GC51H-05
Integrating Solar Power onto the Electric Grid – Bridging the Gap between Atmospheric Science, Engineering and Economics

Friday, 18 December 2015: 09:00
2022-2024 (Moscone West)
Mohamed S Ghonima1, Handa Yang2, Xiong Zhong2, Bengu Ozge2, Dipak Kumar Sahu2, Chang Ki Kim2, Oytun Babacan2, Ryan Hanna2, Ben Kurtz2, Felipe Alejandro Mejia3, Andu Nguyen2, Bryan Urquhart2, Chi Wai Chow2, Patrick Mathiesen3, Juan Bosch2 and Guang Wang2, (1)University of Calif San Diego, La Jolla, CA, United States, (2)University of California San Diego, La Jolla, CA, United States, (3)Univ of California, San Diego, San Diego, CA, United States
Abstract:
One of the main obstacles to high penetrations of solar power is the variable nature of solar power generation. To mitigate variability, grid operators have to schedule additional reliability resources, at considerable expense, to ensure that load requirements are met by generation. Thus despite the cost of solar PV decreasing, the cost of integrating solar power will increase as penetration of solar resources onto the electric grid increases. There are three principal tools currently available to mitigate variability impacts: (i) flexible generation, (ii) storage, either virtual (demand response) or physical devices and (iii) solar forecasting. Storage devices are a powerful tool capable of ensuring smooth power output from renewable resources. However, the high cost of storage is prohibitive and markets are still being designed to leverage their full potential and mitigate their limitation (e.g. empty storage). Solar forecasting provides valuable information on the daily net load profile and upcoming ramps (increasing or decreasing solar power output) thereby providing the grid advance warning to schedule ancillary generation more accurately, or curtail solar power output. In order to develop solar forecasting as a tool that can be utilized by the grid operators we identified two focus areas: (i) develop solar forecast technology and improve solar forecast accuracy and (ii) develop forecasts that can be incorporated within existing grid planning and operation infrastructure. The first issue required atmospheric science and engineering research, while the second required detailed knowledge of energy markets, and power engineering.

Motivated by this background we will emphasize area (i) in this talk and provide an overview of recent advancements in solar forecasting especially in two areas: (a) Numerical modeling tools for coastal stratocumulus to improve scheduling in the day-ahead California energy market. (b) Development of a sky imager to provide short term forecasts (0-20 min ahead) to improve optimization and control of equipment on distribution feeders with high penetration of solar. Leveraging such tools that have seen extensive use in the atmospheric sciences supports the development of accurate physics-based solar forecast models. Directions for future research are also provided.