DOCSLIB.ORG

™2-F - CH^-Cfh Hydrolysis OH C=O CH„

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
™2-F - CH^-Cfh Hydrolysis OH C=O CH„ CHAPTER 2 SURVEY OF LITERATURE ON POLYVINYL NITRATE Polyvinyl nitrate, (C„H 0 N) , is the nitrate ester of polyvinyl alcohol (PVA), which is obtained by hydrolysis of polyvinyl acetate (PVAc). The reaction scheme may be represented as follows: ™2-f - CH^-CfH Hydrolysis OH c=o CH„ Polyvinyl acetate Polyvinyl alcohol Nitration CH^-CfH - 0N0„ Polyvinyl nitrate Polyvinyl nitrate (PVN) is one of the few known polymeric explosives, and bears a formal resemblance to the better known polymeric nitrate explosive called cellulose nitrate or nitrocellulose (NC). Polyvinyl nitrate (PVN) was first prepared in Germany in 1929 by the nitration of polyvinyl alcohol (PVA) with a mixture of 1 nitric acid and sulphuric acid . The product contained only 10% N, against a theoretical value of 15.73°/ N. It detonated when ignited. The work of several investigators on the preparation and properties of PVN has been reported in open as well as patent literatur1,*. ^ e 2-21 A considerable portion of the work has originated in Germany and France. In general, polyvinyl alcohol was used as the starting material, but the composition and experimental conditions were varied with a view to obtaining a better yield and quality of PVN. For example, the methods which were used by investigators for the preparation of PVN Eire summarized below. 30 mesh pulverized (10% moistured) polyvinyl alcohol was slowly added to cold (-8°C) nitric acid with constant stirring, and 2 the temperature was maintained for 3 hrs . The slurry thus obtained was poured into axi equal volume of water with vigorous stirring. After filtering off, the white ppt was washed with water and kept for further 12 hrs in pure water. It was then treated with 95% ethyl alcohol followed by 12% sodium bicarbonate solution. The product was dried in vacuum. It contained 96% PVN with 14.48% N (lower viscosity sample) ajid 13.43% N (higher viscocity sample). The product was soluble in acetone, nitroglycerine (NG), diethylene glycoldinitrate (DEGDN), and insoluble in 95% alcohol. Some workers recommended a classical nitration method (due to simultaneous hydrolysis problem), viz. nitration of polyvinyl alcohol either with a mixture of nitric acid and acetic anhydride or with a solution of nitric acid in carbon tetrachloride, where-by a higher nitrated product, softening at a temperature of 40 - 50°C, 3 was obtained . Nitric acid was directly added to polyvinyl alcohol in inert atmosphere (N or CO ). A product with as high as 15% N 4 5 content was obtained . It has been reported that as polyvinyl alcohol was gradually added to concentrated (>95%) nitric acid, the desired ratio of acid to polyvinyl alcohol was more than 20: 1, otherwise the viscosity of the solution in nitric acid would be 12 very high, maicing it difficult to have an efficient mixing. The temperature was maintained at 0 C for 15 min (for cooling) ajid 15 min for addition of polyvinyl alcohol to nitric acid, 30 min for nitration and 15 min ai'ter nitration at 20°C. The yield of product was 90% with 14.8% N (the degree of nitration was 88.7%). This 5 5 method was not economical . The same investigator has also reported that the nitration of polyvinyl alcohol was best when the concentration of H-SO in the mixed acid was 10-30%. The viscosity of the product, measured by Ostwald viscometer, in 0.5% acetone solution, was found to be 0.45 cps. A 'reverse addition' procedure was followed by some workers for their preparation of PVN in which nitric acid was added to polyvinyl alcohol+acetic anhydride mixture in cold (-5°C) and the reaction temperature was maintained below 20 C. This procedure of adding nitric acid to PVA-slurry permitted greater control, flexibility, and safety. The white product obtained was purified by boiling in frequent change of water. The product was found to contain 14.86% nitrogen . The esterification of polyvinyl alcohol by nitric acid or nitrating mixture has been described in which the nitrogen content and Theological properties of PVN depend on the experimental conditions of manufacture and the degree of polymerization of the polyvinyl alcohol. The yellow white product was thermoplastic in nature with softening point of 30-45°C . A white powder of PVN was obtained with a high degree of nitration and its colour also varied g from white to buff depending on the method of preparation . The o 9 softening point of the product was 30-50 C. Other workers prepared PVN with nitrogen content ranging between 13-15% and found it to be unstable decomposing at room temperature. An extensive preparative method of PVN has been reported by investigators who claimed that 13 the product had a nitrogen content as high as 15.7%. A stabilized PVN has been prepared by some workers who reported that the nitration of polyvinyl alcohol by nitric acid was dependent on the temperature of the reacting mixture, stirring rate and quajitity of occluded acid. A process for preparation of stabilized PVN, having more than 15% N content, produced in the form of free flowing and non-caking 17 pxjwder from the crude product, has been described in a U.S patent . The product was soluble, in all proportions, in acetone, 17 nitrobenzene and liquid nitrate esters Tacticity of polyvinyl nitrate (PVN) depends on the configuration (orientation) of H-atoms and nitric ester (0N0„) groups in space, and, therefore, on the tacticity of polyvinyl alcohol used. The degree of stereoregularity also influences the crystallinity of the polymeric material. Hence, on the basis of spatial arrangement of H atoms and 0N0„ groups in PVN, it can be divided into the following types : (1) Atactic This has irregular or random stereochemical arrangement of hydrogen atoms and 0N0„ groups in the polymeric chain, eg:— H H H H H 0N0_ H 0N0„ I I I I I I ' I I ^ -C— C — C— C— C— C C — C H ONO^ H ONOg H H H H This caji be prepared by nitration of commercially available polyvinyl alcohol. (2) Syndiotactic This has a stereoregular arrangement of H atoms and ONO groups in the polymeric chain, but the alternate ONO groups occur 14 in mutually opposite orientation, as follows H H H 0N0„ H H H 0N0_ I I I 1^1 I I I ^ -c — c — c — c — c — c — c — c — H ONO^ H H H ONO H H (3) Isotactic This also has a stereoregular arrangement of H atoms ajid ONO groups in the polymeric chain, but all ONO^ groups occur on the same side as follows HHHHHHHH I I i I I I I I -c — c — c — c — c — c — c — c — I I I I I I I I H ONO^ H ONO^ H ONO H ONO The above two stereoregular types of PVN have been prepared by some workers using special methods and these are reported to be 18 19 generally superior to atactic PVN ' 20 Some workers followed a method involving nitration of polyvinyl acetate using epichlorhydrin as a crosslinking agent in their preparation of PVN. Determination of nitrogen content in PVN using different methods like Dumas', Kjeldahl's, Nitrometers, Titanium chloride and R in 11 SL'^ 1 Devarda's alloy etc has been reported ' ' . Modified Devarda's 11 method was also employed to determine the nitrogen content in PVN . Because of unreliable results from nitrometer or KJeldahl methods, these have been replaced by modified Dumas' method for estimation 21 of nitrogen content in PVN . Molecular weight of PVN has been 5 7 22 determined by several investigators ' ' using different methods. For exajnple, for PVN (15.15% N), the ultracentrifuge method was 5 - 7 used and Mn found to be 60,000 - 100,000 . Some workers reported 22 - Mw as 200,000 whereas some others reported Mw as 150,000-320,000 15 and Mn as 120,000-140,000. The infra-red (IR) spectrum of thin film of PVN (15.1% N) has 23 -1 been studied by investigators in the extended region of 70 cm to 3600 cm, and polarized infra-red measurements were made on oriented specimens in the range of 350 to 3600 cm . Films were prepared by casting from acetone solution. X-ray diffraction patterns indicated no crystallinity, which suggested atactic configuration and which was also concerned about the local configuration of the nitrate group, i.e. ONO in either rocking or bending mode. It was indicated that although the specimen was not in crystalline portion of the chains, it had a configuration not far from a zig-zag chains. The nature of plasticized PVN has been studied by pulsed 24 NMR spectroscopy . It indicated the presence of rigid and mobile 24 ptolymer phases in mixtures of PVN and dibutyl phthalate . Behaviour of nitrocellulose and polyvinyl nitrate (PVN) in solvents has also 25 been reported PVN is a highly energetic substance capable of detonation under suitable conditions. Explosive and energetic properties of PVN and PVN-containing formulations as well as their likely applications have been reported in literature ' . For 2 exajnple, the detonation of PVN was found to propagate at a rate similar to that of nitrocellulose (NC) of the same N content. The rate of detonation of PVN containing 13.4% N in 30 mm dia card­ board cartridge was found to vary with its density as follows :— Density, gm/cc Detonation Velocity, m/sec. 0.3 2030 0.6 3450-3520 1.0 4920-5020 1.4 6090 1.5 6560 16 2 Also, PVN was recommended for use in double base propellajits e.g. in combinations of NC + NG + PVN or NC + EGDN + PVN.
