An energy management algorithm and system have been implemented to address the stability issues of urban power grids.
National Research Council of Science & Technology
Researchers group photo (from left to right Dr. Jong-Kyu Kim, Dr. Min-Hwi Kim, Dr. Gwangwoo Han, student researcher Dong Eun Jung, Dr. Young-Sub An, and Dr. Hong-Jin Joo)
Credit: KOREA INSTITUTE OF ENERGY RESEARCH
A joint research team from the Renewable Energy System Laboratory and the Energy ICT Research Department at the Korea Institute of Energy Research (KIER) has developed key technologies to realize "Urban Electrification" using artificial intelligence (AI).
Urban electrification aims to reduce the use of fossil fuels and introduce renewable energy sources, such as building-integrated solar technology, to transform urban energy systems. While this concept is relatively unfamiliar in the Republic of Korea, it is being promoted as a key strategy in the U.S. and Europe for achieving carbon neutrality and creating sustainable urban environments.
In traditional urban models, energy supply can be easily adjusted using fossil fuels to meet electricity demand. However, in electrified cities, the high dependence on renewable energy leads to greater variability in energy supply due to weather changes. This causes mismatches in electricity demand across buildings and makes the stable operation of the power grid more challenging.
In particular, Low-Probability High-Impact Events (LPHI), such as sudden cold snaps or extreme heat waves, can cause a sharp increase in energy demand while limiting energy production. These events pose a significant threat to the stability of the urban power grid, potentially leading to large-scale blackouts.
*Low-Probability High-Impact Event (LPHI) refers to incidents that have a low likelihood of occurring but can have significant consequences when they do. These events are difficult to predict and can cause substantial economic and social damage when they occur.
The research team developed an energy management algorithm based on AI analysis to address power grid stability issues and implemented it into a system. The demonstration of the developed system showed an 18% reduction in electricity costs compared to conventional methods.
The research team first used AI to analyze energy consumption patterns by building type and renewable energy production patterns. They also unraveled how complex variables, such as weather, human behavior patterns, and the scale and operational status of renewable energy facilities, affect the power grid. Notably, they discovered that Low-Probability High-Impact Events, which occur on average only 1.7 days per year (around 0.5% of the time), have a decisive impact on the overall stability of the power grid and its operational costs.
The analyzed content is developed into an algorithm and a system. The developed algorithm optimizes energy sharing between buildings and effectively manages peak demand and peak energy production. In addition to maintaining daily energy balance, the system is designed to respond to Low-Probability High-Impact Events, ensuring the stability of the power grid even in extreme situations.
When the developed system was applied to a community-scale real-world environment replicating urban electrification, it achieved an energy self-sufficiency rate* of 38% and a self-consumption rate** of 58%. This is a significant improvement compared to the 20% self-sufficiency and 30% self-consumption rate of buildings without the system. This application also resulted in an 18% reduction in electricity costs and greatly improved the stability of the power grid.
*Energy Self-Sufficiency Rate: This indicates the extent to which a building can meet its electricity demand through its own power generation. A higher value means lower dependence on external power grids, thereby reducing the burden on the grid.
**Energy Self-Consumption Rate: This refers to the proportion of electricity produced by a building that is used directly on-site rather than exported to the power grid. A higher rate contributes to the stable operation of the power grid.
Particularly, the annual energy consumption applied in the demonstration was 107 megawatt-hours (MWh), which is seven times larger than simulation-based studies conducted by leading international institutions. This significantly enhances the potential for applying the system in real urban environments.
Dr. Gwangwoo Han, the lead author of the paper and a researcher at the Energy ICT Research Department, stated, "The results of this study demonstrate that AI can enhance the efficiency of urban electrification and address power grid stability issues, while also highlighting the importance of managing Low-Probability High-Impact Events." He further predicted that "by applying this system to various urban environments in the future, we can improve energy efficiency and enhance grid stability, ultimately making a significant contribution to achieving carbon neutrality."
This research was conducted as part of the Korea Institute of Energy Research’s (KIER) R&D projects. The findings have been published online in the internationally renowned journal Sustainable Cities and Society (Impact Factor 10.7, top 2.7% in JCR rankings) in the field of building studies.
The operational data used in the demonstration study.
Credit
KOREA INSTITUTE OF ENERGY RESEARCH
Journal
Sustainable Cities and Society
DOI
10.1016/j.scs.2024.105648
Article Title
Analysis of grid flexibility in 100% electrified urban energy community: A year-long empirical study
Article Publication Date
15-Oct-2024
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