About Electromechanics

To enable the student to acquire the knowledge, skills and attitude required to ensure the operation and maintenance of automated production equipment; to take action at the primary operational level; to service different types of automated systems and their mechanical, hydraulic, pneumatic, electrical and electronic components; and to work in one of the various types of production industries that use automated systems.

Learning environment


Employment Prospects

  • Photo-Electronic Regulator Repairer
  • Electronic Equipment Repairer
  • Automated Systems Repairer
  • Automated Processing Equipment Repairer
  • Control Panel Tester
  • Maintenance of Automated and Manual Machines
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Program outline

The Automated Systems in Electromechanics program leading to a DEP is a 1800 hour course.

Day program (6 hrs/day): approximately 15 months.

Program Competencies
The Occupation and Training Process
This module introduces the student to the automated systems electromechanics trade and its many interesting opportunities. While learning about which abilities and skills are required, course expectations, as well as working conditions and job prospects, the student reconfirms commitment to the program of study.
 15 1
Health and Safety
The student will learn how to identify hazards, prevent risks and eliminate dangers on construction and industrial maintenance sites.
 30 2
Using Computers
During this preliminary computer module, the student learns data management and research using a personal computer workstation, the local area network, as well as the Internet. Current application programs specific to the electromechanical trade are introduced.
 30 2
Checking Electrical Circuits
The student learns to safely and accurately measure, test and troubleshoot DC and AC circuits using oscilloscopes, A-meters as well as digital and analog instrumentation, on low and medium voltage equipment and machinery.
 120 8
Drawing Sketches
Using design standards and conventions, the student will draw orthogonal, isometric, and freehand sketches using both the imperial and metric systems of measurement.
 30 2
Performing Manual Machining Operations
The student produces a moderately-complex useful object out of plastics, ferrous, and non-ferrous metals using hand tools. The student will practice marking-out, filing, boring and tapping as well as measuring with micrometers and callipers. Students maintain quality and adhere to industry standards and tolerances.
 105 7
Moving Equipment
Safely moving, storing, disassembling and assembling materials and equipment is an integral part of the industry. The student learns appropriate selection and use of techniques for lifting and moving loads with levers, hoists, cranes, cables, and slings. Signalling codes and knowledge of knots enables the student to perform tasks from drawings and written instructions.
 30 2
Cutting and Welding
The student will learn electric arc, semi-automatic MIG and TIG welding techniques for corrective maintenance. He/she will cut and weld metal sheets while learning proper adjustment of welding equipment. Strict health and safety procedures for using, dismantling, and storing welding equipment are stressed.
 75 5
Connecting Conduits
By assembling an actual circuit, the student learns to install and maintain ferrous and non-ferrous pipes, hoses and conduits. He/she will measure, cut, bend, flare, solder, glue, and crimp pipes and conduits made out of copper, iron, and rubber. Quality is measured using leak-test techniques and tools.
 30 2
Industrial Electronics Circuits
Troubleshooting flow charts, detecting input and output (I/O) signal defects and the appropriate selection and replacement of defective components is the cornerstone of this module. The student learns to measure I/O signals using oscilloscopes, VOM-meters, and signal generators on pre-wired electronic boards.
 105 7
Using Machine Tools
Using our extensive machine shop, the student will learn to machine moderately complex parts using lathes, milling and grinding machines, etc. Emphasis is placed on safety as well as precise, methodical work which uses materials economically.
 90 6
Analyzing Logic Circuits
The core of the automated system is the sequential operations of the logic circuit using electric, electronic, pneumatic and hydraulic solutions. The student will analyze and troubleshoot real logic circuits and solve combinational and sequential logic equations with respect to I/O variables.
 90 6
Conventional Alignment
The student will perform vertical and horizontal alignment tests for shafts, belts, and pulleys using gauges, laser devices, and other alignment equipment on a real automated system.
 30 2
Maintaining Mechanical Devices
Conduct preventative and corrective maintenance on motion-transmission mechanical devices, such as shafts, bushings, bearings, pulleys, and belts. While using logical sequencing to assemble and disassemble gear boxes, bearings, drives, and other motion-transmission components, emphasis will be placed on the student acquiring a solid understanding of wear, friction, and industrial lubrication.
 105 7
Assembling Pneumatic Circuits
The student will learn to design, prototype, produce, and troubleshoot an industrial pneumatic circuit. Simulation software is used to size pneumatic components, simulate faults, and debug activities.
 75 5
Assembling Hydraulic Circuits
The student will learn to design, produce and troubleshoot a functional hydraulic circuit operating up to 1000 psi, using an assembly panel, hydraulic instrumentation and hydraulic power packs.
 60 4
Maintaining Motor Circuits
Learn to operate high voltage AC and DC motors, including control of starting, breaking, torque, and speed. The student will schedule and perform preventive and corrective maintenance.
 105 7
Maintaining Pneumatic and Hydraulic Equipment
Perform preventive and corrective maintenance on hydraulic pumps, air compressors, and motors. The student will acquire a thorough knowledge of lubrication, oils and their problems, cleaning methods, as well as the alignment and adjustment of hydraulic and pneumatic components.
 60 4
Calibrating a Control Loop
The student will learn to calibrate and adjust the parameters of an industrial control loop. Student will use a process control simulator to adjust level, pressure, flow and temperature in open and closed loop circuits.
 60 4
Maintaining Electropneumatic & Electrohydraulic Circuits
Maintaining electropneumatic and electrohydraulic circuits includes adjustment and control of pressure and flow, and the inspection of electrical connections and safety devices in concordance with the Canadian Electrical Code. The student will perform quality control, verification, testing and troubleshooting of electropneumatic and electrohydraulic circuits.
 60 4
Programming Controllers
The student will learn the basic languages for programming Programmable Logic Controllers (PLCs). He/she will gain experience using several different communication protocols, such as, Device net, Modbus, Ethernet, etc., as well as different network platforms and user interfaces. Students will learn and apply configurations for communication between controllers and interfaces, defining the run and off modes of automated systems.
 90 6
Electric Motor Control Devices
From the connection of AC and DC drives to their corresponding motors to the programming of the drives, student will learn to configure, activate, assess feedback, and service electric motor control devices. Either as a stand alone system or within a network, the student will learn to monitor and modify the electronic components.
 60 4
Job Search Techniques
Developing strategies and techniques for finding a job are critical components of the training program. The student will prepare a cover letter and a resumé and learn to prepare for employment interviews. Guest speakers will bring practical advice and hints on getting that first job.
 15 1
Installing an Automated System
Working in a team, the student will do the complete installation of a functioning automated system, from the connection of the electrical and mechanical equipment to the configuration and installation of the hardware and software.
 105 7
Planned Maintenance
Proactive preventive maintenance concepts will be reinforced while the student implements a virtual maintenance schedule using specialized software (PM) for an operating automated system. Drawing from concepts learned in previous modules, the student will apply risk management and failure theory to the every day life of an electromechanical system.
 45 3
Troubleshooting Automated Systems
In this module the student faces the ultimate challenge and reward of the program. In an automated system where defects have been intentionally lodged, the student must identify the root causes and then find solutions to the problems.
 90 6
Entering the Work Force
For three to four weeks the student will do a stage at a company with an automated electromechanical system. He/she will apply his/her knowledge while working to gain experience and understanding of working under “real world” conditions.
90 6

Automated Systems in Electromechanics
on Global News Montreal