Introduction
The SRIZFLY wind power inspection drone simulation restores the full picture of the wind turbine through high-precision 3D modeling, and can conduct detailed interactive drills on core components such as blades, nacelles, hubs, and five types of equipment such as towers and bases. The system has built-in training and assessment dual modes, supports step guidance, flight abnormality reset and task evaluation, and integrates a dynamic defect library to flexibly simulate five typical fault scenarios such as gel coat shedding and lightning damage. With the help of laser ranging, EV exposure adjustment and environmental wind field interference simulation technology, it can accurately detect shooting parameter specifications, reproduce the dynamic impact of complex airflow on drones, and comprehensively improve the operator’s standardized inspection and emergency control capabilities in real wind power scenarios.
Equipment Introduction
Paddle
Cabin
Wheel hub
Product features
♦Features
The system has auxiliary functions such as obstacle avoidance, laser ranging, EV exposure adjustment, etc., highly restores the operation interface of DJl Pilot2, and restores the real control experience of inspection.
♦Dynamic Defect Library
The system includes a built-in dynamic defect library, which can flexibly set common defect types. It supports gel coat shedding, fiber layer damage, structural damage, lightning strike, and pipe shedding. It supports one-click setting of multiple typical visible light defect settings for wind turbine inspection.
♦Training Summary
After training, it supports viewing inspection photos, marking defects, and adding, deleting, modifying, and checking defects. It supports analyzing and recording core process parameters such as inspection duration, process accuracy, task completion, and photo accuracy, and generates comparison evaluation reports and results.
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Introduction
The SRIZFLY wind power inspection drone simulation restores the full picture of the wind turbine through high-precision 3D modeling, and can conduct detailed interactive drills on core components such as blades, nacelles, hubs, and five types of equipment such as towers and bases. The system has built-in training and assessment dual modes, supports step guidance, flight abnormality reset and task evaluation, and integrates a dynamic defect library to flexibly simulate five typical fault scenarios such as gel coat shedding and lightning damage. With the help of laser ranging, EV exposure adjustment and environmental wind field interference simulation technology, it can accurately detect shooting parameter specifications, reproduce the dynamic impact of complex airflow on drones, and comprehensively improve the operator’s standardized inspection and emergency control capabilities in real wind power scenarios.
Application Features
Full process training
It supports the simulation of the complete inspection process of the entire wind turbine tower; analyzes and records the core process parameters such as inspection duration, process accuracy, task completion, and photo accuracy, and generates evaluation reports and results; it also supports the marking, addition, deletion, and modification of defects.
Specialized training
It supports special inspection teaching of typical parts such as wind turbine blades, nacelles, and hubs. It has guided teaching steps and highlighted prompts, which can provide participants with clear and systematic inspection training.
What are the benefits of using SRIZFLY for New energy inspection?
Save training costs: In actual UAV new energy wind power inspection, it is easy to cause equipment damage due to improper operation. Using the SRIZFLY UAV simulator can avoid these costs.
Improve work efficiency: The maintenance of new energy wind turbines has always been a major regular expense. The use of wind power inspection simulators allows trainees to quickly and accurately master standard work processes and improve work efficiency, thereby saving time and money for the company!
Higher safety: Safely learn how to deal with various failures that occur during flight in the simulator, such as GPS signal loss, low battery, etc.
Quickly adapt to different scenarios: By simulating various weather conditions (such as strong winds and heavy rains) and terrains (such as mountains and forests), trainees can quickly master skills under different conditions.
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Functions and features
Interactive Simulation Environment
The system employs a AAA level 3D engine, UE4, to create realistic training scenarios. It simulates the drone model and various scenes with vivid details, accurately replicating real environments based on Lidar data. To simulate environmental factors such as wind, ground effect reactions, and dynamic physical impacts, the system creates realistic application scenes that reproduce various flight conditions. It prepares users for the actual operation of diverse situations.
Immersive Flight Experience
The system simulates the flight characteristics of a real UAV and controls it with a real UAV remote control, giving the user the same sensation as a real UAV operation. The system currently supports a wide range of commonly used UAV models. Additionally, it is compatible with mainstream VR headsets, providing an immersive training experience.
Dynamic Defect Library
Built-in dynamic defect library, which can flexibly set common defect types, supports gel coat shedding, fiber layer damage, structural damage, lightning strike, oil pipe body shedding, and no less than 5 typical visible light defect settings for wind turbine inspection.
