1 24 Diesel Engine Emissions Reduction Conference Coronado, California August 29-September 2, 24 Fuel Processor Enabled NOx Adsorber After-Treatment System for Diesel Engine Emissions Control R. Dalla Betta, D. Sheridan, J. Cizeron Catalytica Energy Systems Inc. Mountain View, California
2 Outline Why use a fuel processor for NOx trap regeneration Overview of the fuel processor (XFP Xonon Fuel Processor) Application configuration System efficiency Engine performance results Fuel penalty Low temperature operation Operating range NOx trap capacity Desulfation of LNT Summary
3 Advantages of a Diesel Fuel Processor What the fuel processor does #1 Efficiently converts diesel fuel to REACTIVE REDUCTANTS Regenerate the NOx trap at low temperatures H 2 shown to regenerate NOx trap at 15 C Benefits of Reactive Reductants Reactive reductants used very efficiently by NOx trap Complete regeneration of NOx trap capacity allowing minimum LNT volume NOx conversion, % 1 H 2 Diesel 1 2 3 Temperature, C 2NO 2 + 4H 2 N 2 + 4H 2 O Theoretical reductant Requirements H 2 or CO = 2 NOx Large NOx trap capacity over wide temperature range
4 Application Configuration Fuel XFP Fuel injection In cylinder engine fuel injection In-pipe fuel injection LNT XFP Functions: Regenerate LNT LNT heat up and desulfation Fuel XFP DPF LNT Separate components Components integrated into a single container Regenerate LNT LNT heat up and desulfation Thermal management during PM filter regeneration Technology for fuel injection integrated into the fuel processor package Improved low temperature performance Use of off-the-shelf injector components
5 Operational Description of XFP Oxygen, % 16 14 12 1 8 6 4 2 Throttle/EGR schedule H 2 O 2 CO 122 126 13 134 138 142 Time, s 4 3.5 3 2.5 2 1.5 1.5 H2 and CO, % Test configuration 7 liter engine Gas analysis downstream of the XFP Cycle details Engine throttled to give exhaust with 5% O 2 during regeneration cycle Rich period produces ~3% H 2 and CO.4 to 4% H 2 and CO H 2 /CO ratio ~ 1 Rich pulse length can vary from <1s to many seconds Note: Engine management only required to to lower exhaust O 2 to ~5-7%. Minimizes impact on engine operation
6 Lean-Rich NOx Adsorber Cycle Typical engine cycle 6 s lean with 3 second rich regeneration 16 4 14 H 2 3.5 Oxygen, % 12 1 8 6 4 O 2 CO 3 2.5 2 1.5 1 H2 and CO, % 2.5 5 1 15 2 25 3 Time, s
7 XFP Fuel Efficiency--Discussion NOx trap (LNT) regeneration requires two conditions to be met 1. O 2 in exhaust must be reduced to zero 2. Reductant must be supplied to reduce stored NOx and regenerate the LNT Sources of fuel usage Consume O 2 in the exhaust Reductant to regenerate the NOx trap XFP Operation Throttle position O 2 % XFP design is optimized to achieve Very low fuel requirement to heat up the fuel processor components High activity for combustion of O 2 in entire exhaust flow Efficient conversion of fuel into H 2 and CO Fuel to generate reductants Throttling/EGR fuel cost Time Fuel to consume O 2 Fuel to heat up reformer components
8 5 liter engine test Older XFP-1 design XFP unit oversized for this engine 5 liter engine 5 liter NOx trap Test at steady state condition Speed Load XFP inlet temperatur e Engine out NOx Lean trapping time NOx conversion Fuel penalty rpm Nm C ppm s % % 16 17 354 13 12 93 4.4 18 95 3 16 326 458 38 12 73 2.5 12 85 3
9 8 liter engine test XFP-1.1 design Improved design with reduced fuel consumption XFP unit sized to this engine 8 liter engine 14 liter NOx trap Test at steady state condition Speed Load XFP inlet temperatur e Engine out NOx Lean trapping time NOx conversion Fuel penalty rpm Nm C ppm s % % 12 38 31 19 6 95 5.4 12 98 3.2 18 97 2.3 12 77 34 43 3 98 4.9 6 93 2.9 12 52 1.6
1 XFP Operating Window Desired operating window compared to test points Fuel penalty shown for each test point P indicates XFP test only (without NOx trap) 6 55 All data points showed NOx conversion > 9% Required operating window still being defined Temperature, C 5 45 4 35 3 25 2 3% 3.3% 3% 2.9% 2.3% P 1.7% P 5 1 15 2 25 3 Space velocity, hr-1
