Livens Projector

Last updated

Livens Projector
Livens gas projector loading.jpg
British soldiers loading and fitting electrical leads to a battery of Livens projectors
Type Mortar
Place of originUnited Kingdom
Service history
In service1916–1918
Used by British Empire
United States
Wars World War I
Production history
DesignerCaptain William Howard Livens, Royal Engineers
Designed1916
No. built140,000 projectors
400,000 bombs [1] [2] [3]
Specifications
Shell Gas drum
Calibre 8 inches (200 mm)
Elevation fixed
Traverse fixed
Maximum firing range1,640 yd (1,500 m)
Filling phosgene, [4] flammable oil
Filling weight30 lb (14 kg) [5]
Detonation
mechanism
Impact

The Livens Projector was a simple mortar-like weapon that could throw large drums filled with flammable or toxic chemicals. [6]

Contents

In the First World War, the Livens Projector became the standard means of delivering gas attacks by the British Army and it remained in its arsenal until the early years of the Second World War. [7]

History

The Livens Projector was created by Captain William Livens of the Royal Engineers. [8] Livens designed a number of novel weapons, including a large-calibre flame thrower, to engulf German trenches in burning oil, that was deployed at the Somme in 1916. (One of these weapons was partially excavated in 2010 for an episode of archaeological television programme Time Team , having been buried when the tunnel in which it was being built was hit by a German shell.) In the Second World War, he worked on petroleum warfare weapons such as the flame fougasse and various other flame weapons. [9] [10]

Prior to the invention of the Livens Projector, chemical weapons had been delivered either by cloud attacks or chemical-filled shells fired from howitzers. Cloud attacks at first were made by burying gas-filled cylinders just beyond the parapet of the attacker's trenches and then opening valves on the tanks when the wind was right. (Later British practice was to bring up flatcars with gas cylinders on a line parallel to the front to be attacked, and open the cylinders without removing them from the rail car. [11] ) This allowed a useful amount of gas to be released but there was danger that the wind would change and the gas drift back over the attacking troops. Chemical shells were much easier to aim but could not deliver nearly as much gas as a cylinder.

Livens was in command of Z Company, the unit charged with developing and using flame and chemical weapons. Flame throwers and various means of dispensing chemicals had proven frustratingly limited in effect. During an attack on the Somme, Z Company encountered a party of Germans who were well dug in. Grenades did not shift them and Livens improvised a giant Molotov cocktail using two 5-imperial-gallon (23 L) oil cans. When these were thrown into the German positions they were so effective that Harry Strange wondered whether it would be better to use containers to carry the flame to the enemy rather than relying on a complex flame thrower. [12] [13]

Reflecting on the incident, Livens and Strange considered how a really large shell filled with fuel might be thrown by a mortar. [14] Livens went on to develop a large, simple mortar that could throw a three-gallon drum of oil which would burst when it landed, spreading burning oil over the target. [15] Livens came to the attention of General Hubert Gough who was impressed by his ideas and "wangled" everything that Livens needed for his large projector. [16]

On 25 July 1916 at Ovillers-la-Boisselle during the Battle of the Somme, Z Company used eighty projectors when the Australians were due to attack Pozières. Since the early versions had a short range, it was necessary to, first, neutralize German machine gun nests, and, then place the projectors 200 yd (180 m) forward into no-man's-land. [15]

Z Company rapidly developed the Livens Projector, increasing its range to 350 yd (320 m) and eventually an electrically triggered version with a range of 1,300 yd (1,200 m) used at the Battle of Messines in June 1917. [15]

The Livens Projector was then modified to fire canisters of poison gas rather than oil. This system was tested in secret, at Thiepval in September 1916 and Beaumont-Hamel in November. [15] The Livens Projector was able to deliver a high concentration of gas a considerable distance. Each canister delivered as much gas as several gas shells. Without the need to reload, a barrage could be launched quickly, catching the enemy by surprise. Although the projectors were single-shot weapons they were cheap and used in hundreds or even thousands.

