Global cumulative stationary battery storage capacity to exceed 2TWh by 2033
Batteries for Stationary Energy Storage 2023-2033
Granular ten-year market forecasts for installations of FTM & BTM BESS. Regional analysis on grid-scale, C&I & residential batteries, regulations, renewable/storage targets; based on extensive research into key player activity & government announcements.
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Battery demand for stationary energy storage is set to grow in line with an increasing number of renewable energy resources being added to electricity grids globally. Deployments will also be driven by pressure from governments and states to reach targets pertaining to renewable energy generation and energy storage. An evolving and improving regulatory landscape will also allow energy and battery storage markets to flourish.
IDTechEx predicts that by 2033, global cumulative stationary battery storage capacity is set to exceed 2 TWh. This will see annual stationary storage deployments grow at a CAGR of 30% from 2023-2033.
Lithium-ion Battery Demand (GWh, left) and (% split by market segment, right). Source IDTechEx
This report includes granular market forecasts, key player analysis, technology trends and applications, drivers and business models giving rise to revenue streams, and regional analysis for the top installing countries.
Technology trends for stationary battery storage
Over the past decade, Li-ion batteries have become an increasingly important stationary energy storage technology. They now account for >90% of global installations of electrochemical energy storage. The main driver for their adoption has been the fast improvement in their performance and reduction in their cost.
LFP and NMC chemistries are the most popular in storage applications, though a shift towards LFP for grid-scale batteries is expected. Reasons for this include lower costs, better safety properties, and higher cycle life of LFP versus NMC. Residential battery suppliers are far more agnostic to battery chemistry choice, as these batteries' lifetimes are dictated more by consumer use behaviour than their intrinsic properties and chemistry. Regardless, LFP and NMC will continue to reign as the two dominant chemistries in the residential market.
Other analyses/discussions include the latest residential storage market trends, market size (US$), key players with revenues data, etc. supplemented by new primary information from key company interviews. The first company interviewed is BSL Battery, who operate in China, develop and sell batteries into the solar/residential and low speed vehicle markets. The second company interviewed is E3/DC GmbH, that operate in Germany, develop and sell battery systems to the residential market, and are planning to expand into the Vehicle-to-X (V2X) market. The E3/DC interviewee was a Director for their Battery Business and provided key insights into residential market trends.
The grid-scale market is leaning towards longer duration of battery storage, to accommodate growing volumes of renewable energy capacity on electricity grids. Li-ion may not be well suited to long-duration storage in future, whereas RFBs can store >10 hours of energy, presenting another means for energy companies to install longer-duration grid-scale storage in future. However, this market is still in its early stages, with grid-scale proof-of-concept projects starting to emerge. For instance, in 2022, Sumitomo Electric brought one of the world's largest vanadium RFBs online in Japan.
Applications, business models and revenue streams
Annual front-of-the-meter (FTM) installations will take a larger share of global annual Battery Energy Storage System (BESS) installations, by GWh, than behind-the-meter (BTM) installations in the next decade.
These batteries can provide a range of utility and ancillary services, giving Transmission System Operators (TSOs) the tools necessary to provide adequate national energy security and supply. Moreover, the means for large battery systems to produce revenues for their owners are becoming more apparent, through means such as revenue stacking. As business models continue to mature, investor confidence in BESS profitability will grow, thus facilitating reduced future project costs and increased installation volumes.
Batteries provide value in the BTM market primarily for the customer side. With regions such as Germany phasing out FiT schemes, consumers will take advantage of price arbitrage; using their batteries when grid prices are most expensive at times of peak demand.
This report provides a holistic view, with depictions and explanations, of the various electricity markets that battery storage assets can operate in across all market sectors, in tandem with revenue generation mechanisms.
Market drivers: renewable energy deployment, battery storage targets, regulation
The adoption of energy storage systems (ESS) is necessary for higher levels of renewable energy penetration and integration. As well as this, energy and battery storage targets and clear policy frameworks are necessary if the number of global BESS deployments is to be expedited.
