Plug-in Electric Vehicles and the electrification of road transport
Hunwick Consultants
Presentation to Sydney Mechanical ChapterEngineers Australia
June 18th, 2009
Richard [email protected]
www.hunwickconsulants.com.au
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Our main energy policy concerns
• Long-term price and availability of petroleum.• Imbalances in trade/current accounts.• Rising greenhouse gas emissions.• Increasing “peakiness” of electricity demand.• Barriers to the adoption of renewable energy.• Demand for ever higher power supply reliability.• Urban air pollution esp. photochemical smog.
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A focus on fuelling road transport
Road transport depends on petroleum-based fuels.700 million motor vehicles now registered worldwide. This number will grow rapidly, probably to:
1 billion by 2015, 2 billion by 2030, 4 billion by 2050.
Growth in demand for diesel is faster than for petrol.Aviation and shipping (both growing rapidly) also depend on petroleum-based fuels.
There is no way that petroleum can hope to fuel all of these vehicles over the long term.
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Reducing our petroleum dependency Should the world (and Australia) seek to change:
The fuels that existing types of vehicles use? Or, changeThe vehicles so they can run on other existing energy sources/carriers notably electricity? Or, changeTo new both: i.e. to new vehicles and new energy sources/carriers notably hydrogen? Or, changeTo new infrastructures that reduce the need for motor vehicles—must apply to freight as well?It takes time to bring about significant change, not just new technology. Resources (financial and human)—all are fundamentally scarce.
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Time: the scarcest resourceConsider what can be accomplished in a decade:
Build any major infrastructure e.g. base-load power station.Once built, their lifetimes will be at least 5 decades.But,Motor vehicle fleets almost fully turn over in that time.
The logical conclusion: It makes most sense to change to new vehicle types designed to run on other non-petroleum fuels/energy carriers than to change to new fuels suitable for existing vehicle types.There is only one “fuel” good for the very long-haul: Electricity, via Plug-in Electric Vehicles (PEVs).
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Following sections address:
What are PEVs?Their potential impacts on our electricity supply systems, including on: - total energy and power requirements, - electricity demand patterns (peakiness), - the adoption of renewable energy sources, and - demand for ever higher power supply reliability.Barriers to the adoption of PEVs.What should we be doing?
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What are PEVs?Plug-in Electric Vehicles fit into a continuum best defined by their amount of on-board electricity storage:
Normal light
vehicles<0.1 kWh
All-electric (plug-in)
vehicles (EVs)>25 kWh
Example:Tesla Roadster, 56 kWh
Plug-in HEVs
(PHEVs)5-25 kWh
Examples:A123/Hymotion Prius conversion: 7 kWh;GM Volt, 16kWh
Hybrid-electric vehicles (HEVs)1-2 kWh
Example:Toyota Prius, 1.3 kWh
LOW HIGH
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Hybrid electric vehicles (HEVs) HEVs use electricity and hydrocarbon fuels to drive wheels. But the vehicle’s sole energy source is the hydrocarbon fuel. HEVs can yield up to 50% better fuel economy (city), by:
regenerative braking; turning off IC engine when the host vehicle is stopped;controlling the IC engine to operate more efficiently.
HEVs come in two flavours: Parallel and Series.Parallel HEVs: both the internal combustion engine and electric motor(s) drive the wheels. Toyota Prius the familiar example.Series HEVs: The IC engine only drives a generator, which supplies power to batteries and wheel-drive electric motors. Diesel-electric locomotives and heavy off-road haul trucks are examples.
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Plug-in hybrid-electric vehicles (PHEVs).
Are as for HEVs, but can plug into the electricity grid.On-board batteries allow 30 to 100 km urban-cycle driving.If battery charge gets too low, the ICE cuts in to recharge battery and/or provide motive power to the wheels.As power demand increases, the ICE cuts in to supplement electric motor (parallel type only).Vehicle batteries can be recharged from a standard power point, pref. overnight: Grid to vehicle concept (G2V).And, parked and plugged-in PHEVs can supply power in the reverse direction: Vehicle to grid concept (V2G).
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The first Prius PHEV conversion: in USA-2004
Source: www.calcars.org
Lead-acid batteries15 km electricity-only drive range.
Achieved 2.25 l/100km gasoline fuel economy
In 2006, Li-ion batteries replaced lead-acid, for 50 km all-electric range
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Most auto makers now have PEV programs
Source: www.calcars.org
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A cottage industry: Prius conversions
EnergyCS (California)Existing Prius 1.3 kWh NiMHbattery replaced by 9 kWh Li-ion battery pack.Conversion cost: n.a.
