AMT 613 A/C Powerplant I (Reciprocating Engine) PDF

Summary

This document provides an overview of different types of powerplants and reciprocating engines, including internal combustion engines and their historical development. It covers aircraft engines, along with a brief history section.

Full Transcript

A/C POWERPLANT I (RECIPROCATING ENGINE)
POWERPLANT - are sources of power.

▪ HYDRO-ELECTRIC POWERPLANT
▪ THERMAL POWERPLANT
▪ NUCLEAR POWERPLANT
▪ WINDMILL.

ENGINE- are devices that convert one form of
energy to other.
An engine or motor is a machine designed
to convert energy into useful mechanical motion.

▪ Heat engines, including internal combustion
engines and external combustion engines (such as steam
engines) burn a fuel to create heat, which then creates
force.
▪ Electric motors converts electrical energy
into mechanical motion
▪ Pneumatic motors use compressed air.
WHAT IS THE PURPOSE OF AIRCRAFT
ENGINE?
 TO PROVIDE THRUST
-It is the force that propels an airplane forward
through the air.
BRIEF HISTORY IN AIRCRAFT POWERPLANT
In the 1st century, Hero of Alexandria demonstrates a steam-powered
spinning sphere called an Aeolipile.
▪ Pistons in cylinders first saw use in steam engines.
Scotland's James Watt crafted the first good ones during the
1770s.
▪ A century later, the German inventors Nicolaus Otto and
Gottlieb Daimler introduced gasoline as the fuel, burned
directly within the cylinders.
▪ Such motors powered the earliest automobiles. They were
lighter and more mobile than steam engines, more reliable,
and easier to start.
▪ Some single-piston gasoline engines entered service, but
for use with airplanes, most such engines had a number of
pistons, each shuttling back and forth within its own
cylinder.
▪ Each piston also had a connecting rod, which pushed on a
crank that was part of a crankshaft.
▪ This crankshaft drove the propeller.
▪ In 1862, Nicolaus Otto was
the first to build and sell the
engine.
▪ He designed an indirect-
acting free-piston
compression less engine
whose greater efficiency won
the support of Eugen
Langen and then most of the
market, which at that time
was mostly for small
stationary engines fueled by
lighting gas.
 A 1920s era American
Otto Engine
for Stationary Use

The Otto/Langen
Atmospheric 1885 Daimler's
Engine of 1867 Petroleum Reitwagen
First Use in
Transportation
▪ The Otto & Langen engine was a free piston atmospheric
engine (the explosion of gas was used to create a vacuum
and the power came from atmospheric pressure returning
the piston).
▪ It is the engine (the Otto Silent Engine), and not the Otto &
Langen engine, to which the Otto cycle refers. This was the
first commercially successful engine to use in-cylinder
compression (as patented by William Barnett in 1838).
▪ George Brayton, developed a
two-stroke kerosene engine
▪ (it used two external pumping
cylinders). However, it was
considered the first safe and
practical oil engine.
▪ Otto and his manager Gottlieb Daimler had a major
disagreement on the future direction of the Otto
engine.
▪ While Otto wanted to produce large engines for
stationary applications Daimler wanted to
produce engines small enough to be used in
transportation.
▪ Gustav Otto, the son of inventor
and industrialist Nicolaus August
Otto, was a pioneer aviator
in Bavaria.
▪ His company was one of the
foundation of the Bayerische
Flugzeugwerke (BFW) which will
later be known as Bayerische
Motoren Werke (BMW).
▪ The blue and white panels of the
Bavarian national flag were placed
at the center of the BMW logo. Not
until the late 1920s was the logo
lent a new interpretation as
representing a rotating propeller.
1885
▪ Karl Benz builds a three-wheel automobile
powered by a gasoline engine.
1887
▪ Henry Ford builds his first automobile in Michigan.
1887
▪ Gottlieb Daimler uses his internal combustion
engine to build a four-wheel vehicle, considered
the first modern automobile.
▪ In 1892, Dr. Rudolf Diesel
developed his Carnot heat
engine type motor
▪ 1893 February 23rd , Rudolf
Diesel received a patent for his
compression ignition (diesel)
engine.
▪ 1900, Rudolf Diesel
demonstrated the diesel
engine in the 1900 Exposition
Universelle (Worlds Fair) using
peanut oil fuel.
▪ The diesel engine has
the benefit of running
more fuel-efficiently
than gasoline engines
due to much higher
compression ratios and
longer duration of
combustion, which
means the temperature
rises more slowly,
allowing more heat to
be converted to
mechanical work.
▪ In 1903, the Wright
Brothers flew, The Flyer, with
a 12 horse power gas
powered engine.
▪ From 1903, the year of the
Wright Brothers first flight, to
the late 1930s the gas
powered reciprocating
internal-combustion engine
with a propeller was the sole
means used to propel aircraft.
Combustion engines are heat engines driven by the heat of
a combustion process.

