2009 05 Electric Vehicles In Apac – Fad Or Reality Frost & SullivanAlvin Chua
Electric Vehicles (EV) are seen as a key future trend in the automotive industry in terms of oil independence.
Frost & Sullivan\'s Industry Manager, Vijayendra Rao, will share his views on challenges facing implementation of EVs in APAC, legislative, new business models, infrastructure trends emerging in APAC for implementation of EVs and threat analysis, and recommendations for EV manufacturers and suppliers.
2009 05 Electric Vehicles In Apac – Fad Or Reality Frost & SullivanAlvin Chua
Electric Vehicles (EV) are seen as a key future trend in the automotive industry in terms of oil independence.
Frost & Sullivan\'s Industry Manager, Vijayendra Rao, will share his views on challenges facing implementation of EVs in APAC, legislative, new business models, infrastructure trends emerging in APAC for implementation of EVs and threat analysis, and recommendations for EV manufacturers and suppliers.
Electric vehicles as the future of personal transportation?benboycott
An analysis of three cases against and three cases for electric vehicles. Cases against include: well to wheel carbon emissions, power station requirements and rare earth metal supply. Cases for include: carbon reduction and facilitation of renewable electricity, reduced reliance on oil and health improvements in urban environments.
plug in hybrid electrical vehicals seminar ppt by MD NAWAZMD NAWAZ
A 'gasoline-electric hybrid car' or 'Plug in hybrid electric vehicle' is a vehicle which relies not only on batteries but also on an internal combustion engine which drives a generator to provide the electricity and may also drive a wheel. It has great advantages over the previously used gasoline engine that drives the power from gasoline only. It also is a major source of air pollution. The objective is to design and fabricate a two wheeler hybrid electric vehicle powered by both battery and gasoline. The combination of both the power makes the vehicle dynamic in nature. It provides its owner with advantages in fuel economy and environmental impact over conventional automobiles. Hybrid electric vehicles combine an electric motor, battery and power system with an internal combustion engine to achieve better fuel economy and reduce toxic emissions.
In HEV, the battery alone provides power for low-speed driving conditions where internal combustion engines are least efficient. In accelerating, long highways, or hill climbing the electric motor provides additional power to assist the engine. This allows a smaller, more efficient engine to be used. Besides it also utilizes the concept of regenerative braking for optimized utilization of energy. Energy dissipated during braking in HEV is used in charging battery. Thus the vehicle is best suited for the growing urban areas with high traffic. Initially the designing of the vehicle in CAD, simulations of inverter and other models are done. Equipment and their cost analysis are done. It deals with the fabrication of the vehicle. This includes assembly of IC Engine and its components. The next phase consists of implementing the electric power drive and designing the controllers. The final stage would consist of increasing the efficiency of the vehicle in economic ways.
Electric Vehicles - State of play and policy frameworkLeonardo ENERGY
The objective of this report is to contribute to a better understanding of the potential impact of a transition to electric vehicles (EVs) in Europe and of the barriers that currently impede the realization of this potential. The research and analysis contained in this document indicates that the EV holds enormous environmental, social and economic benefits for Europe. However, it also shows that despite some progress in the right direction, we are currently a long way from realizing it. For this potential to be unlocked to a material extent within a 2050 horizon, a series of barriers need to be surpassed through collaboration by all stakeholders. Details of these findings are provided and recommendations on how to increase EV market uptake and to leverage the potential of EV benefits are presented.
TRIKE is a 3 wheel hybrid vehicle , which has two wheels at the front and drive train to the back wheel ,which is accomodated with the hub motor and the same wheel is linked to the IC engine through the chain drive .
The vehicle can either run through electricity or IC engine and with the combination of both .
The presentation deals with the electric cars and their types.
The working and designs of different types of electric cars has been designed.
The history and the advantages are also included.
Enjoy and thanks for watching..
Cheers!!!
A hybrid electric vehicle (HEV) has two types of energy storage units, electricity and fuel. Electricity means that a battery (sometimes assisted by ultracaps) is used to store the energy, and that an electromotor (from now on called motor) will be used as traction motor. Fuel means that a tank is required, and that an Internal Combustion Engine (ICE, from now on called engine) is used to generate mechanical power, or that a fuel cell will be used to convert fuel to electrical energy. In the latter case, traction will be performed by the electromotor only. In the first case, the vehicle will have both an engine and a motor.
Depending on the drive train structure (how motor and engine are connected), we can distinguish between parallel, series or combined HEVs.
Depending on the share of the electromotor to the traction power, we can distinguish between mild or micro hybrid (start-stop systems), power assist hybrid, full hybrid and plug-in hybrid.
Depending on the nature of the non-electric energy source, we can distinguish between combustion (ICE), fuel cell, hydraulic or pneumatic power, and human power. In the first case, the ICE is a spark ignition engines (gasoline) or compression ignition direct injection (diesel) engine. In the first two cases, the energy conversion unit may be powered by gasoline, methanol, compressed natural gas, hydrogen, or other alternative fuels.
Electric vehicles as the future of personal transportation?benboycott
An analysis of three cases against and three cases for electric vehicles. Cases against include: well to wheel carbon emissions, power station requirements and rare earth metal supply. Cases for include: carbon reduction and facilitation of renewable electricity, reduced reliance on oil and health improvements in urban environments.
plug in hybrid electrical vehicals seminar ppt by MD NAWAZMD NAWAZ
A 'gasoline-electric hybrid car' or 'Plug in hybrid electric vehicle' is a vehicle which relies not only on batteries but also on an internal combustion engine which drives a generator to provide the electricity and may also drive a wheel. It has great advantages over the previously used gasoline engine that drives the power from gasoline only. It also is a major source of air pollution. The objective is to design and fabricate a two wheeler hybrid electric vehicle powered by both battery and gasoline. The combination of both the power makes the vehicle dynamic in nature. It provides its owner with advantages in fuel economy and environmental impact over conventional automobiles. Hybrid electric vehicles combine an electric motor, battery and power system with an internal combustion engine to achieve better fuel economy and reduce toxic emissions.
In HEV, the battery alone provides power for low-speed driving conditions where internal combustion engines are least efficient. In accelerating, long highways, or hill climbing the electric motor provides additional power to assist the engine. This allows a smaller, more efficient engine to be used. Besides it also utilizes the concept of regenerative braking for optimized utilization of energy. Energy dissipated during braking in HEV is used in charging battery. Thus the vehicle is best suited for the growing urban areas with high traffic. Initially the designing of the vehicle in CAD, simulations of inverter and other models are done. Equipment and their cost analysis are done. It deals with the fabrication of the vehicle. This includes assembly of IC Engine and its components. The next phase consists of implementing the electric power drive and designing the controllers. The final stage would consist of increasing the efficiency of the vehicle in economic ways.
Electric Vehicles - State of play and policy frameworkLeonardo ENERGY
The objective of this report is to contribute to a better understanding of the potential impact of a transition to electric vehicles (EVs) in Europe and of the barriers that currently impede the realization of this potential. The research and analysis contained in this document indicates that the EV holds enormous environmental, social and economic benefits for Europe. However, it also shows that despite some progress in the right direction, we are currently a long way from realizing it. For this potential to be unlocked to a material extent within a 2050 horizon, a series of barriers need to be surpassed through collaboration by all stakeholders. Details of these findings are provided and recommendations on how to increase EV market uptake and to leverage the potential of EV benefits are presented.
TRIKE is a 3 wheel hybrid vehicle , which has two wheels at the front and drive train to the back wheel ,which is accomodated with the hub motor and the same wheel is linked to the IC engine through the chain drive .
The vehicle can either run through electricity or IC engine and with the combination of both .
The presentation deals with the electric cars and their types.
The working and designs of different types of electric cars has been designed.
The history and the advantages are also included.
Enjoy and thanks for watching..
Cheers!!!
A hybrid electric vehicle (HEV) has two types of energy storage units, electricity and fuel. Electricity means that a battery (sometimes assisted by ultracaps) is used to store the energy, and that an electromotor (from now on called motor) will be used as traction motor. Fuel means that a tank is required, and that an Internal Combustion Engine (ICE, from now on called engine) is used to generate mechanical power, or that a fuel cell will be used to convert fuel to electrical energy. In the latter case, traction will be performed by the electromotor only. In the first case, the vehicle will have both an engine and a motor.
