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32 results on '"Francesco Concetto Pesce"'

1. Numerical Assessment of Additive Manufacturing-Enabled Innovative Piston Bowl Design for a Light-Duty Diesel Engine Achieving Ultra-Low Engine-Out Soot Emissions

Author

Andrea Bianco, Federico Millo, Andrea Piano, Francesco Concetto Pesce, Salvatore Roggio, and Alberto Vassallo

Subjects
Diesel engine, Numerical simulation, Piston geometry, Spray-wall interaction, Light duty, Numerical assessment, General Medicine, medicine.disease_cause, Automotive engineering, Soot, law.invention, Piston, law, medicine, Environmental science
Published
2021

2. Ducted Fuel Injection: A Numerical Soot-Targeted Duct Geometry Optimization

Author

Federico Millo, Benedetta Peiretti Paradisi, Cristiano Segatori, Lucio Postrioti, Andrea Bianco, Francesco Concetto Pesce, Andrea Piano, Luca Pieracci, and Alberto Vassallo

Subjects
Computational fluid dynamics, Diesel combustion, Duct optimization, Ducted fuel injection, Mixing, Soot mitigation, Spray, Materials science, General Medicine, Mechanics, Fuel injection, Energy minimization, medicine.disease_cause, Soot, medicine, Duct (flow)
Published
2021

4. Numerical Investigation on Mixture Formation and Combustion Process of Innovative Piston Bowl Geometries in a Swirl-Supported Light-Duty Diesel Engine

Author

Federico Millo, Francesco Concetto Pesce, Andrea Bianco, Salvatore Roggio, and Andrea Piano

Subjects
Diesel engine, Numerical simulation, Piston geometry, Spray-wall interaction, Materials science, Computer simulation, Light duty, Mixture formation, Mechanical engineering, General Medicine, law.invention, Piston, Combustion process, law
Published
2020

5. Experimental Study of Additive-Manufacturing-Enabled Innovative Diesel Combustion Bowl Features for Achieving Ultra-Low Emissions and High Efficiency

Author

Andrea Boscolo, Francesco Concetto Pesce, Carlo Beatrice, Gennaro Dileo, Giacomo Belgiorno, Gabriele Di Blasio, Alberto Vassallo, Fabio Numidi, and Roberto Ianniello

Subjects
Materials science, business.industry, Mechanical Engineering, Energy Engineering and Power Technology, Diesel combustion, Management Science and Operations Research, Process engineering, business
Published
2020

7. Mixture formation and combustion process analysis of an innovative diesel piston bowl design through the synergetic application of numerical and optical techniques

Author

Carlos Micó, Francesco Concetto Pesce, Felipe Lewiski, José V. Pastor, Andrea Bianco, Alberto Vassallo, Federico Millo, Andrea Piano, and Salvatore Roggio

Subjects
Diesel engine, Materials science, General Chemical Engineering, Optical engine, Mixing (process engineering), Energy Engineering and Power Technology, Mechanical engineering, Combustion, medicine.disease_cause, law.invention, Piston, Diesel fuel, law, medicine, Coupling (piping), OH* chemiluminescence, Combustion image velocimetry, Organic Chemistry, Air/fuel mixing, Computational Fluid Dynamics, Velocimetry, Soot, Fuel Technology, Innovative piston bowl
Abstract

The optimization of diesel engine piston bowl geometries has a crucial role in improving the near-wall flame evolution for better air/fuel mixing and soot reduction. With these aims, an innovative piston bowl for a light-duty diesel engine was designed, coupling both a sharp-stepped lip and radial bumps in the inner bowl rim. The impact of the proposed design was investigated through both 3D-CFD and single-cylinder optical engine. The numerical model, featuring a calibrated spray model and a detailed combustion mechanism, was used to analyse the non-reactive air/fuel mixing and the combustion processes. Results highlighted a reduced jet-to-jet interaction and better air/fuel mixing for the innovative bowl with respect to a conventional re-entrant design, thus enabling faster combustion process after the end of main injection. Numerical results in terms of flame’s kinematic and oxidation process were compared with the combustion image velocimetry (CIV) and OH* chemiluminescence from the optical engine, showing higher velocity near the radial bumps, and faster flame recirculation towards the piston center. Moreover, both experiments and simulations showed a more intense OH distribution in the radial-bumps region and above the step during the first stage of the combustion process, thanks to the enhanced air/fuel mixing.

Published
2022

8. Effect of a novel piston geometry on the combustion process of a light-duty compression ignition engine: An optical analysis

Author

Felipe Lewiski, José V. Pastor, Carlos Micó, Alberto Vassallo, Francesco Concetto Pesce, and Antonio García

Subjects
Materials science, 020209 energy, Flow (psychology), Geometry, 02 engineering and technology, Bowl geometry, Combustion, medicine.disease_cause, Compression ignition, Industrial and Manufacturing Engineering, law.invention, Cylinder (engine), Piston, 020401 chemical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, medicine, Optical engines, 0204 chemical engineering, Electrical and Electronic Engineering, Optical techniques, Combustion image velocimetry, Civil and Structural Engineering, Mechanical Engineering, Building and Construction, Velocimetry, Compression (physics), Pollution, Soot, Ignition system, General Energy, MAQUINAS Y MOTORES TERMICOS
Abstract

