ACCU DYNE TEST ™ Bibliography
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1286. Gerenser, L.S., “XPS studies of in-situ plasma-modified polymer surfaces,” J. Adhesion Science and Technology, 7, 1019-1040, (1993).
2844. Gerke, G., “Can plasma surface treatment deliver sustainable solutions and reduce cost?,” https://digitaledition.flexpackmag.com/march-2021/plasma-surface/?oly_enc_id=1127B7669590J0V, Mar 2021.
464. Gerstenberg, K.W., “Corona pretreatment to allow wetting and bonding,” Deutsch Papierwirtsch, 1, 8, (1990).
128. Gervason, G., J. Ducom, and H. Cheradame, “Relationship between surface energy and adhesion strength in polyethylene-paper composites,” British Polymer Journal, 21, 53-59, (1989).
1481. Ghali, K., B. Jones, and J. Tracy, “Experimental techniques for measuring parameters describing wetting and wicking in fabrics,” Textile Research J., 64, 106-111, (1994).
129. Ghannam, M.T., and M.N. Esmail, “The effect of pre-wetting on dynamic contact angle,” Canadian J. Chemical Engineering, 70, 408-412, (1992).
756. Gheorghiu, M., G. Popa, M. Pascu, and C. Vasile, “Chemical and physical surface modifications of polymers by ion beam treatments,” in Metallized Plastics: Fundamentals and Applications, Mittal, K.L., ed., 269-280, Marcel Dekker, Nov 1997.
879. Gheorghiu, M., M.C. Pascu, and G. Popa, “Surface modifications of polyolefins by gas-phase methods,” in Handbook of Polyolefins, 2nd Ed., Vasile, C., ed., 649-688, Marcel Dekker, Jun 2000.
1869. Ghosh, I., J. Konar, and A.K. Bhowmick, “Surface properties of chemically modified polyimide films,” J. Adhesion Science and Technology, 11, 877-893, (1997).
2021. Giacometti, J.A., S. Fedosov, and M.M. Costa, “Corona charging of polymers: Recent advances on constant current charging,” Brazilian J. Physics, 29, (Jun 1999).
1997. Gifford, W.A., “The effect of contact angle on ring tensiometry,” J. Colloid and Interface Science, 64, 588-591, (May 1978).
132. Gilberg, G., “Polymer surface characterization: an overview,” J. Adhesion, 21, 129-154, (1987).
2930. Gilbertson, T., and M. Plantier, “Web-handling best practices for corona treating on R2R-converting lines: Why the web path matters,” Converting Quarterly, 12, 69-73, (Oct 2022).
130. Gilbertson, T.J., “Mixing water with electrical energy - succesful printing with water-based inks,” in 1991 Polymers, Laminations and Coatings Conference Proceedings, 321-328, TAPPI Press, Aug 1991.
131. Gilbertson, T.J., “The necessity of using pretreated films in converting applications and why inline treating is required,” Flexible Packaging, 2, 36-37, (Apr 2000).
1057. Gilbertson, T.J., “Corona treating on a solvent line?,” Flexo, 29, 30-31, (Mar 2004).
1111. Gilbertson, T.J., “Double treat it,” Package Printing, 52, 33, (Jan 2005).
1713. Gilbertson, T.J., “Troubleshoot surface treating for print,” Converting, 26, 42-47, (Jun 2008).
2477. Gilbertson, T.J., “Extrusion bonding success improved with surface treating,” http://www.enerconind.com/treating/corona/tech-papers-articles/extrusion, Sep 2013.
2619. Gilbertson, T.J., “Finicky films: The signature relationship to corona treaters,” Flexo, 40, 48-51, (Sep 2015).
2663. Gilbertson, T.J., “Using watt density to predict dyne levels,” http://www.enerconind.com/treating/library/technical-articles/using-watt...,
2810. Gilbertson, T.J., “Hey buddy can you spare a dyne?,” PFFC, 25, 16-18, (Jan 2020).
2243. Gilbertson, T.J., M. Leonardelli, and R.A. Wolf, “Optimizing blown film line layouts for improved surface treating performance,” J. Plastic Film and Sheeting, 26, 83-104, (Jan 2010).
Blown film processors, large and small, have limited resources in both capital and manpower to devote to optimizing their productivity. Yet avenues of improvement are open for even the most over-extended organization. And some of the most effective modifications cost little more than a small change in equipment orientation or procedures. A key aspect of optimizing a blown film layout is line footprint and determining how to minimize footprint and maximize output with each integral piece of equipment on the line. Multiple surface treatment systems are integral to every blown film line and can control product quality and line efficiencies. The objective of this work is to present best practices of blown film manufacturers ranging from multinationals to small privately owned operations relative to the most effective surface treatment system designs, their roll coverings, optimum power density settings, alternative treatment technologies, troubleshooting protocols, and model line layouts that optimize production output.
