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A mortar is usually a simple, lightweight, man portable, muzzle-loaded weapon, consisting of a smooth-bore metal tube fixed to a base plate (to absorb recoil) with a lightweight bipod mount and a sight. They launch explosive shells in high-arcing ballistic trajectories. Mortars are typically used as indirect fire weapons for close fire support with a variety of ammunition.
Mortars have been used for hundreds of years, originally in siege warfare. Many historians consider the first mortars to have been used at the 1453 siege of Constantinople by Mehmed the Conqueror. An Italian account of the 1456 siege of Belgrade by Giovanni da Tagliacozzo said that the Ottoman Turks used seven mortars that fired "stone shots one Italian mile high". The time of flight of these was apparently long enough that casualties could be avoided by posting observers to give warning of their trajectories. However, earlier mortars were used in Korea in a 1413 naval battle when Korean gunsmiths developed the Wan'gu (gourd-shaped mortar) (완구, 碗口). The earliest version of the Wan'gu dates back to 1407. Choi Hae-san (최해산, 崔海山) (1380–1443), the son of Choe Mu-seon(최무선) (1325–1395), is generally credited with inventing the first Wan'gu.
Early mortars, such as the Pumhart von Steyr, were also large and heavy, and could not be easily transported. Simply made, these weapons were no more than iron bowls reminiscent of the kitchen and apothecary mortars whence they drew their name. An early transportable mortar was invented by Baron Menno van Coehoorn (Siege of Grave, 1673). This mortar fired an exploding shell, which had a fuse lit by the hot gases when fired. This innovation was quickly taken up, necessitating a new form of naval ship, the bomb vessel. Mortars played a significant role in the Venetian conquest of Morea and in the course of this campaign an ammunition store in the Parthenon was blown up (see diagram).
An early use of these more mobile mortars as field (rather than siege) weapons was by British forces in the suppression of the Jacobite rising of 1719 at the Battle of Glen Shiel. High angle trajectory mortars held a great advantage over standard field guns in the rough terrain of the West Highlands of Scotland.
The mortar had fallen out of general use in Europe by the Napoleonic era and interest in the weapon was not revived until the beginning of the 20th century.
Mortars were heavily used by both sides during the American Civil War. At the Siege of Vicksburg, General US Grant reported making coehorn mortars "by taking logs of the toughest wood that could be found, boring them out for six- or twelve-pound shells and binding them with strong iron bands. These answered as Coehorns, and shells were successfully thrown from them into the trenches of the enemy".
During the Russo-Japanese War, Lieutenant-General Leonid Gobyato of the Imperial Russian Army applied the principles of indirect fire from closed firing positions in the field and, with the collaboration of General Roman Kondratenko, he designed the first mortar that fired navy shells.
The German Army studied the Siege of Port Arthur, where heavy artillery had been unable to destroy defensive structures like barbed wire and bunkers. As a result, they developed a short-barreled rifled muzzle-loading mortar called the Minenwerfer. Heavily used during World War I, they were made in three sizes; 7.58 cm (2.98 in), 17 cm (6.7 in) and 25 cm (9.8 in).
World War I also saw the introduction of the Stokes mortar. It was the first modern man-portable mortar and the forerunner of all modern mortars in use today. These modern weapons are light, adaptable, easy to operate, and yet possess enough accuracy and firepower to provide infantry with quality close fire support against soft and hard targets more quickly than any other means.
It was not until the Stokes Mortar was devised by Sir Wilfred Stokes in 1915 during the First World War that the modern mortar transportable by one person was born. In the conditions of trench warfare, there was a great need for a versatile and easily portable weapon that could be manned by troops undercover in the trenches. Stokes's design was initially rejected in June 1915 because it was unable to use existing stocks of British mortar ammunition, and it took the intervention of David Lloyd George (at that time Minister of Munitions) and Lieutenant-Colonel J. C. Matheson of the Trench Warfare Supply Department (who reported to Lloyd George) to expedite manufacture of the Stokes mortar. The weapon proved to be extremely useful in the muddy trenches of the Western Front, as a mortar round could be aimed to fall directly into trenches, where artillery shells, due to their low angle of flight, could not possibly go.
