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

Convert the Carrera Ferrari 458 Italia to N-Digital

I have three Carrera slot cars that have been converted to Ninco N-Digital. In all three cases I installed the N-Digital decoder chip leaving the existing Carrera guide assembly in tact. I removed all the Carrera electronics, noise suppression components and wiring between the guide lead wire plug and the motor terminals. I then replaced the Carrera Molex-type plug with one of my own that allows me to plug the decoder chip in and out. This worked fine and I believe that the modestly powered, smooth running Carrera drive train is well suited to the N-Digital system. The only nuisance that I had to deal with was sanding that big thick Carrera guide flag down so that it would tolerate the narrower Ninco slot. And yes, I am aware that Carrera makes a smaller guide flag for non-Carrera tracks, however, I feel that the smaller flag is also too thick for Ninco track -- just my opinion.

Regardless, I recently found a mysterious package on my front door step that contained a brand new Carrera Ferrari 458 Italia. I really don't care how it got there. I just knew that this car needed to be running on my N-Digital track ASAP. The Ferrari 458 Italia is another Pininfarina body design so you know that it looks superb from any angle – I can't resist that. Anyway, this time I decided to try something different in the conversion process. Instead of using the stock Carrera guide assembly, I decided to install a B-Nova guide adapter for Carrera (which, interestingly, was also included in the package) that would allow the use of the Ninco ProRace suspension guide. This particular car has already been expertly reviewed elsewhere in the slot car forums, so I will concentrate strictly on the N-Digital conversion process and performance characteristics that relate to N-Digital operation.

Below is the car and all components required for this conversion: the N-Digital decoder chip, the B-Nova guide adapter for Carrera and the Ninco ProRace suspension guide.

The following photo shows the stock Carrera [analog] chassis out-of-the-box. What I see, from left to right, is the usual Carrera self-centering guide assembly, the PCB that hosts the reversing switch, the plugs that connect the guide to the PCB and the PCB outputs to the motor terminals and, finally, the three noise suppression capacitors across the motor terminals and the motor can. All of these items must be removed.

At this point it is important to mention a characteristic of the Carrera guide assembly on this, and I believe, a few other Carrera GT type cars. Note in the following two photos that the ride height of the car causes the guide flag to sit very high, almost half way out of the slot. The Carrera guide flag is relatively deep, so de-slotting may not be an issue, however, this will not afford the best electrical contact which very likely will be a problem in digital operation where control data are obtained through the rails via the braids. I have seen at least one novel solution to this problem in the slot forums, however, I am not concerned about it here because the combination of the B-Nova adapter and the Ninco ProRace suspension guide will solve this problem for me. The primary reason for installing the B-Nova adapter is to enable the use of the Ninco ProRace suspension guide, which provides superior performance on Ninco/N-Digital track. The fact that the B-Nova adapter helps with this issue is an incidental plus. This will become clear a little later.

Removing the Carrera guide assembly is straight-forward: first pull the guide flag straight down and out of the guide assembly. Then remove the two screws at the top of the assembly, just in front of the front axle, and it will pop out of the chassis. Next, remove the single screw holding the reversing switch PCB in place and it will come away from the chassis. Finally, with a medium wattage pencil-tipped soldering iron, remove the lead wires and noise suppression components from the motor terminals and can.

Because the N-Digital decoder chip uses push-on clips to connect to the motor terminals, any excess solder on the terminals must be removed. Use the pencil-tipped iron and a "solder sucker" to do this, as shown in the photo below.

Below are all the removed components and the motor. Note the condition of the motor terminals – free of excess solder. And don't throw those plug assemblies away. They make great quick disconnect cables for cars with lights that get power from the N-Digital decoder chip.

Next I installed the B-Nova for Carrera guide adapter. This is also a straight-forward process that is documented elsewhere in the slot car forums by the B-Nova creator, so I will not go into detail here. Quite simply, the adapter consists of a "resizing ring" and an "adapter ring" that contains the guide post holder. The resizing ring is glued into the guide assembly hole in the underside of the chassis. The adapter ring is then pushed into the resizing ring and then glued in place. However, I will mention that the adapter was an extremely tight fit for this particular car that required a small amount of sanding in order to complete the installation. Given the tolerances that we are dealing with here, I don't consider this to be an issue at all.