The Livens Projector was also used to fire other substances. At one time or another the drums contained high explosive, oil and cotton-waste pellets, thermite, white phosphorus and "stinks". Used as giant stink bombs to trick the enemy, "stinks" were malodorous but harmless substances such as bone oil and amyl acetate used to simulate a poison gas attack, compelling the opponents to don cumbersome masks (which reduced the efficiency of German troops) on occasions when gas could not be safely employed. [17] Alternatively, "stinks" could be used to artificially prolong the scale, discomfort and duration of genuine gas-attacks i.e. alternating projectiles containing "stinks" with phosgene, adamsite or chloropicrin. There was even a design for ammunition containing a dozen Mills bombs in the manner of a cluster bomb. [18] The Livens Projector remained in the arsenal of the British Army until the early years of the Second World War. [7] In the context of the Invasion Scare in the early years of World War II, over 25,000 Livens Projectors were produced for the defense of Great Britain between 1939-1942. [19]

Description

Typical layout LivensProjectorDiagramWWI.jpg
Typical layout

The Livens Projector was designed to combine the advantages of gas cylinders and shells by firing a cylinder tank at the enemy. [20] It consisted of a simple metal pipe that was set in a ground at a 45-degree angle. Specifications varied during the war. The early field improvisations in July 1916 near La Boselle based the barrel on 12-inch-diameter (300 mm) oil drums, the projectile was an oil can. The production model was decided on in December 1916 after further successful field trials on the Somme. It was based on spare 8-inch-diameter (200 mm) oxy-acetylene welded tubing. [21]

The 8-inch barrel became standard and was first used in number when 2,000 fired a salvo in the Battle of Vimy Ridge in April 1917. Barrels were supplied in three lengths depending on required range: 2 ft 9 in (84 cm) for short range, 3 ft (91 cm) for medium range and 4 ft 3 in (130 cm) for maximum range. [22] A drum 7.6 in (193 mm) in diameter and 20 in (508 mm) long, containing 30 lb (14 kg) of gas, was shot out by an electrically initiated charge, giving it a range of about 1,500 m (1,640 yd). [5] On impact with the target, a burster charge would disperse the chemical filling over the area. [23]

It was also used to project flammable oil, as with 1,500 drums fired before the Battle of Messines in June 1917. [24] Oil was also tried on 20 September 1917 during the Battle of the Menin Road Ridge with 290 projectors used in support of an attempt to capture Eagle Trench east of Langemarck. This included concrete bunkers and machine gun nests but the drums did not land in the trenches and failed to suppress the German defenders there. [25] [26]

Use

Phosgene bomb unearthed on the Somme, 2006 LivensPhosgeneTank.jpg
Phosgene bomb unearthed on the Somme, 2006
Two projectiles and a launcher displayed at the Museum of Lincolnshire Life Livens projector, Museum of Lincolnshire Life.jpg
Two projectiles and a launcher displayed at the Museum of Lincolnshire Life

As a rule, the projectors were sited out in the open some little way behind the front line so that digging, aiming (either by direct line of sight or by compass) and wiring up the electrical leads were easier. When camouflaged the positions would be unknown to the enemy so that although the enemy was able to recognise the direction of the location by the discharge flash he would be uncertain of the range. As such these installations could only be carried out at night. The digging of the narrow trenches did not involve much labour and later in the war the projectors were only buried to a depth of about a one foot (30 cm), instead of up to their muzzles. [27] The projector was somewhat unreliable. To safeguard friendly forces from 'shorts' an area immediately ahead of the projector battery was cleared of troops before firing. This area allowed for the possibility of drums reaching only 60% of the estimated range and veering 20 degrees from the central line of fire by the wind or from some other cause. [27]

The projectors were also inaccurate,

It was distinctly laid down as a principle that, owing to the inaccuracy of the weapon, the most suitable targets were areas which were either strongly held or which contained underground shelters in which the occupants were safe against artillery fire. [28]

A British training manual of 1940 described it as,

...a simple weapon which does not aspire to great accuracy. Its range is limited to about 1,800 yards (1,600 m); the noise of firing is very loud, and at night is accompanied by a vivid flash..... Projectors are the principal armament of C.W. companies, RE. [7]

The projector's unreliability and inaccuracy were more than made up for by the weapon's principal advantages: it was a cheap, simple and extremely effective method of delivering chemical weapons. Typically, hundreds, or even thousands, of Livens projectors would be fired in unison during an attack to saturate the enemy lines with poison gas.

