Unit 1 Internal combustion engine a part of applied thermodynamics

Introduction to Internal Combustion Engines

• =
HEAT ENGINE
Any engine that converts thermal energy
to mechanical work output.
Ex: steam engine, steam power plant, jet engine, gas
turbine power plant, diesel engine, and gasoline
(petrol) engine etc.

HEAT ENGINE
Internal Combustion
(IC) Engine
External Combustion
Engine
On the basis of how thermal energy is being delivered to working
fluid of the heat engine, Heat engine can be classified as

Internal combustion engine:
Combustion takes place within the working fluid of the engine,
• Thus fluid gets contaminated in combustion.
• Petrol engine is an example of internal combustion engine, where the
working fluid is a mixture of air and fuel .
External combustion engine
Working fluid gets energy from outside through some heat exchanger
(Boiler)
• Thus the working fluid does not come in contact with combustion
products.
• Steam engine is an example of external combustion engine, where the
working fluid is steam.

INTERNAL
COMBUSTION
ENGINES
Spark Ignition engines
(ex. Gasoline/Petrol
Engine)
Compression Ignition
engines
(ex. Diesel Engine)

Spark ignition engine (SI engine)
An engine in which the combustion process in each cycle is started
by use of an external spark.
Compression ignition engine (CI engine)
An engine in which the combustion process starts when the air-fuel
mixture self ignites due to high temperature in the combustion
chamber caused by high compression.
[Spark ignition and Compression Ignition engine operate on either a
four stroke cycle or a two stroke cycle]

Figure 1 : IC Engine components

Figure 2 : Schematic View of Engine

I C Engine Components
• Block : Body of the engine containing cylinders, made of cast iron
or aluminium.
• Cylinder : The circular cylinders in the engine block in which
the pistons reciprocate back and forth.
• Head : The piece which closes the end of the cylinders, usually
containing part of the clearance volume of the combustion chamber.
• Combustion chamber: The end of the cylinder between the head and
the piston face where combustion occurs.

• Crankshaft : Rotating shaft through which engine work output
is supplied to external systems.
– The crankshaft is connected to the engine block with the main
bearings.
– It is rotated by the reciprocating pistons through the
connecting rods connected to the crankshaft, offset from the
axis of rotation. This offset is sometimes called crank throw or
crank radius.
• Connecting rod : Rod connecting the piston with the rotating
crankshaft, usually made of steel or alloy forging in most engines but
may be aluminum in some small engines.
• Piston rings: Metal rings that fit into circumferential grooves
around the piston and form a sliding surface against the cylinder
walls.

• Camshaft : Rotating shaft used to push open valves at the proper
time in the engine cycle, either directly or through mechanical or
hydraulic linkage (push rods, rocker arms, tappets) .
• Crankcase : Part of the engine block surrounding the crankshaft.
– In many engines the oil pan makes up part of the crankcase
housing.
• Exhaust manifold : Piping system which carries exhaust
gases away from the engine cylinders, usually made of cast
iron .

• Intake manifold :Piping system which delivers incoming air to
the cylinders, usually made of cast metal, plastic, or
composite material.
– In most SI engines, fuel is added to the air in the intake manifold
system either by fuel injectors or with a carburetor.
– The individual pipe to a single cylinder is called runner.
• Spark plug : Electrical device used to initiate combustion in an
SI engine by creating high voltage discharge across an
electrode gap.

• Flywheel : Rotating mass with a large moment of inertia
connected to the crank shaft of the engine.
– The purpose of the flywheel is to store energy and furnish
large angular momentum that keeps the engine rotating
between power strokes and smooths out engine operation.
• Fuel injector : A pressurized nozzle that sprays fuel into
the incoming air (SI engines )or into the cylinder (CI engines).
• Fuel pump : Electrically or mechanically driven pump to
supply fuel from the fuel tank (reservoir) to the engine.

Unit 1 Internal combustion engine a part of applied thermodynamics

IC
Engines
SI
Ignition System
CI
Working Cycle
Otto Cycle
Diesel Cycle
Brayton Cycle
Cylinder
Arrangement
Four Stroke
No. of Strokes
Two Stroke
Stationary
Application
Mobile
Air Cooled
Cooling System
Liquid Cooled
Single Cyl
No. of Cylinders
Multi Cyl
Vertical / Straight
I
n
l
i
n
e
Horizontal / Flat
V, W, H, U, X
etc.
Radial
Vertical / Straight
Opposed
Horizontal / Flat

• Four stroke cycle : It has four piston strokes
over two revolutions for each cycle.
• Two stroke cycle : It has two piston strokes
over one revolution for each cycle.

