Hollow shaft drive

Comparison with the peg bearing drive

The hollow shaft drive is mostly used for high-speed locomotives and railcars because of the higher manufacturing costs (speeds above about 140 km / h). A simpler type of drive is the paw-bearing drive .

The Deutsche Bundesbahn has been using hollow shaft drives since the standard electric locomotive for all of the electric locomotives it built, as the pawl bearing drive wears down the route excessively due to the high unsprung masses. With the separation into DB Netz AG and various independent operating companies, there is no longer this joint responsibility, so that Deutsche Bahn AG is once again procuring locomotives with peg bearing drives.

For this reason, the Swiss Federal Railways ( SBB) have been charging train-path fees based on wear and tear since 2017, classifying traction vehicles with peg bearing drives at the highest level.

Drive variants

Westinghouse spring drive

B&H alternating current locomotive 2503, 1360 HP, wheel arrangement (1'Bo) (Bo1 '), built in 1910

The Westinghouse spring drive is the oldest type of hollow shaft drive with a spring clutch.

It was developed by Westinghouse in the years up to 1912 for the New York, New Haven and Hartford Railroad as a competitor to General Electric's rubber buffer power transmissions .

It was used, for example, in the USA on the locomotives of the Boston and Maine Railroad from 1910, which were originally numbered 2501 to 2505 , and on the well-known GG1 class of the Pennsylvania Railroad from 1935 to 1943. The Geneva-based Sécheron manufactured the Westinghouse drive under license and developed it further into the Sécheron spring drive .

Sécheron spring drive

ÖBB 1245 511-9 in Selzthal station in 1994

Sécheron spring drive

The Swiss Société Anonyme des Ateliers de Sécheron in Geneva, colloquially known as Sécheron , or SAAS for short, further developed the Westinghouse drive into the Sécheron spring drive . Sécheron replaced the six individual clock springs, the evolute springs, per wheel of the Westinghouse drive with three double spring elements. The clutch springs were thus less stressed and the space for the springs was better used. As a result, smaller wheel diameters than with the Westinghouse drive were possible and the way was cleared for use in the bogies of railcars .

The Sécheron spring drive is characterized by low maintenance costs, especially since it has been possible to weld broken drive springs together.

The first Sécheron spring drives were used for the first time in the frame locomotive Be 4/7 of the Swiss Federal Railways in 1921 . They were originally intended for express train service on the Gotthard mountain route . The frame locomotives Ae 3/5 and Ae 3/6 III of the Swiss Federal Railways also have this drive. A highlight of its use is the frame locomotive Be 6/8 built from 1926 , the later Ae 6/8 of the BLS .

With the Westinghouse and Sécheron spring drives, the firmly clamped springs are subjected to considerable bending stress at higher speeds. This disadvantage is avoided, for example, by the AEG Kleinow spring pot drive described below .

Spring cup drive

An early further development of the Westinghouse drive was the spring cup drive (e.g. the "AEG Kleinow spring cup drive") with which the Deutsche Reichsbahn built the series E 04 (from 1933), E 17 (from 1928) after a few prototypes. , E 18 (from 1935) and E 19 (from 1938).

Spring cup drive from Maschinenfabrik Oerlikon (MFO)

For this drive, six protruding spokes are usually attached to the hollow shaft, the ends of which lead outwards like cantilevers between the wheel spokes. On the outside of the wheel spokes there are coil springs mounted in cup-shaped sockets , each of which is articulated to the hollow-shaft spoke ends. The spoke star and wheel spokes are offset by 30 ° to each other. With this arrangement, the motor rotation is transmitted to the wheels, with both the jerky motor torque when switching on for starting or a gear change while driving is damped relative to the wheel body. In addition, these springs compensate for the relative movements between the wheel set and the hollow shaft mounted in the frame during compression and due to the lateral displacement in the arc.

The steel springs showed themselves to be very susceptible to spring breakage after a long period of operation. The German Federal Railroad replaced them with more modern rubber parabolic springs. With this measure, the top speed of the German E 18 and E 19 series electric locomotives, which was limited to 120 km / h in the post-war period, could be increased back to 140 km / h.

Rubber ring spring drive

The rubber ring spring drive is a further development of the spring cup drive. The drive motor is sprung and supported by the bogie frame and the hollow shaft of the drive wheel set. This type of drive also makes it easier to start off under heavy loads. However, the spring action is only reliable up to a speed of around 160 km / h, and there is a risk of spring breakage. The rubber ring spring drive was first used in Germany on the Deutsche Bundesbahn from 1956 in the group of standard electric locomotives with the series E10 , E40 , E41 and E50 (second batch). This drive is still used in the 111 and 151 series .

The power transmission from the drive motor to the wheel takes place first via a gear on a hollow shaft that surrounds the axle shaft of the wheelset . Several hard rubber elements, so-called rubber ring spring segments (also called rubber segment springs) are attached to both ends of the hollow shaft . These are attached to the wheel disc in a circle on the inside of the wheel set. In some cases these rubber elements also reach through wheel spokes and are attached to them. Thus, an elastic inner and by the friction of rubber elements torsional damping torque transmission in which also the driving motor against shock when riding over results track rugged landscape is better protected.

Joint mechanism with "dancing ring"

At the end of the 1920s, Alstom developed a drive with a spring-loaded gear wheel, hollow shaft, Anneau dansant (French for "dancing ring") and articulated lever. The power is transmitted from the hollow shaft to the wheel set outside the wheel set via a flange-shaped ring that is connected to the hollow shaft by pins that are guided through holes in the wheel disc. The ring is elastically connected on the outside of the wheel with levers that engage pins in the wheel disc. This shape allows for height compensation and smooth start-up without overstressing the electric motors.

The design of the levers is slightly different depending on the design. In the Alstom drive, the ring is connected to the wheel disc with four straight levers, while the version used in Italy only has two lever systems arranged at right angles.

Cardan rubber ring spring drive

With the cardan rubber ring spring drive, the drive motors are built directly into the bogie to keep the unsprung masses small. This dampens the strong bumps in the road at high speeds and compensates for the movements between the wheelset and the drive motor. A well-known representative of this drive is the 103 series .

BBC shaft drive

Hollow shaft drive of the BR 143

The BBC cardan drive is the further development of the cardan rubber ring spring drive. For the development of the DB series 120 , thanks to the uniform torque of the three-phase asynchronous travel motors, the rubber ring springs mounted on the outside of the wheel discs were no longer necessary. All that remained was a drive via the hollow shaft and the rubber-mounted handlebars mounted on the inside of the wheel. The wheels were also equipped as monobloc wheels . Tests were carried out beforehand on the test field and with the Henschel BBC DE 2500 . With the DB class 120, it was possible for the first time to achieve an output per wheelset of 1.4 MW. The basis for this was the higher speed of the three-phase asynchronous machine compared to the single-phase series motor with commutator . Then it was possible to build a four-axle locomotive with a total mass of 84 tons with 6 MW power.

The BBC cardan drive is the basis for the drives of the following series 101 and ICE 1 .

Conical ring spring drive

For the German Reichsbahn developed in the GDR , the locomotive electrotechnical works (LEW) their own version of the hollow shaft drive. An electric drive motor, which is completely cushioned, acts on each axle. Gears arranged on both sides in connection with rubber conical ring springs enable elastic torque transmission. The drives are used in the 112, 114, 143 , 155 and 156 series.

Sécheron cardan lamella drive

The lamellar spring drive is a special form, also a development by the Sécheron company. It consists of a hollow armature shaft, which is connected to a torsion axis on both sides via drivers. This torsion axle drives an axle reduction gear, so the drive is a hybrid of a hollow shaft drive and a journal drive. The drivers, two of which are offset crosswise, are connected to the eponymous lamellae, bundles of thin sheet metal strips, and thus take over the cushioning and torque transmission of the motor, similar to a wedge pack coupling. This drive was used, for example, in Düwag cars of the Vestische tram and in railcars of the ÖBB series 4030 and 1046 .

Other drives

• Buchli drive
• SLM universal drive
• Single axle drive
• Rod drive

Individual evidence

1. ↑ Base price wear in the track price 2017. Accessed on July 3, 2018 . 
2. ↑ Lexicon of the Railway. Transpress VEB Verlag for Transport, Berlin, 1978, page 829
3. ^ Hans-Peter Bärtschi: Electric locomotives from Swiss factories. In: Verkehrshaus der Schweiz (Ed.): Coal, electricity and rails: The railroad conquers Switzerland. Verlag NZZ, Zurich 1998, ISBN 3-85823-715-9 , page 274
4. ^ Karl Sachs: The Swiss development in the construction of electric locomotives for adhesion operation . Schweizerische Bauzeitung, Volume 73 (1955), Issue 42, Page 641. (E-Periodica)
5. ^ Association of Historical Railways Emmental, data sheet BDe 4/4 240 (PDF; 1.6 MB)
6. ↑ Wolfgang Messerschmidt “Lokomotivtechnik im Bild”, 1991, Motorbuchverlag Stuttgart, ISBN 3-613-01384-3 , page 79
7. ↑ Transmission á anneau dansant. Larousse, accessed May 29, 2016 (French, information graphics). 
8. ^ Ingegneria ferroviaria - La corsa prova della E.444. In: www.miol.it. Retrieved on May 28, 2016 (Fig. 8 shows the arrangement of the drive). 
9. ↑ Messerschmidt Lokomotivtechnik in the picture , Motorbuchverlag Stuttgart, 1991, ISBN 3-613-01384-3 , page 86

literature

• Bäzold, Obermeyer: The series E 04 and E 17 and the test locomotives E 05, E 05.1, E 15, E 16.5, E 21 and E 21.5 . Railway Journal IV / 1993.
• Bäzold, Obermeyer: The E 18 and E 19 . Railway Journal IV / 1992.
• K. Sachs: On the development of electric locomotives and railcars in Switzerland . Schweizerische Bauzeitung, Volume 65 (1947), Issue 26, Pages 362–363, Photo Page 361 (E-Periodica). with picture of the Sécheron spring drive
• Wolfgang Messerschmidt: Locomotive technology in the picture . Steam, diesel and electric locomotives . Motorbuch, Stuttgart 1991, ISBN 3-613-01384-3 , p. 52-54 . 

Web links

• Hollow shaft drive