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Grid Design

In this section, we review three power grid design concepts: super grids, smart grids, and microgrids. Each of these is a tool to reduce price volatility and achieve load balancing, necessary for integrating variable renewable energy. These tools can be complementary, but they also compete on the same market of price arbitrage 1.

We recommend the construction of HVDC grids, as outlined below, though only in markets where it has been justified by other studies.

Supergrids

A super grid is a network of high voltage direct current (HVDC) interconnections between grids to transfer power from one to another, reducing price volatility 1.

HVDC interconnections in the United States, including substations, cost an estimated $400 to $2700 per megawatt of capacity over a kilometer 2. A fully-interconnected HVDC network in the United States, as estimated to be able to support 80% wind and solar electricity, would require 34,000 kilometers of cable with a capacity of 12 GW 3. Studies in Ukraine-Romania-Moldova 4 and in Austria 5 have also found that HVDC interconnections can save costs and foster renewable energy penetration relative to AC interconnections. Overbuilding and curtailing of variables sources and electricity storage are other ways to achieve this goal, but HVDC grids are likely to be cheaper.

At distances over about 500 kilometers, direct current (DC) is less expensive than alternating current (AC).

The image: "transmission_cost.svg" cannot be found!

Source: Behravesh and Abbaspour 6.

For undersea cables, HVDC is superior to AC at distances exceeding 50-100 kilometers and valuable for integrating deep offshore wind and ocean energy sources 7.

At distances exceeding about 250 kilometers, DC transmission has lower electricity losses than AC transmission.

The image: "transmission_loss.svg" cannot be found!

Source: EIA 8.

DC also requires less right of way than AC.

The image: "transmission_row.svg" cannot be found!

Source: Mooney and Johnson 9.

Development of superconducting materials could further reduce costs and line losses 7. Additionally, interconnected regions need to harmonize their electricity markets to allow exchange 10.

Concerns have been raised about the health effects of living near power lines, whether AC or DC. To date there is no evidence to substantiate these concerns 8. Regulatory hurdles are the main barrier to expanding HVDC interconnections, and in particular the need to provide compensation to areas that HVDC travel through but do not directly serve 8.

Problem:
Insufficient Grid Interconnection
Solution:
Construct an HVDC Grid in the U.S.

Smart Grids

A smart grid uses information technology to provide real-time price signals to producers and consumers. Especially when coupled with energy storage, a smart grid integrates distributed energy sources. Price signals are a tool to implement demand-side management, reducing price volatility 1. Smart grids can enable modest savings in electricity consumption and greenhouse gas emissions from electricity.

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Potential savings enabled by a smart grid in electricity consumption and greenhouse gas emissions. Source: Friedman and Sreedharan 11.

Microgrids

A microgrid is a largely self-contained grid on the scale of 1 MW of capacity. A microgrid is powered by distributed technologies such as wind, solar, and combined heat and power, and it is regulated through local storage and demand side management. A microgrid can function independently or connect with a larger grid. Microgrids can add resiliency and ancillary services to the larger grid, facilitate integration of distributed renewable energy sources such as rooftop solar, reduce line losses, and accelerate deployment of smart grid technology 12. Progress is needed in interoperability with larger grids, storage technology, standardized inverters and controllers, analytic tools, reliability, and communications strategies 12.

Problem:
Military Base Emissions
Solution:
Renewable Microgrids - U.S. Military

Ancillary Services

Ancillary services are those services, other that provision of power, that are needed to keep an electric grid stable. They are of growing importance with increased amounts of renewable enegy on the grid. Some major ancillary services are as follows.

