Life Cicle Inventory for Lead Azide Manufacture

Galante, Erick; Haddad, Assed; Boer, Dieter; Bonifácio, Danielle

doi:10.5028/jatm.v6i1.289

Cited by 4 publications

(3 citation statements)

References 15 publications

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“…The SPLA makes up a large portion of the current U.S. military stockpile of lead azide, which has existed since the 1960s. [11][12][13][14][15]).…”

Section: Dextrinatedmentioning

confidence: 99%

The Effect of the Reaction pH on Properties of Lead(II) Azide

Biegańska

2021

Materials

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Lead(II) azide is an initiating explosive; even a small amount can trigger an explosion caused by simple external stimuli, such as sparks, flames, friction or pinpricks, and is able to initiate the explosive reaction of rock-crushing explosives. Due to the fact that this initiating explosive triggers further reactions, the effect of priming detonators depends on the properties of its material. Its sensitivity is associated with the size of its crystals. For instance, it is used for mining detonators in the form of fine crystals. The quality of the crystals is also correlated to the safety of the production process, i.e., the crystals should be round-shaped rather than needle-like since breaking it would inevitably trigger an explosion. The process of lead(II) azide production on an industrial scale is based on the reaction of lead(II) nitrate with sodium azide with the presence of dextrin, which determines the desired shape of the crystals. The reaction pH affects the number of sediment particles formed in a periodical reactor. Changing the pH from 6.5 to 7.5 leads to the rapid growth of crystal particles.

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“…The SPLA makes up a large portion of the current U.S. military stockpile of lead azide, which has existed since the 1960s. [11][12][13][14][15]).…”

Section: Dextrinatedmentioning

confidence: 99%

The Effect of the Reaction pH on Properties of Lead(II) Azide

Biegańska

2021

Materials

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“…Lead azide and styphnate are very well established in the explosives industry, making the introduction of any new replacement materials difficult [4,[57][58][59]. Some properties of lead azide are detailed in Table 1.…”

Section: Green Energetic Materialsmentioning

confidence: 99%

Towards Safer Primers: A Review

Lundgaard

Cahill

et al. 2019

Technologies

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Primers are used to reliably initiate a secondary explosive in a wide range of industrial and defence applications. However, established primer technologies pose both direct and indirect risks to health and safety. This review analyses a new generation of primer materials and ignition control mechanisms that have been developed to address these risks in firearms. Electrically or optically initiated metal, oxide and semiconductor-based devices show promise as alternatives for heavy metal percussive primers. The prospects for wider use of low-cost, safe, reliable and non-toxic primers are discussed in view of these developments.

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“…Classifying explosives according to their detonation velocity is far common. RDX is classified as a high explosive (also known as "secondary explosive") due to its output of energy during detonation, when compared to a low explosive (with a detonation velocity in the same magnitude of the speed of sound) (Akhavan, 2011;Cooper, 1996;Galante et al, 2014;Meyer et al , 2007;Urbanski, 1984).…”

Section: Case Of Studymentioning

confidence: 99%

Risk Assessment for Hexamine Nitration into RDX

Galante

Costa

Haddad

et al. 2014

J.Aerosp. Technol. Manag.

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Explosives are widely used in extraction of ores, melts and fuels and in the safe and economical demolition of structures. These applications demonstrate the value of explosives to society and the reason why they are manufactured worldwide despite the hazard of their preparation. Hence, this paper focuses on the manufactory of the military explosive Hexogen (also known as RDX). The characteristics of the process are described by the analysis of a specify manufactory plant. The chosen analysis tool is the Hazard and Operability Study -HazOp. Historically, this methodology has been applied at chemical industries and is used in industrial process operability analysis. This study analyses seven critical nodes in the RDX manufacturing process, identifies several deviations, and causes and consequences. From these results, improvements in the units are suggested and actual conditions discussed. It is important to remark that this work is an initial approach to analysis of the manufacturing process of RDX using the HazOp methodology.

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Life Cicle Inventory for Lead Azide Manufacture

Cited by 4 publications

References 15 publications

The Effect of the Reaction pH on Properties of Lead(II) Azide

The Effect of the Reaction pH on Properties of Lead(II) Azide

Towards Safer Primers: A Review

Risk Assessment for Hexamine Nitration into RDX

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