Plug-in hybrid
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A plug-in hybrid electric vehicle (PHEV) is a hybrid vehicle with batteries that can be recharged by connecting a plug to an electric power source. It shares the characteristics of both conventional hybrid electric vehicles and battery electric vehicles, having an internal combustion engine and batteries for power. Most PHEVs on the road today are passenger cars, but there are also PHEV versions of commercial passenger vans, utility trucks, school buses, motorcycles, scooters, and military vehicles. PHEVs are sometimes called grid-connected hybrids, gas-optional hybrids, or GO-HEVs.
The cost for electricity to power plug-in hybrids for all-electric operation in California has been estimated at less than one quarter of the cost of gasoline (petrol.)[1] Compared to conventional vehicles, PHEVs can reduce air pollution and dependence on petroleum, and lessen greenhouse gas emissions that contribute to global warming. Plug-in hybrids use no fossil fuel during their all-electric range if their batteries are charged from nuclear or renewable energy sources. Other benefits include improved national energy security, fewer fill-ups at the filling station, the convenience of home recharging, opportunities to provide emergency backup power in the home, and vehicle to grid applications.[2]
As of April 2008, plug-in hybrid passenger vehicles are not yet in production. However, Toyota,[3] General Motors,[4] Ford,[5] Chinese automaker BYD Auto,[6] and California startups Fisker Automotive[7] and Aptera Motors[8] have announced their intention to introduce production PHEV automobiles. The PHEV-60 BYD F6DM sedan and F3DM hatchback are expected in 2009;[9] the luxury Fisker Karma PHEV-50 sports car is slated for late 2009; and the Toyota Prius and GM's PHEV-40 Chevrolet Volt and Saturn Vue plug-ins are expected in 2010.[10][11] Conversion kits and services are available to convert production model hybrid vehicles to plug-ins.[12][13] Most PHEVs on the road in the U.S. are conversions of 2004 or later Toyota Prius models, which have had plug-in charging added and their electric-only range extended.
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[edit] Terminology
A plug-in hybrid's all-electric range is designated by PHEV-[miles] or PHEV[kilometers]km in which the number represents the distance the vehicle can travel on battery power alone. For example, a PHEV-20 can travel twenty miles without using its internal combustion engine, or about 32 kilometers, so it may also be designated as a PHEV32km.[14]
The Energy Independence and Security Act of 2007 defines a plug-in electric drive vehicle as a vehicle that:
- draws motive power from a battery with a capacity of at least 4 kilowatt-hours;
- can be recharged from an external source of electricity for motive power; and
- is a light-, medium-, or heavy-duty motor vehicle or nonroad vehicle.
This distinguishes PHEVs from regular hybrid cars mass-marketed today, which do not use any electricity from the grid.
The Institute of Electrical and Electronics Engineers (IEEE) defines PHEVs similarly, but also requires that the hybrid electric vehicle can drive at least ten miles (16 km) in all-electric mode (PHEV-10 / PHEV16km), while consuming no gasoline or diesel fuel.[15]
[edit] History
- For more details on this topic, see History of plug-in hybrids.
Hybrid vehicles were produced beginning as early as 1899 by Lohner-Porsche. Early hybrids could be charged from an external source before operation. However, the term "plug-in hybrid" has come to mean a hybrid vehicle that can be charged from a standard electrical wall socket.
The July 1969 issue of Popular Science featured an article on the General Motors XP-883 plug-in hybrid. The concept commuter vehicle housed six 12-volt lead-acid batteries in the trunk area and a transverse-mounted DC electric motor turning a front-wheel drive.[16] The car could be plugged into a standard North American 120 volt AC outlet for recharging.
In 2003, Renault began selling the Elect'road, a plug-in series hybrid version of their popular Kangoo, in Europe. It was sold alongside Renault's "Electri'cite" electric-drive Kangoo battery electric van. The Elect'road had a 150 km (93 mi) range using a nickel-cadmium battery pack and a 500 cc (31 cu in), 16 kilowatt liquid-cooled gasoline "range-extender" engine. It powered two high voltage/high output/low volume alternators, each of which supplied up to 5.5 kW at 132 volts at 5000 rpm.[17] The operating speed of the internal combustion engine—and therefore the output delivered by the generators—varied according to demand. The fuel tank had a capacity of 10 litres (2.6 US gal/2.2 imp gal) and was housed within the right rear wheel arch. The range extender function was activated by a switch on the dashboard. The on-board 3.5 kilowatt charger could charge a depleted battery pack to 95% charge in about four hours from a 240 volts supply.[18] Passenger compartment heating was powered by the battery pack as well as an auxiliary coolant circuit that was supplied by the range extender engine. After selling about 500 vehicles, primarily in France, Norway and the UK, at a price of about €25,000,[17] the Elect'road was redesigned in 2007.
