Mechanical Engineering
Head: Azim Eskandarian
William S. Cross Professor: D. K. Tafti
George R. Goodwin Professor: R. Pitchumani
Robert E. Hord, Jr. Professor: S. Priya
Samuel P. Langley Professor: C.R. Fuller
W. Martin Johnson Professor: A.J. Kurdila
Chris C. Kraft Professor of Engineering: W. F. Ng
J. Bernard Jones Professor: W.F. O'Brien
Rolls Royce Professor: S. Ekkad
L. S. Randolph Professor: R. G. Parker
Dan Pletta Professor: M. Ahmadian
Professors: M. Ahmadian, F. Battaglia, R.A. Burdisso, H. Chelliah, T.E. Diller, S. Ekkad, A. Eskandarian, C.R. Fuller, T. Furukawa, A. Haghighat, W. Hardy, J.M. Kennedy, A.J. Kurdila, R.L. Mahajan, D.J. Nelson, W.F. Ng, W.F. O'Brien, R. Parker, M.R. Paul, R. Pitchumani, S. Priya, C. Sandu, D.K. Tafti, S. Taheri, and M.R. von Spakovsky
Associate Professors: J. Bayandor, B. Behkam, P. Ben-Tzvi, J.H. Bøhn, J. Cheng, C.L. Dancey, W. Deng, M.W. Ellis, J.B. Ferris, S. Huxtable, M.E.F. Kasarda, K.B. Kochersberger, A.A. Kornhauser, A. Leonessa, R. Müeller, A.S. Nain, R. Qiao, M.J. Roan, S.C. Southward, B. Vick, R.L. West, A.L. Wicks, C.B. Williams, and L. Zuo
Assistant Professors: A. Asbeck, C. Hin, L. Li, Z. Li, Y. Liu, R. Mirzaeifar, P. Tarazaga, Z. Tian, and X. Zheng.
Associate Professor of Practice: R. Ott, M.A. Pierson, and L. Vick
Professors Emeritus: L.J. Arp, R.A. Comparin, N.S. Eiss, R.E. Hedgepeth, C.J. Hurst, J.B. Jones, R.G. Kirk, R.G. Leonard, J. R. Mahan, L.D. Mitchell, R. Mitchiner, J. Moore, A. Myklebust, T.F. Parkinson, F.J. Pierce, J.R. Thomas, W.C. Thomas, and R.J. Whitelaw
Adjunct Professors: R. Anderl (TU Darmstadt), P.G. Brolinson (Edward Via College of Osteopathic Medicine), D. Carlson (Lord Corp.), J. Funk (Biodynamic Research Corp.), M.J. Hampe (TU Darmstadt), T. Kress (BEST Engineering), D. Rabe (Air Force Research Lab), and B. Sanders (Air Force Research Lab)
Web: www.me.vt.edu
Nature of the Profession
Mechanical engineering is the broadest of the engineering professions. Because of the breadth of the ME discipline, mechanical engineers work in a wide variety of technical areas and are employed in a range of job functions. Specialty areas within the mechanical engineering discipline include, among many others, acoustics, biomechanics, CAD, controls, energy conversion and energy management, HVAC, materials, mechanical design, mechatronics, nuclear engineering, robotics and automation, and turbomachinery. The actual job functions which mechanical engineers perform vary widely as well. ME's work in design, research and development, manufacturing, service and maintenance, as well as technical sales, in almost every industry. Many are in management and administration. Many mechanical engineering graduates go on to more advanced degrees, or continue their education in other fields, such a law or business.
Employment Opportunities
Because of the diversity and breadth of the mechanical engineering profession, ME graduates find employment in a wide variety of industries, laboratories, and consulting firms. This results in a relatively stable job market that is not dependent upon a single particular industry. The textile, petroleum, chemical, electronic, automotive, aerospace, power generation, HVAC, and manufacturing industries hire large numbers of mechanical engineering graduates and the starting salaries for ME's are very competitive with the other engineering disciplines.
Because of the wide diversity of specialties and job functions any two mechanical engineers might have significantly different day-to-day activities and responsibilities. Some may be concerned with very large engineering systems while others are working with small and even microscale devices and components; some work might call for highly analytical or mathematical approaches while other work might be more amenable to experimental or empirical approaches. Mechanical engineers may be involved in the operation of processing plants, or the design of engines, prosthetic devices, steam and gas turbines or compressors and pumps, alternative fuel devices, and many other devices and systems. At Virginia Tech there is a close association between the ME departments research and design project activities with industry. This enhances the opportunities for student interaction with industry representatives.
Mechanical Engineering Program Educational Objectives
Within a few years after graduating from the Mechanical Engineering Department at Virginia Tech, the graduates will attain:
- Positions where they utilize fundamental technical knowledge and skills in mathematics, science, and engineering to analyze and solve problems, and apply these abilities to generate new knowledge, ideas or products in academia, industry or government.