"Combustion" refers to burning fuel with an oxidizer, to
supply the heat.
▪ The Internal Combustion Engine is an engine in which
the combustion of a fuel (generally, fossil fuel) occurs with
an oxidizer (usually air) in a combustion chamber.
▪ In an internal combustion engine, the expansion of the
high temperature and high pressure gases (which are
produced by the combustion) directly applies force to
components of the engine (such as the pistons or turbine
blades or a nozzle) and by moving it over a distance,
generates useful mechanical energy.
▪ Aircraft require thrust to produce enough speed for the
wings to provide lift or enough thrust to overcome the
weight of the aircraft for vertical takeoff.
▪ All aircraft engines must meet certain general
requirements of efficiency, economy, and reliability.
▪ Aircraft engines can be classified by several methods.
▪ They can be classed by operating cycles, cylinder
arrangement, or the method of thrust production. All are
heat engines that convert fuel into heat energy that is
converted to mechanical energy to produce thrust.
▪ Most of the current aircraft engines are of the internal
combustion type because the combustion process takes
place inside the engine.
▪ Aircraft engines come in many different types, such as gas
turbine based, reciprocating piston, rotary, two or four
cycle, spark ignition, diesel, and air or water cooled.
▪ An inline engine generally has an even number of cylinders,
although some three-cylinder engines have been constructed.
▪ This engine may be either liquid cooled or air cooled and has only
one crank shaft, which is located either above or below the
cylinders.
▪ If the engine is designed to operate with the cylinders below the
crankshaft, it is called an inverted engine.
Walter LOM 210-hp
engine installation in the
STOL CH 801 (4/00)
▪ The opposed-type engine has two banks of cylinders directly
opposite each other with a crankshaft in the center.
▪ The pistons of both cylinder banks are connected to the single
crankshaft.
▪ Although the engine can be either liquid cooled or air cooled, the
air-cooled version is used predominantly in aviation.
▪ It is generally mounted with the cylinders in a horizontal position.
Continental Engines. Continental O-200-D O-320-H2AD, C172,
▪ In V-type engines, the cylinders are arranged in two in-line
banks generally set 60° apart.
▪ Most of the engines have 12 cylinders, which are either
liquid cooled or air cooled.
▪ This type of engine was used mostly during the second
World War and its use is mostly limited to older aircraft.
The Liberty L-12 V-12
▪ The radial engine consists of a row, or rows, of cylinders
arranged radially about a central crankcase.
▪ This type of engine has proven to be very rugged and
dependable.
▪ The number of cylinders which make up a row may be
three, five, seven, or nine.
▪ Radial engines are still used in some older cargo planes,
war birds, and crop spray planes. Although many of these
engines still exist, their use is limited.
Radial Engine on a PT17 Stearman bi-plane
 RECIPROCATING ENGINES
❑The basic major components of a reciprocating engine are
the crankcase, cylinders, pistons, connecting rods, valves,
valve-operating mechanism, and crankshaft.
❑In the head of each cylinder are the valves and spark
plugs.
❑One of the valves is in a passage leading from the
induction system; the other is in a passage leading to the
exhaust system.
❑Inside each cylinder is a movable piston connected to a
crankshaft by a connecting rod.
❑The foundation of an
engine is the crankcase.
❑It contains the bearings
and bearing supports in
which the crankshaft
revolves.
❑It also provides support
for attachment of the
cylinder assemblies, and
the powerplant to the
aircraft
▪ It is cast in one piece and
provided with means for
mounting the accessories, such
as magnetos, carburetors, fuel,
oil, vacuum pumps, starter,
generator, tachometer drive,
etc., in the various locations
required to facilitate
accessibility.
❑The crankshaft is the backbone
of the reciprocating engine.
❑The crankshaft is carried in a
position parallel to the
longitudinal axis of the
crankcase and is generally
supported by a main bearing
between each throw.
❑Its main purpose is to transform
the reciprocating motion of the
piston and connecting rod into
rotary motion for rotation of the
propeller.
▪ Crankshaft has three main
parts journal, crankpin, and
crank cheek.
▪ Counterweights and dampers,
although not a true part of a
crankshaft, are usually
attached to it to reduce
engine vibration.
▪ The journal is supported by,
and rotates in, a main bearing.
▪ It serves as the center of
rotation of the crankshaft. It is
surface hardened to reduce
wear. The crankpin is the
section to which the
connecting rod is attached.
▪ It is off-center from the main
journals and is often called the
throw. Two crank cheeks and a
crankpin make a throw
▪ Excessive vibration in an engine not only results in fatigue failure of
the metal structures, but also causes the moving parts to wear rapidly.
▪ In some instances, excessive vibration is caused by a crankshaft that
is not balanced.
▪ A crankshaft is statically balanced when the weight of the
entire assembly of crankpins, crank cheeks, and
counterweights is balanced around the axis of rotation.
▪ When checked for static balance, it is placed on two knife
edges. If the shaft tends to turn toward any one position
during the test, it is out of static balance.
❑The connecting rod is the link that
transmits forces between the piston
and the crankshaft.
❑Connecting rods must be strong
enough to remain rigid under load
and yet be light enough to reduce the
inertia forces that are produced when
the rod and piston stop, change
direction, and start again at the end
of each stroke.
❑The piston of a reciprocating engine is
a cylindrical member which moves
back and forth within a steel cylinder.
❑The piston acts as a moving wall within
the combustion chamber.
❑As the piston moves down in the
cylinder, it draws in the fuel/air
mixture. As it moves upward, it
compresses the charge, ignition occurs,
and the expanding gases force the
piston downward.
❑This force is transmitted to the
crankshaft through the connecting rod.
❑The piston pin joins the piston to the connecting rod.
❑The piston pin used in modern aircraft engines is the full-
floating type, so called because the pin is free to rotate in
both the piston and in the connecting rod piston-pin
bearing.
❑The piston pin must be held in place to prevent the pin
ends from scoring the cylinder walls
❑The piston rings prevent leakage of gas pressure from the
combustion chamber and reduce to a minimum the
seepage of oil into the combustion chamber.
❑The rings fit into the piston grooves but spring out to press
against the cylinder walls; when properly lubricated, the
rings form an effective gas seal.
❑The purpose of the compression rings is to prevent the
escape of combustion gases past the piston during engine
operation.
❑They are placed in the ring grooves immediately below
the piston head.
❑Oil control rings are placed in the grooves immediately below the
compression rings and above the piston pin bores.
❑There may be one or more oil control rings per piston; two rings may
be installed in the same groove, or they may be installed in separate
grooves.
❑If too much oil enters the combustion chamber, it burns and leaves a
thick coating of carbon on the combustion chamber walls, the piston
head, the spark plugs, and the valve heads.
❑The portion of the engine in which the power is developed
is called the cylinder.
❑The cylinder provides a combustion chamber where the
burning and expansion of gases take place, and it houses
the piston and the connecting rod.
▪ This carbon can cause the valves and piston rings to stick if
it enters the ring grooves or valve guides. In addition, the
carbon can cause spark plug misfiring as well as
detonation, preignition, or excessive oil consumption.
▪ There are four major factors that need
to be considered in the design and
construction of the cylinder assembly. It
must:
1. Be strong enough to withstand the
internal pressures developed during
engine operation.
2. Be constructed of a lightweight metal
to keep down engine weight.
3. Have good heat-conducting properties
for efficient cooling.
4. Be comparatively easy and
inexpensive to manufacture, inspect, and
maintain.
 ❑The cylinder used in
the air cooled engine
is the overhead valve
type.
❑Each cylinder is an
assembly of two
major parts: cylinder
head and cylinder
barrel

