4 research outputs found
Control and grid integration of MW-range wind and solar energy conversion systems
Solar-based energy generation has increased by more than ten times over the same period. In total, worldwide electrical energy consumption increased by approximately 6340 TWh from 2003 to 2013. To meet the challenges created by intermittent energy generation sources, grid operators have increasingly demanded more stringent technical requirements for the connection and operation of grid-connected intermittent energy systems, for instance concerning fault ride through capability, voltage and frequency support, and inertia emulation. Ongoing developments include new or improved high-voltage converters, power converters with higher power density, control systems to provide ride-through capability, implementation of redundancy schemes to provide more reliable generation systems, and the use of high-voltage direct current (HVdc) links for the connection of large off-shore intermittent energy systems
Modular Multilevel Converter with Sensorless Diode-Clamped Balancing through Level-Adjusted Phase-Shifted Modulation
Cascaded H-bridge and modular multilevel converters (MMC) are on the rise
with emerging applications in renewable energy generation, energy storage, and
electric motor drives. However, their well-known advantages come at the price
of complicated balancing, high-bandwidth isolated monitoring, and numerous
sensors that can prevent MMCs from expanding into highly cost driven markets.
Therefore, an obvious trend in research is developing control and topologies
that depend less on measurements and benefit from simpler control.
Diode-clamped topologies are considered among the more applicable solutions.
The main problem with a diode-clamped topology is that it can only balance the
module voltages of a string in one direction; therefore, it cannot provide a
completely balanced operation. This paper proposes an effective balancing
technique for the diode-clamped topology. The proposed solution exploits the dc
component of the arm current by introducing a symmetrically level-adjusted
phase-shifted modulation scheme, and ensures the balancing current flow is
always in the correct direction. The main advantages of this method are
sensorless operation, no added computation and control effort, and low overall
cost. Analysis and detailed simulations provide insight into the operation of
the system as well as the new balancing technique and the experimental results
confirm the provided discussions
A Novel Diode-Clamped Modular Multilevel Converter with Simplified Capacitor Voltage-Balancing Control
© 1982-2012 IEEE. Multilevel converters have become very attractive for high-voltage-level power conversion in renewable power generation applications. The converter topology is an important issue in the studies of multilevel converter. Many multilevel topologies have been developed, but few of them are qualified with capacitor voltage self-balancing capability. This paper proposes a novel diode-clamped modular multilevel converter with simplified capacitor voltage-balancing control. In this topology, low-power rating diodes are used to clamp the capacitor voltages of the converter. Only the top submodule in each arm of the converter requires capacitor voltage control. Consequently, very few voltage sensors are needed for voltage control and the control computation burden is reduced greatly when the quantity of the submodules is high. A simple voltage-balancing control method with carrier phase-shifted modulation strategy is developed for this topology. Experiments based on a laboratory prototype were carried out and the results validated the capacitor-balancing performance of the proposed topology