• Figure, shows the pressure volume diagram of ideal engine cycle along with
engine terminology as follows:
• Top Dead Center (TDC):
• Position of the piston when it stops at the furthest point away from the
crankshaft. Top because this position is at the top of the engines (not always),
and dead because the piston stops as this point. Because in some engines TDC
is not at the top of the engines (e.g: horizontally opposed engines, radial
engines,etc).
• Some sources call this position Head End Dead Center (HEDC).
• Some source call this point TOP Center (TC).
• When the piston is at TDC, the volume in the cylinder is a minimum called
the clearance volume.
Engine Terminology :

Bottom Dead Center (BDC)
• Position of the piston when it stops at the point closest to the crankshaft.
• Some sources call this Crank End Dead Center (CEDC) because it is not
always at the bottom of the engine.Some source call this point Bottom
Center (BC).
• Stroke : Distance traveled by the piston from one extreme position to the
other : TDC to BDC or BDC to TDC.
• Bore :It is defined as cylinder diameter or piston face diameter; piston face
diameter is same as cylinder diameter( minus small clearance).
• Swept volume/Displacement volume : Volume displaced by the piston as it
travels through one stroke.
• Swept volume is defined as stroke times bore.
• Displacement can be given for one cylinder or entire engine (one cylinder
times number of cylinders).

• Clearance volume : It is the minimum volume of the cylinder available for
the charge (air or air fuel mixture) when the piston reaches at its outermost
point (top dead center or outer dead center) during compression stroke of the
cycle.
–
Minimum volume of combustion chamber with piston at TDC.
• Compression ratio : The ratio of total volume to clearance volume of the
cylinder is the compression ratio of the engine.
Typically compression ratio for SI engines varies form 8 to 12 and for CI
engines it varies from 12 to 24

SI Engine Ideal Otto Cycle
We will be dealing with four stroke SI engine, the following figure
shows the PV diagram of Ideal Otto cycle.

Four strokes of SI Engine Cycle :

Suction/Intake stroke:

Intake of air fuel mixture in cylinder through intake manifold.

The piston travel from TDC to BDC with the intake valve open and exhaust
valve closed.

This creates an increasing volume in the combustion chamber, which in turns
creates a vacuum.

The resulting pressure differential through the intake system from
atmospheric pressure on the outside to the vacuum on the inside causes air to
be pushed into the cylinder.

As the air passes through the intake system fuel is added to it in the desired
amount by means of fuel injectors or a carburettor.

• Compression stroke:
• When the piston reaches BDC, the intake valve closes and the
piston travels back to TDC with all valves closed.
• This compresses air fuel mixture, raising both the pressure and
temperature in the cylinder.
• Near the end of the compression stroke the spark plug is fired
and the combustion is initiated.

• Combustion of the air-fuel mixture occurs in a very short but finite
length of time with the piston near TDC (i.e., nearly constant volume
combustion).
• It starts near the end of the compression stroke slightly before TDC
and lasts into the power stroke slightly after TDC.
• Combustion changes the composition of the gas mixture to that of
exhaust products and increases the temperature in the cylinder to a
high value.
• This in turn increases the pressure in the cylinder to a high value.

Figure 6 : Combustion followSa
enk
dar,D
bM
yE,R
ESE
xT
pansion
stroke.

• Expansion stroke/Power stroke:
• With all valves closed the high pressure created by the combustion
process pushes the piston away from the TDC.
• This is the stroke which produces work output of the engine cycle.
• As the piston travels from TDC to BDC, cylinder volume is increased,
causing pressure and temperature to drop.

Exhaust Blowdown:
Late in the power stroke, the exhaust valve is opened and exhaust blowdown
occurs.
Pressure and temperature in the cylinder are still high relative to the
surroundings at this point, and a pressure differential is created through the
exhaust system which is open to atmospheric pressure.
• This pressure differential causes much of the hot exhaust gas to be pushed
out of the cylinder and through the exhaust system when the piston is near
BDC.
• This exhaust gas carries away a high amount of enthalpy, which lowers the
cycle thermal efficiency.
• Opening the exhaust valve before BDC reduces the work obtained but is
required because of the finite time needed for exhaust blowdown.

