+++ DISCLAIMER +++
Nothing you see here is real, even though the conversion or the presented background story might be based on historical facts. BEWARE!
Some background:
The Société Nationale des Chemins de Fer Luxembourgeois (Luxembourg National Railway Company, abbreviated CFL) is the national railway company of Luxembourg. The Luxembourg rail system comprises (only) 275 route-kilometres (170 miles), of which 140 kilometres (87 mi) is double track and 135 kilometres (84 mi) single track. Of the total track length of 617 kilometres (383 mi), 576 kilometres (358 mi) are electrified at 25 kV, 50 Hz AC.
Luxembourg borders Belgium, France and Germany. Correspondingly, there are cross-border services into these countries. Some are wholly run by CFL, whereas others are run by SNCF, NMBS/SNCB and DB. CFL passenger trains cover most of the network and are operated by EMUs and electric locomotives, typically with push-pull stock. Despite a high degree of electrification, the CFL also had a fleet of diesel locomotives for hauling freight trains and for general shunting purposes. CFL.
The CFLs first electric locomotive, introduced in 1958, was the Class 3600, the so-called “fer à repasser” (= “electric iron”), a group of twenty electric locomotives that were built to the design of the French BB 12000 class. These were primarily intended for freight trains but also capable of pulling light passenger trains with up to 120 km/h (75 mph). The Class 3600 was originally designed to be capable of pulling 750 ton trains along a grade of 10 ‰, but in service it proved more than capable, frequently pulling 1100 tons and then even 1400 ton trains without problems.
However, for fast and heavier passenger trains, especially those that crossed the borders to Northern France with the same 25 kV, 50 Hz alternating current system as Luxembourg as well as to Germany with its 15 kV, 16.7 Hz electrification, the CFL ordered twelve additional dual system locomotive. They were more powerful and faster than the Class 3600 and became the new Class 3800 – roughly comparable with the German E 310/BR 181 dual system locomotives that were operated in the same region. The Class 3800 machines were designed and built between 1959 and 1961 in the Netherlands by Werkspoor in Utrecht, with technical support from the German Siemens-Schuckert-Werke (SSW) for the electric systems. They were heavily influenced by the contemporary Co′Co′ multipurpose Series 1200 electric locomotives for the Netherlands Spoorwegen (NS), originally designed by Baldwin and sporting typical American styling with a brawny silhouette, stepped “Cab unit” style nose sections and doors at the locomotives’ front ends to allow direct access to a coupled wagon from the driver cabins.
Even though they were based on the NS Series 1200, the CFL Class 3800 units used a shortened main frame and newly developed bogies with a Bo′Bo’ arrangement. All in all, the Class 3800 was more than 20 tons lighter than its Dutch six-axle sibling and only shared a superficial similarity – under the hood, the locomotive was technically totally different from the NS’ Series 1200 (which was designed for the Dutch 1.5 kV DC system).
The locomotives drew their energy from the 15 kV / 16 2/3 Hz or 25 kV / 50 Hz catenary via two diamond pantographs with contact strips of different lengths for the different areas of application. The 3-core transformers were oil-cooled, to which the control unit with its 28 running steps was connected. The acceleration was designed to function in delayed mode, where the engineer chose the running step, and the control unit would initiate the chosen setting independently. For emergency operation manual control by hand crank was possible, too. The voltage reached the main transformer via an air-operated main switch. On the secondary side, the traction motors were controlled via thyristors using stepless phase angle control, a modern technology at the time, as were the comparatively light mixed current motors. Mechanical switching mechanisms were therefore no longer required, and the vehicle control technology also worked with modern electronics. To ensure a good frictional connection between rail and wheel, the power converters always regulated a slightly lower tractive force on the preceding wheel sets of each bogie. If, however, one or more wheelsets slipped, the drive control reduced the tractive effort for a short time.
