NABCEP Solar Certification training at the CORE

Specials!

TWO CONSECUTIVE WEEKENDS - ONE GREAT TRAINING!

October 22,23 and 29,30 (40 hours) only $2,495.00

At the College of Renewable Energy, we know it can be difficult to dedicate one week of your time to attending training, that's why we developed our weeekend training course!

At the end of the 40 hours of INTENSIVE weekend training, you write the NACEP exam!

This course is designed for any individual or professionals (Electrician, Roofers, HVAC or solar professional) interested in learning about the requirements and procedures for designing and installing a solar photovoltaic solution. For an in-depth description of the course scroll down.

For more information call (905) 987-5475 or download and fill in our registration form and fax it to (905) 987-1716

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ONE CONSECUTIVE WEEK - October 24-28 (40 hours) $1,995.00

As an added bonus - this course includes:

Fall Arrest Certification that instructs on proper procedures for roof installations.

Training on Ontario's MicroFIT program and how you can take advanatge of it.

Write your NABCEP exam on the Friday afternoon of the training after a morning review.

For more information call (905) 987-5475 or for immediate booking, why not use Papal!

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Course Outline

A diversity of knowledge, skills, and abilities are required to design, install, and commission PV systems. In this hands-on course, participants will learn the fundamental concepts required for safe, code-compliant design and installation of PV systems. This course will cover system components, site analysis, PV module criteria, mounting systems, commissioning, and safety. Participants will also learn the basics of sizing a residential off-grid stand-alone and grid-tied batteryless system, wire sizing, over current protection, and grounding.
Participants who complete this course will be able to

Perform power and energy calculations.

Perform a load analysis for off-grid and batteryless grid-tied systems.

Diagram an array and battery bank in series and parallel configurations.

Determine the azimuth and altitude angle of the sun and evaluate shading potential.

Obtain and apply module specifications for a given module and determine a module’s performance given various environmental

Determine performance of an array/system based on irradiance changes or for array orientation and tilt angle at a given site.

Determine the magnetic declination, find the orientation and altitude angle of the sun, and evaluate the shade potential for a given site.

List the pros and cons of different mounting structures (ground, roof)

Determine the number of modules that can fit on a given roof space.

Interpret and apply data from equipment specification sheets.

Size a residential batteryless grid-tied system including the inverter, array, wiring and over current protection.

Identify the proper safety protocols for working with batteries.

Define battery depth of discharge, days of autonomy, and efficiency.

Specify a battery-based inverter given certain parameters.

Determine acceptable voltage drop for system circuits.

Perform detailed site analysis utilizing commercially available tools

IV-Curve and MPPT and Micro Inverters

Shading analysis

PV system VS conventional electrical systems

Performance calculation

Standard VS Grid-Tie PV system design

How to design a safe and code compliance PV system

Code compliance PV array sizing for Inverters

Common problems in PV system electrical design

A review of available PV computer software