A123 Hymotion (Canada)Retains existing Prius NiMHbattery pack, adds 5 kWh Li-ion battery pack.Conversion cost: c. US$12,000
These conversions are expensive, void Toyota’s warranties and are limited by the Prius’ 21 kW electric motor power. Sources: www.calcars.org
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BYD Auto, ShenzenHybrid-electric (F3DM) andall-electric e6).F3DM on sale now, in China.Warren Buffet’s BerkshireHathaway owns 10%.
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The GM Voltseries PHEV16 kWh Li-ion battery2011 Production version
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A series PHEV conversion
PML Flightlink PHEV Mini (UK) a series PHEV conversion:Configuration: In-wheel motor-generators (4).Batteries: Li-polymer, 21 kWh Ultracapacitor : 350V, 11 Farad, 700A IC engine: 15 kW 2-cylinder 250 cc gasoline Performance: 0-100 km/h in 4.5 sec. Top speed: 240 km/hr Peak power: to 475 kW Braking: No mechanical brakes
Source: www.pmlflightlink.com
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Volvo Recharge PHEV concept.
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Audi Metroproject quattro concept PEVAs shown at October 2007 Tokyo Motor Show
• An example of a “through the road” hybrid (front wheels ICE, rear wheels electric).
• Rear wheels, powered through the road, charge the batteries.
• Concept lends itself to retrofitting existing cars, to convert them to PEVs—and 4WD
• 110 kW petrol motor, 30 kW electric motor, 440 Nm torque with both!
• Up to 100 km all-electric range with Li-ion batteries.
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Tesla Motors Roadster (an all EV)At the LA Motor Show 2006, charging arrangements, rotor of motor/generator (175 kW) at right.
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G2V and V2GCombined with smart meters and control software:
When PEVs are plugged in, power can flow both ways: - grid to vehicle (G2V) (battery charging) and- vehicle to grid (V2G) (grid support).PEVs will soon represent a vast stored electricity resource.Host buildings have a power supply on hand.Renewables-based electricity surplus to immediate needs can be stored in PEV batteries.
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AC mains
Char
ge
Power conditioning and control
DC bus
Energy storage
Case 1: Power spot price <$25/MWh.
Parked plug-in hybrid-electric vehicle
Plug
On-board generator
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Power to/from drivetrain (off)
AC mains
Dis
char
ge
Power conditioning and control
DC bus
Energy storage
Case 2: Power spot price >$150/MWh
Parked plug-in hybrid-electric vehicle
Plug
On-board generator
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Power to/from drivetrain (off)
AC mains
Power conditioning and control
DC bus
Energy storage
Case 3: Power spot price >$300/MWh.
Parked plug-in hybrid-electric vehicle
Plug
On-board generator
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Power to/from drivetrain (off)
Impact of PEVs on load-duration curves
V2G
G2V Without PEVs
With PEVs
0 4,000 6,000 8,000
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2,000 Hours per year
Pow
er d
eman
d
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PEVs in the Australian vehicle fleet. Case 1: Modest support ($2,000/vehicle, falls to $400)
0
2,000
4,000
6,000
8,000
10,000
12,000
14,000
16,000
2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030Year
Tota
l veh
icle
s re
gist
ered
, '00
0
0
4,000
8,000
12,000
16,000
20,000
24,000
28,000
32,000
Pet
role
um fu
el c
onsu
mpt
ion,
Ml/y
ear
Total cars on road, '000Total PHEVs regd, '000Total petr. cons.Ml/yr, no EVsTotal petr. cons.Ml/yr, with EVs
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PEVs in the Australian vehicle fleet. Case 2: Medium support ($5,000/vehicle, falls to $1,100)
0
2,000
4,000
6,000
8,000
10,000
12,000
14,000
16,000
2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030Year
Tota
l veh
icle
s re
gist
ered
, '00
0
0
4,000
8,000
12,000
16,000
20,000
24,000
28,000
32,000
Petro
leum
fuel
con
sum
ptio
n, M
l/yea
r
Total cars on road, '000Total PHEVs regd, '000Total petr. cons.Ml/yr, no EVsTotal petr. cons.Ml/yr, with EVs
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PEVs in the Australian vehicle fleet. Case 3: Aggressive support ($8,000/vehicle, falls to $1,600)
0
2,000
4,000
6,000
8,000
10,000
12,000
14,000
16,000
2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030Year
Tota
l veh
icle
s re
gist
ered
, '00
0
0
4,000
8,000
12,000
16,000
20,000
24,000
28,000
32,000
Petro
leum
fuel
con
sum
ptio
n, M
l/yea
r
Total cars on road, '000Total PHEVs regd, '000Total petr. cons.Ml/yr, no EVsTotal petr. cons.Ml/yr, with EVs
Results from modelling, 2010-2025
CaseMinimal support
Medium support
Aggressive support
Cumulative cost of support ($billion)
$1.1 $7.3 $20.0
Cum. import savings ($bn) $100/barrel
$14.4 $36.0 $57.6
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Impacts on electricity demand & supplyOf all registered PEVs, on average:
Half are parked and connected to grid at any time 6am-8pm.Stored energy available in each parked vehicle: 10 kWh.Charge/discharge rate of each parked vehicle: 10 kW.