- Practical experience and organizational skills, enabling them to interact and communicate effectively (written and/or oral) with others (e.g., supervisor, client and/or team) with regard to the diversity of the stakeholders involved in their work.
- Roles of increasing responsibility leading to leadership positions that benefit themselves, their employers and society.
- Skills in life-long learning through: (a) self-study, (b) continuing education/short courses or workshops, and/or (c) formal graduate level education, and encourages co-workers to have this same motivation.
- Roles in professional and personal life where they demonstrate professional and ethical responsibilities toward peers, employers, and society and follow these precepts in their daily lives.
Program Outcomes
We expect our students to have the following skills, knowledge, and behaviors by the time of their graduation. We want our students to attain:
- an ability to apply knowledge of mathematics, science, and engineering
- an ability to design and conduct experiments, as well as to analyze and interpret data
- an ability to design a system, component, or process to meet desired needs within realistic constraints such as economic, environmental, social, political, ethical, health and safety, manufacturability, and sustainability
- an ability to function on multi-disciplinary teams
- an ability to identify, formulate, and solve engineering problems
- an understanding of professional and ethical responsibility
- an ability to communicate effectively
- the broad education necessary to understand the impact of engineering solutions in a global and societal context
- a recognition of the need for, and an ability to engage in life-long learning
- a knowledge of contemporary issues
- an ability to use the techniques, skills, and modern engineering tools necessary for engineering practice.
The Bachelor of Science in Mechanical Engineering (BSME) degree program at Virginia Tech is accredited by the Engineering Accreditation Commission of ABET, www.abet.org.
One important objective of the Department of Mechanical Engineering is to ensure that every mechanical engineering graduate has the knowledge, ability, and understanding required to meet the basic ABET guidelines. The structure and sequence of courses is designed to provide these requirements for every graduate. The department is committed to providing students with an exceptional experience in both the theory and practice of mechanical engineering. In the senior capstone sequence, students are required to apply classroom knowledge to complex engineering problems requiring teamwork, problem formulation, economic analysis, effective communication, and product realization. These projects are carefully selected and updated to ensure relevancy to contemporary technical issues and needs. The department encourages the involvement of underclass students and students outside the department and college in these projects. The department also encourages hands-on student involvement by providing dedicated machine and welding shops that exclusively serve the undergraduate program. The required sophomore-level Manufacturing Processes Laboratory course and certification by a professional machinist are required prior to use of either of these shops. Opportunity for professional development is provided by participation in student professional organizations, such as the American Society of Mechanical Engineers, ASME, and the American Nuclear Society, ANS.
The Curriculum
A total of 131 semester credits are required for graduation. Please refer to the Registrar's website for official program checksheets showing the graduation requirements and recommended course plans. Unofficial documents are available on the ME website showing prerequisite relationships to courses and alternative course plans (e.g. for co-op students and military 4.5 and 5-year plans). www.me.vt.edu/academic-programs/undergraduate-program/current-students/course-selection/#requiredcourses
The ME curriculum provides a strong foundation in the basic physical and chemical sciences and in mathematics. These are followed by a sequence of courses that provide a broad background in design methodology, computer programming, electronics, solid and fluid mechanics, manufacturing processes, system modeling, machine design, thermodynamics, heat and mass transfer, statistics and materials. Courses in English and in the humanities and social sciences are included to broaden the individual. This background is strengthened and unified through a sequence of engineering design and laboratory courses. Instructional laboratories in the junior and senior years provide opportunities for students to learn measurement and instrumentation techniques. Students apply these skills to the acquisition and analysis of data from various engineering systems.
In all professional endeavors the mechanical engineer must consider ecological effects as well as the economic and social needs of people. The mechanical engineer must consider the conservation of natural resources and the environmental impact in the design of systems. These considerations are included in a number of ME courses and technical elective classes. Students wishing to further strengthen this area may wish to consider the Green Engineering Option at www.eng.vt.edu/green/index.php.
The unifying activity in all aspects of mechanical engineering is the design function. A special emphasis has been placed on the use of computer-aided design methods and applied design project experience as a required part of the curriculum. Elective courses in the junior and senior years provide students with the opportunity to pursue specialized interests related to career plans or preparation for graduate study.
The department participates in the Cooperative Education Program in which qualified students may alternate semesters of study with semesters of professional employment. Approximately twenty percent of all mechanical engineering students participate in this program.
Education Abroad Programs
The Department of Mechanical Engineering is a world leader in providing high-quality education abroad opportunities to its students and preparing them to function effectively as true global engineers. The cornerstone of this strategy is the Ultimate Global Engineer Program, which identifies three major windows of opportunity for students to attend topflight mechanical engineering programs abroad and graduate on time. Students can select to participate in any combination of one, two, or even all three of these windows of opportunity:
Windows #1: Fall semester sophomore year in a country where the language of instruction is English. Currently students can attend the University of Melbourne, the top-ranked mechanical engineering program in Australia.
