EVバッテリー用防火材料の2023年から2034年にかけての年平均成長率は16.3%
電気自動車バッテリー用防火材料 2024-2034年:市場、トレンド、予測
電気自動車、バス、バン、トラック、マイクロモビリティ向けの防火材料および熱暴走対策材料。セラミック、マイカ、エアロゲル、封止材、発泡材、コーティング、相変化材料など。ベンチマーク評価と予測。
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内燃機関車と比べて火災発生率は低いものの、電気自動車にとって、防火性は不可欠で、材料にいくつかのビジネス機会をもたらします。本レポートでは、規制動向やバッテリー設計のトレンドと、それらがセラミック、マイカ、エアロゲル、コーティング、封止材、発泡材、圧縮パッド、相変化材料といった防火材料にどう影響するかを考察しています。また材料・車両セグメント別の年間需要量と市場価値の市場予測を提供しています。
「電気自動車バッテリー用防火材料 2024-2034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)
● 概要
● 電気自動車の火災、リコール、熱暴走の事例
● EVにおける現行の安全規制概要
● セル・ツー・パック、セル・ツー・ボディを含むセル・パック設計の概要
● 防火材料のベンチマーク評価、比較、有力企業:
□ セラミックおよびその他の不織布
□ マイカ
□ エアロゲル
□ コーティング(発泡性防火塗料など)
□ 封止材
□ 発泡封止材
□ 防火特性を備えた圧縮パッド
□ 相変化材料
□ 防火材料としてのポリマー
□ その他の材料カテゴリー
● 液浸冷却の概要と防火への影響
● EVにおける防火材料のユースケース:
□ 自動車
□ 大型車および商用車
□ その他の車両カテゴリー
● 筐体材料の影響
● ブスバー・高電圧ケーブルの絶縁
● 10年間の市場予測:
□ 材料別に見るセル間の保護(kg)
□ 材料別に見るパック単位の保護(kg)
□ 材料別に見る防火材料総量(kg)
□ 材料別に見る防火材料総額(ドル)
□ 車両カテゴリー別に見る防火材料総量(kg)
□ 車両カテゴリー別に見る防火材料総額(ドル)
Electric vehicle (EV) fire safety continues to be a critical topic. Data continues to support the fact that EVs are less likely to catch fire than internal combustion engine vehicles. However, as a new technology, EVs get more press, and besides, even a very low occurrence rate still poses significant risks to vehicle occupants and surroundings. Effective thermal management, quality control, and battery management systems minimize the risk of thermal runaway occurring, but fire protection materials are the primary method of either preventing the propagation of thermal runaway or delaying its progression long enough to meet regulations and provide safety for occupants.
IDTechEx's report on Fire Protection Materials for Electric Vehicle Batteries analyzes trends in battery design, safety regulations, and how these will impact fire protection materials. The report benchmarks materials directly and in application within EV battery packs. The materials covered include ceramic blankets/sheets (and other non-wovens), mica, aerogels, coatings (intumescent and other), encapsulants, encapsulating foams, compression pads, phase change materials, and several other materials. 10-year market forecasts are included by material and vehicle category.
Whilst automotive markets provide the largest battery demand, there are large opportunities for material suppliers in other vehicle segments such as buses, trucks, vans, 2-wheelers, 3-wheelers, and microcars. Some of these smaller vehicle sectors present an even greater risk to owners, as they are often charged or kept inside the home.
Variety in battery design and evolution
Various cell formats and battery structures are used in the EV market. In 2022, 55% of new electric cars sold used prismatic battery cells, with pouch cells accounting for 24% and the rest using cylindrical. Each of these cell formats has different needs in terms of inter-cell materials which has led to trends in fire protection material adoption. For example, cylindrical systems have largely used encapsulating foams, whereas prismatic systems typically use materials in sheet format such as mica.