In September 2004, the California Cars Initiative (CalCars) converted a 2004 Toyota Prius into a prototype of what it called the PRIUS+. With the addition of 130 kg (300 lb) of lead-acid batteries, the PRIUS+ achieved roughly double the fuel economy of a standard Prius and could make trips of up to 15 km (9 mi) using only electric power. The vehicle, which is owned by CalCars technical lead Ron Gremban, is used in daily driving, as well as a test bed for various improvements to the system.[19]
On July 18, 2006, Toyota announced that it "plans to develop a hybrid vehicle that will run locally on batteries charged by a household electrical outlet before switching over to a gasoline engine for longer hauls."[3] Toyota has said it plans to migrate to lithium-ion batteries in future hybrid models,[20] but not in the next-generation Prius, expected in fall 2008.[21] Lithium-ion batteries are expected to significantly improve fuel economy, and have a lower weight-to-energy ratio, but cost more to produce, and raise safety concerns due to high operating temperatures.[21]
On November 29, 2006, GM announced plans to introduce a production plug-in hybrid version of Saturn's Greenline Vue SUV with an all-electric range of 10 mi (16 km).[4] The model's sale is anticipated by fall 2009,[21] and GM announced in January 2007 that contracts had been awarded to two companies to design and test lithium-ion batteries for the vehicle.[22] GM has said that they plan on introducing plug-in and other hybrids "for the next several years".[4]
In January 2007, GM unveiled the Chevrolet Volt, which is expected to initially feature a plug-in capable, battery-dominant series hybrid architecture which they are calling E-Flex.[23] Future E-Flex plug-in hybrid vehicles may use gasoline, diesel, or hydrogen fuel cell power to supplement the vehicle's battery. General Motors envisions an eventual progression of E-Flex vehicles from plug-in hybrids to pure electric vehicles, as battery technology improves.[24] General Motors presented the Volt as a PHEV-40 that starts its engine when 40% of the battery charge remains, and which can achieve a fuel economy of 50 miles per US gallon (21 km/L), even if the vehicle's batteries are not charged.[25]
On July 9, 2007, Ford Motor Company CEO Alan Mulally said he expects Ford to sell plug-in hybrids in five to ten years, the launch date depending on advances in lithium-ion battery technology. Ford will provide Southern California Edison with 20 Ford Escape Hybrid sport utility vehicles reconfigured to work as plug-ins by 2009, with the first by the end of 2007.[5]
On July 25, 2007, Japan's Ministry of Land, Infrastructure and Transport certified Toyota's plug-in hybrid for use on public roads, making it the first automobile to attain such approval. Toyota plans to conduct road tests to verify its all-electric range. The plug-in Prius has an all-electric range of 13 km (8 mi).[26]
On August 9, 2007, General Motors vice-president Robert Lutz announced that GM is on track for Chevrolet Volt road testing in 2008 and production to begin by 2010. Announcing an agreement with A123Systems, Lutz said GM would like to have their planned Saturn Vue plug-in on the roads by 2009.[11] The Volt has an all-electric range of 40 mi (64 km).
On September 5, 2007, Quantum Technologies[27] and Fisker Coachbuild, LLC announced the launch of a joint venture in Fisker Automotive.[28] Fisker intends to build a US$ 80,000 luxury PHEV-50, the Fisker Karma, anticipated in late 2009.[7]
In September 2007, Aptera Motors announced their Typ-1 two-seater. They plan to produce both an electric Typ-1e and a plug-in hybrid Typ-1h with a common three-wheeled, composite body design. As of May 2008, over two thousand pre-orders have been accepted, and production is expected to begin in late 2008.[8]
On October 9, 2007, Chinese manufacturer BYD Automobile Company (which is owned by China's largest mobile phone battery maker) announced that it would be introducing a production PHEV-60 sedan in China in the second half of 2008. BYD exhibited it January 2008 at the North American International Auto Show in Detroit. Based on BYD's midsize F6 sedan, it uses iron-based batteries instead of lithium-ion, and can be recharged to 70% of capacity in just 10 minutes.[6]
In January 2008, a privately-run waiting list to purchase the Chevy Volt reached 10,000 members. The list, administered by Lyle Dennis, was started one year prior.[29]
January 2008: Assistant professor Yi Cui and colleagues at Stanford University's Department of Materials Science and Engineering [30] have made a discovery to use silicon nanowires to give rechargeable lithium ion batteries 10 times more charge.[31]
On March 27, 2008, the California Air Resources Board modified their regulations, requiring automobile manufacturers to produce 58,000 plug-in hybrids during 2012 through 2014.[32] This requirement is an asked-for alternative to an earlier mandate to produce 25,000 pure zero emission vehicles, reducing that requirement to 5,000.[33]
On Jun 4, 2008, "GM's Chevy Volt Is a Go" ( Rick Wagoner, GM chairman and CEO) -- Production Vehicle, in Showrooms in 2010. [34]
On June 05, 2008, Toyota Dealers Sold on Hymotion Plug-In Hybrids. [35]
[edit] Technology
[edit] Powertrains
- For more details on this topic, see Hybrid vehicle drivetrains.