Several US States have energy storage and renewables mandates. With more states announcing new battery storage targets, and expanding older targets (such as New York), this trend is expected to continue and will be a key driver for US BESS growth.
The state-level Australian renewable energy targets and storage incentives are key drivers for their high historical and forecasted BESS installation rates.
Australian storage policy, funding & renewables targets. Source IDTechEx
However, any government-level renewable energy or storage targets are currently absent, while the Victoria Energy Policy Centre (VEPC) has pushed for this. Clearly, state-level pressure is mounting on the policy front in Australia.
Regions are becoming more aware of regulatory barriers for the installation of BESS. For example, the removal of the 50 MW cap for storage deployment auctions in the UK will see larger systems installed in the coming years. Also, currently under India's Electricity Act 2003, storage is not defined as a standalone asset. This has led to regulatory hurdles when taxing these assets, reducing investor confidence, and acting as a major barrier preventing Indian BESS growth.
Comprehensive analysis and market forecasts
This report offers granular 10-year market forecasts, for the annual installations of FTM & BTM BESS (in MWh, GWh, TWh installed).
The seven most active countries have 2023-2033 forecasts with annual MWh installed for residential / C&I / grid-scale splits, or FTM / BTM splits otherwise. The US and China will be responsible for ~59% of these regions' cumulative BESS capacity in 2033, while rivalling each other for total deployments.
The regional analysis section includes detailed discussion and in-depth analysis on regional regulation developments, government and state-level announcements, renewable generation and energy and battery storage targets, key player activity, major project installations, and future project pipelines.
These drivers and developments for future stationary storage deployments are documented, scrutinised, and discussed.
Key aspects
This report provides the following information
Technology trends:
- Overview of materials and chemistries used in batteries for stationary energy storage, including their presence in the current market climate.
- Presents the growth of Li-ion deployments in recent years, with analysis behind the drivers for this.
- Comparisons of other relevant stationary storage technologies are presented and include: redox flow batteries (RFB), lead-acid batteries (LA), hydrogen fuel cells, and high potential Energy Storage Systems (ESS) (Mechanical, Gravitational, CAES, LAES)
- Residential Battery Storage: battery chemistry and property trends (capacity, modular designs, cycle life, warranties) discussed and analyzed by dozens of products/companies.
Value chain analysis:
- Explanation of battery storage services in front-of-the-meter (FTM) and behind the meter (BTM).
- Provides an overview of BESS applications in residential, commercial & industrial (C&I) and utility/grid-scale settings, and how this helps with increasing volumes of renewable energy integration to the grid, stabilization of the grid, etc.
- Analysis and discussion providing a holistic view of the different electricity markets that battery storage assets can operate in across all market sectors.
- Depictions and explanations are provided for the mechanisms that can generate lucrative revenue streams for battery storage asset owners through means such as revenue stacking, Power Purchase Agreements, etc.
- Overview of key players in both residential and large-scale battery (C&I / grid / utility) markets. Includes analysis of incumbent technologies, company market share, and region-specific supply chain developments.
- Other residential battery analyses and discussions include latest residential storage market trends, market size (US$), key players with revenues data, and company/technical product SWOT analyses.
- Includes new primary information from key company interviews, including insights into company financials, market trends, product offerings, product designs, and key areas of product development in the near-term.
- Includes matrix of global players by business application and profiles of the major players in large scale BESS. Includes technical product specifications and recent major installations.
Market Forecasts & Regional Analysis:
- Granular ten-year market forecasts for installations of FTM & BTM Battery Energy Storage Systems (ESS) (in annual MWh, GWh, TWh installed).
- The seven most active countries have 2023 - 2033 forecasts with annual MWh installed for residential / C&I / grid-scale splits, with FTM / BTM splits otherwise.
- Includes detailed discussion and in-depth analysis on regional regulation developments, renewable generation and energy and battery storage targets.
- This has been informed by key player activity and major project installations, government- and state-level announcements, and future project pipelines. Discussion around these drivers for future stationary storage deployments are documented, scrutinised, and discussed.
