Building the Body Buck: Part 2, Putty, Prime, Repeat

Posted by jjludemann on February 18, 2013

After the first coat of ultra-hard Sikafloor epoxy

Here’s where the heavy lifting begins. Many, many passes of plaster or putty, sanding, and primer. The first step was to coat the entire body in plaster, which is best done the messy way: just plunge your hand into the bucket of plaster and smear it on the body buck. Plaster is much better for filling voids than foam is. Especially the insulation foam that comes in a can. Don’t, under any circumstances, use the canned spray foam. It remains flexible permanently, and keeps slowly expanding over a period of weeks or months. If you use it, as I did, to fill voids, you’ll spend days and days digging it out wherever it reaches the surface, refilling the holes with auto body filler.

I discovered that spackling compound, made for smoothing house walls before painting, works great after the plaster. Plaster has a short working time, and you end up mixing lots of little batches when you’re filling ripples. The spackling compound goes on smoothly, you can work it just about as long as you want, it sands extremely easily, and it sands to a feather edge. I also tried gypsum, but it has the disadvantage of remaining water soluble as it doesn’t cure.

I put on a gallon of Jotun Penguard 2-part enamel filler, then found the only auto-body paint supply shop in town and discovered “sprayable body putty”, so I followed up with a couple of gallons of that, spackling and sanding between coats. About the third coat of sprayable body putty, I noticed that the body buck was swelling badly where it had been in the sun. Uh-oh. It turns out the foam expands and contracts with temperature. After that I kept the car only in the garage, never letting sun touch it. It took 2-3 weeks to fix that mistake, now using auto body filler and a double-action (DA) air-powered sander with 40 grit sandpaper, a great combination for this work.

So when I finally got that mess cleared up, I wasn’t too keen on spraying another coat of primer and potentially distorting the surface again. Instead, I went straight to an extra-hard epoxy used for floors, called Sikafloor. This is a very unusual paint as it’s intended to be used only on horizontal surfaces, where it remains liquid for a long time as it flows to become perfectly flat. I sprayed it on, almost unthinned, an “off label use”, but it worked great for my purposes.

Building the Body Buck: Part 1, Ribs & Foam

Posted by jjludemann on January 23, 2013

Here’s what we’re building, sort of. Rather than build a CAD model of an actual assembly of stringer and rib parts, I extruded cuts into the solid model so that the slots will appear in the correct places when I make cross-section drawings at the appropriate locations. This is actually harder to visualize than you might think. I wasn’t sure it would go together flawlessly, especially since the cuts in both the ribs and stringers went to two different depths depending on the typical height of each region. I didn’t want long floppy sticking up from the cuts:

Original 3D CAD model showing slots for assembling plywood ribs and stringers.

: Longitudinal stringer drawings printed on A0 paper and pieced together

: First we need a table to build it on…

: All cross sections cut from 3mm plywood and assembled on the table. THANKS DAVE!

: Starting the process of filling in the voids, using wadded newspaper topped with two-part foam

: Foam filling continues…

: Cut to shape with hacksaw blade, belt sander, and sandpaper

: And continues…

: And continues…

: etc.

: Filling and trimming as I go.

: Many applications left voids, which I attempted to fill with more foam.

: Using whatever is convenient to constrain the foam. Here, bungee cords hold old pillows.

: And continues…

: This foam was difficult to work with. No reaction for 30 sec., then hard in 20 more sec.

: Foaming is finished.

: Filling some voids.

: Trimming almost finished.

: Just the driver’s head fairing left to trim.

Fabricating the Suspension Attachment Points

Posted by jjludemann on January 12, 2013

: Aluminum and steel parts back from the laser cutting shop

: Upper front before welding

: Upper front after welding

: Set of four completed

: Upper rears

: Set of eight completed

: Rear toe rod attachment point before assembly

: Rear toe rod attachment point assembled and clamped for welding

: Rear toe rod attachment point after welding

Hot Off the (3D) Press: Suspension Upright 3-D Print

Posted by jjludemann on July 30, 2012

The suspension uprights have gone through a long evolution, but I’m zeroing in on the goal.

First Design: Machined Billet Aluminum

This design uses radial-style brake caliper mounting. Needed to be redesigned when someone ordered the lug-mount calipers and had them delivered all the way from the USA. Probably a Freudian slip as they’re less expensive.

Second Design: Fabricated Steel

Second design was fabricated from steel. Unfortunately, welding will eliminate the temper in the heat-affected zones. The weakening due to this is hard to predict, and can only be eliminated by heat treatment. That would mean days or weeks finding and learning to deal with a heat-treatment supplier.

Mesh used for finite-element analysis of fabricated steel upright.

Finite-element analysis stress plot for fabricated upright. Strong enough, but where are those heat-affected zones?

Third Design: Cast Aluminum

Here’s the final result of literally hundreds of design revisions, ensuring that the upright is strong enough and as light as possible. This design is made possible by the new technology of 3d printing, which will be used to make the master “plug”, from which molds will be made to cast the actual part. Note that the steering arm is not an integral part of the upright, but is modeled together with the upright because the FEA runs much faster this way.

