DOCSLIB.ORG

Nitrile Butadiene Rubber (Nbr)

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Nitrile Butadiene Rubber (Nbr) NITRILE BUTADIENE RUBBER (NBR) MATERIAL SPECIFICATIONS ChangExp NBR Nitrile rubber known as NBR, Buna-N and acrylonitrile butadiene rubber is s synthetic rubber copolymer elastomer. NBR rubber are widely use in automotive and aeronautical industry to make fuel and oil seals, self-sealing fuel tanks lining. NBR ability to withstand range of temperatures from -20 to +110 Celsius make it an ideal material for aeronautical applications. ChangExp NBR rubber sheet is a nitrile base rubber sheet, providing excellent resistance to petroleum oils as well as mineral and vegetable oils. NBR rubber material is used in applications involving not only oil and fuel resistance but also those applications requiring resistance to heat, abrasion, water and gas permeability. It is resistant to weathering, sunlight and ozone. From oil rigs to bowling alleys, nitrile rubber can be the right material for your applications. Advantage - Excellent oil resistant - Good resistance to heat and aging - Good inpermeability to gases - Good abrasion resistance Applications - Carburetor and fuel pump diaphragms - Chemical container lining - Seal and gasket - Aircraft hoses FEATURES Standard Width : 1000mm Width Range : 100mm - 2000mm 10mm Length : 10m Thickness : From 1mm to 50mm Standard Color : Black Work Temperature : +110 OC ADDRESS : 36/17 Moo 13, Buengkhamproi, Lam Luk Ka Pathumthani 12150 CHANG RUBBER DEVELOPMENT CO., LTD. www.changrubber.co.th NITRILE BUTADIENE RUBBER (NBR) (THNBR1261360) MATERIAL SPECIFICATIONS SPECIFICATION TEST METHOD TEST RESULT UNIT Specific Gravity ASTM D297 1.26 g/cm3 Hardness ASTM D2240 60 +/-5 Shore A Tensile Strength ASTM D-412 13 MPa Elongation ASTM D-412 350 Tear Strength ASTM D-624 30 kgf/cm Compression Set ASTM D-395 20 (22 Hours at 70 OC) WORKING TEMPERATURE In Air -40 OC +125 OC In Oil +100 OC In Water +100 OC MAIN CHARACTERISTICS ELASTICITY COMPRESSION ABRASION FLAME FUELS OZONE Good Good Poor Poor Good Fair ADDRESS : 36/17 Moo 13, Buengkhamproi, Lam Luk Ka Pathumthani 12150 CHANG RUBBER DEVELOPMENT CO., LTD. www.changrubber.co.th.
Load more

Recommended publications
  • The Difference of Butyl Rubber and Butadiene Styrene Rubber? by Butyl Rubber Sheets - [email protected], Date: Sep.18.06
    The difference of butyl rubber and butadiene styrene rubber? By Butyl Rubber Sheets - www.dongrubber.com, [email protected], Date: Sep.18.06 Butyl rubber sheets is a kind of synthetic rubber which is a copolymer of Isobutylene and a small amount of isoprene copolymer, short for IIR. Butyl rubber sheeting has good chemical stability and thermal stability, the most prominent character is the air tightness and water tightness. Its air transmittance is only about 1/7 of the natural rubber, 1/5 of the styrene-butadiene rubber. Meanwhile its transmittance of steam is 1/200 of the natural rubber, and 1/140 of the styrene-butadiene rubber. Thus IIR is mainly used in the manufacture of tires, inner tubes, steam pipe, water dam and bottom gasket and other rubber products. Styrene-butadiene rubber (SBR) is one of the biggest general synthetic rubber varieties, and is also among the first rubber to realize industrialization production. Styrene butadiene rubber sheet is a random copolymer of butadiene and styrene. Its physical performance, processing performance and product performance is close to those of natural rubber sheets, and some properties such as wear resistance, heat resistance, ageing resistance and curing rate are more excellent than natural rubber sheeting, SBR can be used with a variety of natural rubber sheets and synthetic rubbers, widely applied to tires, tape, rubber hose, wire and cable, medical instruments and various kinds of rubber products production and other fields. Author: Butyl Rubber Sheets copyright reserved. Original URL should be kept in reproduction. .
