Classes of Polymeric Materials

1. Classes of Polymeric Materials Professor Joe Greene CSU, CHICO

2. Topics • Introduction • Thermoplastics • General • Commercial plastics • Thermosets • General • Commercial thermosets • Elastomers • General • Commercial elastomers

3. Introduction • Polymeric materials can be either • Thermoplastics, thermosets, and elastomers. • Each section is presented in appropriate groups • Thermoplastics come in a variety of forms • Pellets, powder (1-100 microns), flake, chip, cube, dice, • Shipped in packages of choice • Bags (50 lbs), drums (200 lbs), boxes, cartons, gaylords (1000 lb), • Tank-truck loads (15 tons), rail cars (40 – 80 tons) • Bulk supplies are stored in silos and conveyed pneumatically • Thermosets are supplied in powder or liquid form • Supplied in drums, tank-trucks, and railroad cars. • Rubbers are supplied in bale form.

4. Commercial Thermoplastics • Olefins • Unsaturated, aliphatic hydrocarbons made from ethylene gas • Ethylene is produced by cracking higher hydrocarbons of natural gas or petroleum • LDPE commercialized in 1939 in high pressure process • Branched, high pressure, and low density polyethylene • HDPE commercialized in 1957 in low pressure process • Linear, low pressure, high density • The higher the density the higher the crystallinity • Higher the crystallinity the higher the modulus, strength, chemical resistance, • PE grades are classified according to melt index (viscosity) which is a strong indicator of molecular weight. • Injection molding requires high flow, extrusion grade is highly elastic, thermoforming grade requires high viscosity or consistency

5. Principal Olefin Monomers H H C C H H H H H H H H C C C C C C C2H5 CH3 C5H6 H H H CH3 • Ethylene Propylene • Butene-1 4-Methylpentene

6. Several Olefin Polymers H H H H C C C C H H n CH3 H n H H C C C2H5 H n • Polyethylene Polypropylene • Polyisobutene Polymethylpentene H H C C C5H6 H n CH3

7. Polymers Derived from Ethylene Monomer X Position Material Name Abbreviation H Polyethylene PE Cl Polyvinyl chloride PVC Methyl group Polypropylene PP Benzene ring Polystyrene PS CN Polyacrylonitrile PAN OOCCH Polyvinyl acetate PvaC 3 OH Polyvinyl alcohol PVA COOCH Polymethyl acrylate PMA 3 F Polyvinyl fluoride PVF Note : | Methyl Group is: H – C – H | H Benzene ring is:

8. Addition Polymerization of PE H H H H H H H H H H H H H H H H H H H H C C C C C C C C C C C C C C C C C C C C H H H H H H H H H H H H H H H H H H H … … … … H H C H C H • Polyethylene produced with low (Ziegler) or high pressure (ICI) • Polyethylene produced with linear or branched chains OR n

9. Mechanical Properties of Polyethylene • Type 1: (Branched) Low Density of 0.910 - 0.925 g/cc • Type 2: Medium Density of 0.926 - 0.940 g/cc • Type 3: High Density of 0.941 - 0.959 g/cc • Type 4: (Linear) High Density to ultra high density > 0.959

10. Physical Properties of Polyethylene

11. Processing Properties of Polyethylene

12. Special Low Versions of PolyethyleneProduced through catalyst selection and regulation of reactor conditions • Very Low Density Polyethylene (VLDPE) • Densities between 0.890 and 0.915 • Applications include disposable gloves, shrink packages, vacuum cleaner hoses, tuning, bottles, shrink wrap, diaper film liners, and other health care products • Linear Low Density Polyethylene (LLDPE) • Densities between 0.916 and 0.930 • Contains little if any branching by co-polymerizing ethylene at low pressures in presence of catalysts with small amounts of -olefin co-monomers (butene, hexene, octene) which play the role of uniform short branches along linear backbone. • Properties include improved flex life, low warpage, improved stress-crack resistance, better impact, tear, or puncture versus conventional LDPE • Applications include films for ice, trash, garment, and produce bags at thinner gage.