PHEVs are based on the same three basic powertrain architectures as conventional hybrids:[36]
Series hybrids use an internal combustion engine (ICE) to turn a generator, which in turn supplies current to an electric motor, which then rotates the vehicle’s drive wheels. A battery or capacitor pack, or a combination of the two, can be used to store excess charge. Examples of series hybrids include the Renault Kangoo Elect'Road, Toyota's Japan-only Coaster light-duty passenger bus, DaimlerChrysler's hybrid Orion bus, the Chevrolet Volt concept car, the Opel Flextreme concept car, and many diesel-electric locomotives. With an appropriate balance of components this type can operate over a substantial distance with its full range of power without engaging the ICE. As is the case for other architectures, series hybrids can operate without recharging as long as there is liquid fuel in the tank.[37]
Parallel hybrids, such as Honda's Insight, Civic, and Accord hybrids, can simultaneously transmit power to their drive wheels from two distinct sources—for example, an internal combustion engine and a battery-powered electric drive. Although most parallel hybrids incorporate an electric motor between the vehicle's engine and transmission, a parallel hybrid can also use its engine to drive one of the vehicle's axles, while its electric motor drives the other axle and/or a generator used for recharging the batteries. (This type is called a road-coupled hybrid). The Audi Duo plug-in hybrid concept car is an example of this type of parallel hybrid architecture. Parallel hybrids can be programmed to use the electric motor to substitute for the ICE at lower power demands as well as to substantially increase the power available to a smaller ICE, both of which substantially increase fuel economy compared to a simple ICE vehicle.[38]
Series-parallel hybrids have the flexibility to operate in either series or parallel mode. Hybrid powertrains currently used by Ford, Lexus, Nissan, and Toyota, which some refer to as “series-parallel with power-split,” can operate in both series and parallel mode at the same time. As of 2007, most plug-in hybrid conversions of conventional hybrids utilize this architecture.[39]
[edit] Modes of operation
Regardless of its architecture, a plug-in hybrid may be capable of charge-depleting and charge-sustaining modes. Combinations of these two modes are termed blended mode or mixed-mode. These vehicles can be designed to drive for an extended range in all-electric mode, either at low speeds only or at all speeds. These modes manage the vehicle's battery discharge strategy, and their use has a direct effect on the size and type of battery required:[40]
Charge-depleting mode allows a fully charged PHEV to operate exclusively (or depending on the vehicle, almost exclusively, except during hard acceleration) on electric power until its battery state of charge is depleted to a predetermined level, at which time the vehicle's internal combustion engine or fuel cell will be engaged. This period is the vehicle's all-electric range. This is the only mode that a battery electric vehicle can operate in, hence their limited range.[41]
Charge-sustaining mode is used by production hybrid vehicles (HEVs) today, and combines the operation of the vehicle's two power sources in such a manner that the vehicle is operating as efficiently as possible without allowing the battery state of charge to move outside a predetermined narrow band. Over the course of a trip in a HEV the state of charge may fluctuate but will have no net change.[42] The battery in a HEV can thus be thought of as an energy accumulator rather than a fuel storage device. Once a plug-in hybrid has exhausted its all-electric range in charge-depleting mode, it can switch into charge-sustaining mode automatically.
Blended mode is a type of charge-depleting mode normally employed by vehicles which do not have enough electric power to sustain high speeds without the help of the internal combustion portion of the powertrain. A blended control strategy typically increases the distance from stored grid electricity compared to a charge-depleting strategy.[43] The Renault Kangoo and some Toyota Prius conversions are examples of vehicles that use this mode of operation. The Electri'cité and Elect'road versions of the Kangoo were charge-depleting battery electric vehicles: the Elect'road had a modest internal combustion engine which extended its range somewhat. Conversions of 2004 and later model Toyota Prius can only run without using the ICE at speeds of less than about 42 mph (68 km/h) due to the limits dictated by the vehicle's powertrain control software. However, at faster speeds electric power can still be used to displace gasoline, thus improving the fuel economy in blended mode and generally doubling the fuel efficiency.