    [Show full text]
  • Vulcanization & Accelerators
    Vulcanization & Accelerators Vulcanization is a cross linking process in which individual molecules of rubber (polymer) are converted into a three dimensional network of interconnected (polymer) chains through chemical cross links(of sulfur). The vulcanization process was discovered in 1839 and the individuals responsible for this discovery were Charles Goodyear in USA and Thomas Hancock in England. Both discovered the use of Sulfur and White Lead as a vulcanization system for Natural Rubber. This discovery was a major technological breakthrough for the advancement of the world economy. Vulcanization of rubbers by sulfur alone is an extremely slow and inefficient process. The chemical reaction between sulfur and the Rubber Hydrocarbon occurs mainly at the C = C (double bonds) and each crosslink requires 40 to 55 sulphur atoms (in the absence of accelerator). The process takes around 6 hours at 140°C for completion, which is uneconomical by any production standards. The vulcanizates thus produced are extremely prone to oxidative degradation and do not possess adequate mechanical properties for practical rubber applications. These limitations were overcome through inventions of accelerators which subsequently became a part of rubber compounding formulations as well as subjects of further R&D. Following is the summary of events which led to the progress of ‘Accelerated Sulfur Vulcanization'. Event Year Progress - Discovery of Sulfur Vulcanization: Charles Goodyear. 1839 Vulcanizing Agent - Use of ammonia & aliphatic ammonium derivatives: Rowley. 1881 Acceleration need - Use of aniline as accelerator in USA & Germany: Oenslager. 1906 Accelerated Cure - Use of Piperidine accelerator- Germany. 1911 New Molecules - Use of aldehyde-amine & HMT as accelerators in USA & UK 1914-15 Amine Accelerators - Use of Zn-Alkyl Xanthates accelerators in Russia.
    [Show full text]
  • Crosslink Density of Rubbers
    Characterisation of Crosslinks in Vulcanised Rubbers: From Simple to Advanced Techniques K.L. Mok* and A.H. Eng** *Malaysian Rubber Board, Paper Presenter **Malaysian Institute of Chemistry Copyright © 2017 by K.L. Mok and A.H. Eng 1 Rubber & Elastomer • Rubbery: 1) Sufficient long chain; 2) Flexible molecules with noncollinear single bonds that allow segmental rotations along the backbone; 3) Non crystalline at service temperature • Rubber vs Elastomer: Rubber commonly refers to elastic materials that requires vulcanisation before they can be used in the products. However, there are elastic polymers that do not require vulcanisation such as polyurethane (PU), styrene- isoprene (SIS) copolymer. These elastic materials are classified under elastomer, which normally also includes rubbers. • Unvulcanised Rubbers: Unvulcanised rubbers are normally weak when put under stress during use. With very few exceptions, such as rubber glues almost all rubber products require vulcanisation to provide the required strength for a longer design life. • Elastomers: Polyurethane (PU), styrene-isoprene (SIS) copolymer, do not require vulcanisation to have good strength properties as they contain the hard segment Copyrightwhich © 2017 by K.L.is Mok good and A.H. Engfor strength and the soft segment good elasticity properties. 2 Rubber Vulcanisation & Crosslink Density • Vulcanization or vulcanisation: A reaction that leads to the formation of inter-molecular bonding among the unsaturated rubber molecules with 3 dimensional network such that the mechanical properties such as tensile strength is enhanced. The vulcanising agent originally referred to was elemental sulfur. Later, sulfur donor was included. It now also includes non sulfur systems such as metal oxide and peroxides.