Cutaway view of the cylinder assembly.
❑The purpose of the cylinder head is to provide a place for
combustion of the fuel/air mixture and to give the cylinder
more heat conductivity for adequate cooling.
❑The fuel/air mixture is ignited by the spark in the
combustion chamber and commences burning as the
piston travels toward top dead center (top of its travel) on
the compression stroke.
▪ The cylinder barrel in which the piston operates must be
made of a high-strength material, usually steel.
▪ It must be as light as possible, yet have the proper
characteristics for operating under high temperatures.
❑The firing order of an engine is the sequence in which the
power event occurs in the different cylinders.
❑The firing order is designed to provide for balance and to
eliminate vibration to the greatest extent possible.
❑For a reciprocating engine to operate properly, each valve
must open at the proper time, stay open for the required
length of time, and close at the proper time.
❑Intake valves are opened just before the piston reaches top
dead center, and exhaust valves remain open after top
dead center.
❑At a particular instant, therefore, both valves are open at
the same time (end of the exhaust stroke and beginning of
the intake stroke).
❑This valve overlap permits better volumetric efficiency
and lowers the cylinder operating temperature.
❑This timing of the valves is controlled by the valve-
operating mechanism and is referred to as the valve timing.
Valve-operating mechanism (opposed engine).
❑The fuel/air mixture enters the
cylinders through the intake
valve ports, and burned gases
are expelled through the exhaust
valve ports.
❑The head of each valve opens
and closes these cylinder ports.
❑The valves are also typed by
their shape and are called either
mushroom or tulip because of
their resemblance to the shape
of these plants
Neck
❑The valve mechanism of an
opposed engine is operated by a
camshaft.
❑The camshaft is driven by a gear
that mates with another gear
attached to the crankshaft.
❑The camshaft always rotates at one-
half the crankshaft speed.
❑As the camshaft revolves, the lobes
cause the tappet assembly to rise in
the tappet guide, transmitting the
force through the push rod and
rocker arm to open the valve.
▪ The function of the tappet
assembly is to convert the
rotational movement of
the cam lobe into
reciprocating motion and
to transmit this motion to
the push rod, rocker arm,
and then to the valve tip,
opening the valve at the
proper time.
The tappet assembly consists of:

1. A cylindrical tappet, which slides in and out in a tappet guide
installed in one of the crankcase sections around the cam ring
2. A tappet roller, which follows the contour of the cam ring and lobes
3. A tappet ball socket or push rod socket
4. A tappet spring.
❑Solid lifters or cam followers
generally require the valve
clearance to be adjusted
manually by adjusting a
screw and lock nut.
❑Valve clearance is needed
to assure that the valve has
enough clearance in the
valve train to close
completely.
❑This adjustment or
inspection was a continuous
maintenance item until
hydraulic lifters were used.
▪ Some aircraft engines incorporate
hydraulic tappets that automatically keep
the valve clearance at zero, eliminating the
necessity for any valve clearance
adjustment mechanism.
▪ When the engine valve is closed, the face
of the tappet body (cam follower) is on the
base circle or back of the cam.
▪ The light plunger spring lifts the hydraulic
plunger so that its outer end contacts the
push rod socket, exerting a light pressure
against it, thus eliminating any clearance in
the valve linkage.
▪ As the plunger moves outward, the ball check valve moves
off its seat. Oil from the supply chamber, which is directly
connected with the engine lubrication system, flows in and
fills the pressure chamber. As the camshaft rotates, the cam
pushes the tappet body and the hydraulic lifter cylinder
outward.
❑The push rod, tubular in
form, transmits the lifting
force from the valve
tappet to the rocker arm.
A hardened-steel ball is
pressed over or into each
end of the tube.
❑One ball end fits into the
socket of the rocker arm.
❑ In some instances, the
balls are on the tappet
and rocker arm, and the
sockets are on the push
rod.
❑It permits the engine lubricating oil under pressure to pass
through the hollow rod and the drilled ball ends to
lubricate the ball ends, rocker-arm bearing, and valve-
stem guide.
❑The push rod is enclosed in a tubular housing that extends
from the crankcase to the cylinder head, referred to as
push rod tubes.
❑The rocker arms transmit the lifting force from the cams to
the valves.
❑Rocker arm assemblies are supported by a plain, roller, or
ball bearing, or a combination of these, which serves as a
pivot. Generally, one end of the arm bears against the push
rod and the other bears on the valve stem.
❑The arm may have an adjusting screw, for adjusting the
clearance between the rocker arm and the valve stem tip.
❑Each valve is closed by two or three helical
springs. If a single spring were used, it would
vibrate or surge at certain speeds.
❑To eliminate this difficulty, two or more
springs (one inside the other) are installed on
each valve.
❑Each spring vibrates at a different engine
speed and rapid damping out of all spring-
surge vibrations during engine operation
results.
❑Two or more springs also reduce danger of
weakness and possible failure by breakage
due to heat and metal fatigue.
❑A bearing is any surface which supports, or is supported
by, another surface.
❑A good bearing must be composed of material that is
strong enough to withstand the pressure imposed on it and
should permit the other surface to move with a minimum of
friction and wear.
❑Bearings are required to take radial loads, thrust loads, or
a combination of the two.
❑The vast majority of certified aircraft reciprocating engines
operate on the four-stroke cycle, sometimes called the Otto
cycle after its originator, a German physicist
❑In this type of engine, four strokes are required to
complete the required series of events or operating cycle
of each cylinder.
❑During the intake stroke, the piston is pulled downward in
the cylinder by the rotation of the crankshaft.
❑This reduces the pressure in the cylinder and causes air
under atmospheric pressure to flow through the carburetor,
which meters the correct amount of fuel.
❑The fuel/air mixture passes through the intake pipes and
intake valves into the cylinders.
❑The quantity or weight of the fuel/air charge depends
upon the degree of throttle opening.
❑After the intake valve is closed, the continued upward
travel of the piston compresses the fuel/air mixture to
obtain the desired burning and expansion characteristics.
❑The charge is fired by means of an electric spark as the
piston approaches TDC.
❑The time of ignition varies from 20° to 35° before TDC,
depending upon the requirements of the specific engine to
ensure complete combustion of the charge by the time the
piston is slightly past the TDC position.
❑As the piston moves through the TDC position at the end of
the compression stroke and starts down on the power
stroke
❑As the piston is forced downward during the power stroke
by the pressure of the burning gases exerted upon it, the
downward movement of the connecting rod is changed to
rotary movement by the crankshaft.
❑Then, the rotary movement is transmitted to the propeller
shaft to drive the propeller.
▪ As the piston travels through BDC at the completion
of the power stroke and starts upward on the
exhaust stroke, it begins to push the burned exhaust
gases out the exhaust port.