Carbon Fiber Guitar Body - Made at Techshop

In this instructable I will show you how I made the body for my carbon fiber acoustic guitar, part of a workshop at Techshop. It was made laying layers of carbon fiber and fiberglass over a cardboard mold, then hardening the fibers with marine grade epoxy. The mold was modeled after a 1940 Gibson L-00

This is definitely an unconventional technique, but there are several examples of carbon fiber guitar makers - one company close to me is SF based Blackbird Guitars. They use carbon fiber to form the entire instrument; body, top, neck, fingerboard, etc... Mine definitely isn't as polished and professional as theirs, but it was a great challenge that introduced me to a lot of new materials and methods. I'd like to share the new skills I learned along the way with anyone who's interested. Considering this was my first time making an instrument of any kind, and my first time working with carbon fiber, I'm very happy with how everything turned out.

One note before I start, though - there is probably a lot of room for improvement in this process. The workshop was designed with complete beginners in mine, and therefore ignored advanced techniques such as vacuum bagging in favor of simple, intuitive methods. The whole body was laid up and finished with brush and gloved hands. For a very different approach using vacuum bags (which I hope to try in the future) see this other instructable - A Carbon Fiber Violin.

It's really hard for me to estimate the time and money that went into making this, because I was working on so many project at once I wasn't keeping track very well, but I estimate it took me a bit over 1 week, working nights ,to finish the body alone. I'll break down costs later when I list the materials.

I worked on the entire guitar project most nights for several weeks - making and assembling the mold was done in one night. Making the body took another 3-4 nights - it probably could be done in 1-2 nights, but I had trouble with one coat of my epoxy drying - explained later. After taking a break to work on the other guitar components, final shaping, finishing and installing the other components took another 3-4 nights.

Here is my first attempt at a 3D 'catch' model of my guitar. Click the 3D view button on the left to activate the viewer.

Carbon fiber isn't going to replace wood body guitars anytime soon, but for those who want something different there are some definite advantages to using carbon fiber. As I understand them, the main reasons to use carbon fiber over wood construction (besides looks) are acoustics, durability, and ease of construction.

Acoustics

Durability

Ease of construction

Design software used

•    Autodesk Inventor - used to design the 3D model of the guitar, based on printed plans
• 123D Make (Free!) - converts 3D model into cardboard (or other) mold
•    Adobe Illustrator - Used to laser cut the mold files generated from 123D Make

Tools used

• Epilog 60 watt laser - used to cut the cardboard mold pieces
• Vise - used to hold the guitar mold steady during layup
• Disposable containers and brushes - epoxy will infuse anything it touches. I think there are solvents for cleaning tools, but for beginners or for one-off projects it's best to get cheap dollar store tools to apply the epoxy.
• Gloves - I used disposable latex gloves to spare my fingers
• Dust mask or respirator - Carbon fiber and epoxy make some nasty dust. Use a dust mask or respirator when cutting or sanding.
• Disposable scissors - used for cutting the "wet" carbon fiber and fiberglass during layup
• Hacksaw - used for cutting off small parts of the dried and hardened carbon fiber
• Cutoff wheel or dremel - used for cutting off larger pieces of the dried and hardened carbon fiber
• Sanding block - used to keep sandpaper level on flat areas
• Rag or polishing pad - Used for final buffing of the body after sanding

Materials used

• Cardboard - Used to make the positive mold for the guitar body
• Carbon fiber - I used plain weave, because it was cheap and available locally for a decent price, but there are other styles of carbon fiber that might be better
• S-Glass - Not necessary, but it's a much cheaper filler used between layers of carbon fiber
• Coremat foam - A highly absorbant foam sheet, cut into strips for reinforcing the inside edges and neck of the guitar.
• Epoxy - TAP Plastics Marine Grade premium 314 resin & 109 hardener. Long open time, low odor, few bubbles.
• Black pigment - Designed for tinting plastic resins, bought from TAP Plastics
• Plastic wrap - Used as a mold release, separating the cardboard from the epoxy. Better commercial products can be found, but this was cheap and worked well for cardboard molds
• Auto putty "Bondo" - for smoothing sharp curves on the positive guitar mold
• Painters tape - Used to protect components during assembly, and also used to mark cuts clearly
• Scrap wood - Not part of the body, but used to lift and mount the mold for the guitar during layup
• Waterproof sandpaper - 180, 220, 320 400, 600 and 1000 grit. Also used 80 grit dry sandpaper sparingly
• Turtle Wax auto polishing compound - used to polish the body after sanding

Material costs

•    Carbon fiber (2 yards): $90
•    S-Glass (1 yard): $17
•    Coremat (1/2 yard): $5
•    TAP 314 Marine grade epoxy resin, 1 qt: $26
•    TAP 109 Marine grade epoxy hardener, 8oz: $16
•    5 minute epoxy (2 tubes): $6
•    Sandpaper, various grits: ~$10-15
•    Disposable materials: Gloves, scissors, brushes: ~$10-20
• Total materials for body: ~$180-$200

Notes on materials

• Carbon fiber weave - I used "plain weave" carbon fiber, because it was available locally for a decent price. But this is the worst choice for doing 3D objects like a guitar - I would have been better off choosing "twill weave" or "Harness-Satin" weave, which flow better over complex curves, without tenting or folding.
• Epoxy - I was very happy with my choice of epoxy, but it is one of the more expensive options. To save some money, one could use a cheaper epoxy, or even use polyester resin. But beware that polyester resin has a MUCH stronger odor than epoxy - the instructors said that anyone using polyester resin would have to use it outside.
• Mold materials - the cardboard was cheap, and it was fun and easy to assemble the mold using 123D Make - but sometimes it was awkward to work around the sharp angles between layers - for example I had to use auto-body putty to make the curve between body and neck flow smoothly. Some alternatives that come to mind are lightweight wood, expanded foam, clay and plaster.
  • For those without access to a laser cutter or CNC machine, foam and certain woods also have the advantage that they can be carved by hand or hot wire cutter into precise shapes much easier than cardboard.
•  More durable materials would also be a better choice for those wishing to reuse the mold. My mold actually came out okay, but others' molds were damaged or destroyed during extraction.

The 3D models were provided for me by the instructors, so I can't comment on the process of making them. If I ever pursue this type of modeling further, I may update this step. I've included the 3D model and original plans that this guitar was based on - it was modeled after a 1940 Gibson L-00. The sides of the guitar were rounded like an Ovation style guitar, because carbon fiber doesn't bend well around sharp corners.

I chose to use the stock design provided by the instructors, but others in the workshop chose to customize their instruments - adding cutouts, changing the size and scale of the body, etc... One of the advantages of working with carbon fiber is the ability to make shapes that would be difficult to achieve with wood.

Making a mold

1. Open 123D Make. Use the button on the lefthand side to import a 3D model, open the Guitar.stl file
2. Now the model should be displayed in the center of the window. On the left there should now be an option for "construction techniques." Select "stacked slices," this will create layers of vertically stacked slices, which is perfect for our cardboard construction
3. Next, you need to set the dimensions for the object being made, and the material it's being made from. The program automatically sliced the model into 0.177" slices, which created 56 parts spread over 23 sheets of cardboard.
   • My model size was ~935mm (36in) long X 358mm (14 in) wide X 111mm (4.37 in)
   • My material size was 24 in long X 18 in wide X 0.177 in thick pieces of cardboard
4. Inspect the model and sheets for any errors. If everything looks fine, go to the bottom of the lefthand menu and select "get plans."
5. Select the desired format at the bottom of the window. Exporting .EPS files will allow the sheets to be opened in Illustrator or CorelDraw, where they can be sent to the laser cutter.

The process

1. Print the mold files in order using settings appropriate for cardboard (I used 70% power, 90% speed, 500 hz frequency on the epilog 60 watt laser).
2. Each part should have numbers showing how to assemble them. I suggest dry-fitting the parts together to make sure they are all present and printed correctly.
3. Now assemble the parts with a little glue between each layer.
4. I chose not to clamp my mold parts together, because I didn't want to risk shifting the pieces, and they seemed to hold well on their own. Others clamped their molds, which worked as well - do whatever feels right. Clamping probably helps keep the mold a little more compact.

