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ENGT 3010: Applied Mathematics I for Engineering Technologists

2.00 Credits

Utah Valley University

Prerequisite(s): AET 1060, MATH 1050 and University Advanced Standing. Review concepts taught in college algebra with focus on application into engineering technology. Investigates trigonometry concepts applied to power systems. Analyzes industry matrix models. Includes an introduction to applied calculus within engineering technology.

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ENGT 3020: Applied Mathematics II for Engineering Technologists

2.00 Credits

Utah Valley University

Prerequisite(s): ENGT 3010 and University Advanced Standing. Applies calculus to applications in engineering technology. Introduces basics of applied differential equations and introductory solutions via the Laplace transform technique. Mathematical computations include derivations and problems related to power electronics, power converters, motion control, machines and drives, and proportional, integral, and derivative loops.

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ENGT 3050: Programming and Applied Analytics

3.00 Credits

Utah Valley University

Prerequisite(s): University Advanced Standing. Pre- or Corequisite(s): ENGT 3010. Applies programming and analytics to engineering technology problems. Applies loops, functions, logical statements, and analysis to power, automation, and mechatronic scenarios. Implements trigonometry, linear algebra and calculus based concepts utilizing modern based software and tools.

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ENGT 3100: Power Systems and Automation

3.00 Credits

Utah Valley University

Prerequisite(s): AET 1060, AET 2270, AET 2275, MATH 1050 and University Advanced Standing. Pre- or Corequisite(s): ENGT 3010. Introduces power systems and the steady-state analysis of its major components from generation to the delivery of electrical power. Discusses the flow of active and reactive power and basic control concepts. Introduces equipment nameplates, testing, troubleshooting, and basic automation in power systems. Focuses on fundamental introductory concepts in measurement equipment and Intelligent Electronic Devices (I.E.D.). Introduces the per unit system. Discusses the role of automation, protection, and smart control in power systems. Introduces fault analysis of balanced systems. Provides an introduction to the important topic of symmetrical components. Includes hands-on exercises and demos in the classroom.

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ENGT 3130: Electrical Safety Standards

1.00 Credits

Utah Valley University

Prerequisite(s): MATH 1050 and University Advanced Standing. Emphasizes industrial safety and focuses heavily on electrical safety in the workplace as stated in NFPA 70E and other relevant standards. Includes practices and topics to help mitigate workplace injuries. Discusses when it is appropriate to work on live systems and focuses on the latest NFPA 70E consensus standard. Introduces arc flash hazards, analysis and mitigation strategies.

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ENGT 3150: Power System Analysis and Design

3.00 Credits

Utah Valley University

Prerequisite(s): ENGT 3100 and University Advanced Standing. Reviews electrical one-line diagrams, per unit system, and electrical models for transformers, synchronous generators, induction machines, power lines, and other pertinent apparatus. Discusses analysis techniques utilizing both equivalent circuits and Y-bus methods. Introduces unbalanced fault analysis, symmetrical components, and sequence networks for single-line to ground, phase-phase, and phase-phase-ground faults. Focuses on design concepts and codes related to medium and low voltage power systems.

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ENGT 3160: Power Quality and Reliability

3.00 Credits

Utah Valley University

Prerequisite(s): ENGT 3100, ENGT 3010, and University Advanced Standing. Pre- or Corequisite(s): ENGT 3020. Introduces concepts of power quality measurement and the reliability measures used in the electric power industry. Teaches power quality measures such as VSSI, crest factor, flicker, harmonics and THD. Discusses these PQ measures, common causes of poor PQ and possible mitigation strategies. Emphasizes the concepts and mathematical basis for common power system reliability indices and measures such as SAIDI, CAIDI, MAIFI, and SAIFI. Introduces common strategies for improving power system reliability measures. Discusses power quality problems on distribution systems, application standards, and proper grounding techniques.

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ENGT 3220: Motion Control for Engineering Technologist

3.00 Credits

Utah Valley University

Prerequisite(s): (AET 2270, AET 2275) OR (MECH 2550, MECH 2555) and University Advanced Standing. Corequisite(s): ENGT 3225. Examines design and integration of servo systems in automated systems. Applies mathematical principles to design concepts. Analyzes PID tuning and feedback control. Investigates servo motors for single axis control, multi-axis control, and coordinated motion control. Corequisite: ENGT 3225

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ENGT 3225: Motion Control for Engineering Technologist Lab

1.00 Credits

Utah Valley University

Prerequisite(s): (AET 2270, AET 2275) OR (MECH 2550, MECH 2555) and University Advanced Standing. Corequisite(s): ENGT 3220. Analyzes servo motors in automated systems. Applies servo motors to automated systems including wiring and programming. Explores PID tuning. Examines internal and external feedback loops. Apply servo motors to single axis control, multi-axis control, and coordinated motion control. Corequisite: ENGT 3220

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ENGT 3250: Automated Safety Systems

2.00 Credits

Utah Valley University

Prerequisite(s): AET 2270, AET 2275 and University Advanced Standing. Corequisite(s): ENGT 3255. Explores safety systems in industrial automation including instrumented safety systems, risk assessment, and design. Focuses on a life-cycle approach to automation engineering safety design. Incorporates safety standards such as ISO 13849, ISA 84, IEC 61508 and IEC 61511. Examines safety controllers, peripheral equipment, and relevant technology. Corequisite: ENGT 3255

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