by Martin Gross, ABB
The power industry is on the verge of the biggest changes since the days of Thomas Edison and George Westinghouse.
Recent breakthroughs around the world in power transmission systems have made it imperative for the U.S. to develop a more intelligent, flexible, long-haul transmission network that can carry renewable energy from remote locations to major population centers.
RPS Driving Build Out
Today in the U.S., 33 states have some kind of renewable standard. These renewable portfolio standards (RPS), and their corresponding deadlines for compliance, have significantly impacted generation spending.
Proposed goals for a national RPS vary from 12 to 25 percent. If the government enacts a national standard, experts estimate that incremental capacity additions of more than 300 GW will be needed.
Transmission capacity for this new and mostly remote generation, however, does not exist.
With an average construction schedule of 60 to 72 months for a 500-MW, 345-kV transmission line, it could take well beyond 2025 to build the needed transmission lines.
The North American Electric Reliability Corp.’s (NERC’s) October 2009 publication, “2009 Long-Term Reliability Assessment 2009-2018,” notes that although existing reserve margins are adequate across the U.S. for the next few years, the first priority must be to expand the grid and increase transmission capacity to handle expected renewable generation growth.
The report concludes, “More than 11,000 miles (or 35 percent) of transmission above 200 kV proposed and projected in this report must be developed on time to ensure reliability over the next five years.”
Construction siting is the most urgent issue for the electric power industry now and in the future, according to NERC.
Bulk Transmission Capacity: A Prerequisite
If utilities are to harvest the vast renewable power potential in remote U.S. locations or anywhere in the world, they must be able to move it efficiently from its production point to cities and load centers where people live and work.
Bulk transmission capacity is a prerequisite for large-scale renewable generation. While many renewable power sources’ intermittent nature creates challenges for grid reliability, proven, readily-available and cost-effective transmission technologies exist to mitigate their impact. They are available and include high-voltage direct current (HVDC) and flexible AC transmission systems (FACTS).
Several key U.S. transmission projects focus on transmitting renewable generation:
- Southern California Edison continues to add transmission to support wind generation in the Tehachapi region.
- FPL’s NextEra Energy has completed much of its merchant transmission associated with its Horse Hollow Wind Energy Center project in Texas.
- LS Power’s Southwest Intertie will move renewable power from Wyoming and Montana to substations near Las Vegas using AC and possibly HVDC transmission.
- Another LS Power project, Overland Transmission, will apply either high-voltage AC or DC circuits across 560 miles to move renewables-fueled generation between eastern Wyoming and southern Idaho.
- San Diego Gas & Electric’s Sunrise PowerLink will play a major role in bringing renewable generation from the Imperial Valley into southern California, even though it was built primarily to ensure system reliability and support load growth. According to the Renewable Energy Transmission Initiative, the Imperial Valley region has potential for 6,870 MW of solar, 3,495 MW of wind and 2,000 MW of geothermal power generation.
Although multiple major transmission projects are underway or nearing construction in the U.S., they are not enough to support RPS requirements. The two key renewable power transmission capacity expansion impediments are:
- The fragmented and time-consuming regulatory approval process, and
- The absence of an integrated renewable generation and transmission strategy.
Two recent transmission successes in Europe and China provide an idea of what U.S. transmission could look like.
Europe: Visionary Governments Prepare for Offshore Wind
In the North Sea 81 miles off Germany’s coast, the world’s largest offshore wind farm is connected to the grid using advanced HVDC technology.
With HVDC cables lying underwater and underground, the project’s environmental impact is minimized and the regulatory and siting procedures have been swift.
The project connects wind generators and transmits power to a new substation on Germany’s coast. The power is then connected to the existing transmission grid.
The BORWIN 1 offshore wind farm demonstrates how HVDC can accumulate power generated in remote locations and transmit it to load centers. Using HVDC and wind generation, the transmission grid operator, Transpower, expects to avoid 1.5 million tons of carbon dioxide emissions annually by replacing fossil fuel generation.
A larger project was launched in summer off Europe’s coast. ABB is working with Transpower to supply an 800-MW power link. This project will use HVDC light technology to transmit power from the 400-MW Borkum West II wind farm (see Figure 1) and other wind farms to be developed nearby.
The wind farms will be connected to an offshore HVDC converter station that will transmit electricity to the onshore HVDC station at Dàƒ¶rpen on Germany’s northwestern coast via 165 kilometers of underwater and underground DC cables.