13. Special High Versions of PolyethyleneProducedthrough catalyst selection and regulation of reactor conditions • Ultra High Molecular Weight Polyethylene (UHMWPE) • Extremely high MW at least 10 times of HDPE (MW=3M to 6M) • Process leads to linear molecules with HDPE • Densities are 0.93 to 0.94 g/cc and Moderate cost • High MW leads to high degree of physical entanglements that • Above Tmelt (130 C or 266F), the material behaves in a rubber-like molecule rather than fluid-like manner causing processing troubles, high viscosities • Processed similar to PTFE (Teflon) • Ram extrusion and compression molding are used.

14. Special High Versions of PolyethyleneProduced through catalyst selection and regulation of reactor conditions • Ultra High Molecular Weight Polyethylene (UHMWPE) • Properties include outstanding properties like engineering plastic or specialty resin • Chemical inertness is unmatched; environmental stress cracking resistance and resistance to foods and physiological fluids, • Outstanding wear or abrasion resistance, very low coefficient of friction, excellent toughness and impact resistance. • Applications: • pump parts, seals, surgical implants, pen tips, and butcher-block cutting surfaces. , chemical handling equipment, pen tips, prosthetic wear surfaces, gears

15. Special Forms of Polyethylene • Cross-linked PE (XLPE) • Chemical cross-links improve chemical resistance and improve temperature properties. • Cross-linked with addition of small amounts of organic peroxides • Dicumyl peroxide, etc. • Crosslinks a small amount during processing and then sets up after flowing into mold. • Used primarily with rotational molding • Extruded Products • Films (shrink wrap film in particular) • Pipes • Electrical wire and cable insulation

16. Copolymers of Polyethylene H H H H C C C C H H H O C = O C n m • Ethylene-Vinyl Acetate (EVA) • Repeating groups is ethylene with a vinyl acetate functional that reduces the regularity of the chain; thus the crystallinity and stiffness • Part of the pendent group are highly polar which makes film with increased water vapor permeability, increased oil resistance and cling. • Vinyl acetate reduces crystallinity and increases chemical reactivity because of high regions of polarity. • Applications include flexible packaging, shrink wrap, auto bumper pads, flexible toys, and tubing with vinylacetate up to 50%

17. Copolymers of Polyethylene • Ethylene-vinyl alcohol (EVOH) • Contains equal amounts of two repeat units that act as • Barrier layers or as interlayers (tie layers) between incompatible materials due to strong bonding of vinylalcohol repeat units. • Ethylene-ethyl acrylate (EEA) Ethylene-methyl acrylate (EMA) • Properties range from rubbery to tough ethylene-like properties • Applications include hot melt adhesives, shrink wrap, produce bags, bag-in-box products, and wire coating. • Produced by addition of methyl acrylate monomer (40% by weight) with ethylene gas • reduces crystallinity and increases polarity • Tough, thermally stable olefin with good rubber characteristics. • Applications include food packaging, disposable medical gloves, heat-sealable layers, and coating for composite packaging

18. Copolymers of Polyethylene • Ethylene-carboxylic acid (EAA, EMAA) • Small amounts of acrylic acid (AA) or methacrylic acid (MAA) that feature carboxyl acid groups (COOH) are notable adhesives, especially to polar substrates, including fillers and reinforcements • Problems include tackiness and corrosive to metals and crosslinking nature • Ionomers • Modified ethylene-methacrylic acid copolymers where some of the carboxyl acid groups are converted into corresponding metallic salts (metal metacrylate), where the metals are sodium or zinc. • Ionic bonds are formed between these cationic and the remaining anionic acid groups. Results in a quasi crosslinked polymer at low temperature and is reversible at high temperature • Useful properties, e.g., adhesive and paints to metals (polarity), resistance to fats and oils, Flex, puncture, impact resistance • Applications: golf balls, bowling pin covers, ski boot shells, films

19. Copolymers of Polyethylene H H H H C C C C H CH3 H H n m • Ethylene-Propylene (EPM) • Ethylene and propylene are copolymerized in random manner and causes a delay in the crystallization. • Thus, the copolymer is rubbery at room temp because the Tg is between HDPE (-110C) and PP (-20C). • Ethylene and propylene can be copolymerized with small amounts of a monomer containing 2 C=C double bonds (dienes) • Results in a co-polymer, EPR, or thermoplastic rubber, TPR

