Hot-Melt Adhesives

C. W. Paul

doi:10.1557/mrs2003.125

Abstract

Hot-melt adhesives facilitate fast production processes because the adhesives set simply by cooling. Formulations contain polymers to provide strength and hot tack (resistance to separation while adhesive is hot), and tackifiers and/or oils to dilute the polymer entanglement network, adjust the glass-transition temperature, lower the viscosity, and improve wet-out (molecular contact of the adhesive with the substrate over the entire bonding area). Some adhesives also contain waxes to speed setting, lower viscosity, and improve heat resistance. Obtaining adequate strength and heat resistance from nonreactive hot melts requires that some component of the hot melt separate out into a dispersed but interconnected hard-phase network upon cooling. The hard phases are commonly either glassy styrene domains (for adhesives based on styrenic block copolymers) or organic crystallites (for adhesives based on waxes, olefinic copolymers, or ethylene copolymers). This article will describe first the material properties relevant to the processing and performance of hot-melt adhesives, then the chemistry and function of the specific raw materials used in hot melts, and will conclude with illustrative application examples and corresponding formulations.

References

1.Georjon, O., Faissat, M., and Chambon, F., Adhes. Age (February 1999) p. 44.Google Scholar

2.Godfrey, D.A., U.S. Patent No. 5,763,516 (June 9, 1998).Google Scholar

3.Sustic, A. and Pellon, B., Adhes. Age (November 1991) p. 17.Google Scholar

4.Robe, G., in Proc. TAPPI Hot Melt Symposium (Technical Association of the Pulp and Paper Industry, Norcross, GA, 1992).Google Scholar

5.Eastman, E.F. and Fullhart, L., in Handbook of Adhesives, 3rd ed., edited by Skeist, I. (Van Nostrand Reinhold, New York, 1990) p. 408.CrossRef Google Scholar

6.Stauffer, D., Puletti, P.P., and Kauffman, T.F., U.S. Patent No. 5,331,033 (July 19, 1994).Google Scholar

7.Han, C.D., Kim, J., Kim, J.K., and Chu, S.G., Macromolecules 22 (1989) p. 3443.CrossRef Google Scholar

8.Han, C.D., Kim, J., Baek, D.M., and Chu, S.G., J. Polym. Sci., Part B: Polym. Phys. 28 (1990) p. 315.CrossRef Google Scholar

9.Ruckel, E. and Chu, W., in Proc. TAPPI Hot Melt Symposium (Technical Association of the Pulp and Paper Industry, Norcross, GA, 1998).Google Scholar

Crossref Citations

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Luzinov, Igor Minko, Sergiy and Tsukruk, Vladimir V 2004. Adaptive and responsive surfaces through controlled reorganization of interfacial polymer layers. Progress in Polymer Science, Vol. 29, Issue. 7, p. 635.

Li, Wen Bouzidi, Laziz and Narine, Suresh S. 2008. Current Research and Development Status and Prospect of Hot-Melt Adhesives: A Review. Industrial & Engineering Chemistry Research, Vol. 47, Issue. 20, p. 7524.

Li, W. Kong, X. H. Kharraz, E. Bouzidi, L. and Narine, S. S. 2011. Exploration of Potential Applications of Natural Oils for Green Hot Melt Adhesives: A Comparative Experimental Investigation on Paraffin and Soybean Waxes. The Journal of Adhesion, Vol. 87, Issue. 2, p. 95.

Kalish, Jeffrey P. Ramalingam, Suriyakala Wamuo, Onyenkachi Vyavahare, Omkar Wu, Ying Hsu, Shaw Ling Paul, Charles W. and Eodice, Andrea 2014. Role of n-alkane-based additives in hot melt adhesives. International Journal of Adhesion and Adhesives, Vol. 55, Issue. , p. 82.

Ploeger, Rebecca René de la Rie, E. McGlinchey, Christopher W. Palmer, Michael Maines, Christopher A. and Chiantore, Oscar 2014. The long-term stability of a popular heat-seal adhesive for the conservation of painted cultural objects. Polymer Degradation and Stability, Vol. 107, Issue. , p. 307.

Kalish, Jeffrey P. Ramalingam, Suriyakala Bao, Huimin Hall, Douglas Wamuo, Onyenkachi Hsu, Shaw Ling Paul, Charles W. Eodice, Andrea and Low, Yew-Guan 2015. An analysis of the role of wax in hot melt adhesives. International Journal of Adhesion and Adhesives, Vol. 60, Issue. , p. 63.