Depending on the drive train structure (how motor and engine are connected), we can distinguish between parallel, series or combined HEVs.
Depending on the share of the electromotor to the traction power, we can distinguish between mild or micro hybrid (start-stop systems), power assist hybrid, full hybrid and plug-in hybrid.
Depending on the nature of the non-electric energy source, we can distinguish between combustion (ICE), fuel cell, hydraulic or pneumatic power, and human power. In the first case, the ICE is a spark ignition engines (gasoline) or compression ignition direct injection (diesel) engine. In the first two cases, the energy conversion unit may be powered by gasoline, methanol, compressed natural gas, hydrogen, or other alternative fuels.
Financial Advisors Have a Really Tough Challenge. First They Need to Ditch the Product Mentality and Create a Unique Marketing Message. Next They Need to Build a Platform That Seamlessly Integrates Modern Tools and Strategies.
Plugged-in electric vehicles, renowned as electric vehicles or EVs, is a type of electric vehicles that one can easily plug them in to charge it from an off-board electric power source. There are EVs (plug-in electric vehicles), AEVs (all electric vehicles), Fuel Cell Electric Vehicles (FCEVs) and PHEVs (plug- in hybrid electric vehicles).
plug in hybrid electrical vehicals seminar report by MD NAWAZMD NAWAZ
A 'gasoline-electric hybrid car' or 'Plug in hybrid electric vehicle' is a vehicle which relies not only on batteries but also on an internal combustion engine which drives a generator to provide the electricity and may also drive a wheel. It has great advantages over the previously used gasoline engine that drives the power from gasoline only. It also is a major source of air pollution. The objective is to design and fabricate a two wheeler hybrid electric vehicle powered by both battery and gasoline. The combination of both the power makes the vehicle dynamic in nature. It provides its owner with advantages in fuel economy and environmental impact over conventional automobiles. Hybrid electric vehicles combine an electric motor, battery and power system with an internal combustion engine to achieve better fuel economy and reduce toxic emissions.
In HEV, the battery alone provides power for low-speed driving conditions where internal combustion engines are least efficient. In accelerating, long highways, or hill climbing the electric motor provides additional power to assist the engine. This allows a smaller, more efficient engine to be used. Besides it also utilizes the concept of regenerative braking for optimized utilization of energy. Energy dissipated during braking in HEV is used in charging battery. Thus the vehicle is best suited for the growing urban areas with high traffic. Initially the designing of the vehicle in CAD, simulations of inverter and other models are done. Equipment and their cost analysis are done. It deals with the fabrication of the vehicle. This includes assembly of IC Engine and its components. The next phase consists of implementing the electric power drive and designing the controllers. The final stage would consist of increasing the efficiency of the vehicle in economic ways.
An electric vehicle (EV) is one that operates on an electric motor, instead of an internal-combustion engine that generates power by burning a mix of fuel and gases. Therefore, such as vehicle is seen as a possible replacement for current-generation automobile, in order to address the issue of rising pollution, global warming, depleting natural resources, etc. Though the concept of electric vehicles has been around for a long time, it has drawn a considerable amount of interest in the past decade amid a rising carbon footprint and other environmental impacts of fuel-based vehicles.
An electric vehicle, also called an EV, uses one or more electric motors or traction motors
for propulsion instead of the traditional fossil fuel.
• First electric carriage was built in 1830s and the first electric automobile was built in 1891
in the United States.
• Types : Battery electric Vehicle
Hybrid Electric Vehicle
Plug-in Hybrid Electric Vehicle
Fuel Cell Electric Vehicle
• Electric vehicles will play a pivot role in changing the environment and economy around
the globe in the next two decades.
Enegriegebruik en CO2 uitstoot elektrische auto's ; een vergelijkingZERAuto nl
Vergelijking van enegriegebruik en CO2-emissie elektrische auto's vs benzine en diesel, opgesteld door de European Association for Battery Electric Vehicles. NIet op voorhand neutraal, wel veel goede cijfers, rekenmodellen en achtergronden m.b.t. energiebehoefte en emissies.
Common Questions about Electric VehiclesSibiKrishnan
What are the common questions about electric cars? Let's check out a few questions and answers related to electric vehicles.
* Are they economical?
* Are EVs Green?
* etc.
This is a brief description about the current situation of Electrification of vehicles and E-Mobility in India. The presentation covers everything right from the working of electric vehicles to the usage by various countries. For more info do visit my blog " https://theautofanaticblog.wordpress.com/2018/07/10/10-things-to-know-about-electric-vehicles/ "
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2. Buyers’ Guide for Electric and Hybrid Vehicles
2007 Edition, Version 1
November 2007
3.
4. Table of contents
1 Electric vehicles 4
1.1 What are electric vehicles? 4
1.2 Why buy an electric vehicle? 4
1.3 Disadvantages of electric vehicles 5
1.4 When is it worth buying an electric vehicle? 5
2 Considering Buying an Electric Car? 6
2.1 Buying a Battery Electric Car 6
2.2 Buying a Hybrid Electric Car 9
2.3 Buying a Plug-in Hybrid Electric Car 12
3 Considering Buying an Electric Van? 16
3.1 Buying a Battery Electric Van 16
3.2 Buying a Hybrid Electric Van 18
3.3 Buying a Plug-in Hybrid Electric Van 21
4 Considering Buying an Electric Bus? 25
4.1 Buying a Battery Electric Bus 25
4.2 Buying a Hybrid or Plug-in Hybrid Electric Bus 28
5 Additional Sources of Information 32
6 Glossary 33
5. 1 Electric vehicles
1.1 What are electric vehicles?
Electric vehicles (EVs) come in three main types:
• Battery electric vehicles (BEVs) are powered solely by electricity stored in large batteries
within the vehicles. The battery powers an electric motor, or motors, which in turn drives the
vehicle. The battery needs to be recharged by plugging into recharging points, for example,
the mains electricity supply.
• Hybrid electric vehicles (HEVs), often simply referred to as hybrid vehicles, are powered by
a combination of electricity stored in a battery and either a petrol or diesel internal
combustion engine. A hybrid vehicle does not need to be plugged in to recharge its battery,
as this is recharged automatically as the vehicle is being driven.
• Plug-in hybrid electric vehicles (PHEVs) work similarly to conventional hybrids in that they
operate using the vehicle’s petrol or diesel engine or by using electricity to power an on-
board electric motor. However, PHEVs have much larger batteries than conventional HEVs
and so can also be charged from the mains when not in use – hence ‘plug-in’ – and this
means the vehicle can cover a greater distance. There are two key types of PHEV:
o The first can run indefinitely with the petrol/diesel motor providing power as in a
normal car.
o The second is effectively a battery-powered vehicle with a small onboard generator
to extend the distance the car can travel.
Most new electric vehicles also use an advanced braking system – known as ‘regenerative braking’ –
that allows the electric motor to re-capture the energy expended during braking that would normally
be lost. This improves energy efficiency and reduces wear on the brakes.
1.2 Why buy an electric vehicle?
Good for the environment: Electric vehicles emit lower levels of a range of air pollutants, e.g.
nitrogen oxides, particulate matter and greenhouse gases (e.g. carbon dioxide, CO2) than vehicles
using conventional petrol and diesel engines. Using electricity to power a vehicle means there is no
pollution at all when the vehicle is in use, unlike petrol and diesel cars. A car powered purely by a
battery has zero emissions when in operation, whereas the emissions from hybrids and plug-in
hybrids are lower than conventional vehicles as they use electricity for at least part of the journey.
When in use, all electric vehicles contribute less to air pollution in towns and cities and so have much
less impact on the climate than conventional vehicles.
Cheaper to run: As electricity is cheaper than petrol or diesel, the running costs of EVs are less than
conventional vehicles.
Quieter than conventional vehicles: EVs are also quieter than conventional vehicles – battery-
operated cars operate in almost complete silence, except for noise from the tyres.
Perfect for urban use: Reduced levels of pollution and noise make EVs ideal for inner city and urban
use.
Smooth acceleration and deceleration: BEVs benefit from smooth gearless acceleration and
deceleration, as a result of the characteristics of the electric motor.
