Reactive power management by distribution system operators concept and experience

“…in conditions of the balance of reactive power in the system (2). The Lagrange function for (7) after substituting the values of economic resistances according to (6) will have the form:…”

“…In [6] it is noted that the DES power can cause unacceptable increases in voltage levels in distribution grids, in particular because the grid equipment required to connect the DES generates additional reactive power. However, using the reactive power management of the DES, the operators of distribution grids can solve these problems.…”

“…The modern development of information technologies and computing facilities forms prerequisites for the application of other approaches to solving problems of optimizing the flow of reactive energy, oriented, in particular, to the automation of the EG functioning. Proceeding from this, recently elements of artificial intelligence [12][13][14][15], in particular artificial neural grids [13], expert systems [6], genetic algorithms [14] and evolutionary programming [15] are actively used. However, excessive consumption of time in the case of using evolutionary and genetic algorithms for finding optimal solutions limits their use in energy systems, especially for real-time problems [12].…”

Optimization of the placement of reactive power sources in the electric grid based on modeling of its ideal modes

“…in conditions of the balance of reactive power in the system (2). The Lagrange function for (7) after substituting the values of economic resistances according to (6) will have the form:…”

“…In [6] it is noted that the DES power can cause unacceptable increases in voltage levels in distribution grids, in particular because the grid equipment required to connect the DES generates additional reactive power. However, using the reactive power management of the DES, the operators of distribution grids can solve these problems.…”

“…The modern development of information technologies and computing facilities forms prerequisites for the application of other approaches to solving problems of optimizing the flow of reactive energy, oriented, in particular, to the automation of the EG functioning. Proceeding from this, recently elements of artificial intelligence [12][13][14][15], in particular artificial neural grids [13], expert systems [6], genetic algorithms [14] and evolutionary programming [15] are actively used. However, excessive consumption of time in the case of using evolutionary and genetic algorithms for finding optimal solutions limits their use in energy systems, especially for real-time problems [12].…”

Optimization of the placement of reactive power sources in the electric grid based on modeling of its ideal modes

“…Otherwise, the fixed Q limitation at the T–D interface can provide the required planning security for the grid operators. Whereat, the studies [15, 17, 18] mainly focus on grid operation challenges, only a few grid planning studies on Q management at T–D interface are known by the authors. The availability of DG Q support is analysed in [19] with on optimal power flow approach and in [16, 20] by an analytical assessment of DG measurement and simulation data.…”

Reactive power management at the transmission–distribution interface with the support of distributed generators – a grid planning approach

Market clearing in microgrid-integrated active distribution networks