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| 1. | EXECUTIVE SUMMARY |
| 1.1. | Energy Storage: a Li-ion Battery Led Market |
| 1.2. | Classification of Energy Storage Systems |
| 1.3. | RES and Battery Storage Targets Adoption |
| 1.4. | RES / Storage Targets by Country |
| 1.5. | Redox Flow Batteries Overview |
| 1.6. | The Impact of RES on the Electricity Grid |
| 1.7. | Overview of Ancillary Services |
| 1.8. | Business Models and Revenue Streams Overview |
| 1.9. | Revenue Streams Description |
| 1.10. | Residential Batteries Market Size |
| 1.11. | Residential Battery Chemistries |
| 1.12. | Global Battery Installations Forecast |
| 1.13. | FTM & BTM Market Forecast breakdown |
| 1.14. | Battery Energy Storage Development 2018-2022 |
| 1.15. | Global Trends |
| 1.16. | Global Trends |
| 1.17. | US Executive Summary |
| 1.18. | US States Storage and Targets Overview |
| 1.19. | California Overview |
| 1.20. | US Large Utility Battery Project |
| 1.21. | China Executive Summary |
| 1.22. | India Executive Summary |
| 1.23. | Japan Executive Summary |
| 1.24. | South Korea Executive Summary |
| 1.25. | Australia Executive Summary |
| 1.26. | Australia Storage Policy, Funding, and Renewables Targets |
| 1.27. | Victoria Big Battery |
| 1.28. | UK Executive Summary |
| 1.29. | Germany Executive Summary |
| 1.30. | Italy Executive Summary |
| 1.31. | Forecast Conclusions and Explanations |
| 1.32. | Forecast Conclusions and Explanations |
| 1.33. | Forecast Conclusions and Explanations |
| 2. | INTRODUCTION |
| 2.1. | Consumption of Electricity is Changing |
| 2.2. | Renewables are Leading the Power Source Changes |
| 2.3. | The Advantage of Energy Storage in the Power Grid |
| 2.4. | The Advantage of Energy Storage in the Power Grid |
| 2.5. | Stationary Storage Position in the Power Grid |
| 2.6. | Different Battery Sizes for Different Uses |
| 2.7. | Where Can Energy Storage Fit In? |
| 2.8. | Battery Storage System |
| 2.9. | Battery Storage Designed for Self Consumption |
| 3. | TECHNICAL ASPECTS OF BATTERIES AND OTHER TECHNOLOGIES |
| 3.1. | Li-ion Batteries |
| 3.1.1. | Battery for Stationary Energy Storage: Overview |
| 3.1.2. | More Than One Type of Li-ion Battery |
| 3.1.3. | A Family Tree of Li Based Batteries |
| 3.1.4. | Differences Between Cell, Module, and Pack |
| 3.2. | Cathode Materials |
| 3.2.1. | Cathode Materials - NMC, NCA, and LMO |
| 3.2.2. | Cathode Materials - LCO and LFP |
| 3.2.3. | Cathode Suitability |
| 3.2.4. | Cathode Price Fluctuations |
| 3.2.5. | LFP or NMC for Stationary Storage? |
| 3.3. | Anode Materials |
| 3.3.1. | Anodes Compared 1 |
| 3.3.2. | Anodes Compared 2 |
| 3.3.3. | Where will LTO Play a Role? |
| 3.3.4. | IDTechEx's Li-ion Batteries Related Reports |
| 3.4. | Other Technologies |
| 3.4.1. | Redox Flow Batteries for Stationary Storage? |
| 3.4.2. | Lead-acid Batteries |
| 3.4.3. | Fuel Cell Limitations |
| 3.4.4. | High Potential ES Technologies: Overview |
| 3.4.5. | High Potential ES Technologies: Properties |
| 3.4.6. | High Potential ES Technologies: Properties Comparison |
| 3.4.7. | Comparison of Energy Storage Devices |
| 4. | STATIONARY ENERGY STORAGE: DRIVERS, BUSINESS MODELS, AND REVENUE STREAMS |
