The document discusses the development and components of various types of jet engines, including turbojet engines. It describes the key parts of jet engines like the fan, inlet, compressor, combustor, turbine, and nozzle. The compressor increases the air pressure and temperature. The combustor mixes the compressed air with fuel and ignites it. The hot gases then power the turbine before exiting through the nozzle, producing thrust. Early turbojet engines had limitations like low efficiency and slow response times. Allowable turbine temperatures have increased over time with improved materials and blade cooling designs.
study of jet engines & how they works
1.History of jet engine 2. Introduction 3. Parts of jet engine 4. How a get engine works 5. Types of jet engine (i) Ramjet (ii) Turbojet (iii) Turbofan (iv) Turboprop (v) Turbo shaft 6.Comparison of Turbo Jet 7.Jet engines Vs Rockets 8.Difficulties 9.Suggestion for improvement 10. Merit and Demerits 11. Jet engine uses 12.Conclusion 13.Future vision
This project gives an understanding on how an Aircraft is protected from Icy conditions during flight and while on ground. Hence also the systems and devices and fluid used.
study of jet engines & how they works
1.History of jet engine 2. Introduction 3. Parts of jet engine 4. How a get engine works 5. Types of jet engine (i) Ramjet (ii) Turbojet (iii) Turbofan (iv) Turboprop (v) Turbo shaft 6.Comparison of Turbo Jet 7.Jet engines Vs Rockets 8.Difficulties 9.Suggestion for improvement 10. Merit and Demerits 11. Jet engine uses 12.Conclusion 13.Future vision
This project gives an understanding on how an Aircraft is protected from Icy conditions during flight and while on ground. Hence also the systems and devices and fluid used.
This Presentation gives a brief idea on turbojet engines, their components, working principle and also regarding the type of materials used in the engine parts, applications etc
This compressor works on the principle of centrifugal action. It finds wide variety of applications in engineering field. It is available in market from low to high capacities.
Aerodynamic characterisitics of a missile componentseSAT Journals
Abstract
A Missile is a self-propelled guided weapon system that travels through air or space. A powered, guided munitions that travels through the air or space is known as a missile (or guided missile). The Missile is defined as a space transversing unmanned vehicle that contains the means for controlling its flight path. The aerodynamic characteristics of a missile components such as body, wing and tail are calculated by using analytical methods to predict the drag and the normal forces of the missile. The total drag of the body is computed by using the parasite drag, wave drag, skin friction drag and base drag. The wing surface normal force coefficient (CN)Wing is a function of Mach number, local angle of attack, aspect ratio, and the wing surface plan form area (CN)Wing , based on the missile reference area, decreases with increasing supersonic Mach number and increases with angle of attack and the wing surface area. When the wing surface area is reduced the total weight of the missile and drag are reduced thereby increasing the lift and achieve excessive stability.
Keywords—Aerodynamics, drag, missile, normal forces and stability
This so called PPT for propulsion study for Shenyang Aerospace University. This PPT right protected by Dr. divinder K. Yadav. Its using in SAU by Lale. For all students of Aeronautical Engineering must memorize each & every words from this PPT. If you miss a single words you must fail in the Exam. Remember there is no chance to be creative or use sense you just need to use the power of memorizing.
This Presentation gives a brief idea on turbojet engines, their components, working principle and also regarding the type of materials used in the engine parts, applications etc
This compressor works on the principle of centrifugal action. It finds wide variety of applications in engineering field. It is available in market from low to high capacities.
Aerodynamic characterisitics of a missile componentseSAT Journals
Abstract
A Missile is a self-propelled guided weapon system that travels through air or space. A powered, guided munitions that travels through the air or space is known as a missile (or guided missile). The Missile is defined as a space transversing unmanned vehicle that contains the means for controlling its flight path. The aerodynamic characteristics of a missile components such as body, wing and tail are calculated by using analytical methods to predict the drag and the normal forces of the missile. The total drag of the body is computed by using the parasite drag, wave drag, skin friction drag and base drag. The wing surface normal force coefficient (CN)Wing is a function of Mach number, local angle of attack, aspect ratio, and the wing surface plan form area (CN)Wing , based on the missile reference area, decreases with increasing supersonic Mach number and increases with angle of attack and the wing surface area. When the wing surface area is reduced the total weight of the missile and drag are reduced thereby increasing the lift and achieve excessive stability.
Keywords—Aerodynamics, drag, missile, normal forces and stability
This so called PPT for propulsion study for Shenyang Aerospace University. This PPT right protected by Dr. divinder K. Yadav. Its using in SAU by Lale. For all students of Aeronautical Engineering must memorize each & every words from this PPT. If you miss a single words you must fail in the Exam. Remember there is no chance to be creative or use sense you just need to use the power of memorizing.
Turbojets can be highly efficient for supersonic aircraft. Turbojets have poor efficiency at low vehicle speeds, which limits their usefulness in vehicles other than aircraft. Turbojet engines have been used in isolated cases to power vehicles other than aircraft, typically for attempts on land speed records.
6th International Conference on Machine Learning & Applications (CMLA 2024)ClaraZara1
6th International Conference on Machine Learning & Applications (CMLA 2024) will provide an excellent international forum for sharing knowledge and results in theory, methodology and applications of on Machine Learning & Applications.
