レドックスフロー電池市場 2026-2036年:予測、市場、技術、有力企業
世界のレドックスフロー電池(RFB)市場分析(有力企業、技術ベンチマーク評価、材料・部材イノベーション、電解液生産、政策、用途、長期エネルギー貯蔵(LDES)、データセンター、10年間市場予測など)
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変動性再生可能エネルギーの拡大を背景に、レドックスフロー電池(RFB)は、データセンターの脱炭素化や長期エネルギー貯蔵(LDES)といった新たな用途での利用が見込まれています。バナジウム系、有機系、鉄系の各RFBの性能とコストは、セルスタック部材や電解液の製造方法の進化、エネルギー貯蔵政策の発展を通じて改善するでしょう。本調査レポートでは、RFB技術、有力企業、プロジェクト、政策、部材、材料、アプリケーション、経済的側面、ビジネス機会を予測・分析しています。
「レドックスフロー電池市場 2026-2036年」が対象とする主なコンテンツ
(詳細は目次のページでご確認ください)
■ 全体概要
■ 用途、収益源、長期エネルギー貯蔵、政策、制度、均等化貯蔵原価
■ 技術とバッテリーケミストリー
■ セルスタック用材料・部材
■ レドックスフロー電池市場、バナジウム電解液市場、主な最新情報
■ 10年間の市場予測
■ 企業概要
「レドックスフロー電池市場 2026-2036年」は以下の情報を提供します
■ 市場徹底分析
- 新規参入企業、撤退企業、系統・C&I(商業と産業)用途での新規導入プロジェクト、地域別・バッテリーケミストリー別・企業別導入実績(2015年~2025年第2四半期)、企業別資金調達額(単位:百万ドル、期間:2023年第3四半期~2025年第2四半期)と2025年第2四半期までの累計額(単位:百万ドル)など
■ 有力企業の最新情報
- バナジウムレドックスフロー電池(VRFB)技術、有機レドックスフロー電池(ORFB)、鉄系RFB(鉄-水素、鉄-亜鉛、鉄-クロム、全鉄、鉄-バナジウム)、その他のニッチなバッテリーケミストリー(塩水系、水素-マンガン系、マイクロエマルション系の各種フロー電池)の開発・商用化を進める企業も含む
- 有力企業(数十社)への一次インタビューから得た知見を基に、机上調査を加えて作成
■ RFBバッテリーケミストリーの展望と市場シェア予測(2026-2036年)
■ 世界各地の今後のRFBプロジェクト(容量(MWh)別、企業別、地域別)、RFB生産能力(企業別、地域別)、将来の生産拡大見通し
■ RFBプロジェクトの最近の実績(2023年第3四半期~2025年第2四半期)と今後(2026~2029年以降)をまとめた原データ表
■ 技術の包括的ベンチマーク評価、分析、展望(対象:開発・商用化が進む主なバッテリーケミストリー)
- バッテリーケミストリー別ベンチマーク評価項目:設備投資費(ドル/kWh)、材料コスト(ドル/kWh、ドル/kg)、商用化状況、電圧(V)、代表的エネルギー密度(Wh/L、Wh/kg)、エネルギー効率(%)、電解液溶解度(mol/L)を含む
- RFBと電解液の技術的進歩(不純物耐性、添加剤、高温技術での安定性など)紹介
■ バナジウム電解液市場の主な最新情報
- 世界各地(中国、米国、オーストラリアなど)の主要電解液サプライヤー、バナジウム電解液の生産能力と将来の生産拡大、RFB開発企業との供給契約・パートナーシップ、リース型ビジネスモデル、電解液リサイクルプロセス、世界のバナジウム需給と溶融フレーク状五酸化バナジウム(V2O5)価格の見通し、バナジウム採掘探査プロジェクトなど
■ レドックスフロー電池の部材と材料のイノベーションに関する新たな分析と包括的調査、RFBセルスタックの部材コスト概要
- PFSA系・炭化水素系膜、電極、電極触媒(レドックスフロー電池バッテリーケミストリー別)、バイポーラプレート(BPP)、その他部材(ガスケットとセルフレーム、断熱板、エンドプレート、タイロッドなど)の新旧材料の重要項目も掲載
■ 電極(電気化学的活性表面積(ECSA)の増加など)、バイポーラプレート、フローフレームのイノベーションによるレドックスフロー電池の出力密度向上とコスト低減のための主なトレンド
■ 部材を供給する有力企業紹介(対象:全主要部材)
- 膜(PFSA系膜と炭化水素系膜で分類)、電極、バイポーラプレート、ガスケットとシール材、その他部材(セルフレーム、フローフレーム、テストセルなど)を扱う企業など
■ レドックスフロー電池と長期エネルギー貯蔵(LDES)技術開発と商用化を奨励する主な政策・制度
- OBBBA(One Big Beautiful Bill Act)、英国のキャップ&フロア制度、カリフォルニア州エネルギー委員会(CEC)が支援する主要プロジェクト、欧州でのレドックスフロー電池のその他主要市場など
■ 現在・将来の市場でのRFB技術の主要用途展望
- 既存C&I用バッテリー貯蔵用途、新たな用途(データセンター支援、長期エネルギー貯蔵(LDES)など
■ LDES紹介
- 市場投入タイミング、変動性再生可能エネルギー(VRE)、競合するエネルギー貯蔵技術、主な課題
- レドックスフロー電池とリチウムイオンBESS(バッテリーエネルギー貯蔵システム)の比較分析(比較項目:設置容量(GWh)、技術・商業上の主な利点と欠点)
■ バナジウムRFB技術とリチウムイオンBESS(バッテリーエネルギー貯蔵システム)を比較しながら最新の均等化貯蔵原価(LCOS)を算出・分析
- 貯蔵期間は4時間・6時間・8時間・10時間で、最新の技術CAPEX値を使用
■ レドックスフロー電池市場の10年間詳細予測(2020年-2036年)
- 地域別(GWh):中国、欧州、米国、日本、その他のアジア地域、その他の地域
- バッテリーケミストリー別(GWh):バナジウム(VRFB)、有機、全鉄、鉄-バナジウム(Fe-V)、鉄-クロム(Fe-Cr)、鉄-亜鉛(Fe-Zn)、鉄-水素(Fe-H)、その他(塩水、水素-マンガン、マイクロエマルション、二酸化炭素系などを含む)
- 金額別(単位:10億ドル):バッテリーケミストリー別に算出
■ 45社の企業概要
- レドックスフロー電池参入企業、セルスタック部材・材料サプライヤー、電解液メーカー・サプライヤーなど
IDTechEx forecasts that the redox flow battery (RFB) market is forecast to reach US$9.2B in value by 2036. The growing penetration of variable renewable energy (VRE) in electricity grids will create longer periods where supply from these intermittent sources is not occurring. This will create demand for long duration energy storage (LDES) technologies which can dispatch energy over these longer, 6+ hour, timeframes economically. While Li-ion battery energy storage system (BESS) costs continue to decrease, these technologies cannot decouple their energy capacity and power output. RFBs are capable of this by independently scaling electrolyte volumes for energy capacity and cell stacks for power output. In theory, they can achieve lower Capex (on a US$/kWh basis) than li-ion BESS at longer durations of storage. This, coupled with non-vanadium chemistries such as organic or iron-based RFBs using abundant materials, or electrolytes which are cheaper to synthesize, suggests promise for lower-cost RFB technologies in the long-term.