Mixed mode describes a trip in which a combination of the above modes are utilized.[44] For example, a PHEV-20 Prius conversion may begin a trip with 5 miles (8 km) of low speed charge-depleting, then get onto a freeway and operate in blended mode for 20 miles (32 km), using 10 miles (16 km) worth of all-electric range at twice the fuel economy. Finally the driver might exit the freeway and drive for another 5 miles (8 km) without the internal combustion engine until the full 20 miles (32 km) of all-electric range are exhausted. At this point the vehicle can revert back to a charge sustaining-mode for another 10 miles (16 km) until the final destination is reached. Such a trip would be considered a mixed mode, as multiple modes are employed in one trip. This contrasts with a charge-depleting trip which would be driven within the limits of a PHEV's all-electric range. Conversely, the portion of a trip which extends beyond the all-electric range of a PHEV would be driven primarily in charge-sustaining mode, as used by a conventional hybrid.
[edit] Electric power storage
- Further information: Electric vehicle battery
PHEVs typically require deeper battery charging and discharging cycles than conventional hybrids. Because the number of full cycles influences battery life, this may be less than in traditional HEVs which do not deplete their batteries as fully. However, some authors argue that PHEVs will soon become standard in the automobile industry.[45] Design issues and trade-offs against battery life, capacity, heat dissipation, weight, costs, and safety need to be solved.[46] Advanced battery technology is under development, promising greater energy densities by both mass and volume,[47] and battery life expectancy is expected to increase.[48]
The cathodes of some early 2007 lithium-ion batteries are made from lithium-cobalt metal oxide. This material is expensive, and cells made with it can release oxygen if overcharged. If the cobalt is replaced with iron phosphates, the cells will not burn or release oxygen under any charge. The price premium for early 2007 conventional hybrids is about US$5000, some US$3000 of which is for their NiMH battery packs. At early 2007 gasoline and electricity prices, that would mean a break-even point after six to ten years of operation. The conventional hybrid premium could fall to US$2000 in five years, with US$1200 or more of that being cost of lithium-ion batteries, providing for a three-year payback. The payback period may be longer for plug-in hybrids, because of their larger, more expensive batteries.[49]
Nickel-metal hydride and lithium-ion batteries can be recycled; Toyota, for example, has a recycling program in place under which dealers are paid a US$200 credit for each battery returned.[50] However, plug-in hybrids typically use larger battery packs than comparable conventional hybrids, and thus require more resources. Recently Pacific Gas and Electric Company (PG&E) has suggested that utilities could purchase used batteries for backup and load levelling purposes. They state that while these used batteries may be no longer usable in vehicles, their residual capacity still has significant value.[51]
Lithium iron phosphate (LFP) is a kind of cathode material of lithium iron phosphate batteries that is getting attention from the industry. The most important merit of this battery type is safety and high-power. LiFePO4 is one of three major compounds and technology in LFP family. The other two are Nanophosphate,and NanoCocrystallineOlivine.
In France, Électricité de France (EDF) and Toyota are installing recharging points for PHEVs on roads, streets and parking lots.[52] EDF is also partnering with Elektromotive, Ltd.[53] to install 250 new charging points over six months from October 2007 in London and elsewhere in the UK.[54] Recharging points also can be installed for specific uses, as in taxi stands. Project Better Place has begun in October 2007 and is working with Renault on development of exchangeable batteries (battery swapping).[55]
Ultracapacitors (or "supercapacitors") are used in some plug-in hybrids, such as AFS Trinity's concept prototype, to store rapidly available energy with their high power density, in order to keep batteries within safe resistive heating limits and extend battery life.[12][56] The UltraBattery combines a supercapacitor and a battery in a single unit, creating a hybrid car battery that lasts longer, costs less and is more powerful than current technologies used in plug-in hybrid electric vehicles (PHEVs).[57]
[edit] Conversions of production hybrids
- For more details on this topic, see Electric vehicle conversion.
Conversion of an existing production hybrid to a plug-in hybrid typically involves increasing the capacity of the vehicle's battery pack and adding an on-board AC-to-DC charger. Ideally, the vehicle's powertrain software would be reprogrammed to make full use of the battery pack's additional energy storage capacity and power output.
