7 steps to improve the track performance of your classic Scalextric car

Lap times improved from 18.72 seconds to 6.44 seconds. Read on to find out how we did it…..

Abstract

Frequently the older Scalextric cars can seem slow and difficult to race by the standards set by modern Scalextric cars. This article shows that in seven simple steps a typical Scalextric car from the 1970s can be updated to give track times nearly 3 times faster compared to the car when found. This was all accomplished with some basic servicing and with some readily available replacement parts.

Introduction

The older Scalextric cars from the 1970s and 1980s are great models but can seem slow and difficult to race by the standards set by modern Scalextric cars. Luckily these classic Scalextric cars can be upgraded to greatly enhance their track performance making them competitive on the track while not removing any of the enjoyment and skill required for the older Scalextric cars.

This article lists seven simple changes to greatly improve your classic Scalextric car. We have based this article on a 1970s Scalextric C.052 Ford Escort RS1600 which was selected as being typical of the Scalextric cars of the period. It was not prepared before the test apart from ensuring the motor operated as expected and the car was complete, electrically and mechanically with no obvious faults. The tyres were not cracked or split to any great degree and still had grip when run on classic Scalextric track. Our overall impression is that this car had been stood unused for a long period of time.

The seven steps

The results are based on a Scalextric Sport track with a test circuit specifically designed for this test. Built from the modern Sport Scalextric track the surface offers little mechanical grip with a smoother surface compared to the original classic Scalextric track. It incorporated tight inner corner hairpin sections, long straights, chicanes, corners that tightened, corners that opened out. Essentially all types of challenges.

Step 1: After conducting a visual inspection we measured the best lap times the car could achieve. The best lap time achieved was 18.72 seconds. Then the car was given an electrical service with new; copper pick up braids, pick up pins and wires from the pick up assembly to the motor. A retest gave a new lap time of 15.22 seconds which is an improvement of around 18%.

Step 2: Then, the car given a full lubrication service with all the motor and axle bearings given a small drop of oil each. Also, the gears were lightly coated with Teflon impregnated grease. A retest of the car gave a new best lap time of 13.77 seconds which is a further improvement of around 9.5%.

Step 3: After the lubrication service slightly wider axles were fitted and a little weight added to the rear of the chassis. Again the car was tested of the track and this time gave a best lap time of 12.50 seconds which is an improvement of 9.2%.

Step 4: Next a set of high grip replacement SuperSlix tyres were fitted to the rear wheel hubs. A retest gave a new best lap time of 9.99 seconds which is a further 20.1%.

Step 5: With the improvement made so far the next step was to replace the original Johnson motor with a new Mabuchi motor. This more powerful and lighter motor slightly increased the car’s lap time probably due to problems in getting the power down to the track. The best lap time recorded was 10.49 seconds which is a degradation of 0.5%.

Step 6: In order to give the car a chance to use the power available from the Mabuchi motor a Neodymium magnet was added to the chassis of the Escort. The best lap time achieved was 9.12 seconds which was an improvement of 25.5%

Step 7: Our final change was to add MAX Grip tyres as some tyre slip was clearly evident even with the Neodymium magnet present. These replacement SuperSlix tyres are manufactured from a latex material and give outstanding track grip. The best lap achieved a time of 6.44 seconds which was a further improvement of 25.5%

Conclusion

The overall improvement in lap times make this car competitive on the track while not removing any of the enjoyment and skill required. With these simple changes this car was almost a staggering 3 times faster than when purchased.

A more detailed account of the parts used and the results of each step can be can be found at Scalextric Car Restorations.

About the author:

Gary Harding has been working with Scalextric cars for over 30 years and now operates Scalextric Car Restorations in the UK. Scalextric Car Restorations is a Worldwide internet based business that offers for sale high quality Scalextric cars and Scalextric parts from the 1960s to the present day. All the restoration work is carried out to the highest standards with the highest quality parts available. Only the best cars are selected and the final result is a car that is genuinely like new.

