Estimate e-Golf Battery State Using Diagnostic Data and a Digital Twin

Merkle, Lukas; Pöthig, Michael; Schmid, Florian

doi:10.3390/batteries7010015

Cited by 43 publications

(21 citation statements)

References 23 publications

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“…The authors of [6] mention that the key benefits from DTs are "increased productivity, reduced complexity, time savings, reduced cost, improved quality". The authors also mention that DTs can be used to develop and optimize new and existing products [6] by generating information that is not readily available in the real environment [69]. In this sense, once the physical counterpart exists, there are different configurations of DTs in the automotive industry, such as the following (each configuration will have an impact on different stages of a vehicle's lifecycle from its conceptual design, to the system engineering design, manufacturing, testing, performance and its end of life).…”

Section: Automotivementioning

confidence: 99%

Digital Twin Technology Challenges and Applications: A Comprehensive Review

et al. 2022

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A digital twin is a virtual representation of a physical object or process capable of collecting information from the real environment to represent, validate and simulate the physical twin’s present and future behavior. It is a key enabler of data-driven decision making, complex systems monitoring, product validation and simulation and object lifecycle management. As an emergent technology, its widespread implementation is increasing in several domains such as industrial, automotive, medicine, smart cities, etc. The objective of this systematic literature review is to present a comprehensive view on the DT technology and its implementation challenges and limits in the most relevant domains and applications in engineering and beyond.

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Section: Automotivementioning

confidence: 99%

Digital Twin Technology Challenges and Applications: A Comprehensive Review

et al. 2022

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“…This opens up the possibility of collecting data on vehicle usage as well as degradation over time. Through the use of simulations and digital twins, this research proposes the use of data present on ECUs to track the conditions of vehicle usage and offer insights into which of its components might be appropriate for reuse, repair or re manufacture (Magargle et al, 2017;Merkle et al, 2021;Son et al, 2021). This combination of sensors, network communication technology and analytic simulations will be informative in the implementation of circular economy behaviour within the automotive industry.…”

Section: Framework For Circular Production Of Automotive Partsmentioning

confidence: 99%

Circular production and maintenance of automotive parts: An Internet of Things (IoT) data framework and practice review

Turner

Okorie

Emmanouilidis

et al. 2022

Computers in Industry

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“…The BMW i3 data was obtained by reading the vehicle's CAN-and LIN-Bus communication via a Vector VN1611 device and the signals were then recorded via the software Vector CANoe. For the Tesla, the data recording was performed by a self-developed logging device [43]. Both vehicles' logs use the same sign convention, where discharge currents are defined as negative and charge currents are positive.…”

Section: Databasementioning

confidence: 99%

Effect of Low Temperature on Electric Vehicle Range

Steinstraeter

Heinrich

Lienkamp

2021

WEVJ

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A significant disadvantage of battery electric vehicles compared to vehicles with internal combustion engines is their sharply decreased driving range at low temperatures. Two factors are primarily responsible for this decreased range. On the one hand, the energy demand of cabin heating needs to be supplied by the vehicle’s battery since less waste heat is available from the powertrain, which could be used to cover heating demands. On the other hand, a limited capability to recuperate at low temperatures serves to protect the battery from accelerated aging, which ultimately leads to less energy regeneration. This paper analyzes the impact of both factors separately on a battery electric vehicle’s driving range. Additionally, this paper provides technical requirements for the implementation of an electrothermal recuperation system. Such a system has the potential to reduce the impact of both abovementioned factors on driving range by enabling the direct usage of regeneratable energy for heating when battery charging is limited under cold conditions. The presented analysis is based on BMW i3 and Tesla Model 3 datasets, which combined cover more than 125 trips in and around Munich at different ambient conditions. The results show that the range can decrease by up to 31.9% due to heating and by up to 21.7% due to limited recuperation, which gives a combined maximum range decrease of approximately 50% under cold conditions. Additionally, it was found that a heater with a short reaction time in the lower millisecond range and a power capability of 20 kW would be sufficient for an electrothermal recuperation system to enable the utilization of unused regenerative braking potentials directly for heating.

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Estimate e-Golf Battery State Using Diagnostic Data and a Digital Twin

Cited by 43 publications

References 23 publications

Digital Twin Technology Challenges and Applications: A Comprehensive Review

Digital Twin Technology Challenges and Applications: A Comprehensive Review

Circular production and maintenance of automotive parts: An Internet of Things (IoT) data framework and practice review

Effect of Low Temperature on Electric Vehicle Range

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