Load more

Recommended publications
  • PATENT OFFICE 2,18,48 PROCESS for PREPARNG POLYVNY NTRATE Lawton A
    Patented May 24, 1938 2,118,487 UNITED STATES PATENT OFFICE 2,18,48 PROCESS FOR PREPARNG POLYVNY NTRATE Lawton A. Burrows, Wenonah, and William F. Filbert, Woodbury, N. J. assignors to E. I. du Pont de Nemours & Company, Wilmington, Del, a corporation of Delaware . No Drawing. Application July 15, 1936, Seria No. 90,24 8 Claims. (C. 260-44) The present invention relates to a new and inert toward the material, for example carbon dr improved process for the nitration of polyvinyl oxide or nitrogen. A second method consists in alcohol and more particularly, to an improved immersing the polyvinyl alcohol beneath the Sur process which produces a product having a higher face of the nitric acid in such a manner that the 5 nitrogen content. nitric acid-wetted alcohol is only momentarily in 5 It is known that polyvinyl alcohol may be contact with the gaseous phase above the reaction nitrated with the usual mixed nitration acids. mixture. In order to accomplish this more read Thus, according to DRP 537,303, the nitration ily, instead of attempting to nitrate the polyvinyl may be effected by dissolving polyvinyl alcohol in alcohol in the finely powdered form in which it is O sulfuric acid, and adding the solution to a mix normally available we have discovered, that it is 10 ture of nitric and sulfuric acids. The patent desirable to grain the material. After graining, states that polyvinyl alcohol is not nitrated by the desired amount of the alcohol is more readily pure nitric acid but is oxidized thereby. It is immersed beneath the surface of concentrated generally known in the art that when polyvinyl nitric acid in such manner that no particle of 15 alcohol is added in the usual manner to concen the alcohol remains exposed to the air for any 15 trated nitric acid, the alcohol ignites and burns appreciable period after it comes into contact with a free flame, leaving a carbonaceous residue.
    [Show full text]
  • Prohibited and Restricted Chemical List
    School Emergency Response Plan and Management Guide Prohibited and Restricted Chemical List PROHIBITED AND RESTRICTED CHEMICAL LIST Introduction After incidents of laboratory chemical contamination at several schools, DCPS, The American Association for the Advancement of Science (AAAS) and DC Fire and Emergency Management Services developed an aggressive program for chemical control to eliminate student and staff exposure to potential hazardous chemicals. Based upon this program, all principals are required to conduct a complete yearly inventory of all chemicals located at each school building to identify for the removal and disposal of any prohibited/banned chemicals. Prohibited chemicals are those that pose an inherent, immediate, and potentially life- threatening risk, injury, or impairment due to toxicity or other chemical properties to students, staff, or other occupants of the school. These chemicals are prohibited from use and/or storage at the school, and the school is prohibited from purchasing or accepting donations of such chemicals. Restricted chemicals are chemicals that are restricted by use and/or quantities. If restricted chemicals are present at the school, each storage location must be addressed in the school's written emergency plan. Also, plan maps must clearly denote the storage locations of these chemicals. Restricted chemicals—demonstration use only are a subclass in the Restricted chemicals list that are limited to instructor demonstration. Students may not participate in handling or preparation of restricted chemicals as part of a demonstration. If Restricted chemicals—demonstration use only are present at the school, each storage location must be addressed in the school's written emergency plan. Section 7: Appendices – October 2009 37 School Emergency Response Plan and Management Guide Prohibited and Restricted Chemical List Following is a table of chemicals that are Prohibited—banned, Restricted—academic curriculum use, and Restricted—demonstration use only.
