SAE J3105

Last updated
SAE J3105
Front half of Spokane City Line bus charging at SCC transit center October 2023.jpg
ABB SAE J3105-1 station for Spokane Transit City Line
Type Automotive power connector
Production history
Manufacturer ABB, Heliox, SCHUNK, Siemens, Stäubli and others
Produced 2016+
General specifications
Pins 4
Electrical
Signal DC
Pinout
+ DC DC Power (positive)
DC DC Power (negative)
PE Protective earth full-current protective earthing system
CP Control pilot post-insertion signalling
WiFi (IEEE 802.11n) used for pre-insertion signalling

SAE J3105 is a recommended practice for automated connection devices (ACD) that mate chargers with battery electric buses and heavy-duty vehicles. The practice is maintained by the SAE International with the formal title "Electric Vehicle Power Transfer System Using Conductive Automated Connection Devices Recommended Practice", and was first issued in January 2020. It covers the general physical, electrical, functional, testing, and performance requirements for automated conductive DC power transfer systems intended for heavy duty vehicles, focusing primarily on transit buses.

Contents

J3105 defines a common automated conductive charging system architecture so that any vehicle selecting one of the supplemental specific ACD implementations can use any charger that complies with that specific implementation, regardless of manufacturer, similar to how the earlier IEC 62196, SAE J1772, and SAE J3068 standards define the characteristics for a manually-plugged electric vehicle supply equipment interface.

History

SAE formed the Medium and Heavy-Duty Vehicle Conductive Charging Task Force in 2016 to develop a recommended practice for heavy-duty electric vehicle conductive charging. [1] Participants in the Task Force included transit bus manufacturers (Gillig, New Flyer, Nova Bus, Proterra), charger manufacturers (ABB, Heliox, Opbrid, Siemens, Toshiba), interface manufacturers (Furrer+Frey, SCHUNK, Stäubli, Stemmann), electric utilities (EPRI, SMUD, SCE), transit operators (APTA, CTA, King County Metro, LACMTA, NYCTA), and interested parties (ANL, CalStart, CEC, CTE). [1]

The Task Force first published the SAE J3068 recommended practice in 2018, building on work from existing international standards for charging using three-phase AC power. J3068 defines a manual Type 2 connector that can be used for both AC charging or DC charging up to 1000 V. [2]

General design characteristics

Transit operators may use opportunity charging [lower-alpha 1] to extend the range of electric buses while stopped on a layover. This is in contrast to depot charging, [lower-alpha 2] where the buses are charged at a common garage or storage facility while out of service. [4] :4 An ACD system may be used for both opportunity and depot charging. For instance, the Schipol Airport bus depot has overhead chargers at both 30 kW (depot charging) and 450 kW (opportunity charging) for its all-electric bus fleet. [3] :4

J3105 defines two current levels of DC charging, with supply voltage from 250 to 1000 V:

  1. Up to 600 A (350 kW)
  2. Up to 1200 A (1200 kW)

These levels are mutually compatible; for instance, a Level 1 vehicle could connect to a Level 2 charger and would receive an appropriate amount of power. [5] :8 Specific requirements for the charging station and communication are governed by IEC 61851-23 and ISO 15118.

When a vehicle approaches a charger, wireless communications via IEEE 802.11n will pair the vehicle and charger. The initial communication will be used to guide the vehicle's driver to an appropriate position so the connection can be made, and communications will go through the Control Pilot interface after the vehicle is connected. [5] :8

Relative sizes of the infrastructure-mounted connectors for the three J3105 implementations. J3105-1 includes the vehicle-mounted rails (arranged horizontally). The arrow indicates the forward direction of travel for the vehicle. SAE J3105 connections.svg
Relative sizes of the infrastructure-mounted connectors for the three J3105 implementations. J3105-1 includes the vehicle-mounted rails (arranged horizontally). The arrow indicates the forward direction of travel for the vehicle.

Only four interface connections are defined by J3105. The specific physical interfaces are defined in the supplemental recommended practices. [5] :7

  1.  +  DC Power (+)
  2.    DC Power (–)
  3.  PE  Ground / Protective Earth
  4.  CP  Control Pilot

Specific charging implementations

J3105 includes three supplemental recommended practices for specific ACD implementations:

  1. J3105-1 "Infrastructure-Mounted Cross Rail Connection" (or "Cross rail"): the overhead charging station extends contacts down on a pantograph to meet roof-mounted vehicle rails
  2. J3105-2 "Vehicle-Mounted Pantograph Connection" (or "Bus up"): the vehicle extends a pantograph up from its roof to meet overhead charging station contacts
  3. J3105-3 "Enclosed Pin and Socket Connection": the charging station extends a pin horizontally into a vehicle's roof-mounted socket

The physical characteristics are described in the specific ACD implementations. Each of the recommended practices for specific ACD implementations includes the conductor dimensions and spacing, and the required alignment and connection procedure.

