SAE J 2836 2-2011 Use Cases for Communication between Plug-in Vehicles and Off-Board DC Charger《插入式车辆和场外直流充电器之间交流用例》.pdf

1、SAE Technical Standards Board Rules provide that: “This report is published by SAE to advance the state of technical and engineering sciences. The use of this report is entirely voluntary, and its applicability and suitability for any particular use, including any patent infringement arising theref

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4、A) Fax: 724-776-0790 Email: CustomerServicesae.org SAE WEB ADDRESS: http:/www.sae.orgSAE values your input. To provide feedback on this Technical Report, please visit http:/www.sae.org/technical/standards/J2836/2_201109SURFACEVEHICLEINFORMATIONREPORTJ2836-2 SEP2011 Issued 2011-09Use Cases for Commun

5、ication between Plug-in Vehicles and Off-Board DC Charger RATIONALEThis document will use the on-board charger as a basis, then add and delete info that address the new criteria for vehicle architectures that have been introduced as Plug-In Electric Vehicles (PEV). Rechargeable Energy Storage System

6、s (RESS) have also changed dramatically since Electric Vehicles were introduced and new technologies along with packaging aspects may require specific communication criteria. TABLE OF CONTENTS 1. SCOPE 21.1 Purpose . 32. REFERENCES 32.1 Applicable Documents 32.1.1 SAE PUBLICATIONS 32.2 Related Publi

7、cations (Optional) 33. DEFINITIONS . 33.1 AVAILABLE LINE CURRENT (ALC). 33.2 CHARGER 33.3 ELECTRIC VEHICLE SUPPLY EQUIPMENT (EVSE) . 43.4 ENERGY PORTAL 43.5 ENERGY TRANSFER 43.6 ENERGY TRANSFER STRATEGY 43.7 FORWARD POWER FLOW (FPF) . 43.8 HOME AREA NETWORK (HAN) 43.9 INTEROPERABILITY 43.10 OFF-BOAR

8、D/ON-BOARD BOUNDARY . 53.11 POWER FLOW . 53.12 RECHARGEABLE ENERGY STORAGE SYSTEM (RESS) 53.13 REVERSE POWER FLOW (RPF) 53.14 PLUG-IN VEHICLE . 53.15 POWER FLOW . 53.16 POWER LINE COMMUNICATION . 53.17 SEP 2.0 . 63.18 SMART CHARGING . 63.19 UTILITY . 6Copyright SAE International Provided by IHS unde

9、r license with SAENot for ResaleNo reproduction or networking permitted without license from IHS-,-,-SAE J2836-2 Issued SEP2011 Page 2 of 19 4. TECHNICAL REQUIREMENTS 64.1 System Definition 104.2 Architecture . 124.3 Communication Sequence 144.3.1 Communication Sequence 144.3.2 Inband Signaling . 14

10、4.3.3 PLC using the mains . 144.3.4 Sequence Diagrams . 144.4 Communication Messages, Requirements and Protocols 175. DOCUMENT MAPPING 185.1 Summary . 185.2 Example - Utility Programs Using SEP2.0 185.3 Example - DC Energy Transfer . 195.4 Example - Reverse Power Flow 196. NOTES 196.1 Marginal Indic

11、ia . 19FIGURE 1 SAE CHARGING CONFIGURATIONS AND RATINGS TERMINOLOGY . 6FIGURE 2 CHARGING LOCATIONS AND TYPES OF EVSES EXPECTED 8FIGURE 3 CONNECTOR AND POWER LEVEL VARIATIONS 9FIGURE 4 PEV AND EVSE COMBINATIONS FOR AC L1 & 2 AND DC L1 . 10FIGURE 5 GENERALIZED VEHICLE AND EVSE VARIATIONS 11FIGURE 6 AC

12、 CHARGING ARCHITECTURE . 13FIGURE 7 DC CHARGING ARCHITECTURE (DC LEVEL 1) . 13FIGURE 8 DC CHARGING ARCHITECTURE (DC LEVEL 2) . 14FIGURE 9 1STSEQUENCE INBAND SIGNALING COMMUNICATION ESTABLISHED . 15FIGURE 10 2NDSEQUENCE POWER IS APPLIED . 15FIGURE 11 3RDSEQUENCE PLC COMMUNICATION ESTABLISHED OVER MAI

13、NS 16FIGURE 12 1STSEQUENCE INBAND SIGNALING COMMUNICATION ESTABLISHED . 16FIGURE 13 2NDSEQUENCE POWER IS APPLIED . 17FIGURE 14 3RDSEQUENCE PLC COMMUNICATION ESTABLISHED OVER MAINS 17TABLE 1 WIRING AND CIRCUIT BREAKER SIZE AND ALC VALUES . 71. SCOPE This SAE Information Report SAE J2836/2 establishes

14、 use cases and general information for communication between plug-in electric vehicles and the DC Off-board charger. Where relevant, this document notes, but does not formally specify, interactions between the vehicle and vehicle operator. This applies to the off-board DC charger for conductive char