Hierarchical Digital Twin of a Naval Power SystemKerry Sado
A hierarchical digital twin of a Naval DC power system has been developed and experimentally verified. Similar to other state-of-the-art digital twins, this technology creates a digital replica of the physical system executed in real-time or faster, which can modify hardware controls. However, its advantage stems from distributing computational efforts by utilizing a hierarchical structure composed of lower-level digital twin blocks and a higher-level system digital twin. Each digital twin block is associated with a physical subsystem of the hardware and communicates with a singular system digital twin, which creates a system-level response. By extracting information from each level of the hierarchy, power system controls of the hardware were reconfigured autonomously. This hierarchical digital twin development offers several advantages over other digital twins, particularly in the field of naval power systems. The hierarchical structure allows for greater computational efficiency and scalability while the ability to autonomously reconfigure hardware controls offers increased flexibility and responsiveness. The hierarchical decomposition and models utilized were well aligned with the physical twin, as indicated by the maximum deviations between the developed digital twin hierarchy and the hardware.
Online aptitude test management system project report.pdfKamal Acharya
The purpose of on-line aptitude test system is to take online test in an efficient manner and no time wasting for checking the paper. The main objective of on-line aptitude test system is to efficiently evaluate the candidate thoroughly through a fully automated system that not only saves lot of time but also gives fast results. For students they give papers according to their convenience and time and there is no need of using extra thing like paper, pen etc. This can be used in educational institutions as well as in corporate world. Can be used anywhere any time as it is a web based application (user Location doesn’t matter). No restriction that examiner has to be present when the candidate takes the test.
Every time when lecturers/professors need to conduct examinations they have to sit down think about the questions and then create a whole new set of questions for each and every exam. In some cases the professor may want to give an open book online exam that is the student can take the exam any time anywhere, but the student might have to answer the questions in a limited time period. The professor may want to change the sequence of questions for every student. The problem that a student has is whenever a date for the exam is declared the student has to take it and there is no way he can take it at some other time. This project will create an interface for the examiner to create and store questions in a repository. It will also create an interface for the student to take examinations at his convenience and the questions and/or exams may be timed. Thereby creating an application which can be used by examiners and examinee’s simultaneously.
Examination System is very useful for Teachers/Professors. As in the teaching profession, you are responsible for writing question papers. In the conventional method, you write the question paper on paper, keep question papers separate from answers and all this information you have to keep in a locker to avoid unauthorized access. Using the Examination System you can create a question paper and everything will be written to a single exam file in encrypted format. You can set the General and Administrator password to avoid unauthorized access to your question paper. Every time you start the examination, the program shuffles all the questions and selects them randomly from the database, which reduces the chances of memorizing the questions.
Using recycled concrete aggregates (RCA) for pavements is crucial to achieving sustainability. Implementing RCA for new pavement can minimize carbon footprint, conserve natural resources, reduce harmful emissions, and lower life cycle costs. Compared to natural aggregate (NA), RCA pavement has fewer comprehensive studies and sustainability assessments.
KuberTENes Birthday Bash Guadalajara - K8sGPT first impressionsVictor Morales
K8sGPT is a tool that analyzes and diagnoses Kubernetes clusters. This presentation was used to share the requirements and dependencies to deploy K8sGPT in a local environment.
NUMERICAL SIMULATIONS OF HEAT AND MASS TRANSFER IN CONDENSING HEAT EXCHANGERS...ssuser7dcef0
Power plants release a large amount of water vapor into the
atmosphere through the stack. The flue gas can be a potential
source for obtaining much needed cooling water for a power
plant. If a power plant could recover and reuse a portion of this
moisture, it could reduce its total cooling water intake
requirement. One of the most practical way to recover water
from flue gas is to use a condensing heat exchanger. The power
plant could also recover latent heat due to condensation as well
as sensible heat due to lowering the flue gas exit temperature.
Additionally, harmful acids released from the stack can be
reduced in a condensing heat exchanger by acid condensation. reduced in a condensing heat exchanger by acid condensation.
Condensation of vapors in flue gas is a complicated
phenomenon since heat and mass transfer of water vapor and
various acids simultaneously occur in the presence of noncondensable
gases such as nitrogen and oxygen. Design of a
condenser depends on the knowledge and understanding of the
heat and mass transfer processes. A computer program for
numerical simulations of water (H2O) and sulfuric acid (H2SO4)
condensation in a flue gas condensing heat exchanger was
developed using MATLAB. Governing equations based on
mass and energy balances for the system were derived to
predict variables such as flue gas exit temperature, cooling
water outlet temperature, mole fraction and condensation rates
of water and sulfuric acid vapors. The equations were solved
using an iterative solution technique with calculations of heat
and mass transfer coefficients and physical properties.
Understanding Inductive Bias in Machine LearningSUTEJAS
This presentation explores the concept of inductive bias in machine learning. It explains how algorithms come with built-in assumptions and preferences that guide the learning process. You'll learn about the different types of inductive bias and how they can impact the performance and generalizability of machine learning models.
The presentation also covers the positive and negative aspects of inductive bias, along with strategies for mitigating potential drawbacks. We'll explore examples of how bias manifests in algorithms like neural networks and decision trees.
By understanding inductive bias, you can gain valuable insights into how machine learning models work and make informed decisions when building and deploying them.
Literature Review Basics and Understanding Reference Management.pptxDr Ramhari Poudyal
Three-day training on academic research focuses on analytical tools at United Technical College, supported by the University Grant Commission, Nepal. 24-26 May 2024
HEAP SORT ILLUSTRATED WITH HEAPIFY, BUILD HEAP FOR DYNAMIC ARRAYS.
