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Author: Hybrid - EV Committee
Publisher:
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Category :
Languages : en
Pages : 0
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Book Description
SAE J2293 establishes requirements for Electric Vehicles (EV) and the off-board Electric Vehicle Supply Equipment (EVSE) used to transfer electrical energy to an EV from an Electric Utility Power System (Utility) in North America. This document defines, either directly or by reference, all characteristics of the total EV Energy Transfer System (EV-ETS) necessary to insure the functional interoperability of an EV and EVSE of the same physical system architecture. The ETS, regardless of architecture, is responsible for the conversion of AC electrical energy into DC electrical energy that can be used to charge the Storage Battery of an EV, as shown in Figure 1. The different physical ETS system architectures are identified by the form of the energy that is transferred between the EV and the EVSE, as shown in Figure 2. It is possible for an EV and EVSE to support more than one architecture.This document does not contain all requirements related to EV energy transfer, as there are many aspects of an EV and EVSE that do not affect their interoperability. Specifically, this document does not deal with the characteristics of the interface between the EVSE and the Utility, except to acknowledge the Utility as the source of energy to be transferred to the EV.The functional requirements for the ETS are described using a functional decomposition method. This is where requirements are successively broken down into simpler requirements and the relationships between requirements are captured in a graphic form. The requirements are written as the transformation of inputs into outputs, resulting in a model of the total system.Each lowest level requirement is then allocated to one of four functional groups (FG) shown in Figure 2. These groups illustrate the variations of the three different system architectures, as the functions they represent will be accomplished either on an EV or within the EVSE, depending on the architecture. Physical requirements for the channels used to transfer the power and communicate information between the EV and the EVSE are then defined as a function of architecture. System architecture variations are referred to as follows: aType AConductive AC System ArchitectureSection 7.2.1 bType BInductive System ArchitectureSection 7.2.2 cType CConductive DC System ArchitectureSection 7.2.3 The requirements model in Section 6 is not intended to dictate a specific design or physical implementation, but rather to provide a functional description of the system's expected operational results. These results can be compared against the operation of any specific design. Validation against this document is only appropriate at the physical boundary between the EVSE and EV. See Section 8. This stabilized Recommended Practice documents for reference the historical state of energy transfer systems and communications for electric vehicles as they existed in 2008, as defined in SAE J1772 (per published version 11-1-2001) for conductive charging and SAE J1773 (per published version 11-1-1999) for inductive charging.SAE J1772 continues to be updated to reflect the latest in conductive charging technology. See the latest available version of J1772.SAE J1773 remains unchanged for inductive charging.Documentation for the now-emerging "wireless" inductive charging systems will be published when available.Grid power quality for supplying charging systems is covered in SAE document series J2894.For state-of-the-art documentation on charging communications, refer to the SAE documents in the series J2836, J2847, J2931, and J2953.
Author: Hybrid - EV Committee
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
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Book Description
SAE J2293 establishes requirements for Electric Vehicles (EV) and the off-board Electric Vehicle Supply Equipment (EVSE) used to transfer electrical energy to an EV from an Electric Utility Power System (Utility) in North America. This document defines, either directly or by reference, all characteristics of the total EV Energy Transfer System (EV-ETS) necessary to insure the functional interoperability of an EV and EVSE of the same physical system architecture. The ETS, regardless of architecture, is responsible for the conversion of AC electrical energy into DC electrical energy that can be used to charge the Storage Battery of an EV, as shown in Figure 1. The different physical ETS system architectures are identified by the form of the energy that is transferred between the EV and the EVSE, as shown in Figure 2. It is possible for an EV and EVSE to support more than one architecture.This document does not contain all requirements related to EV energy transfer, as there are many aspects of an EV and EVSE that do not affect their interoperability. Specifically, this document does not deal with the characteristics of the interface between the EVSE and the Utility, except to acknowledge the Utility as the source of energy to be transferred to the EV.The functional requirements for the ETS are described using a functional decomposition method. This is where requirements are successively broken down into simpler requirements and the relationships between requirements are captured in a graphic form. The requirements are written as the transformation of inputs into outputs, resulting in a model of the total system.Each lowest level requirement is then allocated to one of four functional groups (FG) shown in Figure 2. These groups illustrate the variations of the three different system architectures, as the functions they represent will be accomplished either on an EV or within the EVSE, depending on the architecture. Physical requirements for the channels used to transfer the power and communicate information between the EV and the EVSE are then defined as a function of architecture. System architecture variations are referred to as follows: aType AConductive AC System ArchitectureSection 7.2.1 bType BInductive System ArchitectureSection 7.2.2 cType CConductive DC System ArchitectureSection 7.2.3 The requirements model in Section 6 is not intended to dictate a specific design or physical implementation, but rather to provide a functional description of the system's expected operational results. These results can be compared against the operation of any specific design. Validation against this document is only appropriate at the physical boundary between the EVSE and EV. See Section 8. This stabilized Recommended Practice documents for reference the historical state of energy transfer systems and communications for electric vehicles as they existed in 2008, as defined in SAE J1772 (per published version 11-1-2001) for conductive charging and SAE J1773 (per published version 11-1-1999) for inductive charging.SAE J1772 continues to be updated to reflect the latest in conductive charging technology. See the latest available version of J1772.SAE J1773 remains unchanged for inductive charging.Documentation for the now-emerging "wireless" inductive charging systems will be published when available.Grid power quality for supplying charging systems is covered in SAE document series J2894.For state-of-the-art documentation on charging communications, refer to the SAE documents in the series J2836, J2847, J2931, and J2953.
