Model-Based Pre-Ignition Diagnostics in a Race Car Application

Since 2014, Formula 1 engines have been turbocharged spark-ignited engines. In this scenario, the maximum engine power available in full-load conditions can be achieved only by optimizing combustion phasing within the cycle, i.e., by advancing the center of combustion until the limit established by the occurrence of abnormal combustion. High in-cylinder pressure peaks and the possible occurrence of knocking combustion significantly increase the heat transfer to the walls and might generate hot spots inside the combustion chamber. This work presents a methodology suitable to properly diagnose and control the occurrence of pre-ignition events that emanate from hot spots. The methodology is based on a control-oriented model of the ignition delay, which is compared to the actual ignition delay calculated from the real-time processing of the in-cylinder pressure trace. When the measured ignition delay becomes significantly smaller than that modeled, it means that ignition has been activated by a hot spot instead of the spark plug. In this case, the presented approach, implemented in the electronic control unit (ECU) that manages the whole hybrid power unit, detects a pre-ignition event and corrects the injection pattern to avoid the occurrence of further abnormal combustion.

[1]  Darius Mehta,et al.  Engine Operating Condition and Gasoline Fuel Composition Effects on Low-Speed Pre-Ignition in High-Performance Spark Ignited Gasoline Engines , 2011 .

[2]  Gerardo Valentino,et al.  Optical Investigation of the Effect on the Combustion Process of Butanol-Gasoline Blend in a PFI SI Boosted Engine , 2011 .

[3]  Darius Mehta,et al.  The Effect of EGR on Low-Speed Pre-Ignition in Boosted SI Engines , 2011 .

[4]  R. Dibble,et al.  Effect of Mixture Formation and Injection Strategies on Stochastic Pre-Ignition , 2018, SAE Technical Paper Series.

[5]  M. D. Checkel,et al.  Computerized knock detection from engine pressure records , 1986 .

[6]  Jong-hwa Lee,et al.  A New Knock-Detection Method using Cylinder Pressure, Block Vibration and Sound Pressure Signals from a SI Engine , 1998 .

[7]  N. Cavina,et al.  Individual Cylinder Combustion Control Based on Real-Time Processing of Ion Current Signals , 2007 .

[8]  Masatoshi Suzuki,et al.  A Study of Low Speed Preignition Mechanism in Highly Boosted SI Gasoline Engines , 2015 .

[9]  Elana Chapman,et al.  A Literature Review of Abnormal Ignition by Fuel and Lubricant Derivatives , 2015 .

[10]  Robert W. Dibble,et al.  Effect of Timing and Location of Hotspot on Super Knock during Pre-ignition , 2017 .

[11]  Gian Marco Bianchi,et al.  A Control-Oriented Knock Intensity Estimator , 2017 .

[12]  Emiliano Pipitone,et al.  Development of a low-cost piezo film-based knock sensor , 2003 .

[14]  Manfred Amann,et al.  The Effects of Piston Crevices and Injection Strategy on Low-Speed Pre-Ignition in Boosted SI Engines , 2012 .

[15]  John B. Heywood,et al.  Internal combustion engine fundamentals , 1988 .

[16]  Kwang Min Chun,et al.  Measurement and Analysis of Knock in a SI Engine Using the Cylinder Pressure and Block Vibration Signals , 1994 .

[17]  S. Merola,et al.  Optical Investigations of the Abnormal Combustion in a Boosted Spark-ignition PFI Engine , 2009 .

[18]  U. Maas,et al.  Investigations on Pre-Ignition in Highly Supercharged SI Engines , 2010 .

[19]  Y. Moriyoshi,et al.  Numerical Simulation to Understand the Cause and Sequence of LSPI Phenomena and Suggestion of CaO Mechanism in Highly Boosted SI Combustion in Low Speed Range , 2015 .

[20]  Enrico Corti,et al.  Combination of In-Cylinder Pressure Signal Analysis and CFD Simulation for Knock Detection Purposes , 2009 .