[EN] The development of new piston geometries has shown great potential to achieve the low levels of soot emissions required by regulation. Thus, the present paper aims to characterize the influence of a new piston design over combustion process. It is characterized by the introduction of protrusions around the periphery of the bowl, evenly spaced. The performance of this geometry is compared to other geometries that have been extensively analyzed in literature, under similar operating conditions. To achieve this objective, a single cylinder optical compression ignition engine was used with full-quartz pistons rep resenting three bowl geometries: re-entrant, stepped lip and wave-stepped lip. Two optical techniques (OH* chemiluminescence and Natural Luminosity-NL) were applied for identifying the near stoichiometric zones and the differences in the combustion evolution. The flame movement was analyzed by applying the combustion image velocimetry (CIV) algorithms. In addition, an in-cylinder pressure analysis was performed for each piston at 4.5 bar and 7.5 bar IMEP and the differences in terms of Rate of Heat Release were highlighted. A more intense reverse flow was clearly identified when using wave protrusions inside the bowl. The stepped lip and wave-stepped lip bowl present faster late cycle oxidation with much near-stoichiometric zones than re-entrant piston, The authors gratefully acknowledge General Motors Propulsion Systems-Torino S. r.I. for support the project. Daniel Lerida for his laboratory work on the engine maintenance, operation, and control. This work was partially funded by Generalitat Valenciana through the Programa Santiago Grisolia (GRISOLIAP/2018/142) program.

Published
2021

9. Ducted Fuel Injection: Experimental and numerical investigation on fuel spray characteristics, air/fuel mixing and soot mitigation potential

Author

Alberto Vassallo, Lucio Postrioti, Francesco Concetto Pesce, Federico Millo, Andrea Piano, Andrea Bianco, L. Pieracci, and B. Peiretti Paradisi

Subjects
Spray characteristics, 020209 energy, General Chemical Engineering, Nuclear engineering, Nozzle, Energy Engineering and Power Technology, 02 engineering and technology, law.invention, Ducted Fuel Injection, 020401 chemical engineering, law, Mixing combustion, 0202 electrical engineering, electronic engineering, information engineering, Duct (flow), 0204 chemical engineering, Diesel, Fuel spray, Organic Chemistry, Autoignition temperature, Fuel injection, Ignition system, Fuel Technology, Environmental science, Air entrainment, Combustion chamber
Abstract

Enhancing mixture preparation upstream of the premixed autoignition zone is a solution to reduce soot emission formation in compression ignition engines. With this aim, in recent years, Ducted Fuel Injection (DFI) concept has been developed: DFI is based on the idea of injecting the fuel spray through a small cylindrical pipe within the combustion chamber at a certain distance from the nozzle injector hole. Recent research studies have highlighted the high potential of this innovative concept for soot mitigation in both constant volume vessel and engine-like operating conditions. However, the mechanisms driving the soot reduction have not yet been fully understood. The aim of this research work is to further investigate the DFI concept, evaluating its impact on the spray characteristics, on the air/fuel mixing and, therefore, on the soot formation phenomena. Firstly, an experimental activity was carried out by means of a constant volume vessel test bench with optical accesses to compare the spray evolution and sizing with and without duct adoption, over a wide range of vessel thermodynamic conditions and injection pressures. After that, a simulation setup was defined in the commercially available 3D-CFD software CONVERGE reproducing the experimental test bench, calibrating and validating the spray model. Firstly, the spray model was calibrated and validated considering the same non-reacting conditions exploited in the experimental analysis. Then, the calibrated spray model was used as a virtual tool to investigate the air entrainment process. As a results, the DFI adoption increases the air entrainment in the near-nozzle region caused by the high velocity spray that generates a pumping effect at the duct inlet. Moreover, mixing process is also enhanced by the turbulence distribution at the duct exit resulting in a narrower distribution of equivalence ratio at the ignition. As a consequence of the more effective air entrainment and improved turbulent mixing, DFI remarkably mitigates soot emissions, with a reduction up to 80% with respect to free spray configuration in all tested operating conditions.

Published
2021

10. Development and Assessment of an Integrated 1D-3D CFD Codes Coupling Methodology for Diesel Engine Combustion Simulation and Optimization

Author

Mario Rocco Marzano, Benedetta Peiretti Paradisi, Francesco Concetto Pesce, Federico Millo, Andrea Bianco, and Andrea Piano

Subjects
Control and Optimization, Computer science, 020209 energy, Automotive industry, Energy Engineering and Power Technology, 02 engineering and technology, computational fluid dynamics, Computational fluid dynamics, pollutant emissions prediction, Diesel engine, Combustion, medicine.disease_cause, lcsh:Technology, Automotive engineering, Diesel fuel, 0203 mechanical engineering, Calibration, 0202 electrical engineering, electronic engineering, information engineering, medicine, Electrical and Electronic Engineering, Engineering (miscellaneous), automotive_engineering, NOx, diesel engines, Pollutant, Computer simulation, Renewable Energy, Sustainability and the Environment, business.industry, lcsh:T, Soot, 020303 mechanical engineering & transports, numerical simulation, business, Energy (miscellaneous)
Abstract

In this paper, an integrated and automated methodology for the coupling between 1D- and 3D-CFD simulation codes is presented, which has been developed to support the design and calibration of new diesel engines. The aim of the proposed methodology is to couple 1D engine models, which may be available in the early stage engine development phases, with 3D predictive combustion simulations, in order to obtain reliable estimates of engine performance and emissions for newly designed automotive diesel engines. The coupling procedure features simulations performed in 1D-CFD by means of GT-SUITE and in 3D-CFD by means of Converge, executed within a specifically designed calculation methodology. An assessment of the coupling procedure has been performed by comparing its results with experimental data acquired on an automotive diesel engine, considering different working points, including both part load and full load conditions. Different multiple injection schedules have been evaluated for part-load operation, including pre and post injections. The proposed methodology, featuring detailed 3D chemistry modeling, was proven to be capable assessing pollutant formation properly, specifically to estimate NOx concentrations. Soot formation trends were also well-matched for most of the explored working points. The proposed procedure can therefore be considered as a suitable methodology to support the design and calibration of new diesel engines, due to its ability to provide reliable engine performance and emissions estimations from the early stage of a new engine development.

