Jump to content

Variable renewable energy

From Wikipedia, the free encyclopedia
The 150 MW Andasol solar power station is a commercial parabolic trough solar thermal power plant, in Spain. The Andasol plant uses tanks of molten salt to store solar energy so that it can continue generating electricity even after sunset.[1]
Grids with high penetration of renewable energy sources generally need more flexible generation rather than baseload generation[2]

Variable renewable energy (VRE) or intermittent renewable energy sources (IRES) are renewable energy sources that are not dispatchable due to their fluctuating nature, such as wind power and solar power, as opposed to controllable renewable energy sources, such as dammed hydroelectricity or bioenergy, or relatively constant sources, such as geothermal power.

The use of small amounts of intermittent power has little effect on grid operations. Using larger amounts of intermittent power may require upgrades or even a redesign of the grid infrastructure.[3][4]

Options to absorb large shares of variable energy into the grid include using storage, improved interconnection between different variable sources to smooth out supply, using dispatchable energy sources such as hydroelectricity and having overcapacity, so that sufficient energy is produced even when weather is less favourable. More connections between the energy sector and the building, transport and industrial sectors may also help.[5]: 55 

Background and terminology

[edit]

The penetration of intermittent renewables in most power grids is low: global electricity generation in 2021 was 7% wind and 4% solar.[6] However, in 2021 Denmark, Luxembourg and Uruguay generated over 40% of their electricity from wind and solar.[6] Characteristics of variable renewables include their unpredictability, variability, and low operating costs.[7] These, along with renewables typically being asynchronous generators, provide a challenge to grid operators, who must make sure supply and demand are matched. Solutions include energy storage, demand response, availability of overcapacity and sector coupling.[8] Smaller isolated grids may be less tolerant to high levels of penetration.[3][9]

Matching power demand to supply is not a problem specific to intermittent power sources. Existing power grids already contain elements of uncertainty including sudden and large changes in demand and unforeseen power plant failures. Though power grids are already designed to have some capacity in excess of projected peak demand to deal with these problems, significant upgrades may be required to accommodate large amounts of intermittent power.[10]

Several key terms are useful for understanding the issue of intermittent power sources. These terms are not standardized, and variations may be used. Most of these terms also apply to traditional power plants.

  • Intermittency or variability is the extent to which a power source fluctuates. This has two aspects: a predictable variability, such as the day-night cycle, and an unpredictable part (imperfect local weather forecasting).[11] The term intermittent can be used to refer to the unpredictable part, with variable then referring to the predictable part.[12]
  • Dispatchability is the ability of a given power source to add output on demand. The concept is distinct from intermittency; dispatchability is one of several ways system operators match supply (generator's output) to system demand (technical loads).[13]
  • Penetration is the amount of electricity generated from a particular source as a percentage of annual consumption.[14]
  • Nominal power or nameplate capacity is the theoretical output registered with authorities for classifying the unit. For intermittent power sources, such as wind and solar, nameplate power is the source's output under ideal conditions, such as maximum usable wind or high sun on a clear summer day.
  • Capacity factor, average capacity factor, or load factor is the ratio of actual electrical generation over a given period of time, usually a year, to actual generation in that time period. Basically, it is the ratio between the how much electricity a plant produced and how much electricity a plant would have produced if were running at its nameplate capacity for the entire time period.
  • Firm capacity or firm power is "guaranteed by the supplier to be available at all times during a period covered by a commitment".[15]
  • Capacity credit: the amount of conventional (dispatchable) generation power that can be potentially removed from the system while keeping the reliability, usually expressed as a percentage of the nominal power.[16][example needed][clarification needed]
  • Foreseeability or predictability is how accurately the operator can anticipate the generation:[17] for example tidal power varies with the tides but is completely foreseeable because the orbit of the moon can be predicted exactly, and improved weather forecasts can make wind power more predictable.[18]

Sources

[edit]

Dammed hydroelectricity, biomass and geothermal are dispatchable as each has a store of potential energy; wind and solar without storage can be decreased (curtailed) but are not dispatchable.

Wind power

[edit]
Day ahead prediction and actual wind power

Grid operators use day ahead forecasting to determine which of the available power sources to use the next day, and weather forecasting is used to predict the likely wind power and solar power output available. Although wind power forecasts have been used operationally for decades, as of 2019 the IEA is organizing international collaboration to further improve their accuracy.[19]

Erie Shores Wind Farm monthly output over a two-year period
A wind farm in Muppandal, Tamil Nadu, India

Wind-generated power is a variable resource, and the amount of electricity produced at any given point in time by a given plant will depend on wind speeds, air density, and turbine characteristics, among other factors. If wind speed is too low then the wind turbines will not be able to make electricity, and if it is too high the turbines will have to be shut down to avoid damage. While the output from a single turbine can vary greatly and rapidly as local wind speeds vary, as more turbines are connected over larger and larger areas the average power output becomes less variable.[10]

  • Intermittence: Regions smaller than synoptic scale, less than about 1000 km long, the size of an average country, have mostly the same weather and thus around the same wind power, unless local conditions favor special winds. Some studies show that wind farms spread over a geographically diverse area will as a whole rarely stop producing power altogether.[20][21] This is rarely the case for smaller areas with uniform geography such as Ireland,[22][23][24] Scotland[25] and Denmark which have several days per year with little wind power.[26]
  • Capacity factor: Wind power typically has an annual capacity factor of 25–50%, with offshore wind outperforming onshore wind.[27]
  • Dispatchability: Because wind power is not by itself dispatchable wind farms are sometimes built with storage.[28][29]
  • Capacity credit: At low levels of penetration, the capacity credit of wind is about the same as the capacity factor. As the concentration of wind power on the grid rises, the capacity credit percentage drops.[30][31]
  • Variability: Site dependent.[32] Sea breezes are much more constant than land breezes.[10] Seasonal variability may reduce output by 50%.[33]
  • Reliability: A wind farm has high technical reliability when the wind blows. That is, the output at any given time will only vary gradually due to falling wind speeds or storms, the latter necessitating shut downs. A typical wind farm is unlikely to have to shut down in less than half an hour at the extreme, whereas an equivalent-sized power station can fail totally instantaneously and without warning. The total shutdown of wind turbines is predictable via weather forecasting. The average availability of a wind turbine is 98%, and when a turbine fails or is shut down for maintenance it only affects a small percentage of the output of a large wind farm.[34]
  • Predictability: Although wind is variable, it is also predictable in the short term. There is an 80% chance that wind output will change less than 10% in an hour and a 40% chance that it will change 10% or more in 5 hours.[35]

