Going to Rehab

Well, probably not the kind of rehab that you’re thinking of. In this case a slot car is being rehabilitated.

In the 1950’s and 60’s companies such as Strombecker, Eldon, Marx, Cox and others were manufacturing high quality slot cars for the home enthusiast. These cars were, for the most part, well detailed and the bodies were scale accurate. Their chassis were often made from brass or aluminum and although considered primitive by today’s standard, were truly state of the art for mass-produced, ready-to-run slot cars at the time.

We know that they were high quality because many of them are still around and running on slot car tracks today. And, if in pristine condition and good running order, they can be considered collectible.

Naturally the pristine examples are relatively rare. The majority tend to show the effects of decades of hard racing and/or storage in less than ideal conditions. In most cases the chassis is damaged or just worn out, and replacement parts are virtually non existent. And the body may be missing parts such as the windshield, driver’s head or mirrors. But if the body shell is in reasonably good shape, without breaks, cracks or major deformity, then it is a prime candidate for “rehabilitation”. This involves refinishing, or at least cleaning up the body and building or obtaining a new, more modern chassis.

While perusing the major auction site one day, I was lucky enough to win a Strombecker Ferrari Dino 206 S (pictured below) for a very reasonable price. 

The body was in excellent condition with only a small piece missing from the top of the windshield and some discoloration under the number rondel sticker. The overall surface was good with only minor scratches.

The chassis is typical of Strombecker cars that were included in a boxed racing set. Its condition was among the best I have seen in a home market car from this era. I feel that it probably put this car in the collectable category. However, because my goal was to modernize and not restore, I had no use for the chassis. In fact, I was able to sell the chassis for about the same price that I paid for the entire car.

The rehabilitated Dino 206 S is pictured below.

The body was molded in the typical Ferrari red color. I did not paint the body because the original finish looked quite realistic to me. Scratches and mold release lines were wet-sanded out with 600 grit sandpaper. The entire body was then sanded with a 3000 grit automotive finishing pad. This was followed by a complete rubdown with automotive plastic polish, which was also applied to the windshield.

The driver, interior, wheels, inserts and tail lights were the only items that were painted. The tail lights were re-chromed and then painted with translucent acrylic stoplight red paint.

Decals are for an early 1970’s Ferrari Formula 1 car and were provided by Indycals Decals.

The windshield wiper, roll bar and rear view mirror were scratch built from styrene stock and scrap. The rear grills were fashioned from wire mesh coffee filter screen brushed with acrylic silver paint.

The finished body and windshield were clear coated with Future floor polish.

The chosen chassis is a PCS 32. This is an inexpensive, basic, adjustable wheelbase chassis that has a simple straightforward set up yet performs very well.

Chassis components:

• Motor: BWNC1
• Crown gear: Slot.it 27z
• Pinion: Ninco 9z
• Bushings: Slot.it brass
• Axles: Ninco 3/32
• Guide: ScaleAuto
• Wheels/inserts: BWA
• Tires: Ninco Classics for the A/C Cobra

The PCS 32 chassis is ideal for the typical Strombecker body because the original mounting posts are adaptable to the chassis. Mounting post inserts were fabricated by gluing (plastic epoxy) 1/8” styrene tubing inside 3/16” styrene tubing. The combination tubing is then cut to the approximate length and glued inside the existing mounting posts and sanded down to achieve proper stance and ride height. A hole is then drilled in each of the chassis side boards to accommodate the screws that secure the two rear mounting posts.

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The rehabilitated Dino runs very well and will undoubtedly fit nicely, based on looks and performance, into a racing class such as the Ninco Classics.

I think that it’s great that a 55 plus year old slot car can get a new lease on life and be running around a slot car track, where it belongs, once again. So if this kind of project appeals to you, keep an eye on the Internet auction sites for one of these cars. In many cases the body may be offered alone so that you don’t have to buy a chassis that you really don’t want. Let’s get these beautiful slot cars back on the track — they deserve to be there.

_Michael Ashton

Carrera Guide and Braid Maintenance

By Michael Ashton

My 1/32nd scale home track is Ninco N-Digital. It allows me to run a wide variety of slot cars from various manufacturers. This includes a number of Carrera cars. Recently several of my older Carrera GT's began running poorly on the N-Digital track. They seemed to be running erratically. They were not smooth in the straights, balked when crossing a dead strip, were 'jerky' when accelerating and would occasionally zoom to full throttle when braking into a corner.

