THE BRITISH OVERSEAS RAILWAYS HISTORICAL TRUST
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Kevin Jones' Steam Index
Locomotive Magazine and Railway Carriage and Wagon
Review
Volume 40 (1934)
Number 497 (15 January 1934)
British steam locomotives of 1933. 1
New 0-6-2 tank locomotives, Great Southern Rys.,
(Ireland). 2. illustration, diagram (side & front elevations)
Small class of suburban tank engines: 5ft 6in coupled wheels; 18 x
24in cylinders (8in piston valves); 18ft2 grate; heating surfaces:
662 tubes; 112 firebox and 112ft2 superheater, designed by
Harty.
Three cylinder express locomotive, Southern Railway. 3 + coloured plate (supplement)
L.M.S. Ry. Northern Counties Committee. 3.
Greenisland loop to be opened by Duke of Abercorn
Pacific type locomotives, Tientsin-Pukow Ry, China. 3-4. 2 illustrations
200 h.p. diesel-electric rail coach working on the L.M.S.R. 5-8. 3 illustrations, table
Diesel locomotive, Clogher Valley Railway. 8.
2 illustrations
Basically small lorry adapted to run on rails
Drewry saloon railcar, Burma Railways. 9. illustration
Four wheel vehicle capable of carrying 12-15 passengers. 24/26 hp
engine. Built to Rendel, Tritton & Palmer specification
Penmeanmawr & Welsh Granite Co's. locomotives.
10-13. 9 illustrations
The Trevor quarry was served by 1ft 11½in gauge lines (which
are neither illustrated, nor described in detail) and 3ft and standard gauge
at Penmaemawr. Therec were 17 locomotives in service at that time: 10 steam,
5 diesel and 2 petrol. The oldest were De Winton machines with vertical boilers
and four wheels: these were Puffin of 1893; Lilian (1891);
Louisa (1892); Penmaen (1878); Llanfair (1895; illustrated)
and Watkin (1893). There were five Hunslet loomotives (outside cylinder
0-4-0STs): Hughie (illustrated); Stephen; Singapore;
Tiger and Donald. For the standard gauge line at the summit
there were two Avonside Engine Co. diesel mecanical not electric as stated
locomotives named Attic and Kimberley: these are illustrated
by a Works photograph, and photographs of receipt of Attic via
a Sentinel well road lorry and Kimberley at foot of incline and on
a steep pitch: tthere was also a steam "spare" locomotive an ex-L&YR
0-4-0ST No. 43 LMS No. 11245 miodified with Tecalemit lubrication (photographed
at beginning of ascent). See also erratum om page 37 concerning diesel locomotives and additional de Winton Harold of
1894.
Rebuilt "Pacific" locomotive Paris-Orleans Ry. 14-16.
illustration, 2 diagrams including side elevation and sectional elevation
of boiler
See letter from W. Lubsen on page 97 and from Wiliam T. Hoecker on p. 98
L.M.S.R.—N.C.C.. 16
One new 2-6-0, No. 90, had been named Duke of Abercorn in readiness
for the opening of the Greenisland loop. The other three 2-6-0 were named
The Bann, The Bush and The Foyle.
The late Mr. G. J. Churchward. 17.
It is with deep regret that we have to record the death of Mr. G.
J. Churchward, C.B.E., the former chief mechanical engineer of the Great
Western Railway, in his seventy-seventh year. On Tuesday, 19 Dec., he was
knocked down and killed by the 08.55 express train from Paddington for Fishguard,
in the fog, within a few yards of his home, Newburn, Swindon.
Churchward was a native of Stoke Gabriel, Devonshire, and started his railway
career as a pupil to John Wright, locomotive superintendent of the South
Devon Railway at the Newton Abbot shops. He came to Swindon upon the amalgamation
of the S.D. Ry , with the Great Western in 1876. In 1882 he was appointed
manager of the carriage works a post he held until 1895, when he was transferred
to the locomotive works as assistant manager. Upon his appointment as chief
mechanical engineer in succession to William Dean, in June 1902, he commenced
his task of standardising the boilers, engine parts, and types for which
the Great Western Railway has become famous. The first locomotive of the
Pacific type to run on a British railway, the famous The Great Bear,
was built to his designs in 1908. Although at that date this class of engine
was not altogether suitable for the permanent way, it was the forerunner
of the present type of Pacific locomotive which is giving satisfactory service
on other lines. Churchward was one of the first British engineers to appreciate
the advantages of the superheater, and brought into general use on his engines
a very efficient apparatus. He also developed the long piston stroke and
the narrow piston ring and introduced the top-feed for boilers, by which
the difficulty of introducing water at the top of the boiler was overcome.
It was at his suggestion that the Great 'Western Ry. in 1903-5 purchased
three French four-cylinder compound engines, designed by A. de Glehn
similar to those running on the Northern Ry. of France, between Calais and
Paris. These engines gave excellent results on the GWR. though Churchward
decided in favour of four cylinders with simple expansion. In 1910 he arranged
an exchange of express engines with the L. & N.W.R. which led to the
latter designing the Claughton class of four-cylinder express locomotives.
Even more important was the work he did in the lubrication of rolling stock.
He developed the use of resilient pads in oil-boxes which has proved so efficient
that it is almost universally used at the present time.
Although a strict disciplinarian, Churchward was always devoted to the interests
of his men, and in 1907 introduced a scheme enabling apprentices to attend
techmcal classes without loss of pay. In addition he persuaded the directors
of the railway to sanction payment of the school fees by the company and
permit those students who distinguished themselves to spend part of the last
year of their apprenticeship in the drawing office and chemical laboratory.
He was, as always anxious to give full scope and opportumty to those who
aspired to greater knowledge and achievement.
The Churchward era at Swindon may truly be considered that of speed and fine
performance, while his designs kept to the simplicity and neat- ness of outline
distinctive of British locomotive practice.
Mr. Churchward retired in January 1922, and was succeeded by C.B:
Collett..
[W.A. Lelean]. 17
Death on 27 December 1933 of W. A. Lelean, who had been for many years
in charge of the Locomotive Department of Messrs. Rendel, Palmer & Tritton,
consulting engineers to the Indian Government. Lelean served his apprenticeship
in the G.W.R. shops at Swindon, when he secured a Whitworth exhibition. In
1896 he was appointed by Sir Alexander Rendel as inspector in charge of contracts
at the various Glasgow locomotive works, and remained there for 12 years.
For some time he carried out the inspection in Continental locomotive shops,
and then became chief of the locomotive staff of Rendel & Robertson,
afterwards Rendel, Palmer & Tritton. During the last few years, in
collaboration with Devon, and the locomotive builders, Lelean has been
responsible for the designs of the standard locomotives for the Indian Railways.
He also took the greatest interest in the development of the Institution
of Locomotive Engineers, of which he was for many years one of the
vice-presidents, and acted as president for the past year.
[F.J. Davis]. 17
Death occurred after a short illness on 31 December 1933 in his 72nd
year was a partner in the engineering firm of
Taite & Carlton, Iddesleigh
House, 'Westminster. Davis was well known to many railway men as his firm
introduced pneumatic tools, the Holden system of oil fuel burning, the Worsdell
von Borries compound locomotive, the Whitaker water indicator, etc.
Personal. 17
At the end of 1933 A.S. Bailey retired from his position as managing
director of the Metropolitan-Cammell Carriage, Wagon & Finance Co. Ltd.,
and . Archibald J. Boyd, M.A., has been appointed as his successor. Boyd
served as a pupil at the steel works of Carnmell, Laird & Co. Ltd. and
became assistant manager of the company in London in 1913. He went on military
service, but returned from France in 1916 to become assistant general manager
of the new works which had been built by Cammell, Laird & Co. at Nottingham
for the manufacture of shells and guns. He returned to London in 1919 as
assistant manager, and became London manager in 1921, and a local director
of Cammell, Laird & Co. Ltd., in 1925. In the same year he was elected
a director of the Midland Railway Carriage & Wagon Co., Ltd.; the Leeds
Forge Co, Ltd. and the Newlay Wheel Co Ltd. control of which had been acquired
by Cammell, Laird & Co. Ltd. On 1 January 1929, when the railway carriage
and wagon interests of Vickers Ltd. and Cammell, Laird & Co. Ltd. were
amalgamated, the name of the company was altered to the Metropolitan-Cammell
Carriage, Wagon & Finance Co. Ltd. and Boyd became a director, with charge
of the London office and the foreign sales of the company. Mr. F. J. Hills
has been appointed London manager of the company. Mr. Hills was formerly
with the Bristol Wagon and Carriage Works and on its absorption by the Leeds
Forge Co. he entered the service of that company, subsequently joining the
rolling stock department of the London office of Cammell, Laird & Co.
At the Birmingham works of the company J.W. Kidd will act as commercial and
production manager, under the direction of Boyd.
E.A. Phillipson. Steam locomotive design: data and formulae. Valve
gears. 18-20. diagram, 2 tables
Baker valve gear and conjugate valve gears
summarised, the advantages of independent motions for each cylinder, as opposed
to conjugate gears in general, are:
(a). Each valve is accurately set individually, uniformity of the valve events
for all cylinders being in most cases easily achieved.
(b). Setting of valves and correction of errors facilitated: the adjustment
of one valve does not affect that of others.
(c). Effects of wear are not cumulative to the same degree and lost motion
is less extensive.
(d). Components of each valve gear are comparatively light in weight.
The Royal Scot L.M.S.R. return from U.S. and Canadian Tour. 20
The Royal Scot train, after its tour through the United States and
Canada, was on exhibition at No. 6 platform, Euston Station on Friday 15
December 1933 and on Saturday and Sunday following. The engine and eight
coaches were open to free public inspection. In addition to the electric
headlight and bell, which engine No. 6100 was to carry as a permanent feature,
commemorative plates had been affixed to the engine and in each of the coaches
forming the train. The inscription on the engine plate reads:- "This locomotive
with the Royal Scot train was exhibited at the Century of Progress Exposition,
Chicago, 1933, and made a tour of the Dominion of Canada and the United States
of America. 'The engine and train covered 11,194 miles over the railroads
of the North American Continent and was inspected by 3,021,601 people. W.
Gilbertson, driver. J. Jackson, fireman. T. Blackett, fireman. W.C. Woods
fitter.
The inscription on the smaller tablets fixed in the coaches read:-"This vehicle
formed part of the Royal Scot train, which was exhibited at the Century of
Progress Exposition, Chicago, 1933 and made a tour of the Dominion of Canada
and the United States of America. The train covered 11,194 miles over the
railroads of the North American Continent and was inspected by 3,021,601
people.
A ceremony of welcome was accorded to the Royal Scot and its train crew when
it steamed into Euston at 12 o'clock on Friday 15 Dec. by a distinguished
company including the Rt. Hon. Waiter Runciman, President of the Board of
Trade; Sir Josiah Stamp, President of the L.M.S. Railway, the directors,
and a large company. Four of the crew who made the journey with the train
wore smart gold braided uniforms. C.O.D. Anderson, who was in charge on the
technical side, and T.C. Byrom, who looked after the publicity and general
arrangements, were also present. They were given a cordial welcome and Sir
Josiah Stamp handed to each of the six a gold watch inscribed with the names
of the chief cities visited on the tour, and the thanks and appreciation
of the directors of the L.M.S.Ry. Following the successful exhibition at
Euston, where in three days over 33,000 people inspected the train, the Royal
Scot is to be on show at about fourteen of the principal English and Scottish
centres on the L.M.S. Railway during the present month.
Southern Railway. 20
Following closely on their decision to extend the electrically operated
portion of their system from Chislchurst and Bickley to Sevenoaks, via Swanley
and from Orpington to Sevenoaks via Chelsfield, it was announced at the beginning
of December that it had been decided to extend the main line electrification
scheme from Wivesfield Junction to Eastbourne and Hastings and from Haywards
Heath to Horsted Keynes at a cost of £1,750,000. The extension is expected
to be, completed early in 1935. New rolling stock required to include seventeen
6-car units, five 4-car units. and eighteen 3-car units with a number of
Pullmans. Platform extensions will be necessary at London Bridgc, Lcwes and
Eastbourne and alterations at Bexhill Central. Notice has been given of an
application to Parliament for powers to build a loop line four miles long,
from a junction with the main line near Folkestone to a junction with the
same line 557 yards east of Abborscliff Tunnel. This is a deviation to avoid
the possibility of the main line being obstructed by landslips as happened
during WW1.
L.M.S. Railway. 20
Placing orders for 2,000 new freight wagons on renewal account. All
will be of the 12-ton open type for conveying general merchandise. and will
be filled with the continuous brake. Four hundred of the wagons will be built
in the company's workshops, and thc remainder have been ordered in equal
proportions from the following firms: Birmingham Railway Carriage & Wagon
Co. Ltd. Metropolitan Cammcll Carriage, Wagon and Finance Co Ltd. Charles
Roberts & Co. Ltd. Horbury Junction, and Hurst, Nelson & Co. Ltd.,
Glasgow. The new wagons will be fitted with underframes constructed of British
steel.
L. & N.E.Ry. 20
The widened lines between Gidea Park and Shenfield, including the
burrowing junction at the last mentioned place from thc main line to the
Southend branch were brought into operation as from 1 January a result of
this the local service to Shenlield and intermediate stations has been augmented
and improved, and a number of accelerations have been made in the services
to the Southend branch, and also the Colchester main line. Colour light
signalling has been provided, and the stations at Harold Wood, Brerntwood
and Shenfield had been rebuilt.
Electric locomotive design. VII. Driving bogie design. 21-2. illustration,
2 diagrams
Gloucester Railway Carriage & Wagon Co. articulated multiple units
for the South Indian Railway (Robert White & Partners, consulting engineers).
General Electric Co., Schenectady Co+Co design for Russian Railways electrified
at 3000 V.
Vulcan Foundry. 22
Agreement with Frichs Locomotive Works of Aarhus, Denmark to use their
design of diesel locomotives and railcars in the British Empire and British
South American markets
Hartley Main Colliery. 22
Egyptian State Railways, excursion trains. 23. 3
illustrations
For the Cairo to Luxor service taking 12 hours coaches were being
rebuilt with bunks, but still convertible for day use. The work was undertaken
by W.D. Knight, chief mechanical engineer for Mahmoud Bey Shaker, general
manager.
E.E. Joynt. Reminiscences of an Irish locomotive works. 24-6
See separate page
[Messrs. R. & W. Hawthorn, Leslie & Co. Ltd.]. 26
In the last issue it was noted that Messrs. R. & W. Hawthorn,
Leslie & Co. Ltd. were building a 225 H.P. Beardmore-engined six-wheeled
diesel-electric locomotive for the Air Ministry. This was not quite correct:
the locomotive in question was a Diesel-geared locomotive [diesel
mechanical].
Hunslet Engine Co. Ltd. 26
Building an 80 h.p. eight-wheeled double-bogie diesel-mechanical
locomotive for the 18 inch track of the Royal Arsenal Rys., Woolwich. For
the Egyptlan Delta LIght Rys. they were constructing a 110 h.p. diesel-mechanical
locomotive.
Mr. H.E. Allwood. 26
Works manager of the Nigerian Government Railways, appointed chief
mechanical engineer SIerra Leone Government Railway, Cline Town, Sierra Leone,
in succession to Mr. R. Malthus who had retired
Santa Fe type locomotives for the Turkish State Railways. 26-7.
illustration, taable
Thirty locomotives were under construction at the works of Henschel
& Sohn A.G., at Cassel, and the Friedrich Krupp A.G., of Essen, for the
Turkish State Railways, five passenger 4-8-0 had been delivered by former
and ten goods locomotives (2-10-2) had been delivered by latter firm. 2-10-2
illustrated.
A new light rail car. 27. illustration.
Micheline railcar with pneumatic tyres: Michelin Tyre Co.
Model Pacific locomotive. 28. illustration
3½in gauge built by J.W.G. Todd of Amsterdam
Great Western Railway. 28
New Castle class: No. 5023 Brecon Castle; No. 5024 Carew
Castle; No. 5025 Chirk Castle; No. 5026 Criccieth Castle;
No. 5027 Exeter Castle; No. 5028 Farleigh Castle; No. 5029
Nunney Castle; No. 5030 Shirburn Castle; No. 5031 Totnes
Castle; No. 5032 Usk Castle.
Feeder for stone and ore crushing. 28. illustration
Hadfield Ltd: conveyor
London Midland & Scottish Railway. 28
1934 programmne: 232 locomotives; 159 boilers; 674 carriages; 5365
wagons; following orders with Vulcan Foundry and North British Locomotive
Co. for 100 locomotives amd for 2000 wagons from British manufacturers. Since
1923 2500 new locomotives had been put into service and 4800 had been withdrawn.
The number of types had been reduced from 393 to 204. The number of locomotives
with superheaters had grown by over 2000.
Longest through locomotive working in Great Britain.
29
New railway record established by the L.M,S, Railway with the introduction
into regular service between London and Glasgow, and vice versa, of the new
Pacific locomotives The Princess Royal and Princess Elizabeth,
These engines were working daily on The Royal Scot express. Each engine
makes one through trip every weekday from Euston to Glasgow or vice
versa, and the distance of 401½ miles thus covered represents the
longest through locomotive working in this country, if not in Europe, Changing
of engines at Carlisle is avoided, and train loads up to 50U tons are worked
over the summits of Shap and Beattock without assistance. The unpiloicd limit
for the Royal Scot class of engine was 420 tons.
[Leigh-on-Sea]. 29
On Thursday, 4 January 1934, the Mayor of Southend on Sea formally
opened the new LM.S, Station at Leigh-on-Sea.
Great Western Railway. 29
One hundred and three new locomotives were built at Swindon during
1933, comprising: 40 0-4-2 tanks, 48XX and 58XX classes; 13 2-6-2 tanks,
61XX class; 20 4-6-0 tender engines, 59XX class; 30 0-6-0 tanks, 97XX and
87XX classes. All except the 58XX class were fitted with autoruatic train
control apparatus. Among ,the 93 locomotivcs condemned last year, were several
4-6-0 type, Stars and Saints; the last of the 4-4-0 Counties i.e. County
of Somerset, and sornc of the 4-4-2 County tanks, It had been decided
to equip the principal high-speed passenger engines with speedometers. As
a cornmencement one hundred engines wer« to be fitted.
Institution of Locomotive Engineers. 29
At a meeting held on 21 December, at the Institution of Mechanical
Engineers, the papcr on Steam Motive Power Operation, with special reference
to enginc loading, was contributed by T.H. Shields. The subsequent discussion
was participated in by Major C.E. Williams, O.B.E., who was in the chair,
and Messrs. H, Chambers (L.M.S.R.), E.C. Poultney, Cyril Williams and H.
Holcroft (S.Ry.).
The following elections, as recommended by the Council, were approved:-Membcrs:
F.H. Hough (workd manager, L.C. & W. Shops, Nizarns Guaranteed State
Ry, Lallaguda, Dcccan}, A. Lawrence and I. Midderigh (resident engineering
inspectors in Glasgow for the Crown Agents for the Colonies), J. Cook (divisional
loco. supt., F.C, Central, Cordoba, Rosario de Santa Fe, Argentine Republic),
Associate Members:-.A.J. Benedetti (assistant to local works manager, Los
Talleres, F.C. Sud (Seccion B. B. N.O.), Bahia Blanca, Argentine Republic),
R.W. Kennaway (assistant: engineer, Diesel Traction Dept., Sir W. G,
Armstrong-Whitworth & Co. Ltd. Scotswood Works, Newcastle on Tyne), R.I.
Spencer (loco. mechanical inspector, LM.S.R Derby). Associates:- A. Bissett
(manager in Scotland for C. C. Wakefield & Co., Glasgow), K. Fraser (managing
director, The Yorkshire Copper Works, Ltd., Leeds), A.J.R. Walker(director
and general manager, United Water Softeners, Ltd., London).
The Railway Club
The 27th annual dinner was held on Friday, 15 December 1933, at the
Broad Street Station Restaurant. The president was in the chair supported
by Lord Monkswell and W.A. Willox (vice-presiderts) and C J. Allen (past
president), The function was very well attended and an enjoyabln evening
was spent by the members and their guests. It a meeting held at 57 Fetter
Lane. E,C., on 12 January a paper entitled Why the L.& N.W.R. was the
the Premier Line was given by J,D. Goffey.
Stephenson Locomotive Society. 29
The 24th annual meeting was held at headquarters, King's Cross. on
9 December S.H, Beaver was appointed headquarters (London) secretary; : J.H.
Seaford retaining office as honorary general socrctnry. All the other officers,
including tlu provincial branch secretaries , who were present, were re-elected.
The vacant seat on the council was filled by the election of J. Sturt. Further
lecture arrangements were announced for the remainder of the winter sessions
in London, Manchester, Edinburgh and Glasgow. The president, J.N. Maskelyne
took: thc chair at the annual dinner which was held later in the day at thc
Midland Grand Hotel, St. Pancras, when the attendance was a record and an
enjoyable evening spent. The Society is willing to supply speakers
or lantern-lecturers for boys' schools, young mens clubs or the like, upon
railway and locornotivc subjects,
Hobbies and Models Exhibition. 29
The Third Annual Hobbies and Models Exhibition will be held in the
City Hall, Deansgate, Manchester, from Monday, 15 January to Saturday, 27
January, inclusive. It will be opened by Commodore Sir Bertram F. Hayes,
of the White Star Line, Readers who visit this exhibition will be assured
of a very pleasant and interesting hour or two, inspectin the large display
of models of all kinds, covering aviation, building, engineering, railways,
road transport, shipping, yachting, etc. Features of special interest include
the Largest Working Model Railway in the world, the Living Picture Zoo (a
splendid collection of rare animals and birds staged in a novel setting),
displays of working models by Model Clubs, engineering firrns. and
private individuals; a fine collection of foreign and colonial stamps, a
home cine theatre, demonstrations of night photography, model aircraft in
flight, and a host of other attractive exhibits.
Correspondence. 29-30
Steam locomotive design. J.C.
Cosgrave
In the paragraph headed "Eccentric Rod " which appeared in the last
instalment of Phillipson's articles on locomotive design Design, the author
states that the length of the radius rod should not exceed that of the eccentric
rod. While it is certainly correct that the length of the eccentric rod should
not be unduly shortened in favour of the radius rod. it would be interesting
to know of any special reason why the limiting proportion suggested by Phillipson
should be rigidly adhered to: the writer of this letter is acquainted with
several examples of apparently excellent layouts of Walschaerts' gear in
which the radius rod is considerably longer than that of the eccentric rod.
Response from Phillipson pp. 97-8
Invention of the link motion. E.A.
Forward
Re F.W. Brewer article in the December issue on the Invention of the
Link Motion. If the sketch of the original Williams link gear as reproduced
by Colburn, but tirst published in 1846, is correct, then, as pointed out
by J.G.H. Warren, it would appear that the Williams form was really the
forerunner of the Gooch gear, while Howe convericd it into the shifting-
link gear as adopted by Stephenson and Co. Howe's original wooden model,
of 1842, still exists in the Science Museum.
Regarding the Forrestcr locomotive Swiftsure on the Liverpool and
Manchester Railway, it is now known that this engine had the Carmichael gear
with one fixed eccentric and a double-gab eccentric rod, for it was seen
on the L, & M. Ry. in 1834 by Mmrc Sequin, and its gear roughly sketched
by him. It would appear, however, by Alexander Allan's evidence, that the
later Forrester engines for the Dublin and Kingstown Railway had a four fixed
eccentric gear.
Steam locomotive design. C.R.
Caton. 30
Re article on Valve Characteristics and Events in the August Issue,
where the different methods of locomotive workng were discussed mainly Irorn
a theoretical point of view, two references to this subject have appeared
in the Proceedings of the Institution of Mechanical Engineers whicn may be
or interest to your readers. They are as follows:-
Problems of Railways Mechanics,
by Professor G. V. Lomonossoff, Vol. 120, page 650. Year 1931.
...but also establish programmes of action for locomotive drivers, who have
a very strong prejudice against these programmes and instructions, and are
usually quite right in their mistrust of theories. In accordance with Rankin's
theory of the steam engine, ignoring the wire drawing of steam and the phenomenon
of internal condensation in the cylinder, engine drivers were for seventy
years instructed to have the throttle always fully opened, whrle at the same
time their practice showed them that specially for saturated steam, this
is often impossible and always unprotitable. The experiments made by the
author on the Russian railways 1898-1924) and the above mentioned calculations
conflrmed this entirely. Even for superheated steam cut-offs of less than
20 per cent. are not advisable."
"Some Factors affecting the Riding
of Coaching Stock," by A. J. W. Dymond , Vol. 121, page 468. Year
1931
Longitudinal vibration of a coach is not a frequent cause of trouble. It
may occasionally be due to soft butter springs but is more often caused by
factors quite outside the vehicle itself. Slack couplings may cause it, or
the type or locomotive which is hauling the train, or more particularly the
way the engine is being driven. Two-cylinder engines in particular will cause
longitudinal oscillations at high speeds when run in early cut-offs despite
the relatively large proportion of reciprocating masses balanced. This trouble
is practically eliminated if the locomotive is run at later cut-off at a
partial regulator opening. Four-cylinder engines of the Great Western Railway,
with their well known superior balance give no trouble in this respect."
While early cut-off working, under conditions approaching the ideal, is most
economical, yet actually the most economical working in regard to fuel
consumption and repairs varies with different classes of locornorivcs, and
with some, early cur-off working is impossible. The most economical methods
of working depends upon the type and design of valve gear, travel and lap
of the valves, and the port area in relation to cylinder volume. The tables
XLIV and XLV, page 250 of the August volume of the LOCOMOTIVE apparently
give the valve settings of the two types of G.W. Ry. locornotives referred
to by Mr. Dyrnond. They both have long lap valves and steam ports of ample
area, yet the Walschaerts gear engine can be worked at a higher cut-off than
the Stephenson. It has been the writer's experience that generally engines
(including two-cylinder engines) fitted with the former gear can be notched
up higher: than those fitted with the latter gear, although this is not always
the case as the earlier Drurnmond saturated slide valve, Stephenson link
motion engines of the L.S.W. Ry. were very successfully worked half a notch
from mid-gear. Again, the writer has come into contact with engines or recent
design, with long travel valves, etc., but owing to limited port area have
to be worked with partial regulator opening and late cur-off. When worked
by regular and capable drivers these engines are economical and light in
fuel, but when worked by drivers "other than the best, " are pooled, or forced,
longitudinal oscillations are set up resulting in driving box and big end
trouble and heavy repairs generally.
Mechanical World Year Book 1934.-London: Ernmott &: Co.
Ltd.,
The 1934 edition of this useful and handy work of reference contains
the usual' large fund of data and information, which has been revised and
brought up-to-date. It contains a comprehensive section on metals and alloys
and metallurgi- cal muu.er s that concern engineers, and this is illustrated
by plloto-microphotographs and explar ator y sketches. A further new section
deals with machine tools. As is well known the use of these has become a
specialised business which requires carelul consideration of each problem
from the fundamental principles of machine tool design and construction.
This section provides data useful to machine tool users as well as makers.
Another section is allocated to the manufacture ot pressed parts from sheet
metals and deals with the pro- cesses comprehensively. To many factories
where it is de- sired to instal a pressing plant as an auxiliary to the main
processes, this section will be found invaluable.
Trade Notes and Publications.
Diesel-electric engines on the "Royal Scot". 30
Petter four-cylinder diesel generators coupled to G.EC. electric
generators. were fitted in two 60ft long kitchen cars, one of which went
with the Royal Scot train to North America
Number 498 (15 February 1934)
Operating economies. 31
Mainly through civil engineering: notes the cut offs on the Great
Western Railway route to the West of England and the widening between Guidea
Park and Shenfield on the Great Eastern main line and the Greenisland cut-off
in Northern Ireland: both of the latter were covered in this Issue.
See letter from WGT on p. 166
New 2-6-0 locomotives, L.M.&S. Railway. 32-3. illustration,
diagram (side & front elevations)
Stanier design: No. 13245 illustrated
New ten-coupled compound locomotives, Nortern Ry. of France. 33-6. illustration, diagram (side elevation)
[Erratum]. 37
Penmaenmawr Granite Co. diesel locomotives had mechanical not electric
transmission. Also another de Winton Harold of 1894.
Opening of the Greenisland Loop Line, Northern Counties
Committee. 37-8. illustration
Political theatre staged 17 January when the Governor of Northern
Ireland, the Duke of Abercorn assisted by the Prime Minister Lord Craigavon,
opened the Greenisland Loop. Josiah Stamp, W.V. Wood and Harold Hartley were
there to represent the LMS. Major J.A. Torrens Chairman of the NCC with Malcolm
Speir, manager and secretary. Thew special train was driven by John Young
and fired by C.E. M'Cune. The concrete viaduct involved W.K. Wallace, D.
McLellan, LMS Divisional Engineer, Scotland, R.L. M'Ilmoyle, A.M. Scott,
the resident angineer and A. Davidson
Institution of Locomotive Engineers. 39
Meeting held on 25 January R.I. Kirkland, Associate Member, read a
paper on "Locomotive Boiler Repairs in Headquarters Shops." .. The author
dealt at some length with the condition of boilers as revealed on examination
pnor to the commencement of repair, and to trace each of the defects back
to Its origin with the object of enabling a sounder judgment of the ensuing
repair to be formed. Material used as
precis for Paper 321.
L.M.S.R.- Nortiiern Counties Committee.
39.
Engines Nos. 59 and 67 were being rebuilt at Belfast as Class V2 and would
be re-numbered 85 and 86. They were to have names of Castles in Northern
Ireland. Two new 2-6-0 tender engines were to be constructed and numbered
94 and 95. New coaches were to be built for the new fast business train from
and to Portrush, to be similar in design to the stock of the "Royal Scot"
train, and will comprise one brake 3rd class, one buffet car, and one 1st,
2nd and 3rd composite.
Guidea Park to Shenfield widening L.&N.E. Ry.
42-4. 4 illustrations, diagram (track layout and gradient profile)
Also included the dive under for the down Southend line beyond Shenfield.
Contrctor Sir Robert McAlpine & Sons. Design C.J. Brown and immediate
supervision of R.J.M. Inglis.
Centralised traffic control. 55-9. 4 illustrations, 4 diagrams
Including its adoption on the Metropolitan Railway's Stanmore
branch
Oil-electric trains in Germany. 63
Dr. Dorpmueller, managing director of the German State Railways, plan
involves a change over to heavy oil motor- trains on branch and main-line
stopping services, and it is anticipated that a number of services in popular
travel areas will be converted before the end of the year. High-speed units
to travel at 93 miles an hour will be run radially from Berlin to Hamburg,
·Western Germany, Leipzig and Dresden. Four motor-trains of the Flying
Hamburger type, suitable for such work are now being built by a Goerlitz
firm. Motor-trains capable of 75 miles per hour will be put into service
on main-line stopping services for all purposes except in the case of heavy
business trains, while units running up to speeds of 50 miles an hour will
be used on branch lines.
Armstrong Whitworth railbus. 63. illustration
Demonstrated at King's Cross in August 1933 and after carrying out
trials was put into regular service on the western local branches from Newcastle
Central Station on the 25 September 1933. It ran for eleven weeks in that
service covering 137.5 [miles] per day at a fuel consumption which averaged
8.5 miles per gallon and a lubricating oil consumption of 390 miles per gallon
including periodical draining of the sump. On December 11 1933 the vehicle
was put into a more severe turn connected with this service and was running
223 miles per day on the Heaton No. 1 turn of duty which included round trips
from Newcastle to Morpeth, Newcastle to Blackhill and Newcastle to Hexham.
It had maintained the schedule timings without effort. The. smooth running,
comfort, absence of noise and vibration of this vehicle were favourably commented
upon by passengers and the vehicle had become very popular in these services.
Absence of smoke and dirt is in particular favourably received. Illustration
showed railbus leaving Newcastle Central Station.
Mechanical coaling and ash disposal plants. 63
Will be completed at ten locomotive centres on the L.M.S. Railway during
1934. In addition to the provision of new equipment, the layouts of the engine
sheds will be improved to enable locomotives to be dealt with more rapidly
when starting and finishing shifts. The ten centres concerned were Rugby,
Monument Lane and Aston (Birmingham), Edge Hill (Liverpool), Longsight
(Manchester), Springs Branch (Wigan), Bescot (Staffs.), Walsall, Lancaster,
and Farnley.
H McIntosh. .63
Appointed Assistant Mechanical Engineer and Running Superintendent
of the Great Northern Railway of Ireland
L.M.S. Ry. 63
The following appointments had been approved by the directors:-
Chief Operating Manager's Department.
R.F. Harvey, District Locomotive Supt., Edge Hill, to be Assistant Divisional
Supt. of Motive Power, Manchester.
J.S. Elliott, District Locomotive Supt., Toton, to be District Locomotive
Supt., Edge Hill.
R. T. Clews, District Locomotive Supt., Patricroft, to be District Locomotive
Supt., Toton.
E. M. Ambler, District Locomotive Supt., Bescot, to be District Locomotive
Supt., Preston.
W. E. Blakesley, District Locomotive Supt., Preston, to be District Locomotive
Supt., Bescot (including Aston and Monument Lane).
J. C. Foster, Assistant to Superintendent of Motive Power, Derby, to be Assistant
to Divisional Supt. of Operation (Motive Power), Crewe.
Chief Mechanical Engineer's Department, Mr. F. G. Umpleby, Technical Assistant
(Outdoor Machinery), Euston, to be Outdoor Machinery Assistant, Crewe.
Athens-Pireaus Electric Railway. 63
Line being extended to Kifissia which is about ten miles to the north
of Athens. It will run on the surface from Pireaus to Monasterion and from
there underground through Omonia (the present terminus near the centre of
Athens) to Third of September Street and Patissia, which are two new underground
stations. Thence the line will again come to the surface as far as Kifissia,
This railway is British controlled, although the trains were built in Belgium
and the stations by German labour. They are a great improvement on the stations
of other railways in Greece, as they are built in the British style, with
the platform level with the footboards of the trains.
U.S.A. Notes. 63
Baltimore and Ohio R.R. are buildjng two new engines of the 4-6-4
type and rebuilding two of the 2-10-2 type as 2-8-2's. The Pennsylvania are
building a further 121 electric locomotives and are completing the
electrification of the main line between Philadelphia to Washington. The
Burlington stream line train is about to run trials
Reviews. 64.
Richard Trevithick, the engineer and the man. H.W.
Dickinson and Arthur Tilley. London: Cambridge University Press.
64
Among the several ways selected by the committee appointed to celebrate
the centenary of the death of Trevithick, which occurred last year, was the
publication of a biography, and this work was trusted to the joint authors
of this volume who had for some time been collecting material for the purpose.
As most of our readers are aware, a voluminous "Life" was published by
Trevithick's son, Franciis, in 1872, but this was not only somewhat disconnected
but very verbose, and its two volumes bored the reader rather than gave him
an adequate impression of the remarkable individual whose life story they
told. The present writers have freely drawn on this "Life" for their story,
but have also collected a quantity of material which came to hand since the
former work was written and have turned out a very satisfactory and informative
book, although condensed into half the size. Richard Trevithick was a most
remarkable personality, full of energy and inventive faculty, and it is
impossible to enumerate here the many ingenious ideas which he either originated
or developed. The most important of these was, of course, the high-pressure
engine, and this led the way to the most startling of all, the steam locomotive,
of which he has justly been styled the father. His first successful trial
of a road locomotive, when for the first time in the world's history human
beings were conveyed by mechanical power, took place at Camborne on 24 December
1801, whilst that of a railway locomotive was at Pen-y-daren on 13 February
1804, both dates of outstanding irnportnnce in railway history. The full
story of these momentous events is succinctly given as well as all that can
be found out concerning the road and rail locomotives which Trevirhick exhibited
in London in 1803 and 1808 respectively, arid it must always be a matter
of regret that others were left to reap the harvest of the seed which he
had sown. He died in poverty at Danford on 22 April 1833, aged 62 years,
and the precise spot in which his remains were interred is unknown. Although
the honour which was justly due to one to whom the world owes so much was
not accorded to Trevithick during his lifetime, it is satisfactory to know
that some attempt has been made to atone for this on the occasion of the
centenary of his death. The work under notice is entertainingly written and
contains all that can be reasonably wanted concerning the life and character
of this remarkable genius. It is abundantly illustrated and contains an appendix
with particulars of Trevithick's many patents as well as bibliographical
and genealogical details. We may add that its production at a reasonable
figure is in a large measure due to the enterprise and generosity of Messrs.
Babcock and Wilcox Ltd.
Engineering workshop principles and practice, A.G. Robson, (Fourth
edition). London: Emmott & Co. Lld.,
This text- book should enable the engineering student or apprentice
to thoroughly grasp the essential principles of workshop practice. The text
is in plain language,
Number 499 (15 March 1934)
Road versus rail. 65
Paper 322 read at the February
meeting of the Institution of Locomotive Engineers by an eminent consultmg
engmeer, and reported in brief in another column, the author
made some very drastic comparisons between the operating tactics of the
"progressive" road car managers and the "conservative" methods of the railway
men. In some of these we think Mr. Tritton has cause for his remarks; in
others we are inclined to doubt his deductions. As an instance, to secure
rapid and frequent running of rail cars in congested areas, he suggested
cars might follow each other "on sight," as opposed to the restrictions of
block working. We believe the trains of the New York Elevated Railway when
worked by steam, years ago, did run "on sight" —that is to say, the
rear of one train was a signal for the followmg one, but there the atmospheric
conditrons are presumably good and the tracks run in long, straight stretches,
with stations almost equidistant—ahout three to a mile. On approaching
curves, junctions, etc., automatic signals and obligatory traffic stops were
arranged. To railway men this running "on sight" will not, we think, appeal,
and we are not sure that more rapid services could not be made with automatic
signals. On the road a following car can be diverted to right or left to
pass a stationary obstacle; but not on the rails; there, there. is the absolute
necessity to remain on the track.
In his remarks on the comparative tare of road and rail vehicles, he will
probably receive more support from railway rolling stock experts. We believe
this subject has often been referred to in other papers read before the
Institution. One in particular we remember gave some very convincing figures
regarding the heavy dead-weight hauled. One speaker at the last meeting thought
that railway men purposely added weight to the rolling stock, presumably,
in their opinion it was necessary to keep the vehicles on the track.
The principles of railway carriage design have not varied for many years,
but there are signs of these standards givlng way. An instance quoted by
Mr. Tntton is in the design of seats. Quotations were received for bucket
type luxury seats from two firms, one specialising in the manufacture of
railway material. In the railway type the seat offered weighed 125 lb. at
a cost of about £19, whilst the road body specialists offered a seat
to the same design which had a weight of 65 lb. at a cost of £11. Now
that materials are available which combine lightness of weight with great
mechanical strength it should be possible to modify construction. to withstand
the rough usage of railway service with a low tare weight, combined with
suspension giving smooth riding.
Compared with an up-to-date steam train, the figures given for rail cars
built during the past two years appear hopeless, for the weight of passenger
stock has been steadily going up. Fifty years ago on the old L.B. & S.C.
Ry. a suburban train of ten carriages hauled by a Terriertank locomotive
had seating accommodation for 424 passengers, and provided this on a dead
weight of 370 lb. per seat, excluding the motive power. To-day the weight
per seat in a suburban train is from 450-500 lb. without the locomotive.
If the cost of working a railway is directly influenced by the gross ton
miles operated, then a reduction in tare weight of the rolling stock would
assuredly prove an economy which would make itself very evident in the balance
sheet. Other remarks of interest from the author and other speakers were
the possibility of running motor rail cars as multiple-unit trains. This
us being done to a certain extent, as evidenced in many descriptions of rail
cars we have published in this journal; but we do think it could be much
further developed—in fact, there should be no serious reason why the
multiple-unit electric train could not be duplicated with motor-driven rail
cars.
The supposed necessity for sufficient power being provided in rail cars for
the haulage of a horse-box, or milk van, appears a bug-bear with some railway
men. Why this should be we cannot understand, for any traffic of that sort
could just as easily be sent by road as by train. As a matter of fact, we
have been told that one progressive railway manager turned round on such
a question being raised and bluntly said, "leave the d—d thmg behind."
Another and rather important difference between road and rail operation which
calls for attention is the arrangement of the timetables. Road vehicles generally
leave at clearly defined mtervals, so that there is little need to refer
to a time-table. Rail trains could just as easily be started on their journeys
at regular intervals and at even timmgs. Of course there are instances where
this has been arranged, but there is still room for radical improvement on
some lines.
See also Julian Tritton's reservations on this
editorial
Rebuilt Atlantic type engine with poppet valves, L. & N.E.R. 66. illustration
C7/2
Diesel-hydraulic railcar for the L.M.S. Ry. 76-9.
4 illustrations, diagram (side, end & section elevations & plan)
Leyland Motors four-wheel rail-bus: trial run from Euston to Watford
and back. Sir Arthur Rose, a Director
of LMS, took controls on return journey. Includes description and pictures
of braking mechanism based on automotive practice. See
also p. 127
Institution of Locomotive Engineers. "Rail cars"— a
paper read by Mr. J.S. Tritton, Member. 80-1
Paper 322 read
at the meeting held on 22 February: abstract the author gave a concise survey
of the recent rapid development of the rail car for various uses as a guide
to linking up the requirements of the operatmg department with the many types
of vehicles now available.
Until about two years ago railway authorities insisted on standards of weight
and accommodation which road designers considered excessive. The original
"Sentinel" coach built ten years ago for the Jersey Railways weighed eighteen
tons to carry 56 passengers. To meet railway requirements the design was
modified again and again, untII.to-day the same type of vehicle is running
on a British railway, but weighing 30 tons. This state of things is now being
remedied and railway authorities during the last two or three years have
gIven wholehearted co-operation to the car builders m their experiments.
Dunng the war all sorts of road vehicles were converted to run. on railways,
but none of these designs has survived, The snag is that the road type. power
unit and transmission, when no longer cushioned by the pneumatic tyre, will
not stand up to the high frequency vibrations of the railway track.
The problem of specifying requirements from the traffic point of vlew is
no easy one. A preliminary classification indicates their use for four pnmary
purposes:-
(1) To meet road competition m sparsely populated districts.
(2) To develop branch line traffic.
(3) To pick up and distribute between main line junctions.
(4) To provide economical high-speed interurban services for light loads.
In considering the first two categories it must be realised that more people
live along a road than around a station or along a railway line, and the
bus which passes .the door will always have preference for short Journeys
over the train or railcar, unless compensating advantages of speed comfort
and safety are offered, frequency of servIce bemg a common factor. From this
it follows that the rail car must operate in sparsely populated districts
under conditions as similar as possible to those under which the road bus
operates, i.e., wIth frequent stops, high acceleration, close headway and
punctuality. Some rail cars in service in Northern Ireland carry a notice
advising passengers that "This car will stop any- where on request," and
such a provision could readily be made on many branch lines, giving an effective
increase in availability. On certain sections it should also be possible
to dispense with the usual signalling systems, and allow cars to run "on
sight" during certain periods of the day. Effective braking and powerful
headlights should allow such services to be run with as much safety as a
tram car in busy streets, while allowing for increased speed. For such services,
cars of the light 4-wheeled type with seating for 40 passengers, and
accommodation equivalent to the road bus, low level mounting platforms, and
a power-weight ratio. of 5 to 8 h.p. per ton, offer the mast economical solution,
Where higher capacities are reguired, with luggage accommodation, the bogie
railbus, with a seatmg capacity of 40-70 passen gers, will be called for,
the same power-weight ratio being maintained.
Instances have occurred .in which a rail car service has increased traffic
beyond its capacity, and the car has been replaced by the older type of steam
train, but running to the original train timings. The result has been that
traffic has again fallen off. The obvious remedy was to. increase the number
of rail cars or to increase the capacity of the units, wIthout decreasing
their speed and frequency.
For the third category, in which cars are used as pick-up and distribution
units between main line junctions, a more expensive type of car is indicated.
More comfortable accommodation and luggage compartments will be required,
while a higher power-weight ratio becomes necessary to enable the cars to
clear sections rapidly between express trains. In the fourth category, the
use of rail cars for ultra high-speed inter-urban services is of more recent
origin—following on the technical developments of light-weight streamlined
body construction. Here the advantage ot high speed between terminals compensates
for fbe extra time involved in reaching and leaving the termmals, and high
speed can be accomplished with greater safety and comfort than on the road.
There will be a certain amount of overlapping in these categories, but the
more precise the operatmg department can be in their requirements, the more
efficiently can the car be designed and operated.
At present rail cars are being run in experimental services to the timing
of the corresponding steam trains in the same service. Indeed it has become
a criterion of rail car efficiency to say that a rail car has replaced a
train unit under identical conditions for a given period of time. This denies
the rail car of two of its greatest advantages, namely, its increased
availability and its capacity for accelerated schedules as compared with
the train service.
A consideration of the foregoing will assist the designer in meetmg the
requirements.
The thorny question of trailers must be dealt with in considering the seating
capacity of the rail car. To load a rail car with a heavy trailer, defeats
to a great extent its own object, which is to increase the capacity of a
high-speed frequent service. If a road .bus company finds a 70-passenger
load available at a given time and place, there is no question of carrying
the odd twenty passengers in a trailer, but a second bus is put on, capable
of the same speed as the first, and running to practically the same timing.
Under similar conditions the railway is hampered by block section working,
which may enforce a considerable interval between the two units, unless "on
sight" running is permitted. To avoid this, a standard coach is attached
as a trailer, thereby probably doubling the weight and halving the power-weight
ratio of the combination. To take this trailer, either the original booked
speed must be reduced or the original rail car must be overpowered for solo
running. The correct solution is to provide a second rail car capable of
coupling with the first under unit control, thus maintaining the power-weight
ratio, and the combination can run to the original timings and block section
working. Continental practice favours the provision of standing room to take
fluctuating overloads. If a trailer is essential, it should be specially
built of the lightest possible design.
It will be maintained that for branch line working, it is necessary to haul
the occasional wagon and the inevitable horsebox, but this surely is the
'work of the light locomotive handling mixed trains, and should not be allowed
to prejudice the high-speed passenger service, which is the raison d' etre
of the rail car. It must be remembered that to enable the rail car to couple
with and haul a standard vehicle, the increase in weight and power required
is cumulative. A solo rail car was designed to carry fifty passengers. The
weight came to 24 tons for the class of service required. To enable this
car to haul a standard coach as a trailer, the extra weight in the under
frame, standard buffers and couplings, brake gear, etc., worked out at 30%.
To haul this extra weight, in addition to that of the trailer, at schedule
speed increased the engine power required by 75 %. The larger engine, in
its turn, weighed more and took up more space. It also meant heavier
transmission, bigger tanks and auxiliaries, so that the weight of the original
car was increased from 24 tons to 31 tons, and the cost nearly in proportion.
It is doubtful whether the occasional necessity to haul a trailer
can justify the increased running expenses, interest and depreciation charges
which will be entailed throughout the life of the vehicle. As an instance
of how railway standards are giving way is in the design of seats. Quotations
were received from two firms for bucket type luxury seats, one specialising
in the manufacture of railway material and the other in bus material. In
the railway type the seat offered weighed 125· lb. at a cost of about
£19, whilst the road body specialists offered a seat to the same design
which: had a weight of 65 lb. at a cost of £11.
The author considered the vital factor at present in rail car design is the
power-weight ratio on which depends not only the maximum speed but also the
acceleration of which the car is capable. Whereas ratios up to 4 h.p. per
ton were considered adequate up to five years ago, figures of 8 to 10 h.p.
per ton now rule, while for high-speed cars ratios of 25 to 30 h.p. per ton
are used. When considering acceleration, comparison is frequently made with
that of electric suburban services where acceleration of 1.5 m.p.h. per second
is available. The comparison is of course fallacious, since with an external
power supply the acceleration is only limited by the overload rating of the
traction motors, which may momentarily be 200 per cent., and by adhesion
of the driving wheels. With the rail car, however, the limit of power available
is the overload of the power unit, and acceleration therefore depends on'
the power-weight ratio of the vehicle. A power-weight ratio of 5 h.p. per
ton will give an acceleration of 1 m.p.h. per second. This appears to be
about the limit called for, so long as rail cars. are operated on steam train
schedules. The steam power unit scores here, since it can take advantage
of power stored in the boiler, while the steam engine working in late cut-off
can increase its output by 75 per cent. for short periods. Steam cars have
shown to advantage in recent trials in this, respect.
The power-weight ratio is also being increased by reducing the tare weight
of the car. Various methods of doing this in recent designs were given, among
them being:-Elimination of the standard railway under frame; draw and buffing
gear is dispensed with, except for a light spring bumper and emergency coupling
bar; designing- the body as a box girder to eliminate under frame ; welded
units and steel pressings replace castings and forgings wherever possible;
hollow axles and lightened wheel centres, with reduction in wheel diameter;
internal expanding brakes replace cast iron brake blocks and standard gear;
bus type- seats and internal fittings replace railway patterns. It is interesting
to see how the foregoing considerations have been given effect to in recent
practice. A comparison of over forty designs of British and Continental rail
cars built during the past two years shows the following average figures:-
20 seats per axle.
3.2 seats per ton of tare
8.2 h.p. per ton of tare.
It is realised that averages such as these do not take into account the special
conditions under which certain cars have to work.
A track depression indicator. 83-5. 3 illustrations, 2 diagrams
Stone Cardew device fitted to locomotive
L. Derens. The Holland Railway Company and its locomotives. 86-8.
2 illustrations, 3 diagrams (including side elevation)
Blorsig 2-4-0
2-8-0 locomotives, Udaipur-Chitogarh Railway, India, 89.
W.G. Bagnall locomotives for metre gauge line with 3ft 7in coupled
wheels, 16¾ x 22in cylinders, 1163ft2 total heating surface
(including 175ft2 superheater), 23.5ft2 grate
area.
Sir W.G. Armstrong Whitworth & Co. 89
Received an order for ten K3 class 2-6-0 from LNER; and for four
locomotive boilers from Buenos Ayres Greatv Southern Railway.
Robert Stephenson & Co. 89
Received an order for ten K3 class 2-6-0 from LNER.
E.E. Joynt. Reminiscences of an Irish locomotive works.
Last years at Inchicore. 90
See separate file
Rebuilding of three Derbyshire viaducts. 90
Work had begun in the Derwent Valley between Derby and Arnbergate
on the reconstruction of three big viaducts, carrying over the river the
L.M.S. main line from London and Derby to Manchester and the North, which
were to be rebuilt to carry the heaviest types of locomotive. The three viaducts
concerned were Belper Pool, Broadholme and Swainsley. All three to be constructed
in steel and concrete.
A remarkable small-scale model locomotive. 91.
Institution of Loco. Engineers, Annual Dinner. 91-2.
Diesel shunting locomotive Great Western Railway. 92. illustration
0-4-0 diesel mechanical locomotive supplied by John Fowler & Co.
(Leeds) Ltd for use at Swindon Works.
Twin dining cars, "Protea," South African Rys. 93-5. 4 illustrations,
3 diagrams
63 ft long and 9 ft 3 in wide: one car served as a dining saloon,
the other as a spacious kitchen. Special bogies were designed for the
coaches
Reviews. 97
Cross Channel and coastal paddle steamers. F. Burtt. London:
Richard Tilling. 97,
In this volume we have a comprehensive record of the paddle steamers
which have seen service round our coasts. The historical narrative commences
with the experiments ;n 1786 on a loch near Dumfries, followed by the
Charlotte Dundas built by Williarn Symington for traffic on the Forth
and Clvde Canal, which appeared early in 1802.
The first steam boar to carry passengers was the famous Comet, designed
by Henry Bell and launched in 1812 to run on the Clyde between Glasgow and
Greenock. Development was slow until the General Steam Navigation Company,
formed in 1824, put into service two small steamers, the Lord Melville
and the Earl of Liverpool. By the end of that year this company owned
ten steamers, adding five more in 1825.
In 1862, the old London, Chatham and Dover, South Eastern and London, Brighton
and South Coast Railways availed themselves of the recently granted Parliamentary
powers to operate cross-Channel services—which replaced certain French
Government services apparently started in 1820 with the pioneer cross-Channel
boat the Henri Quatre (ex Rob Roy.) The British Admiralty also
ran mail packets for the Post Office cross-Channel services and had quite
a fleet of steamers in commission, to be replaced later by a smaller series,
owned by the Post Office.
In 1863, the Great Eastern Railway obtained powers to run steamers from Harwich
to the Continent. These also replaced earlier services of a more or less
regular character.
The author also outlines the history of the various services of the Manchester,
Sheffield and Lincolnshire, London and South Western, Great Western, London
and North Western and L. & N.W. and L. & Y. Joint Railways, and gives
complete lists of the paddle steamers employed, with copious notes of their
careers. The Irish cross-Channel services of the City of Dublin Steam Packet
Company, Dublin & Glasgow S.P. Co. and Burns and Laird Lines—the
Dundee, Perth & London Co., the Clyde Shipping Co., and David McBrayne's
steamers, as well as those of the Isle of Man Steam Packet Company, are fully
dealt with.
The author expresses regret at the passing of the paddle steamer for the
few remaining examples are almost exclusively reserved for short trips. The
book is particularly well illustrated, with ninety reproductions of paddle
steamers. including a coloured frontispiece and five excellent plates printed
by the offset-litho process. The volume provides pleasant reading. apart
from being a historical record of the steamers. Mr. Burtt has apparently
handled his subject with the same meticulous care for details that he exhibited
in the compilation of the History of the Locomotives of the London, Brighton
and South Coast Railway. The print and finish of the blocks is all that
can be desired, and there is a useful index at the end of the book to some
eight hundred steamers mentioned in the text. We know of no other volume
dealinq with the British Paddle Steamer and we consider it to be a useful
addition to any librarv, as the host of dimensions and details it contains
are arailable in no other book.
Correspondence. 97
Rebuilt Pacifics P.O. Railway. W.
Lubsen
In January issue, you describe a P.O. Pacific rebuilt with 4-8-0 wheel
arrangement. It seems to me that the grate of the new boiler with its narrow
width and its enor mous length is too small in area for the rebuilt engine.
Even with a coal of very high quality, the amount to be burnt hourly per
square metre of the grate are" will be very considerable. On the other hand,
although the grate is steeply inclined, by its enormous length of 3.7 m.
it will be difficult for the crew to keep the fire even over its area. When
the engine is heavy working for a long time the econ- omy in combustion will
suffer from both reasons. Of all the types of modern passenger and express
engines with the same wheel arrangement as the P.O. engine, this machine
has the largest dr iving wheels and other general dimensions, but almost
the smallest grate area, as may be seen by the following table. Only the
grate area of the very light class 401 of the Spanish Andalusian Ry. is smaller.
Railway & class |
Driving wheel diameter |
Grate area m2 |
Weight in working order tons |
Remarks. |
P.O Rebuilt 4521 |
1.8?0 |
3.76 |
106.2 |
|
Austrian Fed. 113 |
1.740 |
4.46 |
85.2 |
|
Polish State Os2 |
1.750 |
4.35 |
90 |
|
Hungaria 424 |
1.606 |
4.45 |
82.3 |
|
Andaluces 401 |
1.620 |
3.52 |
82.3 |
Broad gauge |
M.Z.A. Spain 1301 |
1.600 |
4.10 |
86 |
Broad gauge |
M.Z.A. Spain 1401 |
1.1?? |
4.56 |
86.6 |
Broad gauge |
Nor e Spain 4301 |
1.560 |
4.65 |
88 |
Broad gauge |
Baira-Alta 101 |
1.630 |
3.97 |
83 |
Broad gauge |
In all cases, where it is impossible to build up a wide firebox "over frame and wheels," the classes with a trailing axle such as Mikado, Mountain, and 2-8-4, are preferable to the 4-8-0 arrangement. See also letter from Metzetlin on p.165 .
Steam locomotive design. E.A.
Phillipson. 97-8
I do not think it can be inferred from my text that equality of length
for the radius and eccentric rods of the Walschaerts gear, although desirable
from the ideal point of view, is rigidly essential. Actually, the respective
lengths are ultimately determined by the location of the link trunnion which,
in any given design, is usually restricted by the diameter and disposition
of the coupled wheels, frame design and other extraneous factors; for this
reason the lengths frequently do vary in practice, as stated by
Cosgrave.
Now, neglecting their respective displacements, which form but a small proportion
of the total, the distance between centres of the eccentric crank pin and
point of attachment of the radius rod to the combination lever respectively
may be regarded as a predetermined and more or less fixed dimension in any
design. For reasons which are given below, both the eccentric rod and the
radius rod require to be as long as possible and, as both are affected and
limited by this fixed dimension, this condition may be satisfied, to the
great- est advantage of both rods, by a compromise, i.e., by equalising as
nearly as possible their lengths.
Both rods require to be as long as possible, as also does the link slot,
in order to reduce slip; maximum rod lengths are also required in orrler
to minimise the heavy dynamic loads on the valve spindle guide and link trunnion
bearing, and also that they may be satisfactory, from the point of view of
design, when treated as columns.
Considering the rods individually, the eccentric rod needs to be as long
as possible in order to minimise the effects on the steam distribution of
the vertical movement of the engine on its springs, and also to reduce the
effects of angularity, thus tending to symmetry of link swing. In the case
of the radius rod, optimum length is required in order that the link radius
may be as great as possible, and that the load transmitted m ay be as nearly
as possible normal to the combination Iever.
I was very interested in Caton's remarks on the different
methods of locomotive working, but am not pre- pared to agree that the
arguments for and against working with early cut-offs were discussed in my
article "mainly from a theorct ical point of view"; in this particular instance
theory and practice are, I think, substantially unanimous. As stated by Caton,
and by myself in earlier articles of the series, the feasibility of running
with early cut-offs depends on a number of factors, e.g., valve characteristics
and dimensions, port areas, blast pipe and chimney proper- tions. My footplate
experience leads me to the conclusion that, provided proper regard be paid,
when designing, to th c properties of the valve gear employed (to take a
random example, the increase occurring in the lead as the Stephenson gear
is notched up), the type of motion adopted does not in itself play a decisive
part in the matter. With regard to the two excellent papers, of which extracts
are given by Mr. Caton, from the Journal of the Institution of Mechanical
Engineers, I can only concede a qualified agreement with Prof. Lomonosoff's
remark that "drivers (and, I am tempted to add, many other sections of the
community!) .... are usually quite right in their mistrust at theories."
This may be true in some cases, but as a general- isation is distinctly
dangerous; at the same time it must be admitted that much depends on the
intrinsic worth of the theory concerned! Prof. Lomonosoff's subsequent statement
that "for superheated steam cut-offs of less than 20 per cent. are not advisable"
is contrary to my experience; I am acquainted with several classes of engine
which give satisfactory results with a much earlier cut-off. Turning next
to the question from Dymond's paper, I personally consider the chief cause
of those longitudinal dis- turbances in the train which may be traced to
the locomotive itself lies in imperfect balancing, the effect of which varies
with the square of the velocity, rather than in fluctua- tion ef m.e.p. due
to running with an early cut-off. The extent of recurring impulses arising
from fluctuating piston loads, excessive compression occurring with
insufficiently long valve travels, or excessive lead, is a linear quantity
and therefore directly proportional to the speed. At high speeds of revolution
the fluctuations are so rapid as net to be perceptible in the train, and
at low speeds the probabilities are either that the engine is working with
a late cut-off, in order to accelerate the train, or running with the regulator
shut. The four-cylinder G.W.R. engines are certainly very well balanced,
but the choice of these engines, as an example to support this particular
argument, is unfortunate in that practically all of them run habitually with
a full regulator opening and early cut-offs.
Paris-Orleans Railway 4-8-0 type locomotive. William T. Hoecker. 98
Some of the statements made concerning the performance of this locomotive,
especially in view of its rather small boiler, are most extraordinary and
would perhaps be more convincing if accompanied by detailed data of the trial
runs. It is to be hoped that the remarkable claims for increased power and
economy rest upon a more solid basis than do the extravagant figures which
purport to represent the maximum theoretical tractive efforts. An effort
of 57,470 lb., "with high pressure steam admission to the large cylinders,"
involves a factor of adhesion of only 2.9 and may be dismissed without further
comment. If it is assumed that the power is equally divided between high-pressure
and low- pressure cylinders, the maximum tractive force of 45,930 lb., working
compound, requires a mean effective pressure of 212 lb. in the H.P. cylinders
and of 100 lb. in the L.P. cylinders. It would be both interesting and useful
to know just how a mean effective pressure of 212 lb. can be maintained in
the H.P. cylinders with a boiler pressure of 290 lb. and a back pressure
of at least 100 lb.
(The figures in the article are those officially given by the Railway
company, and the tractive effort is calculated on the assumption of 100%.
The corresponding factors of adhe- sion are officially stated to be: simple
expansion, 2.895; working compound,.-Ed.)
Trade notes and publication. 98
Light-weight Motor Trains. 98
Title of an attractively produced illustrated brochure issued by Sir
W. G. Arrnstrong, Whitworth & Co. Ltd. (Engineers) Scotswood Works,
Newcastle-upon-Tyne. These new vehicles should enable railway companies to
give the public a frequent passenger service, to compete more successfully
with road traffic. The light motor train as compared with the steam power
unit has the advantage of increased availability and in the saving of time
for raising steam and for boiler washouts, etc. Shuttle services can be run
continuously all day, without locomotive movements or duties. The turn-round
time is limited only to the time taken for the driver to walk from one end
of the car to the other.
Powdered and granulated aluminium. 98
Both employed for a number of purposes in engineering, and these are
detailed in a practical and interesting booklet just issued by the British
Aluminium Co. Ltd. of Adelaide House, E.C.4. Probably the largest use of
aluminium powder is for making metallic paint, either in its natural colour
or tinted with aniline dye to obtain gold, bronze and other effects—so-
called silver paint is usually bright aluminium paint. Apart from its use
as a decorative medium, aluminium paint possesses a high protective value
against sun, rain and impure atmospheric conditions generally. As a light
reAector tests have shown that the paint is capable of refecting up to 70
per cent. of the light that falls upon it, and rather more of the ultra-violet
rays that are so destructive to the varnish or oil medium contained in paint.
It reflects not merely the light waves but also the heat waves, and this
property is made use of fer oil storage tanks, tank wagons, refrigerator
cars, and a variety of similar objects more particularly in countries which
are more favoured with sun than these Isles. As a heat conserver aluminium
paint is made use of for reducing the radiation of heat from hot objects
such as boilers, furnaces, steam pipes, annealing ovens and similar plants.
Many other impertant purposes for which aluminium powder has superseded other
compounds are detailed. Another development in the use of aluminium both
powder and so-called "granulated" as a protective agent is known as "calorizing"
which consists of driving aluminium into the surface of another metal, usually
mild steel or cast iron, to form an aluminium alloy x, This alloy is immune
to oxidation up to 9500 C. and is entirely resistant to the corrosive attack
of gaseous sulphur products. Quite a number of other uses and methods are
clearly detailed in this artistically produced booklet.
The 500th Number of the "Locomotive". 99-101.
Diesel locomotve forv Woolwich Arsenal. 101-2.
Twin three axle bogie Hunslet Engine Co, Ltd. for eighteen inch gauge
with McLaren four-cylinder engine and drive through a gearbox and
clutch..
Three-cylinder 2-6-4 passenger tank engine, L.M. & S. Ry.. 102-4.
illustration, diagram (side & front elevations)
No. 2500 illustrated: three-cylindersd for maximum acceleration
Mikado type express engine, Polish State Railways. 104
For service in Danzig Corridor
Project for a locomotive of high capacity. 106. diagram (side elevation
and plan)
Chapelon scheme for a six-cylinder compound 4-8-4 with divided drive
and double blast pipe and thermic syphons.
O.J. Morris. The rolling stock of the Portsmouth Gas Company: industrial locomotives in service. 111-12. illustration
Institution of Locomotive Engineers. "One hundred years
of railway coaches." .119
At the meeting held on the 15 March. a paper with the above title
was read by A.N. Moon Assoc. Member. The president, Major C.E. Williams,
O.B.E., occupied the chair and a large number of members were present. The
author of the paper introduced his subject with a reference to the early
history of wheels and wheeled vehicles prior to the advent of the locomotive.
He then gave on the screen a reproduction of a well known illustration of
trains on the Liverpool and Manchester Railway describing many of the outstanding
features in these. Following up the evolution of the railway carriage, Moon
showed a number of different attempts at improvement in accommodation introduced
be- tween 1840 and 1870 including an early smoking saloon for the Eastern
Counties Railway and a mail coach for the London and Birmingham Ry. The comforts
of third class travellers must have been very limited judging from the
illustration of such a carriage built for the Manchester and Leeds Railway.
Great advance was made m the years immediately following 1870.
By 1872 the Midland Railway's third class compartment had been increased
in size to 6 ft., the first class being 7 ft. 3 in. and in the following
three years the second class was abolished. The third class was then further
improved by the provision of cushioned seats and backs. One oil lamp still
did duty for two compartments, however, the partition being cut to accommodate
the introduction of the roof lamp.
First class sleeping cars of the transverse berth pattern now familiar, were
introduced in 1873 on the orth Eastern Railway, arousing some criticism at
the time. Sleeping cars of the Pullman Car Co. of America commenced running
in the following year on the Midland Railway, presumably fitted with the
American type of longitudinal berth; these cars ran until 1888. The Pullman
Company not only ran sleeping cars but "parlour" or "drawing-room" cars on
the Midland Railway. They were all introduced at the same time, 1874, and
constituted an important step forward, for they were the first bogie coaches
run in this country. Midland drawing-room car No. 8 was shown, probably one
of the 1874 importation and almost certainly of the same type. The bogie
for locomotives was an English invention, being patented in 1812 by William
Chapman, a locomotive builder, but it was not used in this country for passenger
stock until after Ross Winans had applied it to such vehicles in America.
Locomotives were first mounted on bogies in England in 1833. The bogies on
the Pullman car illustrated seem to have had a composite wood and iron framework
and to have been similar in general features to modern American and Continental
practice. The mtenor of this "drawing-room" car was illustrated. The traveller
sat on a swivel chair beside what must then have seemed an embarrassing expanse
of glass window. These open saloon coaches were not received with great favour
by the conservative British public, who preferred the additional privacy
of the old type of compartment stock. The Midland Railway were quick to see
the advantage of the bogie and built bogiie coaches of their own. There is
a drawing m existence at Derby dated 1874 and showing what must have been
a very early attempt at a carriage bogie design. The rivalry which existed
between this railway and the London and North Western prevented the latter
from adopting the bogie. Instead, in 1882, they produced their first coaches
with radial wheels. These carrages were 42 ft. long mounted on six wheels,
of which one pair was arranged to swivel so as to take up a more or less
normal position on a curve. Eventually this railway adopted bogies.
The author's reference to the introduction of continuous brakes on the British
railways was followed with interest especially the mention of Barker's hydraulic
system on the old Great Eastern Railway. Further, the cord communication
in use before the introduction of the present alarm signal apparatus awakened
memories of a device which seldom worked when called upon. Tram lighting
contributed to the very comprehensive contents of Moon's paper as also did
train warming. Finally, a number of recent examples of metal construction
were thrown on the screen and the chief features explained.
In the discussion which followed, the magnificent examples of private cars
used bv Indian princes were mentioned and several speakers contributed items
to the interesting historical details recorded in Moon's paper especially
on the extended use of six-wheeled carriages with radial wheel bases.
See also letter from W.B. Thompson on page 195.
German State Railways. 119
In the course of his remarks at the recent Berlin Automobile Show,
Dr. Dorpmueller, Director-General of the German State Railways, referred
to the application of the internal combustion engine for railway traction,
and said that the German Railways had ordered a large number of express railcars
to work about 23 main line services. Dr. Dorpmueller also gave some details
of results of railcars on the German State system, and mentioned that accumulator
railcars had been abandoned. The manufacturers had been able to increase
the power output up to 400 h.p. per engine. The "Flying Hamburger" had two
400 h.p. engines, making a total output of 800 h.p., and top speed of over
100 m.p.h.; it would soon be surpassed by a type of expres railcar equipped
with two 600 h.p. Maybach 12-cylinder engines, i.e., a total power output
of 1,200 h.p. While the average speeds of the quickest trains in Germany
to-day is 43.4 miles per hour, the average speed with the diesel motor train
will be 64 miles per hour, cutting the timings by over 30 per cent.
Besides the Berlin-Hamburg fast services, the railcars will shortly be introduced
on the Berlin-Leipsig and Berlin-Dresden sections with a seating capacity
of about 180 in each train.
Welded light weight German coaches. 120-1. 2 illustrations
Vereniningente Westdeutsche Waggonfabriken A.G. for German State Railways
seating 84 third class passengers.
Some locomotive inventions of Joseph Beattie. 121-2.
2 diagrams.
GB 8741/1840 (16 December 1840): a device by which the driver could
adjust the weight available for adhesion on a single driving wheel
locomotive.
E.A. Phillipson. Steam locomotive design: data and formulse. Chapter XI. Compound expansion. 123-5.
Obituary. 125
It is with great regret we have to record the death of William Temperley
Batho, who died suddenly of bronchial pneumonia in his sixty-eighth year
at Rio de Janeiro March 26, 1934. He was educated in England and in Bonn,
Germany, and then entered his father's office, the late W.F. Batho. His
apprenticeship was served with Dubs & Co. of Glasgow and afterwards he
was associated for a period with Gaulcher & Co. Batho then joined the
East Indian Railway as a civil engineer and remained in India for a number
of years. Upon his return to England he took an active part in the formation
of the Diesel Engine Co. and was its managing director until merged with
the firm of Carels Freres of Ghent into The Consolidated Diesel Engine
Manufacturers Ltd. with whom he occupied a similar position. Batho was thus
largely responsible for the early commercial development of the Diesel engine
in this country in which work he was closely associated with the late Dr.
Rudolph Diesel. In 1914 he joined Sulzer Bros., London, and has been in charge
of the Diesel Department there since. Upon the formation of Sulzer Bros.
(London) Ltd. he was elected to the board of directors, a position he occupied
until his death. He was a man of firm character, integrity and strong personality
and his death will be regretted among a wide circle of friends in all parts
of the world.
[E.H. Purser]. 125
We regret to record the death of E. H. Purser formerly chief locomotive
inspector of the L.B. & S.C. Railway, on 25 February, at the age of 73.
Purser joined the Brighton Railway at the age of 14 and became fireman, driver
and finally chief locomotive inspector of the Southern Railway. He served
under five chief mechanical engineers, W. Stroudley, R. J. Billinton, D.
E. Marsh, L. Billinton, and R. E. L. Maunsell. He was the first driver to
have the 4-6-2 tank engines Nos. 325 and 326 Abergavenny and
Bessborough , and handled the latter for several years. After 51 years
on the railway, Mr. Purser retired in August, 1926.
L. Derens. The Holland Railway Company and its locomotives. 126-7.
2 diagrams including side elevation
Former broad gauge locomotives built by Robert Stephenson & Co.
as 2-2-2 in 1861-4 and named Castor, Pollux, Amstel and Maas,
These were rebuilt between 1879 and 1881 as 0-4-2 (as shown in diagram).
They were equipped with the Thierry system for smoke consumption. They were
scrapped between 1897 and 1909.
Diesel-hydraulic railcar, L.M.S. Ry. 127
See page 76 et seq: failure to record that
Timken axleboxes fitted to vehicle
London Transport. 127
Osterley station opened on 25 March 1934: it replaced Thornbury Road.
The new station had a tower and beacon and faced thee Great West Road.
Stationary steam engines. 127
The LMS owned two stationary engines which between them had give 222
years of service. The older at Holyhead was 121 years old and pre-dated the
arrival of the railway. It was used to pump out the graving dock and operated
at 5 psi. The 101 year old Swannington engine provided power for the incline.
It had been instaled in 1888 and was built by the Horseley Coal & Iron
Co.
Persian State Railway. 127
Beyer Peacock had received an order for five 2-8-0 locomotives: 3
to work on the Southern Section to the Persian Gulf and two for the Northern
Section from the Caspian Sea to Tehran
New passenger cars for the Barmen-Elberfeld Suspension Ry. 128. illustration
Fast steam trains on the Netherlands Railways. 128-9. table
Trial of 4-cylinder 4-6-0 hauling a light trainn between Amsterdam
and Arnhem.
An ingenious reduction gear. 129-30. illustration
Pierce of the Welsh Granite Co. improvised a reduction gear for a
conveyorusing an old locomotive firebox as the base.
A Russian "booster" of the 'sixties [1860s]. 130.
diagram
Mahovo flywheel invented by C. von Schubersky and shown fitted to
a bogie
Reviews. 131
The wheels of Ind. John W. Mitchell. London:
Thornton Butterworth.
Railway men in different parts of the world have unusual opportunities
for contact with the people they labour amongst, have unique expenences and
many interesting episodes to talk about, but unfortunately few have the
inclination to write them down for publication, Here we have a notable exception;
we have seldom read a more interesting narrative of railway experience than
Mr. Mitchell's. He recounts his life, experiences and adventures, whilst
filling the appointment of a D.T.S. on the Bengal Nagpur Railway in India,
providing a most interesting and instructrve volume.
If only some of our politicians would get some first hand information from
the huge innocent rank and file of India before committing themselves to
so much talk and criticism of the work of European officials it would be
better for all.
Mr. Mitchell gives his experiences frankly and freely. He tells of the artifice,
cunning and deceit of the native staff as well as of the passengers and
merchants; of all these we have ample confirmation from others who have seen
service on the Indian railways. The author comments on the ingratitude displayed
by Indians to a service which has done so much for the advancement of their
country.
Mr. Mitchell's national pride when he noticed that the locomotives he came
in contact with were of British build does not appear to be shared with many
of the Britons still at the head of the railway administration for every
effort seems to be made to secure supplies of stores and even rolling stock
from any country but this, notwithstanding the fact that when the Government
of India wants money, it does not hesitate to come here for it. The number
of Europeans in the railway service has decreased by 2,300 in the decade
1922-1932, not much encouragement for the Briton to do his best in helping
to secure for India a satisfactory and successful transport system. Whether
the gradual extinction of the European element in the personnel is going
to eventually prove a benefit remains to be seen; we very much doubt it.
The tricks of the traffic staff and unreliability of many of the workers
is undoubtedly true to life. The sportsman will find much to amuse him as
the district the author was in charge of happens to be one of the finest
in India for big game; further, those interested in the customs of the Hindu
religious system will find much to entertain them in the author's description
of the huge pilgrimages he personally attended in his official capacity.
The Juggernaut festival at Puri calls for traffic arrangements by the B.N.
Ry. which few railway men in this country can really appreciate.
Finally, the author reminds readers of what the "Wheels of Ind " have done
to help the followers of Vishnu to enjoy- cessation of famine, freedom and
peace, the exploitation of natural and commercial resources of India and
the provision of markets for his produce, thus providing employment for the
people. "These same folk on religion, pleasure or business bent are flung
from Duzdap to Tinsukia, from Tuticorin to Peshawar in but a fraction of
the time of pre-railroad days. "
On November 5th, 1932, a special pilgrim train left Howrah station, Calcutta,
to visit the majority of the most sacred spots of the Hindu faith. The fortunate
ones, who thus encompassed in the space of a few weeks what would have formerly
taken a lifetime, lived and slept in the train. In a great sweep, south,
west, north and south again they rolled from shrine to shrine gathering merit
and absolution at each move of the wheels." A most interesting narrative
from life.
Die Diesellokomotive mit Unmittelbarem Antrieb. Arnold Langen, VDI.
Untersuchungen Ueber den Spuelvorgang an Zweitakt-Maschinen .W. Lindner,
VDI. VDI-Forschungsh~ft 363. Published by VDI-Verlag G.m.b.H., Berlin.
The first article in the above publication is a report on the trials
made by Langen for the Research Department of the Humboldt-Deutzmotoren A.G.
of airless-injection diesel engines, in their possible application to railway
traction. Tests were made with a stationary vertical 4-stroke airless-injection
motor of 250 mm. bore by 450 mm. stroke developing about 50 h.p. per cylinder;
and the informatlon sought was mainly as to the results of super-charging
and data for the necessary compressor plant. A section of the work is devoted
to tests of a method of starting in which combustion takes place in the air
used for initially putting the engine into motion; and this is followed.
with results of trials undertaken with a modified gear-driven locomotive
using an engine of normal construction and weighing about 20 tons.
Aided by comprehensive illustrations, the author reports upon experiments
made with various arrangements of motor, gears, and auxiliaries to overcome
te:chnlcal dlfficulties and in particular the pronounced fluctuations of
starting torque. Following a suggestion made by Wagner, an arrange ment similar
to that of a. steam locomotive was tried, i.e., a horizontal double acting
2-cylinder engine directly connected to the road wheels. The new constructional
problems arising from this design are explained, and the results of the tests
are given. . .
In the second article Lindner deals with engines working on the two-stroke
principle, and chiefly aims at elucidating the scavenging processes in such
motors on an experimental basis in the light of knowledge. gained from the
study of gas-flow in models and from. prevlous research on existing engines.
Cylinder scavengmg is dealt wIth under two aspects; the flow-pictures showing
the effects of high or shallow scavenging. These experiments, conducted both
with stationary and locomotive engines, give many indications useful for
computing the areas of the scavenging ports, the flow-resistance of cylinders
having varying port areas was measured. and a simplified method of calculation,
avoiding flow-equations, has been evolved. Numerous observations on the engines
tested justifies the application of figures derived from experiments made
with the piston at rest to an engine in motion. A section dealt with the
computation of the scavenging efficiency and its relation to the output of
the motor.
Facts about British Railways. 131
The British Railways Press Bureau has published a new edition of the
booklet bearing this title. It contains the figures for the year 1933, and
records many interesting facts. The railways collectively have a capital
of £1,100,000,000 invested by private subscribers, and as an investment
this has shown a very moderate return. In 1913 the net revenue represented
only 4.38 per cent. on the capital, and in 1933 this had fallen to 2.64 per
cent. No one can say the shareholders rob the public, in fact a large proportion
of the railway shareholders are themselves a part of the public. Luckily
the business of the railways is conducted on enterprising lines, and of late
years has shown increasing activity in improving services. One great merit
of the British railways is their safety; there were only two passenger train
accidents involving loss of life to passengers in 1933, six passengers being
killed. Yet, as we all know, many of the express services are run at over
60 miles per hour.
Number 501 (15 May 1934)
Steam still predominant. 133
Three cylinder 4-6-0 passenger engine with tapered boiler,
L.M.& S.R.. 134-5. illustration, diagram (side & front
elevations)
No. 5552 illustrated and one exhibited at Euston station on 23 April
1934 (St. George's Day). Text refers to "rebuilt Claughton", but with taper
boiler. Locomotive illustrated had high-sided version of Fowler tender. No.
5552 built at Crewe.
"Hunslet" diesel locomotive No. 7403, L.M.S.R. 136-7. 2 illustrations
4-8-2 three-cylinder passenger locomotive. Czecho-Slovakian State Railways. 137-8. illustration
Institution of Locomotive Engineers. New President. 138, illustration (portrait)
Trevithick Centenary. 138
E.A. Phillipson. Steam locomotive design: data and formulse. Chapter XI. Compound expansion. Factors affecting distribution of work over cylinders. 139-40.
J.C.M. Rolland. Inspection tour on the Victorian Railways. 140-4. 7 illustrations
Broad v. narrow gauge. Great Western Ry. 144.
illustration
Photograph taken by Edmund Broderip from a train of another train
approaching on the opposite track which was a broad gauge train on mixed
gauge track near Highbridge or Brent Knoll
The Flying Hamburger. 144-6. illustration, diagram
Der Fliegender Hamburger was a light weight
articulated streamlined train capable of 100 mile/h running and powered by
a Maybach engine. Livery was mauve and cream.
Some aspects of modern railway traction. 146-9
The world-wide economic crisis had, in France brought about a disastrous
collapse in railway finances, and anxious scrutiny was given to all proposals
for reducing operative expenses and recovering something of the traffic lost
to other methods of transport. Whilst some would find a remedy in the wholesale
electrification of railways, others maintained that a better solution was
to be found in the improvement of motive power equipment, but retaining the
principle of self-contained locomotives, either in the form of steam or internal
combustion motors according to circumstances and conditions. Considered
impartially, it would seem that all these expedients, i.e., steam, internal
combustion, and electric traction, had a place in the scheme of railway
reformation, but the proper function and scope of each is still undetermined,
and the problem is not clarified by the violent and sometimes obviously
prejudiced propaganda addressed to a lay-public totally unfitted to judge
so highly complicated and technical a matter. A most useful contribution
to this subject had been made by Pierre Lavarde at a conference of the Civil
Engineering Committee of the Societe Industrielle du Nord held last May,
a now published under the title of "Les Elements d'une Traction Autonome
Modern sur les Chemins de fer." Space permits us only a summary of the author's
statements, and it must be borne in mind that he is chiefly concerned with
the question as relating to French railways, but so much of his data has
a general application that his conclusions are valuable in an almost universal
sense.
Considers the costs of diesel versus electric traction for express trains,
for shunting. Mentions the Micheline railcars and light weight rolling
stock.
Locomotives on the Military Camp Railway, Catterick.
150-2. 8 illustrations
Catterick was a major army training ground extending over 25 square
miles and developed during WW1. It was capable of holding 45,000 soldiers
and there was an airfield on the edge of the camp. A 4½ mile branch
linked the Camp Centre to Catterick Bridge on the North Eastern Railway Richmond
branch. As well as troops the branch had to handle military stores including
both food and armaments. A passenger service operated beween the Centre and
Catterick Bridge. The locomotive and carriage stock is both described and
illustrated. The LNER took over the former Camp Railway on 30 September
1923.,
Illustrations: Camp internal train formed of former North London Railway
four-wheel coaches and LSWR 4-4-2T; 2-4-0T WD No. 42 (former Stratford &
Midland Junction Railway No. 5 built by Beyer, Peacock WN 2466/1885); former
LSWR Adams 4-4-2T No. 0424 which had previously been at Longmoor and had
been overhauled at Darlington Works (and slightly modified before going to
Catterick); WD Nos. 102 and 104 were 0-6-0ST locomotives (No. 102 was an
ex-Rymney Railway (one of three acquired by the War Department and had been
built by Sharp, Stewart & Co. in 1872) It is illustrated next to
No. 104, a Hawthorn Leslie & Co. 0-6-0ST (possibly WN 1361/1875) and
was one of twenty purchased by the NER and was disposed to Messrs Wake and
acquired from them by the War Department. After disposal from Catterick it
worked at a colliery in the Barnsley District. WD No. 86 was a side tank,
former North Eastern Railway No. 968 and after WW1 was working at Milford
Haven Docks. WD No. 104 was formerly NER No. 1361 (and in the photograph
on p. 152 clearly displays its NER origin. Finally, Manning, Wardle &
Co.' s standard four-wheel saddle tank engines 0-4-0ST, No. 2, R.A.F.
was supplied by Messrs. Wake to the Royal Air Force, but so far, we have
been unable to trace the aerodrome at which it worked and may not have been
Catterick..
Great Western Railway. 152
The first two of the new series of Castle class engines were
into service: Nos. 5023 Brecon Castle and 5025 Chirk Castle.
New 0-6-0 goods tank engines were Nos. 8700 and 8795-8. Engines withdrawn
recently were 0-4-2 tanks Nos. 542, 829 and 833, 2-4-0 tanks Nos. 907, 975.
983 and 980, 0-6-0 tanks Nos. 639, 642, 1390, 1399, and 1535; 2-6-2 tank
Nos. 3919, 0-6-0 tender engine No. 1094, and 4-4-0 tender engines Nos. 3328
and 3343 Camelot.
Russian Railways. 152
A Diesel-electric streamlined train of four coaches, capable of carrying
185 passengers at over 100 miles an hour, is to be introduced on the
Leningrad-Moscow line this year. By equipping the train with special wheels
and springs, M. Poluyan, the inventor, hopes to increase this speed by more
than 50 per cent. The special wheels would, however, necessitate reconstruction
of points and crossings.
Cravens Ltd. were building for the Russian Government what was believed to
be the world's largest railway wagon. Its load capacity is 200 tons. It will
be of the well type and 100 ft. in length, supported at each end on two
siix-wheel bogies.
Partial re-numbering of locomotives. L.M. & S. Ry.
152-3
Comprehensive scheme of locomotive re-numbering had been adopted on
the L.M. & S. R. and was being brought into operation. When completed
all standard engines will have numbers below 10000 and, when the older types
are scrapped, all five figure numbers will automatically disappear. To reduce
to a minimum the amount of re-numbering necessary, the new scheme is arranged
so that well-known types, such as The Princess Royal, the Royal Scots and
the Midland Compounds will not have their numbers changed.
The numbring was scheduld for three stages
First stage; 193 engines to be renumbered immediately
1. 2-4-0 ex-LNWR Precedent class
No. 5001 to be renumbered 25001
2. 4-6-0 3-cyl. 5X class (The Baby Scots) to be renumbered as
follows:
| old | new | old | new | old | new |
| 5971 | 5500 | 5983 | 5514 | 5996 | 5528 |
| 5902 | 5501 | 5902 | 5515 | 5926 | 5529 |
| 5959 | 5502 | 5982 | 5516 | 6022 | 5530 |
| 5985 | 5503 | 5952 | 5517 | 6027 | 5531 |
| 5987 | 5504 | 6006 | 5518 | 6011 | 5532 |
| 5949 | 5505 | 6008 | 5519 | 5905 | 5533 |
| 5974 | 5506 | 5954 | 5520 | 5935 | 5534 |
| 5936 | 5507 | 5933 | 5521 | 5997 | 5535 |
| 6010 | 5508 | 5973 | 5522 | 6018 | 5536 |
| 6005 | 5509 | 6026 | 5523 | 6015 | 5537 |
| 6012 | 5510 | 5907 | 5524 | 6000 | 5538 |
| 5942 | 5511 | 5916 | 5525 | 5925 | 5539 |
| 5966 | 5512 | 5963 | 5526 | 5901 | 5540 |
| 5958 | 5513 | 5944 | 5527 | 5903 | 5541 |
3. 4-6-0 ex L.N.W.R. Experiment and Prince of vVales classes.
Existing engines numbered between 5500-5552 and 5600-5664 to be re-numbered
by adding 20000 to their present number.
4. 2-4-0 ex M.R.
The eight survivors numbered between 1 and 90 to have 20000 added to their
present number, thus, No. 2 will become 20002.
5. 2-6-2 standard passenger tanks.
The seventy engines of this class, now Nos. 15500-15569 have already been
re-numbered 1-70, whilst twenty more of this class now under construction
will be allotted Nos. 71-90.
Second stage: Engines of standard types are to be re-numbered as they
pass through the shops.
When any engine in the following nine groups is re-numbered should there
be another engrne bearing its new number under the old classification, the
latter will immediately be re-numbered also.
1. 0-4-0 Dock engines.
Nos. 1540-1544 to become 7000-7004.
2. Diesel shunters.
Nos. 7400-7408 to become 7050-7058.
3. 0-6-0 Dock engines.
Nos. 11270-11279 to be re-numbered 7100-7109.
4. 0-6-0 Tanks.
Nos. 1900-1959 to become 7200-7259.
Nos. 7100-7156 to become 7260-7316.
Nos. 16400-16764 to become 7317-7681.
5. 2-6-0 mixed traffic engines.
Nos. 13000-13284 to be re-numbered 2700-2984.
6. 0-6-0 ex M.R. Nos. 2700-2984.
Existing engines to have 20000 added to their present
numbers.
7. Former L.N.W. and N.L.R. tanks.
Surviving engines numbered between 7200-7399 and 7423-7681
to have 20000 added to their present numbers.
8. 4-6-0 ex L.N.W.R. "Experiment" and "Prince of Wales" classes
Engines not included in the First Stage of the programme mentioned above
to have 20000 added to their present numbers.
9. 2-4-0 ex M.R.
Surviving engines numbered between 91 and 279 to have 20000
added to their numbers.
Third stage: The remaining non-standard engines numbered below 10000
will have 20000 added to their numbers only when they are required by engines
of standard type.
From the above, it will be seen that under the new scheme the standard type
locomotives are allocated numbers as follows;-.
1- 399 2-6-2 tanks
Class 3
400- 799 4-4-0 simple
Class 2
900-1199 4-4-0 compound
Class 4
1200-1999 0-6-0 (proposed)
Class 2
2000-2499 2-6-4 tanks (2 cylinder)
Class 4
2500-2699 2-6-4 tanks (3 cylinder)
Class 4
2700-3834 2-6-0
Class 4
3835-4899 0-6-0
Class 4
4900-4999 0-6-6-0 Garratts
5000-5499 4-6-0 mixed traffic
Class 5*
5500-6099 4-6-0 Baby Scots
Class 5X
6100-6199 4-6-0 Royal Scots
Class 6
6200-6299 4-6-2 Princess Royals
Class 7
6400-6999 0-4-4 and 0-6-2 tanks
Class 2
7000-7049 0-4-0 dock tanks
7050-7099 Diesel shunters
7100- 7199 0-6-0 dock tanks
Class 3
7200-7999 0-6-0 tanks
8000-8699 2-8-0
9500-9799 0-8-0
Class 7
* The new 4-6-0 mixed traffic engines will be classified 5 for both passenger
and goods and will carry two separate indications, namely, 5 P and 5 F.
