SBB-CFF-FFS Ce 6/8 I explained

Ce 6/8I 14201
Powertype:Electric
Builder:Brown, Boveri & Cie (BBC)
Schweizerische Lokomotiv- und Maschinenfabrik (SLM)
Builddate:1919
Totalproduction:1
Aarwheels:2-6-6-2
Uicclass:(1′C)(C1′)
Wheeldiameter:13500NaN0
Trailingdiameter:8500NaN0
Length:192400NaN0 buffers
Height:44500NaN0
Weightondrivers:99tonne
Locoweight:118tonne
Electricsystem: catenary
Collectionmethod:Pantograph
Tractionmotors:Four
Transmission:Winterthur drive
see text
Multipleworking:Not available
Maxspeed:650NaN0
Poweroutput:Continuous: 1440kW at 440NaN0
One hour: 1750kW at 410NaN0
Locobrakes:Air
Mechanical hand brake
Trainbrakes:Air
Operator:SBB
Fleetnumbers:14201
Nicknames:Köfferlilok
(due to the small cabinets on both ends)
Deliverydate:7 July 1919
Firstrundate:December 1919
Lastrundate:1982
Retiredate:1982
Withdrawndate:1982
Preservedunits:1
(Museum object)
Currentowner:Verkehrshaus der Schweiz

The Ce 6/8 I 14201 was one of four test locomotives ordered by the Schweizerischen Bundesbahnen (Swiss Federal Railways) (SBB) in June 1917. For gaining experience for ordering electrical locomotives this locomotive should – as its three siblings Be 3/5 12201, Be 4/6 12301 and Be 4/6 12302 – have been used for services on the Gotthardbahn (Gotthard railway). The development of freight locomotives subsequently took a completely different way which was not conceivable at the ordering date (see Ce 6/8II). The Ce 6/8I came into service only after the first Ce 6/8II.

History

In November 1913 the executive board of the Schweizerischen Bundesbahnen (Swiss Federal Railways) (SBB) decided to electrify Gotthardbahn (Gotthard railway) from Erstfeld to Biasca. Coal shortages resulting from World War I progressively forced the SBB to reduce schedules to the point where, in the autumn of 1918, only milk trains ran on Sundays. In response, the SBB hastened the electrification of the Gotthard railway line, among other important lines. This electrification was completed in 1920. For the traction on those lines, the SBB urgently needed passenger and freight locomotives.

Requirement specifications

The SBB put forward the following requirements:

Commissioning and proposal

The contract was awarded as follows:

Beside the compliance with the requirements specifications the designers got big freedom in the work out of their designs.

Delivery date

The locomotive was delivered at 7 July 1919. The scheduled services started only in December 1919 (nota bene one week after the first Ce 6/8II Crocodile was delivered).

Technical details

The mechanical part

Running gear

The running gear consisted of two bogies. In both bogies three drive-axles and a jackshaft were installed. The center drive-wheel had a side play of 2×25 mm. At the outer side of each bogie an idle-axle was mounted. This idle-axle was designed as an Adams axle and had a side-play of 2×31 mm relative to the bogie. Small cabinets were mounted on the outer part of the bogie frames.

Transmission of tractive force

The tractive force was transmitted from the drive-axles to the bogies. From there the force was carried over to the bogie-mounted towing hook and the buffers. In between the bogies were connected with a spring-loaded coupling similar to the tender coupling at steam locomotives. The locomotive body was not engaged in the transmission of tractive force.

Drive

Two motors were mounted in each bogie frame. They were located between the second and third drive-axle. The motors drove big cogwheels in the jackshaft over spring-loaded sprockets. The crank pin of the jackshaft drove over inclined connecting rod a pin mounted on the triangle-shaped coupling rod which connected the first and the second drive-axle. This pin was located close to the crank pin of the first drive-axle. A second coupling rod connected the second and the third drive-axles. This drive is known as Winterthurer Schrägstangenantrieb (Winterthur drive with inclined connecting rod).

Locomotive body

The locomotive body consisted of single bridging slab. On this slab the body parts were fixed with screws. The bridging slab laid on the bogies using pivot bearings. To prevent the transmission of tractive forces over the body the bearings had longitudinal play. Beside these two spring-loaded bearings were mounted. The locomotive body was almost identical to the one of the Be 4/6 12302.

Braking equipment

The automatic Westinghouse air brake and the locomotive brake acted in both bogies to both sides of the driving wheels of each drive-axle. The idle-wheels did not have brakes. Each cab was equipped with a handbrake which acted to the respective bogie.