Below is the underside view of the installed adapter. The height of the guide assembly above the slot is determined by how far the adapter ring is pushed into the resizing ring. In this case, the adapter ring is flush with the resizing ring.

And the Ferrari 458 Italia chassis, ready to receive the Ninco ProRace guide and N-Digital decoder chip, and showing the top side of the B-Nova adapter.

I always lubricate the guide post holder, all axle bushings, the exposed motor armature bushings and the gears. This car had grease in the axle bushings so I did not add any oil there. Also, the gears were well greased so I did not add any grease there either.

Below we see the Ninco ProRace suspension guide installed and the decoder chip connections made to the guide and the motor terminals. A small square double-sided adhesive foam rubber pad (provided with the decoder chip) is used to keep the chip in place.

And finally, the completed conversion, waiting only for the body to be screwed back on.

Comparing the guide assembly height of the converted car shown in the following two photos to the photos of the stock Carrera setup shown above, we now see a perfect "tripod" stance and a guide that is well planted...

...with the added benefit of the suspension effect of the Ninco ProRace guide.

With the conversion complete it was time to put the car on the track. My other three Carreras (an Audi R8 LMS, NASCAR COT and Porsche Spyder LMP) are all competent N-Digital runners. I was hoping that the chosen approach to this conversion would yield at least comparable results – if not better.

The Ferrari 458 Italia has two magnets: a large bar magnet located mid-chassis just in front of the motor; and a medium bar magnet located in front of the rear axle under the pinion. Each magnet has a thin metal bar which is presumably a spacer that can be used to raise the height of the magnet above the rails slightly. I am assuming that the smaller magnet in the rear could also be installed in place of the larger magnet in the middle. I don't have a way to measure magnetic down force but it is obvious that the sum of the two magnets' force is considerable. It is also obvious that this particular setup affords a reasonable level of flexibility in adjusting the down force and, therefore, handling characteristics in magnet driving.

--- Mid-chassis ---               -------- Rear --------

First, some perspective on lap times. My home N-Digital track is about 60' of lane length. Mostly R2 turns, short straights and one straight that is about 10' long. The fastest lap recorded is 6.18 seconds by a Ninco Acura LMP2 with the magnet. I run LMP and NASCAR with magnets. They typically run in the mid to upper 6 second range. Everything else is no-mag. NC-5 equipped Ninco GT's run in the upper 7 to low 8 second range. 18K rpm low-torque FC-130 type motors in a variety of cars run anywhere in the mid 8 to mid 9 second range. I run the NINCO 1 cars no-mag in 'professional' profile with lap times in the low-to-mid 8 second range. The previously mentioned Carrera Audi R8 LMS runs in the low 9 second range in 'amateur' profile.

So, for the purpose of testing, I ran the car in four different configurations of magnet for 25 laps each. First with both magnets in place. Next with the the larger mid-chassis magnet removed and smaller rear magnet in place. Then with the mid-chassis magnet in place and the rear magnet removed. And finally with no magnet. In all cases the magnets had the spacer bar on top allowing the magnet to assume its lower position. With magnets on board the 'professional' throttle profile was used. For no-mag the 'amateur' profile. The data for each 25 lap test run were used unaltered – even with de-slots, because I believe that this is representative of the actual performance that can be expected. The resulting lap times are shown in the table below.

The lap times for full and rear magnet running on my track are very good. About the same as the Carrera NASCAR and LMP that I run this way. My personal feeling is that the car handled better and drove more realistically with only the rear magnet in place. The effect of the mid magnet alone was relatively mild. Very close to running no-mag but its effect was still noticeable. And without at least the mid magnet in place, I was not able to run the car reliably in 'professional' throttle profile. However, I think that the real benefit of the B-Nova adapter/Ninco ProRace guide combination is apparent in the no-mag lap times. The recorded times are typically about 4/10ths faster than that of the Carrera Audi R8 LMS which, as previously noted, was converted using the stock guide assembly. The way to verify this is to install the B-Nova adapter/NincoProRace guide combination in the Audi, which I will do eventually.