This weapon was one which, if the installation had been carried out carefully and camouflaged, was capable not only of flooding the enemy's trenches unexpectedly with a deadly gas a few seconds after notice of its approach had been given by the flash of the discharge but of establishing such a high concentration of poisonous vapour—especially in the neighbourhood where each drum fell—that no respirator could be expected to give adequate protection to its wearer. [...] This 'mass effect' had, of course, not been achieved to any marked extent during the Somme battle, when only a dozen or two makeshift drums were discharged at a time; but now that we were proposing to fire several thousand of them simultaneously in a single operation, the effect might well be expected to be—and in fact was—profound. In a captured German document, dated 27/12/17, an English gas projector bombardment was described as follows: 'The discharge in sight and sound resembles a violent explosion; volcanic sheets of flame or the simultaneous occurrence of many gun flashes, thick noise of impact up to 25 seconds after the flash of discharge. The mines, contrary to the manner of discharge, do not all burst exactly simultaneously: the noise resembles that of an exploding dump of hand-grenades. Fragmentation is very slight'. [29]

German equivalent

German 18 cm Gaswerfer Bundesarchiv Bild 146-1969-024-67, Westfront, Deutsche Gaswerfer (18cm).jpg
German 18 cm Gaswerfer

The Livens projector provided the Germans with inspiration for a similar device, known as the Gaswurfminen. [30] Over eight hundred of these were used against the Italian Army at the Battle of Caporetto.

Surviving examples

See also

Notes

  1. Jones (2007) p. 43
  2. National Archive, T 173/330 – Royal Commission on awards to inventors – Livens
  3. Ministry of Munitions History 1922, p. 100
  4. "The military policy laid down in May, 1917... It [C.G. i.e. phosgene] was the only lethal substance allocated to projector drums". Ministry of Munitions 1922, Volume XI, Part II Chemical Warfare Supplies. p. 8
  5. 1 2 Jones (2007) p. 42
  6. "1916 – Other Corps activities". Corps History – Part 14. Royal Engineers Museum. Archived from the original on 3 June 2010. Retrieved 3 February 2009.
  7. 1 2 3 The Use of Gas in the Field, 1940
  8. Palazzo, 2002, p. 103.
  9. LeFebure, 1926, p. 60
  10. Banks, 1946, p. 33
  11. Ian V. Hogg, Gas, New York: Ballantine, 1975
  12. Croddy, 2001, p138.
  13. Awards to Inventors, 1922, p20
  14. Awards to Inventors, 1922, p30
  15. 1 2 3 4 "Major William Howard Livens (1889–1964)". Notable Individuals of the Great War: # 2. I – L. The Western Front Association. Archived from the original on 21 October 2007. Retrieved 4 March 2008.
  16. Awards to Inventors, 1922, pp 51–62
  17. Foulkes 1934, p. 169.
  18. Rawson 2006, p. 272.
  19. U.K. Central Statistical Office, Fighting with Figures, 1995, Table 7.13.
  20. LeFebure (1926) p. 48–63
  21. Ministry of Munitions History 1922, page 98–99
  22. Ministry of Munitions History 1922, page 99–100
  23. United States Dept. of War, 1942, pp 12–13
  24. Jones 2007, page 44
  25. Farndale 1986, page 207
  26. British Official History (Military Operations France & Belgium 1917), page 270
  27. 1 2 Foulkes 1934, p. 202.
  28. Foulkes 1934, p. 203.
  29. Foulkes 1934, pp. 199–200.
  30. Nash, David (1980). Imperial German Army Handbook, 1914–1918. I. Allen. p. 107. ISBN   978-0711009684.
  31. 03. Lance-mines alliés (allied mine-throwers) – Page 3 – Canons de la Grande Guerre / WW1 guns" Bernard Plumier: webpage (in French)

Related Research Articles

<span class="mw-page-title-main">Chemical warfare</span> Using poison gas or other toxins in war

Chemical warfare (CW) involves using the toxic properties of chemical substances as weapons. This type of warfare is distinct from nuclear warfare, biological warfare and radiological warfare, which together make up CBRN, the military acronym for chemical, biological, radiological, and nuclear, all of which are considered "weapons of mass destruction" (WMDs), a term that contrasts with conventional weapons.