The Sentinel locos. are Nos. 7160-4 and 7190-1 and presumably these will
be re-numbered in duecourse.
Repairing the Bransty Tunnel, Whitehaven.153
To connect the termini of the Whitehaven Junction Railway and the
Whitehaven and Furness Junction Railway at the town of Whitehaven, a single
line tunnel, 1320 yards in length, crossing the town, was built 80 years
before. It is between Corkickle and Bransty stations on the L.M.S.R. coast
line from Barrow in Furness to Carlisle. After an interval of 80 years since
the tunnel was built the lining of red sandstone and brick has perished owing
to the action of weather and engine fumes, and it is now being repaired in
sections of 8 feet at a time, each section taking three weeks to complete.
Owing to railway traffic, work can only be carried on between the hours of
midnight and 4.30 a.m. and the repairs which started in 1932 will not be
completed until 1936. Two squads of miners are engaged in the work. The first
removes the crown of the tunnel arch, and this is followed by another squad
which strips the tunnel lining from the crown to the foundations. A gang
of bricklayers follows the miners, relining with bricks the portions removed
by the latter, and about 20 men are engaged on the work,
Some locomotive inventions of Joseph Beattie. 154-5.
3 diagrams
First part. Second part: combustion
and boilers: refers to Samuel Hall and Dewrance and
Hawthorn in early attempts to
burn coal. GB 13782/1851 enabled a mixture of coke and coal to be burned
in the firebox. GB 69/1853 Certain improvements for economising fuel in the
generation of steam (split firebox)
Electric locomotive design. VIII — Individual axle drives. 156-7.
2 illustrations, diagram
Jeaumont design applied to 1-Co-1 of the Midi Railway; subsequently
adopted by Swiss Locomotive Co. The Buchli-SLM drive was applied on 41 2-Co-1
supplied by Metropolitan-Vickers to the GIPR. The Soc. Alsacienne de Constr.
Mecanique supplied 2-Bo-Bo-2 to PLM; GEC/Hawthorn-Lesle with Oerlikon equipment
supplied 2-Co-2 express locomotives to GIPR; Skoda drive was used in 1A-Bo-A1
for Czechoslovak State Railway; 1-Co-1+1-Co-1 for New York, New Haven &
Hartford Railway used Westinghouse system with helical springs to relieve
torque stresses; and modified S.A. de Secheron AEG Kleinow on E04 and
BLS series 201.
Single-driver tank locomotive, Bergslagernas Ry., Sweden. 162. illustration
H.C.S. Bullock. Miniature Pacific type locomotive. 164. illustration
Engine illustrated was built for 10¼ in. gauge by the writer
to his own designs to produce a machine of maximum hauling power and at the
same time obtain accessibility to all working parts. The two cylinders are
5 in. stroke by 3t in. bore fi.tted with piston valves 1 ~ in. dia. and 1!
in. travel. The valve timing is 1/64 in. steam lead, 75% cut-off in full
gear, 1/64 in. exhaust clearance or negative lap. The valves are actua- ted
by a modified Baker gear. The cylinders are lubricated by a mechanical lubricator
having separate pumps, one for each cylinder. A combined snifting valve and
oil doping cup is fitted to each cylinder. Water pressure relief valves are
fitted to the cylinder covers ; the drain cocks being operated from the foot
plate. Inspection covers are provided opposite the four ports so that the
valves can be set by sight instead of the usual measuring off on the valve
spindle. . The driving and coupled wheels 12 in. dia. are heavy and wide
on the treads and the gauge is decreased slightly to enable the engine to
run freely around curves of small radius; a curve of 35 ft. radius can be
taken with ease. The bogie wheels are 7 in. in dia. The inside framed bogie
is allowed 1½. in. lateral play. The rear truck is fitted with outside
frames in order to clear the ash pan which is sloped forward and drops the
ash on the track; a front damper only is fitted. The pivot of the rear truck
is in front and below the firebox. The wheels are 6 in. dia. and the axle
which on an uneven track at times is heavily loaded, runs on ball bearings.
A powerful steam brake is fitted ; all brake blocks are compensated. The
boiler, which is after the pattern of the G.W.R. The Great Bear, is
13½ in. dia. at the front and 14½ in. at the firebox end. The barrel
is 4 ft. long and the firebox outside is 2 ft. long, 6 ft. overall. Twenty-eight
~ in. dia. and five 1 in. dia. tubes are fitted ; the latter accom- modate
a 5 element Swindon type superheater. The grate area is 262 square inches
and the heating surface 37 square feet. The combined safety valve and top
feed is designed in the form of a small dome from which the steam is collected.
This dome is detachable and provides the inspection hole cover required by
the insurance companies. The boiler is fed by one injector when standing
and a double acting pump worked from the cross head when running. A by-pass
control valve is fitted and can be operated from the foot plate. The engine
is 10ft. long and 21 in. wide over foot plates, and 2 ft. 6 in. high to top
of cab. The tender running on two four-wheel bogies fitted with ball bearings,
carries 28 gallons of water and provides ample seating accommodation. All
controls are easily accessible to the right hand from the driving position.
The length of the tender is 5 ft. 4 in, making a total length of 15 ft. 9
in. over buffers. The weight in working order is 21 cwt. The loco. is so
designed as to be easily converted to 9½ in. gauge
Raiway Club. 164
On Friday, 11 May a paper was read at headquarters, 57 Fetter Lane,
London, by the Rev. R.B. Fellows. entitled The History of the British Non-Stop.
Express.
Polish State Railways. 164
Supplementing the note regarding the locomotive classification on
the Polish State Railways in our last issue, page 104, the following will
be of interest. The letter P denotes express locos., O means passenger, and
T goods and mineral, while an additional k indicates a tank engine. Further
indications are: c, 2-4-0;: d, 4-4-0; e. 2-4-2; f, 4-4-2; h, 0-6-0; i, 2-6-0
or 0-6-2; k, 4-6-0; I, 2-6-2; m 4-6-2; n, 2-6-4; p, 0-8-0; r, 2-8-0; s, 4-8-0;
t, 2-8-2; u , 4-8-2; w, 0-10-0; y, 2-10-0; z, 2-10-2. Thus Pt 31 means a
2-8-2 express locomotive designed in 1931, Pu 29 is a 4-8-2 express locomotive
designed in 1929, and Os 24 a 4-8-0 passenger engine of 1924. Smaller figures
Pk 1, Pk 2, Ok 1, Tp 4, denote types in existence before the Great War, mostly
of German origin, and some Austrian. Russian and other types are marked in
hundreds, thus: Oi 101, Tr 103, Tp 102. Since the formation of the Polish
State Railways Administration the following classes of engines have been
designed: Tr 20, 2-8-0, built by Baldwins. Tr 21, 2-8-0, built by Chrzanow.
Ok 22, 4-6-0, Ty 23, 2-10-0, various builders. Cs 24, 4-8-0, Chrzanow. Old
27, 2-6-0 Tank, Ceaielski. Pu 29, 4-8-2, Cegielski. Pt 31, 2-8-2 Chrzanow.
Okz 32, 2-10-2 Tank,Cegielski. (The first of these is now on trial).
Backworth Colliery Co. 164
Acquired six coupled saddle tank locomotive No. 813 of the Great Western
Rly. now No. 12 in their list, whilst the Seaton Burn Colliery have bought
No. 815, G.W.R. and numbered 2 in their stock. :
Frazer & Sons of Newcastle. 164
Sold G.W.R. engines Nos. 724 and 747 to the Hartley Main Collieries;
now Nos. 24 and 25.
L. &: N.E.R. 164
Engines Nos. 900, 1308 and 1310 working on the Pelaw Main Collieries
Railway.
Correspondence. 165.
Dublin and Kingstown Railway.
C.F. Dendy Marshall.
Re article issue for 15 October 1926, page 330 actually p. 336), on
the early Dublin and Kingstown engines. There it is stated that the first
two engines built by the company were the Star and Jupiter.
From the minutes of the Liverpool and Manchester Railway
(see his Centenary History,
pages 105 and 106) it is clear that the Star was built by the
Horseley Iron Company (designed by Isaac Dodds).
Rebuilt Pacifics, Paris-Orleans Ry. Metzeltin.
Re correspondence of Mr. Lubsen in March issue. After my experience
the length of the grate of 3.7 m. does not prevent so very much a good
distribution of the fire as the writer thinks. When I was a young man I had
to fire locomotives with steeply inclined grates and I must confess that
it was a very easy task. I had to put the coals at the back end of the grate
only, and occasionally to spread some shovels evenly over the other parts
of the grate. By the vibration of the engine the coal worked down to the
front. Of course, a good distribution of the burning coal depends upon the
incline and the type of coal, but this experience can be very soon gained
by the fireman. Furthermore, when condemning the small grate area the writer
has overlooked that the P.O. engine has a deep firebox with 50% to 70% more
heating surface than the other locomotives alluded to. Therefore it is possible
to burn efficiently more coal per square foot of grate area than usual with
flat fireboxes, with the same economy. If the heavy draught lifts more particles
of coal, one must consider that the way and time for burning out is a
proportionally longer one than for flat fireboxes.
Rail cars. Julian S. Tritton. ,
Re editorial comments on my recent paper on Rail Cars I am credited
with suggesting "on sight" running of cars "in congested areas." In my paper
this suggestion was purposely limited to "certain sections," and I should
perhaps have made it clear that branch line working was prirnarily referred
to. There are many branch lines, especially abroad, where traffic at present
does not exceed two or three mixed trains a day in each direction. By restricting
these trains to freight only their number could be reduced, and their timings
arranged to leave the line free for a "bus" service of passenger rail cars.
2. In such circumstances "on sight" working would be perfectly feasible,
and would have many advantages, but the suggestion was not intended to apply
to "congested areas.
Loco. No. 1, N.S.W. Govt. Railways. A.V. Green
As a keen student of railway history, and deeply impressed with the
need of accuracy, permit me to draw attention to a matter which may cause
great doubt to the engineer and historian of the future, if not explained
to-day. On page 160 Locomotive 15 June 1921, and on page 410· Warren's
Centenary of Locomotive Building," appears an illustration of Loco.
No. 1 N.S.W. Govt. Railways. The description McConnel design and Stephenson's
No. 958 is quite correct. But the corrugated iron cab, and its pillars were
added after the engine commenced work here. What I wish to be noted, however,
is that the tender shown is not the original. Old pictures indicate plainly
that this was also of McConnel design with 6 wheels. Only the engine has
been preserved; its tender was broken up long years ago. The tender in the
illustrations I mention was a Beyer Peacock. I saw its maker's plate with
year 1865 on it. Further, maker's No. 542 was stamped on its details, and
this- was the maker's number of original No. 16 N.S.W.G.R. as per reports
of Commissioners Rae and Goodchap to N.S.W. Parliament during the 1870s and
1880s. Will you do your best. to make this clear?
History of the London and South Western. locomotives. C.F.
Dendy Marshall. 165-6
I have acquired a MS. "Report and Repairs Book" of this, line dated
June 1849. It shows that 77 Wildfire was originally named
Hecla; no doubt the name was changed in 1850. when No. 120 came out.
But what is more important, it is clear that the following engines were already
in existence: 17 Queen, 18 Albert, 19 Briton, 20
Princess, and (21) Prince.
I shall be much obliged if any reader can give me some information about
them (especially builders and dates).
In the articles which you published in 1903 no engines with. these names,
nor with these numbers (the omission of the latter is significant; there
is no reason why they should, have been left blank) are mentioned until the
year 1852.
Beattie is said to have introduced numbers. My book. proves they were in
use by June, 1849. In the Locomotive Magazine
for 1903, Vol. 8 page 326, it says: "About 1850 Mr. J. V. Gooch resigned"
In the volume for 1904, page 138, in. one
of the articles on the G.E.R. locomotives, -it says he became locomotive
superintendent of the latter railway in. August 1850.
Prior to Adams' arrival, there were three generations of engines numbered
from 1 to 44 (alterations in the names- being made in only three cases),
with the following exceptions : some of which can be explained, and others
cannot. It may be noticed that the practice on the South Western. was to
keep the numbers very close up, and not leave blanks.
Generation I was 1838-44; II, 1852-6 (except Nos. 27-30) ,. and IIII,
1870-5.
The following are the exceptions referred to;-
3 Transit. No second generation. The first was a Tayleur- of 1838;
the third a Beattie of 1870.
7 Venus and 8 Vesta. No second. The first were Sharps of 1838;
the third Beatties, 1870.
22 Giraffe, 23 Antelope, 24 Elk, 25 Reindeer.
No second. The first were Fairbairns of 1843; the third Beattie's, 1871-2.
Nos. 27:30 can be easily understood. They were large Gooch singles of 1843-4,
and, the second generation came later, namely 1862-3.
38 Vizier had no second generation; the first being a Rothwell of
1838, and the third a Beattie of 1871.
According to the articles in the Locomotive Magazine, there-is yet
another, 45 Titan, but this can I think be explained, by an engine
of 1855 being given as 145 Titan (Vol. VIII p.
394). This is almost certainly a mistake for 45 as they had not quite
reached 145 by then, and 145 Hood came out in 1858. It therefore appears
possible that Beattie may have built the following, or some of them, in the
early fifties, which have been missed, namely 3, 7, 8, 22-25 and 38.
In the article in the Locomotive for 1906, pages 41 and 89, four goods
engines by Beyer, Peacock and Co. which were dated April and May 1878, were
omitted, namely 151 Montrose, 152 Marmion, 160 Thames and
162 Severn. Nos. 229 and 230 were also left out, but supplied in the
corrective article in 1919. [cross references not checked, KPJ]
Operating costs. W.G.T.
Re leading article in February issue suggesting that "operating costs
offer perhaps the most likely field for fruitful economies" on our railways.
' As a frequent traveller on the Weymouth line of the Southern, I have often
thought that Dorchester is just such an instance. Here every passenger train
has to run past the station and be flagged back into the old 1845 terminal
platform. There appears to be no reason why a new platform could not be built
on the up through line. The land required is only used as allotments and,
from its position, ought to be obtainable very cheaply. The G.W.R. are now
modernising their station at Dorchester ; perhaps one day the Southern will
follow suit.
New L. & N.E.R. sleeping cars.. 166
On the sleeping cars used on the East Coast services, in order to
make the compartments more distinctive, a scheme of different colours has
been adopted for the decoration. For the first car shades of blue, yellow,
green and pink were selected for the different pairs of compartments. Each
berth is panelled in mahogany to a height of 3 ft. 6 in. above the floor,
the panelling being plain without redundant moulding. Above this panelling
the walls are finished in colour up to the ceiling, which is also coloured
a lighter shade of that used on the wall. The blankets used in the different
compartments are of colours which harmonise with the wall colours. The Wilton
carpet is in blue and fawn laid over sponge rubber to deaden sound. All fittings
are chromium plated. An ingenious illuminated toilet indicator is provided
in the corridor so that a passenger can see if the lavatory is vacant or
not from the door of his compartment. These cars with ten sleeping compartments,
are 61 ft. 6 in. long, 12 ft. 10 in. high, and 9 ft. wide, and weigh 37
tons.
Special evening excursions to Southend on Sea. 166
From Liverpool Street and Ilford, at return third class fares of 2/-
and 1/3 respectively have been introduced by the L. & N.E.Ry. They were
run on Saturday and Sunday, 12 and 13 May, and will be repeated on the 26
and 27 May. The down journey will be covered in 63 minutes and the return
in 62 minutes. Evening tickets are also being issued to Brighton by the Southern
Rly. on Tuesdays, Wednesdays and Thursdays at 4/- return from Victoria
Societé Nationale des Chemins de Fer BeIges. 166
Ordered eleven heavy-oil motor-trains. This brings the total of such
units in Belgium up to twenty-nine. Ten of the new motor-trains are intended
for short main-line and branch line working, and seat between 60 and 104
passengers; while a larger, 410 H.P. motor-train is to serve on long distance
routes.
Great Southern Railwavs. 166
Nq. 335, a 4-4-0 mixed traffic engine. had been rebuilt at Inchicore
with a Belpaire firebox, extended smokebox and superheater, but retains its
original cab. The other engines of the 333 class which had been rebuilt have
the new "canopy" cab. The new 0-6-2 tank engines Nos. 670-674 are all at
work and are on the Dublin (Amiens Street) to Bray section. "-
Peruvian Corporation Ltd. 166
Lessees of the Central Railway of Peru, placed a contract for three
oil-fired 4-8-0 locomotives with Beyer, Peacock & Co. Ltd. They were
required for passenger service over a heavily graded track.
W. D. Knight, 166
Chief mechanical engineer, .Egyptian State Railways, retiring in July.
Knight served as apprentice under Drummond of the L. & S.W . Railway.
In 1907 he joined the Egyptian State Railways as divisional superintendent,
later becoming assistant chief mechanical engineer. He was appointed chief
mechanical engineer in June, 1933.
Michael B. U. Dewar. 166
Chairman and managing director of British Timken, Ltd., sailed for
the United States to study industrial conditions in that country. Dewar was
elected a vice-president of the Federation of British Industries.
Institution of Locomotive Engineers.166
At the general meeting held on 15 March the following were elected:-
Members: Cyril Eyers, deputy chief mechanical engineer, East Indian Railway;
Edward Hodson Gray, chief mechanical engineer, Rhodesia Railways, Bulawayo,
S. Rhodesia; Thomas Hornbuckle, chief· technical assistant to C.M.E.,
L.M.S. Rly., Euston; Friedrich Joseph Kuretschka, director Caprotti Valve
Gears, Ltd., 66, Victoria Street, S.W.I.; Charles Robert Mayo, consulting
engineer (Fox and Mayo), 155, Dashwood House, Old Broad St., E.C.2.
Transferred from Associate Member to Member: J oseph Campbell, chief draughtsman,
F.C.P., Junin : Harold Montague Feltham. asst. traction supt., F.C.P., Buenos
Aires; Harold Charles Moxon, asst. to C.M.E., F.C.C.C., Alta Cordoba; Leslie
Barnett Norrish, asst. to C.M.E., F.C. Central del Uruguay. Penarol, Montevideo;
David William Powell-John, asst. to C. & W. Supt., F.C.C.A., Rosario
de Santa Fe.
Transfer from Graduate to Member: P. L. Falconer, Loco. Works Manager, F.C.C.A.,
Perez.
Associate members: Ernest Bradshaw, loco. running foreman, L.N.E. Rly ..
Bradford, Yorks.; John Marshall Shedden Dale, junior draughtsman. L.M.S.R.,
St. Rollox, Glasgow; Frederick Turner, asst. traction engineer, Messrs. Sir
W. G. Armstrong, Whitworth & Co., Ltd., Scotswood Works, Newcastle-on-Tyne,
Transfer from Graduate to Associate Member: Sydney Thomas White, progress
engineer, L.N.E.Ry., Openshaw Manchester. Graduates: Anil Nilmani Mukerji,
special class apprentice of Indian State Railways, L.N.E. Ry. Running Shed,
Newcastle-on-Tyne : John Inglis Scott, engineering apprentice, St. Rollox
Loco. Works, L.M.S. Ry., Glasgow; Ramaswamy Subbiah, probationer, Indian
State Railways, Motive Power Department, L.M.S. Rly., Kentish Town,
N.W.
Southern Railway.166
The 22.15 goods train from Nine Elms to Exmouth Junction is made up
of completely braked stock. It covers the 82 miles to Salisbury in 1 hour
46 minutes, nearly 50 miles per hour. 2 hours 20 minutes were allowed for
the last 86 miles over a heavy road. The train usually consists of 49 wagons
and a brake van.
Great Northern Railway (Ireland) . 166
New bogie dining car had been built at Dundalk, and was attached to
the 08.15 Belfast to Dublin breakfast train, returning at 18.45. The novel
feature of the car is the provision of a number of oval windows.
London Transport. 166
Decided to supplement the name of the station "Enfield West" with
the name "Oakwood," which now appears on the station platforms. The name
given to the station "Hillingdon" on the Uxbridge line had been supplemented
with that of "Swakeleys," which is taken from a Tudor mansion nearby, and
is well known in the district.
English Electric Co. 166
Building a standard gauge battery operated shunting locomotive for
the Dundee Corporation Electricity Department. Kathanode locomotive type-
batteries will be fitted, manufactured by the D. P. Battery Co. Ltd.
Number 502 (15 June 1934)
A comparison of 1896 with 1934. 167-9.
Three-cyl. 2-8-2 express loco., L. & N.E.
Railway. 169-71. illustration, diagram (side & front
elevations)
No. 2001 Cock o' the North
An old locomotive favourite in New South Wales. 171-2. illustration
New South Wales Governmennt Railways Terrier type 0-6-0T built in
Australia by Mort & Co. and Vale & Lacy in Sydney.
Two-cylinder Pacific type express locomotives, Alsace-Lorraine Railways.
172-3. 2 illustrations, diagram (side elevation)
Societe Alsacienne design with bar frames and inside Caprotti valve
gear
The first steam-tender loco. 174. diagram
La Jumelle built for the St Etienne and Lyons
Railway in 1843 to design of Verpilleux. It was a steam tender or
0-4-4-0
Diesel-electric trains, Netherlands Railways. 175-7. 5 illustrations,
diagram
Three car articulaterd units capable of being run in multiple joined
by Scharfenberg coupling. Capable of 90 mile/h and desinged to cruise at
60 mile/h. Units built by Werkspoor, Beijnes and Allan with Maybach Vee-type
12-cylinder or by Ganz-Jendrassik 8-cylinder engines built uneder license
by Stork Bros. of Hengelo with Brown Boveri or Smit electrical equipment.
[KPJ: it makes the British Railways entry into diesel traction look even
worse].
300 h.p. double power bogie unit for the South African Rys. 178-9.