Because wind power is generated by large numbers of small generators, individual failures do not have large impacts on power grids. This feature of wind has been referred to as resiliency.[36]

Solar power

[edit]
Daily solar output at AT&T Park in San Francisco
Seasonal variation of the output of the solar panels at AT&T park in San Francisco

Intermittency inherently affects solar energy, as the production of renewable electricity from solar sources depends on the amount of sunlight at a given place and time. Solar output varies throughout the day and through the seasons, and is affected by dust, fog, cloud cover, frost or snow. Many of the seasonal factors are fairly predictable, and some solar thermal systems make use of heat storage to produce grid power for a full day.[37]

  • Variability: In the absence of an energy storage system, solar does not produce power at night, little in bad weather and varies between seasons. In many countries, solar produces most energy in seasons with low wind availability and vice versa.[38]
  • Capacity factor Standard photovoltaic solar has an annual average capacity factor of 10-20%,[39] but panels that move and track the sun have a capacity factor up to 30%.[40] Thermal solar parabolic trough with storage 56%.[41] Thermal solar power tower with storage 73%.[41]
Dish Stirling

The impact of intermittency of solar-generated electricity will depend on the correlation of generation with demand. For example, solar thermal power plants such as Nevada Solar One are somewhat matched to summer peak loads in areas with significant cooling demands, such as the south-western United States. Thermal energy storage systems like the small Spanish Gemasolar Thermosolar Plant can improve the match between solar supply and local consumption. The improved capacity factor using thermal storage represents a decrease in maximum capacity, and extends the total time the system generates power.[42][43][44]

Run-of-the-river hydroelectricity

[edit]

In many countries new large dams are no longer being built, because of the environmental impact of reservoirs. Run of the river projects have continued to be built.[45] The absence of a reservoir results in both seasonal and annual variations in electricity generated.

Tidal power

[edit]
Types of tide

Tidal power is the most predictable of all the variable renewable energy sources. The tides reverse twice a day, but they are never intermittent, on the contrary they are completely reliable.[46]

Wave power

[edit]

Waves are primarily created by wind, so the power available from waves tends to follow that available from wind, but due to the mass of the water is less variable than wind power. Wind power is proportional to the cube of the wind speed, while wave power is proportional to the square of the wave height.[47][48][49]

Solutions for their integration

[edit]
Energy from sunlight or other renewable energy is converted to potential energy for storage in devices such as electric batteries. The stored potential energy is later converted to electricity that is added to the power grid, even when the original energy source is not available.

The displaced dispatchable generation could be coal, natural gas, biomass, nuclear, geothermal or storage hydro.[citation needed][clarification needed] Rather than starting and stopping nuclear or geothermal, it is cheaper to use them as constant base load power. Any power generated in excess of demand can displace heating fuels, be converted to storage or sold to another grid. Biofuels and conventional hydro can be saved for later when intermittents are not generating power. Some forecast that “near-firm” renewables (batteries with solar and/or wind) power will be cheaper than existing nuclear by the late 2020s: therefore they say base load power will not be needed.[50]

Alternatives to burning coal and natural gas which produce fewer greenhouse gases may eventually make fossil fuels a stranded asset that is left in the ground. Highly integrated grids favor flexibility and performance over cost, resulting in more plants that operate for fewer hours and lower capacity factors.[51]

All sources of electrical power have some degree of variability, as do demand patterns which routinely drive large swings in the amount of electricity that suppliers feed into the grid. Wherever possible, grid operations procedure are designed to match supply with demand at high levels of reliability, and the tools to influence supply and demand are well-developed. The introduction of large amounts of highly variable power generation may require changes to existing procedures and additional investments.

The capacity of a reliable renewable power supply, can be fulfilled by the use of backup or extra infrastructure and technology, using mixed renewables to produce electricity above the intermittent average, which may be used to meet regular and unanticipated supply demands.[52] Additionally, the storage of energy to fill the shortfall intermittency or for emergencies can be part of a reliable power supply.

In practice, as the power output from wind varies, partially loaded conventional plants, which are already present to provide response and reserve, adjust their output to compensate. While low penetrations of intermittent power may use existing levels of response and spinning reserve, the larger overall variations at higher penetrations levels will require additional reserves or other means of compensation.

Operational reserve

[edit]

All managed grids already have existing operational and "spinning" reserve to compensate for existing uncertainties in the power grid. The addition of intermittent resources such as wind does not require 100% "back-up" because operating reserves and balancing requirements are calculated on a system-wide basis, and not dedicated to a specific generating plant.

Some gas, or hydro power plants are partially loaded and then controlled to change as demand changes or to replace rapidly lost generation. The ability to change as demand changes is termed "response". The ability to quickly replace lost generation, typically within timescales of 30 seconds to 30 minutes, is termed "spinning reserve".

Generally thermal plants running as peaking plants will be less efficient than if they were running as base load. Hydroelectric facilities with storage capacity, such as the traditional dam configuration, may be operated as base load or peaking plants.

Grids can contract for grid battery plants, which provide immediately available power for an hour or so, which gives time for other generators to be started up in the event of a failure, and greatly reduces the amount of spinning reserve required.[53][54]

Demand response

[edit]

Demand response is a change in consumption of energy to better align with supply. It can take the form of switching off loads, or absorb additional energy to correct supply/demand imbalances. Incentives have been widely created in the American, British and French systems for the use of these systems, such as favorable rates or capital cost assistance, encouraging consumers with large loads to take them offline whenever there is a shortage of capacity, or conversely to increase load when there is a surplus.

