電動建設車両は2043年には2022年の非EV市場と同等の1500億ドル市場に
建設機械の電気自動車 2023-2043年
電動ミニ油圧ショベル、電動油圧ショベル、電動ローダー、テレハンドラーなどを含む建設業向け電動建設機械の技術分析。台数、GWh需要と売上高の20年間予測(地域別と車両タイプ別)。
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IDTechExの『建設機械の電気自動車 2023-2043年』は建設機械の電動化トレンドを徹底分析しています。100種以上の建機のデータベース分析により、バッテリーサイズ、バッテリー価格への影響、性能を理解することができます。対象となる建設機械にはミニ油圧ショベル、油圧ショベル、ローダーなどがあります。4地域と7建機タイプの20年間予測はこの市場がどのようにして2043年に1500億米ドルに成長するのかを示しています。
「建設機械の電気自動車 2023-2043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)
● 全体概要と結論
● イントロダクション
□ 建機OEMと市場
□ 電動建設機械の背景と障壁
□ 環境/健康へのインパクト
● 事例検証
対象となる建機
□ 電動ミニ油圧ショベル(6トン未満)
□ 電動油圧ショベル(6トン超)
□ 電動コンパクトローダー、バックホウローダー、ホイールローダー
□ 電動テレハンドラー、自走式クレーン、その他建設車両
● 実施した分析
□ 電動ミニ油圧ショベルと電動油圧ショベルの特定車両の詳細
□ ミニ油圧ショベルと油圧ショベルのバッテリーサイズ分析
□ OEM電動油圧ショベル開発の事例検証
□ モーターサイズ分析と既存ディーゼルとの比較
□ ディーゼル燃料消費と電力消費分析
□ エネルギーコスト削減分析
□ メンテナンスコスト削減分析
□ 潜在的補助金と排出課徴金インパクト分析
● 主な要素技術
□ リチウムイオン電池: LFPまたはNMC、エネルギー密度、価格体系
□ ナトリウムイオンのイントロダクション
□ 各種モーター: 牽引モータータイプ、サプライヤー、油圧式、全電動化システム
□ 水素: 燃料電池と水素燃焼、長所と短所、バッテリー駆動電動式
● 市場予測2023-2043年:
□ 方式と推計
□ 売上(台数)、バッテリー需要(GWh)、市場規模(米ドル)
□ 建機カテゴリー別予測
□ 地域予測: ヨーロッパ、中国、米国、その他地域
「建設機械の電気自動車 2023-2043年」は以下の情報を提供します
電動建設機械メーカー分析
- 技術トレンド
- バッテリーサイズ分析
- バッテリー価格、損益分岐点、投資収益率分析
- 排気ゼロの建機開発の背景と障壁
- 電動ミニ油圧ショベル(6トン未満)
- 電動中型・大型油圧ショベル(6トン超)
- 電動コンパクトローダー/バックホウローダー/ホイールローダー
- 電動テレハンドラーと自走式クレーン
- 主な要素技術、バッテリーとモーター
- 水素燃料電池/水素燃焼
市場予測と分析:
- 売上(台数)、バッテリー需要(GWh)、市場収益によるバッテリー駆動式電動建設機械の20年間市場予測
- 中国、米国、ヨーロッパ(EU + UK +EFTA)、その他地域
- 7つの建設機械(ミニ油圧ショベル、油圧ショベル、バックホウローダー、その他ローダー、自走式クレーン、テレハンドラー、その他の建機)の個別予測ライン
IDTechEx's report "Electric Vehicles in Construction 2023-2043" provides deep and granular analysis into this fast-growing industry. More than 100 electric construction machines have been analyzed to reveal trends in battery sizing, charging, vehicle power, pricing, and more. These technical trends are explored in detail throughout this report.
The electric construction machine market is in its nascent stages. However, it will benefit from other sectors having already gone through electrification and will be able to accelerate quickly with existing supply chains for batteries, motors, and other electric vehicle components that it will need to make this transition. OEMs are moving quickly to electrify their product ranges. This has started with mini-electric excavators but is now progressing to larger machines. This report considers OEM activities, policy drivers, and potential total cost of ownership savings to predict a 10-year CAGR of 38%, and growth to an electric construction machine market value of ~$150 billion in 2043. This will put the construction industry on target to hit international carbon neutrality goals by 2050.
