Your search keyword '"Scott Curran"' showing total 74 results

1. Fuel Stratification Effects on Gasoline Compression Ignition with a Regular-Grade Gasoline on a Single-Cylinder Medium-Duty Diesel Engine at Low Load

Author

Brian Kaul, Scott Curran, Jordan Easter, Scott Sluder, and James P. Szybist

Subjects

Mechanical Engineering, Nuclear engineering, Energy Engineering and Power Technology, Stratification (water), Management Science and Operations Research, Diesel engine, Compression (physics), Cylinder (engine), law.invention, Ignition system, law, Environmental science, Low load, Gasoline

Published

2021

2. Evaluating Class 6 Delivery Truck Fuel Economy and Emissions Using Vehicle System Simulations for Conventional and Hybrid Powertrains and Co-Optima Fuel Blends

Author

Ram Vijayagopal, Scott Curran, Dean Deter, and Douglas Longman

Published

2022

3. Exploring the potential benefits of high-efficiency dual-fuel combustion on a heavy-duty multi-cylinder engine for SuperTruck I

Author

Marc Allain, K. Dean Edwards, Chloé Lerin, Scott Curran, Sandeep Singh, Jeff Girbach, Eric Nafziger, Melanie Moses-DeBusk, and Brian C. Kaul

Subjects

Thermal efficiency, business.industry, 020209 energy, Mechanical Engineering, Aerospace Engineering, Ocean Engineering, 02 engineering and technology, Oak Ridge National Laboratory, Combustion, Automotive engineering, Dual (category theory), Diesel fuel, 020303 mechanical engineering & transports, 0203 mechanical engineering, Natural gas, Heavy duty, Automotive Engineering, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, business

Abstract

In support of the Daimler SuperTruck I team’s 55% brake thermal efficiency (BTE) pathway goal, researchers at Oak Ridge National Laboratory performed an experimental investigation of the potential efficiency and emissions benefits of dual-fuel advanced combustion approaches on a modified heavy-duty 15-L Detroit™ DD15 engine. For this work, a natural gas port fuel injection system with an independent injection control for each cylinder was added to the DD15 engine. For the dual-fuel strategies investigated, 65%–90% of the total fuel energy was supplied through the added port fuel injection natural gas (NG) fueling system. The remaining fuel energy was supplied by one or more direct injections of diesel fuel using the production high pressure diesel fueling system. The production DD15 air handling system and combustion geometry were unmodified for this study. Efficiency and emissions with dual-fuel strategies including both low temperature combustion (LTC) and non-LTC approaches such as dual fuel direct-injection were investigated along with control authority over combustion phasing. Parametric studies of dual-fuel NG/diesel advanced combustion were conducted in order to experimentally investigate the potential of high-efficiency, dual-fuel combustion strategies to improve BTE in a multi-cylinder engine, understand the potential reductions in engine-out emissions, and characterize the range of combustion phasing controllability. Characterization of mode transitions from mixing-controlled diesel pilot ignition to kinetically controlled ignition is presented. Key findings from this study included a reproducible demonstration of BTE approaching 48% at up to a 13-bar brake mean effective pressure with significant reductions in engine-out NOx and soot emissions. Additional results from investigating load transients in dual-fuel mode and initial characterization of particle size distribution during dual-fuel operation are presented.

Published

2021

4. Live-cell delamination counterbalances epithelial growth to limit tissue overcrowding.

Author

Eliana Marinari, Aida Mehonic, Scott Curran, Jonathan Gale, Thomas Duke, and Buzz Baum

Published

2012

5. An Exploration of Well-being in Former Covert and Undercover Police Officers

Author

Liam Scott Curran

Subjects

Coping (psychology), media_common.quotation_subject, 050901 criminology, 05 social sciences, Social impact, Exploratory research, 050401 social sciences methods, Criminology, Democracy, Legal psychology, Politics, 0504 sociology, Covert, Well-being, Sociology, 0509 other social sciences, Law, Applied Psychology, media_common

Abstract

Little is known about the stressors of working in covert and undercover policing roles and the impact these can have on the health and psychological well-being of police officers. Extant literature focuses upon the social impact of undercover and covert policing in a democratic society, especially in relation to policing political groups. Presented here are the results of an exploratory study into the lives of former police officers who have engaged in various forms of covert/undercover policing. Utilising semi-structured interviews, in a five-participant case-study design, this research investigates the impact that covert and undercover policing has on the well-being of former officers who have undertaken this role, and how they utilised coping strategies. Data were thematically analysed using Braun and Clarke’s framework (Braun and Clarke 2006). Findings were consistent in that fear of violence was a large factor that impacted the well-being and personal relationships of undercover officers. The paper concludes by outlining pertinent suggestions for future research and considers the implications for covert policing.

Published

2020

6. A quantitative and spatial analysis of cell cycle regulators during the fission yeast cycle

Author

Scott Curran, Gautam Dey, Paul Rees, and Paul Nurse

Subjects

Model organisms, Chemical Biology & High Throughput, Spatial Analysis, Multidisciplinary, Cell Cycle, Mitosis, Cell Cycle Proteins, Cell Biology, Protein-Tyrosine Kinases, Biochemistry & Proteomics, Cyclins, Schizosaccharomyces, Cell Cycle & Chromosomes, Synthetic Biology, Schizosaccharomyces pombe Proteins, Genetics & Genomics, Computational & Systems Biology

Abstract

We have carried out a systems-level analysis of the spatial and temporal dynamics of cell cycle regulators in the fission yeastSchizosaccharomyces pombe. In a comprehensive single cell analysis we have precisely quantified the levels of 38 proteins previously identified as regulators of the G2 to mitosis transition, and of 7 proteins acting at the G1 to S-phase transition. Only two of the 38 mitotic regulators exhibit changes in concentration at the whole cell level, the mitotic B-type cyclin Cdc13 which accumulates continually throughout the cell cycle, and the regulatory phosphatase Cdc25 which exhibits a complex cell cycle pattern. Both proteins show similar patterns of change within the nucleus as in the whole cell but at higher concentrations. In addition, the concentrations of the major fission yeast cyclin dependent kinase (CDK) Cdc2, the CDK regulator Suc1 and the inhibitory kinase Wee1 also increase in the nucleus peaking at mitotic onset but are constant in the whole cell. The significant increase in concentration with size for Cdc13 supports the model that mitotic B-type cyclin accumulation acts as a cell size sensor. We propose a two-step process for the control of mitosis. First, Cdc13 accumulates in a size-dependent manner which drives increasing CDK activity. Second, from mid G2 the increasing nuclear accumulation of Cdc25 and the counteracting Wee1 introduces a bistability switch that results in a rapid rise of CDK activity at the end of G2 and thus brings about an orderly progression into mitosis.Significance StatementAcross eukaryotes the increasing level of cyclin dependent kinase (CDK) activity drives progression through the cell cycle. As most cells divide at specific sizes, information responding to the size of the cell must feed into the regulation of CDK activity. In this study, we use fission yeast to precisely measure how proteins that have been previously identified in genome wide screens as cell cycle regulators change in their levels with cell cycle progression. We identify the mitotic B-type cyclin Cdc13 and mitotic inhibitory phosphatase Cdc25 as the only two proteins that change in both whole cell and nuclear concentration through the cell cycle, making them candidates for universal cell size sensors at the onset of mitosis and cell division.

Published

2022

7. Hardware-in-the-Loop Investigation of Emissions Challenges in Hybrid Medium- and Heavy-Duty Powertrains Using a Pre-Production Diesel-Electric Parallel Hybrid System With and Without Stop-Start Operation

Author

Brian Kaul, Chloé Lerin, Adian Cook, Dean Deter, Scott Curran, Melanie Moses-DeBusk, and Vicente Boronat Colomer

Subjects

Diesel fuel, Computer science, Powertrain, Heavy duty, Hybrid system, Hardware-in-the-loop simulation, Production (economics), Automotive engineering

Abstract

Hybrid electric powertrains are a growing market in medium- and heavy-duty applications. There is a lack of available information to understand the challenges in the integration of engine platforms into electrified powertrains, such as cold-start, restart, and load-reduction effects on emissions and emission control devices. Results from the Heavy Heavy-Duty Diesel Truck (HHDDT) cycle using a conventional medium-duty diesel engine were compared with those of a parallel hybrid architecture. Oak Ridge National Laboratory in collaboration with the US Department of Energy and Odyne Systems, LLC developed a powertrain in a hardware-in-the-loop environment, integrating the Odyne Systems, LLC medium-duty parallel hybrid system, which was used for the hybrid portion of this study. Experiments under the HHDDT cycle showed increasing improvements in fuel consumption and engine-out emissions with the integration of stop/start, hybrid, and hybrid with stop/start. However, the effects of load reduction and exhaust temperature on the thermal management strategy have shown an increase in fueling in the second part of the HHDDT cycle. Four configurations of medium-duty electrification were studied and contributed to building a unique data set containing combustion, emissions, and system integration data. Each electrification level was compared with the conventional baseline. The calibration of the conventional engine was not altered for this study. Opportunities to tailor the combustion process were identified with the stop/start strategy.

Published

2021

8. Gasoline Compression Ignition (GCI) on a Light-Duty Multi-Cylinder Engine Using a Wide Range of Fuel Reactivities and Heavy Fuel Stratification

Author

Andrew Ickes, Robert M. Wagner, Scott Curran, William J. Cannella, and Adam B. Dempsey

Subjects

business.industry, Nuclear engineering, Light duty, Stratification (water), Combustion, medicine.disease_cause, Soot, law.invention, Ignition system, Diesel fuel, law, medicine, Environmental science, Exhaust gas recirculation, Gasoline, business

Abstract

Many research studies have focused on utilizing gasoline in modern compression ignition engines to reduce emissions and improve efficiency. Collectively, this combustion mode has become known as gasoline compression ignition (GCI). One of the biggest challenges with GCI operation is maintaining control over the combustion process through the fuel injection strategy, such that the engine can be controlled on a cycle-by-cycle basis. Research studies have investigated a wide variety of GCI injection strategies (i.e., fuel stratification levels) to maintain control over the heat release rate while achieving low temperature combustion (LTC). This work shows that at loads relevant to light-duty engines, partial fuel stratification (PFS) with gasoline provides very little controllability over the timing of combustion. On the contrary, heavy fuel stratification (HFS) provides very linear and pronounced control over the timing of combustion. However, the HFS strategy has challenges achieving LTC operation due to the air handling burdens associated with the high EGR rates that are required to reduce NOx emissions to near zero levels. In this work, a wide variety of gasoline fuel reactivities (octane numbers ranging from < 40 to 87) were investigated to understand the engine performance and emissions of HFS-GCI operation on a multi-cylinder light-duty engine. The results indicate that over an EGR sweep at 4 bar BMEP, the gasoline fuels can achieve LTC operation with ultra-low NOx and soot emissions, while conventional diesel combustion (CDC) is unable to simultaneously achieve low NOx and soot. At 10 bar BMEP, all the gasoline fuels were compared to diesel, but using mixing controlled combustion and not LTC.

Published

2021

9. Gasoline Compression Ignition on a Light-Duty Multi-Cylinder Engine Using a Wide Range of Fuel Reactivities and Heavy Fuel Stratification

Author

William J. Cannella, Scott Curran, Robert M. Wagner, Andrew Ickes, and Adam B. Dempsey

Subjects

Renewable Energy, Sustainability and the Environment, business.industry, 020209 energy, Mechanical Engineering, Light duty, Nuclear engineering, Energy Engineering and Power Technology, Stratification (water), 02 engineering and technology, Compression (physics), law.invention, Ignition system, 020303 mechanical engineering & transports, Fuel Technology, 0203 mechanical engineering, Geochemistry and Petrology, law, Range (aeronautics), 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Exhaust gas recirculation, Gasoline, business

Abstract

Many research studies have focused on utilizing gasoline in modern compression ignition engines to reduce emissions and improve efficiency. Collectively, this combustion mode has become kn+own as gasoline compression ignition (GCI). One of the biggest challenges with GCI operation is maintaining control over the combustion process through the fuel injection strategy, such that the engine can be controlled on a cycle-by-cycle basis. Research studies have investigated a wide variety of GCI injection strategies (i.e., fuel stratification levels) to maintain control over the heat release rate while achieving low-temperature combustion (LTC). This work shows that at loads relevant to light-duty engines, partial fuel stratification (PFS) with gasoline provides very little controllability over the timing of combustion. On the contrary, heavy fuel stratification (HFS) provides very linear and pronounced control over the timing of combustion. However, the HFS strategy has challenges achieving LTC operation due to the air handling burdens associated with the high exhaust gas recirculation (EGR) rates that are required to reduce NOx emissions to near zero levels. In this work, a wide variety of gasoline fuel reactivities (octane numbers ranging from

Published

2021

10. Octane Index Applicability over the Pressure-Temperature Domain

Author

Flavio Dal Forno Chuahy, Roger Cracknell, Scott Curran, Allen Aradi, John Mengwasser, Tommy Powell, and James P. Szybist

Subjects

Work (thermodynamics), Control and Optimization, low temperature heat release (LTHR), 020209 energy, Nuclear engineering, Energy Engineering and Power Technology, 02 engineering and technology, lcsh:Technology, law.invention, chemistry.chemical_compound, 0203 mechanical engineering, law, octane sensitivity, octane index (OI), knock, multimode, advanced compression ignition (ACI), partial fuel stratification (PFS), spark assisted compression ignition (SACI), Range (aeronautics), 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Engineering (miscellaneous), Octane, lcsh:T, Renewable Energy, Sustainability and the Environment, Dominant factor, Autoignition temperature, Pressure temperature, Compression (physics), Ignition system, 020303 mechanical engineering & transports, chemistry, Energy (miscellaneous)

Abstract

Modern boosted spark-ignition (SI) engines and emerging advanced compression ignition (ACI) engines operate under conditions that deviate substantially from the conditions of conventional autoignition metrics, namely the research and motor octane numbers (RON and MON). The octane index (OI) is an emerging autoignition metric based on RON and MON which was developed to better describe fuel knock resistance over a broader range of engine conditions. Prior research at Oak Ridge National Laboratory (ORNL) identified that OI performs reasonably well under stoichiometric boosted conditions, but inconsistencies exist in the ability of OI to predict autoignition behavior under ACI strategies. Instead, the autoignition behavior under ACI operation was found to correlate more closely to fuel composition, suggesting fuel chemistry differences that are insensitive to the conditions of the RON and MON tests may become the dominant factor under these high efficiency operating conditions. This investigation builds on earlier work to study autoignition behavior over six pressure-temperature (PT) trajectories that correspond to a wide range of operating conditions, including boosted SI operation, partial fuel stratification (PFS), and spark-assisted compression ignition (SACI). A total of 12 different fuels were investigated, including the Co-Optima core fuels and five fuels that represent refinery-relevant blending streams. It was found that, for the ACI operating modes investigated here, the low temperature reactions dominate reactivity, similar to boosted SI operating conditions because their PT trajectories lay close to the RON trajectory. Additionally, the OI metric was found to adequately predict autoignition resistance over the PT domain, for the ACI conditions investigated here, and for fuels from different chemical families. This finding is in contrast with the prior study using a different type of ACI operation with different thermodynamic conditions, specifically a significantly higher temperature at the start of compression, illustrating that fuel response depends highly on the ACI strategy being used.

Published

2021

11. Operando measurement of lattice strain in internal combustion engine components by neutron diffraction

Author

David S. Weiss, Eric T. Stromme, Yan Chen, Orlando Rios, Matthew J. Frost, Zachary C. Sims, Scott Curran, Martin Wissink, and Ke An

Subjects

010302 applied physics, Multidisciplinary, Materials science, Nuclear engineering, Neutron diffraction, in situ, 02 engineering and technology, 021001 nanoscience & nanotechnology, Combustion, time-resolved, 01 natural sciences, Engineering, neutron diffraction, Internal combustion engine, operando, Lattice (order), 0103 physical sciences, Physical Sciences, internal combustion engine, Cylinder block, Neutron, 0210 nano-technology, Spallation Neutron Source, Diffractometer

Abstract

Significance Internal combustion engine components experience extreme thermomechanical cycling during operation, and the continuing need to improve engine efficiency while maintaining or improving reliability drives the development of lightweight materials with improved thermal and mechanical integrity. Understanding the behavior of new materials in dynamic operation requires operando characterization tools, but conventional in situ measurements of material behavior during real engine operation are very limited, and no practical means exist to replicate such extreme dynamics for ex situ study. In this work, we demonstrate that the penetrating power of neutrons can provide noninvasive measurement of lattice strains inside components of a firing engine, enabling the operando study of complex load states and thermal gradients throughout the solid materials., Engineering neutron diffraction can nondestructively and noninvasively probe stress, strain, temperature, and phase evolutions deep within bulk materials. In this work, we demonstrate operando lattice strain measurement of internal combustion engine components by neutron diffraction. A modified commercial generator engine was mounted in the VULCAN diffractometer at the Spallation Neutron Source, and the lattice strains in both the cylinder block and head were measured under static nonfiring conditions as well as steady state and cyclic transient operation. The dynamic temporal response of the lattice strain change during transient operation was resolved in two locations by asynchronous stroboscopic neutron diffraction. We demonstrated that operando neutron measurements can allow for understanding of how materials behave throughout operational engineering devices. This study opens a pathway for the industrial and academic communities to better understand the complexities of material behavior during the operation of internal combustion engines and other real-scale devices and systems and to leverage techniques developed here for future investigations of numerous new platforms and alloys.

Published

2020

12. Biofuels with Tailored Properties (A) for Hybrid and Plug-in Electric Vehicles(B)

Author

Doris Doris, Doris Oke, Jennifer Dunn, Greg Zaimes, Doug Longman, Hao Cai, Lauren Sittler, Emily Newes, Aaron Brooker, Ram Vijayagopal, Troy Hawkins, and Scott Curran

Published

2020

13. Advanced Engine and Fuel Technologies Annual Progress Report (FY2019)

Author

Stephen Busch, Mark Musculus, Lyle Pickett, Scott Skeen, John Dec, Isaac Ekoto, S. Goldsborough, Riccardo Scarcelli, James Szybist, Martin Wissink, William Pitz, Russell Whitesides, David Carrington, Jiajia Waters, K. Edwards, Charles Finney, Wael Elwasif, Toby Rockstroh, Muhsin Ameen, Tanmoy Chatterjee, Saumil Patel, Christopher Kolodziej, Hee Seong, Sibendu Som, Robert Wagner, Robert McCormick, Daniel Gaspar, Paul Bryan, C. Sluder, Magnus Sjöberg, Scott Curran, Derek Splitter, Christopher Powell, Charles Mueller, Brad Zigler, Gina Fioroni, Juliane Mueller, J. Bays, Josh Pihl, Melanie Moses-DeBusk, Matthew McNenly, Ajay Agrawal, Joshua Bittle, Robert Middleton, Ingmar Schoegl, Shyam Menon, Eric Petersen, Tianfeng Lu, Lisa Pfefferle, Yuan Xuan, Charles McEnally, Daniel Olsen, Hui Xu, Gregory Hampson, Anthony Marchese, Bret Windom, William Northrop, Thomas Briggs, Jr., Doug Longman, Sreshtha Majumdar, Calvin Thomas, Zhiming Gao, Yong Wang, Todd Toops, Vitaly Prikhodko, James Parks II, Bill Partridge, Abhi Karkamkar, Kenneth Rappé, Pascal Amar, Russell Zukouski, Jeff Girbach, Carl Hergart, Hanho Yun, Richard Roe, Robert Wang, Thomas Wallner, Arup Gangopadhyay, Ali Erdemir, Osman Eryilmaz, Stephen Hsu, Tim Cushing, Gefei Wu, George Fenske, Oyelayo Ajayi, Cinta Lorenzo-Martin, Robert Erck, Dileep Singh, Wenhua Yu, David France, Jun Qu, Xin He, Huimin Luo, Teresa Mathews, Harry Meyer III, Chanaka Kumara, Lelia Cosimbescu, James Van de Ven, Perry Li, Thomas Chase, and Paul Michael

