| |
Mechanical Engineering |
| |
-
MECH 421 - Introduction to Wind Tunnels
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
An introductory course on the experimental techniques used in wind tunnel testing of aerodynamic shapes. Includes operating characteristics of wind tunnels, the characteristics of and use of models and model instrumentation, and the development of analytical techniques for reduction of wind tunnel data.
Prerequisites: MECH 318 and MECH 363
|
| |
-
MECH 426 - Fluid Power Systems
(S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
A mechanical approach to industrial hydraulic applications with emphasis on selection and function of hardware and interfacing of hydraulic systems with mechanical, fluidic and electrical/ electronic controls.
Prerequisite: MECH 318 or instructor consent
|
| |
-
MECH 427 - Experiments in Thermodynamics
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Application of laws and principles of thermodynamics to performance testing of heat engines. Teaches measurement of power, determination of efficiency, preparation of heat balances, analysis of combustion products, and preparation of engineering reports.
Prerequisites: MECH 313 and MECH 363
|
| |
-
MECH 433 - HVAC
(F)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Heating, ventilating, and air conditioning. Application of laws and principles of thermodynamics to analysis, design, and control of mechanically-controlled environments for human comfort, animal health, and food preservation. Teaches computation of heating and cooling loads, humidity control, heating, and refrigeration.
Prerequisite: MECH 323
|
| |
-
MECH 436 - Classical Control Systems
(S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
An introduction to control systems. Both classic control theory and programmable logic controllers are considered. Topics include block diagrams, mathematical models, transfer functions, LaPlace transforms, frequency responses along with control components and PLC programming.
Prerequisite: MECH 480
|
| |
-
MECH 437 - Heat Transfer II
(W)
Lecture Hours: 1
Lab Hours: 3
Credit Hours: 2
A study of experimental heat transfer. Methods and instrumentation used for investigating heat transfer systems will be considered. Laboratory investigations include studies of heat exchangers, forced and free convection experiments, and determination of radiation and convection coefficients.
Prerequisite: MECH 323 or instructor consent
|
| |
-
MECH 438 - Reciprocating and Turbine Engines
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Introduction to construction, operation, and theory of reciprocating and turbine engines. Students will learn engine design, history of development, theory and practice of operation.
Prerequisites: MECH 313 , MECH 315 , and MECH 318
|
| |
-
MECH 475 - Parametric Modeling
(W)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Introduces feature-based parametric solid modeling techniques as applied to Mechanical Design. Emphasizes the concepts and practices of parametric modeling from the user’s perspective. Theoretical and development backgrounds are also covered.
Prerequisite: MET 375
|
| |
-
MECH 480 - Mechanical Vibrations
(W)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
An introduction to mechanical vibration. Topics include the equations of motion, resonant frequencies, mode shapes, damping and applications. The laboratory will introduce vibration instrumentation.
Prerequisites: ENGR 212 , ENGR 266 , MATH 321 , MATH 341 , MECH 315 , and MECH 363
|
Mechanical Engineering Technology |
| |
-
MET 107 - Seminar
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MET 108 - Geometric Dimensioning and Tolerancing
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
The study and application of ANSI geometric dimensioning and tolerancing principles relative to the preparation of engineering drawings.
Prerequisite: MET 241
|
| |
-
MET 207 - Seminar
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MET 218 - Fluid Mechanics
(W,S)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Covers fluid properties, laws of fluid statics, and fluid dynamics, measurement of flow, viscous flow, laminar, and turbulent flow, flow in ducts, forces due to fluid motion, and fluid machinery.
Prerequisites: MATH 112 , and PHY 201 or PHY 221
|
| |
-
MET 232 - Thermodynamics
(F)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
An introductory course in thermodynamics. Develops understanding of energy, heat, work, efficiency, the ideal gas law, the first and second laws of thermodynamics and the general energy equation.