4
6. 1.3 Disadvantages of electric vehicles
More expensive to buy: EVs generally cost more to buy than conventional vehicles.
EVs contribute to higher emissions elsewhere: Although electric-powered vehicles create zero or
fewer emissions than petrol or diesel cars when in use, there are emissions released when the any
mains electricity used is actually being produced. These emissions should be taken into account
when assessing the net environmental benefits of EVs. If renewable energy is used to generate the
electricity then the impact on the environment is much less than other vehicle technologies. If non-
renewable energy is used, then the environmental benefits are reduced. In addition, hybrid electric
vehicles cause greater pollution during manufacture and disposal than conventional vehicles.
Limited range: The distance that battery electric vehicles and some plug-in hybrids can travel
without the need for refuelling is shorter than conventional vehicles. However, hybrids and plug-in
hybrids can travel broadly the same distance, and in some cases further, than petrol and diesel cars.
Smaller vehicles and lower top speeds: Battery-powered vehicles tend to be smaller in size and
have lower top speeds than conventional cars. However, hybrids and plug-in hybrids are comparable
in size and speed.
1.4 When is it worth buying an electric vehicle?
Electric vehicles are cheaper to run, but more costly to buy, than conventional vehicles. So, for some
owners electric vehicles are potentially cost-effective, but not for others. This guide aims to provide
information to help potential buyers of electric cars, vans and buses to decide whether buying an
electric vehicle would be cost effective for them.
5
7. 2 Considering Buying an Electric Car?
2.1 Buying a Battery Electric Car
Costs
Buying a battery electric car: Battery-powered cars generally cost more to buy than conventional
cars, partly because electric batteries are expensive. However, it is likely that the cost of a battery will
reduce in the future as the number of batteries manufactured increases. To help reduce costs,
batteries can often be leased or rented instead of bought, e.g. the Th!ink City car’s battery pack is
leased to consumers at a fee of approximately €120 per month.
Operational and maintenance costs: It costs substantially less to operate a battery electric car than
a conventional car, for example, the Reva G-Wiz costs just 0.08 cents per kilometre (0.13 cents per
mile) to run1. Maintenance costs are also much reduced as battery electric cars are mechanically very
simple.
Taxes: Owners of electric cars pay lower taxes than owners of other cars. In 2007, electric cars solely
propelled by a re-chargeable battery were entitled to up to a 50% reduction in vehicle registration tax
(VRT). Similarly, for the annual motor tax, owners of electric vehicles currently pay €146 per year,
whereas the fee for a conventional private car ranges from €151 for cars with an engine size less than
or equal to 1,000cc up to €1,343 for a car with an engine size over 3,000cc. In 2008, new systems of
VRT and annual motor taxation are likely to be introduced, which could require buyers and users of
higher polluting vehicles to pay even more tax.
Who would benefit from buying a battery electric car?
As can be seen in Figure 1, below, an average car user, who owns a car for 10 years and drives around
17,000 kilometres a year, would benefit financially from buying an electric car. Over the lifetime of the
car, the owner could save around €6,900 by using an electric car instead of a petrol car and around
€5,700 if they bought an electric car instead of a diesel car. These savings relate to the use of relatively
small cars, as these are the most common size of electric car available in 2007.
1
Reva G-Wiz promotional literature
6
8. Figure 1: Comparison of the relative costs of ownership of battery electric cars compared to
petrol and diesel equivalents
30,000
Costs for ownership period, Euro
25,000
20,000
15,000
10,000
5,000
0
BEV Petrol Diesel
Energy costs (fuel)
Running costs (non-energy)
Capital costs
Practicalities
Driving range: Currently, a limitation of battery electric cars is the relatively short distance they can
be driven before they need recharging. Many of the smaller commuting battery-powered cars, such
as the Reva, have a range of around 50 to 100 kilometres (30 to 60 miles) while some high
performance examples, such as the Teslar Roadster, can travel around 240 kilometres (150 miles).
Recharging: Electric cars are recharged by plugging them into an existing conventional mains
socket. The Reva vehicle can be fully charged in six hours, whilst an 80% charge can be achieved in as
little as two-and-a-half hours.
Battery lifetime: The length of time a battery lasts will depend on how often it is used, charged and
discharged. Regular fast-charging can reduce the lifetime of current batteries. However, for average
usage, the battery should only need to be replaced a couple of times in the vehicle’s lifetime. The
manufacturer of the car will be able to advise how best to look after the battery to extend its life.
Battery technology is also improving rapidly – over the last three years there has been a significant
increase in the battery lifetimes.
Top speed: Small urban battery electric cars typically have top speeds of 65 kilometres (40 miles) per
hour.
Vehicle availability: The following is a list of battery electric cars currently on sale in Ireland:
• The Reva G-wiz (http://www.greenmachines.ie/)
• Micro-Vett - Ydea city car (http://www.micro-vett.it/english/ydeaing.html)
• Micro-Vett - Doblo vehicle (http://www.micro-vett.it/english/company.html)
Other battery electric cars not currently available in Ireland, but available in Europe, include:
• The MEGA City car (http://www.niceccarcompany.co.uk)
• The Maranello 4cycle (http://www.maranello4cycle.com/)
• Fiat Fiorino, developed by Micro-Vett
7
9. Other battery electric cars currently under development in Europe include:
• Th!ink City car (http://en.think.no/)
• EV Smart for 2 (being developed for Mercedes)
High performance sports cars (mainly currently only available in the United States) include:
• Teslar Roadster (www.teslamotors.com)
• Zap-X
• WrightSpeed X1
• Tango T600 (other smaller models under development)
Sports electric cars being developed in Japan are:
• Mitsubishi's MIEV
• Subaru R1e
How much better are battery cars for the environment?
Figure 2 shows estimated CO2 emissions for battery electric cars and those of conventional petrol and
diesel cars, for average ownership and use2. As can be seen, a battery electric car emits less CO2 than a
conventional car.
Figure 2: Estimated CO2 emissions arising from the production, disposal and use of battery
electric and conventional petrol and diesel cars
40,000
35,000
30,000
25,000
Kg CO2
20,000
15,000
10,000
5,000
0
BEV P etrol D iesel
P rodu c tion a nd R ec yc ling /D is po s al
In -U s e E m is s io ns - F u el C yc le
In -U s e E m is s io ns - T a ilp ipe
Life-cycle CO2 emissions
2
i.e. driving 17,000 kilometres a year and owning the car for 10 years
8
10. 2.2 Buying a Hybrid Electric Car
Purchase costs: On average, hybrid electric cars can cost around 20-25% more than a petrol or diesel
model to purchase. However, manufacturers are planning to increase their production of hybrid
vehicles, which will result in the manufacturing costs being reduced, and so should bring down the
price of hybrids.
Operational costs: Hybrid electric cars cost less to operate than conventional cars, as fuel
expenditure will be less, which will help to balance out the higher initial purchase costs. The rate at
which the lower cost of use makes up for the higher cost of purchase will depend on particular use
patterns and fuel prices. For example, the further a car is driven, the more it is used in urban areas
and the higher then fuel price, the sooner the owner will start to save money.
Maintenance costs: Given the fact that hybrid cars have both a petrol or diesel engine and an
electric motor, their maintenance costs are likely to be higher than cars which have either an electric
motor or a conventional engine. On the other hand, the use of ‘regenerative’ braking systems in
electric cars means that the vehicle’s brake discs and pads do not wear as quickly and so do not need
to be replaced as often. Additionally, the electric drive systems of hybrid cars also have very low
maintenance requirements.
Taxes: Owners of some hybrid electric cars pay lower taxes than owners of other cars. In 2007, this
amounted to 50% relief from vehicle registration tax (VRT). In 2008, a new system of VRT is likely to be
introduced, which could require buyers and users of higher polluting vehicles to pay more tax.
Who would benefit from buying a hybrid electric car?
