Allan Wang, ABB Jiangjin Turbo Systems Co., Ltd, China Impact of Turbocharging on Fuel Consumption and Emissions CIMAC Circle, Marintec 2009, Shanghai December 8, 2009
Impact of Engine Technology Drivers on Turbocharging Engine Technology Driver Emission Legislations Fuel Efficiency Power Density First costs Operational costs Reliability Fuel Flexibility Alternative Fuels Resulting TC Requirements Pressure Ratio Efficiency More tailored Products Shorter Development Cycles December 8, 2009 Slide 2 Impact of Turbocharging
NOx Emission Reduction Technologies Technology NOx-reduction potential Impact on bsfc / CO 2 Additional operating costs Impact on turbocharging (PIC, ETA) Engine / air systems optimization (CR, moderate miller, 1-stage TC) Engine / air systems optimization (CR, strong miller, VVT, 2-stage TC) Low EGR rate (15%) *) High EGR rate (30%) *) Wet measures - Direct water injection - Air humidification - Fuel water emulsion *) Exhaust after treatment (SCR) *) NOx reduction: up to 30% ( ), 30-60% ( ), above 60% ( ) bsfc / CO 2 impact: neutral ( ), up to +2..3% ( ); up to -5% ( ) Additional operating costs: none ( ), 1% ( ), 2..3%( ), >3% ( ) of fuel price *) Miller timing advantageous to reduce cylinder out emission lower additional operating costs and bsfc December 8, 2009 Slide 3 Impact of Turbocharging
Impact of Miller Timing on NO x and PIC NOx Reduction [ % ] 110 100 90 80 70 60 50 40 30 20 1-stage turbocharging 2-stage turbocharging 4-stroke diesel engine (bmep = const.) 10 CA "moderate" Miller "strong" Miller 4.3 10 20 30 40 50 60 70 80 90 Inlet valve closure earlier 1 bar 8.8 8.3 7.8 7.3 6.8 6.3 5.8 5.3 4.8 Compressor Pressure Ratio Source: CIMAC Congress 2007, Paper No. 101 December 8, 2009 Slide 4 Impact of Turbocharging
Favorable NO x - bsfc Trade-off with Miller Cycle Potential 4-stroke Diesel Engines Source: CIMAC Congress 2007 Paper No. 245 Source: ATK Dresden 2009 NO emissions x -10% -9% Reference IMO I -60% -70% Ref. PIC = 4.7 1-Stage PIC = 5.8 2-Stage PIC = 8 ~ 10 Fuel consumption bsfc NO x emission potential: bsfc potential: Status 2007-60% at constant bsfc -10% at constant NO x Update 2009-70% at constant bsfc -9% at constant NO x December 8, 2009 Slide 5 Impact of Turbocharging
Value Fuction 1- and 2-stage Turbocharging Value 1-stage 2-stage 1-stage π > 5.8 sv increased TC-size limited η TC limited matching flexibility higher stress level 2-stage π > 6.5 sv smaller TC sizes increased η TC matching flexibility high lower stress level improved load response π C,overall TPS-F / TPL-C A100 Power2 December 8, 2009 Slide 6 Impact of Turbocharging
ABB A100 Turbocharger Generation Single-stage / High Efficiency / High Pressure A100-H = for high speed engines A100-M = for medium speed engines A100-L = for low speed engines A100-H Pressure ratio up to 5.8 Turbocharger efficiency close to 68% A100-M Pressure ratio up to 5.8 Turbocharger efficiency up to 68% A100-L Pressure ratio up to 4.7 Turbocharger efficiency up to 75% ABB A100 turbocharger generation is an enabler for meeting the IMO II regulations, while eliminating or limiting bsfc penalties. December 8, 2009 Slide 7 Impact of Turbocharging
ABB Prototype 2-stage Turbocharging High pressure TC on test rig / Switzerland / September 2008 December 8, 2009 Slide 8 Impact of Turbocharging
Conclusions High performance turbocharging supports low emissions and high fuel efficiency engine concepts. ABB A100 turbocharger generation is the today s enabler for meeting IMO II regulations, while eliminating or limiting bsfc penalties. ABB 2-stage turbocharging is currently tested on engines, and will be one of key technologies for meeting IMO III regulations in the near future. High performance turbocharging is a benefit for everybody. For the enduser: lower fuel consumption For the engine builder: higher power density For the environment: less NOx and COx December 8, 2009 Slide 9 Impact of Turbocharging
December 8, 2009 Slide 10 Impact of Turbocharging