Windows #2: Rising junior summer in a country with a non-English language but where the language of instruction is English. Currently students can attend Shanghai Jiao Tong University, the top-ranked mechanical engineering program in China. This program is particularly well suited for students that need to catch up on their course work, reduce their junior-year course load, or get ahead on their course work.
Windows #3: Senior year abroad in a country with a non-English language but where the language of instruction is non-English. Currently students can attend the Technische Universität Darmstadt (TUD), the top-ranked mechanical engineering program in Germany. Language training is integrated into the curriculum, starting as late as spring semester junior year. Students have the opportunity to simultaneously earn both a VT BSME degree and a TUD BSME degree.
For more information about these and other exiting education abroad programs offered by the Department of Mechanical Engineering, please visit:
http://www.me.vt.edu/international
http://www.tud.vt.edu/BS
Entrance Requirement
The College of Engineering at Virginia Tech limits the number of students who may transfer into any particular department, with that number based upon the number of faculty in each separate department. Refer to the Engineering Education website at www.enge.vt.edu for the latest information on transferring into the ME department. The ME academic advisor may also be consulted for information on anticipated entrance requirement changes.
Satisfactory Progress
University policy requires that students who are making satisfactory progress toward a degree meet minimum criteria toward the Curriculum for Liberal Education (see Academics chapter in this catalog), and toward the degree in mechanical engineering.
Satisfactory progress toward a B.S. in Mechanical Engineering includes the following minimum criteria:
- Complete a minimum of 12 credits that apply toward the BSME each year
- maintain an in-major GPA (all ME and NSEG courses) of at least a 2.0
- maintain an extended in-major GPA of at least 2.0 (in all ME, NSEG courses plus ESM 2104, 2204, and 2304).
- complete ESM 2104, Math 2114 and Math 2204 within 45 attempted required course credits (not to include CLE courses, technical electives or free electives)
- complete ESM 2304, ME 2124, and Math 2214 within 60 attempted required course credits (not to include CLE courses, technical electives, or free electives)
- complete ME 3124, ME 3514 and ME 3614 within 72 attempted required course credits (not to include CLE courses, technical electives, or free electives)
- complete ME 4006, ME 4015 and ME 4124 within 90 attempted required course credits (not to include CLE courses, technical electives, or free electives)
The department offers graduate programs leading to the M.S., M.Eng., and Ph.D. in mechanical engineering (see the Graduate Catalog).
The Department of Mechanical Engineering actively seeks input on the nature and quality of our program from all interested individuals and organizations, including students, employers and supporting agencies. Our goal is to provide the best possible service to the students who entrust their education to us. Through our continuous improvement efforts, we pledge to continually improve the content of our curriculum, our educational methods and our facilities. Comments to the department head or any member of the faculty are welcomed. Note that because of this continuous improvement process entrance and degree requirements and course content are subject to change. Please consult the department academic advisor for current information.
Undergraduate Course Descriptions (ME)
2004 (MATH 2004): ENGINEERING ANALYSIS USING NUMERICAL METHODS
Numerical methods applied to engineering analysis. Linear
systems. Root finding. Numerical integration. Ordinary
differential equations. Programming using a software
package such as Matlab. Co: (MATH 1226 or MATH 1206),
(MATH 2114 or MATH 1114)
Pre: (ENGE 1114 or ENGE 1434 or ENGE 1216).
(2H,2C)
2024: INTRODUCTION TO ENGINEERING DESIGN AND ECONOMICS
Design process, mini-design projects, collaborative design,
product dissection, economics of decision making, reverse
engineering, intellectual property, oral, written, and
graphic communications, engineering ethics.
Pre: (ENGE 1216 or ENGE 1114 or ENGE 1434).
Co: ESM 2104, PHYS 2306.
(3H,3C)
2124: INTRODUCTION TO THERMAL AND FLUID ENGINEERING
Basics of thermodynamics, fluid mechanics, and heat
transfer. Fluid and thermal properties of materials. Ideal
gas equation of state. First law of thermodynamics in
closed systems. Transient heat transfer. First law of
thermodynamics in open systems. Fluid mechanics balances,
open systems. Emphasis on applications in all topic areas.
Pre: ESM 2104, (MATH 2114 or MATH 2114H).
Co: MATH 2214.
(2H,2C)
2974: INDEPENDENT STUDY
Variable credit course.
2974H: INDEPENDENT STUDY
Variable credit course.
2984: SPECIAL STUDY
Variable credit course.
2994: UNDERGRADUATE RESEARCH
Variable credit course.