Certain types of load control allow the power company to turn loads off remotely if insufficient power is available. In France large users such as CERN cut power usage as required by the System Operator - EDF under the encouragement of the EJP tariff.[55][56]

Energy demand management refers to incentives to adjust use of electricity, such as higher rates during peak hours. Real-time variable electricity pricing can encourage users to adjust usage to take advantage of periods when power is cheaply available and avoid periods when it is more scarce and expensive.[57] Some loads such as desalination plants, electric boilers and industrial refrigeration units, are able to store their output (water and heat). Several papers also concluded that Bitcoin mining loads would reduce curtailment, hedge electricity price risk, stabilize the grid, increase the profitability of renewable energy power stations and therefore accelerate transition to sustainable energy.[58][59][60][61][62][63][64][65] But others argue that Bitcoin mining can never be sustainable.[66]

Instantaneous demand reduction. Most large systems also have a category of loads which instantly disconnect when there is a generation shortage, under some mutually beneficial contract. This can give instant load reductions or increases.

Storage

[edit]
Construction of the Salt Tanks which provide efficient thermal energy storage[67] so that output can be provided after the sun goes down, and output can be scheduled to meet demand requirements.[68] The 280 MW Solana Generating Station is designed to provide six hours of energy storage. This allows the plant to generate about 38 percent of its rated capacity over the course of a year.[69]
Learning curve of lithium-ion batteries: the price of batteries declined by 97% in three decades.

At times of low load where non-dispatchable output from wind and solar may be high, grid stability requires lowering the output of various dispatchable generating sources or even increasing controllable loads, possibly by using energy storage to time-shift output to times of higher demand. Such mechanisms can include:

Pumped storage hydropower is the most prevalent existing technology used, and can substantially improve the economics of wind power. The availability of hydropower sites suitable for storage will vary from grid to grid. Typical round trip efficiency is 80%.[10][70]

Traditional lithium-ion is the most common type used for grid-scale battery storage as of 2020.[71] Rechargeable flow batteries can serve as a large capacity, rapid-response storage medium.[13] Hydrogen can be created through electrolysis and stored for later use.[72]

Flywheel energy storage systems have some advantages over chemical batteries. Along with substantial durability which allows them to be cycled frequently without noticeable life reduction, they also have very fast response and ramp rates. They can go from full discharge to full charge within a few seconds.[73] They can be manufactured using non-toxic and environmentally friendly materials, easily recyclable once the service life is over.[74]

Thermal energy storage stores heat. Stored heat can be used directly for heating needs or converted into electricity. In the context of a CHP plant a heat storage can serve as a functional electricity storage at comparably low costs. Ice storage air conditioning Ice can be stored inter seasonally and can be used as a source of air-conditioning during periods of high demand. Present systems only need to store ice for a few hours but are well developed.

Storage of electrical energy results in some lost energy because storage and retrieval are not perfectly efficient. Storage also requires capital investment and space for storage facilities.

Geographic diversity and complementing technologies

[edit]
Five days of hourly output of five wind farms in Ontario

The variability of production from a single wind turbine can be high. Combining any additional number of turbines, for example, in a wind farm, results in lower statistical variation, as long as the correlation between the output of each turbine is imperfect, and the correlations are always imperfect due to the distance between each turbine. Similarly, geographically distant wind turbines or wind farms have lower correlations, reducing overall variability. Since wind power is dependent on weather systems, there is a limit to the benefit of this geographic diversity for any power system.[75]

Multiple wind farms spread over a wide geographic area and gridded together produce power more constantly and with less variability than smaller installations. Wind output can be predicted with some degree of confidence using weather forecasts, especially from large numbers of turbines/farms. The ability to predict wind output is expected to increase over time as data is collected, especially from newer facilities.[75]

Electricity produced from solar energy tends to counterbalance the fluctuating supplies generated from wind. Normally it is windiest at night and during cloudy or stormy weather, and there is more sunshine on clear days with less wind.[76] Besides, wind energy has often a peak in the winter season, whereas solar energy has a peak in the summer season; the combination of wind and solar reduces the need for dispatchable backup power.[77]

  • In some locations, electricity demand may have a high correlation with wind output, [citation needed]particularly in locations where cold temperatures drive electric consumption, as cold air is denser and carries more energy.
  • The allowable penetration may be increased with further investment in standby generation. For instance some days could produce 80% intermittent wind and on the many windless days substitute 80% dispatchable power like natural gas, biomass and Hydro.
  • Areas with existing high levels of hydroelectric generation may ramp up or down to incorporate substantial amounts of wind. Norway, Brazil, and Manitoba all have high levels of hydroelectric generation, Quebec produces over 90% of its electricity from hydropower, and Hydro-Québec is the largest hydropower producer in the world. The U.S. Pacific Northwest has been identified as another region where wind energy is complemented well by existing hydropower.[78] Storage capacity in hydropower facilities will be limited by size of reservoir, and environmental and other considerations.

Connecting grid internationally

[edit]

It is often feasible to export energy to neighboring grids at times of surplus, and import energy when needed. This practice is common in Europe[79] and between the US and Canada.[80] Integration with other grids can lower the effective concentration of variable power: for instance, Denmark's high penetration of VRE, in the context of the German/Dutch/Scandinavian grids with which it has interconnections, is considerably lower as a proportion of the total system. Hydroelectricity that compensates for variability can be used across countries.[81]

The capacity of power transmission infrastructure may have to be substantially upgraded to support export/import plans. Some energy is lost in transmission. The economic value of exporting variable power depends in part on the ability of the exporting grid to provide the importing grid with useful power at useful times for an attractive price.

Sector coupling

[edit]

Demand and generation can be better matched when sectors such as mobility, heat and gas are coupled with the power system. The electric vehicle market is for instance expected to become the largest source of storage capacity. This may be a more expensive option appropriate for high penetration of variable renewables, compared to other sources of flexibility.[82] The International Energy Agency says that sector coupling is needed to compensate for the mismatch between seasonal demand and supply.[83]

Electric vehicles can be charged during periods of low demand and high production, and in some places send power back from the vehicle-to-grid.[84][85]

Penetration

[edit]

Penetration refers to the proportion of a primary energy (PE) source in an electric power system, expressed as a percentage.[14] There are several methods of calculation yielding different penetrations. The penetration can be calculated either as:[86]

  1. the nominal capacity (installed power) of a PE source divided by the peak load within an electric power system; or
  2. the nominal capacity (installed power) of a PE source divided by the total capacity of the electric power system; or
  3. the electrical energy generated by a PE source in a given period, divided by the demand of the electric power system in this period.

