Chat with us, powered by LiveChat 레독스 플로우 배터리 (2020-2030년): 전망, 과제, 기회: IDTechEx

레독스 플로우 배터리 (2020-2030년): 전망, 과제, 기회: IDTechEx

바나듐 플로우 배터리가 RFB 시장을 지배하며 시장의 50% 이상을 차지

레독스 플로우 배터리 (2020-2030년): 전망, 과제, 기회

주거용에서 그리드 스케일 응용분야에 이르기까지, 바나듐, 유기 및 플로우 배터리의 기술 및 시장 분석

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바나듐 기술이 전체 시장의 95%를 차지하면서, 유틸리티 배터리 부문에서 성장하는 플로우 배터리 시장이 확대되고 있다. 이 보고서는 현재 시장 및 향후 기회에 대한 개요와 함께 플로우 배터리 기술에 대한 포괄적이고 심층적인 분석을 제공한다. 이로써 OEM, 화학 기업 및 투자자는 레독스(산화 환원 플로우 배터리 산업의 현재 기술 개발, 시장 규모 및 향후 기회를 이해할 수 있다.
The modernization and decarbonization of the electricity grid are setting a big challenge for the electric grid operators. To integrate and update the electricity grid, energy storage devices are one of the main solutions adopted, allowing the storage of the excess electricity produced by renewable energy sources, besides providing ancillary services, and stabilising the grid.
Within the different energy storage technologies, the electrochemical devices are one of the most common choices because of their location flexibility, efficiency, and scalability. From different electrochemical devices available, the Redox flow batteries (RFBs) are one of the most chosen solutions for medium and large-scale applications. The fast time response (in the range of milli seconds), a long cycle life (more than 20,000 cycles), and their easily recyclable components, allow the RFBs to steadily increase their adoption on the market.
While the stationary energy storage market is currently dominated by Li-ion batteries, redox flow batteries are slowly being adopted with an increasing number of projects all over the world.
The redox flow batteries have been developed for more than 40 years, and available on the market for almost 20 years. The flow battery producers, in particular vanadium redox flow battery (VRFB) manufacturers, have abundantly developed, tested, and demonstrated the technology over the years, reaching an overall installation of roughly 70MW of power and 250 MWh of energy. Flow battery producers keep receiving funding to expand manufacture, improve their products and reduce the technology cost. Moreover, solid collaborations between flow battery manufacturers, OEMs, and chemical and mining companies are taking place all over the world, with the common target to make this technology competitive on the market.
To better understand the flow battery market and forecast future developments, IDTechEx performed an in-depth analysis of the different types of flow batteries, investigating the historical development of each technology and related flow battery market evolution. Moreover, to understand the technological development, and the adoption of this technology in the next years, several companies were profiled.
The results of these studies, presented in this report, revealed a market dominated by one of the oldest technologies, the vanadium redox flow battery (VRFB), which accounts for more than 50% of the available companies commercialising flow batteries. Besides the VRFB, other flow battery manufacturers are developing flow batteries based on different electrolytes, like the Organic flow battery (ORFB), and All-iron (Fe-RFB), Hydrogen/Bromine or Zinc/Bromine flow batteries (ZBB). In the report a summary of the main properties of each electrolyte are presented.
The reader will understand the possibilities and the challenges of each type of electrolyte, explained in a simple and concise way. It will allow to evaluate himself/herself the characteristics of each technology, and related chances to conquer its share of the market.
Besides the investigation of different electrolytes, an analysis of the battery electrode stack, one of the core parts of this technology, is provided. The different components of the electrode stack are explained, together with investigating the different possible materials employed. This would allow investors, OEMs and chemical companies, to understand the different materials involved, and where further improvements will be required.
Besides the technical prospective of the technology, IDTechEx investigated why, and how, different countries are involved in the adoption of RFBs. Therefore, Chapter 5 provides an overview of different countries, covering Europe, US, Africa, and China, where it is explained how these countries are approaching the flow battery technology.
From these wide and in-depth techno-economic analysis, IDTechEx aims to facilitate investors, OEMs and chemical industries to understand the current redox flow battery market, and its future development between 2020-2030.
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모든 보고서 구입에는 전문가 분석가와의 최대 30분의 전화통화 시간이 포함되어, 보고서의 주요 결과를 귀하가 제시하는 비즈니스 문제에 연결하도록 돕습니다. 이 전화통화는 보고서를 구매한 후 3개월 이내에 사용해야합니다.
