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Operating Deflection Shapes (ODS) Analysis

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Nuclear power plant after sunset. Dusk landscape with big chimneys.

Mobility Testing

In mobility testing, accelerance, mobility and compliance functions are calculated. For structures with well-separated modes, estimation of natural frequencies and damping ratios is possible. Often done during troubleshooting using hammer testing.

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Operating Deflection Shapes (ODS) Analysis

A versatile application for determining the vibration patterns of machinery and structures under various operating conditions such as engine speed and ambient forces. Our ODS systems guide you through the entire measurement and analysis process.

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Operating Deflection Shapes (ODS) Analysis

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Operating Deflection

Operating Deflection Shapes (ODS) Analysis

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Mobility Testing

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Operating Deflection Shapes (ODS) Analysis

Learn more

Operating Deflection Shapes (ODS) Analysis

Learn more

Operating Deflection Shapes (ODS) Analysis

Learn more

Operating Deflection Shapes (ODS) Analysis

Learn more

Operating Deflection

Operating Deflection Shapes (ODS) Analysis

Learn more

Operating Deflection Shapes (ODS) Analysis

Learn more

Operating Deflection Shapes (ODS) Analysis

Learn more

engineer with glasses working on the computer with two screens showing the durability simulation and analysis software tools

Mobility Testing

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Active vibration-based SHM system on an operating Vestas V27 wind turbine

Detail of a wind turbine blade of a Vestas V27 wind turbine with an active vibration-based Structural Health Monitoring (SHM) system

May 26, 2020  STRUCTURAL HEALTH MONITORING, WIND TURBINE, WHITEPAPERS

Can you detect a 15 cm crack in a wind turbine blade without stopping the wind turbine? A three-year-long research project, partly financed by the Danish government, proved that this is indeed possible.

Modern wind turbine blades are designed to last for 20 to 25 years under severe weather conditions, and during this period, damage is unavoidable. Almost inevitably, a small blade defect will develop into a bigger failure, which if no countermeasures are taken, will become critical, causing serious consequences.

Repairing a small defect is significantly cheaper than repairing a bigger one or replacing an entire blade. Therefore, wind turbine operators pay close attention to monitoring their fleets’ blades. Today, this is done by periodical visual inspections conducted every one to two years. For such an inspection, the wind turbine has to be stopped, then a service technician, often trained climbers, checks every inch of the blade’s surface and documents any defects found. This is a tedious and risky job that can only be done in good weather conditions. Since such inspections are quite expensive, many in the industry realize that a better approach is needed.

Detail of a crack in a wind turbine blade of a Vestas V27 wind turbine with an active vibration-based Structural Health Monitoring (SHM) system

One solution could be an automatic, remote, structural health monitoring system that can instantaneously identify damage without stopping the wind turbine, thus avoiding expensive downtime. HBK, in cooperation with leading Danish wind turbine specialists, has developed a prototype of such a system – an active, vibration-based, structural health monitoring system that uses an actuator and accelerometers to collect vibration data, while a damage detection algorithm indicates if blade damage is present. The solution was used to monitor a real Vestas V27 wind turbine for four months, resulting in the detection of a 15 cm crack on a blade’s trailing edge.

Not just for wind turbines

It is believed that the same principle can be used for monitoring pipelines, tanks, chimneys, aircraft fuselages, and other thin-shell structures.

Read the full Whitepaper