Our FCR solution combines:

• PowerSync EMS – our advanced energy management system for real-time control and optimization

• SCADA Configuration – customized to interface with Kehua’s PCS and external grid systems

• Kehua Power Conversion System (PCS) – grid-proven, high-speed response performance

• FFD BESS – a parallel communication architecture over TCP/IP, enabling fast and accurate communication with the TSO’s EMS

This architecture ensures sub-second response times and precise frequency regulation, meeting the strictest FCR technical requirements.

In addition to the hardware and controls, we provide:

• Pre-installed system software

• Full engineering documentation

• Detailed project BOM

• Layout design and connection drawings

• Preconfigured settings for FCR compliance

This ready-to-deploy solution allows our partners to implement FCR with ease and confidence, saving time and reducing commissioning risks.

FFD Power’s FCR package is designed to:

• Meet all relevant grid codes

• Support critical grid stability functions

• Ensure seamless integration into complex grid environments

Frequency Ranges

47.5 Hz – 49.0 Hz: Operable for more than 30 minutes. In this low-frequency range, the system can continuously provide active power support to prevent further frequency decline and allow time for system recovery.

49.0 Hz – 51.0 Hz: Unlimited operation. This is the normal grid frequency range, where the system can continuously provide frequency regulation services to maintain stability.

51.0 Hz – 51.5 Hz: Operable for more than 30 minutes. In this high-frequency range, the system absorbs excess active power to prevent over-frequency and buffer the grid.

Resistance to Rate of Change of Frequency (RoCoF)

The FFDPOWER BESS can maintain grid-connected operation while withstanding a RoCoF of up to 1.7 Hz/s. This tolerance allows the system to respond to sudden large generator trips or abrupt load changes, preventing disconnection and enhancing grid resilience during severe frequency fluctuations.

Limited Frequency Sensitivity Mode – High Frequency (LFSM-O)

Active Power Regulation: When frequency deviates outside the insensitivity range (50.2–50.5 Hz), the BESS provides active power regulation, ensuring dynamic control only occurs outside minor fluctuation ranges.

Configurable Droop Settings: Active power droop settings are adjustable from 0.1% to 12% via the EMS, enabling flexible response for various grid conditions.

Fast Response Time: The inverter responds in less than 500 milliseconds, providing rapid and reliable grid support during over-frequency events.

LFSM-O Operation: The system adjusts output or absorption based on frequency. It reduces power during over-frequency and increases absorption until full charge, maintaining stable operation while switching flexibly between modes.

Energy Management: The BESS absorbs energy until full capacity is reached, preventing overcharging. TSOs may specify continued absorption during high-frequency events.

Transition Management: Different droop settings and smooth transitions ensure stable power balance during shifts between absorption and release modes.

Limited Frequency Sensitivity Mode – Low Frequency (LFSM-U)

Active Power Regulation: The BESS responds to under-frequency events outside the configurable insensitivity range (49.8–49.5 Hz), providing precise control for grid stability.

Configurable Droop Settings: Droop settings are adjustable from 0.1% to 12%, ensuring compliance with grid requirements.

Fast Response Time: The system reacts within 500 milliseconds, preventing cascading failures and stabilizing the grid.

LFSM-U Operation: The BESS absorbs power during frequency recovery and transitions to discharge mode as needed. It increases output during falling frequency to stabilize the grid.

Energy Management: Discharge continues until full depletion, with TSO options for prolonged support.

Mode Transitions and Capacity Limits: The BESS manages smooth transitions and adheres to energy capacity limits, ensuring safe operation.

Automatic Disconnection: If the system cannot discharge before UFLS activation at 49 Hz, it disconnects to prevent further instability.

Standardized Primary Frequency Regulation (FSM)

Active Power Response: The BESS adjusts output per TSO parameters, with zero deadband or standard settings to ensure immediate response to frequency changes.

Response Parameters: Minimum variation is 10% of rated power, with adjustable deadband (0–200 mHz) and droop (0.1–12%).

Power Regulation: Reduces output during frequency rise and increases output during drop, efficiently managing power flow and grid stability.

Frequency Ramps & Sudden Shifts: The system adapts to rapid changes, maintaining stability and avoiding fluctuations.

Response Timing: Initial reaction is <500 ms, with full adjustment completed in 30 seconds.

aFRR Capability: Supports continuous active power adjustments for Automatic Frequency Restoration Reserve, restoring energy capacity within 2 hours while maintaining regulation during emergencies.

Remote Control & Active Power Management

Remote On/Off: The EMS allows operators to start or stop the BESS remotely. Active power stops within 5 seconds of command.

Active Power Adjustment: Output can be modified within 10 seconds after receiving commands, supporting flexible EMS control.

Regulation: Both remote and manual adjustments are supported. Participation in FCR ensures compliance with TSO-defined activation times, sustained output for at least 60 minutes, and precise setpoint maintenance.

Measurement & Transmission: Key parameters are measured at ≤1-second resolution and transmitted in real time for monitoring.

Automatic Connection & Reconnection

Automatic Reconnection: The BESS reconnects when frequency is 49.9–50.1 Hz and voltage is 0.9–1.1 pu. A minimum 60-second delay ensures stable resynchronization.

Ramp Rate Control: Active power increase is limited to ≤20% of Pmax per minute. Alternative reconnection conditions can be configured with TSO/DSO agreements.

Artificial Inertia

Virtual Inertia Function: The BESS emulates synchronous generator inertia via inverter technology, stabilizing grids with high renewable penetration.

Control System: Configurable per TSO, ensuring effective and fast virtual inertia contribution.

Parallel Operation: Supports grid stability during rapid frequency deviations with preset levels.

Resistance to Short Circuit

Fault Ride-Through (FRT): LVRT and HVRT capabilities allow the system to stay connected during voltage sags or current surges.

Fault Current Contribution: EMS limits fault current to safe ranges, protecting both grid and system.

Fast Protection & Recovery: Rapid fault detection and protection ensure smooth resumption of normal operation after fault clearance, maintaining continuous power supply.

Parameter Compliance: Voltage sag depth, duration, and current limits follow local grid codes and TSO requirements.