Thermosetting polymer

A thermosetting polymer, also called a thermoset, is a polymer that is irreversibly cured from a soft solid or viscous liquid prepolymer or resin.[1] The process of curing changes the resin into an infusible, insoluble polymer network, and is induced by the action of heat or suitable radiation often under high pressure, or by mixing with a catalyst.

Thermoset resins are usually malleable or liquid prior to curing, and are often designed to be molded into their final shape, or used as adhesives. Others are solids like that of the molding compound used in semiconductors and integrated circuits. Once hardened a thermoset resin cannot be reheated and melted to be shaped differently.

Thermosetting polymers may be contrasted with thermoplastic polymers, which are commonly produced in pellets, and shaped into their final product form by melting and pressing or injection molding.

Process

Curing a thermosetting resin transforms it into a plastic, or elastomer (rubber) by crosslinking or chain extension through the formation of covalent bonds between individual chains of the polymer. Crosslink density varies depending on the monomer or prepolymer mix, and the mechanism of crosslinking:

Acrylic resins, polyesters and vinyl esters with unsaturated sites at the ends or on the backbone are generally linked by copolymerisation with unsaturated monomer diluents, with cure initiated by free radicals generated from ionizing radiation or by the photolytic or thermal decomposition of a radical initiator – the intensity of crosslinking is influenced by the degree of backbone unsaturation in the prepolymer;[2]

Epoxy functional resins can be homo-polymerized with anionic or cationic catalysts and heat, or copolymerised through nucleophilic addition reactions with multifunctional crosslinking agents which are also known as curing agents or hardeners. As reaction proceeds, larger and larger molecules are formed and highly branched crosslinked structures develop, the rate of cure being influenced by the physical form and functionality of epoxy resins and curing agents[3] – elevated temperature postcuring induces secondary crosslinking of backbone hydroxyl functionality which condense to form ether bonds;

Polyurethanes form when isocyanate resins and prepolymers are combined with low- or high-molecular weight polyols, with strict stochiometric ratios being essential to control nucleophilic addition polymerisation – the degree of crosslinking and resulting physical type (elastomer or plastic) is adjusted from the molecular weight and functionality of isocyanate resins, prepolymers, and the exact combinations of diols, triols and polyols selected, with the rate of reaction being strongly influenced by catalysts and inhibitors; polyureas form virtually instantaneously when isocyanate resins are combined with long-chain amine functional polyether or polyester resins and short-chain diamine extenders – the amine-isocyanate nucleophilic addition reaction does not require catalysts. Polyureas also form when isocyanate resins come into contact with moisture;[4]

Phenolic, amino and furan resins all cure by polycondensation involving the release of water and heat, with cure initiation and polymerisation exotherm control influenced by curing temperature, catalyst selection/loading and processing method/pressure – the degree of pre-polymerisation and level of residual hydroxymethyl content in the resins determine the crosslink density.[5]

Thermoset plastic polymers characterised by rigid, three-dimensional structures and high molecular weight, stay out of shape when deformed and undergo permanent or plastic deformation under load, and normally decompose before melting. Thermoset elastomers, which are soft and springy or rubbery and can be deformed and revert to their original shape on loading release, also decompose before melting. Conventional thermoset plastics or elastomers therefore cannot be melted and re-shaped after they are cured which implies that thermosets cannot be recycled for the same purpose, except as filler material.[6] There are developments however involving thermoset epoxy resins which on controlled and contained heating form crosslinked networks that can be repeatedly reshaped like silica glass by reversible covalent bond exchange reactions on reheating above the glass transition temperature.[7] There are also thermoset polyurethanes shown to have transient properties and which can thus be reprocessed or recycled.[8]

Thermosetting polymer mixtures based on thermosetting resin monomers and pre-polymers can be formulated and applied and processed in a variety of ways to create distinctive cured properties that cannot be achieved with thermoplastic polymers or inorganic materials.[9][10] Application/process uses and methods for thermosets include protective coating, seamless flooring, civil engineering construction grouts for jointing and injection, mortars, foundry sands, adhesives, sealants, castings, potting, electrical insulation, encapsulation, 3D printing, solid foams, wet lay-up laminating, pultrusion, gelcoats, filament winding, pre-pregs, and molding. Specific methods of molding thermosets are:

Properties

Thermosetting plastics are generally stronger than thermoplastic materials due to the three-dimensional network of bonds (crosslinking), and are also better suited to high-temperature applications up to the decomposition temperature since they keep their shape as strong covalent bonds between polymer chains cannot be easily broken. The higher the crosslink density and aromatic content of a thermoset polymer, the higher the resistance to heat degradation and chemical attack. Mechanical strength and hardness also improve with crosslink density, although at the expense of brittleness.[11]

Fiber-reinforced composites

When compounded with fibers thermosetting resins form fiber-reinforced polymer composites, which are used in the fabrication of factory finished structural composite OEM or replacement parts,[12] and as site-applied, cured and finished composite repair[13][14] and protection materials. When used as the binder for aggregates and other solid fillers they form particulate-reinforced polymer composites, which are used for factory-applied protective coating or component manufacture, and for site-applied and cured construction, or maintenance, repair and overhaul (MRO) purposes.

Examples

See also

References

  1. "thermosetting polymer definition" (PDF). IUPAC Compendium of Chemical Terminology. 2007. Archived from the original (PDF) on 2010-11-22.
  2. Unsaturated Polyester Technology, ed. P.F. Bruins, Gordon and Breach, New York, 1976
  3. Chemistry and Technology of Epoxy Resins, ed. B. Ellis, Springer Netherlands, 1993, ISBN 978-94-010-5302-0
  4. Polyurethane Handbook, ed. G Oertel, Hanser, Munich, Germany, 2nd edition, 1994, ISBN 1569901570, ISBN 978-1569901571
  5. Reactive Polymers Fundamentals and Applications: A Concise Guide to Industrial Polymers (Plastics Design Library), William Andrew Inc., 2nd edition, 2013, ISBN 978-1455731497
  6. The Open University (UK), 2000. T838 Design and Manufacture with Polymers: Introduction to Polymers, page 9. Milton Keynes: The Open University
  7. D. Montarnal, M. Capelot, F. Tournilhac, L. Leibler, Science, 2011, 334, 965-968], DOI: 10.1126/science.1212648
  8. Fortman, David J.; Jacob P. Brutman; Christopher J. Cramer; Marc A. Hillmyer; William R. Dichtel (2015). "Mechanically Activated, Catalyst-Free Polyhydroxyurethane Vitrimers". Journal of the American Chemical Society. doi:10.1021/jacs.5b08084
  9. Concise Encyclopedia of Polymer Science and Engineering, ed. J.I. Kroschwitz, Wiley, New York, 1990, ISBN 0-471-5 1253-2
  10. Industrial Polymer Applications: Essential Chemistry and Technology, Royal Society of Chemistry, UK, 1st edition, 2016, ISBN 978-1782628149
  11. Handbook of Thermoset Plastics, ed. S.H. Goodman, H. Dodiuk-Kenig, William Andrew Inc., USA, 3rd edition, 2013, ISBN 978-1-4557-3107-7
  12. Polymer Matrix Composites: Materials Usage, Design, and Analysis, SAE International, 2012, ISBN 978-0-7680-7813-8
  13. PCC-2 Repair of Pressure Equipment and Piping, American Society of Mechanical Engineers, 2015, ISBN 978-0-7918-6959-8
  14. ISO 24817 Composite Repairs for Pipework: Qualification and Design, Installation, Testing and Inspection, 2015, ICS: 75.180.20
  15. Roberto C. Dante, Diego A. Santamaría and Jesús Martín Gil (2009). "Crosslinking and thermal stability of thermosets based on novolak and melamine". Journal of Applied Polymer Science. 114 (6): 4059–4065. doi:10.1002/app.31114.
  16. Enrique Guzman; Joël Cugnoni; Thomas Gmür (2014). "Multi-factorial models of a carbon fibre/epoxy composite subjected to accelerated environmental ageing". Composite Structures. 111 (4): 179–192. doi:10.1016/j.compstruct.2013.12.028.
  17. T Malaba, J Wang, Journal of Composites, vol. 2015, Article ID 707151, 8 pages, 2015. doi:10.1155/2015/707151
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