Figure7: Exhaust blowdown followed by Exhaust stroke
Sankar,DME,RSE

• Exhaust stroke:
• By the time piston reaches BDC, exhaust blowdown is complete, but the
cylinder is still full of exhaust gases at approximately atmospheric pressure.
• With the exhaust valve remaining open, the piston travels from BDC to
TDC in the exhaust stroke.
• This pushes most of the remaining exhaust gases out of the cylinder into the
exhaust system at about atmospheric pressure, leaving only that trapped in
the clearance volume when the piston reaches TDC.

Near the end of the exhaust stroke before TDC, the intake valve starts to open, so
that it is fully open by TDC when the new intake stroke starts the next cycle.
Near TDC the exhaust valve starts to close and finally is fully closed
sometime after TDC.
This period when both the intake valve and exhaust valve are open is called
valve overlap, it can be clearly seen in valve timing chart given below.

Compression Ignition Engine :
• We will deal with Compression Ignition engine.
• The ideal diesel cycle PV diagram is shown in following
figure 8.

Figure 8: Ideal diesel cycle P-V Diagram.

Figure 9 : Four strokes of ideal Diesel cycle.

Four strokes of CI Engine Cycle :
• Intake/Suction Stroke : The same as the intake stroke in an SI engine with
one major difference : no fuel is added to the incoming air, refer figure 10.
• Compression Stroke : The same as in an SI engine except that only air
is compressed and compression is to higher pressures and temperature,
refer figure11.
• Late in the compression stroke fuel is injected directly into the
combustion chamber, where it mixes with very hot air.
• This causes the fuel to evaporate and self ignite, causing combustion to
start.
» Combustion is fully developed by TDC and continues at about constant
pressure until fuel injection is complete and the piston has started towards
BDC, refer figure12.

Figure12: Fuel injection and combustion followed by Expansion stroke
Asst. Prof. Vishnu Sankar,DME,RSE

Figure13: Exhaust stroke followed by exhaust blowdown.
nu Sankar,DME,RSET

• Expansion/Power stroke : The power stroke continues as
combustion ends and the piston travels towards BDC, refer figure
12.
• Exhaust blowdown same as with an SI engine.
• Exhaust stroke : Same as with an SI engine, refer figure 13.

Previous year questions
1. A petrol engine having a compression ratio of 6 uses a fuel with calorific
valve of 42 MJ/kg. The air fuel ratio is 15: 1. Pressure and temperature at
the start of the suction stroke is 1 bar and 57°C respectively. Determine the
maximum pressure in the cylinder if the index of compression is 1.3 and
specific heat at constant volume is given by C (0.678 +0.00013 T) kJ/kgK.
Compare this value with that obtained when C=0-717 kJ/KgK.
2. What will be the effect on the efficiency of an otto cycle having a
compression ratio of 7, if the specific heat at constant volume
increases by 1%.

3. A trial carried out in a four stroke single cylinder gas engine gave the
following results. Cylinder dia=300 mm, Engine stroke=500mm, Clearance
volume=6750cc, Explosions per minute=100 Pmax KN/m2 = 765 Net work
load on the brake=190kg Brake dia=1.5m Rope dia=2 5mm, Speed of the
engine=240rpm, Gas used=30 m3/kghr , Calorific value of gas=2 0515 KJ/
m3 . Determine compression rat io, mechanical efficiency, indicated thermal
efficiency, air standard efficiency, relative efficiency, assume r=1.4.
4. The following observat ions are recorded during a test on a four-stroke petrol
engine, F.C = 3000 of fuel in 12sec, speed of the engine is 2500rpm, B.P =
20KW, Air intake orifice diameter = 35 mm,Pressure across the orifice = 140mm
of water coefficient of discharge of orifice = 0.6 , piston diameter = 150mm,
stroke length = 100 mm, Density of the fuel = 0.85gm/cc , r=6 .5, Cv of fuel =
42000KJ/Kg, Barometric pressure = 760mm of Hg , Room temperature = 24oC.

5. 42.5 kW engine has a mechanical efficiency of 85%. If the frictional
power is assumed to be constant with load, what is the mechanical
efficiency at 60% of the load?
6. A six cylinder, four stroke IC engine develops 100 KW of brake power at
800 rpm. The stroke to bore ratio is 1.5. The indicated mean effective
pressure is 8 bar and mechanical efficiency is 80 %. Determine the cylinder
diameter and piston stroke of the engine.

Unit 1 Internal combustion engine a part of applied thermodynamics

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