:quality(80)/p7i.vogel.de/wcms/71/fd/71fdcc22d9a9bd2f42985f692c4aefa2/0128924236v2.jpeg "Wolfspeed reported a milestone in silicon carbide manufacturing with the successful production of a single-crystal 300mm SiC wafer. (symbolic image) (Source: © Four888 - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/94/54/94548eaecd020681e558d563bc48ba1d/0128926221v2.jpeg "Harbinger is leveraging its electrification platform technology and battery manufacturing expertise to bring energy storage to Airstream travel trailers. (Source: Harbinger)")
:quality(80)/p7i.vogel.de/wcms/29/99/2999bb9af245dd31f4c837c1d9359046/0128923137v2.jpeg "Trench SiC MOSFET bare dies enable compact, high-performance power semiconductor solutions. (symbolic image) (Source: © ryanking999 - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/10/78/107856328ef320cc081bf88e0baf95e8/0128685487v2.jpeg "Integrated magnetics enable compact and reliable power conversion for space systems. (Source: Exxelia)")
:quality(80)/p7i.vogel.de/wcms/67/62/676279913d77e1db48eb5cbe9be4c767/0128937895v2.jpeg "(Bild: © WrightStudio - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/0f/a2/0fa2b5bdc21e408fd73e637d226d5210/0128681532v2.jpeg "Symbolic Image: Wind and solar power lead Germany’s electricity generation in 2025, marking a continued shift toward renewable energy. (Source: © koosy - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/4f/6f/4f6faf0ca6f748a2967d6b5bba7c88e1/0128682406v2.jpeg "Symbolic Image: SoCs for automotive applications enable enhanced performance in advanced driver-assistance systems. (Source: © Sodapeaw - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/ad/52/ad52f7b5542eff15ba54ec354d31b50d/0128681536v4.jpeg "Symbolic Image: This transaction brings battery technology development, manufacturing strategy, and capital-market access together within a single holding structure. (Source: © Sarut - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/1e/9c/1e9c45d6fcf2fb48dc47756e4cb20174/0128931043v2.jpeg "Syensqo and Axens have launched Argylium to support the development and scale-up of solid-state battery materials in Europe. (symbolic image) (Source: © Anastasiia - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/8b/42/8b4271e1bedea432ab03c83959e30431/0128818204v2.jpeg "Rows of batteries on Kauai island provide more than just power: They stabilize the grid. A project between the Kauai Island Utility Cooperative, NLR, and several more partners showed that electronics can offer equal grid strength to spinning resources. (Source: Connor O’Neil, National Laboratory of the Rockies)")
:quality(80)/p7i.vogel.de/wcms/87/5a/875a8fa395c1eec9677e075fae7f5e8e/0128793884v2.jpeg "MEMS-based hot-switched power panels enable compact, high-performance switching solutions for modern electronics. (Symbolic image) (Source: © Best - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/2f/93/2f9364112e8c6ff38c26f9ba34d0f692/0128791306v2.jpeg "Scalable, high-performance SiC MOSFET solutions enable faster development and improved efficiency in power electronics. (Symbolic image) (Source: © metamorworks - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/3c/d1/3cd1cacbceb792ba63727199c61ca434/0127801860v2.jpeg "Thanks to cloud technology, users can collaborate on projects from anywhere and always have access to the latest planning data. (Source: SIEMENS)")
:quality(80)/p7i.vogel.de/wcms/5a/a0/5aa0436498af618297961fd54ab36cdf/0126290792v2.jpeg "Siemens accelerates student-led semiconductor innovation across Europe’s leading technical universities through Cre8Ventures’ Open Higher Education Program developed in collaboration with Arm and University of Southampton (Source: Siemens Digital Industries Software)")
:quality(80)/p7i.vogel.de/wcms/cb/30/cb30ebdca7fcaea281749cb396654eb3/0124716339v2.jpeg "Rolls-Royce unveils Battery Analytics for its mtu EnergyPack, offering real-time insights, predictive maintenance, and enhanced cybersecurity to boost performance and longevity. (Source: Rolls-Royce plc)")
:quality(80)/p7i.vogel.de/wcms/0b/b4/0bb4cdfa862043eac04c6a195e59b3e0/0124131782v2.jpeg "Siemens has completed the acquisition of DownStream Technologies, a leading provider of manufacturing data preparation solutions for printed circuit board design. (Source: Siemens)")
Energy Transmission HVDC light: Europe’s bet on IGBT
Related Vendors
:fill(fff,0)/p7i.vogel.de/companies/60/7e/607ec89d5d9b5/white-frame.jpg "white frame.jpg (www.rohm.com)")
:fill(fff,0)/p7i.vogel.de/companies/62/a0/62a0a0de7d56a/aic-europe-logo.jpeg "aic-europe-logo (AIC Europe)"){kind=logo}
:fill(fff,0)/p7i.vogel.de/companies/68/2c/682c3e2e9a195/logotype-rvb.jpeg "logotype-rvb (https://www.mersen.com/en)")
HVDC Light (High Voltage Direct Current Light) is a new type of power transmission technology. Some experts consider it superior to HVAC (High Voltage Alternating Current) and classical HVDC. Swedish-Swiss multinational corporation ABB introduced HVDC Light in the late 1990s. In 2018, Swiss company Hitachi Energy acquired HVDC Light, which is still growing in practical applications.