    [Show full text]
  • SAFETY DATA SHEET for Mission Rubber Neoprene Gaskets
    SAFETY DATA SHEET for Mission Rubber Neoprene Gaskets SECTION TOPIC PG 1 Identification 1 2 Hazard Identification 1-2 3 Composition/Information On Ingredients 2 4 First Aid Measures 2 5 Firefighting Measures 2 6 Accidental Release Measures 3 7 Handling and Storage 3 8 Exposure Controls/Personal Protection 3 9 Physical and Chemical Properties 4 10 Stability and Reactivity 4 11 Toxicological Information 4 12 Ecological Information 5 13 Disposal Considerations 5 14 Exposure Controls/Personal Protection 5 15 Regulatory Information 5-6 16 Other Information 6 missionrubber.com (800) 854-9991 SAFETY DATA SHEET NEOPRENE GASKETS Section 1: IDENTIFICATION 1.1 Product identifier Product name: Neoprene Product part number: DPESISGRP251 CAS number: Ingredients: 184963-09-1. Synonyms: Neoprene. Product description: Neoprene Synthetic Rubber Gasket is a black color rubber with a mild characteristic odor. Product type: Solid 1.2 Relevant identified uses of the substance or mixture and uses advised against Product use: For use only as specified in product literature 1.3 Details of the supplier of the safety data sheet Mission Rubber Company, LLC 1660 Lesson Lane Corona, CA 92879 1.4 Telephone number: 800-854-9991 Section 2: HAZARD IDENTIFICATION 2.1 Classification of Substance or Mixture Potential Health Effects Before using Neoprene Synthetic Rubbers, read Bulletin "Guide for Safety in Handling and FDA Status of Neoprene Solid Polymers". ADDITIONAL HEALTH EFFECTS POLYCHLOROPRENE BLEND ACUTE OR IMMEDIATE EFFECTS: ROUTES OF ENTRY AND SYMPTOMS Ingestion One type of Neoprene was tested for oral toxicity in rats. The LD-50 is in excess of 20,000 milligrams per kilogram body weight which is low toxicity.
    [Show full text]
  • Mechanical Study Guide.Pdf
    MECHANICAL CONCEPTS Turn on bookmarks to navigate this document . PURPOSE OF THIS GUIDE . BEARINGS . Michelin North America, Inc. Copyright © 2012 Michelin North America, Inc All rights reserved. The Michelin Man is a registered trademark of Michelin North America, Inc. www.michelin.com BEARINGS AND THEIR CATEGORIES Generalities A bearing is a mechanical device and it is important to know its various components. 1 2 Figure 1-1 . Michelin North America, Inc. Copyright © 2012 Michelin North America, Inc All rights reserved. The Michelin Man is a registered trademark of Michelin North America, Inc. www.michelin.com Categories of bearings Figure 1-2 . Michelin North America, Inc. Copyright © 2012 Michelin North America, Inc All rights reserved. The Michelin Man is a registered trademark of Michelin North America, Inc. www.michelin.com Radial bearings Radial bearings are made with balls or rollers, depending on the how the bearings are used. They are designed to withstand forces that are perpendicular to the axis of the shaft. Figure 1-3 Axial bearings Axial bearings, also known as thrust bearings, have either balls or rollers, but both are designed to withstand axial forces, which push or pull along the axis. Figure 1-4 . Michelin North America, Inc. Copyright © 2012 Michelin North America, Inc All rights reserved. The Michelin Man is a registered trademark of Michelin North America, Inc. www.michelin.com Radial bearings and their functions Ball bearings Name Function Rigid, with balls and Designed mainly to support deep track. radial loads, but can also take a bit of axial load. Name Function With filling notch.
