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MECHANICAL, CHEMICAL AND FLAMMABILITY PROPERTIES OF ABS/PVC BLENDS PM DR SHAHRIR HASHIM PM DR AZMAN HASSAN CHEW SAU YEN NO. VOT PENYELIDIKAN 71820 JABATAN KEJ. POLIMER FAK. KEJ. KIMIA DAN KEJ. SUMBER ASLI UTM SKUDAI, JOHOR PENGHARGAAN Pertama sekali saya ingin mengucapkan setinggi-tinggi terima kasih kepada pihak UPP Universiti Teknologi Malaysia kerana memberikan peruntukkan kewangan melalui Vot 71820 membolehkan saya menjalankan projek penyelidikan ini dengan jayanya. Perhargaan yang ikhlas ditujukan kepada PM Dr Azman Hassan sebagai ahli penyelidik serta penyelia bersama untuk pelajar master, Chew Sau Yen. Penghargaan juga ditujukan kepada rakan-rakan yang telah menjayakan projek ini secara langsung ataupun tidak langsung. xiv LIST OF FIGURES FIGURE No. TITLE PAGE 2.1 Engineered plastics demand, 2001 8 2.2 Emulsion ABS polymerization process 12 2.3 Major property trade-offs for ABS with increasing 14 rubber level (Glenn and Cathleen, 1985) 2.4 Aotomotive Award and People’s Choice Award: 23 Unibody plastic trailer 2.5 ABS resin speeds motorbike to market 24 2.6 Industrial Enclosure Award: Printer/embosser 24 enclosure for a tabletop card personalization system 2.7 Feedstock conversion to vinyl chloride 27 2.8 Oxychlorination process 28 2.9 PVC particle morphology 29 2.10 Schematic curve showing the effect of molecular 30 weight on most mechanical properties of PVC. The exact nature of the plot will depend on the mechanical property selected (Donald, 1986). 2.11 PVC pumps stand up to chemicals, rough use 37 2.12 Vinyl outsoles resist harsh chemicals and oils 37 2.13 High impact PVC sparks electric fence 37 2.14 Critical Barrier Packaging Award: Package for 37 medical components 2.15 Thermoplastic worldwide forecast 38 2.16 Schematic representation of polymer degradation 44 2.17 Polymer combustion process cycle 46 xv 2.18 A typical flame involving organic fuel showing 47 decomposition region where volatilized fuel decomposes before combustion. 2.19 Effect of antimony oxide concentration on the 49 properties of ABS containing 13wt% flame retardant 2.20 Stress concentration around a hole (Charles, 1996) 53 2.21 Surface roughness versus fracture energy for several 54 cured epoxies 2.22 Thermal shrinkage stress directions developed by 56 differential contraction in rubber and glass during cooling 2.23 Crazing cusp for PMMA 56 2.24 Properties versus polymer/polymer ratio in a 58 polyblend 2.25 Morphologies of a blend of polymer A (solid line) 59 and polymer B (dashed line) (a) miscible; (b) immiscible; (c) partially miscible (Fox and Allen, 1985) 2.26 E’ – E” versus temperature for polybutadiene in 61 styrene acrylonitrile copolymer (SAN); -------- experimental; and ______ calculated: (SAN)/PBD : ○, 77/23; and ●, 56/44 (Moore, 1989) 2.27 E’ and E” vs temperature for blended system of 62 PVC and NBR of various compositions (PVC/NBR) at 138 Hz: ○, 100/0; x, 83/17; □, 67/33; ∆,50/50; ©, 20/80; and ●, 0/100 (Moore, 1989) 3.1 Mould for injection moulding specimen 69 3.2 Izod Impact Tester 70 3.3 Dimension for Izod type test specimen 71 3.4 A schematic diagram of a DMA used to determine 72 the compatibility of the blends (Perkin-Elmer Instrument) xvi 3.5 DMA three point bending system 72 3.6 Photograph of SEM JSM 5610 73 3.7 Photograph of Instron universal tester 74 3.8 Typical equipment layout for oxygen index test 76 3.9 Heat distortion tester S-3 machine 77 4.1 Effect of different PVC molecular weight and 80 content on Izod impact strength of high rigidity ABS 4.2 Effect of different PVC molecular weight and 81 content on Izod impact strength of medium impact ABS 4.3 Effect of different PVC molecular weight and 82 content on Izod impact strength of super high impact ABS 4.4 Effect of ABS grades and PVC content on Impact 83 strength of PVC K-58 4.5 Effect of ABS grades and PVC content on Impact 84 strength of PVC K-66 4.6 Effect of ABS grades and PVC content on Impact 85 strength of acrylic grafted PVC 4.7 Notch Izod impact strength of PVC/ABS blends at 86 23oC showing the toughness achieved by balancing matrix ductility against PVC content (Deanin and Moshar, 1974) 4.8 Typical dipole-dipole interaction and segments of 88 chains between molecules of PVC and SAN 4.9 DMA curves for high rigidity ABS as a function of 95 E”/E’ and tan δ 4.10 DMA curves for high rigidity ABS – PVC K66 as a 95 function of E”/E’ and tan δ 4.11 DMA curves for medium