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IEC 62933: Global Standard for Grid Energy Storage Systems
Rahul Jalthar

IEC 62933: Global Standard for Grid Energy Storage Systems

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As renewable energy adoption grows, energy storage systems (ESS) have become critical for balancing supply and demand, improving reliability, and supporting grid resilience. To ensure safety, performance, and interoperability, the International Electrotechnical Commission (IEC) developed the IEC 62933 series, a set of globally recognized standards.

These standards guide manufacturers, developers, and policymakers in designing and deploying safe, efficient, and sustainable storage solutions.

What is IEC 62933?

The IEC 62933 series establishes a framework for electrical energy storage (EES) systems, including grid-scale and commercial applications. It covers general requirements, safety, performance, environmental considerations, and grid integration.

Rather than being a single document, IEC62933 is a family of interlinked standards, each addressing a specific aspect of EES.

Breakdown of Key IEC 62933 Standards

IEC 62933: Global Standard for Safe and Reliable Energy Storage Systems

Here’s a detailed overview of the most important parts:

1. IEC 62933-1 – General Requirements

  • Defines basic concepts, classifications, and terminology for EES.
  • Provides common ground for stakeholders (manufacturers, regulators, utilities).
  • Establishes a systematic approach to planning, designing, and evaluating ESS.

2. IEC 62933-2-1 – Performance Testing for EES Systems

  • Sets methods to evaluate performance of storage systems.
  • Covers energy efficiency, response time, storage capacity, and life cycle.
  • Ensures consistent benchmarks for comparing technologies.

3. IEC TS 62933-2-2 – Functional Safety Assessment

  • A Technical Specification (TS) focusing on safety from a system function perspective.
  • Addresses potential hazards (thermal runaway, electrical failures).
  • Provides methods for risk identification and mitigation.

4. IEC TS 62933-2-3 – Reliability of Energy Storage Systems

5. IEC TR 62933-2-201 – Guidance on Safety Cases

  • A Technical Report (TR) providing practical guidance for ESS safety cases.
  • Supports developers and operators in building safety documentation.
  • Bridges the gap between technical standards and real-world applications.

6. IEC 62933-4-2 – Environmental Impact of EES Systems

  • Focuses on environmental assessment of energy storage technologies.
  • Considers carbon footprint, material use, and recycling practices.
  • Encourages sustainable deployment of large-scale ESS.

7. IEC 62933-4-4 – End-of-Life Management

  • Provides guidelines for decommissioning, recycling, and disposal of EES.
  • Promotes circular economy practices in the storage industry.
  • Reduces environmental risks associated with battery waste.

8. IEC 62933-5-1 – General Safety Considerations

  • Covers general safety requirements for stationary energy storage.
  • Includes electrical, chemical, mechanical, and fire safety aspects.
  • Ensures system safety across all technologies (batteries, flywheels, etc.).

9. IEC 62933-5-2 – Safety for Large-Scale EES

  • Focuses specifically on large battery energy storage systems (BESS).
  • Addresses thermal runaway prevention, emergency response, and system protection.
  • Critical for utility-scale storage projects.

10. IEC 62933-5-3 – Grid Integration Safety

  • Examines safety aspects during grid connection and operation.
  • Ensures ESS does not destabilize or endanger grid infrastructure.
  • Supports secure deployment in smart grids and microgrids.

Importance of IEC 62933 for the Industry

The IEC 62933 series provides:

  • Global Standardization – unifies practices worldwide.
  • Risk Reduction – prevents failures in high-risk ESS installations.
  • Sustainability – ensures safe end-of-life handling.
  • Investor Confidence – promotes compliance and long-term reliability.
  • Innovation Support – enables safe integration of emerging technologies like solid-state and hybrid storage.

Conclusion

The IEC62933 standard family is the backbone of global energy storage deployment. From general guidelines (IEC62933-1) to detailed safety (IEC62933-5-2) and environmental sustainability (IEC62933-4-4), it ensures storage systems are safe, efficient, and future-ready.

Adopting these standards is essential for manufacturers, developers, and regulators who aim to accelerate the clean energy transition while ensuring safety and reliability.

SCADA vs EMS in BESS – Key Differences and Applications in Battery Energy Storage
Rahul Jalthar

SCADA vs EMS in BESS: Understanding the Brain and Nerve System of Energy Storage

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SCADA vs EMS in BESS: Battery Energy Storage Systems (BESS) are more than just batteries—they are intelligent ecosystems. At the heart of this intelligence lie two key control systems: SCADA (Supervisory Control and Data Acquisition) and EMS (Energy Management System).