Published
2020

11. Multi-Objective Optimization of Fuel Injection Pattern for a Light-Duty Diesel Engine through Numerical Simulation

Author

Francesco Sapio, Federico Millo, Francesco Concetto Pesce, and Andrea Piano

Subjects
Optimization, Fuel Injection, Computer simulation, Computer science, 020209 energy, Light duty, Compression Ignition, 02 engineering and technology, General Medicine, Diesel engine, Fuel injection, Multi-objective optimization, Automotive engineering, 020303 mechanical engineering & transports, 0203 mechanical engineering, Automotive Engineering, 0202 electrical engineering, electronic engineering, information engineering, Simulation
Published
2018

12. Experimental and Numerical Assessment of Multi-Event Injection Strategies in a Solenoid Common-Rail Injector

Author

Andrea Cavicchi, Andrea Piano, Francesco Concetto Pesce, Federico Millo, Lucio Postrioti, and Giulio Boccardo

Subjects
Common rail, Computer science, 020209 energy, Solenoid, 02 engineering and technology, General Medicine, Injector, Combustion, Fuel injection, Diesel engine, Automotive engineering, law.invention, Automotive Engineering, Fuel Technology, Dwell time, 020303 mechanical engineering & transports, 0203 mechanical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, Fuel efficiency
Abstract

Nowadays, injection rate shaping and multi-pilot events can help to improve fuel efficiency, combustion noise and pollutant emissions in diesel engine, providing high flexibility in the shape of the injection that allows combustion process control. Different strategies can be used in order to obtain the required flexibility in the rate, such as very close pilot injections with almost zero Dwell Time or boot shaped injections with optional pilot injections. Modern Common-Rail Fuel Injection Systems (FIS) should be able to provide these innovative patterns to control the combustion phases intensity for optimal tradeoff between fuel consumption and emission levels.In this work, a 1D-CFD model in GT-SUITE of a solenoid ballistic Common-Rail injector was firstly refined respect to the previous work [1] and then it was validated against an extensive experimental dataset of single injections, standard double pilot and multi-pilot injection patterns (up to 4 pilot events) with almost zero dwell time between two consecutive injection events. The experimental hydraulic test data used to validate the one-dimensional model were obtained by means of the UniPG Injection Analyzer based on the Zeuch's method.The comparison between the experimental and simulated volumetric injection rates showed a more than satisfactory accuracy of the model in predicting the actual behavior of the ballistic injector for all the injection patterns tested, even for relatively complex injector command strategies, characterized by reduced Dwell Time values between consecutive injection events.

Published
2017

14. Balancing Hydraulic Flow and Fuel Injection Parameters for Low-Emission and High-Efficiency Automotive Diesel Engines

Author

Carlo Beatrice, Francesco Concetto Pesce, Roberto Ianniello, Giacomo Belgiorno, Gabriele Di Blasio, Giovanni Avolio, and Alberto Vassallo

Subjects
Diesel fuel, Materials science, engine, business.industry, Low emission, Flow (psychology), Automotive industry, business, Fuel injection, Automotive engineering
Abstract

The introduction of new light-duty vehicle emission limits to comply under real driving conditions (RDE) is pushing the diesel engine manufacturers to identify and improve the technologies and strategies for further emission reduction. The latest technology advancements on the after-treatment systems have permitted to achieve very low emission conformity factors over the RDE, and therefore, the biggest challenge of the diesel engine development is maintaining its competitiveness in the trade-off "CO2-system cost" in comparison to other propulsion systems. In this regard, diesel engines can continue to play an important role, in the short-medium term, to enable cost-effective compliance of CO2-fleet emission targets, either in conventional or hybrid propulsion systems configuration. This is especially true for large-size cars, SUVs and light commercial vehicles. In this framework, a comprehensive approach covering the whole powertrain is of primary importance in order to simultaneously meet the performance, efficiency, noise and emission targets, and therefore, further development of the combustion system design and injection system represent important levers for additional improvements. For this purpose, a dedicated 0.5 dm3 single-cylinder engine has been developed and equipped with, a state-of-the-art Euro 6 combustion system, and an advanced common rail fuel injection system (FIS) offering higher flexibility in terms of injection strategy and higher quantity accuracy. Three injector nozzles with different hydraulic flow rates (HF) have been selected and employed for the overall combustion process optimization. The optimization has been performed by means of an extensive DoE-based test campaign in which the engine and FIS operating parameters have been parametrized with the aim to carry out a proper combination in terms of HF and injection strategy. The results at partial load conditions evidence significant advantages in applying an advanced injection pattern, while the HF reduction can significantly improve the smoke emission and combustion noise without fuel consumption penalties. Therefore, a proper combination and optimization of the HF and injection strategy can provide low noise and engine-out smoke while maintaining the rated power performance targets.

