGR 311.
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.
3
Prerequisites
EGR 221,
EGR 322
An overview of different types of composite materials; processing and performance characteristics of matrix and reinforcements and their interactions; micromechanics and macromechanics of composites at the lamina and laminate levels; fatigue, creep, and fracture behavior of composites. A project is required as part of the course.
3
Prerequisites
EGR 221,
EGR 322.
Review of different types of welding power sources, processes, and types of electrodes/wires. Basic welding metallurgy, weld joint design, and NDE techniques. A project on weldment analysis is required.
3
Prerequisites
EGR 221
Review of theoretical and experimental techniques of strain and stress analysis with emphasis on electrical strain gauges, brittle coatings, grid methods, and photoelasticity techniques. A project is required involving stress analysis of a component/structure utilizing one or more of the above techniques. Fee: $40.
3
Prerequisites
EGR 322
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.
3
Prerequisites
ME 331,
ME 332 or corequisite,
ME 336 or corequisite.
Corequisites
ME 332 or prerequisite,
ME 336 or prerequisite.
Review of the analysis and design of components of thermal systems such as heat exchangers, pumps and blowers, and drive units. Review of computer methods for analyzing systems. At least two design projects applying thermal systems design procedures will be completed.
3
Prerequisites
ME 332,
ME 336
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.
3
Prerequisites
ME 331
Manufacturing properties of engineering materials. Casting, forging, forming, and joining processes. Conventional and non-conventional material removal processes. Powder metallurgy and coatings. An introduction to the concept of intelligent processing of materials.
3
Prerequisites
EGR 221,
EGR 322
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.
3
Prerequisites
EGR 212
Project oriented course that introduces advanced CAD design, including surfacing as well as rapid prototyping, computer numeric control, and programmable logic controllers. Topics include theory behind these concepts and devices, solid modeling, 3-D model data exchange, slicing and offsetting algorithms, and programming such as numerical control of a mill. Fee: $40.
3
Prerequisites
ME 351
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.
3
Prerequisites
EGR 212,
MTH 321
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: $40.
3
Prerequisites
EGR 212 or
EGR 213 or
EGR 214.
Materials science of living structures and biomedical devices; mechanical behavior and failure mechanisms of biomaterials; medical device application and design; interactions between the biomaterials and biological systems; special topics such as tissue engineering and mechano-biology.
3
Prerequisites
Upper division standing.
Course will cover a variety of biomechanical analysis and instrumentation topics such as skeletal anatomy, ergonomics, and exercise physiology. Methods for measuring and computing force and movement will be covered. Laboratory exercises will be used to demonstrate instrumentation including motion capture, force plates, EMG, ECG, heart rate monitors, accelerometers, and goniometers.
3
Prerequisites
EGR 212 or
EGR 213 or
EGR 214.
Students are required to do design projects including literature search, engineering analysis, and written and oral presentations. These projects are a culminating experience in the mechanical engineering program. Group projects and construction of prototypes is encouraged, where feasible. Fee: $40.
2
Prerequisites
Upper division standing.
Students are required to do design projects including literature search, engineering analysis, and written and oral presentations. These projects are a culminating experience in the mechanical engineering program. Group projects and construction of prototypes is encouraged, where feasible. Fee: $40.
2
Prerequisites
Upper division standing.
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. First offering in fall 2016. Fee: $40.
2
Prerequisites
EGR 300
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. First offering in spring 2017. Fee: $40.
3
Prerequisites
ME 483
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.
Variable
Faculty-directed student research. Before enrolling, a student must consult with a faculty member to define the project. May be repeated for credit.
1-3
Prerequisites
Upper division standing.
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.
3
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.
3
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.
3
An overview of different types of composite materials; processing and performance characteristics of matrix and reinforcements and their interactions; micromechanics and macromechanics of composites at the lamina and laminate levels; fatigue, creep, and fracture behavior of composites. A project is required as part of the course.
3
Review of different types of welding power sources, processes, and types of electrodes/wires. Basic welding metallurgy, weld joint design, and NDE techniques. A project on weldment analysis is required.
3
Review of theoretical and experimental techniques of strain and stress analysis with emphasis on electrical strain gauges, brittle coatings, grid methods, and photoelasticity techniques. A project is required involving stress analysis of a component/structure utilizing one or more of the above techniques. Fee: $20.
3
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.
3
Review of the analysis and design of components of thermal systems such as heat exchangers, pumps and blowers, and drive units. Review of computer methods for analyzing systems. At least two design projects applying thermal systems design procedures will be completed.
3
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.
3
Manufacturing properties of engineering materials. Casting, forging, forming, and joining processes. Conventional and non-conventional material removal processes. Powder metallurgy and coatings. An introduction to the concept of intelligent processing of materials.
3
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.
3
Project oriented course that introduces advanced CAD design, including surfacing as well as rapid prototyping, computer numeric control, and programmable logic controllers. Topics include theory behind these concepts and devices, solid modeling, 3-D model data exchange, slicing and offsetting algorithms, and programming such as numerical control of a mill. Fee: $30.
3
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.
3
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: $20.
3
Materials science of living structures and biomedical devices; mechanical behavior and failure mechanisms of biomaterials; medical device application and design; interactions between the biomaterials and biological systems; special topics such as tissue engineering and mechano-biology.
3
Course will cover a variety of biomechanical analysis and instrumentation topics such as skeletal anatomy, ergonomics, and exercise physiology. Methods for measuring and computing force and movement will be covered. Laboratory exercises will be used to demonstrate instrumentation including motion capture, force plates, EMG, ECG, heart rate monitors, accelerometers, and goniometers.
3
Faculty-directed student research. Before enrolling, a student must consult with a faculty member to define the project. May be repeated for credit.
1-3