Difference between revisions of "Energy Storage 101/Drivers and Big Picture"

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{{DISPLAYTITLE: The State of Energy Storage: {{SUBPAGENAME}}}}
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=Decreases in Technology Costs=
=Drivers for Energy Storage=
==Decreases in Technology Costs==
Massive research and development investment and manufacturing scale-up has driven costs down for lithium ion battery storage. This was initially driven by the consumer electronics market (e.g. cell phones and laptops) and more recently accelerated by the electric vehicle market. There has been an almost 90% reduction in $/kWh cost in the last decade and lithium ion costs are expected to continue to decrease with additional manufacturing improvements and economies of scale. Solar and wind technology cost reductions are also driving deployment of energy storage for hybrid applications.
Massive research and development investment and manufacturing scale-up has driven costs down for lithium ion battery storage. This was initially driven by the consumer electronics market (e.g. cell phones and laptops) and more recently accelerated by the electric vehicle market. There has been an almost 90% reduction in $/kWh cost in the last decade and lithium ion costs are expected to continue to decrease with additional manufacturing improvements and economies of scale. Solar and wind technology cost reductions are also driving deployment of energy storage for hybrid applications.
[[File:BNEF_LiIon_Battery_Pack_Price.png|none|thumb|800px|Bloomberg New Energy Finance projects 2030 lithium ion pack costs at $62/kWh based on observed prices and an 18% learning rate. Source: [https://about.bnef.com/blog/behind-scenes-take-lithium-ion-battery-prices/ BNEF: "A Behind the Scenes Take on Lithium-ion Battery Prices"]]]
Bloomberg New Energy Finance projects 2030 lithium ion pack costs at $62/kWh based on observed prices and an 18% learning rate.<ref>BloombergNEF: "[https://about.bnef.com/blog/behind-scenes-take-lithium-ion-battery-prices/ A Behind the Scenes Take on Lithium-ion Battery Prices]"</ref>
 
[[File:EPRI ES Cost Trends.png|none|thumb|650px|Over 40% cost reduction projected for lithium ion systems by 2030.<ref>"[https://www.epri.com/research/products/000000003002020048 EPRI Battery Energy Storage Lifecyle Cost Assessment Summary: 2020]"</ref>]]


=Increasing Renewable Generation=
==Increasing Renewable Generation==
Solar photovoltaic (PV) is driving midday over generation and increased evening ramping requirements which provides a value stream for flexible energy storage. As more solar comes online, the effective net load in the middle of the day decreases. Wind energy is similarly driving flexibility needs.
Solar photovoltaic (PV) is driving midday over generation and increased evening ramping requirements which provides a value stream for flexible energy storage. As more solar comes online, the effective net load in the middle of the day decreases. Similarly, wind energy is also driving flexibility needs.
[[File:Caiso_Duck_Curve_Ramping.png|none|thumb|650px|Source: [https://www.caiso.com/Documents/FlexibleResourcesHelpRenewables_FastFacts.pdf CAISO: "What the duck curve tells us about managing a green grid"]]]
[[File:Caiso_Duck_Curve_Ramping.png|none|thumb|650px|Source: CAISO - "What the duck curve tells us about managing a green grid"<ref>California Independent System Operator (CAISO): "[https://www.caiso.com/Documents/FlexibleResourcesHelpRenewables_FastFacts.pdf What the duck curve tells us about managing a green grid]"</ref>]]


=Evolving Utility Needs=
==Evolving Utility Needs==
*The grid infrastructure (generation, transmission, and distribution) is sized for infrequent peak needs and therefore most assets are under-utilized most of the time. Energy storage can support peak load reduction to provide significant cost reduction opportunity to electricity customers.  
*The grid infrastructure (generation, transmission, and distribution) is sized for infrequent peak needs and therefore most assets are under-utilized most of the time. Energy storage can support peak load reduction to provide significant cost reduction opportunity to electricity customers.  
*Utility asset infrastructure is aging and peak load reduction may extend asset life and offer opportunity to consider investment in new technologies.
*Utility asset infrastructure is aging and peak load reduction may extend asset life and offer opportunity to consider investment in new technologies.
*Peaker plants are only used a fraction of hours per year and energy storage is being considered as peaking capacity in generation planning. Battery storage is already being deployed for this application and as costs decrease they may be cost competitive with combustion turbines in the next decade. When accounting for operational benefits, the crossover point on cost may be sooner.  
*Peaker plants are only used a fraction of hours per year and energy storage is being considered as peaking capacity in generation planning. Battery storage is already being deployed for this application and as costs decrease they may be cost competitive with combustion turbines in the next decade. When accounting for operational benefits, the crossover point on cost may be sooner.  