2 illustrations
Drewry Car Co. with Parson's 8-cylinder petrol engines
L.M. & S. Ry. 180
After two years' work, necessitating the use of 140 tons of new steelwork,
22,000 linear feet of electric welding and 66,400 welding electrodes, repairs
have been completed to the Sharnbrook Viaduct carrying the main line of the
L.M.S. Railway over the River Ouse at Sharnbrook, near Bedford. The viaduct,
which was constructed in ]881, consists of 10 spans with a total length of
572 feet, and carries the two passenger tracks of the main line from St.
Pancras to the Midlands and the North. Alongside it is another viaduct of
9 spans carrying the goods train tracks, and the electric arc-welding methods
used in the repair of the passenger viaduct have proved so successful that
the goods viaduct is to be similarly repaired in the near future. While repairing
the underside of the superstructure, the welders worked on temporary trestles
slung from the via- duct with the river 35 ft. below them and trains rumbling
over the viaduct above their heads. The repairs, which consisted principally
of providing a new steel floor and generally strengthening the wrought iron
superstructure against the wear and tear caused by the passage over it of
express trains travelling at high speeds, were begun in 1932 and have been
carried on with very little interference to railway traffic. To provide power
for the electric welding operations two 33-H.P. generating units were installed
at the viaduct, and electric hammers, drills and a grinding machine were
also in operation. The welding plant was obtained from the Quasi-Arc Company
Ltd. and built to the railway company's requirements. Each machine consisted
of a Donnan petrol engine of 33 b.h.p. driving a welding dynamo and auxiliary
dynamo at 1,500 revs. per minute. This dynamo supplied current to three welders
simultaneously, and each welder is supplied with a resistance regulator by
which he can adjust the current to suit the particular type and size of electrode
being used.
Great Western Railway. 180
4-6-0 express engines completed at Swindon were: 5023 Brecon
Castle; 5024 Carew Castle; 5025 Chirk Castle; 5026
Criccieth Castle; 5027 Farleigh Castle.
L.M. & S. Railway (L. & N.W. Section).
180
Nos. 5553-5 are the latest 4-6-0 Baby Scot type locomotives with taper
boilers to be completed and turned out, at Crewe. Of the preceeding series,
the last five engines, Nos. 5547-51, were allocated to the Wester n Division
and stationed at Preston. Two of the 0-6-2 coal side tanks. Nos. 7715 and
7722, had been converted from motor rodding to vacuum control gear for working
push and pull truins. The 2-6-2 tanks attached to the Western Division had
all been renumbered bearing Nos. 1-12, 16-20, 41-55 and 66-70. The following
engines were now running rebuilt with standard Belpaire boilers: 4-4-0 George
V class No. 5315; 0-6-0 18 in. goods class No. 8535; 4-6-0 19 in. goods class
No. 8756; 0-8-0 class G1 Nos. 8945, 9239 and 9368. Recent withdrawals included
the last of the Maryport and Carlisle locomotives, viz., 0-6-0 No 12514.
Other withdrawals comprised two further Experiment class 4-6-0s, No. 5461
City of London and 5526 Bactria; and 4-cylinder Claughton class
Nos. 5945 Ingestre, 5931 Captain Fryatt, and 6009 (no name).
4-6-2 Pacific No. 6201 Princess Elizabeth was attached to the Northern
Division and located at Polmadie (Glasgow).
Midland 2-4-0 tender engine No. 155, had become Engineer, South Wales,
with the plates on the splashers. The Clan class engines had been transferred
from the Highland section to work passenger trains on the Callandcr and Oban
line.
L N.E.Ry. 180
The name Cock o' the North carried by the new 2-8-2 engine,
described in another part of this issue was formerly borne by one of the
ex-N.B.R. Atlantics, No. 9903. This engine, had been renamed
Aberdonian, which was carried by another Atlantic No. 9868, withdrawn
from service.
E.A. Phillipson. Steam locomotive design: data and formulse. Tractive
effort of compound engines. 180-2. 3 tables
Continued from page 140. Some formulae for the determination of the
tractive force exerted by compound engines had already been given, see equations
(2), (3) and (4), Chapter II. Further formulae, abstracted from the handbook
of the American Locomotive Company are listed-
The history of the British non-stop express. 182-6
Some locomotive inventions of Joseph Beattie: combusion
and boilers. 186-7.. 3 diagrams.
GB 13782/1953
The stream-lined diesel-electric train. 189-93. 4 diagrams including
elevations & plans
Based on tests conducted on model trains and reported in Transactions
of ASME in 1934.
New Post Office van for Belfast-Coleraine service, N.C.C., L.M.S.R.
195.
A new post office sorting van had been built by the I..M.S.R. (Northern
Counties Committee) and was in service between Belfast and Coleraine. Built
on the lines of the latest N.C.C. coaching stock, to harmonise with the general
appearance of the trains to which it is marshalled, the new vehicle (No.
430) replaced the existing van, now out of date. The vehicle measured 43
ft. 10¼ in. over headstocks, and 9 ft. 6 in. wide over mouldings. It
was somewhat larger than the vehicle replaced and afforded ample room for
carrying out the postal work. The sorting sets, ranged along one side at
the van, comprise three letter' sets of 48 boxes each, one newspaper set
of 43 boxes with zinc-lined well in front and provision underneath for direct
sorting. The registered letter desk had 30 boxes, was partitioned off from
the main desk and had a roller shutter so that it may be locked up when not
required. Underneath these sets the usual swivel seats had been provided.
Opposite the sorting sets were large windows, giving ample light for sorting
work, and below these was the bag rai1. In one corner of the van there was
a nest of six drawers for stattionery and writing materials. The staff
accommodation and appointments of the vehicle were up-to-date in every way,
and included a three-compartment wardrobe, lavatory with hot and cold wash
hand basin, electric urn for making tea, and rest seat and table for the
staff. Full fire protection equipment was fitted, and the vehicle was
electrically lit. We are indebted for the above particulars to Major Ma1colm
Speir, manager of the Northern Counties Committee.
French Railways. 195
Widespread adoption of diesel locomotives and motor-trains is occurring
in the services of all the French railways. There were 73 diesel motor-trains
in service during 1933, and a further 213 were on order. The State Railway,
with 28 motor-trains running, would shortly take delivery of 62 new units;
the P.L.M. Railway was adding to its 14 motor-trains by a further 107, and
had decided to order 3,500 h.p. diesel locomotives for the Paris-Mentone
service, 690 miles; the Eastern Railway with eight motor-trains, had ordered
14; and the Northern' Railway, with six, had ordered 13. Apart from these
orders, the Alsac~-Lorraine Railway, with three motor-trains running, had
eight on order and was contemplating 14 more; the Southern. Railway was adding
to its eight units by six, and the Paris-Orleans Railway was adding to its
six motor-trains by four. These developments were the result of a policy
to speed up services, win back traffic lost to the roads and reduce running
costs: In this regard, M. Tirard, chairman of the Southern Railway Company,
recently stated, "We have noticed on the Marmande to Mont de Marsan run which
since 1 August used only diesel motor-trains, that passenger traffic increased
7%, while other lines in this district, which use steam locomotives recorded
a 10% decline." The developments were also bemg watched closely in official
quarters as it is added they will probably put a stop to further track
electrification: electrification, which is particularly vulnerable to aerial
attack, is already being opposed by the War Department for strategical reasons
in so far as the Eastern, Northern and P.L.M. systems are concerned.
Loughman St. L. Pendred. 195
Among the King's Birthday honours Loughman St. L. Pendred, past president
of the Institution of Mechanical Engineers, and editor in chief of The
Engineer, had been honoured with the C.B.E.
Correspondence. 195
The Holland Railway Company and its locomotives. F. Gaiser.
Re Derens' article on the Holland Railway locomotives in the May issue:
some time ago an old hand-written locomotive list of the Cologne and Minden
Railway came to hand in which the builder's numbers of the four engines,
Ruhrort; Essen, Guetersloh and Bielefeld are
registered in the following order: 63, 61, 62, 64 Thus, the identity of the
Zaan with the Bielefeld is now beyond doubt.
As to the photo of the Muenster, this was given to me by Mueller,
a former locomotive fcreman to the C. and M. Railway at Dortmund, in 1910,
when he was living in retirement in his country home at Neuenahr. He died
in 1911. Druitt-Halpin knew him well. The engine-driver in full dress, standing
on the footplate of the Muenster, was his father. As I distributed
several copies of the photo to my friends there are now, of course, more
than one collection in which they may be found. In 1912, I published the
Muenster in the Locomotive Mag,
V. 20 (p. 218), and this was the first publication of it.
I am longing to mention my admiration for the thorough, well - documented
and inspiring work which Derens is doing. The list of weights included in
the December number is especially interesting inasmuch as it enables one
to distinguish the 2-2-2 long-boiler engines from those having the rear carrying
axle behind the firebox. In the former type of engine the adhesive weight
was always a little less than a third of the total weight, whereas in the
latter it would be considerably more than a third. From this view, of ne
engines Nos. 13-19, 21-27 and 29-36, the following appear to have been of
the long-boiler description: 13-19, 21, 22, 24 and 30, whereas 25-27, 29
and 31-36 were decidedly of the other type. The engine No. 23
(Holland) seems to conceal some mystery, as its dimensions
(see November number, p. 322) are much too small
for a locomotive built in 1856 and as in it the adhesive weight surpasses
only slightly a third of the total weight. The dimensions are the same as
those of the Stephenson engines Komeet and Vesta of 1842, and
this seems to indicate that the Holland was one of the earlier engines
of the railway and that it was reconditioned about 1856 and the rear axle
moved back under (not behind) the firebox, so involving the change of weights.
Fig. 8 (November issue, p. 324) is extremely
interesting in showing the slotted-out frame which was a peculiarity of the
Great Western broad-gauge engines.
One hundred years of railway coaches. W.B.
Thompson
May I add a few comments to your article on p. 119. The earliest British
sleeping cars were, I think, those which began running between Euston and
Glasgow in 1873. The accommodation was by no means luxurious, and I only
once travelled in one of these cars. The Pullman sleepers on the Midland
Scottish trains were of the ordinary American type with fore-and-aft berths,
but of course they had not the advantage of modern electric lighting. The
Pullman draw- ing 1'00111 cars on the Midland day Scotch expresses were perhaps
the most comfortable vehicles I have ever seen on a British railway. The
reason why they were not more used was that not many people could afford
to use them. The Midland company had already taught the public to expect
to be carried in the best trains at fares of Id. per mile, and few passengers
were willing to pay the first class fares plus a Pullman supplement. These
drawing room cars, like the older American Pullmans, had open platforms at
the ends, and when a boy I once, for the sake of experience, stood out on
an end platform while the train ran at full speed through Blea Moor tunnel.
The L. & N.\V.R. 42-feet coaches were 8-wheelers, not 6- wheelers. They
were not bogie vehicles, but the two end axles were fitted with the Webb
radial axle box arrange- ment. I remember seeing chassis which had been put
together at Crewe being hauled to Wolverton to have the bodies added. The
6-wheeled coaches were much smaller and only weighed about 13 tons.
Number 503 (14 July 1934)
What determines the Useful Life of a Steam Locomotive? 197
It may not be realised by many of our readers that the period of useful
life of a locomotive has been legally defined. In the case of Hitchin versus
the Great Northern Railway, a pre-war l[i.e. pre-1914] egal dispute originating
over a matter of rating, the Court, assisted by proper engmeering assessors,
came to the conclusion that the useful life of a locomotive was 30.4 years,
after which span the increasing cost of repairs added to the reasonable
assumption that as a mechanical appliance It was out of date was held to
justify replacement on financial grounds. Such decisions can, naturally,
only be made up on averages but none the less they are reasonably sound;
possibly, for example, the period of 30.4 years was found to be the average
life of two boilers and, as most of us are aware, the condition of the boiler
is often the decisive factor in questions of scrapping. Since that decision
the added requirements of locomotive work and the greater boiler pressure
have increased the general rate of wear and tear, and it is reasonable to
assume that the period of useful life has shortened since the Hitchin decision
to, say, 25 or even 20 years. What are the implications of the Court's
conclusions in this case? At the outset we would emphasise the suggestion
that removal from service should depend on economic grounds and not on
possibilities of repair. Too often an engine, now unfit for its designed
work by reason of increased speeds and loads, is reconditioned for the nth
time and put on to secondary, tertiary or even more minor services yet which
no doubt are performed with ease and magnificent appearance but without reference
to the economics of the matter. Thus one may see any day express engines
with 6 ft.-7 ft. driving wheels probably designed in the nineties and reboilered
early in the present century with higher pressure and enlarged heating-surface
working a two-three coach train over an insignificant branch; or we read
of the conversion of engines to auto-train purposes, presumably two-coach
units at the outside, designed in the seventies [1870s] for what in those
days constituted heavy local goods or mineral traffic; or again an incredibly
dirty specimen of the freight- service power of the eighties [1880s] may
be seen engaged in yard-shunting.
We suggest therefore that the major implication is that there is a financial
limit to the disrating process whereby an engine is relegated to increasingly
light services as its age advances and newer types appear and that on the
attainment of this limit the engine should be scrapped without reference
to its state of repair; we find ourselves unable to believe that modern
locomotive engineering is incapable of designing power which from the operating
as well as the financial side will justify the removal of obsolete or even
obsolescent types that otherwise would be engaged on work for which they
were never designed. The minor implication is that an increased renewal programme
would have an exhilarating effect upon the locomotive building industry and
that the repercussions of improved business would in turn react favourably
on the traffic receipts of the railways who, when all is said and done, are
dependent upon prosperity for prosperity.
G.W.R. 197
Air-conditioned quick lunch-bar cars decoratcd in shades of grcen
and silver and illuminated by champagne coloured lights, were introduced
by the Great Western Railway. The cars, which are of the saloon type, with
large windows, were 57 feet long and 9 feet wide. A counter runs the whole
length of the saloons at which passengers may obtain quick luncheons or light
refreshments. Stand-up rest seats of modern design had been provided along
the counter, beneath which was a recess for hand-bags, etc. Each car was
equipped with refrigerators, griller, hot-plate and special apparatus for
supplying hot water, milk and coffee. The cars brought into use on 9
July 9th, ran in the following services: 09.45 Paddington to Stourbridge
Junction, 14.40. Stourbridge Junction to Birmingham, 16.05 Birmingham to
Paddington, 09.00 Bristol to Paddington, 17.]5 Paddington to Bristol.
London Midland & Scottish Ry. (L. & N. W. Section). 197
In addition to Iocomotivcs Nos. 5552-6, all of which were in service
on the Western Division and stationed at Preston, a further ten 4-6-0
three-cylinder passenger engines of the improved "Baby Scot" typc with taper
boiler were being turned out at Crewe: numbers commence at 5607, thus fol!owing
the fifty similar engines, Nos. 5557-5606, ordered from the North British
Loco. Co., and of which delivery would shortly commence. The re-numbering
uf non-standard engines in the 20,000 series include two 4-6-0 Expcriments
not affected by the scheme applied to standard cngines: Nos. 5456 and
5473. renumbercd 25456 and 25473 respectively. 0-6-2 coal tank No.
7838 had been fitted with vacuum control gear for working push and pul" trains,
while 0-6-2 18-in. tank No. 6890 had its motor rodding gear rrmoved. Recent
transfers include 4-6-0 Experiments Nos. 25509 and 25511 from Central to
Western Division, The remaining Experiments were attached to the Westrrn
Division. Latest rebuilds with standard Belpaire boilers were 4-4-0 George
V class No. 5403; 0-6-0 18-in. goods No. 8509; 0-8-0 G1 class Nos, 8954 and
9239; and 0-8-0 G2 class No. 9437, The new Diesel shunting engine No. 7408
which was engaged at Crewe sorting sidings is now at work on shunting duty
at Camden.
Six-engined "Sentinel" steam locomotives for Colombia. 198-202. 3
illustrations, diagram (detailed side elevation & plan)
Sentinel Waggon Works of Shrewsbury for metre gauge. Locomotive tested
on Societe Nationale de Chemins de Fer Vicineaux Belges between Marches and
Bastogne. Woolnough water tube boiler operating at 550 psi. Bogies had a
Bissel truck.
Oil-engined buffet railcars, Great Western Ry. 203-5. 3 illustrations,
diagram (side elevation & plan)
Supplied by Associated Equipment Company with Park Royal Coachworks
bodywork to requirements of C.B. Collett. To seat 40 passengers; two toilets,
cafeteria and bar. Used on Birmingham to Cardiff service with supplement
charged on third class fare.
Test run with engine No.2001 "Cock o' the North", L. & N.E.R., between King's Cross and Barkston. 205-6.
The high-speed steam locomotive. 207-10. 3 diagrams
In part inspired by the German Henschel high speed steam train.
Boiler for 4-6-2 express locomotive, "Princess Royal", L.M.S.R.. 229-30. 5 diagrams.
Number 504 (15 August 1934)
The relation of the loco. dept. to the railway organisation as a whole. 231.
E.A. Phillipson. Steam locomotive design: data and formulae. Chapter
XII. Main frames: loads and forces. 232-4. 5 diagrams.
Static weight distribution (vertical) is disturbed when locomotive
is in motion. Shock stresses also arise. Shows effect when locomotive lifted
by sheer legs. Loads are also applied in horizontal direction and begins
considerationn of cylinder forces.
Festiniog and Welsh Highland Railways. 234-5.
London Transport Board, engine No. 23. 235-6. illustration
Rebuilt goods loco., L.N.E.R. (G.E. Section). 236.
illustration
J15 No. 7902 illustrated (photograph: E.R. Wethersett): locomotive
had been involved in a buffer stop collision at Ongar and foolowingv repair
in works had new stle chimney, pop safety valves and improved tender
O.J. Morris. The Lydd (Kent) Military Railway and
its locomotives. 238-41. 3 illustrations, 2 tables
Established in 1883 to serve Artillery test ranges and locomotives
acquired in 1885.
| WD No. | type | name | manufacturer | WN | acquired |
132 |
0-6-0ST | Manning Wardle | 948/1885 | 1885 |
|
134 |
0-6-0ST | Manning Wardle | 968/1885 | 1885 |
|
2746 |
0-6-0T | Napier | Hunslet | 882/1905 | 1906 |
1882 |
0-4-2T | Nicholson | Fowler | 10978/1907 | 1907 |
4125 |
0-4-0ST | Trafford | Manning Wardle | 1926/1887* | 1916 |
4109 |
0-4-0ST | Betty | Avonside | 1769/1917 | 1917 |
*Rebuilt in 1903
300 H.P. oil-electric locomotive at work on the L.M.S.R. 242-3.
illustration, diagram (sectionalised elevation)
Built by English Electric Co. Ltd. in conjunction with Hawthorn, Leslie
& Co. Ltd. Diesel electric shunting locomotive tested in Rugby yard and
in Crewe yard on hump shunting. Work on branch line freight and passenger
trains anticipated. Much made of continuous availability.
A "stream-line" locomotive of thirty years ago.
244-6. illustration, 2 diagrams (including side elevation)
Dr von Wittfeld of the Prussian Ministry of Public Works design for
a three-cylinder compound 4-4-4 with the driver's controls at the front within
a V-shaped cab nd the fireman in the normal position. The cranks were set
in the same plain for all three cylinders. The locomotive was built by Henschel
& Son in 1904.
F.W. Brewer. Locomotive regulators. Some early and modern types. 246-8.
Obituary. 262
Death of Fred Bland, a former director of Edgar Allen & Co. Ltd.
He was an authority on tramway track, points and crossings, and the writer
of many articles on the history of railways.
Northern Rly. of France. 262
An oil-electric train of three vehicles was tried between Paris and
Lille. The two end coaches had each a generating set with a heavy oil engine
of 400 H.P. and two motors on the axles. A streamline smoothness is obtained
by rubber panels between the coaches. Ten of these trains were to be built
by the Societe Franco-BeIge. With stops at Amiens, Arras and Douai, the trial
run of 160¼ miles between Paris and Lille was covered in 160
minutes.
Making spring hangers, etc., without drilling. 262
Spring hangers are being made in the Milwaukee shops of the C.M.St.P.
& Pacific Railroad without drilling: the hardened bushes being pressed
into punched holes made in the hanger, and whilst it is hot.
London Transport. 262.
Consideration had been given to the name of "Chancery Lane" station
on the Central London line. Suggestions had been made that a more exact
description of the location is desirable, having regard to the fact that
the new entrances to the station are at the top of Gray's Inn Road. It had
been decided to supplement the name "Chancery Lane" with the name "Gray's
Inn."
London & North Eastern Ry. 262
New 4-4-0 Hunt class engines recently completed at Darlington Works
were 205 The Albrighton, 214 The Atherstone, 217 The
Belvoir, 222 The Berkeley and 226 The Bilsdale. These were
to be followed by another fifteen engines of this class. The passenger service
between Stirling and Buchlyvie and between Gartness and Balloch was to be
withdrawn as from October 1.
Great Southern Rlys. (Ireland) .262
Announced that the line between Galway and Clifden (50 miles) to
be closed on August 27 and between Westport and Achill on Sept. 2. Both formed
part of the Midland Great Western system and were much used by tourists and
visitors to Connemara.
0-4-4 tank engine, No. 6408 LM. & S.R. 263.
illustration
E.R. Wethersettt photograph of No. 6408 on Stanmore branch train.
Stanier falsely accused of being responsible for design with its stove pipe
chimney.
Number 505 (15 September 1934)
Two-cylinder 4-6-0 mixed traffic locomotives, L.M.&
S. Ry.. 266-7. illustration, diagram (s.& f.elevations) +
plate
No. 5020 built at the Vulcan Foundry: both photographs are of same
locomotive: Stanier class 5: first ten to be allocated to Highland
section.
T.R. Perkins. The Saundersfoot Railway. 272-6. 4 illustrations, map
Rebuilt dining car, G.N. Rly (Ireland). 276-7. 2 diagrams (including
side & end elevations and plan)
Car had suffered damage in a malicious derailment and had been restored
with high pressure for cooking
F.W. Brewer. Locomotive regulators, some early and modern types. 278-9 2 diagrams
Lockyer and Hulburd types
75 H.P. standard "Hunslet" diesel locomotive. 287. illustration
Built for work in South America and supplied through Robert Hudson
Ltd., Leeds, is one of a range of standardised small diesel locomotives.
