Abstract
The problematic of energy management, particularly in terms of resources control and efficiency, has become in the space of a few years an eminently strategic subject. Its implementation is both complex and exciting as the prospects are promising, especially in relation with smart grids technologies. The deregulation of the electricity market, the high cost of storage, and the new laws on energy transition incite some significant users (collectivities, cities, regions, etc.) to form themselves into local producers in order to gain autonomy and reduce their energy bills. Thus, they may have their own sources (classic and/or renewable energy sources) to satisfy their needs and sell their excess production instead of storing it. In this idea, the territorial interconnection principle offers several advantages (energy efficiency, environmental protection, better economic balance). The main challenge of such systems is to ensure good energy management. Therefore, power distribution strategy must be implemented by matching the supply and the demand. Such systems have to be financially viable and environmentally sustainable. This allows among others to reduce the electricity bill and limit the systematic use of the national power network, typically using non-renewable sources, and thereby support sustainable development. This paper presents an original model for aid-decision in terms of grid configurations and control powers exchanged between interconnected territories. The model is based on Petri nets. Therefore, an iterative algorithm for power flow management is based on instantaneous gap between the production capability (photovoltaic, wind) and the demand of each user. So, in order to validate our model, we selected three French regions: the PACA region, the Champagne-Ardenne region and the Lorraine region. Due to their policy, their geographical and climatic features, we opted for two renewable sources: “wind” and “photovoltaic”. The numerical simulations are performed using the instantaneous productions of each region and their energy demand for a typical summer day. A detailed economic analysis is performed for two scenarios (with or without interconnections). The results show that the use of renewable energy in an interconnection context (i.e. pooling), offers serious economic and technical advantages.
Highlights
“The world is at a critical crossroad”, the temperature of the land and ocean surfaces has increased globally by almost 1 ̊C and in parts of Africa, Asia, north and South America, the increase is up to 2.5 ̊C
The results show that the use of renewable energy in an interconnection context, offers serious economic and technical advantages
This paper presents an original model for optimization and control of interconnections between users using a special modelling tool, Petri nets and an iterative algorithm for flow management based on instantaneous gap between the power production capability and demand of each user
Summary
“The world is at a critical crossroad”, the temperature of the land and ocean surfaces has increased globally by almost 1 ̊C (from the early 20th century) and in parts of Africa, Asia, north and South America, the increase is up to 2.5 ̊C. Ouammi et al [34] present a centralized control model based on a linear quadratic Gaussian problem, to support optimal decisions in the control of the power exchanged for a smart network of microgrids It considered grid interconnections for additional power exchanges and incorporated storage devices, various distributed energy resources, and loads. Some hypotheses that have been introduced to simplify the model, it demonstrated that the cooperation among grids has significant advantages and benefits to each single grid operation in terms of integrating a common strategy to face shortage or excess of power production due to the intermittent behavior of RESs. Recently, Yu Wang et al [35] investigate a hierarchical power scheduling approach to optimally manage power trading, storage and distribution in a smart power grid with a macrogrid and cooperative microgrids.
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