Electric mini-excavators are taking-off
Mini-excavators are the third largest segment by volume in the world, and the largest segment in Europe. With its smaller size necessitating reasonably sized batteries, it has been a low hanging fruit for the construction industry to begin their electrification journey. In 2023 six out of the top ten largest construction OEMs, including Caterpillar, Komatsu, Kubota, and Hitachi either had a production electric mini-excavator, or had a concept or prototype. JCB and Volvo are companies with examples of series production electric mini-excavators and have helped to kick-start the electric mini-excavator market. Both of these have their own targets to reduce emissions but will also be responding to market demand.
Electric mini excavators offer all the performance of diesel variants but with some significant advantages. Firstly, it improves local air quality and more importantly the air quality for the operator who will be exposed to high concentrations of exhaust gases. The operator will also benefit from reduced noise, reduced vibration, and improved safety through better communication with other site workers thanks to the machines lower noise. The electric motors will also give more precise control over the machine, and in the long term, aid the integration of autonomous features, such as automated digging.
More electric machines are coming, and they are getting larger
With the electric mini-excavator market becoming established, OEMs are already moving onto larger machines. Large excavators with operating weights of more than 6-tonne, and similarly sized loaders, are the two areas where OEMs like Caterpillar, John Deere, XCMG, Komatsu, Volvo, and LiuGong are looking to electrify next. Loaders and excavators make up nearly 55% of construction vehicle sales by volume. Excavators are the largest by volume, and with their increased size comes higher prices, meaning they also dominate revenue.
Chinese OEMs in particular have shown interest in electrifying larger excavators and installing large batteries. One example covered in this report uses a 525kWh battery and double gun-DC charging to replenish this enormous battery in just 2 hours. However, the biggest battery IDTechEx has scene in an excavator is 700kWh from a Japanese OEM also covered in this report.
Within China, LFP appears to be the cell of choice for these larger systems, which makes sense given its lower cost and the vehicles not being sensitive to the extra weight. Meanwhile, Europe has tended to go with NMC as its cell of choice for batteries in electric construction machines. NMC offers better performance, but at additional cost. This report goes into detail on the trade-offs between NMC and LFP relating to construction, while also explaining how lithium-ion battery price reductions can sway the balance between choosing an electric construction machine, or a diesel.
Adoption will likely be driven by reduced TCO rather than policy
On an international scale, construction emissions are not at the forefront of governments concerns in their goals to address global warming and GHG emissions. The construction machine industry is only responsible for 1.1% of GHG emissions and will likely be one of the last vehicle types to get targeted by internal combustion ban policies. On a local scale, countries like Norway, and the Netherlands have shown some activity in tackling emissions from construction vehicles. These are mostly focused on local issues, like local air quality, and reducing noise from building sites.
A better incentive for the adoption, and the mechanism needed to establish growth in the electric construction machine market will be total cost of ownership savings. Construction machinery can burn through a lot of fuel. For example, IDTechEx's analysis shows that over its lifetime a 20-tonne excavator will cost around $120,000 just to fuel. On top of that is maintenance of a large diesel engine, which can also amount to tens of thousands of dollars over the vehicle's lifetime. This creates a large potential window for generating savings through the use of electric vehicles. However, this US$120k can quickly be consumed by the cost of batteries required to give these machines their 8 hours of operation. Local incentives can help tip the TCO balance in favor of electric while battery prices are coming down, but in the long term, the combination of fuel savings, reduced emissions and increased performance and precision, will lead to electric machines winning out.