    [Show full text]
  • 9783527316564.Bindex.Pdf
    385 Index Index and Technical Dictionary with short information without text reference A acide picramique 253 acide picrique 254 A W 1-black blasting powder 35 acide styphnique 300 A W bridgewire detonator A (german. acide trinitrobenzoique 349 now absolete) 41 acquisition, handling and storing 136 A W composition A 62 Acremite 1 AA = antiaircraft A-IX-2 = RDX/alumi- Active Binder W Energetic Binder num/wax 73/23/4 116; 151; 205; 257; 258 abattage par chambre de mine = ADR 2, 70 coyote blasting 65 A.D.C. test = Adreer double cartridge Abbrand = combustion 60 (gap test) Abbrandgeschwindigkeit = burning ADN = Ammonium dinitramide 14; rate 45 324 abbrennen = to burn down 75 adiabatic 1 Abel’s equation 23 adobe charge = mud capping 2; 218 Abel test 1; 178 Aeroplex K = solid rocket propellant abkerben, abspalten W smooth blast- based on KCIO4 and resin ing 64 Aeroplex N = solid rocket propellant Ablonite = french commercial explo- based on NH4CIO4 and resin sive Aerozin = hydrazine/dimethylhydra- abschlagen einer Sprengladung zine 50/50 2 W cut off 67 A-E = single base powder Absperrzone = blast area 36 AGARD 2 Abstand; Sicherheitsabstand = safety Airbag 2; 146 distance 136 air blast 8 Abstandsberechnung W scaled airloader 8 distance 276 Akardit I, II, III 9; 10; 161; 295; 324 abstechen W dismantling 75 Akremit W Acremite 1 Abstichladung = jet tapper 193 Albanite = propellant based on Acardite W Akardite 9 W DINA 108 accessoires pour le sautage = blast- Alex 10 ing accessoires 36 Alex 20 = W composition B plus 20% acceptor 1 aluminium Accord Européen relatif au Transport alginates 10 International des Marcharndises aliphatic nitramines 68; 124; 132; Dangereuses par Route W A.D.
    [Show full text]
  • New Directions in the Area of Modern Energetic Polymers: an Overview
    ISSN 0010-5082, Combustion, Explosion, and Shock Waves, 2017, Vol. 53, No. 4, pp. 371–387. c Pleiades Publishing, Ltd., 2017. Original Russian Text c D.M. Badgujar, M.B. Talawar, V.E. Zarko, P.P. Mahulikar. New Directions in the Area of Modern Energetic Polymers: An Overview a b D. M. Badgujar ,M.B.Talawar, UDC 536.46 V. E. Zarkoc, and P. P. Mahulikar a Published in Fizika Goreniya i Vzryva, Vol. 53, No. 4, pp. 3–22, July–August, 2017. Original article submitted November 8, 2016. Abstract: Energetic polymers containing nitro, nitrato, and azido groups release high energy during combustion and thereby increase the performance of the systems. A number of energetic polymers have been found suitable for use as binders in high-performance propellant and explo- sive formulations. This review describes the synthetic and application aspects of various modern energetic polymers for explosive formulations and propellants. Keywords: energetic polymers, thermoplastic elastomers, energetic binders, plastic bonded ex- plosives (PBX), energetic plasticizers, carborane polymers, energetic polyphosphazenes. DOI: 10.1134/S0010508217040013 INTRODUCTION mers, as, e.g., in the manufacture of nitrocellulose from cellulose [6], picryl nitrocellulose from cellulose [7], Energetic polymers are compounds that generally polyvinyl nitrate from polyvinyl alcohol [8] and nitrated contain energetic groups (explosophores) such as the polybutadiene from polybutadiene [9]. nitro-, nitrato-, azido-, etc., and their combustion prod- ucts contain a significant amount of nitrogen gas. En- ergetic polymers are of interest for use as binders in 1. ENERGETIC POLYMERS propellants and explosives [1]. The binders can be spe- AND PREPOLYMERS cially synthesized polymers containing explosophores or ordinary polymers in combination with energetic plas- Energetic polymers (Table 1) can be used in the ticizers, namely, nitroesters, nitramines, and nitro- and production of low hazard, high power explosives, thus azido-compounds.
