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Use forms of explosives

In 1962, the first method for welding (qv) metals ia spots along a linear path by explosive detonation was patented (8). This method is not, however, used iadustriaHy. In 1963, a theory that explained how and why cladding occurs was pubHshed (9). Research efforts resulted ia process patents which standardized iadustrial explosion cladding. Several of the patents describe the use of variables iavolved ia parallel cladding which is the most popular form of explosion cladding (10—13). Several excellent reviews on metal cladding have been pubHshed (14—16). [Pg.143]

The color requirement is intended to cover the unavoidable presence of a small amt of the red form of Explosive D in admlxt with the yel form. The requirement with respect to irritant contaminarit -represents a control of the purity of PA used in manuf when this is made by the dinitrochlorobenzene process. The chloroform soluble impurities requirement also represents a control of the nature of impurities present in PA manufd by a process other than the nitration of phenol ... [Pg.755]

Pentaerythritol tetranitrate (PETN) is a colorless crystalline solid that is very sensitive to initiation by a primary explosive. It is a powerful secondary explosive that has a great shattering effect. It is used in commercial blasting caps, detonation cords, and boosters. PETN is not used in its pure form because it is too sensitive to friction and impact. It is usually mixed with plasticized nitrocellulose or with synthetic rubbers to form PBXs. The most common form of explosive composition containing PETN is Pentolite, a mixture of 20 to 50% PETN and TNT. PETN can be incorporated into gelatinous industrial explosives. The military has in most cases replaced PETN with RDX because RDX is more thermally stable and has a longer shelf life. PETN is insoluble in water, sparingly soluble in alcohol, ether, and benzene, and soluble in acetone and methyl acetate. [Pg.55]

In the most widely-used form of DCIMS, applied in explosives, drugs, and chemical warfare agent screening, the most common way to produce ions in atmospheric pressure is using a Ni source, which effects ionization of the analyte through a series of ion/molecule reactions. These ions are then injected via an electric potential) through a drift region, where separation takes place, and they are detected subsequently by an ion collector (usually a Faraday plate) [20]. [Pg.207]

MHI) various industries. Hazardous materials may be in the form of explosives, flammable and combustible substances, poisons, and radioactive materials [5]. MHI is an index used by the State of California. It is the material vapor pressure at 25°C divided by the level of concern, which can be defined on the basis of toxicity, fire explosion, etc. [3,6]. [Pg.96]

Since ammonia is a fertilizer, the Haber process cracks open nitrogen for plants, supplying them with an easy-to-use form of this important CHON element. This iron-based chemistry provided the equivalent of plowshares. Then it provided the equivalent of swords. Ammonia is easily reacted into energy-laden nitrates for explosives... [Pg.167]

In the reduction mode, electrochemical detectors can be used for detecting quinones, nitro compounds and consequently for the analysis of various forms of explosives (37). With the use of reagents containing aromatic nitro groups, derivatives of amines, ketones, and acids can also be detected by electrochemical detection. [Pg.122]

Carbon disulphide should never be used if any alternative solvent is available, as it has a dangerously low flash-point, and its vapours form exceedingly explosive mixtures with air. Ether as a solvent for recrystallisation is much safer than carbon disulphide, but again should be avoided whenever possible, partly on account of the danger of fires, and partly because the filtered solution tends to creep up the walls of the containing vessel and there deposit solid matter by complete evaporation instead of preferential crystallisation. [Pg.15]

Ammonia from coal gasification has been used for fertilizer production at Sasol since the beginning of operations in 1955. In 1964 a dedicated coal-based ammonia synthesis plant was brought on stream. This plant has now been deactivated, and is being replaced with a new faciUty with three times the production capacity. Nitric acid is produced by oxidation and is converted with additional ammonia into ammonium nitrate fertilizers. The products are marketed either as a Hquid or in a soHd form known as Limestone Ammonium Nitrate. Also, two types of explosives are produced from ammonium nitrate. The first is a mixture of fuel oil and porous ammonium nitrate granules. The second type is produced by emulsifying small droplets of ammonium nitrate solution in oil. [Pg.168]

Manufacture and Economics. Nitrogen tritiuoride can be formed from a wide variety of chemical reactions. Only two processes have been technically and economically feasible for large-scale production the electrolysis of molten ammonium acid fluoride and the direct fluorination of the ammonia in the presence of molten ammonium fluoride. In the electrolytic process, NF is produced at the anode and H2 is produced at the cathode. In a divided cell of 4 kA having nickel anodes, extensive dilution of the gas streams with N2 was used to prevent explosive reactions between NF and H2 (17). [Pg.217]

Heterocyclics. One of the most characteristic and useful properties of hydrazine and its derivatives is the ability to form heterocycHc compounds. Numerous pharmaceuticals, pesticides, explosives, and dyes are based on these rings. A review of the appHcation of hydrazine in the synthesis of heterocychcs is available (91). For further information in the field of heterocycHc chemistry, see the General References. [Pg.281]

Explosives. Mercury, in the form of organic complexes, eg, mercury fulminate [628-86-4] has had long usage in explosives (see Explosives and propellants). In the United States all mercury for use in explosives is diverted to military uses. An explosive based on mercuric 5-nitrotetra2ole [60345-95-1] has been developed, but its use is on a small scale and in research and development only (3). [Pg.110]

Vessel heads can be made from explosion-bonded clads, either by conventional cold- or by hot-forming techniques. The latter involves thermal exposure and is equivalent in effect to a heat treatment. The backing metal properties, bond continuity, and bond strength are guaranteed to the same specifications as the composite from which the head is formed. AppHcations such as chemical-process vessels and transition joints represent approximately 90% of the industrial use of explosion cladding. [Pg.150]

See other pages where Use forms of explosives is mentioned: [Pg.51]    [Pg.53]    [Pg.57]    [Pg.61]    [Pg.461]    [Pg.472]    [Pg.51]    [Pg.53]    [Pg.57]    [Pg.61]    [Pg.461]    [Pg.472]    [Pg.24]    [Pg.41]    [Pg.1765]    [Pg.29]    [Pg.312]    [Pg.251]    [Pg.44]    [Pg.47]    [Pg.21]    [Pg.165]    [Pg.165]    [Pg.168]    [Pg.188]    [Pg.192]    [Pg.157]    [Pg.56]    [Pg.213]    [Pg.6]    [Pg.225]    [Pg.503]    [Pg.3]    [Pg.6]    [Pg.10]    [Pg.19]    [Pg.32]    [Pg.480]    [Pg.480]    [Pg.12]    [Pg.476]   
See also in sourсe #XX -- [ Pg.51 , Pg.52 , Pg.53 , Pg.54 , Pg.55 , Pg.56 , Pg.57 , Pg.58 , Pg.59 , Pg.60 , Pg.61 , Pg.62 , Pg.63 , Pg.64 , Pg.65 ]



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Explosive forming

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