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Vol.5 , No. 4, Publication Date: Nov. 20, 2018, Page: 84-95
 control, four battery storage systems connected to each capacitor of the <i>DC</i> link and a five level diode clamped inverter connected to the grid by three phase transformer. One of the problems associated with the use of multilevel inverters is the balancing of capacitors, battery banks are used to solve this problem in addition to smooth the power injected to the grid.&picture=http://www.aascit.org/aascit/decorators/img/journal/915.jpg)
| [1] | Ali Berboucha, Laboratory of Renewable Energy Mastery, University of Bejaia, Bejaia. Algeria. |
| [2] | Kamel Djermouni, Laboratory of Renewable Energy Mastery, University of Bejaia, Bejaia. Algeria. |
| [3] | Kaci Ghedamsi, Laboratory of Renewable Energy Mastery, University of Bejaia, Bejaia. Algeria. |
This paper aimed to evaluate the use of wind turbine storage systems to provide electricity in the distribution grid through a five-level inverter. New manner of connecting renewable energy source to a multilevel inverter is presented; the conventional structure consists on the use of a DC bus as an intermediary between AC/DC converters and inverter. The proposed system is composed by four wind turbine generators with MPPT (optimal torque control) control, four battery storage systems connected to each capacitor of the DC link and a five level diode clamped inverter connected to the grid by three phase transformer. One of the problems associated with the use of multilevel inverters is the balancing of capacitors, battery banks are used to solve this problem in addition to smooth the power injected to the grid.
Keywords
Permanent Magnet Synchronous Generator (PMSG), Battery Storage, Five Level Diode Clamped Inverter, Space Vector Modulation, Supervision and Management
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