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Warianty tytułu
Języki publikacji
Abstrakty
In the paper the linear form of burning rate law r=r1źp, describing changes (in proportion to pressure p) in burning rate of propellants is reviewed. The linear form is one of many (but very popular) forms of burning rate law predicted to analysis and computer simulations of propellant gun systems operating and design process of gun. Coeffcient r1 of the linear form is usually calculated on the basis of average dimensions of grain (layer of burnt propellant) and integrated experimental pressure-time curve. Recorded picture of pressure of propellant gas mixture is an effect of closed vessel test. It is assumed that value of coeffcient r1 is constant (for given type of propellant) regardless of value of propellant gas pressure. Different fne-grained propellants (single-base and double-base) were fred in closed vessel tests to determine their burning rate behaviour. The variations in mass of igniter pad (black powder) at the same value of loading density were used. The results of experimental tests and calculations presented in this paper show signifcant infuence of the used type of ignition system (mass of black powder) on burning rate (coeffcient r1) of propellant. The differences in calculations of propellant burning rate and computer simulations of pressure-travel history inside the barrel of a propellant gun system indicate that there are limitations to the validity of the linear form approach particularly for fne-grained propellants.
Rocznik
Tom
Strony
45--61
Opis fizyczny
Bibliogr. 12 poz.
Twórcy
autor
- Institute of Armament Technology, Faculty of Mechatronics Military University of Technology 2 Kaliskiego St., 00-908 Warsaw, Poland, Zbigniew.Leciejewski@wat.edu.pl
Bibliografia
- [1] Krier H., Summerfield M., Interior Ballistic of Guns, Volume 66 Progress In Astronautics and Aeronautics, Published by the American Institute of Aeronautics and Astronautics, New York 1979.
- [2] Moss G.M., Leeming D.W., Farrer C.L., Military Ballistics – A Basic Manual, Royal Military College of Science, Shrivenham, Ed. Brassey’s (UK) Ltd, 1995.
- [3] STANAG 4367 LAND (Edition 2) – Thermodynamic Interior Ballistic Model with Global Parameters, Military Agency for Standardization, Brussels 2000.
- [4] Kadanka V., Internal Ballistics of Gun Systems (in Czech), Ed. Czech Ministry of Defence, Praha 1985.
- [5] Sieriebriakov M., Internal Ballistics (in Russian), Ed. OBORONGIZ, Moscow 1949.
- [6] Torecki S., Internal Ballistics, (in Polish), Ed. Military University of Technology, Warsaw 1980.
- [7] Vasile T., Internal Ballistics of Gun Systems, (in Romanian), Ed. Technical Military Academy, Bucharest 1993.
- [8] Krier H., Adams M.J., An Introduction to Gun Interior Ballistics and a Simplified Ballistic Code, Interior Ballistic of Guns, Volume 66 Progress in Astronautics and Aeronautics, The American Institute of Aeronautics and Astronautics, New York 1979, pp. 1-36.
- [9] STANAG 4115 LAND (Edition 2) – Definition and Determination of Ballistic Properties of Gun Propellants, Military Agency for Standardization, Brussels, 1997.
- [10] Leciejewski Z., Closed Vessel Tests: Part II - Temperature Factor Determination of Fine-Grained Propellant, Proc. VIth International Armament Conference SAAT’2006, Waplewo, Poland, 2006, pp. 632-637.
- [11] Leciejewski Z., Singularities of Burning Rate Determination of Fine-Grained Propellants, Proc. 23rd International Symposium on Ballistics, Volume I, Tarragona, Spain, 16-20 April, 2007, pp. 369-376.
- [12] Jeunieau L., Lefebvre M.H., Papy A., Pirlot M.C., Guillaume P., Reynaud Ch., Closed Vessel Test: Influence of The Ignition Method on The Combustion Rate, Proc. 33rd International Annual Confernce of ICT, June 25, Karlsruhe, Germany, 2002.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BAT1-0034-0043