Many early plug-in hybrid electric vehicle conversions have been based on the 2004 or later model Toyota Prius.[58] Some of the systems have involved replacement of the vehicle's original NiMH battery pack and its electronic control unit. Others, such as Hymotion, the CalCars Prius+, and the PiPrius, piggyback an additional battery back onto the original battery pack, this is also referred to as Battery Range Extender Modules (BREMs).[59] Within the electric vehicle conversion community this has been referred to as a "hybrid battery pack configuration".[60] Early lead-acid battery conversions by CalCars demonstrated 10 miles (15 km) of EV-only and 20 miles (30 km) of double mileage blended mode range.[19]
EDrive Systems use Valence Technology Li-ion batteries and have a claimed 40 to 50 miles (64 to 80 km) of electric range.[61] Other companies offering plug-in conversions or kits for the Toyota Prius (some of them also for Ford Escape Hybrid) include Hymotion, Hybrids Plus Manzanita Micro and OEMtek BREEZ (PHEV-30) [62]. AFS Trinity's XH-150 claims that it has created a functioning plug-in hybrid with a 40-mile all-electric range and that it has solved the overheating problem that rapid acceleration can cause in PHEVs and extend battery life.[56][12] It includes a "conversion interest" page.[63] The Electric Auto Association-PHEV "Do-It-Yourself" Open Source community's primary focus is to provide conversion instructions to help guide experienced converters through the process, and to provide a common design that could demonstrate multiple battery technologies. Many members of organizations such as CalCars and the EAA as well as companies like Hybrids Plus, Hybrid Interfaces of Canada, and Manzanita Micro participate in the development of the project.
Plug-In Supply Inc of Petaluma, California offers components and assemblies to build the Prius+, the plug-in conversion invented by CalCars. The PbA Battery Box Assembly is a complete install pack that provides access to the spare tire and contains 20 PbA20-12 lead-acid batteries, plus all high voltage components and control electronics in a strong welded steel enclosure with plastic powder coat finish. The PbA Battery Box Assembly is also available without batteries. Expect about 10 miles of EV mode range. [64] [65]
[edit] Disadvantages
[edit] Cost, weight, and size
[edit] Batteries
Disadvantages of plug-in hybrids include the additional cost, weight, and size of a larger battery pack. General Motors may allow buyers of its Chevy Volt electric car to rent the vehicle's battery, offsetting some cost.[66] Also used PHEV batteries can be sold to electric utilities to be employed at electrical substations.[51] [67] Not everyone will be able to lease or sell their battery packs, but the economics are changing with oil price increases since 2003.
[edit] Electric motor
Additionaly the cost, weight, and size of the electric motor must also be higher to facilitate much higher electric-only performance.[citation needed]
[edit] Electrical outlets outside garages
Many people living in apartments, condominiums, and townhouses do not have garages. With only on-street parking available, they will need access to electrical outlets to take advantage of all-electric operation. New electrical outlets near their places of residence, or in commercial or public parking lots or streets will need to be installed for them to gain the full advantage of PHEVs.[68]
[edit] Emissions shifted to electric plants
Increased pollution is expected to occur in some areas with the adoption of PHEVs, but most areas will experience a decrease.[69] A study by the ACEEE predicts that widespread PHEV use in heavily coal-dependent areas would result in an increase in local net sulfur dioxide and mercury emissions, given emissions levels from most coal plants currently supplying power to the grid.[70] Although clean coal technologies could create power plants which supply grid power from coal without emitting significant amounts of such pollutants, the higher cost of the application of these technologies may increase the price of coal-generated electricity. The net effect on pollution is dependent on the fuel source of the electrical grid (fossil or renewable, for example) and the pollution profile of the power plants themselves. Identifying, regulating and upgrading single point pollution source such as a power plant—or replacing a plant altogether—may also be more practical. From a human health perspective, shifting pollution away from large urban areas may be considered a significant advantage.[71]
[edit] Tiered rate structure for electrical bills would negate benefits
Electric utility companies generally do not utilize flat rate pricing; for example PG & E (as of 2008) charges $0.10 per kWh for the base tier, but additional tiers are priced as high as $0.30 per kWh. The additional electrical utilization required to recharge the plug-in vehicles would push many households into the higher priced tier and negate much of the benefits. Thus, an accurate comparison of the benefit requires each household to evaluate its current electrical usage (tier) weighed against the cost of petrol.
[edit] Advantages
[edit] Petroleum displacement
- Further information: Oil peak
Each kWh of batteries, used in any kind of PHEV, from subcompact to huge, will displace around 0.1 US gallons (0.38 l) of gasoline (or diesel fuel) per charge, or 20 US gallons (76 l) to 36 US gallons (140 l) per year, depending upon duty cycle (200-360 charges/year). At current petroleum prices, this amounts to US $80-144 of gasoline saved per year per kWh of battery capacity.[citation needed]
[edit] Fuel efficiency
Claimed fuel economy for PHEVs depends on the amount of driving between recharges. If no gasoline is used the MPG equivalent depends only on the efficiency of the electric system. A 120 km (70 mile) range PHEV-70 may annually require only about 25% as much gasoline as a similarly designed PHEV-0, depending on how it will be driven and the trips for which it will be used.[2] The furthest all-electric range in a PHEV planned for mass production is the PHEV-60 BYD F6e.