Owners who have a high annual mileage rate are likely to benefit most from having a hybrid electric
car because although more expensive to buy, hybrids are cheaper to run. As Tables 3 and 4 show,
hybrids have to be used more intensively than conventional cars3 or kept for longer in order for
owners to save money. For example, someone who plans to own a hybrid car for only 5 years will
have to travel 38,000 kilometres (23,500 miles) each year – more than twice the average annual
distance driven in Ireland – to make the purchase of a hybrid petrol car worthwhile. Alternatively,
someone who owns a petrol hybrid car for 10 years (the average length of ownership) will need to
travel 25,500 kilometres (16,000 miles) each year to make the additional costs of purchasing a hybrid
worthwhile. The equivalent distances to make the purchase of a diesel hybrid worthwhile are even
further due to the cheaper fuels costs associated with running conventional diesel cars (compared to
petrol cars).
Drivers who travel the average distance of 17,000 kilometres a year would have to own a petrol
hybrid car for 21 years to recover the additional costs of buying the car, and a diesel hybrid for more
than 25 years.
Table 1: When is it worth buying a petrol hybrid electric car?4
Assumption: Average Short-term Average use/
ownership ownership/ Long-term
high use ownership
Ownership period (years) 10 5 21
Annual distance driven (km) 25,500 38,000 17,000
% of driving in city areas 25% 25% 25%
Financial costs:
Capital cost (after discount and including resale) €25,500 €23,600 €27,100
Running costs (non-energy i.e. tax + maintenance) €7,800 €4,800 €12,200
Running costs (energy) €12,300 €11,200 €12,900
Total cost (over ownership period) €45,500 €39,600 €52,200
3
The average car is driven 17,000 kilometres (10,500 miles) per year in Ireland
4
Compared to a conventional petrol car
9
11. Table 2: When is it worth buying a diesel hybrid electric car?5
Assumption: Average Short-term
ownership ownership/
high use
Ownership period (years) 10 5
Annual distance driven (km) 34,500 53,500
% of driving in city areas 25% 25%
Financial costs:
Capital cost (after discount and including resale) €28,800 €27,300
Running costs (non-energy i.e. tax + maintenance) €7,800 €4,800
Running costs (energy) €13,400 €12,800
Total cost (over ownership period) €50,000 €44,900
Figure 2 shows the differences in total costs for an average driver in Ireland. At this level of usage,
hybrid cars are marginally more expensive than conventional cars.
Figure 2: Relative costs of ownership of hybrid petrol and hybrid diesel cars compared to
petrol and diesel equivalents for an average driver in Ireland
45,000
Costs for ownership period, Euro
40,000
35,000
30,000
25,000
20,000
15,000
10,000
5,000
0
HEV Petrol HEV Diesel
(petrol) (diesel)
Energy costs (fuel)
Running costs (non-energy)
Capital costs
Practicalities
There are essentially no practical limitations of hybrid electric cars compared to regular petrol and
diesel equivalents.
Driving range: The range of a hybrid will be further than that of a conventional petrol or diesel car, as
it uses petrol or diesel as well as a battery.
Recharging: None, as a hybrid’s electric motor is recharged automatically as the car is being driven.
Battery lifetime: Batteries can last several years, e.g. for the Prius, Toyota provides an 8-year (or
160,000 kilometres) warranty for its entire hybrid system including the battery. Experience suggests
that batteries can last longer than this.
Top speed: A hybrid electric car can reach similar speeds as a conventional car.
5
Compared to a conventional diesel car
10
12. Vehicle availability: The following hybrid cars are currently available for purchase in Ireland:
• Toyota Prius www.toyota.ie
• Lexus RX 400h and Lexus GS 450h http://www.lexus.ie/
• Honda Civic IMA www.honda.ie
Other hybrids currently under development include:
• Peugeot 308 Hybride Hdi (on sale in 2009)
• Citroën C4 Hybride Hdi (diesel; demonstration model)
• Opel Astra Diesel Hybrid (being tested by General Motors)
• Volkswagen has made a prototype diesel-electric hybrid car
Other benefits
• There is the potential for reduced motor insurance premiums. For example, the Royal Sun
Alliance announced in December 2006 that it would offer a 25% discount to new and
existing customers with hybrid vehicles. The discount currently applies to the Toyota Prius,
the Lexus RX400H, the Lexus GS450H and the Honda Civic IMA.
• Some hybrid electric vehicles can operate on pure electric mode for short distances at low
speeds so that they are almost completely silent (except for tyre noise, which is low at typical
urban speeds).
How much better are hybrids for the environment?
The figures below show estimated CO2 emissions arising from petrol and diesel hybrids compared to
conventional petrol and diesel cars, for average ownership and use6. As can be seen, a hybrid car
emits less CO2 than a conventional car.
6
i.e. driving 17,000 kilometres a year and owning the car for 10 years
11
13. Figure 3: Estimated CO2 emissions arising from the production, disposal and use of petrol
and diesel hybrid cars under average use.
40,000
35,000
30,000
Kg CO2 25,000
20,000
15,000
10,000
5,000
0
HEV Petrol HEV Diesel
(petrol) (diesel)
Production and Recycling/Dis pos al
In-Us e Em is s ions - Fuel Cycle
In-Us e Em is s ions - Tailpipe
Life-cycle CO2 emissions
2.3 Buying a Plug-in Hybrid Electric Car
Costs
Buying a plug-in hybrid electric car: It is anticipated that plug-in hybrid electric cars may cost up to
40-50% more than a conventional petrol or diesel car to buy, due mainly to the additional cost of the
batteries. However, the difference in cost will come down, as more hybrids come on to the market.
Current plug-in hybrid cars are modified versions of conventional cars and hybrid cars. However,
manufacturers such as Toyota have announced that they are considering developing original plug-in
hybrids, in order to increase the number of hybrid cars on the market.
Operational costs: The fuel costs over the lifetime of a plug-in hybrid car will be significantly lower
than for a car with only a petrol or diesel engine. Owners can therefore make significant savings on
fuel expenditure, which will help to balance out the initial higher purchase costs (see below).
Maintenance costs: As a result of having both an electric motor and a conventional engine, plug-in
hybrids are likely to have higher maintenance costs than those cars with either a motor or an engine.
On the other hand, as with ordinary hybrids, the use of regenerative braking systems in plug-in
hybrids means that brake discs and pads do not wear out as quickly as they would in a conventional
car. Additionally, the electric drive systems in plug-in hybrids have comparatively low maintenance
requirements.
Taxes: Owners of some plug-in hybrid electric cars also pay lower taxes than owners of other cars. In
2007, this amounted to a 50% reduction in vehicle registration tax (VRT). In 2008, a new system of VRT
is likely to be introduced, which could require buyers and users of higher polluting vehicles to pay
more tax.
12
14. Who would benefit from buying a plug-in hybrid electric car?
The benefits of plug-in hybrids are the same as those of ordinary hybrids. They are more expensive to
buy than conventional cars, but cheaper to run, and the further a hybrid is driven, the sooner the
owner will start to save money (see Table 3 and Table 4). For example, an owner planning to keep a
plug-in hybrid car for only five years before selling it on, would save money if they drove a petrol
plug-in hybrid car over 50,000 kilometres a year (compared to a conventional petrol car). If a petrol
plug-in hybrid car were to be kept for 10 years, then the owner would have to drive at least 33,500
kilometres a year to save money. The equivalent figures for a diesel plug-in hybrid (compared to a
conventional diesel car) are much higher at 50,000 kilometres and 77,000 kilometres, respectively.
The average driver (i.e. one who drives 17,000 kilometres a year) would have to keep their car for
more than 25 years to make buying a plug-in hybrid car worthwhile.
Table 3: When does it become worthwhile to buy a petrol plug-in hybrid electric car?7
Assumption: Average Short-term
ownership ownership/
high use
Ownership period (years) 10 5
Annual distance driven (km) 33,500 50,000
% of driving in city areas 25% 25%
% of time battery is charged over-night 80% 80%
% of time running off grid electricity 50% 50%
Financial costs:
Capital cost (after discount and including resale) €30,600 €28,800
Running costs (non-energy i.e. tax + maintenance) €8,200 €5,000
Running costs (energy) €12,300 €11,200
Total cost (over ownership period) €51,100 €45,000
Table 4: When does it become worthwhile to buy a diesel petrol plug-in hybrid car?8
Assumption: Average Short-term
ownership ownership/
high use
Ownership period (years) 10 5
Annual distance driven (km) 50,000 77,000
% of driving in city areas 25% 25%
% of time battery is charged over-night 80% 80%
% of time running off grid electricity 50% 50%
Financial costs:
Capital cost (after discount and including resale) €34,400 €33,300
Running costs (non-energy i.e. tax + maintenance) €8,200 €5,000
Running costs (energy) €16,000 €15,100
Total cost (over ownership period) €58,600 €53,400
Figure 4 shows the differences in total costs for an average driver in Ireland. At this level of usage,
plug-in hybrid cars are more expensive than conventional cars.