2994H: UNDERGRADUATE RESEARCH
Variable credit course.
3124: THERMODYNAMICS
Classical thermodynamics and its applications.
Thermodynamic properties of pure substances: property
tables, property software, equations of state. First law of
thermodynamics. Second law of thermodynamics. Gas
mixtures. Combustion: atom and energy balances. Power and
refrigeration cycles.
Pre: (2124, MATH 2214, MATH 2204) or (ME 2124, MATH 2214, MATH 2204H) or (ME 2124, MA
TH 2214, MATH 2224) or (ME 2124, MATH 2214, MATH 2224H) or (ME 2124, MATH 2214H, MATH
2204) or (ME 2124, MATH 2214H, MATH 2204H) or (ME 2124, MATH 2214H, MATH 2224) or (M
E 2124, MATH 2214H, MATH 2224H) or (ME 2124, MATH 2405H, MATH 2406H).
(3H,3C)
I,II.
3134: FUNDAMENTALS OF THERMODYNAMICS
Fundamental concepts, first and second laws, gas and vapor
processes with emphasis on chemical reactions, statistical
interpretation of entropy, limited use of thermodynamic
property tables. This course is for non-ME students.
Pre: MATH 2214 or MATH 2214H.
(3H,3C)
3304: HEAT AND MASS TRANSFER
Comprehensive basic course in heat and mass transfer for
mechanical engineering students. Principles of conduction,
convection, and radiation with applications to heat
exchangers and other engineering systems.
Pre: (2124, MATH 2214, MATH 2204) or (ME 2124, MATH 2214, MATH 2204H) or (ME 2124, MATH 2214, MATH 2224) or (ME 2124, MATH 2214, MATH 2224H) or (ME 2124, MATH 2214H, MATH
2204) or (ME 2124, MATH 2214H, MATH 2204H) or (ME 2124, MATH 2214H, MATH 2224) or (ME 2124, MATH 2214H, MATH 2224H) or (ME 2124, MATH 2405H, MATH 2406H).
(3H,3C)
3404: FLUID MECHANICS
Comprehensive first course in basic and applied fluid
mechanics. Fluid properties, statics, kinematics, and
dynamics. Eulerâs and Bernoulliâs equations.
Hydrodynamics. Dimensional analysis and similitude. Real
fluids, laminar and turbulent flows. Boundary layer model
and approximate analysis. Compressible flow and propulsion
devices. Flow measurement. Introduction to turbomachinery
with applications.
Pre: (2124, MATH 2214, MATH 2204) or (ME 2124, MATH 2214, MATH 2204H) or (ME 2124, MATH 2214, MATH 2224) or (ME 2124, MATH 2214, MATH 2224H) or (ME 2124, MATH 2214H, MATH
2204) or (ME 2124, MATH 2214H, MATH 2204H) or (ME 2124, MATH 2214H, MATH 2224) or (ME 2124, MATH 2214H, MATH 2224H) or (ME 2124, MATH 2405H, MATH 2406H).
(3H,3C)
3504: DYNAMIC SYSTEMS - VIBRATIONS
Principles of dynamic system modeling with emphasis on
second order mechanical systems. Harmonic and nonharmonic
vibrations of single and multi-degree of freedom systems.
Applications of computer simulation and analysis techniques
in vibrations.
Pre: (3514, MATH 2214) or (ME 3514, MATH 2214H) or (ME 3514, MATH 2405H, MATH 2406H).
(3H,3C)
3514: SYSTEM DYNAMICS
Mathematical descriptions of physical systemsâ behavior
including mechanical, electrical, thermal, and fluid systems
and their combinations; system descriptions using state
variable and transfer functions; analysis of system
responses: convolution integral, frequency response,
numerical simulations, and Laplace transform methods;
systems concepts: input-output, causality, and analogies;
general process descriptions including first-order,
second-order, and time delayed.