Published

2020

14. Detection of Polar Compounds Condensed on Particulate Matter Using Capillary Electrophoresis-Mass Spectrometry

Author

John M. E. Storey, Samuel A. Lewis, Melanie Moses-DeBusk, Raynella M. Connatser, and Scott Curran

Subjects

Chromatography, Chemistry, Chemical polarity, Particulates, Capillary electrophoresis–mass spectrometry

Published

2020

15. Impact of Multimode Range and Location on Urban Fuel Economy on a Light-Duty Spark-Ignition Based Powertrain Using Vehicle System Simulations

Author

Robert M. Wagner and Scott Curran

Subjects

Ignition system, Multi-mode optical fiber, Powertrain, law, Range (aeronautics), Light duty, Spark (mathematics), Environmental science, Automotive engineering, law.invention

Published

2020

16. Compatibility of Elastomers with Polyoxymethylene Dimethyl Ethers and Blends with Diesel

Author

Christopher J. Janke, Raynella M. Connatser, Scott Curran, Michael D. Kass, and Martin Wissink

Subjects

Polyoxymethylene dimethyl ethers, chemistry.chemical_compound, Diesel fuel, Materials science, chemistry, Organic chemistry, Compatibility (geochemistry), Elastomer

Published

2020

17. IJER editorial: The future of the internal combustion engine

Author

Y Moriyoshi, Todd D. Fansler, Bengt Johansson, Paul C. Miles, Z Huang, Rolf D. Reitz, D. Arcoumanis, Raul Payri, Choongsik Bae, N Uchida, Ricardo Novella, Robert M. Wagner, Alfred Leipertz, Angelo Onorati, K Boulouchos, Avinash Kumar Agarwal, Gautam Kalghatgi, M Koike, Christian Hasse, M Guenthner, Ingemar Denbratt, Scott Curran, TV Johnson, Dennis N. Assanis, H Zhao, Song-Charng Kong, D Siebers, Shijin Shuai, Sage L. Kokjohn, W Su, Bianca Maria Vaglieco, Manolis Gavaises, Mario F. Trujillo, M Canakci, Mattias Richter, T Ishiyama, and Hideyuki Ogawa

Subjects

Internal combustion engine, TL, Mechanical Engineering, Automotive Engineering, internal combustion engine, diagnostics, Aerospace Engineering, Environmental science, Ocean Engineering, Future, Automotive engineering, Engine

Abstract

Internal combustion (IC) engines operating on fossil fuel oil provide about 25% of the world's power (about 3000 out of 13,000 million tons oil equivalent per year-see Figure 1), and in doing so, they produce about 10% of the world's greenhouse gas (GHG) emissions (Figure 2). Reducing fuel consumption and emissions has been the goal of engine researchers and manufacturers for years, as can be seen in the two decades of ground-breaking peer-reviewed articles published in this International Journal of Engine Research (IJER). Indeed, major advances have been made, making today's IC engine a technological marvel. However, recently, the reputation of IC engines has been dealt a severe blow by emission scandals that threaten the ability of this technology to make significant and further contributions to the reduction of transportation sector emissions. In response, there have been proposals to replace vehicle IC engines with electric-drives with the intended goals of further reducing fuel consumption and emissions, and to decrease vehicle GHG emissions

Published

2020

18. Closed mitosis requires local disassembly of the nuclear envelope

Author

Buzz Baum, Wanda Kukulski, Uwe Schmidt, Scott Curran, Gautam Dey, Siân Culley, and Ricardo Henriques

Subjects

Cell division, Nuclear Envelope, Fission, Mitosis, Models, Biological, Article, Double membrane, 03 medical and health sciences, 0302 clinical medicine, Schizosaccharomyces, medicine, Nuclear pore, 030304 developmental biology, Physics, 0303 health sciences, Multidisciplinary, biology, biology.organism_classification, Cell biology, medicine.anatomical_structure, Nuclear fission, Schizosaccharomyces pombe, Nuclear Pore, Nucleus, Cell Division, 030217 neurology & neurosurgery

Abstract

At the end of mitosis, eukaryotic cells must segregate the two copies of their replicated genome into two new nuclear compartments1. They do this either by first dismantling and later reassembling the nuclear envelope in an 'open mitosis' or by reshaping an intact nucleus and then dividing it into two in a 'closed mitosis'2,3. Mitosis has been studied in a wide variety of eukaryotes for more than a century4, but how the double membrane of the nuclear envelope is split into two at the end of a closed mitosis without compromising the impermeability of the nuclear compartment remains unknown5. Here, using the fission yeast Schizosaccharomyces pombe (a classical model for closed mitosis5), genetics, live-cell imaging and electron tomography, we show that nuclear fission is achieved via local disassembly of nuclear pores within the narrow bridge that links segregating daughter nuclei. In doing so, we identify the protein Les1, which is localized to the inner nuclear envelope and restricts the process of local nuclear envelope breakdown to the bridge midzone to prevent the leakage of material from daughter nuclei. The mechanism of local nuclear envelope breakdown in a closed mitosis therefore closely mirrors nuclear envelope breakdown in open mitosis3, revealing an unexpectedly high conservation of nuclear remodelling mechanisms across diverse eukaryotes.

Published

2020

19. The effects of distillation characteristics and aromatic content on low-load gasoline compression ignition (GCI) performance and soot emissions in a multi-cylinder engine

Author

Scott W. Wagnon, John Morse Storey, Flavio Dal Forno Chuahy, Scott Curran, and Melanie Moses-DeBusk

Subjects

business.industry, 020209 energy, General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, 02 engineering and technology, medicine.disease_cause, Combustion, Soot, law.invention, Ignition system, Fuel Technology, 020401 chemical engineering, law, Range (aeronautics), 0202 electrical engineering, electronic engineering, information engineering, medicine, Environmental science, Octane rating, 0204 chemical engineering, Gasoline, Process engineering, business, Distillation, NOx

Abstract

The DOE Co-Optima initiative focuses on investigating the ability of fuel properties to work in tandem with advanced combustion engines to increase fuel economy. One of the most promising advanced compression ignition strategies (ACI) is gasoline compression ignition (GCI). GCI leverages the relative auto-ignition resistance of gasoline-like fuels to enable highly premixed combustion processes at a range of air–fuel stratifications. In practical applications, engines must operate over a wide range of conditions, which associated with the inherent limitations and benefits of different ACI modes, suggests the engine should be capable of operating across multiple combustion modes. Operating the engine in multiple combustion modes effectively requires a fundamental understanding of fuel composition effects. The fact that GCI can operate with fuels designed for spark ignition engines enables the engine to be operated in either combustion mode when most suitable. This effort investigates the effects of fuel physical properties and aromatic content on GCI NOx, unburned hydrocarbons (HC), CO and particulate emissions. Three fuels with the same research octane number (RON) but different distillation curves and aromatic content are compared to isolate the impact of the two properties in a production, multi-cylinder engine. Different injection strategies targeting increasing levels of fuel stratification (100%, 70% and 0% premixed fuel) at a constant combustion phasing are utilized. Results showed that changes in fuel stratification had little impact on emissions of NOx, HC and CO until the fuel was injected completely near top dead center (TDC). Particulate sampling showed that the aromatic content of the fuel had greater impact on elemental carbon particulate matter (PM) emissions than the fuel distillation characteristics.

Published

2021

20. Impact of fuel chemical function characteristics on spark assisted and kinetically controlled compression ignition performance focused on multi-mode operation

Author

James P. Szybist, Tommy Powell, Flavio Dal Forno Chuahy, and Scott Curran

Subjects

Materials science, 020209 energy, General Chemical Engineering, Nuclear engineering, Organic Chemistry, Energy Engineering and Power Technology, 02 engineering and technology, medicine.disease_cause, Combustion, Soot, Adiabatic flame temperature, law.invention, Ignition system, Fuel Technology, 020401 chemical engineering, Engine efficiency, law, Range (aeronautics), Compression ratio, 0202 electrical engineering, electronic engineering, information engineering, medicine, Octane rating, 0204 chemical engineering

Abstract

The DOE Co-Optima initiative has a focus on investigating the ability of fuel properties to work in tandem with advanced combustion engines to increase fuel economy. Advanced compression ignition strategies like spark assisted compression ignition (SACI) and partial fuel stratification (PFS) have been shown to achieve better efficiency and emissions performance than traditional combustion processes (i.e., conventional diesel combustion, spark ignited combustion). These strategies rely on a high degree of fuel mixing and a globally dilute environment to achieve lower temperature combustion. The avoidance of fuel rich regions and the reduction in peak flame temperatures result in low soot and NOx formation. Despite their clear benefits, operating range limitations have been identified for all combustion strategies. The limitations stem from the fundamental characteristics of each combustion process, hence they can't be entirely avoided. These limitations are also geometry, fuel type, dilution level and mixture preparation dependent. Metal engine experiments have been conducted on a single-cylinder research engine equipped with variable valve actuation and a 12.5:1 compression ratio, more appropriate for high load boosted spark ignition operation. Five fuels with different chemical class compositions but matched research octane number (RON) were tested under both SACI and PFS at mid load conditions. Combustion phasing was changed over the whole range of operability to show trade-offs between the fuels. Specific chemical, mixture preparation and thermodynamic effects are discussed for performance and emission results. SACI and PFS are then compared to a baseline spark ignition (SI) condition to estimate potential benefits of operating under advanced combustion modes. The results show that there are significant fuel specific effects even at matched RON and octane sensitivity that affect emissions, engine efficiency and range of operability of the different advanced combustion modes.