The design is not new, but it has been brought up to date in almost every
detail, due to the experience gained from locomotives of this type m service
all over the world, several of which have been at work since 1928. The main
frame which carried the engine and gearbox was constructed on locomotive
lines from two vertical frame plates, the frame stays being not only between
the frames but also extending to the extreme limit of width of the locomotive
where they were riveted to a pair of heavy steel channel sections. The engine
was a four-cylinder McLaren unit delivering 75 B.H.P. at 1,000 r.p.m, and
identical with that fitted in the articulated locomotive supplied to W oolwich
Arsenal. The clutch was the' 'Hunslet" patent multiple disc type and the
drive is then taken through a flexible coupling to the gearbox. This is of
the usual built-up type rigidly bolted between the frames, constant mesh
gearing, the wheels being of nickel chrome case hardened steel and the changes
being effected by heavy dog clutches. The change, however, is not of the
automatic type but is operated directly by the driver, the gear change lever
and reverse lever being placed conveniently in the cab for operation. The
final drive from the gearbox is by chain to the trailing axle and by coupling
chains to the intermediate and leading axles. Sanding gear fitted, both leadmg
and trailing.:Locomotive weight 10 tons and capable of hauling about 300
tons on the level.
Southern Railway. 287
No. 862 Lord Collingioood. (Lord 1\clson class) has been
experimentally fitted with a double chimney. No. 923 Uppingham (Schools
class) has been renamed Bradfield. Tbe old L.B.S.C.R. running shed
at llattersea Park was closed on 1 July and the engines transferrcd to the
former S.C. & C.R. shed at Longhedge close by, which officially known
as Stcwarts Lane.
A. B. McLeod has been appointed Assistant Western Divisional Running
Superintendent in succession to the late H. P. Dawson. J. E. Bell succeeded
McLeod as Divisional Superintendent for the Isle of Wight.
Egyptian State Railways. 287.
The new chief mechanical engineer is Abdel Rahman Harnada Bey, M.C., in
succession to Mr. W. D. Knights, who retired recently.
North Western Railway of India. 287
E. L. Manico had been appointed deputy chief mechanical engineer of
this system.
Obituary. 287
The death occurred on Aug. 19 of Edward Herbert Hart, at Bitterne,
Hants, aged 78 years. Mr. Hart was formerly a district locomotive uperintendent
on the Great Indian Peninsula Railway and on many occasions officiated as
head of the locomotive department. Mr. Hart served on the Great Northern
Railway in his early days.
[Robert Coey]. 287
Death at Harrogate on 24 August of Robert Coey, formerly locomotive
engineer of the Great Southern and Western Railway of Ireland, in his 84th
year. Coey was a native of Belfast, and went to Inchicore Works as a draughtsman
in 1876. He was appointed chief draughtsman in 1880 and assistant locomotive
superintendent and works manager a few years later. When lvatt left Inchicore
to become locomotive superintendent of the G N.R. in 1896, he was succeeded
by Coey, who held office as locomotive superintendent of the G.S, & W.
Railway until 1911, when he retired.
Lieut.-Col. M. M. Bidder, 287
Died at the age of 55 on 26 August as a result of a motor accident.
was formerly vice-chairman of Kitson & Co. Ltd. Col. Bidder was a grandson
of the famous G,P. Bidder, the "Calculating Boy," and a colleague of Robert
Stephenson in the early days of railways. His father was G. P. Bidder, Q,C.
Col Bidder joined Kitson & Co. as a director in 1912. During the War
he saw service in Gallipoli and elsewhere.
Number 506 (15 October 1934)
Three-cylinder 4-6-0 passenger engine, L.M. & S. Railway. 296.
illus
Slight modifications to weight distribution and tender: No. 5573
illustrated built North British Locomotive Co. with 4000 gallon tenders
T.R. Perkins. The Saundersfoot Railway. 297-300. 4 illustratuions
E.A. Phillipson. Steam locomotive design: data and formulae.
300-3. 4 diagrams, table
Brakes and brake rigging, See errata on page
340
New Post Office vehicles, L.M.& S. Railway. 304-5. 3
illustrations
Three 60ft and one 57ft sorting vans. The 60ft vehicles were fitted
with mail exchange apparatus and had toilets, electrically heated hot water
and electric ovens. All were fitted with Post Office gangways. Design credited
to Stanier.
F.W. Brewer. Locomotive regulators, some early and modern types. 305-8.
3 diagrams
Joco balanced type with three valves; M.L.S. multiple valve type,
Owen regulator
Beyer-Garrett tank loco, for the British Iron & Steel Co. Ltd.
314. illustration
0-4-4-0T with 3ft 4in diameter coupled wheels, 14 x 20in cylinders
and 185 psi boiler pressure. Hauled dead to Cardiff via Wrexham and
Oswestry
W.B. Thompson. Notes on railway travel in Canada. 318-19
Journey from Montreal to the Rockies and back using the Canadian Pacific
Railway. Noted that fewer trains than in Europe, but that they ran at high
speed and appeared to be punctual. The most exciting part was thr journey
through the Kicking Horse Pass viewed from the observation car.
[World's fastest newspaper train]. 319
The 01.20 Paddington to Swansea was faster to Newport than the fastest
day train. Swansea was reached at 05.44 and connections were arranged for
newspapers to arrive in time for Welsh breakfasts
Propulsion of the Cunard-White Star liner "Queen Mary". 319-20.
illustration
Eight very heavy bronze propellers manufactured by J. Stone
in Deptford and by the Manganese Bronze & Brass Co. of Millowall had
to be moved by road to the Surrey Commercial Docks for shipment to the
Clyde
Locomotive connecting rods. 320-1
Nickel chromium steels had been replacced by vanadium steels. Electric
furnaces tended to be used. Limits for phosphorus, sulphur and manganese.
Heat treatment. Bushes.
The running shed foreman. 321-2.
Charateristics necessary: age, temperament, technical ability, ability
to be able to maintain disipline, etc
The last of the L. & N.W.R. "Precedents.".
327
On the withdrawal of the L.M.S.R. summer services, the last of the
L. & N.W.R. Precedent class of 2-4-0 passenger engines, No. 25001
Snowdon, was taken from traffic. Apart from being the last of its
class in service, it was also the only one to come under the recent renumbering
scheme. Snowdon was built at Crewe in 1875, and was one of the original
"Precedents." Stationed at Penrith shed, its last duties were to work the
3.5 p.m. train to Whitehaven and back. It will be remembered that one of
the 6 ft. 6 in. 2-4-0 engines, Hardwick, is preserved as a relic at
Crewe Works, and there are still a few used as engineers' departmental engines
at Lancaster, Watford, Bangor, etc.
American locomotive notes. 327
A streamlined locomotive of the 4-4-4 type with 7 ft. driving wheels
had been ordered by the Baltimore and Ohio R.R. and would be ready soon.
A streamlined Diesel car was also in hand for the B. & O. Other orders
for locomotives recently placed were 20 of the 4-8-4 type for the Delaware,
Lackawanna and Western, also 20 tender engines to be converted to tank shunters
and 20 other engines of various types. The Boston & Maine R.R. ordered
6 freight engines and one shunter as well as 4 passenger engines (4-8-4 and
4-6-2 types). The Nickel Plate line was purchasing 15, 2-8-4 type and 5 shunters;
the Lehigh Valley 5, 4-8-4 type; Seaboard Air Lines 5, 2-6-6-4 type. Pittsburg
and West Virginia 3, 2-6-6-4 type, and the Northern Pacific 10, passenger
locomotives. Other lines were reconditioning many engines that had been idle
during the slump period.
Great Southern Railways (Ireland). 327
The Galway-Clifden, Westport-Achill branches and also the Cork and
Muskerry Light Railway were being kept open for all traffic until further
notice. A new signal cabin had been erected at Dublin, Amiens Street, and
would shortly be brought into use, and when done the Great Southern will
signal its own trains into and out of the City of Dublin Junction platform
at Amiens Street independently of the Great Northern Co. whose signal box
had hitherto controlled all movements at the north end of the station.
Personal. 327
G.W. Duncan has resigned his appointment as publicity manager of the
London Passenger Transport Board. W. Gott, commercial advertising officer
(railways), and H.L. Spratt, commercial advertising officer (buses and tramways),
will continue to be responsible for their respective sections of the Publicity
Department. H.T. Carr will be acting publicity manager and responsible for
the remainder of the work of the department including the press bureau, traffic
advertising, and public letters.
Eastern Bengal Railway. 327
G. Thomson, deputy chief mechanical engineer, has been appointed to
officiate as chief mechanical engineer. C.A.K. Bradley officiates as deputy
C.M.E in his place.
Correspondence. 327
[State of Britain's railways]. R.B. Hunt
On the eve of my departure for South Africa it may be of interest
for me, as a railway enthusiast, to let you have my reactions on the English
railway systems, based on observations during frequent travels whilst in
the "Old Country. "
The first thing that struck me, and very much disappointed me, was the poor
outward condition of all locomotives. In my boyhood days I was always thrilled
with the beauty of our locomotives, and I submit that this fact is the
fundamental reason for the much-desired enthusiasm of the younger generation.
Whilst appreciating fully the heavy expense of maintaining all railway stock
to perfection, surely it might be possible to give special attention to the
"crack" locomotives of the different lines. As an instance, I submit that,
as there is always a large crowd of interested onlookers to see the departure
of the 10.30 a.m. Cornish Riviera express, headed by one of the
magnificent King class engines, surely all the Kings should be spotless and
brilliant in appearance.
These engines are beautifully finished as they leave Swindon works; it therefore
appears to be a great pity that this is not maintained during useful life.
The condition of the carriages also leaves much to be desired. One of my
particular extravagances is to always travel first class at a cost somewhat
approaching twice that of third. But what do I get for that heavier investment?
The train goes no faster and runs as no higher cost; the only difference
appears to be that the compartments are constructed to hold less people and
one is honoured with an antimacassar. Generally the compartments were not
clean and one longed to get a vacuum cleaner and bucket of' petrol, as well
as a sponge to clean the windows.
I would add that the Pullman Brighton Belle, in which, I travelled
to Brighton, is an extreme exception. This is. the most beautiful and comfortable
train I have ever travelled in.
Your train service has to compete to-day with the modern, comfortable and
fast motor car on beautiful highways and can only do so by offering transport
more comfortable and faster.
This leads me to my next point, speed. Whilst it may be accepted that England
easily leads in this, yet there is much to be done to maintain the supremacy
over the motor' car which has developed its speed out of all recognition
.. We have to-day two-hour expresses to Birmingham and Bristol, but we had
them years and years ago. I am certain that these times could be considerably
improved, proved sufficiently for my satisfaction by the Cheltenham
Flyer which has, I believe, travelled from Swindon to London in 61 minutes.
Surely this is not the only section of Our railway on which a speed of 80
m.p.h. can be maintained. With your perfect tracks one should be allowed
to expect; speeds up to 90 and even 100 m.p.h.
Much could be done by your railway companies to lay stress on the exceptional
safety to the travelling public of' their services. One reads regularly of
hundreds killed and' thousands injured on the highways, yet with thousands
of" millions of miles covered by your trains annually hardly a, life is lost.
I believe I am right in stating that the Underground system has yet to lose
a life through accident. With this in mind much could be done to bring this
safety- factor forcibly before the public mind. See
response from A. Sinkinson in nxt volume
The high speed steam locomotive. 327
It was very pleasing to note that the article on the above- had called
forth Mr. Keiller's letter (August) which I quite appreciate. The main object
of the article was to call attention to the possibilities still extant with
steam, if high-speed- light trains are to be the fashion, and if steam is
to be retained, no doubt a great deal of controversy will arise- as to the
best type of locomotive, as the simplicity of a debate "single versus coupled"
will be a relatively small item compared with the arguments of high-pressure
boiler design, geared engine prospects, etc. The orthodox steam loco. however
still appears to be in the running, and I am sure both Mr. Keiller and myself
look forward to the C.M.E. in combination with the directorate who will in
due course produce- the right machine for this work.
Number 507 (15 November 1934)
Anti-friction bearings. 329-30
National Physiucal Laboratory report on roller bearings. employed
on Metropolitan Railway electric multiple unit train axleboxes. Savings in
cost of lubricant and maintenance
2-8-2 heavy goods tank locomotive, "7200" class, G.W.
Rly.. 330-1. illustration, diagram (side & front elevations)
No. 7200 illustrated. Intended to replace Aberdare 2-6-0. 52XX 2-8-0T
rebuilt with trailing radil truck to accommodate larger bunker holding 6
tons of coal; also larger water tanks.
Great Western Railway. 331
Ten new Hall class 4-6-0 locomotives from Swindon: Nos. 4941 Campion
Hall, 4942 Doldowlod Hall; 4943 Elmdon Hall; 4944 Ickenham
Hall; 4945 Leckhampton Hall; 4946 Marwell Hall; 4947 St.
Benet's Hall; 4948 Siddington Hall; 4949 Trematon Hall and
4950 Wardley Hall.
2-6-0 locomotives for the West Highland line, L. & N.E.R. 331.
illustration
K2 No. 4700 Loch Lomond with side window cab.
Diesel-electric shunting locomotive for the Port of Rosario. 332.
illustration
Supplied by Henschel & Son of Cassel with Sulzer of Winterthur
engine
American locomotive notes. 332
2-6-6-4 Mallet fot Pittsburg & West Virginia R.R.; Baltimore &
Ohio R.R. considering a three-cylinder compound design of 4-8-4 for express
traffic with 6ft 8in coupled wheels; a single inside 27 x 30in high pressure
cylinder and two outside 30 x 30in cylinders. A new 4-4-4 was ready for service.
The Pennsylvania R.R. had ceased to develop steam locomotives for its
Philadelphia to Wshington route as this was beinng electrified.
North West State Rly.: notes on the locomotives of India's largest
railway. 332-5. 8 illustrations.
Illustrations: 2-6-6-2 Mallet No. 490 on freight train at Jhelum;
remainder photographs by P.S.A. Berridge: Class E 4-6-0 No. 427;
Beyer-Garratt 2-6-2+2-6-2 on heavy freight on Lalamusa & Rawal section;
Kitson-Meyer hauling freight on 2ft 6in gauge Kalka Simla line; NG class
0-8-0 shunting locomotive No. 913; H/GS 2-8-0 Nos. 1710 and 412; above Hirok
the Karachi to Quettan Mail hauled and banked by H/GS 2-8-0 locomotives;
Caprotti four-cylinder Pacific XS class on Karachi Mail leaving Lahore.
Great Northern Railway of Ireland. 335
The Bainbridge to Scarva line had reopened using a railbus on all
weekday services but steam trains on Saturdays. The railbus worked through
to Newry.
Forth & Clyde Junction Railway. 335-6. illustration
Passenger services ceased on 29 September 1934, but freight services
remained. The line linked Stirling with Alexandria 26 miles away. The line
was characterised by many curves and many level crossings. It was first projected
in 1845 and was revived in 1852 with an Act being passed in 1853, It opened
on 20 May 1856 and was operated by the Scottish Central Railway until 1859
when four locomotives were ordered from Peto, Brassey and Betts' Canada Works
in Birkenhead. These were Crewe type 2-4-0 with 16 x 26in outside cylinders
and 5ft coupled wheels. The North British Railway took over in August 1871
and the locomotives were renumbered 401-404
In 1879 Nos. 401 to 403 were replaced by 17in. Drummond goods engines. No.
404 was rebuilt at Cowlairs in 1874. In 1883 it was put on the duplicate
list as 404A. In 1895 it was re-numbered 835 and was scrapped in 1900. Two
of the ex Edinburgh and Glasgow Railway singles went to work this section
some time after the NBR had taken it over. Later the line was worked by 0-4-4
and 4-4-2 tanks. The advent of the motor omnibus sealed the fate of the line.
As most of the stations were at some considerable distance from the villages
they were intended to serve, the 'buses lifted people from their doors, and
thus took the bulk of the traffic. In 1928 a Sentinel railcar service was
put into operation, but even this was run at a loss. At the time of closing
the cars so engaged were 31073 Quicksilver. and 39 Pearl. The
Lennoxtown- Buchlyvie-Aberfoyle passenger service remained.
London & North Eastern Rly. 336
On completion of the new series of Hunt class engines at Darlington
Works, we understand the next order to be put in hand will be for another
five Sandringham class 4-6-0 engines: Nos. 2843 Champion Lodge; 2844
Earlham Hall; 2845 Gilwell Park; 2846 Helmingham Hall,
and 2847 Kimberley House. Armstrong, Whitworth & Co. have completed
the following "K3" class 2-6-0 tender engines for the Northern Area:- Nos.
1302, 1304, 1306, 1308, 1310, and 1324, and for the Southern Area, Nos. 2934
to. 2937. Another three of the 4-4-4 tank engines, Nos. 1519, 2149 and 2153
had been converted to the 4-6-2 type, class A8, completing the order for
ten to be reconstructed this year at Darlington. A start has been made with
another series of J39 class goods engines at Darlington, the first seven
bearing the numbers 1475 to 1479, 1488 and 1490. These are to have the tenders
of the Raven Pacifies which are being provided with standard 8-wheeled tenders.
The name of No. 362 given in our last issue as Goatham should be
Goathland. New Pacifies built at Doncaster are Nos. 2505
Cameronian; 2506 Singapore, and 2507 Salmon
Trout.
56-seater Michelin railcar, French State Rlys. 336-7. 2 illustrations
Following extended trials over three years with Michelin pneumatic
tyred railcars, the French State Railways put into service a 56-seater coach,
for operation in both directions. The illustrations give a good idea of its
general appearance externally and internally. The overall length 53 ft. 6ft
in.; width of body 9 ft. 1in., and the overall height from rail level is
9 ft. 4ft in. The car was carried on two eight-wheeled bogies with a wheelbase
of 9 ft. 4 in. each. The front bogie has the two inside axles driven, and
these are coupled by chains. The vertical load is carried by side bearers
and not by the centre pivot.
Pneumatic tyres when running on steel rails are said to be only capable of
carrying about one- third the load they can sustain on an ordinary road,
hence the large number of wheels employed. . The petrol engine, gave 200
h.p. and its gearing giving four speeds in either direction are mounted on
coiled steel springs and rubber m the body chassis in such a way that vibrations
are not transferred to the coach. The Lockheed system of hydraulic braking
is applied to all the wheels, operated by two independent braking systems,
one for each bogie.
The pressed steel disc wheels have 34 in. Michelin pneumatic tyres inflated
to a normal pressure of 9 lb. per square inch, with steel guid- mg flanges
silenced by a rubber insert. Loss of pressure in any tyre sounds a hooter
in the driver's cab.
[Swainsley Viaduct relics]. 337
During the reconstruction of the viaduct between Derby and Belper
a diver investigating scour by the river discovered the timber piles of the
original viaduct built by the North Midland Railway in 1840. These were in
excellent condition. Frederick Swanwick was the original site engineer working
for George Stephenson.
200 H.P. diesel-electric locomotive, Kallehavebanen Denmark. 337-8.
illustration
Weighed 28 tons. Fittedv with 2-stroke Burmeister & Wain type
engine. Capable of 37 mile/h maximum speed. Fitted with electric
heating.
Nigerian Railways locomotives. 338
Notes G.V.O. Bulkley's use of the Kiesel formula to establish tractive
effort when hauling trains. See letter from W.C. Williams
on p. 394
E.A. Phillipson. Steam locomotive design: data and fprmulae. The Westinghouse automatic brake. 338-40. 8 tables
Correction.340.
In the last instalment of Phillipson's article on Steam Locomotive
Design on page 302, we regret to notice that a few words were omitted at
the bottom of the left hand column. As the wording does not convey the intended
meaning we give below the correct version of the text, and have put the words
affected in italics;- "The brake force exerted by the blocks must act
radially
towards the centre of the wheel; the blocks must also be "so disposed that their horizontal centre line is slightly "below that of the wheels, with due regard to the necessity for the resultant of the spring borne load and the brake force to act within the arc of the axle box bearing. With this disposition the brake blocks are assisted to move clear of the wheels when released, this movement being further encouraged, not only by the provision of springs between the blocks and hangers, and also by so inclining the brake hangers that they tend naturally to return to the off' position under the action of gravity; it is important to observe that the necessary extent cf this movement is increased as the engine bearing springs weaken in service.
London, Midland & Scottish Rly. (Western Section).
340
No. 5629 is the latest new engine of the improved Baby Scot type with
taper boiler to be completed and turned out at Crewe. Of the same type the
North British Loco. Co. delivered up to No. 5581. The Vulcan Foundry delivered
new two-cylinder 4-6-0 mixed traffic engines up to No. 5049. The twenty five
similar engines on order at Crewe will follow the Baby Scots now building,
of which No. 5654 will be the last. New locomotives recently allocated to
this section include three-cylinder 4-6-0s Nos. 5557-72 and 5607-16; also
two-cylinder 4-6-0s Nos. 5032-9. No. 9017 is the latest D class 0-8-0 to
be converted to superheater G1 class and was running provided with a standard
Belpaire boiler and also with the vacuum brake throughout. The following
engines rebuilt with Belpaire boilers;-0-6-0 18 in. goods class 10S. 8450
and 8618; 0-8-0 G1 class Nos. 8948, 9250 and 9374; 4-6-0 19 in. goods class
No. 8707. Two ex G. & S.W. 0-6-2 tanks, Nos. 16905 and 16911, were working
temporarily from Workington shed.
Midland Section. 340
New 2-6-4 three-cylinder passenger tank engines, ex Derby, were in
traffic up to No. 2542. These engines for service on the Tilbury line. Two
of the Vulcan two-cylinder 4-6-0s were at work on the Midland section, Nos.
5030-1. Devon's Road shed is now under the Midland Division, while Buxton
shed has been transferred to the Western Division as formerly. Orders have
been placed for a total of 1,700 low-sided goods wagons of 12 tons capacity,
for use in connection with their container traffic, as follows ;-700 from
Metropolitan-Cammell Carriage, Wagon & Finance Company Ltd., Saltley,
and 400 from The Birmingham Railway Carriage & Wagon Company Ltd., Smethwick.
These are to be fitted with the vacuum brake. Three hundred unfitted wagons
from Hurst, Nelson & Co., Motherwell, and 300 unfitted wagons from Charles
Roberts & Co. Ltd., Horbury Junction, near Wakefield.
The L.M. & S. Rly. had for disposal nearly 200 nameplates taken off
locomotives withdrawn from service. Some nearly 8 ft. long. all of brass
with the name of the engine and date of construction engraved on the metal.
All had been taken from engines built at Crewe. They were on sale at the
Locomotive Stores at Crewe.
Diesel-shunting engines for the L.M. & S.R.