The Stokes mortar was a simple muzzle-loaded weapon, consisting of a smoothbore metal tube fixed to a base plate (to absorb recoil) with a lightweight bipod mount. When a mortar bomb was dropped into the tube, an impact sensitive primer in the base of the bomb would make contact with a firing pin at the base of the tube, and detonate, firing the bomb towards the target. It could fire as many as 25 bombs per minute and had a maximum range of 800 yards (730 m) firing the original cylindrical unstabilised projectile.
A modified version of the mortar, which fired a modern fin-stabilised streamlined projectile and had a booster charge for longer range, was developed after World War I; this was in effect a new weapon. By World War II, it could fire as many as 30 bombs per minute, and had a range of over 2,500 yards (2,300 m) with some shell types.
These weapons were the prototypes for all subsequent light mortar developments around the world.
Mortar carriers are vehicles which carry a mortar as a primary weapon. Numerous vehicles have been used to mount mortars, from improvised civilian trucks used by insurgents, to modified Infantry fighting vehicles, such as variants of the M3 half track and M113 armored personnel carrier, to vehicles specifically intended to carry a mortar. Simpler vehicles carry a standard infantry mortar while in more complex vehicles the mortar is fully integrated into the vehicle and cannot be dismounted from the vehicle. Mortar carriers cannot be fired while on the move and some must be dismounted to fire.
There are numerous AFVs and even MBTs that can be equipped with a mortar, either outside or inside of the cabin. The Israeli Merkava tank uses a 60 mm mortar as a secondary armament. The Russian army uses the 2S4 Tyulpan (Tulip) self-propelled 240 mm heavy mortar which is one of the largest mortars in current use.
Gun-mortars are breech loaded mortars usually equipped with a hydraulic recoil mechanism, and sometimes equipped with an autoloader. They are usually mounted on an armored vehicle and are capable of direct fire. The archetypes are the Brandt Mle CM60A1 and Brandt 60 mm LR, which combine features of modern infantry mortars together with those of modern cannon. Such weapons are smoothbore, firing fin stabilised rounds, using relatively small propellant charges in comparison to projectile weight. They have short barrels in comparison to guns and are much more lightly built than guns of a similar calibre – all characteristics of infantry mortars. This produces a hybrid weapon capable of engaging area targets with indirect high angle fire, and also specific targets such as vehicles and bunkers with direct fire. Such hybrids are much heavier and more complicated than infantry mortars, superior to rocket propelled grenades in the anti armour and bunker busting role, but have a reduced range compared to modern gun-howitzers and inferior anti-tank capability compared to modern anti tank guided weapons. However, they do have a niche in, for example, providing a multi-role anti-personnel, anti-armour capability in light mobile formations. The AMOS (Advanced Mortar System) is an example of a modern gun mortar system. It uses a 120 mm automatic twin barrelled, breech loaded mortar turret, which can be mounted on a variety of armored vehicles and attack boats.
Spigot mortars, a particular type of mortar, consist mainly of a solid rod or spigot, onto which a hollow tube in the projectile fits—inverting the normal tube-mortar arrangement. At the top of the tube in the projectile, a cavity contains propellant, such as cordite. There is usually a trigger mechanism built into the base of the spigot, with a long firing pin running up the length of the spigot activating a primer inside the projectile and firing the propellant charge.
The advantage of a spigot mortar is that the firing unit (baseplate and spigot) is smaller and lighter than a conventional tube mortar of equivalent payload and range. It is also somewhat simpler to manufacture. Further, most spigot mortars have no barrel in the conventional sense, which means ammunition of almost any weight and diameter can be fired from the same mortar.
The disadvantage is that while most mortar bombs have a streamlined shape towards the back that fits a spigot mortar application well, using that space for the spigot mortar tube takes volume and mass away from the payload of the projectile. If a soldier is carrying only a few projectiles, the projectile weight disadvantage is not significant. However, the weight of a large quantity of the heavier and more complex spigot projectiles offsets the weight saved due to the spigot mortar being lighter than a conventional mortar.
