DOCSLIB.ORG

Surface Chemistry and Surface Properties of Energetic Nitrocellulose (NC)

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Surface Chemistry and Surface Properties of Energetic Nitrocellulose (NC) Seton Hall University eRepository @ Seton Hall Seton Hall University Dissertations and Theses (ETDs) Seton Hall University Dissertations and Theses Spring 4-29-2020 Surface Chemistry and Surface Properties of Energetic Nitrocellulose (NC) Henry Grau [email protected] Follow this and additional works at: https://scholarship.shu.edu/dissertations Part of the Analytical Chemistry Commons, Materials Chemistry Commons, Organic Chemistry Commons, and the Physical Chemistry Commons Recommended Citation Grau, Henry, "Surface Chemistry and Surface Properties of Energetic Nitrocellulose (NC)" (2020). Seton Hall University Dissertations and Theses (ETDs). 2762. https://scholarship.shu.edu/dissertations/2762 Surface Chemistry and Surface Properties of Energetic Nitrocellulose (NC) By: Henry Grau Dissertation submitted to the Department of Chemistry and Biochemistry of Seton Hall University in partial fulfillment of the requirements for the degree of Doctor of Philosophy April 2020 Seton Hall University South Orange, New Jersey © 2020 (Henry Grau) Seton Hall University College of Arts and Sciences Department of Chemistry and Biochemistry APPROVAL FOR SUCCESSFUL DEFENSE Henry Grau has successfully defended and made the required modifications to the text of the doctoral dissertation for the Ph.D. during this Spring Semester 2020. Dissertation Committee (please sign and date beside your name) The mentor and any other committee members who wish to review revisions will sign and date this document only when revisions have been completed. Please return this form to the Office of Graduate Studies, where it will be placed in the candidate’s file and submit a copy with your final dissertation. Dedicated to my family: My wife Sandy My daughter Sadie My son Trent Abstract This research describes an investigation into the wettability of nitrocellulose (NC), most importantly to nitroglycerin (NG), which are key components of formulations used to propel military ammunition. NG demonstrates complete wetting of NC and, overtime, NG sweats on the NC surface and leaks out. The leaking out of NG from the solid formulation is a known cause of fires and explosions resulting from storage. The origin of this research is inspired by the need to engineer a solution to leakage problems of energetic plasticizer in NC based propellant. While searching for a viable material for a specific application, we journeyed into the very specific details of the properties of NC, and the chemical structures used for surface functionalization. In Chapter 1, we discuss the properties of nitrocellulose and the classes of propellant that contain NC and NG. We discuss the significance of the contact angle and how it’s measured. Experimental data showing the surface tension of nitroglycerin and its use as a probe fluid is described. In Chapter 2, silane surface chemistry and its applications are discussed. We described reactions from previous work involving cellulose that assisted us with work with NC. We discuss our results from reacting alpha cellulose and silyl isocyanate that provided conformation for further applications with NC. We explain experiments for functionalizing NC using acyl chlorides and isocyanate chemistry. We then proceed with our findings that allowed us to establish chemical designs described in the following chapter. We describe approaches for producing a ‘tunable’ NC surface that is derived from a two-step process using the reaction of 3-(triethoxysilyl-propyl) isocyanate followed by reactions with alkyl-, fluoroalkyl-, or phenyl-silane, producing NC surfaces ranging in lyophobicity. Each functional group allows various degrees of reduced wettability of NC with NG. We vi demonstrate surface preparation using tetramethoxysilane and polydimethysilane vapor reactions on solid state NC. We further functionalized the silanol rich solid state NC with alkyl and fluoroalkyl functionalities. In Chapter 3, the progress of reactions is demonstrated by chemical analysis. SEM analysis of modified NC materials suggests bulk properties of NC were not affected by silane. DSC demonstrated consistent decomposition of bare and treated NC. XPS provided evidence of chemically modified fibers. Increased lyophobicity of modified NC demonstrate thermal stability and equivalent energetic properties compared to bare NC. NC was characterized by dynamic contact angles using water, hexadecane, and NG as probe fluids. Wettability of modified NC demonstrated significant variations in surface energy in accordance with the nature of surface functionalities. In Chapter 4, we discuss the methods of measuring contact angles. The contact angles of modified NC demonstrated surfaces with “tunable” wetting. NC grafted with fluoroalkyl-groups showed the most NG- o o repelling properties (θAdv/θRec ~90 /50 ). Estimation of contact angles on nitrocellulose treated fibers allowed insight of the surface properties showing an increase in curvature and reduced capillary effect. Surface energy was estimated using contact angle measurements. In Chapter 5, nitrogen gas adsorption gives insight on textural properties of bare and treated NC. Key words: Wetting and contact angle, Nitrocellulose, Nitroglycerin, Surface functionalization, Silane coupling agents, Surface energy, Energetic materials, Fiber analysis, XPS, Adsorption. vii Acknowledgements I would like to thank the following individuals for their support, teachings, and friendship. Dr. Alexander Y. Fadeev: Thank you for taking me on and showing me a whole new world of chemistry. You do things the ‘old school way’. The way academics and research should be done. I remember a meeting we had before my matriculation exam, I could not answer what should have been a simple chemistry question and you let me ‘have it’ for a good hour. You may not realize how that woke me up and helped me excel in my work, but it did. Thank you for that. Thank you for allowing me to pursue the PhD degree on a part-time basis so I could work full time. I am forever thankful for your help. Matriculation committee: Thank you Dr. Gorun, Dr. Sabatini, Dr Kazakevich, and Dr. Sabatini. You took the time to help me get through the matriculation process and agreed to read my dissertation. Seton Hall University Chemistry Department Staff and Students: While at SHU I heard time and time again how everyone is so ‘nice’ and how everyone at SHU treats each other with respect. This holds true. The first day I visited SHU as a PhD student, I met Dr. Marzabadi. She really took the time to talk to me and answer my many questions. She was very gracious. I must say, to this day she is the nicest college professor I’ve ever met. Thank you to Dr. Maloy, who took the time out to help me with statistic questions as well as my matriculation exam. viii Picatinny Arsenal: I would like to thank my employers and my management at Picatinny Arsenal for funding and allowing me to pursue my PhD. I would like to thank Bill DePiero for giving me a chance to advance my career. I would like to thank Ed Cooke who was always willing for me to pick his brain. Most of all, I would like to thank Alex Gandzelko. He was always willing to help me out with some tough problems. I will be forever grateful. ix Table of Contents Chapter 1: Nitrocellulose, Nitroglycerin, Propellant, and the Importance to Understand their Surface Chemistry ..................................................................................................................... 1 1.1 Introduction ................................................................................................................ 1 1.2 Nitrocellulose and its Properties ................................................................................ 2 1.3 Nitrocellulose Double Base Propellants ..................................................................... 4 1.4 Nitrogylcerin Migration in Solid Propellant and Possible Solutions ......................... 6 1.4.1 Co-extruded Propellant and the Lyophobic Barrier ............................................ 7 1.5 Nitroglycerin Wetting Properties & Surface Tension at Various Temperatures ....... 10 1.5.1 The Young’s Equation and the Contact Angle .................................................. 10 1.5.2 Experimental ..................................................................................................... 14 1.5.2.1 General Information .................................................................................. 14 1.5.2.2 Nitroglycerin Purity ................................................................................... 15 1.5.2.3 Wetting and Contact angles ....................................................................... 15 1.5.2.4 Surface Tension of Nitroglycerin .............................................................. 16 1.6 Results and Discussion ............................................................................................. 16 1.7 Conclusions .............................................................................................................. 20 Chapter 2: Approaches for Nitrocellulose Functionalization ................................................. 22 2.1 Introduction .............................................................................................................. 22 2.2 Cellulose: Its Role in Understanding Nitrocellulose Surface Functionalization...... 23 2.3 Silane Chemistry for Surface and Polymer Modification ........................................ 24 2.4 Cellulose Surface Modification ...............................................................................
