Your search keyword '"Scott Curran"' showing total 6 results

1. 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

2. 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

3. 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

4. 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

5. 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

6. Well-to-wheel analysis of direct and indirect use of natural gas in passenger vehicles

Author

Johney B. Green, Ronald L. Graves, Martin Keller, Scott Curran, and Robert M. Wagner

Subjects

Engineering, Electric vehicles, Compressed natural gas, Industrial and Manufacturing Engineering, Automotive engineering, Miles per gallon gasoline equivalent, Computer Science::Robotics, Natural gas vehicles, Energy(all), Natural gas, Electrical and Electronic Engineering, Astrophysics::Galaxy Astrophysics, Civil and Structural Engineering, Natural gas prices, Petroleum engineering, business.industry, Mechanical Engineering, Natural gas vehicle, WTW (well-to-wheels), Building and Construction, Green vehicle, Pollution, Renewable natural gas, General Energy, Carbon-neutral fuel, business

Abstract

The abundance of natural gas in the United States because of the number of existing natural gas reserves and the recent advances in extracting unconventional reserves has been one of the main drivers for low natural gas prices. A question arises of what is the optimal use of natural gas as a transportation fuel. Is it more efficient to use natural gas in a stationary power application to generate electricity to charge electric vehicles, compress natural gas for onboard combustion in vehicles, or re-form natural gas into a denser transportation fuel? This study investigates the well-to-wheels energy use and greenhouse gas emissions from various natural gas to transportation fuel pathways and compares the results to conventional gasoline vehicles and electric vehicles using the US electrical generation mix. Specifically, natural gas vehicles running on compressed natural gas are compared against electric vehicles charged with electricity produced solely from natural gas combustion in stationary power plants. The results of the study show that the dependency on the combustion efficiency of natural gas in stationary power can outweigh the inherent efficiency of electric vehicles, thus highlighting the importance of examining energy use on a well-to-wheels basis.