HVDC Light is revolutionizing the field of power transmission with its innovative design and improved efficiency. Unlike traditional methods, this technology utilizes advanced converter systems to enhance the control and stability of electricity flow. Its adoption signifies a shift towards more flexible and sustainable energy solutions.
HVDC Light explained
HVDC Light belongs to the family of HVDC. It is a relatively newer transmission technology, only 25 years old. The US Department of Energy (DoE) quotes “HVDC Light is an intelligent link for transmitting electrical power.”
The key difference between HVDC and HVDC Light is the type of converter technology they use. HVDC relies on converters that must be commutated or turned off by a process. HVDC Light relies on self-commutated converters, which can quickly switch between on and off states.
Classical HVDC uses LCC converters (Line Commutated Converter). LCC converters are made from thyristors. We have explained the thyristor in our article. In short, a thyristor is a current-controlled power semiconductor device used to control medium to high power in industrial applications. A control signal can easily turn on a Thyristor.
A thyristor is a latch-on device, meaning that it always remains on and cannot be turned off by control. Thyristor turn-off is a wholesome process. A strong grid is required to provide a zero-crossing current to turn it off. The power direction is reversed by changing the DC voltage polarity.
HVDC Light implements a smart converter technology, known as VSC (Voltage Source Converter), built from self-commutated devices such as IGBT (Insulated Bipolar Junction Transistor) network in series. IGBT is a voltage-controlled power semiconductor device that can be easily turned on and off by control. The power direction can be changed without even reversing the voltage polarity. As a result, HVDC Light offers better power transmission and current capabilities than classical converters used in HVDC.
IGBT-based VSCs use PWM (Pulse Width Modulation) as a control and reactive power compensation technique to result in higher current densities with lower power losses. Recent HVDC Light implementations use BIGTs (Bimodal Insulated Gate Transistors) with advanced switching algorithms to offer better results.
HVDC Light features
Active power control, reactive power change, filtering, harmonic suppression, power oscillation damping, and many more “electrical features” have scaled HVDC Light deployment globally.
Compact design: HVDC Light uses compact converter stations that deliver effective control and reduced power losses. The relative size ratio between classical HVDC and HVDC Light is 4:1, indicating that HVDC Light incorporates small converter stations and offers room for multi-terminal configuration.
Invisible connectivity: Transmitting power beneath the ground or underwater is one of the main benefits of implementing HVDC Light. Hitachi Energy refers to HVDC Light as “invisible power lines” because, in most cases, people won’t be able to catch a glimpse of them like classical transmission lines.
Environmentally sound: HVDC Light is an effort to focus on environmental safety. It offers fewer field emissions, noise, and EMI. It is an oil-free transmission technology. Other transmission technologies use oil as an insulation and cooling medium. Although oil is a good solution for dielectric strength, it is not safe in urban areas. HVDC Light uses dry XLPE (Extruded Solid Polymer) DC solid-state cables that exhibit high power density.
Grid support: The capabilities of HVDC Light can integrate into HVAC to support AC voltage, reactive power compensation, active power control, harmonic suppression, power system stabilization, and also black start a grid. HVDC light can also function as an interconnector between asynchronous grids because it can easily adapt to grid codes.
HVDC Light use cases
HVDC Light use cases include the following:
- Offshore wind generation above 100 km, from wind farms to onshore grids.
- Underwater power links between countries.
- Providing electricity to topologically differentiated areas such as islands, canal cities, and forests.