| 4.1. | Introduction to ES Drivers |
| 4.2. | ESS for Every Position in the Value Chain |
| 4.3. | Power Capacity VS. Discharge Duration |
| 5. | BUSINESS MODELS AND REVENUE STREAMS |
| 5.1. | Business Models and Revenue Streams Overview |
| 5.2. | Revenue Streams Overview |
| 5.3. | Revenue Streams Description |
| 5.4. | Power Purchase Agreements |
| 5.5. | Battery Storage and Flexibility Optimisation PPAs |
| 6. | BTM APPLICATION SUMMARIES |
| 6.1. | BTM Summary: Values Provided by Battery Storage - Customer Side |
| 6.2. | Virtual Power Plants |
| 6.3. | Virtual Power Plant Companies |
| 7. | RESIDENTIAL BATTERY STORAGE |
| 7.1. | The Importance of Residential Battery Storage |
| 7.2. | Key Technology Trends and Observations |
| 7.2.1. | Residential Batteries Market Size |
| 7.2.2. | Residential Market Players |
| 7.2.3. | Battery Chemistries for Residential Storage |
| 7.2.4. | LMO Chemistry Market Share |
| 7.2.5. | Residential Battery Capacities |
| 7.2.6. | Modular Residential Battery Designs |
| 7.2.7. | Residential Battery Price/kg & Energy Density |
| 7.2.8. | Outlier Explanations |
| 7.2.9. | Importance of Cycle Life for Residential Battery Suppliers |
| 7.2.10. | Residential Battery Warranties |
| 7.3. | Company Interviews and SWOT Analyses |
| 7.3.1. | E3/DC - IDTechEx Index Scoring |
| 7.3.2. | E3/DC |
| 7.3.3. | BSL Battery - IDTechEx Index Scoring |
| 7.3.4. | BSL Battery |
| 7.3.5. | SunPower |
| 7.3.6. | BYD |
| 7.3.7. | Sonnen |
| 7.3.8. | Eaton |
| 7.3.9. | Enphase |
| 7.3.10. | Sungrow |
| 7.3.11. | Senec GmbH Offer a Market-leading Cycle Life |
| 7.3.12. | Residential Batteries Summary |
| 8. | FTM APPLICATION SUMMARIES |
| 8.1. | FTM: Values Provided by Battery Storage in Ancillary Services |
| 8.2. | Ancillary Service Requirements |
| 8.3. | Frequency Regulation |
| 8.4. | Levels of Frequency Regulation |
| 8.5. | Load Following |
| 8.6. | Spinning and Non-spinning Reserve |
| 8.7. | Dynamic Containment (DC) |
| 8.8. | Stacking Revenues for Battery Storage Asset Owners |
| 8.9. | FTM: Values Provided by Battery Storage in Utility Services |
| 8.10. | Gas Peaker Plant Deferral |
| 8.11. | Off-grid and Remote Applications |
| 8.12. | Other Drivers |
| 8.13. | Concluding Remarks |
| 9. | ENERGY STORAGE PLAYERS: LARGE SCALE BESS FOCUS |
| 9.1.1. | Players Overview |
| 9.1.2. | ES Player Business Model Reminder |
| 9.1.3. | Energy Storage Integrators |
| 9.1.4. | Leading FTM and C&I Stationary Storage Players |
| 9.2. | Company Lists and Profiles |
| 9.2.1. | Storage, Solar, Utility, and Energy Companies |
| 9.2.2. | Global Players by Business Application |
| 9.2.3. | Global Players by Region HQ |
| 9.2.4. | Companies from Other Sectors Jumping In |
| 9.2.5. | Value Chain |
| 9.2.6. | Company Profiles (Hyperlinks) |
| 9.2.7. | Benchmark of IDTechEx Index Across Vendors |
| 9.3. | Other Notable Companies |
| 9.3.1. | Tesla's ESS Business |
| 9.3.2. | Tesla: Powerwall and Powerpack |
| 9.3.3. | Tesla: Major Powerpack Projects |
| 9.3.4. | Tesla: Megapack |
| 9.3.5. | BYD |
| 9.3.6. | BYD's Layout is Similar to Tesla's |
| 9.3.7. | Fluence 2022 Update |
| 9.3.8. | NextEra Energy Resources 2022 Update |
| 9.3.9. | Wärtsilä 2022 Update |
| 9.3.10. | Aggreko 2022 Update |
