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Course Criteria
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0.00 Credits
0.000 Credit Hours 60.000 Other hours Levels: Non Credit Schedule Types: Online/Seminar (OPD Courses) School of Continuing Education College Professional Development Department
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0.00 Credits
0.000 Credit Hours 200.000 Other hours Levels: Non Credit Schedule Types: Online/Seminar (OPD Courses) School of Continuing Education College Professional Development Department
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0.00 Credits
0.000 Credit Hours 260.000 Other hours Levels: Non Credit Schedule Types: Online/Seminar (OPD Courses) School of Continuing Education College Professional Development Department
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3.00 Credits
This course provides an overview of the various classes of materials including metals, ceramics, and polymers and the role of these materials in service and design applications.Subjects include atomic structure and bonding, the periodic table, crystal structure, microstructure, defects, diffusion, binary phase diagrams, phase transformations, and corrosion.The effects of processing, microstructure and composition on mechanical, electrical, and thermal properties are discussed.Lab sessions examine mechanical testing methods and microstructure analyses.Students learn sample preparation and metallographic techniques.(Prerequisites: CH 11, CH 11L) Three credits.
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3.00 Credits
An in-depth introduction to the science, math, and engineering of computer-aided manufacturing methods, the course provides a comprehensive view of manu-facturing planning, design, automation, flexible auto-mation, and computers in manufacturing, using a strong science-based and analytical approach.CNC and tooling for CNC application are discussed.The course consists of lectures, group discussions, case studies, a term project, computer simulation, and laboratory.(Prerequisite: CD 211) Three credits.
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3.00 Credits
The course balances CAD and CAM with up-to-date information on rapid prototyping, NT-based solid modeling systems, and Web-related issues.Complicated mathematical terminology is kept to a minimum; instead, the concepts are explained in as intuitive a way as possible.Students are required to have a background only in programming, calculus, and matrix and vector algebra.The course also covers components of CAD/CAM/CAE Systems and CAD/CAM postprocessor development manufacturing systems.The course consists of lectures, group discussions, case studies, a term project, computer simulation, and laboratory.(Prerequisite: MF 230) Three credits.
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3.00 Credits
This course introduces the design and implementation of programmable logic controllers for use in industry in the areas of automation, manufacturing, and other related applications.It takes an overall look at Programmable Logic Controllers while concentrating on relay ladder logic techniques and how the PLC is connected to external components in an operating control system.State-of-the-art software used includes: MultiSim, LabView, Cosivis, Veep, and RS Logix 500.The course also covers input/output ports, continuous process control, timing and counting functions, chaining sequences, and digital gate logic.The course consists of lectures, group discussions, case studies, a term project, computer simulation, and laboratory.(Prerequisite: PS 16 ) Three credits.
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1.00 Credits
This course is designed to teach the students to work with the PLC.The student learns to analyze open- and closed-loop control tasks from the field of activities, and to develop structured and PLC-adequate programs in either function plan, ladder diagram, instruction list, sequential function chart, or structured text.Allen Bradley, Mitsubishi, GE, Fanuc, and Siemens PLC are used.The students must create the PLC programs from description of desired operations.State-of-the-art software used includes: MultiSim, LabView, Cosivis, Veep, and RS Logix 500, Fluid Sym P, and others.(Co-requisite: MF 250) One credit.
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3.00 Credits
This course introduces the integration of fluids and mechanics theory to real world applications.Fluid power components and how they are configured to operate efficient mechanical work are discussed.The primary topics include piping, hydraulic fluids, pumps, diverting valves, actuators, ISO symbols, and system design with safety as a priority.Upon completion, students have an understanding of how a fluid power system is developed and applied to satisfy industrial requirements.The course consists of lectures, group discussions, case studies, a term project, computer simulation, and laboratory.(Prerequisite: ME 241) Three credits.
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3.00 Credits
This course shows how CIM fits into the current manufacturing systems and how the technology is used to solve real-world industrial problems.It integrates basic product design techniques and manufacturing fundamentals and principles, along with a look at the changing operations and information systems that support CIM in the enterprise.Topics include concepts of CIM and the manufacturing enterprise; the design elements and production engineering; managing the enterprise resources; and enabling processes and systems for modern manufacturing.The course consists of lectures, group discussions, case studies, a term project, computer simulation, and laboratory.(Prerequisite: MF 240) Three credits.
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