20. Mechanical Properties of PE Blends

21. Processing Properties of PE Blends

22. Polypropylene History • Prior to 1954 most attempts to produce plastics from polyolefins had little commercial success • PP invented in 1955 by Italian Scientist F.J. Natta by addition reaction of propylene gas with a sterospecific catalyst titanium trichloride. • Isotactic polypropylene was sterospecific (molecules are arranged in a definite order in space) • PP is not prone to environmental stress-cracking like PE • Polypropylene is similar in manufacturing method and in properties to PE • Tg of PP = -25C versus Tg of PE of -100C

23. Chemical Structure H H H H H H H H H H H H C C C C C C C C C C C C CH3 CH3 CH3 CH3 CH3 CH3 H H H H H H • Propylene • Isotactic- CH3 on one side of polymer chain (isolated). Commercial PP is 90% to 95% Isotactic n

24. Polypropylene Stereostatic Arrangements H H H H H H H H H H CH3 H CH3 H H H CH3 H CH3 CH3 C C C C C C C C C C C C C C C C C C C C CH3 CH3 H CH3 CH3 H H H CH3 H H H H H H H H H H H • Atactic- CH3 in a random order (A- without; Tactic- order) Rubbery and of limited commercial value. • Syndiotactic- CH3 in a alternating order (Syndio- ; Tactic- order)

25. Addition Polymerization of PP • Polypropylene produced with low pressure process (Ziegler) • Polypropylene produced with linear chains • Polypropylene is similar in manufacturing method and in properties to PE • Differences between PP and PE are • Density: PP = 0.90; PE = 0.941 to 0.965 • Melt Temperature: PP = 176 C; PE = 110 C • Tg of PP = -25C versus Tg of PE of -100C • Service Temperature: PP has higher service temperature • Hardness: PP is harder, more rigid, and higher brittle point • Stress Cracking: PP is more resistant to environmental stress cracking

26. Advantages/Disadvatages of Polypropylene • Disadvantages • High thermal expansion • UV degradation • Poor weathering resistance • Subject to attack by chlorinated solvents and aromatics • Difficulty to bond or paint • Oxidizes readily • flammable • Advantages • Low Cost • Excellent flexural strength • Good impact strength • Processable by all thermoplastic equipment • Low coefficient of friction • Excellent electrical insulation • Good fatigue resistance • Excellent moisture resistance • Service Temperature to 126 C • Very good chemical resistance

27. Mechanical Properties of Polypropylene

28. Physical Properties of Polyethylene

29. Processing Properties of Polyethylene

30. Several Olefin Polymers H H H H C C C C HCH H n H3C C CH3 C2H5 H n • Polybutylene (PB) • Based on butene-1 monomer • Plus comonomers (small amt) • Melt Point 125C similar to PE • Tg, -25C is closer to PP • Good creep & ESC resistance • Good for pipe and film extrusions • Polymethylpentene (PMP) • Trade name is TPX • Crystallizes to high degree (60%) • Highly transparent (90% transmis) • Properties similar to PP • Density is 0.83 g/cc, Tg =30C • Stable to 200C, Tm=240C • Creep and chemical resistance is good and low permeability. • Electrical properties are excellent • Process by injection & extrusion • Good for lighting, packaging, trays, bags, coffee makers, wire covering, connectors, syringes. • Poor ESC and UV H

31. Polyolefin_Polybutylene H H CH3 C C CH2 H • History • PB invented in 1974 by Witco Chemical • Ethyl side groups in a linear backbone • Description • Linear isotactic material • Upon cooling the crystallinity is 30% • Post-forming techniques can increase crystallinity to 55% • Formed by conventional thermoplastic techniques • Applications (primarily pipe and film areas) • High performance films • Tank liners and pipes • Hot-melt adhesive • Coextruded as moisture barrier and heat-sealable packages

32. Properties of Polybutylene

33. Polyolefin_Polymethylpentene (PMP) H H C C CH2 H • Description • Crystallizes to 40%-60% • Highly transparent with 90% transmission • Formed by injection molding and blow molding • Properties • Low density of 0.83 g/cc; High transparency • Mechanical properties comparable to polyolefins with higher temperature properties and higher creep properties. • Low permeability to gasses and better chemical resistance • Attacked by oxidizing agents and light hydrogen carbon solvents • Attacked by UV and is quite flammable • Applications • Lighting elements (Diffusers, lenses reflectors), liquid level • Food packaging containers, trays, and bags. H3C-CH-CH3