Pre: (ESM 2104, ESM 2304, MATH 2214, MATH 2204, MATH 2114) or (ESM 2104, ESM 2304, MATH 2214, MATH 2204, MATH 2114H) or (ESM 2104, ESM 2304, MATH 2214, MATH 2204, MATH 2405H) or (ESM 2104, ESM 2304, MATH 2214, MATH 2204H, MATH 2114) or (ESM 2104, ESM 2304
, MATH 2214, MATH 2204H, MATH 2114H) or (ESM 2104, ESM 2304, MATH 2214, MATH 2204H, MATH 2405H) or (ESM 2104, ESM 2304, MATH 2214, MATH 2224, MATH 2114) or (ESM 2104, ESM
2304, MATH 2214, MATH 2224, MATH 2114H) or (ESM 2104, ESM 2304, MATH 2214, MATH 2224
, MATH 2405H) or (ESM 2104, ESM 2304, MATH 2214, MATH 2224H, MATH 2114) or (ESM 2104,
ESM 2304, MATH 2214, MATH 2224H, MATH 2114H) or (ESM 2104, ESM 2304, MATH 2214, MATH
2224H, MATH 2405H) or (ESM 2104, ESM 2304, MATH 2214H, MATH 2204, MATH 2114) or (ESM
2104, ESM 2304, MATH 2214H, MATH 2204, MATH 2114H) or (ESM 2104, ESM 2304, MATH 2214H, MATH 2204, MATH 2405H) or (ESM 2104, ESM 2304, MATH 2214H, MATH 2204H, MATH 2114)
or (ESM 2104, ESM 2304, MATH 2214H, MATH 2204H, MATH 2114H) or (ESM 2104, ESM 2304, MATH 2214H, MATH 2204H, MATH 2405H) or (ESM 2104, ESM 2304, MATH 2214H, MATH 2224, MATH 2114) or (ESM 2104, ESM 2304, MATH 2214H, MATH 2224, MATH 2114H) or (ESM 2104, ESM
2304, MATH 2214H, MATH 2224, MATH 2405H) or (ESM 2104, ESM 2304, MATH 2214H, MATH 222
4H, MATH 2114) or (ESM 2104, ESM 2304, MATH 2214H, MATH 2224H, MATH 2114H) or (ESM 2104, ESM 2304, MATH 2214H, MATH 2224H, MATH 2405H) or (ESM 2104, ESM 2304, MATH 2405H,
MATH 2406H).
(3H,3C)
3604: KINEMATICS AND DYNAMICS OF MACHINERY
Kinematic analysis and design of cams, gears, and linkages,
velocity, acceleration and force analysis, kinematic
synthesis, balancing, kinematic and force analysis by
complex numbers, computer-aided analysis, and synthesis of
linkages.
Pre: ESM 2304.
(3H,3C)
3614: MECHANICAL DESIGN I
Design of mechanical components subject to static and
fatigue loads. Design using screws, fasteners, springs and
bearings. Computer-aided design using transfer matrix and
finite element methods.
Pre: (ESM 2104, ESM 2204, MATH 2214, MATH 2204) or (ESM 2104, ESM 2204, MATH 2214, MATH 2224) or (ESM 2104, ESM 2204, MATH 2214H, MATH 2204) or (ESM 2104, ESM 2204, MATH
2214, MATH 2204H) or (ESM 2104, ESM 2204, MATH 2214H, MATH 2204H) or (ESM 2104, ESM 2
204, MATH 2405H, MATH 2406H).
(3H,3C)
4005-4006: MECHANICAL ENGINEERING LAB
Principles of measurement, measurement standards and
accuracy, detectors and transducers, digital data
acquisition principles, signal conditioning systems and
readout devices statistical concepts in measurement,
experimental investigation of engineering systems,
technical report writing.
Pre: 3514, (ECE 2054 or ECE 3054) or (ECE 2004, ECE 2074), (STAT 3704 or STAT 4604 or
STAT 4705 or STAT 4714) for 4005; 4005, ECE 3254 for 4006.
Co: ECE 3254 for 4005.
(2H,3L,3C)
4015-4016: ENGINEERING DESIGN AND PROJECT
Team oriented, open-ended, multi-disciplinary design
projects focused on industrially relevant problems. A
specific, complex engineering design problem is normally
taken from problem definition to product realization and
testing. Emphasis is placed on documenting and reporting
technical work, idea generation and selection, application
of design and analysis tools developed in previous courses,
project management, selling technical ideas and working in
teams.
Pre: (4005, 2024, ECE 3254, ME 3614, ME 3304), (ME 3504 or ME 4504) for 4015; 4015 for 4016.
(2H,1L,3C)
4034: BIO-INSPIRED TECHNOLOGY
Introduction to engineering solutions inspired by biological
systems. Overview over the approach of bio-inspired
technology and the state of the art. Exploration of the
relationship between engineered and natural biological
systems. Explanation of concepts of biological systems, such
as evolutionary optimization, sensing, actuation, control,
system integration, assembly and materials in engineering
terms. Practice of interdisciplinary analysis skills in
technical report writing projects where man-made and
biological systems are evaluated for parallels to
engineering and their technological potential.
Pre: (PHYS 2205, PHYS 2206) or (PHYS 2305, PHYS 2306).
(3H,3C)
4124: COMPUTER AIDED DESIGN OF FLUID-THERMAL SYSTEMS
Review of physical laws and engineering concepts introduced
in thermodynamics, fluid mechanics, and heat transfer with
applications. Emphasis on analysis, modeling, and design of
engineering systems, components, and physical
phenomena with state-of-the-art computer software such
as Ansys CFX, Star CCM, Aspen Plus, and ProSimPlus.