7
Compared to a petrol car
8
Compared to a diesel car
13
15. Figure 4: Relative costs of ownership of plug-in hybrid petrol and plug-in hybrid diesel cars
compared to petrol and diesel equivalents under the “average” scenario
50,000
Costs for ownership period, Euro
45,000
40,000
35,000
30,000
25,000
20,000
15,000
10,000
5,000
0
PHEV Petrol PHEV Diesel
(petrol) (diesel)
Energy costs (fuel)
Running costs (non-energy)
Capital costs
14
16. Practicalities
Driving range: The driving range of plug-in hybrid car is further than that of a battery electric car, as
for longer journeys, the car uses the electric motor first before switching to the petrol or diesel
engine. It can be expected that the range of a plug-in hybrid car would be similar to that of a
conventional hybrid car.
Recharging: Plug-in hybrids can be recharged both from the engine and from the mains electricity
supply. The normal charging time from the mains is around 8 to 9 hours.
Battery lifetime: Battery life is shorter than for ordinary hybrids due to the fact that the battery is
used more regularly in a plug-in.
Top speed: The top speed of a plug-in hybrid car is likely to be similar to the top speed of a hybrid or
conventional car.
Vehicle availability: There are no plug-in hybrid electric cars currently available for sale in Ireland,
but it is likely that they will become available over the next few years. For example, Toyota has
announced plans to develop a plug-in version of the Prius (www.toyota.ie), while other
manufacturers, such as General Motors, Ford and Chinese automaker BYD Auto, have announced
their intention to introduce plug-in hybrid cars.
How much better are plug-in hybrids for the environment?
The figure below compares CO2 emissions for petrol and diesel plug-in hybrids compared to
conventional petrol and diesel cars, for average ownership and use. As can be seen, a plug-in hybrid
car emits less CO2 than a conventional car.
Figure 5: Estimated CO2 emissions arising from the production, disposal and use of petrol
and diesel plug-in hybrid cars
40,000
35,000
30,000
25,000
Kg CO2
20,000
15,000
10,000
5,000
0
PHEV Petrol PHEV Diesel
(petrol) (diesel)
Production and Recycling/Disposal
In-Use Emissions - Fuel Cycle
In-Use Emissions - Tailpipe
Life-cycle CO2 emissions
15
17. 3 Considering Buying an Electric Van?
3.1 Buying a Battery Electric Van
Costs
Buying a battery electric van: On average, a battery electric van will cost more than a conventional
petrol or diesel van, although it is possible to find electric vans which are not much more than a diesel
model. It is likely that the cost of a battery will decline in the future as the number of batteries
manufactured increases. It is also anticipated that conventional diesel vans may increase in price over
the next few years due to increased manufacturing costs and the development of costlier pollution
control systems. This will therefore reduce the price difference between diesel and battery electric
vans.
Operational and maintenance costs: It costs substantially less to run a battery electric van than a
conventional van. Maintenance costs are also comparatively low, estimated at only a few hundred
euros per year.
Taxes: Battery electric vans benefit from a discounted rate of tax (€80 per annum) for electric goods
vehicles not over 1,500kg, compared to petrol and diesel equivalents.
Who would benefit from buying a battery electric van?
As can be seen from Figure 6, below, an average van user, i.e. one who owns a van for 10 years and
drives 22,500 kilometres a year, would benefit from buying an electric van. Over the lifetime of the
van, the owner would make a saving of around €600. It should be noted that the comparison in the
table below is based on relatively small vans, as these are the most commonly used.
Figure 6: Comparison of the relative costs of ownership of battery electric vans compared to
petrol and diesel equivalents
60,000
50,000
40,000
30,000
20,000
10,000
0
BEV Petrol Diesel
Energy costs
Running costs (non-energy)
Capital costs
16
18. Practicalities
Driving range: Battery electric vans currently available (see below) have a range of between 70 to
160 kilometres (45 to 100 miles).
Recharging: Vans generally require an overnight (8 hour) charge. Some battery electric vans can be
recharged by plugging them into an existing conventional socket; whilst fast-charging stations are
also available.
Battery lifetime: The length of time a battery lasts will depend on how often it is used, charged and
discharged, although regular fast charging can reduce the lifetime of current batteries. However, for
average usage, an owner of a battery electric van could be expected to replace the battery a couple
of times in the lifetime of the vehicle. The van manufacturer will be able to advise how best to look
after the battery to extend its life. Battery technology is improving – in recent years there has been a
significant increase in the expected life of a battery.
Top speed: The battery electric vans currently available in Ireland have top speeds of between 60
(Micro-Vett Porter) and 80 (Modec) kilometres (37.5 to 50 miles) per hour.
Vehicle availability: There are currently two European manufacturers of battery electric vans
accessible in Ireland:
• UK-based Modec (www.modec.co.uk); and
• Italian Micro-Vett (http://www.micro-vett.it/eng/indexing.html)
Other companies that are producing electric vans, include
• Smith Electric Vehicles (SEV) (http://www.smithelectricvehicles.com/)
• NICE (No Internal Combustion Engine) (http://www.nicecarcompany.co.uk/megatruck/)
• Zap Truck XL: all electric multipurpose urban truck (http://www.zapworld.com/electric-
vehicles/electric-cars)
How much better are battery electric vans for the environment?
The figure below shows estimated emissions of CO2 from battery electric vans compared to those of
conventional petrol and diesel vans, for average ownership and use9. The data shows that a battery
electric van emits less CO2 than a conventional van.
9
i.e. driving 22,500 kilometres a year and owning the van for 10 years
17
19. Figure 7: Estimated CO2 emissions arising from the production, disposal and use of battery
electric and petrol and diesel vans
80,000
70,000
60,000
Kg CO2 50,000
40,000
30,000
20,000
10,000
0
BEV Petrol Diesel
Production and Recycling/Disposal
In-Use Emissions - Fuel Cycle
In-Use Emissions - Tailpipe
Life-cycle CO2 emissions
3.2 Buying a Hybrid Electric Van
Costs
Purchase costs: On average, hybrid electric vans can cost around 25% more than conventional petrol
or diesel vans. However, manufacturers are planning to increase their production of hybrid vehicles,
which should quickly drive down the costs, and thus the price of hybrids.
Operational costs: Operating a hybrid van costs less than operating a conventional van, as fuel
expenditure will be less, which will help to balance out the initial purchase costs (see below). The rate
at which the higher purchase costs are recovered will depend on the particular use patterns and fuel
prices. The costs will be recovered fastest when the van is driven long distances, used mainly in urban
areas and when fuel prices are high.
Maintenance costs: Given the fact that hybrid vans have both a conventional (petrol or diesel)
engine and an electric motor, their maintenance costs are likely to be higher than vans with either an
electric motor or a conventional engine. On the other hand, the use of regenerative braking systems
means that the conventional brake discs and pads receive lower rates of wear and require less
frequent replacement. Furthermore, the electric drive systems of hybrid vans also have very low
maintenance requirements.
Taxes: There are currently no direct tax incentives for hybrid electric vans relative to conventional
petrol and diesel equivalents in Ireland.
18
20. Who would benefit from buying a hybrid electric van?
As can be seen from Table 5, the average owner of a petrol van would save approximately €1,600 a
year if they were to use a petrol hybrid van instead. However, petrol vans are more expensive than
hybrid vans, and are less common than diesel vans, so a better comparison of the costs are the figures
given for diesel vans (see Table 6). These are less favourable, although an average owner of a hybrid
diesel van (i.e. one who keeps the van for 10 years) could save money if they were to travel more than
26,500 kilometres a year, which is about 20% further than an average van would be driven in a year.
