Tech - Aircraft Engineering Flashcards

1
Q

Name four different types of rotary-wing aircraft. To which general aircraft category do all these aircraft belong? What other kinds of aircraft are possible?

A
  • Autogyro
  • Gyrodyne
  • Compound helicopter
  • Convertiplane
  • Helicopter

They belong in the general aircraft category “Heavier-than-air Aircraft”, subdivision “Rotary-wing Aircraft”. Other subdivisions are “Fixed-wing Aircrafts” and “Rockets”

The other general aircraft category is “Lighter-than-air Aircraft” I.e:

  • Ballon
  • Airship.
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2
Q

Which rotorcraft requires torque compensation?

A

All rotorcraft with a single shaft driven rotor.

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3
Q

Name the SI base units!

A
  • Length, Meter (l,d)
  • Mass, Kilogram (m)
  • Time, Second (t)
  • Current, Ampére (I)
  • Temperature, Kelvin (T)
  • Luminous intensity, Candela (lv)
  • Amount of substance, Mol (n)
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4
Q

Combine the base units to derive the units of force, pressure, work and power.

A
  • Force (Newton): mass * acceleration

kg * m/s2= N

  • Pressure (Pascal): force / area

N/m2=Pa

  • Work (Joule): force * length
    1 Nm = 1 Joule
  • Power (Watt): work / time

Nm/s = Watt

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5
Q

Convert the given velocity into: knots, ft/min, m/s, km/h!

A

100kt = 10 124 ft/min 51,4 m/s 185,2 km/h
5 m/s = 984 ft/min 9,72 kn 18 km/h
180 ft/min = 0,9 m/s 1,78 kn 3,3 km/h

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6
Q

Name and describe the three laws of motion developed by Newton! Give an example of each law!

A

Newton’s first law (“law of inertia”):
“Each body remains in its state, rest or uniform straight movement, as long as no external force is applied to it. Only if an external force is applied to it, the body will be accelerated.” Sum of all forces = equal.

  • I.e. Apple hanging in a tree.

Newton’s second law (“Law of acceleration”):
“Force = mass * acceleration.”
Force is directly proportional to the net force applied, and inversely proportional to the mass of the object.

  • I.e. Apple falling from the tree towards the ground.

Newton’s third law (“Law of equality of action and reaction”):
“For every action, there is an equal and opposite reaction.”

Apply force on an object, object will react with the same amount of force in the opposite direction.
- I.e. Apple hitting the ground.

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7
Q

Explain Bernoulli’s law!

A

The total pressure of a horizontal flow, i.e.
the sum of static and dynamic pressure, remains constant.

P total = P stat + P dyn = constant.

I.e. If dynamic pressure increases, static pressure decreases and vice versa.

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8
Q

Explain the principle of a nozzle and a diffusor!

A
Nozzle (Flow from bigger to smaller area): 
Velocity increases (dynamic pressure increases, static pressure decreases). 
Diffusor (Flow from smaller area to bigger area): 
Velocity decreases (dynamic pressure decreases, static pressure increases).
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9
Q

Describe the terms isobaric- / isochoric- / isothermal- / isentropic- / polytropic- change of state!

A

Universal gas law=(p * V)/T

  • Isobaric change of state:
    Pressure remains constant. Volume and temperature changes.

I.e. Piston rises (volume increases) when heat is applied (temperature increase).

  • Isochoric change of state:
    Volume remains constant. Pressure and temperature changes.

I.e. Pressure cooker. Heat is applied (temperature increases), Pressure increase.

  • Isothermal change of state:
    Temperature remains constant. Pressure and volume changes.

I.e. Bike pump. Volume decreases, pressure increases, temperature (heat) is transferred to the surrounding. Happens slowly.

  • Isentropic change of state:
    Adiabatic change of state which means the change occurs without any heat exchange with the environment, i.e. in complete thermal insulation (and is therefore possible in theory only).
  • Polytropic change of state:
    Between the borderline cases of isothermal and adiabatic changes of state that cannot be achieved technically, where heat can be partially exchanged with the environment.
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10
Q

Which are the two main principles of driving the main rotor?

A
  • Tip drives.

- Shaft drives.

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11
Q

Which are the main consequences arising from these principles?

