TY - JOUR T1 - Parallel Binding Process of Alternators with Arduino AU - Bahar, Elif Merve AU - Basaran, Kivanc AU - Topbas, İsa Serdar PY - 2018 DA - December JF - The Eurasia Proceedings of Science Technology Engineering and Mathematics JO - EPSTEM PB - ISRES Publishing WT - DergiPark SN - 2602-3199 SP - 56 EP - 60 IS - 4 LA - en AB - Inthis study, the conditions for parallel binding of the alternators used in thepower plants to grid were examined and the fulfillment of these conditions wascarried out with Arduino. The power plant drive system has been modeled asAsynchronous motor module with 3 phase power of 5 kW. In the alternator part,asynchronous machine was used at 13 kVA power. Voltage, frequency, phasesequence and phase difference magnitudes of alternator and grid are used asinput data of Arduino. Voltage, frequency, phase sequence and phase differencemagnitudes of alternator and network are used as input data of Arduino. Fourdifferent modules have been designed to be integrated into Arduino for everymagnitude. These modules evaluate the information from the grid and thealternator. Arduino brings the alternator and the grid in parallel via therelay at the output when appropriate conditions met. Modules designed for thetraining set, software embedded in Arduino allows practical parallel connectionwithout using different measuring instruments.   KW - Power plants KW - Alternator KW - Grid KW - Training set CR - Colak, I. (2003). Synchronous Machines. Seçkin Publishing, Ankara. Chapman, S.J. (1987). Electric Machinery Fundamentals. McGraw-Hill Book Company. Çolak, I., Yılmaz, E.N. (1999). Simulation of the parallel connection of electrical power stations. IJEEE International Journal of Electrical Engineering Education, 36 (4), 332-341. IEEE Std. (2005). IEEE Power Engineering Society. IEEE standard for synchrophasors for power systems, C37. 118. Mahmoud, M. S., Ismail, A. (2003). Control of electric power systems. Systems Analysis Modeling Simulation, 43(12), 1639-1673. Martin, K.E. (1993). Precise timing in electric power systems. IEEE International Frequency Control Symposium, 15-22. Metwally, H.M.B. (2000). Operation of new variable speed constant voltage and frequency generator connected to the grid. Energy Conversion and Management, 41(7), 701-712. Phadke AG and subcommittee of the IEEE Power System Relaying Committee, Synchronized sampling and phasor measurements for relaying and control, IEEE Transactions on Power Delivery, 9 (1), 442- 452, 1994. Radovanovic, A. (2001). Using the internet in networking of synchronized phasor measurement units. Elsevier, Electrical Power and Energy Systems 23, 245-250. UR - https://dergipark.org.tr/en/pub/epstem/issue//494344 L1 - https://dergipark.org.tr/en/download/article-file/592020 ER -