Prerequisites: MATH 252 , and PHY 202 or PHY 222
|
| |
-
MET 241 - CAD for Mechanical Design I
(F,W,S)
Lecture Hours: 1
Lab Hours: 3
Credit Hours: 2
Computer aided drafting (CAD) for mechanical design. The focus of this course is the construction of 2-D drawings using current industry software. Topics include construction principles, input schemes, command structures, and data management.
Prerequisite: ENGR 111 or instructor consent
|
| |
-
MET 242 - CAD for Mechanical Design II
(F,W,S)
Lecture Hours: 1
Lab Hours: 3
Credit Hours: 2
Computer aided drafting (CAD) for mechanical design. The focus of this course is the construction of drawing sets using current industry software. Topics include detail part drawings, assembly drawings, and an introduction to 3-D drafting.
Prerequisite: MET 241
|
| |
-
MET 298 - Reading and Conference
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MET 299 - Laboratory Practice
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MET 304 - MET Co-op Field Practice
Credit Hours: (Terms and hours to be arranged with approval of the curriculum coordinator.)
An approved work program related to the student’s field of specialization for a continuous three-month period. The employer and the type, level, and difficulty of the particular job must be approved prior to the employment period. A written comprehensive report must be submitted during the following term of residence.
|
| |
-
MET 307 - Seminar
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MET 313 - Applied Thermodynamics
(W,S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Application of laws and principles of thermodynamics to real thermodynamic cycles. Teaches analysis of performance and design of internal and external combustion engines, steam generators, heat pumps, compressors, and refrigeration machinery.
Prerequisite: ENGR 355
|
| |
-
MET 315 - Machine Design I
(F,W)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Knowledge and skills developed in preceding courses are extended and applied to design and selection of machine elements and machines. Attention is given to functional requirements, methods of manufacture, choice of materials, and economic factors.
Prerequisites: ENGR 213 or MECH 223 , and MECH 260
|
| |
-
MET 316 - Machine Design II
(W,S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
A study of power transmission systems components, their selection, and application to power transmission systems. Special consideration is given to the dynamic characteristics of the systems.
Prerequisite: MET 315
|
| |
-
MET 323 - Heat Transfer I
(F,W,S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
An introduction to the three modes of heat transfer, conduction, convection, and radiation. Teaches the analytical and empirical techniques used for solving problems in heat transfer, including those for which computer application is most suited.
Prerequisites: ENGR 355 and MET 218
|
| |
-
MET 351 - Finite Element Analysis
(W,S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
This course is an introduction to the use of finite element analysis (FEA) in the solution of mechanical engineering problems. Existing FEA computer codes are used.
Prerequisite: MET 375
Pre- or Corequisite: MET 315
|
| |
-
MET 360 - Engineering Materials II
(F)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
This course extends the MECH 260 - Engineering Materials I course using a more theoretical approach. Subjects include metals, polymers, ceramics, and composites.
Prerequisite: MECH 260
|
| |
-
MET 363 - Engineering Instrumentation
(F)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Study of measurement techniques and equipment used in mechanical engineering. Instrumentation for measurements in mechanics, thermodynamics, fluid dynamics, and electrical systems considered. Methods of calibration, correction, and data reduction presented.
Prerequisite: ENGR 236
Pre- or Corequisite: ENGR 213
|
| |
-
MET 375 - Solid Modeling
(F,W,S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Introduces solid modeling techniques as applied to mechanical design. Topics include extruded and swept shapes, Boolean operations, and other construction techniques.
Prerequisite: MET 242
|
| |
-
MET 404 - MET Co-op Field Practice
Credit Hours: (Terms and hours to be arranged with approval of the curriculum coordinator.)