Published

2021

21. Development of a range-extended electric vehicle powertrain for an integrated energy systems research printed utility vehicle

Author

Lonnie J. Love, Shean Huff, Roderick K Jackson, Scott Curran, Robert M. Wagner, Johney B. Green, Brian K. Post, and Paul Chambon

Subjects

Rapid prototyping, Engineering, business.product_category, Chassis, Powertrain, business.industry, 020209 energy, Mechanical Engineering, 02 engineering and technology, Building and Construction, Management, Monitoring, Policy and Law, Oak Ridge National Laboratory, 021001 nanoscience & nanotechnology, Bridge (nautical), Automotive engineering, General Energy, Energy(all), Range (aeronautics), Electric vehicle, 0202 electrical engineering, electronic engineering, information engineering, Fuel efficiency, 0210 nano-technology, business, Civil and Structural Engineering

Abstract

Rapid vehicle and powertrain development has become essential to for the design and implementation of vehicles that meet and exceed the fuel efficiency, cost, and performance targets expected by today’s consumer while keeping pace with reduced development cycle and more frequent product releases. Recently, advances in large-scale additive manufacturing have provided the means to bridge hardware-in-the-loop (HIL) experimentation and preproduction mule chassis evaluation. This paper details the accelerated development of a printed range-extended electric vehicle (REEV) by Oak Ridge National Laboratory, by paralleling hardware-in-the-loop development of the powertrain with rapid chassis prototyping using big area additive manufacturing (BAAM). BAAM’s ability to accelerate the mule vehicle development from computer-aided design to vehicle build is explored. The use of a hardware-in-the-loop laboratory is described as it is applied to the design of a range-extended electric powertrain to be installed in a printed prototype vehicle. The integration of the powertrain and the opportunities and challenges it presents are described in this work. A comparison of offline simulation, HIL and chassis rolls results is presented to validate the development process. Chassis dynamometer results for battery electric and range extender operation are analyzed to show the benefits of the architecture.

Published

2017

22. An assessment of thermodynamic merits for current and potential future engine operating strategies

Author

Derek A. Splitter, Scott Curran, Adam B. Dempsey, Brian C. Kaul, James P. Szybist, and Martin Wissink

Subjects

Thermal efficiency, Work (thermodynamics), Engineering, business.industry, 020209 energy, Mechanical Engineering, Nuclear engineering, Homogeneous charge compression ignition, Weight change, Aerospace Engineering, Mechanical engineering, Ocean Engineering, 02 engineering and technology, Combustion, Physics::Fluid Dynamics, 020303 mechanical engineering & transports, 0203 mechanical engineering, Automotive Engineering, Compression ratio, 0202 electrical engineering, electronic engineering, information engineering, Working fluid, Physics::Chemical Physics, Current (fluid), business

Abstract

This work compares the fundamental thermodynamic underpinnings (i.e. working fluid properties and heat release profile) of various combustion strategies with engine measurements. The approach employs a model that separately tracks the impacts on efficiency due to differences in rate of heat addition, volume change, mass addition, and molecular weight change for a given combination of working fluid, heat release profile, and engine geometry. Comparative analysis between the measured and modeled efficiencies illustrates fundamental sources of efficiency reductions or opportunities inherent to various combustion regimes. Engine operating regimes chosen for analysis include stoichiometric spark-ignited combustion and lean compression-ignited combustion including homogeneous charge compression ignition, spark-assisted homogeneous charge compression ignition, and conventional diesel combustion. Within each combustion regime, the effects of engine load, combustion duration, combustion phasing, compression ratio,...

Published

2017

23. Response Characteristics of a Stable Mixed Potential Ammonia Sensor in Simulated Diesel Exhaust

Author

Vitaly Y. Prikhodko, Kannan Pasupathikovil Ramaiyan, Rangachary Mukundan, Cortney R. Kreller, Josh A. Pihl, Eric L. Brosha, Scott Curran, and James E. Parks

Subjects

Materials science, Diesel exhaust, Renewable Energy, Sustainability and the Environment, 020209 energy, Response characteristics, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Pulp and paper industry, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Mixed potential, Ammonia, chemistry.chemical_compound, chemistry, 0202 electrical engineering, electronic engineering, information engineering, Materials Chemistry, Electrochemistry, 0210 nano-technology

Published

2017

24. Closed mitosis requires local disassembly of the nuclear envelope

Author

Gautam Dey, Siân Culley, Ricardo Henriques, Wanda Kukulski, Buzz Baum, and Scott Curran

Subjects

Physics, 0303 health sciences, biology, Fission, biology.organism_classification, Cell biology, Double membrane, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Live cell imaging, Nuclear fission, Schizosaccharomyces pombe, medicine, Mitosis, Nucleus, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

At the end of mitosis, eukaryotic cells must segregate both copies of their replicated genome into two new nuclear compartments (1). They do this either by first dismantling and later reassembling the nuclear envelope in a so called “open mitosis”, or by reshaping an intact nucleus and then dividing into two in a “closed mitosis” (2, 3). However, while mitosis has been studied in a wide variety of eukaryotes for over a century (4), it is not known how the double membrane of the nuclear envelope is split into two at the end of a closed mitosis without compromising the impermeability of the nuclear compartment (5). In studying this problem in the fission yeastSchizosaccharomyces pombe, a classical model for closed mitosis (5), we use genetics, live cell imaging and electron tomography to show that nuclear fission is achieved via local disassembly of the nuclear envelope (NE) within the narrow bridge that links segregating daughter nuclei. In doing so, we identify a novel inner NE-localised protein Les1 that restricts the process of local NE breakdown (local NEB) to the bridge midzone and prevents the leakage of material from daughter nuclei. The mechanics of local NEB in a closed mitosis closely mirror those of NEB in open mitosis (3), revealing an unexpectedly deep conservation of nuclear remodelling mechanisms across diverse eukaryotes.

Published

2019

25. Response Characteristics of Stable Mixed-Potential NH3 Sensors in Diesel Engine Exhaust

Author

Scott Curran, Eric L. Brosha, James E. Parks, Josh A. Pihl, R. Mukundan, Cortney R. Kreller, and Vitaly Y. Prikhodko

Subjects

Diesel particulate filter, Materials science, business.industry, Calibration curve, Health, Toxicology and Mutagenesis, Mass flow controller, Analytical chemistry, Exhaust gas, 02 engineering and technology, Management, Monitoring, Policy and Law, Diesel engine, 01 natural sciences, Pollution, 010406 physical chemistry, 0104 chemical sciences, Electrochemical gas sensor, 020303 mechanical engineering & transports, 0203 mechanical engineering, AFR sensor, Automotive Engineering, Exhaust gas recirculation, business

Abstract

A mixed-potential, electrochemical sensor platform is extended to NH3 sensing by the introduction of a new gold alloy working electrode. A planar, pre-commercial NH3 sensor utilized LANL’s controlled interface approach, and a Pd-Au alloy working electrode was tested in exhaust of a GM 1.9 L diesel engine downstream of a diesel oxidation catalyst through a slipstream arrangement. A fraction of the exhaust was pulled across the sensor with a pump at 20 L/min. In order to simulate NH3 slip inside of a full SCR emissions control system, NH3 was injected immediately upstream of the sensor using a calibrated mass flow controller. The sensor response quantitatively tracked the NH3 as measured via Fourier transform infrared (FTIR) analyzer. A calibration curve was obtained in the exhaust from an ammonia staircase response with the engine running at steady-state engine conditions resulting in low background concentrations of NOx and HC (

Published

2016

26. Evolution and current understanding of physicochemical characterization of particulate matter from reactivity controlled compression ignition combustion on a multicylinder light-duty engine

Author

Reed Hanson, William F. Northrop, Vitaly Y. Prikhodko, Melanie Moses-DeBusk, Samuel A. Lewis, Adam B. Dempsey, Scott Curran, John M. E. Storey, and Teresa L Barone

Subjects

Smoke, Waste management, Chemistry, 020209 energy, Mechanical Engineering, Aerospace Engineering, Ocean Engineering, 02 engineering and technology, Particulates, Compression (physics), Combustion, medicine.disease_cause, Soot, law.invention, Absorbance, Ignition system, Chemical engineering, law, Automotive Engineering, 0202 electrical engineering, electronic engineering, information engineering, medicine, Current (fluid)

Abstract

Low-temperature compression ignition combustion can result in nearly smokeless combustion, as indicated by a smoke meter or other forms of soot measurement that rely on absorbance due to elemental ...