    [Show full text]
  • EXPLOSIVES OR THERMIC COMPOSITIONS (Blasting F42D); MANUFACTURE THEREOF; USE of SINGLE SUBSTANCES AS EXPLOSIVES (Compounds in Ge
    C06B EXPLOSIVES OR THERMIC COMPOSITIONS (blasting F42D); MANUFACTURE THEREOF; USE OF SINGLE SUBSTANCES AS EXPLOSIVES (compounds in general C01, C07 or C08; [N: demolition agents based on cementitious or like materials C04B41/0009 ]) Definition statement This subclass/group covers: Explosive compositions: compositions included are those containing both a fuel and sufficient oxidiser so that, upon initiation, they are capable of undergoing a chemical reaction of a relatively high rate of speed, resulting in the production of usable force for blasting, firearms, propelling missiles, or the like. Thermic compositions; compositions included have • a consumable fuel component which consists of any element which is a metal, B, Si, Se or Te, or mixtures, compounds, or hydrides thereof; and • in combination an oxidant component which is either a metal oxide or a salt (organic or inorganic) capable of yielding a metal oxide on decomposition. Compositions which are fuels for rocket engines and intended for reaction with an oxidant, excluding air, in order to provide thrust for motive power purposes. Compositions used for affecting the explosion environment, e.g. for neutralising the poisonous gases of explosives or for cooling the explosion gases. Methods or apparatus for preparing or treating, e.g. working-up, the compositions mentioned above, not otherwise provided for in the IPC. Methods of using single substances as explosives. Compositions mentioned above, defined by structure or arrangement of the components or products. Relationship between large subject matter areas This subclass does not cover chemical compounds or their preparation as such, which subject matter is covered by classes C01 (inorganic chemistry), C07 (organic chemistry) and C08 (organic macromolecular compounds).
    [Show full text]
  • An Appraisal of Methods for Estimating Self-Reaction Hazards
    NATL INST. OF STAND & TECH MIST PUBLICAHON| NBSIR 74-551 An Appraisal of Methods for Estimating Self-Reaction Hazards W. Tsang and E. S. Domalski Physical Chemistry Division Institute for Materials Research National Bureau of Standards Washington, D. C. 20234 June 1974 Interim Report for Period January -June 1974 Prepared for Office of Hazardous Materials sartment of Transportation shington, D. C. 20024 NBSIR 74-551 AN APPRAISAL OF METHODS FOR ESTIMATING SELF-REACTION HAZARDS W. Tsang and E. S. Domalski Physical Chemistry Division Institute for Materials Research National Bureau of Standards Washington, D. C. 20234 June 1974 Interim Report for Period January- June 1974 Prepared for Office of Hazardous Materials Department of Transportation Washington, D.C. 20024 , 7 , U. S. DEPARTMENT OF COMMERCE, Frederick B. Dent. Secretary NATIONAL BUREAU OF STANDARDS. Richard W. Roberts. Director Preface The production of chemical compounds and their transportation constitutes a vital segment of our nation's technological growth and economic stability. Hazardous materials require appropriate labeling and identification in connection with their handling and transport in commerce and industry. The Hazardous Classification System proposed by the Department of Transportation, Hazardous Materials Regulations Board, describes various classifications for materials, however, thermally unstable or self-reactive materials are indicated only as a secondary descriptor. The possibility of identifying thermal instability of chemical substances without recourse to experimental studies is the basic purpose of this study. Our approach has been to evaluate certain procedures which claim to be capable of estimating hazard potential by a direct comparison with the results of explosive sensitivity tests and the predictions from the hazard evaluation schemes.
