HANDBOOK OF Antiblocking, Release, and Slip Additives George Wypych ChemTecPublishing Toronto 2005 PublishedbyChemTecPublishing 38EarswickDrive,Toronto,OntarioM1E1C6,Canada ©ChemTecPublishing,2005 ISBN1-895198-31-3 All rights reserved. No part of this publication may be reproduced, stored or transmitted in any form or by any means without written permission of copyright owner.NoresponsibilityisassumedbytheAuthorandthePublisherforanyinjury or/anddamagetopersonsorpropertiesasamatterofproductsliability,negligence, use, or operation of any methods, product ideas, or instructions published or suggestedinthisbook. CanadianCataloguinginPublicationData Wypych,George Handbookofantiblocking,release,andslipadditives/GeorgeWypych.--1sted. Includesbibliographicalreferencesandindex. ISBN1-895198-31-3 1.Polymers--Additives.2.Polymers--Additives--Healthaspects. 3.Polymers--Additives--Environmentalaspects. I.Title. TP1142.W9642004 668.9 C2004-906653-6 PrintedinCanadabyTranscontinentalPrintingInc.,505ConsumersRd. Toronto,OntarioM2J4V8 Table of Contents i Table of Contents 1 INTRODUCTION 1 1.1 Historical developments 1 1.2 Expectations from commercial additives 2 1.3 Definitions 3 1.4 Classification 4 References 6 2 GENERIC TYPES 7 2.1 Introduction 7 2.2 Characteristic properties of commercial additives 7 2.2.1 Antiblocking agents 7 2.2.1.1 Inorganic 7 2.2.1.1.1 Calcium carbonate 8 2.2.1.1.2 Carbon nanotubes, fibers, graphite 9 2.2.1.1.3 Ceramic and glass spheres and fly ash 10 2.2.1.1.4 Diatomaceous earth and other natural silicas 11 2.2.1.1.5 Synthetic silica 12 2.2.1.1.6 Synthetic clay (laponite) 13 2.2.1.1.7 Talc 14 2.2.1.1.8 Zeolite 15 2.2.1.2 Organic 16 2.2.1.2.1 Microparticles 16 2.2.2 Mold release agents 17 2.2.2.1 Fluorocompounds 17 2.2.2.2 Polydimethylsiloxanes 18 2.2.2.3 Polymeric waxes 19 2.2.2.4 Other chemical compounds 20 2.2.3 Slip agents 21 2.2.3.1 Acids 21 2.2.3.2 Esters 22 2.2.3.3 Fatty acid amides 23 2.2.3.4 Natural wax and its substitutes 24 2.2.3.5 Salts 25 References 25 ii Table of Contents 3 STANDARD METHODS OF CONTROL 27 3.1 Adhesives 27 3.2 Floor coverings 28 3.3 Footwear and walkway surfaces 28 3.4 Geosynthetics 29 3.5 Leather and coated fabrics 29 3.6 Lubricants 30 3.7 Medical 31 3.8 Paints and coatings 31 3.9 Paper 31 3.10 Plastics and rubber 32 3.11 Roads and pavement 33 3.12 Sport equipment 34 3.13 Textiles 35 References 35 4 TRANSPORTATION AND STORAGE 41 4.1 Transportation 41 4.2 Storage 42 References 43 5 MECHANISMS OF ACTION 45 5.1 Antiblocking agents 45 5.2 Slip agents 53 5.3 Release agents 56 References 58 6 COMPATIBILITY AND PERFORMANCE 61 References 64 7 DIFFUSION AND MIGRATION 67 7.1 Diffusion 67 7.2 Distribution of additive in bulk and on surface 69 7.3 How mobility affects additive selection? 72 7.4 Additive transfer to material in contact 73 7.5 Additive loss 74 References 75 Table of Contents iii 8 INTERACTION WITH OTHER COMPONENTS OF FORMULATION 77 8.1 Fillers 77 8.2 Other components of formulation 79 8.3 Synergy between surface additives 80 8.4 Other properties 82 References 82 9 PROCESSING AND ADDITIVE PERFORMANCE 85 References 87 10 EFFECT ON PRODUCT PROPERTIES 89 10.1 Mechanical properties 89 10.2 Mar and abrasion 91 10.3 Shrinkage and warpage 92 10.4 Blocking force 93 10.5 Adhesion to mold and demolding 