HVDC PLUS (VSC Technology)
General Information
- Description
- Benefits
- Applications
- References
HVDC PLUS is an Innovation in the field of HVDC transmission systems and opens up new fields of the proven HVDC technology.
Its innovative design allows technical as well as economical advantages. Via implementation of a new concept of modular multilevel voltage-sourced converters, HVDC PLUS is the preferred solution where shortage of space is a criterion. It is ideal for connection of remote offshore platforms and wind farms to the onshore grid as well as for power supply high-density areas such as mega cities. HVDC PLUS improves the performance of the transmission grid with regard to system security.
As an innovation leader in HVDC transmission, Siemens developed HVDC PLUS, an advanced and universally applicable solution for power transmission in the range up to thousand megawatts or higher.
HVDC PLUS offers significant technological benefits for transmission grids:
- It can be operated in AC grids with extremely low short-circuit levels or with passive loads.
- It has independent control of active and reactive power (full four quadrant operation).
- It can be connected to blacked-out networks and re-energize them.
- It can be operated in an unsymmetrical network (e.g. during AC network faults) and it provides unbalance control to compensate unsymmetrical loads.
- It is flexible with respect to reactive power and offers voltage control for weak AC grids.
- It is robust with respect to AC network faults, fault-ride through capability and it serves as firewall for limitation of spread of system disturbances.
- It is fully suitable for Back-to-Back application as well as for long-distance-transmission with DC cables or with DC overhead-line.
Economical Aspects
The VSC technology provides a straight forward AC side connection. The modular multilevel converter principle renders AC harmonic filters superfluous.
A standard transformer design can be used without special requirements to withstand DC voltage or harmonic currents.
The converter does not produce any significant high frequency noise, so outdoor installation of AC- and DC reactors (if necessary) and switchgear is feasible.
The modular rack-type converter arrangement provides flexibility with respect to building height versus -length. It allows to lower building height compared to conventional HVDC converters.
The converter modules are operated with a low switching frequency resulting in low converter losses.
The converter and the control equipment is designed with a high level of component redundancy.
The features of HVDC PLUS are:
- Low space requirements
- Low height of the installation
- Short installation and commissioning period
- Lower losses in comparisone with 2 and 3-level converters
- High Reliability
Environmental Aspects & CO2 reduction:
As the power industry strives to reduce its environmental impacts by utilizing more renewable energy resources (e.g. large wind farms) the transmission system owners face the difficulties of integrating these often remote and fluctuating energy sources into the grid.
HVDC PLUS is the key solution to these challenges which impede the take-up of renewable energies. In this regard, the possibility to operate with low short-circuit levels, the small footprint, and the independent control of MW and Mvar are of particularly advantages.
With HVDC PLUS, islanded networks, such as oil and gas platforms as well as mines, can be connected without the need for local generation which is less efficient. This helps reduce the CO2 emissions.
Applications
- Back-to-Back Transmission
- Submarine DC cable long-distance transmission
- Long-distance transmission with DC overhead line
- Offshore Applications (e.g. wind farms or oil/gas offshore platforms)
- Multiterminal Configuration
Submarine DC Transmission
HVAC cable transmission systems have a limited transmission length, from both technical and economical points of view, whereas the HVDC PLUS has practically no restrictions. Therefore, it provides an optimal solution for longer transmission distances. The HVDC transmission is the solution for cable systems longer than 80 - 120 km.
HVDC PLUS, with its symmetrical monopole configuration, is a particularly attractive solution for cable applications. A wide range of economic cable designs is available in combination with HVDC PLUS. Typical applications include: energy platforms, offshore wind farms, island connections, urban in-feeds etc. which can be connected via submarine cables to the main grids.
Back-to-Back Transmission
DC Back-to-Back is frequently used to couple neighboring AC networks, e. g. two or more national grids, with different frequency or voltage control characteristics. In such cases a synchronous AC interconnection is not possible.
A Back-to-Back connection with HVDC PLUS will overcome the above mentioned difficulties: HVDC PLUS makes power flow. Furthermore, the interconnection with a Back-to-Back HVDC PLUS link will not increase the short-circuit power of the systems. In addition, it prevents the spread of cascading disturbances (firewall for Blackout prevention).
Overhead Line Transmission
DC overhead lines use more narrow transmission corridors for the same power transfer when compared with their AC counterparts and this is often a crucial issue while opting for DC transmission. In the future DC may also be used to increase the power transfer through existing rights-of-way by converting AC lines to DC. HVDC PLUS with its flexible topology is an ideal converter to simplify this process.
All OHL sections are subjected to a higher risk of fault (from lightning strikes etc.) than the insulated cables and therefore HVDC PLUS has the capability to cope with faults on the DC line.
Offshore Applications
Offshore wind farms as well as oil and gas platforms are often located more than 150 km away from the coast line. They can be connected to the onshore grid via HVDC systems. From the electrical point of view, these offshore farms and platforms constitute weak isolated grids.
Connection of offshore wind farms and oil platforms via HVDC PLUS to the onshore grid helps overcome some challenges:
- For civil engineering: Some major electrical equipment has to be installed under difficult environmental conditions.
- For large installations: An individual top side proves to be a better solution. The module is completely assembled and pre-tested in a shipyard. It is moved by a vessel to its final position and lifted by a special crane as a single-piece-unit on the jacket.