I tried a number of things without any improvement. This included thoroughly cleaning the track rails and treating with INOX, checking voltage level all around the track and installing a fresh set of pickup braids in each car.  Finally, I removed the braids, intending to check connectivity at all points from the guide to the motor when my attention was immediately drawn to the small rail that makes contact between the guide and braid assemblies (see below).

It appeared to be tarnished and/or oxidized when compared to the shiny brass of the new braid assembly that was just installed. So, I took a small flathead screwdriver and burnished the exposed surface and the surfaces that are recessed into the rectangular openings of the guide plate.

I then took the previous braid assemblies that had been removed and performed the same operation on their contact surfaces and reinstalled them in the guide.

I returned the car to the N-Digital track and the performance increase was immediate and noticeable. The car ran much smoother around the track and did not hesitate at the dead strips. All the previous problems were either gone or significantly reduced.

This does not appear to be an issue when running analog and it's possible that it only affects Carrera cars running on N-Digital. Now this may be common knowledge to Carrera users, however, it was a significant discovery for me. Regardless, it could also be a problem on Carrera's Digital 132 system because, as with N-Digital, the Carrera system transmits its data through the rails.

Anyway, it's something to think about if you ever have subtle performance problems with a Carrera Digital 132 car.

_Michael Ashton

N-Digital DPR Chip for SSD Slot Cars

I have always managed to live in places that can only be characterized as a slot car 'wasteland'. By that I mean that no one else within a hundred miles is involved in the hobby. No one to race with or tinker with the cars. Anyway, I recently moved from Southwest Florida to North Central Florida, effectively replacing one slot car wasteland with another. Naturally I assumed that my lonely isolation in the slot car hobby would continue. So you can imagine my surprise, followed by overwhelming joy, when I received a message through an Internet slot car forum from Ray.

Ray is a 1/32nd scale slot car enthusiast — just like me! Ray has a digital slot car track — just like me! Ray lives less that 30 minutes from me! I could not believe it. Another DIGITAL slot racer less than 30 minutes away! I thought that I was going to explode. But wait. Ray’s track is Scalextric Sport Digital (SSD) while my track is Ninco N-Digital. The two systems are not compatible, therefore, he can’t run his cars on my track and vice versa. Unless we are both willing to install digital decoder chips from the other system in our cars, we would have to borrow cars when visiting each other’s track. Not a terrible solution but I would be hesitant to race another person’s cars really hard in case I break something. And we would like to race our own better cars — not just beat up 'runners'.

Ah, but there is hope. For quite a while now most Scalextric and Pioneer slot cars come with a chassis that is designed to accept the Digital Plug Ready (DPR) Easy Fit decoder chip. Shown in the following photo, the DPR chip is mounted on a removable panel that fits into the underside of the chassis just behind the guide. The car is equipped at the factory with an analog version of the panel that passes power through directly to the motor terminals. Converting the car to digital is a simple matter of removing and unplugging the analog panel and replacing it with the DPR chip — without having to remove the car’s body. Truly plug and play.

So, I got to thinking, what if there were an N-Digital version of the DPR chip? That would allow Ray and me to run all of our DPR-equipped Scalextric and Pioneer slot cars on SSD, N-Digital and analog tracks without any modifications to the cars. All that we would have to do is plug in the appropriate DPR chip or the analog panel. Well, the only way an N-Digital DPR chip was going to exist is if I were to create it. So I did!

                                        ☯                    ☯                    ☯                    ☯                    ☯

The remainder of this article describes the necessary steps to fabricate an N-Digital DPR chip and what I learned in the process. The N-Digital DPR chip is a relatively simple DIY project with the only requirement being basic soldering skills. Tools and materials needed are:

• Low wattage (30 watt) pencil type soldering iron.
• Solder removal tool (solder sucker).
• N-Digital decoder chip (any version of the chip will work).
• Analog panel from a DPR-equipped Scalextric or Pioneer car (see the following photo). The white DPR plug must be removed and will be wired to the N-Digital decoder chip.

• Narrow heat shrink tubing for the lead wire connections to the DPR plug.
• 9 - 10 mm heat shrink tubing to protect the entire DPR plug assembly.
• CA adhesive (super glue).
• Two part plastic epoxy adhesive.
• Double sided adhesive foam pad or tape.

