Abstract
As more variable renewable energy (VRE) such as wind and solar are integrated into electric power systems, technical challenges arise from the need to maintain the balance between load and generation at all timescales. This paper examines the challenges with integrating ultra-high levels of VRE into electric power system, reviews a range of solutions to these challenges, and provides a description of several examples of ultra-high VRE systems that are in operation today.
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1 Introduction
Over the last 100 years, electric power systems have developed in a way where dispatchable generation is used to provide electricity when customer loads demanded it. The primary energy sources used in disptachable generation includes generation from coal, nuclear, hydropower, diesel, and natural gas plants. These sources are able to store some amount of the primary energy source on site and then generate electricity to meet demand needs. One key feature of these conventional sources is the use of synchronous generators as the point of connection to the electrical power system. A synchronous generator is used to develop a 50 or 60 Hz alternating current (AC) waveform of electricity. AC was chosen over a century ago as a preferred method of producing and moving electricity mostly because of the ability to transmit AC power over long distances at very high voltage and relatively low current levels. This was the most economic transmission method because of the minimization of conductor size and because the transmission losses are proportional to the square of the current. This characteristic enabled large-scale central station power plants to be built far from load centers and the electricity was transferred via high voltage AC transmission lines. Innovations in the design and use of AC power grids have allowed them to become the dominant system design for power grids around the world.
During the last 30 years, there has been significant increase in the use of wind and solar power generation. These technologies offer a free fuel source but are variable in nature and only produce power when there are solar or wind resources. Therefore, we call them variable renewable energy (VRE). Wind and solar photovoltaic (PV) do not naturally have on-site energy storage, so their output is typically referred to as non-dispatchable. Other characteristics that make VRE integration a challenge are the uncertainty associated with their output and asynchronous nature of interconnection to the grid. As costs for wind and solar continue to decrease and regulations require the use of more clean energy technologies, there is a need to understand the technical challenges and develop solutions to integrate ultra-high levels of VRE into electrical power systems. This paper defines ultra-high levels as VRE penetrations over 50% on an annual energy basis across a synchronous power system and up to 100% on an instantaneous basis. The annual penetration level is an average of the amount of energy the VRE produce (Wh) divided by the total amount of energy (Wh) needed for an entire year. Instantaneous penetration refers to the VRE power output (W) divided by the total power requirement (W) at any point in time. Instantaneous penetration can vary considerably during the course of a day depending on the available renewable resources and the electricity load.
One of the unique features of PV and wind turbines is that they are typically designed using a power electronic interface to the grid called an inverter instead of a synchronous generator. This is because a PV system naturally produces DC electricity and most new wind turbine designs use some type of power electronics to convert the non-synchronous rotation of wind turbines into AC waveforms compatible with the power grid. The inverter converts direct current (DC) electricity to grid compatible AC power. Discussion on the design of inverters for renewable and distributed energy applications can be found in the references [1,2,3,4].
The development of advanced inverter technologies over the last thirty years has allowed both PV and wind technologies to be easily integrated into AC electrical grids, however they do have different characteristics from synchronous generators and therefore have unique challenges with this integration [5]. One difference is the inherent inertia that a large rotating mass from a synchronous generator can provide. This rotating inertia helps synchronous generators ride through voltage and frequency deviations in the grid caused by abnormal operations such as a fault. As more synchronous generators in a power system are replaced by inverter based VRE, the inverters will need to be able to provide “synthetic” inertia that mimics the characteristics of synchronous generators. Current power electronics can be designed to provide this as well as a large array of ancillary services that are needed to support reliable grid operations [6,7,8].
2 Power system operations
With all AC power systems the main technical challenge is to maintain proper voltage and frequency at all timescales and deliver electrical power to loads. This ensures stable and reliable operation. The power system must also be able to maintain safe operations within a number of physical limits including voltage and current levels. Figure 1 from [9] shows a generic daily load curve for a power system, with system load (MW) increasing during the middle of the day and lowering at night. At all time periods during this day, the demand must be satisfied with power from generation or storage.
2.1 Regulation
The fast response to disturbances or load changes is called regulation because you are regulating the frequency of the AC power system. This is done continuously throughout the day and focuses on the fast timescales from instantaneous to minutes. To maintain proper frequency in an AC power system, generators need to be able to respond instantaneously to events that require more or less power (load changes). This is referred to as the primary frequency response or inertial response. The physical characteristics of the generator dictate how fast a synchronous generator can respond during an abnormal event and if it can return to a steady-state frequency. Secondary response from generators is then used to correct the frequency to its pre-event levels. In large systems, the use of automatic generator controls (AGC) brings a signal to the generators in a system to correct the frequency back to nominal value [10]. A tertiary response may be needed to protect the system against possible subsequent events when both primary and secondary responses have been depleted. The main challenge with this area is that since power electronic based inverters do not have any physical rotating mass, they can impact the overall inertial response of a synchronous power system. New studies have shown that both wind and solar can provide these fast regulation services and in some cases can respond faster than synchronous generators [6,7,8, 11].
2.2 Load following
Load following in a power system occurs throughout the day and happens on the order of minutes to hours. To follow the natural increase or decrease in demand over hours, the power from generation is slowly increased or decreased (or new generation is brought on/off line) to meet the load. This service is usually provided by generation with relatively fast ramping capabilities or the ability to turn on/off in tens of minutes. Since VRE produce power when renewable resources are available, they are not typically designed to follow load unless paired with some type of energy storage. When adding ultra-high levels of VRE into power systems, special attention must be paid to the overall net load after VRE is accounted for. In some cases, the new ramping requirements may be considerable different that the original system requirements [12].
2.3 Scheduling
Scheduling in a power system is the planning for generation to meet the daily energy and peak power requirements. This often involves forecasting the demand for the day and scheduling what generation will meet that demand at a coarse level with adequate reserve margins. Since scheduling is intricately connected to forecasts of the generation output and availability, being able to forecast variable renewable resources is critical in systems with ultra-high levels of VRE.
3 Challenges and solutions to integrate VRE
There are a variety of challenges to integrate high levels of VRE into electric power systems. This section will discuss some of those challenges focusing on operational considerations and also review a range of possible solutions. The solutions are always system and location dependent and may or may not be applicable to certain situations.
The main attribute of VRE that must be addressed is the variability of the resource and how to account for this variability over several time scales. Since VRE is not dispatchable, there are a number of technical opportunities to create grids that are more flexible and can accommodate higher levels of VRE. Cochran et al. [13] describe a number of integration options and how they can increase the amount of VRE in power systems.
3.1 Geographic diversity of variable resource
It is important to understand the benefits of geographic diversity of variable resources. As you spread the VRE across an area, there is a marked decline in the system-wide variability. Numerous studies have examined how the system-wide variability is reduced for both wind and solar [14, 15]. This is only possible as the interconnected system size increases and some small systems may not have any way to increase the geographic diversity of their system. Another interesting point on diversity is that there is often complimentary nature of wind and solar depending on location [16, 17]. These can be both daily and seasonal complements.
3.2 Renewable forecasting
Being able to forecast the VRE output is critical to operate ultra-high renewable systems unless significant reserve margins are designed to account for not being able to predict the future VRE output. Forecasting can have different impacts and values at different forecasting horizons, ranging from day-ahead to minutes-ahead [18]. The renewable resource forecasting acts like a scheduling mechanism used for dispatchable generation. Accurate forecasting of VRE output can significantly reduce reserve margins and ensure the most economic systems. New forecasting techniques have shown increased value beyond persistent forecasting and the value of renewable forecasting has been studied for integrating higher penetrations of VRE [19, 20].
3.3 Generator flexibility
Generator flexibility includes the ability of the generator to ramp power up and down and operate at low output levels. The ramping capability of existing generation is an important consideration when trying to balance load and available generation. Since large amounts of VRE can cause large changes in the net loads seen by other generators, it is important that there are available ramping capabilities. The minimum load on existing generators is also another important consideration since it is usually a determining factor as to how much VRE can be run at any particular point in time.
3.4 Energy storage
Energy storage is very important in the systems with ultra-high levels of VRE. Energy storage can be used for a variety of functions including regulation, load following, and energy shifting to add or absorb energy from a power system when there is too little or too much renewable energy. There are a variety of energy storage options that can be included in electric power systems and detailed discussion can be found in [21]. In large-scale power systems the amount of energy storage to reach ultra-high levels of VRE while large, can be a relatively small fraction of the overall system size. A study conducted by the National Renewable Energy Laboratory called the Renewable Electricity Futures (REF) study [22] showed that to reach a 90% renewable energy scenario that included 48% wind and solar required around 140 GW of installed storage capacity, as shown in Fig. 2.
