Wireless Plug-in Electric Vehicle (PEV) Charging
John M. MillerOak Ridge National Laboratory
10 May, 2011
Project ID: VSS061
This presentation does not contain any proprietary, confidential, or otherwise restricted information
2011 U.S. DOE Hydrogen and Fuel Cells Program and Vehicle Technologies Program Annual Merit Review and Peer Evaluation Meeting
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Overview
• Start – Oct. 2010• Finish – Sept. 2013• 84% complete
• Plug-in Electric Vehicles (PEV) are burdened by the need for cable and plug charger, galvanic isolation of the on-board electronics, bulk and cost of this charger and the large energy storage system (ESS) packs needed.
• Wireless charging opportunity:• Provides convenience to the customer.• Inherent electrical isolation.• Regulation done on grid side.• Reduce on-board ESS size using dynamic
on-road charging.
• Program targets– Level II charging at 3.6kW to 19kW level– On road stationary charging– On road dynamic charging (vehicle in motion)
• Total project funding– DOE share – 100%
• Funding received for FY11– $400K
Timeline
Budget
Barriers and Opportunity
Partners/Advisors• ORNL Fusion Energy RF experts
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Objective
Objective for FY11• Develop an efficient method for transferring large power
levels over moderate distances in stationary setting– Loosely coupled magnetic resonant transformers have the potential to
accomplish this goal.– Target for Vehicle application: Level II 3.6kW, 200mm gap @ >90% efficiency
Overall program• Wireless charging of PEV stationary and dynamic conditions
– Demonstrate 90% transfer efficiency from plug to battery at SAE J1772 Level II power of 3.6kW to 19kW.
– Comply with SAE J2954 Wireless Power Transfer (WPT) emissions guidelines of 500uT in active zone and <62.5mG outside the active zone.
– Target for Vehicle application: Level III >60kW to vehicle in motion.
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Milestones
Month/Year Milestone or Go/No-Go Decision
Sept-2011 Milestone: Completed three (3) iterations of antenna designMilestone: Completed skin and proximity effect model and simulation to understand power loss mechanismsMilestone: Completed current sensor scale calibration
May-2012 Milestone: Demonstrate antenna design with field shaping and shielding sufficient to meet ICNIRP field levelsGo/No-Go Decision: Functional prototype meets field constraints and coil-to-coil efficiency >96%
Sept-2012 Milestone: Complete integration of wireless power transfer (WPT) into battery electric vehicle.Milestone: Complete integration of one (1) WPT into solar canopy charging station at ORNL.
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Approach• Design a system that first targets efficiency and then power
levels:− Optimum operating points for maximum efficiency are quite
different than for maximum power.• Simulate circuit to find “best” operating region and to
identify its required operating parameters.• Target methods for best magnetic coupling over moderate
distances and verify in the lab.– Vehicle ground clearance requirements:
• U.S. 200mm and European vehicles 150mm gap
– Dedicated power inverter needed• Design, analyze, simulate LCL inverter concepts at 3.6kW
– Design and demonstrate grid side vs. vehicle side controls• Energy Storage System (Battery) regulation and communications needs.
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Approach (contd.)
• Design and develop antenna system suitable for vehicle integration for stationary, on-road stationary and on-road dynamic charging at high power levels.– Technically: a non-radiating, near field reactive zone power transfer method– Practically: a convenient, safe and flexible means to charge electric vehicles.
Vehicle to WPT communicationsRFID localizer for positioning
Use existing on-board charger, or dedicated fast-charge and energy management strategy
Active zone field meets international standards (ICNIRP)
Smart grid compliant utility feed and modern power electronics
Graphic: Lindsey Marlar ORNL graphics services
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Approach (contd.)
• Wireless charging technical challenges:– Antenna coil field shaping, vehicle chassis/wiring shielding, alignment tolerance– Maximum power across active zone and minimal side lobe emissions
Vehicle graphic Lindsey Marlar, ORNL
Zone 1: Active field, ~1m2, <500uTZone 2: Transition:300mm boundaryZone 3: Public zone: Field focusing &
shielding <62.5mG (incl. cabin)
ORNL developed power inverter courtesy Gui-Jia Su.
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Approach (contd.)
• Wireless power transfer using magnetic resonance coupling of air core transformer.– Power converter to regulate and drive resonant coil system– Simple uncontrolled rectifier on secondary
• Prototype hardware identified sensor accuracy issue– Current sensors, especially flux nulling type, suffer from scale error in this
application.
Circuit diagram obtained from Dr. Matthew Scudirie of ORNL
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Approach (contd.)
• Antenna (coil) design is crucial to this program– Meeting plug to battery efficiency target demands very high coil-to-coil
efficiency
1st Gen 2nd Gen 3rd Gen
Copper tube (0.635mm), 2 in parallel, 3 turns overall:Rac = 16mOhmLs = 15.3 uH
Copper plate (2.37mm thich by 25.4mm width), 3 turns overall:Rac = 11mOhmLs = 15.3 uH
Copper tube (0.635mm) around plexiglass core for field shaping materials, 4 turns overallRac = xx mOhmLs = yy uH
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Approach (contd.)