A further advantage of PHEVs is that they have potential to be even more efficient than conventional hybrids because a more limited use of the PHEV's internal combustion engine may allow the engine to be used at closer to its maximum efficiency. While a Prius is likely to convert fuel to motive energy on average at about 30% efficiency (well below the engine's 38% peak efficiency) the engine of a PHEV-70 would be likely to operate far more often near its peak efficiency because the batteries can serve the modest power needs at times when the combustion engine would be forced to run well below its peak efficiency.[41] The actual efficiency achieved depends on losses from electricity generation, inversion, battery charging/discharging, the motor controller and motor itself, the way a vehicle is used (its duty cycle), and the opportunities to recharge by connecting to the electrical grid.
The Society of Automotive Engineers (SAE) developed their recommended practice in 1999 for testing and reporting the fuel economy of hybrid vehicles and included language to address PHEVs. An SAE committee is currently working to review procedures for testing and reporting the fuel economy of PHEVs.[72]
[edit] Greenhouse gas emissions
Another advantage of PHEV adoption is a predicted reduction in carbon emissions. Increased drivetrain efficiency results in significant reduction of greenhouse gas emissions, even taking into account energy lost to inefficiency in the production and distribution of grid power and charging of batteries. A study by the American Council for an Energy Efficient Economy (ACEEE) predicts that, on average, a typical American driver is expected to achieve about a 15% reduction in net CO2 emissions compared to the driver of a regular hybrid, based on the 2005 distribution of power sources feeding the U.S. electrical grid.[73] Additionally, for PHEVs recharged in areas where the grid is fed by power sources with lower CO2 emissions than the current average, net CO2 emissions associated with PHEVs will decrease correspondingly.
A large-scale June 2007 joint study by the Electric Power Research Institute (EPRI) and the Natural Resources Defense Council (NRDC) similarly found that the introduction of PHEVs into America’s consumer vehicle fleet could achieve significant greenhouse gas emission reductions.[74] The EPRI-NRDC report estimates that, between 2010 and 2050, a shift toward PHEV use could reduce GHG emissions by 3.4 to 10.4 billion metric tons. The magnitude of these reductions would ultimately depend on the level of PHEV market penetration and the carbon intensity of the US electricity sector. In general, PHEVs can be viewed as an element in the "Pacala and Socolow wedges" approach which shows a way to stabilize CO2 emissions using a portfolio of existing techniques, including efficient vehicles.
The ACEEE study predicts that in areas where more than 80% of grid-power comes from coal-burning power plants, local net CO2 emissions will increase.[73] However, given the global nature of problems associated with CO2 emissions, specifically global warming, localized increases in CO2 emissions are not considered a significant problem if global CO2 emissions are decreased.[14]
GM Vice Chairman Bob Lutz has said the Chevy Volt will emit 40 grams of carbon dioxide per kilometer. That is well below the proposed European Union emission standards of 120-130 g/km.[75]
Martin Eberhard, who co-founded plug-in maker Tesla Motors, says "if you do the math, you´ll find that an electric car, even if you use coal to make electricity, produces less pollution per mile than burning gasoline in the best gasoline-powered car."[76] The Minnesota Pollution Control Agency found that if Minnesota's fleet of vehicles making lengthy trips were placed by plug-in hybrids, it would produce more carbon dioxide emissions per mile than existing hybrid vehicles unless more than 40% of the electricity used to charge them came from non-polluting sources such as hydro or wind.[77] Plug-in hybrids use less fuel in all cases, and produce much less carbon dioxide in short commuter trips, which is how most vehicles are used. The difference is such that overall carbon emissions would decrease if all internal combustion vehicles were converted to plug-ins.[69]
[edit] Operating costs
In a 2006 research estimate in California, the cost to plug in at night was equivalent to US$0.75 per U.S. gallon (3.8 L) of gasoline,[1] whereas the pre-tax cost of gasoline is just under US$3 per gallon. The cost of electricity for a Prius PHEV is about US$0.03 per mile (US$0.019 per km), based on 0.26 kW·h/mi (129 mpg) and a cost of electricity of US$0.10 per kilowatt hour.[78][79] During 2008, many government and industry researchers are focusing on determining what level of all-electric range is economically optimum for the design.[80] In 2008, a PHEV can travel 30 miles for just US$ 1.04 (the same mileage as a gallon of gasoline costing $3.00.)[81]
[edit] Vehicle-to-grid electricity
