Ducol


Ducol or "D"-steel is the name of a number of high-strength low-alloy steels of varying composition, first developed from the early 1920s by the Scottish firm of David Colville & Sons, Motherwell.
Applications have included warship hull construction and light armouring, road bridges, and pressure vessels including locomotive steam boilers and nuclear reactors.

History

The original Ducol, or "D"-steel, is a manganese-silicon steel, a toughened version of the new, proven standard construction steels developed by David Colville & Sons just after WW1.
It was an improvement on British Admiralty "HT" steel, a shipbuilding and light armour steel developed c1900 and used through the end of WWI. HT was a carbon steel with a small amount of nickel, which allowed it to be hardened to a greater level without cracking. Foreign similar steels – for example, German "Low-%" Nickel Steel and U.S. High Tensile Steel – were more complex alloys using chromium, vanadium and molybdenum.
Up until about 1945, Ducol generally contained only manganese and silicon as alloying elements. More recent weldable grades include varying amounts of nickel, chromium, copper, molybdenum and vanadium.

Composition

Grade% C% Mn% Si% P% S% Ni% Cr% Mo% Cu% VNotes
Royal Navy "HT" steel0.35~0.400.8~1.20.15
§R. Sumida bridges0.24~0.301.4~1.6
IJN Ducol0.25~0.301.20~1.60?
Ducol, RN "D"-steel0.24~0.301.500.06~0.10tracetrace
§Chelsea Bridge0.251.520.130.030.030.36
Ducol W210.231.70.5 max0.25 max
Ducol W250.2 max1.5 max0.5 max0.3 max0.3 max
Ducol W300.18 max1.4 max0.5 max0.8 max0.25 max0.5 max0.1 max
Ducol W30
Grade A		0.11~0.171.0~1.50.4 max0.7 max0.4~0.70.2~0.280.3 max0.04~0.12
Ducol W30
Grade B		0.09~0.150.9~1.50.4 max0.7~1.00.4~0.70.2~0.280.3 max0.04~0.12
§Sizewell 'A'0.11.4?0.20.50.250.1

Weldability

Although modern grades of Ducol are termed 'weldable', this doesn't necessarily mean 'easily weldable'. A 1970 report on an explosion in a cylinder made of Ducol 30 found that in Ducol W30, embrittlement of the heat-affected zone occurs in welds unless post-weld heat treatment takes place at a sufficient temperature.
In addition, the original product from the 1920s was also weldable, but with dubious results. The Imperial Japanese Navy built large warships using all-welded Ducol structural elements, which swiftly led to severe problems with the Mogami-class cruisers.

Applications

Ships

Ducol has been used for bulkheads in both general construction and against torpedoes, and for light armour in warships of several countries, including the British, Japanese and perhaps Italian navies. After WW2 the highest grades of the commercial shipbuilding steels were based on this type of steel.

Royal Navy

Ducol steel was used in and to save weight, and may have contributed to initial structural damage when the big guns were fired.
It was used in British anti-torpedo-system design practice in its last battleships. The internal hull and torpedo bulkheads and internal decks were made of Ducol or "D"-class steel, an extra-strong form of HTS. According to Nathan Okun, the King George V-class battleships had the simplest armour arrangement of all post-WWI capital ships. "Most of the load-bearing portions of the ship were constructed of British Ducol extra-high-strength silicon-manganese high-tensile construction steel, including the weather deck and the bulkheads."
's fully-enclosed armoured hangar and the armoured flight deck which it supported were constructed of Ducol.
Other types of armour used on Navy ships:
The Imperial Japanese Navy made considerable use of Ducol made under licence by Japan Steel Works in Muroran, Hokkaidō, Japan: the company was set up with investment from Vickers, Armstrong Whitworth and Mitsui.
The Mogami-class cruisers were originally designed with all-welded Ducol bulkheads which were then welded to the ship's hull. The resultant faults caused by electric welding used in the structural portions of the hull resulted in deformation, and the main gun turrets were unable to train properly. They were re-built with riveted construction, and the other two were redesigned.
All of the following ships or classes used Ducol in structural bulkheads and protective plating:
  1. Japanese aircraft carrier Kaga
  2. Japanese cruiser Takao
  3. Mogami-class cruisers,
  4. Nagato-class battleships x2,
  5. Japanese aircraft carrier Shōkaku
  6. Japanese battleship Yamato
  7. Japanese battleship Musashi
  8. Japanese aircraft carrier Hiyō
  9. Japanese cruiser Oyodo
  10. Agano-class cruisers x4,
  11. Japanese aircraft carrier Shinano
In addition, the IJN's '25-ton' type river motor gun boat had an all-welded hull, protected by 4-5mm Ducol steel.

