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HVDC Classic – powerful and economical — High-performance power transmission

Brochure · EN — Siemens Energy brochure (© 12/2021) on HVDC Classic, the line-commutated converter (LCC) HVDC technology: why grid operators need HVDC (renewables-driven load-flow changes, cross-border corridors, power-flow control, low CAPEX/OPEX), the technology's headline ratings (up to 6 GW at ±600 kV and up to 10 GW at ±800 kV; nearly 14 GW in bipolar systems with the new six-inch thyristor rated up to 6.25 kA), 30–50 percent lower transmission losses than comparable HVAC overhead lines beyond 600 km, parallel/series/multi-terminal converter arrangements, four decades of thyristor development culminating in light-triggered thyristors (fewer than 600 thyristors per 1,000 MW in the latest generation versus ~28,000 in 1970), the HVDC Classic after-sales service portfolio with typical system-lifetime guidance, the New Zealand HVDC Inter-Island link Pole 3 case study (700 MW monopolar / 1,400 MW bipolar at ±350 kV DC, strictest seismic requirements ever implemented in an HVDC installation), and a 43-entry selected-references table from Cahora Bassa (1975) to the Vindhyachal Upgrade (2021).

Power rating
Up to 6 GW at ±600 kV and up to 10 GW at ±800 kV; the new six-inch thyristor enables up to nearly 14 GW in bipolar HVDC Classic systems
Transmission efficiency
Lowest losses of all HVDC technologies; typically 30 to 50 percent lower transmission losses than comparable HVAC overhead lines for long-distance transmission over 600 km and more
Right of way
Carries 30 to 40 percent more power than HVAC given the same right of way, plus an overload functionality for emergencies
Thyristor technology
Six-inch light-triggered thyristor (LTT), rated current up to 6.25 kA; fewer than 600 thyristors per 1,000 MW in the latest generation (vs. ~28,000 thyristors/1,000 MW for both valve halls in 1970)
Track record
Proven in more than 50 HVDC projects worldwide; references table lists 43 selected HVDC installations commissioned 1975–2021
World firsts
Changji–Guquan (China): world's first 1,100 kV HVDC link, 12 GW over 3,284 km, converter transformers with 19-meter-long valve bushings connected directly to China's 1,050 kV AC grid; Western HVDC Link (UK) set a world record for 600 kV power transmission via subsea cable

HVDC – the silver bullet? Major challenges for grid operators

The brochure opens by framing HVDC as the answer to optimized grid operation in the face of technical constraints and market development: an ever-increasing share of volatile renewable infeed calls for future-proof, flexible solutions that meet regional regulations and standards. In more than 50 projects worldwide, Siemens Energy has proven its high-voltage direct-current (HVDC) technology to be the best solution for long-distance transmission, grid access, and grid stability.

High power transmission capability: the energy transition from fossil to renewable resources is dramatically changing load flows and requiring improvements to the existing power transmission infrastructure. Increasing distances between power generation and load centers mean higher transmission capabilities are essential, and emerging international electricity markets call for improved transmission capacities and new corridors for power transfer and cross-border interconnectors.

Optimal efficiency: power losses must be kept to an absolute minimum. The ability to flexibly increase current or even temporarily overload power lines in an emergency enhances power grid efficiency, while the minimized right of way required for overhead lines and cables compared to AC systems reduces costs.

Flexibility for future challenges: very fast and accurate power flow control becomes essential as infeed from intermittent renewable sources increases — and fluctuates with the weather. Power also needs to be transmitted in diverse directions and into different regions or even countries, depending on market requirements; other challenges include more flexible grid configurations, redundancies, and more grid-stabilizing functionalities.

Keeping costs low: the lowest achievable CAPEX and OPEX are indispensable, possibly over the entire lifecycle of the investment — supported during operation by high availability and a low-loss solution with minimized operating and maintenance costs. Safety and security for a reliable power supply round out the challenge list: the impact of failures on security of supply must be limited, the highest safety standards maintained in maintenance and operation, and the grid must have optimal resilience against natural disasters, terrorist attacks, and cyber attacks.

