Your search keyword '"4-stroke"' showing total 7 results

1. Numerical Investigation on the Performance of a 4-Stroke Engine with Different Passive Pre-Chamber Geometries Using a Detailed Chemistry Solver.

Author

Bigalli, Simone, Catalani, Iacopo, Balduzzi, Francesco, Matteazzi, Nicola, Agostinelli, Lorenzo, De Luca, Michele, and Ferrara, Giovanni

Subjects

*SPARK ignition engines, *COMPUTATIONAL fluid dynamics, *COMBUSTION chambers, *TURBULENT jets (Fluid dynamics), *AIR-fuel ratio (Combustion), *ENGINES

Abstract

Pre-chamber turbulent jet ignition represents one of the most promising techniques to improve spark ignition engines efficiency and reduce pollutant emissions. This technique consists of igniting the air-fuel mixture in the main combustion chamber by means of several hot turbulent flame jets exiting a pre-chamber. In the present study, the combustion process of a 4-stroke, gasoline SI, PFI engine equipped with a passive pre-chamber has been investigated through three-dimensional CFD (Computational Fluid Dynamics) analysis. A detailed chemistry solver with a reduced reaction mechanism was employed to investigate ignition and flame propagation phenomena. Firstly, the combustion model was validated against experimental data for the baseline engine configuration (i.e., without pre-chamber). Eventually, the validated numerical model allowed for predictive simulations of the pre-chamber-equipped engine. By varying the shape of the pre-chamber body and the size of pre-chamber orifices, different pre-chamber configurations were studied. The influence of the geometrical features on the duration of the combustion process and the pressure trends inside both the pre-chamber and main chamber was assessed and discussed. Since the use of a pre-chamber can extend the air-fuel mixture ignition limits, an additional sensitivity on the air-fuel ratio was carried out, in order to investigate engine performance at lean conditions. [ABSTRACT FROM AUTHOR]

Published

2022

2. 2-Stroke RCCI Engines for Passenger Cars

Author

Enrico Mattarelli, Carlo Alberto Rinaldini, Luca Marmorini, Stefano Caprioli, Francesco Legrottaglie, and Francesco Scrignoli

Subjects

automotive diesel engine, 4-stroke, RCCI (gasoline–diesel), experimental engine characterization, 1D-CFD, 2-stroke, Technology

Abstract

Reactivity Controlled Compression Ignition (RCCI) is one of the most promising solutions among the low temperature combustion concepts, in terms of thermal efficiency and pollutant emissions. However, for values of brake mean effective pressure higher than 10 bar, in-cylinder peak pressure rise rates tend to be too high, limiting the specific power of any 4-Stroke (4S) engine. Such a limitation can be canceled by moving to the 2-Stroke (2S) cycle. Among many alternatives, the “Uniflow” scavenging system with exhaust poppet valves on the cylinder head allows the designer to reproduce the same identical combustion patterns of a 4-stroke RCCI engine, while increasing the indicated power output. The goal of the paper is to explore the potential of a 2-stroke RCCI engine, on the basis of a comprehensive experimental campaign carried out on a modified automotive 2.0 L, 4-stroke, four-cylinder, four-valve diesel engine. The developed prototype can run with one cylinder operating in 4-stroke RCCI mode (gasoline–diesel), while the others work in the standard diesel mode. A One Dimensional-Computational Fluid Dynamics (1D-CFD) model has been built to predict the performance of the same prototype, when operating all four cylinders in RCCI mode. In parallel, an equivalent 2-stroke RCCI virtual engine has been developed, by means of 1D-CFD simulations and empirical assumptions. A numerical comparison between the 4S and the 2S engines is finally presented, in terms of performance and emissions at full load. The study demonstrates that a 2S RCCI engine can maintain all of the advantages of the RCCI combustion, strongly reducing the penalization in terms of performance, in comparison to a standard 4S diesel engine.

Published

2022

3. An investigation of in-cylinder flow and combustion in a spark ignition engine using particle image velocimetry

Author

Haste, Martin J.

Subjects

621.43, 4-stroke, Premixed, Turbulent, Opticle

Abstract

Engine manufactures are currently seeking to develop spark ignition engines that are more fuel efficient, more refined and produce lower amounts of polluting emissions. To achieve these objectives an improved understanding of the factors governing the combustion process is required. Engine in-cylinder fluid motion is known to fundamentally affect fuel–air mixture preparation and flame propagation. Therefore, characterisation and quantification of the in-cylinder flow is an important step in the process of achieving the conditions necessary for optimal combustion. This thesis reports the application of two-colour Particle Image Velocimetry (PIV) to measure extended velocity fields within the combustion chamber of a firing production geometry optical engine. Two-colour PIV was used to obtain high spatial resolution fluid velocity maps for a range of crank angles and engine conditions. PIV measurements were obtained in the unburned gas ahead of the propagating flame and a combustible seeding material was used to clearly define the burned gas region. Data is presented for both the normal 2-valve running conditions and with one inlet port deactivated for both open-valve and closed-valve fuel injection timing.