The level of penetration of intermittent variable sources is significant for the following reasons:

  • Power grids with significant amounts of dispatchable pumped storage, hydropower with reservoir or pondage or other peaking power plants such as natural gas-fired power plants are capable of accommodating fluctuations from intermittent power more easily.[87]
  • Relatively small electric power systems without strong interconnection (such as remote islands) may retain some existing diesel generators but consuming less fuel,[88] for flexibility[89] until cleaner energy sources or storage such as pumped hydro or batteries become cost-effective.[90]

In the early 2020s wind and solar produce 10% of the world's electricity,[91] but supply in the 40-55% penetration range has already been implemented in several systems,[6] with over 65% planned for the UK by 2030.[92][93]

There is no generally accepted maximum level of penetration, as each system's capacity to compensate for intermittency differs, and the systems themselves will change over time. Discussion of acceptable or unacceptable penetration figures should be treated and used with caution, as the relevance or significance will be highly dependent on local factors, grid structure and management, and existing generation capacity.

For most systems worldwide, existing penetration levels are significantly lower than practical or theoretical maximums.[86]

Maximum penetration limits

[edit]

Maximum penetration of combined wind and solar is estimated at around 70% to 90% without regional aggregation, demand management or storage; and up to 94% with 12 hours of storage.[94] Economic efficiency and cost considerations are more likely to dominate as critical factors; technical solutions may allow higher penetration levels to be considered in future, particularly if cost considerations are secondary.

Economic impacts of variability

[edit]

Estimates of the cost of wind and solar energy may include estimates of the "external" costs of wind and solar variability, or be limited to the cost of production. All electrical plant has costs that are separate from the cost of production, including, for example, the cost of any necessary transmission capacity or reserve capacity in case of loss of generating capacity. Many types of generation, particularly fossil fuel derived, will have cost externalities such as pollution, greenhouse gas emission, and habitat destruction, which are generally not directly accounted for.

The magnitude of the economic impacts is debated and will vary by location, but is expected to rise with higher penetration levels. At low penetration levels, costs such as operating reserve and balancing costs are believed to be insignificant.

Intermittency may introduce additional costs that are distinct from or of a different magnitude than for traditional generation types. These may include:

  • Transmission capacity: transmission capacity may be more expensive than for nuclear and coal generating capacity due to lower load factors. Transmission capacity will generally be sized to projected peak output, but average capacity for wind will be significantly lower, raising cost per unit of energy actually transmitted. However transmission costs are a low fraction of total energy costs.[95]
  • Additional operating reserve: if additional wind and solar does not correspond to demand patterns, additional operating reserve may be required compared to other generating types, however this does not result in higher capital costs for additional plants since this is merely existing plants running at low output - spinning reserve. Contrary to statements that all wind must be backed by an equal amount of "back-up capacity", intermittent generators contribute to base capacity "as long as there is some probability of output during peak periods". Back-up capacity is not attributed to individual generators, as back-up or operating reserve "only have meaning at the system level".[96]
  • Balancing costs: to maintain grid stability, some additional costs may be incurred for balancing of load with demand. Although improvements to grid balancing can be costly, they can lead to long term savings.[97][98][99][100]

In many countries for many types of variable renewable energy, from time to time the government invites companies to tender sealed bids to construct a certain capacity of solar power to connect to certain electricity substations. By accepting the lowest bid the government commits to buy at that price per kWh for a fixed number of years, or up to a certain total amount of power. This provides certainty for investors against highly volatile wholesale electricity prices.[101][102][103] However they may still risk exchange rate volatility if they borrowed in foreign currency.[104]

Examples by country

[edit]

Great Britain

[edit]

The operator of the British electricity system has said that it will be capable of operating zero-carbon by 2025, whenever there is enough renewable generation, and may be carbon negative by 2033.[105] The company, National Grid Electricity System Operator, states that new products and services will help reduce the overall cost of operating the system.[106]

Germany

[edit]

In countries with a considerable amount of renewable energy, solar energy causes price drops around noon every day. PV production follows the higher demand during these hours. The images below show two weeks in 2022 in Germany, where renewable energy has a share of over 40%.[107] Prices also drop every night and weekend due to low demand. In hours without PV and wind power, electricity prices rise. This can lead to demand side adjustments. While industry is dependent on the hourly prices, most private households still pay a fixed tariff. With smart meters, private consomers can also be motivated i.e. to load an electric car when enough renewable energy is available and prices are cheap.

Steerable flexibility in electricity production is essential to back up variable energy sources. The German example shows that pumped hydro storage, gas plants and hard coal jump in fast. Lignite varies on a daily basis. Nuclear power and biomass can theoretically adjust to a certain extent. However, in this case incentives still seem not be high enough.

Renewable and conventional energy production in Germany over two weeks in 2022. In hours with low wind and PV production, hard coal and gas fill the gap. Nuclear and biomass show almost no flexibility. PV follows the increased consumption during daytime hours but varies seasonally.
Electricity market in Germany over two weeks in 2022. With the integration of solar PV, prices drop around noon every day in spite of a higher demand. Prices also drop every night and weekend due to low demand. A high availability of wind power causes the low prices on the right half. In hours without PV and wind power, the most expensive substitute set the price. The extreme levels for natural gas in 2022 were caused by Russian's invasion in Ukraine. The low availability of French nuclear power during these months increased the demand for exports.