| Report Metrics | Details |
|---|---|
| Historic Data | 2021 - 2022 |
| CAGR | The electric construction vehicle market is taking off imminently and will grow have a 10-year CAGR of 37% |
| Forecast Period | 2023 - 2043 |
| Forecast Units | Unit sales, revenue (US$), battery demand (GWh) |
| Regions Covered | Worldwide |
| Segments Covered | Mini-excavators, excavators, backhoe loaders, other loaders, telehandlers, cranes, other construction vehicles. |
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担当: 村越美和子 m.murakoshi@idtechex.com
| 1. | EXECUTIVE SUMMARY |
| 1.1. | Report Summary |
| 1.2. | Key Report Findings (1) |
| 1.3. | Key Report Findings (2) |
| 1.4. | Construction Vehicles |
| 1.5. | Key Construction Machine Types for Electrification |
| 1.6. | Construction Market Continues to Bounce Back |
| 1.7. | Top 15 Construction Market Players |
| 1.8. | Electrification Activity of Major Construction OEMs (1) |
| 1.9. | Electrification Activity of Major Construction OEMs (2) |
| 1.10. | Drivers for Construction Vehicle Electrification |
| 1.11. | TCO Drivers for Electric Construction Vehicles |
| 1.12. | Advantages of / Barriers to Machine Electrification |
| 1.13. | Technology Positioning for Construction Equipment |
| 1.14. | Performance Advantages of an Electric Excavator |
| 1.15. | Battery Capacity and Operation Runtime |
| 1.16. | Battery Sizes for Different Vehicle Types |
| 1.17. | Options for Meeting Power Duty Cycle Power Demand |
| 1.18. | Electric vs Diesel Break-even: Fuel Cost Saving |
| 1.19. | Electric vs Diesel Break-even: Fuel + Maintenance |
| 1.20. | Battery Price Impact on Break Even Point |
| 1.21. | OEM Dealer Electric Retrofitting Partnerships |
| 1.22. | Engine Manufacturers Looking Toward Electrification |
| 1.23. | Dealer Driven Electrification Development |
| 1.24. | Chinese OEMs Large Battery Excavators |
| 1.25. | Large Electric Excavator Price Premium (Retrofit) |
| 1.26. | Large Electric Excavator Price Premium (OEM) |
| 1.27. | Construction Equipment Electrification Opportunities (1) |
| 1.28. | Construction Equipment Electrification Opportunities (2) |
| 1.29. | EV Construction Machine Sales Forecast by Region |
| 1.30. | Global Construction EV Sales Forecast by Machine Type |
| 1.31. | EV Construction Machines Battery Demand by Machine Type (GWh) |
| 1.32. | EV Construction Machines Market Size by Machine Type (US$ Billions) |
| 2. | INTRODUCTION TO THE CONSTRUCTION INDUSTRY |
| 2.1. | Overview |
| 2.1.1. | Construction Vehicles |
| 2.1.2. | Types of Construction Vehicle |
| 2.1.3. | Top 15 Construction Market Players |
| 2.1.4. | Construction Vehicle Revenue by OEM Region |
| 2.1.5. | CO2 Emission Contribution of Construction Machines |
| 2.1.6. | CO2 Emissions Driver for Construction Machine Electrification |
| 2.1.7. | GHG Emissions: China, US & Europe |
| 2.1.8. | Vehicles a Major Source of Greenhouse Gas Emission |
| 2.1.9. | Emissions by Construction Machine Type |
| 2.1.10. | Urban Air Quality |
| 2.1.11. | Construction Worksite Air Quality |
| 2.1.12. | Fossil Fuel Bans (Cities) |
| 2.1.13. | Emission Standards Target Air Quality not GHG Emission |
| 2.1.14. | Drivers for Construction Vehicle Electrification |
| 2.2. | Regional & Company Emissions Policy & Case Studies |