    [Show full text]
  • Effect of the Nitrile Content on Nitrile Rubber Cure in Wide Temperature Range
    INTERNATIONAL JOURNAL OF SCIENTIFIC & TECHNOLOGY RESEARCH VOLUME 9, ISSUE 02, FEBRUARY 2020 ISSN 2277-8616 Effect Of The Nitrile Content On Nitrile Rubber Cure In Wide Temperature Range. Denis Kalugin, Anton Nashchokin, Anna Sutyagina, Nikolay Tikhonov, Artem Malakho Victor Avdeev Abstract: Vulcanization of NBR rubber with different nitrile content was studied. Enthalpy of vulcanization drops from 6.62J/g for 18% nitrile rubber to 1.89J/g for 40% one. The peak of vulcanization shifts to higher temperatures for 12°C with nitrile content increase. No secondary vulcanization process was observed for 18% nitrile rubber. The other rubbers possess thermal polymerization at 285°C in neat rubbers accelerated by nitrile groups. This process is additionally accelerated when vulcanization additives are present in rubber. Thus the post-vulcanization peak shifts up to 20°C to lower temperatures for 40% nitrile rubber with increase in enthalpy in 5 times compared to neat rubber. When heated at 250°C for 6 hours no significant change in rubber hardness is occurred for 18% nitrile rubber and 2 times increase for 40% nitrile rubber is measured indicating dramatic role of nitrile content for rubber properties. No considerable effect of nitrile groups cross link on rubber hardness is observed. Index Terms: cross-link, cure, DSC, hardness, NBR, nitrile, properties, rubber, vulcanization —————————— ◆ —————————— 1 INTRODUCTION The resulted mixture is poured into silicon paper box and rest Acrylonitrile–butadiene rubber (NBR), commonly known as for night for primary solvent evaporation. After that the resulted nitrile rubber, has been commercially available for more than film was dried at 50°C in vacuum to a constant weight.
    [Show full text]
  • BIOMIMETIC SYNTHETIC RUBBER Better Than Natural Rubber
    Better than natural rubber BISYKA BIOMIMETIC SYNTHETIC RUBBER 30 % less FRAUNHOFER abrasion EXPERTISE Elastomers Superior Life sciences roll resistance Silica fillers Scale up Can be produced in existing plants THE FRAUNHOFER-GESELLSCHAFT ABOUT THE FRAUNHOFER-GESELLSCHAFT The Fraunhofer-Gesellschaft is contract research, 70 percent of Europe’s leading organization which is through contracts with in applied research. It is made up of industry and with publicly financed 72 institutes and research facilities research projects. International collab- located throughout Germany. More oration with outstanding research than 26,600 employees generate partners and innovative companies an annual research volume of more worldwide provides direct access than 2.5 billion euros. Of this, more to major scientific and economic than 2.1 billion euros come from regions now and into the future. www.fraunhofer.de/en 2 CONTENT On behalf of the Fraunhofer-Gesellschaft, 4 Why is rubber so important for the auto- I would like to congratulate the BISYKA motive industry? Fraunhofer’s project on consortium on its excellent outcomes in the field biomimetic synthetic rubber of biomimetic synthetic rubber. “BISYKA” 6 What makes natural rubber so unique? Within the framework of MAVO, 8 Understanding Fraunhofer’s internal research program for dandelion rubber market-oriented preliminary research, Biocomponents enable innovative elastomers the Fraunhofer-Gesellschaft bundles the 12 From natural rubber expertise of various institutes into original to biomimetic preliminary research projects. synthetic rubber Synthesis of BISYKA rubber BISYKA is an excellent example of how on a pilot scale synergies can be used effectively in this way 16 Novel silica fillers for the rubber and tire industry to develop new and original solutions.