The first step is to remove the housing which contains the white four-pin DPR plug from the analog panel. This is easily done using the blade of a sharp hobby knife to loosen and pry the housing away. The DPR plug is removed from the housing in the same manner. Just be gentle and patient. The DPR plug, freed from the analog panel housing is shown in the photo below.

The red arrows point to the plug’s two pairs of input/output pins which are soldered together for analog operation. The solder on these pins must be removed by heating them with the soldering iron and then using a solder sucker to pull the solder away from the pins. The resulting plug should look as shown below.

The DPR plug is now ready to be connected to the N-Digital chip’s lead wires, however, the pins may be somewhat loose, allowing them to move inside the plug. Applying a small amount of viscous CA adhesive (super glue) to the base of each pin will keep them secure in their position.

The following two illustrations identify the pin positions of the DPR plug and the corresponding lead wire positions of the N-Digital chip. It is just a matter of soldering the N-Digital chip’s '+ guide' lead wire to the DPR plug’s '+ guide' pin, then the '- guide' lead wire to the '- guide' pin and so forth.

                     DPR Plug                                                                                                     N-Digital Chip

Cut the N-Digital lead wires to a length of about 20 mm. Then strip and tin the ends of each trimmed lead wire with solder. Before soldering to the pins, slip a 1/4” length of narrow heat shrink tubing over each lead wire. Now solder each lead wire to the pins according to the position identifications shown above. Push the shrink tubing over each solder connection so that it is completely covered and shrink the tubing using the hot soldering iron. Next, cut a 15 mm length of the larger (9 -10 mm) heat shrink tubing and push/stretch it over the whole DPR plug assembly. Shrink that tubing until it appears as shown in the photo of the finished project below.

One last point: the solder connections of the N-Digital chip lead wires to the printed circuit board (PCB) are notoriously fragile. I mixed some two part plastic epoxy adhesive and applied it to the base of each lead wire's connection to the PCB to form 'boots'. This will keep the lead wires from bending and being stressed at the solder joint. Finally, the finished N-Digital chip/plug assembly is attached to the DPR panel using double sided mounting foam tape or pads. The mounting pads suppled with the N-Digital chip are ideal for this.

The N-Digital DPR chip is shown below being installed in a Pioneer Camaro. This car has a full interior and somewhat restricted space above the DPR panel and the N-Digital DPR chip still fits quite easily. The chip has been installed and tested in a small but representative sample of Scalextric and Pioneer cars without any problems in either installation or performance.

So, if there are any N-Digital users still hanging in there, and you have a few (or a lot of) Scalextric and/or Pioneer cars that are DPR ready, then you may want to make one or two N-Digital DPR chips. It’s a fairly easy project that provides benefits that are more than commensurate with the time and effort required. At least Ray and I think so. We now have a small fleet of cars that is easily switchable among SSD, N-Digital and analog racing, without even having to remove the car’s body. All we have to do now is find the time to race.  

_Michael Ashton

Healing a Broken Wing (Slot Car That Is)

By Michael Ashton

This is how I felt after my Ninco Audi R8 Spider left the slot at high speed and massacred the rear spoiler.

The spoiler was damaged in the worst way possible. One strut was broken off the wing. And the mounting tabs for both struts were snapped off.

And if that wasn’t bad enough, the mounting tabs were still in the slots of the rear deck, held in place by the world’s strongest thermonuclear glue!

Stop Crying and Get To Work!

I really wanted to fix the spoiler in a way that results in a reliable repair that also maintains the aesthetic appearance of the car as much as possible. Not just gobs of glue all around the mounting slots to provide reinforcement. So here is what I did…

First cut a square notch in the base of each strut where the mounting tabs used to be.

Next, cut a short rectangular strip from a sheet of styrene plastic that is slightly thicker than the strut itself. The styrene strip should be about 6 to 7 mm in length and the same width as the notch that was cut into the base of the strut.

The strip should fit snugly into the notch, as shown above. The strip is going to be our new mounting tab.

The strip is then glued into the notch using two-part plastic epoxy cement. This type of glue provides a very strong bond between the strip and the strut. Note how plenty of glue is applied. This effectively encases the strip and strut in a cocoon of very hard glue. Don’t worry about the excess because after curing it will be sanded down to a smooth, even finish. The combination of support on three sides and the surfaces of the new tab coupled with the bonding and hardness of the plastic epoxy provides a very strong repair.