Redox flow battery energy and power decoupling. Source: IDTechEx.
Outside of the future demand for LDES technologies, and amid the artificial intelligence (AI) boom, RFBs could also be used to support data centers. IDTechEx has observed several key RFB-data center projects being developed in Europe and the US. RFBs can support data center decarbonization by replacing the need for diesel generators to provide uninterruptible power supply (UPS) over sustained periods, to manage volatile compute loads, and to peak shave electricity from the grid. The use of non-flammable electrolyte in RFBs and increasing scrutiny of Li-ion battery storage safety amid recent large-scale fires provides a key value proposition for RFB developers. Other key advantages such as electrolyte recyclability and a lower levelized cost of storage (LCOS) at longer durations of storage will be leveraged by RFB developers in the medium-term. These factors are but some which will drive the RFB market to grow at a CAGR of 27% for the 2026-2036 period.
Over the past few years, the RFB market has seen significant growth compared to pre-2023, with key player Rongke Power being responsible for several multi-100-MWh flow battery projects, and even a GWh-scale project. Other key players such as Sumitomo Electric Industries, Invinity Energy Systems, and CellCube, have continued to steadily deploy volumes of vanadium flow batteries also, while scaling their businesses and forming supply chain partnerships. Funding across the market is also significant, with IDTechEx identifying over US$1B raised cumulatively by RFB players. This is a significant volume for any energy storage technology competing against the incumbent li-ion BESS.
Recently installed redox flow battery projects. Source: IDTechEx.
Policies and Programs to Drive RFB Growth
While recent RFB growth has been significant, these volumes are still minor compared to those seen by li-ion BESS. This has been driven primarily by the high cost of vanadium RFB (VRFB) technologies. To support RFB and LDES growth, key policies and programs such as the One Big Beautiful Bill Act (OBBBA) in the US, the UK Cap & Floor Scheme, and key projects supported by the California Energy Commission (CEC) will also factor into the emergence of growing western RFB markets. The impact of these policies, programs, and projects are discussed in this IDTechEx report.
Redox Flow Battery Chemistries
VRFBs are the most widely deployed and understood RFB chemistry, thanks to its sufficient performance. Compared to Li-ion BESS, this performance is often worse (e.g., energy density), and at shorter durations of storage, cost is often higher. This is driven by the use expensive electrolyte which uses the critical mineral, vanadium. Therefore, demand for other non-vanadium RFB chemistries has increased in recent years. IDTechEx has observed an uptick in development, commercialization of, and key projects of organic and iron-based chemistries which could include all-iron, chromium, zinc, vanadium, and hydrogen. Other, niche RFB chemistries also see development, for example utilizing manganese, CO2, saltwater, or microemulsion formulations. The variety of redox couples that can be used is vast. However, for an RFB technology to be successful in an increasingly competitive global energy storage market, the use of abundant and low-cost materials in easy-to-access supply chains, coupled with strong performance across energy density, energy efficiency, power density, and system lifetime will be needed. This IDTechEx report benchmarks 10 redox flow battery chemistries across Capex, commercial status, and key performance metrics, assesses their advantages and disadvantages, and provides an outlook for RFB chemistry market share over the next 10 years.
Innovation in Components, Materials and Electrolytes
While the electrolyte is one of the main parts of flow batteries, these devices are complex systems, similar to fuel cells and electrolyzers in their structure. The overall performance is dictated by its constituent components including the electrolyte, cell stack, and balance of plant. IDTechEx has observed innovations in cell stack materials and components to improve the power density of the stack, with focus on the electrodes and bipolar plates (BPP). Indeed, improving the performance of RFB components will be needed to improve overall RFB outlook in the energy storage market. The expansion of vanadium electrolyte manufacturing capacity has also been observed, with the emergence of supply chain partnerships and leasing occurring between electrolyte manufacturers and RFB developers in key regions. This IDTechEx report provides analysis on vanadium supply, key electrolyte market updates, cell stack component innovation, key component suppliers, and future material trends in the cell stack including key commentary on PFAS-based membranes and alternatives.
Exploded redox flow battery cell stack and components. Source: IDTechEx.
Forecasts
This IDTechEx report provides 10-year market forecasts on the redox flow battery market for the 2020-2036 period, by region (GWh), chemistry (GWh) and value by chemistry (US$B). Regions include China, Europe, United States, Japan, Rest of Asia, and Rest of the World. Chemistry forecasts include vanadium (VRFB), organic, all-iron, iron-vanadium (Fe-V), iron-chromium (Fe-Cr), iron-zinc (Fe-Zn), iron-hydrogen (Fe-H), and "other".
