Your search keyword '"Dheeraj B"' showing total 10 results

1. Exhaust valve profile modulation for improved diesel engine curb idle aftertreatment thermal management

Author

Dheeraj B Gosala, Mrunal C Joshi, James McCarthy, Lisa Farrell, and Gregory M. Shaver

Subjects

Idle, Exhaust manifold, Modulation, Exhaust valve, Mechanical Engineering, Automotive Engineering, Fuel efficiency, Aerospace Engineering, Environmental science, Ocean Engineering, Thermal management of electronic devices and systems, Diesel engine, Automotive engineering

Abstract

Rapid warm-up of a diesel engine aftertreatment system (ATS) is a challenge at low loads. Modulating exhaust manifold pressure (EMP) to increase engine pumping work, fuel consumption, and as a result, engine-outlet temperature, is a commonly used technique for ATS thermal management at low loads. This paper introduces exhaust valve profile modulation as a technique to increase engine-outlet temperature for ATS thermal management, without requiring modulation of exhaust manifold pressure. Experimental steady state results at 800 RPM/1.3 bar BMEP (curb idle) demonstrate that early exhaust valve opening with negative valve overlap (EEVO+NVO) can achieve engine-outlet temperature in excess of 255°C with 5.7% lower fuel consumption, 12% lower engine out NOx and 20% lower engine-out soot than the conventional thermal management strategy. Late exhaust valve opening with internal EGR via reinduction (LEVO+Reinduction) resulted in engine-outlet temperature in excess of 280°C, while meeting emission constraints at no fuel consumption penalty. This work also demonstrates that LEVO in conjunction with modulation of exhaust manifold pressure results in engine-outlet temperature in excess of 340°C while satisfying desired emission constraints. Aggressive use of LEVO can result in engine-outlet temperatures of 460°C, capable of active regeneration of DPF at curb idle, without the significant increase in engine-out soot emissions seen in previously studied strategies.

Published

2021

2. Fuel-efficient thermal management in diesel engines via valvetrain-enabled cylinder ventilation strategies

Author

Timothy P. Lutz, James McCarthy, Gregory M. Shaver, and Dheeraj B Gosala

Subjects

Mechanical Engineering, Aerospace Engineering, Ocean Engineering, Thermal management of electronic devices and systems, Diesel engine, Automotive engineering, Cylinder (engine), law.invention, Valvetrain, Diesel fuel, law, Automotive Engineering, Ventilation (architecture), Fuel efficiency, Environmental science

Abstract

Modern diesel engine aftertreatment systems require elevated temperatures for effective reduction of engine-out emissions. Maintaining elevated aftertreatment temperatures in a fuel-efficient manner is a challenge, especially at low-load engine operation where engine-outlet temperatures are low; therefore, higher engine-outlet temperatures are typically achieved via increased fuel consumption. Previous studies have demonstrated that strategies such as cylinder deactivation (method where there is neither valve motion nor fuel injection in a subset of cylinders, thereby isolating the deactivated cylinders from the gas exchange process) and cylinder cutout (method where there is no fuel injection in a subset of cylinders, implemented with high recirculated gas rates) reduce fuel consumption while elevating engine-outlet temperatures, by reducing the overall airflow through the engine. This article introduces and characterizes “non-fired cylinder ventilation” as alternate means to achieve fuel-efficient aftertreatment thermal management, by reduction of overall airflow through the engine. Fuel injection is deactivated from a subset of cylinders during non-fired cylinder ventilation, and the non-firing cylinders participate in the gas exchange process with the same manifold at a time, thereby reducing the intake-to-exhaust manifold gas exchange through the cylinders. It is demonstrated that non-fired cylinder ventilation shows similar fuel efficiency and thermal management as cylinder deactivation when the valves of the non-firing ventilated cylinders are open by at least 4 mm, due to similar, negligible, gas-exchange losses, while non-fired cylinder ventilation with lower valve lifts enables elevated engine-outlet temperatures with relatively higher fuel consumption than cylinder deactivation. Non-fired cylinder ventilation strategies demonstrate 75 °C higher temperatures at fuel-neutral conditions, and up to 35% fuel savings at similar temperatures, compared to six-cylinder operation.

