Your search keyword '"Randy P. Hessel"' showing total 14 results

1. Applying Advanced CFD Analysis Tools to Study Differences between Start-of-Main and Start-of-Post Injection Flow, Temperature and Chemistry Fields Due to Combustion of Main-Injected Fuel

Author

Jacqueline O'Connor, Mark P. B. Musculus, Zongyu Yue, Rolf D. Reitz, and Randy P. Hessel

Subjects

Engineering, Chemistry, business.industry, Flow (psychology), Mechanical engineering, General Medicine, Computational fluid dynamics, Post injection, Combustion, business, Process engineering

Published

2015

2. Application of gaseous sphere injection method for modeling under-expanded H2 injection

Author

Salvador M. Aceves, Russell Whitesides, Randy P. Hessel, and Daniel L. Flowers

Subjects

Materials science, Hydrogen, business.industry, General Chemical Engineering, General Physics and Astronomy, Energy Engineering and Power Technology, chemistry.chemical_element, General Chemistry, Mechanics, Computational fluid dynamics, Combustion, Fuel Technology, chemistry, Modeling and Simulation, Model testing, Injector nozzle, business, Mass fraction

Abstract

A methodology for modeling gaseous injection has been refined and applied to recent experimental data from the literature. This approach uses a discrete phase analogy to handle gaseous injection, allowing for addition of gaseous injection to a CFD grid without needing to resolve the injector nozzle. This paper focuses on model testing to provide the basis for simulation of hydrogen direct injected internal combustion engines. The model has been updated to be more applicable to full engine simulations, and shows good agreement with experiments for jet penetration and time-dependent axial mass fraction, while available – radial mass fraction data is less well predicted.

Published

2011

3. Determination of Cycle Temperatures and Residual Gas Fraction for HCCI Negative Valve Overlap Operation

Author

Jordan A. Snyder, Ronald K. Hanson, Russell P. Fitzgerald, Randy P. Hessel, and Richard R. Steeper

Subjects

Valve timing, Residual gas fraction, Chemistry, Nuclear engineering, Homogeneous charge compression ignition, Analytical chemistry, General Medicine

Published

2010

4. A fully coupled computational fluid dynamics and multi-zone model with detailed chemical kinetics for the simulation of premixed charge compression ignition engines

Author

Daniel L. Flowers, Salvador M. Aceves, Randy P. Hessel, Dennis N. Assanis, and Aristotelis Babajimopoulos

Subjects

Mathematical model, Chemistry, business.industry, Mechanical Engineering, Homogeneous charge compression ignition, Aerospace Engineering, Thermodynamics, Ocean Engineering, Charge (physics), Mechanics, Computational fluid dynamics, Combustion, Compression (physics), law.invention, Ignition system, Chemical kinetics, law, Automotive Engineering, business

Abstract

Modelling the premixed charge compression ignition (PCCI) engine requires a balanced approach that captures both fluid motion as well as low- and high-temperature fuel oxidation. A fully integrated computational fluid dynamics (CFD) and chemistry scheme (i.e. detailed chemical kinetics solved in every cell of the CFD grid) would be the ideal PCCI modelling approach, but is computationally very expensive. As a result, modelling assumptions are required in order to develop tools that are computationally efficient, yet maintain an acceptable degree of accuracy. Multi-zone models have been previously shown accurately to capture geometry-dependent processes in homogeneous charge compression ignition (HCCI) engines. In the presented work, KIVA-3V is fully coupled with a multi-zone model with detailed chemical kinetics. Computational efficiency is achieved by utilizing a low-resolution discretization to solve detailed chemical kinetics in the multi-zone model compared with a relatively high-resolution CFD solution. The multi-zone model communicates with KIVA-3V at each computational timestep, as in the ideal fully integrated case. The composition of the cells, however, is mapped back and forth between KTVA-3V and the multi-zone model, introducing significant computational time savings. The methodology uses a novel re-mapping technique that can account for both temperature and composition non-uniformities in the cylinder. Validation cases were developed by solving the detailed chemistry in every cell of a KIVA-3V grid. The new methodology shows very good agreement with the detailed solutions in terms of ignition timing, burn duration, and emissions.