A small amount of misalignment is tolerated, depending on the specific implementation:

J3105 nominal alignment requirements [6]
SupplementLocation [lower-roman 1] Roll angle [lower-roman 2] Pitch angle [lower-roman 3] Yaw angle [lower-roman 4]
Towards curbAway from curbUpDown
J3105-1
"Cross rail"		1,170 ± 150 mm
46.1 ± 5.9 in		3.5°3.5°5.0°5.0°5.0°
J3105-2
"Bus up"		0 ± 50 mm
0.0 ± 2.0 in [lower-roman 5] 		4.0°2.0°5.0°5.0°2.0°
J3105-3
"Pin"		1,000 ± 10 mm
39.37 ± 0.39 in		3,050 ± 10 mm
120.08 ± 0.39 in [lower-roman 6] 		5.0°5.0°5.0°5.0°5.0°
Notes
  1. Distance measured from centerline of front door to centerline of vehicle-mounted contacts, towards the rear of the bus, unless otherwise noted.
  2. Angle of vehicle body relative to a plane perpendicular to the street.
  3. Angle of vehicle wheelbase relative to the street plane.
  4. Angle of vehicle (along its length) relative to curb line.
  5. Measured to centerline of hood with charging contacts.
  6. Measured from ground vertically up to centerline of funnel.

Cross rail (J3105-1)

Bertrange, Volvo Electric Hybrid AVL (2).jpg
ABB cross rail charger with Volvo 7900 at the first OppCharge station
Station de recharge - Square-Victoria - 03.jpg
Retracted pantograph

In the cross rail ACD implementation (officially, "Infrastructure-mounted Cross Rail Connection"), a curbside charging station includes an overhead structure overhanging the street. After the bus pulls up to the charging station, contacts are lowered from the overhead charger on a pantograph and connect to rails mounted on the forward roof of the bus.

The cross rail implementation is marketed commercially as OppCharge (opportunity charging) and the OppCharge consortium, led by Volvo Buses, includes several bus and charging infrastructure manufacturers. [7] The first OppCharge station was deployed at the end of 2016 in Bertrange, Luxembourg by ABB for hybrid buses built by Volvo. [8] In the United States, the first OppCharge stations were deployed in 2019 by New Flyer Infrastructure Solutions as on-route chargers for the New York City Transit Authority along its M42 route. [9]

Bus up (J3105-2)

Connexxion 9758 pantograph detail.jpg
VDL Citea with a SCHUNK SLS 102 bus-up pantograph
SAE J3105-2 schematic.svg
Schematic showing pantograph head and infrastructure-mounted contact hood

The bus up ACD implementation (officially, "Vehicle-mounted Pantograph Connection") also uses an overhead charger, but the charging contacts remain fixed in place while the bus extends a pantograph up from its roof to meet the charger. The charging contacts are on the underside of a long hooded enclosure to facilitate the bus and charger contact connection.

The bus up implementation has been adopted by VDL Bus & Coach using chargers provided by Heliox, with both companies based in The Netherlands. The Amstelland-Meerlanden  [ nl ] charging depots at Schipol Airport were the largest electric bus charger installation in Europe when they were completed in 2018, including 23 450 kW opportunity chargers and 84 30 kW depot chargers from Heliox, servicing a fleet of 100 VDL Citea SLFA articulated buses equipped with bus-up pantographs. [10] [11] Heliox also introduced a dual-interface system compatible with both top-down (J3105-1) and bus-up (J3105-2) vehicles in 2018. [12]

Pin and socket (J3105-3)

Two pin sizes for J3105-3 SAE J3105-3 pin sizes.svg
Two pin sizes for J3105-3

In the pin and socket ACD implementation (officially, "Enclosed Pin and Socket Connection"), a pin is inserted horizontally from a curbside charging station into a socket with a guiding funnel on the roof of the vehicle.