Company Profiles
This IDTechEx report includes 45 company profiles, including redox flow battery players, cell stack component and material suppliers, and electrolyte manufacturers and suppliers.
Key Aspects
This report provides the following information:
- In-depth analysis on the redox flow batteries market including key player updates, new market entrants, company closures, newly deployed projects in grid-scale and commercial and industrial (C&I) applications, historic deployments (2015 - Q2 2025) by region, chemistry, and player, funding by player Q3 2023 - Q2 2025 (US$M) and cumulative to Q2 2025 (US$M).
- Key player updates include those developing and commercializing vanadium redox flow battery (VRFB) technologies, organic redox flow batteries (ORFB), iron-based RFBs (iron-hydrogen, iron-zinc, iron-chromium, all-iron, and iron-vanadium), and other niche chemistries, e.g., saltwater, hydrogen-manganese, microemulsion flow batteries. This draws insights from dozens of primary interviews between IDTechEx and key players, while also being complimented by desk-based research.
- IDTechEx's outlook on RFB chemistries and market share predictions for the 2026-2036 period.
- Identified future RFB projects globally by capacity (MWh), player and region, RFB production capacities by player and region, and future expansions.
- Raw data tables for recent historic (Q3 2023 - Q2 2025) and future RFB projects (2026-2029+).
- Comprehensive redox flow battery technology benchmarking, analysis and outlook on key chemistries being developed and commercialized. Benchmarking, by chemistry, covers redox flow battery Capex ($/kWh), material cost ($/kWh and/or $/kg), commercial status, voltage (V), and typical energy densities (Wh/L, Wh/kg), energy efficiencies (%), and electrolyte solubilities (mol/L). Includes coverage on technology advancement for RFBs and electrolytes (e.g., impurity tolerance, additives, stability in higher temperature technologies).
- Key updates on the vanadium electrolyte market, including key electrolyte suppliers globally including China, the US, and Australia, vanadium electrolyte production capacities and future expansions, supply deals and partnerships with RFB developers, leasing business models, and electrolyte recycling process, global vanadium supply vs demand and fused flake V2O5 price outlook, and vanadium mining exploration projects.
- New analysis and comprehensive research on redox flow battery component and material innovations, and overview of RFB cell stack component costs. Includes key coverage on existing and future materials for PFSA-based and hydrocarbon-based membranes, electrodes and electrode catalysts by redox flow battery chemistry, bipolar plates (BPPs), and other components such as gaskets & cell frames, insulation boards, end plates and tie rods.
- Key trends to increase redox flow battery power density and reduce costs through innovations in electrodes (e.g., increasing electrochemical surface area (ECSA)), bipolar plates and flow frames.
- Key players across all key redox flow battery component suppliers, including those for membranes (segmented by PFSA and hydrocarbon membranes), electrodes, bipolar plates, gaskets & sealants, and other components e.g., cell frames, flow frames, and test cells.
- Key policies and programs to incentivize redox flow battery and long duration energy storage (LDES) technology development and commercialization, including The One Big Beautiful Bill Act (OBBBA), the UK Cap & Floor Scheme, key projects supported by the California Energy Commission (CEC), and other key markets for redox flow batteries in Europe.
- Key applications outlook for RFB technologies in current and future markets, including established C&I battery storage applications, and emerging applications e.g., data center support and long duration energy storage (LDES).
- An introduction to LDES, its market timing, variable renewable energy (VRE), competing energy storage technologies, and key challenges. Analysis on redox flow batteries vs Li-ion battery energy storage systems (BESS), covering installation volumes (GWh), key technical and commercial advantages and disadvantages.
- Updated levelized cost of storage (LCOS) calculations and analysis of vanadium RFB technologies vs Li-ion battery energy storage systems (BESS) for 4h, 6h, 8h, and 10h durations of storage, using updated technology Capex values.
- Granular 10-year redox flow battery market forecasts, by region (GWh) China, Europe, US, Japan, Rest of Asia, Rest of the World, and by chemistry (GWh) [vanadium (VRFB), organic, all-iron, iron-vanadium (Fe-V), iron-chromium (Fe-Cr), iron-zinc (Fe-Zn), iron-hydrogen (Fe-H), and "other" (encompassing e.g., saltwater, hydrogen-manganese, microemulsion, carbon dioxide-based, etc.) for the 2020-2036 period. Value (US$B) forecasts are provided by chemistry for the 2020-2036 period.
- 45 company profiles, including redox flow battery players, cell stack component and material suppliers, and electrolyte manufacturers and suppliers.
