FS E.323 and E.324 explained

FS locomotives E.323 and E.324
Powertype:Electric
Builder:Tecnomasio
Builddate:1st series: 1966-1967; 2nd series: 1970-1971.
Totalproduction:30 E.323 + 10 E.324
Uicclass:C
Wheeldiameter:1040mm
Leading:4000mm (1500+)
Length:9240mm
Height:3700mm
Locoweight:46t
Powersupply:Direct current at 3 kV
Gear Ratio:1:15.8 (Vmax32abbr=onNaNabbr=on);
1:7.54 (Vmax 64abbr=onNaNabbr=on).
Maxspeed:64km/h
Poweroutput 1 Hr:210kW
Poweroutput Cont:190kW
T/E Starting:147kN
T/E 1 Hr:91.2kN at 6.66km/h
T/E Continuous:82.4kN at 7.44km/h

The E.323 locomotives and E.324 motor trailers were two sets of 3000 V direct current electric locomotives of the Italian State Railways (FS) used for shunting service in large rail yards and in embarking and disembarking from ferries.

Unlike the E.323s, the E.324s were locomotives lacking the driver's cab and pantograph and were used in double traction with multiple control with the former to double their performance.

They constituted the sequel to the FS E.321 and E.322 classes, of which they resumed the design of the electrical part, updated on the basis of experience in operation and technological advances, while the mechanical part was designed from scratch.[1]

In the early 1970s, as part of a collaboration between the FS and the Faculty of Engineering of the University of Rome "La Sapienza," it was decided to use a unit from the E.323 class to develop the design and testing of an electronic converter suitable for powering a three-phase traction motor, an idea later abandoned as a result of developments in power electronics related to the design of the E.402 locomotives. This would have been the world's first application of a three-phase traction motor to a 3 kV DC locomotive.

History

Project

In the second half of the 1960s, the good operating results achieved by the E.321 and E.322 prompted the FS to extend the use of electric locomotives in shunting service. In developing the project, it was decided to keep the electrical part of their progenitors while it was decided to build from scratch the mechanical part (carriage, running gear and brake steering) following the design of the unified 245 locomotives (245.1001-1020, 2001-2020, 6010-6124). This solution, keeping the same GLM 2405 engine as the E.321 and E.322, made it possible to use a transmission with universal joints and telescopic shafts and to arrange the gearbox assembly with two gear ratios: the first to have a speed of 32km/h suitable for shunting and the second to achieve a speed of 64km/h suitable for hauling traction[2] and for full line movements. The design, as with the E.321 and E.322, was developed by the FS with the collaboration of the Tecnomasio Italiano Brown Boveri (TIBB).[3]

Construction

The construction of the electrical and mechanical parts was entrusted to Tecnomasio Italiano Brown Boveri. As with E.321, "motor trailers" controlled by E.323 and classified as E.324 were also designed and ordered, identical to the same E.323 but without a driver's cab (for this feature they were called "dogs" like E.322). Subclasses E.323.001-010 and 011-020 (delivered in 1966 and 1970–71), E.323.101-105 (delivered 1966-1967), E.323.201-205 (delivered 1971), E.324.101-105 (delivered 1966-1967) and E.324.201-205 (delivered 1971) were built.[4]

Given the previous experience with E.321.200 and E.322.200, E.323.200 was designed and built with the ability to remote control two E.324.200s.[5]

Between April and October 1967 the E.323.105, along with other locomotives, passenger railroad cars and wagons was exhibited in major Italian stations to present to the general public the renewal of the rolling stock underway as a result of the FS's Ten-Year Modernization Plan (1962-1972).[6] [7]

Maintenance

Locomotives E.323 and E.324 were subjected to a major repair every 40000 hours of service. In the middle of the interval an "R III" repair was interspersed, which did not involve complete disassembly of the car.[8] [9]

Operation

Services

The E.323 and E.324 were always employed in shunting service, gradually going to replace the last steam shunting locomotives in the process of being phased out, flanking the Diesel locomotives and their direct progenitors E.321 and E.322, which had demonstrated full responsiveness to the onerous continuous duties on the launching saddles of the large marshalling yards.[10]

In addition to services on the sidings of the station they were employed continuously in marshalling yards and in ferry boarding of trains to and from Sicily at Messina Marittima and Villa San Giovanni stations.[11] [12]

Because of their characteristics, they were only occasionally used for traction of the troop trains[13] and in the middle of the line.[14]

Performance in shunting service

The performance in shunting service of the E.323 and E.324 locomotives is shown in the following table, taken from the General Preface to the Timetable of Service (PGOS)[15] of the State Railways, which expresses the load in tons that can be hauled by the locomotives in shunting service, depending on the track gradient.

