|
|
|
|
|
|
|
Course Criteria
Add courses to your favorites to save, share, and find your best transfer school.
-
4.00 Credits
Stresses and strains. Torsion. Bending. Beam deflection. Shear force and moment distributions in beams. Yielding and buckling of columns. Combined loading. Transformation of stresses and strain. Yielding criteria. Finite elements analysis of frames. Dynamics of a two-bar truss. Prerequisites: Engineering MAE30 or ENGR30; Mathematics 2J. Same as ENGR150. Only one course from MAE150/ENGR150, ENGRH150, CEE150, and CEEH150 may be taken for credit. (Design units: 2)
-
1.00 Credits
Experimental techniques for the measurement of mechanical properties of materials and structures. Tension, torsion, bending, compression. Determination of strength, stiffness, toughness for metals, polymers, ceramics and composite. Weibull's analysis. Corequisite: MAE150. Prerequisite: MAE30. MAE150L and CEE150L may not both be taken for credit.
-
4.00 Credits
A comprehensive group design project experience that involves identifying customer needs, idea generation, reverse engineering, preliminary design, standards, prototype development, testing, analysis, and redesign of a product involving fluid, thermal, and mechanical components. Introduces design for manufacturing and the environment. Prerequisites: MAE120, MAE145, and MAE170; senior standing. (Design units: 3)
-
4.00 Credits
Elements and principles of computer-aided engineering with modern hardware and software are presented with a design focus. Case studies are used to assist in finite-element method techniques. Prerequisites: ENGR150, MAE120. Formerly MAE152A. (Design units: 2). Not offered every year.
-
4.00 Credits
Motivation for composite materials. Different classifications according to the nature of the matrix (PMC, MMC, CMC) and the reinforcement topology (fibers, whiskers, particulates). Mechanical properties. Failure mechanisms. Designing with composite materials. Advantages and limitations of homogenization techniques for numerical modeling. Prerequisites: ENGR54; MAE150 or CEE150 or ENGR150. Concurrent with MAE255.
-
4.00 Credits
Principles governing structure and mechanical behavior of materials, relationship relating microstructure and mechanical response with application to elasticity, plasticity, yielding, necking, creep, and fracture of materials. Introduction to experimental techniques to characterize the properties of materials. Design parameters. Prerequisites: ENGR54. Same as CBEMS155. (Design units: 2)
-
4.00 Credits
Fundamentals of torsion and bending. Analysis and design of thin-walled and composite beams. Stress analysis of aircraft components. Stiffness, strength, and buckling. Introduction to the Finite Element method and its application to plates and shells. Prerequisite: MAE150 or CEE150 or ENGR150. (Design units: 2)
-
4.00 Credits
Fundamentals of flight theory applied to subsonic propeller and jet aircraft. Nature of aerodynamic forces, drag and lift of wing and fuselage, high-lift devices, level-flight performance, climb and glide performance, range, endurance, take-off and landing distances, static and dynamic stability and control. Prerequisites: MAE130A. (Design units: 2)
-
4.00 Credits
Preliminary design of subsonic general aviation and transport aircraft with emphasis on layout, aerodynamic design, propulsion, and performance. Estimation of total weight and weight distribution, design of wings, fuselage, and tail, selection and location of engines, prediction of overall performance. Prerequisites: MAE112, MAE136, MAE158. (Design units: 4)
-
4.00 Credits
Sources, dispersion, and effects of air pollutants. Topics include emission factors, emission inventory, air pollution, meteorology, air chemistry, air quality modeling, impact assessment, source and ambient monitoring, regional control strategies. Prerequisites: MAE91; MAE130A or CEE170. (Design units: 2)
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Privacy Statement
|
Terms of Use
|
Institutional Membership Information
|
About AcademyOne
Copyright 2006 - 2024 AcademyOne, Inc.
|
|
|