| Report Metrics | Details |
|---|---|
| Historic Data | 2015 - Q2 2025 |
| CAGR | The RFB market will grow at a CAGR of 27% for the 2026-2036 period, based on the volume of annual, global installations (GWh). |
| Forecast Period | Q3 2025 - 2036 |
| Forecast Units | GWh, US$B |
| Regions Covered | China, Europe, United States, Japan, All Asia-Pacific, Worldwide |
| Segments Covered | This IDTechEx report provides ten-year market forecasts on the redox flow battery market for the period 2020 - 2036, by capacity (GWh) and market value (US$B). Capacity forecasts are provided by regional and chemistry splits. Chemistries include vanadium (VRFB), organic, all-iron, iron-vanadium (Fe-V), iron-chromium (Fe-Cr), iron-zinc (Fe-Zn), iron-hydrogen (Fe-H), and "other" (encompassing e.g., saltwater, hydrogen-manganese, microemulsion, carbon dioxide-based, etc. |
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詳細
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担当: 村越美和子 m.murakoshi@idtechex.com
| 1. | EXECUTIVE SUMMARY |
| 1.1. | Global redox flow battery market headlines and key commentary |
| 1.2. | Key drivers and opportunities for redox flow batteries and adjacent markets |
| 1.3. | Key challenges for redox flow batteries and adjacent markets |
| 1.4. | Energy storage technology classification |
| 1.5. | RFBs - decoupling energy and power (1) |
| 1.6. | RFBs - decoupling energy and power (2) |
| 1.7. | What is long duration energy storage? |
| 1.8. | RFBs - decoupling energy and power for LDES and comparison to Li-ion BESS |
| 1.9. | Market timing for LDES technologies: Global average electricity generation mix from VRE |
| 1.10. | Redox flow battery applications and timeline overview |
| 1.11. | LCOS of vanadium redox flow battery versus Li-ion battery (4h, 6h, 8h, 10h duration) |
| 1.12. | Redox flow batteries vs Li-ion battery energy storage systems - installation by GWh, market overview, and key advantages |
| 1.13. | UK 'Cap and Floor Scheme' overview and timeline |
| 1.14. | Redox flow battery technology and chemistry outlook |
| 1.15. | RFB technology benchmarking (Capex, electrolyte cost, commercial status, voltage, energy density, energy efficiency, electrolyte solubility, etc.) |
| 1.16. | RFB strengths, weaknesses and commercial status by chemistry |
| 1.17. | RFB component and material trends to reduce costs and improve performance |
| 1.18. | Overview of RFB stack components |
| 1.19. | RFB components material summary - incumbent and future materials |
| 1.20. | RFB cell stack materials map |
| 1.21. | IEM materials contribute significantly to overall RFB stack cost |
| 1.22. | Enabling reduced RFB cell costs with higher power densities |
| 1.23. | RFB materials & components supplier and player map |
| 1.24. | Overview of vanadium supply, production, V2O5 prices in 2025 and long-term trends |
| 1.25. | Redox flow battery market - key trends, player activity, partnerships, chemistries, funding, installations & applications |
| 1.26. | Redox flow battery deployments by region 2015 - 2025 |
| 1.27. | Cumulative redox flow battery deployments and market share by player (MWh) |
| 1.28. | Cumulative redox flow batteries installed by chemistry (MWh) |
| 1.29. | RFB technology developer map by chemistry |
| 1.30. | RFB projects 2023-2025 by application - C&I vs grid-scale by MWh |
| 1.31. | RFB developer funding and investments received Q3 2023 - Q2 2025 (US$M) and cumulative funding |
| 1.32. | Key global identified RFB project installations 2023-2025 |
| 1.33. | Key and identified future global RFB projects map |
| 1.34. | Global RFB and electrolyte production capacity by player and region map (MWh / annum, chemistry) |
| 1.35. | Global RFB production and electrolyte production expansions: Player and region map |
| 1.36. | RFB developer and electrolyte supply deals and joint ventures (JV) map |
| 1.37. | New alternative RFB chemistry manufacturer entrants and project developers in the global RFB market |
| 1.38. | Key RFB developer closures and restructures |
| 1.39. | Redox flow battery forecasts by region (GWh) 2020-2036 |
| 1.40. | Redox flow battery forecasts by chemistry (GWh) 2020-2036 |
| 1.41. | RFB chemistry market share forecast and analysis |
| 1.42. | Redox flow battery forecasts by value (US$B) 2020-2036 |
| 1.43. | Access more with an IDTechEx subscription |
| 2. | APPLICATIONS, LONG DURATION ENERGY STORAGE, POLICY, PROGRAMS & LEVELIZED COST OF STORAGE |
| 2.1. | Summary |
| 2.1.1. | Redox flow battery applications and timeline overview |
| 2.2. | Applications and Revenue Streams |
| 2.2.1. | The three core BESS market segments |
| 2.2.2. | Applications and revenues overview |
| 2.2.3. | Business models and revenue streams overview |
| 2.2.4. | Revenue stream descriptions |
| 2.2.5. | FTM: Values provided by battery storage in ancillary services |
| 2.2.6. | FTM: Values provided by battery storage in utility services |
| 2.2.7. | BTM summary: Values provided by battery storage - customer side |
| 2.2.8. | Microgrids and remote locations |
| 2.2.9. | Established RFB application examples |
| 2.2.10. | Redox flow batteries for data centers - emerging application (1) |
| 2.2.11. | Redox flow batteries for data centers - emerging application (2) |
| 2.2.12. | Redox flow batteries for data centers - emerging application (3) |