Heap sort is a comparison-based sorting technique based on Binary Heap data structure. It is similar to the selection sort where we first find the minimum element and place the minimum element at the beginning. Repeat the same process for the remaining elements.
TOP 10 B TECH COLLEGES IN JAIPUR 2024.pptxnikitacareer3
Looking for the best engineering colleges in Jaipur for 2024?
Check out our list of the top 10 B.Tech colleges to help you make the right choice for your future career!
1) MNIT
2) MANIPAL UNIV
3) LNMIIT
4) NIMS UNIV
5) JECRC
6) VIVEKANANDA GLOBAL UNIV
7) BIT JAIPUR
8) APEX UNIV
9) AMITY UNIV.
10) JNU
TO KNOW MORE ABOUT COLLEGES, FEES AND PLACEMENT, WATCH THE FULL VIDEO GIVEN BELOW ON "TOP 10 B TECH COLLEGES IN JAIPUR"
https://www.youtube.com/watch?v=vSNje0MBh7g
VISIT CAREER MANTRA PORTAL TO KNOW MORE ABOUT COLLEGES/UNIVERSITITES in Jaipur:
https://careermantra.net/colleges/3378/Jaipur/b-tech
Get all the information you need to plan your next steps in your medical career with Career Mantra!
https://careermantra.net/
2. Lab: Engine Disassembly & Assembly
Task1: The task is about the development of Aero Engines
(Turbojet Engine; Turbofan Engine; Turboshaft Engine;
Turboprop Engine).
Answer:
The development of Aero Engines
Introduction
An aero engine is a component of the propulsion system for an aircraft that generates
mechanical power. Aero engines are almost always either lightweight piston engines or gas
turbines, except for small multicopter UAVs which are almost always electric aircraft. There
are many kinds of aero engines. Here, I have to discuss about develop of Aero Engines like
Turbojet, Turbofan, Turboshaft and Turboprop Engine.
The question asks about the development of Aero Engines that means all engines are Jet
Engines which are also called Gas Turbine Engines.
Jet engines move the airplane forward with a great force that is produced by a tremendous
thrust and causes the plane to fly very fast. So, the main principal is Newton’s third law of
motion. Sir Isaac Newton in the 18th century was the first to theorize that a rearward-channeled
explosion could propel a machine forward at a great rate of speed. This theory was based on
his third law of motion. As the hot air blasts backwards through the nozzle the plane moves
forward.
Frank Whittle, a British pilot, who designed and patented the first turbo jet engine in 1930.
The Whittle engine first flew successfully in May, 1941. This engine featured a multistage
compressor, and a combustion chamber, a single stage turbine and a nozzle.
Jet Engine parts:
Figure1 Jet Engine parts
3. Lab: Engine Disassembly & Assembly
All jet engines, which are also called gas turbines, work on the same principle.
The engine sucks air in at the front with a fan. A compressor raises the pressure of the air. The
compressor is made with many blades attached to a shaft. The blades spin at high speed and
compress or squeeze the air. The compressed air is then sprayed with fuel and an electric spark
lights the mixture. The burning gases expand and blast out through the nozzle, at the back of
the engine. As the jets of gas shoot backward, the engine and the aircraft are thrust forward. As
the hot air is going to the nozzle, it passes through another group of blades called the turbine.
The turbine is attached to the same shaft as the compressor. Spinning the turbine causes the
compressor to spin.
While each of the engines are different, But, they share some parts in common. These are
discussed below
Fan: The fan is the first component in a turbofan.
Figure1.1 Fan (red color)
The large spinning fan sucks in large quantities of air. Most blades of the fan are made of
titanium. It then speeds this air up and splits it into two parts. One part continues through the
"core" or center of the engine, where it is acted upon by the other engine components.
The second part "bypasses" the core of the engine. It goes through a duct that surrounds the
core to the back of the engine where it produces much of the force that propels the airplane
forward. This cooler air helps to quiet the engine as well as adding thrust to the engine.
4. Lab: Engine Disassembly & Assembly
Inlet: All turbine engines have an inlet to bring free stream air into the engine. The
inlet sits upstream of the compressor and, while the inlet does no work on the flow, inlet
performance has a strong influence on engine net thrust. As shown in the figures above, inlets
come in a variety of shapes and sizes with the specifics usually dictated by the speed of the
aircraft.
Figure1.2 Inlet (Intake in British)
Subsonic inlets: For aircraft that cannot go faster than the speed of sound, like large
airliners, a simple, straight, short inlet works quite well. On a typical subsonic inlet, the
surface of the inlet from outside to inside is a continuous smooth curve with some
thickness from inside to outside. The most upstream portion of the inlet is called
the highlight, or the inlet lip. A subsonic aircraft has an inlet with a relatively thick lip.
Supersonic inlets: For a supersonic aircraft, the inlet must slow the flow down to
subsonic speeds before the air reaches the compressor because of shock waves. Some
supersonic inlets, like the one at the upper right, use a central cone to shock the flow
down to subsonic speeds. Other inlets, like the one shown at the lower left, use flat
hinged plates to generate the compression shocks, with the resulting inlet geometry
having a rectangular cross section. This variable geometry inlet is used on the F-14 and
F-15 fighter aircraft.
Hypersonic inlets: Inlets for hypersonic aircraft present the ultimate design challenge.