| 9.3.11. | Leclanché |
| 9.3.12. | Green Charge Networks |
| 9.3.13. | Green Mountain Power |
| 9.3.14. | Green Mountain Power's Innovation Strategy |
| 9.3.15. | Ampard and Fenecon |
| 9.3.16. | Stem |
| 10. | REGIONAL ANALYSIS |
| 10.1. | Introduction |
| 10.1.1. | Long-term Forecasting of New Technologies |
| 10.1.2. | Forecast Methodology |
| 10.1.3. | Global Battery Installation Forecast |
| 10.1.4. | Global Battery Installation Forecast (BTM & FTM) |
| 10.2. | Australia |
| 10.2.1. | Australia Summary |
| 10.2.2. | Australia's Grid-scale and Residential Storage Growth |
| 10.2.3. | Australia Energy Storage Targets, Policies, and Rules |
| 10.2.4. | Australia Storage Policy, Funding, and Renewables Targets |
| 10.2.5. | Other State Policies, Schemes, and Targets |
| 10.2.6. | Victoria's Neighbourhood Battery Initiative |
| 10.2.7. | Victoria's Neighbourhood Battery Initiative |
| 10.2.8. | Australia's Li-ion Gigafactory and Supply Chain |
| 10.2.9. | Victoria Big Battery |
| 10.2.10. | Tesla to Supply 300MWh of its Megapack BESS for Edify Energy |
| 10.2.11. | Australian Player Activity Summary |
| 10.2.12. | Australia Concluding Remarks |
| 10.2.13. | Australia Battery Installation Forecast |
| 10.3. | Japan |
| 10.3.1. | Introduction to the Japanese Energy Status |
| 10.3.2. | Japanese multiple approaches toward energy resiliency |
| 10.3.3. | A trend shift: Residential2012 - Utility2017 - Residential2022 |
| 10.3.4. | FiT phase out, driver for battery energy storage |
| 10.3.5. | Private households investing in Solar + Batteries |
| 10.3.6. | Peer-to-peer (P2P) residential energy trading |
| 10.3.7. | Tesla entering Japanese home battery market |
| 10.3.8. | Other approaches besides Home Batteries |
| 10.3.9. | Vehicle-to-grid (V2G) |
| 10.3.10. | Japan's grid-scale battery situation and project examples |
| 10.3.11. | Grid-scale batteries in Hokkaido |
| 10.3.12. | The "Basic Hydrogen Roadmap" |
| 10.3.13. | 10MW Fukushima Electrolyser |
| 10.3.14. | Japan: Concluding Remarks |
| 10.4. | South Korea |
| 10.4.1. | South Korea overview |
| 10.4.2. | Polluting more now, to pollute less later |
| 10.4.3. | Government approach toward ES system |
| 10.4.4. | Korea: Market Drivers |
| 10.4.5. | Korean Renewable Energy Certificate (REC) |
| 10.4.6. | South Korea's state of electricity generation and battery storage |
| 10.4.7. | South Korea: ESS developer market share |
| 10.4.8. | Reduced battery installations after 2018 |
| 10.4.9. | Battery fires in Korea |
| 10.4.10. | Causes of battery fires |
| 10.4.11. | Utility scale battery storage projects |
| 10.4.12. | South Korea: Concluding Remarks |
| 10.5. | India |
| 10.5.1. | India's commitment toward renewables |
| 10.5.2. | A lead-acid dominated industry |
| 10.5.3. | Battery storage and solar capacity trajectory under current circumstances |
| 10.5.4. | Battery Storage tenders and government push |
| 10.5.5. | India: Challenges, Predictions and Developments |
| 10.5.6. | The Indian Li-ion battery industry development |
| 10.5.7. | India's rooftop solar PV market and residential batteries situation |
| 10.5.8. | India Concluding Remarks |
| 10.5.9. | India Battery Installations Forecast |
| 10.6. | China |