About eighteen months previously this railway ordered a variety of
types of oil-engined shunting locomotives. Some of these have been in service
for nearly a year, and others have only just been completed. Tenders had
been invited for a further twenty shunting locomotives of higher power, up
to 300 b.h.p.
Sheffield-Twinberrow type bogies. 341-3. 4 illustrations
Colonel H.A. Stenning. 350. illustration
(portrait)
Colonel Harry A. Stenning, O.B.E., T.D., M.I.M.E., for many years
Managing Director of The Superheater Company, Ltd., is retiring from that
position at the end of this year. His connection of nearly thirty years with
Superheating will not be severed as he retains his seat on the Board, and
will act as Consultant to the Company. Colonel Stenning commenced his career
in locomotive work under the late James Stirling at Ashford, and was afterwards
at Nine Elms under the late Mr. Dugald Drummond. In 1904 he was introduced
to William Schmidt by the late Leslie S. Robertson, then secretary of the
Standardisation Committee. Dr. Schmidt had made the development of the
superheated steam engine his life work; he had designed several different
types of super- heaters, all of which produced a high degree of superheat,
and he also succeeded in so modifying the details of the locomotive as to
successfully meet the conditions imposed by the use of steam of very high
temperatures. Colonel Stenning with Mr. Robertson introduced the smoke tube
superheater into this country, and in 1906 induced Mr. George Hughes, chief
mechanical engineer of the Lancashire & Yorkshire Ry., to fit two engines,
a six-coupled goods and a 4-4-0 passenger, with a Schmidt smoke-tube superheater.
Shortly afterwards the D. Earle Marsh, of the L.B. & S.C.R., H. A. Ivatt
of the G.N.R., and J. G. Robinson of the G.C.R., fitted several engines with
superheaters for trial, and later adopted the system. As a result of an extended
trial of one of Marsh's L.B. & S.C.R. 4-4-2 tank engines be- tween Rugby
and Brighton, fitted with a superheater, in competition with a L. & N.W.R.
4-4-0 tender engine using saturated steam, in 1910 the last mentioned railway
took up superheating under the late Bowen Cooke. It was then standard British
locomotive practice to use slide valves, and the earliest superheat engines
in this country were so fitted, but piston valves were gradu- ally introduced
largely at the instigation of Colonel Stenning. In 1913 the Superheater Company
established its works at Trafford Park, but the war period prevented progress
until 1920-1. The company was reconstructed as Marine and Locomotive
Superheaters, Ltd., and undertook the manu- facture of the superheater equipment
throughout. Later developments include the introduction of machine-forged
return bends for the superheater elements. The name was again changed to
the Superheater Co. Ltd. in 1924 and Its activities largely extended not
only in relation to the rail- ways, but with electricity power houses, and
marine engine builders. Overseas the Superheater Co. first applied their
apparatus to locomotives for the Argentine, followed by South Africa and
India, where the first engines fitted were for the Madras and Southern Mahratta
Railway. At the works the Company now deal with some 2,000 tons of steel
tubes for the manufacture of steam super- heaters per annum.
We are notified that Eric A. Robinson, General Manager, has been elected
a Director of the Company.
Kofler Train Stop. 350
Further trials with this device on the electrified section of the
North Milan Railway demonstrated its satisfactory working at speeds up to
80 kilometres (50 miles) per hour. We gave a description of the Kofter mechanical
train-stop apparatus in our issue of October 15, 1932.
Central Railway of Peru. 350
Orders placed by the Peruvian Corporation Ltd. for a Sentinel-Cammell
steam rail bus to seat 82 second-class passengers, with a bogie trailer car
to take 20 first and 44 second-class passengers. Also a Sentinel-Cammell
freight unit to carry 20 tons. Both cars will be fitted with two compound
engines and Woolnough boilers, with automatic coal feeding devices so that
only one man is necessary to look after the driving and firing. The Peruvian
Corporation has also ordered a petrol driven inspection trolley to seat two
persons from D. Wickharn & Co. Ltd. of Ware.
Crown Agents for the Colonies. 350
Placed an order with Sir W. G. Armstrong, Whitworth & Co. Ltd.
for a 15-ton [diesel] oil-electric shunting locomotive, metre gauge, for
the Penang Harbour Board, Straits Settlements.
A Dorsetshire narrow gauge railway. 358-9. 2 illustrations
B. Fayle & Co. on the Isle of Purbeck
Number 508 (15 December 1934)
Travel speeds of the future. 363-4.
Editorial comment on high speed trains based upon a paper by Raymond
Carpmael presented to the Institute of Transport, notably on the Great Western
Railway. See also letter from WHT on reference
to Chicago, Milwaukee, St. Paul & Pacific Railroad
Southern Railway: conversion of 4-6-4 type "Baltic" tank engines to 4-6-0
type engines. 365-6. illustration, diagram (iside & front
elevations)
No. 2329 Stephenson illustrated: rebuilt at Easleigh
Works
Heavy tank locomotives for the Netherlands State Coal Mines. 367.
illustration
Werkspoor 2-8-2T for a new railway to link the Hendrik and Emma mines
to the Juliana canal
Model railway catalogue, Section "A". 367
Bassett Lowke Ltd
The last of the "Jumbos," L.M. & S. Railway.
369-70. illustration
No. 25001 Snowdon had been withdrawn. Precedent class introduced
by Webb in 1874 and which grew to a class of 166. Hardwicke and
Charles Dickens were the most famous members
G.N. Rly. (Ireland), pneumatic-tyred petrol railbus. 370-1. 2 illustrations
Steel passenger cars, Nigerian Railways. 372-3. 3
illustrations
Metropolitan Carriage & Wagon Co. Ltd light weight third class
with Sheffield-Twinberrow bogies. Crown Agents inspection
L. Derens. The Holland Railway Company and its locomotives. 374-7, 2 illustrations, 3 diagrams
See also letter from W.S. Upton in next Volume and Author's response
2-8-2 type engine, "Earl Marischal". L. & N.E. Rly. 378.
illustration
No. 2002 fitted with Walschaert-Gresley valve gear.
The railways of the Londonderry Port anf Harbour
Commissioners. 379-81. 4 illustrations
Originally laid with flat bottom rails most was changed to tramway
girder rails in 1902. Originally standard Irish gauge of 5ft 3in but when
the Londonderry & Lough Swilly Railway changed to 3ft gauge in 1883 the
six mile system became mixed gauge. The original locomotive was one of the
former LLSR broad gauge engines: 0-6-0T John Cooke, a Rober Stephenson &
Co. product of 1864. There were two locomotives in 1934: No. 1 (Robert Stephenson
& Co. 0-6-0ST WN 2748/1891) and No. 3 R.S. Smyth (Avonside WN
2031/1928). The latter displaced No. 2 (Robert Stephenson & Co. 0-6-0ST
WN 2836/1896). Horses had been displaced by a Fordson tractor for shunting
on the quays along the River Foyle, although electric capstans were also
used. The tracks crossed the Foyle by the Craigavon Bridge. Trains of mixed
gauge wagons were worked and the locomotives could couple to either gauge.
The assistance of the Harbour Engineers: W.E. Hutson (late) and J.S. Watt
(then current),
Some locomotive inventions of Joseph Beattie: Combustion
and boilers. 384-5. 6 diagrams
GB Patent 259/1854. Continued in Volume 41
on p. 23
Institution of Locomotive Engineers. 391-2.
Abstract of ILocoE Paper
334
Obituary. 394
Dr. Carl Sulzer, chairman of the Arm of Sulzer Brothers, passed away
at Winterthur on 30 October in his seventieth year. He was the eldest son
of the distinguished engineer, Mr. Henry Sulzer, and after training in the
Winterthur works studied at Lausanne and Dresden under Zeuner and Lewicki.
A short period in the Sulzer designing office was followed by a visit to
America, where he was employed by the Brown & Sharpe Co. Upon his return
in 1891 he undertook the design of workshop equipment and tools in the Sulzer
works, the developrnent of which necessitated specialised tool equipment.
In 1895 when he became a partner in the business, the Sulzer steam engine
was approaching its zenith, and Dr. Sulzer had a considerable share in the
management of this branch and in the evolution of large units for direct
coupling to electric generators. He was responsible for several installations
in Britain, notably those for the Metropolitan Electric Supply Co., Willesden,
Harland & Wolff Belfast, Singer Manufacturing Co., Clydebank, and the
Charing Cross Electrical Supply Co., Bow. Under his lead a complete change
took place in the steam engine era in 1909 by the successful evolution of
the "Uniflow" engine with its considerably increased revolution speed, forked
frame and simplified valve gear, the first engines of which type were supplied
to the Hafod Copper Works of Messrs. Vivian at Swansea. The experience with
this design proved of great value in the modernisation of the ammonia compressor
with which Dr. Sulzer was intimately connected, in collaboration with Professor
Linde. He took a prominent part in the design and manufacture of steam boilers
and high pressure pipe lines for hydraulic power stations, pressure vessels,
gas holders, etc., in this respect closely following in the footsteps of
his father. The introduction of the valve-type water level indicator was
due to him. He was largely responsible for the adoption of the corrugated
"Fox" flue" for Cornish and Lancashire boilers and the efficient arrangement
of superheaters. Increasing steam pressure led to the manufacture of the
vertical single and double bank straight tube boiler which was taken upon
Dr. Sulzer's advice after exhaustive tests in 1890, and later, under his
guidance, a boiler of 1,500 lb. per square inch pressure was designed, from
which the Sulzer Monotube steam generator was evolved. Dr. Sulzer also took
a keen interest in the development of the centrifugal pump for irrigation
purposes, Pumps for de-watering became equally prominent, and as an example
of Dr. Sulzer's perseverance the big installation at Codigoro should be
mentioned, where stringent guarantees had to be given, which experts at that
time considered unobtainable; but, in co-operation with Professor Prasil
of Zurich, irnpellers were designed which enabled the guarantees to be complied
with. The turbine pump was also developed, and the first high-lift mine pumps
for Horcajo and the Victor Rauxel pit in Westphalia are of interest. When
the Sulzer organisation was converted into a limited company in 1914 Dr.
Sulzer became chairman and, leaving the technical side on the business more
in younger hand, devoted much of his time to social and political duties
for his country.
Correspondence. 394
Nigerian railway locomotives. W. Cyril
Williams
Re page 338, you refer to the very interesting innovation by the General
Manager of the Nigerian Railways, G. V. O. Bulkeley, of the Kiesel formula
for the calculation of tractive effort. This is certainly novel, but caution
would appear to be necessary in its application, as Kiesel doubtless evolved
his formula having in mind the long barrels and shallow fire-boxes of American
locomotives. In the example cited, comparison is made with the Garratt
locomotive. Here we have a boiler with a wide and deep firebox and a short
barrel of large diameter, this design being possible due to the slinging
of the boiler in a cradle between the wheels. Thus all the heating surface
of the Garratt boiler is nearer the source of supply, many Garratt boilers
having as much as 50 per cent. more tube heating surface nearer the radiant
heat of the firebox, Thus it is the value not the amount of each square foot
of heating surface that counts and this is taken into account in Garratt
boiler design.
The Garrntt is shewn as losing 2,381 lb. of tractive effort by comparison
on the Kiesel formula basis. In practice no such loss is experienced; on
the contrary, the output at the economical peed is in every way comparable
and often exceeds that of the ordinary locomotive owing to the ease with
which a boiler of adequate heating surface can be ap- plied. Further, the
superheat of the Garratt boiler is markedly higher than in the ordinary engine,
and in recent tests in South Africa the highest superheat ever recorded on
the 160 odd classes of locomotives on the South African Railways, namely
730°F., has been obtained from one of the large Garratt locomotives.
So it seems that the Kiesel formula cannot be used indiscriminately.
Ashley Brown, General Secretary, The British Rly. Stockholders'
Union, Ltd.
I read with great interest the letter contributed by Mr. R. B. Hunt
to your issue of the 15th October. Giving, as he does, the impartial view
of a man who visits England from abroad and who is able to compare what he
sees with what he remembers, his criticisms have a peculiar force. Changes
are frequently so gradual that those of us who live amongst them fail to
notice them, and it is often something of a shock to us to be compelled to
appreciate the great gulf that separates our practice of to-day from our
standards of long ago.
As Mr. Hunt points out, in the up-keep of our locomotives there has been
a very serious falling off. I recollect the pleasure it gave me as a boy
to visit Paddington Station for that great event the annual family holiday
in Cornwall or Somerset, and the respect with which I contemplated the perfect
appearance of Mr. Dean's handsome locomotives of that time. I felt vaguely
that the company was making a concession in admitting to its trains so
insignificant a person as myself. The first class carriage with its clerestory
roof, its delightful internal paint-work and its large and imposing lighting
apparatus produced upon my small mind a picture which I can see even to-day
in all its detail.
Those days are gone and we live in times in which the locomotive and the
carriage are expected to perform a maxi- mum of work at a rrururnurn of cost.
The modern locomotive is, of course, as far superior to the Great Western
locomotives of the 1890s as electric light is superior to oil, but our mood
has changed, dignity has gone, pride is at a discount. We are all struggling
to live. All the same, this phase of things can be carried too far. I am
told that at least one railway company is working its engines to death in
a fashion definitely unprofitable. Economies in, maintenance and oil sooner
or later produce a bill upon which sav- ings appear as a loss, with compound
interest added. It is the same thing with the first class carriage, little
by little we economise at the expense of its comfort and after a time our
first class passengers drift away into third class carriages.
When Mr. Hunt refers to the speed of our trains, however, I am not absolutely
of one mind with him. The best British trains will compare very favourably
with steam-hauled trains in any part of the world. To compare the Cheltenham
Flyer with the two-hour Birmingham express is unfair to the Birmingham
train which has to contend with gradients and curves utterly unknown on the
Swindon-London run. I do not doubt that the journey from London to Birmingham
could be made in exceptional circumstances 'in possibly one hour and fonty-five
minutes, but it is not of advantage to any company to advertise a very fast
train which is liable to be late on four days out of seven. What is so remarkable
about the Swindon train is that it is always on time, or a minute or two
early. See response from A. Sinkinson in nxt volume
Anti-friction bearings. A.D. Roberts.
On perusal of your leading article on "Anti-Friction Bearings" it
occurred to me that the following passage, quoted from An Outline History
of Anti-Friction Bearings published by the Fafnir Bearing Company, may
be of interest to your readers.- " As early as 1870, we find several rail
roads in the United States using roller bearings. Roller bearing railway
car axles were operating in Ohio at that time. The Spencer Roller Bearing
was in use on at least two other rail roads duning that period. By 1890,
the Delaware & Hudson Railroad was using roller bearings fairly extensively.
In those days the Boston & Albany had one car completely equipped with
such bearings."
William T. Hoecker.
I have read with much interest Mr. W.B. Thompson's notes on railway
travel in Canada, in the October Issue. In regard to left-hand running on
double lines, this practice was followed 'on the Chicago-Omaha section of
the Chicago and North 'Western Railway, as recently as 1931, and may still
be in effect. Mr. Thompson's remarks relating to the scarcity of passenger
trains between important towns, and the large numbers of motor cars seen
from the trains, indicate that he has observed a condition which had gradually
developed all over North America during the past twenty years. Perhaps a
brief account of what has happened in my own vicinity may be of interest
to Mr. Thompson, as a typical example. Prior to 1912, Houston, a town of
nearly 300,000 persons, and Galveston, a well-known seaport and summer resort
of slightly more than 50,000 population, were connected by three steam railway
lines. The passenger service over these lines consisted of 13 trains on weekdays
and 16 on Sundays, in either direction. In 1912, an electric passenger railway
was opened between the two towns and hourly trains, usually consisting of
a motor car and trailer, were instituted. The electric line promptly absorbed
by far the greater share of local traffic and caused the withdrawal of some
steam trains, but worse was to follow. A fairly good highway has always existed
between Galveston and Houston; however, within the past decade this has been
replaced by a concrete speedway. Under ordinary conditions it is possible
to run the 48 miles over this concrete road in a little over an hour. There
are long straight stretches between the small villages along the route, and
some daring motorists attain speeds of 80 to 90 miles per hour. Naturally,
fatal accidents are not uncommon, especially on week-ends and special holidays
when the volume of traffic is tremendous. As a result of all this competition,
the electric line now runs only half as many trains as formerly, and they
are generally not well filled. On the steam lines, there are but five long-
distance trains, all local trains having long ago disappeared.
There seems to be no solution to this problem, from a railway standpoint.
Motor cars are so numerous (there are about 10,000 in Galveston County alone,
and probably 50,000 in Houston] that the authorities are compelled to build
expensive concrete roads between all the principal cities. There are several
varieties of first-class, fully-equipped motor cars, capable of carrying
five persons at 80 miles per hour, priced at around £160 sterling, when
new. Very good second-hand cars can be bought for as little as £50.
High-grade petrol sells for 9d. per gallon (including 2½d. tax). No
steam railway can successfully compete with such conditions as these. Some
of us have long been hoping the supply of petroleum would one day give out,
but such hopes are apparently vain, as more oil is being discovered in Texas
every day. And even if the supply were to fail, some genius would probably
perfect a vehicle to run on hot air or some equally plentiful and inexpensive
substance, so we may as well resign ourselves to the inevitable.
Reviews. 395-6
Railways for all. J.F. Gairns. Revised Edition
by J. Kenneth Taylor. London: Ward, Lock & Co., Ltd. 396
This popular book has been substantially revised and new matter covering
a wide range of railway developments during the past few years, incorporated.
In addition to the large amount of detail on all sections of railway activity
contained in the original work, descriptions have now been included of the
latest locomotives, such as the L.M.S.R. Princess Royal and the L.N.E.R.
Cock o' the North classes if' this country, articulated and other high-powered
locomotives at home and abroad, details of steam locomotive design such as
poppet valve gears. heavy oil-engined locomotives and railcars and the use
of such units in high-speed service, and steam railcars. The Southern Railway's
electrification schemes are described, and recent express accelerations here
and abroad, improved methods of operation such as express freight services,
and increased use of colour light signalling, are touched upon. The notes
on marshalling yards now include a description of the working of the L.N.E.R.
yards at Whitemoor. The formation of the London Passenger Transport Board,
the forthcoming introduction by the Southern Railway of a cross-channel train
ferry, and the association of the home railways with road and air transport
are also among the varied items referred to in the new edition. Smaller type
has been adopted, which has enabled extra matter to be included without altering
the general style of the book. The numerous illustrations throughout are
excellent.
Modern traction for industrial and agricultural
railways. Roderick Hedley. London: The Locomotive Publishing Co.,
Ltd.
This is a very substantial book, of nearly 200 pages. de- voted entirely
to tractors and tractor details for use on the thousands of miles of tracks
of all gauges which exist to serve the needs of collieries, steelworks, sugar
plantations, etc., and which, viewed 'broadly, provide an infinitely wider
scope and variety of service than exists on any ordinary passenger and freight
railway system.
The subject of tractive power is thoroughly covered by sections on steam
locomotives, compressed air locomotives, internal-combustion locomotives
electric locomotives and crane locomotives, and concluding chapters deal
with the principles of mechanical traction, fuels for internal combustion
engines, and anti-friction bearings. The latter in particular is of considerable
importance in view of the low starting efforts, as in general, the tracks
of industrial and agricultural railways are not specially well laid or well
maintained so that the weight of the tractor has to be limited, and obviously,
the lower starting effort required, the more useful is the hauling power
available.
It is an open point as to whether it is quite legitimate to include amongst
the illustrations pictures of engines for the Sudan Government Railways and
the Kalka-Simla line, although it will be readily admitted that engines of
these types and sizes are not infrequently necessitated for purposes outside
the true railway systems. The sections on geared' locomotives and articulated
locomotives are of considerable interest, in view of modern developments.
but we are rather surprised to find that no reference is made to the Shay
loco- motive, which was one of the pioneer types, and carries out very useful
work to-day, particularly we believe, in the North American logging
industry.
This book should be of considerable value to manufacturers and engineers
who are in any way connected with the plant or operation of railways external
to the main systems, as it provides a very great wealth of information relative
to the various types of engines which are now available for all classes of
power. It is only some three decades ago that industrial and agricultural
light railways had to depend for their motive power on either steam or animal
traction. whereas to-day well-tried tractors are in use employing compressed-air
storage; electric-conductor or accumulator power, or both combined; petrol
or Diesel-electric; and straight petrol or Diesel drives. The matter of tractor
selection for a given job is not therefore quite as simple as it once was,
but on the other hand, it should be more readily possible to make a choice
of power which has the maximum of technical and economic efficiency - and
undoubtedly a study of this book will be of the utmost value to those responsible
engineers who have this problem to solve.
The Railway King, 1800-1871. Richard S. Lambert.
London: George AlIen & Unwin, Ltd.
The name of George Hudson, the Railway King, is familiar to al! who
have studied the intricate history of early railways in England. In 1839,
this 'inen draper of York, who had inherited a fortune of £30,000, entered
the field to amal- gamate and extend the small railways then connecting a
few scattered towns, each in the hands of a different company, mostly watching
new developments which might cut off or lower the stream of traffic on which
it was relying for revenue. He made an alliance with George Stephenson and
his son Robert in railway promotion and established the foundations of the
North Eastern, Midland and Eastern Counties Railways, and planned the idea
of a single company whose trains under one management should run from Rugby
(or even London) to Edinburgh, with control of the branches east and west
of the main line. How nearly he succeeded is shown by the fact that at the
close of 1848, just before the disastrous crash and the start of the investi-
gations into his fraudulent financial methods, out of 5,007 miles of railway
in the United Kingdom, 1,450 were under his control, and he had had the spending
of £30,000,000 of subscribed capital. The story of his achievements
in buying or leasing the smaller lines, often at extravagant prices, and
how he managed to keep bankrupt sections open, as they formed links in his
scheme of a railway system for the country, how he paid dividends which had
never been earned, and how he fought to prevent his impending downfall, makes
an intensely interesting narrative. Mr. Lambert in an excellent account gives
details of the business morals in politics and finance at that period. Hudson
was made the scape-goat for the disastrous crash following the undeniable
financial frauds, but he was not prosecuted partly because so many honourable
names were contaminated by his bribes. The story is well told of his later
years in France in thircl- rate hotels and often hungry, and how his friends
came to the rescue and bought him an annuity of £600, and how to the
day of his death in 1871 his spirit was as sanguine as ever, never confessing
defeat. The book has a good index for reference, and should find a place
in the library of all who study railway history.
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