    [Show full text]
  • Lehigh Technologies
    CONFIDENTIAL “Technology and Innovation in the use of Micronized Rubber Powder in today’s Green World” 11 April, 2013 CONFIDENTIAL • Setting the Stage and What we are Learning • Who is Lehigh Technologies • Technical Presentation • What Does it All Mean in Terms of Green? 1 | Lehigh Technologies Inc. Millions of End-of-Life Tires Generated Each Year Energy Recovery Civil Engineering Landfill Stockpiled Data Not Available 292 250 112 80 30 2 | Lehigh Technologies Inc. 2 CONFIDENTIAL The First Chemical Revolution 1800s 1850-1900 1900-1930 dyes/pigments oil and gas cracking/refining discoveries metals synthetic chemistry carbohydrates soaps atomic theory and the chemical bond 3 | Lehigh Technologies Inc. 3 The World Today – 3 Challenges 4lbs /person/day oil prices over $80 world population and spiking to 7B people >$100/bbl over 200 million tons per year 1 billion in the borrow-buy-burn developed world is US energy consume as much strategy energy as the other 6B. 4 | Lehigh Technologies Inc. 4 The Second Chemical Revolution Bury or burn is not a solution infinite cycles of Vast resource pools available use • Huge technology challenge • • sustainable Must be waste based. production of Amyris, Kior, Renmatix, Genomatica building blocks • Small companies leading • • efficient use of Principles of Green Chemistry existing carbon Chemical companies leading sources • • 5 | Lehigh Technologies Inc. 5 Micronized Rubber Powder Industry – Lehigh Experience Image of industry: Reliability of supply-process safety; quality Scale-not capable of supporting
    [Show full text]
  • Polymer Composites Based on Plasticized PVC and Vulcanized Nitrile Rubber Waste Powder for Irrigation Pipes
    Hindawi Publishing Corporation ISRN Materials Science Volume 2013, Article ID 726121, 5 pages http://dx.doi.org/10.1155/2013/726121 Research Article Polymer Composites Based on Plasticized PVC and Vulcanized Nitrile Rubber Waste Powder for Irrigation Pipes Maria Daniela Stelescu National R&D Institute for Textile and Leather, Leather and Footwear Research Institute, 93 Ion Minulescu Street, 031215 Bucharest, Romania Correspondence should be addressed to Maria Daniela Stelescu; [email protected] Received 19 June 2013; Accepted 18 July 2013 Academic Editors: V. Contini, Y. X. Gan, and V. Ji Copyright © 2013 Maria Daniela Stelescu. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. The paper presents the technique of production and characterization of polymer composites based on plasticized PVC and rubber powder from vulcanized nitrile rubber waste. The new polymer composites have lower hardness, higher elongation at break, a better tensile strength, and better ozone resistance, and the blend suitable for irrigations pipes for agricultural use was selected. The selected polymer composites have a good behavior under accelerated aging, repeated flexion at room temperature and atlow ∘ temperature (−20 C), a very good behavior for immersion in water, concentrated acid and basis, animal fat, soya, and sun flower oil, proving their suitability for gaskets, hoses, protection equipment, rubber footwear, and so forth. The resulted thermoplastic polymer composites can be processed by injection, extrusion, and compression molding. 1. Introduction Poly (vinyl chloride) (PVC) is a versatile polymer, used in flexible, semirigid, and rigid forms.
    [Show full text]
  • (Pp)/ Ground Tire Rubber
    MANUFACTURING OF POLYPROPYLENE (PP)/ GROUND TIRE RUBBER (GTR) THERMOPLASTIC ELASTOMERS USING ULTRASONICALLY AIDED EXTRUSION A Thesis Presented to The Graduate Faculty of The University of Akron In Partial Fulfillment of the Requirements for the Degree Master of Science Jieruo Liu August, 2013 MANUFACTURING OF POLYPROPYLENE (PP)/ GROUND TIRE RUBBER (GTR) THERMOPLASTIC ELASTOMERS USING ULTRASONICALLY AIDED EXTRUSION Jieruo Liu Thesis Approved: Accepted ______________________ _______________________ Advisor Department Chair Dr. Avraam I. Isayev Dr. Robert Weiss _______________________ _______________________ Committee Member Dean of the College Dr. Thein Kyu Dr. Steven Cheng _______________________ ________________________ Committee Member Dean of the Graduate School Dr. Younjin Min Dr. George Newkome ________________________ Date ii ABSTRACT Compounding ground tire rubber (GTR) from whole waste tires with thermoplastic polyolefins, such as polypropylene (PP), is a possible way to manufacture thermoplastic elastomers and also to recycle waste tires to solve a major environmental problem. The present study looks at the effect of PP/GTR mixing ratio, rubber particle size, type of extruder, maleic anhydride grafted polypropylene (PP-g-MA) compatibilizer and ultrasound on the mechanical and rheological properties of PP and PP/GTR blends. PP and GTR were compounded at ratios of 30/70, 50/50 and 70/30. Whole tire GTR particles of 40 and 140 mesh sizes were used. Both the single screw extruder (SSE) and twin screw extruder (TSE) without and with ultrasonic treatment were applied. PP-g-MA compatibilizer was added to PP/GTR 50/50 blends at concentration of 10 wt %. Rheological, tensile and impact properties of uncompatibilized and compatibilized PP/GTR 50/50 blends were compared.
