Downscaling Solar Power Output to 4-Seconds for Use in Integration Studies (Presentation)

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High penetration renewable integration studies require solar power data with high spatial and temporal accuracy to quantify the impact of high frequency solar power ramps on the operation of the system. Our previous work concentrated on downscaling solar power from one hour to one minute by simulation. This method used clearness classifications to categorize temporal and spatial variability, and iterative methods to simulate intra-hour clearness variability. We determined that solar power ramp correlations between sites decrease with distance and the duration of the ramp, starting at around 0.6 for 30-minute ramps between sites that are less than 20 km apart. ... continued below

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24 p.

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Hummon, M.; Weekley, A.; Searight, K. & Clark, K. October 1, 2013.

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High penetration renewable integration studies require solar power data with high spatial and temporal accuracy to quantify the impact of high frequency solar power ramps on the operation of the system. Our previous work concentrated on downscaling solar power from one hour to one minute by simulation. This method used clearness classifications to categorize temporal and spatial variability, and iterative methods to simulate intra-hour clearness variability. We determined that solar power ramp correlations between sites decrease with distance and the duration of the ramp, starting at around 0.6 for 30-minute ramps between sites that are less than 20 km apart. The sub-hour irradiance algorithm we developed has a noise floor that causes the correlations to approach ~0.005. Below one minute, the majority of the correlations of solar power ramps between sites less than 20 km apart are zero, and thus a new method to simulate intra-minute variability is needed. These intra-minute solar power ramps can be simulated using several methods, three of which we evaluate: a cubic spline fit to the one-minute solar power data; projection of the power spectral density toward the higher frequency domain; and average high frequency power spectral density from measured data. Each of these methods either under- or over-estimates the variability of intra-minute solar power ramps. We show that an optimized weighted linear sum of methods, dependent on the classification of temporal variability of the segment of one-minute solar power data, yields time series and ramp distributions similar to measured high-resolution solar irradiance data.

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24 p.

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  • Presented at the 2013 International Workshop on Integration of Solar Power into Power Systems, 20 - 22 October 2013, London, United Kingdom; Related Information: NREL (National Renewable Energy Laboratory)

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  • Report No.: NREL/PR-6A20-60336
  • Grant Number: AC36-08GO28308
  • Office of Scientific & Technical Information Report Number: 1097304
  • Archival Resource Key: ark:/67531/metadc870284

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Office of Scientific & Technical Information Technical Reports

Reports, articles and other documents harvested from the Office of Scientific and Technical Information.

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  • October 1, 2013

Added to The UNT Digital Library

  • Sept. 16, 2016, 12:32 a.m.

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  • April 4, 2017, 3:06 p.m.

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Hummon, M.; Weekley, A.; Searight, K. & Clark, K. Downscaling Solar Power Output to 4-Seconds for Use in Integration Studies (Presentation), article, October 1, 2013; Golden, Colorado. (digital.library.unt.edu/ark:/67531/metadc870284/: accessed October 20, 2017), University of North Texas Libraries, Digital Library, digital.library.unt.edu; crediting UNT Libraries Government Documents Department.