The pin and socket implementation was developed by Stäubli, who market it as the Quick Charging Connector (QCC). [13] QCC has been implemented on a test basis at ports in Hamburg (6 charging stations and 25 automated guided vehicles [AGV]) and Singapore (3 stations and 22 AGVs). [14] In addition, the Port of Long Beach has announced its intentions to convert an existing fleet of 33 diesel-powered tractors to battery-electric drivetrains, which will include the installation of charging stations. The quantity of charging stations, built by Tritium and fitted with the Stäubli QCC system, will be sufficient to allow all 33 tractors to be charged simultaneously. [15] The Long Beach charger installation was completed in December 2023. [16]

Rejected implementation

A fourth ACD implementation ("Infrastructure-Mounted Blade Connection" or "Blade") was part of the preliminary development, but marketing was discontinued during development of the J3105 standard and the Blade implementation was not included in the initial issue.

Blade

Proterra Testing (19765330235).jpg
Proterra Catalyst and roof "scoop"
Proterra electric bus at Eastgate P&R (23543054351).jpg
Charger shoe, positioned above "blade" contact

The blade ACD implementation ("Infrastructure-mounted Blade Connection") is similar to the cross rail implementation, as both use an overhead charging device with a passive vehicle contact. However, in the blade implementation, a funnel-like "scoop" on the roof of the bus is used to mechanically guide the charger shoe onto a "blade" charging contact at the rear roof of the bus. The blade implementation is slower to engage than the cross rail, but the docking process to mate the vehicle to the charger is more automated.

The blade implementation was developed by Proterra for its line of battery-electric buses. Proterra offered royalty-free access to its patented design starting in 2016. [17] Despite this, the blade design was not adopted by other manufacturers and the blade implementation was eventually dropped from J3105 during development, some time after 2018. [3] :26  [4] :11 Proterra has since adopted J3105-1 (pantograph-down) or J3105-2 (pantograph-up) charging systems for newer buses. [18]

Notes

  1. Opportunity charging is also known as layover, on-route, or fast charging (350 kW+ charging rates). [3] :34 Because the charging is done while the bus is in revenue service, opportunity charging locations are selected by dwell times and route schedules. Fast chargers at high power are used to shorten charge times.
  2. Depot charging (also known as base or slow charging, 50 – 100 kW) [3] :34 is similar to operations with conventionally-fueled (diesel, natural gas, or hydrogen) buses, where refueling is performed at bus maintenance and storage depots. Depot charging can be performed at lower power because the charging buses will not be returning to service for several hours.

Related Research Articles

<span class="mw-page-title-main">G Line (Los Angeles Metro)</span> Bus rapid transit line

The G Line is a bus rapid transit line in Los Angeles, California, operated by the Los Angeles County Metropolitan Transportation Authority (Metro). It operates between Chatsworth and North Hollywood stations in the San Fernando Valley. The 17.7-mile (28.5 km) G Line uses a dedicated, exclusive right-of-way for the entirety of its route with 17 stations located at approximately one-mile (1.6 km) intervals; fares are paid via TAP cards at vending machines on station platforms before boarding to improve performance. It is one of the two lines in the Los Angeles Metro Busway system.

Avcon is a company that manufactures charging interfaces for battery electric vehicles (EV). The lettering convention is Avcon for the company and AVCON (capitals) for the EV charging connector.

<span class="mw-page-title-main">Inductive charging</span> Type of wireless power transfer

Inductive charging is a type of wireless power transfer. It uses electromagnetic induction to provide electricity to portable devices. Inductive charging is also used in vehicles, power tools, electric toothbrushes, and medical devices. The portable equipment can be placed near a charging station or inductive pad without needing to be precisely aligned or make electrical contact with a dock or plug.

<span class="mw-page-title-main">Battery electric bus</span> Electric bus which obtains energy from on-board batteries

A battery electric bus is an electric bus that is driven by an electric motor and obtains energy from on-board batteries. Many trolleybuses use batteries as an auxiliary or emergency power source.

<span class="mw-page-title-main">Charging station</span> Installation for charging electric vehicles

A charging station, also known as a charge point, chargepoint, or electric vehicle supply equipment (EVSE), is a power supply device that supplies electrical power for recharging plug-in electric vehicles.

<span class="mw-page-title-main">SAE J1772</span> Electric vehicle charging connector in North America

SAE J1772, also known as a J plug or Type 1 connector after its international standard, IEC 62196 Type 1, is a North American standard for electrical connectors for electric vehicles maintained by SAE International under the formal title "SAE Surface Vehicle Recommended Practice J1772, SAE Electric Vehicle Conductive Charge Coupler".

<span class="mw-page-title-main">Proterra (bus manufacturer)</span> American electric bus manufacturer

Proterra Inc. is an American electric vehicle and powertrain manufacturer based in Burlingame, California. The company designs and manufactures battery electric transit buses, battery systems for other heavy-duty vehicle builders and charging systems for fleets of heavy-duty vehicles. Founded in 2004, it became a public company in June 2021. The company delivered 199 new transit buses and battery systems for 1,229 vehicles in 2022. The company filed for Chapter 11 bankruptcy in August 2023. In November, its assets were auctioned to three companies.

<span class="mw-page-title-main">IEC 62196</span> International standards for vehicle charging technology

IEC 62196Plugs, socket-outlets, vehicle connectors and vehicle inlets – Conductive charging of electric vehicles is a series of international standards that define requirements and tests for plugs, socket-outlets, vehicle connectors and vehicle inlets for conductive charging of electric vehicles and is maintained by the technical subcommittee SC 23H “Plugs, Socket-outlets and Couplers for industrial and similar applications, and for Electric Vehicles” of the International Electrotechnical Commission (IEC).

Road powered electric vehicles (RPEV) collect any form of potential energy from the road surface to supply electricity to locomotive motors and ancillary equipment within the vehicle.

<span class="mw-page-title-main">Conductive charging</span>

Conductive charging is conductive power transfer that replaces the conductive wires between the charger and the charged device with conductive contacts. Charging infrastructure in the form of a board or rail delivers the power to a charging device equipped with an appropriate receiver, or pickup. When the infrastructure recognizes a valid receiver it powers on, and power is transferred.

<span class="mw-page-title-main">New Flyer Xcelsior</span> Transit bus vehicle

The New Flyer Xcelsior is a line of transit buses available in 35-foot rigid, 40-foot rigid, and 60-foot articulated nominal lengths manufactured by New Flyer Industries since 2008. In addition to the different available lengths, the buses are sold with a variety of propulsion systems: conventional diesel, compressed natural gas (CNG), diesel-electric hybrid, hydrogen fuel cell, overhead electric wire and battery electric. A future autonomous bus variant was announced in January 2021.

<span class="mw-page-title-main">Type 2 connector</span> Electric vehicle charging connector in Europe

The IEC 62196 Type 2 connector is used for charging electric vehicles, mainly within Europe, as it was declared standard by the EU. Based on widespread red IEC 60309 three phase plugs with five pins, which come in different diameters according to maximum current, a single size was selected, as maximum possible power will be communicated to the car via two additional communication pins and by a simple resistor coding within the cable. The onboard charger inside the car has to limit the current accordingly.

<span class="mw-page-title-main">SAE J3068</span> Electric vehicle charging standard

SAE J3068 "Electric Vehicle Power Transfer System Using a Three-Phase Capable Coupler" is a North American recommended practice published and maintained by SAE International. J3068 defines electrical connectors and a control protocol for electric vehicles. It has the formal title "SAE Surface Vehicle Recommended Practice J3068". J3068 defines a system of conductive power transfer to an electric vehicle using a coupler capable of transferring single-phase and three-phase AC power as well as DC power, and defines a digital communication system for control. J3068 also specifies requirements for the vehicle inlet, supply equipment connector, mating housings and contacts.

<span class="mw-page-title-main">Electric road</span> Road which supplies electric power to vehicles travelling on it

An electric road, eroad, or electric road system (ERS) is a road which supplies electric power to vehicles travelling on it. Common implementations are overhead power lines above the road and ground-level power supply through conductive rails or inductive coils embedded in the road. Overhead power lines are limited to commercial vehicles while ground-level power can be used by any vehicle, which allows for public charging through power metering and billing systems. Of the three systems, ground-level conductive rails are estimated to be the most cost-effective. Korea was the first to implement an induction-based public electric road with a commercial bus line in 2013 after testing an experimental shuttle service in 2009. Sweden has been performing assessments of various electric road technologies since 2013 and expects to start formulating a national electric road system in 2022 and finish planning by 2033.

The GB/T charging standard is a set of GB/T standards, primarily in the GB/T 20234 family, for electric vehicle AC and DC fast charging used in China. The standards were revised and updated most recently in 2015 by the Standardization Administration of China. The term is an abbreviation of 国标推荐 (guóbiāo/tuījiàn), translated as "recommended/voluntary national standard".

SAE J2954 is a standard for wireless power transfer (WPT) for electric vehicles led by SAE International. It defines three classes of charging speed, WPT 1, 2 and 3, at a maximum of 3.7 kW, 7.7 kW and 11 kW, respectively. This makes it comparable to medium-speed wired charging standards like the common SAE J1772 system. A much more powerful WPT9 is being defined in J2954/2 for 500 kW charging for heavy-duty vehicles which have the room necessary to mount the larger induction plate.

<span class="mw-page-title-main">Proterra Catalyst</span> American battery electric transit bus

The Proterra Catalyst is a battery-electric low-floor transit bus that was built by Proterra from 2014 to 2020. The second generation of Proterra's battery-electric buses, it succeeded the earlier EcoRide as the company's flagship product.

<span class="mw-page-title-main">Proterra ZX5</span> American battery electric transit bus

The Proterra ZX5 is a battery-electric, low-floor transit bus manufactured by Proterra since 2020. Succeeding the Catalyst as Proterra's flagship product, the ZX5 is the third generation of battery electric bus built by the company.

<span class="mw-page-title-main">Megawatt Charging System</span> Electric vehicle charging connector for commercial vehicles

The Megawatt Charging System (MCS) is a charging connector under development for large battery electric vehicles. The connector will be rated for charging at a maximum rate of 3.75 megawatts.

References

  1. 1 2 Shuttleworth, Jennifer (June 2018). "Conductive Automatic Charging Recommended Practice nears completion" (PDF). Automotive Engineering. Society of Automotive Engineers. Retrieved 6 November 2020.
  2. "SAE International Releases New Specification (SAE J3068) for Charging of Medium and Heavy Duty Electric Vehicles" (Press release). Society of Automotive Engineering International. April 26, 2018. Retrieved 6 November 2020.
  3. 1 2 3 4 Kosowski, Mark (October 22, 2019). "Transit Bus Fleet Size" (PDF). Electric Power Research Institute. Retrieved 7 November 2020.
  4. 1 2 Battery-Electric Bus Implementation Report: Interim Base and Beyond (PDF) (Report). King County Metro. January 2020. Retrieved 7 November 2020.
  5. 1 2 3 Kosowski, Mark (June 12, 2018). "SAE J-3105 Heavy-Duty Conductive Automatic Charging Recommended Practice" (PDF). Electric Power Research Institute. Retrieved 9 November 2020.
  6. Kosowski, Mark (March 10, 2020). "SAE J-3105 Heavy-Duty Conductive Automatic Charging Recommended Practice" (PDF). Electric Power Research Institute. Retrieved 9 November 2020.
  7. "Home Page". OppCharge. Retrieved 7 November 2020.
  8. "ABB delivers OppCharge fast charger for electric hybrid buses to Bertrange, Luxembourg" (Press release). ABB Group. December 21, 2016. Retrieved 9 November 2020.
  9. "New Flyer Launches U.S.' First OppCharge Charging Stations" (Press release). New Flyer of America. April 23, 2019. Retrieved 9 November 2020.
  10. Kane, Mark (April 27, 2018). "Heliox Launches Europe's Largest Opportunity & Depot Charging For Buses". Inside EVs. Retrieved 9 November 2020.
  11. "charging urban life" (PDF). Heliox. 2018. Retrieved 9 November 2020.
  12. Kane, Mark (November 25, 2018). "Heliox Introduces Multi-Standard Charging For Buses In Europe". Inside EVs. Retrieved 9 November 2020.
  13. "Automatic Rapid Charging Solution QCC" (PDF). Stäubli Electrical Connectors. Retrieved 7 November 2020.
  14. "Taking Charge". Land Sea Air. No. 178. March 12, 2020. Retrieved 9 November 2020.
  15. "Stäubli teams up for automated charging of electrical vehicles in port logistics" (Press release). Stäubli Electrical Connectors. July 22, 2019. Retrieved 9 November 2020.
  16. "Stäubli and partners complete North America's first mechanized large-scale port EV charging program". Green Car Congress. 4 December 2023. Retrieved 27 February 2024.
  17. "Proterra offers single-blade overhead fast-charging technology to transit industry on royalty-free basis". Green Car Congress. June 29, 2016. Retrieved 7 November 2020.
  18. "Proterra Catalyst Platform Introduction for the California Transit Association" (PDF). Proterra, Inc. November 14, 2019. Retrieved 7 November 2020.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.