95 10.6 Coefficient of friction 99 10.7 Residues on molds 104 10.8 Residues on molded parts 105 10.9 Optical properties 105 10.10 Rheological properties 108 10.11 Electrical properties 111 10.12 Structure and orientation 111 10.13 Thermal aging 113 10.14 UV radiation 115 10.15 Effect on other properties 115 References 117 11 USE IN SPECIFIC POLYMERS 121 11.1 ABS 121 11.2 Acrylics 123 11.3 Bromobutyl rubber 125 11.4 Cellulose acetate 126 11.5 Cellulose, acetate, butyrate and propionate 127 11.6 Cellulose nitrate 128 11.7 Chlorinated polyvinylchloride 129 11.8 Chlorosulfonated polyethylene 129 iv Table of Contents 11.9 Copolymers 130 11.10 Cyanoacrylates 133 11.11 Ethyl cellulose 133 11.12 Ethylene-propylene-diene copolymer, EPDM 134 11.13 Ethylene-propylene rubber, EPR 136 11.14 Epoxy resin 137 11.15 Ethylene-vinyl acetate copolymer, EVA 138 11.16 Ionomers 140 11.17 Nitrile rubber 141 11.18 Polyamide 141 11.19 Polybutadiene 142 11.20 Polycarbonate 143 11.21 Polyester 145 11.22 Polyetherimide 147 11.23 Polyethylene 148 11.24 Polyimide 155 11.25 Polylactide 156 11.26 Polymethylmethacrylate 157 11.27 Polyoxymethylene 159 11.28 Poly(N-vinylcarbazole) 159 11.29 Polyphenylene ether 160 11.30 Polypropylene 161 11.31 Polystyrene 164 11.32 Polysulfone 166 11.33 Poly(phenylene sulfide) 166 11.34 Polyvinylacetate 167 11.35 Polyvinylalcohol 167 11.36 Polyvinylbutyral 168 11.37 Polyvinylchloride 168 11.38 Polyurethanes 170 11.39 Proteins 173 11.40 Rubber, natural 174 11.41 Silicone 174 11.42 Styrene-butadiene rubber 176 11.43 Styrene-butadiene-styrene 176 11.44 Starch 177 References 178 12 USE IN INDUSTRIAL PRODUCTS 187 12.1 Adhesives and sealants 187 12.2 Aerospace 189 Table of Contents v 12.3 Agriculture 190 12.4 Automotive applications 192 12.5 Bottles 194 12.6 Ceramic materials 196 12.7 Composites 197 12.8 Coated fabrics 197 12.9 Cosmetics 199 12.10 Dental materials 199 12.11 Electronics 200 12.12 Fibers 202 12.11 Film 203 12.12 Food 212 12.13 Foams 213 12.14 Gaskets 215 12.15 Inks, varnishes, and lacquers 215 12.16 Medical devices 216 12.17 Membranes 217 12.18 Paints and coatings 217 12.19 Pharmaceutical products 218 12.20 Photographic materials 220 12.21 Pipes 222 12.22 Roofing materials 222 12.23 Tires 223 12.24 Toys 225 12.25 Wire & cable 225 References 225 13 VARIOUS PROCESSING METHODS 231 13.1 Blow molding 231 13.2 Calendering 233 13.3 Coextrusion 233 13.4 Compression molding 234 13.5 Compounding (mixing) 237 13.6 Dip coating 238 13.7 Dryblending 240 13.8 Extrusion 241 13.9 Extrusion blow molding 244 13.10 Injection molding 246 13.11 Printing 249 13.12 Reaction injection molding 252 13.13 Rotational molding 253 vi Table of Contents 13.14 Rubber processing 254 13.15 Slip casting 255 13.16 Thermoforming 256 13.17 Transfer molding 257 References 257 14 SPECIALIZED ANALYTICAL METHODS 261 14.1 Identification 261 14.2 Determination of concentration 262 14.3 Determination of volatility and molecular motion 263 14.4 Study of materials containing additives 265 References 267 15 MATHEMATICAL MODELLING 269 References 271 16 HEALTH, SAFETY AND ENVIRONMENTAL 273 16.1 Antiblocking agents 273 16.1.1 Inorganic 273 16.1.1.1 Calcium carbonate 273 16.1.1.2 Carbon related materials 274 16.1.1.3 Ceramic and glass spheres and fly ash 274 16.1.1.4 Diatomaceous