Industrial Systems Technology

Wallace and Sparks Campuses

(FORMERLY APPLIED ENGINEERING TECHNOLOGY)

The Industrial Systems Technology program provides instruction and skills development in the rapidly growing, related field of Industrial Systems Technology. Instruction is presented at a highly technical level, involving the applications of mathematics, science, and communication skills as well as hands-on training in AC and DC fundamentals, process controls, and principles of industrial mechanics and maintenance, robotics, programmable controllers, hydraulics and pneumatics. Successful completion of the program prepares graduates for entry-level employment in a variety of industrial-related fields.

Degrees and Certificates

Course Descriptions

INT 100: Mathematics for Industrial Technicians

Credits 3 Lecture Hours 3 Lab Hours 0

This course is designed to provide an understanding of basic mathematical concepts used in an industrial setting. Topics include the arithmetic of whole numbers, fractions, and decimals; basic ratio, proportion, and percent; application problems in industrial maintenance.

INT 101: DC Fundamentals

Credits 3 Lecture Hours 2 Lab Hours 3

This course provides an in depth study of direct current (DC) electronic theory. Topics include atomic theory, magnetism, properties of conductors and insulators, and characteristics of series, parallel, and series-parallel circuits.  Inductors and capacitors are introduced and their effects on DC circuits are examined.   Students are prepared to analyze complex DC circuits, solve for unknown circuit variables and to use basic electronic test equipment.  This course also provides hands on laboratory exercises to analyze, construct, test, and troubleshoot DC circuits. Emphasis is placed on the use of scientific calculator and the operation of common test equipment used to analyze and troubleshoot DC and to prove the theories taught during classroom instruction. This is a CORE course.

INT 103: AC Fundamentals

Credits 3 Lecture Hours 2 Lab Hours 3

This course provides an in depth study of alternating current (AC) electronic theory.  Students are prepared to analyze complex AC circuit configurations with resistors, capacitors, and inductors in series and parallel combinations. Topics include electrical safety and lockout procedures, specific AC theory functions such as RLC, impedance, phase relationships, and power factor. Students will be able to define terms, identify waveforms, solve complex mathematical problems, construct circuits, explain circuit characteristics, identify components, and make accurate circuit measurements using appropriate measurement instruments. They should also be able to perform fundamental tasks associated with troubleshooting, repairing, and maintaining industrial AC systems. This is a CORE course.

Prerequisites

ELT 108 OR INT 101

INT 105: Introduction to Process Technology

Credits 3 Lecture Hours 2 Lab Hours 2

This course is designed to provide students with an introduction to process control technology and various instruments used to control processes. Upon completion, students should be able to comprehend principles of process control technology and the application of various instruments used to control processes in an industrial setting.

INT 113: Industrial Motor Control I

Credits 3 Lecture Hours 1 Lab Hours 4

This course is a study of the construction, operating characteristics, and installation of different motor control circuits and devices. Emphasis is placed on the control of three phase AC motors. This course covers the use of motor control symbols, magnetic motor starters, running overload protection, pushbutton stations, multiple control stations, two wire control, three wire control, jogging control, sequence control, and ladder diagrams of motor control circuits. Upon completion, students should be able to understand the operation of motor starters, overload protection, interpret ladder diagrams using pushbutton stations and understand complex motor control diagrams.

Prerequisite Courses

INT 117: Principles of Industrial Mechanics

Credits 3 Lecture Hours 2 Lab Hours 3

This course provides instruction in basic physics concepts applicable to mechanics of industrial production equipment. Topics include the basic application of mechanical principles with emphasis on power transmission, specific mechanical components, alignment, and tension. Upon completion, students will be able to perform basic troubleshooting, repair and maintenance functions on industrial production equipment. This is a CORE course.

INT 118: Fundamentals of Industrial Hydraulics and Pneumatics

Credits 3 Lecture Hours 2 Lab Hours 3

This course includes the fundamental concepts and theories for the safe operation of hydraulic and pneumatic systems used with industrial production equipment. Topics include the physical concepts, theories, laws, air flow characteristics, actuators, valves, accumulators, symbols, circuitry, filters, servicing safety, and preventive maintenance and the application of these concepts to perform work. Upon completion, students should be able to service and perform preventive maintenance functions on hydraulic and pneumatic systems. This is a CORE course.

INT 119: Principles of Mechanical Measurement and Technical Drawing

Credits 3 Lecture Hours 1 Lab Hours 4

This course provides instruction in the use of precision measuring tools and the interpretation of technical drawings. Topics include the use of calipers, micrometers, steel rules, dial indicators, identifying types of lines and symbols of technical drawings, recognition and interpretation of various types of views, tolerances, and dimensions. Upon course completion, students will be able to use precision measuring tools and interpret technical drawings.  