Electrical part

Primary circuit

Two diamond-shaped pantographs – controllable with a valve in each cab – led the current from the catenary to the two main knife switches on the roof of the locomotive body. From these main knife switches the current was transferred to the Earthing knife switch. This was then led to the oil-cooled transformer over a lightning protection inductor and the oil-propelled main switch. The transformer was located in the center of the locomotive body. The huge lightning protection inductor was removed later since the practical experience showed that it was not necessary.

The cooling of the oil of the transformer occurred over a tube systems on both sides of the locomotive body by the use of an oil pump. These tubes were cooled by the air flow and the fan apertures in the body behind the tubes. These tubes were the main part of the very distinctive appearance of the locomotive as the Be 4/6 12302 and their successors Be 4/6 12303-12342.

The stepping switch transmitted the traction current to the motors which were connected in series circuit. The flat track stepping switch was mounted to the transformer. It consisted of 18 steps with voltages between 230 V and 1300 V. For both motor groups a reverse switch was mounted.

Auxiliary systems

The subsequent listed auxiliary systems were fed from the lowest tap of the transformer over a main fuse:

The train heating system was powered directly from the transformer with 1000 V over an electro-pneumatical hopper.

The control and lighting circuits were fed from the batteries with 36 V DC. The motor-generator for battery charging was mounted in the cabinet II.

Electrical brake

The locomotive was designed first with six drive-axles. Because of the weight limit it was not possible to install an electrical brake. However, for the long steep slopes such a brake would have been beneficial.

But shortly after the first runs a regenerative brake was installed 1920 and – at the beginning only with two motors – tested between Kandersteg und Frutigen on the Lötschbergbahn. The outcome was encouraging. The equipment was then completed for service on the Gotthardbahn (Gotthard railway).

The principle was as follows: A rotating phase converter fed the stators of the motors. In this way the activated rotors fed back the current through the transformer to the catenary.

The brake was extremely efficient. It was possible to hold 300 t at 26 ‰ in steady conditions. But the design was complicated and the operation was difficult. As a result, huge flashovers occurred from time to time. Several explosions in the main switch occurred too. Therefore, the equipment was removed in 1931.

Multiple-unit control

The locomotive was not equipped with a multiple-unit control.

Service

The Ce 6/8I started with scheduled services at December 1919. She led freight and commuter trains between Bern and Spiez.

20 January 1920 the SBB commissioned the locomotive. From March 1920 until October 1920 the regenerative brake was tested between Kandersteg und Frutigen.

As Ce 6/8I 14201 it continued the scheduled service at 18 October 1920. The trips never went further than to Spiez. March 1921 the locomotive was relocated to the Gotthard.

The Ce 6/8I started its scheduled service almost at the same time as the first Ce 6/8II. The second one followed short time after. There was nothing more to test anymore than the regenerative brake. Therefore, the designation "prototype" – even used sometimes in the technical literature – was wrong since the design of the Ce 6/8II was completely new.

At the beginning the locomotive started its services from the depot of Erstfeld. It was jointly scheduled in services with the Ce 6/8II. From 1925 until 1930 it was assigned to the depot of Biasca. Its duties were boost services ahead of trains between Biasca and Airolo at the southern end of the Gotthard rail tunnel. For this services the regenerative brake was a big advantage. With this brake the locomotive was able to return single to Biasca.

After the removal of the regenerative brake the locomotive returned 1931 to Erstfeld. 1938 it was relocated to the depot of Basle. There she was leading miscellaneous freight trains. The locomotive drivers did not like the quite poor running characteristics. On the other hand, they had to admit that they liked the high tractive force at lower speeds.

In 1961 two motors were damaged heavily. Since the EXPO 64 (Swiss National Exhibition/Schweizerische Landesausstellung) was very close it was decided to re-coil the defective motors. During this repairing action the locomotive was used in the Ticino canton. The two defective motors were replaced by ballast weights. Subsequently, the two motors were mounted again and the two others were revised.

After this action the performance of the locomotive was still very remarkable:

Later the performance decreased rapidly:

At the end of its career the locomotive was used up to 1982 test locomotive for brake tests. It was then handed over to the Verkehrshaus der Schweiz. Together with the locomotives of the test operation between SeebachWettingen she represents the initiation of the electric traction. At that moment the locomotive had covered a distance of 2,500,000 km.

References