15、ging, which supplies DC current to the vehicle battery of the electric vehicle through a SAE J1772 Hybrid coupler or SAE J1772 AC Level 2 type coupler on DC power lines, using the AC power lines or the pilot line for PLC communication, or dedicated communication lines that is further described in SA

16、E J2847/2.The specification supports DC energy transfer via Forward Power Flow (FPF) from grid-to-vehicle.The relationship of this document to the others that address PEV communications is further explained in section 5. This is the 1st version of this document and completes step 1 effort that captu

17、res the initial objectives of the SAE task force. The intent of step 1 was to record as much information on “what we think works” and publish. The effort continues however, to step 2 that allows public review for additional comments and viewpoints, while the task force also continues additional test

18、ing and early implementation. Results of step 2 effort will then be incorporated into updates of this document and lead to a republished version. Copyright SAE International Provided by IHS under license with SAENot for ResaleNo reproduction or networking permitted without license from IHS-,-,-SAE J

19、2836-2 Issued SEP2011 Page 3 of 19 1.1 Purpose The purpose of SAE J2836/2 is to document the general information which must be supported by SAE Recommended Practice SAE J2847/2, Communication between Plug-in Vehicles and the off-board charger in the EV Supply Equipment (EVSE).2. REFERENCES 2.1 Appli

20、cable Documents The following publications form a part of this specification to the extent specified herein. Unless otherwise indicated, the latest issue of SAE publications shall apply. 2.1.1 SAE PUBLICATIONS Available from SAE International, 400 Commonwealth Drive, Warrendale, PA 15096-0001, Tel:

21、877-606-7323 (inside USA and Canada) or 724-776-4970 (outside USA), www.sae.org.J1772 SAE Electric Vehicle and Plug in Hybrid Electric Vehicle Conductive Charge Coupler J2836-1 Use Cases for Communication between Plug-in Vehicles and Utility Grid (Surface Vehicle Information Report).J2836-3 Use Case

22、s for Communication between Plug-in Vehicles and the Utility Grid for Reverse Power Flow (Surface Vehicle Information Report). J2847-1 Communication between Plug-in Vehicles and the Utility Grid (Surface Vehicle Recommended Practice). J2847-2 Communication between Plug-in Vehicles and the Supply Equ

23、ipment (EVSE) (Surface Vehicle Recommended Practice). J2847-3 Communication between Plug-in Vehicles and the Utility Grid for Reverse Power Flow (Surface Vehicle Recommended Practice). J2931-1 Digital Communications for Plug-in Electric Vehicles 2.2 Related Publications (Optional) The following publ

24、ications are provided for information purposes only and are not a required part of this document: 3. DEFINITIONS 3.1 AVAILABLE LINE CURRENT (ALC) Available Line Current is transmitted by the EVSE using the Pilot duty cycle identified in SAE J1772. This indicates to the vehicle the maximum current dr

25、aw for this premises. The purpose of this is for the vehicle not to request more current that this and to not trip the premises circuit breaker.3.2 CHARGER The charger can either be on-board the vehicle or off-board. On-board chargers require AC energy transfer to the vehicle (either 120 or 240V sin

26、gle phase) and Off-board chargers are within the EVSE and require DC energy transfer to the vehicle.Copyright SAE International Provided by IHS under license with SAENot for ResaleNo reproduction or networking permitted without license from IHS-,-,-SAE J2836-2 Issued SEP2011 Page 4 of 19 3.3 ELECTRI

27、C VEHICLE SUPPLY EQUIPMENT (EVSE) PEV connects to the grid using an Electric Vehicle Supply Equipment (EVSE). Electric Vehicle Supply Equipment (EVSE) is the physical electrical cord and connectors that are specified by applicable SAE standards (e.g., SAE J1772, SAE J2836 SAE J2847 & SAE J2931.) tha

28、t provide transfer of electrical energy from energy portal to PEV. This can be 120V or 240V AC depending upon connection. Two type of connection include 1) EVSE cordset and 2) Premises Mounted version. The Premises EVSE would not include the charger for AC Level 2 energy transfer described in SAE J1

29、772. This would expect the charger to be included on the vehicle. If the EVSE includes an off-charger, DC energy transfer is expected and the vehicle would by-pass any on-board charger and use the one in the EVSE. This EVSE that includes the charger for DC Level 1 may also be capable of AC energy tr

30、ansfer at both 120V (AC Level 1) and 240V (AC Level 2) levels. The larger off-board charger in DC Level 2 systems is not expected to also deliver AC since these are Fast charge stations and extended time at this location is not desired since 10 to 20 minute charges are desired. 3.4 ENERGY PORTAL Ene

31、rgy Portal is any charging point for a PEV. At a minimum, the Energy Portal is a 120V, 15A outlet but can also be a 240V Electric Vehicle Supply Equipment (EVSE) outlet connected to the premises circuit. 3.5 ENERGY TRANSFER Energy Transfer is the process of flowing energy to the EV from the EVSE. 3.