Published

2016

27. A perspective on the range of gasoline compression ignition combustion strategies for high engine efficiency and low NOx and soot emissions: Effects of in-cylinder fuel stratification

Author

Adam B. Dempsey, Scott Curran, and Robert M. Wagner

Subjects

Chemistry, business.industry, 020209 energy, Mechanical Engineering, Homogeneous charge compression ignition, Aerospace Engineering, Ocean Engineering, Autoignition temperature, 02 engineering and technology, Diesel cycle, Combustion, Automotive engineering, law.invention, Ignition system, Brake specific fuel consumption, 020303 mechanical engineering & transports, 0203 mechanical engineering, Internal combustion engine, law, Automotive Engineering, 0202 electrical engineering, electronic engineering, information engineering, Octane rating, Process engineering, business

Abstract

Many research studies have shown that low temperature combustion in compression ignition engines has the ability to yield ultra-low NOx and soot emissions while maintaining high thermal efficiency. To achieve low temperature combustion, sufficient mixing time between the fuel and air in a globally dilute environment is required, thereby avoiding fuel-rich regions and reducing peak combustion temperatures, which significantly reduces soot and NOx formation, respectively. It has been demonstrated that achieving low temperature combustion with diesel fuel over a wide range of conditions is difficult because of its properties, namely, low volatility and high chemical reactivity. On the contrary, gasoline has a high volatility and low chemical reactivity, meaning it is easier to achieve the amount of premixing time required prior to autoignition to achieve low temperature combustion. In order to achieve low temperature combustion while meeting other constraints, such as low pressure rise rates and maintaining control over the timing of combustion, in-cylinder fuel stratification has been widely investigated for gasoline low temperature combustion engines. The level of fuel stratification is, in reality, a continuum ranging from fully premixed (i.e. homogeneous charge of fuel and air) to heavily stratified, heterogeneous operation, such as diesel combustion. However, to illustrate the impact of fuel stratification on gasoline compression ignition, the authors have identified three representative operating strategies: partial, moderate, and heavy fuel stratification. Thus, this article provides an overview and perspective of the current research efforts to develop engine operating strategies for achieving gasoline low temperature combustion in a compression ignition engine via fuel stratification. In this study, computational fluid dynamics modeling of the in-cylinder processes during the closed valve portion of the cycle was used to illustrate the opportunities and challenges associated with the various fuel stratification levels.

Published

2016

28. Ignition Delay in Low Temperature Combustion

Author

Joseph Drallmeier, Scott Curran, Robert M. Wagner, and Martin Wissink

Subjects

Materials science, Chemical engineering, Low temperature combustion, medicine, Ignition delay, medicine.disease_cause, Nitrogen oxides, Soot

Published

2018

29. Drive cycle simulation of high efficiency combustions on fuel economy and exhaust properties in light-duty vehicles

Author

John F. Thomas, David Smith, James E. Parks, Scott Curran, C. Stuart Daw, Robert M. Wagner, K. Dean Edwards, and Zhiming Gao

Subjects

Engineering, business.industry, Mechanical Engineering, Homogeneous charge compression ignition, Building and Construction, Management, Monitoring, Policy and Law, Combustion, Automotive engineering, law.invention, Ignition system, General Energy, Energy(all), Internal combustion engine, Economy, law, Carbureted compression ignition model engine, Octane rating, Hydrogen fuel enhancement, business, Gasoline direct injection, Civil and Structural Engineering

Abstract

Results from computational simulations of fuel economy and engine-out emissions are presented for light-duty conventional and hybrid vehicles powered by conventional and high-efficiency combustion engines, including use of port fuel-injected, lean gasoline direct injection, reactivity controlled compression ignition, and conventional diesel combustion. The results indicate that multimode operation with conventional diesel combustion plus reactivity controlled compression ignition, conventional diesel combustion only, and lean gasoline direct injection has the potential to significantly exceed port fuel-injected fuel economy. In all cases, hybridization is predicted to significantly improve fuel economy by permitting the maximum exploitation of high efficiency engine combustion states. Predicted engine-out emissions vary considerably with combustion mode, with reactivity controlled compression ignition generating the highest carbon monoxide and hydrocarbon emissions. On the other hand, reactivity controlled compression ignition is predicted to generate the lowest emissions of nitrogen oxides. Importantly, lean gasoline direct injection and reactivity controlled compression ignition combustion modes are expected to dramatically decrease exhaust temperatures, especially for reactivity controlled compression ignition, which can potentially limit aftertreatment performance. While all results presented are from simulations, the results provide prediction of important details and trends for advanced vehicles that are currently extremely difficult to experimentally study.

Published

2015

30. Load Limit Extension in Pre-Mixed Compression Ignition Using a 2-Zone Combustion System

Author

Rolf D. Reitz, Christopher J. Rutland, Michael Bergin, Scott Curran, and Adam B. Dempsey

Subjects

Materials science, Homogeneous charge compression ignition, General Medicine, Mechanics, Fuel injection, Compression (physics), Automotive engineering, law.invention, Ignition system, Brake specific fuel consumption, Internal combustion engine, law, Combustion chamber, Engine knocking

Published

2015

31. Characterization of Reactivity Controlled Compression Ignition (RCCI) Using Premixed Gasoline and Direct-Injected Gasoline with a Cetane Improver on a Multi-Cylinder Engine

Author

Scott Curran, Rolf D. Reitz, and Adam B. Dempsey

Subjects

Diesel fuel, Cetane Improver, Homogeneous charge compression ignition, Octane rating, Environmental science, General Medicine, Gasoline, Fuel injection, Diesel engine, Cetane number, Automotive engineering

Abstract

The focus of the present paper was to characterize Reactivity Controlled Compression Ignition (RCCI) using a single-fuel approach of gasoline and gasoline mixed with a commercially available cetane improver on a multi-cylinder engine. RCCI was achieved by port-injecting a certification grade 96 research octane gasoline and direct-injecting the same gasoline mixed with various levels of a cetane improver, 2-ethylhexyl nitrate (EHN). The EHN volume percentages investigated in the direct-injected fuel were 10, 5, and 2.5%. The combustion phasing controllability and emissions of the different fueling combinations were characterized at 2300 rpm and 4.2 bar brake mean effective pressure over a variety of parametric investigations including direct injection timing, premixed gasoline percentage, and intake temperature. Comparisons were made to gasoline/diesel RCCI operation on the same engine platform at nominally the same operating condition. The experiments were conducted on a modern four cylinder light-duty diesel engine that was modified with a port-fuel injection system while maintaining the stock direct injection fuel system. The pistons were modified for highly premixed operation and feature an open shallow bowl design. The results indicate that the authority to control the combustion phasing through the fuel delivery strategy (e.g., direct injection timing or premixed gasoline percentage) ismore » not a strong function of the EHN concentration in the direct-injected fuel. It was also observed that NOx emissions are a strong function of the global EHN concentration in-cylinder and the combustion phasing. Finally, in general, NOx emissions are significantly elevated for gasoline/gasoline+EHN operation compared with gasoline/diesel RCCI operation at a given operating condition.« less

Published

2015

32. Isolating the effects of reactivity stratification in reactivity-controlled compression ignition with iso-octane and n -heptane on a light-duty multi-cylinder engine

Author

Scott Curran, Christine Mounaïm-Rousselle, Martin Wissink, Greg Roberts, Mark P. B. Musculus, Groupe d'étude de l'atmosphère météorologique (CNRM-GAME), Institut national des sciences de l'Univers (INSU - CNRS)-Météo France-Centre National de la Recherche Scientifique (CNRS), Laboratoire pluridisciplinaire de recherche en ingénierie des systèmes, mécanique et énergétique (PRISME), Université d'Orléans (UO)-Institut National des Sciences Appliquées - Centre Val de Loire (INSA CVL), and Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)

Subjects

Materials science, 020209 energy, Analytical chemistry, Aerospace Engineering, Stratification (water), Ocean Engineering, 02 engineering and technology, Combustion, 7. Clean energy, law.invention, chemistry.chemical_compound, law, Low temperature combustion, 0202 electrical engineering, electronic engineering, information engineering, ComputingMilieux_MISCELLANEOUS, Octane, Heptane, business.industry, Mechanical Engineering, Light duty, [SPI.FLUID]Engineering Sciences [physics]/Reactive fluid environment, Structural engineering, Ignition system, chemistry, Automotive Engineering, business

Abstract

Reactivity-controlled compression ignition (RCCI) is a dual-fuel variant of low-temperature combustion that uses in-cylinder fuel stratification to control the rate of reactions occurring during combustion. Using fuels of varying reactivity (autoignition propensity), gradients of reactivity can be established within the charge, allowing for control over combustion phasing and duration for high efficiency while achieving low NOx and soot emissions. In practice, this is typically accomplished by premixing a low-reactivity fuel, such as gasoline, with early port or direct injection, and by direct injecting a high-reactivity fuel, such as diesel, at an intermediate timing before top dead center. Both the relative quantity and the timing of the injection(s) of high-reactivity fuel can be used to tailor the combustion process and thereby the efficiency and emissions under RCCI. While many combinations of high- and low-reactivity fuels have been successfully demonstrated to enable RCCI, there is a lack of fundamental understanding of what properties, chemical or physical, are most important or desirable for extending operation to both lower and higher loads and reducing emissions of unreacted fuel and CO. This is partly due to the fact that important variables such as temperature, equivalence ratio, and reactivity change simultaneously in both a local and a global sense with changes in the injection of the high-reactivity fuel. This study uses primary reference fuels iso-octane and n-heptane, which have similar physical properties but much different autoignition properties, to create both external and in-cylinder fuel blends that allow for the effects of reactivity stratification to be isolated and quantified. This study is part of a collaborative effort with researchers at Sandia National Laboratories who are investigating the same fuels and conditions of interest in an optical engine. This collaboration aims to improve our fundamental understanding of what fuel properties are required to further develop advanced combustion modes.

Published

2017

33. Spray-Wall Interactions in a Small-Bore, Multi-Cylinder Engine Operating With Reactivity-Controlled Compression Ignition

Author

Sage L. Kokjohn, Chaitanya Kavuri, Scott Curran, and Martin Wissink

Subjects

Heptane, Materials science, business.industry, 020209 energy, Silicon on insulator, 02 engineering and technology, Computational fluid dynamics, Combustion, Compression (physics), law.invention, Ignition system, chemistry.chemical_compound, chemistry, law, 0202 electrical engineering, electronic engineering, information engineering, Reactivity (chemistry), Wetting, Composite material, business

Abstract

Experimental work on reactivity-controlled compression ignition (RCCI) in a small-bore, multi-cylinder engine operating on premixed iso-octane and direct-injected n-heptane has shown an unexpected combustion phasing advance at early injection timings, which has not been observed in large-bore engines operating under RCCI at similar conditions. In this work, computational fluid dynamics (CFD) simulations were performed to investigate whether spray-wall interactions could be responsible for this result. Comparison of the spray penetration, fuel film mass, and in-cylinder visualization of the spray from the CFD results to the experimentally measured combustion phasing and emissions provided compelling evidence of strong fuel impingement at injection timings earlier than −90 crank angle degrees (°CA) after top dead center (aTDC), and transition from partial to full impingement between −65 and −90°CA aTDC. Based on this evidence, explanations for the combustion phasing advance at early injection timings are proposed along with potential verification experiments.