    [Show full text]
  • Investigation of Nitrogen-Rich Polymers Based on Tetrazoles and Triazoles
    Dissertation zur Erlangung des Doktorgrades der Fakultät für Chemie und Pharmazie der Ludwig-Maximilians-Universität München Investigation of Nitrogen-Rich Polymers Based on Tetrazoles and Triazoles vorgelegt von Stefan M. Sproll aus Tübingen München 2009 Erklärung Diese Dissertation wurde im Sinne von § 13 Abs. 3 der Promotionsordung vom 29. Januar 1998 von Herrn Prof. Dr. Thomas M. Klapötke betreut. Ehrenwörtliche Versicherung Diese Dissertation wurde selbstständig, ohne unerlaubte Hilfe erarbeitet. München, den 24.11.2009 Stefan Sproll Dissertation eingereicht am 26.11.2009 1. Berichtserstatter: Prof. Dr. Thomas M. Klapötke 2. Berichtserstatter: Prof. Dr. Konstantin Karaghiosoff Mündliche Prüfung 12. Januar 2010 Die vorliegende Arbeit wurde in der Zeit von Januar 2007 bis November 2009 am Department Chemie und Biochemie der Ludwig-Maximilians-Universität München unter der Anleitung von Prof. Dr. Thomas M. Klapötke angefertig. Danksagung Ich danke ganz besonders Herrn Prof. Dr. Klapötke für die freundliche Aufnahme in den Arbeitskreis, sowie für die interessante Themenstellung dieser Dissertation, des Weiteren für die gute Betreuung, die es mir ermöglichte mich jederzeit mit Fragestellungen an ihn zu wenden, welche dann sofort erörtert und gelöst wurden und für die Freiheiten die es mir gestatteten kreative Antworten zu suchen und manchmal zu finden. Herrn Prof. Dr. Konstantin Karaghiosoff möchte ich für zahlreiche NMR-Messungen danken (inklusive Hilfe bei besonders schweren Fällen), sowie für anregende Diskussionen und für die Übernahme des Zweitgutachtens. Herrn Akad. ORat Dr. Burkhard Krumm möchte ich für seine Offenheit danken, die es mir ermöglichte mich jederzeit mit chemischen und sicherheitstechnischen Fragen an ihn zu wenden. Frau Irene S. Scheckenbach möchte ich für ihre Freundlichkeit, die organisatorische Betreuung sowie die regelmäßige Unterhaltung mit Prüfungsbeisitzen danken.
    [Show full text]
  • Investigations on Polyvinyl Nitrate As a High Energetic Material
    64 Propellants, Explosives, Pyrotechnics 20,64-69 (1995) Investigations on Polyvinyl Nitrate as a High Energetic Material U.C. Durgapal*, P.K.Dutta, S.C. Mishra, and Jyotsna Pant Institute of Armament Technology, Girinagar, Pune-411025 (India) Untersuchungen an Polyvinylnitrat, einer energiereichen Verbin- Etudes sur le polyvinylnitrate, compose 6nergCtique dung Le polyvinylnitrate (PVN) est I’un des quelques explosifs polymk- Polyvinylnitrat (PVN) ist einer der weniger bekannten polymeren res connus. Le PVN a CtC prCparC par addition contr6lCe d’acide nit& Explosivstoffe. PVN wurde dargestellt durch kontrollierte Zugabe von que froid pour former une suspension prkrefroidie d’alcool polyvinyli- kalter Salpetersaure zu einer vorgekiihlten Suspension von que dans de I’anhydride acCtique et traitement subsequent du produit Polyvinylalkohol in Essigsaureanhydrid und nachfolgender Aufarbei- de rkaction. La teneur en azote de diffkrents Cchantillons de PVN ktait tung des Reaktionsproduktes. Der Stickstoffgehalt verschiedener situCe entre I1,76% et 15,71% pour un poids molkculaire de l’ordre de PVN-Proben lag zwischen 11,76% und 15,71% bei einem Molekular- 100000. On a CtudiC diffkrentes propriCtCs du PVN et on les a mises gewicht um 1OOOOO. Verschiedene Eigenschaften des PVN sind unter- en con-Clation avec le degrb de nitration. Des microscopies electroni- sucht und korreliert worden mit dem Nitrierungsgrad. Scanning Elec- ques B balayage de fibres PVN rtvdent une surface poreuse. Les tronen-Mikrographien von PVN-Fasern zeigen eine porose Ober- valeurs du test d’Abel B 82°C indiquent que le PVN fibreux possitde flache. Die Werte des Abel-Tests bei 82°C weisen auf eine leidlich une stabilitk relativement bonne, qui diminue lorsque la teneur en gute Stabilitat des faserigen PVN, die abnimmt mit der Zunahme des azote augmente.
    [Show full text]
  • CCC) at Elevated Temperatures
    Improvements in the Structural Integrity of Resin Based Combustible Cartridge... 117 Central European Journal of Energetic Materials, 2015, 12(1), 117-127 ISSN 2353-1843 Improvements in the Structural Integrity of Resin Based Combustible Cartridge Cases (CCC) at Elevated Temperatures Abhijit DEY*, Javaid ATHAR, Siddhartha GOGOI, Pradeep B. NAVLE, Arun K. SIKDER** High Energy Materials Research Laboratory, DRDO, Sutarwadi, Pune, 411 021, India E-mails: *[email protected], **[email protected] Abstract: An advanced, solvent-less resin based Combustible Cartridge Case (CCC), designed to resolve the inherent problems of shrinkage and limited mechanical strength associated with the gelatinisation of nitrocellulose, has already been developed. The felt-moulded components contain thermoplastic polyvinyl acetate (PVAc) resin as the binder and the enhanced mechanical strength is achieved by carrying out hot compaction of dry felts at an elevated temperature (105 ± 2 °C). Presently, resin based technology is adopted for tank gun ammunition and also for the developed modular CCCs, i.e. the Modular Combustible Case (MCC) for different types of artillery gun ammunition. However, during exhaustive trials conducted with the resin based CCCs in 120 mm tank gun ammunition at three temperatures, i.e. -10, 27 and 55 °C, severe geometrical deformation was noticed when the rounds were conditioned at 55 °C for 24 h., adversely affecting the loading of rounds into the gun chamber. This was attributed to the combined effects of softening of the resin at that temperature and the load of the projectile/ shell (14.4 kg) experienced by the CCC region during conditioning of the round in the horizontal mode.
    [Show full text]
  • Decomposition and Reaction of Polyvinyl Nitrate Under Shock and Thermal Loading: a Reaxff Reactive Molecular Dynamics Study Md Mahbubul Islam and Alejandro Strachan*
    Article pubs.acs.org/JPCC Decomposition and Reaction of Polyvinyl Nitrate under Shock and Thermal Loading: A ReaxFF Reactive Molecular Dynamics Study Md Mahbubul Islam and Alejandro Strachan* School of Materials Engineering and Birck Nanotechnology Center, Purdue University, West Lafayette, Indiana 47907, United States *S Supporting Information ABSTRACT: We use molecular dynamics (MD) simulations with the reactive force field ReaxFF to investigate the response of polyvinyl nitrate (PVN), a high-energy polymer, to shock loading using the Hugoniostat technique. We compare predictions from three widely used ReaxFF versions, and in all cases, we observe shock-induced, volume- increasing exothermic reactions following a short induction time for strong enough insults. The three models predict NO2 dissociation to be the first chemical, and relatively similar final product populations; however, we find significant differences in intermediate populations indicating different reaction mechanisms due to discrepancies in the relative stability of various intermediate fragments. A time-resolved spectral analysis of the reactive MD trajectories enables the first direct comparison of shock-induced chemistry between atomistic simulations and experiments; specifically, ultrafast spectroscopy on laser shocked samples. The results from one of the ReaxFF versions are in excellent agreement with the experiments both in terms of threshold shock strength required for the disappearance of NO2 peaks and in the time scale associated with the process. Such direct comparison between physical observables is an important step toward a definite determination of detailed chemistry for high-energy density materials. I. INTRODUCTION interactions with molecular monolayers.11 The experiment on 12 Shock-induced chemistry of high-energy (HE) materials and PVN revealed that 18 GPa shocks resulted in chemical the shock to detonation transition involve complex and inter- reactions within approximately 150 ps indicated by the disappearance of a peak associated with NO2.