An approved work program related to the student’s field of specialization for a continuous three-month period. The employer and the type, level, and difficulty of the particular job must be approved prior to the employment period. A written comprehensive report must be submitted during the following term of residence.
|
| |
-
MET 405 - Reading and Conference
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MET 407 - Seminar
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MET 414 - Applied Aerodynamics
(W)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
An introductory course on the fundamentals of aerodynamics. Includes a review of the behavior of fluids in motion, definition of the important parameters in aerodynamic behavior, and study of flow about simple aerodynamic shapes. Emphasis will be placed on low-speed aerodynamics.
Prerequisites: ENGR 355 or MET 232 , and MET 218
|
| |
-
MET 415 - Design Project
(F,S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
This course involves using material from prior coursework in individual student projects.
Prerequisites: MET 218 and MET 315
Pre- or Corequisite: MET 316
|
| |
-
MET 416 - Energy Systems
(F)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Compares available energy resources by application of laws and principles of thermodynamics. Provides computational skills for assessment of a given resource with respect to a given application. Develops understanding of energy economics.
Prerequisites: ENGR 355 or MET 232
|
| |
-
MET 417 - Gas Laws
(F)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Application of thermodynamics and fluid mechanics to the analysis of flow of both ideal and real gasses in pipes, nozzles, diffusers, compressors and turbines. The course also emphasizes the use of appropriate instrumentation.
Prerequisites: MET 218 , MET 313 , and MET 363
|
| |
-
MET 421 - Wind Tunnel Technology
(W)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
An introductory course on the experimental techniques used in wind tunnel testing of aerodynamic shapes. Includes operating characteristics of wind tunnels, the characteristics of and use of models and model instrumentation, and the development of analytical techniques for reduction of wind tunnel data.
Prerequisites: ENGR 355 or MET 232 , MET 218 , and MET 363
|
| |
-
MET 427 - Experiments in Thermodynamics
(S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Application of laws and principles of thermodynamics to performance testing of heat engines. Teaches measurement of power, determination of efficiency, preparation of heat balances, analysis of combustion products, and preparation of engineering reports.
Prerequisites: MET 313 and MET 363
|
| |
-
MET 433 - HVAC
(W)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Heating, ventilating, and air conditioning. Application of laws and principles of thermodynamics to analysis, design, and control of mechanically-controlled environments for human comfort, animal health, and food preservation. Teaches computation of heating and cooling loads, humidity control, heating, and refrigeration.
Prerequisites: MET 313 and MET 323
|
| |
-
MET 436 - Control Systems
(F,W,S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
An introduction to control systems. Both classic control theory and modern digital process control are considered. Topics include block diagrams, mathematical models, transfer functions, LaPlace transforms, frequency response along with control components and digital controllers.
Prerequisites: ENGR 212 , ENGR 236 , ENGR 355 or MET 232 , MET 218 , and MET 363
|
| |
-
MET 437 - Heat Transfer II
(F,W)
Lecture Hours: 1
Lab Hours: 3
Credit Hours: 2
A study of experimental heat transfer. Methods and instrumentation used for investigating heat transfer systems will be considered. Laboratory investigations include studies of heat exchangers, forced and free convection experiments, and determination of radiation and convection coefficients.
Prerequisite: MET 323
|
| |
-
MET 438 - Reciprocating and Turbine Engines
(W,S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Introduction to construction, operation, and theory of reciprocating and turbine engines. Students will learn engine design, history of development, theory and practice of operation.
Prerequisites: MET 218 , MET 313 , and MET 315
|
| |
-
MET 462 - Vacuum Technology
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
An introductory course defining the role of high and ultra-high vacuum in the process of high vacuum technology. Material will include such topics as vacuum pumping, vacuum gauging, processing of materials in a vacuum, evaporative deposition, sputtering, thin films, mass spectrometry, and leak detection.
Prerequisite: MET 417
|
| |
-
MET 465 - Computational Strength of Materials
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Advanced topics in structural mechanics using calculus and finite element approaches. Topics include stresses and deflections of non-uniform 2-d beams; shafts and connecting rods; axisymmetric shells; circular and rectangular plates; inertial stresses from rotation and seismic effects. Applications are emphasized.
Prerequisites: ENGR 211 or MECH 222 , ENGR 213 , MATH 252 , MECH 221 , and MET 351
|
| |
-
MET 475 - Parametric Modeling
(W)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Introduces feature-based parametric solid modeling techniques as applied to Mechanical Design. Emphasizes the concepts and practices of parametric modeling from the user’s perspective. Theoretical and development backgrounds are also covered.
Prerequisite: MET 375
|
| |
-
MET 480 - Vibrations
(F,W)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
An introduction to mechanical vibration. Topics include the equations of motion, resonant frequencies, mode shapes, damping and applications. The laboratory will introduce vibration instrumentation.
Prerequisites: ENGR 212 , ENGR 266 , MATH 321 , MECH 315 , and MECH 363
|
Manufacturing Engineering Technology |
| |
-
MFG 101 - Introduction to Manufacturing
(S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
An introduction to the manufacturing engineering technology discipline. Orientation to the use of personal computers. Instruction in problem solving and laboratory procedures emphasized. Laboratory provides demonstration and practice in a variety of manufacturing equipment and procedures.
|
| |
-
MFG 103 - Introductory Welding Processes
(F,W,S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Applications of welding in modern industry. Topics include: Oxyacetylene welding and cutting, shielded metal arc welding, gas tungsten arc welding, gas metal arc welding, and robotic welding.
Prerequisite: Enrolled in any MMET program or instructor consent
|
| |
-
MFG 107 - Seminar
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MFG 112 - Introduction to Manufacturing Processes
(W)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
A survey of common manufacturing processes, including a history of manufacturing technology. Manufacturing economic considerations. Influence of product design on process selection. Manufacturing taxonomy, surface finish, tolerances, and functional specifications.
|
| |
-
MFG 120 - Introductory Machining Processes
(F,W,S)
Lecture Hours: 2
Lab Hours: 6
Credit Hours: 4
An introductory course in metal removal processes emphasizing drilling, milling, and lathe processes. Includes tool bit grinding. Emphasis on production speeds and feeds.
Prerequisites: ENGR 111 and MATH 100
|
| |
-
MFG 204 - Data Management
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
Current topics in data acquisition and management.
|
| |
-
MFG 207 - Seminar
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MFG 220 - Manufacturing Processes II
(W)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Advanced concepts in material removal. Turning, milling, shaping, and drilling. Cutting tools and cutting requirements.
Prerequisites: MECH 260 , MET 241 , and MFG 120
|
| |
-
MFG 223 - Casting and Molding Processes
(S)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Casting and molding processes including: pattern making, casting and molding methods, mold and core making, pouring, cleanup, sand conditioning and testing, quality considerations and economic factors.
Prerequisites: ENGT 115 and MECH 260
|
| |
-
MFG 245 - Electronics Manufacturing
(F)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Processes and materials specific to the production of printed circuit board and integrated circuit components. Topics include surface mount technology, vacuum system theory, photolithography, etching and deposition processes, micro-bonding, and component packaging.
Prerequisites: CHE 101 and MET 112
|
| |
-
MFG 275 - CAD for Manufacturing
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Computer aided drafting for manufacturing. Presents equipment and programs from the user’s perspective. Topics include construction principles, input schemes, command structures, and data management.
Prerequisite: One computer language
|
| |
-
MFG 295 - Individual Studies
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MFG 298 - Reading and Conference
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MFG 299 - Laboratory Practice
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MFG 307 - Seminar
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MFG 313 - Manufacturing Analysis and Planning
(F)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Analysis and planning of manufacturing methods, procedures and equipment. Includes designing for manufacturing efficiency, tolerance analysis, equipment and resource allocation and scheduling.
Prerequisites: MET 242 , MFG 112 , and MFG 120
|
| |
-
MFG 314 - Geometric Dimensioning and Tolerancing
(F,S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
The study and application of ANSI and ISO geometric dimensioning and tolerancing principles and practices relative to product design and manufacturing operations.
Prerequisites: MATH 112 and MET 242
|
| |
-
MFG 317 - Machine Element Design
(F)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Stress calculations and design of machine elements for general applications. Theories of failure, fatigue considerations, and material selection of shafts and associated parts, gear and belt drives, bearings, power screws, threaded fasteners, riveting, welding, and springs.
Prerequisites: ENGR 213 or MECH 222 , and MET 241 , or instructor consent
|
| |
-
MFG 325 - Principles of Metrology, Machining and Welding
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Measuring techniques using precision devices. Metal removal processes such as lathe, mill, and grinder. Correct use of tools and cutting parameters. Basic welding processes and theory.
|
| |
-
MFG 326 - Solid Mechanics
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Concentrated study of statics and strength of materials comprising the principles of equilibrium, strain-stress relationships, and analysis of internal stresses for different loading systems.
Prerequisite: MATH 112
|
| |
-
MFG 331 - Industrial Controls
(S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Fundamentals of control of manufacturing processes. Applications of relay logic, input and output devices, and programmable logic controllers (PLC). Design of complete control circuits, selection of components, and cost estimation. PLC programming for discrete event control and for analog applications.
|
| |
-
MFG 333 - Statistical Methods for Quality Improvement
(F,W,S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Strategies for continuous manufacturing process improvement. Graphical and numerical methods for data analysis. Methods for manufacturing process control and acceptance criteria.
Prerequisite: MATH 361
|
| |
-
MFG 334 - Manufacturing Group Project
(W,S)
Lecture Hours: 1
Lab Hours: 6
Credit Hours: 3
Development of a product by a group of manufacturing students working together. This includes creating or modifying the design of the product, writing operation sheets, specifying materials, tools and equipment needed, design of special tooling, setup and operation of equipment and actual manufacturing of the project.
Prerequisite: MFG 342
|
| |
-
MFG 341 - Numerical Control Programming
(F)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Introduction to manual numerical control programming. Includes interpreting part drawings, process planning, machining setup and sequence. Program debugging and introduction to tool path simulation and computer-aided programming tools.
Prerequisites: MATH 112 , MET 242 , and MFG 120
|
| |
-
MFG 342 - Computer Aided Machining
(W,S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Development of CNC machine tool manufacturing programs using computer-aided process planning and advanced CAD/CAM software. Emphasis on analysis and planning required for successful CNC production, development of CAD drawings and solid models for CAM program development, toolpath simulation, and manufacturing engineering issues.
Prerequisites: MET 375 and MFG 341
|
| |
-
MFG 343 - Manufacturing Tool Design
(W)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Fundamentals of jig and fixture design. Locating and clamping methods for manufacturing production. Design of sheet-metal stamping, piercing, and forming tools. Study of the effect of manufacturing machines and production methods on tooling design.
Prerequisites: MET 315 or MECH 315 , MFG 313 , MFG 314 , and MFG 341 , or instructor consent
|
| |
-
MFG 344 - Design of Manufacturing Tooling
(S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Using material from prior courses students work in individual and team design projects. Design and analyze a variety of manufacturing fixtures, jigs, molds, and stamping dies.
Prerequisite: MFG 343
|
| |
-
MFG 351 - Microelectronics Manufacturing Processes I
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
A three term sequence providing in-depth theory of the processes used in the manufacture of electronic components. Primary topics include integrated circuits, printed circuits, electronic assembly. Vacuum system theory, photolithography, process specific chemistry, etching and deposition processes, and surface mount technology.
Prerequisites: CHE 101 and PHY 202
|
| |
-
MFG 352 - Microelectronics Manufacturing Processes II
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
A three term sequence providing in-depth theory of the processes used in the manufacture of electronic components. Primary topics include integrated circuits, printed circuits, electronic assembly. Vacuum system theory, photolithography, process specific chemistry, etching and deposition processes, and surface mount technology.
Prerequisite: MFG 351
|
| |
-
MFG 353 - Microelectronics Manufacturing Processes III
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
A three term sequence providing in-depth theory of the processes used in the manufacture of electronic components. Primary topics include integrated circuits, printed circuits, electronic assembly. Vacuum system theory, photolithography, process specific chemistry, etching and deposition processes, and surface mount technology.
Prerequisite: MFG 352
|
| |
-
MFG 404 - Co-op Field Practice
Credit Hours: (Terms and hours to be arranged with approval of the curriculum coordinator.)
An approved work program related to the student’s field of specialization for a continuous three-month period. The employer and the type, level, and difficulty of the particular job must be approved prior to the employment period. A written comprehensive report must be submitted during the following term of residence.
|
| |
-
MFG 405 - Reading and Conference
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MFG 407 - Seminar
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MFG 408 - Workshop
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MFG 415 - Finishing Methods
(F)
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
Review of material finishing technologies with focus on functional requirements of final product, life-cycle environmental considerations, and manufacturing technologies for material finishing.
Prerequisite: MECH 260
|
| |
-
MFG 420 - Advanced Manufacturing Processes
(W)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Introduction to less conventional and recently developed manufacturing processes and materials. Emphasis on understanding unique characteristics, advantages, limitations, and applications. Analysis required for selection of appropriate materials and processes. Examples of computer programs that aid the selection process.
Prerequisites: MATH 112 , MET 242 , MFG 120 , and PHY 221 , or instructor consent
|
| |
-
MFG 425 - Plastic Manufacturing Processes
(S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Fundamentals of polymer science and plastic manufacturing methods. Introduction to the effect of chemistry and morphology of plastics on material selection, product design, and process design. Emphasis is on thermoplastic processes such as injection molding.
Prerequisites: MECH 260 and MET 375 , or instructor consent
|
| |
-
MFG 445 - Plant Layout and Handling Systems
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
In-depth study of facilities planning for manufacturing engineers. Focus is on layout optimization algorithms and applications, work cell design, warehouse design, materials handling systems, process/product/material/labor cost estimates and evaluations, and agile manufacturing.
Prerequisites: MFG 112 and MFG 313
|
| |
-
MFG 447 - Lean Manufacturing
(W,S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Introduction of principles, techniques and skills of lean manufacturing. Process optimization and quality improvement for manufacturing. Plant layout, design and job scheduling. JIT skills, such as Kaizen, Kanban, value added analysis and one piece flow to reduce inventory and waste.
Prerequisite: MFG 333
|
| |
-
MFG 453 - Automation and Robotics in Manufacturing
(F,S)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Study of the appropriate level of manufacturing automation based upon economics and productivity. Discussion of robotics and a study of automated manufacturing including automatic machine design and material handling.
Prerequisite: Senior standing in MET or MfgET or instructor consent
|
| |
-
MFG 454 - Thermal Systems for Manufacturing
(F,S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Fundamentals of thermal energy analysis, including introduction to thermodynamics and heat transfer. Emphasis is on solving manufacturing related problems in thermal process control and analysis.
Prerequisite: MATH 252
|
| |
-
MFG 456 - Materials Science
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Study of the relationship of a material’s structure to its properties. Materials studied include nonferrous metals, polymers, ceramics, composites, and electronics materials.
Prerequisite: MFG 420
|
| |
-
MFG 465 - Advanced Welding Methods
(F,S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
High energy density, solid state, and plastics welding processes. Welding metallurgy supports, metal combination choices and solutions to typical welding problems. Codes, procedure qualification, welding design and nondestructive testing.
Prerequisites: MECH 260 and MFG 103
|
| |
-
MFG 503 - Thesis
(F,W,S)
Credit Hours: (Variable Credit 1-16)
Course may be repeated for credit.
|
| |
-
MFG 507 - Seminar
Credit Hours: (Hours to be arranged each term.)
|
| |
-
MFG 521 - The Manufacturing Management Team in the Global Enterprise
(S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Concepts and theories needed to understand the management of people, work groups, and organizations in a global environment. Exploration of cultural differences, organizations, communication and business relationships; strategic thinking in a global context, and international e-communications. Emphasis on contemporary case studies regarding the operational problems facing the international firm.
|
| |
-
MFG 522 - Manufacturing Business Philosophies
(S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Contemporary world class manufacturing concepts and philosophies including Just-in-Time (JIT) applications for manufacturing and inventory management; methods and practices of total quality control in manufacturing; and continuous improvement techniques in manufacturing. Focus on contemporary cases in global manufacturing.
|
| |
-
MFG 523 - Capitalization Principles for Manufacturing
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Theory and concepts of capitalization for manufacturing assets; land, buildings, and equipment. Historical cost for valuing an asset. Net income, real and tax depreciation, and timing the disposal or exchange of assets. Exploration of capitalization of cost, post-acquisition asset costs, interest capitalization and expense, asset impairments, and multinational capital budgeting and financial management.
|
| |
-
MFG 524 - Project and Budget Planning for Manufacturing
(W,S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Exploration of the theories, tools, and techniques needed to effectively plan and manage manufacturing projects and budgets. Development of the characteristics of project plans including scope of work statements, work breakdown structure, project schedules, schedule and budget metrics, and project change cost analysis. Core topics include cost, time, and resource estimation, management and budgeting.
|
| |
-
MFG 525 - International Economics for Manufacturing
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Exploration of international economics. Impact on manufacturing industries. Focus on the foundations of international trade including classical and modern theories of production and industrial organization. Free trade policies; foreign competition; direct foreign investment, fiscal and monetary policy; tariffs, quotas, and subsidies. International monetary market on production, and anti-globalization politics. Concentration on contemporary cases in manufacturing.
Prerequisite: ECO 201 and ECO 202 or equivalent (see instructor)
|
| |
-
MFG 531 - Engineering Mechanics
(S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Fundamentals of statics. Dry, viscous, and rolling friction. Kinematics of particles: rectilinear and curvilinear motion. Kinetics of particles: work and energy, impulse and momentum. Kinematics of rigid bodies: translation and rotation. Kinetics of rigid bodies: work and energy, impulse and momentum. Fundamentals of stress analysis.
|
| |
-
MFG 533 - Thermal Processes and Technology in Manufacturing
(F)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Review of the laws of thermodynamics. Review of heat transfer including conduction, convection, and radiation. Vacuum technology. Autoclave processes. Cryogenics: materials, techniques, and safety. Plasma processes. The processing of non-metallics. The processing of insulation materials. Energy costs and conservation in manufacturing processes.
|
| |
-
MFG 534 - Design Technology for Manufacturability
(F)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Cutting costs and improving productivity, managing the manufacturing supply chain. Reducing time to market. Establishing core competencies and maintaining vital corporate best practices. The role of standards and lean manufacturing in design.
|
| |
-
MFG 535 - Product Life Software
(F)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Use of high-end enterprise-wide software products for integrating design, automating the workflow, and comprehensively controlling security. Revision management over all types of data. Creating document links. Leveraging subject matter experts across the extended enterprise.
|
| |
-
MFG 536 - Automated Technology for Tool Path Generation
(F)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Reviewing and validating manufacturing processes for administrators, managers, and designers. Reviewing the creation of tool paths using standard 3D and 2D mechanical design tools and the generative 2.5-axis and 3, 4 and 5-axis surface machining NC software tools. Controller, machine, and software selection and integration.
|
| |
Page: 1 <- 6
| 7
| 8
| 9
| 10
| 11
| 12
| 13
| 14
| 15
| 16
-> 18 |
Print this Page