- For weight and size restrictions: The equipment has to be shrinked down to a minimum, using SF 6 insulated devices, whenever possible. Attention is paid to the particular protection of the equipment against the harsh environmental conditions.
- Despite of compactness: The module is unique due to its accessibility. Even large pieces of equipment, such as converter transformers can be changed easily.
The HVDC PLUS represents the ideal power transmission system for such interconnections. It offers some outstanding advantages over the conventional HVDC: the design is very compact and synchronous condensers for voltage support are not necessary.
Moreover, Siemens has the experience and capability to carry out comprehensive system analysis as well as to design, deliver and maintain a complex transmission system with its typical sub-systems, offshore medium voltage distribution, HVDC or HVAC such as this system of transmission from offshore to onshore, FACTS devices and control as well as protection and communication systems.
Multiterminal Configuration
With HVDC PLUS more than two AC systems can be interconnected via a DC transmission system, for the structure and controllability of the HVDC grid is much simpler with an HVDC PLUS than with the conventional HVDC. If the power flow direction has to be changed, a polarity reversal of the DC voltage is no longer necessary.
Multiterminal configurations can be implemented as a radial or a meshed system or in a combination of both. For megacities for example it offers an opportunity of an HVDC ring around an inner-city distribution network, using peripheral power plants for power supply.
Siemens´ HVDC PLUS with its multilevel converter provides the appropriate technology to connect remote energy sources to the grid or ensure power supply by means of HVDC technology even in tight spots like megacities. Trans Bay Cable LLC chose Siemens to meet that challenge in the area of San Francisco where the TransBay Cable project will form a milestone of HVDC PLUS technology. Read more about this first step into a smarter way of HVDC power transmission.
Please use the following link for a overview of our references.
Our Portfolio (4)
Control & Protection of HVDC PLUS
- Description
- Operator Control and Monitoring Level
- Control & Protection Level
- Field Level
Control & Protection of HVDC PLUS
Win-TDC is a recent innovation from Siemens in the field of HVDC control & protection and has already proved its benefits on existing HVDC projects and in a wide area of industrial applications. The system is based on the SIMATIC WinCC Human Machine Interface (HMI) and the SIMATIC TDC (Technology and Drive Control) control system which gives Win-TDC its name.
Compact design is provided by high integration. Fast communication links allow for an independent, central and redundant measuring system, resulting in a highly reliable design. The use of the systems, based on Microsoft Windows®, for all operator´s control, monitoring and engineering purposes enhances user´s acceptance and minimizes training time.
Control & protection Structure
The C&P system for HVDC PLUS follows the well-proven Siemens three level hierarchical structure:
- Operator Control and Monitoring Level
- Control & Protection Level
- Field Level
The different levels are interconnected by powerful redundant serial communication links, such as Fast Ethernet (IEEE 802.3u) and PROFIBUS DP (EN 50170). The use of standardized communication protocols, e.g. TCP/IP and UDP, provides easy adaptation to specific requirements with the flexible implementation of additional features, such as remote access for maintenance purposes.
The operator control and monitoring level consists of the fully redundant HMI system for control and monitoring of the plant, the Linux based remote control interface for communication with control centers via the redundant Local Area Network (LAN), the transient fault recording system (TFR) and the inter station communication system.
The TFR master station provides the central interface for evaluation and configuration. Data from decentralized peripherals is transferred to the master station via a dedicated high speed network ensuring very short download times. As an integral part of Win-TDC, the TFR is directly connected to the measuring systems via serial fiber optic links.
Redundant telecommunication equipment interconnects the LANs of the separate converter stations and provides the interface to their control centers.
The control & protection level comprises the Station Control, High Level Control, DC Protection and Measuring systems, all based on SIMATIC TDC, which includes a powerful standard function block library, the possibility of graphical programming and enables a high integration of control and protection functions while maintaining redundancy.
The central measuring system is connected to the different control & protection systems and provides the interface with the well-proven Siemens hybrid optical DC measuring system.
The High Level Control defines the operating point of the HVDC PLUS converter; it contains the main active and reactive power control algorithms, generating current orders to the lower level high speed current controller. The Station Control integrates the HVDC system into the existing power system (e.g. start-up/shut-down) and carries out administrative functions (e.g. managing the control authorities).
A common redundancy concept relating to hardware and basic software modules (e.g. communication software) is used. Both redundant systems operate with identical states with one system active and the other passive; this allows hot-standby redundancy switchovers without interruption of power transmission.
The protective systems ensure that all possible faults are detected, selectively acted upon and announced. The protection systems are divided into main and backup systems. The protection is equipped with redundant systems. To reduce number of interfaces and their complexity, the processor and I/O boards of the protection systems are housed in the same sub-racks. To provide the strict separation of control & protection tasks, the protection functions use separate processor and I/O boards and TDM bus connections.
At the field level, the commands and indications of the high-voltage devices are converted to or from binary I/O signals to serial signals and connected to the field bus. Input/output units which have been specially designed for switchyard applications are used to interface with the HV switchgear. The lowest operating level for the high voltage components is manually at breakers, disconnectors and ground switches using the Local/Off/Remote selector switch and the Open/Close pushbuttons.
The auxiliary systems are also controlled locally. Status and analog signals of the auxiliary systems are provided on the HMI´s display, Sequence-of-Events Recorder and trend systems.