| 2.2.13. | RFB for data center support - key project (1) |
| 2.2.14. | RFB for data center support - key project (2) |
| 2.2.15. | RFBs for residential applications? |
| 2.3. | Introduction to Long Duration Energy Storage |
| 2.3.1. | Energy storage technology classification |
| 2.3.2. | Advantages and disadvantages of energy storage technologies |
| 2.3.3. | What is long duration energy storage? |
| 2.3.4. | Introduction to variable renewable energy (VRE) |
| 2.3.5. | Global outlook of electricity generated by VRE |
| 2.3.6. | GW, GWh and duration of storage (hours) vs electricity generation % from VRE |
| 2.3.7. | Market timing for LDES technologies: Global average electricity generation mix from VRE |
| 2.3.8. | The earlier adopting regions of LDES |
| 2.3.9. | LDES revenue generation challenges and further research on Long Duration Energy Storage by IDTechEx |
| 2.4. | RFB & LDES Policies and Programs |
| 2.4.1. | Flow Batteries Europe - policymaking for flow batteries in Europe |
| 2.4.2. | DESNZ - LDES and energy storage support programs |
| 2.4.3. | DESNZ - UK 'Cap and Floor Scheme' timelines |
| 2.4.4. | The Faraday Institution - Views on demand for LDES and future UK market and programmes for ultra-low cost LDES technologies |
| 2.4.5. | California Energy Commission - development of BESS / LDES in California (1) |
| 2.4.6. | California Energy Commission - development of BESS / LDES in California (2) |
| 2.4.7. | OBBBA: FEOC restrictions, MACR thresholds and impact on 45X Production Credit eligibility |
| 2.4.8. | Section 48 Investment Tax Credit (ITC) after The OBBBA |
| 2.4.9. | Hungary's Ministry of Energy - views on Hungarian electricity and ESS market, and tender for energy storage |
| 2.4.10. | Austria's Department for Renewable Energy Generation - new Acts to promote BESS, RFB, and LDES growth |
| 2.5. | Perspectives on RFB Business & Project Development |
| 2.5.1. | CellCube - views on Austrian market for LDES and RFBs |
| 2.5.2. | CellCube - emerging RFB markets, tenders, and key applications |
| 2.5.3. | EDP - energy operator and investor's perspective on RFBs and key pilot projects |
| 2.5.4. | Verbund - energy utility's involvement in RFB project development and views on electricity markets |
| 2.5.5. | R.Flo - RFBs to rebuild Ukraine's energy grid, business cases and electricity markets in Ukraine |
| 2.5.6. | Vanevo - RFB component supplier's views on business cases for RFBs, LCOE, and 24/7 clean PPAs |
| 2.5.7. | Invinity Energy Systems - importance of stakeholder collaboration in RFB project development |
| 2.6. | RFB LCOS Calculations |
| 2.6.1. | LCOS of vanadium redox flow battery versus Li-ion battery (4h, 6h, 8h, 10h duration) |
| 2.6.2. | LCOS Calculation: Formula and assumptions (1) |
| 2.6.3. | LCOS Calculation: Formula and assumptions (2) |
| 2.6.4. | LCOS Calculation: Formula and assumptions (3) |
| 2.6.5. | LCOS Calculation: Formula and assumptions (4) |
| 2.6.6. | LCOS Calculation: Considerations and limitations (1) |
| 2.6.7. | LCOS Calculation: Considerations and limitations (2) |
| 2.6.8. | VRFB levelized cost of storage conclusions (1) |
| 2.6.9. | VRFB levelized cost of storage conclusions (2) |
| 3. | REDOX FLOW BATTERY TECHNOLOGIES AND CHEMISTRIES |
| 3.1. | Summary: Redox Flow Battery Technologies and Chemistries |
| 3.1.1. | Executive summary - RFB technologies and chemistries |
| 3.1.2. | RFB technology benchmarking (Capex, electrolyte cost, commercial status, voltage, energy density, energy efficiency, electrolyte solubility, etc.) |
| 3.1.3. | RFB strengths, weaknesses and commercial status by chemistry |
| 3.1.4. | RFB technology developer map by chemistry |
| 3.2. | Introduction to Redox Flow Battery Technologies |
| 3.2.1. | Summary - RFB component and material trends to reduce costs and improve performance |
| 3.2.2. | Definitions - RFB electrochemistry |
| 3.2.3. | Definitions - efficiencies |
| 3.2.4. | RFBs - decoupling energy and power (1) |
| 3.2.5. | RFBs - decoupling energy and power (2) |
| 3.2.6. | RFBs - decoupling energy and power for LDES and comparison to Li-ion BESS (1) |
| 3.2.7. | RFBs - decoupling energy and power for LDES and comparison to Li-ion BESS (2) |
| 3.2.8. | RFBs - Fit-and-forget philosophy |
| 3.2.9. | Comparison of RFBs vs fuel cells |
| 3.2.10. | Choice of redox-active species and solvents (1) |
| 3.2.11. | Choice of redox-active species and solvents (2) |
| 3.2.12. | Redox flow battery classification (1) |
| 3.2.13. | Redox flow battery classification (2) |
| 3.2.14. | RFB historical timeline |
| 3.3. | Redox Flow Battery Chemistries |
| 3.3.1. | All vanadium RFB (VRFB) |
| 3.3.2. | VRFB strengths and weaknesses |
| 3.3.3. | All-iron RFB |
| 3.3.4. | All-iron RFB strengths and weaknesses |
| 3.3.5. | Zinc-iron (Zn-Fe) RFB |
| 3.3.6. | Alkaline Zn-Ferricyanide RFB |
| 3.3.7. | Zn-Fe RFB strengths and weaknesses |
| 3.3.8. | Iron-chromium (Fe-Cr) RFB |
| 3.3.9. | Fe-Cr RFB strengths and weaknesses |
| 3.3.10. | Iron-vanadium (Fe-V) RFB |
| 3.3.11. | Fe-V RFB strengths and weaknesses |
| 3.3.12. | Hydrogen-iron (H-Fe) RFB |
| 3.3.13. | H-Fe RFB strengths and weaknesses |
| 3.3.14. | Hydrogen-manganese (H-Mn) RFB |
| 3.3.15. | H-Mn strengths and weaknesses |
| 3.3.16. | Organic redox flow batteries (ORFB) |
| 3.3.17. | Classification of ORFBs |
| 3.3.18. | Active species for ORFBs |
