1 / 23

…background

…background. ECS cabin air distribution design for multi-mission aircraft Air pattern definition is a key factor for ECS design goals Passengers aircraft and cargo aircraft design objectives usually different (comfort for passengers and prompt smoke detection for cargo configuration)

verity
Download Presentation

…background

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. …background • ECS cabin air distribution design for multi-mission aircraft • Air pattern definition is a key factor for ECS design goals • Passengers aircraft and cargo aircraft design objectives usually different (comfort for passengers and prompt smoke detection for cargo configuration) • CFD approach • Tool complexity balanced by powerful investigation capabilities • Technical risks reduction and shorten development phase

  2. Presentation Summary • ECS Cabin Air Distribution Model • Model Creation • Model Development • CFD analysis and improvements identification • Optimization process through iterative loop • CAD-CFD FEM interaction • Model Validation • Design evolution • Full scale aircraft fuselage compartment ground smoke tests campaign • Test results and conclusions

  3. Model Creation and Development • ECS cabin air distribution optimization for passengers comfort and smoke detection • 3D model analyzed by a finite elements method CFD code • Domain extension and computational workload taken into account: • Only a fuselage half section represented • Entire extension obtained through cyclic and symmetrical boundary conditions Symmetric Boundary Condition Cyclic Boundary Condition

  4. First Solution for Cabin Air Distribution - Outlet Inlet Boundary Condition Pressure Boundary Condition Honeycomb Slice Detail

  5. First Solution for Cabin Air Distribution - Outlet cont’d

  6. Symmetric Boundary Condition Inlet Boundary Condition Cyclic Boundary Condition Pressure Boundary Condition First Solution for Cabin Air Distribution - Flow Pattern Analysis Cruise at 5000 ft cabin altitude ECS in heating and cooling operations

  7. First Solution for Cabin Air Distribution - Flow Pattern Results Heating Operation (Tf = 167°F, OAT=-67°F) Section at the ECS Outlet

  8. First Solution for Cabin Air Distribution - Flow Pattern Results cont’d Heating Operation (Tf = 167°F, OAT=-67°F) Middle Section between two ECS Outlets

  9. First Solution Analysis Results Shortfalls identified • High air velocity in the cabin and flow pattern jeopardizing smoke detection • Passengers comfort penalties Corrective action • New design of the ECS outlet, changing the orientation on the surface fuselage

  10. Final Solution for Cabin Air Distribution - Outlet Inlet Boundary Condition Pressure Boundary Condition Honeycomb Slice Detail

  11. Final Solution for Cabin Air Distribution - Outlet cont’d

  12. Final Solution for Cabin Air Distribution - Flow Pattern Results Heating Operation (Tf = 167°F, OAT=-67°F) Section at the ECS Outlet

  13. Final Solution for Cabin Air Distribution - Flow Pattern Results cont’d Heating Operation (Tf = 167°F, OAT=-67°F) Middle Section between two ECS Outlets

  14. Analysis Results and Design Progress • Air distribution and temperature uniformity with low air velocity in the cabin leading to passenger comfort and smoke detection benefits • the flow pattern in the cabin helps the smoke to rise up to the fuselage ceiling where the smoke detectors are installed • Most suitable zone for the smoke detectors installation identified • the section between two ECS outlets • on the ceiling just after the wall • Analysis results application • CFD Model Validation • Solution embodied into design

  15. x Diffuser ECS Outlet Exit z C ‘ 1.23 in” B’ A’ MID C 23 in” B A 4.92” O y CFD Model Validation Test CFD model validated by test laboratories Measurement, through an anemometer, of the air velocity in different points along two different stations Dedicated CFD model created to simulate the test condition and measurement pattern ECS Outlet Exit Measurement Grid

  16. Numerical and Experimental Results Comparison

  17. Ground Smoke Tests Ground smoke tests campaign Compartment full scale mock-up with draw-thru smoke detectors and approved smoke generator ECS outlets and outlets grids detail level reproduced 11 test points along the compartment Different flow conditions in normal operation and failure cases Test Rig Scheme Test Rig Detail Level

  18. Ground Smoke Tests Results Cargo Main Deck - Normal Operation - 25 SCFM - Left Side

  19. Ground Smoke Tests Results Cargo Main Deck - Normal Operation - 32.5 SCFM - Central Zone

  20. Ground Smoke Tests Results Cargo Main Deck - Failure Case - 25 SCFM - Right Side

  21. Conclusions CFD analysis benefits along the design process • Flow pattern simulation compliant with the test results in all the normal operation and failure conditions • Correct identification of the most suitable zone for smoke detectors installation • Flexible investigation on wide spectrum of solutions • Reduction of the smoke detection time • Reduction of the technical risk associated to the development and certification tests

More Related