Your search keyword '"Dimitris Assanis"' showing total 6 results

1. Estimation of Wiebe Function Parameters for Syngas and Anode Off-Gas Combustion in Spark-Ignition Engines

Author

Zhongnan Ran, Dimitris Assanis, and Ruinan Yang

Subjects

Materials science, Nuclear engineering, Mechanical Engineering, Energy Engineering and Power Technology, Aerospace Engineering, Combustion, law.invention, Anode, Ignition system, Outgassing, Fuel Technology, Nuclear Energy and Engineering, law, Spark (mathematics), Syngas

Abstract

Wiebe functions, analytical equations that estimate the fuel mass fraction burned (MFB) during combustion, have been effective at describing spark-ignition (SI) engine combustion using gasoline fuels. This study explores if the same methodology can be extended for SI combustion with syngas, a gaseous fuel mixture composed of H2, CO, and CO2, and anode-off gas; the latter is an exhaust gas mixture emitted from the anode of a Solid Oxide Fuel Cell, containing H2, CO, H2O, and CO2. For this study, anode off-gas is treated as a syngas fuel diluted with CO2 and vaporized water. Combustion experiments were run on a single-cylinder, research engine using syngas and anode-off gas as fuels. One single Wiebe function and three double Wiebe functions were fitted and compared with the MFB profile calculated from the experimental data. It was determined that the SI combustion process of both the syngas and the anode-off gas could be estimated using a governing Wiebe function. While the detailed double Wiebe function had the highest accuracy, a reduced double Wiebe function is capable of achieving comparable accuracy. On the other hand, a single Wiebe function is not able to fully capture the combustion process of a SI engine using syngas and anode off-gas.

Published

2023

2. The Use of Neural Nets for Matching Fixed or Variable Geometry Compressors With Diesel Engines

Author

Zoran Filipi, S. A. Nelson, and Dimitris Assanis

Subjects

Engineering, Artificial neural network, business.industry, Mechanical Engineering, Energy Engineering and Power Technology, Aerospace Engineering, Control engineering, Context (language use), Diesel engine, Automotive engineering, Fuel Technology, Nuclear Energy and Engineering, Internal combustion engine, Spark-ignition engine, Turbomachinery, business, Gas compressor, Turbocharger

Abstract

A technique which uses trained neural nets to model the compressor in the context of a turbocharged diesel engine simulation is introduced. This technique replaces the usual interpolation of compressor maps with the evaluation of a smooth mathematical function. Following presentation of the methodology, the proposed neural net technique is validated against data from a truck type, 6-cylinder 14-liter diesel engine. Furthermore, with the introduction of an additional parameter, the proposed neural net can be trained to simulate an entire family of compressors. As a demonstration, a family of compressors of different sizes is represented with a single neural net model which is subsequently used for matching calculations with intercooled and nonintercooled engine configurations at different speeds. This novel approach readily allows for evaluation of various options within a wide range of possible compressor configurations prior to prototype production. It can also be used to represent the variable geometry machine regardless of the method used to vary compressor characteristics. Hence, it is a powerful design tool for selection of the best compressor for a given diesel engine system and for broader system optimization studies.

Published

2003

3. Manifold Gas Dynamics Modeling and Its Coupling With Single-Cylinder Engine Models Using Simulink

Author

G. Q. Zhang and Dimitris Assanis

Subjects

Volumetric efficiency, Engineering, business.industry, Mechanical Engineering, Single-cylinder engine, Energy Engineering and Power Technology, Aerospace Engineering, Mechanical engineering, Diesel engine, law.invention, Ignition system, Diesel fuel, Fuel Technology, Nuclear Energy and Engineering, Internal combustion engine, law, Total variation diminishing, Spark-ignition engine, Physics::Chemical Physics, business

Abstract

A flexible model for computing one-dimensional, unsteady manifold gas dynamics in single-cylinder spark-ignition and diesel engines has been developed. The numerical method applies an explicit, finite volume formulation and a shock-capturing total variation diminishing scheme. The numerical model has been validated against the method of characteristics for valve flows without combustion prior to coupling with combustion engine simulations. The coupling of the gas-dynamics model with single-cylinder, spark-ignition and diesel engine modules is accomplished using the graphical MATLAB-SIMULINK environment. Comparisons between predictions of the coupled model and measurements shows good agreement for both spark ignition and diesel engines. Parametric studies demonstrating the effect of varying the intake runner length on the volumetric efficiency of a diesel engine illustrate the model use.

Published

2003

4. A Nonlinear, Transient, Single-Cylinder Diesel Engine Simulation for Predictions of Instantaneous Engine Speed and Torque

Author

Dimitris Assanis and Zoran Filipi

Subjects

Engineering, business.industry, Mechanical Engineering, Single-cylinder engine, Energy Engineering and Power Technology, Aerospace Engineering, Angular velocity, Mechanics, Moment of inertia, Diesel engine, Automotive engineering, Cylinder (engine), law.invention, Diesel fuel, Acceleration, Fuel Technology, Nuclear Energy and Engineering, law, Torque, business

Abstract

A non-linear, transient, single-cylinder diesel engine simulation has been developed for predictions of instantaneous engine speed and torque. The foundation of our model is a physically based, thermodynamic, steady-state diesel engine simulation (Assanis, D. N., and Heywood, J. B., 1986, “Development and Use of a Computer Simulation of the Turbocompounded Diesel System for Engine Performance and Component Heat Transfer Studies,” SAE Paper 860329), which has been comprehensively validated for various engine designs. The transient extension of the parent model represents the diesel engine as a non-linear, dynamic system. The instantaneous crank-shaft speed is determined from the solution of the engine-external load dynamics equation, where the engine torque is tracked on a crank-angle basis. Validation of the transient model during rapid engine acceleration shows that both the cyclic fluctuations in the instantaneous crank-shaft speed line and the overall engine response are in good agreement with experimental measurements. Predictions of single-cylinder engine starting reveals the importance of selecting the proper value of the engine moment of inertia in order to control the amplitude of angular velocity fluctuations and ensure stable engine operation. It is further shown that the variation in the inertial forces on the reciprocating components with speed has a dramatic impact on the instantaneous torque profile, and consequently on angular velocity fluctuations.

Published

2000

5. Study of Using Oxygen-Enriched Combustion Air for Locomotive Diesel Engines

Author

G. R. Cataldi, Raj Sekar, R. B. Poola, and Dimitris Assanis

Subjects

Diesel exhaust, Waste management, business.industry, Mechanical Engineering, Energy Engineering and Power Technology, Aerospace Engineering, Exhaust gas, Fuel injection, Combustion, Diesel engine, Diesel fuel, Fuel Technology, Nuclear Energy and Engineering, Internal combustion engine, Environmental science, Exhaust gas recirculation, business

Abstract

A thermodynamic simulation is used to study the effects of oxygen-enriched intake air on the performance and nitrogen oxide (NO) emissions of a locomotive diesel engine. The parasitic power of the air separation membrane required to supply the oxygen-enriched air is also estimated. For a given constraint on peak cylinder pressure, the gross and net power output of an engine operating under different levels of oxygen enrichment are compared with those obtained when a high-boost turbocharged engine is used. A 4 percent increase in peak cylinder pressure can result in an increase in net engine power of approximately 10 percent when intake air with an oxygen content of 28 percent by volume is used and fuel injection timing is retarded by 4 degrees. When the engine is turbocharged to a higher inlet boost, the same increase in peak cylinder pressure can improve power by only 4 percent. If part of the significantly higher exhaust enthalpies available as a result of oxygen enrichment is recovered, the power requirements of the air separator membrane can be met, resulting in substantial net power improvements. Oxygen enrichment with its attendant higher combustion temperatures, reduces emissions of particulates and visible smoke but increases NO emissions (by up to three times at 26 percent oxygen content). Therefore, exhaust gas after-treatment and heat recovery would be required if the full potential of oxygen enrichment for improving the performance of locomotive diesel engines is to be realized.

Published

2000

6. An Imaging Study of Compression Ignition Phenomena of Iso-Octane, Indolene, and Gasoline Fuels in a Single-Cylinder Research Engine

Author

Bradley T. Zigler, S.M. Walton, Elizabeth Perez, Dimitris Assanis, Steven Wooldridge, and Margaret S. Wooldridge

Subjects

Materials science, Mechanical Engineering, Homogeneous charge compression ignition, Energy Engineering and Power Technology, Aerospace Engineering, Compression (physics), Combustion, Automotive engineering, Cylinder (engine), law.invention, Ignition system, chemistry.chemical_compound, Fuel Technology, Nuclear Energy and Engineering, chemistry, Internal combustion engine, law, Gasoline, Octane

Abstract

High-speed imaging combined with the optical access provided by a research engine offer the ability to directly image and compare ignition and combustion phenomena of various fuels. Such data provide valuable insight into the physical and chemical mechanisms important in each system. In this study, crank-angle resolved imaging data were used to investigate homogeneous charge compression ignition (HCCI) operation of a single-cylinder four-valve optical engine fueled using gasoline, indolene, and iso-octane. Lean operating limits were the focus of the study with the primary objective of identifying different modes of reaction front initiation and propagation for each fuel. HCCI combustion was initiated and maintained over a range of lean conditions for various fuels, from 0.69 to 0.27. The time-resolved imaging and pressure data show that high rates of heat release in HCCI combustion correlate temporally to simultaneous, intense volumetric blue emission. Lower rates of heat release are characteristic of spatially resolved blue emission. Gasoline supported leaner HCCI operation than indolene. Iso-octane showed a dramatic transition into misfire. Similar regions of preferential ignition were identified for each of the fuels considered using the imaging data. DOI: 10.1115/1.2898720

Published

2008