Injector Fouling and Its Impact on Engine Emissions and Spray Characteristics in Gasoline Direct Injection Engines

Henkel, Sebastian; Hardalupas, Y.; Taylor, A. M. K. P.; Conifer, Christopher; Cracknell, Roger; Goh, Tor Kit; Reinicke, Paul-Benjamin; Sens, Marc; Rieß, Michael

doi:10.4271/2017-01-0808

Cited by 45 publications

(21 citation statements)

References 29 publications

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“…In gasoline direct injection (GDI), tip coking can generate a progressive tip sooting that is a large source of particles. [1][2][3] High-magnification and spectrally filtered images of the injector tip showed a high probability of soot formation near the injector tip and also showed an increased probability of hard soot on the injector surface compared to inside the nozzle holes. 1,4 To our knowledge, very limited work has been published in the field of multi-hole direct injection tip wetting as a main factor of the tip coking then fouling, and no clear and detailed process has been proposed up to now.…”

Section: Introductionmentioning

confidence: 99%

The process of tip wetting at the spray injection end

Hélie

Lamarque

Fremaux

et al. 2019

International Journal of Engine Research

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Gasoline direct injection engines mainly use multi-hole high-pressure injectors. To respect the current pollutant regulation (particle number and particle mass) and continue to decrease pollutant emissions in the future, it is of outmost importance to identify the various sources of carbon particles. In gasoline direct injection, tip wetting can generate a progressive tip sooting that can be a source of large number of particles especially in hot engine conditions. The different topics related to the tip wetting are investigated here without counterbore after the metering hole in order to have a direct access to the optical visualization. In this article, the different phases of the tip wetting are identified experimentally and phenomenological models are proposed.

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Section: Introductionmentioning

confidence: 99%

The process of tip wetting at the spray injection end

Hélie

Lamarque

Fremaux

et al. 2019

International Journal of Engine Research

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“…In addition, Jiang's work found that the penetration length and mean droplet size of each jet were increased significantly, in contrast to Song's observations. An increased penetration length was also observed by Henkei et al [134]. Wang et al [69] indicated that deposits inside the counter bore could restrict air recirculation and entrainment, leading to lower exiting turbulent kinetic energy of the spray from a coked injector and producing a larger mean droplet size.…”

Section: Effect Of Injector Deposits On Engine Performancementioning

confidence: 61%

“…Results obtained by Wen et al [137] with a GDI vehicle having a mileage of 13,000 km showed that particulate mass and fuel consumption were increased by 376 and 3.02%, respectively, compared with the values obtained using fresh injectors. In addition, gaseous emissions such as THC, non-methane hydrocarbon (NMHC) and NOx increased by 17.1, 24.5 and 23.4%, respectively, and PN emissions could be increased by several orders of magnitude [133,134]. The fuel stored in the fouled injector tip deposits during injection and then released later caused diffusive combustion events and thus increased PM and PN emissions [112].…”

Section: Effect Of Injector Deposits On Engine Performancementioning

confidence: 99%

Recent Progress in Automotive Gasoline Direct Injection Engine Technology

Shuai

et al. 2018

Automot. Innov.

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Gasoline direct injection (GDI) engines are currently the dominant powertrains for passenger cars. With the implementation of increasingly stringent fuel consumption and emission regulations worldwide, GDI engines are facing challenges owing to high particulate matter emissions and a tendency to knock, leading to a change in the research and design (R&D) issues compared with those in the twentieth century. This paper reviews the progress in research regarding GDI engine technologies over the past 20 years, focusing on combustion system configurations, and also highlights common issues in GDI R&D, including preignition and deto-knock, soot formation and PM emissions, injector deposits and gasoline compression ignition (GCI). First, an overview of recent developments in the field as driven by regulations is provided, following which progress in injection and combustion systems is examined. Third, the review addresses the occurrence and mechanism of deto-knock and considers means of suppressing this phenomenon. The fourth section discusses soot formation mechanisms and particulate matter emission characteristics of GDI engines and describes the application of gasoline particulate filter (GPF) after-treatment. The subsequent section summarizes studies regarding injector deposit formation, as well as pioneering research into GCI combustion modes. Finally, a summary and future prospects for GDI engine technologies are provided.

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“…Investigations of the effect of injector deposits on the injector performance and thermal conditions are scarce [8,17,[80][81][82]. As a result, the mechanism of their adverse action is not completely understood.…”

Section: Effect Of the Deposits On The Injector Performancementioning

confidence: 99%

An adsorption-precipitation model for the formation of injector external deposits in internal combustion engines

et al. 2018

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The occurrence of deposits on fuel injectors used in gasoline direct injection engines can lead to fuel preparation and combustion events which lie outside of the intended engine design envelope. The fundamental mechanism for deposit formation is not well understood. The present work describes the development of a computational model and its application to a direct injection gasoline engine in order to describe the formation of injector deposits and quantify their effect on injector operation. The formation of fuel-derived deposits at the injector tip and inside the nozzle channel is investigated. After the end of an injection event, a fuel drop may leak out of the nozzle and wet the injector tip. The model postulates that the combination of high temperature and the presence of NOx produced by the combustion leads to the initiation of a reaction between the leaked fuel and the oxygen dissolved in it. Subsequently, the oxidation products attach at the injector surface as a polar proto-deposit phase. The rate of deposit formation is predicted for two limiting mechanisms: adsorption and precipitation. The effects of the thermal conditions within the engine and of the fuel composition are investigated. Branched alkanes show worse deposit formation tendency than n-alkanes. The model was also used to predict the impact of injector nozzle deposit thickness on the rate of fuel delivery and on the temperature of the injector surface.

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Injector Fouling and Its Impact on Engine Emissions and Spray Characteristics in Gasoline Direct Injection Engines

Cited by 45 publications

References 29 publications

The process of tip wetting at the spray injection end

The process of tip wetting at the spray injection end

Recent Progress in Automotive Gasoline Direct Injection Engine Technology

An adsorption-precipitation model for the formation of injector external deposits in internal combustion engines

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