See also

[edit]

References

[edit]
  1. ^ Cartlidge, Edwin (2011-11-18). "Saving for a Rainy Day". Science. 334 (6058): 922–924. Bibcode:2011Sci...334..922C. doi:10.1126/science.334.6058.922. ISSN 0036-8075. PMID 22096185.
  2. ^ "Flexible Power Plant Operation to Enable High Renewable Energy Penetration". IESR. 2022-06-15. Retrieved 2022-11-21.
  3. ^ a b "All Island Grid Study" (PDF). Department of Communications, Energy and Natural Resources. January 2008. pp. 3–5, 15. Archived from the original (PDF) on 2009-03-18. Retrieved 2008-10-15.
  4. ^ "The Carbon Trust & DTI Renewables Network Impacts Study" (PDF). Carbon Trust and UK Department of Trade and Industry. January 2004 [commissioned June 2003]. Archived from the original (PDF) on 2010-09-19. Retrieved 2009-04-22.
  5. ^ IPCC: Climate Change 2022, Mitigation of Climate Change, Summary for Policymakers (PDF). ipecac.ch (Report). Intergovernmental Panel on Climate Change. 4 April 2022. Archived from the original (PDF) on 2022-08-07. Retrieved 2004-04-22.
  6. ^ a b c "Global Electricity Review 2022". Ember. 2022-03-29. Retrieved 2022-03-31.
  7. ^ Riesz, Jenny; Milligan, Michael (May 2015). "Designing electricity markets for a high penetration of variable renewables". WIREs Energy and Environment. 4 (3): 279–289. Bibcode:2015WIREE...4..279R. doi:10.1002/wene.137. ISSN 2041-8396. S2CID 167079952.
  8. ^ Sinsel, Simon R.; Riemke, Rhea L.; Hoffmann, Volker H. (2020-01-01). "Challenges and solution technologies for the integration of variable renewable energy sources—a review". Renewable Energy. 145: 2271–2285. Bibcode:2020REne..145.2271S. doi:10.1016/j.renene.2019.06.147. hdl:20.500.11850/373407. ISSN 0960-1481. S2CID 198480155.
  9. ^ Czisch, Gregor; Gregor Giebel. "Realisable Scenarios for a Future Electricity Supply based 100% on Renewable Energies" (PDF). Institute for Electrical Engineering – Efficient Energy Conversion University of Kassel, Germany and Risø National Laboratory, Technical University of Denmark. Archived from the original (PDF) on 2014-07-01. Retrieved 2008-10-15.
  10. ^ a b c d "Variability of Wind Power and other Renewables: Management Options and Strategies" (PDF). IEA. 2005. Retrieved 2008-10-15.
  11. ^ Widén, Joakim; Carpman, Nicole (1 April 2015). "Variability assessment and forecasting of renewables: A review for solar, wind, wave and tidal resources". Renewable and Sustainable Energy Reviews. 44: 356–375. Bibcode:2015RSERv..44..356W. doi:10.1016/j.rser.2014.12.019. ISSN 1364-0321.
  12. ^ Pommeret, Aude; Schubert, Katheline (2019). "Energy Transition with Variable and Intermittent Renewable Electricity Generation". Cesifo Working Paper Series. CESifo Working Paper. 7442: 2.
  13. ^ a b Kuntz, Mark T.; Justin Dawe (2005). "renewable. rechargeable. remarkable". VRB Power Systems. Mechanical Engineering. Archived from the original on 2009-01-15. Retrieved 2008-10-20.
  14. ^ a b International Energy Agency Wind Task Force, "Design and Operation of Power Systems with Large Amounts of Wind Power" Archived 2007-10-25 at the Wayback Machine Oklahoma Conference Presentation, October 2006
  15. ^ "firm power". www.ecowho.com. Retrieved 2021-02-10.
  16. ^ Giebel, Gregor. "Wind Powers Has a Capacity Credit" (PDF). Risø National Laboratory. Archived from the original (PDF) on 2009-03-18. Retrieved 2008-10-16.
  17. ^ Suchet, Daniel; Jeantet, Adrien; Elghozi, Thomas; Jehl, Zacharie (2020). "Defining and Quantifying Intermittency in the Power Sector". Energies. 13 (13): 3366. doi:10.3390/en13133366.
  18. ^ "Volatile but predictable: Forecasting renewable power generation". Clean Energy Wire. 2016-08-15. Retrieved 2021-02-10.
  19. ^ "IEA wind task 36". iea wind forecasting. Retrieved 2019-07-25.
  20. ^ "The power of multiples: Connecting wind farms can make a more reliable and cheaper power source". 2007-11-21.
  21. ^ Archer, C. L.; Jacobson, M. Z. (2007). "Supplying Baseload Power and Reducing Transmission Requirements by Interconnecting Wind Farms" (PDF). Journal of Applied Meteorology and Climatology. 46 (11): 1701–1717. Bibcode:2007JApMC..46.1701A. CiteSeerX 10.1.1.475.4620. doi:10.1175/2007JAMC1538.1.
  22. ^ David JC MacKay. "Sustainable Energy - without the hot air. Fluctuations and storage".
  23. ^ Andrzej Strupczewski. "Czy w Polsce wiatr wystarczy zamiast elektrowni atomowych?" [Can the wind suffice instead of nuclear power in Poland?] (in Polish). atom.edu.pl. Archived from the original on 2011-09-04. Retrieved 2009-11-26.
  24. ^ Diesendorf, Mark (August 2007). "The Base-Load Fallacy" (PDF). Institute of Environmental Studies. www.energyscience.org.au. Archived from the original (PDF) on 2008-07-08. Retrieved 2008-10-18.
  25. ^ "Analysis of UK Wind Generation" 2011
  26. ^ Sharman, Hugh (May 2005). "Why wind power works for Denmark". Proceedings of the Institution of Civil Engineers - Civil Engineering. 158 (2): 66–72. doi:10.1680/cien.2005.158.2.66.
  27. ^ "Average annual capacity factors by technology, 2018 – Charts – Data & Statistics". IEA. Retrieved 2021-02-10.
  28. ^ "How Dispatchable Wind Is Becoming a Reality in the US". www.greentechmedia.com. Retrieved 2020-08-10.
  29. ^ "51MWh vanadium flow battery system ordered for wind farm in northern Japan". Energy Storage News. 20 July 2020. Retrieved 2020-08-10.
  30. ^ "Blowing Away the Myths" (PDF). The British Wind Energy Association. February 2005. Archived from the original (PDF) on 2007-07-10. Retrieved 2008-10-16.