Pre: 3124, 3304, 3404.
(2H,2L,3C)
4154: INDUSTRIAL ENERGY SYSTEMS
Survey of energy-intensive technologies used in typical
industrial plants, with emphasis on cost-effective energy
conservation. Burners, boilers, pumps, air compressors,
electric motors, lights, refrigeration plants, HVAC systems,
cogeneration systems, waste heat recovery equipment.
Energy-efficient design and operation. Determination of
energy efficiency based on field measurements. Economic
analysis of energy conservation measures. Mitigation of
environmental impacts.
Pre: 3114 or 3124 or 3134 or CHE 2164 or BSE 3154.
(3H,3C)
4164: ENERGY SYSTEMS FOR BUILDINGS
Application of the fundamental principles of thermodynamics,
heat transfer, and fluid flow to analyze energy use for
building environmental control. Exploration of approaches
for configuring basic thermal-fluid engineering components
(e.g. pumps, piping, fans, heat exchangers, refrigeration
cycles, etc.) to yield systems that provide heating,
cooling, and ventilation. Introduction to techniques and
software tools for estimating energy use by these systems
and the associated economic and environment impact.
Examination of alternate technologies for meeting building
energy needs including small scale combined heat and power
systems and renewable energy systems.
Pre: 2124, 3124.
(3H,3C)
4174 (AOE 4174): SPACECRAFT PROPULSION
Spacecraft propulsion systems and their applications in
orbital, interplanetary, and interstellar flight. Rocket
propulsion fundamentals; advanced mission analysis; physics
and engineering of chemical rockets, electrical thrusters,
and propellantless systems (tethers and sails); spacecraft
integration issues.
Pre: 4234 or AOE 4234.
(3H,3C)
4194 (ESM 4194): SUSTAINABLE ENERGY SOLUTIONS FOR A GLOBAL SOCIETY
Addresses energy metrics, global and US energy supply and
demand, transitional energy sources (natural gas, petroleum,
coal, nuclear), sustainable/renewable source (solar,
geothermal, hydro, tidal, wind, biofuels), and methods for
increasing efficiencies (energy storage, batteries, green
building, conservation). Options for transportation,
electricity, lighting and heating needs of industry,
agriculture, community, and citizens. Production,
transmission, storage, and disposal issues considered in the
context of global political, economic, and environmental
impacts.
Senior Standing in major may be substituted for
pre-requisite ENGL 3764.
Pre: (CHEM 1035 or CHEM 1055), PHYS 2306, ENGL 3764.
(3H,3C)
4204: INTERNAL COMBUSTION ENGINES
Analysis and design of gasoline and diesel engines.
Fundamental processes and their application in current
technology. Thermodynamics: air standard and air-fuel
cycles. Combustion: stoichiometry, fuels, chemical
equilibrium, chemical kinetics, flame propagation, knock,
pollutant formation and control. Flow processes:
volumetric efficiency, intake and exhaust tuning, two-stroke
scavenging, carburetion, fuel injection, super- and
turbo-charging.
Pre: 3124, 3404.
(3H,3C)
4224: AIRCRAFT ENGINES AND GAS TURBINES
Performance and characteristics of aircraft engines and
industrial gas turbines, as determined by thermodynamic,
fluid mechanic, heat transfer, and solid mechanic behavior
of components. Operational limitations and component
matching. Stress and associated temperature limits and
influence of blade cooling techniques on turbines.
Pre: 4234 or 4124.
(3H,3C)
4234 (AOE 4234): AEROSPACE PROPULSION SYSTEMS
Design principles and performance analysis of atmospheric
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 inlets, turbomachines, combustors,
and nozzles. Matching of propulsion system to vehicle
requirements. Must have a C- or better in pre-requisites
ME 3404 and ME 3124 or AOE 3114 and AOE 3134.
Pre: (3404, 3124) or (AOE 3114, ME 3134).
(3H,3C)
4244 (AOE 4244): MARINE ENGINEERING
Analysis of major ship propulsion devices (propellers,
water jets). Integration with propulsion plant and
machinery. Characteristics of marine steam turbines,
nuclear power plants, marine diesels, and marine gas
turbines. Shafting system, bearings, and vibration
problems. Must have a C- or better in pre-requisites
AOE 3204 and ME 3124 or ME 3134.
Pre: AOE 3204, (ME 3134 or ME 3124).
(3H,3C)
4324: ENERGY SYSTEMS: THEORY AND APPLICATIONS
Theory and applications of thermodynamic and fluid mechanics
principles as applied to energy systems. Fundamental
concepts on exergy, mixtures, psychrometry and
thermochemistry. Analyses and applications include vapor and
gas power systems, refrigeration, air conditioning,
combustion processes and one-dimensional compressible
flow.
Pre: 3124, 3404.