Author: Electric Vehicle Forum Committee
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
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Book Description
SAE J2293 establishes requirements for Electric Vehicles (EV) and the off- board Electric Vehicle Supply Equipment (EVSE) used to transfer electrical energy to an EV from an Electric Utility Power System (Utility) in North America. This document defines, either directly or by reference, all characteristics of the total EV Energy Transfer System (EV-ETS) necessary to insure the functional interoperability of an EV and EVSE of the same physical system architecture. The ETS, regardless of architecture, is responsible for the conversion of AC electrical energy into DC electrical energy that can be used to charge the Storage Battery of an EV, as shown.
Author: SAE International
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
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Book Description
Author: Hybrid - EV Committee
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
Get Book Here
Book Description
SAE J2293 establishes requirements for Electric Vehicles (EV) and the off-board Electric Vehicle Supply Equipment (EVSE) used to transfer electrical energy to an EV from an Electric Utility Power System (Utility) in North America. This document defines, either directly or by reference, all characteristics of the total EV Energy Transfer System (EV-ETS) necessary to insure the functional interoperability of an EV and EVSE of the same physical system architecture. The ETS, regardless of architecture, is responsible for the conversion of AC electrical energy into DC electrical energy that can be used to charge the Storage Battery of an EV, as shown in Figure 1. The different physical ETS system architectures are identified by the form of the energy that is transferred between the EV and the EVSE, as shown in Figure 2. It is possible for an EV and EVSE to support more than one architecture.This document does not contain all requirements related to EV energy transfer, as there are many aspects of an EV and EVSE that do not affect their interoperability. Specifically, this document does not deal with the characteristics of the interface between the EVSE and the Utility, except to acknowledge the Utility as the source of energy to be transferred to the EV.The functional requirements for the ETS are described using a functional decomposition method. This is where requirements are successively broken down into simpler requirements and the relationships between requirements are captured in a graphic form. The requirements are written as the transformation of inputs into outputs, resulting in a model of the total system.Each lowest level requirement is then allocated to one of four functional groups (FG) shown in Figure 2. These groups illustrate the variations of the three different system architectures, as the functions they represent will be accomplished either on an EV or within the EVSE, depending on the architecture. Physical requirements for the channels used to transfer the power and communicate information between the EV and the EVSE are then defined as a function of architecture. System architecture variations are referred to as follows: aType AConductive AC System ArchitectureJ2293-16.2.1 bType BInductive System Architecture J2293-16.2.2 cType CConductive DC System ArchitectureJ22936.2.3 The requirements model in Section 6 is not intended to dictate a specific design or physical implementation, but rather to provide a functional description of the system's expected operational results. These results can be compared against the operation of any specific design. Validation against this document is only appropriate at the physical boundary between the EVSE and EV. See Section 8. This stabilized Recommended Practice documents for reference the historical state of energy transfer systems and communications for electric vehicles as they existed in 2008, as defined in SAE J1772 (per published version 11-1-2001) for conductive charging and SAE J1773 (per published version 11-1-1999) for inductive charging.SAE J1772 continues to be updated to reflect the latest in conductive charging technology. See the latest available version of J1772.SAE J1773 remains unchanged for inductive charging.Documentation for the now-emerging "wireless" inductive charging systems will be published when available.Grid power quality for supplying charging systems is covered in SAE document series J2894.For state-of-the-art documentation on charging communications, refer to the SAE documents in the series J2836, J2847, J2931, and J2953.
