Progress and recent trends in 48 V hybridisation and e-boosting technology on passenger vehicles – a review

Hu, Bo; Chen, Chunlin; Zhan, Zhangsong; Su, Xueying; Hu, T; Zheng, Guangyong; Yang, Zhiyong

doi:10.1177/0954407017729950

Cited by 8 publications

(6 citation statements)

References 26 publications

(52 reference statements)

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“…However, despite being built upon an existing vehicle topology, the development of the configuration is not without its challenges. Firstly, the power demands in the commercial sector are significantly higher than those encountered in the wider automotive sector, in which 48V architecture has become popular for many of the emerging mild-hybrid and hybrid configurations [6]. There are several configurations, categorised by the location of the MGU in the powertrain, that can be adopted, ranging from P0 which incorporates a belt driven starter and generator through to P4 with the MGU located on the drive axle.…”

Section: Background To Hybridisation In the Bus Industrymentioning

confidence: 99%

“…There are several configurations, categorised by the location of the MGU in the powertrain, that can be adopted, ranging from P0 which incorporates a belt driven starter and generator through to P4 with the MGU located on the drive axle. During development of the current vehicle architecture, an initial P0/P1 style hybrid with an engine mounted MGU on a 48V system was considered, as this is the most straightforward configuration to implement and is one of the most popular configurations for emerging vehicles [6]. However, for this particular powertrain, it was found to have limited fuel consumption reduction benefits when balanced against the increased cost of the vehicle with the new electrified components.…”

Section: Background To Hybridisation In the Bus Industrymentioning

confidence: 99%

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Modelling and Control of a Hybrid Urban Bus

Murtagh¹,

Early²,

Stevens³

et al. 2019

SAE Technical Paper Series

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Section: Background To Hybridisation In the Bus Industrymentioning

confidence: 99%

Section: Background To Hybridisation In the Bus Industrymentioning

confidence: 99%

Modelling and Control of a Hybrid Urban Bus

Murtagh¹,

Early²,

Stevens³

et al. 2019

SAE Technical Paper Series

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“…7,8 The fuel economy, performance, and cost of hybrid electric vehicles are significantly influenced by the powertrain architectures. Based on the location of the electric machine within the powertrain or driveline, the hybrid powertrains architectures can be categorized into five groups as P0, P1, P2, P3, and P4, 9 as shown in the Figure 1. The P0 architecture is mainly for engine start/stop function (engine idle elimination) while utilizing 12 V Starter-lighting-Ignition (SLI) battery.…”

Section: Introductionmentioning

confidence: 99%

“…However, a higher torque electric machine is necessary in P3 and P4 architectures to enable pure electric drive since the torque from the electric machine is not amplified by the transmission. 3,7,9,20…”

Section: Introductionmentioning

confidence: 99%

Fuel economy improvement and emission reduction of 48 V mild hybrid electric vehicles with P0, P1, and P2 architectures with lithium battery cell experimental data

Liu

Liao

Lai

2021

Advances in Mechanical Engineering

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This paper intends to provide design selections of hybrid powertrain architectures in 48 V mild hybrid electric vehicles. Based on the location of the electric machine in the driveline, the hybrid powertrain architectures can be categorized into five groups, P0, P1, P2, P3, and P4. This paper uses simulation software to investigate the fuel economy improvements and emission reduction of 48 V mild hybrid electric vehicles with P0, P1, and P2 architectures. A baseline conventional and a 12 V start/stop vehicle models based on the production vehicle are built for comparison. The 48 V battery pack model is based on experimental data including open-circuit voltage and internal resistance of a 20 Ah lithium polymer battery cell. Four standard driving cycles are used to assess the fuel economy and emissions of the vehicle models. With features of engine idle elimination, electric power assist, and regenerative braking, the 48 V P0 and P1 respectively gains average 13.5% and 15.5% simulated fuel economy compared to baseline vehicle. The 48 V P2 enables feature of electric launch/driving and improves the fuel economy by average 18.5% better than baseline vehicle. The 48 V mild hybrid system seems to be one of the promising techniques to meet future fuel economy standards and emission regulations.

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“…For more than a decade, engine boosting has seen widespread adoption by passenger and heavy goods vehicle powertrains in order to increase the specific power and enable the downsizing megatrend [2]. However, many challenges still remain, as the regulation requirements become stricter, and the demand for low-carbon powertrains increases [3]. Currently, the growing expectations of vehicle performance, including an excellent transient response with high boost levels, have converged within the demand for increased downsizing and higher levels of EGR.…”

Section: Introductionmentioning

confidence: 99%

A Hybrid End-to-End Control Strategy Combining Dueling Deep Q-network and PID for Transient Boost Control of a Diesel Engine with Variable Geometry Turbocharger and Cooled EGR

et al. 2019

Energies

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Deep reinforcement learning (DRL), which excels at solving a wide variety of Atari and board games, is an area of machine learning that combines the deep learning approach and reinforcement learning (RL). However, to the authors’ best knowledge, there seem to be few studies that apply the latest DRL algorithms on real-world powertrain control problems. If there are any, the requirement of classical model-free DRL algorithms typically for a large number of random exploration in order to realize good control performance makes it almost impossible to implement directly on a real plant. Unlike most of the other DRL studies, whose control strategies can only be trained in a simulation environment—especially when a control strategy has to be learned from scratch—in this study, a hybrid end-to-end control strategy combining one of the latest DRL approaches—i.e., a dueling deep Q-network and traditional Proportion Integration Differentiation (PID) controller—is built, assuming no fidelity simulation model exists. Taking the boost control of a diesel engine with a variable geometry turbocharger (VGT) and cooled (exhaust gas recirculation) EGR as an example, under the common driving cycle, the integral absolute error (IAE) values with the proposed algorithm are improved by 20.66% and 9.7% respectively for the control performance and generality index, compared with a fine-tuned PID benchmark. In addition, the proposed method can also improve system adaptiveness by adding another redundant control module. This makes it attractive to real plant control problems whose simulation models do not exist, and whose environment may change over time.

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Progress and recent trends in 48 V hybridisation and e-boosting technology on passenger vehicles – a review

Cited by 8 publications

References 26 publications

Modelling and Control of a Hybrid Urban Bus

Modelling and Control of a Hybrid Urban Bus

Fuel economy improvement and emission reduction of 48 V mild hybrid electric vehicles with P0, P1, and P2 architectures with lithium battery cell experimental data

A Hybrid End-to-End Control Strategy Combining Dueling Deep Q-network and PID for Transient Boost Control of a Diesel Engine with Variable Geometry Turbocharger and Cooled EGR

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