Automated Control Unit of Power Flow in Intellectual Electricity Distribution Network

Results of the development of scienti ﬁ c and technical decisions on creation automated control unit power ﬂ ow in the intellectual electricity distribution network with microprocessor control system based on modern technologies of design of power electronics devices and digital control systems are presented. Goals and objectives of the study are indicated. Relevance, novelty and practical significance of the work are shown. Properties and opportunities created in the framework of the project equipment are listed.

semiconductor switch is one of the most technically and economically effective tools for power management in active-adaptive electric networks. PSD with semiconductor switch is not evaluated and implemented so far. The widespread prototypes of PSD are phase-shift transformers with mechanical control devices under the load, have performance with hundreds of times less than the proposed solution in the project. Proposed PSD solution characterized by the original topology and control algorithms of its semiconductor converter, which provide enhanced ACUPF reliability and functionality. The proposed PSD solution, as opposed to the alternative, ensures equality voltage modules at its inputs and outputs, greatly expands the possible range of controlled phase-shift angles and improves its dynamic characteristics.
The aim of the project is ACUPF development with microprocessor control system based on of power electronics devices and digital control systems. ACUPF designed for intellectualization of electric power transmission and distribution process in active-adaptive electric networks and provide high levels of reliability and efficiency of energy transportation and control via power transmission lines.
Major tasks solved in the framework of the project: • Review of scientific literature and patent search; • Topology justification of ACUPF; • Simulation models development of power line with ACUPF location, ACUPF and control system development; • ACUPF control algorithms development; • Physical model for the study and debugging ACUPF design; • Physical model and experimental sample of ACUPF design and manufacturing; • Physical model and experimental sample of ACUPF evaluation.
The project is the next step for practical realization of active-adaptive power grid. The proposed solution allows to create a world-class technology for the development and implementation of high-speed devices for energy management in power grid with power semiconductor devices and digital control systems.
One of the features of the project is to use Russian components base of power electrical engineering, electronics, and software, which, in turn, contributes to the technological independence of the country in the field of electricity.
In the framework of the project, ACUPF experimental sample was created in conjunction with the physical model of a three-phase power line of 10 kV with a variable phase-shift at the ends of the line. They are unique and can be used for design and evaluation of different ACUPF structures.
The main project results are: • New methods of ACUPF control; • Simulation models of ACUPF and power line; • Proposed approach for simulation and evaluation of ACUPF performance in its specific location in power grid; • A physical model including experimental sample of ACUPF and power system model (Fig. 1). The model is intended for research and testing of received The results of the research: defended one PhD thesis, one dissertation presented to the defense in December 2016, received two patents [1,2], published eight scientific articles in Russia and abroad [3][4][5][6][7][8][9][10].

Conclusions
1. The effectiveness of automated control unit power flow (ACUPF) with semiconductor switch for power grid modes control had been demonstrated. 2. New algorithms, hardware, and software of ACUPF control system had been developed. 3. ACUPF simulation models had been developed and evaluated. 4. Physical models of power system and ACUPF have been manufactured. 5. Experiments obtained on physical model of power system and ACUPF confirmed the main projects proposals: methods of semiconductor switch control, models of power line, PSD, control system, algorithms, software, and hardware of control system. 6. The guidelines for ACUPF design for its specific location in power grid had been designed. The images or other third party material in this chapter are included in the chapter's Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the chapter's Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder.