ATS Basics and Design Considerations This engineering module reviews transfer switch basics (terminology and theory of operation) , design, controls, and specifier considerations to include sizing, withstand and close-on ratings, enclosure types, and maintenance services. Bonding and Ground of the EPSS This engineering module provides the student with a foundational understanding of bonding and grounding, to include NEC definitions, grounding theory, overviews of ground faults, and the difference between separately derived and not-separate derived systems. Introduction to Generator Set Sizing Generators have several factors that need to be considered when appropriately sizing for a project, other than the summation of kW. In this engineering module, the student will learn how various parameters of an application (such as ambient conditions, load details, stepping, code requirements, etc.) must all be considered when optimally sizing a generator set. Data Centers are growing and evolving at a rapid pace. Designing power generation for data center needs has some unique application considerations. This engineering module will break down common industry terminology, identify component designs, explain the difference between Tier 4 certified, Tier 4 compliant, and Tier IV data center, and describe key factors impacting high density generator yards. Battery Energy Storage Systems (BESS) Battery energy storage systems are one major part of onsite power generation landscape. In this engineering module, students learn BESS basics, different types of energy storage technologies, the difference between BESS and generators, as well as how hybrid systems combine BESS and diesel generators. In addition, you will learn about industry trends related to battery energy storage, specifically as it relates to hybrid genset applications. Paralleling Basics and Considerations for Hybrid Technology and Microgrids Paralleling power generation systems is a design consideration that has been around for a long time, but in recent years it has become increasingly important to understand what paralleling does, how it is accomplished, and why it is important for hybrid technologies and microgrids applications. In this engineering module, the student will learn about paralleling terminology, theory, and controls that make these system designs reliable, scalable, and resilient. In addition, they will learn how paralleling technology fits into hybrid and microgrid design considerations. Economics of Generators and Standby Power Systems This engineering module provides an introduction to feasibility studies for Microgrid applications. Students will learn to assess a wide range of design options that integrate various dispatchable and renewable energy sources, such as synchronous generators, energy storage systems, solar, and fuel cells. Students will learn how to optimize energy assets to meet economic and sustainability goals through detailed load profile analysis and site-specific data. By the end of this course, participants will be able to understand feasibility assessments that drive decisions for low-cost and low-emission microgrid solutions. Design Considerations and Special Applications Data Center Basics and Design Considerations
Product/Service
Member Pricing
Non-Member Pricing
EGSA Engineering School
$280
$350
Duration
8 hours
How to buy? Please visit EGSA’s website to register: https://egsa.org or login to MyEGSA and click on the ‘Events’ tab. If you are interested in hosting an Engineering School, please reach out to EGSA’s Education team at education@egsa.org to iquire. (Pricing subject to change.)
12 | EGSA Course Catalog
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