Class !! colspan="6"
Gradient ‰ !PowerHP
3 6 10 15 20 25
E.321
E.322 (1)
740 550 400 300 240 190 260
E.323
E.324 (1)
1050 770 560 420 340 260 260
(1) For the pairs E.321 + E.322 and E.323 + E.324, the performance is twice as much as shown in the table.
Performance on the line

The performance in traction and full-line service of E.323 and E.324 locomotives is shown in the following table, taken from the General Preface to the Timetable of Service (PGOS) of the State Railways, which expresses the load in tons that can be hauled by locomotives in full-line service as a function of performance grade.[16]

Speed !! colspan="24"
Performance grades of the lines
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24
50 km/h 65 60 55 50 45 40 35 30 25 25
40 km/h 145 135 125 120 110 110 95 90 80 75 65 60 55 50 45 40 35 30 25 20
35 km/h 210 200 185 175 165 160 145 135 125 115 105 95 85 80 75 70 60 55 50 45 40 40 35 30
30 km/h 310 290 270 255 240 225 210 200 180 165 150 140 130 120 110 105 95 90 80 75 70 65 60 55
25 km/h 440 410 385 360 340 320 300 280 260 240 220 200 190 180 170 160 145 130 120 110 105 100 95 90
20 km/h 620 570 535 500 475 450 425 400 370 340 315 290 270 250 235 220 205 190 180 170 160 150 140 130
(1) For the pairs E.321 + E.322 and E.323 + E.324, the performance is twice as much as shown in the table.

Depots

In January 1985, units of the E.323 and E.324 groups were distributed to the following depots:[17]

On December 31, 1991, all units of the E.323 and E.324 classes were still in service distributed in the following depots:[18]

According to Haydock[19] in 1995 all units of both groups still existed and were assigned as follows:

Shelving and decommissioning

As of January 30, 2000, all units were in service, namely, thirty E.323s, assigned to the FS Regional (16), Passenger (3) and Cargo (11) Divisions and ten E.324s, assigned to the FS Regional (2), Passenger (2) and Cargo (6) Divisions.[20] [21]

They were shelved starting in 2002[22] and decommissioned between October 2002 and June 2009.[23]

To this day, locomotive E.323.010 still remains shelved for years at the Rimini Locomotive Depot in rather poor condition.[24]

Museum preservation

There still exists the E.323.105+E.324.105 complex in consignment to the amateur association AISAF based in Lecce.[25]

Features

On the basis of the favorable operating results of the E.321 and E.322 locomotives, which resulted in appreciable savings compared to the cost of Diesel traction units, the FS decided to purchase an additional batch of similar units, for which, however, a completely new mechanical part was developed to meet all the requirements of shunting service.[26]

For the same reasons mentioned about the E.321 the Ward Leonard type scheme was retained[27] using the same electrical machinery: 260kW double-commutator primary engine powered at 3 kV, main generator[28] of TIBB-CGE construction of 210kW power at 1,250 rpm, at 460 V voltage and traction motor developing at continuous speed a power of 190kW as well as at hourly speed a power of 210kW. The only variation introduced was the adoption of field weakening[29] on the traction motor.[30]

Significantly, without modifying the electrical machinery, the adoption of the two-speed gearbox assembly and the introduction of field weakening resulted in a significant increase in performance over the E.321 and E.322 locomotives, as can be seen from the extract from Table 45 of the PGOS given in the Services section.

Mechanical part

Despite the excellent operating results mentioned above, the E.321 and E.322 locomotives suffered from the limitations imposed by an outdated mechanical part design, which was penalized by the connecting rod transmission and internal bushings with plain bearings.[31]

In the design of E.323 and E.324 it was decided to overcome these drawbacks by adopting the same mechanical part developed for the new "unified" Diesel locomotives[32] of class 245, characterized by:[33]

The gearbox unit was connected to the traction motor by means of a coupling with rubber spring elements and activated the drive decks[35] (Hurt type HSK 19) mounted on each locomotive wheelset with universal joints.