A near-silent mortar can operate using the spigot principle. Each round has a close-fitting sliding plug in the tube that fits over the spigot. When the round is fired, the projectile is pushed off the spigot, but before the plug clears the spigot it is caught by a constriction at the base of the tube. This traps the gases from the propelling charge and hence the sound of the firing. After World War II the Belgium Fly-K silent spigot mortar was accepted into French service as the TN-8111.
Spigot mortars are generally out of favor in modern usage, replaced by small conventional mortars. Military applications of spigot mortars include:
- The 290 mm petard mortar used on the Churchill AVRE by Britain in World War II.
- The 320 mm Type 98 mortar used by Japan in World War II to some psychological effect in the battles of Iwo Jima and Okinawa
- Anti-tank launchers
- Anti-submarine launchers
- The Hedgehog launcher, used from the deck of a ship, used 24 spigot mortars which fired a diamond pattern of anti-submarine projectiles into the sea ahead of the ship. A sinking projectile detonated if it struck a submarine, and the pattern was such that any submarine partly in the landing zone of the projectiles would be struck one or more times.
Non-military applications include the use of small-calibre spigot mortars to launch lightweight, low-velocity foam dummy targets used for training retriever dogs for bird hunting. Extremely simple launchers use a separate small primer cap as the sole propellant (similar or identical to the cartridges used in industrial nail guns).
Improvised, or "home-made", mortars have been used by insurgent groups, usually to attack fortified military installations or to terrorize civilians. They are usually constructed from heavy steel piping mounted on a steel frame. These weapons may fire standard mortar rounds, purpose made shells, re-purposed gas cylinders filled with explosives and shrapnel, or any other type of improvised explosive, incendiary or chemical munitions. These were called "Barrack Busters" by the Provisional Irish Republican Army (IRA). They are known as "Hell Cannons" in the Syrian Civil War, where observers have noted that they are "wildly inaccurate" and responsible for hundreds of civilian deaths.
Most modern mortar systems consist of four main components: a barrel, a base plate, a bipod and a sight. Modern mortars normally range in calibre from 60 mm (2.36 in) to 120 mm (4.72 in). However, both larger and smaller mortars have been produced.
The modern mortar is a muzzle-loaded weapon and relatively simple and easy to operate. It consists of a tube into which the gunners drop a mortar round. When the round reaches the base of the tube it hits a fixed firing pin that fires the round. The tube is generally set at an angle of between 45 and 85 degrees to the ground, with the higher angle producing a shorter horizontal round trajectory. Some mortars have a moving firing pin, operated by a lanyard or trigger mechanism.
Ammunition for mortars generally comes in two main varieties: fin-stabilized and spin-stabilized. Examples of the former have short fins on their posterior portion, which control the path of the bomb in flight. Spin-stabilized mortar bombs rotate as they travel along and leave the mortar tube, which stabilizes them in much the same way as a rifle bullet. Both types of rounds can be either illumination (infra-red or visible illumination), smoke, high explosive and training rounds. Mortar bombs are often referred to, incorrectly, as "mortars".
Operators may fire spin-stabilized rounds from either a smoothbore or a rifled barrel. Rifled-mortars are more accurate, but slower to load. Since mortars are generally muzzle-loaded, mortar bombs for rifled barrels usually have a pre-engraved band, called an obturator, that engages with the rifling of the barrel. Exceptions to this were the U.S. M2 4.2 inch mortar and M30 mortar, whose ammunition had a sub-caliber expandable ring that enlarged when fired. This allows the projectile to slide down the barrel freely, but grip the rifling when fired. The system resembles the Minié ball for muzzle-loading rifles.