  31. ^ Nedic, Dusko; Anser Shakoor; Goran Strbac; Mary Black; Jim Watson; Catherine Mitchell (July 2005). "Security assessment of future UK electricity scenarios" (PDF). Tyndall Centre for Climate Change Research. Archived from the original (PDF) on January 11, 2007. Retrieved 2008-10-20.
  32. ^ Junling Huang; Xi Lu; Michael B. McElroy (2014). "Meteorologically defined limits to reduction in the variability of outputs from a coupled wind farm system in the Central US" (PDF). Renewable Energy. 62: 331–340. Bibcode:2014REne...62..331H. doi:10.1016/j.renene.2013.07.022. S2CID 3527948.
  33. ^ [1] Graham Sinden (1 December 2005). "Characteristics of the UK wind resource" pg4
  34. ^ Reliability of Wind Turbines[permanent dead link] [dead link]
  35. ^ "Wind Systems Integration Basics". Archived from the original on 7 June 2012.
  36. ^ "renewable is doable A Smarter Energy Plan for Ontario (brochure version)" (PDF). PEMBINA Institute. August 2007. Archived from the original (PDF) on 2008-08-27. Retrieved 2008-10-17.
  37. ^ Gemasolar, energía non stop Archived 2013-02-06 at the Wayback Machine Spanish 26 October 2011
  38. ^ Jurasz, J.; Canales, F.A.; Kies, A.; Guezgouz, M.; Beluco, A. (2020-01-01). "A review on the complementarity of renewable energy sources: Concept, metrics, application and future research directions". Solar Energy. 195: 703–724. arXiv:1904.01667. Bibcode:2020SoEn..195..703J. doi:10.1016/j.solener.2019.11.087. ISSN 0038-092X.
  39. ^ "Average annual capacity factors by technology, 2018 – Charts – Data & Statistics". IEA. Retrieved 2021-02-10.
  40. ^ World Energy Perspective (PDF) (Report). World Energy Council. 2013. p. 21.
  41. ^ a b "Executive Summary: Assessment of Parabolic Trough and Power Tower Solar Technology Cost and Performance Forecasts" (PDF). National Renewable Energy Laboratory. October 2003. Retrieved 2016-11-07.
  42. ^ Spain Pioneers Grid-Connected Solar-Tower Thermal Power p. 3. Retrieved December 19, 2008.
  43. ^ Mills, David; Robert G. Morgan (July 2008). "A solar-powered economy: How solar thermal can replace coal, gas and oil". RenewableEnergyWorld.com. Retrieved 2008-10-17.
  44. ^ "Solar Air Cooling". Integration of Renewable energy on Farms. March 2008. Archived from the original on 2011-07-06. Retrieved 2008-10-17.
  45. ^ "Project Description – Keeyask Hydropower Limited Partnership". 10 February 2011.
  46. ^ "Energy Resources: Tidal power". www.darvill.clara.net. Retrieved 2022-03-31.
  47. ^ "Wind and Waves". Archived from the original on 2012-09-13. Retrieved 2012-06-04.
  48. ^ "Comparing the Variability of Wind Speed and Wave Height Data" (PDF). Archived from the original (PDF) on 2012-06-17. Retrieved 2012-06-04.
  49. ^ "Savenkov, M 2009 'On the Truncated Weibull Distribution and its Usefulness in Evaluating the Theoretical Capacity Factor of Potential Wind (or Wave) Energy Sites', University Journal of Engineering and Technology, vol. 1, no. 1, pp. 21-25" (PDF). Archived from the original (PDF) on 2015-02-22. Retrieved 2014-11-30.
  50. ^ Harvey, George (2022-06-28). "We Don't Need Base Load Power". CleanTechnica. Retrieved 2022-11-21.
  51. ^ Michael G. Richard: Death by 'capacity factor': Is this how wind and solar ultimately win the game?, 2015-10-06
  52. ^ "Solar and Energy Storage: A Perfect Match - Energy Storage to the Test". RenewableEnergyWorld.com. Retrieved 2011-03-08.
  53. ^ "UK battery storage capacity could reach 70% growth in 2019 as business models evolve". Solar Power Portal. 13 June 2019.
  54. ^ "UK battery storage market reaches 1GW landmark as new applications continues to grow". Solar Power Portal. 2 April 2020.
  55. ^ Andrews, Dave (May 24, 2009). "How CERN is encouraged to not do atom or quark smashing, during periods of high demand and low power station availablity [sic], by means of the EJP tarrif". - Extract from CERN newsletter indication when to switch of loads bulletin 46 Archived 2008-04-04 at the Wayback Machine
  56. ^ http://www.claverton-energy.com/download/42/ description of EJP tariff Archived December 8, 2008, at the Wayback Machine
  57. ^ "2005 Integrated Energy Policy Report". California Energy Commission. November 21, 2005. Archived from the original on 2019-06-01. Retrieved 2006-04-21.
  58. ^ Fridgen, Gilbert; Körner, Marc-Fabian; Walters, Steffen; Weibelzahl, Martin (2021-03-09). "Not All Doom and Gloom: How Energy-Intensive and Temporally Flexible Data Center Applications May Actually Promote Renewable Energy Sources". Business & Information Systems Engineering. 63 (3): 243–256. doi:10.1007/s12599-021-00686-z. hdl:10419/287421. ISSN 2363-7005. S2CID 233664180. To gain applicable knowledge, this paper evaluates the developed model by means of two use-cases with real-world data, namely AWS computing instances for training Machine Learning algorithms and Bitcoin mining as relevant DC applications. The results illustrate that for both cases the NPV of the IES compared to a stand-alone RES-plant increases, which may lead to a promotion of RES-plants.
  59. ^ Rhodes, Joshua. "Is Bitcoin Inherently Bad For The Environment?". Forbes. Retrieved 2022-01-16. Mining and transacting cryptocurrencies, such as bitcoin, do present energy and emissions challenges, but new research shows that there are possible pathways to mitigate some of these issues if cryptocurrency miners are willing to operate in a way to compliment the deployment of more low-carbon energy.