For ramjet-powered aircraft, the inlet must bring the high speed external flow down to
subsonic conditions in the burner. High stagnation temperatures are present in this
speed regime and variable geometry may not be an option for the inlet designer because
of possible flow leaks through the hinges. For scramjet-powered aircraft, the heat
environment is even worse because the flight Mach number is higher than that for a
ramjet-powered aircraft. Scramjet inlets are highly integrated with the fuselage of the
aircraft. On the X-43A, the inlet includes the entire lower surface of the aircraft forward
5. Lab: Engine Disassembly & Assembly
of the cowl lip. Thick, hot boundary layers are usually present on the compression
surfaces of hypersonic inlets. The flow exiting a scramjet inlet must remain supersonic.
Inlet efficiency: An inlet must operate efficiently over the entire flight envelope of the
aircraft. At very low aircraft speeds, or when just sitting on the runway, free stream air
is pulled into the engine by the compressor. At high speeds, a good inlet will allow the
aircraft to maneuver to high angles of attack and sideslip without disrupting flow to the
compressor. Because the inlet is so important to overall aircraft operation, it is usually
designed and tested by the airframe company, not the engine manufacturer. But because
inlet operation is so important to engine performance, all engine manufacturers also
employ inlet aerodynamicists. Different airframers use different indices, but all of the
indices are based on ratios of the local variation of pressure to the average pressure at
the compressor face.
hypersonic inlets are normally characterized by their kinetic energy efficiency. If the
airflow demanded by the engine is much less than the airflow that can be captured by
the inlet, then the difference in airflow is spilled around the inlet. The airflow mis-
match can produce spillage drag on the aircraft.
Compressor: The compressor is the first component in the engine core. The compressor is
made up of fans with many blades and attached to a shaft. The compressor squeezes the air that
enters it into progressively smaller areas, resulting in an increase in the air pressure. This results
in an increase in the energy potential of the air. The squashed air is forced into the combustion
chamber.
Figure1.3 Compressor
6. Lab: Engine Disassembly & Assembly
As shown in the above figure, there are two main types of
compressors: axial and centrifugal.
In the picture, the compressor on the left is called an axial compressor because the flow
through the compressor travels parallel to the axis of rotation. Modern
large turbojet and turbofan engines usually use axial compressors.
The compressor on the right is called a centrifugal compressor because the flow
through this compressor is turned perpendicular to the axis of rotation. Centrifugal
compressors, which were used in the first jet engines, are still used on small turbojets
and turboshaft engines and as pumps on rocket engines.
Combustor: In the combustor the air is mixed with fuel and then ignited. There are as many
as 20 nozzles to spray fuel into the airstream. The mixture of air and fuel catches fire. This
provides a high temperature, high-energy airflow. The fuel burns with the oxygen in the
compressed air, producing hot expanding gases. The inside of the combustor is often made of
ceramic materials to provide a heat-resistant chamber. The heat can reach 2700.
Figure1.4 Combustor-Burner
There are three main types of combustors, and all three designs are found in modern gas
turbines:
The burner at the left is an annular combustor with the liner sitting inside the outer
casing which has been peeled open in the drawing. Many modern burners have an
annular design.
The burner in the middle is an older can or tubular design. The photo at the top left
shows some actual burner cans. Each can have both a liner and a casing, and the cans
are arranged around the central shaft.
7. Lab: Engine Disassembly & Assembly
A compromise design is shown at the right. This is a can-annular design, in
which the casing is annular and the liner is can-shaped. The advantage to the can-
annular design is that the individual cans are more easily designed, tested, and serviced.
Turbine: The high-energy airflow coming out of the combustor goes into the turbine, causing
the turbine blades to rotate. The turbines are linked by a shaft to turn the blades in the
compressor and to spin the intake fan at the front. This rotation takes some energy from the
high-energy flow that is used to drive the fan and the compressor. The gases produced in the
combustion chamber move through the turbine and spin its blades. The turbines of the jet spin
around thousands of times. They are fixed on shafts which have several sets of ball-bearing in
between them.
Figure1.5 Turbine
Depending on the engine type, there may be multiple turbine stages present in the engine.
Turbofan and turboprop engines usually employ a separate turbine and shaft to power
the fan and gear box respectively. Such an arrangement is termed a two spool engine.
The power turbine shown on the upper left of the figure is for a two spool, turbofan
engine.
For some high performance engines, an additional turbine and shaft is present to power
separate parts of the compressor. This arrangement produces a three spool engine.
8. Lab: Engine Disassembly & Assembly
Nozzle: The nozzle is the exhaust duct of the engine. This is the engine part which actually
produces the thrust for the plane. The energy depleted airflow that passed the turbine, in
addition to the colder air that bypassed the engine core, produces a force when exiting the
nozzle that acts to propel the engine, and therefore the airplane, forward. The combination of
the hot air and cold air are expelled and produce an exhaust, which causes a forward thrust.
The nozzle may be preceded by a mixer, which combines the high temperature air coming from
the engine core with the lower temperature air that was bypassed in the fan. The mixer helps
to make the engine quieter.
Figure1.6 Nozzle
As shown above, nozzles come in a variety of shapes and sizes depending on the mission of
the aircraft.
Simple turbojets, and turboprops, often have a fixed geometry convergent nozzle as
shown on the left of the figure.
Turbofan engines often employ a co-annular nozzle as shown at the top left. The core
flow exits the center nozzle while the fan flow exits the annular nozzle. Mixing of the
two flows provides some thrust enhancement and these nozzles also tend to be quieter
than convergent nozzles.