The 'Major challenges for grid operators' box summarizes: low investment and operation costs; highest efficiency with minimum losses; maximum operational availability and reliability and the best possible resiliency requirements; compact, adaptable, and economical solution; power exchange between interconnected systems and asynchronous grids; maintenance-friendly, safe, and reliable design with comprehensive lifetime services; future-oriented, flexible solutions for varying power market requirements.

HVDC Classic: Proven technology for sustainable performance

Siemens Energy's HVDC Classic (with line-commutated converter) technology helps grid operators solve diverse technical and economic challenges — while improving grid performance and stability and providing an outstanding control of power flows.

Lowest transmission losses: while HVDC Classic features the lowest losses of all HVDC technologies, it is especially efficient in long-distance transmission over 600 km and more. In this case, HVDC transmission typically features 30 to 50 percent lower transmission losses than comparable HVAC (high-voltage alternating-current) overhead lines. It can also carry 30 to 40 percent more power given the same right of way, and the HVDC transmission link offers an overload functionality that helps supply sufficient power in emergencies and improves grid resilience without requiring more infrastructure investments.

Sustainable savings: HVDC Classic offers the lowest CAPEX and OPEX and has set the efficiency benchmark in long-distance bulk power transmission. With a power rating of up to 6 GW at a voltage level of ±600 kV and up to 10 GW at ±800 kV, HVDC Classic solutions offer very high power transmission capabilities that boost performance and provide a firewall against blackouts in existing overloaded AC grids.

Enhanced grid stability: any HVDC Classic system can improve grid stability, and in special cases the addition of FACTS devices can enhance voltage stability even further — optimizing grid stability such that it achieves the performance of Siemens Energy's voltage-sourced converter technology (HVDC PLUS). Increased security of supply can be achieved by arrangements of series and parallel connected converters in each pole, and multi-terminal setups take this a step further by connecting several stations, for example across several countries.

Ease of maintenance and safety: the converter modules have been redesigned to facilitate easier, faster, and much safer installation, service, and maintenance activities. Thanks to the C-shaped design of these next-generation valve modules, all components can be accessed without having to leave the lifting platform.

Operational advantages (as boxed in the brochure): high power and current transmission capability; optimized grid resilience thanks to sufficient transmission capacity to stabilize AC networks; a very high level of system reliability and redundancy of all key components of the converter control; state-of-the-art control and protection system with hardware and software in hot standby and proven in practice; all current HVDC Classic systems in line with latest cyber security standards (e.g. NERC CIP ready); minimized maintenance and service requirements and the highest health and safety standards.

A new dimension in power rating: parallel, series, and multi-terminal converters

Siemens Energy has developed a variety of technologies to meet the need for ever-higher power transmission capacities. One of them is the new six-inch thyristor with a rated current up to 6.25 kA: it has a high blocking voltage and increased power density, allowing a robust design with a minimum number of components. This development enables up to nearly 14 GW of power transmission in bipolar HVDC Classic systems.

Siemens Energy is delivering the world's most powerful converter transformers to China to create the world's first 1,100 kV HVDC transmission link. This component features 19-meter-long valve bushings that enable the insulation clearance required in air. The Changji–Guquan link is 3,284 kilometers long and has a transmission capacity of 12 GW; its special converter transformers can be directly connected to China's 1,050 kV AC grid, another world's first.

Parallel converters: one answer to the increasing demand for large power transfers, offering very high bulk power transmission, availability, and reliability due to the redundant design. It is also very flexible in operation, with an option to increase current ratings; thanks to its very high currents and minimized height of the transmission towers and valve halls, these installations also enjoy improved public acceptance.

Series converters: this design features improved redundancy and availability during converter failures. It enables grid operators to realize very high transmission voltages and power transfer, yet it is constructed using standardized components and designed to facilitate low investment and high cost advantages during operation, achieved by reducing losses and a simplified operation.

Multi-terminal installation: a system of three or more converter stations that can be built in different locations, offering highly flexible operation and adaptation to changing power flow needs — the perfect solution for connecting AC grids because it offers fast control and support for AC network stability and increased efficiency. In addition, a project can be developed in stages, allowing an early start of power transmission and revenues.

A station-layout photo on this spread labels the main elements of an HVDC Classic converter station: valve hall, DC hall, control building, converter transformers, AC switchgear, and AC filters.