Author:
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ISBN:
Category : Battery chargers
Languages : en
Pages : 84
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Author:
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ISBN:
Category : Charge coupled devices
Languages : en
Pages : 268
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Author: John T. Warner
Publisher: Elsevier
ISBN: 0443138087
Category : Technology & Engineering
Languages : en
Pages : 472
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Book Description
The Handbook of Lithium-Ion Battery Pack Design: Chemistry, Components, Types and Terminology,?Second Edition provides a clear and concise explanation of EV and Li-ion batteries for readers that are new to the field. The second edition expands and updates all topics covered in the original book, adding more details to all existing chapters and including major updates to align with all of the rapid changes the industry has experienced over the past few years. This handbook offers a layman’s explanation of the history of vehicle electrification and battery technology, describing the various terminology and acronyms and explaining how to do simple calculations that can be used in determining basic battery sizing, capacity, voltage, and energy. By the end of this book the reader will have a solid understanding of the terminology around Li-ion batteries and be able to undertake simple battery calculations. The book is immensely useful to beginning and experienced engineers alike who are moving into the battery field. Li-ion batteries are one of the most unique systems in automobiles today in that they combine multiple engineering disciplines, yet most engineering programs focus on only a single engineering field. This book provides the reader with a reference to the history, terminology and design criteria needed to understand the Li-ion battery and to successfully lay out a new battery concept. Whether you are an electrical engineer, a mechanical engineer or a chemist, this book will help you better appreciate the inter-relationships between the various battery engineering fields that are required to understand the battery as an Energy Storage System. It gives great insights for readers ranging from engineers to sales, marketing, management, leadership, investors, and government officials. Adds a brief history of battery technology and its evolution to current technologies? Expands and updates the chemistry to include the latest types Discusses thermal runaway and cascading failure mitigation technologies? Expands and updates the descriptions of the battery module and pack components and systems?? Adds description of the manufacturing processes for cells, modules, and packs? Introduces and discusses new topics such as battery-as-a-service, cell to pack and cell to chassis designs, and wireless BMS?
Author: Takuro Sato
Publisher: John Wiley & Sons
ISBN: 1118653777
Category : Technology & Engineering
Languages : en
Pages : 488
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Book Description
A fully comprehensive introduction to smart grid standardsand their applications for developers, consumers and serviceproviders The critical role of standards for smart grid has already beenrealized by world-wide governments and industrial organizations.There are hundreds of standards for Smart Grid which have beendeveloped in parallel by different organizations. It istherefore necessary to arrange those standards in such a way thatit is easier for readers to easily understand and select aparticular standard according to their requirements without goinginto the depth of each standard, which often spans from hundreds tothousands of pages. The book will allow people in the smart grid areas and in therelated industries to easily understand the fundamental standardsof smart grid, and quickly find the building-block standards theyneed from hundreds of standards for implementing a smart gridsystem. The authors highlight the most advanced works and effortsnow under way to realize an integrated and interoperable smartgrid, such as the “NIST Framework and Roadmap for Smart GridInteroperability Standards Release 2.0”, the” IEC SmartGrid Standardization Roadmap”, the ISO/IEC’s“Smart Grid Standards for Residential Customers”, theZigBee/HomePlug’s “Smart Energy Profile Specification2.0”, IEEE’s P2030 “Draft Guide for Smart GridInteroperability of Energy Technology and Information TechnologyOperation with the Electric Power System (EPS), and End-UseApplications and Loads”, and the latest joint researchproject results between the world’s two largest economies, USand China. The book enables readers to fully understand the latestachievements and ongoing technical works of smart grid standards,and assist industry utilities, vendors, academia, regulators, andother smart grid stakeholders in future decision making. The book begins with an overview of the smart grid, andintroduces the opportunities in both developed and developingcountries. It then examines the standards for power griddomain of the smart grid, including standards for blackoutprevention and energy management, smart transmission, advanceddistribution management and automation, smart substationautomation, and condition monitoring. Communication and securitystandards as a whole are the backbone of smart grid and theirstandards, including those for wired and wireless communications,are then assessed. Finally the authors consider the standards andon-going work and efforts for interoperability and integrationbetween different standards and networks, including the latestjoint research effort between the world’s two largesteconomies, US and China. A fully comprehensive introduction to smart grid standards andtheir applications for developers, consumers and serviceproviders Covers all up-to-date standards of smart grid, including thekey standards from NIST, IEC, ISO ZigBee, IEEE, HomePlug, SAE, andother international and regional standardization organizations. TheAppendix summarizes all of the standards mentioned in the book Presents standards for renewable energy and smart generation,covering wind energy, solar voltaic, fuel cells, pumped storage,distributed generation, and nuclear generation standards. Standardsfor other alternative sources of energy such as geothermal energy,and bioenergy are briefly introduced Introduces the standards for smart storage and plug-in electricvehicles, including standards for distributed energy resources(DER), electric storage, and E-mobility/plug-in vehicles The book is written in an accessible style, ideal as anintroduction to the topic, yet contains sufficient detail andresearch to appeal to the more advanced and specialist reader.
Author: SAE International
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
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Author: Sumedha Rajakaruna
Publisher: Springer
ISBN: 981287299X
Category : Technology & Engineering
Languages : en
Pages : 355
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Book Description
This book focuses on the state of the art in worldwide research on applying optimization approaches to intelligently control charging and discharging of batteries of Plug-in Electric Vehicles (PEVs) in smart grids. Network constraints, cost considerations, the number and penetration level of PEVs, utilization of PEVs by their owners, ancillary services, load forecasting, risk analysis, etc. are all different criteria considered by the researchers in developing mathematical based equations which represent the presence of PEVs in electric networks. Different objective functions can be defined and different optimization methods can be utilized to coordinate the performance of PEVs in smart grids. This book will be an excellent resource for anyone interested in grasping the current state of applying different optimization techniques and approaches that can manage the presence of PEVs in smart grids.