Published
2019

17. Key Fuel Injection System Features for Efficiency Improvement in Future Diesel Passenger Cars

Author

Roberto Ianniello, Francesco Concetto Pesce, Gabriele Di Blasio, Carlo Beatrice, Giovanni Avolio, and Alberto Vassallo

Subjects
Diesel fuel, Peak firing pressure reduction, Key (cryptography), Environmental science, Advanced fuel injection system, Fuel injection, Automotive engineering, Advanced fuel injection pattern Diesel engine, High efficiency
Abstract

Diesel will continue to be an indispensable energy carrier for the car fleet CO2 emission targets in the short-term. This is particularly relevant for heavy-duty vehicles as for mid-size cars and SUVs. Looking at the latest technology achievements on the after-treatment systems, it can be stated that the concerning about the NOx emission gap between homologation test and real road use is basically solved, while the future challenge for diesel survival is to keep its competitiveness in the CO2 vs cost equation in comparison to other propulsion systems. The development of the combustion system design still represents an important leverage for further efficiency and emissions improvements while keeping the current excellent performance in terms of power density and low-end torque. The paper describes the results achieved in developing a new diesel combustion system for car application that, leveraging on the high flexibility of the latest fuel injection technology, combines outstanding power and fuel efficiency with low pollutant emissions in ultralight engine designed for lower maximum peak cylinder pressure. The study has been carried out on a 0.5l single-cylinder engine on which an advanced and last generation common rail system, capable of very high injection pressure, has been installed. Through an extensive DoE-based test campaign in which all engine operating parameters have been carefully parametrized, the capability to achieve high power density and excellent fuel economy with low engine-out pollutant emissions has been demonstrated and discussed in the paper.

Published
2019

18. Numerical and experimental investigation of a piston thermal barrier coating for an automotive diesel engine application

Author

Francesco Concetto Pesce, Federico Millo, Giulio Boccardo, Sabino Caputo, Giancarlo Cifali, and Andrea Piano

Subjects
Automotive engine, Materials science, 020209 energy, Energy Engineering and Power Technology, 02 engineering and technology, engineering.material, Industrial and Manufacturing Engineering, Automotive engineering, law.invention, Thermal barrier coating, Piston, Engine efficiency, 020401 chemical engineering, Coating, law, Thermal barrier, 0202 electrical engineering, electronic engineering, information engineering, Thrust specific fuel consumption, 0204 chemical engineering, coating Diesel, engine, Low heat rejection engine, Engine insulation, coating Piston, Engine efficiency, Heat transfer, Fuel efficiency, engineering
Abstract

This paper investigates the potential of coated pistons in reducing fuel consumption and pollutant emissions of a 1.6 l automotive diesel engine. After a literary review on the state-of-the-art of the materials used as Thermal Barrier Coatings for automotive engine applications, anodized aluminum has been selected as the most promising one. In particular, it presents very low thermal conductivity and heat capacity which ensure a high “wall temperature swing” property. Afterwards, a numerical analysis by utilizing a one-dimensional Computational Fluid Dynamics engine simulation code has been carried out to investigate the potential of the anodized aluminum as piston Thermal Barrier Coating. The simulations have highlighted the potential of achieving up to about 1% in Indicated Specific Fuel Consumption and 6% in heat transfer reduction. To confirm the simulation results, the coated piston technology has been experimentally evaluated on a prototype engine and compared to the baseline aluminum pistons. Despite the promising potential for Indicated Specific Fuel Consumption reduction highlighted by the numerical simulation, the experimental campaign has indicated a slight worsening of the engine efficiency (up to 2% at lower load and speed) due to the slowdown of the combustion process. The primary cause of these inefficiencies is attributed to the roughness of the coating.

Published
2019

19. Impact of counter-bore nozzle on the combustion process and exhaust emissions for light-duty diesel engine application

Author

Raul Payri, Joaquin De La Morena, Javier Monsalve-Serrano, Francesco Concetto Pesce, and Alberto Vassallo

Subjects
020209 energy, Mechanical Engineering, Light duty, Nozzle, Mixing (process engineering), Aerospace Engineering, Combustion, Ocean Engineering, 02 engineering and technology, Fuel injection, Diesel engine, Hydraulic, Automotive engineering, Spray, 020303 mechanical engineering & transports, 0203 mechanical engineering, Engine efficiency, Combustion process, Emissions, Automotive Engineering, MAQUINAS Y MOTORES TERMICOS, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Counter-bore
Abstract

[EN] This article describes the main results of an investigation about counter-bore injector nozzle impact on the combustion process in a modern Euro 6 diesel engine. First, hydraulic and spray visualization tests have been performed, showing a potential advantage of such nozzle design in fuel-air mixing efficiency. Then, combustion performance has been assessed on a GM-designed 1.6-L four-cylinder engine. The engine has been installed on a dynamometric test bench and instrumented with an AVL cylinder pressure transducer for heat release rate analysis, as well as HORIBA MEXA gas analyzer for exhaust emissions and AVL 415 Smoke Meter. Engine efficiency and emissions have been analyzed on four different part-load steady-state points, representative of New European Driving Cycle and Worldwide harmonized Light duty Test Cycle certification cycles, and covering engine speeds from 1250 to 2000 r/min and brake mean effective pressure between 0.2 and 1.4 MPa. Results of indicated analysis show that counter-bore nozzles have significant differences in terms of pilot injection combustion at low load points, which in turn lead to a better ignition and shorter combustion of the main injection. In addition, an improvement of diffusive combustion is observed as load increases. Because of both, fuel consumption is reduced by approximately 1% with respect to a standard nozzle. Finally, an appreciable decrease in engine exhaust emissions has been recorded, especially in terms of particulate matter and hydrocarbon emissions. This reduction has been linked to the improvement of fuel-air mixing promoted by the counter-bore nozzle previously observed., The authors would like to thank General Motors Global Propulsion Systems-Torino S.r.l. for sponsoring the current work. Part of the equipment was purchased with the help of Generalitat Valenciana in project IDIFEDER2018 with title "Equipamiento de diagnostico optico de alta velocidad para estudiar procesos de inyeccion''.