Many manufacturers are also moving towards a cell-to-pack design where module housings (and a host of other materials) are removed, leading to improved energy density, but potentially more challenging thermal runaway propagation prevention. These design choices all greatly impact the choice and deployment of fire protection materials and hence are covered in IDTechEx's report to aid in determining material demands.
Many materials are applicable for fire protection in EV batteries. Source: IDTechEx - "Fire Protection Materials for EV Batteries 2024-2034: Markets, Trends, and Forecasts"
Ceramic blankets have been a common choice to provide protection above the cells and below the lid and to delay the propagation of fire outside the pack. Mica sheets are another popular choice with excellent dielectric performance at thin thicknesses between cells but are often used in thicker sheets above modules. Aerogels are continuing to see market progress with significant adoption in China, but also now globally with adoption from GM, Toyota, and Audi to name a few.
The use of encapsulating foams has also seen significant adoption for cylindrical cell battery packs with the likes of Tesla, to provide lightweight thermal insulation and structure. For pouch cells, compression pads are commonplace to accommodate cell swelling and several material suppliers are starting to combine this functionality with fire protection to provide a multifunctional solution.
There are many material options in addition to the ones discussed above, and polymer suppliers are making a big push to provide major components of the battery pack with fire-retardant polymers or even polymers with intumescent properties. These have the potential to be lighter, more customizable in geometry, and lower cost that metals and fire protection materials combined. However, there are still significant challenges here, such as integrating EMI shielding and providing the necessary crash performance.
Developments in safety regulations
Many will be aware that China was an early adopter of thermal runaway specific regulations, with, among other requirements, a need to prevent fire or smoke exiting the battery pack for 5 minutes after the event occurs.
The regulations in other regions are getting closer to being formalized with the UN ECE regulation continuing to be revised. Whilst the specific targets are still in flux, it is very likely that detection of thermal runaway will be required, followed by an "escape time" for vehicle occupants. The 5-minute escape time is unlikely to be sufficient for future regulations and more effective thermal runaway propagation measures will be necessary. Therefore OEMs have started to target longer escape times in order to pre-empt future regulations and improve overall safety.
IDTechEx's report discusses the regulations that are currently in place and those being discussed. These feed into IDTechEx's market forecasts showing a greater adoption of fire protection materials per vehicle. However, this must be paired with trends around battery development that can often reduce material use per vehicle. The variety of battery designs and material solutions presents a large opportunity across several markets and suppliers. IDTechEx predicts this market will grow at 16.3% CAGR from 2023 to 2034.