Afterburning turbojets and turbofans require a variable geometry convergent-divergent
- CD nozzle as shown on the left. In this nozzle, the flow first converges down to
the minimum area or throat, then is expanded through the divergent section to the exit
at the right. The flow is subsonic upstream of the throat, but supersonic downstream of
the throat.
All of the nozzles we have discussed thus far are round tubes. Recently, however, engineers
have been experimenting with nozzles with rectangular exits. This allows the exhaust flow to
9. Lab: Engine Disassembly & Assembly
be easily deflected, or vectored, as shown in the middle of the figure. Changing the
direction of the thrust with the nozzle makes the aircraft much more maneuverable.
Turbojet Engine
Figure2 Turbojet Engine
The turbojet is an air breathing jet engine, typically used in aircraft. It consists of a gas
turbine with a propelling nozzle. The gas turbine has an air inlet, a compressor, a combustion
chamber, and a turbine (that drives the compressor). Two engineers, Frank Whittle in
the United Kingdom and Hans von Ohain in Germany, developed the concept independently
into practical engines during the late 1930s.
A turbojet is a type of gas turbine engine that was originally developed for military fighters
during World War II. When turbojets were introduced, the top speed of fighter aircraft
equipped with them was at least 100 miles per hour faster than competing piston-driven aircraft.
In the years after the war, the drawbacks of the turbojet gradually became apparent. Below
about Mach 2, turbojets are very fuel inefficient and create tremendous amounts of noise. Early
designs also respond very slowly to power changes, a fact that killed many experienced pilots
when they attempted the transition to jets. These drawbacks eventually led to the downfall of
the pure turbojet, and only a handful of types are still in production. The last airliner that used
turbojets was the Concorde, whose Mach 2 airspeed permitted the engine to be highly efficient.
Early Development and Designs: Early German turbojets had severe limitations on the
amount of running they could do due to the lack of suitable high temperature materials for the
turbines. British engines such as the Rolls-Royce Welland used better materials giving
improved durability. The Welland was type-certified for 80 hours initially, later extended to
150 hours between overhauls, as a result of an extended 500-hour run being achieved in
10. Lab: Engine Disassembly & Assembly
tests. Despite their high maintenance, some of the early jet fighters are still
operational with their original engines.
General Electric in the United States was in a good position to enter the jet engine business due
to its experience with the high-temperature materials used in their turbosuperchargers during
World War II.
Water injection was a common method used to increase thrust, usually during takeoff, in early
turbojets that were thrust-limited by their allowable turbine entry temperature. The water
increased thrust at the temperature limit, but prevented complete combustion, often leaving a
very visible smoke trail.
Allowable turbine entry temperatures have increased steadily over time both with the
introduction of superior alloys and coatings, and with the introduction and progressive
effectiveness of blade cooling designs. On early engines, the turbine temperature limit had to
be monitored, and avoided, by the pilot, typically during starting and at maximum thrust
settings. Automatic temperature limiting was introduced to reduce pilot workload and reduce
the likelihood of turbine damage due to over-temperature.
Design & Development:
Air intake/ Inlet: An intake, or tube, is needed in front of the compressor to help direct the
incoming air smoothly into the moving compressor blades. Older engines had stationary vanes
in front of the moving blades. These vanes also helped to direct the air onto the blades. The air
flowing into a turbojet engine is always subsonic, regardless of the speed of the aircraft itself.
The intake has to supply air to the engine with an acceptably small variation in pressure (known
as distortion) and having lost as little energy as possible on the way (known as pressure
recovery). The ram pressure rise in the intake is the inlets contribution to the propulsion
system overall pressure ratio and thermal efficiency.
The intake gains prominence at high speeds when it transmits more thrust to the airframe than
the engine does.
Compressor: The compressor is driven by the turbine. It rotates at high speed,
adding energy to the airflow and at the same time squeezing (compressing) it into a smaller
space. Compressing the air increases its pressure and temperature. The smaller the compressor,
the faster it turns. At the large end of the range, the GE-90-115 fan rotates at about 2,500 RPM,
while a small helicopter engine compressor rotates around 50,000 RPM.
Turbojets supply bleed air from the compressor to the aircraft for the environmental control
system, anti-icing, and fuel tank pressurization, for example. The engine itself needs air at
various pressures and flow rates to keep it running. This air comes from the compressor, and
without it, the turbines would overheat, the lubricating oil would leak from the bearing cavities,
the rotor thrust bearings would skid or be overloaded, and ice would form on the nose cone.
The air from the compressor, called secondary air, is used for turbine cooling, bearing cavity
11. Lab: Engine Disassembly & Assembly
sealing, anti-icing, and ensuring that the rotor axial load on its thrust bearing will not
wear it out prematurely. Supplying bleed air to the aircraft decreases the efficiency of the
engine because it has been compressed, but then does not contribute to producing thrust. Bleed
air for aircraft services is no longer needed on the turbofan-powered Boeing 787.
Compressor types used in turbojets were typically axial or centrifugal. Early turbojet
compressors had low pressure ratios up to about 5:1. Aerodynamic improvements including
splitting the compressor into two separately rotating parts, incorporating variable blade angles
for entry guide vanes and stators, and bleeding air from the compressor enabled later turbojets
to have overall pressure ratios of 15:1 or more. For comparison, modern civil turbofan engines
have overall pressure ratios of 44:1 or more. After leaving the compressor, the air enters the
combustion chamber.
