Systematic Development of Highly Efficient and Clean Engines to Meet Future Commercial Vehicle Greenhouse Gas Regulations

Stanton, Donald W.

doi:10.4271/2013-01-2421

Cited by 134 publications

(108 citation statements)

References 21 publications

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“…Open cycle efficiency (OCE) captures the efficiency of the gas exchange process, closed cycle efficiency (CCE) represents the effectiveness of combustion and mechanical efficiency (ME) captures frictional and accessory losses (Stanton, 2013). The three efficiencies contribute to the brake thermal efficiency (BTE) as shown in equation (1) (for more information see Stanton et al (2013)).…”

Section: Efficiency Analysismentioning

confidence: 99%

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

et al. 2017

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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.

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Section: Efficiency Analysismentioning

confidence: 99%

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

et al. 2017

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“…1a). In the continued work, the ORC system was packaged on a truck employing low rates of EGR and high efficiency Selective Catalytic Reduction (SCR) system [11]. The system delivered 4.5-6% fuel efficiency improvements, the turbine output power was mechanical to the crankshaft through a gearbox and the condenser was a direct air cooled condenser at the front of the engine cooling module.…”

Section: Review -Refrigerantsmentioning

confidence: 99%

“…Experimental results with efficiencies approaching 80% with scroll expander by Wang et al [8], 70% with screw expander by Zhang et al [9] and 65% with piston expander by Seher et al [10] have been presented. Furthermore, the trucking sector is integrating prototypes to address issues relating to durability, packaging and controls [11]. ORCs were the most demonstrated technology in the 5-15 kW range, offering thermal efficiencies around 8-12% and a potential of 4-6% reduction in fuel consumption.…”

Section: Introductionmentioning

confidence: 99%

Organic Rankine cycle – review and research directions in engine applications

Panesar

2017

E3S Web Conf.

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Abstract. Waste heat to power conversion using Organic Rankine Cycles (ORC) is expected to play an important role in CO2 reductions from diesel engines. Firstly, a review of automotive ORCs is presented focusing on the pure working fluids, thermal architectures and expanders. The discussion includes, but is not limited to: R245fa, ethanol and water as fluids; series, parallel and cascade as architectures; dry saturated, superheated and supercritical as expansion conditions; and scroll, radial turbine and piston as expansion machines. Secondly, research direction in versatile expander and holistic architecture (NOx + CO2) are proposed. Benefits of using the proposed unconventional approaches are quantified using Ricardo Wave and Aspen HYSYS for diesel engine and ORC modelling. Results indicate that, the implementation of versatile piston expander tolerant to two-phase and using cyclopentane can potentially increase the highway drive cycle power by 8%. Furthermore, holistic architecture offering complete utilisation of charge air and exhaust recirculation heat increased the performance noticeably to 5% of engine power at the design point condition.

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“…waste heat recovery) and use of 38 alternative fuels (e.g. biodiesel) [2,3]. The HDDE is expected to remain the prime mover of choice for long-haul trucks…”

mentioning

confidence: 99%

“…The selected engine 97 platform utilised a high efficiency Selective Catalytic Reduction (SCR) system as the only means to meet the Euro 6 98 oxides of nitrogen level. With a steadily increasing SCR efficiency, it is expected that exhaust gas recirculation may be 99 phased-out by the end of the decade [3]. This will additionally offer marginal improvements in the base engine 100 efficiency, and reduction in carbon deposits and engine wear [22,23].…”

mentioning

confidence: 99%

An innovative Organic Rankine Cycle system for integrated cooling and heat recovery

Panesar

2017

Applied Energy

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6Converting a portion of the waste heat into usable power by implementing Rankine and Organic Rankine Cycles 7 (ORC) on long-haul trucks is seen as a potential way to improve the overall system efficiency. To identify 8 techno-economical heat sources across the drive cycle of a Heavy Duty Diesel Engine (HDDE), an energy and exergy 9 analysis was performed on all the available heat streams. As a result, to recover the combined exhaust gases and 10 coolant heat, a reference cascade system was analysed. Owing to the nature of this application, a size vs. 11performance optimisation was performed for the cascade system utilising water and R245fa fluid combination. Despite 12 a 1.8% Brake Thermal Efficiency (BTE) improvement, the key consideration in the research and development efforts 19HYSYS V8 showed that, compared to the reference cascade system, the proposed dual-pressure system has the 20 potential to deliver an average of 20% improvement in the system power, a 50% reduction in the total heat exchanger 21 footprint, and a reduced system complexity. These advantages bode well for an integrated and relatively compact

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Systematic Development of Highly Efficient and Clean Engines to Meet Future Commercial Vehicle Greenhouse Gas Regulations

Cited by 134 publications

References 21 publications

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

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

Organic Rankine cycle – review and research directions in engine applications

An innovative Organic Rankine Cycle system for integrated cooling and heat recovery

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