| 10.6.1. | Chinese emissions target |
| 10.6.2. | Chinese power grid upgrade |
| 10.6.3. | China's Historic Energy Storage Deployments |
| 10.6.4. | Recent Regulation and Target Developments |
| 10.6.5. | China Energy Storage by Technology Split |
| 10.6.6. | China Concluding Remarks |
| 10.6.7. | China Battery Installations Forecast |
| 10.6.8. | China Forecast Assumptions |
| 10.7. | US overview |
| 10.7.1. | US States Storage and Targets Overview |
| 10.7.2. | US Electricity Costs |
| 10.7.3. | US Electricity Costs: Retail Price by State in 2020 (cents/kWh) |
| 10.7.4. | US Key Developments: Inflation Reduction Act |
| 10.7.5. | US Key Developments: American Energy Innovation Act |
| 10.7.6. | US Key Developments: FERC Order 2222 |
| 10.7.7. | FERC 2222 advantages for ES market |
| 10.7.8. | US Key Developments: FERC Order 841 |
| 10.7.9. | US: Anecdotes (1/3) |
| 10.7.10. | US: Anecdotes (2/3) |
| 10.7.11. | US: Anecdotes (3/3) |
| 10.7.12. | US Concluding Remarks |
| 10.7.13. | US Battery Installation Forecast |
| 10.8. | California overview |
| 10.8.1. | Large Utility Battery Projects (1/2) |
| 10.8.2. | Large Utility battery projects (2/2) |
| 10.8.3. | California home-batteries policies: SGIP |
| 10.8.4. | California home-batteries policies: NEM |
| 10.8.5. | California home battery market |
| 10.9. | Hawaii: 'The prototype state' |
| 10.9.1. | Hawaii clean energy initiative |
| 10.9.2. | Renewables + Storage are competitive with fossil fuels |
| 10.9.3. | Large Utility Battery Projects in O'ahu |
| 10.9.4. | Net Energy Metering (NEM) and its upgrade |
| 10.9.5. | Performance-based regulations & forecast |
| 10.10. | Virginia overview |
| 10.10.1. | Energy Storage Policy: Virginia |
| 10.10.2. | Energy Storage Policy: Virginia |
| 10.10.3. | Dominion Battery Project |
| 10.11. | New York overview |
| 10.11.1. | New York state moving toward Energy Storage |
| 10.11.2. | New York state energy storage roadmap |
| 10.11.3. | New York, and the largest installed battery - 2.5 GWh |
| 10.11.4. | New York Large Batteries Summary |
| 10.12. | South Carolina overview |
| 10.12.1. | South Carolina: Energy Freedom Act |
| 10.13. | Germany |
| 10.13.1. | Germany: the European 'California' |
| 10.13.2. | Structure and targets of the 'Energy Concept' |
| 10.13.3. | Germany overview |
| 10.13.4. | From coal to storage |
| 10.13.5. | Electricity grid upgrade |
| 10.13.6. | FTM in Germany |
| 10.13.7. | The German Energy Transition Emblem: 'BigBattery Lausitz' |
| 10.13.8. | GridBooster Project |
| 10.13.9. | RWE large batteries with hydropower |
| 10.13.10. | Innovation Auctions: 2020 & 2021 |
| 10.13.11. | BTM: Home batteries as a solution |
| 10.13.12. | Solar-plus-storage has reached cost parity |
| 10.13.13. | KfW bank subsidy |
| 10.13.14. | Further options, after the FiT |
| 10.13.15. | Home batteries in Germany |
| 10.13.16. | Residential, C&I and Grid Battery Summary |
| 10.13.17. | Germany Battery Installations Forecast |
| 10.14. | Italy |
| 10.14.1. | Italy Overview |
| 10.14.2. | The Italian Feed-in Tarif, and the new RES Decree |
| 10.14.3. | Italian Historical Feed-in tariff |
| 10.14.4. | Electricity Storage in Italy: VPP development |
| 10.14.5. | FCA V2G in Mirafiori |