Further help and advice relating to this article or Scalextric cars in general can be found at:

http://www.scalextric-car.co.uk

Scalextric tyres

Finding the right Scalextric tyres for your Scalextric cars can be a real problem.  They all seem to be black and round so pictures of the tyres are hopeless.  So, then there are application lists which are great if you know the C number of your car.  Also, how many application lists would you need to check before you find the right one?  There are over 40 commonly used Scalextric tyres for the older cars, let alone the newer cars.

To overcome this problem Scalextric Car Restorations have developed a unique tyre finder tool.  Simply type into a search box the C number or description of your Scalextric car and a list of matches is shown.  Each possible car is shown with its C number, description and a picture so you’ll be certain when you find your Scalextric car.  This database holds the details of 882 individual Scalextric cars made from 1960 to 2005.

 

When you’ve identified your Scalextric car the front and rear tyres are given.  This simple to use tyre finder tool can be used by anyone and expert knowledge about Scalextric cars is not required.

Another great innovation from Scalextric Car Restorations.

Scalextric front tyres tires for vintage Scalextric Javelin etc.

These new Scalextric tyres are remanufactured as direct replacements for the tyres fitted to the vintage Scalextric cars listed below from the late 1960 to the mid 1970s. They are produced from a high grip material allowing the cars full performance to be utilised and are especially good if these classic Scalextric cars are used on the modern smooth Scalextric Sport track.

They are hand moulded from 29 Shore A hardness rubber which is a very high grip material.

The tyres are treaded and have the words SCALEXTRIC RACING written on the tyre sidewall.

 

Ref.	Description	Fitment
C3	Javelin	Front
C4	Electra	Front
C10	Super Javelin	Front
C11	Super Electra	Front
C13	Tiger Special	Front
C15	Ford Mirage	Front
C16	Ferrari P4	Front
C17	Lamborghini Miura	Front
C18	Ford 3L GT	Front
C20	Dart	Front	Rear
C22	Porsche 917	Front
C23	Scaletti Arrow	Front
C34	Jaguar Type E	Front	Rear
C48	Tyrrell Ford 002 (Spanish narrow)	Front
YS103	Javelin	Front
YS115	Ford Mirage	Front
YS116	Ferrari P4	Front
YS117	Lamborghini Miura	Front
YS118	Ford 3L GT	Front

Another great product from Scalextric Car Restorations

Scalextric tyres tires for Scalextric Formula Junior cars and Austin Healey 3000

The new hand made MAX Grip tyres are unique to Scalextric Car Restorations and give the absolute maximum in performance at all times. Cornering and acceleration will all be at their maximum with these tyres. They give the very best performance possible on all track surfaces at all times. Simply put we have not yet discovered a better tyre for grip and race performance.

The MAX Grip tyres are hand moulded from 29 Shore A hardness rubber which is a very high grip material.

Ref.	Description	Fitment
C66	Cooper	Front	Rear
C67	Lotus	Front	Rear
C72	BRM	Front	Rear**
C73	Porsche 804	Front	Rear**
C74	Austin Healey 3000	Front	Rear
C81	Cooper	Front	Rear**
C82	Lotus 25	Front	Rear**
C85	BRM	Front	Rear**
C86	Porsche 804	Front	Rear**
C93	Austin Healey 3000 (Race Tuned)	Front	Rear

** Used on later cars

Another great product from Scalextric Car Restorations

How to service the RX motor in your Scalextric car

Maintain your Scalextric car’s RX motor with these simple hints and tips

Abstract

The earlier Scalextric cars produced in the 1960s were fitted with open frame motors the most common of which is known as the RX motor. This motor was also fitted to many of the Hornby locomotives of the period. This article shows how an RX motor can be serviced in a methodical way by considering the mechanical, electrical and magnetic aspects of the motor.

Introduction

The RX motor was fitted to most Scalextric cars from the 1960s. In order for your Scalextric car’s RX motor to give the best possible performance it has to be in the best possible health. Effectively giving the maximum torque for the electrical power available to it. For any electrical motor to give its best 3 key areas need to be considered; the mechanical condition of the motor, the electrical condition of the motor and the magnetic condition of the motor.

 

Mechanical

Mechanically the RX motor needs to be in the best condition possible to ensure that no energy is lost and the motor can transfer all of the generated torque to the rear axle. To do this several areas need to be reviewed:

• Firstly check and ensure that all the parts are present and undamaged. All missing or damaged parts must must be replaced.
• Check and ensure the motor armature spins freely with no rubbing or tight spots. This could be caused by missing or damaged bearings or a damaged motor housing.
• Review the motor pinion gear and ensure all the gear teeth are in good condition. Replace the pinion gear if gear teeth damage is found.
• Add a drop of oil to each of the bearing felt pads.
• Ensure the brush spring sleeve is present and in good condition. Replace if necessary.

Electrical

There are many electrical connections and contacts used on the RX motor. Each of these must be in good condition to ensure the best performance of the motor. To do this several areas need to be reviewed:

• Firstly check and ensure that the solder joint between the wire from the pick-up brush and the eyelet that fits over the brush spring sleeve is complete and sound. Replace or remake this joint if any of the wire strands are broken or not making contact.
• Inspect the eyelet for any dirt or metal oxides that may have formed over the years. Clean the brush spring back to clean shiny metal where it contacts the motor brush.
• Inspect the brush spring for any dirt or metal oxides that may have formed over the years. Clean the brush spring back to clean shiny metal where it contacts the motor brush and the screw that secures the magnet.
• Inspect and clean the motor brushes removing any dirt, oil and carbon deposits. Ensure the carbon block is present and securely attached to the brass strip. Clean the motor brushes back to clean shiny metal where they contact the brush spring and eyelet.
• Remove any dirt, oil and carbon deposits from between the commutator segments of the armature.
• Remove any dirt, oil and carbon deposits from the commutator.
• Check the three solder joints that secure the armature windings to the commutator, remake these joints if necessary.
• The electrical connections for a car with an RX motor are:
  • Contact: Track braid to track rail
  • Contact: Braid contact to track braid
  • Solder joint: Wire to braid contact
  • Solder joint: Motor brush sleeve to wire
  • Contact: Motor brush to motor brush sleeve
  • Solder joint: Motor brush carbon block to motor brush
  • Contact: Commutator to motor brush carbon block
  • Solder joint: Armature wire to commutator
  • Solder joint: Armature wire to commutator
  • Contact: Commutator to motor brush carbon block
  • Solder joint: Motor brush carbon block to motor brush
  • Contact: Motor brush to brush spring
  • Contact: Brush spring brass bolt
  • Contact: Brass bolt to eyelet
  • Solder joint: Eyelet to wire
  • Solder joint: Wire to braid contact
  • Contact: Braid contact to track braid
  • Contact: Track braid to track rail

Magnetic

The magnetic field used by the RX motor is provided by a permanent magnet at the rear of the motor. The magnetic field reaches the outside of the armature by the use of steel plates that are also used as the housing for the motor. To ensure the magnetic circuit is maintained the RX motor uses various materials to ensure the magnetic field is not reduced.

• Ensure the magnet is secured by the correct brass screw.
• Ensure both the steel housing plates make good tight contact with the magnet.
• Ensure the aluminum plate adjacent to the magnet is fitted correctly.
• Ensure the brass plate at the commutator end of the motor is fitted correctly.

General

Through experience we have found that some RX motors still do not perform well even with all of these checks completed. This may be caused by a weak magnet or internally damaged armature windings. These faults are outside the scope of this article. There are many other possible faults with the earlier cars with the open frame motors. This is intended as a simple fault finding guide only. If the information above does not resolve the fault then contact us for further information.

About the author:

Gary Harding has been working with Scalextric cars for over 30 years and now operates Scalextric Car Restorations in the UK. Scalextric Car Restorations is a Worldwide internet based business that offers for sale high quality Scalextric cars and Scalextric parts from the 1960s to the present day. All the restoration work is carried out to the highest standards with the highest quality parts available. Only the best cars are selected and the final result is a car that is genuinely like new.

Further help and advice relating to this article or Scalextric cars in general can be found at:

http://www.scalextric-car.co.uk

Scalextric slot car tyres and more grip

Scalextric cars and slot cars, just like real racing cars, depend on tyre grip for best race track performance.  The rear tyres of Scalextric cars have a huge amount of work to perform, they must drive the car forward and they must provide cornering force.

The rear of the Scalextric car slides outwards on corners when the forces become too much.  This is made worse by the fact that Scalextric cars have a fixed rear axle with no differential.  This means that the inside and outside rear tyre must travel at the same speed.  So, one or both, of the rear tyres must be slipping on the track while cornering.

The grip generated by the tyre (F) is proportional to the force pushing the tyre into the track (N).  This downward force is generally the weight of the car acting on the tyre plus any downward attraction caused by magnets acting on the tyre.  The proportionality is known as the friction (µ) between the two materials.

So, that gives us the mathematical formula:

Force = Friction x Normal force (F= µN).

So, to improve the grip and hence performance of your Scalextric cars there are only 2 items to work on, the friction between the tyre and the track and the downward force exerted on each rear tyre.  Modern Scalextric cars use a Neodymium magnet to give high values of N for the rear tyres which gives an instant increase in the grip of the tyres for no real weight increase.

Adding weight in the form of lead or other heavy metals is a long standing favourite too, especially if magnets are not allowed or don’t work, for example if a wooden track is used.  There is always a compromise with weight as this needs to accelerated and taken round corners too.

Working on the other part of the equation another technique is to increase the friction between the tyre and the track, often referred to as mechanical grip.  There are several ways to do this:

• Keep the track and the tyres dust free
• Remove any oxide that forms on the surface of the tyres
• Keep the tyres warm
• Use tyres with more grip

Anyone who has watched a Formula 1 race will know the importance of the tyres and the influence they can have on the car’s track performance.  Fitting the best tyres and keeping them in top condition is vital if you want your car to perform at it’s very best.

The MAX Grip range of Scalextric tyres produced by Scalextric Car Restorations do just that.  These tyres give the raw, physical grip that’s needed for best race track performance.

Another great aticle by Scalextric Car Restorations

New MAX Grip Scalextric tyres tires for the Scalextric cars, Camaro, Mustang, Corvette and Torino W8543

These new MAX Grip tyres are used on all the Chevrolet Camaro, Ford Mustang, Chevrolet Corvette and Torino Scalextric cars.

These new Scalextric tyres are remanufactured as direct replacements for the tyres fitted to the Scalextric cars listed below. They are produced from a high grip material allowing the cars full performance to be utilised and are especially good if these Scalextric cars are used on the modern smooth Scalextric Sport track.

They are hand moulded from 29 Shore A hardness rubber which is a very high grip material.

Ref.	Description	Fitment
C2399	Chevrolet Camaro		Rear
C2400	Chevrolet Camaro		Rear
C2401	Ford Mustang		Rear
C2402	Ford Mustang		Rear
C2436	Ford Mustang		Rear
C2437	Ford Mustang		Rear
C2502	Chevrolet Corvette		Rear
C2503	Chevrolet Corvette		Rear
C2508	Chevrolet Camaro		Rear
C2545	Ford Mustang		Rear
C2553	Torino		Rear
C2566	Chevrolet Corvette		Rear
C2575	Chevrolet Corvette		Rear
C2576	Ford Mustang		Rear
C2577	Chevrolet Camaro		Rear
C2653	Chevrolet Corvette		Rear
C2654	Chevrolet Camaro		Rear
C2656	Ford Mustang		Rear
C2739	Ford Mustang		Rear
C2740	Chevrolet Camaro		Rear
C2750	Chevrolet Corvette		Rear
C2759	Chevrolet Camaro		Rear
C2760	Ford Mustang		Rear
C2775	Ford Mustang		Rear
C2797	Ford Mustang		Rear
C2889	Chevrolet Corvette		Rear

