2 research outputs found
Development and implementation of a LabVIEW based SCADA system for a meshed multi-terminal VSC-HVDC grid scaled platform
This project is oriented to the development of a Supervisory, Control and Data Acquisition
(SCADA) software to control and supervise electrical variables from a scaled platform that
represents a meshed HVDC grid employing National Instruments hardware and LabVIEW logic
environment. The objective is to obtain real time visualization of DC and AC electrical variables
and a lossless data stream acquisition.
The acquisition system hardware elements have been configured, tested and installed on the
grid platform. The system is composed of three chassis, each inside of a VSC terminal cabinet,
with integrated Field-Programmable Gate Arrays (FPGAs), one of them connected via PCI bus
to a local processor and the rest too via Ethernet through a switch. Analogical acquisition
modules were A/D conversion takes place are inserted into the chassis. A personal computer is
used as host, screen terminal and storing space.
There are two main access modes to the FPGAs through the real time system. It has been
implemented a Scan mode VI to monitor all the grid DC signals and a faster FPGA access mode
VI to monitor one converter AC and DC values. The FPGA application consists of two tasks
running at different rates and a FIFO has been implemented to communicate between them
without data loss.
Multiple structures have been tested on the grid platform and evaluated, ensuring the
compliance of previously established specifications, such as sampling and scanning rate, screen
refreshment or possible data loss.
Additionally a turbine emulator was implemented and tested in Labview for further testing
Development and implementation of a LabVIEW based SCADA system for a meshed multi-terminal VSC-HVDC grid scaled platform
This project is oriented to the development of a Supervisory, Control and Data Acquisition
(SCADA) software to control and supervise electrical variables from a scaled platform that
represents a meshed HVDC grid employing National Instruments hardware and LabVIEW logic
environment. The objective is to obtain real time visualization of DC and AC electrical variables
and a lossless data stream acquisition.
The acquisition system hardware elements have been configured, tested and installed on the
grid platform. The system is composed of three chassis, each inside of a VSC terminal cabinet,
with integrated Field-Programmable Gate Arrays (FPGAs), one of them connected via PCI bus
to a local processor and the rest too via Ethernet through a switch. Analogical acquisition
modules were A/D conversion takes place are inserted into the chassis. A personal computer is
used as host, screen terminal and storing space.
There are two main access modes to the FPGAs through the real time system. It has been
implemented a Scan mode VI to monitor all the grid DC signals and a faster FPGA access mode
VI to monitor one converter AC and DC values. The FPGA application consists of two tasks
running at different rates and a FIFO has been implemented to communicate between them
without data loss.
Multiple structures have been tested on the grid platform and evaluated, ensuring the
compliance of previously established specifications, such as sampling and scanning rate, screen
refreshment or possible data loss.
Additionally a turbine emulator was implemented and tested in Labview for further testing