impact ABS as a function 96 of E”/E’ and tan δ 4.12 DMA curves for medium impact ABS – PVC K66 96 xvii as a function of E”/E’ and tan δ 4.13 DMA curves for super high impact ABS as a 97 function of E”/E’ and tan δ 4.14 DMA curves for super high impact ABS - PVC K66 97 as a function of E”/E’ and tan δ 4.15 Schematic stress-whitening zone of Izod impact 99 specimen, near the edge and on the fracture surface region 4.16A SEM micrographs of the fractured surfaces of the 101 virgin high rigidity ABS (Magnification X200) 4.16B SEM micrographs of the fractured surfaces of the 101 virgin high rigidity ABS (Magnification X2000) 4.17A SEM micrographs of the fractured surfaces of the 102 high rigidity ABS/PVC K-66 (90/10 phr/phr) (Magnification X200) 4.17B SEM micrographs of the fractured surfaces of the 102 high rigidity ABS/PVC K-66 (90/10 phr/phr) (Magnification X2000) 4.18A SEM micrographs of the fractured surfaces of the 103 super high impact ABS/PVC K-66 (80/20 phr/phr) (Magnification X200) 4.18B SEM micrographs of the fractured surfaces of the 103 super high impact ABS/PVC K-66 (80/20 phr/phr) (Magnification X2000) 4.19A SEM micrographs of the fractured surfaces of the 104 medium impact ABS/acrylic grafted PVC (85/15 phr/phr) (Magnification X200) 4.19B SEM micrographs of the fractured surfaces of the 105 medium impact ABS/acrylic grafted PVC (85/15 phr/phr) (Magnification X2000) 4.20 Forces involved in a simple beam (Vishu, 1998) 107 4.21 Effect of PVC molecular weight on heat distortion 118 temperature of high rigidity ABS xviii 4.22 Effect of PVC molecular weight on heat distortion 119 temperature of medium impact ABS 4.23 Effect of PVC molecular weight on heat distortion 120 temperature of super high impact ABS 4.24 Determination of balance properties based on 128 impact strength and flexural modulus of high rigidity ABS 4.25 Determination of balance properties based on 129 impact strength and flexural modulus of medium impact ABS 4.26 Determination of balance properties based on 129 impact strength and flexural modulus of super high impact ABS 4.27 Determination of balance properties based on 130 impact strength and flexural modulus for selected ABS/PVC blends xxi LIST OF APPENDICES APPENDIX TITLE PAGE A A technological scheme of the production of ABS 152 polymer by the blending technique B Comparison between suspension, mass and 153 emulsion polymerization C A technological scheme of the production of ABS 154 polymer by grafting in emulsion D Scheme of the production of ABS polymer by the 155 emulsion-mass technology E Block flow diagram for PVC by suspension process 156 F PVC by mass process block flow diagram 157 G Block flow diagram for PVC by emulsion process 157 H Calculation of cost per unit volume of pure ABS 158 and ABS/PVC blends I Published paper 170 xii LIST OF TABLES TABLE No. TITLE PAGE 2.1 Effect of molecular characteristics of the elastomer 13 phase and SAN copolymer forming the matrix 2.2 Historical background of PVC 26 2.3 Blends with ABS (Adam et.al, 1993) 39 2.4 Impact strength data for various PVC/ABS blends 40 (Datta and Lohse, 1996) 2.5 Impact strength data for various ABS compositions 41 blended with PVC (Datta and Lohse, 1996) 2.6 Burning characteristics, burn rates and LOI index of 45 some polymers 2.7 Properties of flame retardant ABS resin 50 2.8 Oxygen index of various metal-stabilized PVC 51 samples 3.1 Typical properties of Toyolac ABS 64 3.2 Types, trade name, manufacturer and Purpose of 65 ABS and PVC 3.3 Types, trade name, manufacturer and purpose of 66 additives 3.4 Blend formulation 67 3.5 Extrusion operating conditions 68 3.6 Injection moulding operation condition 69 3.7 Dimension measurement for Izod type test specimen 71 4.1 Transition temperature of loss tan delta for selected 93 materials xiii 4.2 Flexural modulus for ABS/PVC blends 107 4.3 LOI index for ABS 111 4.4 LOI index for ABS/PVC blends 113 4.5 MFI data for ABS 122 4.6 MFI data for ABS obtained from Toray Plastics 122 4.7 Melt flow index for ABS/PVC blends 123 4.8 Calculation of cost per unit volume of pure ABS 126 and ABS/PVC blends 4.9 Relationship between impact properties, flexural 131 modulus, cost per unit volume and flame retardancy of selected ABS/PVC blends

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MECHANICAL, CHEMICAL AND FLAMMABILITY. PROPERTIES OF ABS/PVC BLENDS. PM DR SHAHRIR HASHIM. PM DR AZMAN HASSAN. CHEW SAU
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