Wind offers an immense, never ending source of energy that can be successfully harnessed to power all of the things that currently draw energy from non-renewable resources. The wind doesn't always blow, though.
Researchers from North China Electric Power University and North China University of Science and Technology recently developed a model to help predict wind frequency and potential contributions to more traditional energy sources. The scientists published their paper in IEEE/CAA Journal of Automatica Sinica (JAS).
"Reliable load frequency control is crucial to the operation and design of modern electric power systems," wrote Yi Zhang, a doctoral student at the North China Electric Power University and an author on the paper. "Due to the randomness and intermittence of the wind power, the controllability and availability of wind power significantly differs from conventional power generation."
Their method is based on "Model Predictive Control," wherein checkpoints across a power grid can exchange information and adjust accordingly. The researchers decentralized this model, so that a problem in one area could be solved to benefit the entire grid. The computer algorithm predicts the variables that influence the grid (demand, supply, etcetera) and applies those constraints for any problem that any part of the system might encounter.
A traditionally controlled grid could, for example, redirect otherwise unused energy from sleeping citizens to a power-hungry hospital or some other entity that continues to require energy even during typical off times. In a decentralized system, like the one modeled by Zhang and her colleagues, the system works the same way, but instead of having to clear the redirection with every checkpoint, the variables are assumed and the action is nearly immediate.
To test their algorithm, the researchers compared the volume output and dependability of a four-part system - four plants sharing responsibility for generating power in different areas - with and without the incorporation of wind power.
In the analysis of a conventional power plant, the researchers found that their model required much less computational time compared to the traditional Model Predictive Control. That's a major advantage, as the computing process is expensive in both time and energy.
When the researchers added the hard-to-predict wind turbines as a source of power in the model, it still worked as well. According to the scientists, the major flaw is that computational needs will increase to maintain system stability, which cannot be guaranteed in their algorithm.
"Our future work is focused on [pursuing] the implementation of [our algorithm] with guaranteeing stability and feasibility while reducing the computation and communication requirements," Zhang wrote.
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Fulltext of the paper is available: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=7815559
IEEE/CAA Journal of Automatica Sinica (JAS) is a joint publication of the Institute of Electrical and Electronics Engineers, Inc (IEEE) and the Chinese Association of Automation. JAS publishes papers on original theoretical and experimental research and development in all areas of automation. The coverage of JAS includes but is not limited to: Automatic control/Artificial intelligence and intelligent control/Systems theory and engineering/Pattern recognition and intelligent systems/Automation engineering and applications/Information processing and information systems/Network based automation/Robotics/Computer-aided technologies for automation systems/Sensing and measurement/Navigation, guidance, and control.
To learn more about JAS, please visit: http://ieeexplore.ieee.org/xpl/RecentIssue.jsp?punumber=6570654
Journal
IEEE/CAA Journal of Automatica Sinica