| 2.2.1. | Norway Pioneering Zero Emission Construction Machines |
| 2.2.2. | The Netherlands, Denmark and Finland |
| 2.2.3. | Electrifying Construction Sites |
| 2.2.4. | Colorado Clean Diesel Program |
| 2.2.5. | UK Incentivizing Decarbonization of Off-road |
| 2.2.6. | Construction Industry Committing to GHG Reductions |
| 2.2.7. | Construction Firms Addressing GHG Emission |
| 2.2.8. | Noise Reduction |
| 2.2.9. | What do Electric Machines Need to Deliver |
| 2.2.10. | Power Demand for Electric Construction Vehicles |
| 2.2.11. | Technology Positioning for Construction Equipment |
| 2.2.12. | Volvo Group Fossil Fuel Free Timeline |
| 2.2.13. | Construction Equipment Electrification Opportunities |
| 2.2.14. | Future Opportunities in Electric Mobile Machinery |
| 2.2.15. | Mobile Equipment Chargers / Hydrogen Fuelling |
| 2.2.16. | Zero Emission Gensets / Microgrids / Energy Storage |
| 2.2.17. | Autonomous Systems and Digitalization |
| 3. | ELECTRIC MINI EXCAVATORS (<6 TONNES) |
| 3.1. | Overview |
| 3.1.1. | Electric Mini-Excavators Summary |
| 3.1.2. | Mini Excavators Leading CE Electrification |
| 3.1.3. | Performance Advantages of an Electric Excavator |
| 3.1.4. | Mini Excavator OEMs |
| 3.1.5. | Electric Mini Excavator Example Specifications |
| 3.1.6. | Electric Mini Excavator Example Specifications |
| 3.1.7. | Mini Excavator: ICE Engine vs Electric Motor Size (kW) |
| 3.1.8. | Mini Excavator Size vs Battery Capacity |
| 3.1.9. | Example mini-excavator battery sizing and runtime |
| 3.1.10. | Battery Capacity and Operation Runtime |
| 3.1.11. | Options for Meeting Power Duty Cycle Power Demand |
| 3.1.12. | Electric Mini-Excavator Price Premium |
| 3.1.13. | ICE Mini-Excavator Fuel Consumption Cost |
| 3.1.14. | Electrification Fuel Cost Saving |
| 3.1.15. | Electric vs Diesel Break-even: Fuel Cost Saving |
| 3.1.16. | Total Cost of Ownership: Maintenance |
| 3.1.17. | Cummins' Electric Mini Excavator Analysis |
| 3.1.18. | Electric vs Diesel Break-even: Fuel + Maintenance |
| 3.1.19. | Incentivising Electric Machines: Low Emission Zones |
| 3.1.20. | Incentivizing Through Emissions Charges |
| 3.1.21. | Early Electric Machine Deployment: Rental Companies |
| 3.1.22. | OEM Dealer Electric Retrofitting Partnerships |
| 3.1.23. | Engine Manufacturers Looking Toward Electrification |
| 3.1.24. | Electric Mini-Excavators CO2 Emission Saving |
| 3.2. | Mini Excavators: OEM Models & Case Studies |
| 3.2.1. | Volvo Construction Equipment |
| 3.2.2. | Volvo Group |
| 3.2.3. | Volvo Expanding their Electric CE Portfolio |
| 3.2.4. | Volvo EC55 Electric |
| 3.2.5. | Komatsu PC30E-5 Electric Mini-Excavator |
| 3.2.6. | Komatsu Remote Controlled Electric Mini Excavator |
| 3.2.7. | Komatsu / Honda Micro Electric Excavators |
| 3.2.8. | Hyundai Construction Equipment (HCE) |
| 3.2.9. | Yanmar Construction Equipment |
| 3.2.10. | Yanmar Prototype |
| 3.2.11. | Doosan Electric DX17Z-5 Prototype |
| 3.2.12. | Develon (previously Doosan) production ready model |
| 3.2.13. | Doosan (now Develon) & Bobcat E10e / E19e |
| 3.2.14. | JCB E-TECH Electric Mini Excavator |
| 3.2.15. | XCMG XE35U_E |
| 3.2.16. | Wacker Neuson EZ17e |
| 3.2.17. | Takeuchi TB220e |
| 3.2.18. | SUNCAR HK 216E / Takeuchi |
| 3.2.19. | KTEG ZE19 / Hitachi / Suncar HK |
| 3.2.20. | Hitachi Construction Machinery |
