Herbert William Garratt

Herbert William Garratt (8 June 1864 25 September 1913) was an English mechanical engineer and the inventor of the Garratt system of articulated locomotives.

Herbert William Garratt, inventor of the articulated steam locomotives that bore his name.

Garratt began his engineering career by serving an apprenticeship under John Carter Park, then locomotive superintendent of the North London Railway, from 1879-1882 at the North London Railway Bow works. He gained further experience at Doxford's marine engineering works in Sunderland, and later as an inspector for Sir Charles Fox and Sir Alexander Rendel. Garratt joined the Argentine Central Railway in 1889, where he became Locomotive Superintendent in 1892, and between 1900 and 1906 he worked for railways in Cuba, Lagos, and Lima (Peru). In 1902, Garratt was elected to membership of the Institute of Mechanical Engineers. He returned to England in 1906, taking on a role inspecting locomotives built for the New South Wales Government Railways by British manufacturers.

Design and impact of Garratt locomotives

Key components of the Garratt locomotive design

Garratt was granted a patent for an innovative locomotive design in 1908; Beyer, Peacock & Co. Ltd purchased sole rights of manufacture in Britain. After the patents ran out in 1928, the company began to use the name "Beyer-Garratt" to distinguish the locomotives they had manufactured.[1]

Garratt's design for an articulated steam locomotive featured an engine unit at each end carrying coal and water supplies, and a boiler unit suspended between them on pivots. The design was deployed in many regions throughout Africa, South America, South-east Asia, Australia and New Zealand. In these regions, difficult terrain often prevailed, adding to construction costs. Usually the railway lines suffered from low load-bearing capacity because they had been built cheaply; Garratt locomotives, with their weight usually distributed over 12 to 16 driving wheels and 8 to 16 non-driving wheels, minimised destructive forces on rails. Additionally, because they were articulated, they could generally traverse sharper curves than non-articulated locomotives. Their higher ability to penetrate previously impassable regions often had the effect of increasing human and economic interactions between settlements, reducing the isolated nature of previously remote areas of the world.

Garratt locomotives were particularly effective on narrow gauge railway lines not only because of their flexibility: the size of their fireboxes below the "bridge" between the two engine units was constrained only by the lateral distance between the bridge frames – much greater than the distance between the narrow frames of non-articulated locomotives.[note 1] This greatly increased the capacity to generate steam, on which power output depended. High efficiency compared with that of fixed-frame locomotives reduced the numbers of locomotives per train, allowed much heavier trains, and averted the need to convert rail lines to a wider gauge – an incentive for further rail network and economic expansion.

Notes

  1. The firebox space between locomotive frames on a non-articulated locomotive built for 2 ft 6 ins (762 mm) gauge, for example, is only about 40 per cent of the space on a 4 ft 812 ins (1435 mm) standard gauge locomotive.
gollark: The Twitter thread is just another incoherent ramble about some actual research leading onto... nothing?
gollark: Especially since you're not actually explaining it at all.
gollark: Whatever you're proposing doesn't seem *simpler*.
gollark: Generally speaking, probably mathematical models, but the maths involved in quantum physics and whatnot is beyond my knowledge anyway.
gollark: Also that.

References

  1. "Beyer Peacock & Co Ltd". Science Museum Group. Science Museum Group. 2019. Retrieved 8 January 2020.

Bibliography

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.