Before laying up the carbon, we have to do a little prep work to the mold.

Soften edges

Make a handle

Mold-release

1. Neatly arrange EVERYTHING before starting. Once you mix the epoxy together, things will start to get very messy very fast. And every pot of epoxy  has a hard time limit before it hardens - mine had a 20-30 minute pot life. If you are familiar with cooking, think of a "mise en place" style work space.
   • Protect the workspace by laying down some more plastic wrap or tarps over the floor, table and vise 
2. Cut the sheets of carbon fiber and S-glass to size by laying them over the mold, cut them just a little longer and a little wider than the mold (I had ~1/2" on each side). You don't want too much material, because the extra weight will cause it to drape in funny ways.
3. Save one special layer of carbon and set it aside. The first few layers can be as messy as you please, but the final layer will be your show-layer. You want it to look as nice as possible, without any warping for fraying.
4. Once the materials and tools are ready, mix up the epoxy. Carefully follow the mixing instructions of whatever epoxy you are using. In my case, it said to mix 4 parts resin to 1 part hardener.
   • I started mixing it by eye in a measuring cup - 8 ounces resin, then pouring in 2 more ounces hardener for 10 ounces of epoxy. This worked okay, but it's not the best method. A better way is to use a scale to measure out be weight. I always weighed later mixtures.
   • Epoxy likes it warm - so be aware of the work room temperature. This workshop was held during a cold-spell and it took several hours longer for the resin to dry than it should have. The epoxy instructions should include a minimum recommended temperature.
5. Lay the first layer of carbon over the mold, then load up your brush and start spreading epoxy around the surface. Once the epoxy hits the fiber, it will instantly start to hug the curves of the mold. The large curves are easy, but once you get into tight areas it can get tricky -
   • Tight corners like around the neck will make the carbon fiber tent and pull away from the mold. If you are using plain weave fiber like me, you can't win this fight. Instead, cut some relief slits down the middle of the area that is pulling away,then over-lap the two sides of the fiber. Don't worry about how this looks, since this is only the first layer.
   • You want all the carbon fiber to be thoroughly coated with epoxy, no dry spots or bubbles. It can be hard to tell with pure black carbon fiber, but just examine each section carefully and look for differences between wet and dry spots.
6. Put down a layer of S-glass in exactly the same way. It's easier to tell when fiberglass is fully epoxied, because it becomes transparent when wet. If the S-glass also tents or pulls away in tight curves, cut relief slits just like with the carbon. If necessary, cut some extra scraps of S-glass or carbon and bulk up the sharp corner to soften the curve.
7. Finally, lay another layer of carbon down. By now the sharp corners should be softened, so try to lay these lay these layers down without cutting relief slits.
8. When it's time to lay your show-layer down, be as careful as you can not to pull or tug the carbon out of place. Everything you do now will show on the surface.

Overall layup tips

• I mixed one batch of epoxy per layer of carbon fiber / S-glass - this ensured I was always working with fresh, easy flowing epoxy and it gave me time to relax and get the details right.
• Use your brush to apply the epoxy, but don't be shy about using your (gloved) hands. Tug, push, smooth and reshape the fiber by hand, especially on the under-layers.
• Try to get the final layer of epoxy looking nice, but don't over-think it. The final step in my whole guitar building process was to go back and sand the body smooth before applying one more gloss-coat of epoxy.

There will be a lot of excess carbon and epoxy fringe handing off the bottom of the mold. Be VERY careful when removing this fringe - the little spikes can be as sharp as knives, and make some pretty nasty splinters when broken. I suggest using gloves, and definitely use a dust-mask, or better yet a respirator.

Cut away all the extra material to just above the cardboard mold. Some people used an angle grinder or dremel tool, but I preferred to take it slow and use a hacksaw. When hacksawing I tried to saw off large sections at once, giving the saw a lot of material to bit into, instead of sawing each small part, which caused the saw to flex.

