CO2 Reduction for Spark-Ignition Engines: Two Paths to Success

CO2 Reduction for Spark-Ignition Engines: Two Paths to Success Leveraging Air Delivery and Fuel Injection Technologies to Improve Engine Efficiency

John E. Kirwan Delphi Powertrain Systems

High Level Gasoline Engine Technology Roadmap PZEV Market Drivers: EURO 5 EURO 5+ Emissions & CARB CO2 EU 130g/km Fuel Economy US Senate CAFE

EURO 6 EU 95g/km

EU 70g/km US CAFE Update H2 DI-Engine CNG DI-Engine Alternate cycles, VCR, camless

HCCI GDi Engine, DICP & VVA & eVCP Spray Stratified Boosted GDi Engines Spray Stratified GDi Engines Homogeneous, Boosted GDi Engines, DICP & VVA Homogeneous, Boosted GDi Engines, DICP Homogeneous GDi Hybrid Engines Homogeneous GDi Engines, VVT Alternate Fuel – H2 Engine Alternate Fuel – CNG, LPG Alternate Fuel Compatible Engine – Flex fuel, E10-E100 Boosted PFI Engines Gasoline Hybrid Engine Gasoline Advanced PFI Engine, active VT, mixture motion, PZEV Gasoline PZEV (AIR)

2008

2010

2012

2014 2

2016

2018

2020

Future

Where Does the Fuel Energy Go? Fuel Energy Available Heat Rejection

Combustion Inefficiency

Exhaust

Coolant Engine Friction Pumping Losses

Indicated Work

Accessories

Shaft Work

Transmission

Vehicle Consumption

Inertia Aero Drag Rolling Resistance Source: Nat’l Acad Eng. (2002)

3

Where Does the Fuel Energy Go? Fuel Energy Available Heat Rejection

Combustion Inefficiency

Exhaust

Coolant

Source: SAE 2003-01-0029

Engine Friction Pumping Losses

Indicated Work

Accessories

Shaft Work

Transmission

Vehicle Consumption

Inertia Aero Drag Rolling Resistance Source: Nat’l Acad Eng. (2002)

4

Where Does the Fuel Energy Go? Fuel Energy Available Heat Rejection

Combustion Inefficiency

Exhaust Target Domain: Improve Net Engine Efficiency

Coolant Engine Friction Pumping Losses

Indicated Work

Accessories

Shaft Work

Transmission

Vehicle Consumption

Inertia Aero Drag Rolling Resistance Source: Nat’l Acad Eng. (2002)

5

Fundamental SI Engine Control Parameters Fuel Energy Available

hTarget: Reduce pumping losses hMethods: q Valvetrain Technologies 8 Variable Cam Phasing 8 Cylinder Deactivation 8 Variable Valve Lift q Turbo / Supercharging

Combustion Inefficiency

Heat Rejection

◊ Air

Exhaust

Coolant

Source: SAE 2003-01-0029

Engine Friction Pumping Losses

Indicated Work

Accessories

Shaft Work

Transmission

Vehicle Consumption

Inertia Aero Drag Rolling Resistance Source: Nat’l Acad Eng. (2002)

◊ Fuel hTarget: Reduce heat rejection and pumping losses hMethods: q Homogeneous Gasoline Direct Injection q Stratified Gasoline Direct Injection

◊ Spark hTarget: Proper timing minimizes heat rejection; advanced ignition systems can enable higher dilution combustion strategies 6

Valvetrain Technologies

Variable Cam Phasing Functionality: Control air flow through valve timing to gain performance, emissions reduction and fuel economy Benefit Application Type Acronym

Schematic

Performance Fuel Economy

Emissions HC NOx

∆Ι

Intake Only

IVCP Exhaust

4-7%

1-2%

15%

25%



Stratified GDi

100

◊ Benefits

40

60

h Fuel economy improvement q 10-15% for naturally aspirated q 15-20% with downsizing and boost h Improved fuel control and rapid catalyst light-off with split-injection during cold start h Increased power and torque 27

80

100 120 Engine Power [kW]

140

160

◊ European strategy h Current barriers to US implementation: q More stringent NOx standards q Lean NOx catalyst durability q Fuel sulfur concentration

Gasoline Direct Injection Stratified Systems ◊ Key Requirements hOperation at fuel pressures up to 200 bar hLow noise in critical frequency range hWell-atomized and well-placed stratified mixture under engine conditions hMultiple injection capability hHigh linear flow range

Fuel Mass (mg/shot)

140

20%

fp = 200 bar

15%

120

10%

100

5%

80

0%

60

-5%

40

-10%

20

-15%

0 0.00

1.00

2.00 3.00 Injector Pulse Width (ms)

4.00

Deviation (%)

160

-20% 5.00

28

Stable spray under engine conditions 5 bar

10 bar Backpressure

20 bar

Summary ◊ Variable valvetrain technologies and gasoline direct injection offer technology improvements for two critical paths to CO2 reduction in SI engines h Attack pumping losses and heat rejection to improve net engine efficiency h Can be used to optimize alternative fuel performance and advanced combustion strategies (e.g. HCCI / CAI, highly dilute combustion)

◊ These innovations will substantially contribute to reducing fuel consumption required by Government and sought by customers h Applicable to wide spectrum of engine sizes / power needs h Offer simultaneous performance benefits so that CO2 reduction need not conflict with “fun-to-drive” vehicles Fuel Energy Available Heat Rejection

Combustion Inefficiency

Exhaust

Coolant

Source: SAE 2003-01-0029

Engine Friction Pumping Losses

Indicated Work

29

Accessories

Shaft Work

Transmission

Vehicle Consumption

Inertia Aero Drag Rolling Resistance Source: Nat’l Acad Eng. (2002)

Thank you

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