Innovative Control Strategies for the Diagnosis of Injector Performance in an Internal Combustion Engine via Turbocharger Speed

Becciani, Michele; Romani, Luca; Vichi, Giovanni; Bianchini, Alessandro; Asai, Go; Minamino, Ryota; Bellissima, Alessandro; Ferrara, Giovanni

doi:10.3390/en12081420

Cited by 3 publications

(2 citation statements)

References 31 publications

(22 reference statements)

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“…Each sample presents a certain num- ber of features (inputs to the model) and two labels (outputs of the model) referring respectively to a general anomaly (at least 1 out of 4 cylinders has a wrong injection) and to a localized anomaly (the 1 st cylinder presents a wrong injection). Data collection phase was not performed during this activity but was carried out previously; indeed the experimental setup, the sensors description and the engine features are extensively reported by Becciani et al in (Becciani et al, 2019). For a better understanding Figure 1 shows the matrix of tests performed during data collection; in particular it shows the normalized injected fuel quantity at three engine load levels by varying the engine speed from 1000 rpm to 3000 rpm by steps of 250 rpm.…”

Section: Case-study Scenariomentioning

confidence: 99%

Wrong Injection Detection in a Small Diesel Engine, a Machine Learning Approach

2022

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In the last ten years, Machine Learning (ML) and Artificial Intelligence (AI) have overwhelmed every engineering research branch finding a broad variety of applications; anomaly detection and anomaly classification are two of the topics that have benefited mostly by data-driven methods’ insights. On the other side, in the small diesel engine domain, the current trend is to lean on traditional anomaly detection/classification procedures and do not foster the use of AI. The goal of this work is to detect anomalies in the in-cylinders injectors of a small diesel engine as soon as a wrong quantity of fuel is inputted into one or more cylinders by means of ML approaches. Part of the analysis aim to understand which measurements are the most relevant for the detection and to compare different techniques to select the most suitable one. Furthermore, a condition-based methodology for maintenance is proposed. After a brief review of the state-of-the-art, the case study scenario is presented grouping sensors accordingly to their degree of accessibility; then, the implemented techniques are explained, and results are discussed.

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Section: Case-study Scenariomentioning

confidence: 99%

Wrong Injection Detection in a Small Diesel Engine, a Machine Learning Approach

2022

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“… engine block vibrations, [6][7][8];  acoustic emissions [9][10][11][12];  engine torque by means of torque sensors [13];  measurements through a load cell placed under the head studs, [14][15][16], correlating force to internal pressure;  the use of an instantaneous speed sensor of the turbocharger, [17][18], which allows to derive the thermodynamic cycle of the various cylinders through the analysis of the energy contained in the exhaust gases; However, all these technologies have the common downside of needing the installation of additional sensors on the engine. On the other hand, the use of instantaneous speed measurement, obtained from the engine's phonic wheel, allows to derive the in-cylinder pressure without the need of additional sensors, being this signal already acquired by the engine control unit [19][20][21][22][23][24].…”

Section: Introductionmentioning

confidence: 99%

Real Time Estimation of Combustion Indicators on a 4-Cylinder CI Turbocharged Engine Based on Instantaneous Engine Speed Measurement with Rapid Prototyping Implementation

Bosi

Catalani

Baroni

et al. 2022

J. Phys.: Conf. Ser.

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In the field of Internal Combustion Engines (ICEs), increasingly stricter regulations on pollutant emissions have made necessary to continuously monitor engine operation. Indeed, in order to tackle fault-induced variations in engine performance, continuous, real-time data related to the engine’s thermodynamic cycle is needed: specifically, obtaining detailed information on the engine combustion phase is paramount. Combustion indicators are calculated through in-cylinder pressure, for which both direct and indirect measurement techniques can be employed. The former are accurate, but suffer from limited durability, while the latter are less accurate, but durable and less expensive, therefore more attractive for mass production applications. A technique for reconstructing the pressure cycle of each cylinder, through the combination of instantaneous crankshaft speed signal and a 0D thermodynamic model, was developed by the authors in MATLAB-Simulink environment and validated against experimental data. The objective of the present study is to implement this model on a four-cylinders CI turbocharged engine. Specifically, since focus was put on assessing the model real-time capability, efforts were made to execute the model inside a real-time controller. The paper presents the results of the experimental campaign that was carried out to validate the developed model. The signals from the pickup wheel and the camshaft phase sensor represent the main inputs, as they allow for the calculation of the engine speed and the detection of each cylinder Firing Top Dead Center (FTDC), respectively. Pressure sensors were mounted in all the cylinders for direct pressure acquisition. Tests were carried out under different operating conditions, specifically by varying speed, load and by reproducing the effects of injector malfunction in one cylinder. The developed model proved to be sensitive to operating conditions variations, correctly calculating combustion indicators such as the Indicating Mean Effective Pressure with real-time capability.

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A Test Method for Individual Control of the Engine’s Ecological Parameters

Гриценко

Shepelev

Moor

2020

IOP Conf. Ser.: Earth Environ. Sci.

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An analysis of the state-of-the-art has shown that the dominating number of failures falls at internal combustion engines (ICEs): the ignition system - 15-25%, the power system -30-44%, the exhaust system - 10-15%. It follows from the analysis of modern ICE configurations that the most applicable ICE control method is a selective control method with a subsequent individual adjustment for the current technical condition. The combination of a gas analyzer installed individually in each collector, a motor tester and a test mode former with the function of ensuring test modes allows us to identify failures of the three systems with a high accuracy and to assign an individual corrective action to ensure the specified ecological and economic parameters. A small percentage of throttle opening reliably reflects the information on the mechanical and electrical parts of the injector, matching of the mixture formation and the combustion process at minimal toxicity. In case of a large percentage of throttle opening, the data on the injector section, operation of the ignition system on a rich mixture and significant outlet resistance is informatively reflected.

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Innovative Control Strategies for the Diagnosis of Injector Performance in an Internal Combustion Engine via Turbocharger Speed

Cited by 3 publications

References 31 publications

Wrong Injection Detection in a Small Diesel Engine, a Machine Learning Approach

Wrong Injection Detection in a Small Diesel Engine, a Machine Learning Approach

Real Time Estimation of Combustion Indicators on a 4-Cylinder CI Turbocharged Engine Based on Instantaneous Engine Speed Measurement with Rapid Prototyping Implementation

A Test Method for Individual Control of the Engine’s Ecological Parameters

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