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Table of Contents
1.1.The slow market of Redox Flow Batteries
1.2.Market forecast: Market Insight
1.3.Market forecast: Considerations
1.4.IDTechEx Flow Battery Forecast
1.5.Market forecast: Assumptions
1.6.Market forecast: Market Share
1.7.Companies in this Report
1.8.Market Analysis: Redox flow battery Market Overview
1.9.Market Analysis: TRL and MRL explanation
1.10.Market Analysis: Flow Battery on the Market
1.11.Market Analysis: Companies TRL, MRL Evaluation
1.12.Market Analysis: Technology Market Share
1.13.Market Analysis: Company Market Share
1.14.Market Analysis: Companies Power/Energy Product Comparison
1.15.Market Analysis: Energy Densities Comparison for Residential Sector
1.16.Redox flow batteries in the news
1.17.From the News: BASF interests in Flow Batteries
1.18.From the News: ViZn... back on the scene!
1.19.From the News: CellCube Part 1 - 100 MWh in USA
1.20.From the News: CellCube Part 2 - 120 MWh in UK
1.21.From the News: CellCube Part 3 - "Enerox for Sale"
1.22.From the News: Schmid Group from China to Saudi Arabia.
1.23.From the News: Shell: from Vanadium (RFB) to LIB
1.24.From the News: Voltstorage on the News
1.25.From the News: Bushveld, the company that created its future
2.1.Useful charts for performance comparison
2.2.Definitions: What is a battery?
2.3.Definitions: Electrochemistry definitions
2.4.Electrochemistry definitions
2.5.Definitions: Efficiencies
2.6.Definitions: Cross-Mixing, and Shunt current
2.7.Redox Flow Battery: Energy & Power
2.8.Redox Flow Battery: Decoupled power and energy
2.9.Redox Flow Battery: Working Principle
2.10.Redox Flow Battery: Fit-and-forget philosophy
2.11.Redox Flow Battery: RFB views
2.12.What does 1 kilowatt-hour (kWh) look like?
2.13.Finding the right market
2.14.New avenues for stationary storage
2.15.The battery trilemma
2.16.The increasingly important role of stationary storage
2.17.Stationary energy storage is not new
2.18.New avenues for stationary storage
2.19.Values provided at the customer side
2.20.Values provided at the utility side
2.21.Values provided in ancillary services
2.22.Comparison of RFBs and conventional batteries
2.23.Competing technologies: Li-ion
2.24.Competing technologies: Tesla PowerWall
2.25.Competing technologies: LCOS of Li-ion and RFBs
2.26.Competing technologies: Na/S
2.27.The case for RFBs
2.28.The case for RFBs: A Comparison
2.29.The case for RFBs: Stationary Batteries Comparison
2.30.The case for RFBs: RFB Cost
2.31.The case for RFBs: LCOS
2.32.Redox flow batteries and caves
2.33.Redox Flow Batteries for Automotive
2.34.Redox Flow Batteries for Automotive: GE
2.35.Redox Flow Batteries for Automotive: Toyota
2.36.Redox Flow Batteries for Automotive: nanoFlowcell
3.1.Definition: Gaseous and liquid electrodes
3.2.Definition: Catholytes and anolytes
3.3.Choice of redox-active species and solvents
3.4.Redox Flow Battery Classification
3.5.History of RFB
3.6.RFB chemistries: Iron/Chromium
3.7.RFB chemistries: Polsulfides/Bromine flow batteries (PSB)
3.8.RFB chemistries: Vanadium/Bromine
3.9.RFB chemistries: All Vanadium (VRFB)
3.10.RFB chemistries: Zinc Bromine flow battery (ZBB) - Hybrid
3.11.RFB chemistries: Hydrogen/Bromide - Hybrid
3.12.RFB Chemistries: all Iron - Hybrid
3.13.Other RFBs: Organic Redox Flow Battery
3.14.Other RFBs: non-aqueous
3.15.Other RFBs: Lab-scale flow battery projects
3.16.Other RFBs: Microflow batteries?
3.17.Technology Recap
3.18.Cost factors at electrolyte level
3.19.Hype Curve® for RFB technologies
4.1.Materials for Redox Flow Batteries
4.2.Membranes: Overview
4.3.Membranes: Mesoporous Separators
4.4.Membranes: Ionic Exchange Membranes (IEM)
4.5.Membranes: Composite Membranes, and Solid State Conductors
4.6.Bipolar Electrodes
4.7.Bipolar Electrodes: Parasitic Effect
4.8.Bipolar Electrodes: Electrode Materials
4.9.Electrodes: Carbon-based Electrodes
4.10.(Bipolar) Electrodes
4.11.Flow distributors and turbulence promoters
4.12.Electrolyte flow circuit
4.13.Cost breakdown of a Vanadium-redox flow battery
4.14.RFB value chain
4.15.Raw materials for RFB electrolytes
4.16.Vanadium: Overview
4.17.Vanadium: Mining and Products
4.18.Vanadium: Ore Processing
4.19.The Vanadium Industry
4.20.Vanadium: Price Trend
5.1.Case Study: Bushveld Energy
5.2.Case Study: RedT / Avalon Battery Merge
5.3.Case Study: Jena Batteries
5.4.Regional Analysis: EU
5.5.Regional Analysis: China
5.6.Regional Analysis: U.S.
5.7.Regional Analysis: Australia
5.8.Regional Analysis: South Africa
5.9.Company Profiles
6.2.Technology and manufacturing readiness
6.3.List of RFB Producers: Categorized Chemistry

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