| dc.description.abstract | The design process of complex power electronics converters, such as the multilevel converter, can be simplified with the concept of Power Electronic Building Blocks (PEBBs). PEBB is a fully integrated hardware with power
switches, gate driver, low level protection and measurement sensors assembled in
one single block. Therefore, a range of multilevel converters can be easily
constructed. However, in high power application, such as HVDC, an array of PEBBs
is required. With increasing numbers of PEBBs, the conventional control interface
between the controller and PEBBs will become increasingly complex. A large
number of wires will be used to deliver the control, measurement and status signals.
Therefore, a ring control network was introduced to simplify the wiring system. The
exchanged information will be packed into data frame format and transmitted within
the ring. However, data transmission delays must be accurately compensated for to
ensure all PEBBs are able to initialize new duty cycles simultaneously. Besides,
communication cable redundancy must be enabled to increase the ring reliability.
This thesis first studied and investigated the prospect of implementing an
established industrial network for internal monitoring and control of a power
converter. A set of basic communication requirements was developed to evaluate
some of the potential industrial networks. As a result, EtherCAT is recognized as the
most potentially useful control network in this research. It meets the proposed
maxima acceptable delay (approximately ± 20 ns) and supports single fault tolerance
with its cable redundancy. Furthermore, a PEBB prototype was designed with
EtherCAT FB1130 Piggy Back Controller board is included as a Slave
Communication Controller. This thesis also proposed a simple redundancy
controller for a cascaded multilevel converter. When PEBB failure is detected, this
controller will either swap the backup PEBB with the defective unit or it will
degrade the system level automatically.
Finally, a Modular Multilevel Converter (MMC) with 2 kHz switching
frequency is setup for experimental verification. Xilinx Zynq ZC702 Evaluation
board is employed as a master controller. Level Shifted Pulse Width Modulation and
capacitor voltage balancing control schemes are implemented within the Programmable Logic of XC7020. The feasibility of the MMC control strategies and
the redundancy controller has been fully validated. Three ring behavioral tests are
conducted to study the MMC performance by emulating EtherCAT network for
internal monitoring and control of the converter. The results prove that MMC will
operate normally if all PEBBs manage to initialize new duty cycles simultaneously
with low latency (approximately ± 20 ns). | nb_NO |