PHEVs and fully electric cars may allow for more efficient use of existing electric production capacity, much of which sits idle as operating reserve most of the time. This assumes that vehicles are charged primarily during off peak periods (i.e., at night), or equipped with technology to shut off charging during periods of peak demand. Another advantage of a plug-in vehicle is their potential ability to load balance or help the grid during peak loads. This is accomplished with vehicle to grid technology. By using excess battery capacity to send power back into the grid and then recharge during off peak times using cheaper power, such vehicles are actually advantageous to utilities as well as their owners. Even if such vehicles just led to an increase in the use of night time electricity they would even out electricity demand which is typically higher in the day time, and provide a greater return on capital for electricity infrastructure.[14]
In October 2005, five Toyota engineers and one Asian AW engineer published an IEEE technical paper detailing a Toyota-approved project to add vehicle-to-grid capability to a Toyota Prius.[82] Although the technical paper described "a method for generating voltage between respective lines of neutral points in the generator and motor of the THS-II (Toyota Hybrid System) to add a function for generating electricity", it did not state whether or not the experimental vehicle could be charged through the circuit, as well. However, the vehicle was featured in a Toyota Dream House, and a brochure for the exhibit stated that "the house can supply electricity to the battery packs of the vehicles via the stand in the middle of the garage", indicating that the vehicle may have been a plug-in hybrid.[83]
In November 2005, more than 50 leaders from public power utility companies across the United States met at the Los Angeles Department of Water and Power headquarters to discuss plug-in hybrid and vehicle-to-grid technology. The event, which was sponsored by the American Public Power Association, also provided an opportunity for association members to plan strategies that public power utility companies could use to promote plug-in hybrid technology. Greg Hanssen and Peter Nortman of EnergyCS[84] and EDrive[85] attended the two-day session, and during a break in the proceedings, made an impromptu display in the LADWP parking lot of their converted Prius plug-in hybrid.[86]
In September 2006, the California Air Resources Board held a Zero Emission Vehicle symposium that included several presentations on V2G technology.[87] In April 2007, Pacific Gas and Electric showcased a PHEV at the Silicon Valley Leadership Alternative Energy Solutions Summit with vehicle-to-grid capability, and demonstrated that it could be used as a source of emergency home power in the event of an electrical power failure.[88] Regulations intended to protect electricians against power other than from grid sources would need to be changed, or regulations requiring consumers to disconnect from the grid when connected to non-grid sources will be required before such backup power solutions would be feasible.[89]
Federal Energy Regulatory Commissioner Jon Wellinghoff coined the term "Cash-Back Hybrids" to describe payments to car owners for putting their batteries on the power grid. Batteries could also be offered in low-cost leasing or renting or by donation (including maintenance) to the car owners by the public utilities, in a vehicle-to-grid agreement.[90]
[edit] Public support
As of February, 2008, all three of the major U.S. presidential candidates have taken a position on plug-in hybrids:
- Senator Barack Obama delivered a speech on February 28, 2006 calling for every government car to be a PHEV.[91] On April 19, 2007, Obama joined with senators Maria Cantwell and Republican Orrin Hatch to introduce legislation providing: tax credits to consumers who purchase plug-ins, patterned after existing incentives for conventional hybrids; tax incentives for the U.S. production of PHEVs and dedicated parts; and incentives for electric utilities to provide rebates to customers who purchase plug-ins, scaled to provide larger incentives to utilities producing greener energy.[92]
- Senator John McCain pledged on April 23, 2007 to promote partnerships between utilities and automakers to accelerate the deployment of plug-in hybrids.[93]
- Senator Hillary Clinton called on February 11, 2008 for investment in research and to stimulate demand for the first commercial PHEVs by investing $2 billion in research and development to reduce the cost and increase the longevity and durability of batteries; offering consumers tax credits of up to $10,000 for purchasing a plug-in hybrid; and adding 100,000 plug-in hybrids to the federal fleet by 2015.[94]
[edit] Public deployment and pilot projects
Public deployment includes:
- DoE´s FreedomCAR
- PHEV Research Center
- Washington State PHEV Pilot Project. [95]
- City of Toronto [96]
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[edit] Production and Commercialization
PHEVs have been sold as commercial passenger vans,[97] utility trucks,[98][99] general and school buses,[100][101] motorcycles,[102] scooters,[103] and military vehicles.[104] Hybrid Electric Vehicle Technologies, Inc converts diesel buses to plug-in hybrids, under contract for the Chicago Transit Authority.