For extra range, propellant rings (augmentation charges) are attached to the bomb's fins. The rings are usually easy to remove, because they have a major influence on the speed and thus the range of the bomb. Some mortar rounds can be fired without any augmentation charges, e.g., the 81 mm L16 mortar.
|Charge 1||110 m/s||390–1,120m|
|Charge 2||137 m/s||580–1,710m|
|Charge 3||162 m/s||780–2,265m|
|Charge 4||195 m/s||1,070–3,080m|
|Charge 5||224 m/s||1,340–3,850m|
|Charge 6||250 m/s||1,700–4,680m|
Video of L16 81 mm mortar fired
The XM395 Precision Guided Mortar Munition (PGMM) is a 120 mm guided mortar round developed by Alliant Techsystems. Based on Orbital ATK's Precision Guidance Kit for 155 mm artillery projectiles, XM395 combines GPS guidance and directional control surfaces into a package that replaces standard fuzes, transforming existing 120 mm mortar bodies into precision-guided munitions. The XM395 munition consists of a GPS-guided kit fitted to standard 120 mm smoothbore mortar rounds that includes the fitting of a nose and tail subsystem containing the maneuvering parts.
The Strix mortar round is a Swedish endphase-guided projectile fired from a 120 mm mortar currently manufactured by Saab Bofors Dynamics. STRIX is fired like a conventional mortar round. The round contains an infrared imaging sensor that it uses to guide itself onto any tank or armoured fighting vehicle in the vicinity where it lands. The seeker is designed to ignore targets that are already burning. Launched from any 120 mm mortar, Strix has a normal range of up to 4.5 km. The addition of a special sustainer motor increases the range to 7.5 km.
Compared to artillery
Modern mortars and their ammunition are generally much smaller and lighter than artillery, such as guns and howitzers, which allows light and medium (typically, 60 mm and 81 mm/82 mm) mortars to be considered light weapons; i.e. capable of transport by personnel without vehicle assistance. They are short-range weapons, and often more effective than artillery for many purposes within their shorter range. In particular, due to its high, parabolic trajectory with a near vertical descent, the mortar can land bombs on nearby targets, including those behind obstacles or in fortifications, such as light vehicles behind hills or structures, or infantry in trenches or spider holes. This also makes it possible to launch attacks from positions lower than the target of the attack. (For example, long-range artillery could not shell a target 1 km away and 30 metres (100 ft) higher, a target easily accessible to a mortar.)
Mortars are also highly effective when used from concealed positions, such as the natural escarpments on hillsides or from woods, especially if forward observers (FOs) are being employed in strategic positions to direct fire, an arrangement where the mortar is in relatively close proximity both to its FO and its target, allowing for fire to be quickly and accurately delivered to lethal effect. Mortars suffer from instability when used on snow or soft ground, because the recoil pushes them into the ground or snow unevenly. A Raschen bag addresses this problem.
Fin-stabilised mortar bombs do not have to withstand the rotational forces placed upon them by rifling or greater pressures, and can therefore carry a higher payload in a thinner skin than rifled artillery ammunition. Due to the difference in available volume, a smooth-bore mortar of a given diameter will have a greater explosive yield than a similarly sized artillery shell of a gun or howitzer. For example, a 120 mm mortar bomb has approximately the same explosive capability as a 155 mm artillery shell. Also, fin-stabilised munitions fired from a smooth-bore, which do not rely on the spin imparted by a rifled bore for greater accuracy, do not have the drawback of veering in the direction of the spin.
From the 17th to the mid 20th century, very heavy, relatively immobile siege mortars were used, of up to one metre calibre, often made of cast iron and with an outside barrel diameter many times that of the bore diameter. An early example was Roaring Meg, with a 15.5-inch (390 mm) barrel diameter and firing a 220 lb (100 kg) hollow ball filled with gunpowder and used during The English Civil War in 1646.
The largest mortars ever developed were the Belgian "Monster Mortar" (24 inches; 610 mm; developed by Henri-Joseph Paixhans in 1832), Mallet's Mortar (36 inches; 914.4 mm; developed by Robert Mallet in 1857), and the "Little David" (36 inches; 914.4 mm; developed in the United States for use in World War II). Although the latter two had a caliber of 36 inches, only the "Monster Mortar" was used in combat (at the Battle of Antwerp in 1832). The World War II German Karl-Gerät was a 60 cm (23.6 inch) mortar and the largest to see combat in modern warfare.
World War II US Army propaganda movie footage of the 914 mm "Little David" mortar
- Carcass (projectile), used in mortars before the modern age
- Chemical mortar battalion
- Eprouvette, a mortar used to test the strength of gunpowder.
