A Simplified Catalytic Converter Model for Automotive Coldstart Control Applications

A Simplified Catalytic Converter Model for Automotive Coldstart Control Applications
Pannag R Sanketi, Karl Hedrick, Tomoyuki Kaga

Citation
Pannag R Sanketi, Karl Hedrick, Tomoyuki Kaga. "A Simplified Catalytic Converter Model for Automotive Coldstart Control Applications". Proceedings of 2005 ASME International Mechanical Engineering Congress and Exposition (IMECE2005), November, 2005; Orlando, Florida USA.

Abstract
More than three-fourths of the unburned hydrocarbon (HC) emissions in a typical drive cycle of an automotive engine are produced in the initial 2 minutes of operation, commonly known as the coldstart period. Catalyst light-off plays a very important role in reducing these emissions. Model-based paradigm is used to develop a control-oriented, thermodynamics based simple catalyst model for coldstart purposes. It is a modified version of an available model consisting of thermal dynamics and static efficiency maps, the critical modification being in the thermal submodel. Oxygen storage phenomenon does not play a significant role during the warm-up of the engine. The catalyst is modeled as a second-order system consisting of catalyst brick temperature and temperature of the feedgas flowing through the catalyst as its states. Energy balance of an unsteady flow through a control volume is used to model the feedgas temperature, whereas energy balance of a closed system is used to model the catalyst brick temperature. Wiebe profiles are adopted to empirically model the HC emissions conversion properties of the catalyst as a function of the catalyst temperature and the air-fuel ratio. The static efficiency maps are further extended to include the effects of spatial velocity of the feedgas. Experimental results indicate good agreement with the model estimates for the catalyst warm-up. It is shown that the model represents the system more accurately as compared to the previous model on which it is based and offers a broader scope for analysis.

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HTML

Pannag R Sanketi, Karl Hedrick, Tomoyuki Kaga. <a
href="http://chess.eecs.berkeley.edu/pubs/87.html"
>A Simplified Catalytic Converter Model for Automotive
Coldstart Control Applications</a>, Proceedings of
2005 ASME International Mechanical Engineering Congress and
Exposition (IMECE2005), November, 2005; Orlando, Florida USA.

Plain text

Pannag R Sanketi, Karl Hedrick, Tomoyuki Kaga. "A
Simplified Catalytic Converter Model for Automotive
Coldstart Control Applications". Proceedings of 2005
ASME International Mechanical Engineering Congress and
Exposition (IMECE2005), November, 2005; Orlando, Florida USA.

BibTeX

@inproceedings{SanketiHedrickKaga05_SimplifiedCatalyticConverterModelForAutomotiveColdstart,
    author = {Pannag R Sanketi and Karl Hedrick and Tomoyuki Kaga},
    title = {A Simplified Catalytic Converter Model for
              Automotive Coldstart Control Applications},
    booktitle = {Proceedings of 2005 ASME International Mechanical
              Engineering Congress and Exposition (IMECE2005)},
    month = {November},
    year = {2005},
    note = {Orlando, Florida USA},
    abstract = {More than three-fourths of the unburned
              hydrocarbon (HC) emissions in a typical drive
              cycle of an automotive engine are produced in the
              initial 2 minutes of operation, commonly known as
              the coldstart period. Catalyst light-off plays a
              very important role in reducing these emissions.
              Model-based paradigm is used to develop a
              control-oriented, thermodynamics based simple
              catalyst model for coldstart purposes. It is a
              modified version of an available model consisting
              of thermal dynamics and static efficiency maps,
              the critical modification being in the thermal
              submodel. Oxygen storage phenomenon does not play
              a significant role during the warm-up of the
              engine. The catalyst is modeled as a second-order
              system consisting of catalyst brick temperature
              and temperature of the feedgas flowing through the
              catalyst as its states. Energy balance of an
              unsteady flow through a control volume is used to
              model the feedgas temperature, whereas energy
              balance of a closed system is used to model the
              catalyst brick temperature. Wiebe profiles are
              adopted to empirically model the HC emissions
              conversion properties of the catalyst as a
              function of the catalyst temperature and the
              air-fuel ratio. The static efficiency maps are
              further extended to include the effects of spatial
              velocity of the feedgas. Experimental results
              indicate good agreement with the model estimates
              for the catalyst warm-up. It is shown that the
              model represents the system more accurately as
              compared to the previous model on which it is
              based and offers a broader scope for analysis.},
    URL = {http://chess.eecs.berkeley.edu/pubs/87.html}
}

Posted by Pannag R Sanketi on 11 May 2006.
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