But what’s the difference between them? Why do you need both in your energy storage infrastructure? Let’s break it down.

🔍 What is SCADA in BESS?

SCADA is like the central nervous system of your energy infrastructure. It allows operators to monitor and control equipment remotely and in real-time.

✅ Key Functions of SCADA:

  • Real-time Monitoring: Tracks voltage, temperature, SOC (State of Charge), power output, and more.
  • Data Acquisition: Collects data from sensors, meters, and other field devices.
  • Alarm Management: Triggers alerts in case of system faults, safety issues, or performance anomalies.
  • Remote Control: Lets operators switch systems ON/OFF or change parameters remotely.
  • Visualization: SCADA HMIs (Human-Machine Interfaces) display data visually for easy interpretation.

SCADA systems in BESS typically interact with Battery Management Systems (BMS), Power Conversion Systems (PCS), Inverters, and environmental sensors.

⚙️ What is EMS in BESS?

EMS (Energy Management System) is a higher-level optimization system that manages how, when, and where energy is stored or dispatched, often based on grid requirements, market conditions, and renewable energy forecasts.

EMS is the strategic brain of the energy storage system. While SCADA controls how things operate, EMS decides what should be done to maximize efficiency, economics, and reliability.

✅ Key Functions of EMS:

EMS works above the SCADA layer, making strategic decisions based on data collected by SCADA and other sources.

🔁 Key Differences: SCADA vs EMS in BESS

FeatureSCADAEMS
Primary RoleOperational monitoring & controlStrategic energy optimization
ScopeDevice & hardware levelSystem-wide & market interaction
Real-time ControlYesNo (uses planning-based control)
ForecastingNoYes
Alarm & Event HandlingYesLimited (depends on integration)
Grid InteractionMinimalFull (based on market, grid, or DSO signals)
VisualizationSCADA HMI/GUIDashboards/Reports

🧠 Real-World Comparison: How SCADA & EMS Work Together

Imagine a utility-scale solar-plus-storage project:

SCADA’s Role:

  • Monitors PV inverter voltage, battery temperature, current flows.
  • Flags errors in PCS (Power Conversion System) and triggers shutdowns if needed.
  • Logs all sensor data every second.

EMS’s Role:

  • Analyzes day-ahead pricing forecasts and predicts solar production.
  • Decides to charge batteries at noon and discharge at 6 PM to maximize ROI.
  • Communicates with SCADA to execute commands.

Together, EMS and SCADA form a closed-loop intelligence system—SCADA watches, EMS decides.

🌐 Different Use Cases (EMS vs SCADA in BESS)

🔋 Residential ESS

  • SCADA is usually embedded at low levels.
  • EMS often comes pre-configured or in cloud-based form for load shifting and solar self-use.

🏭 Commercial & Industrial ESS

  • SCADA monitors multiple assets: batteries, PV, diesel gensets.
  • EMS optimizes cost-saving strategies across multiple sites.

⚡ Utility-Scale BESS

  • SCADA integrates with substation automation and DNP3/IEC 61850 protocols.
  • EMS participates in energy markets, frequency response, and ancillary services.

📈 Why You Need Both

Some may think EMS alone is enough, but it’s not. Without SCADA, the EMS is blind. Without EMS, the SCADA is mute.

✅ SCADA ensures the system runs safely.
✅ EMS ensures it runs profitably.

You need both for your BESS to be intelligent, safe, and profitable.

❓ FAQ: SCADA vs EMS in BESS

Q1. Can SCADA and EMS be integrated into one platform?
Yes. Many vendors offer combined platforms or modular systems where EMS sits on top of SCADA.

Q2. Is EMS cloud-based and SCADA local?
Generally, yes. SCADA operates locally for fast response, while EMS can be local or cloud-based for broader optimization.

Q3. Which one is more expensive?
EMS often costs more due to its software intelligence, licensing, and integration needs.

Q4. Which is more important for safety?
SCADA is crucial for safety and reliability. EMS focuses more on economic performance.

📌 Final Thoughts: Build a Smarter BESS with SCADA and EMS

Understanding the SCADA vs EMS in BESS distinction is not just academic—it has real business and technical consequences. If you want your Battery Energy Storage System to be both safe and smart, you need both systems.

Understanding their roles and differences is crucial for:

  • System integrators
  • Project developers
  • Energy consultants
  • Facility managers
  • And anyone involved in the deployment of BESS

Whether you’re building a microgrid or managing utility-scale storage, make sure your BESS includes both a robust SCADA and an intelligent EMS.

Looking for help integrating SCADA and EMS in your energy project? Reach out to a qualified consultant who understands both layers of the stack and can optimize your BESS from the ground up.