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Assessment of Technologies for Improving Light-Duty Vehicle Fuel Economy2025-2035 [Mīkstie vāki]

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  • Formāts: Paperback / softback, 468 pages, height x width: 279x216 mm
  • Izdošanas datums: 28-Jan-2022
  • Izdevniecība: National Academies Press
  • ISBN-10: 0309371228
  • ISBN-13: 9780309371223
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Assessment of Technologies for Improving Light-Duty Vehicle Fuel Economy2025-2035Palielināt
  • Formāts: Paperback / softback, 468 pages, height x width: 279x216 mm
  • Izdošanas datums: 28-Jan-2022
  • Izdevniecība: National Academies Press
  • ISBN-10: 0309371228
  • ISBN-13: 9780309371223
Citas grāmatas par šo tēmu:
Permanent link: https://www.kriso.lv/db/9780309371223.html
From daily commutes to cross-country road trips, millions of light-duty vehicles are on the road every day. The transportation sector is one of the United States' largest sources of greenhouse gas emissions, and fuel is an important cost for drivers. The period from 2025-2035 could bring the most fundamental transformation in the 100-plus year history of the automobile. Battery electric vehicle costs are likely to fall and reach parity with internal combustion engine vehicles. New generations of fuel cell vehicles will be produced. Connected and automated vehicle technologies will become more common, including likely deployment of some fully automated vehicles. These new categories of vehicles will for the first time assume a major portion of new vehicle sales, while internal combustion engine vehicles with improved powertrain, design, and aerodynamics will continue to be an important part of new vehicle sales and fuel economy improvement.



This study is a technical evaluation of the potential for internal combustion engine, hybrid, battery electric, fuel cell, nonpowertrain, and connected and automated vehicle technologies to contribute to efficiency in 2025-2035. In addition to making findings and recommendations related to technology cost and capabilities, Assessment of Technologies for Improving Light-Duty Vehicle Fuel Economy - 2025-2035 considers the impacts of changes in consumer behavior and regulatory regimes.

Table of Contents



Front Matter Summary 1 Introduction 2 Fuel Economy, Greenhouse Gas Emissions, and Vehicle Efficiency Background 3 2025 Baseline of Vehicles 4 Internal Combustion Engine-Based Powertrain Technologies 5 Battery Electric Vehicles 6 Fuel Cell Electric Vehicles 7 Non-Powertrain Technologies 8 Connected and Automated Vehicles 9 Autonomous Vehicles 10 Energy and Emissions Impacts of Non-Petroleum Fuels in Light-Duty Vehicle Propulsion 11 Consumer Acceptance and Market Response to Standards 12 Regulatory Structure and Flexibilities 13 Emergent Findings, Recommendations, and Future Policy Scenarios for Continued Reduction in Energy Use and Emissions of Light-Duty Vehicles Appendixes Appendix A: Committee Biographical Information Appendix B: Disclosure of Conflicts of Interest Appendix C: Committee Activities Appendix D: Acronyms Appendix E: Center for Automotive Research Commissioned Study
Summary 1(9)
1 Introduction
10(10)
1.1 A Snapshot of Today's LDV Fleet
10(1)
1.2 A Look at the Future
11(2)
1.3 LDV System Energy Use
13(2)
1.4 Context for Fuel Economy Improvements
15(1)
1.5 Statement of Task
16(2)
1.6 References
18(2)
2 Fuel Economy, Greenhouse Gas Emissions, And Vehicle Efficiency Background
20(11)
2.1 Technology Principles Affecting Vehicle Efficiency
20(2)
2.2 Fuel Consumption, GHG Emissions, and Energy Use
22(2)
2.3 Technical, Regulatory, and Statutory History
24(5)
2.4 Test Cycle and Real-World Fuel Economy
29(1)
2.5 References
30(1)
3 2025 Baseline Of Vehicles
31(13)
3.1 Comparative Benchmarks for 2016-2026 Vehicles
31(1)
3.2 Baseline Vehicle Classes
31(1)
3.3 Future Year Co2 Reduction and Increased Efficiency to 2025
32(1)
3.4 MY 2020 Vehicles with Lowest Co2 Emissions
33(4)
3.5 Benchmark for MY 2025 and MY 2026
37(1)
3.6 Benchmark for MY 2025
37(2)
3.7 Technology Packages in 2025
39(1)
3.8 International Market and Regulations
40(2)
3.9 References
42(2)
4 Internal Combustion Engine-Based Powertrain Technologies
44(28)
4.1 Downsized/Boosted ICE Pathway
44(8)
4.2 Naturally Aspirated ICE Pathway
52(2)
4.3 Compression Ignition Diesel Engines
54(2)
4.4 Transmission Pathway
56(1)
4.5 Hybridized Powertrain Pathway
57(12)
4.6 Advanced Combustion Technologies
69(1)
4.7 References
70(2)
5 Battery Electric Vehicles
72(72)
5.1 Introduction
72(2)
5.2 The Electric Drive
74(10)
5.3 Batteries for EVs
84(31)
5.4 Electric Charging Infrastructure
115(14)
5.5 Summary of EV Costs
129(4)
5.6 References
133(11)
6 Fuel Cell Electric Vehicles
144(57)
6.1 Background
144(1)
6.2 Fuel Cell Basics
145(3)
6.3 FCEV Current Status and Planned Developments
148(12)
6.4 FCEV Technology R&D
160(20)
6.5 Hydrogen Refueling Infrastructure for FCEVs
180(9)
6.6 Summary of Fuel Cell Vehicle Costs
189(2)
6.7 Findings and Recommendations for FCEVs
191(1)
6.8 References
192(9)
7 Non-Powertrain Technologies
201(37)
7.1 Aero
201(5)
7.2 Mass Reduction
206(17)
7.3 Tires
223(6)
7.4 Accessories and Other Off-Cycle Technologies
229(2)
7.5 Considerations for Mass and Safety in Light of Increased Penetration of ADAS and Electrification
231(2)
7.6 Total Opportunities for Road Load and Accessory Power Draw Reduction
233(2)
7.7 References
235(3)
8 Connected And Automated Vehicles
238(31)
8.1 Introduction
238(1)
8.2 CAV Technologies
239(7)
8.3 Impacts of CAV Technologies on Vehicle Efficiency
246(11)
8.4 Estimates of Fuel Efficiency Effects
257(5)
8.5 Policy Issues Related to CAV Energy Impacts
262(2)
8.6 References
264(5)
9 Autonomous Vehicles
269(14)
9.1 Introduction
269(1)
9.2 Vehicle Miles Traveled
270(1)
9.3 Vehicle Ownership Models
271(1)
9.4 Vehicle Characteristics
272(1)
9.5 Relationships Among Autonomy, Connectivity, Sharing, and Electrification of Vehicles
273(1)
9.6 Combined Energy Impacts of Autonomous Vehicles
273(4)
9.7 Autonomous Vehicles and Energy Use: Policy Issues
277(2)
9.8 Findings and Recommendations
279(1)
9.9 References
280(3)
10 Energy And Emissions Impacts Of Non-Petroleum Fuels In Light-Duty Vehicle Propulsion
283(20)
10.1 Introduction
283(1)
10.2 Electricity, Hydrogen, and Low-Carbon Synthetic Fuels
284(13)
10.3 Low-Carbon Fuels in the 2025-2035 Fleet
297(2)
10.4 Recommendations for Non-Petroleum Fuels
299(1)
10.5 References
299(4)
11 Consumer Acceptance And Market Response To Standards
303(31)
11.1 Historical Market Trends
304(6)
11.2 Fuel Economy and Vehicle Travel: Rebound Effects
310(1)
11.3 How Much Do Consumers Value Fuel Cost Savings and What Are the Implications for Benefit-Cost Analysis?
311(6)
11.4 Transitions to New Technology
317(6)
11.5 Role of EV Incentives, Impact of Incentive Expiration, and Whether to Continue EV Incentives
323(6)
11.6 References
329(5)
12 Regulatory Structure And Flexibilities
334(31)
12.1 History of Vehicle Fuel Economy Regulation
334(2)
12.2 Measuring Fuel Economy and GHG Emissions
336(9)
12.3 Regulatory Flexibilities
345(8)
12.4 International Context of Regulatory Environment
353(7)
12.5 Fuel Economy Regulation in a Warming World
360(1)
12.6 References
361(4)
13 Emergent Findings, Recommendations, And Future Policy Scenarios For Continued Reduction In Energy Use And Emissions Of Light-Duty Vehicles
365(15)
13.1 Emergent Findings and Recommendations
366(7)
13.2 Big Picture: Rethinking Regulation of Fuel Economy in 2025-2035 and Beyond
373(4)
13.3 References
377(3)
APPENDIXES
A Committee Biographical Information
380(6)
B Disclosure of Conflicts of Interest
386(1)
C Committee Activities
387(5)
D Acronyms
392(6)
E Center for Automotive Research Commissioned Study
398