Conference paper
Development of Tools for Simulation Systems in a Distribution Network and Validated by Measurements
The increasing amount of DER components into distribution networks involves the development of accurate simulation models that take into account an increasing number of factors that influence the output power from the DG systems. This paper presents two simulation models: a PV panel model using the single-diode four-parameter model based on data sheet values and a VRB system model based on the efficiency of different components and the power losses.
The models were implemented first in MATLAB/Simulink and the results have been compared with the data sheet values and with the characteristics of the units. Moreover to point out the strong dependency on ambient conditions and its influence on array operation and to validate simulation results with measured data a complex model has also been developed.
A PV inverter model and a VRB inverter model, using the same equations and parameters as in MATLAB/Simulink, has also been developed and implemented in PowerFactory to study load flow, steadystate voltage stability and dynamic behavior of a distribution power system.
Language: | English |
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Year: | 2012 |
Pages: | 199-206 |
Proceedings: | 13th International Conference on Optimisation of Electrical and Electronic Equipment |
ISBN: | 1467316504 , 1467316520 , 1467316539 , 9781467316507 , 9781467316521 and 9781467316538 |
ISSN: | 26433958 and 18420133 |
Types: | Conference paper |
DOI: | 10.1109/OPTIM.2012.6231807 |
ORCIDs: | Bindner, Henrik W. |
Biological system modeling DER components Data models Equations Integrated circuit modeling MATLAB Mathematical model PV inverter model PV panel model Simulink Temperature measurement VRB inverter model Wind speed distribution network distribution networks distribution power system invertors load flow mathematics computing power factory power system measurement power system simulation power system stability simulation systems single-diode four-parameter model steady-state voltage stability tools development