Most of this electricity storage capacity would be paid for by the motorist (distributors might well pay for the parking charge/discharge infrastructure).
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Minimal PHEV market growth
Aggressive PHEV market growth
Energy storage represented by parked PEVs, Australia
0
5
10
15
20
25
30
35
40
45
50
55
60
2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030Year
GW
, GW
h
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0
40,000
80,000
120,000
160,000
200,000
240,000
280,000
320,000
360,000
400,000
2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030Year
Ele
ctric
ity c
onsu
mpt
ion,
GW
h p.
a.
Electricity use by PHEVs GWhElectricity use, non transport, GWh
Electricity demand from PEVs, aggressive growth
PEV’s: the incentives mapLikely to be (or at least should be) in favour:
The electricity supply industry (ESI), esp. distributors, retailersBase-load power generators.Renewable energy producers: solar and wind.Governments.
Perhaps less likely to be in favour:
Some oil companies.Some car companies.Peak-load power generators.
What about the motorist (business as well as private)?
Will like dramatically lower fuel costs.Will like low maintenance costs, performance, low noise. Won’t like sticker prices in early years.
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Is there an emerging consensus?Recent statements from overseas sources:
“Electricity in transportation has to be done. It is urgent. It is so important that everything else is secondary… the drumbeat of the electrical transportation is accelerating like nothing I've ever seen in my life.”
Andy Grove, former CEO Intel Corp.I would invest $150 billion over the next 10 years to create green jobs, particularly in the automotive industry and to improve the electricity grid so people can drive plug-in hybrid vehicles… We should make sure that every government car is a plug-in hybrid."
USA president-elect Barak Obama.“We will introduce an all-electric car in 2010 in the United States and Japan, and we will mass-market it globally in 2012….People today are very interested in cars that are good for the environment, and we believe there is strong latent demand for electric cars.
Renault and Nissan CEO Carlos Ghosn
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What about the utilities?"Through this capability (PEVs), we're able to reduce stress on the grid during peak periods and keep rates low "
David Mohler, Chief Technology Officer, Duke Energy
“Electrification of road transport is one of the last frontiers for electricity and a key to reducing oil-dependency and cutting CO2 emissions.”
Lars Joseffson, CEO Vattenfall
“This innovation…strives to reconcile the challenges of individual mobility, economic growth and environmental impacts.”
Pierre Gadonneix, President and CEO, Electricité de France (EdF)
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Barriers to the adoption of PEVs
Lithium batteries are still too expensive, and have lingering safety concerns, but costs falling rapidly. Cheaper alternatives e.g. CSIRO-developed Ultrabattery, OK for many commercial vehicles: buses, rigid trucks.Parallel PEV designs (the only type currently on the roads) don’t represent the future, being complex and expensive.(Series PEVs do: they allow elimination of mechanical transmission, mechanical/hydraulic brakes, large IC engines.)By 2015 PEVs likely to have a price premium c. A$5000.
PEVs are coming--if any incumbents resist the trend, demand will be met from upstart Chinese or Indian manufacturers.
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A range of adoption alternatives
Alternatives available may demand choices:The Better Place business model.Hybrid-electric or all-electric.
Which is best for: The electricity supply industry?Renewable energy development?Local design and manufacture?An after-market PEV conversion industry?
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What, then, should we be doing?State (and local) governments can encourage:
Use of qualifying PEVs by giving them access to transit lanes, bus lanes, parking spaces, reduced registration fees.Departments, SOCs, Councils, purchase PEVs for their fleets.Electricity distributors to install charging stations and draft standardised charging and V2G contracts.
The Federal Government can encourage:Local manufacture of Series PEVs and key components by vehicle & parts manufacturers (via $500 million “green car”fund?)Adoption (including conversions) of PEV-based buses and rigid trucks by tax concessions/rebates.
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Last word:PEVs represent a disruptive technology, above all for the electricity supply industry.Yet they may well be the energy policy silver bullet
Thank you
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