Published

2005

5. Modeling Iso-octane HCCI Using CFD with Multi-Zone Detailed Chemistry; Comparison to Detailed Speciation Data Over a Range of Lean Equivalence Ratios

Author

Aristotelis Babajimopoulos, Salvador M. Aceves, Daniel L. Flowers, M. Lee Davisson, Magnus Sjöberg, David E. Foster, Randy P. Hessel, William J. Pitz, John E. Dec, and Francisco Espinosa-Loza

Subjects

chemistry.chemical_classification, business.industry, Homogeneous charge compression ignition, Nuclear engineering, Analytical chemistry, Computational fluid dynamics, Combustion, chemistry.chemical_compound, Hydrocarbon, chemistry, Compression ratio, Combustion chamber, business, Equivalence (measure theory), Octane

Abstract

Multi-zone CFD simulations with detailed kinetics were used to model iso-octane HCCI experiments performed on a single-cylinder research engine. The modeling goals were to validate the method (multi-zone combustion modeling) and the reaction mechanism (LLNL 857 species iso-octane) by comparing model results to detailed exhaust speciation data, which was obtained with gas chromatography. The model is compared to experiments run at 1200 RPM and 1.35 bar boost pressure over an equivalence ratio range from 0.08 to 0.28. Fuel was introduced far upstream to ensure fuel and air homogeneity prior to entering the 13.8:1 compression ratio, shallow-bowl combustion chamber of this 4-stroke engine. The CFD grid incorporated a very detailed representation of the crevices, including the top-land ring crevice and headgasket crevice. The ring crevice is resolved all the way into the ring pocket volume. The detailed grid was required to capture regions where emission species are formed and retained. Results show that combustion is well characterized, as demonstrated by good agreement between calculated and measured pressure traces. In addition, excellent quantitative agreement between the model and experiment is achieved for specific exhaust species components, such as unburned fuel, formaldehyde, and many other intermediate hydrocarbon species. Some calculated trace intermediate hydrocarbon species do not agree as well with measurements, highlighting areas needing further investigation for understanding fundamental chemistry processes in HCCI engines.

Published

2008

6. Gaseous Fuel Injection Modeling Using a Gaseous Sphere Injection Methodology

Author

Salvador M. Aceves, Daniel L. Flowers, Randy P. Hessel, and Neerav Abani

Subjects

Entrainment (hydrodynamics), Waste management, Hydrogen, Physics::Instrumentation and Detectors, business.industry, Chemistry, Nuclear engineering, chemistry.chemical_element, Combustion, Liquid fuel, Physics::Fluid Dynamics, Fuel gas, Natural gas, Air entrainment, Physics::Chemical Physics, business, Physics::Atmospheric and Oceanic Physics

Abstract

The growing interest in gaseous fuels (hydrogen and natural gas) for internal combustion engines calls for the development of computer models for simulation of gaseous fuel injection, air entrainment and the ensuing combustion. This paper introduces a new method for modeling the injection and air entrainment processes for gaseous fuels. The model uses a gaseous sphere injection methodology, similar to liquid droplet in injection techniques used for liquid fuel injection. In this paper, the model concept is introduced and model results are compared with correctly- and under-expanded experimental data.