| 3.3.19. | ORFBs strengths and weaknesses |
| 3.3.20. | Hydrogen-bromine (H-Br) RFB |
| 3.3.21. | H-Br RFB strengths and weaknesses |
| 3.3.22. | Zinc-bromine (Zn-Br) RFB |
| 3.3.23. | Zn-Br RFB strengths and weaknesses |
| 3.3.24. | Polysulfides-bromine (PSB) RFB |
| 3.3.25. | PSB historical timeline |
| 3.3.26. | PSB key weakness |
| 3.3.27. | Vanadium-bromine (V-Br) RFB |
| 3.3.28. | V-Br RFB strengths and weaknesses |
| 3.3.29. | Acid-base (salt water) 'flow battery' |
| 4. | MATERIALS AND COMPONENTS FOR REDOX FLOW BATTERY CELL STACKS |
| 4.1. | Materials and Components Summary |
| 4.1.1. | Summary - RFB component and material trends to reduce costs and improve performance |
| 4.1.2. | Introduction to the RFB system |
| 4.1.3. | Overview of RFB stack components |
| 4.1.4. | RFB components material summary - incumbent and future materials |
| 4.1.5. | RFB cell stack materials map |
| 4.1.6. | Key material choices for RFBs |
| 4.1.7. | IEM materials contribute significantly to overall RFB stack cost |
| 4.1.8. | Enabling reduced RFB cell costs with higher power densities |
| 4.1.9. | RFB materials & components supplier and player map |
| 4.1.10. | Further research on ion exchange membranes (IEMs), electrodes, bipolar plates (BPP) and other components |
| 4.1.11. | Membranes for Redox Flow Batteries |
| 4.1.12. | Ion exchange membranes for RFBs summary |
| 4.1.13. | Ion exchange membranes in redox flow batteries: Introduction |
| 4.1.14. | Ion exchange membranes in redox flow batteries: Overview |
| 4.1.15. | RFB cell stack materials map |
| 4.1.16. | Choice of separator - ion exchange membranes (IEMs) vs porous separators |
| 4.1.17. | Perfluorinated and hydrocarbon ion exchange membranes |
| 4.1.18. | Overview of redox flow battery chemistries and IEM requirements |
| 4.1.19. | Impact of potential ban on PFAS materials on RFB market |
| 4.1.20. | Key membrane manufacturers, by membrane material |
| 4.1.21. | Comparison of PFSA membrane supplier and membrane properties |
| 4.1.22. | Commercial hydrocarbon AEM material examples (I) |
| 4.1.23. | Commercial hydrocarbon AEM material examples (II) |
| 4.1.24. | Syensqo - Hydrocarbon-based ionomer for redox flow battery membranes and costs of hydrocarbon membranes |
| 4.1.25. | Syensqo - Hydrocarbon membrane performance for redox flow batteries |
| 4.1.26. | IEM material innovation areas in RFBs (I) |
| 4.1.27. | IEM material innovation areas in RFBs (II) |
| 4.1.28. | IEM material innovation areas in RFBs (III) |
| 4.1.29. | Innovation areas for reinforced multilayer IEMs |
| 4.2. | Electrodes for Redox Flow Batteries |
| 4.2.1. | Overview of electrodes for RFBs - function & characteristics |
| 4.2.2. | Overview of electrodes for RFBs - substrate materials & catalysts |
| 4.2.3. | Common electrode catalysts for different RFB chemistries |
| 4.2.4. | Flow-nano - nanostructured electrode development and process for redox flow batteries |
| 4.2.5. | Flow-nano - nanostructured electrode performance for RFBs |
| 4.2.6. | Flow-nano - scale-up of RFB electrode manufacturing process and continued carbon nano-onion development |
| 4.2.7. | Flow-nano - nanostructured electrode cost benefit for redox flow batteries |
| 4.2.8. | Advanced Carbon Materials - recycled activated carbon and graphite felt electrodes for RFBs |
| 4.3. | Bipolar Plates for Redox Flow Batteries |
| 4.3.1. | Overview of bipolar plates in RFBs - functions & materials |
| 4.3.2. | Overview of bipolar plates in RFBs - materials & manufacturing |
| 4.3.3. | Bipolar plate flow fields |
| 4.3.4. | Comparison of flow fields |
| 4.3.5. | Key manufacturers for RFB bipolar plates |
| 4.3.6. | Schmalz - Improved flow frame design to minimizing pressure loss and shunt currents in RFBs |
| 4.3.7. | Future directions for bipolar plate flow fields |
| 4.4. | Gaskets, Seals & Cell Frames for Redox Flow Batteries |
| 4.4.1. | Gaskets for RFBs |
| 4.4.2. | RFB gasket functions & requirements |
| 4.4.3. | Gasket design considerations |
| 4.4.4. | Gasket material selection (1/2) |
| 4.4.5. | Gasket material selection (2/2) |
| 4.4.6. | Gasket and sealant suppliers for redox flow batteries |
| 4.4.7. | WEVO-CHEMIE - RFB gaskets, sealants and adhesives (1) |
| 4.4.8. | WEVO-CHEMIE - RFB gaskets, sealants and adhesives (2) |
| 4.4.9. | WEVO-CHEMIE's gasket manufacturing considerations, advantages and supply for RFB applications |
| 4.4.10. | O-ring & injection molded gaskets |
| 4.4.11. | Cell frames |
| 4.5. | Other Components for Redox Flow Batteries |
| 4.5.1. | Current collector plates - overview and key materials |
| 4.5.2. | Current collector plates - innovations and key suppliers |
| 4.5.3. | End plates / insulation boards for RFBs |
| 4.5.4. | Syensqo - PPS endplates |
| 4.5.5. | Pinflow - RFB component provider and support for RFB developers |
| 4.5.6. | BioZen Batteries - RedoxinoTM mini flow cell test system |
| 5. | REDOX FLOW BATTERY MARKET, VANADIUM ELECTROLYTE MARKET, AND KEY UPDATES |
| 5.1. | Redox Flow Battery Market Summary, Updates & Data Analysis |
| 5.1.1. | Redox flow battery market executive summary - key trends, player activity, partnerships, chemistries, funding, installations & applications |
| 5.1.2. | Redox flow battery deployments by region 2015-2025 |
| 5.1.3. | Cumulative redox flow battery deployments and market share by player (MWh) |
