Enhancement of Rigidity and Thermal Performances of Fabrics Through the Addition of Nanoadditifs
American Journal of Nano Research and Applications
Volume 3, Issue 4-1, July 2015, Pages: 7-10
Received: Feb. 4, 2015;
Accepted: Feb. 5, 2015;
Published: Feb. 14, 2015
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K. Abid, Laboratoire de génie Textile, Institut Supérieur des Etudes Technologique de Ksar Hellal, Université de Monastir, Avenue Hadj Ali Soua, Ksar Hellal, Tunisia
A. Elamri, Laboratoire de génie Textile, Institut Supérieur des Etudes Technologique de Ksar Hellal, Université de Monastir, Avenue Hadj Ali Soua, Ksar Hellal, Tunisia
S. Dhouib, Laboratoire de génie Textile, Institut Supérieur des Etudes Technologique de Ksar Hellal, Université de Monastir, Avenue Hadj Ali Soua, Ksar Hellal, Tunisia
F. Sakli, Laboratoire de génie Textile, Institut Supérieur des Etudes Technologique de Ksar Hellal, Université de Monastir, Avenue Hadj Ali Soua, Ksar Hellal, Tunisia
In this study, the nanocomposites have been synthesized with the natural Tunisian clay which has the advantage of being cheap. In fact, it is composed of many kinds of clay (Kaolinite, Dolomite, calcite, Illite and Quartz). This clay has been cleaned, purified, dried and mixed with different resins currently used in many textile applications such as comfort, elasticity, impermeability … etc. The samples have been examined under MEB in order to identify them and ensure the formation of nanocomposites. The mixture resin/clay has been deposit on a 100% cotton fabric (400 g/m2) and tested on adiathermic power (AP%) measuring equipment. The parameter of thermal isolation of coated fabrics has been calculated through the difference in temperature between the interior and the exterior of the fabric in focus. It has been noticed that the increase in clay quantity improves significantly the thermal characteristics of the coated fabrics. The rigidity of the fabrics has also increased in terms of clay quantity, this proves that this new kind of fabric must be used in specific domains that compile their isolating characteristics and their increasing rigidity with the rate of clay inserted.
Enhancement of Rigidity and Thermal Performances of Fabrics Through the Addition of Nanoadditifs, American Journal of Nano Research and Applications. Special Issue: Nanocomposites Coating and Manufacturing.
Vol. 3, No. 4-1,
2015, pp. 7-10.
Patend, Nanostructured Thin Films and Their Uses, Cross-Reference to Related Application Serial No. 60/611,116, filed September 17, 2004 United States Government support under the Department of Health and Human Services, National Institutes of Health, National Human Genome Research Institute grant number 1 R43 HG003480-01.
Jing Gao, Weidong Yu, Ning Pan , Structures and Properties of the Goose Down as a Material for Thermal Insulation, Textile College, Donghua University, Shanghai 200051, China, Textile Research Journal, Vol. 77, No. 8, 617-626 (2007).
M. Juma, Heat Transfer Properties of Cord-reinforced Rubber Composites Journal of Reinforced Plastics and Composites, Vol. 25, No. 18, 1967-1975 (2006).
M. ROCHERY, Optimisation of the Structure of a Polyurethane/clay used as Flame Retartdent Textile coating European Coating Conference 22, 23, 24 march 2006, page 3.
A.A. Voevodin, J.P. O’Neill, J.S. Zabinski Nanocomposite tribological coatings for aerospace applications, Surface and Coatings Technology 116–119 (1999) 36–45. Materials and Manufacturing Directorate, Air Force Research Laboratory, AFRL/MLBT, Wright–Patterson Air Force Base, OH 45433-7750, USA.
D. WEBSTER, Non Isocyanate Polyurethane Coating Via Glycedyl, European Coating Conference 22, 23, 24 march 2006, page 4.
G. N. Gerasimov, E. I. Grigoriev, A. E. Grigoriev, P. S. Vorontsov, S. A. Zavialov, and L. I. Trakhtenberg, Chem. Phys. Rep. 17, 1247 (1998).
R. M. Hill, ERA Research Report, No. 5232 (1967), p. 1.
J. VAN HOLEN, Novel Routes to Urethanr Acrylate, European Coating Conference 22, 23, 24 March 2006, page 5.
T. H. Kim, Lee W.jang, Dong C. Lee, Hyoung J. Choi, Myung S. Jhon Synthesis and Rheology of Intercalated Polystyrene/Na+-Montmorillonite Nanocomposites, Macromolecular Rapid Communications, 2002, 23, 191-195.
Huang J. Choi, Myung S. Jhon, Seong G. Kim, yang H. Hyung Preparation and Rheological Characteristics of Solvent-Cast(ethylene oxide)-Montmorillonite Nanocomposites, Macromolecular Rapid Communications, 2001, 22, 320-325.
Sung T. Lim, yang H. Hyung and Hyoung J. Choi, Synthetic Biodegradable Aliphatic Polyester/Monmorillonite Nanocomposites, American Chemical Society, 2002, 14, 1839-1844.
S. K.Lim, J. W. Kim, I. Chin, W. K. Kwon and Hyoung J.Choi, Preparation and Intercalation Characteristics of with Miscible Polymer Blend of Polyethylene Oxide and PMMA, American Chemical Society, 2002, 14, 1989-1994.
K. Abid, S. Dhouib and F. Sakli; JTI, Addition Effect of Nanoparticles on the Mechanical Properties of Coated Fabric, JTI, 2008.
F.Benabdallah, Characterization of Composite Materials Based on PP-Cork Blends Journal of Reinforced Plastics and Composites, Vol. 25, No. 14, 1499-1506 (2006).
Hackett E, Manias E, Giannelis E P (1998), `Molecular dynamics simulations of organically modified layered silicates', J Chem Phys, 108, 7410±15.
Hackett E, Manias E, Giannelis E P (2000), `Computer simulation studies of PEO/ layered silicate nanocomposites', Chem Mater, 12, 2161±7.
VanderHart D L, Asano A, Gilman JW(2001), `NMR measurements related to clay dispersion quality and organic-modifier stability in nylon 6/clay nanocomposites', Macromolecule, 38, 3819±22.
Loo L S, Gleason K K (2003), `Fourier transforms infrared investigation of the deformation behavior of montmorillonite in nylon 6/nanoclay nanocomposites', Macromolecules, 36, 2587±90.
Bernard Miller, Thermoanalytical Studies on the Durable-Press Curing of Cellulose CopyTextile Research Journal, Vol. 38, No. 1, 1-15 (1968).
Bement AL, American Society for Metals and the Metallurgical Society Joint Distinguished Lecture in Materials and Society, Materials Week, October 1986.