Published

2006

7. A Comparison of the Effect of Combustion Chamber Surface Area and In-Cylinder Turbulence on the Evolution of Gas Temperature Distribution from IVC to SOC: A Numerical and Fundamental Study

Author

Salvador M. Aceves, Daniel L. Flowers, and Randy P. Hessel

Subjects

Surface (mathematics), Fundamental study, Distribution (mathematics), Chemistry, Turbulence, Thermodynamics, Cylinder, Mechanics, Combustion chamber

Published

2006

8. Analysis of the Effect of Geometry Generated Turbulence on HCCI Combustion by Multi-Zone Modeling

Author

Salvador M. Aceves, Francisco Espinosa-Loza, Joel Martinez-Frias, Randy P. Hessel, Magnus Christensen, Daniel L. Flowers, and Bengt Johansson

Subjects

Turbulence, Chemistry, K-epsilon turbulence model, Homogeneous charge compression ignition, Fluid mechanics, Geometry, K-omega turbulence model, Combustion, law.invention, Physics::Fluid Dynamics, Piston, law, Physics::Chemical Physics, Combustion chamber

Abstract

This paper illustrates the applicability of a sequential fluid mechanics, multi-zone chemical kinetics model to analyze HCCI experimental data for two combustion chamber geometries with different levels of turbulence: a low turbulence disc geometry (flat top piston), and a high turbulence square geometry (piston with a square bowl). The model uses a fluid mechanics code to determine temperature histories in the engine as a function of crank angle. These temperature histories are then fed into a chemical kinetic solver, which determines combustion characteristics for a relatively small number of zones (40). The model makes the assumption that there is no direct linking between turbulence and combustion. The results show that the multi-zone model yields good results for both the disc and the square geometries. The model makes good predictions of pressure traces and heat release rates. The experimental results indicate that the high turbulence square geometry has longer burn duration than the low turbulence disc geometry. This difference can be explained by the sequential multi-zone model, which indicates that the cylinder with the square bowl has a thicker boundary layer that results in a broader temperature distribution. This broader temperature distribution tends to lengthen the combustion, as cold mass withinmore » the cylinder takes longer to reach ignition temperature when compressed by the expansion of the first burned gases. The multi-zone model, which makes the basic assumption that HCCI combustion is controlled by chemical kinetics, is therefore capable of explaining the experimental results obtained for different levels of turbulence, without considering a direct interaction between turbulence and combustion. A direct connection between turbulence and HCCI combustion may still exists, but it seems to play a relatively minor role in determining burn duration at the conditions analyzed in this paper.« less

Published

2005

9. Optimization of a Large Diesel Engine via Spin Spray Combustion*

Author

Rolf D. Reitz, Randy P. Hessel, and Michael Bergin

Subjects

Computer simulation, Chemistry, business.industry, Nozzle, Mixing (process engineering), Mechanics, Computational fluid dynamics, Diesel engine, medicine.disease_cause, Combustion, Automotive engineering, Soot, Fuel efficiency, medicine, business

Abstract

A numerical simulation and optimization study was conducted for a medium speed direct injection diesel engine. The engine's operating characteristics were first matched to available experimental data to test the validity of the numerical model. The KIVA-3V ERC CFD code was then modified to allow independent spray events from two rows of nozzle holes. The angular alignment, nozzle hole size, and injection pressure of each set of nozzle holes were optimized using a micro-genetic algorithm. The design fitness criteria were based on a multi-variable merit function with inputs of emissions of soot, NO x , unburned hydrocarbons, and fuel consumption targets. Penalties to the merit function value were used to limit the maximum in-cylinder pressure and the burned gas temperature at exhaust valve opening. The optimization produced a 28.4% decrease in NO x and a 40% decrease in soot from the baseline case, while giving a 3.1% improvement in fuel economy. The improvements were found to be due to the formation of circulatory flows caused by the interaction of adjacent optimally timed injections. The resulting spinning flow field greatly enhances mixing and combustion rates, and is called "Spin-Spray Combustion*". The resulting fast mixing allowed the use of retarded injection timings, thereby lowering NO x production without increasing soot beyond the target values.