Key aspects of this report
Overview and evolution of:
- Electric vehicle fires and thermal runaway
- Electric vehicle recalls related to fires
- Regulations in different global regions
Material analysis and trends including thermal conductivity, dielectric strength, density, and more for:
- Ceramics (and other non-wovens)
- Mica
- Aerogels
- Coatings (intumescent and other)
- Encapsulants
- Encapsulating foams
- Compression pads (with fire protection properties)
- Phase change materials
- Polymers as fire protection materials
- Other material categories
10 year market forecasts & analysis:
- EV battery demand for cars, buses, trucks, vans, scooters, and motorcycles (GWh)
- Cell-to-cell protection by material (kg)
- Pack-level protection by material (kg)
- Total fire protection by material (kg)
- Total fire protection by material (US$)
- Total fire protection by vehicle category (kg)
- Total fire protection by vehicle category (US$)
| Report Metrics | Details |
|---|---|
| Historic Data | 2021 - 2023 |
| CAGR | 16% |
| Forecast Period | 2023 - 2034 |
| Forecast Units | kg, US$ |
| Regions Covered | Worldwide |
| Segments Covered | Cars, buses, trucks, vans, 2 wheelers, 3 wheelers, microcars, ceramics, aerogels, mica, encapsulants, foams, compression pads, coatings, phase change materials |
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担当: 村越美和子 m.murakoshi@idtechex.com
| 1. | EXECUTIVE SUMMARY |
| 1.1. | Thermal Runaway and Fires in EVs |
| 1.2. | Battery Fires and Related Recalls (automotive) |
| 1.3. | Automotive Fire Incidents: OEMs and Situations |
| 1.4. | EV Fires: When do They Happen? |
| 1.5. | Conclusions on Solid-state Battery Safety |
| 1.6. | Summary of Na-ion Safety |
| 1.7. | Regulations |
| 1.8. | Cell Format Market Share |
| 1.9. | Drivers and Challenges for Cell-to-pack |
| 1.10. | Thermal Runaway in Cell-to-pack |
| 1.11. | Fire Protection Materials: Main Categories |
| 1.12. | Material Comparison |
| 1.13. | Market Shares in 2023 and 2034 |
| 1.14. | Density vs Thermal Conductivity - Thermally Insulating |
| 1.15. | Material Intensity (kg/kWh) |
| 1.16. | Pricing Comparison in a Cylindrical Cell Battery (inter-cell) |
| 1.17. | Pricing Comparison in a Pouch Cell Battery (inter-cell) |
| 1.18. | Pricing Comparison in a Prismatic Cell Battery (inter-cell) |
| 1.19. | Pricing Comparison in a Battery (pack-level) |
| 1.20. | Cell-level Fire Protection Materials Forecast (mass) |
| 1.21. | Pack-level Fire Protection Materials Forecast (mass) |
| 1.22. | Total Fire Protection Materials Forecast (mass) |
| 1.23. | Total Fire Protection Materials Forecast (value) |
| 1.24. | Total Fire Protection Materials by Vehicle (value) |
| 2. | INTRODUCTION |
| 2.1. | Overview |
| 2.1.1. | Thermal Runaway and Fires in EVs |
| 2.2. | Fires and Recalls in EVs |
| 2.2.1. | Battery Fires and Related Recalls (automotive) |
| 2.2.2. | GM's Bolt Recall |
| 2.2.3. | Hyundai Kona Recall |
| 2.2.4. | VW PHEV Recall |