    [Show full text]
  • Rubber Division ACS Best Paper Awards
    Rubber Division ACS Best Paper Awards The Best Paper Committee of Rubber Division, ACS seeks to improve the quality of technical presentations by evaluating and publicly recognizing the authors of outstanding papers presented our technical meetings. Each year Committee Judges and peer attendees, rate each presentation on quality of content, originality, and clarity. Winning papers are selected from the top-rated presentations after further review by the Best Paper Committee. The Best Symposium is awarded to the symposium with the highest average paper ratings and best average attendance of presentations. Meeting Year Award Authors/Moderators Affiliation Title 196th, Fall 2019 Best Paper Steven K. Henning & Fabien Total Cray Valley Silane-Terminated Liquid Poly(butadienes) in Tread Formulations: A Mechanistic Study 196th, Fall 2019 Best Symposium Ed Terrill & Crittenden ARDL, Inc. & University of Testing and Predicting Behavior of Rubber and Tires Ohlemacher Akron 194th, Fall 2018 Best Paper Nuthathai Warasitthinon and Cooper Tire & Rubber Co. The Payne Effect: Primarily Polymer-Related or Filler-Related Phenomenon? Chris Robertson 194th, Fall 2018 Pest Symposum Cal Moreland & Sy Mowdood Michelin USA & Pirelli Advances in Material and Processes of Car and Truck Tires (Retired 192nd, 2017 Best Paper Anke Blume*, Katarzyna S. University of Twente, Influence of Network Structure on Elastomer Properties Fall Bandzierz, Louis A.E.M. Netherlands Reuvekamp, Jerzy Dryzek, Wilma K. Dierkes, Dariusz M. Bielinski 192nd, 2017 Best Symposium Crittenden Ohlemacher & University of Akron & Characterization Tools for Elastomers Fall Michael Warner CCSI, Inc. 190th, Fall 2016 Best Paper Peter Mott U.S. Naval Research The Thermomechanical Response of Polyurea Laboratory, Chemistry Division 190th, Fall 2016 Honorable Mention Steven K Henning and Taejun Yoo Total Cray Valley The Synthesis and Characterization of Farnesene-Based Oligomers 190th 2016 Best Symposium Sy Mowdood and J.
    [Show full text]
  • Toyo Tire Talk
    TOYO TIRE TALK Subject: Rubber Compound ··· Polymers As you will all know well, a tire is mainly made of "rubber" and cords. In the past, we have talked about the important functions of cords. Therefore, this time we would like to talk about the most important material in tires "rubber". When we talk about rubber, we generally mean the rubber compound to be exact. The compound is made by mixing polymer, reinforcement material, softener and various chemicals. Different characteristics are required for every type of tire or tire part. For example, a TBR tire requires heat, wear and cut resistance for the tread rubber, while the sidewall requires good weather resistance. We therefore need many kinds of rubber compounds. In this chapter, we'll talk about polymers, their types, characteristics and uses, that all perform very important functions. The main polymers used for tires are as follows : 1) Natural Rubber (NR) 2) Styrene Butadiene Rubber (SBR) 3) Butadiene Rubber (BR) 4) Isoprene Rubber (IR) 5) Halogenated Butyl Rubber All of the above are synthetic rubber except Natural Rubber of course. 1) Natural Rubber (NR) Characteristics NR is made from latex taken from rubber Advantage Disadvantage trees, mainly grown in Southeast Asia. Tear Strength Uniformity of quality Although there are now various kinds of Wear Resistance Aging Resistance synthetic rubber available, Natural Rubber Impact Resilience Fatigue Resistance is still used extensively in tires. Low Heat Generation Ozone Resistance 2) Styrene Butadiene Rubber (SBR) Characteristics SBR is now the most common synthetic Advantage Disadvantage rubber being used in tires. It is made by Processability Impact Resilience polymerizing Styrene and Butadiene Uniform quality Heat Generation together, it is also possible by changing Aging by heat Styrene content and polymerization process Frictional Force to make various types of SBR's with different characteristics.
    [Show full text]