| 5.1.4. | Cumulative redox flow batteries installed by chemistry (MWh) |
| 5.1.5. | RFB technology developer map by chemistry |
| 5.1.6. | RFB projects 2023-2025 by application - C&I vs grid-scale by MWh |
| 5.1.7. | RFB projects 2023-2025 by application - grid-scale project application analysis |
| 5.1.8. | RFB projects 2023-2025 by application - C&I project application analysis |
| 5.1.9. | RFB developer funding and investments received Q3 2023 - Q2 2025 (US$M) |
| 5.1.10. | Cumulative RFB developer funding (US$M) |
| 5.1.11. | Key global identified RFB project installations 2023-2025 |
| 5.1.12. | Key and identified future global RFB projects map |
| 5.1.13. | Global RFB and electrolyte production capacity by player and region map (MWh / annum, chemistry) |
| 5.1.14. | Global RFB production and electrolyte production expansions: Player and region map |
| 5.1.15. | RFB developer and electrolyte supply deals and joint ventures (JV) map |
| 5.1.16. | Key RFB developer and electrolyte producer joint ventures and partnerships (1) |
| 5.1.17. | Key RFB developer and electrolyte producer joint ventures and partnerships (2) |
| 5.1.18. | New alternative RFB chemistry manufacturer entrants and project developers in the global RFB market |
| 5.1.19. | Key RFB developer closures and restructures |
| 5.1.20. | Historical RFB projects raw data table 2023-2025 [technology provider, partners, MW, MWh, duration of storage, chemistry, year deployed, country, region, application, C&I vs grid] (1) |
| 5.1.21. | Historical RFB projects raw data table 2023-2025 [technology provider, partners, MW, MWh, duration of storage, chemistry, year deployed, country, region, application, C&I vs grid] (2) |
| 5.1.22. | Historical RFB projects raw data table 2023-2025 [technology provider, partners, MW, MWh, duration of storage, chemistry, year deployed, country, region, application, C&I vs grid] (3) |
| 5.1.23. | Future RFB projects raw data table (2026-2027) [technology provider, partners, MW, MWh, duration of storage, chemistry, future year deployed, country, region, application, C&I vs grid] |
| 5.1.24. | Future RFB projects raw data table (2028-2029+) [technology provider, partners, MW, MWh, duration of storage, chemistry, future year deployed, country, region, application, C&I vs grid] |
| 5.1.25. | RFB production capacity and expansions: Raw data table [MWh / annum, location] |
| 5.1.26. | Vanadium electrolyte production capacity and expansions raw data table [player, MWh / annum, location, RFB customer] |
| 5.2. | Key RFB Players, VRFB Technologies, and Project Updates 2023-2025 |
| 5.2.1. | Rongke Power - Updates from globally leading RFB player |
| 5.2.2. | Saudi Aramco - Fe-V RFB development and scale-up in Saudi Arabia and key partnership with Rongke Power (1) |
| 5.2.3. | Rongke Power Key VRFB Projects |
| 5.2.4. | Saudi Aramco - Fe-V RFB development and scale-up in Saudi Arabia and key partnership with Rongke Power (2) |
| 5.2.5. | Sumitomo Electric - VRFBs and global activity |
| 5.2.6. | Sumitomo Electric - configuration, energy density, technology CapEx, and vanadium markets |
| 5.2.7. | Invinity Energy Systems - key market updates and discussion |
| 5.2.8. | Invinity Energy Systems overview and design for changing duration of storage |
| 5.2.9. | Invinity Energy Systems - Endurium VRFB technology (1) |
| 5.2.10. | Invinity Energy Systems - Endurium VRFB technology (2) |
| 5.2.11. | Invinity Energy Systems - tolerance of metal impurities in electrolyte, electrolyte additives, and cost |
| 5.2.12. | CellCube - VRFB technology development and insights from site visit |
| 5.2.13. | CellCube - Insights from site visit, manufacturing process, quality control, and cell stack evolution |
| 5.2.14. | CellCube - strategies to manage vanadium electrolyte imbalance and changes in oxidation state (1) |
| 5.2.15. | CellCube - strategies to manage vanadium electrolyte imbalance and changes in oxidation state (2) |
| 5.2.16. | CellCube - strategies to manage vanadium electrolyte imbalance and changes in oxidation state (3) |
| 5.2.17. | Idemitsu Kosan - VRFB project development in Australia with Sumitomo Electric and views on lack of LDES value proposition in Australia |
| 5.2.18. | FlexBase - development of RFB project for data center application (1) |
| 5.2.19. | RFB for data center support - key project (2) |
| 5.2.20. | H2, Inc. - key VRFB project in Spain, system architecture, and lessons learned with component transportation logistics |
| 5.2.21. | H2, Inc. - Latest VRFB technology and performance metrics |
| 5.2.22. | VFlowTech - VRFB demonstration project in Singapore |
| 5.2.23. | Fraunhofer ICT - Development of VRFB in project SMHYLES |
| 5.3. | Vanadium Electrolyte Market & Updates |
| 5.3.1. | Executive summary - overview of vanadium supply, production, V2O5 prices in 2025 and long-term trends |
| 5.3.2. | Global vanadium production by region and technique |
| 5.3.3. | Vanadium price trend and spikes in demand pre-2022 |
| 5.3.4. | Raw materials for RFB electrolytes |
| 5.3.5. | Vanadium overview |
| 5.3.6. | Vanadium mining and products (1) |
| 5.3.7. | Vanadium mining and products (2) |
| 5.3.8. | Vanadium ore processing |
| 5.3.9. | Vanadium junior miners and projects |
| 5.3.10. | Vanadium electrolyte recycling |
| 5.3.11. | Vanadium electrolyte leasing |
