@ARTICLE{ iet:/content/journals/10.1049/iet-gtd.2017.0356, author = {Mikhail Andreev}, author = {Yury Borovikov}, author = {Alexander Gusev}, author = {Almaz Sulaymanov}, author = {Nikolay Ruban}, author = {Alexey Suvorov}, author = {Ruslan Ufa}, author = {Július Bemš}, author = {Tomáš Králík}, keywords = {electric power system stability;automatic emergency control;energy security;fast turbine valving control;power units;hybrid real-time power system simulator;EPS reliability;FTVC;electric power industry;Tyumen power system;HRTSim simulator;Russia;Surgut GRES-2 thermal power station;}, ISSN = {1751-8687}, language = {English}, abstract = {The stability of electric power system (EPS) insures energy security of consumers. Therefore, saving the stability of EPS is the main task for professionals around the world. For its solution, a variety of activities is used. This publication deals with the description of the authors' experience for solving the task in the Tyumen power system. The hybrid real-time power system simulator (HRTSim) developed in Tomsk Polytechnic University was used as a platform for research carrying out. The study presents the research result fragments of the momentary and sustained fast turbine valving control (FTVC) which is one of the most effective ways of an automatic emergency control of power units in the thermal power station. Using the simulator HRTSim, one of the greatest challenges of electric power industry in Russia has been solved, i.e. FTVC adequate setting of the power units in the thermal power station Surgut GRES-2 in the Tyumen power system. An FTVC operation largely determines the reliability and stability of the EPS. Therefore, an incorrect setting may result in substantial disturbance or disruption of the stability that already occurred in the past. The adequacy of turbine and FTVC simulations is verified by comparing it with the real data.}, title = {Application of hybrid real-time power system simulator for research and setting a momentary and sustained fast turbine valving control}, journal = {IET Generation, Transmission & Distribution}, issue = {1}, volume = {12}, year = {2018}, month = {January}, pages = {133-141(8)}, publisher ={Institution of Engineering and Technology}, copyright = {© The Institution of Engineering and Technology}, url = {https://digital-library.theiet.org/;jsessionid=31ncpiihw1wlb.x-iet-live-01content/journals/10.1049/iet-gtd.2017.0356} }