 

Another great Scalextric spare part from Scalextric Car Restorations

 

New Scalextric tyres tires for the Scalextric GT cars

Announcing new MAX Grip Scalextric tyres in the 2000s for the Scalextric GT cars.

These new MAX Grip Scalextric tyres are remanufactured as direct replacements for the tyres fitted to the Scalextric cars listed below from the early 2000s. They are produced from a high grip material allowing the cars full performance to be utilised and are especially good if these Scalextric cars are used on the modern smooth Scalextric Sport track.

They are hand moulded from 29 Shore A hardness rubber which is a very high grip material.

 

Ref.	Description	Fitment
C2366	MG Lola		Rear
C2367	MG Lola		Rear
C2453	TVR Tuscan		Rear
C2454	TVR Tuscan		Rear
C2482	MG Lola		Rear
C2483	MG Lola		Rear
C2521	Lister Storm		Rear
C2532	TVR Tuscan		Rear
C2533	TVR Tuscan		Rear
C2570	Ford GT 2003		Rear
C2590	TVR Tuscan		Rear
C2591	TVR Tuscan		Rear
C2618	TVR Tuscan		Rear
C2630	Maserati MC12		Rear
C2632	Mercedes Benz McLaren SLR		Rear
C2644	Aston Martin DBR9		Rear
C2657	TVR Tuscan		Rear
C2658	Lister Storm		Rear
C2660	MG Lola		Rear
C2661	Ford GT 2003		Rear
C2678	Maserati MC12		Rear
C2728	Maserati MC12		Rear
C2734	Ford GT 2003		Rear
C2753	Mercedes Benz McLaren SLR		Rear
C2756	Mercedes Benz McLaren SLR F1 safety car		Rear
C2758	Aston Martin DBR9		Rear
C2784	Maserati MC12		Rear
C2790	Aston Martin DBR9		Rear
C2804	Ferrari F430		Rear
C2810	Lamborghini Gallardo		Rear
C2812	Porsche RS Spyder		Rear
C2818	Ferrari F430		Rear
C2822	Ferrari F430		Rear
C2823	Ford GT 2003		Rear
C2834	Lamborghini Gallardo drift		Rear
C2835	Ferrari F430		Rear
C2846	Ferrari F430		Rear
C2861	Lamborghini Gallardo drift		Rear
C2862	Lamborghini Gallardo drift		Rear
C2874	Ferrari F430		Rear
C2875	Lamborghini Gallardo drift		Rear
C2902	Ferrari F430		Rear
C2903	Aston Martin DBR9		Rear
C2906	Porsche RS Spyder		Rear
C2938	Ferrari F430		Rear
C2984	Ford GT 2003		Rear
C2996	Lamborghini Gallardo		Rear
C3006	Lamborghini Gallardo		Rear
C3009	Lamborghini Gallardo		Rear
C3012	Ferrari F430		Rear
C3075	Lamborghini Gallardo		Rear
C3078	Lamborghini Gallardo		Rear
C3086	Porsche RS Spyder		Rear

Another great new product from Scalextric Car Restorations

 

 

Scalextric tyres tires for the Ford Focus and Subaru Impreza Scalextric cars

Announcing the new MAX Grip Scalextric tyres tires for the Ford Focus and Subaru Impreza Scalextric cars.  These tyres were used extensively in the during the 2000s for the Scalextric Ford Focus and Subaru Impreza cars (W8492, W8280).