• Current sensor issue added unanticipated tasks– Can exhibit significant scale error at operating frequency– Tests performed at 20kHz over full range of current for the following sensors:– LEM LA100S; LEM LC300S; Tektronix® probe TCP404XL
Scale error is repeatable Correction factor necessary for LEMTektronix current probe stable with current magnitude.
Charts courtesy of Dr. John McKeever of ORNL
Current Probe Calibration(Normal Trigger at 20 kHz)
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TCP404XL_2 LC300S_2 LA100S_2 TCP404XL_1 LC300S_1 LA100S_1
Runs _1 taken on 1/20/2011 Runs_2 taken on 1/27 2011
LEM LC300S Current Probe Calibration(Normal Trigger)
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Technical Accomplishments and Progress - Overall
• Completed fabrication of laboratory test apparatus– Two antennas are mounted vertically to allow easier access for experimental work. – The closer “mobile” antenna rides in a track that translates it in the direction of travel
to measure longitudinal displacement effects. – The transmitting antenna in the back could be adjusted to measure coil spacing (d) and
lateral displacement effects to study variation of coefficient of coupling (k).
Photo and chart courtesy of Dr. Matt Scudiere of ORNL
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Technical Accomplishments and Progress – FY11 (contd.)
• Evaluation of stacked “ribbon” antennas– ORNL evaluated the performance (Rac, Ls) of 1, 3 and 4 antenna coils in parallel– Very disappointing results due to substantial proximity effect in 2nd gen ribbon coil antenna.
Plot of coil field at 20kHz excitation in air
Source: coil CAD drawings courtesy Dr. Matthew Scudiere, Laboratory test data Dr. John McKeeverField flux plot simulation: Dr. Pan-Seok Shin
L and R of Ribbon Antennae
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L_4_3-turn Cu tubecoils
R_1_3-turn ribboncoil
R_3_3-turn ribboncoilscoils
R_4_3-turn ribboncoils
R_4_3-turn Cu tubecoils
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Technical Accomplishments and Progress – FY11 (contd.)
• Experimental finding that multiple “ribbon” antennas operating in parallel offer no benefit in terms of loss reduction.– Two such coils in close proximity (~15mm) exhibit virtually unchanged Rac and Ls
Top: End on view of flux lines for 3 turn ribbon coil antenna. Bottom: end on view of ribbon coil conductor current density plots shown extensive skin effect and proximity effects in two outside bars.
Source: Field flux plot simulation: Dr. Pan-Seok Shin
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Technical Accomplishments and Progress – FY11 (contd.)
• RF experts at ORNL Fusion Energy modeled and simulated the copper tube antenna system showing coil-coil efficiency ~96% =(S21)2
– Reflection coefficient S11 and transmission coefficient S21 analyzed wrt coil spacing d.– Top chart shows S11 and S21 when k=0.244 and bottom chart S11 and S21 when k=0.138
Source: Dr. John Caughman ORNL Plasma Tech. & Appl., Fusion Energy Division (FED)
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S11_S21 z17x00 data
S21 mag calcS21 mag
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Coil spacing = 17.2 cmFull overlap
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S11_S21 z17x00 data
S11 mag calcS11 mag
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S11_S21 z30x00 data
S11 mag calcS11 mag
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Coil spacing = 30.0 cmFull overlap
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S11_S21 z30x00 data
S21 mag calcS21 mag
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MathCad kfac LC data
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Coil Spacing (cm)
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Technical Accomplishments and Progress – FY11 (contd.)
• ORNL APEEM experimental work measured the transfer efficiency results for the copper tube coil antenna design as function of frequency.– Efficiencies >95% were obtained coil-coil, but power factors were low!
– Power factor versus Transfer Efficiency does not include the H-bridge converter. A commercial, or purpose designed (sister project), inverter will have better efficiency.
– Low power factor means a larger inverter is necessary, or, the resonant design shifts from the present LC to an LCL design.
Source: Dr. Matthew Scudiere and Dr. John McKeever ORNL APEEM
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Collaborations
• ORNL Plasma Energy & Applications, Fusion Energy Division– Dr. John Caughman, Dr. Timothy Bigelow, Dr. Phillip M. Ryan
• SAE J2954 Wireless PEV Charging Task Force– Mr. Jesse Schneider (BMW) chairman
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Future Work
• Remainder of FY11– Design, model, simulate and fabricate 3rd Gen antenna and
demonstrate coil-coil efficiency, field focusing and shielding.– Subtask on dedicated inverter to demonstrate kW/kVA0.5– Demonstrate plug to secondary rectifier output eff>90%
• FY12– Design, model, simulate and fabricate strip line power cables– Characterize antenna shielding effect in proximity to concrete
and vehicle chassis floor pan galvaneal.– Refine design for vehicle integration and stationary vehicle
charging demonstration.
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SummaryFY11 Accomplishments• This project has demonstrated an efficient wireless power transfer
technology capable of transferring large power levels over coil-coil gaps commensurate with vehicle ground clearance.
• Loosely coupled magnetic resonance transformer approach is shown to have the best performance.
• New antenna designs are underway to address shielding and field focusing to minimize emissions.
• Impacts– Wireless charging eliminates the inconvenience of plug and cable.– Introduces inherent electrical isolation into the charging process.– Regulation can be done grid side with short range communications
to/from the vehicle over Zigbee, active RFID, others.– Opportunity for on-board energy storage system size reduction.