Published

2017

34. Summary Report on the SAE 2016 Range Extenders for Electric Vehicles Symposium

Author

Scott Curran, Robert M. Wagner, and Russ Campbell

Published

2017

35. RCCI Combustion Regime Transitions in a Single-Cylinder Optical Engine and a Multi-Cylinder Metal Engine

Author

Ethan Eagle, Scott Curran, Gregory Roberts, Mark P. B. Musculus, Christine Rousselle, Martin Wissink, Groupe d'étude de l'atmosphère météorologique (CNRM-GAME), Institut national des sciences de l'Univers (INSU - CNRS)-Météo France-Centre National de la Recherche Scientifique (CNRS), Laboratoire pluridisciplinaire de recherche en ingénierie des systèmes, mécanique et énergétique (PRISME), Université d'Orléans (UO)-Institut National des Sciences Appliquées - Centre Val de Loire (INSA CVL), Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA), Sandia National Laboratories [Livermore], and Sandia National Laboratories - Corporation

Subjects

Materials science, law, 020209 energy, [SPI.FLUID]Engineering Sciences [physics]/Reactive fluid environment, 0202 electrical engineering, electronic engineering, information engineering, Mechanical engineering, 02 engineering and technology, General Medicine, Combustion, Automotive engineering, ComputingMilieux_MISCELLANEOUS, Cylinder (engine), law.invention

Abstract

International audience

Published

2017

36. The Contribution of Lubricant to the Formation of Particulate Matter with Reactivity Controlled Compression Ignition in Light-Duty Diesel Engines

Author

Samuel A. Lewis, Scott Curran, Christopher M. Wright, John M. E. Storey, N. Ryan Walker, Rolf D. Reitz, and Adam B. Dempsey

Subjects

Diesel particulate filter, Materials science, Waste management, Health, Toxicology and Mutagenesis, Homogeneous charge compression ignition, Management, Monitoring, Policy and Law, Diesel engine, Fuel injection, medicine.disease_cause, Pollution, Soot, Diesel fuel, Carbureted compression ignition model engine, Automotive Engineering, medicine, Gasoline

Abstract

Reactivity controlled compression ignition (RCCI) has been shown in single- and multi-cylinder engine research to achieve high thermal efficiencies with ultra-low NOX and soot emissions. The nature of the particulate matter (PM) produced by RCCI operation has been shown in recent research to be different than that of conventional diesel combustion and even diesel low-temperature combustion. Previous research has shown that the PM from RCCI operation contains a large amount of organic material that is volatile and semi-volatile. However, it is unclear if the organic compounds are stemming from fuel or lubricant oil. The PM emissions from dual-fuel RCCI were investigated in this study using two engine platforms, with an emphasis on the potential contribution of lubricant. Both engine platforms used the same base General Motors (GM) 1.9-L diesel engine geometry. The first study was conducted on a single-cylinder research engine with primary reference fuels (PRFs), n-heptane, and iso-octane. The second study was conducted on a four-cylinder GM 1.9-L ZDTH engine which was modified with a port fuel injection (PFI) system while maintaining the stock direct injection fuel system. Multi-cylinder RCCI experiments were run with PFI gasoline and direct injection of 2-ethylhexyl nitrate (EHN) mixed with gasoline at 5 % EHN by volume. In addition, comparison cases of conventional diesel combustion (CDC) were performed. Particulate size distributions were measured, and PM filter samples were collected for analysis of lube oil components. Triplicate PM filter samples (i.e., three individual filter samples) for both gas chromatography-mass spectroscopy (GC-MS; organic) analysis and X-ray fluorescence (XRF; metals) were obtained at each operating point and queued for analysis of both organic species and lubricant metals. The results give a clear indication that lubricants do not contribute significantly to the formation of RCCI PM.

Published

2014

37. Reactivity-controlled compression ignition drive cycle emissions and fuel economy estimations using vehicle system simulations

Author

Zhiming Gao, Scott Curran, and Robert M. Wagner

Subjects

Engineering, business.industry, Mechanical Engineering, Homogeneous charge compression ignition, Aerospace Engineering, Ocean Engineering, Diesel cycle, Automotive engineering, law.invention, Ignition system, Economy, Internal combustion engine, law, Carbureted compression ignition model engine, Automotive Engineering, Compression ratio, Octane rating, Ignition timing, business

Abstract

In-cylinder blending of gasoline and diesel to achieve reactivity-controlled compression ignition has been shown to reduce NOX and soot emissions while maintaining or improving brake thermal efficiency as compared with conventional diesel combustion. The reactivity-controlled compression ignition concept has an advantage over many advanced combustion strategies in that the fuel reactivity can be tailored to the engine speed and load, allowing stable low-temperature combustion to be extended over more of the light-duty drive cycle load range. A multi-mode reactivity-controlled compression ignition strategy is employed where the engine switches from reactivity-controlled compression ignition to conventional diesel combustion when speed and load demand are outside of the experimentally determined reactivity-controlled compression ignition range. The potential for reactivity-controlled compression ignition to reduce drive cycle fuel economy and emissions is not clearly understood and is explored here by simulating the fuel economy and emissions for a multi-mode reactivity-controlled compression ignition–enabled vehicle operating over a variety of US drive cycles using experimental engine maps for multi-mode reactivity-controlled compression ignition, conventional diesel combustion, and a 2009 port-fuel injected gasoline engine. Drive cycle simulations are completed assuming a conventional mid-size passenger vehicle with an automatic transmission. Multi-mode reactivity-controlled compression ignition fuel economy simulation results are compared with the same vehicle powered by a representative 2009 port-fuel injected gasoline engine over multiple drive cycles. Engine-out drive cycle emissions are compared with conventional diesel combustion, and observations regarding relative gasoline and diesel tank sizes needed for the various drive cycles are also summarized.

Published

2014

38. Geoanalysis of park-and-ride facilities for future laboratory-wide commuting program

Author

Amy D. Bittler, Amy Moore, Scott Curran, and Melissa Voss Lapsa

Subjects

Transportation, Park and ride, Management Science and Operations Research, Oak Ridge National Laboratory, GIS, Park-and-ride, lcsh:HE1-9990, Zip code, Transport engineering, Routing (hydrology), Work (electrical), Emissions, Greenhouse gas, Automotive Engineering, Environmental science, Pilot program, lcsh:Transportation and communications, Transportation planning, Vehicle type, Routing, Civil and Structural Engineering

Abstract

There is a growing interest in reducing the amount of vehicle miles traveled (VMT) to reduce overall carbon emissions and energy usage. The Oak Ridge National Laboratory (ORNL) has more than 4500 employees, most of which live in and around Knoxville, Tennessee. ORNL is currently developing a pilot commuting program for all employees, which incorporates the use of park-and-ride facilities. This study outlines the methodology behind the preliminary geoanalysis and routing used in developing a lab-wide commuting program. The data used for the study included numbers of employee residences per zip code. Commuting configurations by clustered zip code area and vehicle type were developed. Satellite imagery was used to locate actual, suitable parking facilities to accommodate the specified number of residents involved in each commuting configuration. Routing and estimations of travel times were performed using TransCAD. Energy estimates in kilowatt-hours (kwh) and gallons of gasoline, and gallons of gasoline equivalent, were all determined based on the resulting scenarios. Standard petroleum-fuelled vehicles were used in the initial estimates. Standard electric vehicles were also used in alternative scenarios to estimate potential additional energy and fuel savings. The initial findings from this work will be used to develop a pilot program for ORNL.

Published

2019

39. Effectiveness of Diesel Oxidation Catalyst in Reducing HC and CO Emissions from Reactivity Controlled Compression Ignition

Author

Scott Curran, Robert M. Wagner, James E. Parks, and Vitaly Y. Prikhodko

Subjects

Diesel particulate filter, Diesel exhaust, Waste management, business.industry, Strategy and Management, Mechanical Engineering, Metals and Alloys, Combustion, Industrial and Manufacturing Engineering, chemistry.chemical_compound, Diesel fuel, chemistry, Chemical engineering, Nitrogen oxide, Exhaust gas recirculation, Gasoline, business, NOx

Abstract

Reactivity Controlled Compression Ignition (RCCI) has been shown to allow for diesel-like or better brake thermal efficiency with significant reductions in nitrogen oxide (NOX) particulate matter (PM) emissions. Hydrocarbon (HC) and carbon monoxide (CO) emission levels, on the other hand, are similar to those of port fuel injected gasoline engines. The higher HC and CO emissions combined with the lower exhaust temperatures with RCCI operation present a challenge for current exhaust aftertreatments. The reduction of HC and CO emissions in a lean environment is typically achieved with an oxidation catalyst. In this work, several diesel oxidation catalysts (DOC) with different precious metal loadings were evaluated for effectiveness to control HC and CO emissions from RCCI combustion in a light-duty multi-cylinder engine operating on gasoline and diesel fuels. Each catalyst was evaluated in a steady-state engine operation with temperatures ranging from 160 to 260 C. A shift to a higher light-off temperature was observed during the RCCI operation. In addition to the steady-state experiments, the performances of the DOCs were evaluated during multi-mode engine operation by switching from diesel-like combustion at higher exhaust temperature and low HC/CO emissions to RCCI combustion at lower temperature and higher HC/CO emissions. High CO andmore » HC emissions from RCCI generated an exotherm keeping the catalyst above the light-off temperature.« less