Published
2019

20. Numerical and Experimental Assessment of a Solenoid Common-Rail Injector Operation with Advanced Injection Strategies

Author

Andrea Cavicchi, Giulia Biscontini, Federico Millo, Lucio Postrioti, Andrea Piano, and Francesco Concetto Pesce

Subjects
Common rail, Materials science, 020209 energy, Solenoid, 02 engineering and technology, General Medicine, Injector, Automotive engineering, law.invention, Automotive Engineering, Fuel Technology, law, 0202 electrical engineering, electronic engineering, information engineering
Published
2016

22. The Key Role of Advanced, Flexible Fuel Injection Systems to Match the Future CO2 Targets in an Ultra-Light Mid-Size Diesel Engine

Author

Carlo Beatrice, Francesco Concetto Pesce, Alberto Vassallo, Giacomo Belgiorno, Gabriele Di Blasio, and Giovanni Avolio

Subjects
020303 mechanical engineering & transports, 0203 mechanical engineering, 020209 energy, Advanced Injection Systems, 0202 electrical engineering, electronic engineering, information engineering, Key (cryptography), Environmental science, 02 engineering and technology, Fuel injection, Diesel engine, Diesel Engines, High Efficiency, Automotive engineering
Abstract

The paper describes the results achieved in developing a new diesel combustion system for passenger car application that, while capable of high power density, delivers excellent fuel economy through a combination of mechanical and thermodynamic efficiencies improvement. The project stemmed from the idea that, by leveraging the high fuel injection pressure of last generation common rail systems, it is possible to reduce the engine peak firing pressure (pfp) with great benefits on reciprocating and rotating components light-weighting and friction for high-speed light-duty engines, while keeping the power density at competitive levels. To this aim, an advanced injection system concept capable of injection pressure greater than 2500 bar was coupled to a prototype engine featuring newly developed combustion system. Then, the matching among these features have been thoroughly experimentally examined. The results confirmed the benefits of the employment of high fuel injection pressures as a way to reduce the pfp, combining competitive performance and excellent fuel efficiency with emissions and Noise Vibration Harshness (NVH) requirements of last generation diesel engines for passenger car applications. In particular, the paper discusses the engine power and efficiency sensitivities to the boundary conditions of the charging/exhaust systems, the fuel injection pressure and the mechanical base engine design (with particular reference to the pfp). Eventually, a balanced set of targets for the entire system based on such results are carried out.

Published
2018

23. Experimental and Numerical Investigations of Close-Coupled Pilot Injections to Reduce Combustion Noise in a Small-Bore Diesel Engine

Author

Kan Zha, Richard C. Peterson, Alok Warey, Stephen Busch, Alberto Vassallo, Francesco Concetto Pesce, and Paul C. Miles

Subjects
Materials science, Internal combustion engine, business.industry, Carbureted compression ignition model engine, Homogeneous charge compression ignition, General Medicine, Exhaust gas recirculation, Diesel cycle, business, Diesel engine, Fuel injection, Automotive engineering, Petrol engine
Published
2015

24. Functional Requirements to Exceed the 100 kW/l Milestone for High Power Density Automotive Diesel Engines

Author

Francesco Concetto Pesce, Alberto Vassallo, Carlo Beatrice, Giacomo Belgiorno, and Gabriele Di Blasio

Subjects
Engineering, High Power density High Fuel Injection Pressures High Power Diesel Engines, business.industry, 020209 energy, Automotive industry, Functional requirement, 02 engineering and technology, General Medicine, High power density, 010501 environmental sciences, 01 natural sciences, Automotive engineering, Manufacturing engineering, Diesel fuel, 0202 electrical engineering, electronic engineering, information engineering, Milestone (project management), business, 0105 earth and related environmental sciences
Abstract

The paper describes the challenges and results achieved in developing a new high-speed Diesel combustion system capable of exceeding the imaginative threshold of 100 kW/l. High-performance, state-of-art prototype components from automotive diesel technology were provided in order to set-up a single-cylinder research engine demonstrator. Key design parameters were identified in terms boost, engine speed, fuel injection pressure and injector nozzle flow rates. In this regard, an advanced piezo injection system capable of 3000 bar of maximum injection pressure was selected, coupled to a robust base engine featuring ?-shaped combustion bowl and low swirl intake ports. The matching among the above-described elements has been thoroughly examined and experimentally parameterized. The tests confirmed the benefits of the employment of very high fuel injection pressures as a way to decouple the trade-off between an excellent power rating and emissions / NVH / CO2 at part load, whose combination truly defines the leading edge of modern diesel engines for automotive application. The paper also discusses the system sensitivity to the boundary conditions, of the charging and exhaust systems, and develops a balanced set of targets for the entire system based on thermo-structural, fluid-dynamics and efficiency considerations. This would represent, in the authors' view, the 'recipe' for the next generation of premium diesel engines for automotive application

Published
2017

25. Digital Shaping and Optimization of Fuel Injection Pattern for a Common Rail Automotive Diesel Engine through Numerical Simulation

Author

Andrea Piano, Francesco Sapio, Francesco Concetto Pesce, and Federico Millo

Subjects
Diesel / Compression Ignition engines, Engineering, Common rail, business.industry, 020209 energy, 02 engineering and technology, Fuel injection, Combustion, Diesel engine, Simulation and modeling, Automotive engineering, Brake specific fuel consumption, Burn rate (chemistry), 020303 mechanical engineering & transports, 0203 mechanical engineering, Range (aeronautics), 0202 electrical engineering, electronic engineering, information engineering, business, NOx
Abstract