The REF study looked at the entire continental United States’ electricity needs in 2050 of around 4126 TWh of load being met with around 1400 GW of installed capacity from nuclear, renewable, and fossil fuel sources. The energy storage on a capacity basis is around 10% of the total installed capacity. The storage used in this study was a combination of pumped hydro storage and compressed air. In this case, the system’s storage is mostly used for daily load balancing and not to support any days of autonomy. Days of autonomy are the number of days that a power system can operate without wind or solar power.
On smaller systems for example the Hawaiian island of Lanai, a study [23] showed that much more energy storage is needed to reach ultra-high levels of VRE. To reach 88% VRE on an annual energy basis required 16 MW of PV to supply the total annual load of 30244 MWh per year with a peak demand of 4.9 MW. The system also required 84 MWh of storage, which is fairly large compared to the overall load. The amount of energy required under this study is high because the limited fuel diversification and relatively low capacity factors for PV (around 20%). Less storage was needed when the system was designed using wind in place of PV since the wind resource had a higher capacity factor, less daily variability, and provided more renewable energy during the course of a year.
3.5 Curtailment
Due to the fact that wind and solar have relatively low capacity factors compared to other generation sources, they must be over-built in terms of capacity to supply enough energy for ultra-high penetration levels. One challenge is that sometimes it is not feasible to store or use all of this excess energy and it must be reduced or curtailed. The curtailment of both PV and wind is relatively easy to achieve since PV systems can be operated off of their maximum power point all the way to zero output. Wind turbines can be curtailed by a number of mechanisms including furling the blades and even braking the turbine rotors. Curtailed energy in smaller isolated systems can also be dissipated in dump loads that consist of banks for resistors. The excess energy in dump loads is often used to heat water since this is the natural byproduct. Larger system studies have shown that curtailed energy does not necessarily have to be significant. The REF study [22] showed that even at high levels of 90% RE/48% VRE, the total amount of curtailed wind and solar was only 7% of the total energy, as shown in Fig. 3.
3.6 Load control
Another option to increase the amount of VRE is to shift demand through load control. Instead of designing grids to deliver energy when loads demand it, a system can be designed to use energy when there is available power from VRE. In this case, the generation won’t follow loads. Instead, the load starts to follow the generation. Controllable loads can be used to shift power and energy usage throughout the day and in some cases act as storage by preheating or precooling the thermal mass of buildings. Reference [24] have shown that using responsive loads is one of the most underutilized reliability resources and has the potential to provide balancing capability over all time frames from seconds to seasons.
3.7 Other considerations
In large systems, additional ways to increase system flexibility to integrate higher levels of VRE include improving joint operations of adjacent power systems as a way to share resources, additional grid infrastructure built outs to remove congestion and constraints, and market mechanisms that improve overall economics and incentivize flexibility.
4 Examples of VRE penetrations in power grids
AC power systems can range in size from very small single households to continental systems that stretch over large land areas. The physical size of the electric power system has had an impact on the amount of VRE integrated into grids to date. Figure 4 shows a graph of currently operating power systems with capacities ranging from 100 kW to 1000 GW and amount of VRE on an annual basis that has been integrated.
The smaller systems are true synchronous AC grids with ultra-high levels of renewables. These are mostly very small systems under 1 MW of installed capacity that are located in remote areas and island power systems. At the very small end of the spectrum are island like Ta’u in America Samoa located in the South Pacific. This island recently replaced its diesel generators with a 1.4 MW PV system and 6 MWh battery system [25]. The average load is only around 80 kW. The reason that the installed capacity for the PV and battery is so much higher than the average load is because the system must be sized to fully meet its energy needs with only solar energy and the capacity factor for solar even in the best locations is around 20%. So to produce enough power for 24-h operations a PV system would need to be sized at least 5 times larger than the load on a daily basis. The PV and energy storage must also be designed to provide several days of power when there is no sun.
Remote villages often operate with high levels of VRE. These systems are mainly wind-diesel-battery hybrid power systems. Examples of these small types of systems can be found throughout the world. VRE is often integrated into these systems to reduce diesel fuel usage since it is costly to bring fuel to these remote locations. An example of such a system is in St. Paul, Alaska [26, 27]. This system has an average load of 70 kW and operates with 55% annual penetration of wind and instantaneous penetrations over 100%. Another Alaskan Island—Kodiak Island—also operates with high levels of renewable energy. It integrated around 20% wind, but heavily relies on hydropower (80%) as a way to balance its needs [28].