  60. ^ "Green Bitcoin Does Not Have to Be an Oxymoron". news.bloomberglaw.com. Retrieved 2022-01-16. One way to invest in Bitcoin that has a positive effect on renewable energy is to encourage mining operations near wind or solar sites. This provides a customer for power that might otherwise need to be transmitted or stored, saving money as well as carbon.
  61. ^ Moffit, Tim (2021-06-01). "Beyond Boom and Bust: An emerging clean energy economy in Wyoming". Currently, projects are under development, but the issue of overgenerated wind continues to exist. By harnessing the overgenerated wind for Bitcoin mining, Wyoming has the opportunity to redistribute the global hashrate, incentivize Bitcoin miners to move their operations to Wyoming, and stimulate job growth as a result. {{cite journal}}: Cite journal requires |journal= (help)
  62. ^ Rennie, Ellie (2021-11-07). "Climate change and the legitimacy of Bitcoin". Rochester, NY. doi:10.2139/ssrn.3961105. S2CID 244155800. SSRN 3961105. In responding to these pressures and events, some miners are providing services and innovations that may help the viability of clean energy infrastructures for energy providers and beyond, including the data and computing industry. The paper finds that if Bitcoin loses legitimacy as a store of value, then it may result in lost opportunities to accelerate sustainable energy infrastructures and markets. {{cite journal}}: Cite journal requires |journal= (help)
  63. ^ Eid, Bilal; Islam, Md Rabiul; Shah, Rakibuzzaman; Nahid, Abdullah-Al; Kouzani, Abbas Z.; Mahmud, M. A. Parvez (2021-11-01). "Enhanced Profitability of Photovoltaic Plants By Utilizing Cryptocurrency-Based Mining Load". IEEE Transactions on Applied Superconductivity. 31 (8): 1–5. Bibcode:2021ITAS...3196503E. doi:10.1109/TASC.2021.3096503. hdl:20.500.11782/2513. ISSN 1558-2515. S2CID 237245955. The grid connected photovoltaic (PV) power plants (PVPPs) are booming nowadays. The main problem facing the PV power plants deployment is the intermittency which leads to instability of the grid. [...] This paper investigating the usage of a customized load - cryptocurrency mining rig - to create an added value for the owner of the plant and increase the ROI of the project. [...] The developed strategy is able to keep the profitability as high as possible during the fluctuation of the mining network.
  64. ^ Bastian-Pinto, Carlos L.; Araujo, Felipe V. de S.; Brandão, Luiz E.; Gomes, Leonardo L. (2021-03-01). "Hedging renewable energy investments with Bitcoin mining". Renewable and Sustainable Energy Reviews. 138: 110520. Bibcode:2021RSERv.13810520B. doi:10.1016/j.rser.2020.110520. ISSN 1364-0321. S2CID 228861639. Windfarms can hedge electricity price risk by investing in Bitcoin mining. [...] These findings, which can also be applied to other renewable energy sources, may be of interest to both the energy generator as well as the system regulator as it creates an incentive for early investment in sustainable and renewable energy sources.
  65. ^ Shan, Rui; Sun, Yaojin (2019-08-07). "Bitcoin Mining to Reduce the Renewable Curtailment: A Case Study of Caiso". Rochester, NY. doi:10.2139/ssrn.3436872. S2CID 219382864. SSRN 3436872. The enormous energy demand from Bitcoin mining is a considerable burden to achieve the climate agenda and the energy cost is the major operation cost. On the other side, with high penetration of renewable resources, the grid makes curtailment for reliability reasons, which reduces both economic and environment benefits from renewable energy. Deploying the Bitcoin mining machines at renewable power plants can mitigate both problems. {{cite journal}}: Cite journal requires |journal= (help)
  66. ^ "Can renewable energy make crypto mining greener? | Sifted". sifted.eu. 16 June 2022. Retrieved 2022-06-27.
  67. ^ Wright, matthew; Hearps, Patrick; et al. Australian Sustainable Energy: Zero Carbon Australia Stationary Energy Plan, Energy Research Institute, University of Melbourne, October 2010, p. 33. Retrieved from BeyondZeroEmissions.org website.
  68. ^ Innovation in Concentrating Thermal Solar Power (CSP), RenewableEnergyFocus.com website.
  69. ^ Solana: 10 Facts You Didn't Know About the Concentrated Solar Power Plant Near Gila Bend
  70. ^ Benitez, Pablo C.; Lilianna E. Dragulescu; G. Cornelis Van Kooten (February 2006). "The Economics of Wind Power with Energy Storage". Resource Economics and Policy Analysis (REPA) Research Group. Department of Economics, University of Victoria. Retrieved 2008-10-20.
  71. ^ "Grid-Scale Battery Storage Frequently Asked Questions" (PDF).
  72. ^ "The global race to produce hydrogen offshore". BBC News. 2021-02-12. Retrieved 2021-02-12.
  73. ^ "Mechanical energy storage". Archived from the original on 2022-02-19. Retrieved 2022-02-19.
  74. ^ "Kinetic energy storage". Archived from the original on 2022-02-19. Retrieved 2022-02-19.
  75. ^ a b Junling Huang; Michael B. McElroy (2014). "Meteorologically defined limits to reduction in the variability of outputs from a coupled wind farm system in the Central US" (PDF). Renewable Energy. 62: 331–340. Bibcode:2014REne...62..331H. doi:10.1016/j.renene.2013.07.022. S2CID 3527948.
  76. ^ Lovins, Amory; L. Hunter Lovins (November 1983). "The Fragility of Domestic Energy" (PDF). The Atlantic. Archived from the original (PDF) on June 25, 2008. Retrieved 2008-10-20.
  77. ^ Nyenah, Emmanuel; Sterl, Sebastian; Thiery, Wim (2022). "Pieces of a puzzle: solar-wind power synergies on seasonal and diurnal timescales tend to be excellent worldwide". Environmental Research Communications. 4 (5): 055011. Bibcode:2022ERCom...4e5011N. doi:10.1088/2515-7620/ac71fb. S2CID 249227821.