Development trends in modern Common Rail Fuel Injection System (FIS) show dramatically increasing capabilities in terms of optimization of the fuel injection pattern through a constantly increasing number of injection events per engine cycle along with a modulation and shaping of the injection rate. In order to fully exploit the potential of the abovementioned fuel injection pattern optimization, numerical simulation can play a fundamental role by allowing the creation of a kind of a virtual injection rate generator for the assessment of the corresponding engine outputs in terms of combustion characteristics such as burn rate, emission formation and combustion noise (CN). This paper is focused on the analysis of the effects of digitalization of pilot events in the injection pattern on Brake Specific Fuel Consumption (BSFC), CN and emissions for a EURO 6 passenger car 4-cylinder diesel engine. The numerical evaluation was performed considering steady-state conditions for 3 key points representative of typical operating conditions in the low-medium load range. The optimization process was carried out through numerical simulation, by means of a suitable target function aiming to minimize BSFC and CN while not exceeding the target NOx emissions level. By means of a previously developed fuel injection system model, possible different injection patterns with high number of pilot injections were evaluated thus obtaining a kind of virtual injection rate generator, the outcomes of which were then used as input for a DIPulse combustion model in order to predict BSFC, combustion noise and emissions. Through numerical optimization of pilot injection pattern digitalization, potential for achieving significant reductions in BSFC and CN for low load engine points while not exceeding the target NOx emissions level, was demonstrated.

Published
2017

26. Numerical Investigation on the Effects of Different Thermal Insulation Strategies for a Passenger Car Diesel Engine

Author

Giancarlo Cifali, Federico Millo, Francesco Concetto Pesce, and Sabino Caputo

Subjects
Thermal efficiency, Materials science, business.industry, 020209 energy, Mechanical engineering, 02 engineering and technology, General Medicine, Thermal conduction, Diesel engine, Automotive engineering, law.invention, Thermal barrier coating, Piston, 020303 mechanical engineering & transports, 0203 mechanical engineering, Thermal insulation, law, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Combustion chamber, business
Abstract

One of the key technologies for the improvement of the diesel engine thermal efficiency is the reduction of the engine heat transfer through the thermal insulation of the combustion chamber. This paper presents a numerical investigation on the effects of the combustion chamber insulation on the heat transfer, thermal efficiency and exhaust temperatures of a 1.6 l passenger car, turbo-charged diesel engine. First, the complete insulation of the engine components, like pistons, liner, firedeck and valves, has been simulated. This analysis has showed that the piston is the component with the greatest potential for the in-cylinder heat transfer reduction and for Brake Specific Fuel Consumption (BSFC) reduction, followed by firedeck, liner and valves. Afterwards, the study has been focused on the impact of different piston Thermal Barrier Coatings (TBCs) on heat transfer, performance and wall temperatures. This analysis has been performed using a 1-D engine simulation code coupled with a lumped mass thermal model, representing the engine structure. A time-periodic wall conduction model has been used to calculate the wall temperature swings along the combustion chamber surface and within the engine cycle. Two different TBC materials, Yttria-Partially Stabilized Zirconia (Y-PSZ) and anodized aluminum, and different layer thicknesses have been simulated.

Published
2017

27. On the Reduction of Combustion Noise by a Close-Coupled Pilot Injection in a Small-Bore Direct-Injection Diesel Engine

Author

Stephen Busch, Richard C. Peterson, Francesco Concetto Pesce, Alok Warey, and Kan Zha

Subjects
Combustion noise, Materials science, business.industry, 020209 energy, Mechanical Engineering, Energy Engineering and Power Technology, Aerospace Engineering, 02 engineering and technology, Diesel cycle, Combustion, Diesel engine, Automotive engineering, Reduction (complexity), 020303 mechanical engineering & transports, Fuel Technology, 0203 mechanical engineering, Nuclear Energy and Engineering, 0202 electrical engineering, electronic engineering, information engineering, Noise control, Pilot injection, Exhaust gas recirculation, business
Abstract

For a pilot–main injection strategy in a single-cylinder light-duty diesel engine, the dwell between the pilot- and main-injection events can significantly impact combustion noise. As the solenoid energizing dwell decreases below 200 μs, combustion noise decreases by approximately 3 dB and then increases again at shorter dwells. A zero-dimensional thermodynamic model has been developed to capture the combustion noise reduction mechanism; heat release (HR) profiles are the primary simulation input and approximating them as top-hat shapes preserves the noise reduction effect. A decomposition of the terms of the underlying thermodynamic equation reveals that the direct influence of HR on the temporal variation of cylinder pressure is primarily responsible for the trend in combustion noise. Fourier analyses reveal the mechanism responsible for the reduction in combustion noise as a destructive interference in the frequency range between approximately 1 kHz and 3 kHz. This interference is dependent on the timing of increases in cylinder pressure during pilot HR relative to those during main HR. The mechanism by which combustion noise is attenuated is fundamentally different from the traditional noise reduction that occurs with the use of long-dwell pilot injections, for which noise is reduced primarily by shortening the ignition delay of the main injection. Band-pass filtering of measured cylinder pressure traces provides evidence of this noise reduction mechanism in the real engine. When this close-coupled pilot noise reduction mechanism is active, metrics derived from cylinder pressure such as the location of 50% HR, peak HR rates, and peak rates of pressure rise cannot be used reliably to predict trends in combustion noise. The quantity and peak value of the pilot HR affect the combustion noise reduction mechanism, and maximum noise reduction is achieved when the height and steepness of the pilot HR profile are similar to the initial rise of the main HR event. A variation of the initial rise rate of the main HR event reveals trends in combustion noise that are the opposite of what would happen in the absence of a close-coupled pilot. The noise reduction mechanism shown in this work may be a powerful tool to improve the tradeoffs among fuel efficiency, pollutant emissions, and combustion noise.

