Journal of Control System and its Recent Developments

At present, multi-days the truth is pushing toward green and clean energy economical energy for instance, (wind, sun powered, biomass, hydro and flowing), these can overcome the voltage rundown and low voltage deformity ride as per standard fake code. For a specific PV, light and temperature, wind speed (for WECS) and water stream rate (for hydro), there is dependably a place where most extreme power out of these frameworks can be removed. This paper first audits supportable energy the breeze power and photovoltaic (PV) power age strategies and their greatest power-point following (MPPT) techniques are portrayed. Then, at that point, another Network tied feasible energy based power creating framework is proposed. A permanent-magnet synchronous machine is used to generate wind power, maximizing wind power capture through optimal speed control. For the PV power age support converter is embraced to outfit the most extreme sun based power by tuning the obligation cycle. Recreation approvals are giving to life partner of proposed framework.

Chen, Y. M., Liu, Y. C., Hung, S. C., & Cheng, C. S. (2007). Multi-input inverter for grid-connected hybrid PV/wind power system. IEEE transactions on power electronics, 22(3), 1070-1077.

Snyder, B., & Kaiser, M. J. (2009). A comparison of offshore wind power development in Europe and the US: Patterns and drivers of development. Applied Energy, 86(10), 1845-1856.

Krichen, L., Francois, B., & Ouali, A. (2008). A fuzzy logic supervisor for active and reactive power control of a fixed speed wind energy conversion system. Electric Power Systems Research, 78(3), 418-424.

Kamoji, M. A., Kedare, S. B., & Prabhu, S. V. (2009). Experimental investigations on single stage modified Savonius rotor. Applied Energy, 86(7-8), 1064-1073.

De Almeida, R. G., Castronuovo, E. D., & Lopes, J. P. (2006). Optimum generation control in wind parks when carrying out system operator requests. IEEE transactions on power systems, 21(2), 718-725.

Tapia, A., Tapia, G., & Ostolaza, J. X. (2004). Reactive power control of wind farms for voltage control applications. Renewable energy, 29(3), 377-392.

Thiringer, T., & Linders, J. (1993). Control by variable rotor speed of a fixed-pitch wind turbine operating in a wide speed range. IEEE Transactions on Energy Conversion, 8(3), 520-526..

Nagai, B. M., Ameku, K., & Roy, J. N. (2009). Performance of a 3 kW wind turbine generator with variable pitch control system. Applied Energy, 86(9), 1774-1782.

Simoes, M. G., Bose, B. K., & Spiegel, R. J. (1997). Fuzzy logic based intelligent control of a variable speed cage machine wind generation system. IEEE transactions on power electronics, 12(1), 87-95.

Hilloowala, R. M., & Sharaf, A. M. (1996). A rule-based fuzzy logic controller for a PWM inverter in a stand alone wind energy conversion scheme. IEEE Transactions on Industry Applications, 32(1), 57-65.