| 2.2.5. | Ford Kuga PHEV Recall |
| 2.2.6. | Automotive Fire Incidents: OEMs and Situations |
| 2.2.7. | Electric Scooter Fires in India |
| 2.2.8. | Electric Bus Fires |
| 2.2.9. | EV Fires Compared to ICEs (1) |
| 2.2.10. | EV Fires Compared to ICEs (2) |
| 2.2.11. | Issues with EV and ICE Fire Comparisons |
| 2.2.12. | Severity of EV Fires |
| 2.2.13. | EV Fires: When do They Happen? |
| 2.3. | Causes and Stages of Thermal Runaway |
| 2.3.1. | Causes of Failure |
| 2.3.2. | The Nail Penetration test |
| 2.3.3. | Stages of Thermal Runaway (1) |
| 2.3.4. | Stages of Thermal Runaway (2) |
| 2.3.5. | LiB Cell Temperature and Likely Outcome |
| 2.3.6. | Cell Chemistry and Stability |
| 2.3.7. | Cell Chemistry Impact on Fire Protection |
| 2.3.8. | Cathode Market Share for Li-ion in EVs (2015-2034) |
| 2.3.9. | Thermal Runaway Propagation |
| 2.3.10. | The Impact of Solid-state Batteries |
| 2.3.11. | Are Solid-state Batteries Safer? |
| 2.3.12. | Conclusions on Solid-state Battery Safety |
| 2.3.13. | Na-ion Battery Safety |
| 2.3.14. | 0 V Capability of Na-ion Systems |
| 2.3.15. | Summary of Na-ion Safety |
| 2.4. | Regulations |
| 2.4.1. | Regulations |
| 2.4.2. | China |
| 2.4.3. | Europe |
| 2.4.4. | Europe (Revision 3, 2022) |
| 2.4.5. | US |
| 2.4.6. | UN-GTR20 Phase 2 Standard Act and Beyond |
| 2.4.7. | Regulation Landscape |
| 2.4.8. | India |
| 2.4.9. | What Does it all Mean for EV Battery Design? |
| 3. | CELL AND PACK DESIGN |
| 3.1. | Introduction |
| 3.1.1. | Cell Types |
| 3.1.2. | Which Cell Format to Choose? |
| 3.1.3. | Cell Format Market Share |
| 3.1.4. | Li-ion Batteries: from Cell to Pack |
| 3.1.5. | What's in a Battery Module? (pouch/prismatic) |
| 3.1.6. | What's in a Battery Module? (cylindrical) |
| 3.1.7. | What's in an EV Battery Pack? |
| 3.2. | Cell-to-Pack, Cell-to-Chassis, and Large Cell Formats |
| 3.2.1. | What is Cell-to-pack? |
| 3.2.2. | Drivers and Challenges for Cell-to-pack |
| 3.2.3. | What is Cell-to-chassis/body? |
| 3.2.4. | Gravimetric Energy Density and Cell-to-pack Ratio |
| 3.2.5. | Volumetric Energy Density and Cell-to-pack Ratio |
| 3.2.6. | Outlook for Cell-to-pack & Cell-to-body Designs |
| 3.2.7. | Thermal Runaway in Cell-to-pack |
| 3.2.8. | Material Intensity Changes in Cell-to-pack |
| 4. | FIRE PROTECTION MATERIALS |
| 4.1. | Introduction |
| 4.1.1. | What are Fire Protection Materials? |
| 4.1.2. | Thermally Conductive or Thermally Insulating? |
| 4.1.3. | Fire Protection Materials: Main Categories |
| 4.1.4. | Composition and Application of Each Material Category |
| 4.1.5. | Advantages and Disadvantages |
| 4.1.6. | Market Maturity, OEM Use-cases, and Suppliers |
| 4.1.7. | Material Comparison |
| 4.1.8. | Material Market Shares 2023 |
| 4.1.9. | Market Shares in 2023 and 2034 |
| 4.2. | Material Testing for Thermal Runaway |
| 4.2.1. | How to Screen Materials for Thermal Runaway |
| 4.2.2. | UL Torch and Grit Test |
| 4.2.3. | UL BETR |
| 4.3. | Material Benchmarking: Thermal, Electrical, and Mechanical Properties |
| 4.3.1. | Thermal Conductivity Comparison |
| 4.3.2. | Density Comparison |