- List of heavy mortars
- List of infantry mortars
- Livens Projector
- Military technology and equipment
- "Light Polish LM-60 Mortars". Defence 24. 29 June 2017.
- Gábor Ágoston (2005). Guns for the Sultan: Military Power and the Weapons Industry in the Ottoman Empire. Cambridge University Press. p. 68. ISBN 978-0-521-84313-3.
- Franz Babinger (1992). Mehmed the Conqueror and His Time. Princeton University Press. p. 140. ISBN 978-0-691-01078-6.
- Siege Weapons of the Far East (2): AD 960–1644 By Stephen Turnbull pg. 13
- "Toys". Culturecontent.com. Retrieved 19 November 2017.
- "대완구". Data.kdata.kr. Retrieved 19 November 2017.
- Chisholm, Hugh, ed. (1911). Encyclopædia Britannica. 8 (11th ed.). Cambridge University Press. p. 40. .
- Personal Memoirs of Ulysses S Grant, by Sam Grant, Kindle location 12783,
- naval-military-press.com[dead link]
- "Archived copy". Archived from the original on 2015-01-15. Retrieved 2014-07-17.CS1 maint: Archived copy as title (link)
- War Dept. Technical Manual TM9-2005, Volume 3, Ordnance Materiel – General, Page 17, December 1942
- Chris Bishop (2002). The Encyclopedia of Weapons of World War II. Sterling Publishing Company. p. 202. ISBN 978-1-58663-762-0.
- "Brandt mle 27 (Mortier Brandt de 81 mm modele 27) Infantry Mortar". Militaryfactory.com. Retrieved 19 November 2017.
- John Norris (2002). Infantry Mortars of World War II. Osprey Publishing. pp. 42–43. ISBN 978-1-84176-414-6.
- "Tank Hurls Flying Dust Bins and Lays Tracks". Popular Mechanics, December 1944, p. 7.
- Oliver Holmes (December 12, 2014). "Syrian rebel 'hell cannons' kill 300 civilians: monitoring group". Reuters. Yahoo! News. Retrieved December 13, 2014.
- Slough observer:Suspected Second World War mortar exploded in Windsor today, 3 October 2014. Example of use of the word "mortar" for a mortar bomb
- Hogg, Ian V.: The Illustrated Encyclopedia of Ammunition, p. 126
- "Alliant Techsystems Takes Army Mortar Contract (Again)". defenseindustrydaily.com.
- "Northrop Grumman Corporation". Northrop Grumman.
- Picatinny fields first precision-guided mortars to troops in Afghanistan - Army.mil, 29 March 2011
- "XM395: 120 mm Precision Mortar" (PDF). ATK Advanced Weapon. ATK. Retrieved 21 February 2012.
- "GMM 120 - 120 mm Guided Mortar Munition". Israel Military Industries. Retrieved 6 April 2014.
- "Israeli army tests GPS-guided mortar shell". i24news. Archived from the original on 2014-04-07. Retrieved 6 April 2014.
- "Largest Mortar". Guinness World Records. Archived from the original on 2006-02-10. Retrieved 2006-04-04.
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- "Field Manual 3-22.90 – Mortars" (PDF). Department of the Army. December 2007. Archived from the original (PDF) on 17 February 2013. Retrieved 7 January 2013.
- "Field Manual 3-22.91 – Mortar Fire Direction Procedures" (PDF). Department of the Army. 17 July 2008. Archived from the original (PDF) on 17 February 2013. Retrieved 7 January 2013.
- "Field Manual 23-91 – Mortar Gunnery" (PDF). Department of the Army. 1 March 2000. Retrieved 7 January 2013.
- Mallet's Mortar, the largest British mortar ever made.
- Defense Update: Modern Mobile 120 mm Mortars
- Defense Update: Advanced Mortar Munitions
- How does a Mortar work? - Visualization (Video)
- Mortars during World War I
- The Karl Morser, WW II-era German 60 cm self-propelled mortar.
- Video (streaming wmv)
- International Defense Supplier, a seller of mortars