Energy Storage Ancillary Services
ServiceDurationDescription
Inertia 13InstantaneousSlow rate of change of frequency.
Fast Frequency Response 13MillisecondsStabilize frequency.
Black Start Services 14Less than a secondRestart from a blackout.
Frequency and Voltage Regulation 14Less than a second to secondsEnsure the grid's frequency and voltage is in specified ranges.
Primary Frequency Respose 13SecondsStabilize frequency.
Spinning Reserves 14Seconds or tens of secondsRetain back-up power in active generators.
Non-spinning Reserves 14Tens of seconds to minutesRetain back-up power in inactive generators.
Flexibility Reserves 1310-15 minutesFor insufficient ramp capability for load forecast
Tertiary Reserves 1330-60 minutesBack-up spinning and non-spinning reserves.
Ramping Reserves 13HoursRespond to large forecasting errors.
Peak Shaving 14HoursRespond to daily peaks or troughs in demand.
Firm Power, Avoid Curtailment 14Hours to tens of hoursKeep daily demand and supply profile flat.
Seasonal Storage 14Days to monthsProvide power during summer and winter.

The financial value of ancillary services typically comprise only 2-3% of the wholesale value of electricity, but they are of outsized importance 15. Markets in ancillary services can be developed by making supply 16 or demand 15 more flexible. To date, relatively few ancillary services markets exist, leaving these services not properly priced.

Problem:
Need for Load Balancing
Solution:
Ancillary Service Market

References

  1. Blarke, M., Jenkins, B. "SuperGrid or SmartGrid: Competing strategies for large-scale integration of intermittent renewables?". Energy Policy 58, pp. 381-390. 2013. 2 3

  2. MacDonald, A., Clack, C., Alexander, A., Dunbar, A., Wilczak, J., Xie, Y. "Future cost-competitive electricity systems and their impact on US CO₂ emissions". Nature Climate Change 6, pp. 526–531. January 2016.

  3. Shaner, M., Davis, S., Lewis, M., Caldeira, K. "Geophysical constraints on the reliability of solar and wind power in the United States". Energy & Environmental Science 11(4), pp. 914-925. 2018.

  4. Udrea, O., Lazaroiu, G., Ungureanu, G., Violeta, V. "HVDC Transmission Corridor -- Cost Benefit Analysis". In 2014 49th International Universities Power Engineering Conference (UPEC), pp. 1-6, IEEE. September 2014.

  5. Burgholzer, B., Auer, H. "Cost/benefit analysis of transmission grid expansion to enable further integration of renewable electricity generation in Austria". Renewable Energy 97, pp. 189-196. November 2016.

  6. Behravesh, V., Abbaspour, N. "New Comparison of HVDC and HVAC Transmission system". International Journal of Engineering Innovation & Research 1(3), ISSN : 2277 – 5668. 2012.

  7. Friends of the Supergrid. "Roadmap to the Supergrid Technologies". June 2014. 2

  8. U. S. Energy Information Administration. "Assessing HVDC Transmission for Impacts of Non‐Dispatchable Generation". U. S. Department of Energy. June 2018. 2 3

  9. Mooney, J., Johnson, B. "HVdc Transmission and Integration into an AC Grid". Protection, Automation & Control World. September 2016.

  10. Union of the Electricity Industry. "Integrating intermittent renewables sources into the EU electricity system by 2020: challenges and solutions". 2010.

  11. Friedman, H., Sreedharan, P. "Wiring the Smart Grid for Energy Savings: Mechanisms and Policy Considerations". ACEEE Summer Study on Energy Efficiency in Buildings. 2010.

  12. Sandia National Laboratories. "The Advanced Microgrid: Integration and Interoperability". March 2014. 2

  13. Electric Power Research Institute. "Ancillary Services in the United States". June 2019. 2 3 4 5 6

  14. Chueh, W. "The Next Big Opportunities in Energy Storage". Stanford University, YouTube video. December 2018. 2 3 4 5 6 7

  15. Heffner, G., Goldman, C., Kirby, B., Kintner-Meyer, M. "Loads Providing Ancillary Services: Review of International Experience". Ernest Orlando Lawrence Berkeley National Laboratory, LBNL–62701, ORNL/TM-2007/060, PNNL-16618. May 2007. 2

  16. Anisie, A., Ocenic, E., Boshell, F., Kanani, H., Singla, R. "Innovative Ancillary Services: Innovation Landscape Brief". International Renewable Energy Agency, Abu Dhabi. ISBN 978-92-9260-129-4. 2019.