| 3.2.21. | Kobelco |
| 3.2.22. | Caterpillar 301.9 |
| 3.2.23. | Limach Electric Mini Excavators |
| 3.2.24. | Kubota Prototype Mini Excavator |
| 3.2.25. | Hybrid Dual Power Diesel-Electric Tethered Excavators |
| 4. | LARGE ELECTRIC EXCAVATORS (>6 TONNES) |
| 4.1. | Overview |
| 4.1.1. | Large Electric Excavators Summary (1) |
| 4.1.2. | Large Electric Excavators Summary (2) |
| 4.1.3. | Medium / Large Excavator OEMs |
| 4.1.4. | Electric Excavators >6t, Summary of Models |
| 4.1.5. | Electric Excavators >6t, Summary of Models |
| 4.1.6. | Large Electric Excavator Emission / Cost Saving |
| 4.1.7. | Excavator (>6t): ICE Engine vs Electric Motor Size (kW) |
| 4.1.8. | Examples Battery Capacity and Operational Runtime |
| 4.1.9. | Battery Capacity and Operation Runtime >6t Excavators |
| 4.1.10. | Annual Fuel Cost Saving Diesel vs Electric Excavators |
| 4.1.11. | >6t Excavator CO2 Emission Saving |
| 4.1.12. | Dealer Driven Electrification Development |
| 4.1.13. | Large Electric Excavator Price Premium (retrofit) |
| 4.1.14. | Break-even electric excavator TCO (OEM) |
| 4.2. | OEM Models & Case Studies |
| 4.2.1. | John Deere - Electric Excavator |
| 4.2.2. | Pon Equipment: CAT Zero Emission Excavators |
| 4.2.3. | Pon Cat 323F Z-line Power Schematic |
| 4.2.4. | Pon Equipment: NextGen Electric Excavators |
| 4.2.5. | Next Generation Pon Cat Excavators |
| 4.2.6. | Caterpillar 320 Now In-house |
| 4.2.7. | Volvo EC230 Electrified Excavator |
| 4.2.8. | Volvo R&D: Large Rear Screen |
| 4.2.9. | Mecalac e12 Electric Wheeled Excavator |
| 4.2.10. | Hidromek HICON 7W |
| 4.2.11. | Hyundai Excavator HX260AL Electric |
| 4.2.12. | Doosan DX300LC Electric |
| 4.2.13. | Doosan Tethered Electric Excavator System |
| 4.2.14. | KTEG ZECOM ZE85 Electric Excavator |
| 4.2.15. | NASTA ZERON Electric Excavators |
| 4.2.16. | NASTA ZERON Electric Excavators |
| 4.2.17. | Hitachi ZX85US-6EB and ZX135US-7EB |
| 4.2.18. | Liebherr R922 BE Electric Crawler |
| 4.2.19. | Limach E88.1 Excavator |
| 4.2.20. | Chinese OEMs Large Battery Excavators |
| 4.2.21. | LiuGong Excavator |
| 4.2.22. | Komatsu Hybrid Hydraulic Excavator |
| 4.2.23. | Komatsu PC 210E with a 700kWh battery! |
| 4.2.24. | Kobelco SK210H Electric Hybrid |
| 4.2.25. | Hydraulic Hybrid Excavators - Not Electric Vehicles |
| 5. | ELECTRIC COMPACT & SKID STEER LOADERS |
| 5.1. | Overview |
| 5.1.1. | Electric Compact Loaders Summary |
| 5.1.2. | Compact Loaders / Skid Steer / Dumpers |
| 5.1.3. | Sales of Compact Loaders |
| 5.1.4. | Electric Compact Loaders / Dumper Example Specs (1) |
| 5.1.5. | Electric Compact Loaders / Dumper Example Specs (2) |
| 5.1.6. | Electric Compact Loaders Motor Size (kW) |
| 5.1.7. | Electric Loader / Dumper Size vs Battery Capacity |
| 5.1.8. | Battery Capacity and Endurance |
| 5.1.9. | Electric Compact Loader Price Premium |
| 5.1.10. | Fuel Savings |
| 5.1.11. | Compact / Skid-steer Loaders OEMs |
| 5.2. | OEM Models & Case Studies |
| 5.2.1. | Volvo L25 Electric Compact Wheel Loader |
| 5.2.2. | Volvo L20 Electric Wheel Loader |
| 5.2.3. | Schäffer 24E Electric Wheel Loader |
| 5.2.4. | Bobcat (Doosan Group) |
| 5.2.5. | Bobcat / Moog: T7X All Electric System |
| 5.2.6. | Gehl Electric Skid Steer with Battery Swap |
| 5.2.7. | Tobroco-Giant G2200E Wheel Loader |