Published
2016

28. On the Reduction of Combustion Noise by a Close-Coupled Pilot Injection in a Small-Bore DI Diesel Engine

Author

Francesco Concetto Pesce, Alok Warey, Kan Zha, Richard C. Peterson, and Stephen Busch

Subjects
Reduction (complexity), law, Noise reduction, Noise control, Fuel efficiency, Environmental science, Mechanics, Combustion, Diesel engine, Noise (radio), Simulation, Cylinder (engine), law.invention
Abstract

For a pilot-main injection strategy in a single cylinder light duty diesel engine, the dwell between the pilot- and main-injection events can significantly impact combustion noise. As the solenoid energizing dwell decreases below 200 μs, combustion noise decreases by approximately 3 dB and then increases again at shorter dwells. A zero-dimensional thermodynamic model has been developed to capture the combustion-noise reduction mechanism; heat-release profiles are the primary simulation input and approximating them as top-hat shapes preserves the noise-reduction effect. A decomposition of the terms of the underlying thermodynamic equation reveals that the direct influence of heat-release on the temporal variation of cylinder-pressure is primarily responsible for the trend in combustion noise. Fourier analyses reveal the mechanism responsible for the reduction in combustion noise as a destructive interference in the frequency range between approximately 1 kHz and 3 kHz. This interference is dependent on the timing of increases in cylinder-pressure during pilot heat-release relative to those during main heat-release. The mechanism by which combustion noise is attenuated is fundamentally different from the traditional noise reduction that occurs with the use of long-dwell pilot injections, for which noise is reduced primarily by shortening the ignition delay of the main injection. Band-pass filtering of measured cylinder-pressure traces provides evidence of this noise-reduction mechanism in the real engine. When this close-coupled pilot noise-reduction mechanism is active, metrics derived from cylinder-pressure such as the location of 50% heat-release, peak heat-release rates, and peak rates of pressure rise cannot be used reliably to predict trends in combustion noise. The quantity and peak value of the pilot heat-release affect the combustion noise reduction mechanism, and maximum noise reduction is achieved when the height and steepness of the pilot heat-release profile are similar to the initial rise of the main heat-release event. A variation of the initial rise-rate of the main heat-release event reveals trends in combustion noise that are the opposite of what would happen in the absence of a close-coupled pilot. The noise-reduction mechanism shown in this work may be a powerful tool to improve the tradeoffs among fuel efficiency, pollutant emissions, and combustion noise.

Published
2015

29. Multidimensional Modeling of Natural Gas Jet and Mixture Formation in Direct Injection Spark Ignition Engines—Development and Validation of a Virtual Injector Model

Author

Mirko Baratta, Francesco Concetto Pesce, and Andrea Catania

Subjects
Jet (fluid), business.industry, Mechanical Engineering, Nuclear engineering, Nozzle, Injector, Methane, law.invention, Ignition system, chemistry.chemical_compound, chemistry, law, Natural gas, Spark (mathematics), Environmental science, Combustion chamber, business
Abstract

During the last few years, the integration of CFD tools in the internal combustion (IC) engine design process has continually increased, allowing time and cost savings as the need for experimental prototypes has diminished. Numerical analyses of IC engine flows are rather complex from both the conceptual and operational sides. In fact, these flows involve a variety of unsteady phenomena and the right balance between numerical solution accuracy and computational cost should always be reached. The present paper is focused on computational modeling of natural gas (NG) direct injection (DI) processes from a poppet-valve injector into a bowl-shaped combustion chamber. At high injection pressures, the gas efflux from the injector and the mixture formation processes include turbulent and compressible flow features, such as rarefaction waves and shock formation, which are difficult to accurately capture with numerical simulations, particularly when the combustion chamber geometry is complex and the piston and intake/exhaust valve grids are moving. In this paper, a three-dimensional moving grid model of the combustion engine chamber, originally developed by the authors to include simulation of the actual needle lift, has been enhanced by increasing the accuracy in the proximity of the sonic section of the critical valve-seat nozzle, in order to precisely capture the expansion dynamics the methane undergoes inside the injector and immediately downstream from it. The enhanced numerical model was then validated by comparing the numerical results to Schlieren experimental images for gas injection into a constant-volume bomb. Numerical studies were carried out in order to characterize the fuel-jet properties and the evolution of mixture formation for a centrally mounted injector configuration in the case of a pancake-shaped test chamber and the real engine chamber. Finally, the fluid properties calculated by the model in the throat section of the critical nozzle were taken as reference data for developing a new effective virtual injector model, which allows the designer to remove the whole computational domain upstream from the sonic section of the nozzle, keeping the flow properties virtually unchanged there. The virtual injector model outcomes were shown to be in very good agreement with the results of the enhanced complete injector model, substantiating the reliability of the proposed novel approach.