A

Tip drives:
- No torque effect on the helicopter airframe = torque balancing not needed = tail rotor not required = weight reduction.
- Have no gearbox for power transmission = weight reduction.
- High fuel consumption.
- High noise levels.
- Low propeller efficiency and insufficient lubrication due to centrifugal forces
(blade propeller drives)

Shaft drives:
- If the helicopter has only a single rotor driven by the engine via a shaft, the rotor shaft generates an equal, but opposite reaction moment that acts on the helicopter airframe. Torque balancing needed. .

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12
Q

Which anti-torque systems do you know? Name the advantages and disadvantages of these systems!

A
Conventional tail rotor: 
\+	Easy to construct	 
\+	Cheap 
\+	Easy maintenence 
\+	Common 
\+	Can be used on bigger helicopters 
  • Exposed. Can hit people and obstacles
  • High noise levels

Shrouded tail rotor:
+ Covered. Safer for people and for not hitting obstacles.
+ Quieter. (High frequency).

  • Complex maintenance = Expensive.
  • Heavy. Not suited for heavy aircraft.
  • Less efficient. Needs more power.

NOTAR (No tail rotor):
+ Safe (hitting people and obstacles)
+ Quieter
+ Low operating cost - Lower vibration

  • Only suited for light helicopters
  • Hard to control autorotation after touchdown

Example of other rotor system:
Tandem rotors:
+ All engine power goes to rotor thrust. No power sacrificed for a tail rotor.

  • Mechanically complex. A lot of work.
  • Take up a lot of space for landing.

Coaxial rotors:
+ All engine power goes to rotor thrust.

  • Difficult design.
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13
Q

You are about to lift off in a helicopter with a counterclockwise rotating main rotor (as seen from above). Where will the aircraft yaw with increasing engine power? Which countermeasure do you have to take?

A

The helicopter will want to yaw to the right with increasing engine power. To counter it, you will have to push left pedal to increase the thrust from the tail rotor.

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14
Q

You are in a hover flight with a single-rotor helicopter. The rotor is turning counter-clockwise (as seen from above). What will happen if you push the left and the right pedal respectively?

A

Left pedal:
The blade pitch on the tail rotor will increase, increasing thrust and torque, making the helicopter yaw to the left.

Right pedal:
The blade pitch on the tail rotor will decrease, decreasing thrust and torque, making the helicopter yaw to the right.

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15
Q

Which types of stress do you know? State an example for each type!

A

Bending - Rotor blades.
Shearing - Bolts for main rotor blades, rivets.
Compression - Landing gear / skids, shock absorbers.
Tension - Rotor blades being pulled apart.
Torsion - Drive shaft.
Buckling - Landing gear / skids.

MEMO: Come To The Shining Beautiful Bückeburg

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16
Q

Describe the most commonly used materials in aircraft engineering! (fuselage old & modern, gearbox, rotor blade)

A
  • Fuselage old:
    Wood or steel covered with fabric. Later on, steel titanium and light metals (I.e. aluminium).
  • Fuselage modern:
    Composite fiber designs (plastic, glass- and carbon fiber reinforced plastics). Sandwich structures.
  • Gearbox: Cast iron, steel and aluminium.
  • Rotor blade: Composite fiber materials, titanium, steel, aluminium.
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17
Q

Describe the term “sandwich structure”!

A
  • Lightweight core material (wood, hard foam or a metal/plastic honeycomb core)
  • Outer thin and stiff skin of wood, glass-fiber reinforced plastic or metal, bonded to both sides.

This provides protection from different types of stress, while at the same time keeping the weight down.

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18
Q

Name the design principles in aircraft engineering! State an example for each principle!

A
Safe life (maintenance): 
Ensuring throughout the service life of an aircraft that no damage occurs in any component relevant to the safety of the aircraft structure. 
(maintenance, replacing parts after x amount of hours). 

I.e. ???

Fail safe (redundancy): 
Designing the aircraft so that damage in, or failure of individual components do not result in failure of the aircraft. (redundancy, I.e. two hydraulic systems, stringers and formers). 

I.e. tailboom fuselage.

Crash safety (compression): 
Energy absorbing cell structures allowing compression. 

I.e. Load absorbing landing gear, Compressible landing skids, crash dampening seats.

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19
Q

Explain the terms truss frame design, monocoque design and semi-monocoque design!

A
Truss frame design: 
Primary structure in the form of a frame, with no additional shell. 
Primary structure takes all the load. Frame is made of wood or metal. Mostly consist of four main steel tubes with three or four diagonal struts. The connecting points are welded.
\+	Simple, easy to build
\+	Easy to repair 
\+	Cheap 
\+	Stable 
-	Heavy 
-	Reduced interior space 

Monocoque design:
One shell that absorbs the entire load. No inner frame. Allows for aerodynamic shape.
- Prone to buckling and compression.

Semi-monocoque design: 
Primary structure in the form of a frame (formers and stringers) for load carrying. Secondary structure (outer shell) for aerodynamics. 
\+	Fail safe (redundancy) 
\+	Lightweight 
-	Expensive/more complicated
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20
Q

What are the names of the different axes of orientation for an aircraft? Name the associated movements about these axes!

A

Roll - Longitudinal axis
Yaw - Vertical axis
Pitch - Lateral axis

MEMO: Roll – Andra bokstaven samma, d.v.s. O.
Yaw – Y ser nästan ut som ett V.

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21
Q

Which (helicopter) control device does initiate which type of movement?

A
  • The cyclic stick to operate the cyclic pitch control.
  • The collective pitch lever to operate the collective pitch control
  • Pedals for directional control

Extended answer, see below…

Cyclic stick:

  • Pitch along the lateral axis
  • Roll along the longitudinal axis

Collective:
- Lift along the vertical axis

Pedals:
- Yaw about the vertical axis

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22
Q

Name and describe the two main assemblies of a swashplate (Which movements does it have to fulfill)

A

Rotating and stationary part. The motion of the swashplate moves the control rods resulting in changes of the mechanical angle (angle of incidence).

SVARET KAN BEHÖVA UTVECKLAS.

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23
Q

How is forward flight initiated with a helicopter? Describe the entire procedure from the pilot’s input on the stick to the resulting movement of the helicopter!

A
  • Control input via the cyclic stick
  • Tilting of the stationary swashplate by control linkage
  • Tilting of the rotating swashplate
  • Cyclic change of angle of incidence (by push rod (control rod))
  • Cyclic change of lift
  • Cyclic flapping of rotor blades
  • Tilting of tip-path plane
  • Tilting of thrust vector and resulting motion of the helicopter
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24
Q

How and where does the coning angle develop?

A

Creating a coning angle between the horizontal plane and the rotor tips.

If more collective is pulled, more angle of attack on rotor blades, more force (lift) is generated, and the rotor starts to shape a cone. The angle between the tips of the blades are called tip path plane. The flapping hinges allows the blades to form the coning angle. When the lift force is higher than the weight, the rotor blades bends
upward .

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25
Q

How is forward flight initiated with a helicopter? Describe the entire procedure from the pilot’s input on the stick to the resulting movement of the helicopter!

A
  • Control input via the cyclic stick
  • Tilting of the stationary swashplate by control linkage
  • Tilting of the rotating swashplate
  • Cyclic change of angle of incidence (by push rod (control rod))
  • Cyclic change of lift
  • Cyclic flapping of rotor blades
  • Tilting of tip-path plane
  • Tilting of thrust vector and resulting motion of the helicopter

Alternative answer:

  • Forward input via the cyclic stick
  • Stationary and rotating part of swashplate tilts
  • Maximum blade pitch angle and lift at 9 o’clock by control rods.
  • Blade reaches highest position 90° later.
  • Change of lift occurs.
  • Flapping of rotor blades (tip-path plane tilting forward).
  • Lift is tilted forward, helicopter moves forward.
  • (Increased collective and torque compensation with pedals as a result of increased collective needed as well).
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26
Q

Which physical phenomenon calls for the use of lead-lag hinges? Explain this phenomenon using an example from everyday life!

A

Conservation of angular momentum.

Higher velocity is caused to the blade flapping upwards due to its closer proximity to the center of rotation. (Rotor blade center of gravity is shifted closer to the axis of rotation). This requires the blade to be able to “lead”.

I.e. Figure skater increasing his/hers rotation by pulling arm inwards toward the body.

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27
Q

Which other effect causes lead-lag of the rotor blades? Where does this effect always occur?

A

Hooke’s joint effect. Blades moves in the direction of flight at 3 and 9 o’clock.

28
Q

Explain the lead/lag position of a 4-bladed main rotor during forward flight (counterclockwise rotation)!

A
  • Advancing blade (at 3 o´clock) is accelerated(leading)
  • Retreating blade (at 9o´clock) is decelerated(lagging)
  • Blade at 12 o’clock lagging
  • Blade at 6 o’clock leading
29
Q

How and by which control input is the pitch angle of the tail rotor blades changed?

