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Procedure :Overview

Below is the detailed procedure for how the first flight candidate fin can was manufactured. A phenolic tube (insulation from motor case) was overwrapped with 3 layers of carbon fiber (structural support). After the fins were manufactued (see "Hermes 2 Fin Design"), they were attached to the tube and 6 plies of increasing size were added to each of the 4 sides of the fin can in the tip-to-tip layup. After vacuum-bagging and room temperature curing for 24 hours, the fin can was oven-cured. Post-processing (sanding, painting, etc.) was not done because we wanted to manufacture a second flight candidate fin can to make some improvements, namely concerning the misalignment between the phenolic leading edge and the tip-to-tip plies.

1. Tube Tube Preparation

Sanded inside of tube by hand with 60-grit sandpaper, went over with 220-grit (this took a long time so for next time ordered a flapper wheel, 60-grit)

Tube layup: 3 layers of carbon fiber (cut piece slightly longer than necessary for some wiggle room), did not oven cure because of time constraints and whole thing oven cured in the end. 

 Image Removed

-Used Systems 3000 epoxy but didn't oven cure after layup

Image Added

2. Root Bond and Root Fillet

Did root bond

 

using 5-minute. fin can jig needs to be improved

AFTER root bond, attached phenolic LE to G10 fin core (did after root bond because phenolic wouldn't have fit in the fin can jig)

Root fillet (West Systems fast hardener + colloidal silica)

3. Carbon Fiber Cut-outs for Tip-to-tip Layup

The carbon fiber cutouts are the pieces of carbon fiber used in the tip-to-tip layup, which consists of laying plies from the tip of one fin, over the tube in between them, over the tip of the next fin (and repeating for the other three sides). 

Quentin designed CF cutouts (6 sizes --> small to large)

Lasercut CF cutout - went well but largest cutout size did not fit in the laser cutter

 

4. Preparation of Vacuum Bagging Materials

Prepared vacuum bagging materials

5. Tip-to-tip Layup

Mark centerlines on tube and CF cutouts

...

Layer SizeDry mass of one layer
1 (smallest cutout size)20g
222g
323g
426g
533g
6 (largest)39g
Total mass of all cutouts (6 sizes x 4)652g


6. Vacuum Bagging

Vacuum bag was 32 x 38" (this is TOO BIG, make smaller next time. For the test fin can though the bagging was too SMALL, so find a good middle ground)

7. Oven Cure (ATTACH SOP)

Positioned fin can horizontally as shown, because there wasn't enough vertical space in the oven we used. This may have caused the fins to splay (weight of the tube + epoxy loosening --> fins move), so in the future we should position it vertically.

8. Post-processing

Vacuum bagging materials were difficult to remove, but not impossible

...