PCIM SOUTH AMERICA 2014 INTERNATIONAL CONFERENCE AND EXIBITION FOR POWER ELECTRONICS,INTELLIGENT MOTION,RENEWABLE ENERGY AND ENERGY MANAGEMENT

Design and Implementation of a Fuzzy Adaptive Sliding-Mode Voltage Control System for Three-Phase UPS Inverter Khawar Naheem DIVISION OF ELECTRONIC AND ELECTRICAL ENGINEERING DONGGUK UNIVERSITY SEOUL

 ( Abstract )
Nowadays, the nonlinear nature of electric loads leads to a strong demand of a high-quality and reliable power source both by the customers and utilities. To address this issue, the uninterruptible power supplies (UPSs) are extensively employed for the critical loads such as communication systems (i.e., data centers), medical support systems, semiconductor manufacturing systems, etc. For improving the power quality using UPS system, it is important to achieve the sinusoidal output voltage waveform with very low total harmonic distortion (THD) regardless of the load types. Typically, the inverter with LC output filter in the UPS system is a suitable solution to fulfill this requirement. The main criteria to evaluate the regulation performance of the UPS inverter output voltage are fast dynamic response, small steady-state error, and low THD. Furthermore, the various load conditions (abrupt load changes, unbalanced load, and nonlinear load) including parameters uncertainties extremely degrade the performance of the UPS inverter. Thus, an appropriate control strategy is desired to sufficiently meet the performance criteria of the UPS systems under any type of electrical loads and uncertainties.
LINK
http://www.mediafire.com/view/wg9c9ogcdtpdz46/FUZZY_INVERTER.pdf

Robust Control of a Grid Connected 3 Phase 2 Level Photo Voltaic Inverter and Development of an Inverter Operating SW Using Test Driven Development Approach Ahn, Kyung Pil

Robust Control of a Grid Connected 3 Phase 2 Level Photo
Voltaic Inverter and Development of an Inverter Operating
SW Using Test Driven Development Approach

Ahn, Kyung Pil
(Supervisor Lee, Young Il)
Dept. of Control and Instrumentation Eng.
Graduate School of Industry and Engineering
Seoul National University of Science and Technology

This study discusses robust control of grid connected three-phase two-level photo voltaic inverter where LC filter is used and its reliable implementation method for the system.
The suggested control method uses the cascaded strategy in which inner-loop controller for the ac current control and outer-loop controller for the dc-link voltage are used. In the inner-loop ac current controller, it is important to maximize convergence rate and keep the stability at the same time. So the optimal controller design method based on the LMI (Linear Matrix Inequality) is used with the integration action. Though this method, it can achieve high performance in term of tracking the reference as well as eliminate the offset-error. More over it guarantees system stability even when there are parameter mismatch by considering the parameter uncertainty set. In the outer-loop dc-link controller the PI controller is used with the dc-ac current linearization. So it can have concurrent performance though overall inverter operating condition.
On the other hand, the high power product such as three-phase photo voltaic inverter is in the mission-critical area due to its riskness of an accident. More over the photo voltaic inverter system become more an more complex with increasing requirement of functions in the grid connection rule for each country. With these trend it is difficult to keep the system integrity. This study shows the cases how the inverter operating SW can be builded using Test Driven Development (TDD) approach.
LINK
http://www.mediafire.com/view/bd7kt3oq2d6n34g/CONTROL_INVERTER_PHOTOVOLTAIC.pdf

AUTOMAÇÃO DO CICLO DE CARGA PARA BATERIAS SERGIO FEGER DA EATON (ALEMANHA)

PCIM SOUTH AMERICA SÃO PAULO 14-15 OCTOBER 2014 International Conference and Exhibition for Power Electronics, Intelligent Motion, Renewable Energy and Energy Management

MAIOR INFORMAÇÃO LINK
http://www.mesago.de/en/SAPCIM/The_conference/sapcim/index.htm