LVDC power distribution system: computational modelling
Lana, Andrey (2014-08-15)
Väitöskirja
15.08.2014
Lappeenranta University of Technology
Acta Universitatis Lappeenrantaensis
Julkaisun pysyvä osoite on
https://urn.fi/URN:ISBN:978-952-265-619-3
https://urn.fi/URN:ISBN:978-952-265-619-3
Tiivistelmä
In the doctoral dissertation, low-voltage direct current (LVDC) distribution system
stability, supply security and power quality are evaluated by computational modelling
and measurements on an LVDC research platform. Computational models for the
LVDC network analysis are developed. Time-domain simulation models are
implemented in the time-domain simulation environment PSCAD/EMTDC. The
PSCAD/EMTDC models of the LVDC network are applied to the transient behaviour
and power quality studies. The LVDC network power loss model is developed in a
MATLAB environment and is capable of fast estimation of the network and component
power losses. The model integrates analytical equations that describe the power loss
mechanism of the network components with power flow calculations.
For an LVDC network research platform, a monitoring and control software solution is
developed. The solution is used to deliver measurement data for verification of the
developed models and analysis of the modelling results.
In the work, the power loss mechanism of the LVDC network components and its main
dependencies are described. Energy loss distribution of the LVDC network components
is presented. Power quality measurements and current spectra are provided and
harmonic pollution on the DC network is analysed. The transient behaviour of the
network is verified through time-domain simulations. DC capacitor guidelines for an
LVDC power distribution network are introduced.
The power loss analysis results show that one of the main optimisation targets for an
LVDC power distribution network should be reduction of the no-load losses and
efficiency improvement of converters at partial loads.
Low-frequency spectra of the network voltages and currents are shown, and harmonic
propagation is analysed. Power quality in the LVDC network point of common coupling
(PCC) is discussed. Power quality standard requirements are shown to be met by the
LVDC network.
The network behaviour during transients is analysed by time-domain simulations. The
network is shown to be transient stable during large-scale disturbances. Measurement
results on the LVDC research platform proving this are presented in the work.
stability, supply security and power quality are evaluated by computational modelling
and measurements on an LVDC research platform. Computational models for the
LVDC network analysis are developed. Time-domain simulation models are
implemented in the time-domain simulation environment PSCAD/EMTDC. The
PSCAD/EMTDC models of the LVDC network are applied to the transient behaviour
and power quality studies. The LVDC network power loss model is developed in a
MATLAB environment and is capable of fast estimation of the network and component
power losses. The model integrates analytical equations that describe the power loss
mechanism of the network components with power flow calculations.
For an LVDC network research platform, a monitoring and control software solution is
developed. The solution is used to deliver measurement data for verification of the
developed models and analysis of the modelling results.
In the work, the power loss mechanism of the LVDC network components and its main
dependencies are described. Energy loss distribution of the LVDC network components
is presented. Power quality measurements and current spectra are provided and
harmonic pollution on the DC network is analysed. The transient behaviour of the
network is verified through time-domain simulations. DC capacitor guidelines for an
LVDC power distribution network are introduced.
The power loss analysis results show that one of the main optimisation targets for an
LVDC power distribution network should be reduction of the no-load losses and
efficiency improvement of converters at partial loads.
Low-frequency spectra of the network voltages and currents are shown, and harmonic
propagation is analysed. Power quality in the LVDC network point of common coupling
(PCC) is discussed. Power quality standard requirements are shown to be met by the
LVDC network.
The network behaviour during transients is analysed by time-domain simulations. The
network is shown to be transient stable during large-scale disturbances. Measurement
results on the LVDC research platform proving this are presented in the work.
Kokoelmat
- Väitöskirjat [1102]