My purpose here is to answer two questions: 1.) is the Carrera Ferrari 458 Italia a good choice of car to convert to N-Digital? And, 2.) does installing the B-Nova guide adapter to allow the use of the Ninco ProRace suspension guide provide a measurable benefit to the conversion result?

The answer to the first question is really personal and subjective. Regardless, it is a resounding yes! I like the appearance of the car. And its performance, both with and without magnet, on my N-Digital track is very good. The Carrera GT cars are obvious candidates for a N-Digital racing class. They can run competently both with and without the magnet, run well in either of the available N-Digital throttle profiles (except as noted), and have a great deal of flexibility in magnet racing setup without having to tinker with the car.

Based on the recorded lap times, the answer to the second question (at this point at least) is also yes. This car is ideal for no-mag digital racing, where in my opinion, control and handling will consistently trump brute force speed and power – certainly on my type of track. I ran the Ferrari 458 Italia and the Audi R8 alternately for a considerable number of laps. There is less front end bouncing, smoother power through the turns and generally a better feeling of control with the Ferrari 458 Italia as configured.

In conclusion, if you're an N-Digital user and you run no-mag, get one of these cars and set it up this way. I think that you will be very pleased by the result. Certainly enough to consider the Carrera GT's as a N-Digital racing class. And if you run with magnets, I think the flexibility afforded by the magnet set-up will give you lots of options to optimize performance on your N-Digital track.

by Michael Ashton

N-Digital Tips, Tricks & Tweaks

Well, I finally found (it would be more accurate to say, was given) a new, permanent home for my my N-Digital track. It now fills every available square foot of what used to be the guest bedroom. Now, the only guests in this room will be slotheads. Anyway, as long as I had to go through the arduous task of moving the track, I thought I would make some improvements and address a few niggling issues that have been tolerated far too long. Below is the new layout.

The next photo shows my prior track. Given the space constraint, it was a pretty good layout, providing many hours of competitive racing. And it was actually less than one foot shorter than the new circuit. But it definitely had some line-of-sight problems. And, it occupied one entire end of the living room. But the main thing that I didn't like was having the Pit Lane on the back straight – hard to reach. But there was no other option because that was the only straight long enough to accommodate it.

The new layout has a long enough straight in the front to accommodate the Pit Lane. However, this required that the N-Digital console/track be located after the pit exit, otherwise cars exiting the pits would bypass the start/finish (S/F) line and their current lap would not be counted. This could be done but it meant that the console/track (and, therefore, the S/F line) would be the last section going into an R2 turn. Not a good situation in the final lap of a close race. So I wanted my S/F line to be prior to the pit exit. In other words, next to the Pit Lane, not after it.

The solution was the N-Digital Multi-Lane Sensor track. This track section is normally used to provide a S/F line in a four (or more) lane layout, but it can also serve the same purpose in the Pit Lane. The two photos below show how the Multi-Lane Sensor track is installed within the Pit Lane as the last track section prior to the pit exit. It's the track section with the yellow cone standing on it. This allows the N-Digital console/track to also be moved back to a position prior to the pit exit, leaving room to slow down before the first R2 curve. Now when a car goes through the Pit Lane it crosses the S/F line and the lap is counted. Note that the Multi-Lane Sensor has a data cable just like the Pit Lane that must be connected to the N-Digital console. This will require the NINCO #40306 N-Digital Multi Connector Jack to accommodate both cables.

Important note: Obviously, only one lane (i.e., the left lane) of the Multi-Lane Sensor track is connected to the Pit Lane. After connecting the Multi-Lane Sensor as shown in the above photos and plugging its data cable into the N-Digital console, to my dismay laps were not being counted for cars passing through the Pit Lane. After some short but futile troubleshooting I removed the electronics cover on the underside of the track piece and discovered that the electronics (PCB) receives power from the rails of the right hand lane – the one that is not connected! The solution was to solder two short jumper wires to connect the respective rails of both lanes. Replaced the cover and problem solved.
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A well documented nuisance of the N-Digital lane change (LC) track sections is the gap that exists in the plastic slot liner where the tip of the flipper contacts the side of the slot. The gap is intended to allow full left/right movement of the flipper during a lane change. An unintended consequence of this gap occurs when a car's guide flag collides head on with the trailing edge of the liner gap – not a pleasant experience. Over the last few years several solutions to this problem have emerged, incdluding using a strip of tape to cover the gap or creating a bulge in the slot wall to deflect the guide flag away from the gap. They worked well enough but were not perfect or particularly elegant.