Published
2011

30. Computational and Experimental Analysis of Direct CNG Injection and Mixture Formation in a Spark Ignition Research Engine

Author

Mirko Baratta, Andrea Catania, and Francesco Concetto Pesce

Subjects
Engineering, business.industry, Mechanical engineering, Injector, law.invention, Cylinder (engine), Ignition system, Piston, law, Spark-ignition engine, Compression ratio, Combustion chamber, business, Engine coolant temperature sensor
Abstract

Direct injection (DI) of compressed natural gas (CNG) under high pressure conditions is a topic of great interest, owing to its potential for improving SI engine performance and fuel consumption. However, relevant technical difficulties have yet to be resolved in order to stabilize combustion process, especially for stratified engine operating conditions. The present paper is focused on experimental and numerical investigations of the jet formation and fuel-air mixing process in a research optical-access single-cylinder engine. The engine is based on the multi-cylinder engine under development within the European Community (EC) VII Framework Program (FP) InGAS Integrated Project, and features a centrally mounted poppet-valve injector on a pent-roof combustion chamber with a bowl in piston. Experimental investigations were made by means of the planar laser-induced fluorescence technique, and revealed a cycle-to-cycle jet shape variability. In particular, for specific cylinder pressure values at the start of injection, the jet can adhere to chamber walls for a relevant number of cycles, leading to an ‘umbrella-like’ shape. This can change the mixing capabilities of the combustion chamber and cause instabilities in the combustion process. The mentioned behaviour is strongly dependent not only on the injection and cylinder pressures, but also on important design parameters, such as needle cone angle and in-chamber injector protrusion. For this reason, in order to obtain a deep insight into the injected gas behaviour on an average cycle basis, the experimental investigation was supported by a numerical analysis. Simulations were carried out by an optimized variable-density finite-volume numerical model which was built within the Star-CD environment. A previously developed and validated ‘virtual injector’ model was implemented. The outcomes of the numerical model were compared to laser-induced fluorescence images, for both stratified- and homogeneous-charge engine operating conditions and a good agreement was obtained, substantiating the reliability of the applied computational model. Then, the effects of the injector protrusion in the combustion chamber and of injection timing were analyzed, and their impact on jet stability and mixture-formation process was analyzed.Copyright © 2010 by ASME

Published
2010

31. CNG Injector Nozzle Design and Flow Prediction

Author

Francesco Concetto Pesce, Mirko Baratta, and Andrea Catania

Subjects
Engineering, business.industry, Internal flow, Nozzle, Mechanical engineering, Injector, Compressed natural gas, law.invention, Lift (force), law, Natural gas, Lubrication, business, Contact area, Simulation
Abstract

In the last few years, a great research effort has been made for developing and enhancing Direct Injection (DI) compressed natural gas (CNG) engines. A number of research projects has been promoted by the European Community (EC) in this field with the objectives of finding new solutions for the automotive market and also of encouraging a fruitful knowledge exchange among car manufacturers and technical universities. The present paper concerns part of the research activity that has been carried out at Politecnico di Torino (PT) within the EC VII Framework Program (FP) InGAS Integrated Project (IP). The target of the work was to support the design phase of a new injector for CNG direct injection, paying specific attention to the nozzle configuration and also to its behavior under different conditions and over runtime. The needle design was carried out with the aims of enhancing the injector reliability and reducing the injector internal friction, which usually causes injector wear due to the lack of lubrication effect with respect to liquid-fuel injectors. The new needle design concept which was considered in the present research project was oriented to maximize the contact area between the needle and its cartridge so as to reduce needle wear. For this reason, the injector feeding part was realized by means of two series of holes. The design was assisted by 3D numerical simulations which indicated the best feeding-hole number and geometry to obtain a maximum mass-flow rate. For this investigation, the needle was kept at its maximum lift and the feeding pressure was gradually increased up to the design rail pressure. The results indicated that the hole number remarkably influences the flow losses along the internal flow path and, in turn, the resultant mass-flow rate. These effects, along with the flow field characteristics inside the injector, are examined and discussed in detail throughout the paper.Copyright © 2010 by ASME

Published
2010

32. Multidimensional Modeling of Natural GAs Jet and Mixture Formation in DI SI Engines - Development and Validation of a Virtual Injector Model

Author

Francesco Concetto Pesce, Mirko Baratta, and Andrea Catania

Subjects
Jet (fluid), Engineering, business.industry, Nozzle, Mechanical engineering, Injector, Computational fluid dynamics, law.invention, Piston, law, Valve seat, Spark-ignition engine, Combustion chamber, business
Abstract

During the last years, the integration of computational CFD tools in the internal combustion (IC) engine design process has continuously been increased, allowing to save time and cost as the need of experimental prototypes has diminished. Numerical analyses of IC engine flows are rather complex from both the conceptual and operational sides. In fact, such flows involve a variety of unsteady phenomena, and the right balance between numerical solution accuracy and computational cost should be always reached. The present paper is focused on computational modeling of natural gas (NG) direct injection (DI) processes from a poppet-valve injector into a bowl-shaped combustion chamber. At high injection pressures, the efflux of gas from the injector and the mixture formation processes include compressible and turbulent flow features, such as rarefaction waves and shock formation, which are difficult to be accurately captured by the numerical simulation, particularly when combustion chamber geometry is complex and piston and intake/exhaust valve grids are moving. A three-dimensional moving grid model of the combustion engine chamber, originally developed by the authors, was enhanced by increasing the accuracy in the sonic section proximity of the critical valve seat nozzle, in order to precisely capture the expansion dynamics the methane undergoes inside the injector and immediately downstream from it. The enhanced numerical model was validated by comparing numerical results to Schlieren experimental images for nitrogen injection into a constant-volume bomb. Then, numerical studies were carried out in order to characterize the fuel jet properties and the evolution of mixture-formation for a centrally-mounted injector configuration in both cases of a pancake test chamber and the real-shaped engine chamber. Finally, the fluid properties computed by the model in the throat-section of the critical nozzle were taken as reference data for developing a new effective ‘virtual injector’ model, which allows the designer to remove the whole computational domain upstream from the sonic section of the nozzle, keeping the flow properties practically unchanged. The outcomes of such a virtual injector model were shown to be in very good agreement with the results of the enhanced complete injector model, confirming the reliability of the proposed novel approach.Copyright © 2009 by ASME

Published
2009

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