=Increasing Utility Customer Choice and Engagement=
==Increasing Utility Customer Choice and Engagement==
Customers (residential, commercial, industrial) are considering energy storage for:
Customers (residential, commercial, industrial) are considering energy storage for:
*Bill savings
*Bill savings
Line 23: Line 24:
*Backup premise or critical loads
*Backup premise or critical loads


=Policy and Regulatory Changes=
==Policy and Regulatory Changes==
==U.S. Federal Policy==
===U.S. Federal Policy===
[[File:Us_Fed_Regulation.png|none|thumb|800px|Overview of recent energy storage related Federal Energy Regulatory Commission (FERC) orders]]
In the last decade there has been a shift in policy towards energy storage. At the federal level, FERC has issued several orders as outline below to support energy storage in markets.
'''FERC Order 755''': Frequency Regulation Compensation in Organized Markets
[[File:Us_Fed_Regulation.png|none|thumb|800px|Overview of recent energy storage related Federal Energy Regulatory Commission (FERC) orders. <br>
*Pay for Performance compensation based on speed and accuracy
<sup>1</sup>Lawrence Berkeley National Lab, Hybrid Power Plants: Status of Installed and Proposed Projects.<ref>Lawrence Berkeley National Lab, Hybrid Power Plants: Status of Installed and Proposed Projects</ref>]]
'''FERC Order 841''': Electric Storage Participation in Markets Operated by RTOs and ISOs
 
*Storage can participate in energy, ancillary services, and capacity markets when technically able
 
*Clarifies technical provisions for energy storage
===U.S. State Policy===
'''FERC Order 845-A''': Reform of Generator Interconnection Procedures and Agreements
At the state level, there has been an expanding number of policies to address energy storage in various ways.
*Revises large generator interconnection requirements
 
*Allows interconnection below combined nameplate for hybrid systems
*'''Clean Energy Goals''': Carbon-free, renewable portfolio standards, and net-zero goals.
'''FERC Order 2222''': Participation of Distributed Energy Resource Aggregations in Markets Operated by RTOs and ISOs
*'''Procurement Targets''': Regulators or legislators set procurement goals and mandates requiring utilities to directly procure or contract storage.
*Enables Aggregated DER (or Virtual Power Plant) participation in ISO/RTO markets
*'''Resource Plans''': State agencies or regulators fund studies or direct utilities to create an energy plan with consideration of storage. Many utilities and states included storage in their resource plan even if not directed to by regulators (not shown on the figure).
*'''Incentives''': Legislators created economic incentives (e.g., rebates or subsidies) for deploying storage.
 
 
[[File:Es101driver10.png|none|thumb|800px|States are taking varying approaches to energy storage deployment.<ref>Pacific Northwest National Laboratory (PNNL): [https://energystorage.pnnl.gov/regulatoryactivities.asp Energy Storage Policy Database]</ref>]]


==U.S. State Policy==
=Current Status and Future Outlook=
'''Procurement Targets:''' Regulators or legislators set procurement goals and mandates requiring utilities to directly procure or contract storage.
By the end of 2018, battery energy storage had been deployed in nearly every region of the U.S. under a variety of ownership models. IPPs owned most of the power capacity, providing market services for ISOs like PJM and ERCOT. Conversely, IOUs owned most of the energy capacity, serving needs such as renewable firming and load shifting in places like California and New England. <ref>Helman U, Kaun B, and Stekli J (2020) "[https://www.frontiersin.org/articles/10.3389/fenrg.2020.539752/full Development of Long-Duration Energy Storage Projects in Electric Power Systems in the United States: A Survey of Factors Which Are Shaping the Market]"</ref>


'''Incentives:''' Legislators create economic incentives (e.g. rebates or subsidies) for deploying storage; No mandatory procurement 
==Energy Storage Deployment Trends==
Since 2018, the size and duration of projects has generally increased. Announcements for new battery energy storage sites planned over the next 2-3 years have grown &mdash; now, individual sites may host hundreds of megawatts and nearly a gigawatt-hour each.