Published

2005

10. Spatial Analysis of Emissions Sources for HCCI Combustion at Low Loads Using a Multi-Zone Model

Author

Francisco Espinosa-Loza, Magnus Sjöberg, Salvador M. Aceves, John E. Dec, Daniel L. Flowers, Randy P. Hessel, Robert W. Dibble, and Joel Martinez-Frias

Subjects

Pollutant, Internal combustion engine, Chemistry, Nuclear engineering, Homogeneous charge compression ignition, Autoignition temperature, Combustion chamber, Diesel engine, Combustion, Equivalence (measure theory), Automotive engineering

Abstract

We have conducted a detailed numerical analysis of HCCI engine operation at low loads to investigate the sources of HC and CO emissions and the associated combustion inefficiencies. Engine performance and emissions are evaluated as fueling is reduced from typical HCCI conditions, with an equivalence ratio f = 0.26 to very low loads (f = 0.04). Calculations are conducted using a segregated multi-zone methodology and a detailed chemical kinetic mechanism for iso-octane with 859 chemical species. The computational results agree very well with recent experimental results. Pressure traces, heat release rates, burn duration, combustion efficiency and emissions of hydrocarbon, oxygenated hydrocarbon, and carbon monoxide are generally well predicted for the whole range of equivalence ratios. The computational model also shows where the pollutants originate within the combustion chamber, thereby explaining the changes in the HC and CO emissions as a function of equivalence ratio. The results of this paper contribute to the understanding of the high emission behavior of HCCI engines at low equivalence ratios and are important for characterizing this previously little explored, yet important range of operation.

Published

2004

11. Effect of Mixing on Hydrocarbon and Carbon Monoxide Emissions Prediction for Isooctane HCCI Engine Combustion Using a Multi-zone Detailed Kinetics Solver

Author

Daniel L. Flowers, Salvador M. Aceves, Joel Martinez-Frias, Robert W. Dibble, and Randy P. Hessel

Subjects

Convection, Chemistry, business.industry, Homogeneous charge compression ignition, Heat transfer, Fluid dynamics, Thermodynamics, Fluid mechanics, Mechanics, Computational fluid dynamics, Solver, Combustion, business

Abstract

This research investigates how the handling of mixing and heat transfer in a multi-zone kinetic solver affects the prediction of carbon monoxide and hydrocarbon emissions for simulations of HCCI engine combustion. A detailed kinetics multi-zone model is now more closely coordinated with the KIVA3V computational fluid dynamics code for simulation of the compression and expansion processes. The fluid mechanics is solved with high spatial and temporal resolution (40,000 cells). The chemistry is simulated with high temporal resolution, but low spatial resolution (20 computational zones). This paper presents comparison of simulation results using this enhanced multi-zone model to experimental data from an isooctane HCCI engine. The chemical kinetics part of the simulation is handled using the multi-zone segregated solver method developed previously, but now KIVA3V is used to handle the fluid dynamics (convection, mass diffusion and heat transfer) for the entire compression and expansion processes. The results show that carbon monoxide and hydrocarbon emissions may be greatly influenced by the mixing and heat transfer during expansion. The prediction of HC and CO is significantly improved by inclusion of these effects in the simulation.

Published

2003

12. Piston-Liner Crevice Geometry Effect on HCCI Combustion by Multi-Zone Analysis

Author

Salvador M. Aceves, Francisco Espinosa-Loza, Joel Martinez-Frias, Bengt Johansson, Magnus Christensen, Randy P. Hessel, Daniel L. Flowers, and Robert W. Dibble

Subjects

chemistry.chemical_classification, Turbulence, Homogeneous charge compression ignition, Thermodynamics, Geometry, Combustion, law.invention, Piston, chemistry.chemical_compound, Direct energy conversion, Hydrocarbon, chemistry, law, Compression ratio, Carbon monoxide

