비연료소비율 (SFC) (SFC: Specific Fuel Consumption)
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Definition
엔진 연료 효율의 척도: 시간당 생산된 추력 단위당 소비되는 연료 질량으로, lb/(lbf·h) 또는 kg/(kN·h)로 표시된다.
What Is Specific Fuel Consumption?
Specific Fuel Consumption (SFC) — also called Thrust Specific Fuel Consumption (TSFC) for jet engines — quantifies how efficiently an engine converts fuel energy into useful thrust. It expresses the mass of fuel burned per unit of thrust per unit of time. A lower SFC means a more fuel-efficient engine: less fuel is consumed to produce the same thrust, directly extending range and reducing operating costs.
How It Works
SFC is calculated as:
- SFC = (fuel flow rate) / (net thrust produced)
- In imperial units: lb of fuel per hour per lbf of thrust → lb/(lbf·h)
- In SI units: kg per hour per kN → kg/(kN·h) or equivalently mg/(N·s)
Key factors that influence SFC:
- Bypass Ratio: Higher Bypass Ratio dramatically improves SFC by accelerating more air at lower velocity. Doubling BPR from 5:1 to 10:1 can improve SFC by 10–15%.
- Overall Pressure Ratio (OPR): Higher compression improves thermodynamic efficiency. Modern engines achieve OPR of 45–60:1 vs. 15–20:1 in 1960s jets.
- Turbine Inlet Temperature (TIT): Higher TIT improves Carnot efficiency. Enabled by ceramic thermal barrier coatings and film cooling.
- Altitude: SFC improves at cruise altitude because cooler air increases the density ratio and reduces intake ram drag penalties.
- Airspeed: SFC increases at higher Mach numbers due to ram drag — a key economic penalty for supersonic flight.
Performance Specifications
- CFM56-7B (737 NG, circa 1997): ~0.545 lb/(lbf·h) at cruise
- CFM LEAP-1B (737 MAX, 2017): ~0.490 lb/(lbf·h) — approximately 15% improvement
- Pratt & Whitney PW1100G (A320neo, 2016): ~0.460–0.480 lb/(lbf·h) — best in class for single-aisle
- Rolls-Royce Trent XWB (A350, 2015): ~0.478 lb/(lbf·h) — best SFC of any large turbofan at launch
- Concorde Olympus 593 (supersonic): ~1.195 lb/(lbf·h) — over twice modern turbofans due to low BPR and supersonic penalties
Aircraft Examples
- Boeing 787-9 (GEnx-1B): SFC ~0.486 lb/(lbf·h); combined with composite airframe yields 25% better fuel burn per seat than 767
- Airbus A320neo (PW1100G): 20% better fuel efficiency than A320ceo, driven largely by SFC improvement plus airframe drag reduction
- ATR 72-600 (PW127M turboprop): Turboprops use shaft-horsepower SFC (lb/SHP·h): ~0.48 — far better than jets for short sectors below 400 nm
- Future Open Fan (CFM RISE program): Targeting 20% SFC improvement over LEAP by ~2035 using unducted fan architecture with BPR >20:1
SFC is the core metric linking engine efficiency to aircraft range. Engineers use the Breguet range equation, in which SFC appears as a direct denominator — halving SFC doubles range for a given fuel load.
Related Terms
바이패스비 (BPR)
엔진 코어를 우회하는 공기 질량과 코어를 통과하는 공기의 비율로, 연료 효율의 핵심 지표.
기어드 터보팬 (Geared Turbofan)
팬과 저압 터빈 사이에 감속 기어박스를 사용하여 각각 최적 속도로 회전할 수 있도록 한 터보팬 설계.
고바이패스 터보팬 (High-Bypass Turbofan)
바이패스비가 5:1 이상인 터보팬 엔진으로, 흡입 공기의 대부분을 엔진 코어 주변으로 우회시켜 연료 효율을 극대화하고 소음을 최소화한다.
추력 (Thrust)
항공기 엔진이 생성하는 전진력으로, 파운드포스(lbf) 또는 킬로뉴턴(kN) 단위로 측정되며 비행과 상승을 가능하게 한다.
터보팬 엔진 (Turbofan Engine)
대형 팬을 사용하여 대부분의 추력을 생성하는, 상용 항공에서 가장 일반적인 제트 엔진 유형.
터보프롭 엔진 (Turboprop Engine)
감속 기어박스를 통해 프로펠러를 구동하는 제트 엔진으로, 저고도 및 단거리 노선에서 높은 효율을 제공한다.