| 5.2.8. | Cat 906 Electric Wheel Loader Concept |
| 5.2.9. | JCB 1T-E Electric Site Dumper |
| 5.2.10. | AUSA D100AHA Electric Dumper |
| 5.2.11. | AUSA D151AEG |
| 5.2.12. | Poclain Hydraulics 1.8t Wheel Loader |
| 5.2.13. | Avant Techno e Series Loaders |
| 5.2.14. | Wacker Neuson WL20e Wheel Loader |
| 5.2.15. | Kovaco Elise 900 |
| 5.2.16. | Kramer 5055e Wheel Loader |
| 5.2.17. | Komatsu - Moog |
| 6. | ELECTRIC BACKHOE LOADERS |
| 6.1. | Overview |
| 6.1.1. | Electric Backhoe Loaders Summary |
| 6.1.2. | Backhoe Loaders |
| 6.1.3. | Example Electric Backhoes |
| 6.1.4. | Fuel Saving Opportunity |
| 6.1.5. | Backhoe: ICE Engine Size (kW) |
| 6.1.6. | Backhoe Loaders |
| 6.2. | OEM Models & Case Studies |
| 6.2.1. | CASE Construction: Project Zeus |
| 6.2.2. | CASE Construction 580 EV |
| 6.2.3. | John Deere 310X-Tier E-Power |
| 6.2.4. | Huddig Electric PHEV Backhoe |
| 6.2.5. | Huddig 1260T: Hybrid Operating Modes |
| 6.2.6. | Huddig Battery / Motor Suppliers |
| 7. | ELECTRIC WHEEL LOADERS (>6T) |
| 7.1. | Overview |
| 7.1.1. | Electric Large Loader Summary |
| 7.1.2. | Wheel Loaders |
| 7.1.3. | Electric Wheel Loaders (>6t) Examples |
| 7.1.4. | Electric X power and weight comparison |
| 7.1.5. | Battery Capacity for Wheel Loaders |
| 7.1.6. | Electrification Cost and Savings |
| 7.1.7. | Savings for Higher Cost Batteries |
| 7.1.8. | High Battery Costs and Lower Utilization |
| 7.1.9. | Fuel Consumption and Savings |
| 7.1.10. | Battery Price Impact on Break Even Point |
| 7.1.11. | Many Chinese Electric Loader Models Emerging |
| 7.1.12. | Dual Gun Ultra-Fast Charging |
| 7.2. | OEM Models & Case Studies |
| 7.2.1. | Caterpillar 950GC - Electric Wheel Loader |
| 7.2.2. | XCMG XC918-EV Electric Loader |
| 7.2.3. | LiuGong 856E-MAX 18.8t Electric Loader |
| 7.2.4. | LuiGong 856H-E MAX |
| 7.2.5. | Danfoss Editron Full Electric Wheel Loader |
| 7.2.6. | Ahlmann AZ 95 Electric Swing Loader |
| 7.2.7. | Greenland GEL-5000 Electric Loader |
| 7.2.8. | XCMG XC958-EV Electric Loader |
| 7.2.9. | Sany SW956E Electric Loader |
| 7.2.10. | Volvo L120H Electric Conversion |
| 7.2.11. | Volvo Electric Site Research Project |
| 7.2.12. | Diesel Electric Hybrid Wheel Loaders |
| 7.2.13. | Diesel Electric Hybrid Wheel Loader Examples |
| 7.2.14. | Cat 988K XE: Electric Drive Wheel Loader |
| 8. | ELECTRIC TELEHANDLERS |
| 8.1. | Overview |
| 8.1.1. | Electric Telehandlers Summary |
| 8.1.2. | Telescopic Handlers |
| 8.1.3. | Electric Telehandler Example Specifications |
| 8.1.4. | Telehandler: ICE Engine vs Electric Motor Size (kW) |
| 8.1.5. | Telehandler battery capacities |
| 8.1.6. | Telehandlers |
| 8.2. | OEM Models & Case Studies |
| 8.2.1. | Liebherr Electric Telescopic Handler - DEUTZ |
| 8.2.2. | JCB 525-60E Electric Telehandler |
| 8.2.3. | JLG Full Electric Telehandler Concept |
| 8.2.4. | Manitou Electric Telehandlers |
| 8.2.5. | Manitou MTE 625 and MT625e Electric |
| 8.2.6. | Faresin / Snorkel Full Electric Telehandler |
| 8.2.7. | Faresin: Aliant Battery Assembly |
| 8.2.8. | XCMG XC6-2506E Telehandler |
| 9. | ELECTRIC MOBILE CRANES |
| 9.1. | Overview |
| 9.1.1. | Electric Mobile Cranes Summary |
| 9.1.2. | Mobile Cranes |
| 9.1.3. | Electric Crane Example Specifications |
| 9.1.4. | Mobile Cranes |
| 9.2. | OEM Models & Case Studies |
