Abstract
A boundary layer scaling (BLS) method for predicting long-term average near-surface wind speeds and power densities was developed in this work. The method was based on the scaling of reference climatological data either from long-term average wind maps or from hourly wind speeds obtained from high-resolution Numerical Weather Prediction (NWP) models, with case study applications from Great Britain. It incorporated a more detailed parameterisation of surface aerodynamics than previous studies and the predicted wind speeds and power densities were validated against observational wind speeds from 124 sites across Great Britain. The BLS model could offer long-term average wind speed predictions using wind map data derived from long-term observational data, with a mean percentage error of 1.5% which provided an improvement on the commonly used NOABL (Numerical Objective Analysis of Boundary Layer) wind map. The boundary layer scaling of NWP data was not, however, able to improve upon the use of raw NWP data for near surface wind speed predictions. However, the use of NWP data scaled by the BLS model could offer improved power density predictions compared to the use of the reference data sets. Using a vertical scaling of the shape factor of a Weibull distribution fitted to the BLS NWP data, power density predictions with a 1% mean percentage error were achieved. This provided a significant improvement on the use of a fixed shape factor which must be utilised when only long-term average wind speeds are available from reference wind maps. The work therefore highlights the advantages that use of a BLS model for wind speed and NWP data for power density predictions can offer for small to medium scale wind energy resource assessments, potentially facilitating more robust annual energy production and financial assessments of prospective small and medium scale wind turbine installations.
Highlights
National governments across the world are attempting to decarbonise their electricity supplies as part of their efforts to meet CO2 emission reduction targets and mitigate the risks of climate change [1]
The aim of the analysis presented in this paper was to determine whether a boundary layer scaling (BLS) model can provide an accurate prediction of long-term average near-surface wind speeds using either wind map or Numerical Weather Prediction (NWP) data
The work presented in this paper was developed to analyse the accuracy of wind speed and power density predictions available from both the Microgeneration Certification Scheme (MCS) methodology and the BLS model using the reference wind climatologies of Numerical Objective Analysis of Boundary Layer (NOABL), National Climatic Information Centre (NCIC) and NWP data
Summary
National governments across the world are attempting to decarbonise their electricity supplies as part of their efforts to meet CO2 emission reduction targets and mitigate the risks of climate change [1]. As part of this action, national governments have committed to ambitious renewable energy generation targets. As part of the EU’s renewable energy generation commitment, the UK government committed to a legally binding target to provide 15% of its total energy from renewable sources by 2020 [2]. The UK has one of the highest wind resource potentials in Europe [5] and wind power, including small and medium wind energy, will be a key component in the UK’s energy system transition
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