The existing mounting tabs had to be “routed” from the slots on the car’s rear deck. This was done very carefully with a sharp scribing tool and a hobby knife with a narrow pointed blade. Be very patient when performing this step. Once this is accomplished the newly fabricated mounting tabs can be shaped by filing and sanding until they fit tightly in the mounting slots. 

The following two photos show the repaired spoiler. The strut that was separated from the wing has been glued back in place with CA glue and appears to be quite secure. The underside of the wing and the struts were painted with Krylon Fusion Gloss Black. After the paint cured for 24 hours the struts were coated with Pledge Floor Care.

Not Perfect, But Very Good.

The new mounting tabs fit tightly enough in the mounting slots that glue was not required. So this car has a tear away spoiler — at least for now. If it does ever become too loose for a friction fit I can always glue it in place.

The repaired spoiler has held up well so far. Even through a couple of minor incidents. Therefore, I would recommend this type of repair for any wing of similar structure where the struts have sufficient thickness and surface area to allow it. It’s a bit tedious and time consuming, however, I believe that the preserved appearance of the slot car makes it worthwhile. Not perfect, but very good I would say. Anyway, if it breaks again, I’ll fix it again.

Now see how I feel…

_Michael Ashton

Building a 1/32nd Scale Slot Car: Group 44 TR3

By Michael Ashton

In my younger days I owned four Triumph sports cars, including a TR3. So when a Lindberg TR3 static model kit “fell” into my possession I decided to make my first attempt at building a 1/32nd scale slot car. At first I thought that I would make a replica of the TR3 that I knew and loved. However, as with many slot car enthusiasts, I am not particularly interested in street (non-racing) versions of automobiles. But if not my trusty old TR3, I wanted it to be something worthwhile historically.

After a fair amount of Internet research on who has raced the Triumph TR3 it became obvious to me that one of the Group 44 racing team’s cars would be a great example. Most notably the TR3 built and driven by Brian Fuerstenau. Along with the more famous Bob Tullius, Brian was a cofounder of Group 44 Racing. He was a self-taught automotive genius who could make Triumphs, Jaguars and many other sports cars of the era perform uncannily well. And he was a champion driver at the national level long before Group 44 came to be. Sadly, he died in 1993 when the T-6 aircraft he was piloting (his other passion) crashed.

One thing is certain: no matter what form of motor sport Brian Fuerstenau would have been involved in — whether at Le Mans or a dirt track in the Ozarks — he would have competed at the top level. I hope that my humble attempt at recreating his rustic ride as a slot car would have met with his approval.

© Copyright Don Struke. Used with permission.

© Copyright VIR History. Used with permission.

The Model

Notes on the Process

The basis for the project was the Lindberg Triumph TR3 static plastic model kit.

The body is reasonably scale accurate, however, it has only rudimentary detail. Now my modeling skills and experience are quite limited. Therefore techniques such as cutting, filling and reshaping body details are beyond my capability — at least for now. So I have to create the illusion of detail using the primary assets that I do possess, namely tenacity and patience. Following are some of the techniques that I used.

For me, the most difficult task was the creation of the tonneau cover. The TR3 cover is unusually difficult because it has multiple surfaces (top and sides) and must conform to a number of undulations around the entire cockpit. I experimented with several methods and materials including very fine grit wet/dry sandpaper and surgical tape. I literally stumbled on the solution that I used while wandering around a craft store.

Chalkboard tape has the ideal characteristics for the TR3 tonneau cover: It has almost perfect color and texture; it is reasonably malleable but very strong and tear resistant; it is self-adhesive which is particularly useful during the fitting process.

First cut a strip long enough to cover the entire cockpit, as shown below.

Next, remove the backing exposing the adhesive side and press the tape all around cockpit edges. This will leave an impression of the cockpit’s geometry in the tape. You can also trace the required outline onto the surface of the tape with a pencil before removing the tape. Remember, this is chalkboard tape — the pencil lines erase easily.

Now it is relatively easy to perform a rough cut of the cover with sharp scissors or a hobby knife. Leave extra material around the outline to allow for test fitting and subsequent fine trimming. The fact that this is adhesive tape that can be easily removed and repositioned helps immeasurably here.

Once the tonneau cover shape is correct and conformed to the cockpit edges, the tape adhesive around the edges is removed using solvent and a Q-Tip. The cover is then glued in position with a permanent adhesive. I used two-part plastic epoxy. Be careful to keep the glue away from the outer most edges of the cover to avoid marring the car’s painted surfaces.