Combustion chamber: The burning process in the combustor is significantly different from
that in a piston engine. In a piston engine, the burning gases are confined to a small volume,
and as the fuel burns, the pressure increases. In a turbojet, the air and fuel mixture burn in the
combustor and pass through to the turbine in a continuous flowing process with no pressure
build-up. Instead, a small pressure loss occurs in the combustor.
The fuel-air mixture can only burn in slow-moving air, so an area of reverse flow is maintained
by the fuel nozzles for the approximately stoichiometric burning in the primary zone. Further
compressor air is introduced which completes the combustion process and reduces the
temperature of the combustion products to a level which the turbine can accept. Less than 25%
of the air is typically used for combustion, as an overall lean mixture is required to keep within
the turbine temperature limits.
Turbine: Hot gases leaving the combustor expand through the turbine. Typical materials for
turbines include inconel and Nimonic. The hottest turbine vanes and blades in an engine have
internal cooling passages. Air from the compressor is passed through these to keep the metal
temperature within limits. The remaining stages do not need cooling.
In the first stage, the turbine is largely an impulse turbine (similar to a pelton wheel) and rotates
because of the impact of the hot gas stream. Later stages are convergent ducts that accelerate
the gas. Energy is transferred into the shaft through momentum exchange in the opposite way
to energy transfer in the compressor. The power developed by the turbine drives the compressor
and accessories, like fuel, oil, and hydraulic pumps that are driven by the accessory gearbox.
Nozzle: After the turbine, the gases expand through the exhaust nozzle producing a high
velocity jet. In a convergent nozzle, the ducting narrows progressively to a throat. The nozzle
pressure ratio on a turbojet is high enough at higher thrust settings to cause the nozzle to choke.
If, however, a convergent-divergent de Laval nozzle is fitted, the divergent (increasing flow
area) section allows the gases to reach supersonic velocity within the divergent section.
Additional thrust is generated by the higher resulting exhaust velocity.
12. Lab: Engine Disassembly & Assembly
Thrust augmentation: Thrust was most commonly increased in turbojets injection or
afterburning. Some engines used both at the same time.
Afterburner: An afterburner or "reheat jetpipe" is a combustion chamber added to reheat the
turbine exhaust gases. The fuel consumption is very high, typically four times that of the main
engine. Afterburners are used almost exclusively on supersonic aircraft, most being military
aircraft. Two supersonic airliners, Concorde and the Tu-144, also used afterburners as
does Scaled Composites White Knight, a carrier aircraft for the experimental Space Ship
One suborbital spacecraft.
Net thrust: If the speed of the jet is equal to sonic velocity the nozzle is said to be choked. If
the nozzle is choked the pressure at the nozzle exit plane is greater than atmospheric pressure,
and extra terms must be added to the above equation to account for the pressure thrust.
Figure2.1 Turbojet Thrust
The rate of flow of fuel entering the engine is very small compared with the rate of flow of
air. If the contribution of fuel to the nozzle gross thrust is ignored, the net thrust is:
The speed of the jet Ve must exceed the true airspeed of the aircraft V0 if there is to be a net
forward thrust on the airframe. The speed Ve can be calculated thermodynamically based
on adiabatic expansion.
13. Lab: Engine Disassembly & Assembly
Cycle improvements: The operation of a turbojet is modelled approximately by the Brayton
cycle.
Figure2.2 The idealized Brayton cycle
Where,
P = pressure,
V = volume,
T = temperature,
S = entropy, and
Q = the heat added to or rejected by the system
The efficiency of a gas turbine is increased by raising the overall pressure ratio, requiring
higher-temperature compressor materials, and raising the turbine entry temperature, requiring
better turbine materials and/or improved vane/blade cooling. It is also increased by reducing
the losses as the flow progresses from the intake to the propelling nozzle. These losses are
quantified by compressor and turbine efficiencies and ducting pressure losses. When used in a
turbojet application, where the output from the gas turbine is used in a propelling nozzle, raising
the turbine temperature increases the jet velocity. At normal subsonic speeds this reduces the
propulsive efficiency, giving an overall loss, as reflected by the higher fuel consumption, or
SFC.
However, for supersonic aircraft this can be beneficial, and is part of the reason why the
Concorde employed turbojets. Turbojet systems are complex systems therefore to secure
optimal function of such system, there is a call for the newer models being developed to
advance its control systems to implement the newest knowledge from the areas of automation.
14. Lab: Engine Disassembly & Assembly
Turbofan Engine
Figure3 Schematic diagram of a high-bypass turbofan engine
Principles: A turbofan engine has a large fan at the front, which sucks in air. Most of the air
flows around the outside of the engine, making it quieter and giving more thrust at low speeds.
Most of today's airliners are powered by turbofans. In a turbojet all the air entering the intake
passes through the gas generator, which is composed of the compressor, combustion chamber,
and turbine. In a turbofan engine only a portion of the incoming air goes into the combustion
chamber. The remainder passes through a fan, or low-pressure compressor, and is ejected
directly as a "cold" jet or mixed with the gas-generator exhaust to produce a "hot" jet. The
objective of this sort of bypass system is to increase thrust without increasing fuel consumption.
It achieves this by increasing the total air-mass flow and reducing the velocity within the same
total energy supply.
Bypass ratio: The bypass ratio (BPR) of a turbofan engine is the ratio between the mass flow
rate of the bypass stream to the mass flow rate entering the core. A 10:1 bypass ratio, for
example, means that 10 kg of air passes through the bypass duct for every 1 kg of air passing
through the core.