Owners who only keep a diesel hybrid van for five years would have to travel 39,500 kilometres a year
– 75% more than average – to make the purchase of a diesel hybrid van worthwhile. Alternatively, an
owner who drives the average distance for vans each year – 22,500 kilometres – would have to own
the van for 13 years to make the additional costs of purchase worthwhile.
Table 5: When is it worth buying a petrol hybrid electric van?10
Assumption: Average use Average Short-term
and ownership ownership ownership
Ownership period (years) 10 10 5
Annual distance driven (km) 22,500 15,000 22,000
% of driving in city areas 30% 30% 30%
Financial costs:
Capital cost (after discount and including resale) €24,400 €23,000 €20,700
Running costs (non-energy i.e. tax + maintenance) €11,200 €11,200 €6,900
Running costs (energy) €18,000 €12,000 €10,800
Total cost (over ownership period) €53,600 €46,200 €38,400
Savings compared to conventional petrol van €1,600 -* -*
* Nominal
Table 6: When is it worth buying a diesel hybrid electric van?11
Assumption: Average Short-term Average use/
ownership ownership Long-term
ownership
Ownership period (years) 10 5 13
Annual distance driven (km) 26,500 39,500 22,500
% of driving in city areas 30% 30% 30%
Financial costs:
Capital cost (after discount and including resale) €27,200 €25,200 €27,700
Running costs (non-energy i.e. tax + maintenance) €11,200 €6,900 €13,300
Running costs (energy) €14,000 €12,800 €14,200
Total cost (over ownership period) €52,400 €44,900 €55,200
Figure 8 shows the differences in total costs for an average van driver in Ireland12. At this level of
usage, diesel vans are marginally cheaper than hybrid vehicles.
10
Compared to a conventional petrol van
11
Compared to a conventional diesel van
12
i.e. one who drives 22,500 kilometres a year and keeps their van for 10 years
19
21. Figure 8: Relative costs of ownership of hybrid petrol and hybrid diesel vans compared to
petrol and diesel equivalents
60,000
Costs for ownership period, Euro
50,000
40,000
30,000
20,000
10,000
0
HEV (petrol) Petrol HEV Diesel
(diesel)
Energy costs (fuel)
Running costs (non-energy)
Capital costs
Practicalities
One of the main practical differences between a hybrid electric van and a conventional diesel van
would be that the batteries take up space that could otherwise be used for carrying loads.
Driving range: The range of a hybrid van will be further than that of a conventional petrol or diesel
van, as a hybrid electric van has an engine that uses petrol or diesel, as well as a battery.
Recharging: None, as a hybrid van’s electric motor is recharged automatically as the van is being
driven.
Battery lifetime: In theory, batteries in hybrid vans should last the same time as those used in hybrid
cars over the same distance. However, in practice, as vans are usually used more intensively than cars,
the battery is unlikely to last as long.
Top speed: A hybrid electric van can reach similar speeds to a conventional petrol or diesel van.
Vehicle availability: Current hybrid van manufacturers include:
• XGEM: http://www.xgem.net/
• DaimlerChrysler: http://www.daimlerchrysler.com/
• Azure Dynamics: http://www.azuredynamics.com/index.htm
• Micro-Vett: http://www.micro-vett.it/english/bimodaleing.html
How much better are hybrid vans for the environment?
The figure below provides estimated CO2 emissions for petrol and diesel hybrid vans compared to
conventional petrol and diesel vans, for average ownership and use13. As can be seen, a hybrid van
emits less CO2 than a conventional van.
13
i.e. driving 22,500 kilometres and owning the van for 10 years
20
22. Figure 9: Estimated CO2 emissions arising from the production, disposal and use of petrol
and diesel hybrid vans
80,000
70,000
60,000
50,000
Kg CO2
40,000
30,000
20,000
10,000
0
HEV Petrol HEV Diesel
(petrol) (diesel)
Production and Recycling/Disposal
In-Use Emissions - Fuel Cycle
In-Use Emissions - Tailpipe
Life-cycle CO2 emissions
3.3 Buying a Plug-in Hybrid Electric Van
Costs
Purchase costs: Plug-in hybrid electric vehicles can cost over 60% more than a conventional petrol or
diesel vehicle, due mainly to the additional cost of batteries. However, as higher numbers of plug-in
hybrid vehicles come onto the market and the technology develops, the difference in price will
become less.
Operational costs: The fuels costs over the lifetime of a plug-in hybrid van will be significantly lower
than for a van with only a petrol or diesel engine. Owners can therefore save significant amounts of
money on fuel expenditure, which will help to balance out the initial purchase costs (see below).
Maintenance costs: As for conventional hybrid vehicles, maintenance costs are likely to be higher, as
a result of having both an electric motor and a conventional engine. On the other hand, the use of
regenerative braking systems in plug-ins means that brake discs and pads do not wear out as quickly.
Additionally, the electric drive systems in plug-in hybrids have comparatively low maintenance
requirements.
Taxes: At the moment, there are no direct tax incentives for plug-in hybrid vans relative to their
conventional petrol and diesel equivalents in Ireland. However, it is possible that the discount that
currently applies to battery electric vans (electrical goods vehicles not over 1,500kg benefit from a
discounted rate of tax (€80 per annum) compared to petrol and diesel equivalents) could be
extended to plug-in hybrids.
21
23. Who would benefit from buying a plug-in hybrid electric van?
Currently the cost of plug-in hybrid electric vans means that only those owners who use vans – either
petrol or diesel – intensively would benefit financially from buying and using such a vehicle (see
Table 7and Table 8).
Table 7: When is it worth buying a petrol plug-in hybrid electric van?14
Assumption: Average Short-term
ownership ownership
Ownership period (years) 10 5
Annual distance driven (km) 53,500 79,500
% of driving in city areas 30% 30%
% of time battery is charged over-night 40% 40%
Financial costs:
Capital cost (after discount and including resale) €36,600 €35,500
Running costs (non-energy i.e. tax + maintenance) €13,400 €8,200
Running costs (energy) €39,500 €36,000
Total cost (over ownership period) €89,500 €79,600
Table 8: When is it worth buying a diesel plug-in hybrid electric van?15
Assumption: Average Short-term
ownership ownership
Ownership period (years) 10 5
Annual distance driven (km) 97,000 148,500
% of driving in city areas 30% 30%
% of time battery is charged over-night 40% 40%
Financial costs:
Capital cost (after discount and including resale) €40,600 € 40,500
Running costs (non-energy i.e. tax + maintenance) €13,400 € 8,200
Running costs (energy) €49,900 € 46,800
Total cost (over ownership period) €103,800 € 95,500
Figure 10 shows the differences in total costs for an average van driver in Ireland16. At this level of
usage, plug-in hybrids are more expensive than conventional vans.
14
Compared to a conventional petrol van
15
Compared to a conventional diesel van
16
i.e. one who drives 22,500 kilometres a year and keeps their van for 10 years
22
24. Figure 10: Relative costs of ownership of plug-in hybrid petrol and plug-in hybrid diesel vans
compared to petrol and diesel equivalents
70,000
Costs for ownership period, Euro
60,000
50,000
40,000
30,000
20,000
10,000
0
PHEV Petrol PHEV Diesel
(petrol) (diesel)
Energy costs (fuel)
Running costs (non-energy)
Capital costs
Practicalities
Driving range: The driving range of plug-hybrid van is longer than that of a battery electric van, as
for longer journeys, the van uses the electric motor first before using the petrol or diesel engine. The
range of a plug-in hybrid van is similar to that of an ordinary hybrid van.
Recharging: Plug-in hybrid vans can be recharged both from the engine and from the mains
electricity supply. The usual charging time from the mains is around 8 to 9 hours, although some
models, such as the Citroen Berlingo Electrique allow a fast charge, in which a ten-minute charge time
will provide 20 kilometres (12 miles) operation. In addition, photovoltaic panels can be used in some
cases to allow re-charging whilst the vehicle is parked, as available on the XGEM-HEV. The distance
travelled on one tank of fuel – for either a petrol or a diesel plug-in hybrid van – is typically two to
three times greater than the distance that a conventional van would travel on the same amount of
fuel.
Battery lifetime: Battery life for plug-in hybrids is shorter than for ordinary hybrids due to the fact
that the battery is used more regularly in a plug-in. Battery technology is currently not fully
developed, as it has high production and warranty costs.
Top speed: The top speed of a plug-in hybrid van is broadly similar to the top speed of a hybrid or
conventional petrol or diesel van.
Vehicle availability: A variety of companies are currently producing plug-in hybrid vans such as
Mercedes-Benz/ DaimlerChrysler (Germany/USA), UQM Technologies, Inc. (USA), Azure Dynamics
(USA), XGEM (USA), MICRO-VETT (Italy) and Citroen (France).
Other benefits
• When operating in pure electric mode, plug-in hybrids are almost completely silent (except
for tyre noise, which is low at typical urban speeds) offering significant benefits for use in
sensitive areas or at night-time.
23
25. How much better are plug-in hybrids for the environment?
The figure below provides estimated CO2 emissions for petrol and diesel plug-in hybrids compared to
conventional petrol and diesel vans, for average ownership and use. Plug-in hybrid vans emit less CO2
than conventionally fuelled vans.
Figure 11: Estimated CO2 emissions arising from the production, disposal and in-use
emissions of petrol and diesel plug-in hybrid vans
80,000
70,000
60,000
50,000
Kg CO2
40,000
30,000
20,000
10,000
0
PHEV Petrol PHEV Diesel
(petrol) (diesel)
Production and Recycling/Disposal
In-Use Emissions - Fuel Cycle
In-Use Emissions - Tailpipe
Life-cycle CO2 emissions
24
26. 4 Considering Buying an Electric Bus?
4.1 Buying a Battery Electric Bus
Costs
Purchase costs: Estimates in the United States suggest that a 7.5m battery electric bus would cost
somewhere between 50% and 100% more than a diesel bus, falling to about 33% for larger 10m
versions.
Operational and maintenance costs: The fact that battery electric buses have relatively simple
electric transmissions should mean that maintenance costs are greatly reduced compared to a diesel
bus. However, given that there is little experience with maintaining such vehicles at present (due to
the fact that there are few battery electric buses in operation), it is likely that maintenance costs
might currently be high.
Taxes: There are currently no direct tax incentives for battery electric buses relative to conventional
diesel equivalents in Ireland.
Who would benefit from buying a battery electric bus?
As can be seen from Table 9, below, if owned for 10 years, a battery electric bus would need to be
used intensively to recover the additional purchase costs of the vehicle. The owner would need to
operate the bus for a minimum of 130,000 kilometres before starting to save money.
On the basis of average usage17, battery electric buses would have to be operated for more than 25
years to recover the additional costs of purchase.
Table 9: When is it worth buying a battery electric bus?
Assumption: Full size or midi-bus Minibus
Inter- Average
Urban urban Express life-time
Ownership period (years) 10 10 10 10
Annual distance driven (km) 130,000 207,000 320,000 130,000
% of driving in city areas 90% 40% 10% 40%
% of time battery is charged over- 30% 20% 10% 60%
night
Financial costs:
Capital cost (after discount and €418,500 €422,200 €422,300 €82,200
including resale)
Running costs (non-energy i.e. tax + €265,600 €265,600 €265,600 €24,100
maintenance)
Running costs (energy) €121,300 €212,300 €345,900 €41,900
Total cost (over ownership period) €805,500 €900,100 €1,033,800 €148,200
Figure 12 shows that, for comparable use and ownership characteristics, diesel buses are cheaper to
own and operate than battery electric buses.
17
Where average annual bus usage is taken to be 27,500 kilometres for mini buses, 48,500 kilometres for urban
buses, 80,500 kilometres for inter-urban buses and 112,500 kilometres for express buses
25
27. Figure 12: Comparison of the relative costs of ownership of battery electric and diesel buses
in urban areas, and battery electric and diesel minibuses for average usage
700,000 120,000
600,000
100,000
Costs for ownership period, Euro
Costs for ownership period, Euro
500,000
80,000
400,000
60,000
300,000
40,000
200,000
20,000
100,000
0 0
BEV Dies el BEV Dies el
E nergy cos ts (fuel) E nergy cos ts (fuel)
R unning cos ts (non-energy) R unning cos ts (non-energy)
C apital cos ts C a pita l cos ts
Full size/Midi-Bus - Urban Minibus – Average use
Practicalities
Driving range: Battery electric buses suffer heavily from lack of range due to their weight. This
technology is therefore generally limited to mini- or midi-buses which are very well suited to certain
types of journeys, such as transit buses at airports or large industrial sites where a recharging
infrastructure is easy to establish. Alternatively, they could be used in areas of comparatively light
usage, such as parks or other tourist areas where they operate as an attraction as well as a viable
means of transport. One example of this is the Ebus transit shuttle that is manufactured in California
and has an operational range of approximately 95 to 145 kilometres (60 to 90 miles) when operating
on nickel cadmium batteries.
Recharging: In general, recharging is a slow process that can take several hours and this is one of the
biggest barriers to large-scale usage of battery electric buses. However, the technology is developing
and faster charging is now possible. For example, the Ebus transit shuttle allows ‘opportunity
charging’, with approximately 1.6 kilometres of range added for every minute of charge added to the
battery pack. Such a quick charge approach, however, may have an adverse affect on battery life.
Vehicle availability: There are no totally independent large electric buses at present, although some
have the capability to operate away from the grid for a short time. The weight inherent in utilising
battery electric technology also has limitations on the size of vehicles available. Currently, most
independent electric buses are in the mini to midi size ranges and are suited to specific usages. For
example, Ebus sell a shuttle-sized electric bus ideal for use in small towns or locations such as airports,
as well as heritage style trolleys for use in historic areas, parks or seafront areas.
26
28. Other benefits
• As with other electric vehicles, battery electric buses operate quietly, with smooth
acceleration through the gearless transmission and deceleration through the regenerative
braking system. The electric motor is suited to inner city and urban usage, as well as steep
hills.
• Some battery electric vehicles do not have the need for gear shifting, giving both smoother
acceleration and braking.
How much better are battery electric buses for the environment?
The figures below compare CO2 emissions for diesel, hybrid and plug-in hybrid buses, both full-
sized/midi-buses and minibuses, for comparable ownership and use characteristics. The figures for
full-size/midi-buses represent typical urban use, while those for minibuses represent ‘average’ use18.
The figures show that battery electric buses are better for the environment than diesel buses.
Figure 13: Estimated CO2 emissions arising from the production, disposal and use of battery
electric and diesel buses
600,000 80,000
70,000
500,000
60,000
400,000
50,000
Kg CO2
Kg CO2
300,000 40,000
30,000
200,000
20,000
100,000
10,000
0 0
BE V Dies el BE V Dies el
P roduction and R ecycling/Dis pos al P roduction and R ecycling/Dis pos al
In-Us e E mis s ions - Fuel C ycle In-Us e E mis s ions - Fuel C ycle
In-Us e E mis s ions - Ta ilpipe In-Us e E mis s ions - Ta ilpipe
Full size/Midi-Bus Minibus
Life-cycle CO2 emissions
18
i.e. driving 27,500 kilometres a year and owning the bus for 10 years
27
29. 4.2 Buying a Hybrid or Plug-in Hybrid Electric Bus
Costs
Purchase costs: Hybrid buses are more expensive to buy then diesel buses, although if hybrid buses
are used extensively, there is the potential to save money in the longer-term.
Operational costs: In general, hybrid electric buses use significantly less fuel than regular diesels and
this can lead to large cost savings over the operational lifetime of the vehicle.
Maintenance costs: At the moment, hybrid buses are expensive to maintain mainly because the
technology is very new. Also, there are few hybrid buses in operation and this means that the market
is too small to provide cheap parts and servicing. However, if more hybrid buses enter into operation,
then maintenance costs are expected to fall.
Taxes: There are currently no direct tax incentives for hybrid buses relative to conventional diesel
equivalents in Ireland.
Who would benefit from buying a hybrid electric bus?
As can be seen from the tables below, if owned for 10 years, hybrid buses would need to be used
intensively to recover the additional purchase and maintenance costs of the vehicle, compared to a
diesel bus. The shortest annual distance travelled after which the operator would start to make cost
savings is 121,000 kilometres. On the basis of average usage19, hybrid buses would have to be
operated for more than 25 years to recover the additional costs of purchase.