Estan-Cerezo, Gabriel and Martín-Martínez, José Miguel 2015. Thermal, viscoelastic and adhesion properties of EVA (ethylene-co-vinyl acetate) hot melts containing polypropylene waxes of different nature. Journal of Adhesion Science and Technology, Vol. 29, Issue. 9, p. 875.

Ploeger, Rebecca McGlinchey, Chris W. and de la Rie, E. René 2015. Original and reformulated BEVA®371: Composition and assessment as a consolidant for painted surfaces. Studies in Conservation, Vol. 60, Issue. 4, p. 217.

Moyano, María Alejandra París, Rodrigo and Martín-Martínez, José Miguel 2016. Changes in compatibility, tack and viscoelastic properties of ethylene n-butyl acrylate (EBA) copolymer–pentaerythritol rosin ester blend by adding microcrystalline wax, Fischer–Tropsch wax and mixture of waxes. International Journal of Adhesion and Adhesives, Vol. 65, Issue. , p. 47.

Cimino, Dafne Chiantore, Oscar de La Rie, E. René McGlinchey, Christofer W. Ploeger, Rebecca Poli, Tommaso and Poulis, Johannes A. 2016. Binary mixtures of ethylene containing copolymers and low molecular weight resins: A new approach towards specifically tuned art conservation products. International Journal of Adhesion and Adhesives, Vol. 67, Issue. , p. 54.

Ploeger, R. Del Grosso, C. Poulis, J. A. Cimino, D. Poli, T. de la Rie, E. R. and McGlinchey, C. W. 2017. Consolidating Adhesive Project. MRS Advances, Vol. 2, Issue. 33-34, p. 1731.

Moyano, María Alejandra París, Rodrigo and Martín-Martínez, José Miguel 2017. Assessment of the compatibility in hot melts by using different thermoanalytical methods. Ethylene/n-butyl acrylate (EBA) hot melts containing tackifiers of different nature. Journal of Thermal Analysis and Calorimetry, Vol. 129, Issue. 3, p. 1495.

Wamuo, Onyenkachi Wu, Ying Hsu, Shaw Ling Paul, Charles W. Eodice, Andrea Huang, Kuan-Yeh Chen, Meng-Hsin Chang, Yih-Her and Lin, Jen-Lien 2017. Effects of chain configuration on the crystallization behavior of polypropylene based copolymers. Polymer, Vol. 116, Issue. , p. 342.

Chen, Tso-Hsuan Yeh, Yu-Chi and Liao, Ying-Chih 2018. Healable and Foldable Carbon Nanotube/Wax Conductive Composite. ACS Applied Materials & Interfaces, Vol. 10, Issue. 28, p. 24217.

Hsu, Shaw Ling 2018. Encyclopedia of Polymer Science and Technology. p. 1.

Del Grosso, Chelsey A. Poulis, Johannes A. and de la Rie, E. René 2019. The photo-stability of acrylic tri-block copolymer blends for the consolidation of cultural heritage. Polymer Degradation and Stability, Vol. 159, Issue. , p. 31.

Denk, Philipp Ortner, Eva and Buettner, Andrea 2019. Characterization of odorants in waxes for hot melt adhesives using sensory and instrumental analyses. International Journal of Adhesion and Adhesives, Vol. 95, Issue. , p. 102406.

Lang, Johann Winkeljann, Benjamin Lieleg, Oliver and Zollfrank, Cordt 2019. Continuous Synthesis and Application of Novel, Archaeoinspired Tackifiers from Birch Bark Waste. ACS Sustainable Chemistry & Engineering, Vol. 7, Issue. 15, p. 13157.

Moyano, María Alejandra París, Rodrigo and Martín-Martínez, José Miguel 2019. Viscoelastic and adhesion properties of hot-melts made with blends of ethylene-co-n-butyl acrylate (EBA) and ethylene-co-vinyl acetate (EVA) copolymers. International Journal of Adhesion and Adhesives, Vol. 88, Issue. , p. 34.

del Prado, Anselmo Hohl, Diana Kay Balog, Sandor de Espinosa, Lucas Montero and Weder, Christoph 2019. Plant Oil-Based Supramolecular Polymer Networks and Composites for Debonding-on-Demand Adhesives. ACS Applied Polymer Materials, Vol. 1, Issue. 6, p. 1399.

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Hot-Melt Adhesives

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