After the extra material is cut away, you can either tear up the mold from the inside out, or try to pop it out in one whole piece. To pop the mold out, it really helps to have a second set of hands. One person can hold the guitar body steady while the other tugs on the mold. Carbon fiber is very tough, so don't worry about pulling on it - but don't go crazy either, it is possible to snap thinner parts right off.

Once free from the mold, examine your handi-work - the hardest part is now over, the rest is just details.

The role of the guitar body is to be solid and steady, without too much flexing - any energy spent bending the guitar body is energy taken away from the sound of the instrument. I went around the instrument and looked for any areas that were flexing too much.

Most of my body was very solid - but the edges flexed just a little bit, especially at the "hips" around the center of the guitar. Also, some parts of the neck were a little less stiff than I wanted. The neck in particular must be very strong, to withstand more than 100 lbs of pull from all the the strings.  A traditional guitar has a "truss rod" - a strong threaded rod that can adjust the neck stiffness. It's probably possible to make an adjustable truss rod for this style of guitar, but we chose to just make a very stiff neck, reinforced with coremat.

Coremat is a super-absorbant foam that sucks up lots of epoxy, making it very hard and stiff once it dries. I put a layer of coremat all along the edges of the guitar and down the center from the neck. The coremat by itself does not stick well to the carbon fiber - so I put a strip of S-glass under the coremat to help secure it. This application of the coremat also has a secondary benefit, which I'll discuss in the next step.

It's not pretty, but nobody will see these parts anyway.

The coremat

Flattening the body

Make space for the soundboard

1. Measure the thickness of the soundboard precisely (mine was 2.6mm thick)
2. Using painters tape (or other contrasting material) mark off a line down from the top edge of the guitar body. The goal is to make a lower lip where the soundboard can sit, allowing the strings to run straight off the fretboard to the bridge.
3. Use a Dremel or angle grinder to cut to the line of the painters tape. I wasn't confident with this part, so I got the instructor to cut my lip for me.
   • Instead of measuring, you can also put your soundboard next to the body (turned upside down) and draw a line directly onto the body using the thickness of the board as a reference.
4. See the last picture. This is the goal - a nice pocket where the soundboard can sit.

The soundboard

• Spread 5 minute epoxy around the perimeter of the guitar, using the lip created by the coremat reinforcement.
• Press the soundboard flat against the body, making sure it is centered.
• Make sure the bracing on the back of the soundboard is not touching the sides of the body
• Since the body doesn't have a flat back to clamp against, I turned the guitar upside down and placed a heavy lead weight on top.

The headstock

• I cut the headstock portion of the carbon fiber to fit my wooden headstock using a dremel cutoff tool.
• I spread 5 minute epoxy onto the coremat inside the headstock and neck
• I fit a ~2" inch piece of the headstock wood inside the neck
• I test fit the fretboard, to see if the end of the headstock was sticking out above the neck.
• There was a little piece sticking out - I sanded it down with 80 grit sandpaper until the fretboard rested flat

The fretboard

• I cut the fretboard to fit the neck and circle around my sound hole.
• I spread 5 minute epoxy over the coremat inside the neck then installed the fretboard
• I firmly clamped the fretboard, with F-clample placed every couple inches. I also used a long-reaching C-clamp inside the sound hole to clamp the bottom of the fretboard.

The bridge

• Mix up a little epoxy (5 minute or slow cure, as you prefer)
• Add some black pigment to match the carbon fiber
• Use a toothpick or other fine tool to poke the epoxy into the holes

Protect wood components

Level sanding

Wet sanding

• Using waterproof sandpaper, I started with 180 grit, then moved up through 220, 320 and 400 grit papers
• The surface always looks PERFECT when wet (very deceptive). So between grits I wiped away the muddy dust with a damp rag and let it dry a minute.
• Once dry, I wiped away any remaining dust with a tack cloth and looked at the surface. I was looking for the scratch pattern - a uniform grey with evenly spaced and sized scratch marks.
  • Larger, deeper scratches remaining after a thorough sanding, they are left over from a lower grit of sandpaper. You may have to drop down to a lower grit to remove these before continuing
  • Shiny spots are areas that have not been sanded. You want to sand everything evenly before moving to higher grits.

Continue wet sanding

Polishing