The CFL Class 3800’s four traction motors collective output was 3,700 kW (5,000 hp). This gave the Class 3800 a tractive effort of 275 kN (62,000 lbf) and a theoretical top speed of 150 km/h (93 mph), even though this was in practice limited to 140 km/h (87 mph). A time-division multiplex push-pull and double-traction control system was installed, too, so that two of these locomotives could together handle heavier freight trains and exploit the locomotives’ good traction. All locomotives featured an indirect air brake, with automatically stronger braking action at high speeds; for shunting/switching service an additional direct brake was present, too. All units featured a separately excited rheostatic/regenerative brake, which was coupled to the air brake. The heat generated by the electric brakes was dissipated via roof exhausts, supported by a pair of cooling fans.
The safety equipment in the driver's cab featured a mechanical or electronic deadman's device, punctiform automatic train controls, and train radio equipment with GSM-R communication. For operations in Germany the units received a third front light and separate red taillights, as well as an “Indusi” inductive system for data transfer between the track and locomotive by magnets mounted beside the rails and on the locomotive. Later in their career, automatic door locking at 0 km/h was retrofitted, which had become a compulsory requirement for all locomotives in passenger service.
After a thorough test phase of the pre-production locomotives 3801 and 3802 in 1960, the first Class 3800 serial units went into service in 1961 and were, due to the characteristic design of their driver’s cabins and their bulky shape, quickly nicknamed “Bouledogue” (Bulldog). The initial two locomotives were delivered in a pale blue-grey livery, but they were soon repainted in the CFL’s standard burgundy/yellow corporate paint scheme, and all following Class 3800 locomotives from 3803 on were directly delivered in this guise.
Initially, the service spectrum of the Bouledogues comprised primarily fast passenger trains on the CFL’s domestic main routes to the North and to the East, with additional border-crossing express trains, including prestigious TEE connections, to Germany (e. g. to Trier and Cologne) and France (Paris via Reims). The 3800s supplemented the CFL’s fast Series 1600 diesel locomotives on these important international destinations once they had been fully electrified. Occasionally, they were also used for freight trains in the industrial Esch-sur-Alzette region and for fast freight trains on the electrified main routes, as well as for regional passenger traffic on push-pull trains. Heavier freight trains remained the working field of the CFL Class 3600, even though occasional ore trains were handled by Class 3800 locomotives in double traction, too.
Even though Werkspoor hoped for more CFL orders for this dual-system type, the twelve Series 3800 locomotives remained the sole specimen. Potential buyers like Belgium or the Netherlands also did not show much interest – even though the SNCB ordered several multi-system locomotives, including eight indigenous Class 16 locomotives, equipped to run in France, Netherlands and Germany, or the six Class 18 four-system machines derived from the French SNCF CC 40100 express passenger locomotives.
During the Nineties the CFL started to use more and more EMUs on the domestic passenger routes, so that the Class 3800s gradually took over more and more freight train duties, relieving the older Series 3600s and replacing diesel-powered locomotives (esp. the Class 1800) on electrified routes. Border-crossing passenger train services were furthermore limited to trains to Germany since long-distance passenger train services in France switched to the TGV train system with its separate high-speed lines. Freight trains to France were still frequent Class 3800 duties, though, and occasionally coal trains were pulled directly to the industrial Ruhr Area region in Western Germany.
After the Millennium the Class 3800s gradually lost their duties to the new CFL Class 4000 multi-system locomotives, a variant of the Bombardier TRAXX locos found working across Europe. On 31 December 2006 the last Class 3800 (3809) was retired. Their versatility, robustness and performance have, however, allowed some of these locomotives to exceed 45 years of service. Bouledogue “3803” reached more than 9,2 million kilometers (5.7 million miles), a remarkable performance.
Only two 3800s had to be written off during the type’s career: 3804 suffered a major transformer damage and was destroyed by the ensuing fire near Troisvierges in Northern Luxembourg and 3810 was involved in a freight train derailment south of Differdange, where it was damaged beyond repair and had to be broken up on site. A single Class 3800 locomotive (3811) survived the retirement and has been kept as a static exhibition piece at the CFL Dépot at Luxembourg, the rest was scrapped.
General characteristics:
Gauge: 1,435 mm (4 ft 8½ in) standard gauge
UIC axle arrangement: Bo´Bo´
Overall length: 16.49 m (54 ft 1 in)
Pivot distance: 7,9 m (25 ft 10 in)
Bogie distance: 3,4 m (11 ft 1½ in)
Wheel diameter (when new): 1.250 mm (4 ft 1½ in)
Service weight: 83 t
Engine:
Four traction motors with a collective output of 3,700 kW (5,000 hp)
Performance:
Maximum speed: 150 km/h (93 mph), limited to 140 km/h (87 mph) in service
Torque: 275 kN starting tractive effort
164 kN continuous traction effort
The model and its assembly:
My second attempt to create a functional H0 scale what-if locomotive – and after I “only” did a color variant with some cosmetic changes on the basis of a Märklin V160/BR 216 diesel locomotive, I wanted something more special and challenging. However, kitbashing model locomotives with a metal chassis that includes a functional motor, respective drivetrain/gearing and electronics is not as easy as gluing some plastic parts together. And finding “matching” donor parts for such a stunt is also not as easy as it may seem. But what would life be without attempts to widen its boundaries?
This time I wanted an electric locomotive. Inspiration (and occasion) somewhat struck when I stumbled upon a running/functional chassis of a Märklin E 10/BR 110 (#3039), just without light and naturally missing the whole upper hull. Due to its incompleteness, I got it for a reasonable price, though. With this basis I started to watch out for eventual (and affordable) donor parts for a new superstructure, and remembered the collectible, non-powered all-plastic locomotive models from Atlas/IXO.
The good thing about the Märklin 3039 chassis was that it was just a solid and flat piece of metal without integrated outer hull elements, headstock or side skirts, so that a new hull could (theoretically) be simply tailored to fit over this motorized platform. Finding something with the exact length would be impossible, so I settled upon an Atlas H0 scale Nederlands Spoorwegen Series 1200 locomotive model, which is markedly longer than the German BR 110, due to its six axles vs. the E 10/BR 110’s four. Another selling point: the NS 1200’s body is virtually blank in its middle section, ideal for shortening it to match the different chassis. Detail of the Atlas plastic models is also quite good, so there was the potential for something quite convincing.
Work started with the disassembly of the static Atlas NS Class 1200 model. It's all-styrene, just with a metal plate as a chassis. Against my expectations the model's hull was only held on the chassis by two tiny screws under the "noses", so that I did not have to use force to separate it. The body's walls were also relatively thin, good for the upcoming modifications. The model also featured two nice driver's stations, which could be removed easily, too. Unfortunately; they had to go to make enough room for the electronics of the Märklin 3039 all-metal chassis.
Dry-fitting the chassis under the Class 1200 hull revealed that the stunt would basically work - the chassis turned out to be only marginally too wide. I just had to grind a little of the chassis' front edges away to reduce pressure on the styrene body, and I had to bend the end sections of the chassis’ stabilizing side walls.
To make the Class 1200 hull fit over the shorter BR 110 chassis a section of about 3 cm had to be taken out of the body’s middle section. The Class 1200 lent itself to this measure because the body is rather bare and uniform along its mid-section, so that re-combining two shortened halves should not pose too many problems.
To make the hull sit properly on the chassis I added styrene profiles inside of it - easy to glue them into place, thanks to the material. At this time, the original fixed pantographs and some wiring on the roof had gone, brake hoses on the nose were removed to make space for the BR 110 couplers, and the clear windows were removed after a little fight (they were glued into their places, but thankfully each side has three separate parts instead of just one that would easily break). PSR on the seam between the hull halves followed, plus some grey primer to check the surface quality.
Even though the new body now had a proper position on the metal chassis, a solution had to be found to securely hold it in place. My solution: an adapter for a screw in the chassis’ underside, scratched. I found a small area next to the central direction switch where I could place a screw and a respective receiver that could attached to the body’s roof. A 3 mm hole was drilled into the chassis’ floor and a long Spax screw with a small diameter was mated with a hollow square styrene profile, roughly trimmed down in length to almost reach the roof internally. Then a big lump of 2C putty was put into the hull, and the styrene adapter pressed into it, so that it would held well in place. Fiddly, but it worked!
Unfortunately, the pantographs of the Atlas/IXO model were static and not flexible at all. One was displayed raised while the other one was retracted. Due to the raised pantograph’s stiffness the model might lose contact to or even damage the model railroad catenary, even when not pulling power through it – not a satisfactory condition. Since the chassis could be powered either from below or through the pantographs (the Märklin 3039 chassis offers an analogue switch underneath to change between power sources) I decided to pimp my build further and improve looks and functionality. I organized a pair of aftermarket diamond pantographs, made from metal, fully functional and held in place on the model’s roof with (very short and) small screws from the inside.
I was not certain if the screws were conductive, and I had to somehow connect them with the switch in the chassis. I eventually soldered thin wire to the pantographs’ bases, led them through additional small holes in the roof inside and soldered them to the switch input, with an insulating screw joint in-between to allow a later detachment/disassembly without damage to the body. There might have been more elegant solutions, but my limited resources and skills did not allow more. It works, though, and I am happy with it, since the cables won’t be visible from the outside. This layout allows to draw power through them, I just had to create a flexible and detachable connection internally. Some plugs, wire and soldering created a solution – rough (electronics is not my strength!), but it worked! Another investment of money, time and effort into this project, but I think that the new pantographs significantly improve the overall look and the functionality of this model.
Internally, the missing light bulbs were retrofitted with OEM parts. A late external addition were PE brass ladders for the shunting platforms and under the doors for the driver’s cabins. They were rather delicate, but the model would not see much handling or railroading action, anyway, and the improve the overall impression IMHO a lot. On the roof, some details like cooling fans and tailored conduits (from the Atlas Series 1200) were added, they partly obscure the seam all around the body.
Unfortunately, due to the necessary space for the chassis, its motor and the electronics, the driver stations’ interiors could not be re-mounted – but this is not too obvious, despite the clear windows.
Painting and markings:
Finding a suitable operator took some time – I wanted a European company, and the livery had to be rather simple and easy to create with my limited means at hand, so that a presentable finish could be achieved. Belgium was one candidate, but I eventually settled on the small country of Luxembourg after I saw the CFL’s Class 3600s in their all-over wine-red livery with discreet yellow cheatlines.
The overall basic red was, after a coat with grey primer, applied with a rattle can, and I guesstimated the tone with RAL 3005 (Weinrot), based on various pictures of CFL locomotives in different states of maintenance and weathering. Apparently, the fresh paint was pretty bright, while old paint gained a rather brownish/maroon hue. For some contrast, the roof was painted in dark grey (Humbrol 67; RAL 7024), based on the CFL’s Class 3600 design, and the pantographs’ bases were painted and dry-brushed with this tone, too, for a coherent look. The chassis with its bogies and wheels remained basically black, but it was turned matt, and the originally bare metal wheel discs were painted, too. The visible lower areas were thoroughly treated with dry-brushed red-brown and dark grey, simulating rust and dust while emphasizing many delicate details on the bogies at the same time.
The hull was slightly treated with dry-brushed/cloudy wine red, so that the red would look a bit weathered and not so uniform. The grey roof was treated similarly.
The yellow cheatlines were created with yellow (RAL 1003) decal stripes from TL Modellbau in 5 and 2mm width. Generic H0 scale sheets from the same company provided the yellow CFL logos and the serial numbers on the flanks, so that the colors matched well. Stencils and some other small markings were procured from Andreas Nothaft (Modellbahndecals.de).
After securing the decals with some acrylic varnish the model was weathered with watercolors and some dry-brushing, simulating brownish-grey dust and dirt from the overhead contact line that frequently collects on the roof and is then washed down by rain. Finally, the whole body was sealed with matt acrylic varnish from the rattle can – even though it turned out to be rather glossy. But it does not look wrong, so I stuck with this flaw.
Among the last steps was the re-mounting of the clear windows (which had OOB thin silver trim, which was retained) and head- and taillights were created with ClearFix and white and red clear window color.