Load more

Recommended publications
  • 890 Part 1238—Microforms Records Management
    § 1237.30 36 CFR Ch. XII (7–1–10 Edition) (h) Document information about dig- 40–2007 (incorporated by reference, see ital photographic images as they are § 1237.3). produced. For permanent or unsched- (3) Follow the packing and shipping uled images descriptive elements must of nitrate film as specified in Depart- include: ment of Transportation regulations (49 (1) An identification number; CFR 172.101, Hazardous materials table; (2) Information about image content; 172.504, Transportation; 173.24, Stand- (3) Identity and organizational affili- ard requirements for all packages; and ation of the photographer; 173.177, Motion picture film and X-ray (4) Existence of any copyright or film—nitrocellulose base). other potential restrictions on image (b) Agencies must inspect cellulose- use; and acetate film periodically for an acetic (5) Technical data including file for- odor, wrinkling, or the presence of mat and version, bit depth, image size, crystalline deposits on the edge or sur- camera make and model, compression face of the film that indicate deteriora- method and level, custom or generic tion. Agencies must notify the Na- color profiles (ICC/ICM profile), and, tional Archives and Records Adminis- where applicable, Exchangeable Image tration, Modern Records Program File Format (EXIF) information em- (NWM), 8601 Adelphi Road, College bedded in the header of image files by Park, MD 20740, phone number (301) certain digital cameras. 837–1738, immediately after inspection (i) Provide a unique file name to about deteriorating permanent or un- identify the digital image. scheduled audiovisual records com- (j) Develop finding aids sufficiently posed of cellulose acetate so that they detailed to ensure efficient and accu- can be copied by the agency prior to rate retrieval.
    [Show full text]
  • Protein Blotting Guide
    Electrophoresis and Blotting Protein Blotting Guide BEGIN Protein Blotting Guide Theory and Products Part 1 Theory and Products 5 Chapter 5 Detection and Imaging 29 Total Protein Detection 31 Transfer Buffer Formulations 58 5 Chapter 1 Overview of Protein Blotting Anionic Dyes 31 Towbin Buffer 58 Towbin Buffer with SDS 58 Transfer 6 Fluorescent Protein Stains 31 Stain-Free Technology 32 Bjerrum Schafer-Nielsen Buffer 58 Detection 6 Colloidal Gold 32 Bjerrum Schafer-Nielsen Buffer with SDS 58 CAPS Buffer 58 General Considerations and Workflow 6 Immunodetection 32 Dunn Carbonate Buffer 58 Immunodetection Workflow 33 0.7% Acetic Acid 58 Chapter 2 Methods and Instrumentation 9 Blocking 33 Protein Blotting Methods 10 Antibody Incubations 33 Detection Buffer Formulations 58 Electrophoretic Transfer 10 Washes 33 General Detection Buffers 58 Tank Blotting 10 Antibody Selection and Dilution 34 Total Protein Staining Buffers and Solutions 59 Semi-Dry Blotting 11 Primary Antibodies 34 Substrate Buffers and Solutions 60 Microfiltration (Dot Blotting) Species-Specific Secondary Antibodies 34 Stripping Buffer 60 Antibody-Specific Ligands 34 Blotting Systems and Power Supplies 12 Detection Methods 35 Tank Blotting Cells 12 Colorimetric Detection 36 Part 3 Troubleshooting 63 Mini Trans-Blot® Cell and Criterion™ Blotter 12 Premixed and Individual Colorimetric Substrates 38 Transfer 64 Trans-Blot® Cell 12 Immun-Blot® Assay Kits 38 Electrophoretic Transfer 64 Trans-Blot® Plus Cell 13 Immun-Blot Amplified AP Kit 38 Microfiltration 65 Semi-Dry Blotting Cells
    [Show full text]
  • General Introduction Sustainability Issues in the Preservation of Black and White Cellulose Esters Film- Based Negatives Collections
    Élia Catarina Tavares Costa Roldão Licenciada em Conservação e Restauro A contribution for the preservation of cellulose esters black and white negatives Dissertação para obtenção do Grau de Doutor em Ciências da Conservação do Património, Especialidade em Ciências da Conservação Orientador: Doutora Ana Maria Martelo Ramos, Professora Associada, FCT NOVA Co-orientadores: Doutor Bertrand Lavédrine, CRC Doutor António Jorge D. Parola, Professor Associado com Agregação, FCT NOVA Júri: Presidente: Doutora Maria João Seixas de Melo, Professora Catedrática, FCTNOVA Arguentes: Doutor Hugh Douglas Burrows, Professor Catedrático Jubilado, FCT-UC Doutora Ana Isabel S. C. Delgado Martins, Directora do AHU-DGLAB Vogais: Doutora Ana Maria Martelo Ramos, Professora Associada, FCT NOVA Doutor João Pedro Martins de Almeida Lopes, Professor Auxiliar, FF- UL Novembro, 2018 A contribution for the preservation of cellulose esters black and white negatives Copyright © Élia Catarina Tavares Costa Roldão, Faculdade de Ciências e Tecnologia, Universidade Nova de Lisboa. A Faculdade de Ciências e Tecnologia e Universidade Nova de Lisboa têm o direito, perpétuo e sem limites geográficos, de arquivar e publicar esta dissertação através de exemplares impressos reproduzidos em papel ou de forma digital, ou por qualquer outro meio conhecido ou que venha a ser inventado, e de divulgar através de repositórios científicos e de admitir a sua cópia e distribuição com objectivos educacionais ou de investigação, não comerciais, desde que seja dado crédito ao autor e editor.
