Binder effectiveness of microcapsules applied onto cotton fabrics during laundry

[EN] Microcapsules can be added to fabric in industrial processes; however, they have not been widely spread among industrial companies. In this study, we suggest the possibility of reloading microcapsules onto a fabric while clothes are washed. The effectiveness of different resins when microcapsules are applied in washing machine during domestic laundry process has been studied. Microcapsules containing lavender fragrance and melamine formaldehyde shell were adhered to the fabric by means of one acrylic acid as a resin (RES) or some cross-linking agents, such as butanetetracarboxylic acid or succinic acid (SUC). In order to evaluate their behaviour, some laundering or ironing tests were conducted according to international standards (ISO). Every sample from the laboratory was studied with scanning electron microscopy and with a particle size counter. As a result, we could observe which was the most suitable auxiliary used to bind microcapsules to fabric, and conclude that the conditions in which we obtained the application with SUC as binder and cured at 150 °C for 2 min show the optimal results. It was demonstrated that domestic laundry is a suitable process to incorporate microcapsules to garments.Authors gratefully acknowledge the financial support received by this research project from the Spanish government in the programme 'Plan Nacional 2008-2011' reference Mat 2009-14210-C02-01.Bonet Aracil, MA.; Bou Belda, E.; Monllor Pérez, P.; Gisbert; Jaime (2016). Binder effectiveness of microcapsules applied onto cotton fabrics during laundry. The Journal of the Textile Institute. 107(3):300-306. https://doi.org/10.1080/00405000.2015.1029808S300306107

A comparison between padding and bath exhaustion to apply microcapsules onto cotton

The final publication is available at Springer via http://dx.doi.org/10.1007/s10570-015-0600-8[EN] The use of Microcapsules has increased in the textile sector. They have been applied as a possible means of introducing new products to textiles, such as insect repellents, antibiotics, skin moisturizers, etc. Microencapsulation technology has improved the fragrance durability on fabrics. Historically, the durability of the fragrance was poor, especially once the fabric had been washed. Microcapsules have been used in textiles for many years, however their previous characterization, adhesion behaviour and permanence on the fabrics are not well known. Nowadays the majority of textile industries are not able to characterize commercial products, or to study the process of adhering the microcapsule to the fibre's surface nor their functionality. Thus, the characterization of microencapsulated fabrics with different active core and the knowledge of the various application processes becomes a major challenge in the field of microcapsules use. There are various industrial processes to apply microcapsules, but determining optimal amounts of products, temperature, conditions and other process variables are an important challenge for the textile sector in order to achieve the highest depositions and retention of microcapsules. This work is focused on determining and quantifying presence fragrance microcapsules when applied onto fabrics by padding and by bath exhaustion and determining which method is the most effective. Consequently, diverse analysis techniques such as microscopy (SEM), spectroscopy FTIR and XPS have been used. We concluded that proposed techniques seem to be useful to compare fabrics treated with microcapsules. Results demonstrate that padding application gives better yields than bath exhaustion.Bonet Aracil, MA.; Monllor Pérez, P.; Capablanca Francés, L.; Gisbert Paya, J.; Díaz-García, P.; Montava Seguí, IJ. (2015). A comparison between padding and bath exhaustion to apply microcapsules onto cotton. Cellulose. 22(3):2117-2127. doi:10.1007/s10570-015-0600-8S21172127223Bonet M, Quijada C, Muñoz S, Cases F (2004) Characterization of ethylcellulose with different degrees of substitution (DS): a diffuse-reflectance infrared study. Can J Anal Sci Spectrosc 49(4):234–239Bonet M, Capablanca L, Monllor P, Díaz P, Montava I (2012) Studying bath exhaust as a method to apply microcapsules on fabrics. J Text Inst 103(6):629–635Buchert J, Pere LS, Johanson JM, Campbell J (2001) Analysis of surface chemistry of linen and cotton fabrics. Text Res J 71:626–629Fras L, Johanson LS, Stenius P, Laine P, Stana-Kleinscheck K, Ribitsch V (2005) Analysis of theoxidation of cellulosefibresbytitration and XPS. Colloids Surf A 260:101–108Gisbert G, Ibañez F, Bonet M, Monllor P, Díaz P, Montava I (2009) Increasing hydration of the epidermis by microcapsules in sterilized products. J Appl Polym Sci 113(4):2282–2286Hong K, Park S (1999) Melamine resin microcapsules containing fragant oil: synthesis and characterization. J Appl Polym Sci 58:128–131Jing HU, Zuobing X, Rujun Z, Shuangshuang M, Mingxi W, Zhen L (2011) Properties of aroma sustained-release cotton fabric with rose fragrance nanocapsule. Chin J Chem Eng 19(3):523–528Kokot S, Czarnik-Matusewicz C, Ozaki Y (2002) Two- dimensional correlation spectroscopy and principal component analysis studies of temperature-dependent IR spectra of cotton-cellulose. Biopolymers 67:456–469Kondo T, Sawatari C, Manley RJ, Gray DG (1994) Characterization of hydrogen bonding in cellulose synthetic polymer blend systems with regioselectively substituted methylcellulose. Macromolecules 27(1):210–215Miró Specos MM, Escobar G, Marino P, Puggia C, Defain Tesoriero MV, Hermida L (2010) Aroma finishing of cotton fabrics by means of microencapsulation techniques. J Ind Text 40(1):13–32Monllor P, Bonet M, Cases F (2007) Characterization of the behaviour of flavour microcapsules in cotton fabrics. Eur Polym J 43:2481–2490Monllor P, Bonet M, Sánchez L, Cases F (2009) Thermal behaviour of microencapsulated flavours when applied to cellulose fabrics. Text Res J 79(4):365–380Monllor P, Capablanca L, Gisbert J, Díaz P, Bonet M (2010) Improvement of microcapsule adhesion to fabrics. Text Res J 80(7):631–635Nelson G (1991) Microencapsulates in textile coloration and finishing. Rev Prog Color Relat Top 21:72–85Nelson G (2001) Microencapsulation in textile finishing. Rev Prog Color Relat Top 321:57–64Nelson G (2002) Application of microencapsulation in textiles. Int J Pharm 242:55–62Rodrigues SN, Fernandes I, Martins IM, Mata VG, Barreiro F, Rodrigues AE (2008) Microencapsulation of limonene for textiles application. Ind Eng Chem Res 47:4142–4147Rodrigues SN, Martins, IM, Fernades IP, Gomes PB, Mata VG, Barreiro MF, Rodrigues AE (2009) Scentfashion®: microencapsulated perfumes for textile application. Chem Eng J 149(1–3):463–472. ISSN:1385-8947Sócrates G (1997) In: Infrared characteristic group frequencies. Tables and charts, 2nd ednTopalovic T, Nierstrasz VA, Bautista L, Jocic D, Navarro A, Warmoeskerken MMCG (2007) XPS and contact angle study of cotton surface oxidation by catalytic bleaching. Colloids Surf A 296:76–85Wilson RC, Pfhol WF (2000) Study of crosslinking reactions of melamine/formaldehyde resin with hydroxyl functional polyester by generalized 2-D infrared spectroscopy. Vib Spectrosc 23:13–22Zhang H, Wang X (2009) Fabrication and performances of microencapsulated phase change materials based on n-octadecane core and resorcinol-modified melamine-formaldehyde shell. Colloids Surf A 332:129–13