A

The tail rotor blade pitch is collectively changed by using the pedals. The tail rotor thrust is then changed so that it becomes lower or higher than the thrust required for torque balancing.

30
Q

Which components are required for the safe operation of a hydraulic system

A
  • Reservoir (open or enclosed (pressurized))
  • Fluid (incompressible)
  • Pipes, lines and hoses
  • Pump
    o Radial piston (also called centrifugal)
    ▪ Gear pumps
    o Axial piston
    ▪ Swashplate pumps
    o Other
    ▪ Gerotor
  • Monitoring system
  • Consumers
  • Valves
31
Q

Which helicopter systems are usually operated hydraulically?

A
  • Flight control systems (swash plate, tail rotor pitch)
  • Landing gear
  • Doors (ramps)
  • Brakes (wheel, rotor)
  • Winch
  • Folding of rotor blades (to save space)
32
Q

Which hydraulically operated system is of particular importance to a helicopter pilot? (Justify your answer)

A

The hydraulic flight control systems are of particular importance since most modern helicopters are too heavy to control without hydraulic support.

33
Q

Which type of reservoir should be used an aircraft hydraulic system? What is the most important characteristic?

A

An enclosed (pressurized) system should be used on aircraft to prevent cavitation that could otherwise damage the system, especially on higher altitudes.

34
Q

Which types of pumps are used in hydraulic systems? In what essential respects do these pumps differ from each other?

A

Gear pump:

  • Simple construction
  • Good efficiency
  • Constant volumetric displacementGerotor pump (Fuel pump) (tillhör gear pump)
  • Low noise
  • High efficiency
  • Compact design
  • Constant volumetric displacementAxial piston pump (Flight Control System)
  • Low noise
  • Long life cycle
  • High volume flow rate
  • Adjustable flow rate (variable volumetric displacement)

Radial pump:
- Change direction of flow

35
Q

Which type of pump is primarily used for flight control purposes?

A

Axial piston pump.

36
Q

Where are the most important hydraulic pumps mounted? And why?

A

In or close to the MGB (main gearbox) so the pumps can be driven by the MR (main rotor) during engine failure since the MGB still operates during autorotation.

37
Q

Name the different types of rotor configurations! Name one German Army helicopter type each for every type of system!

A
  • Fully articulated rotor
  • CH 53
  • Semi rigid rotor
  • Bell 206
  • Rigid rotor (Hingeless)
  • BO105
  • Rigid (hinge- and bearingless)
  • EC135
38
Q

Which movements must the rotor blades be able to perform?

A

Flapping, lead/lag and feathering.

39
Q

How are these movements allowed in the different rotor designs?

A
  • Fully articulated:
    hinges and bearings allow each rotor blade to flap, lead/lag and feather.
  • Semi-rigid (see-saw / teetering / underslung):
    One central flapping hinge. No lead/lag hinges are needed. Has feathering bearing on each rotor blade. Can only be used as a two-blade configuration.
  • Rigid (hingeless):
    Only has feathering bearings. Fiber composite materials allow for bending, tension or torsion to be absorbed by the material itself.
  • Rigid (hinge- and bearingless):
  • Rotor blades are bolted to the rigid rotor hub. The neck of each blade is designed as a flexible element (flexbeam, torsion module) which can be elastic flexed in the flapping- and lead lag motion.

Change of angle of incidence is possible due to the elastic torsion of the rotor blade root via a control element.

40
Q

Name advantages and disadvantages of the different rotor designs!

A

Fully articulated:
+ Low vibration (with the help of dampers)

  • Complex
  • Expensive
  • Needs lubrication
  • High maintenance
Used in heavy helicopter systems.
 
Semirigid: 
\+	Simple 
\+	Cheap 
  • Stabilizers leads to time delay from input to effect
  • Risk of mast-bumping
  • Tailboom strike

Used in light helicopter systems.

Rigid (hingeless): 
\+	Quick response from control input 
\+	Few parts 
\+	Improved stability 
\+	Enhanced controllability 
\+	Protection against self-induced vibrations 
-	Rotating mast bending moment 
-	High opposite forces 
-	Proneness to malfunctions caused by outside influence, such as gusts 
Rigid (hinge- and bearingless): 
\+	Low maintenance 
\+	Low cost 
\+	Long life cycle 
\+	Lightweight 
-	Not suitable for larger systems
41
Q

How is a tail rotor provided with a delta 3 hinge affected by flapping? How does this angle come about?