    [Show full text]
  • I. Solubility and Blend Studies of Nitrocellulose It
    I. SOLUBILITY AND BLEND STUDIES OF NITROCELLULOSE IT. RELAXATION PROPERTIES OF THIN FILM COATINGS: THE ROLE OF SURFACE TOPOGRAPHY by Eduardo Baleens Thesis submitted to the Faculty of the Virginia Polytechnic Institite and State University in partial fulfillment of the requirements for the degree of MASTER OF SCIENCE in Chemistry APPROVED: T.C. Ward, Chairman J.D. Graybeal J.P. Wightman July, 1988 Blacksburg, Virginia I. SOLUBILITY AND BLEND STUDIES OF NITROCELLULOSE II. RELAXATION PROPERTIES OF THIN ALM COATINGS: THE ROLE OF SURFACE TOPOGRAPHY by Eduardo Balcells Committee Chainnan: T. C. Ward Chemistry (ABSTRACT) In the first part of this two part thesis, interaction parameters of nitrocellulose with various solvent systems were investigated by Inverse Gas Chromatography. From these data, the solubility parameters of nitrocellulose were detennined at a series of nitration levels which were used to guide the selection of suitable plasticizers for nitrocellulose films. Subsequent dynamic mechanical experiments were then used to evaluate the effectiveness of the blend fonnulations in broadening the glass transition dispersion of the nitrocellulose blended films; in addition, stress-strain experiments were done in order to evaluate the tensile modulus of the nitrocellulose blends. In the second part of this thesis, both dynamic mechanical thermal analysis and dielectric thermal analysis were used to evaluate the relaxation properties of thin film polysulfone coatings and the effect of substrate surface topography on these properties. Both dynamic mechanical and dielectric thermal analysis revealed that the topographical nature of the substrate influenced the linear viscoelastic properties of the thin film coatings and that the extent of this influence was dependent on the coating thickness.
    [Show full text]
  • NITROGYLCERIN and ETHYLENE GLYCOL DINITRATE Criteria for a Recommended Standard OCCUPATIONAL EXPOSURE to NITROGLYCERIN and ETHYLENE GLYCOL DINITRATE
    CRITERIA FOR A RECOMMENDED STANDARD OCCUPATIONAL EXPOSURE TO NITROGYLCERIN and ETHYLENE GLYCOL DINITRATE criteria for a recommended standard OCCUPATIONAL EXPOSURE TO NITROGLYCERIN and ETHYLENE GLYCOL DINITRATE U.S. DEPARTMENT OF HEALTH, EDUCATION, AND WELFARE Public Health Service Center for Disease Control National Institute for Occupational Safety and Health June 1978 For »ale by the Superintendent of Documents, U.S. Government Printing Office, Washington, D.C. 20402 DISCLAIMER Mention of company name or products does not constitute endorsement by the National Institute for Occupational Safety and Health. DHEW (NIOSH) Publication No. 78-167 PREFACE The Occupational Safety and Health Act of 1970 emphasizes the need for standards to protect the health and provide for the safety of workers occupationally exposed to an ever-increasing number of potential hazards. The National Institute for Occupational Safety and Health (NIOSH) evaluates all available research data and criteria and recommends standards for occupational exposure. The Secretary of Labor will weigh these recommendations along with other considerations, such as feasibility and means of implementation, in promulgating regulatory standards. NIOSH will periodically review the recommended standards to ensure continuing protection of workers and will make successive reports as new research and epidemiologic studies are completed and as sampling and analytical methods are developed. The contributions to this document on nitroglycerin (NG) and ethylene glycol dinitrate (EGDN) by NIOSH staff, other Federal agencies or departments, the review consultants, the reviewers selected by the American Industrial Hygiene Association, and by Robert B. O ’Connor, M.D., NIOSH consultant in occupational medicine, are gratefully acknowledged. The views and conclusions expressed in this document, together with the recommendations for a standard, are those of NIOSH.