Efficiency: Since the efficiency of propulsion is a function of the relative airspeed of the
exhaust to the surrounding air, propellers are most efficient for low speed, pure jets for high
speeds, and ducted fans in the middle. Turbofans are thus the most efficient engines in the
range of speeds from about 500 to 1,000 km/h (310 to 620 mph), the speed at which most
commercial aircraft operate. Turbofans retain an efficiency edge over pure jets at
low supersonic speeds up to roughly Mach 1.6 (1,960.1 km/h; 1,217.9 mph).
15. Lab: Engine Disassembly & Assembly
Thrust: The thrust (FN) generated by a turbofan depends on the effective exhaust
velocity of the total exhaust, as with any jet engine, but because two exhaust jets are present
the thrust equation can be expanded as:
Figure3.1 Turbofan Thrust
Nozzles: The cold duct and core duct's nozzle systems are relatively complex due to there being
two exhaust flows.
In high bypass engines the fan is generally situated in a short duct near the front of the engine
and typically has a convergent cold nozzle, with the tail of the duct forming a low pressure
ratio nozzle that under normal conditions will choke creating supersonic flow patterns around
the core.
The core nozzle is more conventional, but generates less of the thrust, and depending on design
choices, such as noise considerations, may conceivably not choke.
In low bypass engines the two flows may combine within the ducts, and share a common
nozzle, which can be fitted with afterburner.
Recent development:
Aerodynamic modelling: Aerodynami is a mix of subsonic, transonic and supersonic airflow
on a single fan/gas compressor blade in a modern turbofan. The airflow past the blades has to
be maintained within close angular limits to keep the air flowing against an increasing pressure.
Otherwise the air will come back out of the intake.
16. Lab: Engine Disassembly & Assembly
Blade technology: A 100 g turbine blade is subjected to 1,700 °C/3100 °F, at 17
bars/250 Psi and a centrifugal force of 40 kN/ 9,000 lbf, well above the point of plastic
deformation and even above the melting point. Exotic alloys, sophisticated air
cooling schemes and special mechanical design are needed to keep the physical stresses within
the strength of the material. Rotating seals must withstand harsh conditions for 10 years, 20,000
missions and rotating at 10–20,000 rpm.
Fan blades: Fan blades have been growing as jet engines have been getting bigger: each fan
blade carries the equivalent of nine double-decker buses and swallows the volume of a squash
court every second. Advances in computational fluid dynamics (CFD) modelling have
permitted complex, 3D curved shapes with very wide chord, keeping the fan capabilities while
minimizing the blade count to lower costs. Coincidentally, the bypass ratio grew to achieve
higher propulsive efficiency and the fan diameter increased.
Cycle improvements: According to simple theory, if the ratio of turbine rotor inlet
temperature/(HP) compressor delivery temperature is maintained, the HP turbine throat area
can be retained. However, this assumes that cycle improvements are obtained, while retaining
the datum (HP) compressor exit flow function (non-dimensional flow). In practice, changes to
the non-dimensional speed of the (HP) compressor and cooling bleed extraction would
probably make this assumption invalid, making some adjustment to HP turbine throat area
unavoidable. This means the HP turbine nozzle guide vanes would have to be different from
the original. In all probability, the downstream LP turbine nozzle guide vanes would have to
be changed anyway.
Thrust growth: Thrust growth is obtained by increasing core power. There are two basic
routes available:
hot route: increase HP turbine rotor inlet temperature
cold route: increase core mass flow
Both routes require an increase in the combustor fuel flow and, therefore, the heat energy added
to the core stream. The hot route may require changes in turbine blade/vane materials and/or
better blade/vane cooling. The cold route can be obtained by one of the following:
adding T-stages to the LP/IP compression
adding a zero-stage to the HP compression
improving the compression process, without adding stages.
all of which increase both overall pressure ratio and core airflow.
Future progress: Engine cores are shrinking as they are operating at higher pressure ratios and
becoming more efficient, and become smaller compared to the fan as bypass ratios increase.
Blade tip clearances are harder to maintain at the exit of the high-pressure compressor where
blades are 0.5 in (13 mm) high or less, backbone bending further affects clearance control as
the core is proportionately longer and thinner and the fan to low-pressure turbine driveshaft is
in constrained space within the core.
17. Lab: Engine Disassembly & Assembly
Turboprop Engine
Figure4 Schematic diagram showing the operation of a turboprop engine
Principles: A turboprop engine is a jet engine attached to a propeller. The turbine at the back
is turned by the hot gases, and this turns a shaft that drives the propeller. Some small airliners
and transport aircraft are powered by turboprops.
Like the turbojet, the turboprop engine consists of a compressor, combustion chamber, and
turbine, the air and gas pressure is used to run the turbine, which then creates power to drive
the compressor. Compared with a turbojet engine, the turboprop has better propulsion
efficiency at flight speeds below about 500 miles per hour. Modern turboprop engines are
equipped with propellers that have a smaller diameter but a larger number of blades for efficient
operation at much higher flight speeds. To accommodate the higher flight speeds, the blades
are scimitar-shaped with swept-back leading edges at the blade tips. Engines featuring such
propellers are called propfans.
Turboprop Thrust:
Figure4.1 Turboprop Thrust
18. Lab: Engine Disassembly & Assembly
Technological aspects:
Figure4.2 Propulsive efficiency comparison for various gas turbine engine
configurations.