These new Scalextric tyres are remanufactured as direct replacements for the tyres fitted to the classic Scalextric cars listed below from the early 2000s. They are produced from a very high grip material allowing the cars full performance to be utilised and are especially good if these Scalextric cars are used on the modern smooth Scalextric Sport track.

They are hand moulded from 29 Shore A hardness rubber which is a very high grip material.

Ref.	Description	Fitment
C2175	Ford Focus	Front	Rear
C2176	Ford Focus	Front	Rear
C2341	Subaru Impreza	Front	Rear
C2342	Ford Focus	Front	Rear
C2343	Ford Focus	Front	Rear
C2362	Subaru Impreza	Front	Rear
C2393	Ford Focus	Front	Rear
C2405	Ford Focus	Front	Rear
C2406	Ford Focus	Front	Rear
C2411	Ford Focus	Front	Rear
C2412	Subaru Impreza	Front	Rear
C2414	Subaru Impreza	Front	Rear
C2427	Ford Focus	Front	Rear
C2428	Ford Focus	Front	Rear
C2471	Ford Focus	Front	Rear
C2488	Ford Focus Police car	Front	Rear
C2489	Ford Focus	Front	Rear
C2492	Subaru Impreza	Front	Rear
C2496	Ford Focus	Front	Rear
C2802	Ford Focus	Front	Rear
C2883	Ford Focus	Front	Rear
C2962	Ford Focus	Front	Rear

Another great product from Scalextric Car Restorations.

Scalextric tyres tires for the Porsche 911 GT3

Announcing the remanufacture of new Scalextric tyres tires for the Porsche 911 GT3, Opel V8 Coupe DTM, Mercedes DTM, Opel Astra and Maserati Trofeo Scalextric cars.  These tyres were used extensively in the during the 2000s for the Scalextric road and DTM cars (W8528).

These new Scalextric tyres are remanufactured as direct replacements for the tyres fitted to the Scalextric cars listed below from the early 2000s. They are produced from a high grip material allowing the cars full performance to be utilised and are especially good if these Scalextric cars are used on the modern smooth Scalextric Sport track.

They are hand moulded from 29 Shore A hardness rubber which is a very high grip material.

 

 

Ref.	Description	Fitment
C2268	Porsche 911 GT3		Rear
C2274	Porsche 911 GT3		Rear
C2297	Opel V8 Coupe DTM		Rear
C2297	Opel V8 Coupe DTM		Rear
C2338	Porsche 911 GT3		Rear
C2339	Porsche 911 GT3		Rear
C2391	Mercedes DTM		Rear
C2392	Mercedes DTM		Rear
C2409	Opel V8 Coupe DTM		Rear
C2410	Opel V8 Coupe DTM		Rear
C2429	Opel V8 Coupe DTM		Rear
C2430	Opel V8 Coupe DTM		Rear
C2461	Porsche 911 GT3		Rear
C2462	Porsche 911 GT3		Rear
C2474	Opel Astra		Rear
C2475	Opel Astra		Rear
C2480	Porsche 911 GT3		Rear
C2481	Porsche 911 GT3		Rear
C2504	Maserati Trofeo		Rear
C2505	Maserati Trofeo		Rear
C2528	Opel Astra		Rear
C2567	Mercedes CLK Digital		Rear
C2569	Opel Astra		Rear
C2592	Opel Vectra		Rear
C2593	Opel Vectra		Rear
C2659	Maserati Trofeo		Rear
C2664	Porsche 911 GT3R		Rear
C2665	Porsche 911 GT3R		Rear
C2665	Porsche 911 GT3R Digital		Rear
C2684	Opel Vectra		Rear
C2685	Opel Vectra		Rear
C2688	Maserati Trofeo		Rear
C2689	Maserati Trofeo		Rear
C2730	Porsche 911 GT3R		Rear
C2731	Porsche 911 GT3R		Rear
C2786	Porsche 911 GT3R		Rear
C2857	Porsche 911 GT3R		Rear

 

Another great new product from Scalextric Car Restorations