SERIES HYBRIDS: In series hybrids o

SERIES HYBRIDS: In series hybrids only electric motor
drives the train and ICE works as generator to power electric
motor or to recharge batteries. The battery pack can be
recharged through regenerative braking or by internal
combustion engine. Series hybrids usually have smaller
combustion engine but a larger battery pack as compared to
parallel hybrids which makes them more expensive than
parallel. This configuration makes series hybrids more
efficient in city driving. Some of the examples of series
hybrids are Chevrolet.
4. POWERSPLIT HYBRIDS: It has benefits of
combination of series and parallel characteristics. As a result,
they have more efficient at lower speed and parallel tend to be
more efficient at higher speeds. Some of the examples of
power-split hybrids are Ford, Lexus, Nissan and Toyota.
5. Components of the HEV Battery System
The battery in an HEV is the energy storage device for the
electric motor. Unlike the gasoline in the fuel tank, which can
only power the gasoline engine, the electric motor in a hybrid
car can put energy into the battery as well as draw energy
from it.
Battery: Two or more electrochemical energy cells connected
together to provide electrical energy
Generator: The generator is similar to an electric motor, but
it acts only to produce electrical power
Electric motor: Advanced electronics allow it to act as a
motor as well as a generator. For example, when it needs to, it
can draw energy from the batteries to accelerate the car. But
acting as a generator, it can slow the car down and return
energy to the batteries
SOC: The State of Charge of a battery is its
available capacity expressed as a percentage of its
rated capacity
6. COMPARSION OF HYBRID ELECTRIC VEHICLES
TO CONVENTIONAL VEHICLES
EMISSIONS: Available HEV technology will decrease
emissions of conventional air pollutants substantially as
compared to standard vehicles today. HEV combines both
carbon dioxide and non-carbon dioxide reductions.
ENERGY: HEV’S decrease fuel consumption substantially
compared to conventional vehicles used today and also
compared to CNG and new generation of cleaner diesel
vehicles. Calculations have shown that over the average HEV
useful life time saves an amount of 6,000 litres of fuel.
LIFE CYCLE COST: While HEV’S are more expensive
initially the savings are recouped based on mileage and
driving conditions. Analysis has shown that HEV life cycle
cost, including cost of purchase, fuel and maintenance cost is
less than conventional vehicle.
STRATEGIC STEPPING STONE:
HEV’S and plug in hybrids and full electric vehicles and fuel
cell vehicles share basic technologies such as electric motors,
batteries and power electronic devices. Therefore HEV’S and
plug in hybrids function as stepping stone technologies for
large scale electrification through reduction of carbon dioxide
emissions from road transport and low carbon transport sector.
7. HYDROGEN AS FUEL:
Hydrogen can be used in cars in two ways: a source of
combustible heat, or a source of electrons for an electric
motor. The burning of hydrogen is not being developed in
practical terms; it is the hydrogen fuel-cell electric vehicle
(HFEV) which is garnering all the attention. Hydrogen fuel
cells create electricity fed into an electric motor to drives the
wheels. Hydrogen is not burned, but it is consumed. This
means molecular hydrogen, H2, is combined with oxygen to
form water. 2H2 (4e-
) + O2 --> 2H2O (4e-
). The molecular
hydrogen and oxygen's mutual affinity drives the fuel cell to
separate the electrons from the hydrogen, to use them to
power the electric motor, and to return them to the ionized
water molecules that were formed when the electron-depleted
hydrogen combined with the oxygen in the fuel cell. Recalling
that a hydrogen atom is nothing more than a proton and an
electron; in essence, the motor is driven by the proton's atomic
attraction to the oxygen nucleus, and the electron's attraction
to the ionized water molecule. Hybrids the ICE and
electric motor are both connected to mechanical transmission
and can simultaneously transmit power to drive the wheels
usually through a conventional transmission. These are also
capable of regenerative braking and internal combustion can
also act as generator for supple-mental recharging. Parallel
hybrids are more efficient than comparable to non-hybrid
vehicles especially during urban stop and go conditions and at
times during high way operation where electric motor is
permitted to contribute. Some of the examples of parallel
hybrids are Honda insight, civic, Accord