<span class="mw-page-title-main">Flamethrower</span> Ranged incendiary device designed to project a controllable stream of fire

A flamethrower is a ranged incendiary device designed to project a controllable jet of fire. First deployed by the Byzantine Empire in the 7th century AD, flamethrowers saw use in modern times during World War I, and more widely in World War II as a tactical weapon against fortifications.

<span class="mw-page-title-main">Chemical weapons in World War I</span> Contains Chlorine, phosgene (a choking agent) and mustard gas

The use of toxic chemicals as weapons dates back thousands of years, but the first large-scale use of chemical weapons was during World War I. They were primarily used to demoralize, injure, and kill entrenched defenders, against whom the indiscriminate and generally very slow-moving or static nature of gas clouds would be most effective. The types of weapons employed ranged from disabling chemicals, such as tear gas, to lethal agents like phosgene, chlorine, and mustard gas. This chemical warfare was a major component of the first global war and first total war of the 20th century. The killing capacity of gas was limited, with about 90,000 fatalities from a total of 1.3 million casualties caused by gas attacks. Gas was unlike most other weapons of the period because it was possible to develop countermeasures, such as gas masks. In the later stages of the war, as the use of gas increased, its overall effectiveness diminished. The widespread use of these agents of chemical warfare, and wartime advances in the composition of high explosives, gave rise to an occasionally expressed view of World War I as "the chemist's war" and also the era where weapons of mass destruction were created.

<span class="mw-page-title-main">Trench warfare</span> Land warfare involving static fortification of lines

Trench warfare is a type of land warfare using occupied lines largely comprising military trenches, in which combatants are well-protected from the enemy's small arms fire and are substantially sheltered from artillery. It became archetypically associated with World War I (1914–1918), when the Race to the Sea rapidly expanded trench use on the Western Front starting in September 1914.

<span class="mw-page-title-main">Mortar (weapon)</span> Artillery weapon that launches explosive projectiles at high angles

A mortar is usually a simple, lightweight, man-portable, muzzle-loaded weapon, consisting of a smooth-bore metal tube fixed to a base plate with a lightweight bipod mount and a sight. They launch explosive shells in high-arching ballistic trajectories. Mortars are typically used as indirect fire weapons for close fire support with a variety of ammunition.

<span class="mw-page-title-main">Technology during World War I</span> Technology available in World War I

Technology during World War I (1914–1918) reflected a trend toward industrialism and the application of mass-production methods to weapons and to the technology of warfare in general. This trend began at least fifty years prior to World War I during the American Civil War of 1861–1865, and continued through many smaller conflicts in which soldiers and strategists tested new weapons.

<span class="mw-page-title-main">Early thermal weapons</span> Weapons during the classical and medieval periods that used heat or burning for damage

Early thermal weapons, which used heat or burning action to destroy or damage enemy personnel, fortifications or territories, were employed in warfare during the classical and medieval periods.

<span class="mw-page-title-main">QF 18-pounder gun</span> WW1 British field gun

The Ordnance QF 18-pounder, or simply 18-pounder gun, was the standard British Empire field gun of the First World War-era. It formed the backbone of the Royal Field Artillery during the war, and was produced in large numbers. It was used by British Forces in all the main theatres, and by British troops in Russia in 1919. Its calibre (84 mm) and shell weight were greater than those of the equivalent field guns in French (75 mm) and German (77 mm) service. It was generally horse drawn until mechanisation in the 1930s.

<span class="mw-page-title-main">Newton 6-inch mortar</span> British mortar weapon

The Newton 6-inch mortar was the standard British medium mortar in World War I from early 1917 onwards.

<span class="mw-page-title-main">2-inch medium mortar</span> Smooth bore muzzle loading medium trench mortar

The 2 inch medium trench mortar, also known as the 2-inch howitzer, and nicknamed the "toffee apple" or "plum pudding" mortar, was a British smooth bore muzzle loading (SBML) medium trench mortar in use in World War I from mid-1915 to mid-1917. The designation "2-inch" refers to the mortar barrel, into which only the 22-inch bomb shaft but not the bomb itself was inserted; the spherical bomb itself was actually 9 inches (230 mm) in diameter and weighed 42 lb (19 kg), hence this weapon is more comparable to a standard mortar of approximately 5-6 inch bore.