Published

2013

40. Effects of Biofuel Blends on RCCI Combustion in a Light-Duty, Multi-Cylinder Diesel Engine

Author

Scott Curran, Rolf D. Reitz, Reed Hanson, and Robert M. Wagner

Subjects

Materials science, Biofuel, law, Light duty, General Medicine, Combustion, Diesel engine, Automotive engineering, Cylinder (engine), law.invention

Published

2013

41. Overview of the Oak Ridge National Laboratory Advanced Manufacturing Integrated Energy Demonstration Project: Case Study of Additive Manufacturing as a Tool to Enable Rapid Innovation in Integrated Energy Systems

Author

Robert M. Wagner, Lucas Tryggestad, Michael Starke, Johney B. Green, Brian Lee, Roderick K Jackson, Paul Chambon, Burak Ozpineci, Brian K. Post, Madhu Chinthavali, Lonnie J. Love, and Scott Curran

Subjects

Engineering, Electricity generation, Computer-integrated manufacturing, business.industry, Integrated Computer-Aided Manufacturing, Process development execution system, Advanced manufacturing, Oak Ridge National Laboratory, business, Energy (signal processing), Energy storage, Manufacturing engineering

Abstract

Oak Ridge National Laboratory’s Additive Manufacturing Integrated Energy (AMIE) demonstration project leverages rapid innovation through additive manufacturing to connect a natural-gas-powered hybrid electric vehicle to a high-performance building designed to produce, consume, and store renewable energy. The AMIE demonstration project consists of a building and vehicle that were additively manufactured (3D-printed) using the laboratory’s big area additive manufacturing (BAAM) capabilities and an integrated energy system with smart controls that connects the two via wireless power transfer. The printed utility vehicle features a hybrid electric powertrain with onboard power generation from a natural gas fueled auxiliary power unit (APU). The APU extends vehicle range through a series hybrid powertrain configuration that recharges the vehicle’s lithium-ion energy storage system and acts as a mobile power generation system for the printed building. The development of the powertrain used for the printed range-extended electric vehicle was completed using a powertrain-in-the-loop development process and the vehicle prototype implementation was accelerated using BAAM. A flexible 3.2 kW solar photovoltaic system paired with electric vehicle batteries will provide renewable power generation and storage. Energy flows back and forth between the car and house using fast, efficient bidirectional wireless power transfer. The AMIE project marked the first demonstration of bidirectional level 2 charging through wireless power transfer. The accelerated creation and printing of the car and house will further demonstrate the program’s function as an applied science tool to get products to market more quickly than what currently is possible with traditional manufacturing. This paper presents a case study that summarizes the efforts and technical details for using the printed research platforms. This paper explores the focuses on printing of the vehicle, powertrain integration, and possibilities for vehicles providing power to buildings in different scenarios. The ability for BAAM to accelerate the prototype development for the integrated energy system process is explored. Details of how this was successfully accomplished in 9 months with more than 20 industry partners are discussed.

Published

2016

42. Analysis of Engine Air Handling Systems for Light-Duty Compression Ignition Engines Using 1-D Cycle Simulation: Achieving High Dilution Levels for Advanced Combustion

Author

Adam B. Dempsey, Nandini Gowda Kodebyle Raju, and Scott Curran

Subjects

Ignition system, Internal combustion engine, Carbureted compression ignition model engine, law, Homogeneous charge compression ignition, Internal combustion engine cooling, Environmental science, Diesel cycle, Engine knocking, Automotive engineering, Petrol engine, law.invention

Abstract

Previous research studies have shown that low temperature combustion (LTC) strategies are capable of achieving very low NOx and soot emissions while maintaining high thermal efficiency. To achieve LTC, there has to be sufficient mixing time between the fuel and air in a dilute, yet overall lean, environment. Dilution with a combination of fresh air and exhaust gas recirculation (EGR) is typically used to achieve longer mixing times and reduce the peak combustion temperatures. However, there are challenges associated with today’s engine air handling systems’ ability to move large combinations of EGR and air simultaneously. As the EGR demand is increased to reduce NOx emissions or retard combustion phasing, the global equivalence ratio tends to increase because of the boosting systems’ limited ability to supply fresh air. In this study, a one-dimensional engine modeling approach was used to analyze the behavior of a production light duty diesel engine equipped with a variable geometry turbocharger and a high-pressure loop EGR system under LTC conditions. The model is used to predict the global equivalence ratio as a function of the EGR level at a variety of operating conditions. The EGR level was varied from 0 to 50% at speeds ranging from 1,500 to 2,500 rpm and loads from 2 to 10 bar brake mean effective pressure. The objective of this study is to evaluate the air handling system’s capability of driving high amounts of EGR and air simultaneously for light duty engines to successfully achieve LTC operation over a large portion of the operating space. The results of the simulations show that at light loads, large amounts of EGR can be used while maintaining globally lean operation. However, as the engine load increases, a globally stoichiometric condition is reached relatively quickly, and high engine loads with greater than 30% EGR and overall lean conditions were achievable.

Published

2016

43. Myosin II controls junction fluctuations to guide epithelial tissue ordering

Author

Jasper Bathmann, Scott Curran, Guillaume Salbreux, Alexandre Kabla, Marc de Gennes, Charlotte Strandkvist, Buzz Baum, Kabla, Alexandre [0000-0002-0280-3531], and Apollo - University of Cambridge Repository

Subjects

junction fluctuations, vertex model, Cell division, Myosin, Morphogenesis, morphogenesis, Article, Epithelium, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Drosophila Proteins, neighbor exchange, 030304 developmental biology, Myosin Type II, 0303 health sciences, Chemistry, Dynamics (mechanics), epithelia, Actomyosin, Adherens Junctions, Cadherins, cadherin, Drosophila melanogaster, medicine.anatomical_structure, Order (biology), tissue refinement, tissue mechanics, Biophysics, Drosophila, Epithelial tissue, Gradual increase, 030217 neurology & neurosurgery

Abstract

Summary Under conditions of homeostasis, dynamic changes in the length of individual adherens junctions (AJs) provide epithelia with the fluidity required to maintain tissue integrity in the face of intrinsic and extrinsic forces. While the contribution of AJ remodeling to developmental morphogenesis has been intensively studied, less is known about AJ dynamics in other circumstances. Here, we study AJ dynamics in an epithelium that undergoes a gradual increase in packing order, without concomitant large-scale changes in tissue size or shape. We find that neighbor exchange events are driven by stochastic fluctuations in junction length, regulated in part by junctional actomyosin. In this context, the developmental increase of isotropic junctional actomyosin reduces the rate of neighbor exchange, contributing to tissue order. We propose a model in which the local variance in tension between junctions determines whether actomyosin-based forces will inhibit or drive the topological transitions that either refine or deform a tissue., Graphical Abstract, Highlights • Fluctuations in junction length cause neighbor exchange events without morphogenesis • The variance in junction tension determines how actomyosin influences T1 rates • Globally increasing junctional actomyosin levels inhibits neighbor exchange • A developmental increase in isotropic junction tension refines cellular packing, Curran et al. investigate adherens junction remodeling in the fly notum, where differences in actomyosin levels drive fluctuations in junction length and neighbor exchange, but not morphogenesis. A developmental increase in global junctional tension reduces, rather than drives, neighbor exchange to promote tissue ordering.

Published

2016

44. Big Area Additive Manufacturing and Hardware-in-the-Loop for Rapid Vehicle Powertrain Prototyping: A Case Study on the Development of a 3-D-Printed Shelby Cobra

Author

David Smith, Scott Curran, Ronald L. Graves, Randall F. Lind, Brian K. Post, Martin Keller, Paul Chambon, Lonnie J. Love, Johney B. Green, Steven Whitted, Craig A. Blue, and Robert M. Wagner

Subjects

Engineering, Powertrain, business.industry, Hardware-in-the-loop simulation, Cobra, 02 engineering and technology, 021001 nanoscience & nanotechnology, Automotive engineering, Manufacturing engineering, 020303 mechanical engineering & transports, Development (topology), 0203 mechanical engineering, 0210 nano-technology, business, computer, computer.programming_language

Published

2016

45. Summary of OEM Idling Recommendations from Vehicle Owner's Manuals

Author

Melissa Voss Lapsa, Scott Curran, and Kristy Keel-Blackmon

Subjects

Engineering, Aeronautics, business.industry, Advertising, Misinformation, Oak Ridge National Laboratory, business, Original equipment manufacturer, Variety (cybernetics)

Abstract

The project upon which this report is based was conceived in 2012 during discussions between the East Tennessee Clean Fuels Coalition (ETCleanFuels) and Oak Ridge National Laboratory (ORNL) who both noted that a detailed summary of idling recommendations for a wide variety of engines and vehicles were not available in the literature. The two organizations agreed that ETCleanFuels would develop a first-of-its-kind collection of idling recommendations from the owner’s manuals of modern production vehicles. Vehicle engine idling, a subject that has long been debated, is largely shrouded in misinformation. The justifications for idling seem to be many: driver comfort, waiting in lines, and talking on cell phones to name a few. Assuredly, a great number of people idle because of the myths and misinformation surrounding this issue. This report addresses these myths by turning to statements taken directly from the automobile and engine manufacturers themselves.

