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WWS402: Renewable Energy and the Electric Grid
Professor Harold Feiveson
Plug-in Vehicles and Vehicle To Grid Technology
Jonathan Moch
5/03/11
Student Honor Code Pledge:
I pledge my honor that this paper represents my own work in accordance with University regulations.
Signature: Jonathan Moch
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Executive Summary
The plug-in hybrid electric vehicle and the plug-in electric vehicle, collectively referred
to as electric vehicles, have enormous potential to reduce carbon emissions, improve urban air
quality,and reduce American reliance on foreign oil.
Electric vehicles, if adopted on a large scale, also portend a significant new load on the
American electrical infrastructure, and could cause new demand peaks and exacerbate existing
power management issues. However, with the use of smart charging policies and technologies
to manage electric vehicle charging times, stresses on the electric infrastructure can be greatly
reduced.
Currently significant resources are being invested in electric vehicle research and
development, with the goals of reducing the overall cost of these vehicles and significantly
increasing driving range by developing a new generation of advanced batteries. Still, at existing
costs and capabilities, electric vehicles remain reliant on extensive state and federal subsidies
to be economical for the average American driver.
Vehicle to Grid technology (V2G) has the potential to enhance the benefits from electric
vehicles and reduce infrastructure stresses from electric vehicle deployment, all the while
generating a profit for utility companies, auto companies, and the consumer. V2G enabled
vehicles would be equipped for bi-directional electric flow when connected to the grid, have on
board metering, and have two-way communication with grid operators.
V2G enabled vehicles would provide regulation demand services to the grid via small
adjustments in electrical flow to and from the battery. In addition to earning profits for vehicle
owners, V2G regulation services could also be of value to utilities.
V2G enabled vehicles can also be used to store and return electricity from intermittent
renewable energy sources such as wind and solar. Through regulation and storage of
intermittent energy, a V2G fleet equivalent to 11% to 41% of the current American light duty
vehicle fleet would have the ability to support wind energy equaling to 50% of current total US
power generation
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Background
Overview of Electric Vehicles
In his 2011 State of the Union Address, President Obama highlighted a goal of having
one-million electric vehicles (EVs) on the road by 2015.1The American Recovery and
Reinvestment Act of 2009 (ARRA) therefore provided $2.4 billion dollars to accelerate the
manufacturing and deployment of the next generation of U.S. batteries and electric vehicles,2
the plug-in hybrid electric vehicle (PHEVs) and the plug-in electric vehicle (PEV). The widespread
adoption of EVs offersa method of significant greenhouse gas emissions reductions that also
enjoys broad auto and power industry support.3
The major difference between EVs, which include PHEVs and PEVs, and existing hybrid
electric vehicles (HEVs) such as the Toyota Prius, is that plug-in vehicles contain larger advanced
batteries, and are better designed to connect to the electric power grid. EVs store electricity
from the grid in an onboard battery, which is then used to power and electric motor. In
contrast, energy stored in a HEV battery is originally derived from an internal combustion
engine.A PEV contains only an electric motor, and must be plugged into the grid to fully
recharge the battery.Some energy, however, can be recovered with regenerative breaking
technology, which involves slowing the vehicle by absorbing its energy and converting the
mechanical energy back into electricity which can be stored in the onboard battery.4 Once a
PEVs battery runs out of charge, the vehicle is no longer able to function, just as when
1Obama, 2011
2The White House Office of the Press Secretary. 2009
3Clay, 2010.
4U.S. DOE, 2003
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conventional cars run out of gas. PHEVs, on the other hand, also contain an internal
combustion engine. PHEVs are capable of running purely on the energy stored in the battery
for as long as the battery contains electricity, after which the car can continue to run by using a
conventional internal combustion engine. The PHEV battery can be recharged by plugging into
an outlet, by capturing energy from the internal combustion engine, , or by using regenerative
braking.5
A traditional hybrid electric vehicle, in contrast, produces its electricity via small
onboard generating plants that are driven by a conventional internal combustion engine.