| 9.2.1. | Liebherr Electric Crawler Cranes |
| 9.2.2. | Liebherr LR1250.1 Deployed at HS2 Station Site |
| 9.2.3. | Liebherr Electric Crawler Cranes Schematic |
| 9.2.4. | Liebherr Expand Range of Electric Crawler - LR1130.1 Unplugged & LR1160.1 Unplugged |
| 9.2.5. | Liebherr LTC1050-3.1 |
| 9.2.6. | PV-E Crane 100% Electric Crawler Cranes |
| 9.2.7. | Madea All-Electric Mini Crawler Crane |
| 9.2.8. | Zoomlion ZTC250N-EV Electric Truck Crane |
| 9.2.9. | Zoomlion ZAT2200VE863 Super Heavy Crane |
| 9.2.10. | Sany STC250HBEV Electric Truck Crane |
| 9.2.11. | Sany SCE800TB-EV fully electric crawler crane |
| 9.2.12. | XCMG XCT25EV and XCA60EV PHEV Truck Cranes |
| 10. | ELECTRIC OTHER CONSTRUCTION VEHICLES |
| 10.1. | Other Construction Vehicles |
| 10.2. | Liebherr Hybrid Concrete Mixer Truck - Not Electric |
| 10.3. | Futuricum Electric Concrete Mixer Truck |
| 10.4. | Chinese OEMs Electric Mixer Trucks |
| 10.5. | Volvo FMX |
| 10.6. | Renault Trucks D Wide Z.E. |
| 10.7. | Chinese Battery Swapping Dump Trucks |
| 10.8. | Sany Electric Dump Trucks |
| 10.9. | BYD Electric Dump Trucks For Shenzhen |
| 10.10. | Truck OEMs Commit to Electrification |
| 10.11. | Junttan Electric Pile Driving Rig |
| 10.12. | Liebherr LB 16 Electric Drilling Rig |
| 10.13. | BAM Electric Road Roller |
| 10.14. | Electric Asphalt Rollers |
| 10.15. | Cat / Medatech Electric Road Grader |
| 10.16. | Cat Electric Drive (hybrid) Dozer |
| 11. | LI-ION BATTERY TECHNOLOGY & HEAVY-DUTY PACK SUPPLIERS FOR CONSTRUCTION |
| 11.1. | Lithium Battery Chemistry Overview |
| 11.2. | Current & Emerging Lithium Batteries Ranked |
| 11.3. | The Promise of Silicon |
| 11.4. | Silicon Anode Material Opportunities |
| 11.5. | Silicon Anode - Company Benchmarking |
| 11.6. | LTO Battery Cell Technology |
| 11.7. | Battery Requirements in Construction: Performance |
| 11.8. | Battery Requirements in Construction: Pricing |
| 11.9. | Battery Requirements in Construction: Reliability |
| 11.10. | Key Performance Indicators For Construction Battery Systems |
| 11.11. | Battery Chemistry Benchmarking for Construction |
| 11.12. | LFP or NMC Comparison |
| 11.13. | Introduction To Sodium-ion Batteries (Sibs) |
| 11.14. | Na-ion vs Other Chemistries |
| 11.15. | Cell Chemistry in Construction |
| 11.16. | Regional Cell Chemistry Choices |
| 11.17. | Cylindrical, Prismatic, Pouch Cell Format Comparison |
| 11.18. | Shifts in Cell and Pack Design |
| 11.19. | Larger Format 4680 Cylindrical Cells |
| 11.20. | Li-ion Batteries: From Cell to Pack |
| 11.21. | Heavy Duty Battery Pack Manufacturing Trends |
| 11.22. | Battery Pack Materials |
| 11.23. | Eliminating the Battery Module |
| 11.24. | Battery Enclosure Materials Summary |
| 11.25. | Lightweighting Battery Enclosures |
| 11.26. | IDTechEx Li-ion Battery Timeline |
| 11.27. | Timeline and Outlook for Li-ion Cell Energy Densities |
| 11.28. | Li-ion Timeline Commentary |
| 12. | HEAVY DUTY BATTERY SUPPLIERS |
| 12.1. | Akasol |
| 12.2. | Akasol AKASYSTEM |
| 12.3. | Northvolt Voltpack Core |
| 12.4. | Webasto Modular Battery System |
| 12.5. | Webasto & ECE - Large Electric Excavator |
| 12.6. | Proterra |
| 12.7. | Hyperdrive Innovation |
| 12.8. | Cummins |
| 12.9. | Deutz AG |
| 12.10. | Other European Battery Manufacturers |