A

Flapping is reduced due to mounting. Shaft can be shorter – tailrotor can be closer to the tailboom.

Extended answer:
The flapping will change the angle of incidence due to an offset hinge. This practice allows for the tail rotor to be closer to the tailboom, ultimately reducing vibration. The blade will flap less and still achive the same result.

42
Q

Why is the conventional tail rotor installed on a pylon?

A

In order for the tail rotor to be at the same height as the main rotor, to counteract a roll movement.

Extended answer:
By placing the tail rotor on a pylon, the vertical distance between the horizontal component of the total rotor thrust and tail rotor thrust is smaller, and the couple strength is reduced. A similar result is obtained by slanting the tail boom upward, as seen on a number of helicopters.

43
Q

What is the purpose of the transmission system?

A
  • Transferring forces
  • Change direction of forces
  • Change of RPM
44
Q

Name five components of the transmission system!

A
  • Drive shaft
  • Clutch
  • Freewheel unit/assembly (also named clamp coupling)
  • Rotor brakes
  • Main Gearbox
45
Q

When is a centrifugal clutch required in a helicopter?

A

Required for helicopters with piston engines and single-shaft gas turbines to ensure unloaded engine start. Clutch allows the engine to gradually pick up the weight of the rotor.

46
Q

Why is a centrifugal clutch unsuitable for autorotation?

A

A centrifugal clutch is unsuitable for autorotation because it would not disengage until the RRPM is too low to recover. The rotor would drive the dead engine(s) which would only result in unnecessary friction. The coning angle would also be to big.

47
Q

Which component is suitable for power-off landings? Describe this component’s design/structure and explain how it works.

A

The freewheel is suitable for power-off landings.

As long as the blue shaft (A) (ex engine) spins faster or equally fast (clockwise) as the green shaft (B ) (ex main gearbox) the freewheel will engage and transmit the clockwise rotation from A to B. However, if B spins faster the freewheel will disengage and allow B to spin freely without affecting A.

The freewheeling unit automatically disengages the engine from the main rotor when engine RPM is less than main rotor RPM. If the engine fails, the rollers move inward, allowing the outer drum to exceed the speed of the inner portion. (Clamp coupling principle)

(SEE PICTURE IN DOCUMENT)

48
Q

Describe the design/structure of the main drive shaft!

A

A shaft with flexible parts to compensate for movements such as linear deformation and angular deviation

The main drive shaft is often hollow and very thin compared to the main rotor mast (which reduces weight). This is possible due to the low torque but high RPM produced by the engine.

49
Q

How can offset and torsion of the tail rotor drive shaft be compensated for?
What causes these offsets?

A

With flexible couplings

  • Couplings connecting gear to shaft and between shaft elements.
  • Angular deflections and axial offsets results usually from installation as well as from gearbox vibrations. Also from tail rotor thrust and environmental influences (I.e. gusts and turbulences).
50
Q

How is the main gearbox lubricated?

A

Wet sump lubrication system. Oil is stored in the reservoir. Distributed via pumps.
Drips back down to the reservoir because of gravity.

Or,

Dry sump lubrication system. Same as wet sump. Pumps pump oil back to reservoir instead of just dripping down.

51
Q

Which information on the lubrication oil circuit can be displayed in the cockpit?

A
  • Pressure
    o Pressure indicator
    o Pressure warning light
  • Temp
    o Temp indicator
    o Temp warning light
  • Chip detector
  • (Filter popped, oil level filter = Can’t be seen in cockpit though)

Alternative answer:
The oil system pressure and temperature. (Chip abrasion and filter/-s condition are also monitored. The flow of the oil is also monitored).

52
Q

How is the final stage of the main gearbox frequently designed? Why?

A

final stage of the main gearbox frequently designed? Why?

  • Planetary gears
  • Advantage: enables us to change the rpm (higher change in rpm)
  • Compact design

Alternative answer:
With planetary gears. This design allows the lowest structural weight and the smallest dimensions at high reduction ratios and high transfer torques. It also distribute stresses.

Contrary to conventional gears, the torque increase caused by each gear reduction is absorbed by various planet gears.

53
Q

How are forces transmitted from the rotor system to the airframe?

A

Via Mast – MGB – Airframe

54
Q

Which auxiliary systems are usually driven by the transmission system?

A
  • Hydraulic pump
  • Lubrication oil pump
  • Oil cooler fan
  • Generator/alternator
55
Q

Which are the main differences between gas turbines and piston engines with regard to their working cycles (place and time)? What happens to the pressure during the combustion process?