'''Resource Plans:''' State agencies or regulators fund studies or direct utilities to create an energy plan with consideration of storage; No targets or incentives
==Deployments by Technology==
[[File:Es101driver10.png|States are taking varying approaches for energy storage deployment]]
[[File:Global_ES_by_technology.PNG|none|thumb|900px|A breakdown of global energy storage installations by technology. Data Source: CNESA<ref>China Energy Storage Alliance (CNESA): "[https://en.cnesa.org/latest-news/2020/9/26/cnesa-global-energy-storage-market-analysis2020q2-summary Global Energy Storage Market Analysis—2020.Q2 (Summary)]"</ref>]]


=Resources=
=References=
<references />

Latest revision as of 15:49, 19 November 2021


Drivers for Energy Storage

Decreases in Technology Costs

Massive research and development investment and manufacturing scale-up has driven costs down for lithium ion battery storage. This was initially driven by the consumer electronics market (e.g. cell phones and laptops) and more recently accelerated by the electric vehicle market. There has been an almost 90% reduction in $/kWh cost in the last decade and lithium ion costs are expected to continue to decrease with additional manufacturing improvements and economies of scale. Solar and wind technology cost reductions are also driving deployment of energy storage for hybrid applications. Bloomberg New Energy Finance projects 2030 lithium ion pack costs at $62/kWh based on observed prices and an 18% learning rate.[1]

Over 40% cost reduction projected for lithium ion systems by 2030.[2]

Increasing Renewable Generation

Solar photovoltaic (PV) is driving midday over generation and increased evening ramping requirements which provides a value stream for flexible energy storage. As more solar comes online, the effective net load in the middle of the day decreases. Similarly, wind energy is also driving flexibility needs.

Source: CAISO - "What the duck curve tells us about managing a green grid"[3]

Evolving Utility Needs

  • The grid infrastructure (generation, transmission, and distribution) is sized for infrequent peak needs and therefore most assets are under-utilized most of the time. Energy storage can support peak load reduction to provide significant cost reduction opportunity to electricity customers.
  • Utility asset infrastructure is aging and peak load reduction may extend asset life and offer opportunity to consider investment in new technologies.
  • Peaker plants are only used a fraction of hours per year and energy storage is being considered as peaking capacity in generation planning. Battery storage is already being deployed for this application and as costs decrease they may be cost competitive with combustion turbines in the next decade. When accounting for operational benefits, the crossover point on cost may be sooner.

Increasing Utility Customer Choice and Engagement

Customers (residential, commercial, industrial) are considering energy storage for:

  • Bill savings
  • Increased energy independence
  • Renewable energy goals
  • Backup premise or critical loads

Policy and Regulatory Changes

U.S. Federal Policy

In the last decade there has been a shift in policy towards energy storage. At the federal level, FERC has issued several orders as outline below to support energy storage in markets.

Overview of recent energy storage related Federal Energy Regulatory Commission (FERC) orders.
1Lawrence Berkeley National Lab, Hybrid Power Plants: Status of Installed and Proposed Projects.[4]


U.S. State Policy

At the state level, there has been an expanding number of policies to address energy storage in various ways.

  • Clean Energy Goals: Carbon-free, renewable portfolio standards, and net-zero goals.
  • Procurement Targets: Regulators or legislators set procurement goals and mandates requiring utilities to directly procure or contract storage.
  • Resource Plans: State agencies or regulators fund studies or direct utilities to create an energy plan with consideration of storage. Many utilities and states included storage in their resource plan even if not directed to by regulators (not shown on the figure).
  • Incentives: Legislators created economic incentives (e.g., rebates or subsidies) for deploying storage.


States are taking varying approaches to energy storage deployment.[5]

Current Status and Future Outlook

By the end of 2018, battery energy storage had been deployed in nearly every region of the U.S. under a variety of ownership models. IPPs owned most of the power capacity, providing market services for ISOs like PJM and ERCOT. Conversely, IOUs owned most of the energy capacity, serving needs such as renewable firming and load shifting in places like California and New England. [6]

Energy Storage Deployment Trends

Since 2018, the size and duration of projects has generally increased. Announcements for new battery energy storage sites planned over the next 2-3 years have grown — now, individual sites may host hundreds of megawatts and nearly a gigawatt-hour each.

Deployments by Technology

A breakdown of global energy storage installations by technology. Data Source: CNESA[7]

References

  1. BloombergNEF: "A Behind the Scenes Take on Lithium-ion Battery Prices"
  2. "EPRI Battery Energy Storage Lifecyle Cost Assessment Summary: 2020"
  3. California Independent System Operator (CAISO): "What the duck curve tells us about managing a green grid"
  4. Lawrence Berkeley National Lab, Hybrid Power Plants: Status of Installed and Proposed Projects
  5. Pacific Northwest National Laboratory (PNNL): Energy Storage Policy Database
  6. Helman U, Kaun B, and Stekli J (2020) "Development of Long-Duration Energy Storage Projects in Electric Power Systems in the United States: A Survey of Factors Which Are Shaping the Market"
  7. China Energy Storage Alliance (CNESA): "Global Energy Storage Market Analysis—2020.Q2 (Summary)"