| 12.11. | WATTALPS: Non-Road Mobile Machinery Batteries |
| 12.12. | WATTALPS Battery Pack |
| 12.13. | Chemistry Choice - Europe and North America |
| 12.14. | Chinese Electric Heavy-Duty Battery Suppliers |
| 12.15. | Known construction & battery supplier relationships (1) |
| 12.16. | Known construction & battery supplier relationships (2) |
| 13. | MOTORS |
| 13.1. | Comparison of Traction Motor Construction and Merits |
| 13.2. | Summary of Traction Motor Types |
| 13.3. | Dana TM4 |
| 13.4. | Dana E-Axles |
| 13.5. | ZF Friedrichshafen AG |
| 13.6. | ZF Preferred Electric Drivetrain Architecture |
| 13.7. | Danfoss Editron |
| 13.8. | ABB |
| 13.9. | Artemis / Danfoss |
| 13.10. | Electric Motor Performance Designed to Match ICE |
| 13.11. | Electrically Powered Hydraulic Systems |
| 13.12. | All-Electric Systems |
| 14. | HYDROGEN FUELLED CONSTRUCTION VEHICLES: INTRODUCTION & CASE STUDIES |
| 14.1. | Hydrogen for Construction Vehicles? |
| 14.2. | Proton Exchange Membrane Fuel Cells |
| 14.3. | Fuel Cells Technologies Overview |
| 14.4. | Attraction of Fuel Cell Vehicles |
| 14.5. | Deployment Barriers for Hydrogen Fuel Cell Vehicles |
| 14.6. | A Kaleidoscope of Hydrogen Colours |
| 14.7. | Must be Green H2 for Fuel Cell Machines to be 'Green' |
| 14.8. | Battery Electrification More Efficient than Fuel Cell EV |
| 14.9. | The Key Challenge: Green Hydrogen Cost Reduction |
| 14.10. | Power-to-Liquid Fuels - Terrible Efficiency |
| 14.11. | PEMFC Market Players |
| 14.12. | Hyundai Fuel Cell Construction Equipment |
| 14.13. | Bumhan Industry Fuel Cell Mini-Excavator |
| 14.14. | SANY Fuel Cell Construction Machines |
| 14.15. | Chinese Fuel Cell Dump Trucks |
| 14.16. | Comparison Hydrogen Fuel Cost vs Diesel Cost |
| 14.17. | The Cost of Green Hydrogen - Montpellier FCEV Buses |
| 14.18. | JCB Hydrogen Combustion Engines |
| 14.19. | JCB / Ryze / Fortescue Green Hydrogen Deal |
| 14.20. | Fuel Cell Construction Machines |
| 14.21. | AVL H2 Combustion Engines |
| 14.22. | ULEMCo |
| 14.23. | KEYOU Hydrogen ICE |
| 14.24. | Hydrogen Combustion Engines |
| 14.25. | Advantages and Disadvantages of BEV, FCEV, H2ICE |
| 14.26. | Summary Hydrogen Fuelled Construction Vehicles (1) |
| 14.27. | Summary Hydrogen Fuelled Construction Vehicles (2) |
| 15. | FORECASTS |
| 15.1. | Forecast Methodology (1) |
| 15.2. | Forecast Methodology (2) |
| 15.3. | Fuel Cells in Construction Commentary |
| 15.4. | Other Alternative Powertrains in Construction |
| 15.5. | Forecast Assumptions |
| 15.6. | Construction vehicle total addressable market |
| 15.7. | EV Construction Machine Sales Forecast by Region |
| 15.8. | Global Construction EV Sales Forecast by Machine Type |
| 15.9. | US Construction EV Sales Forecast by Machine Type |
| 15.10. | Europe Construction EV Sales Forecast by Machine Type |
| 15.11. | China Construction EV Sales Forecast by Machine Type |
| 15.12. | RoW Construction EV Sales Forecast by Machine Type |
| 15.13. | EV Construction Machines Battery Demand by machine type (GWh) |
| 15.14. | EV Construction Machines Battery Demand by region (GWh) |
| 15.15. | EV Construction Machines Market Size by machine type ($USD Billions) |
| 15.16. | EV Construction Machines Market Size by region ($USD Billions) |
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