Recently a very novel solution to this problem was documented by Maurizio Ferrari of Slot.it. Very simply, a small thin strip of brass is inserted behind the leading edge of the gap between the liner and the rail, and extending just beyond the trailing edge of the gap to create a ramp (this will become clear with the following photos and description). This was a brilliant solution, however, there is some concern about using a conductive metal strip in the slot so close to the rails. So, Brian at BRS Hobbies located some very thin (0.01" thickness) styrene sheet material that works perfectly and eliminates the possibility of electrical damage should the ramp ever come loose.

The following photo shows the ramp cut from a styrene sheet. The dimensions that I use are about 4.5 mm high and 39 mm long. The leading edge is tapered slightly downward so as not to present a sharp corner sticking up from the slot wall to the on-coming guide.

The photos below show the ramp installed in the slot. The two black arrows highlight the gap in the slot liner. The edge of the gap depicted by the left black arrow (trailing edge) is where the guide flag can collide with the slot liner. The red arrow shows where the ramp is inserted between the rail and the liner. it is secured in place by a very small dab of CA glue on both sides. I set the trailing edge of the ramp to extend about 8-9 mm beyond the end of the gap. This allows the end of the ramp to be highly flexible, presenting minimum resistance to the passing guide flag. I find that if the overlap is too short then the ramp can seem a little stiff in this area, however, I don't feel that the overlap length has any physical effect on the guide flag as it passes through as long as it extends some distance beyond the end of the gap. The styrene is strong yet very flexible, but not at all malleable, making it perfect for this application. This fix is not necessary for the other gap (leading into the crossover lane) because, when the lane change is activated, centrifugal force acting on the guide flag presses it against the flipper, away from this gap.

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Quite a bit has been written about methods used to facilitate switching between digital and analog operation of an N-Digital track. Schemes range from the relatively simple, where the digital console is replaced with an analog power base; to the highly complex where external electrical switching circuits and/or N-Digital track section modifications are employed. I will describe the simplest method that there is (along with its limitations) and also provide a tip (a warning, actually) regarding two things that should not be done under any circumstances.

So, the simplest method of converting a N-Digital track to analog operation is pictured below. All that is needed is to replace the N-Digital console (half straight) and one additional half straight track section with the standard Ninco power base track. Additionally, if there are any N-Digital Control Towers in the layout, they must be disconnected from their half-straight track section. That section may then be left in the layout.

Use the same power source that was being used for N-Digital, either the N-Digital regulated 14 volt 3 amp power transformer (recommended), or a regulated power supply set no higher than 14.5 volts. You can then attach one (and only one) analog controller, such as the Ninco 55 Plus. Why only one? Because by leaving the N-Digital lane change track sections in the layout, what you have is a single lane analog circuit. This is because the rails of both lanes of the LC sections are cross connected internally to help with power/data distribution in digital operation. Remember that the N-Digital track is one single lane electrically regardless of how many physical lanes you may have.

This happens to be fine for me because it is all that I need. At least for now, I only use analog operation to tune and test cars that I am not ready or willing to convert to digital operation. So running one car at a time suits my purpose. Otherwise, I just prefer digital operation, even when running by myself.

Now if you really want that fully independent two lane operation without having to remove the LC sections you can modify the LC's by removing (de-soldering) the internal wires that connect the two lanes' rails together. It's a relatively simple, straight forward process, however, that subject is not covered here because it is well documented elsewhere in the slot car forums. Also, I always strive to avoid physical modifications to cars and track that are irreversible or may affect a current warranty. Not always possible, but I try. Suffice it to say that all LC's will require modification, or they will have to be replaced with comparable sections of regular track.

The Pit Lane is a single lane so it can be left in the layout in its stock condition. As previously mentioned, if there are any N-Digital Control Towers in the layout, they must be disconnected from their half-straight track section, leaving that track section in the layout.

At this point you can connect a second controller and race two cars independently.