Published

2019

3. Experimental assessment of diesel engine cylinder deactivation performance during low-load transient operations

Author

Mrunal C Joshi, Dheeraj B Gosala, Cody M Allen, Lisa Farrell, Gregory M. Shaver, and James McCarthy

Subjects

Mechanical Engineering, Aerospace Engineering, Ocean Engineering, Thermal management of electronic devices and systems, Diesel engine, Automotive engineering, Cylinder (engine), law.invention, Diesel fuel, law, Automotive Engineering, Fuel efficiency, Environmental science, Low load, Transient (oscillation)

Abstract

Fuel-efficient aftertreatment thermal management in modern diesel engines is a difficult challenge, especially during low-load operation. This study explores the performance of cylinder deactivation in a diesel engine during low-load operation following highway cruise through experimental evaluation of two drive cycles, specifically extended idle and repeated heavy heavy-duty diesel truck creep cycles. Cylinder deactivation operations are shown to maintain comparable aftertreatment thermal management performance to conventional thermal management operation while reducing fuel up to 40% during extended idle operation. This fuel efficiency improvement coincides with engine-out emission reductions of 72% for soot and 52% for NOx. Cylinder deactivation also shows improved thermal management compared to a more fuel-efficient conventional operation.

Published

2019

4. Reverse breathing in diesel engines for aftertreatment thermal management

Author

Troy E Odstrcil, Aswin K Ramesh, Soumya Nayyar, James McCarthy, Dheeraj B Gosala, Gregory M. Shaver, and Edward Koeberlein

Subjects

020209 energy, Mechanical Engineering, Aerospace Engineering, Ocean Engineering, 02 engineering and technology, Thermal management of electronic devices and systems, Automotive engineering, Diesel fuel, Idle, 020303 mechanical engineering & transports, 0203 mechanical engineering, Component (UML), Automotive Engineering, 0202 electrical engineering, electronic engineering, information engineering, Breathing, Fuel efficiency, Environmental science

Abstract

Approximately 40% of typical heavy-duty vehicle operation occurs at loaded idle during which time conventional diesel engines are unable to maintain aftertreatment component temperatures in a fuel-efficient manner. Fuel economy and thermal management at this condition can be improved via reverse breathing, a novel method in which exhaust gases are recirculated, as needed, from exhaust to intake manifold via one or more cylinders. Resultant airflow reductions increase exhaust gas temperatures and decrease exhaust flow rates, both of which are beneficial for maintaining desirable aftertreatment component temperatures while consuming less fuel via reduced pumping work. Several strategies for implementation of reverse breathing are described in detail and are compared to cylinder deactivation and internal exhaust gas recirculation operation. Experimental data demonstrate 26% fuel consumption savings compared to conventional stay-warm operation, 60 °C improvement in turbine outlet temperature and 28% reduction in exhaust flow compared to conventional best fuel consumption operation at the loaded idle condition (800 r/min, 1.3 bar brake mean effective pressure). The incorporation of reverse breathing to more efficiently maintain desired aftertreatment temperatures during idle conditions is experimentally demonstrated to result in fuel savings of 2% over the heavy-duty federal test procedure drive cycle compared with conventional operation.

Published

2018

5. Utilizing low airflow strategies, including cylinder deactivation, to improve fuel efficiency and aftertreatment thermal management

Author

Soumya Nayyar, James McCarthy, Doug Nielsen, Cody M Allen, Dina M Caicedo Parra, Aswin K Ramesh, Dheeraj B Gosala, Edward Koeberlein, and Gregory M. Shaver

Subjects

Bar (music), 020209 energy, Mechanical Engineering, Airflow, Aerospace Engineering, Ocean Engineering, 02 engineering and technology, Thermal management of electronic devices and systems, Automotive engineering, Cylinder (engine), law.invention, 020303 mechanical engineering & transports, 0203 mechanical engineering, Mean effective pressure, law, Automotive Engineering, 0202 electrical engineering, electronic engineering, information engineering, Fuel efficiency, Environmental science

Abstract

Approximately 30% of the fuel consumed during typical heavy-duty vehicle operation occurs at elevated speeds with low-to-moderate loads below 6.5 bar brake mean effective pressure. The fuel economy and aftertreatment thermal management of the engine at these conditions can be improved using conventional means as well as cylinder deactivation and intake valve closure modulation. Airflow reductions result in higher exhaust gas temperatures, which are beneficial for aftertreatment thermal management, and reduced pumping work, which improves fuel efficiency. Airflow reductions can be achieved through a reduction of displaced cylinder volume by using cylinder deactivation and through reduction of volumetric efficiency by using intake valve closure modulation. This paper shows that, depending on load, cylinder deactivation and intake valve closure modulation can be used to reduce the fuel consumption between 5% and 25%, increase the rate of warm-up of aftertreatment, maintain higher temperatures, or achieve active diesel particulate filter regeneration without requiring dosing of the diesel oxidation catalyst.