INT 123: Concepts of Solid State Electronics

Credits 3 Lecture Hours 3 Lab Hours 2

This course is an introduction to semiconductor fundamentals and applications to electronic devices.  It covers the basic operations and applications of rectifier circuits, transistors, and thyristors.  Coverage is given to safety, use, and care with hazardous materials and personnel as well as material and environmental considerations.  Upon completion students will be able to construct and test for proper operation of various types of solid state devices. 

INT 127: PRINCIPLES OF INDUSTRIAL PUMPS AND PIPING SYSTEMS

Credits 3 Lecture Hours 2 Lab Hours 2

This course provides instruction in the fundamental concepts of industrial pumps and piping systems.  Topics include pump identification, operation, and installation, maintenance and troubleshooting, and piping systems, and their installation.  Upon course completion, students will be able to install, maintain, and troubleshoot industrial pumps and piping systems.

INT 129: INDUSTRIAL SAFETY AND MAINTENANCE TECHNIQUES

Credits 3 Lecture Hours 1 Lab Hours 4

This course provides instruction in basic maintenance techniques and safety.  Topics include drawing, sketching, basic hand tools, portable power tools, stationary power tools, measurement, screw threads, mechanical fasteners, machinery and equipment installation, rigging, and their proper safe operations. 

INT 132: Preventive and Predictive Maintenance

Credits 3 Lecture Hours 2 Lab Hours 2

This course focuses on the concepts and applications of preventive and predictive maintenance. Topics include the introduction to optic alignment equipment, vibration testing and analysis, data collection, job safety, tool safety, systems analysis, preventive maintenance procedures and tasks, and predictive maintenance concepts. Upon completion, students will demonstrate the ability to apply the planning process for proper preventive and predictive maintenance.

INT 134: Principles of Industrial Maintenance Welding and Metal Cutting Techniques

Credits 3 Lecture Hours 2 Lab Hours 3

This course provides instruction in the fundamentals of acetylene cutting and the basics of welding needed for the maintenance and repair of industrial production equipment. Topics include oxy-fuel safety, choice of cutting equipment, proper cutting angles, equipment setup, cutting plate and pipe, hand tools, types of metal welding machines, rod and welding joints, and common welding passes and beads. Upon course completion, students will demonstrate the ability to perform metal welding and cutting techniques necessary for repairing and maintaining industrial equipment. This is a CORE course.

INT 139: Introduction to Robot Programming

Credits 3 Lecture Hours 1 Lab Hours 4

This course provides an introduction robotic programming. Emphasis is placed on but not limited to the following: Safety, motion programming, creating and editing programs, I/O instructions, macros, program and file storage. Upon completion the student will be able to safely perform basic functions in the work cell as well as program a robot to perform simple functions.

INT 140: F.A.M.E. MANUFACTURING CORE EXERCISE 1, SAFETY CULTURE

Credits 1 Lecture Hours 1 Lab Hours 0

This course introduces the Federation of Advanced Manufacturing Education (FAME) MCE-1 (Manufacturing Core Exercise) for Safety Culture.  The course includes an introduction to safety and safety practice and the development of a safety culture.  Specific topics covered regarding safety culture are:

  1. Internal, self-driven value for safe behavior
  2. Active concern for both personal safety and the safety of others
  3. Full understanding of the impact and consequence of unsafe behavior and acts
  4. Proactive thinking about safety, safe practices, and consequences
  5. Self-driven initiative to be safe and to promote the safety of others

INT 142: F.A.M.E. MANUFACTURING CORE EXERCISE 2, WORKPLACE VISUAL ORGANIZATION (5S)

Credits 1 Lecture Hours 1 Lab Hours 0

This course introduces the Federation of Advanced Manufacturing Education (FAME) MCE-2 (Manufacturing Core Exercise) for Workplace Visual Organization (AKA:  5S).  Students will learn how to achieve higher productivity, produce fewer defects, meet deadlines, attain higher workplace safety and how to expose abnormal work conditions quickly and easily for correction and countermeasure.  The 5S process will be clearly defined with experiential exercises, reinforcing the following process steps and their objectives: 

  1. Sift                                    Organization
  2. Sort                                   Orderliness
  3. Sweep and Wash             Cleanliness
  4. Spic and Span                  Total Standardization
  5. Sustain                          System Sustainment