Published

2000

4. Numerical Investigation on the Performance of a 4-Stroke Engine with Different Passive Pre-Chamber Geometries Using a Detailed Chemistry Solver

Author

Simone Bigalli, Iacopo Catalani, Francesco Balduzzi, Nicola Matteazzi, Lorenzo Agostinelli, Michele De Luca, and Giovanni Ferrara

Subjects

CFD, CONVERGE, numerical simulation, combustion, ICE, gasoline, 4-stroke, TJI, pre-chamber, Control and Optimization, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, Building and Construction, Electrical and Electronic Engineering, Engineering (miscellaneous), Energy (miscellaneous)

Abstract

Pre-chamber turbulent jet ignition represents one of the most promising techniques to improve spark ignition engines efficiency and reduce pollutant emissions. This technique consists of igniting the air-fuel mixture in the main combustion chamber by means of several hot turbulent flame jets exiting a pre-chamber. In the present study, the combustion process of a 4-stroke, gasoline SI, PFI engine equipped with a passive pre-chamber has been investigated through three-dimensional CFD (Computational Fluid Dynamics) analysis. A detailed chemistry solver with a reduced reaction mechanism was employed to investigate ignition and flame propagation phenomena. Firstly, the combustion model was validated against experimental data for the baseline engine configuration (i.e., without pre-chamber). Eventually, the validated numerical model allowed for predictive simulations of the pre-chamber-equipped engine. By varying the shape of the pre-chamber body and the size of pre-chamber orifices, different pre-chamber configurations were studied. The influence of the geometrical features on the duration of the combustion process and the pressure trends inside both the pre-chamber and main chamber was assessed and discussed. Since the use of a pre-chamber can extend the air-fuel mixture ignition limits, an additional sensitivity on the air-fuel ratio was carried out, in order to investigate engine performance at lean conditions.

Published

2022

5. Real-time driving cycle measurements of ultrafine particle emissions from two wheelers and comparison with passenger cars.

Author

Momenimovahed, A., Olfert, J., Checkel, M., Pathak, S., Sood, V., Singh, Y., and Singal, S.

Subjects

*PARTICLE emissions, *MOTORCYCLES, *AUTOMOBILE emissions, *REAL-time computing, *GASOLINE & the environment, *LIQUEFIED petroleum gas & the environment

Abstract

Two wheel vehicles (scooters and motorcycles) make up 74% of the vehicle population in India. An experimental study has been conducted to assess and compare the particulate emissions from several two wheelers and passenger car in a typical Indian fleet. The vehicles, including four 4-stroke, two 2-stroke two-wheelers, and one gasoline-LPG bi-fuel passenger cars, were tested on a chassis dynamometer using the Indian Driving Cycle. A differential mobility spectrometer was employed to measure the particle size distribution in real-time in the range of 5 nm to 560 nm. Particulate size distributions from the two-wheelers were typically bi-modal. The count median diameter with 4-stroke two wheelers was observed in the range of 26 nm to 48 nm. The number and mass emission factors ranged between 9.5 × 10 km to 1.3 × 10 km and 0.80 mg/km to 40 mg/km; respectively. In the case of 2-stroke two wheelers, it was observed that not only the count median diameter is 3 times larger compared to 4-strokes, but also 2-stroke vehicles produce 5 times more particles in term of number and about 60 times more particles in terms of mass. The 2-stroke and 4-stroke two wheelers produced particulate emissions (both in terms of number and mass), which were higher than a gasoline and a LPG passenger vehicle operating on the same driving cycle. [ABSTRACT FROM AUTHOR]

Published

2014

6. 2-Stroke RCCI Engines for Passenger Cars.

Author

Mattarelli, Enrico, Rinaldini, Carlo Alberto, Marmorini, Luca, Caprioli, Stefano, Legrottaglie, Francesco, and Scrignoli, Francesco

Subjects

*DIESEL motors, *ENGINES, *THERMAL efficiency, *EXHAUST systems, *FLUID dynamics

Abstract

Reactivity Controlled Compression Ignition (RCCI) is one of the most promising solutions among the low temperature combustion concepts, in terms of thermal efficiency and pollutant emissions. However, for values of brake mean effective pressure higher than 10 bar, in-cylinder peak pressure rise rates tend to be too high, limiting the specific power of any 4-Stroke (4S) engine. Such a limitation can be canceled by moving to the 2-Stroke (2S) cycle. Among many alternatives, the "Uniflow" scavenging system with exhaust poppet valves on the cylinder head allows the designer to reproduce the same identical combustion patterns of a 4-stroke RCCI engine, while increasing the indicated power output. The goal of the paper is to explore the potential of a 2-stroke RCCI engine, on the basis of a comprehensive experimental campaign carried out on a modified automotive 2.0 L, 4-stroke, four-cylinder, four-valve diesel engine. The developed prototype can run with one cylinder operating in 4-stroke RCCI mode (gasoline–diesel), while the others work in the standard diesel mode. A One Dimensional-Computational Fluid Dynamics (1D-CFD) model has been built to predict the performance of the same prototype, when operating all four cylinders in RCCI mode. In parallel, an equivalent 2-stroke RCCI virtual engine has been developed, by means of 1D-CFD simulations and empirical assumptions. A numerical comparison between the 4S and the 2S engines is finally presented, in terms of performance and emissions at full load. The study demonstrates that a 2S RCCI engine can maintain all of the advantages of the RCCI combustion, strongly reducing the penalization in terms of performance, in comparison to a standard 4S diesel engine. [ABSTRACT FROM AUTHOR]

Published

2022

7. Numerical Investigation of a 4-Stroke, 8-Cylinder Diesel Engine Using a 1-D Code

Author

Anye, Emmanuel and Anye, Emmanuel

Abstract

Diesel engines are important for the movement of people and goods. But they are also essential for generating electricity. While it is desirable that engines become, more efficient, reliable, durable and also environmentally-friendly, achieving this requires a better understanding of the complexities surrounding engine combustion processes. Recent technological advancements, including computer simulation have facilitated research and development of new diesel engines. Using a 1-D model of an 8-Cylinder, 4-Stroke diesel engine and applying a vibe combustion model, this study presents how in-cylinder processes affect diesel engine performance. The results reveal close proximity of the developed model to test bed measurements of the engine under investigation. Additionally, the findings demonstrate the capability of AVL BOOST to provide advanced models that allow for adequate prediction of engine performance.

Published

2016