Development of a model-based transient calibration process for diesel engine electronic control module tables – Part 1: data requirements, processing, and analysis

Brahma, Indranil; Chi, John

doi:10.1177/1468087411424376

Cited by 21 publications

(63 citation statements)

References 26 publications

(49 reference statements)

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“…A BoxCox [15] transform was used for the emission models based on previous work by Brahma et al [16,17], which suggests that an exponential dependence of emissions on engine parameters increases prediction accuracy because it represents the physical phenomena better than a linear quadratic expression. However, the Box-Cox transform, commonly used by statisticians, imposes an exponential dependence between emissions and all independent variables, as illustrated by equation (1). This cannot parallel the physical phenomena; for example, it is hard to imagine an exponential relationship between PM and engine speed (r/min) or injection timing, but not for the oxygen mole fraction ln(Y ) = a 0 + a 1 engine speed + a 2 timing + a 3 O 2 fraction.…”

Section: Modelling Methods and Model Formmentioning

confidence: 99%

“…These cycles were chosen from the 31 FTP cycles and corresponding snap throttle cycles described in the companion work [1] to span the calibration spectrum in an equidistant manner. No FTP cycle data were included in the training data to ensure that the model was not 'memorizing' the FTP cycle.…”

Section: Estimation Of Chosen Model Accuracymentioning

confidence: 99%

“…The current work asks three questions not found in the literature. 1. What kind of empirical modelling methods are most suitable for modelling transient emissions and torque?…”

Section: Introductionmentioning

confidence: 99%

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Development of a model-based transient calibration process for diesel engine electronic control module tables – Part 2: modelling and optimization

Brahma

Chi

2011

International Journal of Engine Research

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This is the second part of a study investigating a model-based transient calibration process for diesel engines. The first part addressed the data requirements and data processing required for empirical transient emission and torque models. The current work focuses on modelling and optimization. The unexpected result of this investigation is that when trained on transient data, simple regression models perform better than more powerful methods such as neural networks or localized regression. This result has been attributed to extrapolation over data that have estimated rather than measured transient air-handling parameters. The challenges of detecting and preventing extrapolation using statistical methods that work well with steady-state data have been explained. The concept of constraining the distribution of statistical leverage relative to the distribution of the starting solution to prevent extrapolation during the optimization process has been proposed and demonstrated. Separate from the issue of extrapolation is preventing the search from being quasi-static. Second-order linear dynamic constraint models have been proposed to prevent the search from returning solutions that are feasible if each point were run at steady state, but which are unrealistic in a transient sense. Dynamic constraint models translate commanded parameters to actually achieved parameters that then feed into the transient emission and torque models. Combined model inaccuracies have been used to adjust the optimized solutions. To frame the optimization problem within reasonable dimensionality, the coefficients of commanded surfaces that approximate engine tables are adjusted during search iterations, each of which involves simulating the entire transient cycle. The resulting strategy, different from the corresponding manual calibration strategy and resulting in lower emissions and efficiency, is intended to improve rather than replace the manual calibration process.

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Section: Modelling Methods and Model Formmentioning

confidence: 99%

Section: Estimation Of Chosen Model Accuracymentioning

confidence: 99%

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Development of a model-based transient calibration process for diesel engine electronic control module tables – Part 2: modelling and optimization

Brahma

Chi

2011

International Journal of Engine Research

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“…[1][2][3] It was noticed that many kinds of empirical model could 'fit' the PM data but model predictions for test data generated from any transient calibration which are significantly different from that used to generate the training data were poor, i.e. models were calibration dependent.…”

Section: Introductionmentioning

confidence: 98%

A decision-tree-based approach to smoke spike detection in a heavy-duty diesel engine

Brahma

2012

Proceedings of the Institution of Mechanical Engineers, Part D:

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Smoke spikes occurring during transient engine operation have detrimental health effects and increase fuel consumption by requiring more frequent regeneration of the diesel particulate filter. This paper proposes a decision tree approach to real-time detection of smoke spikes for control and on-board diagnostics purposes. A contemporary, electronically controlled heavy-duty diesel engine was used to investigate the deficiencies of smoke control based on the fuel-to-oxygenratio limit. With the aid of transient and steady state data analysis and empirical as well as dimensional modeling, it was shown that the fuel-to-oxygen ratio was not estimated correctly during the turbocharger lag period. This inaccuracy was attributed to the large manifold pressure ratios and low exhaust gas recirculation flows recorded during the turbocharger lag period, which meant that engine control module correlations for the exhaust gas recirculation flow and the volumetric efficiency had to be extrapolated. The engine control module correlations were based on steady state data and it was shown that, unless the turbocharger efficiency is artificially reduced, the large manifold pressure ratios observed during the turbocharger lag period cannot be achieved at steady state. Additionally, the cylinder-to-cylinder variation during this period were shown to be sufficiently significant to make the average fuel-to-oxygen ratio a poor predictor of the transient smoke emissions. The steady state data also showed higher smoke emissions with higher exhaust gas recirculation fractions at constant fuel-to-oxygen-ratio levels. This suggests that, even if the fuel-to-oxygen ratios were to be estimated accurately for each cylinder, they would still be ineffective as smoke limiters. A decision tree trained on snap throttle data and pruned with engineering knowledge was able to use the inaccurate engine control module estimates of the fuel-to-oxygen ratio together with information on the engine control module estimate of the exhaust gas recirculation fraction, the engine speed, and the manifold pressure ratio to predict 94% of all spikes occurring over the Federal Test Procedure cycle. The advantages of this non-parametric approach over other commonly used parametric empirical methods such as regression were described. An application of accurate smoke spike detection in which the injection pressure is increased at points with a high opacity to reduce the cumulative particulate matter emissions substantially with a minimum increase in the cumulative nitrogrn oxide emissions was illustrated with dimensional and empirical modeling.

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“…This controller was able to prevent excessive ignition delay and to improve NOx/HC emissions. Brahma and Chi [26] also developed a model-based transient cali bration process by using both steady-state and transient data. The NOx and PM rates measured for initial and final federal test proce dure (FTP) runs were significantly improved by using their pro posed transient calibration method.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Combustion Phasing Control Strategy During Reactivity Controlled Compression Ignition (RCCI) Multicylinder Engine Load Transitions

Hanson

Reitz

2014

Journal of Engineering for Gas Turbines and Power

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The dual fuel reactivity controlled compression ignition (RCCI) concept has been suc cessfully demonstrated to be a promising, more controllable, high efficiency, and cleaner combustion mode. A multidimensional computational fluid dynamics (CFD) code coupled with detailed chemistry, kiva-chemkin, was applied to develop a strategy for phasing con trol during load transitions. Steady-state operating points at 1500 revlmin were cali brated from 0 to 5 bar brake mean effective pressure (BMEP). The load transitions considered in this study included a load-up and a load-down load change transient between 1 bar and 4 bar BMEP at 1500 revlmin. The experimental results showed that during the load transitions, the diesel injection timing responded in two cycles while around five cycles were needed for the diesel common-rail pressure to reach the target value. However, the intake manifold pressure lagged behind the pedal change for about 50 cycles due to the slower response o f the turbocharger. The effect of these transients on RCCI engine combustion phasing was studied. The CFD model was first validated against steady-state experimental data at 1 bar and 4 bar BMEP. Then the model was used to develop strategies for phasing control by changing the direct port fuel injection (PFI) amount during load transitions. Specific engine operating cycles during the load transitions (six cycles for the load-up transition and seven cycles for the load-down tran sition) were selected based on the change of intake manifold pressure to represent the transition processes. Each cycle was studied separately to find the correct PFI to diesel fuel ratio for the desired CA50 (the crank angle at which 50% of total heat release occurs). The simulation results showed that CA50 was delayed by 7 to 15 deg for the load-up transition and advanced by around 5 deg during the load-down transition if the precalibrated steady-state PFI table was used. By decreasing the PFI ratio by 10% to 15% during the load-up transition and increasing the PFI ratio by around 40% during the load-down transition, the CA50 could be controlled at a reasonable value during transitions. The control strategy can be used for closed-loop control during engine tran sient operating conditions. Combustion and emission results during load transitions are also discussed.

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Development of a model-based transient calibration process for diesel engine electronic control module tables – Part 1: data requirements, processing, and analysis

Cited by 21 publications

References 26 publications

Development of a model-based transient calibration process for diesel engine electronic control module tables – Part 2: modelling and optimization

Development of a model-based transient calibration process for diesel engine electronic control module tables – Part 2: modelling and optimization

A decision-tree-based approach to smoke spike detection in a heavy-duty diesel engine

Investigation of Combustion Phasing Control Strategy During Reactivity Controlled Compression Ignition (RCCI) Multicylinder Engine Load Transitions

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