INT 144: F.A.M.E. MANUFACTURING CORE EXERCISE 3, LEAN MANUFACTURING

Credits 1 Lecture Hours 1 Lab Hours 0

This course introduces the Federation of Advanced Manufacturing Education (FAME) MCE-3 (Manufacturing Core Exercise) for Lean Manufacturing.  Students will be introduced to a systematic method for waste minimization (AKA:  Muda) within a manufacturing system, without sacrificing productivity.  Lean also takes into account waste created through overburden (AKA:  Muri) and waste created through unevenness in workloads (AKA:  Mura).  The Lean management philosophy will be clearly defined and explained with experiential exercises, reinforcing the following concepts:

  1. The value-added product
  2. The maintenance value-added product
  3. Value-added work and necessary work
  4. How this leads to increased profit
  5. Workload unevenness (Mura)
  6. Waste created through overburden (Muri)
  7. The seven areas of non-value-added waste (Muda):  conveyance, correction, motion, over-production, over-processing, waiting and inventory

INT 146: F.A.M.E. MANUFACTURING CORE EXERCISE 4, PROBLEM SOLVING

Credits 1 Lecture Hours 1 Lab Hours 0

This course introduces the Federation of Advanced Manufacturing Education (FAME) MCE-4 (Manufacturing Core Exercise) for Problem Solving.  Students will learn how to use the eight-step problem solving model in an experiential learning environment, in conjunction with the PDCA cycle (plan, do, check and act).  The eight steps students will learn to use are:

  1. Clarify the problem (plan)
  2. Breakdown the problem (plan
  3. Set the target (plan)
  4. Analyze the root cause (plan)
  5. Develop countermeasures (plan)
  6. Implement countermeasures (do)
  7. Monitor results and process (check)
  8. Standardize and share success (act)

INT 148: F.A.M.E. MANUFACTURING CORE EXERCISE 5, MACHINE RELIABILITY

Credits 1 Lecture Hours 1 Lab Hours 0

This course introduces the Federation of Advanced Manufacturing Education (FAME) MCE-5 (Manufacturing Core Exercise) for machine reliability.  Students will learn how to use the process of Reliability-Centered Maintenance (RCM) to drive for zero downtime and reach for maximum Heijunka.  Students will be given an in depth understanding of Heijunka (Japanese for “leveling”), as a process that maintains a balanced relationship between predictability by leveling demand, flexibility by decreasing changeover time and stability by averaging production volume and type, over the long-term.  The RCM process will be clearly defined with experiential exercises reinforcing comprehension and application of the following core questions:

  1. What are the functions of the equipment?
  2. How does it fail?
  3. What causes it to fail?
  4. Does it matter if it fails?
  5. What can be done to predict or prevent each failure?
  6. What if the failure cannot be prevented?

INT 208: Advanced Process Simulation

Credits 3 Lecture Hours 1 Lab Hours 4

Upon completion, students will be able to demonstrate their ability to develop programs, load programs into real-world PLCs, and troubleshoot the system if necessary. Emphasis is placed on analog programming, designing complete working systems, start-up and troubleshooting techniques, and special projects. Topics include plant safety, piping and instrument diagrams, pressures, levels, flows and temperature, and loops designed to function in real time.

INT 213: Industrial Motor Control II

Credits 3 Lecture Hours 1 Lab Hours 4

This course is a continuation of INT 113 focusing on additional theory and practice regarding industrial motor control schematics and wiring. Included are multispeed and softstart wiring techniques for industrial motors and synchronous motor control. The student will also be exposed to the theory, setup and programming of variable speed drives. Upon completion students will be able to remove, replace, and wire different types of resistors, reactors and transformers similar to those used in the control of industrial polyphase motors and large DC motors.

Prerequisites

ELT 209 or INT 113

INT 253: INDUSTRIAL ROBOTICS

Credits 3 Lecture Hours 2 Lab Hours 2

This course provides instruction in concepts and theories for the operation of robotic servo motors and power systems used with industrial robotic equipment. Emphasis is on the application of the computer to control power systems to perform work. Student competencies include understanding of the functions of hydraulic, pneumatic, and electrical power system components, ability to read and interpret circuitry for proper troubleshooting and ability to perform preventative maintenance.

INT 284: Advanced Programmable Logic Controllers (PLC's)

Credits 3 Lecture Hours 2 Lab Hours 3

This course includes the advanced principles of PLC's including hardware, programming, and troubleshooting.  Emphasis is placed on developing on advanced working programs and troubleshooting hardware and software communication problems.  Upon completion, students should be able to demonstrate their ability in developing programs and troubleshooting the system.

Prerequisites

INT 184 OR ELT 231

INT 296: CO-OP

Credits 1 Lecture Hours 0 Lab Hours 5

This course constitutes a series wherein the student works on a part-time basis in a job directly related to Applied Engineering.  In this course the employer evaluates the student's productivity and the student submits a descriptive report of his work experiences.  Upon completion, the student will demonstrate skills learned in an employment setting.

Prerequisites

Instructor Approval