A Revealing Look Inside Passive and Active DPF Regeneration: In
Transcript of A Revealing Look Inside Passive and Active DPF Regeneration: In
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Massachusetts Institute of Technology Sloan Automotive Laboratory Cambridge, MA
A Revealing Look Inside Passive and Active DPF Regeneration:
In-Situ Optical Analysis of Ash Formation and Transport
A Consortium to Optimize Lubricant and Diesel Engines for Robust Emission Aftertreatment Systems
October 17, 2011
Alexander Sappok, Ifran Govani, Carl Kamp, Victor W. Wong
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Ash Impacts on Particulate Filter Performance
Particle filters (DPF, GPF) trap incombustible “ASH” emissions.
DPF Ash PM
• Total pressure drop • Pressure drop response • Catalyst performance • Soot storage capacity • Soot distribution
Understanding fundamental ash properties is critical !
Fuel Economy (ΔP & Regen) Filter Life (Plugging)
Ash alters DPF performance over filter’s useful life.
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DPF
Engine-Out Ash Precursors Small (< 100nm)
Image: Adapted from ORNL
Soot
Ash (Ca)
K. Hanamura (SAE2011-01-0602)
0102030405060708090
100
Co
unts
Zn
S
P
A1A2
100 nm A1
A2
A. Sappok DEER 2006, SAE2007-01-0318
Soot
Metal Oxides 10-30nm
A. Mayer (SAE2012-01-0841) (SAE2010-01-0792)
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Ash Agglomerates Grow Larger in DPF (1-10 μm)
Image: Adapted from ORNL
DPFDPF
K. Aravelli, DEER 2007 900 nm900 nm
1 μm 2 μm
A. Sappok, DEER 2006, SAE2007-01-0318
C. Kamp, DEER 2011, SAE2012-01-0836
Ash Particle Growth in DPF
~ 100 nm ~ 1 μm
Ash Agglomerates Porous/Hollow
Impacts Efficiency and Performance
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Ash Build-Up in the DPF is a Dynamic Process
~ 100 μm ~ 0.1 μm
~ 10 μm Ash Properties Impacted by Regeneration
VChannel
VWall
SAE 2009-01-2882
Regeneration may exert large impact on ash morphology and distribution
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Initial Results Show Soot-Ash Interactions During Regen
DEER 2011 Conditions •Stereo Microscope
•Soot Oxidation
•Existing Ash Layer
•Air
•No Flow
•600 °C
Initial Optical Studies
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Quartz Glass
Gasket
27mm by 1.44mm Slit in Matting and One Channel of the DPF
Optical Setup for Regeneration Visualization Studies
Channel View
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Bare and Ash-Loaded Filter Evaluation Sequence
ΔP, T Sensors
DPF Core
FTIR
4. Optical Bench Regeneration
1. Ash Loading Accelerated ash loading system Simulate over 180K miles Utilize full-size DPFs Significant validation and
comparison with field DPFs
3. PM Loading (Cummins, Yanmar)
2. Core Sample Preparation
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Large Test Matrix to Investigate PM Oxidation/Ash Formation
PM Level Configuration Flow Ash Level Temperature
1. Impact of PM Level at Start of Oxidation on PM Mobility and Ash Interactions
Low
Moderate
Low
Moderate
High
2. Effect of NO2 Source (DOC vs. CDPF) on PM/Ash Mobility
0 g/L
30+ g/L
3. Impact of Exhaust Flow Rate During Regeneration on Ash/PM Mobility
Low
High
4. Impact of Exhaust Temperature During Regeneration on Ash/PM Mobility
Moderate DOC+CDPF Moderate 30+ g/L High
5. Impact of Oxidation Mechanism via O2 vs. NO2 on Ash Formation
0 g/L
30+ g/L
UCDPF Moderate 0 g/L
HighModerateCDPF
Moderate
Moderate30+ g/LDOC+CDPF
Moderate
Moderate
CDPF Moderate
0 g/L
30+ g/L
Moderate
DOC+CDPF Moderate Moderate
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Local Regeneration on C-DPF Concentrates Remaining PM
Regeneration on bench reactor shows localized PM mobility
1 2
3 4
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Video: PM Oxidation on Clean CDPF (Moderate PM)
Regeneration Conditions: 450 °C, 500 ppm NO, 40,000 GHSV
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Video: Ash Formation and Agglomeration Substrate
Regeneration Conditions: 450 °C, 500 ppm NO, 40,000 GHSV
Light “dusting” of CJ-4 ash applied on top of PM layer using burner system to visualize ash agglomeration process.
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Video: Ash Formation and Particle Transport Substrate
Regeneration Conditions: 400 °C, 500 ppm NO, 20,000 GHSV
PM with elevated CJ-4 ash concentration generated using burner system in combination with engine to visualize ash formation.
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General Observations of Ash Formation and Transport
Regeneration with elevated ash concentration in PM shows local soot and ash mobility and significant agglomeration.
Bulk soot and ash transport along DPF channels observed during regeneration for larger particles loosely bound to surface.
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Summary of Ash Agglomeration During PM Oxidation
~ 100 nm ~ 1 μm
Ash residence time in DPF is long ~ 100,000 + Miles
Internal void shows walls composed of ~nm scale particles
PM
(T, Flow, Gas)
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Summary and Conclusions
• PM oxidation proceeds locally and exhibits some surface mobility for the cases investigated (C-DPF)
• Mobility of soot cake on DPF surface during regeneration most pronounced at elevated PM levels
• Regeneration with soot cake appears to concentrate ash precursors during PM oxidation process
• Concentration of ash deposits may promote ash particle agglomeration and growth
• Transport of bulk ash and soot observed during regeneration for agglomerates that become loosely bound to surface
• Current investigations ongoing to understand underlying mechanisms outlined in full test matrix
Processes occurring during regeneration (active or passive) play an important role in influencing ash particle formation and transport.
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Acknowledgements
Research supported by: MIT Consortium to Optimize Lubricant and Diesel Engines for Robust Emission Aftertreatment Systems
We thank the following organizations for their past and/or present support:
- Caterpillar - Chevron - Cummins
- Detroit Diesel - Infineum - Komatsu
- NGK - Oak Ridge National Lab - Süd-Chemie
- Valvoline - Ford - Ciba - Lutek
MIT Center for Materials Science and Engineering