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Modification of the Detonation Parameters of Mining Explosives Containing Hydrogen Peroxide and Aluminium Powder

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Języki publikacji
EN
Abstrakty
EN
Presently, due to rising environmental consciousness, numerous actions are being taken to prevent devastation of the natural environment. If explosive mixtures are manufactured in an insufficiently controlled manner, they contain too much ammonium nitrate and generate nitrogen oxides (NOx), which are both harmful for living organism and responsible for negative weather phenomena. However, the products from decomposition of hydrogen peroxide are only oxygen and hydrogen, which are both environmentally friendly. This paper presents the results of research on the impact of two types of aluminium powder on the detonation parameters of mining explosives containing hydrogen peroxide 60% as an oxidiser. The detonation velocities were measured by means of short circuit sensors. Direct measurement of the blast wave overpressure was performed with piezoelectric sensors and the positive phase impulse was analyzed. Measurement of the explosive strength was made by the ballistic pendulum method for 10 g samples. The results of these experiments showed that the addition of both types of aluminium, as well as their content in the explosive mixture, have a significant impact on all of the measured parameters.
Rocznik
Strony
477--491
Opis fizyczny
Bibliogr. 18 poz., rys., tab.
Twórcy
  • Military University of Technology, 2 gen. S. Kaliskiego Street, 00-908 Warsaw 46, Poland
  • Łukasiewicz Research Network – Institute of Industrial Organic Chemistry, 6 Annopol Street, 03-236 Warsaw, Poland
  • Łukasiewicz Research Network – Institute of Industrial Organic Chemistry, 6 Annopol Street, 03-236 Warsaw, Poland
  • Military University of Technology, 2 gen. S. Kaliskiego Street, 00-908 Warsaw 46, Poland
Bibliografia
  • [1] Parmeter, J.E. Historical Survey: German Research on Hydrogen Peroxide/Alcohol Explosives, Sandia National Laboratories Report, US Department of Energy, 2015.
  • [2] Shanley, E.S.; Kaufmann, O.H. Peroxide-Glycerol Explosive. Patent US 2452074, 1948.
  • [3] Bouillet, E.; Colery, J.C.; Declerck, C.; Ledoux, P. Process for the Manufacture of Explosive Cartridges, and Explosives Cartridges Obtained Using the Said Process. Patent US 4942800, 1990.
  • [4] Sheffield, S.A.; Dattelbaum, D.M.; Stahl, D.B.; Gibson, L.L.; Bartram, B.D.; Engelke, R. Shock Initiation and Detonation Study on High Concentration H2O2/H2O Solutions Using In-Situ Magnetic Gauges. Proc. 14th Int. Detonation Symp. Coeur d’Alene, ID, US, 2010, 601-610.
  • [5] Fullelove, I.; Araos, M.; Onederra, I. Detonation Performance of Novel Hydrogen Peroxide and Nitrate Based Hybrid Explosives. Proc. 9th EFEE World Conf. on Explosives and Blasting, Stockholm, 2017, 197-208.
  • [6] Onederra, I.; Araos, M. Preliminary Quantification of the In Situ Performance of a Novel Hydrogen Peroxide Based Explosive. Min. Technol. 2017, 113-122.
  • [7] Araos, M.; Onederra, I. Detonation Characteristics of a NOx-free Mining Explosive Based on a Sensitised Mixtures of Low Concentration Hydrogen Peroxide and Fuel. Cent Eur. J. Energ. Mater. 2017, 14(4): 759-774.
  • [8] Araos, M.; Onederra, I. Development of a Novel Mining Explosive Formulation to Eliminate Nitrogen Oxide Fumes. Maney Pub. on Behalf of the Institute of Materials. 2014, 16-23.
  • [9] Araos, M.; Onederra, I. Detonation and Breakage Performance of a Hydrogen Peroxide Based Explosive Formulation. A Component of ACARP Project C23029, presentation, 2015.
  • [10] Araos, M.; Onederra, I. Detonation Characteristics of Alternative Mining Explosives based on Hydrogen Peroxide as the Oxidising Agent. Proc. 7th World Conf. on Explosives and Blasting, Moscow, Russia, 2013, 182-186.
  • [11] Nikolczuk, K.; Wilk, Z.; Florczak, B.; Maranda, A. Explosives Based on Hydrogen Peroxide. Przem. Chem. 2017, 96(11): 2305-2311.
  • [12] Nikolczuk, K.; Jóźwik, P.; Koślik, P.; Wilk, Z.; Florczak, B.; Maranda, A. „Green explosives” – Alternative Mining Explosives Based on Hydrogen Peroxide. Proc. 30th Int. Conf. Blasting Techniques 2018, Stara Lesna, Slovak Republic, 2018, 136-148.
  • [13] Hydrogen Peroxide 60%. (in Polish) Envolab, Quality specification from 2013, https://envolab.pl/dokumenty/Nadtlenek-wodoru-60-specyfikacja-jakosciowa.pdf [retrieved July 30, 2020].
  • [14] Material Safety Data Sheet: PULAN®. (in Polish) Grupa Azoty Group Puławy S.A., Version 7.1. from 2017, https://flora-praszka.pl/nawozy-azotowe/pulan.pdf [retrieved January 10, 2019].
  • [15] Maranda, A.; Czerwińska, A.; Paszula, J.M.; Jóźwik, P. Modification of Detonation Parameters of Emulsion Explosives by the Addition of an Oxidizer-Fuel System. (in Polish) Przem. Chem. 2020, 99(1): 40-45.
  • [16] Trzciński, W.A.; Cudziło, S.; Paszula, J.; Callaway, J. Study of the Effect of Additive Particle Size on non-Ideal Explosive Performance. Propellants Explos. Pyrotech. 2008, 33(3): 227-235.
  • [17] Manner, V.W.; Pemberton, S.J.; Gunderson, J.A.; Herrera, T.J.; Lloyd, J.M.; Salazar, P.J.; Rae, P.J.; Tappan, B.C. The Role of Aluminum in the Detonation and post-Detonation Expansion of Selected Cast HMX-based Explosives. Propellants Explos. Pyrotech. 2012, 37(2): 198-206.
  • [18] Cooper, P.W. Explosives Engineering. Wiley-VCH, New York, 1996.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-2b809a74-ce9e-4393-89de-c50f4d480b99
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