| 4.3.3. | Density vs Thermal Conductivity - Thermally Insulating |
| 4.3.4. | Density vs Thermal Conductivity - Cylindrical Cell Systems |
| 4.3.5. | Dielectric Strength Comparison |
| 4.3.6. | Fire Protection Temperature Comparison |
| 4.3.7. | Material Intensity (kg/kWh) |
| 4.4. | Material Benchmarking: Costs |
| 4.4.1. | Pricing Comparison: Volumetric and Gravimetric |
| 4.4.2. | Pricing Comparison in a Cylindrical Cell Battery (inter-cell) |
| 4.4.3. | Pricing Comparison in a Pouch Cell Battery (inter-cell) |
| 4.4.4. | Pricing Comparison in a Prismatic Cell Battery (inter-cell) |
| 4.4.5. | Pricing Comparison in a Battery (pack-level) |
| 4.5. | Ceramics and Other Non-Wovens |
| 4.5.1. | Typical Properties of Ceramic Blankets/papers |
| 4.5.2. | Challenges with Ceramic Blankets |
| 4.5.3. | 3M |
| 4.5.4. | Alkegen |
| 4.5.5. | Dongguan Taiya Electronic Technology Co., Ltd. |
| 4.5.6. | Luyang Energy-Saving Materials Co., Ltd. |
| 4.5.7. | MAFTEC Concept (EDAG, Mitsubishi Chemical Group, Kreisel) |
| 4.5.8. | Morgan Advanced Materials |
| 4.6. | Mica |
| 4.6.1. | Muscovite and Phlogopite Mica |
| 4.6.2. | Typical Properties of Mica Sheets |
| 4.6.3. | Challenges with Mica |
| 4.6.4. | Asheville Mica |
| 4.6.5. | Axim Mica |
| 4.6.6. | COGEBI |
| 4.6.7. | Elmelin |
| 4.6.8. | Von Roll |
| 4.7. | Aerogels |
| 4.7.1. | Why aerogels? |
| 4.7.2. | Aerogels |
| 4.7.3. | Concerns for Aerogels in EV Batteries and How They're Addressed |
| 4.7.4. | Historic Uptake |
| 4.7.5. | Current Applications of Aerogels in China |
| 4.7.6. | Current Applications of Aerogels in China (2) |
| 4.7.7. | Aspen Aerogels |
| 4.7.8. | JIOS Aerogel |
| 4.7.9. | Alkegen |
| 4.7.10. | Toray |
| 4.7.11. | SAIC/GM: Aerogels |
| 4.7.12. | Cabot Corporation |
| 4.8. | Coatings |
| 4.8.1. | Coatings (intumescent and other) |
| 4.8.2. | Challenges for Coatings |
| 4.8.3. | Henkel |
| 4.8.4. | H.B. Fuller |
| 4.8.5. | Parker Lord |
| 4.8.6. | PPG |
| 4.8.7. | Sika |
| 4.8.8. | NeoGraf - Graphite Additives for Reactive Coatings |
| 4.8.9. | WEVO Chemie |
| 4.8.10. | Other Examples of EV Battery Fire Protection Coatings |
| 4.9. | Encapsulants (excluding foams) |
| 4.9.1. | Encapsulants/potting |
| 4.9.2. | DEMAK - resin potting for batteries |
| 4.9.3. | ELANTAS |
| 4.9.4. | Epoxies, Etc. |
| 4.9.5. | Huntsman |
| 4.9.6. | Von Roll |
| 4.10. | Encapsulating Foams |
| 4.10.1. | Foams |
| 4.10.2. | Challenges with Encapsulating Foams |
| 4.10.3. | Asahi Kasei - Cell Holder Foams |
| 4.10.4. | Solimide/Polyimide Foam |
| 4.10.5. | CHT Silicones |
| 4.10.6. | Dow Silicones |
| 4.10.7. | Elkem |
| 4.10.8. | H.B. Fuller |
| 4.10.9. | Parker Lord |
| 4.10.10. | Zotefoams - Nitrogen Foam |
| 4.11. | Compression Pads with Fire Protection |
| 4.11.1. | Compression Pads |
| 4.11.2. | Dow |
| 4.11.3. | Freudenberg Sealing Technology |
| 4.11.4. | Rogers Corporation |
| 4.11.5. | Saint-Gobain |
| 4.12. | Phase Change Materials |
| 4.12.1. | Phase Change Materials (PCMs) |
| 4.12.2. | PCM Categories and Pros and Cons |
| 4.12.3. | Phase Change Materials - Players |
| 4.12.4. | PCMs - Players in EVs |
| 4.12.5. | AllCell (Beam Global) |
| 4.12.6. | PCMs - Use-case and Outlook |
| 4.13. | Tapes |
| 4.13.1. | Tapes for Fire Protection |
| 4.13.2. | ATP Adhesive Systems |
| 4.13.3. | Avery Denison |
| 4.13.4. | Coroplast Tape |
| 4.13.5. | Lohmann Tapes |
| 4.13.6. | Rogers |
| 4.13.7. | Tesa Tapes |
| 4.14. | Polymers as Fire Protection |
| 4.14.1. | Fire Retardant Additives (1) |
| 4.14.2. | Fire Retardant Additives (2) |
| 4.14.3. | How Polymers Can Address Thermal Runaway (1) |
| 4.14.4. | How Polymers Can Address Thermal Runaway (2) |
| 4.14.5. | How Polymers Can Address Thermal Runaway (3) |
| 4.14.6. | Covestro - Flame-retardant Plastics |
| 4.14.7. | LG Chem - Fire Protection Plastic |
| 4.15. | Other Fire Protection Materials |
| 4.15.1. | AIS |
| 4.15.2. | Elven Technologies |
| 4.15.3. | Alternative Thermal Barriers |
| 4.15.4. | 3M - Thermal Barriers |
| 4.15.5. | ADA Technologies |
| 4.15.6. | AOK Technology |
| 4.15.7. | Armacell |
| 4.15.8. | DuPont - Nomex |
| 4.15.9. | H.B. Fuller - Flame-resistant Pack Seal |
| 4.15.10. | HeetShield - Ultra-thin Insulations |
| 4.15.11. | KULR Technology - NASA's solution |
| 4.15.12. | Pyrophobic Systems |
| 4.15.13. | Stokvis Tapes - Fire Protection Materials |
| 4.15.14. | svt Group |
| 4.16. | Summary |
| 4.16.1. | Fire Protection Materials Outlook |
| 5. | IMMERSION COOLING |
| 5.1. | Immersion Cooling: introduction |
| 5.2. | Immersion Cooling Fluids Requirements |
| 5.3. | Immersion Cooling Architecture |
| 5.4. | Players: Immersion Fluids for EVs (1) |
| 5.5. | Players: Immersion Fluids for EVs (2) |
| 5.6. | Immersion Fluids: Density and Thermal Conductivity |
| 5.7. | Immersion Fluids: Summary |
| 5.8. | SWOT Analysis |
| 5.9. | IDTechEx Outlook |
| 5.10. | What Does it Mean for Fire Protection Materials? |
| 6. | FIRE PROTECTION MATERIAL USE-CASES |
| 6.1. | Use-Cases: Automotive |
| 6.1.1. | Faraday Future FF91 |
| 6.1.2. | Ford Mustang Mach-E |
| 6.1.3. | GAC Aion |
| 6.1.4. | GMC Hummer EV Example |
| 6.1.5. | Hyundai E-GMP |
| 6.1.6. | Jaguar I-PACE |
| 6.1.7. | Lucid Air |
| 6.1.8. | MG ZS |
| 6.1.9. | Mercedes EQS |
| 6.1.10. | Mercedes GLC300e PHEV |
| 6.1.11. | Polestar |
| 6.1.12. | Rivian |
| 6.1.13. | Tesla 4680 pack |
| 6.1.14. | Tesla Model 3/Y |
| 6.1.15. | Tesla Model 3/Y prismatic LFP pack |
| 6.1.16. | Tesla Model S P85D |
| 6.1.17. | Tesla Model S Plaid |
| 6.1.18. | Voyah (Dongfeng) |
| 6.1.19. | VW MEB Platform |
| 6.2. | Use-Cases: Heavy Duty and Commercial Vehicles |
| 6.2.1. | American Battery Solutions |
| 6.2.2. | Ford Transit |
| 6.2.3. | Lion Electric - self extinguishing modules |
| 6.2.4. | Nissan e-NV200 |
| 6.2.5. | Romeo Power |
| 6.2.6. | Voltabox |
| 6.2.7. | Xerotech |
| 6.2.8. | XING Mobility |
| 6.3. | Use-Cases: Other |
| 6.3.1. | Cadenza Innovation - stationary energy storage |
| 6.3.2. | Hero Maxi (lead-acid) |
| 6.3.3. | Ola Hyperdrive battery |
| 7. | BATTERY PACK ENCLOSURES |
| 7.1. | Impact of Enclosure Material on Fire Protection |
| 7.2. | Battery Enclosure Materials and Competition |
| 7.3. | From Steel to Aluminium |
| 7.4. | Towards Composite Enclosures? |
| 7.5. | Composite Enclosure EV Examples (1) |
| 7.6. | Composite Enclosure EV Examples (2) |