Now for the warnings. Once you have switched over to analog operation with N-Digital track sections still connected:

First, do not use the standard unregulated Ninco (or anyone else's) power pack that comes with the analog race sets. If you are using a variable voltage power supply, it must be regulated (switching) and it must not be set higher than 14.5 volts. Failure to heed this warning will result in damaged LC electronics. So, just use the same power source that you were using for N-Digital, set and configured the same way, and you will have no worries.

Second, the direction switch on the Ninco power base track should be in the position for clockwise racing direction (see the blue arrow in the photo below). The same as N-Digital. Do not change the direction. The N-Digital track sections all get their power from the rails. As of now, I do not know what the effect of reversing polarity will be on the electronic circuits in the N-Digital track sections. I am not aware of any testing that has been done and for now, I'm not anxious to find out what will happen. It would probably be a good idea to cover the switch with tape or even hot glue (which could be removed later).

The information above on switching an N-Digital track between digital and analog operation is available as a Adobe pdf document that can be accessed by clicking this link - NDigital to Analog.
••••••••••••••••••••

Here are some thoughts on positioning lane change (LC, XLC, XLC curve) track sections in an N-Digital layout.

Where not to put them:

My first rule is to avoid placing a LC track section at the end of a long straight. This is due to the potential of getting stuck on the LC's dead strip when breaking hard while entering the corner – especially when running with a magnet. But looking at the photo of my new layout above, most prominent in the foreground is the XLC curve sitting at the end of the longest straight! It's really a tradeoff that I will address momentarily.

Don't connect two or more opposite single or XLC's together (consecutively). You will find your cars changing lanes and then immediately changing back because it's difficult to release the lane change button quickly enough to complete the first lane change while avoiding the second.

Good locations:

Remember that changing lanes is not just about overtaking. Every track has an optimal racing line. So, some thought should be given to placing LC's to provide access to the best racing line. For example, I placed a inside-to-outside LC just prior to the only (R1) hairpin turn in my layout so that the gentler radius outside lane could be used when taking the turn.

And, regarding that XLC curve section at the end of the long straight? It's in that position to allow 1.) a last second outside-to-inside lane change to get into the correct lane for a pit stop and, 2.) a last second inside-to-outside lane change to avoid someone who is about to exit the pit lane. It's a tradeoff that I have accepted for now. The fact that there is a mild down slope from the overpass helps by providing some extra momentum through the turn. Regardless, I'm dealing with the issue of being at the end of the straight by learning to drive better.

Generally, I try to place LC's at the beginning of a straight section for overtaking or right after a turn in more complex sections of the layout. There are no rules so it's important to experiment. If an LC causes problems in one location, try it somewhere else. After all, the LC's are supposed to make racing more fun, not to add stress. There are lots of opinions on this so look at these thoughts as a starting point.
••••••••••••••••••••

Finally, if you clean/treat your track rails with a solvent-based product such as WD-40 or INOX, here is a simple but effective applicator that will insure that the cleaner will be applied only to the rails and not the plastic part of the track.

First, cut the ends off a double-tipped Q-Tip, leaving about one quarter of an inch of the shaft in place for each of the resulting two pieces. Next you will need an old slot car guide that has a reasonably deep guide flag. In this example I used a Ninco standard suspension guide without the spring. The longer shaft of the suspension guide makes the guide easier to hold in this application. The final component is a small to medium insulated alligator clip.

Place one Q-Tip end piece on each side of the guide flag held tightly up against the base of the guide. Then use the alligator clip to pinch the remainder of the two Q-Tip shafts together against the guide flag. This will hold the two Q-Tip ends firmly in place. The following two photos show the fully assembled machine.

Apply the cleaning fluid to the Q-Tip ends, place the guide flag in the slot, and push the assembly along the slot with mild downward force for about four feet of track length. You will find a coating of the cleaning fluid deposited quite uniformly on the track rails and not on the plastic part of the track itself. Wipe the rails with a clean soft cloth and you are done. When the Q-Tip ends get dirty and ragged just replace them with a new pair.

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So, this is all fairly simple stuff but hopefully it will be useful to an N-Digital user or two. Perhaps there are some of you out there who have similar, or better, ideas that can make N-Digital racing a little better. Let us know by posting them here.

by Michael Ashton