    [Show full text]
  • United States Patent Office Patented May 8, 1973 2 3,732,130 Tion, the Formulations Are Still Based Primarily Upon GUN PROPELLANT CONTAINING NONENER
    3,732,130 United States Patent Office Patented May 8, 1973 2 3,732,130 tion, the formulations are still based primarily upon GUN PROPELLANT CONTAINING NONENER. itsellulose With or without nitroglycerine as indicated GETIC PLASTICIZER, NATROCELLULOSE AND abOWe. TRAMNOGUANDENE NITRATE The early single-base gun propellant, utilizing nitro Joseph E. Flanagan, Woodland Hills, and Vernon E. 5 cellulose with 13.15% nitrogen content, has a mass im Haury, Santa Susana, Calif., assignors to North Ameri petus of 357,000 ft.-lbs./lb. and an isochoric flame tem can Rockwell Corporation perature of 3292. K. Incorporation of 20 weight percent No Drawing. Filed Oct. 14, 1971, Ser. No. 192,717 of nitroglycerin gives the standard double-base propel Int, C. C06d 5/06 lant with a mass impetus of 378,000 ft.-lbs./lb. and an U.S. C. 149-18 10 Claims O isochoric flame temperature of 3592 K. As mentioned previously, the high flame temperature of the double ABSTRACT OF THE DISCLOSURE base system is very undesirable since it severely limits the barrel life of the gun due to barrel erosion. To over Non-metallized gun propellant systems are provided come this critical problem, triple-base gun propellants containing triaminoguanidine nitrate oxidizer alone or in 15 were developed in which nitroguanidine was incorporated combination with other oxidizers such as cyclotrimethyl as a coolant into the nitrocellulose-nitroglycerine system. ene trinitramine or cyclotetramethylene tetranitramine. Representative conventional triple base propellants are the The binder system is based on nitrocellulose and a non M30 (impetus=364,000 ft.-lbs./Ib.; Ty=3040 K.) and energetic plasticizer such as polyethylene glycol.
    [Show full text]
  • Fire Effects and Fire Control in Nitrocellulose Photographic-Film Storage
    Fire Effects and Fire Control in Nitrocellulose Photographic-Film Storage United States Department of Commerce National Bureau of Standards Building Materials and Structures Report 145 BUILDING MATERIALS AND STRUCTURES REPORTS On request, the Superintendent of Documents, U. S. Government Printing Office, Wash- ington 25, D. C., will place your name on a special mailing list to receive notices of new reports in this series as soon as they are issued. There will be no charge for receiving such notices. If 100 copies or more of any report are ordered at one time, a discount of 25 percent is allowed. Send all orders and remittances to the Superintendent of Documents, U. S. Government Printing Office, Washington 25, D. C. The following publications in this series are available by purchase from the Super- intendent of Documents at the prices indicated: BMSl Research on Building Materials and Structures for Use in Low-Cost Housing * BMS2 Methods of Determining the Structural Properties of Low-Cost House Constructions.. * BMS3 Suitability of Fiber Insulating Lath as a Plaster Base * BMS4 Accelerated Aging of Fiber Building Boards 100 BMS5 Structural Properties of Six Masonry Wall Constructions 250 BMS6 Survey of Roofing Materials in the Southeastern States * BMS7 Water Permeability of Masonry Walls * BMS8 Methods of Investigation of Surface Treatment for Corrosion Protection of Steel 150 BMS9 Structural Properties of the Insulated Steel Construction Co.’s “Frameless-Steel” Con- structions for Walls, Partitions, Floors, and Roofs * BMS10 Structural
    [Show full text]
  • Provisional Peer-Reviewed Toxicity Values for Nitrocellulose (Casrn 9004-70-0)
    EPA/690/R-09/039F l Final 9-08-2009 Provisional Peer-Reviewed Toxicity Values for Nitrocellulose (CASRN 9004-70-0) Superfund Health Risk Technical Support Center National Center for Environmental Assessment Office of Research and Development U.S. Environmental Protection Agency Cincinnati, OH 45268 COMMONLY USED ABBREVIATIONS BMD Benchmark Dose IRIS Integrated Risk Information System IUR inhalation unit risk LOAEL lowest-observed-adverse-effect level LOAELADJ LOAEL adjusted to continuous exposure duration LOAELHEC LOAEL adjusted for dosimetric differences across species to a human NOAEL no-observed-adverse-effect level NOAELADJ NOAEL adjusted to continuous exposure duration NOAELHEC NOAEL adjusted for dosimetric differences across species to a human NOEL no-observed-effect level OSF oral slope factor p-IUR provisional inhalation unit risk p-OSF provisional oral slope factor p-RfC provisional inhalation reference concentration p-RfD provisional oral reference dose RfC inhalation reference concentration RfD oral reference dose UF uncertainty factor UFA animal to human uncertainty factor UFC composite uncertainty factor UFD incomplete to complete database uncertainty factor UFH interhuman uncertainty factor UFL LOAEL to NOAEL uncertainty factor UFS subchronic to chronic uncertainty factor i FINAL 9-8-2009 PROVISIONAL PEER-REVIEWED TOXICITY VALUES FOR NITROCELLULOSE (CASRN 9004-70-0) Background On December 5, 2003, the U.S. Environmental Protection Agency’s (U.S. EPA) Office of Superfund Remediation and Technology Innovation (OSRTI) revised its hierarchy of human health toxicity values for Superfund risk assessments, establishing the following three tiers as the new hierarchy: 1) U.S. EPA’s Integrated Risk Information System (IRIS). 2) Provisional Peer-Reviewed Toxicity Values (PPRTVs) used in U.S.
    [Show full text]
  • Effect of Solid Additives on the Rheological Property
    Appl. Rheol. 2020; 30:14–26 Research Article Le Qi, Zhongliang Ma*, Jiahao Liang, and Zhongliang Xiao Effect of Solid Additives on the Rheological Property of Nitroglycerin Plasticized Nitrocellulose https://doi.org/10.1515/arh-2020-0002 equations will form a contribution to the research on ex- Received Jul 02, 2019; accepted Feb 21, 2020 trusion process of this energetic material containing Cy- clotrimethylenetrinitramine (RDX) and graphene, and the Abstract: The rheological properties of energetic materials results obtained by this research have certain practical sig- comprising nitroglycerin plasticized nitrocellulose were nificance of the extrusion process for this energetic mate- studied using rheological tests in a parallel plate rheome- rial. ter. The Carreau-Yasuda equation was applied to calcu- late the zero-shear viscosity, and the dependence of solid Keywords: Rheometer, Zero-shear viscosity (ZSV), Viscous additives, temperature and solvent content on zero-shear flow activation energy, Carreau-Yasuda equation, master viscosity was developed. One can study flow character- curve istics of the energetic materials by observing the zero- shear viscosity instead of the effect of solid additives, tem- perature and solvent content. Additionally, the relation- ship between zero-shear viscosity and additives concen- 1 Introduction tration was studied. The Kissinger-Akahira-Sunose (KAS) Energetic materials can be defined as metastable materi- method was used to obtain the viscous flow activation als with high energy density containing a high amount of energy, and the equation to describe the relationship be- stored chemical energy that can be released. Nitrocellulose tween solid additives concentration and viscous flow ac- (NC) is an important energetic material for some specific tivation energy was represented.
    [Show full text]
  • Hazardous Substance Fact Sheet
    Right to Know Hazardous Substance Fact Sheet Common Name: NITROCELLULOSE CAS Number: 9004-70-0 Synonyms: Collodion; Cellulose Nitrate Solution; Pyroxylin Solution RTK Substance Number: 1366 Chemical Name: Cellulose, Nitrate DOT Number: UN 2556 (solid) Date: April 2001 Revision: February 2010 UN 2059 (solution) Description and Use EMERGENCY RESPONDERS >>>> SEE LAST PAGE Nitrocellulose is a white, granular chip or fibrous material, Hazard Summary which is usually kept wet in water or an alcohol solution. It is Hazard Rating NJDOH NFPA used for automobile lacquers, and in printing inks, explosives HEALTH - 2 and rocket propellants. 3 (Nitrocellulose) FLAMMABILITY - 4 (Collodion) 3 (Nitrocellulose) REACTIVITY - 0 (Collodion) FLAMMABLE AND REACTIVE Reasons for Citation EXPLOSIVE WHEN DRY POISONOUS GASES ARE PRODUCED IN FIRE f Nitrocellulose is on the Right to Know Hazardous CONTAINERS MAY EXPLODE IN FIRE Substance List because it is cited by DOT and NFPA. f This chemical is on the Special Health Hazard Substance Hazard Rating Key: 0=minimal; 1=slight; 2=moderate; 3=serious; List. 4=severe f Nitrocellulose can affect you when inhaled. f Contact can irritate the skin and eyes. f Inhaling Nitrocellulose can irritate the nose and throat. f Exposure can cause headache, dizziness, difficulty SEE GLOSSARY ON PAGE 5. breathing and loss of consciousness. f Nitrocellulose may affect the nervous system. f Nitrocellulose is FLAMMABLE and REACTIVE and a FIRST AID DANGEROUS FIRE and EXPLOSION HAZARD. Eye Contact f Immediately flush with large amounts of water for at least 15 minutes, lifting upper and lower lids. Remove contact lenses, if worn, while rinsing. Workplace Exposure Limits No occupational exposure limits have been established for Skin Contact Nitrocellulose.