Italian Navy

The Italian Navy used a similar type of steel to Ducol in its Pugliese torpedo defense system. This underwater "bulge" system was introduced in the Italian Littorio-class battleships, and in the completely rebuilt versions of the Italian battleship Caio Duilio and the Conte di Cavour-class battleships. The inboard-facing side was consisted of a layer of silicon-manganese high-tensile steel from 28-40mm thick called "Elevata Resistenza" steel, which was probably somewhat similar to the British Ducol Steel used for light armour and torpedo bulkheads in WWII.

Tanks

According to one source, during WW2 Russian tanks were made of a similar type of steel because of a critical lack of alloying elements such as chromium and nickel.

Bridges

Sumida River

The Eitai-bashi and Kiyosu-bashi bridges over the Sumida River in Tokyo seem to have been some of the first bridges to be made with Ducol, at the time a state-of-the-art technology.
The bridges were built by Kawasaki Dockyard Co., to replace earlier crossings which were destroyed in the 1923 Great Kanto earthquake. High-tensile Ducol was used for the lower supports of the Eitai-bashi tied-arch bridge, and for the upper cables of the Kiyosu-bashi self-anchored suspension bridge. The steel was made at Kawasaki's Hyogo Works, Kobe.

Chelsea Bridge

Ducol was also used in the construction of the stiffening girders of Chelsea Bridge joined by HTS rivets. A small amount of copper was added to the mix to improve corrosion resistance.

Glen Quoich Road Bridge

Used in the construction of the Glen Quoich Road Bridge, Aberdeenshire - built 1955 by Sir William Arrol & Co. crossing the Qoich Water between Mar Lodge and Allanaquoich, not far from where it joins the River Dee.

Pressure vessels

Ducol has been used in pressure vessels including steam boilers and solid wall ammonia converter shells as used in the Haber-Bosch process. Normalised and tempered Ducol W30 has been used in heavy walled nuclear reactors.
In the UK, the British Standard for low alloy steels used for high temperature pressure purposes is BS EN 10028-2:2006. It replaced the old BS1501 Part 2: 1988.

Steam locomotives

The boiler plates for the Southern Railway 4-6-0 Lord Nelson class locomotives, designed by Richard Maunsell in 1926 to work at, were made of Ducol.

Incidents

A number of pressure vessels & boilers constructed with Ducol have failed. Such failures have all been because of faulty fabrication or testing of the vessel, rather than the steel itself.

Sizewell 'A'

Ducol was used in the boiler shells at Sizewell ‘A’ nuclear reactor.
Failure of Sizewell ‘A’ boiler under hydrostatic test, May 1963. "The boiler was 18.9 m long, 6.9 m diameter, and was fabricated from plates 57 mm thick in a low alloy steel, conforming to BW87A specification, of composition 0.1C, 1.4Mn, 0.5Cr, 0.25Mo, 0.2Ni, 0.1 V. The cause of the failure was attributed to a shock impact loading, when the wooden chocks on which the vessel was resting during the hydro-test suddenly gave way."
Ducol would have been used for the later stations, but was superseded by prestressed concrete pressure vessels. The advantage of prestressed concrete is that once the initial compression has been applied, the resulting material has the characteristics of high-strength concrete when subject to any subsequent compression forces, and of ductile high-strength steel when subject to tension forces.

John Thompson pressure vessel

In December 1965 a boiler made of Ducol was under construction by John Thompson, Wolverhampton, for ICI's ammonia plant at Fisons' Immingham works. It was being pressure-tested after heat treatment when it exploded, throwing one chunk weighing 2 tons right through the workshop wall and landing 50 metres away.
In Ducol W30, embrittlement of the heat-affected zone in welds occurs unless post-weld heat treatment takes place at a sufficient temperature. The amount of pre-heating and the type of welding consumables (eg low hydrogen

Cockenzie power station

A boiler drum made with Ducol plates, manufactured by Babcock & Wilcox Ltd at Renfrew, near Glasgow, to BS 1113 was installed at Cockenzie Power Station in East Lothian, Scotland. It exploded on 6th May 1967 under repeated pressure testing. According to Jim Thomson, the failure was caused by a crack which occurred next to an economiser nozzle replaced during testing; the crack had penetrated part-way through the thick wall of the pressure vessel.