earth and natural silicas 274 16.1.1.5 Synthetic silica 275 16.1.1.6 Synthetic clay (laponite) 275 16.1.1.7 Talc 275 16.1.2 Organic 276 16.1.2.1 Microparticles 276 16.2 Release agents 276 16.2.1 Fluorocompounds 276 16.2.2 Polydimethylsiloxane 276 16.2.3 Polymeric waxes 277 16.2.4 Other chemical compounds 277 16.3 Slip agents 278 16.3.1 Acids 278 16.3.2 Esters 278 16.3.3 Fatty acid amides 278 16.3.4 Natural wax 279 16.3.5 Salts 279 Table of Contents vii 17 REGULATIONS AND DATA 281 17.1 Toxic substance control 281 17.2. Carcinogenic effect 283 17.3 Workplace exposure limits 284 17.4 Food regulatory acts 286 References 288 18 PERSONAL PROTECTION 289 18.1 Clothing 289 18.2 Gloves 290 18.3 Eye protection 292 18.4 Respiratory protection 293 References 297 INDEX 299 1 Introduction 1.1 HISTORICAL DEVELOPMENTS Surface blocking was a technological hurdle for as long as humans began to pro- cess materials. In ancient times natural products were used to improve technologi- cal output and quality. These included beeswax, plant waxes, natural resins, oils, etc. They were used advantageously in cosmetics (e.g., creams used by Cleopatra in Egypt), plasters (e.g., wall plasters in Pompei, Italy), molds, etc. The priority of application of modern additives is not documented in research publications but the use of antiblocking, release, and slip agents is rather recent advancements of technological processes. This is easy to predict knowing the ori- gin of several materials involved in their production. Stearic acid is the oldest syn- thetic material used in material processing. It was first obtained by French chemist Chevreul who began studies of soaps and isolated the most common fatty acids. In 1825, together with Gay-Lussac, Chevreul patented use of stearic acid in candle manufacturing. It took about a century to apply stearic acid in polymer processing. Calcium stearate was first used for commercial purposes by Harrison in 1924.1 Crambe abyssinica, which is a cool-season oilseed containing large concen- trations of erucic acid, was introduced in the United States of America in 1940 by the Connecticut Agricultural Experiment Station.2 About 39% of high-erucic-acid oils are now used for production of erucamide, which is a common slip agent.2 The first major paper on mold release was published in 1946 by Ziegler.3 It contained a thorough analysis of the influence of mold material on release proper- ties. Even more important, the paper3 contained a proposal for a new method of mold release testing, which gave the fundamental tool for rational analysis of the problem. More than twenty of the so-called “mold lubricants” were tested by the newly developed pull-out force method. In addition, the effect of “lubricant” on product clarity was observed − both results being considered in the final selection. In the best cases, the decrease of up to 80% of pull-out force was obtained with these tested “lubricants”. Plasticizers and pigments were also found to facilitate mold release properties in combination with mold release agents. Film wrapping and handling characteristics were of major concern for film producers and these prompted studies of slip agents. The first major paper on improvement of friction coefficient of polypropylene film was published in 19664