- Connecting remote areas and undeveloped areas.
- Underground power links.
- City center infeed.
- DC links in AC grids.
- Interconnections that require a small physical footprint and weight, where HVAC is impractical.
:quality(80)/p7i.vogel.de/wcms/fc/56/fc560a734e228ae9f5466272c5566b17/0124012165v2.jpeg "Press pack-device approaches and active heat sinks can enhance IGBT designs, thus improving performance. (Source: engel.ac - stock.adobe.com)")
COOLING SOLUTIONS
Maximize Lifetime & Power Density in High Power Semiconductors Modules
Examples of some upcoming HVDC Light projects
HVDC Light has been implemented in many parts of Europe, followed by the USA and Asian countries. The world’s first HVDC Light link was deployed in Gotland, Sweden, in 1997.
HVDC Light is marketed as a “solution” to European energy needs because multiple HVDC projects run in Europe—for example, the Viking Link between the UK and Denmark and the NordLink Interconnector between Germany and Norway.
Examples of upcoming projects are listed below:
- 1. SuedLink DC4 is one of the most upcoming energy transition projects in Germany, powered by HVDC Light. Hitachi Energy claims that the project will deliver emission-free 2000 MW of energy to 5 million German homes.
- 2. Zhangbei DC-grid project in China. Commissioned in 2020, the total power transmitted is 3000 MW.
- 3. Project Lightning is a subsea power transmission in the MENA region, outside Norwegian waters, with two links. The commissioning target is 2025.
- 4. SunZia Transmission Project in the USA, linking Arizona’s grid to New Mexico’s wind farms. The commissioning target is 2026.
HVAC vs HVDC vs HVDC Light
HVAC vs HVDC vs HVDC Light is not a debate. Each transmission technology is best suited for its use case. However, this section explains a basic difference between the three.
HVAC is the traditional method to deliver power to every home, commercial space, or factory. High-voltage AC is stepped up from the power station, sent through transmission lines, where it gets stepped down to reach the destination.
HVAC, with an optimal range between 300 and 600 km, is not suitable for long distances. While classical HVDC is suitable for very long distances, such as 600 km to 2500 km+, HVDC Light is suitable for long distances from 50 to 2000 km, slightly less than HVDC.
| Feature | HVAC | HVDC | HVDC Light |
| Current Type | AC | DC | DC |
| Converter Type | No converter Transformer performs the main function | Line Commutated Converter LCC | Voltage Source Converter VSC |
| Sub-converter Type | - | Thyristor | IGBT |
| Power Direction Control | Limited Strong dependency | DC polarity Strong grid dependency | Operates without a grid |
| Independent Power Control | No | No | Yes |
| Reactive Power Control | Complex | Compensator network | Independent control |
| Harmonics | Moderate | Moderate with filters | Low due to PWM |
| Cable Type | Overhead | Oil-filled | Lightweight and flexible, without oil-filling |
| Distance | 300 to 600 km | 600 to 2500 km+ | 600 to 2000 km |
| Power | Moderate (Mega Watts) | Very high (Giga Watts) | Moderate (3000 Mega Watts) |
| Bulk Power Transmission | Low | High | Moderate |
| Grid Interconnection | Synchronized grid interconnection | Asynchronous grid interconnection is possible | Asynchronous grid interconnection is possible |
| Implementation | Highly common | Highly common | Relatively new |
| Delivery Time | 18-30 months | 36 months | 24 months |
| Cost | Economical | Economical | Costly |
| Application | Homes and offices | Intercontinental links | Offshore links, islands, canal cities, windmill farms, weak and grids |
| Scheduled Maintenance | 2-3% | <1% | <0.5% |
| Reliability | Low | High | High |
| Maturity | 140 years | 70 years | 25 years |
(ID:50598767)
:quality(80)/p7i.vogel.de/wcms/af/07/af073e302fcca1153bcaca553175006c/0124143921v2.jpeg "Thyristors are power semiconductor devices used in industrial power control applications. These devices are nothing new; they have been on the market for decades. Learn more about them here. (Source: jossbomon - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/21/7f/217fcc66cf062b3e3212dcb6c2d53992/0124480366v4.jpeg "Discover the DIAC, a bidirectional semiconductor device blending diode and thyristor properties, revolutionizing AC circuits with its unique structure, operation, and applications. (Source: © Hseyin - stock.adobe.com)")