燃油效率 (Fuel Efficiency)
Embed This Widget
Add the script tag and a data attribute to embed this widget.
Embed via iframe for maximum compatibility.
<iframe src="https://planefyi.com/iframe/glossary/fuel-efficiency/" width="420" height="400" frameborder="0" style="border:0;border-radius:10px;max-width:100%" loading="lazy"></iframe>
Paste this URL in WordPress, Medium, or any oEmbed-compatible platform.
https://planefyi.com/glossary/fuel-efficiency/
Add a dynamic SVG badge to your README or docs.
[](https://planefyi.com/glossary/fuel-efficiency/)
Use the native HTML custom element.
Definition
每旅客每公里的燃油消耗量,是飞机运营经济性和环境影响的关键指标。
什么是燃油效率?
Fuel efficiency in aviation quantifies how productively fuel energy is converted into transported passengers or cargo over distance. The most common metric for commercial aviation is liters per 100 passenger-kilometers (L/100 pax-km), analogous to automotive fuel economy. A lower number means a more efficient aircraft. Fuel efficiency integrates the effects of airframe aerodynamics, engine thermal efficiency (expressed as specific fuel consumption), seat count, load factor, cruise speed, and route stage length. It is both an economic metric — fuel represents 20–30% of airline operating costs — and an environmental metric, as CO₂ emissions are directly proportional to fuel burned.
测量方法
Fuel efficiency is calculated as: (Total fuel burned in liters) ÷ (Passengers carried × distance in km). It is highly sensitive to load factor: an aircraft flying with 70% seats occupied appears far less efficient than the same aircraft at 90% load factor. The International Civil Aviation Organization (ICAO) uses a standardized metric called CO₂ efficiency (grams of CO₂ per revenue tonne-kilometer, RTK) for environmental assessments. Engine efficiency is captured by bypass ratio — modern high-bypass turbofans (bypass ratio 10–12:1 on the LEAP and PW1100G engines) deliver substantially lower specific fuel consumption than older low-bypass designs. Winglets reduce induced drag and typically improve fuel efficiency by 3–5% on retrofitted aircraft.
各机型典型数值
| Aircraft | Fuel Burn (L/100 pax-km) | Engine Family | vs. 2000 Baseline |
|---|---|---|---|
| Boeing 727-200 (1970s) | ~9.0 | JT8D (low bypass) | baseline era |
| Boeing 737-800 | ~3.7 | CFM56-7B | −59% |
| Airbus A320neo | ~2.9 | LEAP-1A / PW1100G | −68% |
| Boeing 787-9 | ~2.5 | GEnx / Trent 1000 | −72% |
| Airbus A350-900 | ~2.4 | Trent XWB | −73% |
| Airbus A220-300 | ~2.4 | PW1500G | −73% |
Modern best-in-class aircraft consume approximately 2.4–2.9 L/100 pax-km at typical load factors, comparable to a small car shared by one passenger — a dramatic improvement over the 1970s generation.
重要原因
Fuel efficiency is perhaps the single most strategically important aircraft performance parameter for commercial aviation. At $0.80/liter jet fuel, a single percentage point improvement in fuel efficiency on a 200-aircraft fleet operating 3,000 cycles per year saves approximately $15–20 million annually. Beyond economics, fuel efficiency determines CO₂ footprint: ICAO's CORSIA scheme and EU ETS price carbon, making high efficiency a regulatory compliance necessity. Improvements in fuel efficiency have enabled the growth of ultra-long-range routes — flights like Singapore–New York or Perth–London become economically viable only with the range achievable by highly efficient modern turbofans and lightweight composite airframes.
Related Terms
可持续航空燃料(SAF)
由可再生原料生产的直接替代喷气燃料,可将生命周期CO2排放量减少最多80%。
复合材料革命
飞机结构从铝合金主导转向碳纤维增强聚合物复合材料的转变过程,以结构重量超过50%使用复合材料的Boeing 787 Dreamliner为代表。
开式转子发动机
采用无涵道反转风扇叶片的下一代推进概念,在喷气速度下实现涡桨发动机级别的效率。
燃油箱惰化系统
通过向燃油箱余隙空间充入富氮空气将氧气浓度降至可燃阈值以下,防止燃油蒸气点燃的安全系统。
翼梢小翼
安装在飞机机翼尖端的小型垂直延伸结构,可减少阻力并提高燃油效率。
重心
飞机总重量被视为集中作用的点,对纵向稳定性和操纵效能至关重要。