Thermodynamic cycles can be divided into two general
categories: power cycles, which produce a net power output, and refrigeration
and heat
pump cycles, which consume a net power input. The thermodynamic power
cycles can be categorized as gas cycles and vapor cycles. In gas cycles,
the working
fluid remains in the gas phase throughout the entire cycle. In vapor
cycles, the working fluid exits as vapor phase during one part of the
cycle and as liquid phase during another part of the cycle. Internal
combustion engines and gas turbines undergo gas power cycle.
Internal combustion engines, which are commonly used in automobiles,
have two principal types: spark-ignition (SI) engines and compression-ignition
(CI) engines. This section will introduce the spark-ignition (SI) engines
and
the ideal
cycle for spark-ignition engines - Otto Cycle.
Internal Combustion Engine Terminology
Internal combustion engines are reciprocating engines, which basically
are piston-cylinder devices. The sketch of a reciprocating engine
is shown on the left. The sketch is labeled with some special terms.
The
piston is said to be at the top dead center (TDC) when it has moved
to a position where the cylinder volume
is minimum. This volume is called a clearance volume.
The
piston is said to be at the bottom dead center (BDC) when it
has moved to a position where the cylinder volume
is maximum.
The volume swept out by the piston when it moves from TDC
to BDC is called the displacement volume.
The distance from TDC
to BDC is called stroke.
The bore of the cylinder is its diameter.
Two other terms frequently used in conjunction with reciprocating
engines are compression ratio (r) and mean effective pressure (MEP).
The compression
ratio is defined as the ratio of the maximum volume formed in the cylinder
to the minimum volume (clearance volume).
r = Vmax/Vmin
The mean effective pressure is
a fictitious pressure. It is defined as the pressure that would act
on the piston during the entire power stroke, to produce the
same
amount
of net work
as that would be produced during the actual cycle.
Wnet = MEP Displacement
volume
or
MEP = Wnet /(VBDC -
VTDC)
Four-stroke Combustion Cycle
In a spark-ignition (SI) engine, a mixture of fuel and air is ignited
by a spark plug. Spark-ignition engines are suited for use in automobiles
since they are relatively light and lower in cost. Most cars currently
use what is called a four-stroke combustion cycle to convert gasoline
into motion. The four strokes are:
Intake stroke
Compression stroke
Combustion stroke (power stroke)
Exhaust stroke
The piston is connected to the crank shaft by a connecting rod. When
the engine goes through its cycle:
The piston starts at the top, the intake valve opens, and the piston moves
down to let the engine take in a cylinder-full of air and gasoline. This
is the intake stroke.
The piston moves back up to compress this fuel/air mixture. Compression
makes the explosion more powerful. This is the compression stroke.
When the piston reaches the top of its stroke (TDC), the spark plug
emits a spark to ignite the gasoline. The gasoline in the cylinder
explodes, driving the piston down. This is the combustion stroke.
Once the piston hits the bottom of its stroke (BDC), the exhaust
valve opens and the exhaust leaves the cylinder to go out through the
tail pipe.This
is the exhaust stroke.
Then the engine is ready for the next cycle, so it intakes another charge of
air and gas.
Air-standard Assumption
Internal combustion engine operates on an open cycle since its working
fluid is thrown out of the engine at some point instead of being returned
to its initial state. That means the working
fluid does not undergo a complete thermodynamic cycle. A detailed study
of the performance of an actual gas power cycle is rather complex and
accurate modeling of internal combustion engines normally involves computer
simulation.
To conduct elementary thermodynamic analyses of internal combustion engines,
considerable simplification is required. To simplify the analysis, air-standard
assumptions are made:
Gas and air mixture are modeled as air and an ideal gas,
which continuously circulates in a closed cycle. Thus, there
are no intake and
exhaust processes.
All the processes making up the cycle are internally reversible.
The combustion process is replaced by a heat-addition process from
an external source.
The exhaust process is replaced by a heat-rejection process and the
gas returns to its initial state.
In addition, if specific heats are assumed constants at their
ambient temperature, this assumption is called a cold air-standard assumption.
Ideal Otto Cycle - Ideal Cycle for Spark-ignition Engines
The Otto cycle is the ideal cycle for spark-ignition engines, in honor
of Nikolaus Otto, who invented
it
in
1867. In ideal Otto cycles, air-standard assumption is used. The ideal
Otto cycle consists of four internal reversible processes:
1-2 Isentropic compression
2-3 Constant volume heat addition
3-4 Isentropic expansion
4-1 Constant volume heat rejection
The Otto cycle is executed in a closed system and the working fluid
is air according to the air-standard assumption. Also, changes in kinetic
and potential energies are negligible. No heat transfer is involved in
the two isentropic processes. The energy balances for these two processes
are:
-w12 = u2 - u1
-w34 = u4 - u3
w12 is negative since work is needed to compress the air
in the cylinder and w34 is positive since air does work to
the surroundings during its expansion.
In the constant volume heat addition and heat rejection process, no
work interaction is involved since no volume change occurs. The energy
balances for these two processes are:
q23 = u3 - u2
q41 = u1 - u4
q23 is positive since heat is added to the air and q41 is
negative since heat is rejected to the surroundings.
The thermal efficiency for an ideal Otto cycle is ηth,
Otto = wnet/qin
According to the analysis above, the net work output is
wnet =
w34 + w12 = q23 + q41
qin = q23 ηth,
Otto = 1+ q41/q23
Under the cold air-standard assumption, the thermal efficiency
of the ideal Otto cycle is
Process 1-2 and process 3-4 are isentropic. Thus,
Since v2 = v3 and v4 = v1,
Considering all the relations above, the thermal efficiency becomes,
where r is the compression ratio and k is the specific heat ratio.
The expression of thermal efficiency under cold air-standard assumption
is only a function of the compression ratio. Thus, a higher r can generate
a higher thermal efficiency. But when higher r is used, the temperature
of the air-fuel mixture may rise above the auto ignition temperature
of the
fuel during the compression process, and will cause an early and rapid
burn before the spark ignition. This early and rapid burn produces an
audible noise, which is called engine knock. Engine knock in spark-ignition
engine cannot be tolerated since it hurts performance and can cause engine
damage. Thus there is an upper limit of compression ratio
for spark-ignition engines.