Formula 1000 rules require a chain guard equivalent to 1/4″ aluminum to contain the chain in case of a break. I had the blank laser cut, then bent it on my tubing bender. After bending, it was sliced in two parts for easier access to the chain and rear sprocket, drilled and tapped for an overlapping tab, cross-drilled for mounting holes, and installed.
I decided there was too much play between the axle halfshafts and the differential extensions, so I made collars with the precise inner diameter and length necessary to remove all play. I was pleased that I could make them so precisely, even on my old beat-up lathe, that they made an almost airtight seal. I’m showing many of the steps below as a reminder of just how many operations go into making even the simplest-looking parts.
Completing the car is now just one long series of small projects. Three are shown here.
The original chain tensioner design was not able to take up enough slack in the chain. The chain was either too short or too long, no matter how many links I used or where I put the adjustment. I had to come up with a new design with two idler sprockets instead of one, as you can see in this post. The bearings are special ceramic hybrids to handle the extreme chain speeds seen with a GSX-R1000 engine.
I’ve had a rear sprocket on the car for some time, but that was just for fitting. The lightening holes on that sprocket conflicted with the mounting holes required by the differential, so it wouldn’t have been strong enough. Instead, I ordered a blank sprocket from England and machined the correct mounting holes and center hole, then cut it in half on the bandsaw so that it could be mounted or changed without disassembling the whole rear axle and suspension.
I also built an adapter to go from the auto shift linkage to the transmission gear change lever. I bought a Suzuki GSX-R shift link rod from Ebay, cut off the front, and welded it to a threaded rod. The rod threads into a bushing I made that fits inside the eye of the shift linkage. The sleeve of the shift cable must be held securely, so you can see here the bracket that mounts it to the frame rails.
I was lucky enough to find some 7075-T651 aircraft aluminum plate, still with the Martin Marietta markings on it. Very useful for miscellaneous parts like this ECU mount. That stuff is strong! Almost as hard to bend as steel, but it makes for a very stiff end result. So I just cut this blank out of the aluminum plate, bent it in my hydraulic press, and added lightness using the milling machine. It mounts to the frame with aluminum clamshell mounts purchased on Ebay.
Yet another video update. Here you’ll get a tour around the car pointing out the newest additions, followed by fabricating the fuel swirl pot and mount, the first power-up of the electrical system, mounting components on the instrument panel, drilling the firewall for fuel lines, fabricating braided stainless steel fuel lines, building and installing the throttle pedal cable pull rod and the cable itself, building the ECU mounting platform, and machining the rear sprocket to fit the differential.
Here’s a big project that spread out over a number of months. I’m aggregated the photos here and attempted to make them tell a coherent story.
The cluster as a whole can be adjusted forward and back for drivers of different heights. The gas pedal is adjustable for foot travel, throttle cable travel and left/right position. The brake pedal height is independently adjustable, and brake bias is adjustable from front to back. The hydraulic clutch pedal is also independently adjustable for height.
Many of the original pieces were laser cut from steel, then bent and welded to form the complex shapes required. Some of the bushings were CNC turned, but most were made by hand. The master cylinders, brake bias adjustment cable, and the nuts and bolts were purchased, with everything else custom made. This includes the brake bias adjustment assembly, which forced me to learn how to cut threads on the lathe. It’s not as easy as it looks. Take a look at the brake bias adjustment bar– it has three sets of threads independently cut on a manual lathe, three diameters, two snap rings and a threaded hole. Good fun! Due to changes in the steering rack mount, the main pedal bracket had to be widened as you can see in the photos.
Not much to say about this one… Just lots more piddly little brackets. The large bracket at the tail is necessary as that will be where the rear impact absorber will mount. Had to make some changes just behind the driver’s left shoulder to allow access to the fuel filler.
While the sides of the cockpit already have side-intrusion panels on the outside, they will also have a second panel on the inside to prevent the seat foam from extruding between the frame tubes and pushing on the outside panels, something those outside panels aren’t equipped to properly resist. The interior panels also must follow the SCCA rule against stressed skins that requires chassis attachment points to be more than 6 inches apart. Due to their different shape and size, the interior panels have a completely different mounting pattern and can’t share any of the exterior panel mount points. Thus, many more tabs are cut and welded on.
The seat back is formed by the fuel tank and three additional pieces of aluminum, shaped at the sides to provide shoulder support on the front while providing space and access at the back to the fuel pump on one side and the fuel filler on the other. The center section is removable to access the shoulder harness mounting points.
SCCA Formula 1000 rules require side-impact protection consisting of either kevlar laminated to the inside of the body, or 0.060″ aluminum or 18-gauge steel bolted to the frame. To keep the side impact panels from being used as a stressed member, attachment points to the frame must be more than 6″ apart. Mine are laser cut from 1.6 mm aluminum. The mounting holes were also cut by the laser to be sure of the 6″ rule, but this was a mistake as it made the mounting tabs much harder to fabricate. It would have been much easier to weld the tabs in place with holes already drilled, then drill through the tabs to the aluminum panels for exactly aligned holes. As you can see from one of the photos below, the panels fit perfectly. This project was a lot of cutting and welding with little apparent progress.