Multiphase Modular Multilevel Converter Based Drive System For Oil And Gas Recovery In Subsea Applications
الملخص
Adjustable Speed Drives (ASDs) in subsea/offshore oil and gas applications are
involved in several processes throughout production, transportation, and treatment
phases, as they supply pumps and compressors. Therefore, ASDs’ in subsea
applications have gone through continuous development. The currently existing
systems exhibit several energy-conversion challenges that negatively impact the
industry costs and green energy. In order to improve the energy-conversion
efficiencies, this thesis, apparently, adopts a trend of using low-rating semiconductor
devices to handle medium-/high-voltage levels along the various drive system stages.
A trend that is believed, by the author, to become in the near future the foundation of
flexible, redundant, and compact energy-conversion in the majority of medium-/high
voltage power applications. This thesis proposes the employment of Modular
Multilevel Converters (MMCs) in MV-ASD applications in order to ease a
transformerless operation while handling medium voltages using low-rating
semiconductors. This, in return, reduces the system size and weight. The zero-/low
speed operation of MMC-based ASDs (a main challenge of applying MMCs in ASDs)
is investigated in this thesis. The recent techniques proposed to improve operation
during those intervals, implement complex hardware/software approaches. To cope
with this issue, this thesis proposes multiphase machines for MMC-based AC-drives.
Among several advantages regarding the power splitting, multiphase machines provide
additional degrees of freedom compared to their three-phase counterparts. Novel exploitation to these additional degrees of freedom is proposed by injecting a secondary
current component in the load current with specific magnitude and frequency during
zero-/low-speed intervals enabling the drive system to function duly. Since the control
of these secondary components is already inherited in the current controller structure of
any multiphase machine, no additional algorithms or sensors will be required.
Moreover, a hybrid-boost MMC converter is proposed to boost the MMC output
voltage. The stepped output voltage generated by the MMC reduces or eliminates the
filtering requirements. The boosting capability of the proposed architecture eliminates
the need for bulky low-frequency transformers at the converter output terminals. In
order to enhance the drive output torque, a Trapezoidal Phase Disposition Pulse Width
Modulation Technique (TPD-PWM) is proposed in this thesis. Different slope angles
of the trapezoidal modulation signal are tested and compared to other modulation
techniques in order to select the angle with the best torque enhancement meanwhile
maintaining good Total Harmonic Distortion (THD) levels. Moreover, the adopted
modulation technique reduces the switching losses compared to the conventional
Sinusoidal-based PWM. Eventually, a series-connected Half-Bridge (HB) modules are
proposed as an Active Front End (AFE) rectifier for the drive system in order to
generate an adequate DC-link voltage for the medium-voltage drive system using low
rating semiconductor devices. The proposed techniques through this thesis have been
supported with both experimental and simulation results.
DOI/handle
http://hdl.handle.net/10576/12361المجموعات
- الهندسة الكهربائية [53 items ]