<span class="mw-page-title-main">Sapping</span> Type of siege operation in warfare

Sapping is a term used in siege operations to describe the digging of a covered trench to approach a besieged place without danger from the enemy's fire. The purpose of the sap is usually to advance a besieging army's position towards an attacked fortification. It is excavated by specialised military units, whose members are often called sappers.

<span class="mw-page-title-main">William Howard Livens</span> British engineer and soldier

William Howard Livens, was an engineer, a soldier in the British Army and an inventor particularly known for the design of chemical warfare and flame warfare weapons. Resourceful and clever, Livens' successful creations were characterised by being very practical and easy to produce in large numbers. In an obituary, Sir Harold Hartley said "Livens combined great energy and enterprise with a flair for seeing simple solutions and inventive genius."

<span class="mw-page-title-main">British Army uniform and equipment in World War I</span>

The British Army used a variety of standardized battle uniforms and weapons during World War I. According to the British official historian Brigadier James E. Edmonds writing in 1925, "The British Army of 1914 was the best trained best equipped and best organized British Army ever sent to war". The value of drab clothing was quickly recognised by the British Army, who introduced Khaki drill for Indian and colonial warfare from the mid-19th century on. As part of a series of reforms following the Second Boer War, a darker khaki serge was adopted in 1902, for service dress in Britain itself. The British military authorities showed more foresight than their French counterparts, who retained highly visible blue coats and red trousers for active service until the final units received a new uniform over a year into World War I. The soldier was issued with the 1908 Pattern Webbing for carrying personal equipment, and he was armed with the Short Magazine Lee–Enfield rifle.

<span class="mw-page-title-main">2nd Chemical Battalion (United States)</span> Military unit

The 2nd Chemical Battalion is a United States Army chemical unit stationed at Fort Hood, Texas, United States, and is part of the 48th Chemical Brigade. The battalion can trace its lineage from the 30th Engineer Regiment and has served in World War I, World War II, Korean War, Operation Desert Storm, and Operation Iraqi Freedom.

<span class="mw-page-title-main">M1 flamethrower</span> Flamethrower

The M1 and M1A1 were portable flamethrowers developed by the United States during World War II. The M1 weighed 72 lb, had a range of 15 meters, and had a fuel tank capacity of five gallons. The improved M1A1 weighed less, at 65 lb, had a much longer range of 45 meters, had the same fuel tank capacity, and fired thickened fuel (napalm).

<span class="mw-page-title-main">Flame fougasse</span> Anti-personnel and anti-tank mine

A flame fougasse is a type of mine or improvised explosive device which uses an explosive charge to project burning liquid onto a target. The flame fougasse was developed by the Petroleum Warfare Department in Britain as an anti-tank weapon during the invasion crisis of 1940. During that period, about 50,000 flame fougasse barrels were deployed in some 7,000 batteries, mostly in southern England and a little later at 2,000 sites in Scotland. Although never used in combat in Britain, the design saw action later in Greece.

The Petroleum Warfare Department (PWD) was a government department established in Britain in 1940 in response to the invasion crisis during World War II, when Germany apparently would invade the country. The department was initially tasked with developing the uses of petroleum as a weapon of war, and it oversaw the introduction of a wide range of flame warfare weapons. Later in the war, the department was instrumental in the creation of the Fog Investigation and Dispersal Operation that cleared runways of fog allowing the landing of aircraft returning from bombing raids over Germany in poor visibility, and Operation Pluto, which installed prefabricated fuel pipelines between England and France soon after the Allied invasion of Normandy in June 1944.

<span class="mw-page-title-main">No. 106 fuze</span> British instantaneous percussion artillery fuze

The number 106 fuze was the first British instantaneous percussion artillery fuze, first tested in action in late 1916 and deployed in volume in early 1917.

Livens Large Gallery Flame Projectors were large experimental flamethrowers used by the British Army in World War I, named after their inventor, Royal Engineers officer William Howard Livens.

References

Further reading

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.