Abstract
The energy transition poses a challenge for the electricity distribution network design as new energy technologies cause increasing and uncertain network loads. Traditional static load models cannot cope with the stochastic nature of this new technology adoption. Furthermore, traditional nonlinear power methods have difficulty evaluating very large networks with millions of cables, because they are computationally expensive. This paper proposes a method which uses copulas for modeling the uncertainty of technology adoption and load profiles, and combines it with a fast linear load flow model. The copulas are able to accurately model the stochastic behavior of solar irradiance, load measurements, and mobility data, converting them into electricity load profiles. The linear load flow model has better scalability and stability compared to traditional load flow models. The models are applied to a case study which uses a real-world dataset consisting of a realistic technology adoption scenario and a low-voltage network with millions of cables, which considers both voltage and current problems. Results show that risk profiles can be generated for all cables in the network, resulting in a valuable map for the district network operator as to where to focus their efforts.
Highlights
The energy transition poses a challenge for electricity distribution network design as new energy technologies cause increasing and uncertain network loads
Distribution network operators (DNO), which are responsible for maintaining the medium and low-voltage (LV) networks, are trying to determine the exact impact of these technologies
This is especially challenging on a low voltage level, given that the technology adoption of individual customers is hard to predict
Summary
The energy transition poses a challenge for electricity distribution network design as new energy technologies cause increasing and uncertain network loads. Consumers are electrifying their transportation and heating needs with electric vehicles (EV) and heat pumps (HP). Each of these techniques has a significant impact on the residential electricity consumption [2]. Distribution network operators (DNO), which are responsible for maintaining the medium and low-voltage (LV) networks, are trying to determine the exact impact of these technologies. This is especially challenging on a low voltage level, given that the technology adoption of individual customers is hard to predict. Because of their vast size, the impact on urban low voltage networks is hard to simulate
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