| 7.7. | Alternatives to Phenolic Resins |
| 7.8. | Are Polymers Suitable Housings? |
| 7.9. | Plastic Intensive Battery Pack from SABIC |
| 7.10. | Polymers Replacing Metals |
| 7.11. | Composites with Fire Protection |
| 7.12. | Examples of Fire Protection with Composite Enclosure Players |
| 7.13. | Adding Fire Protection to Composite Parts |
| 7.14. | Envalior - Plastic Enclosure for HV Battery |
| 7.15. | Composite Enclosure Outlook |
| 8. | BUSBARS AND HIGH VOLTAGE CABLE INSULATION |
| 8.1. | Why Busbars and Cables Need Fire Protection |
| 8.2. | Busbar Insulation Materials |
| 8.3. | HV Cable Insulation Operating Temperature Benchmark |
| 8.4. | Polymer Players in Busbar Insulation (1) |
| 8.5. | Polymer Players in Busbar Insulation (2) |
| 8.6. | Polymer Players in Busbar Insulation (3) |
| 8.7. | Polymer Players in Busbar Insulation (4) |
| 8.8. | Busbar, Interconnect, and HV Cable Insulation Demand Forecast 2021-2034 (kg) |
| 9. | FORECASTS |
| 9.1. | EV Battery Demand Forecast (GWh) |
| 9.2. | Methodology: Material Intensity (kg/kWh) |
| 9.3. | Methodology: Cell Formats |
| 9.4. | Cell-level Fire Protection Materials Forecast (mass) |
| 9.5. | Pack-level Fire Protection Materials Forecast (mass) |
| 9.6. | Total Fire Protection Materials Forecast (mass) |
| 9.7. | Material Pricing |
| 9.8. | Total Fire Protection Materials Forecast (value) |
| 9.9. | Fire Protection Materials Forecast by Vehicle Type (mass) |
| 9.10. | Total Fire Protection Materials by Vehicle (value) |
| 9.11. | Comparison with Previous Forecasts |
| 10. | COMPANY PROFILES |
| 10.1. | ADA Technologies |
| 10.2. | Aerobel |
| 10.3. | Aerogel Core Ltd |
| 10.4. | AllCell Technologies (Beam Global): Phase Change Material for EVs |
| 10.5. | Amphenol Advanced Sensors |
| 10.6. | Armacell |
| 10.7. | Asahi Kasei: Fire Retardant Plastics |
| 10.8. | Ascend Performance Materials: High Temperature PA66 |
| 10.9. | Aspen Aerogels: Aerogels for EV Battery Packs |
| 10.10. | Axalta Coating Systems |
| 10.11. | Cadenza Innovation |
| 10.12. | Carrar: Two-Phase Immersion Cooling for EVs |
| 10.13. | e-Mersiv |
| 10.14. | Elven Technologies: Fire Protection Materials |
| 10.15. | Freudenberg Sealing Technologies: EV Inter-Cell Fire Protection |
| 10.16. | FUCHS: Dielectric Immersion Fluids for EVs |
| 10.17. | H.B. Fuller: Fire Protection Materials for EV Batteries |
| 10.18. | IBIH Advanced Materials |
| 10.19. | JIOS Aerogel |
| 10.20. | Johnson Controls: Thermal Runaway Detection and Prevention |
| 10.21. | Keey Aerogel |
| 10.22. | KULR Technology |
| 10.23. | LG Chem |
| 10.24. | Pyrophobic Systems: Fire Protection Materials for EVs |
| 10.25. | Rogers Corporation: Compression Pads With Fire Protection |
| 10.26. | WEVO Chemie: Battery Thermal Management Materials |
| 10.27. | Xerotech |
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電気自動車バッテリー用防火材料 2024-2034年:市場、トレンド、予測
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レポート概要
| スライド | 311 |
|---|---|
| 企業数 | 27 |
| フォーキャスト | 2034 |
| 発行日 | Feb 2024 |
| ISBN | 9781835700167 |
コンテンツのプレビュー
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