34. Properties of Polymethylpentene

35. PVC Background • Vinyl is a varied group- PVC, PVAc, PVOH, PVDC, PVB • Polyvinyls were invented in 1835 by French chemist V. Regnault when he discovered a white residue could be synthesized from ethylene dichloride in an alcohol solution. (Sunlight was catalyst) • PVC was patented in 1933 by BF Goodrich Company in a process that combined a plasticizer, tritolyl phosphate, with PVC compounds making it easily moldable and processed. • PVC is the leading plastic in Europe and second to PE in the US. • PVC is made by suspension process (82%), by mass polymerization (10% ), or by emulsion (8%) • All PVC is produced by addition polymerization from the vinyl chloride monomer in a head-to-tail alignment. • PVC is amorphous with partially crystalline (syndiotactic) due to structural irregularity increasing with the reaction temperature. • PVC (rigid) decomposes at 212 F leading to dangerous HCl gas

36. PVC and Vinyl Products • Rigid-PVC • Pipe for water delivery • Pipe for structural yard and garden structures • Plasticizer-PVC or Vinyl • Latex gloves • Latex clothing • Paints and Sealers • Signs

37. PVC and PS Chemical Structure H H H Cl H H C C C C C C H H H Cl OH Cl n n n n H H H H C C C C H n H OCOCH3 • Vinyl Groups (homopolymers produced by addition polymerization) • PVC - poly vinylidene - polyvinylalcohol (PVOH) chloride (PVDC) • polyvinyl acetate (PVAc) - PolyStyrene (PS)

38. Mechanical Properties of Polyvinyls

39. Physical Properties of Polyvinyls

40. Processing Properties of Polyvinyls

41. Vinylchloride Co-Polymers • Chlorinated PVC (CPVC) • Possible to chemically modify PVC by substituting Cl for H • Cl content can be raised from 56.8% in PVC to 62%-72% • CPVC has improved chemical and temperature resistance that can be used for pipe and hot water applications, even boiling water. • Vinylchloride-vinylacetate (PVC-VAC) • Internally plasticizing PVC with 3% to 30% vinyl acetate • Impact properties and processing ease are improved for • Floor coverings, phonograph records. • Polyalloys • Improves impact resistance of rigid PVC by blending with elastomers, e.g., EVA, Nitrile rubber (NBR), Chloronated PE. • Blend PVC with PMMA and SAN for better transparency • Blend PVC with ABS for improved combustion resistance

42. Vinylchloride Co-Polymers H Cl C C H Cl n H H C C n H OCOCH3 • Polyvinylidenechloride (PVDC) • Homopolymer can crystallize. Tg = -18C, Tm = 190C • Decomposition temperature is slightly above melt temperature of abut 200C • PVDC has outstanding barrier properties for O2, CO2, and H2O. • Copolymerized with 10-15% vinyl chloride to create Saran Wrap. • Copolymerize with acrlonitrile and acrylate esters up to 50%. • Coplymerization reduces crystallinity to 35-45% and the Tmelt ot 175C • Polyvinyl acetate (PVAC) • Not used as a plastic • Noncrystallizing • Low Tg = 30C, it is • It is best as a major ingredient in adhesives and paint, Elmers Glue • Vinylacetate repeat units form the minor component in imporant copolymers with vinylchloride (PVC-PVAC) and ethylene (EVA)

43. Vinylchloride Co-Polymers H H C C OH H n CH2 CH3 H H C C n H CH2 • Polyvinylalcohol (PVAL or PVOH) • Homopolymer is very polar can crystallize • Water soluable. Tg = 80C, Tm = 240C • Random copolymer that is derived from PVAC • Used as a release film for reinforced plastics or barrier film. • Polyvinylbutyral (PVB) • Random copolymer (PVB-PVAL) • containing 10-15% VAL • Low Tg = 50C • Used in plasticized form as adhesive interlayer • For windshield safety glass (Saflex from Monsanto) • Powder is extruded into sheet and then placed between two layers of glass • Requires • Toughness, transparency, weatherability, and adhesion to glass.