Interest in plug-in hybrids increased in 2006 to such a level that the architecture was included as an area of research in President George W. Bush's advanced energy initiative and mentioned in his 2007 State of the Union Address. Incentives for the development of PHEVs are included in the Energy Independence and Security Act of 2007.[105]
At least fourteen car companies of all sizes are exploring or planning to offer a plug-in.[106] After hearing an explanation of PHEVs, 49% of U.S. consumers surveyed in 2006 said they would consider purchasing one. That is about the same level of interest as standard hybrid technology.[107]
GM's Chevy Volt is a production vehicle, in showrooms in 2010. [108]
[edit] Patent encumbrance of NiMH batteries
In 1994, General Motors acquired a controlling interest in Ovonics's battery development and manufacturing, including patents controlling the manufacturing of large nickel metal hydride (NiMH) batteries. In 2001, Texaco purchased GM's share in GM Ovonics. A few months later, Chevron acquired Texaco. In 2003, Texaco Ovonics Battery Systems was restructured into Cobasys, a 50/50 joint venture between Chevron and Energy Conversion Devices (ECD) Ovonics.[109] Chevron's influence over Cobasys extends beyond a strict 50/50 joint venture. Chevron holds a 19.99% interest in ECD Ovonics.[110] Chevron also maintains veto power over any sale or licensing of NiMH technology.[111] In addition, Chevron maintains the right to seize all of Cobasys' intellectual property rights in the event that ECD Ovonics does not fulfill its contractual obligations.[111] On September 10, 2007, Chevron filed a legal claim that ECD Ovonics has not fulfilled its obligations. ECD Ovonics disputes this claim.[112] Since that time, the arbitration hearing was repeatedly suspended while the parties negotiate with an unknown prospective buyer. No agreement has been reached with the potential buyer. [113]
In her book, Plug-in Hybrids: The Cars that Will Recharge America, published in February 2007, Sherry Boschert argues that large-format NiMH batteries are commercially viable but that Cobasys refuses to sell or license them to small companies or individuals. Boschert reveals that Cobasys accepts only very large orders for these batteries. When Boschert conducted her research, major auto makers showed little interest in large orders for large-format NiMH batteries. However, Toyota employees complained about the difficulty in getting smaller orders of large format NiMH batteries to service the existing 825 RAV-4EVs. Since no other companies were willing to make large orders, Cobasys was not manufacturing nor licensing any large format NiMH battery technology for automotive purposes. Boschert concludes that "it's possible that Cobasys (Chevron) is squelching all access to large NiMH batteries through its control of patent licenses in order to remove a competitor to gasoline. Or it's possible that Cobasys simply wants the market for itself and is waiting for a major automaker to start producing plug-in hybrids or electric vehicles."[114]
However, recently-signed Cobasys contracts demonstrate that the company is willing to use its NiMH technology in the automotive industry, specifically for use with hybrid electric vehicles. In December 2006, Cobasys and General Motors announced that they had signed a contract under which Cobasys provides NiMH batteries for the Saturn Aura hybrid sedan.[115] In March 2007, GM announced that it would use Cobasys NiMH batteries in the 2008 Chevrolet Malibu hybrid as well. Cobasys remains unwilling to sell NiMH batteries in smaller quantities to individuals or companies interested in building or retrofitting their own PHEVs.[citation needed]
Still other actions by Cobasys suggest that the company remains unwilling to make NiMH battery technology economically feasible for the development of automobiles that rely on electric motor technology more than currently available hybrid cars. In October 2007, International Acquisitions Services, Inc., Innovative Transportation Systems AG and Neville Chamberlain filed suit against Cobasys and its parents for refusing to fill a large, previously agreed-upon order for large-format NiMH batteries to be used in the electric Innovan. [116]
Electro Energy Inc., working with CalCars, converted a Prius using its own bipolar NiMH batteries. Plug-In Conversions uses Nilar NiMH batteries and the EAA-PHEV open source control system in its Prius PHEV conversions. These organizations maintain that these developments are allowable because their NiMH battery technologies are not covered by Cobasys' patents.
[edit] See also
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[edit] References
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- ^ ECD Ovonics 10-Q Quarterly Report for the period ending March 31, 2008
- ^ Boschert, S. (2007) Plug-in Hybrids: The Cars that Will Recharge America (Gabriola Island, BC: New Society Publishers) ISBN 9780865715714
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- ^ ECD Ovonics 10-Q Quarterly Report for the period ending March 31, 2008
[edit] External links
- How Plug-In Hybrid Cars Work at HowStuffWorks
- Plug-in Hybrid Electric Vehicles - U.S. Office of Energy Efficiency and Renewable Energy
- "Plugging into the Grid" by Joseph Romm and Peter Fox-Penner in the Progressive Policy Institute's March 2007 newsletter, explaining how PHEVs can help "break America's oil addiction and slow global warming"
- Groups promoting plug-ins
- Electric Automobile Association's Hybrid and Plug-In Hybrid Electric Vehicles Wiki - conversion and technical documentation
- California Cars Initiative, PHEV news service, What Carmakers are saying about PHEVs
- Plug-in Hybrid Development Consortium
- Plug-In Partners
- Set America Free Coalition
- Plug-in Hybrid Electric School Bus Project
- Advanced Vehicle Innovations (AVI)
- Conferences and events
- Plug-in Conference: July 24-28, 2008, San José, California.
- Plug-In Electric Vehicles 2008 by The Brookings Institution and Google.org.
- News