1775. Gilbertson, T.J., and M. Plantier, “Blame the corona treater: The truth about watt density, dyne levels & adhesion,” Converting Solutions, 24, 22-27, (Feb 2019).
2587. Gilbertson, T.J., and M. Plantier, “Blame the corona treater - the truth about watt density, dyne levels, and adhesion,” Converting Quarterly, 4, 82-84, (Apr 2014).
1963. Gillberg, G., “Polymer surface characterization: An overview,” J. Adhesion, 21, 129-154, (Feb 1987).
133. Gilleo, K.B., “Rheology and surface chemistry for screen printing,” ScreenPrinting, 79, 128, (Feb 1989).
875. Gilleo, K.B., “Rheology and surface chemistry,” in Coatings Technology Handbook, Satas, D., ed., 3-19, Marcel Dekker, 1991 (also in Coatings Technology Handbook, 2nd Ed., D. Satas and A.A. Tracton, eds., p. 3-17, Marcel Dekker, Jan 2001, and Coatings Technology: Fundamentals, Testing, and Processing Techniques, A.A. Tracton, ed., p. 1/1-1/9, CRC Press, Oct 2006).
2968. Gilliam, M., “Polymer surface treatment and coating technologies,” in Handbook of Manufacturing Engineering and Technology, A.Y.C. Nee, ed., 99-124, Springer, Sep 2014.
2323. Gilman, A., “Effect of treatment conditions in a glow discharge on the wettability of PTFE,” High Energy Chemistry, 24, 64-66, (1990).
2721. Gilpin, A.D., B.R. Oakley, and R.G. Dillingham, “Water contact angle as a quantitative measure of total polyethylene surface energy,” J. Adhesion Science and Technology, 29, 890-895, (2015).
A wide variety of plasma treatments was performed on polyethylene surfaces, resulting in a wide range of total surface energies. The linear correlation of 
with cos θ was discussed in light of the Young–Dupré equation. Hundred percent of the surface energy variation was accounted for by the polar component of surface energy; the dispersive component was not affected by surface treatment. These data show that for this polymer the contact angle of a single polar liquid can be used as a robust quantitative indicator of treatment level, and because of its excellent linear correlation with total surface energy for this system, can be used as a quantitative measure of total surface energy.
134. Girifalco, L.A., and R.J. Good, “A theory for the estimation of surface and interfacial energies, I. Derivation and application to interfacial tension,” J. Physical Chemistry, 61, 904-909, (1957).
135. Giroux, T.A., and S.L. Cooper, “Surface characterization of plasma-derivatized polyurethanes,” J. Applied Polymer Science, 43, 145-155, (1991).
2921. Glasmacher-Seiler, B., S. Voigt, and H. Reul, “Determination of surface energetic properties by contact angle measurements,” in The Reference Materials of the European Communities, W. Lemm, ed., 85-94, Springer, 1992.
2404. Glocker, D.A., M.M. Romach, R.C. Soper, and E.A. Perez-Albuerne, “Glow discharge treatment of a web substrate surface in a web coating line,” U.S. Patent 5954926, Sep 1999.
2312. Glocker, D.A., and M.M. Romach, “Near atmospheric pressure treatment of polymers using helium discharges,” U.S. Patent 5767469, Jun 1998.
2161. Glogauer, S., “Plasma and adhesion to rubber, plastics substrates,” Rubber and Plastics News, 38, 16-19, (Jun 2009).
World-class, fully automated manufacturing processes rely more and more on advanced, environmentally friendly surface treatment technologies. An innovative atmospheric pressure plasma technique allows inline rubber and plastic manufacturing processes to become fully automated with total process control. A thorough pretreatment must produce surfaces with reliable and repeatable characteristics to achieve optimal adhesive bonding, coating and printing results. In addition, pretreatment must be delivered in a cost-effective and safe manner. The new process uses the high effectiveness of plasma for microfine cleaning, high-surface activation and nanocoating. In most cases the plasma application takes the place of environmentally unfriendly and costly solvent cleaning or chemical adhesion promoters and primers.
1393. Glover, J.H., “Slip migration in extrusion coatings of LDPE,” in 1987 Polymers, Laminations and Coatings Conference Proceedings, 231, TAPPI Press, Aug 1987.
465. Golander, C.-G., and B.-A. Sultan, “Surface modification of polyethylene to improve its adhesion to aluminum,” J. Adhesion Science and Technology, 2, 125, (1988).
2061. Goldblatt, R.D., L.M. Ferreiro, S.L. Nunes, et al, “Characterization of water vapor plasma-modified polyimide,” J. Applied Polymer Science, 46, 2189-2202, (Dec 1992).
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