Abstract

A multi-zone model has been developed that accurately predicts HCCI combustion and emissions. The multizone methodology is based on the observation that turbulence does not play a direct role on HCCI combustion. Instead, chemical kinetics dominates the process, with hotter zones reacting first, and then colder zones reacting in rapid succession. Here, the multi-zone model has been applied to analyze the effect of piston crevice geometry on HCCI combustion and emissions. Three different pistons of varying crevice size were analyzed. Crevice sizes were 0.26, 1.3 and 2.1 mm, while a constant compression ratio was maintained (17:1). The results show that the multi-zone model can predict pressure traces and heat release rates with good accuracy. Combustion efficiency is also predicted with good accuracy for all cases, with a maximum difference of 5% between experimental and numerical results. Carbon monoxide emissions are underpredicted, but the results are better than those obtained in previous publications. The improvement is attributed to the use of a 40-zone model, while previous publications used a 10-zone model. Hydrocarbon emissions are well predicted. For cylinders with wide crevices (1.3 and 2.1 mm), HC emissions do not decrease monotonically as the relative air/fuel ratio ({lambda}) increases. Instead, maximum HC more » emissions are obtained for an intermediate value of {lambda}. The model predicts this relative air/fuel ratio for maximum HC emissions with very good accuracy. The results show that the multi-zone model can successfully predict the effect of crevice geometry on HCCI combustion, and therefore it has applicability to the design of HCCI engines with optimum characteristics for high efficiency, low emissions and low peak cylinder pressure. « less

Published

2002

13. A Decoupled Model of Detailed Fluid Mechanics Followed by Detailed Chemical Kinetics for Prediction of Iso-Octane HCCI Combustion

Author

Daniel L. Flowers, Robert W. Dibble, Joel Martinez-Frias, J. Ray Smith, John F. Wright, Salvador M. Aceves, and Randy P. Hessel

Subjects

Chemical kinetics, chemistry.chemical_compound, Materials science, chemistry, Hcci combustion, Thermodynamics, Fluid mechanics, Octane

Published

2001

14. A Sequential Fluid-Mechanic Chemical-Kinetic Model of Propane HCCI Combustion

Author

John F. Wright, Salvador M. Aceves, Joel Martinez-Frias, William J. Pitz, Charles K. Westbrook, Wole C. Akinyemi, J. Ray Smith, Randy P. Hessel, Daniel L. Flowers, and Robert W. Dibble

Subjects

Chemistry, Homogeneous charge compression ignition, Mixing (process engineering), Thermodynamics, Fluid mechanics, Mechanics, Combustion, law.invention, Ignition system, chemistry.chemical_compound, law, Propane, Heat transfer, Current (fluid)

Abstract

We have developed a methodology for predicting combustion and emissions in a Homogeneous Charge Compression Ignition (HCCI) Engine. This methodology combines a detailed fluid mechanics code with a detailed chemical kinetics code. Instead of directly linking the two codes, which would require an extremely long computational time, the methodology consists of first running the fluid mechanics code to obtain temperature profiles as a function of time. These temperature profiles are then used as input to a multi-zone chemical kinetics code. The advantage of this procedure is that a small number of zones (10) is enough to obtain accurate results. This procedure achieves the benefits of linking the fluid mechanics and the chemical kinetics codes with a great reduction in the computational effort, to a level that can be handled with current computers. The success of this procedure is in large part a consequence of the fact that for much of the compression stroke the chemistry is inactive and thus has little influence on fluid mechanics and heat transfer. Then, when chemistry is active, combustion is rather sudden, leaving little time for interaction between chemistry and fluid mixing and heat transfer. This sequential methodology has been capable of explaining the mainmore » characteristics of HCCI combustion that have been observed in experiments. In this paper, we use our model to explore an HCCI engine running on propane. The paper compares experimental and numerical pressure traces, heat release rates, and hydrocarbon and carbon monoxide emissions. The results show an excellent agreement, even in parameters that are difficult to predict, such as chemical heat release rates. Carbon monoxide emissions are reasonably well predicted, even though it is intrinsically difficult to make good predictions of CO emissions in HCCI engines. The paper includes a sensitivity study on the effect of the heat transfer correlation on the results of the analysis. Importantly, the paper also shows a numerical study on how parameters such as swirl rate, crevices and ceramic walls could help in reducing HC and CO emissions from HCCI engines.« less

Published

2001