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- Category: Articles
How Smart Curtailment Systems Can Improve Wind Farm RevenuesBat fatalities resulting from collisions with wind turbines have been extensively documented at operating wind farms throughout the world, but they are of particular concern in the USA, where the ranges of several endangered bat species overlap with a large number of operating wind farms. One leading mitigation measure involves curtailing the turbines during relatively low wind speed periods when bats are likely to be present. This has been shown to reduce bat fatalities significantly. While curtailment helps reduce bat mortality, it comes at the cost of lost revenue because the turbines are not producing power even though the wind is blowing. A better way to approach mitigation is to use a smart curtailment system that detects bat activity and modifies the operation of the turbines accordingly. This article explains how this system works and its operational and mitigation benefits.
By Dr Chris Ziesler, Roger Rodriguez, Taurin Spalding, Devin Saywers, Natural Power Consultants, USA
- Category: Articles
Capturing More Wind with Breakthroughs in OptimisationIn the wind industry, our collective mission is crystal clear. It is to maximise the energy that we capture at the lowest cost and lowest environmental impact. The amount of progress that has been made over the last two decades towards that goal is nothing short of extraordinary.
By Marouane Salhi, CEO, Qubit Engineering, USA
- Category: Articles
Blade Surface Aerodynamic Pressure MeasurementsBoth the aerodynamic/acoustic design of the rotor blades and their performance during operation can be improved by measuring the aerodynamic surface pressure distribution. For blade design, an understanding of the three-dimensional (3D) unsteady aerodynamics can allow the aerodynamic profiles to be optimally chosen and distributed along the blade length. An understanding of the acoustic emissions can allow the blades to be optimally designed in terms of noise production and to identify and avoid undesirable effects such as flow separation. For wind farm operation, an understanding of the 3D unsteady aerodynamics can allow controller settings to be optimised depending on the site and layout conditions, as well as leading edge erosion and even structural damage to be detected and classified. This can support decisions for maximising production and optimising the maintenance strategy. The Aerosense MEMS-based surface pressure and acoustic smart measurement system seamlessly enables the acquisition and exploitation of such measurements in an industrial setting for the first time (Figure 1).
By Sarah Barber, Head of the Wind Energy Innovation Division, Eastern Switzerland University of Applied Sciences, Switzerland
- Category: Articles
Capacitive Transfer System Cable for Efficient Wind Energy IntegrationEnertechnos has developed an innovative cable design called the Capacitive Transfer System (CTS), which delivers a substantial change in power system design while providing significant benefits to wind developers and owners, including power loss reduction, improved reactive power management, and the potential for reduced operating voltage or reduced size and weight of cables through increased current density. Case studies demonstrate that CTS cable can deliver more power over the same cross-section, thus allowing reductions in copper use and the associated carbon footprint.
By Dr Alexander Yanushkevich, Owen Johnson and Sebastian Amedick, Enertechnos, UK
- Category: Articles
Grid-Enhancing Technologies Unlock Dynamic Transmission Capacity for RenewablesEven areas with persistent transmission congestion and associated renewable energy curtailment have gigawatts of untapped transfer capacity. With grid-enhancing technologies – hardware and software tools that turn the grid into a flexible and dispatchable asset – grid operators can unlock more value from existing infrastructure.
By Julia Selker, Executive Director, WATT Coalition, USA
- Category: Articles
Assessing the Impact on Wind Turbine Energy ProductionWind turbine upgrades can potentially yield performance enhancements and an increase in annual energy production (AEP). However, the precise influence of such upgrades can be difficult to quantify, mainly due to uncertainty in the wind speed measurement and complex operational conditions. This article explores an innovative approach to the use of 10-minute SCADA data for quickly and cost-effectively evaluating the effectiveness of upgrades and the impact on wind turbine performance. Operational data is used selectively in order to match conditions before and after the upgrade, and remaining uncertainties are quantified in order to deliver results with a defined level of precision.
By Julien Tissot and Christopher Gray, i4See Tech, Austria
- Category: Articles
Combining Infrared Thermography and AIRain erosion can significantly impact wind turbine performance and maintenance costs, particularly affecting the leading edge of turbine blades. This erosion can cause pitting, surface roughness and even cracks, which compromise blade integrity while reducing aerodynamic efficiency and energy output. Energy output loss due to rain erosion is known to be approximately 0.5 to 2% and in some severe cases even more. The consequences of this damage could increase maintenance and operation costs. Traditional inspection and maintenance methods cause turbine downtime, leading to lost revenue. Modern non-destructive testing technologies such as infrared thermography combined with artificial intelligence for data analysis can provide an efficient solution to detect rain erosion on operational wind turbine blades, minimising the impact on maintenance and operation costs.
By Michael Stamm, Somsubhro Chaudhuri and Daniel Hein, BAM, Germany
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