Published

2016

46. Volatility characterization of nanoparticles from single and dual-fuel low temperature combustion in compression ignition engines

Author

Vitaly Y. Prikhodko, William F. Northrop, John M. E. Storey, Glenn Lucachick, and Scott Curran

Subjects

Tandem, Chemistry, 020209 energy, Thermodynamics, Nanoparticle, 02 engineering and technology, Particulates, Pollution, Aerosol, Dilution, law.invention, Ignition system, Diesel fuel, law, 0202 electrical engineering, electronic engineering, information engineering, Environmental Chemistry, General Materials Science, Volatility (chemistry)

Abstract

This work explores the volatility of particles produced from two diesel low temperature combustion (LTC) modes proposed for high-efficiency compression ignition engines. It also explores mechanisms of particulate formation and growth upon dilution in the near-tailpipe environment. The number distribution of exhaust particles from low- and mid-load dual-fuel reactivity controlled compression ignition (RCCI) and single-fuel premixed charge compression ignition (PPCI) modes were experimentally studied over a gradient of dilution temperature. Particle volatility of select particle diameters was investigated using volatility tandem differential mobility analysis (V-TDMA). Evaporation rates for exhaust particles were compared with V-TDMA results for candidate pure n-alkanes to identify species with similar volatility characteristics. The results show that LTC particles are mostly comprised of material with volatility similar to engine oil alkanes. V-TDMA results were used as inputs to an aerosol condensation and evaporation model to support the finding that smaller particles in the distribution are comprised of lower volatility material than large particles under primary dilution conditions. Although our results show that saturation levels are high enough to drive condensation of alkanes onto existing particles under the dilution conditions investigated, they are not high enough to allow homogeneous nucleation of these same compounds in the primary exhaust plume. Therefore, we conclude that observed particles from LTC operation must grow from low concentrations of highly nonvolatile compounds present in the exhaust. Copyright © 2016 American Association for Aerosol Research

Published

2016

47. Reactivity controlled compression ignition combustion on a multi-cylinder light-duty diesel engine

Author

Robert M. Wagner, Reed Hanson, and Scott Curran

Subjects

Materials science, Mechanical Engineering, Homogeneous charge compression ignition, Aerospace Engineering, Ocean Engineering, Diesel cycle, Diesel engine, Automotive engineering, law.invention, Ignition system, Internal combustion engine, Carbureted compression ignition model engine, law, Automotive Engineering, Compression ratio, Octane rating

Abstract

Reactivity controlled compression ignition is a low-temperature combustion technique that has been shown, both in computational fluid dynamics modeling and single-cylinder experiments, to obtain diesel-like efficiency or better with ultra-low nitrogen oxide and soot emissions, while operating primarily on gasoline-like fuels. This paper investigates reactivity controlled compression ignition operation on a four-cylinder light-duty diesel engine with production-viable hardware using conventional gasoline and diesel fuel. Experimental results are presented over a wide speed and load range using a systematic approach for achieving successful steady-state reactivity controlled compression ignition combustion. The results demonstrated diesel-like efficiency or better over the operating range explored with low engine-out nitrogen oxide and soot emissions. A peak brake thermal efficiency of 39.0% was demonstrated for 2600 r/min and 6.9 bar brake mean effective pressure with nitrogen oxide emissions reduced by an order of magnitude compared to conventional diesel combustion operation. Reactivity controlled compression ignition emissions and efficiency results are compared to conventional diesel combustion operation on the same engine.

Published

2012

48. Piston Bowl Optimization for RCCI Combustion in a Light-Duty Multi-Cylinder Engine

Author

Reed Hanson, Sage L. Kokjohn, Derek A. Splitter, Robert M. Wagner, Rolf D. Reitz, and Scott Curran

Subjects

Engineering, Thermal efficiency, Engine configuration, business.industry, Mechanical engineering, General Medicine, Combustion, Automotive engineering, law.invention, Ignition system, Diesel fuel, Piston, law, Range (aeronautics), Gasoline, business

Abstract

Reactivity Controlled Compression Ignition (RCCI) is an engine combustion strategy that that produces low NO{sub x} and PM emissions with high thermal efficiency. Previous RCCI research has been investigated in single-cylinder heavy-duty engines. The current study investigates RCCI operation in a light-duty multi-cylinder engine at 3 operating points. These operating points were chosen to cover a range of conditions seen in the US EPA light-duty FTP test. The operating points were chosen by the Ad Hoc working group to simulate operation in the FTP test. The fueling strategy for the engine experiments consisted of in-cylinder fuel blending using port fuel-injection (PFI) of gasoline and early-cycle, direct-injection (DI) of diesel fuel. At these 3 points, the stock engine configuration is compared to operation with both the original equipment manufacturer (OEM) and custom machined pistons designed for RCCI operation. The pistons were designed with assistance from the KIVA 3V computational fluid dynamics (CFD) code. By using a genetic algorithm optimization, in conjunction with KIVA, the piston bowl profile was optimized for dedicated RCCI operation to reduce unburned fuel emissions and piston bowl surface area. By reducing these parameters, the thermal efficiency of the engine was improved while maintaining low NOx and PMmore » emissions. Results show that with the new piston bowl profile and an optimized injection schedule, RCCI brake thermal efficiency was increased from 37%, with the stock EURO IV configuration, to 40% at the 2,600 rev/min, 6.9 bar BMEP condition, and NOx and PM emissions targets were met without the need for exhaust after-treatment.« less

Published

2012

49. Emission Characteristics of a Diesel Engine Operating with In-Cylinder Gasoline and Diesel Fuel Blending

Author

Robert M. Wagner, Samuel A. Lewis, James E. Parks, John M. E. Storey, Scott Curran, Teresa L Barone, Kukwon Cho, and Vitaly Y. Prikhodko

Subjects

Diesel exhaust, Diesel particulate filter, Waste management, business.industry, Chemistry, Strategy and Management, Mechanical Engineering, Homogeneous charge compression ignition, Metals and Alloys, Analytical chemistry, Diesel engine, Industrial and Manufacturing Engineering, Diesel fuel, Carbureted compression ignition model engine, Octane rating, Exhaust gas recirculation, business

Abstract

Advanced combustion regimes such as homogeneous charge compression ignition (HCCI) and premixed charge compression ignition (PCCI) offer benefits of reduced nitrogen oxides (NOx) and particulate matter (PM) emissions. However, these combustion strategies often generate higher carbon monoxide (CO) and hydrocarbon (HC) emissions. In addition, aldehydes and ketone emissions can increase in these modes. In this study, the engine-out emissions of a compression-ignition engine operating in a fuel reactivity- controlled PCCI combustion mode using in-cylinder blending of gasoline and diesel fuel have been characterized. The work was performed on a 1.9-liter, 4-cylinder diesel engine outfitted with a port fuel injection system to deliver gasoline to the engine. The engine was operated at 2300 rpm and 4.2 bar brake mean effective pressure (BMEP) with the ratio of gasoline to diesel fuel that gave the highest engine efficiency and lowest emissions. Engine-out emissions for aldehydes, ketones and PM were compared with emissions from conventional diesel combustion. Sampling and analysis was carried out following micro-tunnel dilution of the exhaust. Particle geometric mean diameter, number-size distribution, and total number concentration were measured by a scanning mobility particle sizer (SMPS). For the particle mass measurements, samples were collected on Teflon-coated quartz-fiber filters and analyzed gravimetrically. Gaseousmore » aldehydes and ketones were sampled using dinitrophenylhydrazine-coated solid phase extraction cartridges and the extracts were analyzed by liquid chromatography/mass spectrometry (LC/MS). In addition, emissions after a diesel oxidation catalyst (DOC) were also measured to investigate the destruction of CO, HC and formaldehydes by the catalyst.« less

Published

2010

50. Effect of Premixed Fuel Preparation for Partially Premixed Combustion With a Low Octane Gasoline on a Light-Duty Multicylinder Compression Ignition Engine

Author

Robert M. Wagner, William C. Cannella, Scott Curran, and Adam B. Dempsey

Subjects

Engineering, Common rail, business.industry, Mechanical Engineering, Homogeneous charge compression ignition, Energy Engineering and Power Technology, Aerospace Engineering, Fuel pump, Diesel engine, Fuel injection, Automotive engineering, Brake specific fuel consumption, Fuel Technology, Nuclear Energy and Engineering, Internal combustion engine, Engine knocking, business

Abstract

Gasoline compression ignition (GCI) concepts with the majority of the fuel being introduced early in the cycle are known as partially premixed combustion (PPC). Previous research on single- and multicylinder engines has shown that PPC has the potential for high thermal efficiency with low NOx and soot emissions. A variety of fuel injection strategies have been proposed in the literature. These injection strategies aim to create a partially stratified charge to simultaneously reduce NOx and soot emissions while maintaining some level of control over the combustion process through the fuel delivery system. The impact of the direct injection (DI) strategy to create a premixed charge of fuel and air has not previously been explored, and its impact on engine efficiency and emissions is not well understood. This paper explores the effect of sweeping the direct injected pilot timing from −91 deg to −324 deg ATDC, which is just after the exhaust valve closes (EVCs) for the engine used in this study. During the sweep, the pilot injection consistently contained 65% of the total fuel (based on command duration ratio), and the main injection timing was adjusted slightly to maintain combustion phasing near top dead center. A modern four cylinder, 1.9 l diesel engine with a variable geometry turbocharger (VGT), high pressure common rail injection system, wide included angle injectors, and variable swirl actuations was used in this study. The pistons were modified to an open bowl configuration suitable for highly premixed combustion modes. The stock diesel injection system was unmodified, and the gasoline fuel was doped with a lubricity additive to protect the high pressure fuel pump and the injectors. The study was conducted at a fixed speed/load condition of 2000 rpm and 4.0 bar brake mean effective pressure (BMEP). The pilot injection timing sweep was conducted at different intake manifold pressures, swirl levels, and fuel injection pressures. The gasoline used in this study has relatively high fuel reactivity with a research octane number of 68. The results of this experimental campaign indicate that the highest brake thermal efficiency (BTE) and lowest emissions are achieved simultaneously with the earliest pilot injection timings (i.e., during the intake stroke).

Published

2015