Sage Journals: Discover world-class research

Abstract

In order to limit modification to the surface of wool fibers and decrease pollution caused by conventional chemical treatments using chlorine, a water-in-oil-type reversed-phase microemulsion with decamethylcyclopentasiloxane as the external phase was prepared containing very small amounts of an aqueous solution of alkali. The edges of the wool cuticle scales were modified by the alkali in aqueous solution contained in the reversed-phase microemulsion. The external phase decamethylcyclopentasiloxane can be recycled after application. In this paper, the solubility of water in the reversed-phase microemulsion and its stability were first studied and then it was applied in the treatment of wool. The results showed that surfactant sodium alcohol ether sulfate/NaOH aqueous solution was quite stable. Felting shrinkage of treated wool was reduced and the initial dyeing speed was higher than that for untreated wool. The corroded scales of treated wool were observed by scanning electron microscopy and the bromine Allwörden reaction with bromine water was reduced or eliminated after treatment. This adsorbable organohalogen-free modification should be useful in improving the manufacturing properties of wool, such as hydrophilicity, and as a pretreatment for wool printing.

Keywords

microemulsion alkali wool surface modification hydrophilicity shrink resistance

Get full access to this article

View all access options for this article.

References

Liu

Wang

. A comparative study on the felting propensity of animal fibers. Text Res J 2007; 77: 957–963.

Chen

Wei

et al.

Research on pretreatment of wool fabrics printing with low temperature plasma. J Text Res 1989; 10: 8–11.

Makinson

. Shrinkprooﬁng of wool, New York: Marcel Dekker, 1979.

Jocic

Jovancic

Trajkovic

et al.

Influence of a chlorination treatment on wool dyeing. Text Res J 1993; 63: 619–626.

Kan

Chan

Yuen

CWM

et al.

Effect of low temperature plasma, chlorination, and polymer treatments and their combinations on the properties of wool fibers. Text Res J 1998; 68: 814–820.

Bettina

. Adsorbable organic halogens in textile effluents. Rev Prog Coloration 1992; 22: 14–21.

Wang

Dai

. Influence of process conditions on the formation of AOX compounds during wool chlorine pretreatment. J Dong Hua Univ 2001; 18: 1–3.

Steenken

Zahn

. Investigation of the alkaline modification of wool using new analytical methods for the determination of degradation. JSDC 1986; 102: 269–273.

Lagermalm

Philip

. The action of alkali on the epicuticle of wool. Text Res J 1950; 10: 668–670.

10.

Kantouch

El-Sayed

. Surface modiﬁcation of wool fabric for printing with acid and reactive dyes. Color Technol 2006; 122: 213–216.

11.

McPhee

. The reaction of wool with sodium hydroxide in concentrated salt solutions. Text Res J 1959; 4: 303–310.

12.

Sawada

Ueda

. Enzyme processing of textiles in reverse micellar solution. J Biotechnol 2001; 89: 263–269.

13.

Sawada

Ueda

. Dyeing of protein fiber in a reverse micellar system. Dyes Pigm 2003; 58: 99–103.

14.

Liu

Miao

. A study on non-aqueous dyeing of reactive dyes in D5. Adv Mater Res 2012; 441: 138–144.

15.

Leigh

Richard

Paal

. Toxicology and humoral immunity assessment of decamethylcyclopentasiloxane (D5) following a 1-month whole body inhalation exposure in Fischer 344 rats. Toxicol Sci 1998; 43: 28–38.

16.

Leigh

Richard

Robert

. Inhalation toxicology of decamethylcyclopentasiloxane (D5) following a 3-month nose-only exposure in Fischer 344 rats. Toxicol Sci 1998; 43: 230–240.

17.

Naylor

Stannett

Deffieux

et al.

The radiation-induced polymerization of dimethylcyclosiloxanes in the liquid state: 3. Copolymerization of D3 with D4 and D4 with D5, reactivities and interpretation. Polymer 1994; 35: 1764–1768.

18.

GreenEarth. https://www.greenearthcleaning.com (accessed 24 July 2016).

19.

Union. http://www.uniondc.com (accessed 24 July 2016).

20.

Bharadwaj

Kames

. The photochemical formation and gas-particle partitioning of oxidation products of decamethyl cyclopentasiloxane and decamethyl tetrasiloxane in the atmosphere. Atmos Environ 2001; 35: 87–95.

21.

Lindberg

. Allwörden’s reaction. Text Res J 1949; 1: 43–45.

22.

King

NLR

Bradbury

. The chemical composition of wool V. The Epicuticle. Aust J Biol Sci 1968; 21: 375–384.

23.

Fraser

RDB

Rogers

. The bromine Allwörden reaction. Biochim Biophys Acta 1955; 16: 307–316.

24.

Lang

Lalem

Zana

. Quaternary water in oil microemulsions. 1. Effect of alcohol chain length and concentration on droplet size and exchange of material between droplets. J Phys Chem 1991; 95: 9533–9541.

25.

Manoj

Jayakumar

Rakshit

. Physicochemical studies on reverse micelles of sodium bis (2-ethylhexyl) sulfosuccinate at low water content. Langmuir 1996; 12: 4068–4072.

The structure and properties of wool treated with a reversed-phase microemulsion containing aqueous alkali

Abstract

Keywords

Get full access to this article

References