| 5.3.12. | Electrolyte leakage mitigation |
| 5.3.13. | RFB developer and electrolyte supply deals and joint ventures (JV) map |
| 5.3.14. | Key RFB developer and electrolyte producer joint ventures and partnerships (1) |
| 5.3.15. | Key RFB developer and electrolyte producer joint ventures and partnerships (2) |
| 5.3.16. | Idemitsu Kosan - supporting mining operations and vanadium electrolyte production in Australia and expansion plans to the US |
| 5.3.17. | R&D Investment Center / Adamant CTC - vanadium production (V2O5) and FeV mining |
| 5.3.18. | Storion Energy - vanadium electrolyte manufacturer targeting US production and electrolyte leasing model |
| 5.3.19. | Storion Energy - impacts of electrolyte leasing and cell stacks on upfront VRFB costs |
| 5.4. | Non-Vanadium RFB Players, Technologies and Projects (organic, Fe-Cr, Zn-Mn, H-Mn, all-iron, saltwater) |
| 5.4.1. | Redox One / Tharisa - iron-chromium RFB development (1) |
| 5.4.2. | Redox One / Tharisa - iron-chromium RFB development (2) |
| 5.4.3. | Redox One / Tharisa - iron-chromium RFB development (3) |
| 5.4.4. | Zinc-Manganese RFB performance and cost |
| 5.4.5. | Electrodes to promote stability in Zn-Mn RFBs |
| 5.4.6. | Improving performance of Zinc-Bromine RFBs |
| 5.4.7. | Performance and stability of Hydrogen-Manganese RFB (1) |
| 5.4.8. | Performance and stability of Hydrogen-Manganese RFB (2) |
| 5.4.9. | RFC Power - development of H-Mn RFB technology and projects |
| 5.4.10. | ESS Inc. overview and all-iron RFB technology |
| 5.4.11. | ESS Inc. all-iron RFB technology updates |
| 5.4.12. | ESS Inc. key market updates and discussion |
| 5.4.13. | TNO / ESS Inc. - All-iron RFB project at Schiphol Airport |
| 5.4.14. | AquaBattery - development of saltwater flow battery (1) |
| 5.4.15. | AquaBattery - development of saltwater flow battery (2) |
| 5.4.16. | AquaBattery - development of saltwater flow battery (3) |
| 5.4.17. | Quino Energy - organic RFB development overview |
| 5.4.18. | Quino Energy - organic RFB anolyte development and synthesis |
| 5.4.19. | Quino Energy - organic RFB projects and applications (1) |
| 5.4.20. | Quino Energy - organic RFB projects and applications (2) |
| 5.4.21. | Quino Energy - organic RFB costs and performance |
| 5.4.22. | Iberian Center for Research in Energy Storage - improving electrode hydrophilicity for improved ORFB performance |
| 5.4.23. | Jolt Energy - development of ORFB technology with pyridinium |
| 5.4.24. | Jolt Energy - use of machine learning AI in non-aqueous organic RFB development |
| 5.4.25. | Rivus Batteries - organic RFB developer |
| 5.5. | Redox Flow Battery Market Q3 2021 - Q2 2023 updates timeline |
| 5.5.1. | Q3 2021 - Q4 2022 timeline |
| 5.5.2. | Q1 2023 - Q2 2023 timeline |
| 5.5.3. | September 2021 - February 2022 |
| 5.5.4. | February 2022 - July 2022 |
| 5.5.5. | August 2022 - November 2022 |
| 5.5.6. | November 2022 - February 2023 |
| 5.5.7. | February 2023 - March 2023 |
| 5.5.8. | April 2023 - June 2023 |
| 6. | REDOX FLOW BATTERY FORECASTS 2020-2036 |
| 6.1. | Executive summary - redox flow battery forecasts 2020-2036 |
| 6.2. | Assumptions, methodology & key changes for redox flow battery forecasts 2020-2036 (1) |
| 6.3. | Assumptions, methodology & key changes for redox flow battery forecasts 2020-2036 (2) |
| 6.4. | Redox flow battery forecasts by region (GWh) 2020-2036 |
| 6.5. | Redox flow battery forecasts by region data table (MWh) 2020-2036 |
| 6.6. | Redox flow battery forecasts by chemistry (GWh) 2020-2036 |
| 6.7. | Redox flow battery forecasts by chemistry data table (MWh) 2020-2036 |
| 6.8. | RFB chemistry market share forecast and analysis |
| 6.9. | Redox flow battery forecasts by value (US$B) 2020-2036 |
| 6.10. | Redox flow battery forecasts by value data table (US$B) 2020-2036 |
| 7. | COMPANY PROFILES |
| 7.1. | Agora Energy Technologies |
| 7.2. | AquaBattery |
| 7.3. | AvCarb |
| 7.4. | BioZen Batteries |
| 7.5. | CellCube (2025) |
| 7.6. | CellCube (2023) |
| 7.7. | CMBlu Energy (2024) |
| 7.8. | CMBlu Energy (2023) |
| 7.9. | Elestor (2023) |
| 7.10. | Elestor (2023) |
| 7.11. | ESS Inc. (2024) |
| 7.12. | ESS Inc. (2023) |
| 7.13. | FlexBase |
| 7.14. | Flow-nano |
| 7.15. | Fumatech |
| 7.16. | Green Energy Storage (GES) |
| 7.17. | H2, Inc. (2025) |
| 7.18. | H2, Inc. (2023) |
| 7.19. | Hyproof Tech. |
| 7.20. | Idemitsu Kosan (Vanadium Electrolyte) |
| 7.21. | Invinity Energy Systems (2025) |
| 7.22. | Invinity Energy Systems (2024) |
| 7.23. | Invinity Energy Systems (2023) |
| 7.24. | Ionomr Innovations |
| 7.25. | Jolt Energy |
| 7.26. | Kemiwatt |
| 7.27. | Korid Energy/AVESS |
| 7.28. | Largo |
| 7.29. | Pinflow |
| 7.30. | Quino Energy (2025) |
| 7.31. | Quino Energy (2023) |
| 7.32. | RFC Power (2025) |
| 7.33. | RFC Power (2023) |
| 7.34. | Rivus Batteries |
| 7.35. | Rongke Power (2025) |
| 7.36. | Rongke Power (2023) |
| 7.37. | Schmalz |
| 7.38. | Storen Technologies |
| 7.39. | Storion Energy |
| 7.40. | Sumitomo Electric Industries (2025) |
| 7.41. | Sumitomo Electric Industries (2023) |
| 7.42. | VFlowTech |
| 7.43. | VRB Energy |
| 7.44. | WattJoule |
| 7.45. | WeView (& ViZn Energy) |
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レポート概要
| スライド | 357 |
|---|---|
| フォーキャスト | 2036 |
| 発行日 | Nov 2025 |
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