Technology that explores new frontiers: four decades of thyristor development

Siemens Energy is at the forefront of HVDC development and has set many milestones over more than four decades of research and practical implementation. Its overload capability, the advantages of Siemens Energy light-triggered thyristors, and the option to choose between voltage-sourced (HVDC PLUS) and line-commutated converters (HVDC Classic) are part of the company's HVDC success story. (The printed section heading reads 'Technology that explore new frontiers', as published.)

A development chart (1970–2021) shows the continuous improvement of thyristor technology for maximum power density and compact design: from 1.5-inch thyristors with 1.65 kV blocking voltage around 1970 — when roughly 28,000 thyristors per 1,000 MW were needed for both valve halls — to today's six-inch light-triggered thyristors with 8.5 kV blocking voltage, so that with the latest generation only 600 thyristors are required to transmit 1,000 MW of power (the chart's annotation reads '< 600 thyristors/1,000 MW').

An economical solution: depending on system and ambient temperature and on the availability of redundant cooling equipment, the overload capabilities of thyristor-based HVDC Classic systems are an extremely economical asset. The cost benefits are amplified by the rugged system design, which allows for both short-term and long-term overloads if the appropriate cooling is installed. For grid operators this means improved stability of the AC systems, shared spinning reserves, and reliable supply for peak loads; even in the event of a pole outage, power reduction can be minimized.

Light instead of electronics: the thyristor valves convert AC into DC — but while it is common to use electronics to trigger the thyristors, Siemens Energy has developed a more reliable trigger based on fiber optics and a light impulse. The light-triggered thyristor (LTT) uses far fewer electronic components and is therefore more reliable. Fire-retardant and self-extinguishing materials make the thyristors robust and safer in terms of fire prevention, and parallel cooling of the valve levels with de-ionized water helps support maximum utilization of the thyristors.

Large range of high-power applications: the current-carrying capacity of the thyristors, up to 6.25 kA, makes it possible to transmit power at high voltages and currents over very large distances, which cannot be achieved by any other AC or DC transmission technology. The HVDC Yunnan–Guangdong link in China was the first 800 kV project ever realized with overhead lines, and the Western HVDC link in the UK set a world record for 600 kV of power transmitted via subsea cable.

An application-range chart (DC voltage vs. DC current) places HVDC Classic with cable around the 600 kV / 2 kA region (Western Link, UK, 2,200 MW), HVDC Classic with overhead lines from roughly 800 kV / 3 kA (Yunnan–Guangdong, CN, 5,000 MW; Jinping–Sunan, CN, 7,200 MW) up to 1,000 kV / 5 kA (Changji–Guquan, CN, 12,000 MW), and HVDC Classic back-to-back in the low-voltage region (Black Sea, GEO, 2 x 350 MW).

HVDC Classic Services: Partners for decades

Investments in the transmission network are based on long-term calculations of power demand, mirrored in the life expectancy of the transmission equipment. Even high-quality installations require regular maintenance and other services to keep them perfectly efficient. Siemens Energy's dedicated after-sales services start with on-site condition assessments of all assets, complemented by continuous monitoring of critical systems, which minimizes unplanned downtime through preventive maintenance. A lifecycle wheel on this spread runs from engineering, manufacturing, delivery, commissioning, and training through operation, maintenance, repair, upgrade, refurbishment, and replacement to disposal (printed 'Diposal', as published).

The service offering is grouped into four pillars. 'We make your assets more transparent': on-site condition assessments, condition monitoring and diagnostics, remote services, asset management and advisory services. 'We ensure high asset availability': preventive maintenance, field service and repair, spare parts, 24/7 expert hotline and technical support, obsolescence management. 'We optimize asset performance': refurbishment, upgrade and uprate, patch management. 'We support you in operation management': asset operation, spare-part management, customer qualification and training, cyber security services.

A 'Typical life time of systems' chart gives lifetime bands per system layer over a 5–40-year axis, with a general recommendation per layer (reproduced in the table below). For HMI and COM, industrial IT lasts ~5–8 years and standard IT ~2–4 years; control and protection (C&P) lasts ~15–20 years; main components and sub-systems last ~30–40 years.