44. PS Background • PS is one of the oldest known vinyl compounds • PS was produced in 1851 by French chemist M. Berthelot by passing benzene and ethylene through a red-hot-tube (basis for today) • Amorphous polymer made from addition polymerization of styrene • Homopolymer (crystal): (2.7 M metric tons in ’94) GPPS (General Purpose PS) • Clear and colorless with excellent optical properties and high stiffness. • It is brittle until biaxially oriented when it becomes flexible and durable. • Graft copolymer or blend with elastomers- High Impact Polystyrene (HIPS): • Tough, white or clear in color, and easily extruded or molded. • Properties are dependent upon the elastomer %, but are grouped into • medium impact (Izod<1.5 ft-lb), high impact (Izod between 1.5 to 2.4 ft-lb) and super-high impact (Izod between 2.6 and 5 ft-lb) • Copolymers include SAN (poly styrene-acrylonitrile), SMA (maleic anhydride), SBS (butadiene), styrene and acrylic copolymers. • Expandable PS (EPS) is very popular for cups and insulation foam. • EPS is made with blowing agents, such as pentane and isopentane. • The properties are dependent upon cell size and cell size distribution

45. Polystyrene Polymers CH3 CH3 n n H H H C C C C H H • Poly-para-methyl-styrene (PPMS) • Similar to PS (Tg=100C) with a slightly higher Tg=110C • Low cost alternative to PS in homo and co-polymers • Poly-alpha-methyl-styrene (PAMS) • High Tg =160C and better Temp resistance • Not much commercial importance by itself • Has significant use in copolymers • Rubber-toughened impact polystyrene (HIPS) • Random copolymerization with small fraction of elastomer type repeat units. Lowers Tg • Block copolymerization of elastomeric component is more expensive, but keeps Tg same as PS

46. PSB, SAN, ABS Chemical Structure H H H H C C C C H H H H H CH3 C:::N CH3 n m C C C C CH3 CH3 H C:::N n m H H H H H H C C C C C C H H H k k k • PSB (copolymer -addition) * Styrene- acrylonitrile (SAN) • ABS acrylonitrile butadiene styrene (Terpolymer- addition)

47. Polystyrene Co-Polymers • Styrene-Butadiene (PSB) • Tg= % of each PS (100C) and Butadiene (-80C) • Example, 50% PS and 50% B, Tg=10C • Easy to copolymerize and can be rubbery (butadiene-dominant) or plastic like (styrene-like), out 70% of the PSB is styrene dominant • Random (styrene dominant) copolymers have been used in emulsion (latex) form to produce coatings (paints). • Block copolymers are commercial butadiene styrene-plastics • Styrene Acrylonitrile (SAN) • Random copolymer of 30% polyacrylonitrile repeat units yields • Increased Temp performance and transparent, ease to process • Resistant to food and body oils • Used for transparent medical products, houseware care items • Polyalloys (blends) with polysulphone

48. Polystyrene Co-Polymers • Acrylonitrile Butadiene Styrene (ABS) • First introduced in the late 1940s as replacement for rubber. • Terpolymer: Three repeat units vary according to grade (20%A, 20%B, 60%S) • Acrylonitrile for chemical and temperature resistance • Butadiene for impact resistance; Styrene for cost and processability • Graft polymerization techniques are used to produce ABS • Very versatile applications that are injection molded and extruded • Rigid pipes and fittings, thermoformed refrigerator door liners, Legos toys • Small boat hulls, telephone and computer housings • Family of materials that vary from high gloss to low matte finish, and from low to high impact resistance. • Additives enable ABS grades that are flame retardant, transparent, high heat-resistance, foamable, or UV-stabilized • ABS-based polyalloys (blends) • PVC/ABS for flame resistance • TPU/ABS for polyurethane; PSU/ABS for polysulphone • PC/ABS for temperature and impact resistance (Saturn door) • .

49. Mechanical Properties of PS, ABS, SAN n H H C C H Tg =100C

50. Physical Properties of PS, ABS, SAN