Optimization and Evaluation of a Low Temperature Waste Heat Recovery System for a Heavy Duty Engine over a Transient Cycle

Singh, Vikram; Rijpkema, Jelmer Johannes; Li, Xiufei; Munch, Karin; Verhelst, Sebastian

doi:10.4271/2020-01-2033

Cited by 4 publications

(2 citation statements)

References 23 publications

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“…Traditional engine design and optimization processes mainly address a single research topic: the estimation of the in-cylinder heat release rate [3], the increase of thermal efficiency by means of renewable fuels [4], or a specific waste heat recovery system [5]. The model proposed in this study represents a significant advancement in this respect, mainly because of its comprehensive representation of the internal combustion engine across the entire operating cycle.…”

Section: Introductionmentioning

confidence: 99%

Development and Validation of a Novel Zero-Dimensional Heat Rejection Model for High-Efficiency Engines

Furia,

Ravaglioli,

Cerofolini

et al. 2024

Energies

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In recent years, the trend towards the performance maximization of modern internal combustion engines has led to the creation of accurate simulation models to optimize the engine design and operating conditions. Temperature management is crucial to achieve the performance goals of an internal combustion engine without affecting the component’s reliability. Formula 1 mandates that only a limited number of experimental tests can be performed, which leads to the necessity of simulators capable of substituting empirical tests. Furthermore, the requirement of adapting the vehicle setup before each race weekend to maximize the performance on each circuit layout necessitates short computational time. To address this, the development of a zero-dimensional model of the thermal flows within an engine is presented in this paper. This model allows to precisely compute the dynamic variations of all the heat flows inside the combustion engine, excluding only the radiative ones and the engine components’ temperatures. The new simulation approach has been developed and validated on a Formula 1 engine and shown to be precise and fast. The results demonstrate the value of the proposed model with an average engine fluid temperature error of less than 1 °C for a computational cost comparable with on-board applications.

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Section: Introductionmentioning

confidence: 99%

Development and Validation of a Novel Zero-Dimensional Heat Rejection Model for High-Efficiency Engines

Furia,

Ravaglioli,

Cerofolini

et al. 2024

Energies

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“…Sustainability 2024, 16,1924 44 of 74 performance, and experimental demonstrations of performance and control, accompanied by full cost reporting. Singh et al [226] detail the use of a dual-loop Rankine cycle for WHR from a large Scania D13 engine. The authors consider 10 working fluids (acetone, cyclopentane, DME, ethanol, methanol, MM, Novec 649, R1233zd(E), R1234ze(Z), and water) for the separate loops, one recovering coolant heat and the other recovering exhaust heat.…”

mentioning

confidence: 99%

Review of Organic Rankine Cycles for Internal Combustion Engine Waste Heat Recovery: Latest Decade in Review

Sprouse

2024

Sustainability

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The last decade (2013–2023) was the most prolific period of organic Rankine cycle (ORC) research in history in terms of both publications and citations. This article provides a detailed review of the broad and voluminous collection of recent internal combustion engine (ICE) waste heat recovery (WHR) studies, serving as a necessary follow-on to the author’s 2013 review. Research efforts have targeted diverse applications (e.g., vehicular, stationary, and building-based), and it spans the full gamut of engine sizes and fuels. Furthermore, cycle configurations extend far beyond basic ORC and regenerative ORC, particularly with supercritical, trilateral, and multi-loop ORCs. Significant attention has been garnered by fourth-generation refrigerants like HFOs (hydrofluoroolefins), HFEs (hydrofluoroethers), natural refrigerants, and zeotropic mixtures, as research has migrated away from the popular HFC-245fa (hydrofluorocarbon). Performance-wise, the period was marked by a growing recognition of the diminished performance of physical systems under dynamic source conditions, especially compared to steady-state simulations. Through advancements in system control, especially using improved model predictive controllers, dynamics-based losses have been significantly reduced. Regarding practically minded investigations, research efforts have ameliorated working fluid flammability risks, limited thermal degradation, and pursued cost savings. State-of-the-art system designs and operational targets have emerged through increasingly sophisticated optimization efforts, with some studies leveraging “big data” and artificial intelligence. Major programs like SuperTruck II have further established the ongoing challenges of simultaneously meeting cost, size, and performance goals; however, off-the-shelf organic Rankine cycle systems are available today for engine waste heat recovery, signaling initial market penetration. Continuing forward, next-generation engines can be designed specifically as topping cycles for an organic Rankine (bottoming) cycle, with both power sources integrated into advanced hybrid drivetrains.

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Evaluating the thermodynamic potential for carbon capture from internal combustion engines

Voice¹,

Hamad²

2022

Transportation Engineering

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Optimization and Evaluation of a Low Temperature Waste Heat Recovery System for a Heavy Duty Engine over a Transient Cycle

Cited by 4 publications

References 23 publications

Development and Validation of a Novel Zero-Dimensional Heat Rejection Model for High-Efficiency Engines

Development and Validation of a Novel Zero-Dimensional Heat Rejection Model for High-Efficiency Engines

Review of Organic Rankine Cycles for Internal Combustion Engine Waste Heat Recovery: Latest Decade in Review

Evaluating the thermodynamic potential for carbon capture from internal combustion engines

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