11 Operation of LNT at Low Temperature H 2 +CO reductants give good NOx trap capacity at low temperature Comments Rig data shows H 2 +CO will regenerate LNT down to 15 C This demonstration was limited by low temperature operation of XFP Cycle optimization should allow improved NOx conversion at low temperatures NOx Conversion, % 1 8 XFP 6 4 2 In Pipe injection 1 15 2 25 3 35 4 45 NOx Trap Inlet Temp., C 8 liter engine 6s lean cycle Note: Exhaust temperature limit of XFP is currently 22 C These data obtained using transient engine operation
12 Low Temperature Operation of XFP Issues Fuel injection, mixing and vaporization Low temperature light off Quick rise to reforming operation TEmperature, C 6 55 5 45 4 35 3 25 2 15 XFP start up at 2 C inlet temp. Fuel Test on 8.3 liter engine 8571 8591 8611 8631 8651 8671 Time Current status XFP can operate with exhaust temperatures down to 22 C Development systems show lower temperature operation Integrated fuel injection and mixing Fuel processor component and gas temperatures
13 Efficient Use of Reductant Reductant to NOx ratio varied by changing rich cycle conditions Reductant per cycle calculated from measured XFP fuel flow (model) 5 liter engine 5 liter NOx trap Region of interest Low fuel penalty High NOx conversion Fuel penalty, % 2 18 16 14 12 1 8 6 4 2 Low load Med load High load 1 9 8 7 6 5 4 3 2 1 NOx conversion, % 5 1 15 2 25 3 H2+CO/NOx ratio Effective NOx trap can give high NOx conversions with (CO+H 2 )/NOx ratios 3
14 NOx Trap Capacity High NOx trap capacity demonstrated in engine tests with XFP Cyclic XFP-NOx trap operation at steady state engine operation Vary lean trapping time and rich regeneration time varies NOx loading on LNT Very effective LNT regeneration with reactive reductant (H 2 + CO) NOx conversion, % 12 1 8 6 4 2 Drop in conversion gives ~ LNT capacity g NO 2 /liter.28.51.97 5 1 15 2 25 LNT Capacity, mmols/liter LNT Engine test data Different NOx traps have widely different NOx capacities
LNT Desulfation Using the XFP Strategy Use lean fuel combustion in XFP to raise exhaust temperature into downstream LNT Uniformly heat LNT to desulfation temperature Control can be model based or can use measured exhaust temperature Operate XFP in rich mode to produced continuous or pulsed reductant in the exhaust (H 2 +CO) at levels from.5% to 3% Rich mode operation uses throttle or EGR to reduce O 2 level to 5-6% 15
16 Desulfation: XFP 8 liter engine with 17 liter NOx trap XFP provides good LNT temperature control XFP provided rich regeneration conditions: ~ 2% H 2 +CO Desulfation starts at 62 C S desorption occurs over a wide temperature range 12 7 1 LNT Temp 6 SO2(ppm) 8 6 4 Pulsed H 2 +CO ppm S 5 4 3 Temperature (C) 2 2 1 5 1 15 2 25 3 TIME (sec)
17 Summary XFP fuel processing system combined with NOx traps demonstrated on 5 to 14 liter diesel engines Engine management limited to reducing exhaust O 2 to ~5% during rich cycle NOx conversion > 9% achieved Lean cycle times typically 6 to 18s Fuel cost in the range of 2 to 3% over most engine conditions XFP operation at exhaust temperatures as low as 22 C Demonstrated regeneration of LNT at exhaust temperatures at low as 2 C Exhaust temperature thermal management LNT desulfation PM filter active regeneration
18 Status Work in progress Transient engine testing: 4Q24 On engine durability testing: 4Q24 Engine test of 3ed generation fuel processor design: 1Q5 On vehicle demonstration: 2Q or 3Q25 Product improvement directions Improved low temperature performance Better coverage of test cycles that emphasize low speed urban conditions Shorter regeneration cycle time Easier integration with transient control Develop improved transient control strategies Durability testing Long term rig testing On-engine testing of components Contaminants testing
19 Contracts Business: Technical: Thank you Jonathan Roberts cccjroberts#@catalyticaenergy.com (remove ccc) (63)762-92 Ralph Dalla Betta cccrdallabetta@catalyticaenergy.com (remove ccc) (65)94-631