In shunting, the slow gear was normally used, which allowed the highest tractive efforts to be generated up to the speed of 32km/h; in isolated locomotive trips or with limited load, the fast gear was used, which allowed up to 64km/h with the tractive effort halved.[36]

Switching between the two speed ranges could take place only when the locomotive was stationary by means of an electropneumatic device, which also allowed the speed reducer to be set in the "neutral" position, severing the mechanical connection with the traction motor when the locomotive had to be pulled by another vehicle.

Electrical part

The electrical part replicated the one of E.321 and E.322, with some modifications suggested to the designers by the experience of operation with the progenitors.[37]

As with E.321 and E.322, the electric machines, with the exception of the wagon-mounted traction motor, were arranged on the front of the locomotive bed, inside the forebody.[38]

The electrical equipment included a primary motor fed from the 3 kV DC overhead line and flanged on the main generator's armature shaft so as to form a one-piece unit with it. This unit drove by means of pulleys and V-belts another monoblock unit consisting of two DC generators, the first of which supplied the auxiliary circuits and recharged the batteries, while the second provided separate excitation to the primary motor. The same genset was used to drive the centrifugal fan that cooled the traction motor, while on the opposite side of the main unit the compressor was driven to power the pneumatic system and the brake circuit.[39]

Traction circuit

Conventional electrical equipment with a DC motor powered at constant voltage would have created serious limitations on a shunting service locomotive, both because of the rapid decrease in torque with increasing motor speed and because of the heavy energy dissipation on the starting rheostat.[40] Moreover, the latter, being intended to run continuously engaged for frequent starts, would have had to take up a considerable amount of space. At the same time, the modest power required to perform this type of service made it almost obligatory to resort to a single traction motor, making impractical the technique, adopted on locomotives for line services, of obtaining speed regulation by connecting the motors in series and in parallel.[41]

As in the case of the earlier E.321 and E.322 units, therefore, an equipment similar to that of the Diesel-electric locomotives was opted for, in which the Diesel engine would be replaced by an electric primary motor, thus obtaining a system similar to the Ward Leonard unit used in industrial drives, suitably adapted for railway needs.

Thus, the same structure made for the E.321/322 was confirmed, with minimal variations, consisting of a primary motor fed directly from the catenary at 3 kV mechanically coupled with a main generator, which in turn fed the traction motor with an adjustable voltage within wide limits, suitably varying its speed without resorting to the series rheostat.

Running adjustment was carried out by the driver by inserting a series of resistors into the excitation circuit of the main generator, obtaining for each position of the shunting combiner one of five curves, called "external characteristics," shown in red on the voltage-current graph shown in the figure.[42]

The external characteristics obtained in this way exhibited strong voltage variations as the load current varied, which enabled the main generator to limit the traction motor's inrush current and automatically adjust its voltage during the acceleration phase, realizing without energy dissipation the same function as the starting rheostat of conventional locomotives.[43]

The only variant introduced in the traction circuit compared with the locomotives of the earlier E.321 and E.322 classes was the adoption of field weakening on the traction motor, which entailed the addition of an electropneumatic contactor (see diagram) and the upgrading of the control circuit.

Control circuitry

The addition of traction motor field weakening and speed selector (32or) entailed the inclusion of the respective controls in addition to those on the E.321 shunting bench and the implementation of an interlocking circuit between the E.323 locomotive and the E.324 motor trailers to synchronize the position of the speed reducers on the coupled units.

Electric heating circuit

The system for electric heating of coaches was not installed on any of the E.323 and E.324 units.

Auxiliary circuits

As with E.321/322, power for the auxiliary circuits was produced by a belt-driven DC generator from the primary engine, to the terminals of which was connected a voltage regulator that supplied the control, lighting and battery charging circuits.[44]

Pneumatic part

Compressed air for the pneumatic controls and the brake circuit was produced by a Westinghouse 241-P type compressor mechanically driven by the primary engine, a solution that made it possible to eliminate expensive 3 kV motors for the motor compressors.

An electric compressor powered by the auxiliary generator or battery produced the air needed to raise the pantograph.

Compared with the electropneumatic circuit of the E.321/322 were added:

Economic considerations

Comparison with the Diesel-hydraulic 245 locomotives, with primary engine calibration power of 368 kW versus 260 kW of the E.323, resulted in slightly lower performance for the latter, as evidenced by the graph showing the tractive effort curves in the speed range between 0and; for speeds up to 64km/h the tractive efforts are halved, but the operating conditions of the two types of locomotives remain practically unchanged.