32、6 ENERGY TRANSFER STRATEGY A strategy that accounts for all of the electrical energy needs of an EV and the present status of all on-board equipment, including the EV Storage Battery. It determines the rate that energy is to be transferred to the EV and how the ETS shall be operated to accomplish th

33、is. 3.7 FORWARD POWER FLOW (FPF) Forward Power Flow means the direction of energy for Charging a Vehicle is from the source to the vehicle 3.8 HOME AREA NETWORK (HAN) A HAN is an energy related network, contained within a premises used for communicating with devices within the premises. HANs do not

34、necessarily require connectivity outside the premises, but may be connected to one or more external communication networks (e.g., Utility AMI, internet, cell phone network, etc.) using gateways, bridges and interfaces.Homeplug powerline adapters are an alternative solution for having your house comp

35、letely networked using existing power lines. The advanced Homeplug powerline adapter is capable of transmitting data at up to 200 Mbps channel data rate. The Homeplug powerline adapter delivers maximum range and speed for voice, Internet, video, and music throughout your home or office. 3.9 INTEROPE

36、RABILITY The condition where components of a system, relative to each other, are able to work together to perform the intended operation of the total system. Information interoperability is the capability of two or more networks, systems, devices, applications, or components to share and readily use

37、 information securely and effectively with little or no inconvenience for the user. As an example, a 10-mm box-end hand wrench and a 10-mm socket wrench are interoperable, relative to a 10-mm hex-head bolt. The wrench and the bolt are both parts of a fastening system. The fact that the system will p

38、erform as required with either wrench establishes the interoperability of the wrenches and the bolt. Copyright SAE International Provided by IHS under license with SAENot for ResaleNo reproduction or networking permitted without license from IHS-,-,-SAE J2836-2 Issued SEP2011 Page 5 of 19 3.10 OFF-B

39、OARD/ON-BOARD BOUNDARY Off-Board/On-Board Boundary is the point where the ETS is divided into two physical parts. One part becomes realized within the off-board Electric Vehicle Supply Equipment (EVSE). The other part becomes realized within an Electric Vehicle. This boundary will be in different pl

40、aces, depending on the system architecture. 3.11 POWER FLOW See Forward Power Flow (FPF), Reverse Power Flow (RPF), Grid to Vehicle (G2V), Vehicle to Home (V2H) and Vehicle to Grid (V2G) for further definitions. 3.12 RECHARGEABLE ENERGY STORAGE SYSTEM (RESS) Means a system that stores energy for del

41、ivery of electric energy and which is rechargeable 3.13 REVERSE POWER FLOW (RPF) Reverse Power Flow means the direction of energy for Discharging a Vehicle is from the vehicle to the load. 3.14 PLUG-IN VEHICLE Plug-in Electric Vehicle (PEV). Plugs into an Energy Portal (see actor definition below) a

42、t a premises to charge vehicle. A PEV may be a BEV (Battery Electric Vehicle) that relies only on electric propulsion. A PEV may also be a PHEV (Plug-In-Hybrid Vehicle) that also includes an alternative source of propulsion power. 3.15 POWER FLOW See Forward Power Flow and Reverse Power Flow. 3.16 P

43、OWER LINE COMMUNICATION Power line communication (PLC), also called power line carrier, mains communication, power line telecom (PLT) or power line networking (PLN) are terms describing several different systems for using electric power lines to carry information over the power line. Electrical AC p

44、ower is transmitted over high voltage transmission lines, distributed over medium voltage, and used inside buildings and homes at lower voltages. Power line communications can be applied at each stage. Most PLC technologies limit themselves to one set of wires (for example, premises wiring), but som

45、e can cross between two levels (for example, both the distribution network and premises wiring). In most cases, these technologies may be used on DC lines and in the absence of power. Since the power wiring was designed for the transmission of power and not for communications, many challenges exist,

46、 such as faultless communications in the presence of noise and over long distances. Power line communications systems operate using a variety of modulation techniques (including frequency, phase or OFDM modulation schemes), and in different frequency bands. In general, the lower band solutions (in t

47、he 10 490 KHz range) are used in applications with data rates less than 256 Kbps. The upper band (2 MHz and above), has been used for broadband applications. As there are many different incompatible proprietary, alliance specifications and standards, the issue of co-existence is a major concern. The

48、 medium can extend beyond the consumers premises and may be used for multiple different applications, from simple lighting control to video distribution in the home to communicating to the Utility electrical meter outside. One example of a PLC technology is HomePlug. Founded in 2000, the HomePlug Po

49、werline Alliance, Inc. is the global leading open-standards based organization developing interoperable powerline communications technologies and certifying powerline-based products. With 65 members and more than 4.5 million HomePlug-certified products shipped worldwide, the organization has developed HomePl