ACCU DYNE TEST ™ Bibliography
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755. Takata, T. and M. Furukawa, “Surface modification of aramid fibers by a low temperature plasma to improve their adhesion,” in Metallized Plastics: Fundamentals and Applications, Mittal, K.L., ed., 251-268, Marcel Dekker, Nov 1997.
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.
757. Ibidunni, A.O., and R.J. Brunner, “Metal/polymer adhesion: effect of ion bombardment on polymer interfacial reactivity,” in Metallized Plastics: Fundamentals and Applications, Mittal, K.L., ed., 281-290, Marcel Dekker, Nov 1997.
759. Lindland, H.T., “Flame surface treatment,” in Coatings Technology Handbook, Satas, D., ed., 287-294, Marcel Dekker, 1991 (also in Coatings Technology Handbook, 2nd Ed., D. Satas and A.A. Tracton, eds., p. 343-350, Marcel Dekker, Jan 2001, and Coatings Technology: Fundamentals, Testing, and Processing Techniques, A.A. Tracton, ed., p. 39/1-39/7, CRC Press, Oct 2006).
760. Kaplan, S.L., and P.W. Rose, “Plasma surface treatment,” in Coatings Technology Handbook, Satas, D., ed., 295-301, Marcel Dekker, 1991 (also in Coatings Technology Handbook, 2nd Ed., D. Satas and A.A. Tracton, eds., p. 351-357, Marcel Dekker, Jan 2001, and Coatings Technology: Fundamentals, Testing, and Processing Techniques, A.A. Tracton, ed., p. 40/1-40/6, CRC Press, Oct 2006).
761. Milker, R., and A. Koch, “Surface treatment of polymer webs by fluorine,” in Coatings Technology Handbook, Satas, D., ed., 303-309, Marcel Dekker, 1991 (also in Coatings Technology Handbook, 2nd Ed., D. Satas and A.A. Tracton, eds., p. 359-365, Marcel Dekker, Jan 2001, and Coatings Technology: Fundamentals, Testing, and Processing Techniques, A.A. Tracton, ed., p. 41/1-41/6, CRC Press, Oct 2006).
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).
876. Dahlquist, C.A., “The theory of adhesion,” in Coatings Technology Handbook, Satas, D., ed., 51-61, Marcel Dekker, 1991 (also in Coatings Technology Handbook, 2nd Ed., D. Satas and A.A. Tracton, eds., p. 51-61, Marcel Dekker, Jan 2001, and Coatings Technology: Fundamentals, Testing, and Processing Techniques, A.A. Tracton, ed., p. 5/1-5/9, CRC Press, Oct 2006).
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.
883. Kwok, D.Y., and A.W. Neumann, “Contact angle techniques and measurements,” in Surface Characterization Methods: Principles, Techniques, and Applications, Milling, A.J., ed., 37-86, Marcel Dekker, Aug 1999.
884. Radu, C.-D., P. Kiekens, and J. Verschuren, “Surface modification of textiles by plasma treatments,” in Surface Characteristics of Fibers and Textiles, Pastore, C.M., and P. Kiekens, eds., 203-218, Marcel Dekker, Dec 2000.
903. Chehimi, M.M., A. Azioune, and E. Cabet-Deliry, “Acid-base interactions: Relevance to adhesion and adhesive bonding,” in Handbook of Adhesive Technology, 2nd Ed., Pizzi, A., and K.L. Mittal, eds., 95-144, Marcel Dekker, Aug 2003.
1060. Hartland, S., ed., Surface and Interfacial Tension: Measurement, Theory, and Applications, Marcel Dekker, 2004.
1061. Blokhuis, E.M., “Liquid drops at surfaces,” in Surface and Interfacial Tension: Measurement, Theory, and Applications, Hartland, S., ed., 149-194, Marcel Dekker, 2004.
1062. Katoh, K., “Contact angle and surface tension measurement,” in Surface and Interfacial Tension: Measurement, Theory, and Applications, Hartland, S., ed., 375-424, Marcel Dekker, 2004.
1063. Song, B., A. Bismarck, and J. Springer, “Contact angle measurements on fibers and fiber assemblies, bundles, fabrics, and textiles,” in Surface and Interfacial Tension: Measurement, Theory, and Applications, Hartland, S., ed., 425-482, Marcel Dekker, 2004.
1064. Eriksson, J.C., and S. Ljunggren, “Thermodynamics of curved interfaces in relation to the Helfrich curvature free energy approach,” in Surface and Interfacial Tension: Measurement, Theory, and Applications, Hartland, S., ed., 547-614, Marcel Dekker, 2004.
1106. Yasuda, H., Luminous Chemical Vapor Deposition and Interface, Marcel Dekker, 2005.
1153. Harrington, W.F. Jr., “Surface treatment of plastics,” in Coatings Technology Handbook, Satas, D., ed., Marcel Dekker, 1991 (also in Coatings Technology Handbook, 2nd Ed., D. Satas and A.A. Tracton, eds., p. 335-342, Marcel Dekker, Jan 2001, and Coatings Technology: Fundamentals, Testing, and Processing Techniques, A.A. Tracton, ed., p. 38/1-38/7, CRC Press, Oct 2006).