| 10.14.6. | Italy: Home Batteries recession |
| 10.14.7. | Italy's growing solar installations |
| 10.14.8. | First Italian CO₂ 'battery' storage facility |
| 10.14.9. | Italy Concluding Remarks |
| 10.14.10. | Italy Battery Installation Forecast |
| 10.15. | United Kingdom |
| 10.15.1. | UK Renewable Energy Overview |
| 10.15.2. | FTM and BTM Overview |
| 10.15.3. | Capacity Markets: Explained |
| 10.15.4. | A step forward for clean energy sources |
| 10.15.5. | Capacity Market Update Timeline |
| 10.15.6. | Batteries lost value after BEIS de-rating |
| 10.15.7. | Storage de-rating factors |
| 10.15.8. | Revenue Stacking (1/3) |
| 10.15.9. | Revenue Stacking (2/3) |
| 10.15.10. | Revenue Stacking (3/3) |
| 10.15.11. | Large UK BESS Project Developments; 2022 |
| 10.15.12. | UK Residential Market |
| 10.15.13. | United Kingdom Residential & Grid Battery Summary |
| 10.15.14. | UK Battery Installation Forecast |
| 10.16. | Latin America |
| 10.16.1. | Latin America Energy Supply Overview |
| 10.16.2. | Chile and AES Andes lead the way |
| 10.16.3. | Other large developments |
| 10.17. | Africa |
| 10.17.1. | Africa Energy Overview |
| 11. | FORECASTS |
| 11.1. | Global Battery Installations Forecast |
| 11.2. | FTM & BTM Market Forecast (GWh) |
| 11.3. | FTM & BTM Market Forecast (US$B) |
| 11.4. | Australia Battery Installation Forecast |
| 11.5. | India Battery Installations Forecast |
| 11.6. | China Battery Installations Forecast |
| 11.7. | US Battery Installation Forecast |
| 11.8. | Germany Battery Installations Forecast |
| 11.9. | Italy Battery Installation Forecast |
| 11.10. | UK Battery Installation Forecast |
| 12. | COMPANY PROFILES |
| 12.1. | Aggreko |
| 12.2. | BSL Battery (Residential)) |
| 12.3. | E3/DC GmbH (Residential) |
| 12.4. | Electric Era |
| 12.5. | Engie Storage |
| 12.6. | Fluence |
| 12.7. | Kokam |
| 12.8. | Leclanché |
| 12.9. | Powin Energy |
| 12.10. | Schneider Electric |
Ordering Information
Batteries for Stationary Energy Storage 2023-2033
£$€¥元
Electronic (1-5 users)
£5,650.00
Electronic (6-10 users)
£8,050.00
Electronic and 1 Hardcopy (1-5 users)
£6,450.00
Electronic and 1 Hardcopy (6-10 users)
£8,850.00
Electronic (1-5 users)
$7,000.00
Electronic (6-10 users)
$10,000.00
Electronic and 1 Hardcopy (1-5 users)
$7,975.00
Electronic and 1 Hardcopy (6-10 users)
$10,975.00
Electronic (1-5 users)
€6,400.00
Electronic (6-10 users)
€9,100.00
Electronic and 1 Hardcopy (1-5 users)
€7,310.00
Electronic and 1 Hardcopy (6-10 users)
€10,010.00
Electronic (1-5 users)
¥900,000
Electronic (6-10 users)
¥1,260,000
Electronic and 1 Hardcopy (1-5 users)
¥1,020,000
Electronic and 1 Hardcopy (6-10 users)
¥1,380,000
Electronic (1-5 users)
元50,000.00
Electronic (6-10 users)
元72,000.00
Electronic and 1 Hardcopy (1-5 users)
元58,000.00
Electronic and 1 Hardcopy (6-10 users)
元80,000.00
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Report Statistics
| Slides | 334 |
|---|---|
| Forecasts to | 2033 |
| ISBN | 9781915514325 |
Preview Content
 Webinar Slides
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Webinar Slides - EOY 2022
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Sample pages
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