  78. ^ Harden, Blaine (2007-03-21). "Air, Water Powerful Partners in Northwest". The Washington Post. ISSN 0190-8286. Retrieved 2023-08-08.
  79. ^ JUNE, WE (2022-01-27). "The European Super Grid : A solution to the EU's energy problems • Eyes on Europe". Eyes on Europe (in French). Retrieved 2022-03-31.
  80. ^ "US, Canada expand clean energy cooperation". IHS Markit. 2021-06-30. Retrieved 2022-03-31.
  81. ^ "How Norway became Europe's biggest power exporter". Power Technology. 2021-04-19. Retrieved 2022-03-31.
  82. ^ IRENA (2018). Power System Flexibility for the Energy Transition, Part 1: Overview for policy makers (PDF). Abu Dhabi: International Renewable Energy Agency. pp. 25, 42. ISBN 978-92-9260-089-1.
  83. ^ "System integration of renewables – Topics". IEA. Retrieved 2021-05-21.
  84. ^ "Is Vehicle-to-Grid Technology the Key to Accelerating the Clean Energy Revolution?". POWER Magazine. 2020-11-09. Retrieved 2021-02-12.
  85. ^ "UK city of Nottingham uses vehicle-to-grid (V2G) and IoT to optimise EV fleet charging". Traffic Technology Today. 2021-01-18. Retrieved 2021-02-12.
  86. ^ a b Gross, Robert; Heptonstall, Philip; Anderson, Dennis; Green, Tim; Leach, Matthew; Skea, Jim (March 2006). The Costs and Impacts of Intermittency (PDF). UK Energy Research Council. ISBN 978-1-903144-04-6. Archived from the original (PDF) on 2009-03-18. Retrieved 2010-07-22.
  87. ^ http://repa.econ.uvic.ca/publications/Working%20Paper%202006-02.pdf[permanent dead link]
  88. ^ Shumais, Mohamed; Mohamed, Ibrahim. "DIMENSIONS OF ENERGY INSECURITY ON SMALL ISLANDS: THE CASE OF THE MALDIVES" (PDF).
  89. ^ "Transforming small-island power systems". /publications/2019/Jan/Transforming-small-island-power-systems. 27 January 2019. Retrieved 2020-09-08.
  90. ^ "Shining a light on a smart island". MAN Energy Solutions. Retrieved 2020-09-08.
  91. ^ "Wind and solar produce record 10% of world's electricity, but faster change needed, scientists warn". www.independent.co.uk. 13 August 2020. Archived from the original on 2022-08-11. Retrieved 2020-09-08.
  92. ^ Ltd, Renews (2020-08-11). "Britain urged to hit 65% renewables by 2030". reNEWS - Renewable Energy News. Retrieved 2020-09-08.
  93. ^ "UK Looks To Triple Solar And More Than Quadruple Offshore Wind Power". OilPrice.com. Retrieved 2022-03-31.
  94. ^ Tong, Dan; Farnham, David J.; Duan, Lei; Zhang, Qiang; Lewis, Nathan S.; Caldeira, Ken; Davis, Steven J. (2021-10-22). "Geophysical constraints on the reliability of solar and wind power worldwide". Nature Communications. 12 (1): 6146. Bibcode:2021NatCo..12.6146T. doi:10.1038/s41467-021-26355-z. ISSN 2041-1723. PMC 8536784. PMID 34686663.
  95. ^ http://www.claverton-energy.com/what-is-the-cost-per-kwh-of-bulk-transmission-national-grid-in-the-uk-note-this-excludes-distribution-costs.html Electric power transmission costs per kWh transmission / National Grid in the UK (note this excludes distribution costs)
  96. ^ http://www.ukerc.ac.uk/component/option,com_docman/task,doc_download/gid,550/ Archived 2007-07-06 at the Wayback Machine The Costs and Impacts of Intermittency, UK Energy Research Council, March 2006
  97. ^ Welle (www.dw.com), Deutsche. "Will war fast-track the energy transition? | DW | 04.03.2022". DW.COM. Retrieved 2022-03-31.
  98. ^ Morse, Richard; Salvatore, Sarah; Slusarewicz, Joanna H.; Cohan, Daniel S. (2022-03-14). "Can wind and solar replace coal in Texas?". Renewables: Wind, Water, and Solar. 9 (1): 1. Bibcode:2022RWWS....9....1M. doi:10.1186/s40807-022-00069-2. ISSN 2198-994X. S2CID 247454828.
  99. ^ Vetter, David. "5 New Reports Show Wind And Solar Power Can Cripple Putin, Secure Climate Goals". Forbes. Retrieved 2022-03-31.
  100. ^ "Accelerating Grid Integration". www.usaid.gov. 2022-02-17. Retrieved 2022-03-31. Grid modernization reduces medium- to long-term curtailment, stagnation of large-scale renewable energy deployment, reduces long-term costs, and enables new business models, such as electric vehicles (EVs), aggregation, demand-side management, and distributed energy resources. It also promotes regional market coordination and power system integration which can unlock billions of dollars in electricity revenue through cross-border trade.
  101. ^ ES, Tetra Tech; order, Inc under USAID’s Scaling Up Renewable Energy task (2021-07-28). "Renewable Energy Auctions Toolkit | Energy | U.S. Agency for International Development". www.usaid.gov. Retrieved 2022-05-19.
  102. ^ "Feed-In Tariffs vs Reverse Auctions: Setting the Right Subsidy Rates for Solar". Development Asia. 2021-11-10. Retrieved 2022-05-19.
  103. ^ "Government hits accelerator on low-cost renewable power". GOV.UK. Retrieved 2022-05-19.
  104. ^ "Currency Risk Is the Hidden Solar Project Deal Breaker". www.greentechmedia.com. Retrieved 2022-05-19.
  105. ^ Ambrose, Jillian (2020-07-27). "UK electricity grid's carbon emissions could turn negative by 2033, says National Grid". The Guardian. ISSN 0261-3077. Retrieved 2020-11-03.
  106. ^ "Zero carbon operation of Great Britain's electricity system by 2025 | National Grid ESO". www.nationalgrideso.com. Retrieved 2019-07-09.
  107. ^ "Renewable energies in figures". Umweltbundesamt (German environmental agency). 11 June 2013. Retrieved 25 October 2022.

Further reading

[edit]
  • Sivaram, Varun (2018). Taming the Sun: Innovation to Harness Solar Energy and Power the Planet. Cambridge, MA: MIT Press. ISBN 978-0-262-03768-6.
[edit]