1477. Della Volpe, C., and S. Siboni, “Acid-base behaviour of (polymer) surfaces: Theory,” in Encyclopedia of Surface and Colloid Science, Hubbard, A., ed., Marcel Dekker, 2002.
1724. no author cited, “Surface free energy of polymers - Optimisation of the determination of polymer surface free energy,” Materials Australia, 33, (Dec 2001).
2974. Deshmukh, R.R., and N.V. Bhat, “The mechanism of adhesion and printability of plasma processed PET films,” Materials Research Innovations, 22, 283-290, (Sep 2003).
541. Occhiello, E., M. Morra, G. Morini, and F. Garbassi, “Effect of oxygen plasma treatments on polypropylene - epoxy interfacial strength,” in Interfaces Between Polymers, Metals, and Ceramics, Ishida, H., 199-204, Materials Research Society, 1989.
2625. Rudawska, A., and J. Kuczmaszewski, “Surface free energy of zinc coating after finishing treatment,” Materials Science - Poland, 24, (2006).
Protective properties of zinc coating increase with an additional coating such as: chromate, phosphate, paint and polymer coating. Besides, additional treatment of zinc coating serves decorative purposes as well. The paper presents the influence of additional coating of zinc coating on their adhesive properties which are especially helpful in processes where adhesion plays an essential role. These processes include among others: gluing, painting or varnishing. Adhesive properties are characterized by the value of surface free energy.
2975. Nowak, S., and O.M. Kuttel, “Plasma treatment of polymers for improved adhesion properties,” Materials Science Forum, 142, 705-726, (1993).
387. Winters, H.F., R.P.H. Chang, C.J. Mogab, J. Evans, J.A. Thornton, and H. Yasuda, “Coatings and surface modification using low pressure non-equilibrium plasmas,” Materials Science and Engineering, 70, 53-77, (1985).
2081. Lawrence, J., and L. Li, “Modification of the wettability characteristics of polymethyl methacrylate (PMMA) by means of CO2, Nd:YAG, excimer and high power diode laser radiation,” Materials Science and Engineering A, 303, 142-149, (May 2001).
2979. Pichal, J., J. Cerman, H. Sourkova, and P. Spatenka, “Plasma pre-treatment of polypropylene surface for industrial purposes,” Materials and Manufacturing Processes, 37, 1483-1489, (2022).
The paper describes an experimental investigation of the possibility of industrial modification of surface wettability and adhesion of polymers by the action of a plasma of a gliding discharge generated in air at atmospheric pressure in a simulated production process. The test material was polypropylene plates (PP). The modification was performed by a device with a multi-electrode (four pairs) system, which is not common. The quality of pre-processing and usability was evaluated primarily in terms of the industrial requirements, which means a change in wettability and adhesion expressed by the contact angle/surface free energy value in dependence to sample exposure time expressed by the conveyor belt speed. The surface free energy assessment of a treated polymeric surface by contact angle measurement was carried out by analyzing static sessile drops and evaluated by Owens–Wendt–Rabel–Kaelble (OWRK) model. The results determined a set of operating parameters at which the modification process meets the industrial requirements. By evaluating the change in surface free energy in relation to the storage time, the degree of hydrophobic recovery of the treated samples, i.e. the time stability of the plasma-treated surface, was also determined. It has been found that plasma-treated PP surface fully meets industrial demands and can be stored for at least 50 days.
887. Veselovsky, R.A., and V.N. Kestelman, Adhesion of Polymers, McGraw-Hill, Dec 2001.
1535. Petrie, E.M., “Surfaces and surface preparation,” in Handbook of Adhesives and Sealants, 2nd Ed., 227-275, McGraw-Hill, Jan 2007.
910. Wettermann, R.P., “Electrical surface treatment of medical plastics,” Medical Device & Diagnostic Industry, (Oct 1990).
2947. Palmers, J., “Surface modification using low-pressure plasma technology,” Medical Device & Diagnostic Industry, (Jan 2000).
352. Stobbe, B.D., “Corona discharge treatment for medical surface preparation,” Medical Device and Diagnostic Industry, (Feb 2000).
179. Jones, W.C., “Testing surfaces for cleanliness,” Metal Finishing, 83, 13-15, (Oct 1985).
452. Dobreva, E.D., M.A. Encheva, and A.T. Trandafilov, “The effect of preliminary treatment with surfactants in the metallization of dielectrics,” Metal Finishing, 90, 29-32, (Mar 1992).
2015. Kuhn, A., “Starting off with a clean slate: Using dyne liquids is one of the easiest and most cost-effective means of assessing surface cleanliness,” Metal Finishing, 103, 72-79, (May 2005).
2869. Kuhn, A., “Determining whether a metal surface is really clean: Two testing methods offer an inexpensive yet accurate means for measuring cleanliness,” Metal Finishing, 103, 16-21, (Sep 2005).
893. Hibbard, D., “Sticky science: new polymer technology makes it easier to paint and glue plastic parts,” Modern Paints & Coatings, 91, 31, (Dec 2001).
27. Blitshteyn, M., and R. Wetterman, “Surface treatment of polyolefins,” Modern Plastics, 67, 424, (Oct 1990).
146. Greene, R., “High energy system prepares molded parts,” Modern Plastics, 68, 30-31, (Aug 1991).
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