Battery Energy Storage Systems (BESS)

Learn how BESS works end-to-end—tech fundamentals, cost and revenue models, grid integration, BMS, digital twins, and lifecycle planning.

Battery Energy Storage Systems (BESS) is a live, instructor-led program built around real industry thinking: how storage is sized, evaluated, deployed, and operated. You’ll cover CapEx/OpEx and lifecycle cost, revenue streams like arbitrage and ancillary services, modeling of power system components, performance metrics (cycle life, LCOE), battery management systems, digital twin simulation, augmentation planning, thermal/electrical integration, and distributed vs utility-scale storage strategies—with case studies throughout.

Format Live Online
Duration 100 Hours
Start Date Cohort Based (Announced Soon)
Final Assessment Required
Sponsorship Sponsored Seats After Qualifying Exam
Prerequisites Basic Electrical / Energy Concepts (Preferred)
Enroll Now

Key Program Takeaways

Understand BESS technology, economics, and grid integration—plus how real projects think about performance, safety, and lifecycle ROI.

Cost Modeling

CapEx / OpEx / Lifecycle

Revenue Streams

Arbitrage + Ancillary

Power System Modeling

Grid Component Response

BMS Fundamentals

Safety + Control

Digital Twin

Lifecycle Extension

Deployment Strategies

DERs vs Utility Scale

List of Modules in this Program

01

Storage Landscape & Fundamentals

Overview of storage technologies (including pumped hydro), where BESS fits, and the basics of energy applications and use-cases.

02

Techno-Economics of BESS

CapEx breakdown (cells, BOS, installation), OpEx (degradation, maintenance), sensitivity and scenario planning, lifecycle cost projections, and performance metrics like cycle life and LCOE.

03

Markets, Revenue & Grid Response

Revenue streams: energy arbitrage, capacity markets, ancillary services—plus market rules, bidding strategies, and modeling/response of power system components with case studies.

04

Operations, Digital Twin & Integration

Digital twin simulation and implementation architectures, BMS design and functions, strategic augmentation planning (compatibility + case study), thermal/electrical integration of new modules, and distributed vs centralized storage strategies with interoperability examples.

Why This Program

Tech + Economics Together

Not just battery theory—learn how projects are justified using lifecycle cost and revenue.

Market-Linked Thinking

Understand arbitrage, capacity, and ancillary services with rules and bidding case studies.

Modern Operations

Digital twins, augmentation planning, and integration topics that show up in real deployments.

Battery Management System

Design and functions of BMS—safety, control logic, monitoring, and operational best practices.

Revenue Modeling

Arbitrage, capacity markets, and ancillary services with bidding case studies.

"
The cost and revenue breakdowns made BESS finally feel real. I could explain LCOE, degradation, and market value clearly.

Pranav K

Energy Analyst

Digital Twin

Simulation for predictive lifecycle extension and operational optimization.

Thermal Integration

Thermal/electrical integration of new modules, modeling, and toolchains.

Deployment Strategy

Distributed (DERs, microgrids) vs centralized (utility-scale BESS) strategies, interoperability, and case studies.

CapEx / OpEx Markets BMS Digital Twin

Get Certified

Earn a completion certificate and assessment-based evaluation at program end.

Certificate Battery Energy Storage Systems (BESS)