Electricity from these onboard generating plants is then fed to an electric motor which can be
used to move the vehicle. Electricity generated by the car can also be stored in an onboard
battery, which is further charged by recovering energy lost when braking. Energy stored in a
HEVs onboard battery can then be used to provide extra power to the electric motor when
accelerating or be used as a sole source of energy for the vehicle, depending on the HEVs
design.6
The Current State of Electric Vehicles: The Nissan Leaf and The Chevy Volt
In the winter of 2010, Nissan introduced the Leaf, the first PEV from a major car
company. The Leaf is advertised to travel 100 miles per charge and is currently being sold in
California, Oregon, Washington, Arizona and Tennessee.
7
It has a suggested retail price of
$32,780; however, with federal tax credits of up to $7,500, the price to the purchaser can be
5Pratt, et al. 2010
6U.S. DOE, 2003
7Vlasic, 2010 Leaf
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reduced to $25,280.8 In addition, many tax incentives exist at the state level, such a $2500 cash
rebate towards the Leaf in Tennessee and a $5,000 tax credit toward the purchasing of a Leaf in
California, further decreasing the price.9
Shortly after the release of the Leaf, General Motors introduced the Chevy Volt, a PHEV,
with a suggested retail price of $40,280. As with Nissan, G.M. is relying on the governments
$7,500 tax credit to reduce the purchasing price to $32,780. The Volt is designed to go 35 miles
using the electricity stored in the battery, after which it switches to an internal combustion
engine that works with the electrical motors to give the car an additional 340 miles using one
tank of gas.10
To recharge, the Volt can connect to a standard 120-volt outlet and is projected to
cost owners between $1 and $1.50 per charge. The Volt is currently sold at only 600 designated
Chevrolet dealers in 6 states, but GMplans to expand sales nationwide by 2012.11
The $7,500 tax credit that applies to both the Volt and the Leaf is supplemented by
giveaways of free homecharging units from the EV Project, a $230 million national program
financed by several government agencies, utilities and corporations.12
The home charging units,
which have a retail cost of $3,000, are designed to charge the cars battery in 4-6 hours using
220-volt power. 5,700 of the chargers were randomly given to Leaf buyers and 2,600 to Volt
purchasers. In addition to providing free home charging units, the EV Project will build 15,000
charging stations in 18 cities in the States where the Volt and Leaf are being sold.Using data
8Nissan, 2011
9Vlasic, 2010
10General Motors, 2011
11Bunkley, 2010. Volt
12Vlasic, 2010
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2009 and 2013, and the US will be able to produce enough components and batteries to
support 500,000 EVs.18
Building on ARRA grants, President Obamas 2011 budget proposed a three-part
advanced technology vehicle plan that includes support for electric vehicle manufacturing and
adoption in the US through consumer rebates, investment in research and development, and a
competitive program to incentivize community investment in electric vehicle
infrastructure.19The first part of plan involves changing the existing $7,500 tax credit for an EV
to a rebate modeled on the Cash for Clunkers program. By changing the tax credit to a rebate,
the administration hopes to make EVs more financially feasible for American families by making
sure they do not have to wait until after paying taxes to receive the credit.20 The R&D section
calls for expanding regular funding for EV technologies by 90%, to nearly $590 million, with
goals of further reducing battery cost and creating a battery able to power a vehicle for 300
miles on a single charge.21
The competitive grant program has already begun, with the
Department of Energy (DOE) issuing $10 million grants to communities that show concrete
reforms and an ability to use funds to enhance EV deployment. The DOE grants are targeted
toward infrastructure improvements, conversions of vehicle fleets and creation of EV incentives
such as special parking and HOV lane access.22
18Ibid.
19Ibid.
20Ibid.
21Ibid.
22Ibid.
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Costs and Benefits of Electric Vehicles
Reductions in Carbon Dioxide Emissions
In 2009, the net carbon dioxide emissions from fossil fuel combustion were 5,212 Tg CO2
equivalent.23 Of that, 1,723.3 Tg CO2 equivalent (33%) were from combustion in the
transportation sector.24Therefore, to meet President Obamas goal of reducing US CO2
emissions to 83% below 2005 levels by 2050,25
the transportation sector must play a
role.Widespread use of EVs has the potential for significant reductions in carbon emissions
simply due to the higher energy efficiency of an electric motor when compared to an internal
combustion engine.26An internal combustion engine has an energy efficiency of around 25%,
while the energy efficiency of an electric motor and battery system is around 65%.27,28
Due to
the inherent efficiency gains with a switch to EVs, even in a scenario where EVs derive almost
all of their electricity from coal based power plants, an EV results in 28% to 34% lower
emissions when compared to conventional vehicles.29For the current grid and todays mix of
power plants, it is estimated that if every conventional vehicle from a fleet with an average fuel
economy of 20.7 mpg were replaced by EVs, it would result in a 27% carbon emissions
reduction for the entire nation, equivalent to an 81% reduction in transportation emissions.
23U.S. EPA, 2011
24Ibid.
25 Broder, 200926
Kinter- Meyer, et al. 2007.27
Energy efficiency is the ratio between the amount of energy put into a system, here an engine, and the amount
of energy harnessed by the system for some particular purpose, generally termed work. Energy not harnessed to
do work is generally lost as heat. Energy efficiency is written as (useful output)/(total input), so a machine with a
high energy efficiency is able to do more work for a set unit of energy than a machine with a low energy efficiency.28
Prat, et al. 201029
Ibid. p 117.
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As non-fossil fuel and natural gas energy sources are added to the grid, CO2 emissions
reductions compared to conventional vehicles will increase further, as a result of efficiency
gains combined with lower fossil fuel intensity. In 2010, 53% of the net electricity generation
was from natural gas, nuclear, hydroelectric or renewable sources, all of which have
significantly lower CO2 emissions per kilowatt hour (kWh) than coal-generated electricity.30
Therefore, as a national average, a conversion to EVs right now would already have significantly
higher CO2 reductions than those due to the higher energy efficiency of the electric motor. EVs
will also take multiple mobile emissions sources and concentrate their emissions in a much
smaller number of stationary generators. These, in turn, could be the targets for future
emissions reductions, such as through carbon sequestration, which would not have been
possible or cost effective with the dispersed emissions from internal combustion engines.31
Overall Improvements in Local Air Quality
Because EVs have no emissions while in electric drive mode, EVs have the potential to
significantly improve local air quality, especially in densely populated urban areas with high
vehicle traffic. Along with carbon dioxide, fossil fuel combustion also produces various other
gases that cause local air pollution issues, so by shifting to EVs, tailpipe emissions of pollutants
will be shifted to generators, which are generally outside of population centers. From there
pollutants will be transported over regional scales (10-100 kilometers), resulting in a much
lower exposure in population centers due to the dilution, deposition and chemical
30U.S. Energy Information Administration, 2011
31Peterson, et al. 2011
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transformation of the pollutants during transport.32 However, one side effect of moving
pollution sources from tailpipes to generators is that air quality around power plants will be
slightly degraded. Thiscould polarize relationships between urban and rural communities and
result in construction of new power plants meeting more local resistance.33
When compared with tailpipe emissions, the average fossil fuel based generator emits
less nitrogen dioxide and nitric oxide (NOx), as well as less carbon monoxide (CO) and volatile
organic compounds (VOCs) due to the more complete combustion and the nature of the fuels
used. However, coal based generators also have much higher sulfur dioxide (SO2) emissions
when compared with gasoline combustion. Because of the current emissions profile of
American power generation, a switch to EVs is projected to decrease total NOx emissions,
reduce total VOC emissions, and slightly increase SO2 emissions.34This reduction in NOx and
VOCs, coupled with the fact that emissions will occur away from population centers, brings the
potential to significantly reduce urban ozone pollution and photochemical smog, which is
created due to chemical interactions of NOx, VOCs and sunlight.35 Although EVs will place
upward pressure on SO2 emissions, due to the cap on SO2 emissions from the Clean Air Act,
total SO2 emissions are unlikely to increase as a result of increased EV usage.36
32Sioshansi, 2009
33Sovacool and Hirsh, 2009
34Peterson, et al. 2011
35Brasseur, Orlando and Tyndall. 1999.
36Peterson, et al. 2011.
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One of the main draws of EVs for a consumer is that of lower gasoline costs. On average,
it costs an EV about $1 to travel as far as a conventional internal combustion engine vehicle
would on a gallon of gasoline, assuming the EV is compared to a conventional vehicle that
averages 30 mpg.42
Savings from reduced gasoline costs would add up to a savings of
approximately $600 per year for the average American driver,43 an amount that could make EVs
economical for many drivers if subsidies are accounted for. In addition, EVs have fewer moving
parts than traditional vehicles and therefore should require less maintenance.44
Although EVs could eventually save money, initial prices still are high enough that EVs
are more expensive than conventional vehicles for most Americans, and therefore EVs will
remain reliant on large federal and state subsidies.45Even for the cases when EVs could be
economical, most American families do not analyze fuel costs in any systematic way when
purchasing a new vehicle.46 After purchasing gas, most people rapidly forget how much money
was spent, and therefore when purchasing a vehicle most consumers are not able to calculate
how much they could save due to a reduction in gasoline use. Consumers instead make
significant errors estimating potential savings over time.47
Furthermore, EVs suffer from a range anxiety problem, where prospective buyers are
worried that the battery of the EV will be insufficient for their driving needs and will leave
42Letendre, et al. 2006
43Sana, 2005.
44Sovocool and Hirsh. 2009.
45Keller, 2010
46Turrentine and Kurani, 2007.
47Ibid.
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themunable to make longer trips.48This problem is exacerbated by the fact that currently, EVs
can only be charged at home, work or specific charging stations, and require at least 3 hours of
charging time49
depending on the type of battery and voltage at which the battery is charging.
In some cases obtaining a full charge can take up to 12 hours.50
The charging infrastructure for
EVs is also extremely limited, with charging stations just starting to be built around the country.
51 Even stopping at a 440 volt quick charging station would still require 30 minutes or more to
reach a complete charge, significantly longer than the average time spent at a gas station.52
Taken together, the long charging times and sparse locations will make EVs limited to mostly
congested urban areas until charging times drop, battery capacity increases, and/or
infrastructure improves.53
Load Management Issues
Along with providing a significant new source of revenue for utilities, the electrification
of the transportation sector will also significantly increase the load on the existing power
infrastructure. This increase in load has the potential to overwhelm existing primary and
secondary distribution networks, as many of the circuits involved do not have spare capacity.54
Currently, EVs on average require 0.2 to 0.3 kWh of energy for each mile of driving.55 For a
vehicle such as the Chevy Volt with a 30-40 mile all electric range, 7 to 10 kWh will be required
48 Kitman, 2010.49
Ipakachi and Albuyeh, 2009.50
Pratt, et al. 201051
De Lorenzo, 2010.52
Knittel, 201053
De Lorenzo, 2010.54
Ipakachi and Albuyeh, 200955
Ibid.
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to fully charge the battery.56If charging occurs using a standard 120-volt outlet, fully charging
the battery for a Chevy Volt may take anywhere between 3 and 8 hours for 3.3 kW and 1.4 kW
charging respectively.57
More advanced batteries, such as those currently being designed with
ARRA funds, may require significantly longer charging times due to a larger capacity. Batteries
capable of enabling 220 miles of driving on a single charge may take 33 hours to completely
charge when plugged into a standard outlet.58
In order to reduce charging times, 240 volt charging may become the norm for EVs, and
240-volt outlets are currently required for new garages in California, which expects high EV use
in the future.59
However, 240-volt charging also doubles the peak load impact of unmanaged
charging, therefore reducing the number of EVs that the grid can support by half, to around 70
million vehicles.60 Most studies assume that 80% to 90% of EV charging will occur at night,
when commuters return from work.61This period of nighttime charging will partially coincide
with peak electricity demand in many regions, and therefore may both set new system peaks or
increase current peak electricity demand depending on the region.62 For example, for a typical
California house, EV charging doubles the household load when plugged into a standard
outlet.63Charging at a higher voltage further increases the household load.64
56Ibid.
57 Ibid.58
Ibid.59
Pratt, et al. 201060
Ibid.61
NERC, 201162
Pratt, et al. 201063
Ipakchi and Albuyeh, 2009.64
Ibid.
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Figure 1: The impact of plug-in vehicle charging on the residential home load profile for atypical Southern Californian home.
65
Most of the electricity distribution systems currently used in the US were put into use
over a decade ago, and were based on the loading analysis of the grid at the time.66 An increase
in the number of EVs could unbalance the flow of electricity through the grid, resulting in
multiple grid related problems, such as voltage issues, degradation of power quality, and a
distortion of increasing harmonics, which could lead to further degradation of power quality.67
Large changes in load patterns, such as those projected with widespread 240-volt EV charging,
may also impact the voltages of long distance transmission lines.68 On a more local level, many
local distribution circuits are already operating with loads close to their operational limits, and
65Ipakachi and Albuyeh, 2009
66Ibid.
67Ibid.
68Ibid.
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the extra load from EVs may push some regional circuits over their emergency operating limits,
causing a localized overload of the circuit and connected transformers.69
The Effect of Smart
Charging on Electric Vehicles
Charging Management: Policy and Technology Options
Many of the benefits that arise from EVs can be further enhanced by controlling when
EV charging occurs. One of the easiest ways to promote smart charging of electric vehicles is
simply for the Federal, State or Local Governments to prohibit charging of EVs during peak
demand hours. However, such policies are likely to meet with significant political resistance.70
Smart charging of EVs can also be achieved indirectly by changing the structure of customer
utilities rates to encourage off-peak charging of EVs. This can be accomplished by increasing
rates at peak demand times and decreasing rates during off peak times.71
Charging times of EVs could also be managed by the integration of smart grid
technology into the existing power infrastructure. Broad deployment of smart technologies,
such as real-time automated interactive electricity pricing, would likely entail significant
investment on the part of utilities and the federal government. However, creation of a smart
grid would also allow for streamlined integration of intermittent energy sources such as solar
and wind into the existing power infrastructure.72
Full deployment of a smart grid would allow
69Ibid.
70NERC, 2010
71Ibid.
72Pratt, et al. 2010
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for large scale demand management, redirecting power to areas where it is needed most and
limiting demand in peak areas.73
A third method for managing EV charging load would be to employ the use of smart
appliances and smart chargers that apply specifically to EVs. Such appliances would allow the
system operator to monitor and control the charging of EVs, either through price signals or
directly, such as by turning off the charger.74 However, the widespread use of the
communication technologies required for sending and receiving such signals would require a
standardization of communications protocols across the nation, so that smart charging signals
can be received no matter where the vehicle is located.75
Additionally, although smart charging
technology exclusive to EVs would be less expensive overall than a full smart grid deployment,
the costs of adding smart charging technology to EVs would likely mean increasing the initial
cost of EVs, already one of the biggest obstacles to EV adoption.76 Making smart charging
technology exclusively for EVs also means that there will be considerable reliance on consumer
acceptance of the technology to ensure it is fully utilized, rather than having the technology be
implemented by the utility companies.77
73Ibid.
74Fell, et al. 2010
75Pratt, et al. 2010
76Ibid.
77Ibid.
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Effects on Load Management, Emissions, and Potential Electric Vehicle Deployment
Smart charging technologies and policies can significantly reduce and in many cases
eliminatethe load management issues that arise from EV deployment. If the charging times of
EVs are managed so that they do not coincide with peak demand, the current electric
infrastructure in the US has the potential to provide electricity to 73% of the US LDV fleet,
around 186 million vehicles.78The impact of a smart grid is even further amplified if EV charging
occurs at 240 volts. If all EVs charge at 240volts, in an unmanaged charging scenario EVs could
replace 32% of the existing LDV fleet. However if smart charging is used in a 240 volt charging
scenario, the grid can still support a 73% replacement of the current LDV fleet.79
The energy needed to power 73% of the US LDV fleet is equivalent to 910 billion kWh,80
or 22% of the electricity generated in 2010.81 In such a scenario, the grid would be heavily
loaded for most of the day, and overall grid reliability may decrease as the current reserve
capacity is be used to power EV charging.82 However, in this scenario the power sector also
gains $6.8 trillion per year in additional revenue from what was frequently underutilized
equipment, assuming an average electricity price of 7.5 cents per kWh, a conservative
estimate.83
78Kinter-meyer, et al. 2007
79Ibid. Percentages were calculated by determining how much power idle electricity generation capacity exists
within the country during off peak periods. Average travel distance for a vehicle in one year was then estimated,along with the corresponding energy required for different types sizes of EVs. It was then calculated how many
vehicles would be able to run using only the idle generation capacity, creating a valley filling approach. System
load data was based on NERC data for 2002.80
Kinter-meyer, et al. 200781
U.S. Energy Information Administration, 2011.82
Kinter-Meyer, et al. 200783
Letendre, et al. 2006
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In addition to allowing for the deployment of more EVs, smart charging of EVs also relies
on using the intermediate or base-load power plants that supply energy during off-peak times,
generally leading to greater emissions reductions even for the same deployment of EVs.84
Overall, smart charging is estimated to lead to at least a 3% reduction in energy use just from
the expanded deployment of EVs.85 When the greater energy efficiencies of off-peak
generation are taken into account, emissions reductions could be much greater.86 However,
the effect of smart charging in emissions reductions varies by region, as in some areas less
efficient generation occurs off peak.87
For example, for two different grid operators, NYSIO and
PJM, a significant difference is observed in the effect of smart charging on emissions. For NYISO,
smart charging of EVs leads to greater emissions reductions, as off-peak generation relies 86%
on natural gas instead of the 44% natural gas reliance during peak hours. On the other hand,
PJM relies 98% on coal for off-peak generation, leading to an increase instead of decrease in
CO2 emissions for the region when smart charging is used.88
Vehicle to Grid Technolgy: A Solution for Electric Vehicle Woes?
Vehicle to Grid Technology and Services Overview
The basic concept behind vehicle-to-grid services (V2G) is that when plugged into the
grid EVs can feed electricity back into the grid which can be directed to where it is needed, as
well as be used to stabilize power flow. In order to be V2G enabled, a vehicle must be able to
84Pratt, et al. 2010
85Ibid.
86Ibid.
87Peterson, et al. 2011.
88Ibid.
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plug into the grid for bidirectional electricity flow, have two-way communication with grid
operators via some control or connection mechanism, and contain on-board precision
metering.89
EVs, with their solid state chargers, can accurately and rapidly control electricity
consumption, although this is limited by the charge rates of the battery.90
Additionally, due to
the stop and go nature of driving, EV batteries are designed to provide for frequent large power
fluctuations over short periods of time.91 Taken together, these qualities make EVs ideal
candidates for assisting in regulation,92 which involves directing power flows to respond to
minute-by-minute changes in supply and demand,93
as well as for providing reserves to store
electricity and help with overall demand management.94 The average car in the US spends only
4% to 5% of the day on the road, which means that for the vast majority of the day an EV would
be parked and could be plugged into the grid to provide V2G services.95
The purpose of regulation is to adjust the grid to a target frequency and voltage that
matches demand, especially on local scales. Frequency and voltage regulation are under the
direct control of the grid operator, and the units providing regulation, usually specifically
designated generators, are able to respond to signals from the grid operator within less than a
minute and accordingly increase or decrease electrical output.96 The battery of an EV is actually
better suited for regulation than conventional generators, as it is able to respond to a signal
89 Tomic and Kempton, 2007.90
NERC, 201091
Tomic and Kempton, 2007.92
Fell, et al. 201093
NERC, 201094
Fell, et al. 201095
Tomic and Kempton, 2007.96
Tomic and Kempton, 2005. Vehicle-to-grid power fundamentals: Calculating capacity and net revenue
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within less than a second, rather than on a near minute timescale.97 Once a signal is received by
an EV, the battery would increase the amount of power being provided to the grid in the case
of a regulation up signal or, in the case of a regulation down signal, either reduce output or
draw in power from the grid as done with regular battery charging.98
The price of power for regulation services is determined by both a capacity price and an
energy price, which taken together make V2G power cost effective for regulation. The capacity
price is what is paid for the generator, or in this case a V2G battery, to be able to respond to
fluctuations in demand on a minutes notice. The energy price is what is paid for the actual
energy output from the generator.99
For regulation, the energy output is generally very small, so
the cost per kWh is inconsequential for the overall price. Instead, the ability to quickly vary
output, the capital cost of the generation or storage and the ability to provide regulation
without frequent maintenance are all more important factors when determining the price per
kWh of regulation.EVs with their specially designed batteries are better than generators in all
three of these areas, so using V2G regulation will actually increase utility sector
profits.100Traditionally, regulation is purchased by a power distribution company, which then
makes monthly contract payments for availability in terms of dollars per MWh, as well as an
additional payments for each kWh actually produced.101
Although the annual value of V2G
97Tomic and Kempton, 2007
98Ibid.
99Ibid.
100Ibid. For example, the cost of ancillary services in 2000 for CAISO was 15.4 US$/MWh. A fleet of 252 EVs and a
total capacity of 3.78 MW For an average of 83.2 GWh over the course of a year, the annual cost of regulation A
fleet of 252 EVs and a total capacity of 3.78 MW101
Ibid.
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regulation is low102 when compared with the total $12 billion market,103profits per vehicle could
be somewhere in the range of $100 to $1000 annually, depending on the market conditions,
type of regulation supplied, and specifications of the battery.104
Other studies show annual
V2G profits approaching $4,000 per vehicle.105
In addition to providing regulation services, V2G also has the potential to serve as
storage for intermittent renewable energy sources, thereby assisting with demand response.
Currently the US gets approximately 4% of electricity from renewable sources such as wind and
solar power.106 At these low levels the intermittent nature of renewable energy can be handled
by the existing power infrastructure. However, as renewables start to account for 10% to 30%
of US power generation, new resources will be needed to match the large intermittent energy
supply with already shifting load profiles.107Although each individual battery cannot store large
amounts of electricity, taken together an EV fleet has a large potential for distributed energy
storage. For example, 5,000 EV sedans have a potential storage capacity around 80
MWh.108EVs can thus absorb the excess electricity when wind and solar power generation is
high, and feed it back to the grid when such sources are inadequate.
102Ibid.
103 Tomic and Kempton, 2005. Vehicle-to-grid power fundamentals: Calculating capacity and net revenue104
Tomic and Kempton 2007.105
Sovacool and Hirsh, 2009106
U.S. Energy Information Administration, 2011107
Kempton and Tomic, 2005. Vehicle-to-grid power implementation: From stabilizing the grid to
supporting large-scale renewable energy108
Ipakchi and Albuyeh, 2009.For a sedan with a 16 kWh battery, 5000 sedans would equal a capacity of 80000
kWh, equivalent to 80 MWh.
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For Photovoltaic solar power (PV), peak electricity generation is between 12 and 2
p.m.on the East Coast, which is followed by peak loading around mid to late afternoon.109 PV
can be integrated into the grid by storing the extra energy from the PV generation peak and
releasing it back into the grid when there is peak demand. If solar power were to supply one
fifth of electricity generation, 26% of the LDV fleet could be used to store and rerelease the PV
electricity, assuming that only half of the vehicles under contract are available when needed on
a given day and a storage capacity of 7kW per vehicle.110 Wind power, on the other hand,
varies more irregularly and might require more or less storage capacity on any given day
depending on wind intensity. However, storage of energy would operate along the same lines
as with PV, storing energy during periods of excess supply and returning it to the grid during
peak demand. One study indicates that a modernized grid could support a high degree of
intermittent generation, especially wind generation, equivalent to 50% of the current total US
power generation, if a V2G fleet equivalent to 3% of the current LDV fleet was dedicated to
frequency and voltage regulation, along with a V2G fleet equivalent to between 8% and 38% of
the current LDV fleet providing storage.111
Obstacles to Vehicle to Grid Technology
Although V2G offers great opportunities for consumers, utilities and automobile
manufacturers, there are still many technical, economic and social obstacles to the V2G
concept. The major barrier to V2G implementation remains the high cost of batteries and EVs
109Kempton and Tomic, 2005. Vehicle-to-grid power implementation: From stabilizing the grid to
supporting large-scale renewable energy110
Ibid.111
Ibid.
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when compared to conventional vehicles.112 However, the additional cost from adding V2Gto a
vehicle, for expenses such as an onboard electric metering system, is around $550, and
therefore not a significant factor in the overall cost of an EV.113
Another problem with V2G is that the excessive cycling of the battery has the potential
to shorten the life of the battery.114
However, the type of shallow cycling involved with V2G
regulation, where small amounts of electricity flow in and out of the battery has a much smaller
effect on battery lifetime than does deep cycle charging, where a battery 100% discharges.115
For example, testing on a Saft lithium-ion battery shows a 3,000 cycle lifetime when the battery
is discharged 100%, but shallow cycling of the battery extends the battery lifetime to 1 million
cycle lifetime.116 One battery cycle is equivalent to a full discharge of the battery and
subsequent return to a full charge. Therefore, a 3,000 cycle lifetimes means that the battery is
able to sufficiency hold a charge for the equivalent of 3,000 full charges and discharges, while a
1 million cycle lifetime means that the battery is able to go through the energy equivalent of 1
million full charges and discharges.117 Nevertheless, there is considerable worry in the auto-
industry that V2G could reduce battery lifetime and therefore exacerbate limited range
problems inherent in EVs as well as expose automakers to extra risk due to vehicle warrantees.