(3H,3C)
4344 (CHE 4304): BIOLOGICAL TRANSPORT PHENOMENA
Engineering analysis and predictive modeling of heat
and mass transport in biological systems (e.g., tissues,
organs, organisms, and biomedical devices). Examination
of processes that involve conduction, convection, diffusion,
generation/consumption. Application of analytical and
computational methods to solve differential equations that
describe unsteady and/or multi-dimensional transport. Topics
include oxygen transport, pharmacokinetic analysis, kidney
function, blood perfusion, burns, and cryopreservation.
Pre: (CHE 3114, CHE 3044, CHE 3144) or (ME 3304, ME 3404) or (CHE 3114, CHE 3044, CHE
3144) or (ME 3304, ME 3404).
(3H,3C)
4454 (EDCI 4454): ENGINEERING LEADERSHIP IN PRACTICE: MANAGING THE TECHNICAL DESIGN PROCESS
Introduction to management and mentoring skills associated
with the application of the engineering design process.
Course covers skills necessary for leading diverse teams of
people through a technical design project. Managing teams
of local high school students through an authentic technical
design experience associated with design competitions.
Course addresses the practical applications of science,
math and engineering, while building and managing teams
of people to meet technical project goals.
Pre-requisite: ME 4015 or similar team-based design
experience, or by permission of instructor.
Pre: 4015.
(2H,3L,3C)
4504: DYNAMIC SYSTEMS - CONTROLS ENGINEERING I
Fundamentals of feedback control theory, classical analysis
and design techniques for automatic controls, introduction
to modern control theory.
Pre: (3514, MATH 2214) or (ME 3514, MATH 2214H) or (ME 3514, MATH 2405H, MATH 2406H).
(3H,3C)
4524: INTRODUCTION TO ROBOTICS AND AUTOMATION
Automation, robot technology, kinematics, dynamics,
trajectory planning, and control of two-dimensional and
spatial robots; robot programming; design and simulation
of robotic devices.
Pre: (ECE 2574, STAT 4714) or (ME 3514, STAT 3704).
(3H,3C)
4534: LAND VEHICLE DYNAMICS
Analytical methods for land vehicle dynamics. Mechanics
of pneumatic tires on pavement and steel wheels on rails.
Vehicle stability, handling, response to random guideway
and roadway irregularities, ride quality computation
methods and standards, suspension design.
Pre: 3514.
(3H,3C)
4544: AUTOMOTIVE ENGINEERING
Vehicle performance, drive train, suspension, steering, and
brake systems. Steady state and transient conditions.
Senior standing in Mechanical Engineering required.
(3H,3C)
4554: ADVANCED TECHNOLOGY FOR MOTOR VEHICLES
Energy use and environmental issues for motor vehicles:
Emissions standards, fleet requirements, dynamometer
testing, fuel economy, and vehicle performance.
Alternative fuel vehicles: Characteristics and
infrastructure of fuels, batteries, electric vehicles, and
hybrid electric vehicles. Vehicle design: Modeling and
simulation of vehicle energy use and performance,
component sizing. Fuel cells for transportation. Heavy-duty
vehicles and busses. Low mass vehicles and future vehicle
technology.
Pre: 3114 or 3124 or 3134.
(3H,3C)
4564: VEHICLE CONTROL
Overview of vehicle control systems and control algorithms
for anti-lock braking, stability, road holding, lane
departure, traction control, and tire pressure monitoring.
Advanced driver assist systems and intelligent tire
technology. Hands-on experience with hardware-in-the-
loop systems. Mathematical modeling and simulation of
vehicle control.
Pre: 4504.
(3H,3C)
4614: MECHANICAL DESIGN II
Design of mechanical elements such as welded joints
hydrodynamic bearings, spur gears, shafts, brakes.
Alternative fatigue design methods, cumulative fatigue,
mechanical design computer software.
Pre: 3614.
(3H,3C)
4624: FINITE ELEMENT PRACTICE IN MECHANICAL DESIGN
Application of the finite element method to stress analysis
problems in mechanical design. Modeling techniques, proper
use of existing computer programs, interpreting of results,
application to design modification.
Pre: 3614.
(3H,3C)
4634: INTRODUCTION TO COMPUTER-AIDED DESIGN AND MANUFACTURING
Participants will study the computer-aided design and
manufacturing of mechanical systems. A mechanical system
will be designed including preliminary design, analysis,
detail design, numerical control programming, and
documentation. Applications programs will be written
and interfaced to the CAD/CAM database. All assignments
will be carried out on a CAD/CAM system.
(2H,3L,3C)
4644: INTRODUCTION TO RAPID PROTOTYPING
Participants will study topics fundamental to rapid
prototyping and automated fabrication, including the
generation of suitable CAD models, current rapid prototyping
fabrication technologies, their underlying material science,
the use of secondary processing, and the impact of these
technologies on society. The rapid prototyping process will
be illustrated by the actual design and fabrication of a
part. Programming skills required.