A
  • A piston engine have 4 strokes performed sequentially after each other - intake, compression, combustion and exhaust. Only one of the strokes produce power.
  • Pressure decreases.
  • A gas turbine also perform intake, compression, combustion and exhaust but simultaneously in different parts of the engine.
  • Slight decrease of pressure.
56
Q

How are the individual strokes of an internal combustion engine called?

A

Intake - compression - combustion - exhaust.

57
Q

Name the different types of jet engines! EXTRAAA: How does their efficiency change at different flight speeds?

A
  • Scramjet
  • Ramjet
  • Turbojet
  • Turbofan
  • Turboprop
  • Turboshaft
  • Propfan
  • Rockets
    ▪ Solid fuel
    ▪ Liquid fuel

Extended answer…

Scramjet:

Ramjet:
- Suitable for maximum airspeeds and can only be used above a specific minimum airspeed, to which the aircraft must be accelerated by a booster engine. Requires pre-compressed air.

Turbojet:
- More effective at higher speeds.

Turbofan:
- High efficiency at medium speeds.

Turboprop:

  • High efficiency at lower speeds.
  • Lower top speeds.
  • Shorter take-off.

Turboshaft:

Rockets:

  • Solid
  • Liquid
58
Q

Which main assembly groups does a turboshaft engine consist of?

A
  • Intake
  • Compressor
  • Combustion chamber
  • N1 turbine (compression)
  • N2 turbine (free power turbine)
  • Exhaust
59
Q

Which are the main differences between jet engines and turboshaft engines?

A
  • Jet engines produces thrust force.

- Turboshaft engines produces shaft power.

60
Q

What is the purpose of a turboshaft engine’s compressor?

A
  • Increase Pstat, thus provide the air for combustion
  • Clear combustion direction

Alternative answer (other wording):

  • Create a higher pressure before the combustion chamber to prevent backfire.
  • To increase the static pressure, in order to provide enough air mass for combustion.
61
Q

Which main dangers are compressors exposed to? How can these dangers be avoided?

A
  • FOD (Foreign object damage)
    o I.e. sand erosion and glassing of the engines -> use filter
  • Compressor stall or surge – Avoid fast accelerations.
62
Q

Describe the principal structure/design of a compressor! How do pressure and temperature behave in the different stages?

A
  • Rotor + stator in multiple stages.
  • Throughout the rotor and stators, The total pressure increases.
  • In the rotor stage both dynamic and static pressure increases.
  • In the stator stage, the static pressure increases, and the dynamic pressure decreases.
  • At the end of the compressor, a low dynamic pressure and a high static pressure should be achieved.
  • Temperature increases throughout the compressor.

TIP: Write diagram.

Axial compressor - Radial/centrifugal compressor

63
Q

Name the different types of combustion chambers! Which type is the most common one used in helicopters? Why?

A
  • Tubular combustion chamber
  • Annular combustion chamber
  • Reverse flow tubular combustion chamber
  • Reverse flow annular combustion chamber
    o Most common due to compact design = Saving space
  • Combination combustion chamber (also called can-annular)
64
Q

Into which airflows does the airstream split up in the combustion chamber and what is the purpose of these airflows respectively?

A
Primary air (20-25% of the airflow): 
-	Mixed with fuel and burned. 

Secondary air (75-80% of the airflow):

  • Centering the flame.
  • Provides a cooling “coating” for the flame.
  • Flame cutout.
65
Q

Which turbine types are used in twin turboshaft engines? Which of the two turbines is first passed through by the airstream?

A
  • Compressor turbine (N1)
  • Free power turbine (N2)

”N1” is passed through first.

66
Q

Describe the design/structure of a reaction turbine and explain how pressure and temperature behave within this type of turbine!

A
  • Stator + rotor in multiple stages.
  • Throughout the stator and rotor, The total pressure decreases.
  • In the stator stage, the static pressure decreases, and the dynamic pressure increases.
  • In the rotor stage both dynamic and static pressure decreases.
  • At the end of the turbine, a low total pressure should be achieved.
  • Temperature decreases throughout the turbine.

TIP: Write diagram.

(The inverse of question 62.)

67
Q
  1. Describe the design of the exhaust of turboshaft engines!
A

It has the form of a diffuser, so that air similar to the surrounding air. Minimizing temp signature. Less noise.