    [Show full text]
  • United States Patent Office Patented Sept
    3,208,890 United States Patent Office Patented Sept. 28, 1965 2 3,208,890 From the table, it is thus evident that the two propyl GELATNIZED EXPLOSIVE ene glycol dinitrates, and especially the 1,2-compound, Carl Torsten Edlund and Gustav Allan Wetterholm, Gyttorp, Sweden, assignors to Nitroglycerin Aktiebola are decidedly less soluble in water than nitroglycol, where get, a company of Sweden by they are absorbed by the blood to a less degree. No Drawing. Filed Feb. 27, 1963, Ser. No. 261,521 Claims priority, application Sweden, Feb. 28, 1962, THE PRESENT INVENTION 2,232/62 The present invention relates to an explosive having an 5 Claims. (Cl. 149-47) improved physiological acceptance and a low sensitivity to impact, consisting of or containing propylene-glycol di The present invention generally relates to a novel ex 0. nitrate, and one or more inorganic oxygen-delivering plosive of the gelatinized type having improved physio salts. One important characterizing feature of the ex logical acceptance and a low sensitivity to impact. More plosive according to the invention is that the oxygen-de specifically the present invention pertains to an explosive livering inorganic salt or salts are present in a sufficient comprising an oxygen-delivering inorganic salt and an ex amount to substantially oxygen-balance the explosive. plosive oil consisting of propylene-glycol dinitrate or a 15 Because the explosives according to the invention mixture of propylene-glycol dinitrate with no more than possess a combination of high insensitivity to impact with 50 percent of nitroglycerine. an excellent physiological acceptance, they represent a BACKGROUND valuable advance in the field of explosives.
    [Show full text]
  • Rapid Identification of Cellulose Nitrate and Cellulose Acetate Film In
    Carter et al. Herit Sci (2020) 8:51 https://doi.org/10.1186/s40494-020-00395-y RESEARCH ARTICLE Open Access Rapid identifcation of cellulose nitrate and cellulose acetate flm in historic photograph collections Elizabeth A. Carter1,2* , Brad Swarbrick2, Thérèse M. Harrison1 and Lucilla Ronai3 Abstract Cellulose nitrate transparent plastic flm was used by photographers and movie flmmakers from its release in the 1880s to the 1950s. The storage of this material is a challenge for cultural institutions because of its instability and haz- ardous nature, as nitrate is highly fammable and deteriorates over time. Historically, cellulose acetate gradually began to replace cellulose nitrate as it is not fammable. Despite its non-fammable properties, leading to cellulose acetate being called ‘safety’ flm, over time it became clear that it also deteriorates in hazardous ways. Identifcation of cellu- lose nitrate and cellulose acetate in collections is necessary for preservation and risk management to collections and humans. Both cellulose nitrate and cellulose acetate are found in gallery, library, archive and museum photographic collections. As a result, identifcation and management of this material might be the responsibility of curators, librar- ians, archivists, collection managers, registrars or conservators, depending on the institution stafng and structure. Currently, there is no single identifcation method readily available to heritage institutions that meets the require- ments to identify and distinguish between cellulose nitrate and cellulose acetate reliably, non-destructively and rapidly. In this study samples from both the Sydney University Museums and Australian National Maritime Museum collections have been analysed using infrared total refectance spectroscopy, a novel approach which demonstrates great potential for rapid and non-invasive identifcation particularly when combined with multivariate statistical analysis methods.
    [Show full text]