    [Show full text]
  • Chapter 4 Explosive Properties of Polyvinyl
    CHAPTER 4 EXPLOSIVE PROPERTIES OF POLYVINYL NITRATE AND EFFECT OF ADDITIVES THEREON INTRODUCTION Several compounds containing C-NO_ groups (the nitro compxjunds), N-NOp groups (the nitramines), and 0-N0_ groups (the nitrates or nitric esters) are knovm to exhibit explosive properties, i.e. they decompose rapidly producing heat and gaseous products under the influence of suitable mechanical and/or thermal stimuli. Polyvinyl nitrate (PVN), being a nitrated polymer, is expected to exhibit explosive properties depending on its degree of nitration (expressed in terms of % N by weight). The propensity of PVN tovreu'ds explosive decomposition is attributable to the presence of the relatively weaJc N-0 bond (bond energy 53 kcal/mol) in large number throughout the chain. It vras, therefore, considered desirable, in this study, to investigate a few selected explosive properties of PVN which would have a bearing on its practical application, viz. the deflagration (or autoignition) temperature, sensitiveness to impact loads, heats of combustion and explosion, and thermal stability. (Detonation characteristics, like detonation velocity, critical diameter, power, etc, were not included in the study due to lack of experimental facilities). It is intended to investigate the influence of certain variables on the explosive properties of PVN, as, for example, the type (fibrous or gelatinized) as well as nitrogen content of PVN vis-a-vis its deflagration temperature; the type, nitrogen content and sensitizer additive in PVN vis-a-vis its impact sensitiveness; the type, stabilizer additive and its concentration in PVN vis-a-vis its heat stability. Thermochemical properties of PVN were determined, najnely, heats of combustion and explosion by calorlmetrlc experiments, and heat of formation by calculation, In order to obtain an Idea of Its energetic potential.
    [Show full text]
  • Thermodynamic Data for Biomass Conversion and Waste Incineration
    /SP-271-2839 Notice This report was prepared as an account of work sponsored by an agency of the United States Government. Neither the United States Government nor any agency thereof, nor any of their employees, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any informa- tion, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, or service by trade name, trademark, manufacturer, or otherwise, does not necessarily constitute or imply its endorsement, recommendation, or favoring by the United States Government or any agency thereof. The views and opinions of authors expressed herein do not necessarily state or reflect those of the United States Govetn- ment or any agency thereof. Acknowledgments This document was prepared for the Solar Technical Information Program, US. Depatt- ment of Energy, by Eugene S. Domalski and Thomas L. fobe, Jr. of the Chemical Ther- modynamics Data Center, Chemical Thermodynamics Division, Center for Chemical Physics, and the Office of Standard Reference Data, National Bureau of Standards, Gaithersburg, Md; with assistance from Thomas A. Milne of SERI. It is based on Thermo- dynamic Data of Waste Incineration, NBSIR 78-1479, August 1978, prepared for the American Society for Mechanical Engineers, Research Committee on Industrial and Municipal Wastes, United Engineering Center, New York, and also available as a separate hard-cover publication with the same title from the American Society for Mechanical Engineers. Sarah Sprague is the Information Program Coordinator for the Biofuels and Municipal Waste Technology Division, U.S.
    [Show full text]