(3H,3C)
4664: INTRO GLOBAL COLL ENGR DESIGN
Participants will study topics fundamental to global
collaborative engineering design, product data
management, and collaborative product data
management. These topics will be applied during a team
project with team members located overseas, utilizing
state-of-the-art collaborative engineering and product
data management software and hardware
technologies. Partially duplicates 5664. Credit
may only be received for one course.
Pre: 2024, 4634.
(3H,3C)
4724: ENGINEERING ACOUSTICS
Basic acoustical theory and practice, acoustic terminology,
measurement, transmission, and perception of sound, muffler
design, noise control techniques.
Pre: 3514.
(3H,3C)
4735,4736: MECHATRONICS
Electromechanical system modeling, control and applications.
Design and building of electronic interfaces and controllers
for mechanical devices, sensors, signal acquisition,
filtering, and conditioning. Microcontroller-based
closed-loop control and device communications. Sensor and
actuator selection, installation, and application strategies
are studied. A term design project is a key component to
this course (for 4736).
Pre: (ECE 3254, ME 3514) or (ECE 2004, ECE 2704) for 4735; 4735 for 4736.
(3H,3C)
4864: MICRO/NANO-ROBOTICS
Overview of Micro/Nano-robotic systems. Physics of
reduced length scales (scaling effects in the
physical parameters, surface forces, contact mechanics,
and Micro/Nano-scale dynamical phenomena), Basics of
Micro/Nano-manufacturing, microfabrication and soft
lithography, Biomimetic design strategies for mobile
micro-robots, Principle of transduction, material
properties and characteristics of Micro/Nano-actuators
(piezoelectric, shape-memory alloy, and a variety of MEMS
and polymer actuators), Control requirements and challenges
of Micro/Nano-actuators, Micro/Nano sensors for mobile
microrobotic applications, Micro/Nano-manipulation (scanning
probe microscopy, operation principles, designing
experiments for nanoscale mechanical characterization of
desired samples).
Pre: MATH 2214, ME 3404, ME 3514, ESM 2204.
(3H,3C)
4974: INDEPENDENT STUDY
Variable credit course.
4974H: INDEPENDENT STUDY
Honors
Variable credit course.
4984: SPECIAL STUDY
Variable credit course.
4994: UNDERGRADUATE RESEARCH
Variable credit course.
4994H: UNDERGRADUATE RESEARCH
Variable credit course.
Undergraduate Course Descriptions (NSEG)
3145-3146: FUNDAMENTALS OF NUCLEAR ENGR
Application of fundamental principles of neutron physics and
reactor theory. Introduction to nuclear cross-section data,
neutron scattering, nuclear fission, and diffusion theory.
Examination of current and next generation nuclear power.
Pre: MATH 2214 or MATH 2214H for 3145; 3145 or ME 3145 for 3146.
(3H,3C)
3604: RADIATION DETECTION, PROTECTION AND SHIELDING
Radioactive decay, interaction of charged particles and
photons with matter, methods of radiation detection and
radiation dosimetry, counting statistics, radiation
protection criteria and exposure limits, external radiation
protection using time, distance and shielding.
Pre: PHYS 2306.
Co: MATH 2214.
(3H,3C)
4204: NUCLEAR FUEL CYCLE
Uranium nuclear fuel cycle: radiation basics, uranium
reserves, mining, conversion, enrichment, fuel
manufacturing, in-core fuel management and refueling,
spent fuel storage, reprocessing/recycling and final
disposition as waste in a geologic repository. Introduction
to nuclear safeguards and nonproliferation as applied to
each step of cycle. Alternative fuel cycles.
Co: 3146.
(3H,3C)
4214: NUCLEAR POWER PLANT OPERATIONS
Emphasis on pressurized water reactor plant operations.
Review of boiling water reactor operations. Detailed system
functions and operation, reactor plant startup and shutdown
procedures, reactor refueling, reactor plant safety
analysis, reactor plant licensing, ethics and integrity in
the nuclear industry.
Pre: 3146.
(3H,3C)
4424: REACTOR THERMAL HYDRAULICS
Fundamental proceses of heat generation and transport in
nuclear reactors: reactor coolant systems and components,
heat generation and spatial distribution, heat transport by
conduction and convection, single-phase flow, two-phase
flow and boiling, critical heat flux.
Pre: 3145.
(3H,3C)
4974: INDEPENDENT STUDY
Variable credit course.
4984: SPECIAL STUDY
Variable credit course.
4994: UNDERGRADUATE RESEARCH
Variable credit course.
4994H: UNDERGRADUATE RESEARCH
Honors Section
Variable credit course.