The Dàƒ¶rpen/West converter station will in turn feed AC power to the mainland grid. At 320 kV, this will be the highest voltage level of extruded cable used for HVDC.
Transmission technologies such as these are integrating renewable energy sources efficiently, ensuring grid reliability and stability and lowering environmental impact.
China: Transmission Link up, Running
China continues to set the example and lead in developing advanced transmission technologies that tap the power of renewable energies without many of the state or national obstacles faced in the U.S. or Europe.
For example, ABB recently worked with the State Grid Corp. of China (SGCC) to create the world’s first ultrahigh-voltage direct current (UHVDC) transmission link for commercial operation.
It is the world’s longest and most powerful transmission link (see Figure 2), according to ABB.
The ±800 kV Xiangjiaba to Shanghai UHVDC link can transmit up to 7,200 MW of power from the Xiangjiaba hydropower plant in southwestern China to Shanghai, the country’s leading industrial and commercial center, which is some 2,000 kilometers away in eastern China.
The new link can meet the electricity needs of some 24 million people and sets a new benchmark in voltage levels and transmission capacity, superseding the 600-kV Itaipu transmission line in Brazil, also developed by ABB.
The high-capacity power link comprises a single overhead line and occupies less space than the existing system. Moreover, transmission losses on the new line are less than 7 percent; considerably less than the existing 500-kV system. The electricity saved is equivalent to the power needs of some 1 million people in China.
UHVDC transmission is a new and expanded development of HVDC. It is particularly suitable for vast countries such as China and India where consumption centers are often far from power sources, including renewables.
Overcoming U.S. Obstacles
While in other parts of the world governments, regulators, utilities and industries are working toward common goals, many U.S. transmission projects have not overcome regulatory hurdles.
Things can be done differently. In Texas, utilities, multiple regulatory agencies, generation companies and reliability councils are working together to execute a public utility commission (PUC) order effectively, timely and fairly. Hallmark to this activity is the PUC-driven coordination among transmission and generation stakeholders.
When completed by the end of 2013, this Texas Competitive Renewable Energy Zones (CREZ) initiative should result in incremental addition of more than 5,000 miles of HVAC transmission, allowing 18 GW of renewable generation to be moved reliably from western Texas into Dallas, San Antonio and Austin.
The Electric Reliability Council of Texas consulted other regional transmission organizations, independent organizations, independent system operators and utilities while studying and developing multiple scenarios.
The Texas Department of Wildlife provided impact analysis. Based on ERCOT recommendations, the PUC chose one of four CREZ scenarios and ordered its development.
The PUC provided stakeholders with guidelines and protocols, assuring them that neither generation nor transmission investment will be “stranded.”
This was done to provide generation stakeholders the assurance they need before building new wind generation.
To comply, wind generators have been busy. Nearly 11 GW of wind power are installed, 450 MW of new wind power are under construction and nearly 13 GW of wind are in development.
These Texas projects got off the ground in years, not decades.
Swift regulatory and siting procedures, fair cost allocation and political courage to execute are needed to resolve obstacles delaying renewable energy and related transmission build out across the U.S. and other nations grappling with this issue.
A progressive PUC, such as the Texas PUC, and cooperation among the regulatory agencies that have agreed on common goals and executed the reviews and permits needed to keep schedules on track, can lead to success.
“The recent economic recession has slowed the growth in demand for electricity, but we cannot squander this opportunity to address future needs,” said Idaho Gov. C.L. Otter. “It is clear that coordination among states, the federal government, all segments of the industry and nongovernmental organizations is essential for the region to meet its clean energy needs.”
The Texas CREZ shows how things can get done in the U.S. A visionary PUC with political support, a coordinated regulatory process, and the courage by everyone involved combines for a favorable environment for sustainable renewable power growth.
This model can be applied across the U.S. as it is elsewhere.
Once a fast-track, integrated renewable power and transmission strategy is set in motion, the U.S. will meet its RPS targets and be positioned to take full advantage of these rapidly growing transmission technologies, systems and capacity already being built and implemented elsewhere throughout the world.
Martin Gross is the global head of grid systems business for ABB. Prior to being appointed to the role earlier this year, Martin was region division manager in North America and local division manager in the U.S. for the power systems division of ABB. Gross has been with ABB in various leadership roles since 1986.More Electric Light & Power Articles
Past EL&P Issues