Abstract
Increasing photovoltaic (PV) generation in the world’s power grid necessitates accurate solar irradiance forecasts to ensure grid stability and reliability. The University of Texas at San Antonio (UTSA) SkyImager was designed as a low cost, edge computing, all-sky imager that provides intra-hour irradiance forecasts. The SkyImager utilizes a single board computer and high-resolution camera with a fisheye lens housed in an all-weather enclosure. General Purpose IO pins allow external sensors to be connected, a unique aspect is the use of only open source software. Code for the SkyImager is written in Python and calls libraries such as OpenCV, Scikit-Learn, SQLite, and Mosquito. The SkyImager was first deployed in 2015 at the National Renewable Energy Laboratory (NREL) as part of the DOE INTEGRATE project. This effort aggregated renewable resources and loads into microgrids which were then controlled by an Energy Management System using the OpenFMB Reference Architecture. In 2016 a second SkyImager was installed at the CPS Energy microgrid at Joint Base San Antonio. As part of a collaborative effort between CPS Energy, UT San Antonio, ENDESA, and Universidad de La Laguna, two SkyImagers have also been deployed in the Canary Islands that utilize stereoscopic images to determine cloud heights. Deployments at three geographically diverse locations not only provided large amounts of image data, but also operational experience under very different climatic conditions. This resulted in improvements/additions to the original design: weatherproofing techniques, environmental sensors, maintenance schedules, optimal deployment locations, OpenFMB protocols, and offloading data to the cloud. Originally, optical flow followed by ray-tracing was used to predict cumulus cloud shadows. The latter problem is ill-posed and was replaced by a machine learning strategy with impressive results. R2 values for the multi-layer perceptron of 0.95 for 5 moderately cloudy days and 1.00 for 5 clear sky days validate using images to determine irradiance. The SkyImager in a distributed environment with cloud-computing will be an integral part of the command and control for today’s SmartGrid and Internet of Things.
Highlights
The Department of Energy (DOE) estimates that PV power will grow to 14% of the electricity supply by 2030 as the price of solar electricity reaches a point at which it is cost-competitive with cogen ($0.06/kwh by 2020)
We focus on cumulus clouds because they have the greatest effect on ramp events
The analysis strongly suggests that resolve the frequency and voltage swings that occur during a sudden ramp event, Phasor Measurement Units (PMU)
Summary
It is imperative that power grid reliability and stability be maintained under this high penetration of low carbon energy [1]. Reliability Corporation (NERC) and California Energy Commission (CEC) [2] have formulated several requirements needed in a “grid-friendly” PV power plant. CEC has developed a set of several smart inverter functionalities such as dynamic volt/var operation and ramp rate control. Existing PV plants do not have these functionalities even though the inverters are capable, due to the lack of communications standards and dynamic control. For PV power plants to participate in energy markets and ancillary services markets, they need to be considered “dispatchable” power plants
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