Since no official data had been published, the economic evaluation was carried out by extrapolating the "hourly operating costs without the cost of train crews" related to the comparison of electric E.321 locomotives and Diesel 235 locomotives published in 1963, from which a 27% lower hourly cost between the former and the latter emerged (1 105 vs. 1 530 Lit/h).[45] [46] [47]

Considering that the operating cost of the E.323s should not have varied from the E.321s, the machines being entirely similar, while the 245s should have entailed a greater expense for fuel because of the greater power of the Diesel engine compared to the 235s, it was estimated that at equal performance the operating cost of the Diesel locomotive was at least 40% higher than that of the electric locomotive.

Faced with such a considerable difference in costs and counting on the fact that no practical changes were necessary in the organization of services and facilities for electric shunting operation, the technicians of the Tecnomasio Italiano Brown Boveri (TIBB) prospected the State Railways (FS) to reflect on the convenience of augmenting its fleet with more electric shunting equipment, providing where possible to complete the electrification of the yards at an expense that would be offset by the service economies and longer service life of an electric shunting vehicle compared to a Diesel traction vehicle.

On the other hand, the TIBB also recalled in its analysis the considerations against convenience, such as the need to have a certain number of fully autonomous locomotives (Diesel) available for ready intervention in case of accidents affecting the power supply network or for its maintenance, as well as safety constraints that required a certain number of non-electrified tracks to be present on the yards.

For their part, the FS decided not to go beyond the planned orders and, in order to avoid the recurrence of accidents that dragged with them lengthy court cases, they later undertook the de-electrification of many of the yards' sidings.[48]

Studies and experiments

In 1972, in a series of talks between representatives of the FS and the Institute of Automation of the Faculty of Engineering of the University of Rome "La Sapienza," it was agreed to experimentally transform a locomotive of the E.323 class by replacing the rotary converter and the DC traction motor with an electronic converter suitable for powering a three-phase traction motor.[49]

This was an important experiment because it constituted the world's first application of a three-phase traction motor to a 3 kV DC locomotive, the main critical issues of which were related to the state of the art of power thyristors, which were then suitable for relatively low working voltages and were extremely sensitive to overvoltages, which in 3,000 V DC electrification systems could reach peak values of up to 12,000 V due to line inductance.[50]

Although a shunting locomotive allowed only partial use of the advantages offered by the three-phase motor, the decision to carry out the experimentation on E.323s, which were equipped with a single motor of relatively low power that would make it possible to minimize the difficulties and expense of transformation, was considered a very convenient tradeoff.

The division of tasks called for the Institute of Automatics to carry out the feasibility study, choose the traction motor, design and build a laboratory prototype of the converter, and build the control circuits for the converter. On the other hand, the FS was responsible for purchasing the traction motor, making the final converter and auxiliary equipment, reassembling the locomotive, and financing the entire work.[51]

It was also agreed to precede the assembly on the E.323 with an experimental application on the ground, carried out at the premises of the electrical substation in Rome Magliana by the State Railways Experimental Institute.

The conversion work initially involved only the replacement of the electrical traction equipment, but the subsequent choice of a 4-pole three-phase motor, more advantageous in terms of mass and footprint than the 6-pole motor initially planned, required the transmission ratio to be changed to compensate for its higher rotational speed.

The new traction equipment included:

A constant tractive force capability, i.e., with power increasing linearly with speed, of about 79kN in the speed range between 0and and with slightly decreasing power, from a maximum of about 276kW, from 13km/h to maximum speed was planned for the new locomotive.[52]

Electric braking was planned without in-line recovery, with energy dissipation on a resistor.[53]

In 1973 funding was allocated by the FS and studies began, leading to the submission of the feasibility report in December 1974 with a favorable outcome.

By mid-1977, the progress of work was as follows:

After the realization and ground testing by the FS Experimental Institute of the electronic equipment devised by the Institute of Automatics at the University of Rome, developments in power electronics related to the E.402 locomotive project caused interest in the E.323 inverter to wane, and the project was abandoned.[54]

Nicknames

As was the case with E.322, the E.324 engine trailer was nicknamed "dog" or "doggie" because it appeared to be walking on the leash of its master, E.323.[55]

Chronological summary

On the subject of the historical data of any class of railroad rolling stock, two points in the introduction by engineer Fabio Cherubini, former manager of the FS Material and Traction Service and railroad popularizer, to one of his publications are noteworthy:

E.323 series 000

E.323 locomotivesnot suitable for remote control of E.324
Numberof serviceAdmissionin service[56] Cancellation
E.323.001 1966 December 2002[57]
E.323.002 1966 December 2002
E.323.003 1966 December 2002
E.323.004 1966 after 30/1/2000[58]
E.323.005 1966 April 2004[59]
E.323.006 1966 October 2002[60]
E.323.007 1966 December 2002
E.323.008 1966 December 2003[61]
E.323.009 1966 after 30/1/2000
E.323.010 1966 after 30/1/2000
E.323.011 1970 October 2002
E.323.012 1970 December 2002
E.323.013 1971 December 2002
E.323.014 1971 October 2002
E.323.015 1971 after 30/1/2000
E.323.016 1971 October 2002
E.323.017 1971 after 30/1/2000
E.323.018 1971 October 2002
E.323.019 1971 October 2002
E.323.020 1971 May 2003[62]

E.323 and E.324 series 100 and 200

E.323 locomotivessuitable for remote control of E.324E.324 locomotivesassigned in pairs
Numberof serviceAdmissionin serviceCancellation Numberof serviceAdmissionin serviceCancellation
E.323.101 1966 after 30/1/2000E.324.101 1966 February 2003
E.323.102 1966 after 30/1/2000E.324.102 1966 after 30/1/2000
E.323.103 1966 after 30/1/2000E.324.103 1966 after 30/1/2000
E.323.104 1967 August 2003[63] E.324.104 1967 after 30/1/2000
E.323.105 1967 preserved as historic rolling stock[64] E.324.105 1967 preserved as historic rolling stock
E.323.201 1971 April 2009[65] E.324.201 1971 April 2009
E.323.202 1971 luglio 2003[66] E.324.202 1971 August 2003
E.323.203 1971 April 2009E.324.203 1971 June 2009[67]
E.323.204 1971 December 2003E.324.204 1971 October 2009[68]
E.323.205 1971 April 2004E.324.205 1971 March 2003

