Post by bazooka on Aug 18, 2019 21:17:36 GMT
Military explosives
Military requirements for high explosives differ in many respects from those for commercial users. Military explosives must have insensitivity to shock and friction and must be unlikely to detonate from small-arms fire and yet have excellent shattering power. They must have the ability to withstand long periods of adverse storage without deterioration and must be able to be fired in projectiles or dropped in aerial time bombs without premature explosion. Some types are required to possess almost unlimited water resistance. Many types must have complex fuses for detonation.
TNT
Military requirements for high explosives differ in many respects from those for commercial users. Military explosives must have insensitivity to shock and friction and must be unlikely to detonate from small-arms fire and yet have excellent shattering power. They must have the ability to withstand long periods of adverse storage without deterioration and must be able to be fired in projectiles or dropped in aerial time bombs without premature explosion. Some types are required to possess almost unlimited water resistance. Many types must have complex fuses for detonation.
TNT
Trinitrotoluene (TNT) is the most useful military high explosive. Although it had been known for many years and was used extensively in the dye industry, it was not employed as an explosive until 1904. It is an excellent military explosive in itself, but its most valuable property is that it can be safely melted and cast either alone or as a slurry with other explosives. This is because there is a wide spread between its melting point and its decomposition temperature.
It has two shortcomings: first, it is extremely insensitive in the cast form, and second, it is difficult to cast without air holes. The first problem can be overcome by drilling a hole, about 2.5 centimetres (1 inch) in diameter, the length of the charge in the shell and filling it with trinitrophenylmethylnitramine (tetryl); the second, by using a mixture of 40 percent trinitroxylene (TNX) and 60 percent TNT. This mixture not only casts perfectly but can be detonated with a smaller tetryl booster. There is no indication that any TNX was used in World War II; it is believed to have been replaced by PETN and RDX.
Picric acid and ammonium picrate
Picric acid was used as a shell explosive in Europe during the 1880s and carried through World War I on a large scale. Quantities of it were made in the United States, but the army and navy used mainly TNT.
Picric acid and ammonium picrate
Picric acid was used as a shell explosive in Europe during the 1880s and carried through World War I on a large scale. Quantities of it were made in the United States, but the army and navy used mainly TNT.
Ammonium picrate (Explosive D) has exceptional value as a charge for armour-piercing projectiles. Loaded in a shell with a suitably insensitive primer, it can be fired through 30 centimetres (12 inches) of armour plate and made to detonate on the far side. These armour-piercing shells were used in both World Wars.
Early in World War I it was found that mixtures of molten TNT and ammonium nitrate were almost as effective for shell loadings as pure TNT. The mixtures most commonly used were 80–20 and 50–50 AN and TNT, known as amatol. Their principal advantages were that they made the supply of TNT go further and were considerably cheaper. In World War II the amatols were used in aerial bombs as well as artillery shells.
To conserve TNT in World War I, a nitrostarch-base composition was also developed for loading hand grenades and trench-mortar shells.
Several explosives, although previously known, only came into use during World War II. The most important of these were RDX, PETN, and ethylenediaminedinitrate (EDNA), all of which were cast with varying amounts of TNT, usually 40 to 50 percent, and used where the highest possible shattering power was desired. For example, cast 60–40 RDX-TNT, called cyclotol, develops a detonation pressure of about 270,000 atmospheres (4,000,000 pounds per square inch). Corresponding mixtures of PETN and TNT have almost as much shattering effect. The EDNA mixtures, or ednatol, were used only to a limited extent and for special purposes. Probably the most powerful of all nonatomic military explosives are the cast mixtures containing aluminum. The torpedo warhead Torpex, for example, is a cast mixture of RDX, TNT, and aluminum.
A series of plastic demolition explosives with great shattering power, designated Composition C-1 to Composition C-4, has had considerable publicity. These contain about 80 percent RDX combined with a mixture of various oils, waxes, and plasticizers. The only significant difference is in the temperature range through which they remain useful. C-3 stays plastic to −29° C (−20° F) and does not exude oil below 49° C (120° F). In contrast, C-4 remains plastic to −57° C (−70° F) and does not leak below 77° C (170° F).
Shaped charges
The shaped charge, principally the hand-fired rocket, is another highly publicized product introduced during World War II. A shaped charge normally consists of a cone made of metal or glass surrounded by a high-strength, high-density explosive and means to obtain the proper standoff, or distance to the target.
When the explosive is detonated, the cone is collapsed and vaporized, forming a small, high-temperature jet containing particles of liner material moving at 3,050 to 9,100 metres (10,000 to 30,000 feet) per second. This strikes the target with such heat and force that the target simply flows radially from the point of impact leaving a deep, nearly round hole. As spectacular as the results are, only about 15 percent of the explosive energy is focused.
Early in World War I it was found that mixtures of molten TNT and ammonium nitrate were almost as effective for shell loadings as pure TNT. The mixtures most commonly used were 80–20 and 50–50 AN and TNT, known as amatol. Their principal advantages were that they made the supply of TNT go further and were considerably cheaper. In World War II the amatols were used in aerial bombs as well as artillery shells.
To conserve TNT in World War I, a nitrostarch-base composition was also developed for loading hand grenades and trench-mortar shells.
Several explosives, although previously known, only came into use during World War II. The most important of these were RDX, PETN, and ethylenediaminedinitrate (EDNA), all of which were cast with varying amounts of TNT, usually 40 to 50 percent, and used where the highest possible shattering power was desired. For example, cast 60–40 RDX-TNT, called cyclotol, develops a detonation pressure of about 270,000 atmospheres (4,000,000 pounds per square inch). Corresponding mixtures of PETN and TNT have almost as much shattering effect. The EDNA mixtures, or ednatol, were used only to a limited extent and for special purposes. Probably the most powerful of all nonatomic military explosives are the cast mixtures containing aluminum. The torpedo warhead Torpex, for example, is a cast mixture of RDX, TNT, and aluminum.
A series of plastic demolition explosives with great shattering power, designated Composition C-1 to Composition C-4, has had considerable publicity. These contain about 80 percent RDX combined with a mixture of various oils, waxes, and plasticizers. The only significant difference is in the temperature range through which they remain useful. C-3 stays plastic to −29° C (−20° F) and does not exude oil below 49° C (120° F). In contrast, C-4 remains plastic to −57° C (−70° F) and does not leak below 77° C (170° F).
Shaped charges
The shaped charge, principally the hand-fired rocket, is another highly publicized product introduced during World War II. A shaped charge normally consists of a cone made of metal or glass surrounded by a high-strength, high-density explosive and means to obtain the proper standoff, or distance to the target.
When the explosive is detonated, the cone is collapsed and vaporized, forming a small, high-temperature jet containing particles of liner material moving at 3,050 to 9,100 metres (10,000 to 30,000 feet) per second. This strikes the target with such heat and force that the target simply flows radially from the point of impact leaving a deep, nearly round hole. As spectacular as the results are, only about 15 percent of the explosive energy is focused.