System layerTypical lifetimeScope (as charted)General recommendation
HMI and COMIndustrial IT ~5–8 years; Standard IT ~2–4 yearsHuman-machine interface and communication systemsKeep spare parts on site (especially in case of obsolescence); consider replacement every ~7–8 years
C&P (control and protection)~15–20 yearsStation control; diagnostic systems; pole control; HVDC protection; hybrid optical measuring / DC measuring system; auxiliary systemsKeep spare parts on site (especially in case of obsolescence); consider modernization and retrofit (incl. HMI and COM) after ~15–20 years
Main components and sub-systems~30–40 yearsConverter transformer; thyristor valves and valve base electronic (HVDC Classic); converter / power modules (HVDC PLUS); valve cooling / converter water cooling (aux power supply); AC/DC yard equipment (conventional primary equipment)Keep spare parts according to recommended spare-parts list / own experience

Selected HVDC references (1975–2021)

Siemens Energy positions itself as a reliable and experienced partner in the development, installation, commissioning, and operation of HVDC Classic solutions. Numerous references around the world — plotted on a world map and listed in the table below — demonstrate its role as a technology leader offering highly efficient solutions for economical long-distance power transmission and interconnecting grids operating asynchronously or at different frequencies.

No.CommissioningProject nameCountryPower rating
011975Cahora Bassa (1975/1998)South Africa – Mozambique1,920 MW
021981AcarayParaguay55 MW
031983DürnrohrAustria550 MW
041984Poste ChâteauguayCanada2 x 500 MW
051987Virginia SmithUSA200 MW
061989Gezhouba – NanqiaoChina1,200 MW
071993EtzenrichtGermany600 MW
081993Wien-SuedostAustria600 MW
091995Sylmar East Valve ReconstructionUSA550 (825) MW
101995Welsh 1995/2017USA600 MW
111997Celilo 1997/2004USA3,100 MW
122000Tianshengqiao – GuangzhouChina1,800 MW
132001Moyle Interconnector (2001/2022)United Kingdom2 x 250 MW
142001Thailand-MalaysiaThailand – Malaysia300 MW
152003East-South Interconnector II and UpgradeIndia2,000/2,500 MW
162004Guizhou – GuangdongChina3,000 MW
172005LamarUSA210 MW
182006BasslinkAustralia500 MW
192007Neptune RTSUSA660 MW
202008Guizhou – Guangdong IIChina3,000 MW
212009Yunnan – GuangdongChina5,000 MW
222010Xiangjiaba – ShanghaiChina6,400 MW
232010Ballia – BhiwadiIndia2,500 MW
242010StorebæltDenmark600 MW
252011BritNedUnited Kingdom1,000 MW
262012COMETASpain2 x 200 MW
272012Jinping – SunanChina7,200 MW
282012Mundra – MohindergarhIndia2,500 MW
292013Black Sea Transmission NetworkGeorgia2 x 350 MW
302013HudsonUSA660 MW
312014Inter-Island link Pole 3New Zealand700 MW
322014EstLink 2Finland-Estonia670 MW
332014Xiluodu – GuangdongChina2 x 3,200 MW
342015Nuozhadu – GuangdongChina5,000 MW
352016EATLCanada1,000 MW
362016WATLCanada1,000 MW
372018Nelson River, Bipole 1 / 2 / 3 (2004 / 1977 / 2018)Canada1,000 / 2,000 / 2,000 MW
382018Bheramara BtB Block 1/2 (2013/2018)Bangladesh2 x 500 MW
392018HVDC BrazilBrazil4,000 MW
402019Western HVDC LinkUnited Kingdom2,200 MW
412020Ethiopia – Kenya HVDC InterconnectorEthiopia - Kenya2,000 MW
422020Moyle C&P RefurbishmentUnited Kingdom2 x 250 MW
432021Vindhyachal UpgradeIndia2 x 250 MW

Figures & drawings

Click any figure to enlarge.

Cover: HVDC Classic – powerful and economical. High-performance power transmission (siemens-energy.com/hvdc).
HVDC Classic converter station layout with labelled elements: valve hall, DC hall, control building, converter transformers, AC switchgear, AC filters (brochure page 6).
Application range for HVDC Classic power transmission — DC voltage vs. DC current, with the with-cable, with-OHL, and back-to-back regions and reference links from Black Sea (2 x 350 MW) to Changji–Guquan (12,000 MW) (brochure page 9).

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