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Systems engineering for automotive powertrain development

Record Type:	Electronic resources : Monograph/item
Title/Author:	Systems engineering for automotive powertrain developmentedited by Hannes Hick, Klaus Kupper, Helfried Sorger.
other author:	Hick, Hannes.
Published:	Cham :Springer International Publishing :2021.
Description:	xix, 895 p. :ill., digital ;24 cm.
Contained By:	Springer Nature eReference
Subject:	AutomobilesPower trains.
Online resource:	https://doi.org/10.1007/978-3-319-99629-5
ISBN:	9783319996295$q(electronic bk.)

Systems engineering for automotive powertrain development
Systems engineering for automotive powertrain development[electronic resource] /edited by Hannes Hick, Klaus Kupper, Helfried Sorger. - Cham :Springer International Publishing :2021. - xix, 895 p. :ill., digital ;24 cm. - Powertrain,1613-6349. - Powertrain..

Part I: Challenges for Powertrain Development -- Challenges for Future Automotive Mobility - Challenges of Passenger Cars Challenges of Powertrain System Diversity - Technical Challenges in Automotive Powertrain Engineering - Product Lifecycle Challenges for Powertrain Systems in the Automotive Industry - Organizational Challenges in Automotive Development- Part II: Systems Engineering -- Systems Engineering Principles - Model-Based Systems Engineering Concepts - Systems Engineering Processes - Systems Engineering Methods and Tools - Systems Engineering - Organizational Constraints and Responsibilities - Standards, Certifications, and Quality Features for Systems Engineering Supported Development in Automotive Decision-Making and the Influence of the Human Factor Part III: Automotive Systems Engineering Approach -- Automotive Powertrain Development Process - Systems Engineering Methods for Automotive Powertrain Development - Product Lifecycle Management in Automotive Industry - Integrated and Open Development Platform for the Automotive Industry - System Simulation in Automotive Industry - Cost Engineering as an Essential Part of Systems Engineering Part IV: Powertrain Development Case Studies. -Case Study - Hybrid Powertrain System Development; - Case Study - Engine System Developmen;t - Case Study - E-Drive System Development; - Case Study - Transmission System Development; - Case Study: Battery System Development; - Case Study: Fuel Cell System Development; - Case Study: Vehicle Attribute Engineering; - Case Study - Thermal System Development for High Voltage Battery Electric Vehicles - Part V: Outlook -- Information Communication Technology - a Base for Innovative Automotive Solutions and Key Enabler for Efficient and Effective Systems Engineering; - Digitalization as Opportunity to Remove Silo-Thinking and Enable Holistic Value Creation; - Future of Systems Engineering.

For the last century, the automotive industry has been dominated by internal combustion engines. Their flexibility of application, driving range, performance and sporty characteristics has resulted in several generations of this technology and has formed generations of engineers. But that is not the end of the story. Stricter legislation and increased environmental awareness have resulted in the development of new powertrain technologies in addition and parallel to the highly optimized internal combustion engine. Hybrid powertrains systems, pure battery electric systems and fuel cell systems, in conjunction with a diverse range of applications, have increased the spectrum of powertrain technologies. Furthermore, automated driving together with intelligent and highly connected systems are changing the way to get from A to B. Not only is the interaction of all these new technologies challenging, but also several different disciplines have to collaborate intensively in order for new powertrain systems to be successfully developed. These new technologies and the resulting challenges lead to an increase in system complexity. Approaches such as systems engineering are necessary to manage this complexity. To show how systems engineering manages the increasing complexity of modern powertrain systems, by providing processes, methods, organizational aspects and tools, this book has been structured into five parts. Starting with Challenges for Powertrain Development, which describes automotive-related challenges at different levels of the system hierarchy and from different point of views. The book then continues with the core part, Systems Engineering, in which all the basics of systems engineering, model-based systems engineering, and their related processes, methods, tools, and organizational matters are described. A special focus is placed on important standards and the human factor. The third part, Automotive Powertrain Systems Engineering Approach, puts the fundamentals of systems engineering into practice by adding the automotive context. This part focuses on system development and also considers the interactions to hardware and software development. Several approaches and methods are presented based on systems engineering philosophy. Part four, Powertrain Development Case Studies, adds the practical point of view by providing a range of case studies on powertrain system level and on powertrain element level and discusses the development of hybrid powertrain, internal combustion engines, e-drives, transmissions, batteries and fuel cell systems. Two case studies on a vehicle level are also presented. The final part, Outlook, considers the development of systems engineering itself with particular focus on information communication technologies. Even though this book covers systems engineering from an automotive perspective, many of the challenges, fundamental principles, conclusions and outlooks can be applied to other domains too. Therefore, this book is not only relevant for automotive engineers and students, but also for specialists in scientific and industrial positions in other domains and anyone who has to cope with the challenge of successfully developing complex systems with a large number of collaborating disciplines.

ISBN: 9783319996295$q(electronic bk.)

Standard No.: 10.1007/978-3-319-99629-5doiSubjects--Topical Terms:

677982
Automobiles
--Power trains.

LC Class. No.: TL260 / .S87 2021

Dewey Class. No.: 629.244

Systems engineering for automotive powertrain development
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520 $a For the last century, the automotive industry has been dominated by internal combustion engines. Their flexibility of application, driving range, performance and sporty characteristics has resulted in several generations of this technology and has formed generations of engineers. But that is not the end of the story. Stricter legislation and increased environmental awareness have resulted in the development of new powertrain technologies in addition and parallel to the highly optimized internal combustion engine. Hybrid powertrains systems, pure battery electric systems and fuel cell systems, in conjunction with a diverse range of applications, have increased the spectrum of powertrain technologies. Furthermore, automated driving together with intelligent and highly connected systems are changing the way to get from A to B. Not only is the interaction of all these new technologies challenging, but also several different disciplines have to collaborate intensively in order for new powertrain systems to be successfully developed. These new technologies and the resulting challenges lead to an increase in system complexity. Approaches such as systems engineering are necessary to manage this complexity. To show how systems engineering manages the increasing complexity of modern powertrain systems, by providing processes, methods, organizational aspects and tools, this book has been structured into five parts. Starting with Challenges for Powertrain Development, which describes automotive-related challenges at different levels of the system hierarchy and from different point of views. The book then continues with the core part, Systems Engineering, in which all the basics of systems engineering, model-based systems engineering, and their related processes, methods, tools, and organizational matters are described. A special focus is placed on important standards and the human factor. The third part, Automotive Powertrain Systems Engineering Approach, puts the fundamentals of systems engineering into practice by adding the automotive context. This part focuses on system development and also considers the interactions to hardware and software development. Several approaches and methods are presented based on systems engineering philosophy. Part four, Powertrain Development Case Studies, adds the practical point of view by providing a range of case studies on powertrain system level and on powertrain element level and discusses the development of hybrid powertrain, internal combustion engines, e-drives, transmissions, batteries and fuel cell systems. Two case studies on a vehicle level are also presented. The final part, Outlook, considers the development of systems engineering itself with particular focus on information communication technologies. Even though this book covers systems engineering from an automotive perspective, many of the challenges, fundamental principles, conclusions and outlooks can be applied to other domains too. Therefore, this book is not only relevant for automotive engineers and students, but also for specialists in scientific and industrial positions in other domains and anyone who has to cope with the challenge of successfully developing complex systems with a large number of collaborating disciplines.
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