See also

References

  1. .
  2. "Troop trains" are defined in railway regulations as the dispatch of wagons or carriages from one facility to another in a complex junction. Such trains, driven by drivers called "TMs" ("Tradotte e Manovre"), could exceed a mass of 1,000 tons in the early 1960s. Cf 2007. Marco. Cantini. I Treni. 299. 14. Locomotive Diesel D.141.
  3. .
  4. For the anomalous classification in classes E.323 and E.324, which descends from that of E.321 and E.322, cf Maurizio Grassi, Classificazione e dintorni delle locomotive F.S. a 3000 V c.c..
  5. 2000. Stefano. Patelli. Tutto Treno. 131. 20–29. Il comando multiplo nelle FS.
  6. 2012. Angelo. Nascimbene. Tutto Treno & Storia. 27. 32–39. 1967: rotabili FS in esposizione.
  7. As of January 1, 1968, the FS electric locomotive fleet included 1669 3 kV direct current machines and 167 3.4 kV 16.7 Hz alternating current machines. Cf Book: Giuseppe Vicuna. 1968. Roma. 402. Collegio Ingegneri Ferroviari Italiani. Organizzazione e tecnica ferroviaria.
  8. Book: Giuseppe Vicuna. 1986. 2. Roma. 698–699. Collegio Ingegneri Ferroviari Italiani. Organizzazione e tecnica ferroviaria.
  9. By the end of the 1960s, when the experimental phase of Diesel and electric shunting locomotive operation was considered over, the FS Material and Traction Service had unified the respective preventive maintenance cycles by providing that Major Repairs, involving the disassembly and restoration of every part of the machine to a new state, would be interspersed with an "R III" repair involving only the general repair of the primary engines (thermal or electric depending on the type of locomotive) and the rearrangement of the electrical part. Cf Giuseppe Vicuna, Organizzazione e tecnica ferroviaria, Roma, Collegio Ingegneri Ferroviari Italiani, 1968, p. 544.
  10. .
  11. .
  12. .
  13. 2009. Marco. Cacozza. Tutto Treno & Storia. 21. 4–13. Ai tempi di tradotte e manovre.
  14. .
  15. .
  16. In the mechanics of railway locomotion, a line is defined as any extension of track connecting two points. A line consists of several sections of any given gradient and curve. Straight level tracks are defined as pairs of curves of infinite radius. Yard tracks are generally flat and straight, with the exception of diverted branches of switches.
  17. .
  18. .
  19. .
  20. .
  21. As of June 2000, the Regional Transport Division had 11 E.323.000s, assigned to Alessandria (3), Bolzano (2), Foggia (1), Genoa Rivarolo (2), and Pisa (3), one E.323.200 assigned to Verona, and one E.324.200 assigned to Verona. Cf 2001. Sergio. Pautasso. Tutto Treno. 138. 29. Materiale motore Trasporto Regionale FS Trenitalia.
  22. .
  23. 2003–2009. I Treni. numeri vari dal 246 al 231. Arrivi e partenze.
  24. 2019. Ferrovie.it. Ferrovie, ancora a Rimini i rotabili "storici" fermi da anni.
  25. 2003. Fabio. Vergari. I Treni. 251. 11–15. Museo ferroviario in Puglia.
  26. .
  27. The Ward Leonard system was used in particular industrial applications (e.g., hoisting plants, rolling mills, winding reels, and paper machines), which required DC motors with outstanding performance, such as starting without a rheostat, considerable possibility of overloading, regenerative braking, a remarkably wide and easily adjustable speed range, and the possibility of reversing the direction of travel without stopping the machine. The unit consisted of a three-phase primary motor that drove in rotation a dynamo with separate excitation and adjustable voltage, by means of which the final motor, also with separate excitation, was driven. Cfr Mario Pezzi, Macchine elettriche, Bologna, Zanichelli, 1967, pp. 211-214. The railway version adopted by the FS differed in replacing the three-phase primary motor with a DC motor and using a traction motor with series excitation, which was more suitable for railway needs.
  28. The term "main generator" is used to distinguish the dynamo that powers the traction motor from the dynamos, called "auxiliary generators," which are used to power the excitation circuits of other electrical machines and the locomotive's control and lighting circuits.
  29. The speed of the DC motor is directly proportional to the voltage applied to its terminals and inversely proportional to the magnetic field produced by the excitation circuit. Reducing the excitation current thus causes a weakening of the magnetic field, which makes it possible to increase, within certain limits, the speed of rotation of the motor beyond the value corresponding to the maximum supply voltage.
  30. .
  31. .
  32. The so-called "unified class" included the 245.1001-1020, 2001-2020 and 6010-6124 series. Cfr Book: Nascimbene . Angelo . FS Trenitalia. Locomotive Diesel . Vanni . Luca . Duegi Editrice . 2002 . Albignasego . 42, 93, 94, 97 . 1124-4232.
  33. .
  34. .
  35. The transmission bridge consisted of a set of gears that transferred the rotary motion received from the drive shaft to the drive axle.
  36. .
  37. .
  38. .
  39. .
  40. The so-called "rheostatic starting" is done by inserting a set of limiting resistors (rheostat) in series with the DC motor, which are progressively excluded as the motor speed increases.
  41. .
  42. .
  43. .
  44. .
  45. .
  46. .
  47. .
  48. .
  49. .
  50. .
  51. .
  52. .
  53. .
  54. 1986. I Treni Oggi. 63. 4. Notizie flash.
  55. .
  56. .
  57. Arrivi e partenze, in I treni, 24 (2003), n. 248, pp. 32-33.
  58. The unit was reported to be in service as of January 30, 2000 (cf), but the date of cancellation is not available in the specialized literature.
  59. Arrivi e partenze, in I treni, 25 (2004), n. 263, p. 32.
  60. Arrivi e partenze, in I treni, 24 (2003), n. 246, pp. 12-13.
  61. Arrivi e partenze, in I treni, 25 (2004), n. 259, p. 33.
  62. Arrivi e partenze, in I treni, 24 (2003), n. 253, pp. 32-33.
  63. Arrivi e partenze, in I treni, 25 (2004), n. 256, p. 31.
  64. On consignment to the amateur association AISAF.
  65. Arrivi e partenze, in I treni, 30 (2009), n. 319, p. 35.
  66. Arrivi e partenze, in I treni, 25 (2004), n. 255, p. 34.
  67. Arrivi e partenze, in I treni, 30 (2009), n. 321, p. 35.
  68. Arrivi e partenze, in I treni, 31 (2010), n. 330, p. 34.

Bibliography

Printed sources

Historiography and complements

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