112Romm, 2006.
113Tomic and Kempton, 2007.
114Ipakchi and Albuyeh, 2009.
115Tomic and Kempton, 2007.
116Ibid.
117Ibid.
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Automakers are therefore likely to void warrantees of EVs used for V2G unless something is
done to reduce risk exposure.118
Another obstacle to the implementation of V2G is the possibility that consumers may
opt out of any V2G services. Utility operators will therefore need to assure that EV owners are
adequately compensated for V2G services, in order to assure EVs remain in the program and
the grid retains V2G capacity.119 Furthermore, as seen in the history of hybrid vehicles, and for
energy technologies in general, people are generally very resistant towards technologies they
view as different and untested.120 If EV sales mimic early hybrid sales, EVs demand will initially
be confined to the coasts, rather than the Midwest and Southeast. EVs could thus further be
confined to a niche market and make widespread EV deployment and thus V2G more
difficult.121
PrincipalFindings
Electric vehicles, both PEVs and PHEVs, show enormous promise for reducing carbon
emissions, improving local air quality, and reducing dependence on foreign oil.
y With large public support for goals such as oil independence, along with bothautomobile and power industry support, the United States should continue to make
investments in EV research and development, as well as continue to encourage EV
purchases through various incentives.
118Interview with Kathryn Clay, 2011
119NERC, 2010
120Sovocool and Hirsh, 2009.
121Fell, et al. 2010
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Vehicle to Grid technology has the potential to solve many of the load issues
surrounding thelarge-scale deployment of EVs.
yV2G technology would also allow for improvements in power quality and large scale
V2G fleets would be able to support significant expansion of renewable energy in the US
without the need to invest in expensive permanent storage devices. However, using
V2G for ancillary services may be more practical than using V2Gfor support of
renewables due to the fact that smaller fluctuations in power have a smaller impact on
EV battery life.
y V2G would be profitable for utilities for exploit for regulation and for energy storage,and these profits could be passed on to the consumer, making EVs more economical for
many American families. Furthermore, with V2G consumers are actually being paid by
utilities to charge their cars, rather than simply saving money on gasoline costs. This
may have an oversized psychological effect and make EVs seem more economical to
most families, as people generally consider on hand assets rather than potential savings
when purchasing a vehicle, even though the majority of savings would come from
energy efficiency.
Along with continued investment in EVs, the federal government, automobile industry,
and power industry should increase investment in V2G research and development, and
continue to keep track of charging patterns such as is currently being done with the EV
Project.
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y FERC can help promote V2G research by encouraging ISOs to examine the impacts ofV2G for their specific region.
FERC
should work with utilities and automakers to establish guidelines and standards
for warrantee sharing between industries.
y If utilities pick up some of the liability for the vehicle warrantee, automakers may bemore willing to allow vehicles to be used for V2G without voiding the warrantee.
FERC should establish non-discrimination rules protecting third parties engaged in
ancillary services.
y Non-discrimination rules would help promote adoption of V2G technology by removingthe uncertainty surrounding utility industry acceptance of the new technology.
The auto-industry and power industry should work more closely together to promote
V2G as a potential selling point of EVs.
y Along with the current $7,500 federal tax credits and numerous other state and federalincentives, V2G contracts could be sold to an EV purchaser as part of an overall package
of incentives. Such a V2G contract could instantly shave $1000 off the initial EV
purchasing price for regulation contracts, possibly more if contracts for storage capacity
are included. Initial V2G contracts could also be extended for multiple years, reducing
the initial price of an EV by thousands of dollars. FERC could assist in fostering this type
of cooperation between the two industries by multiple means such as organizing
conferences revolving around V2G technology.
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