FEA mesh plot for cast upright

FEA stress plot inner

View from outside

Finally, the Master Copy

The upright had to be split into four pieces for 3D printing; split vertically so I can make two mold halves and remove the masters from the molds, and split horizontally to fit the 3D printer. The 3D printer extrudes hot ABS plastic in X-Y layers onto a heated Z-axis stage with 0.3mm resolution. The print is slightly rough and the parting plane is slightly warped, which will have to be corrected with auto body putty, primer, sanding, and paint. The cast aluminum blank will still require several machining steps to cut off the gate and sprue, drill mounting holes, bore the bearing hole and retaining ring slot, and mill the brake caliper mounts. Still far better than trying to machine individual parts (or even a mold pattern) this complex, which would be approximately impossible and semi-infinitely expensive.

One half printed in two colors to highlight the split required to fit it into the 3d printer

Full set of four 3d prints. The cylinder protruding in the upper left is the gate, where molten aluminum will be poured into the finished mold.

Some people get excited by shoe sales. I get excited by this!

Fabricating the Lower A-arms

Posted by jjludemann on June 16, 2012

No, I haven’t just been sitting around the house eating chocolate, but a major malfunction in my main computer leaves me time to update the blog and get caught up on other things I should have done, like taxes. Unlike EVERY OTHER COUNTRY IN THE WORLD (except the Phillipines), even though I haven’t set foot in the USA in over four years, I still have to pay US taxes. The bright side is that California no longer considers me a resident so I don’t have to pay California taxes anymore, which is quite reasonable given that I moved out 11 years ago.

I made the mistake of turning the computer off overnight to help save the planet and all, and the next day it kept dying like someone pulled the plug. Computer shop says I need a new motherboard and graphics card, and oh, by the way, there are no new LGA 1366 motherboards for Intel i7 CPUs in Thailand and the old one will take about a month to fix under warranty. Which is understandable, given that Intel stopped making LGA 1366 i7 CPUs ages ago! Oh wait, they still make them? Or maybe not, from Intel’s website I can’t tell. At least Gigabyte’s warranty will cover their product, or maybe I just haven’t heard what their fine-print objection will be, yet. Azus, on the other hand, says my graphics card is corroded, and corrosion isn’t covered under warranty. Great plan! Make a product that corrodes, then say corrosion isn’t covered. It might be more honest to say “No Warranty”, though. The Azus graphics card was inside a warm computer (which was _almost_ never power-cycled) in an office environment for it’s entire life. Azus is now on my Deferred Vendor List.

Anyway, on to fabricating the lower A-arms, or control arms:

Repeat everything four times. Final result: four lower A-arms

: Starting with the spherical bearing cups, face and cut outside diameter

: Cutting the internal diameter on a bearing cup. This is a press fit, so it has to be cut as perfectly as the tools will allow.

: My boring bar won’t fit into my new quick-change tool holder, so I had to cut it down to fit.

: Boring bar now fits into tool block.

: Cutting the groove for a snap ring. I wasn’t sure I could get the press fit perfect, so I included provisions for a snap ring

: Snap ring in place for a trial fit.

: Using the cutoff tool to cut the part off the stock

: Bearing cup, spherical bearing, snap ring, and ID gauge for cup. I don’t have an internal micrometer, so used my external micrometer to cut a gauge to the precise length for the ID.

: I ground a carbide cutting tool for the boring bar to the correct width to cut the snap ring groove. It took a lot of grinding. Carbide is really hard!

: Starting the rod end receptacles that will be welded to the legs of the A-arms. Face and cut OD on lathe.

: Cut step to fit inside A-arm tube.

: Use center drill for accuracy.

: Drill hole to be tapped for rod end

: Using cutoff tool to part off

: Tap for 3/8-24 left hand threads. A later version of the A-arms may have easy rod-end adjusters, so I’m using left hand threads here, too.

: Cutting a chamfer on the face of the rod-end receptacle. Looks better, is lighter.

: Four finished rod-end receptacles

: Setup for tack welding rod end receptacle into A-arm tube

: Tack welded in place

: Welded all the way around. Holding the tube in a V block makes it easy to turn while welding

: Made 2 aluminum bushings to fit inside the bearing cup and locate it on the jig

: Rod ends are held in jig for welding.

: A-arm jig is made from printed drawing glued to plywood.

: Spherical bearing cup fully welded to one leg of an A-arm

: Both legs of an A-arm fully welded to a bearing cup

: A-arm bearing cup braces marked and cut

: Bearing cup braces in place and welded

: Pushrod mount in place and welded. These pieces were made with the patented (not patented!) technique of printing on sticker paper, cutting with a plasma cutter, grinding to exact shape.

: Spherical bearing is pressed into place on my home made hydraulic press. Custom bushings were made to only push on the correct places, like not the ball.

: Anti-intrusion bar test fitted

: Anti-intrusion bar fully welded. Weld shrinkage is a problem here.

: Welding distorted the bearing cap enough that I had to recut the bore. First, find the center of the hole.

: Next, use a boring head to cut the hole to exact dimension. Very tricky; had to use 1/2 the smallest tick mark on the boring head. Total overlap for press fit is around 0.001″

: Repeat everything four times. Final result: four lower A-arms

Fabricating Lower Suspension Clevis Spacers & Washers

Posted by jjludemann on May 10, 2012

Need some spacers to keep the clevises from interfering with some of the frame tubes. Also, custom load-spreading washers that my FEA says are important: