100% satisfaction guarantee Immediately available after payment Both online and in PDF No strings attached
logo-home
Summary Notes summarizing ATPL courses: Theoretical subdivisions of the Aircraft General Knowledge certificate $16.80   Add to cart

Summary

Summary Notes summarizing ATPL courses: Theoretical subdivisions of the Aircraft General Knowledge certificate

 32 views  2 purchases
  • Course
  • Institution

Notes summarizing the books “Electrics”, “Airframes” and “Engines” from ATPL Theoretical Certificate 021

Preview 3 out of 22  pages

  • October 3, 2022
  • 22
  • 2020/2021
  • Summary
avatar-seller
AGK
System design, load, stress & maintenance
• Damage/fault tolerant design:
- Capability to withstand a certain amount of weakening of a structure without catastrophic failure
- Takes cracking of the structure into account
• Fail safe design:
- More than one load carrying component, parallel structural parts, load sharing
- Based on redundancy of components
- Does not imply that the system will never fail despite having backups
• Safe life design:
- Replacement of part after a given number of cycles/flight hours in use
- One load carrying component is sufficient provided it is strong enough
- Does not imply that the system will never fail in the safe life period
There is no most favourable design method, as each component varies
• Maintenance:
1. Hard time: Component overhauled/removed after a set number of hours/cycles regardless of condition
2. On condition: Monitoring of critical parameters & replacement of parts if a limit value is exceeded
• Stress: Force/area
1. Tension: Force resisting from being pulled apart
2. Torsion: Caused by twisting
3. Compression: Push force
4. Torque: Axial rotation force
5. Shear: Force parallel to cross section
6. Buckling: Effect of more than one force
• Strain:
- Deformation due to stress, expressed as a % change of dimension of original dimension
• Elastic deformation
- Tendency of material to return to its original state
- Temporary & reverses when load is removed
• Corrosion: Incorrect metallic bonding
1. Stress: Continuous tensile load + corrosion
2. Intergranular: Grain boundaries inside metal
• Fatigue: Material is continually loaded & unloaded & will eventually break even though load is the same
• Aircraft flies beyond certified load factor: Subject to permanent deformation

No effect Minor Major Hazardous Catastrophic
Qualitive None Probable Remote Extremely remote Extremely improbable
Quantative None 10-3 10-5 10-7 10-9
Flight crew None Slight workload Physical discomfort Physical distress Fatality/Incapacitation
Airplane margins None Slight reduction Significant reduction Large reduction Hull loss
Passengers Inconvenience Physical discomfort Physical distress Serious/fatal injury Multiple fatalities

Airframe
• Engine compartment decking & firewall: Stainless steel/titanium sheet
• Sandwich structure:
- Consists of two thin sheets separated with light core material
- Low mass high stiffness
- Stabilizes covering sheets
- Unsuitable for absorbing concentrated loads
- Does not use resin
• Composite structure:
- Consists of matrix & fibres
- Component strengths can be tailored to the direction of load, not the same in all directions
- Higher strength to weight ratio compared to other metal
• Truss type: Small light aircraft/training planes
• Monocoque:
- Takes all the load on a stressed skin
- Normally uses aluminium/magnesium alloy
• Semi-monocoque:
- Fuselage of transport airplanes

, - Consists of skin, frames & stringers
- Normally uses aluminium/magnesium alloy
• Cantilever:
- Attached to the aircraft at the wing root only (No struts/braces/wires)
- Vertical loads/bending moments highest at wing root
• Wings:
- Torsion box: Consists of spars, ribs, wing skin reinforced by stringers
- Ribs:
• Maintains aerodynamic shape
- Stringers:
• Assists skin to absorb longitudinal compressive loads
- Wing skin:
• When unable to bear load, it transfers them to the spar via ribs & stringers
• Bears cylindrical load during pressurization (TENSION)
- Spar:
• Bears most of the load
• Consists of web & girders (I-beam)
- In the air:
• Lift loads carried by upper/lower skin surfaces & spars
• Tension on lower surface & compression on upper surface
- On the ground:
• Tension in upper surface & compression on lower surface
- Wing bending moments:
• Reduced by installing “upfloat” ailerons, using fuselage fuel first while maintaining fuel in wings as long as
possible
• Torsion: Effect of aileron deflection or positive sweep (As the surfaces hit the air at non uniform levels a
twisting motion is induced)
• From wing root to the tip: First compression then tension
• Aerodynamic flutter:
- Caused by torsion & bending, COP ahead of COG
- Avoided by increasing torsional stiffness & adding balancing mass in front of control surface hinge
- Avoided by ensuring correct mass distribution within the control surface during design
- Wing bends downwards: Flutter may occur if the aileron deflects upwards as aileron COG is behind hinge line
- Wing bends upwards: Flutter may occur if the aileron deflects downwards as aileron COG is behind hinge line
• T – Tail aircraft:
- Vertical stabiliser Is not affected by influence of wing turbulence
• Fuselage:
- Consists of: skin, frames & stringers (No spars/girders)
- Pressurization load = Tension
- Shell structures transmit: Normal bending, tangent bending, tension & torsional stresses (NO SHEAR)
- Torque links: Most stress when making tight turns during taxiing, turning at a small radius
- Floor proximity emergency escape lights: Gives additional guidance during evacuation in reduced visibility
• Cockpit window:
- De-icing provided by electrical heating
- Some aircraft have speed restrictions related to bird impact when window heating inoperative
- Window heating improves strength of cockpit windows
- Cockpit side windows not provided with de-icing, only defoggers
- Made of: Glass & Inner surface made of soft polycarbonate laminate
- Green system “On” information light and an amber failure warning light
• Airplanes designed for long haul cannot be used for short haul flights as lifetime of fatigue sensitive parts have been
determined on a load spectrum
• MZFM: Maximum zero fuel mass – Total maximum permissible mass of the aircraft without usable fuel

Hydraulics
• Pascal’s law: Pressure exerted on hydraulic fluid within an enclosed system the pressure will increase equally throughout
the fluid, and act at right angles to the container walls. Force/area\
• Area(A) x distance(A) = Area(B) x distance(B)
• Most common:
- Phosphate ether based fluids (Skydrol) is purple
- Synthetic oil (Maybe mineral). Synthetic = Highest resistance against cavitation

, - Operated at 3000psi
• Hydraulic power is a function of system pressure & volume flow
• Monitoring parameters: Pressure, fluid temperature & quantity
• Flight deck indicator for hydraulic pressure: Transducer connected to an indirect indicator
• Max power output & low mass: Achieved by having high pressure system & low volume flow
• Hydraulic circuits:
- Open centre: Has capabilities for idle flow
• Hydraulic braking system:
- Uses nitrogen
• Valves:
- Shuttle valves: (Switches between 2 sources of pressure)
• Switch hydraulically operated units to the most appropriate pressure supply
• Enables an alternate supply to an actuator
- Selector valve: Direct system pressure to either side of the piston of an actuator
- Check/non return valve: Works the same as an electronic diode allowing fluid to flow in one direction only
- Pressure relieve valves: Protects against excessive system pressure
- Cut-out valve: Used in a fixed volume pressure control hydraulic system
- High pressure relief valve: Failure of normal method of system pressure limiting control
- Relief valve: Makes sure the pressure does not exceed permitted pressure in the system
• Actuator/jack:
- Converts hydraulic pressure into linear motion
- Hydraulic lock is when no movement of piston takes place
- Single actuator: Is powered in one direction only by hydraulic power, the return movement being another force
• Pumps
- Variable displacement vs. constant pump: Variable adjusts the fluid pumped to the fluid required, moves fluid only
when necessary
- Separate pressure regulator: Used in hydraulic system in conjunction with constant delivery type pump
- Hand pumps: Connected to the bottom of the reservoir
- Axial piston pumps: Produces high pressure when required but can be off loaded to reduce power consumption
- Over heat detectors: Installed at the pumps
- Low pressure alert: Located at pump outlet, indicates insufficient pump output
- Pump failure: Quill drive will shear to offload & protect gearbox
• Filters:
- In both pressure & return lines
- Pop-out indicators: Warn of impending clogging/by-pass
• Reservoir:
- When powering up, fluid in reservoir will decrease slightly
- Discounting leaks, it fluctuates with jack displacement & accumulator pressure
- Pressurized to prevent cavitation in the pump inlet to the EDP, using bleed air
- Pressurized to ensure inlet is provided with continuous supply of fluid free from foaming
- Hydraulic fluid temperature is measured here
• Accumulator:
- Store fluid under pressure (energy storage)
- Provide a limited alternate supply of pressure in an emergency
- Dampen out fluid pressure fluctuations/variations
- Allow for thermal expansion
- Cater for small internal leaks
- Hydraulic fluid found in gas container = an internal leak in accumulator
• Hydraulic fluid properties:
- Thermal stability
- Low emulsifying characteristic
- Anti-corrosive
- High flash point
- Irritating to eyes & skin
- Incompressible
- Ideally low viscosity to minimise power consumption and resistance to flow
• Internal leaks will cause fluid temperature increase (As the pistons/accumulators have to work more, becomes hotter)
• The security of the hydraulic system comprises:
- Filters
- Pressure Relief Valves
- By-pass valves
- Fire Shut-off valves
- Hydraulic fuse: Prevent total system loss in the event of hydraulic leak/rupture

The benefits of buying summaries with Stuvia:

Guaranteed quality through customer reviews

Guaranteed quality through customer reviews

Stuvia customers have reviewed more than 700,000 summaries. This how you know that you are buying the best documents.

Quick and easy check-out

Quick and easy check-out

You can quickly pay through credit card or Stuvia-credit for the summaries. There is no membership needed.

Focus on what matters

Focus on what matters

Your fellow students write the study notes themselves, which is why the documents are always reliable and up-to-date. This ensures you quickly get to the core!

Frequently asked questions

What do I get when I buy this document?

You get a PDF, available immediately after your purchase. The purchased document is accessible anytime, anywhere and indefinitely through your profile.

Satisfaction guarantee: how does it work?

Our satisfaction guarantee ensures that you always find a study document that suits you well. You fill out a form, and our customer service team takes care of the rest.

Who am I buying these notes from?

Stuvia is a marketplace, so you are not buying this document from us, but from seller AsimEres. Stuvia facilitates payment to the seller.

Will I be stuck with a subscription?

No, you only buy these notes for $16.80. You're not tied to anything after your purchase.

Can Stuvia be trusted?

4.6 stars on Google & Trustpilot (+1000 reviews)

78252 documents were sold in the last 30 days

Founded in 2010, the go-to place to buy study notes for 14 years now

Start selling

Recently viewed by you


$16.80  2x  sold
  • (0)
  Add to cart