Energy & Power Wind Power Generation

Coordinated Control System for Wind Turbine Pitch, Yaw, and Grid Integration

Update: 2026-01-09

Problem Definition

Engineering Verification

This solution has been validated by Atlamech Engineering based on the following standards:

View Details

Technical Scope

Compliance Standards

Implementation Strategy

Key Deliverables

Control system specification, PLC/SCADA configuration, grid code compliance documentation, and commissioning procedures

Consultation Notes

Implement IEC 61400-25 compliant communication protocols
Consider redundancy for critical control loops
Coordinate pitch and yaw response times to minimize mechanical stress
Validate grid code compliance across entire power range
Include predictive maintenance algorithms for pitch bearings

Infrastructure Taxonomy

Industrial PCs

Power Quality Analyzers

Grid-Tie Inverters

Servo Drives

Absolute Encoders

Typical Application Patterns: Pitch control during wind gusts Yaw optimization for wind direction changes Reactive power compensation for grid support Low-voltage ride-through coordination

Knowledge Areas

Wind Power Generation Systems & Grid Integration

Engineering Relation Summary

Technical Components

master controller, PLC/SCADA configuration, pitch control subsystem

Engineering Constraints

-30°C to +50°C operating temperature, IEC 61400-1 Class I/II/III wind conditions

Core Optimization Logic

hierarchical control architecture, Control Logic

Implementation Evidence Summary

Project Brief

Coordinated Control System for Wind Turbine Pitch, Yaw, and Grid Integration Implementation

System Scale

Multiple wind turbines with individual power ratings between 1500-12000 kW, operating at 690-33000 V.

Operating Conditions

IEC 61400-1 Class I/II/III wind conditions, operating temperature range -30°C to +50°C.

Implementation Constraints

Grid code compliance requirements, mechanical stress limitations on pitch and yaw systems, real-time response requirements.

Technical Knowledge Cluster

Wind Power Generation Systems & Grid Integration

Technical analysis of wind power generation systems covering aerodynamic design, power electronics architecture, and grid integration challenges, with reference to IEC, IEEE, and ENTSO-E standards for structural and electrical compliance.

Wind Turbine Aerodynamic Design & IEC 61400 Standards

Analysis of blade aerodynamics, power coefficient optimization, and compliance with IEC 61400-1 structural design requirements.

Power Electronics for Variable-Speed Wind Turbines

Design of doubly-fed induction generator (DFIG) and full-converter systems with grid code compliance for voltage/frequency regulation.

Ready to Specify?

Use Manual Inquiry Form

Technical Assistant

FOCUSED ON VFD / MOTOR / PUMP

Engineering Assistance

Need help selecting the right equipment? Our AI assistant can guide you through technical specifications for VFDs, Motors, and Pumps.

Coordinated Control System for Wind Turbine Pitch, Yaw, and Grid Integration

Problem Definition

Engineering Verification

Technical Scope

Compliance Standards

Implementation Strategy

Key Deliverables

Consultation Notes

Infrastructure Taxonomy

Knowledge Areas

Engineering Relation Summary

Technical Components

Engineering Constraints

Core Optimization Logic

Implementation Evidence Summary

Project Brief

Technical Knowledge Cluster

Wind Power Generation Systems & Grid Integration

Ready to Specify?

Technical Assistant

Engineering Assistance

Global Connect