Published

2017

6. Diesel Engine Cylinder Deactivation for Improved System Performance over Transient Real-World Drive Cycles

Author

Gregory M. Shaver, Kalen R Vos, Alexander H Taylor, James McCarthy, Edward Koeberlein, Aswin K Ramesh, Dheeraj B Gosala, Matthew VanVoorhis, Cody M Allen, Lisa Farrell, Mrunal C Joshi, and Sirish Srinivasan

Subjects

020209 energy, 02 engineering and technology, Diesel engine, Fuel injection, Automotive engineering, Cylinder (engine), law.invention, 020303 mechanical engineering & transports, 0203 mechanical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, Fuel efficiency, Environmental science, Transient (oscillation), Nitrogen oxides, Turbocharger

Published

2018

7. Reducing Diesel Engine Drive Cycle Fuel Consumption through Use of Cylinder Deactivation to Maintain Aftertreatment Component Temperature during Idle and Low Load Operating Conditions

Author

Dheeraj B Gosala, Alexander H Taylor, Gregory M. Shaver, Mrunal C Joshi, Matthew Van Voorhis, Kalen R Vos, Cody M Allen, Edward Koeberlein, Lisa Farrell, James McCarthy, and Dale Arden Stretch

Subjects

cylinder deactivation, Engineering, lcsh:Mechanical engineering and machinery, 020209 energy, 02 engineering and technology, Diesel engine, Industrial and Manufacturing Engineering, Automotive engineering, Idle, 0203 mechanical engineering, 0202 electrical engineering, electronic engineering, information engineering, lcsh:TJ1-1570, thermal management, General Materials Science, Exhaust gas recirculation, NOx, business.industry, Mechanical Engineering, Fuel injection, fuel economy, Computer Science Applications, 020303 mechanical engineering & transports, Fuel efficiency, business, HD-FTP, Driving cycle, diesel engine, Turbocharger

Abstract

Modern on-road diesel engine systems incorporate flexible fuel injection, variable geometry turbocharging, high pressure exhaust gas recirculation, oxidation catalysts, particulate filters, and selective catalytic reduction systems in order to comply with strict tailpipe-out NOx and soot limits. Fuel consuming strategies, including late injections and turbine-based engine exhaust throttling, are typically used to increase turbine-outlet temperature and flow rate in order to reach the aftertreatment component temperatures required for efficient reduction of NOx and soot. The same strategies are used at low load operating conditions to maintain aftertreatment temperatures. This paper demonstrates that cylinder deactivation (CDA) can be used to maintain aftertreatment temperatures in a more fuel-efficient manner through reductions in airflow and pumping work. The incorporation of CDA to maintain desired aftertreatment temperatures during idle conditions is experimentally demonstrated to result in fuel savings of 3.0% over the HD-FTP drive cycle. Implementation of CDA at non-idle portions of the HD-FTP where BMEP is below 3 bar is demonstrated to reduce fuel consumption further by an additional 0.4%, thereby resulting in 3.4% fuel savings over the drive cycle.

Published

2017

8. Fuel-efficient thermal management in diesel engines via valvetrain-enabled cylinder ventilation strategies.

Author

Gosala, Dheeraj B., Shaver, Gregory M., McCarthy Jr., James E., and Lutz, Timothy P.

Abstract

Modern diesel engine aftertreatment systems require elevated temperatures for effective reduction of engine-out emissions. Maintaining elevated aftertreatment temperatures in a fuel-efficient manner is a challenge, especially at low-load engine operation where engine-outlet temperatures are low; therefore, higher engine-outlet temperatures are typically achieved via increased fuel consumption. Previous studies have demonstrated that strategies such as cylinder deactivation (method where there is neither valve motion nor fuel injection in a subset of cylinders, thereby isolating the deactivated cylinders from the gas exchange process) and cylinder cutout (method where there is no fuel injection in a subset of cylinders, implemented with high recirculated gas rates) reduce fuel consumption while elevating engine-outlet temperatures, by reducing the overall airflow through the engine. This article introduces and characterizes ‘‘non-fired cylinder ventilation’’ as alternate means to achieve fuel-efficient aftertreatment thermal management, by reduction of overall airflow through the engine. Fuel injection is deactivated from a subset of cylinders during non-fired cylinder ventilation, and the non-firing cylinders participate in the gas exchange process with the same manifold at a time, thereby reducing the intake-to-exhaust manifold gas exchange through the cylinders. It is demonstrated that non-fired cylinder ventilation shows similar fuel efficiency and thermal management as cylinder deactivation when the valves of the non-firing ventilated cylinders are open by at least 4 mm, due to similar, negligible, gas-exchange losses, while non-fired cylinder ventilation with lower valve lifts enables elevated engine-outlet temperatures with relatively higher fuel consumption than cylinder deactivation. Non-fired cylinder ventilation strategies demonstrate 75 °C higher temperatures at fuel-neutral conditions, and up to 35% fuel savings at similar temperatures, compared to six-cylinder operation. [ABSTRACT FROM AUTHOR]

Published

2021

9. Reverse breathing in diesel engines for aftertreatment thermal management.

Author

Ramesh, Aswin K, Odstrcil, Troy E, Gosala, Dheeraj B, Shaver, Gregory M, Nayyar, Soumya, Koeberlein, Edward, and McCarthy, James

Abstract

Approximately 40% of typical heavy-duty vehicle operation occurs at loaded idle during which time conventional diesel engines are unable to maintain aftertreatment component temperatures in a fuel-efficient manner. Fuel economy and thermal management at this condition can be improved via reverse breathing, a novel method in which exhaust gases are recirculated, as needed, from exhaust to intake manifold via one or more cylinders. Resultant airflow reductions increase exhaust gas temperatures and decrease exhaust flow rates, both of which are beneficial for maintaining desirable aftertreatment component temperatures while consuming less fuel via reduced pumping work. Several strategies for implementation of reverse breathing are described in detail and are compared to cylinder deactivation and internal exhaust gas recirculation operation. Experimental data demonstrate 26% fuel consumption savings compared to conventional stay-warm operation, 60 °C improvement in turbine outlet temperature and 28% reduction in exhaust flow compared to conventional best fuel consumption operation at the loaded idle condition (800 r/min, 1.3 bar brake mean effective pressure). The incorporation of reverse breathing to more efficiently maintain desired aftertreatment temperatures during idle conditions is experimentally demonstrated to result in fuel savings of 2% over the heavy-duty federal test procedure drive cycle compared with conventional operation. [ABSTRACT FROM AUTHOR]

Published

2019

10. Utilizing low airflow strategies, including cylinder deactivation, to improve fuel efficiency and aftertreatment thermal management.

Author

Ramesh, Aswin K., Shaver, Gregory M., Allen, Cody M., Nayyar, Soumya, Gosala, Dheeraj B., Parra, Dina Caicedo, Koeberlein, Edward, McCarthy, James, and Nielsen, Doug

Abstract

Approximately 30% of the fuel consumed during typical heavy-duty vehicle operation occurs at elevated speeds with low-to-moderate loads below 6.5 bar brake mean effective pressure. The fuel economy and aftertreatment thermal management of the engine at these conditions can be improved using conventional means as well as cylinder deactivation and intake valve closure modulation. Airflow reductions result in higher exhaust gas temperatures, which are beneficial for aftertreatment thermal management, and reduced pumping work, which improves fuel efficiency. Airflow reductions can be achieved through a reduction of displaced cylinder volume by using cylinder deactivation and through reduction of volumetric efficiency by using intake valve closure modulation. This paper shows that, depending on load, cylinder deactivation and intake valve closure modulation can be used to reduce the fuel consumption between 5% and 25%, increase the rate of warm-up of aftertreatment, maintain higher temperatures, or achieve active diesel particulate filter regeneration without requiring dosing of the diesel oxidation catalyst. [ABSTRACT FROM AUTHOR]

Published

2017