Exhaust thrust in a turboprop is sacrificed in favour of shaft power, which is obtained by
extracting additional power (up to that necessary to drive the compressor) from turbine
expansion. Owing to the additional expansion in the turbine system, the residual energy in the
exhaust jet is low. Consequently, the exhaust jet typically produces around or less than 10% of
the total thrust. A higher proportion of the thrust comes from the propeller at low speeds and
less at higher speeds.
Propellers lose efficiency as aircraft speed increases, so turboprops are normally not used on
high-speed aircraft above Mach 0.6-0.7. However, propfan engines, which are very similar to
turboprop engines, can cruise at flight speeds approaching Mach 0.75. To increase propeller
efficiency, a mechanism can be used to alter their pitch relative to the airspeed. A variable-
pitch propeller, also called a controllable-pitch propeller, can also be used to generate negative
thrust while decelerating on the runway. Additionally, in the event of an engine failure, the
pitch can be adjusted to a vaning pitch (called feathering), thus minimizing the drag of the non-
functioning propeller.
Uses: Turboprop engines are generally used on small subsonic aircraft, but the Tupolev Tu-
114 can reach 470 kt (870 km/h, 541 mph). Large military and civil aircraft, such as
the Lockheed L-188 Electra and the Tupolev Tu-95, have also used turboprop power.
The Airbus A400M is powered by four Europrop TP400 engines, which are the third most
powerful turboprop engines ever produced, after the eleven megawatt-output Kuznetsov NK-
12 and 10.4 MW-output Progress D-27
Reliability: Between 2012 and 2016, the ATSB observed 417 events with turboprop aircraft,
83 per year, over 1.4 million flight hours: 2.2 per 10,000 hours. Three were “high risk”
involving engine malfunction and unplanned landing in single-engine Cessna 208 Caravans,
four “medium risk” and 96% “low risk”. Two occurrences resulted in minor injuries due to
engine malfunction and terrain collision in agricultural aircraft and five accidents involved
aerial work: four in agriculture and one in an air ambulance.
19. Lab: Engine Disassembly & Assembly
Turboshaft Engine
A turboshaft engine is a form of gas turbine that is optimized to produce shaft power rather
than jet thrust.
In concept, turboshaft engines are very similar to turbojets, with additional turbine expansion
to extract heat energy from the exhaust and convert it into output shaft power. They are even
more similar to turboprops, with only minor differences, and a single engine is often sold in
both forms.
Turboshaft engines are commonly used in applications that require a sustained high power
output, high reliability, small size, and light weight. These include helicopters, auxiliary power
units, boats and ships, tanks, hovercraft, and stationary equipment.
Figure5 Schematic diagram showing the operation of a simplified turboshaft engine.
The compressor spool is shown in green and the free / power spool is in purple.
Overview: A turboshaft engine may be made up of two major parts assemblies: the 'gas
generator' and the 'power section'. The gas generator consists of the compressor, combustion
chambers with ignitors and fuel nozzles, and one or more stages of turbine. The power section
consists of additional stages of turbines, a reduction system, and the shaft output. The gas
generator creates the hot expanding gases to drive the power section. Depending on the design,
the engine accessories may be driven either by the gas generator or by the power section.
20. Lab: Engine Disassembly & Assembly
In most designs, the gas generator and power section are mechanically separate so
they can each rotate at different speeds appropriate for the conditions, referred to as a 'free
power turbine'. A free power turbine can be an extremely useful design feature for vehicles, as
it allows the design to forgo the weight and cost of complex multiple-
ratio transmissions and clutches.
The general layout of a turboshaft is similar to that of a turboprop. The main difference is a
turboprop is structurally designed to support the loads created by a rotating propeller, as the
propeller is not attached to anything but the engine itself. In contrast, turboshaft engines usually
drive a transmission which is not structurally attached to the engine. The transmission is
attached to the vehicle structure and supports the loads created instead of the engine. In
practice, though, many of the same engines are built in both turboprop and turboshaft versions,
with only minor differences.
An unusual example of the turboshaft principle is the Pratt & Whitney F135-PW-
600 turbofan engine for the STOVL F-35B – in conventional mode it operates as a turbofan,
but when powering the LiftFan, it switches partially to turboshaft mode to send
29,000 horsepower forward through a shaft and partially to turbofan mode to continue to send
thrust to the main engine's fan and rear nozzle.
Large helicopters use two or three turboshaft engines for redundancy. The Mil Mi-26 uses
two Lotarev D-136 at 11,400 hp each, while the Sikorsky CH-53E Super Stallion uses
three General Electric T64 at 4,380 hp each.
Early turboshaft engines were adaptations of turboprop engines, delivering power through a
shaft driven directly from the gas generator shafts, via a reduction gearbox. Examples of direct-
drive turboshafts include marinised or industrial Rolls-Royce Dartengines.
Principles: This is another form of gas-turbine engine that operates much like a turboprop
system. It does not drive a propeller. Instead, it provides power for a helicopter rotor. The
turboshaft engine is designed so that the speed of the helicopter rotor is independent of the
rotating speed of the gas generator. This permits the rotor speed to be kept constant even when
the speed of the generator is varied to modulate the amount of power produced.
Turboshaft takeaway:
Pros:
Much higher power-to-weight ratio than piston engines
Typically, smaller than piston engines
Cons:
Loud
Gear systems connected to the shaft can be complex and break down