Another application for power systems with high levels of VRE mines in remote locations. The Raglan mine in northern Canada uses wind to provide about 40% of its annual energy [29]. The Raglan mine has 3 MW of wind and 1.6 MW of diesel with and average load of 1.4 MW.
Two islands between Australia and Tasmania also operate with very high levels of variable renewable energy. Flinders Island operates with 60% and King Island operates with 65% variable renewables. King Island has a 3 MW peak load and operates a 65% annual renewable generation and is evaluating using biodiesel to get to 100% renewable energy [30]. Another system of similar size is El Hierro, one of the Canary Islands off the coast of northwestern Africa. El Hierro aimed to be the world first 100% renewable energy island but currently operates at around 35% VRE and uses a significant amount of hydropower and pump hydro storage to balance supply and demand [31]. El Hierro’s peak load is 7.5 MW and average load is around 4 MW.
In the United States, the island of Maui reached over 35% wind and solar energy in 2016 [32]. This is a mix of both large-scale wind plants and smaller distributed and customer-sited PV and wind systems. Maui’s peak load is around 200 MW and with an average load of 80 MW.
There are very few actually operating synchronous power systems above 1 GW that have over 20% VRE. One example is the country of Ireland. Ireland has a peak electricity demand of around 6.5 GW and an average demand of 5.5 GW. It reached 21.3% annual wind penetration in 2016 and allows the system to operate at up to 60% instantaneous penetration. Ireland has a target of reaching 40% renewable electricity by 2020 and has done a large amount of work on integrating non-synchronous energy sources to their grid [33].
Other areas in the figure are worth note. Denmark reached 42% penetration of VRE, Germany 20%, and California 14% in 2015, but these areas are parts of larger synchronous AC grids and can ship excess power from VRE to neighboring regions and rely on the overall system for stability support. Larger synchronous AC systems, such as the Western Interconnection of the United States that is coordinated for reliability by the Western Electrical Coordinating Council (WECC) are only around 14% wind and solar by capacity and 9% by annual energy [34]. The WECC power system has a peak demand of approximately 150 GW. Studies have been conducted to examine the impacts of high levels of VRE in the WECC [35]. These studies have shown that 35% on an annual basis and 65% on an instantaneous basis are technically possible.
The final point on the graph is for the continental United States. It reached around 7% VRE in 2016 [36]. One note is that the United States power grid is actually made up of three separate synchronous grids connected with back-to-back DC ties.
5 Conclusion
As higher levels of VRE are integrated into electric power system, the main technical challenges deal with variability, uncertainty, and asynchronous operations. There are a variety of key technologies and management measures that can be used to increase the penetration levels of VRE. Geographic diversity, flexible conventional generation, load control, and curtailment can be used to deal with variability. Better renewable forecasting can help with uncertainty in generation and reserves. Energy storage can help deal with all aspects of the integration challenge, but also is one of the most expensive options. At the very highest levels of VRE penetration, energy storage is crucially important to allow for significant energy shifting and grid availability when the renewable resource is not available. In order to provide enough energy, VRE systems may need to be oversized and may require significant curtailment during some parts of the day. As the penetration of VRE increases, there is also typically a need to increase both energy storage requirements and the amount of energy that is curtailed due to over-production at certain times during the day. Another critical issue is that VRE will also need to be designed to provide a full range of essential grid reliability services to ensure system stability. This means that there must be some device (either the VRE or energy storage devices) that needs to be like a voltage source when there is not enough synchronous generation to maintain a voltage reference and respond to voltage and frequency deviations.
This paper also examined several real-world operating systems that operate at high levels of VRE penetration and showed that ultra-high levels have been achieved at small to medium sized grids. These systems often have very large VRE and energy storage compared to the load to account for operations during several days of low wind or solar availability. This should lay the foundation for how to achieve ultra-high levels of VRE at large-sized grids.
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This work was supported by the U.S. Department of Energy under Contract No. DE-AC36-08GO28308 with Alliance for Sustainable Energy, LLC, the Manager and Operator of the National Renewable Energy Laboratory. The U.S. Government retains and the publisher, by accepting the article for publication, acknowledges that the U.S. Government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this work, or allow others to do so, for U.S. Government purposes.
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KROPOSKI, B. Integrating high levels of variable renewable energy into electric power systems. J. Mod. Power Syst. Clean Energy 5, 831–837 (2017). https://doi.org/10.1007/s40565-017-0339-3
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DOI: https://doi.org/10.1007/s40565-017-0339-3