Table 10: When is it worth buying a hybrid diesel or plug-in hybrid diesel bus?
Assumption: Hybrid bus Plug-in hybrid bus
Inter- Inter-
Urban urban Express Urban urban Express
Ownership period (years) 10 10 10 10 10 10
Annual distance driven (km) 121,000 196,000 305,000 124,000 201,000 325,000
% of driving in city areas 90% 40% 10% 90% 40% 10%
Financial costs:
Capital cost (after discount €365,900 €370,900 €371,000 €392,300 €397,000 €371,000
and including resale)
Running costs (non-energy €201,400 €201,400 €201,400 €222,100 €222,100 €201,400
i.e. tax + maintenance)
Running costs (energy) €211,700 €303,100 €435,000 €173,800 €267,900 €462,900
Total cost (over ownership €779,000 €875,400 €1,006,800 €788,200 €887,000 €1,035,300
period)
19
Where average annual bus usage is taken to be 27,500 kilometres for mini buses, 48,500 kilometres for urban
buses, 80,500 kilometres for inter-urban buses and 112,500 kilometres for express buses
28
30. Table 11: When is it worth buying a hybrid diesel or plug-in hybrid diesel mini bus?
Assumption: Plug-in
Hybrid mini bus hybrid
Average
Average ownership Average
ownership and city use ownership
Ownership period (years) 10 10 10
Annual distance driven (km) 58,000 43,000 125,000
% of driving in city areas 40% 100% 40%
Financial costs:
Capital cost (after discount and including resale) €49,000 €47,000 €66,900
Running costs (non-energy i.e. tax + €19,000 €19,000 €22,900
maintenance)
Running costs (energy) €29,500 €28,100 €54,800
Total cost (over ownership period) €97,500 €94,100 €144,600
Figure 14 shows that, for comparable use and ownership characteristics, diesel buses are cheaper to
own and operate than hybrid or plug-in hybrid buses.
Figure 14: Relative costs of ownership of diesel, hybrid diesel and plug-in diesel full
size/midi-buses and minibuses
700,000 100,000
90,000
600,000
80,000
Costs for ownership period, Euro
Costs for ownership period, Euro
500,000 70,000
60,000
400,000
50,000
300,000 40,000
30,000
200,000
20,000
100,000 10,000
0
0 Dies el HEV PHEV
Dies el HEV (dies el) PHEV (dies el) (dies el)
(dies el) E nergy cos ts (fuel)
E nergy cos ts (fuel) R unning cos ts (non-energy)
R unning cos ts (non-energy) C a pita l cos ts
C apital cos ts
Full size/Midi-Bus (urban conditions) Minibus (average use and ownership)
29
31. Practicalities
Driving range: The fact that a hybrid bus has a diesel engine means that there is no significant limit
on the range of these vehicles. Fuel consumption in a hybrid bus is better than a diesel model so this
means that hybrid buses can travel further. Also, the fuel tank of a hybrid bus can be made smaller,
thus reducing the weight of the vehicle and providing further fuel economy without any loss of
range.
Recharging: Hybrid buses operate exactly as diesel buses and can be fuelled in much the same
manner. There are none of the charging time issues relating to electric buses and as such, turn around
times will be similar to those experienced in a conventional fleet. Plug-in hybrid buses can, however,
be charged using mains electricity to increase the range.
Battery lifetime: The length of a hybrid bus battery’s life will depend on how often it is used,
charged and discharged, although regular fast charging can significantly reduce the lifetime of
current batteries. Further information on looking after the battery in order to extend its life can be
obtained from the manufacturer. Over the last three years, there has been a significant increase in the
expected length of a battery’s life.
Top speed: Hybrid buses can travel at similar speeds to diesel buses and are more than capable at
operating at the speeds required for transporting passengers.
Vehicle availability: Wrightbus, based in Northern Ireland (www.wrightbus.com), is one of the
largest hybrid bus manufacturers and offers hybrid versions of its single and double-deck buses, as
well as an articulated tram-style bus. Currently, there are six test buses in London and trial of a hybrid
double-deck bus was due to begin in Dublin in 2007.
Other operational issues: There are a number of specific issues relating to the use and maintenance
of hybrid and plug-in hybrid electric drive buses. It should be noted that the difference in technology
leads to different skills and requirements for maintenance. For example, a study conducted for New
York City Transit found that there was a need to ‘condition’ the batteries once every sixth months.
This required the batteries to be connected to a specific charger for a period of about 8-10 hours.
Manufacturers would be able to provide greater information as to the specific maintenance
requirements of different vehicles.
Other benefits
• An electric motor is particularly suited to climbing hills and accelerating, making it an ideal
system to power an urban bus
• Electric drive systems are very reliable. This, along with the ability to reduce the size of the
combustion engine allows for less frequent maintenance.
How much better are hybrid buses for the environment?
The figures below provide estimated CO2 emissions for diesel, hybrid and plug-in hybrid buses, both
full-sized/midi-buses and minibuses, for comparable ownership and use characteristics. As above, the
figures for full-size/midi-buses represent typical urban use, while those for minibuses represent
‘average’ use20. The figures show that generally plug-in buses are better for the environment than
hybrid buses, which are in turn significantly better for the environment than diesel buses.
20
i.e. driving 27,500 kilometres a year and owning the bus for 10 years
30
32. Figure 15: Estimated CO2 emissions arising from the production, disposal and use of diesel,
hybrid and plug-in hybrid urban buses
600,000
500,000
Kg CO2 400,000
300,000
200,000
100,000
0
Dies el HE V P HE V
(dies el) (dies el)
P roduction a nd R ecycling/Dis pos a l
In-U s e E mis s ions - Fuel C ycle
In-U s e E mis s ions - Tailpipe
Life-cycle CO2 emissions
Figure 16: Estimated CO2 emissions arising from the production, disposal and use of diesel,
hybrid and plug-in hybrid minibuses
80,000
70,000
60,000
50,000
Kg CO2
40,000
30,000
20,000
10,000
0
Dies el HE V P HE V
(dies el) (dies el)
P roduction and R ecycling/Dis pos al
In-Us e E mis s ions - Fuel C ycle
In-Us e E mis s ions - Ta ilpipe
Life-cycle CO2 emissions
31
33. 5 Additional Sources of Information
International Energy Agency - hybrid and electric vehicle implementing agreement:
http://www.ieahev.org/
Anderman, 2007. Status and prospects of battery technology for hybrid electric vehicles, including
plug-in hybrid electric vehicles. Briefing to the U.S. Senate committee on energy and natural
resources. January 26, 2007.
Duvall, 2003. Advanced batteries for electric drive vehicles. A technology and cost-effectiveness
assessment for battery electric, power assist hybrid electric and plug-in hybrid electric vehicles. March
25th, 2003. EPRI, California, USA.
The US Department of Energy, Clean Cities Programme: http://www.eere.energy.gov/cleancities/hev/
Well to wheel analysis of future automotive fuels and powertrains in the European context:
http://www.senternovem.nl/mmfiles/114333_tcm24-124321.pdf
Hybrid buses in London:
http://www.tfl.gov.uk/corporate/projectsandschemes/environment/2019.aspx
Information from the UK’s Energy Saving Trust on hybrid and battery operated vehicles:
http://www.energysavingtrust.org.uk/fleet/technology/lowcarbonvehicles/hybridvehicles/
http://www.energysavingtrust.org.uk/fleet/technology/lowcarbonvehicles/electricvehicles/
32
34. 6 Glossary
Carbon dioxide (CO2) – A gas that is present in a low concentration in the Earth's atmosphere and is
essential for life. It therefore does not have a direct impact on human health. However, the gas is a
greenhouse gas that contributes to global warming and climate change.
Midibus - a classification of single decker buses which are between minibuses and full size buses in
terms of size, with seating capacities between 20 to 40 people. Midibuses are often designed to be
light weight to save on fuel (e.g. smaller wheels than on larger buses), but are then less durable than
full size buses.
Regenerative Braking – Technology that allows energy that would otherwise be wasted as heat
during braking to be recycled back into the electrical storage system.
33
35. Sustainable Energy Ireland t + 353 1 836 9080
Glasnevin f + 353 1 837 2848
Dublin 9 e info@sei.ie
Ireland w www.sei.ie