I found it almost impossible to create the tonneau cover snaps using paint. I just could not create tiny uniform circles by any method. So, I used tiny pins that I found in the sewing and jewelry sections of the local craft/hobby store. The pins on the left were used to simulate the tonneau fasteners while those on the right were used for the windscreen snaps and the roll bar opening covers.

The heads of both pins were too large to my eye so I reduced their diameter with a Dremel sanding disk. Correct spacing was achieved by creating a template from a narrow strip of masking tape with the fastener positions marked equally spaced on a guide line. The tape was then positioned around the edges of the cover and marked with a sharp scribing tool. I used a pin vise with the smallest available bit to drill tiny holes through the template, cover and cockpit edges.

The pins were then cut to a few millimeters in length and pushed all the way into the holes.

Enough of the pin protrudes through the inside of the cockpit (not visible externally) to allow CA glue to be applied from the inside, avoiding any glue residue showing on the cover itself.

Another area that required a little ingenuity was the kick panel behind each door. The Lindberg body has only the faintest relief detail of this feature (see the following photo) and it was not symmetrical on both sides.

I probably made a mistake by not addressing this prior to painting the body. I tried several types of matte silver paint, but even after allowing up to week of curing time, the silver paint never dried properly and tended to rub off — even under the clear coat! Then I remembered that I had bought some silvered copper tape to apply to the rails of my track.

The tape had the perfect, durable finish that I was looking for and a very effective adhesive. I was able to cut the exact shapes that were needed and position it precisely on the body. To make sure that the bond would be permanent and could withstand rough handling I applied some two-part plastic epoxy cement along the inside of the lower and trailing edges. Finally, two coats of clear coat were added locally for protection.

Decals were home made, printed on Testors clear decal paper using a medium quality inkjet printer. I was able to zero in on the appropriate type sizes by test printing on plain paper, cutting out samples and tacking them in position on the body. The dashboard gauges are drastically reduced images similar to TR3 gauges available on the Internet. The finished decal sheet received a light coat of Testors clear coat and allowed to cure for at least a week prior to application.

Microscale solutions were used to optimize the decal application. Micro Set to apply and create good adhesion to the surface. Micro Sol to allow the decals to conform to surface details and minimize edge visibility by softening the decal substrate.

Ranking high under the topic of “the illusion of detail” is the highlighting of chrome plated fixtures. The Lindberg model has no chrome plated surfaces or parts at all. And I have never found a chrome paint that was able to create a realistic looking finish (although Testors comes close). Luckily there is a product called Bare-Metal Foil that makes realistic chrome detail on any model possible.

It is a very thin foil with an adhesive backing that is basically burnished onto the surface and then trimmed to the desired area. No special tools are needed beyond a sharp hobby knife, Q-Tips and tooth picks. Reasonable dexterity and patience are a plus.

The chassis used to make this model a slot car is the Slot Classic. This is a very simple plastic chassis with an adjustable wheel base, designed for the standard Mabuchi [type] FC-130 motor.

The chassis for the Group 44 TR3 is outfitted with:

• A ScaleAuto 10K RPM FC-130 motor. Very mild but appropriate, I think, for this model.
• Slot.it axles, gears and bushings.

• The guide and pickup braids are Ninco Standard Suspension and ProRace tinned, respectively.

• Aluminum setscrew wheels and resin-cast inserts are BWA.

• The inserts were first sprayed with automotive primer then finished with Krylon matte aluminum paint.
• Tires are Ninco Classic 20x7.

Other Details

The driver figure is made by MRRC. It is the same figure that is used in many MRRC models, most notably, the 427 A/C Cobra. The head was repositioned to a more natural attitude. The figure was first primed and then painted with acrylic paints.

The Lindberg TR3 body was primed with DupliColor white primer and finished with DupliColor Ford Pure White.

The clear coat is Pledge Floor Care (formerly known as Future). This provides an attractive finish and also protects decals and Bare-Metal Foil chrome accents. It is easy to apply with a 1/2” soft bristled art brush.

This article covers many of the techniques employed and issues encountered in the building of this slot car. Feel free to post any questions that you may have in the comments section and I will do my best to answer them. You may also have suggestions about better ways to do things which are, of course, welcome.

_Michael Ashton