外文--基于溶膠—凝膠技術(shù)的棉織物的表面處理

1、<p>　　Surface Review and Letters, Vol. 16, No. 5 (2009) 715–721</p><p>　　c World Scienti?c Publishing Company</p><p>　　SURFACE TREATMENT OF ANTI-CREASE FINISHED</p><p>　　COTTON

2、 FABRIC BASED ON SOL–GEL TECHNOLOGY</p><p>　　Charles Q. Yang,*,? Qingliang He,? and Bojana Voncina?</p><p>　　Department of Textiles, Merchandising and Interiors, The University of Georgia, Athen

3、s, Georgia 30602, United States</p><p>　　Faculty of Mechanical Engineering, Department of Textiles, University of Maribor, Maribor, Slovenia</p><p><b>　　Abstract:</b></p><

4、p>　　The silica sol was applied onto 1, 2, 3, 4-butanetetracarboxylic acid (BTCA) ?nished cotton</p><p>　　fabrics with the attempt to improve the physical properties especially the tensile strength which&l

5、t;/p><p>　　had a big loss in the previous anti-crease ?nishing processing. The parameters including the</p><p>　　dosage of the coupling agent, the concentration and pH of the sol and the processing

6、 methods</p><p>　　were studied in detail. Compared to the sample ?nished with BTCA, 11.8% of the increase in</p><p>　　the crease recovery angle and 18.6% of the enhancement in the tensile streng

7、th of the cotton</p><p>　　fabric also treated with silica sol in the better selected conditions were obtained. The abrasion</p><p>　　resistance was also improved.</p><p><b>　　

8、Keywords:</b></p><p>　　Sol–gel; cotton fabric; anti-crease ?nishing; strength loss.</p><p>　　1. Introduction</p><p>　　Cotton fabrics shrink and wrinkle easily due to the</p

9、><p>　　shift and deformation of cellulose macromolecules</p><p>　　after repeated wet rubbings.1 N , N -dimethylol-</p><p>　　4,5-dihydroxyethyleneurea (DMDHEU) had been</p><p

10、>　　the most widely used crosslinking agent in tex-</p><p>　　tile industry to provide cotton fabrics in the anti-</p><p>　　crease ?nishing owing to the ether linkages formed</p><p&g

11、t;　　between DMDHEU and the cellulose molecules. The</p><p>　　time desirable mechanical stability properties were</p><p>　　given and the potential to release formaldehyde,</p><p>　　a

12、 known human carcinogen, was also imparted.2,3</p><p>　　Signi?cant decrement but not avoidance in the</p><p>　　release of formaldehyde could be obtained by ether-</p><p>　　ifying DM

13、DHEU or by continuing to treat the</p><p>　　?nished fabric with hydrolyzed glycidyloxypropyl-</p><p>　　trimethoxysilane (GPTMS) solutions.4 Another ?n-</p><p>　　ishing agent, 1, 2,

14、3, 4-butanetetracarboxylic acid</p><p>　　(BTCA) catalyzed with sodium hypophosphite</p><p>　　(SHP) can provide an alternative possibility for</p><p>　　the formaldehyde-free crease r

15、esistant ?nish.5–7</p><p>　　However, the serious strength loss due to depoly-</p><p>　　merizations and crosslinkings of the cellulose macro-</p><p>　　molecules is one reason for its

16、 relatively small market</p><p>　　penetration.8</p><p>　　Sol–gel technology is a chemical processing based</p><p>　　on hydrolysis and subsequent condensation of metal</p><

17、;p>　　or semimetal alkoxides.9 It is conducted at a low</p><p>　　temperature which also enables the incorporation</p><p>　　of organic compounds into the inorganic struc-</p><p>　　

18、ture without decomposition.10 The sol–gel process</p><p>　　has been recognized as an excellent technological</p><p>　　approach for coating textiles to impart new and</p><p>　　freque

19、ntly multifunctional properties to the sam-</p><p>　　ples, such as water and oil repeling, UV radiation</p><p>　　protection, antimicrobial property, self-cleaning and</p><p>　　contr

20、olled release of fragrance.11–20 Applications of</p><p>　　silicone coating technology can be seen in sleep-</p><p>　　ing bags, paragliding, hot-air balloons and high-</p><p>　　perfo

21、rmance sportswear.21 The e?ects of silica sol</p><p><b>　　?</b></p><p>　　Corresponding author.</p><p><b>　　715</b></p><p><b>　　716</b&g

22、t;</p><p>　　treatment on the properties of the cotton fabric were</p><p>　　previously reported, and it was found that sol–gel</p><p>　　treatment could remarkably increase the abrasi

23、on</p><p>　　resistance.22</p><p>　　In this paper, BTCA ?nished cotton fabrics were</p><p>　　treated with silica sol to improve the decreased ten-</p><p>　　sile strength

24、 in the anti-crease ?nishing. E?ects of the</p><p>　　parameters on the crease recovery angle, the tensile</p><p>　　strength and the abrasion resistance were discussed</p><p>　　in de

25、tail to obtain the better cotton fabric sol treat-</p><p>　　ment conditions.</p><p>　　2. Experimental</p><p>　　2.1. Materials</p><p>　　The cotton fabric (weight 141.0 g

26、/m2). BTCA</p><p>　　and SHP were available from Herst International </p><p>　　Group. Tetraethoxysilane (TEOS),ethanol (EtOH), γ-methacryloxypropyltrimethox- ysilane (MPTS) and </p><p&

27、gt;　　the anhydrous sodium carbon- ate were supplied by</p><p>　　Sinopharm Chemical Reagent Co., Ltd. The</p><p>　　hydrochloride and the ammonia were obtained from</p><p>　　Sinopharm

28、 Shanghai Chemical Reagent Co.</p><p>　　2.2. Preparation of silica sol</p><p>　　Certain amounts of TEOS were added to the mixture</p><p>　　of EtOH and di?erent amounts of MPTS, foll

29、owed by</p><p>　　adding deionized water and catalyst. The molar ratio</p><p>　　of TEOS, EtOH and H2O was 1:6:5. The mixtures</p><p>　　were stirred with a magnetic stirring apparatus

30、 and</p><p>　　kept in a concussing water bath kettle for 6 h for</p><p>　　su?cient reactions.</p><p>　　2.3. Anti-crease ?nishing</p><p>　　BTCA (100 g/L) and SHP (50 g/L

31、) were added to</p><p>　　a given amount of deionized water and the result-</p><p>　　2.4. Silica sol treatment</p><p>　　Anti-crease ?nished cotton fabrics were impregnated</p>

32、<p>　　with the prepared silica sol for 2 min, followed by</p><p>　　padding twice to a wet pickup of about 80%. The</p><p>　　treated fabrics were then predried at 80?C for 4 min</p>

33、<p>　　and cured at 160?C for 3 min.</p><p>　　2.5. Crease recovery angle</p><p>　　measurement</p><p>　　The cotton fabrics were conditioned at 20?C and 65%</p><p>　　

34、R.H. for 24 h and tested on the machine YG(B)541D</p><p>　　according to ISO 2313:1972. Fabrics were creased and compressed under controlled conditions of time and load. </p><p>　　After removal o

35、f the creasing loads, the angles formed </p><p>　　between the limbs were measured.5 Five samples were</p><p>　　measured in the warp direction and ?ve in the ?ll direction. </p><p>　

36、　The values presented were the sums of each average warp </p><p>　　and ?ll values.</p><p>　　2.6. Tensile strength measurement</p><p>　　According to ISO 13934-1:1999, the cotton fabr

37、ics</p><p>　　were conditioned at 20?C and 65% R.H. for 24 h</p><p>　　prior to testing on the machine YG(B). The tensile </p><p>　　strengths were averages of each three mea-surements

38、 </p><p>　　in the warp direction.</p><p>　　2.7. Abrasion resistance</p><p>　　measurement</p><p>　　The abrasion resistance was measured according to</p><p>

39、　　ISO 5470. The samples were mounted in a speci-</p><p>　　men holder, subjected to a de?ned load, and rubbed</p><p>　　against a standard fabric in a translational move-</p><p>　　men

40、t on the machine YG522. The abrasion resistance </p><p>　　property was denoted by the Wloss value,</p><p>　　ing mixture was stirred until complete dissolution</p><p>　　occurred. The

41、 cotton fabrics were impregnated with</p><p>　　Wloss = W0 ? W1/S</p><p><b>　　(1)</b></p><p>　　the mixture for 2 min at room temperature and</p><p>　　then pa

42、dded twice to a wet pickup of about 80%</p><p>　　with a laboratory pad mangle obtained from Labor-</p><p>　　tex Co., Ltd., Taiwan. The treated fabrics were</p><p>　　predried at 80?C

43、 for 4 min and cured at 160?C for</p><p><b>　　3 min.</b></p><p>　　where Wloss was the weight loss per square meter</p><p>　　(g/m2), W0 was the weight before the experime

44、nt,</p><p>　　W1 was the weight after the experiment and S was</p><p>　　the abrasive area of the sample (20 cm2). The Wloss</p><p>　　values were inversely proportional to the abrasio

45、n</p><p>　　resistance.</p><p>　　Surface Treatment of Anti-Crease Finished Cotton Fabric Based on Sol–Gel Technology</p><p><b>　　717</b></p><p><b>　　No

46、.</b></p><p><b>　　Table 1.</b></p><p>　　Di?erent processing Methods.</p><p>　　Processing Method</p><p><b>　　1</b></p><p><

47、b>　　2</b></p><p><b>　　3</b></p><p><b>　　4</b></p><p><b>　　5</b></p><p><b>　　6</b></p><p><b>

48、　　Padded</b></p><p><b>　　Padded</b></p><p><b>　　Padded</b></p><p><b>　　Padded</b></p><p><b>　　Padded</b></p>

49、<p><b>　　Padded</b></p><p><b>　　the</b></p><p><b>　　the</b></p><p><b>　　the</b></p><p><b>　　the</b>&l

50、t;/p><p><b>　　the</b></p><p><b>　　the</b></p><p>　　anti-crease ?nishing bath → Dried → Cured → Padded the silica sol bath → Dried → Cured</p><p>　　

51、silica sol bath → Dried → Cured → Padded the anti-crease ?nishing bath → Dried → Cured</p><p>　　anti-crease ?nishing bath → Dried → Padded the silica sol bath → Dried → Cured</p><p>　　silica sol

52、 bath → Dried → Padded the anti-crease ?nishing bath → Dried → Cured</p><p>　　anti-crease ?nishing bath → Padded the silica sol bath → Dried → Cured</p><p>　　silica sol bath → Padded the anti-cr

53、ease ?nishing bath → Dried → Cured</p><p>　　2.8. Treatment methods</p><p>　　In order to investigate the e?ect of the processing</p><p>　　methods of the two times of ?nishing on the

54、physical</p><p>　　properties of the cotton fabrics, samples were treated</p><p>　　with di?erent methods illustrated in Table 1.</p><p>　　3. Results and Discussion</p><p&g

55、t;　　3.1. Dosage of MPTS</p><p>　　MPTS in the reaction system might play the roles of</p><p>　　promoting the hydrolyzed TEOS to polycondensate,</p><p>　　crosslinking the polycondensa

56、ted polymer ?lm with</p><p>　　the cotton fabric or conglutinating the macromolec-</p><p>　　ular chains of cotton ?bers or all.</p><p>　　Figure 1 demonstrated that the crease recover

57、y</p><p>　　angle was dependent on the dosage of MPTS. It</p><p>　　was clear that the value increased severely when</p><p>　　the increase in the MPTS dosage was from 0.005 to</p&g

58、t;<p>　　0.02 mol/L. This enhancement could be interpreted</p><p>　　in terms of all roles of MPTS. Firstly, hydrolyzed</p><p>　　TEOS polycondensated rapidly and formed high</p><

59、p>　　degree polymers in the presence of MPTS. Secondly,</p><p>　　formed polymers were crosslinked to the fabrics also</p><p><b>　　255</b></p><p><b>　　250</b&g

60、t;</p><p><b>　　245</b></p><p><b>　　240</b></p><p><b>　　235</b></p><p>　　with MPTS. Thirdly, the macromolecular chains</p><

61、;p>　　of cotton ?bers were conglutinated by MPTS too.</p><p>　　The higher the dosage of MPTS added, the higher</p><p>　　the degree of the polymerization; more polymers</p><p>　　we

62、re anchored to the fabric and more macromolec-</p><p>　　ular chains were conglutinated. The polymers cross-</p><p>　　linked to the fabrics formed a transparent ?exible</p><p>　　thre

63、e-dimensional silicon oxide ?lm. The fabric was</p><p>　　bended for the excuse of external forces. When the</p><p>　　applied force was withdrawn, the internal stresses</p><p>　　betw

64、een the macromolecular chains trend the fab-</p><p>　　ric to restore its original shape. The conglutinating</p><p>　　improves the forces between the macromolecular</p><p>　　chains.

65、The anchored ?lm also improved the forces</p><p>　　due to its ?exibility and its crosslinking with the</p><p>　　fabric. So increasing the dosage of MPTS could</p><p>　　improve the a

66、bility of restoring from deformation,</p><p>　　thus enhancing the crease recovery angle. There</p><p>　　might be another explanation: the capacity of outer</p><p>　　force resistance

67、 could be improved by the bending</p><p>　　rigidity which corresponded to the diameter of ?ber.</p><p>　　MPTS worked as a bridge which made hydrolyzed</p><p>　　TEOS aggregate mutual

68、ly. The higher the dosage of</p><p>　　MPTS added, the greater the amount of the poly-</p><p>　　mer anchored on the fabric, the thicker the diame-</p><p>　　ter of ?ber. This results

69、in stronger bending rigidity,</p><p>　　stronger capacity of outer force resistance and higher</p><p>　　crease recovery angle. When the MPTS dosage was</p><p>　　increased further, th

70、e enhancement in the crease</p><p>　　recovery angle was very small. It had likely reached a</p><p>　　saturated value. The dosage of 0.02 mol/L was prob-</p><p>　　ably enough to aggr

71、egate hydrolyzed TEOS, anchor</p><p>　　the ?lm onto the ?bers and conglutinate the macro-</p><p><b>　　0</b></p><p><b>　　0.01</b></p><p><b>

72、;　　0.02</b></p><p><b>　　0.03</b></p><p><b>　　0.04</b></p><p><b>　　0.05</b></p><p>　　molecular chains of ?bers. Dosage in exces

73、s would</p><p>　　Dosage of MPTS/mol/L</p><p>　　Fig. 1. E?ect of dosages of MPTS on the crease recovery</p><p>　　angles of fabrics treated with concentration of the sol</p>&l

74、t;p>　　100% and pH of the sol.</p><p>　　not make signi?cant e?ect on the crease recovery</p><p><b>　　angle.</b></p><p>　　Figure 2 showed that the tensile strength</

75、p><p>　　decreased with increasing dosage of MPTS. For</p><p><b>　　718</b></p><p><b>　　660</b></p><p><b>　　640</b></p><p>&

76、lt;b>　　260</b></p><p><b>　　250</b></p><p><b>　　620</b></p><p><b>　　240</b></p><p><b>　　600</b></p><p

77、><b>　　580</b></p><p><b>　　0</b></p><p>　　0.01 0.02 0.03 0.04</p><p><b>　　0.05</b></p><p><b>　　230</b></p>&

78、lt;p><b>　　40</b></p><p><b>　　60</b></p><p><b>　　80</b></p><p><b>　　100</b></p><p><b>　　120</b></p>

79、<p>　　Dosage of MPTS/mol/L</p><p>　　Fig. 2. E?ect of dosages of MPTS on the tensile stre-</p><p>　　ngths of fabrics treated with concentration of the sol</p><p>　　100% and pH

80、of the sol 8.</p><p>　　the existence of many hydroxyl groups, the forces</p><p>　　between the macromolecular chains of cotton ?bers</p><p>　　such as the hydrogen bonds are very stro

81、ng. When</p><p>　　there is an external force, the breaking could ?rst</p><p>　　occur in the bonds in the internal of the molecular</p><p>　　chains of amorphous areas but not the bon

82、ds between</p><p>　　the macromolecular chains. That means that cotton</p><p>　　Concentration of the sol/%</p><p>　　Fig. 3. E?ect of concentrations on the crease recovery</p>

83、<p>　　angle of fabrics treated with MPTS 0.02 mol/L and pH</p><p>　　of the sol 8.</p><p><b>　　640</b></p><p><b>　　620</b></p><p><b>　

84、　600</b></p><p><b>　　580</b></p><p><b>　　560</b></p><p>　　fabric is broken for the breaking but not the slip-</p><p><b>　　40</b&g

85、t;</p><p><b>　　60</b></p><p><b>　　80</b></p><p><b>　　100</b></p><p><b>　　120</b></p><p>　　page of molecular

86、 chains. Furthermore, the formed</p><p>　　transparent ?exible three-dimensional silicon oxide</p><p>　　?lm on the fabric and the conglutination between the</p><p>　　?bers enhanced t

87、he forces between the macromolec-</p><p>　　ular chains. Thus, the movements of macromolecu-</p><p>　　lar chains conglutinated were restricted and uneven</p><p>　　distribution of int

88、ernal stress which mostly concen-</p><p>　　trated to the molecular chains of the amorphous</p><p>　　areas occurred. This resulted in a decline in strength.</p><p>　　When the externa

89、l force was strong enough, the</p><p>　　bond in the internal of the molecular chains of amor-</p><p>　　phous areas was broken and the fabric destroyed.</p><p>　　The more MPTS added,

90、 the more polymers were</p><p>　　anchored to the fabric and the more the cellulose</p><p>　　molecular chains were conglutinated. As a result,</p><p>　　the tensile strength decreases

91、 sharply. Compared to</p><p>　　the sample only treated with BTCA, the increase of</p><p>　　20.5% in the tensile strength of the silica sol treated</p><p>　　fabric could be obtained

92、when the MPTS dosage was</p><p>　　0.02 mol/L.</p><p>　　3.2. Concentration of the sol</p><p>　　Figures 3 and 4 demonstrated the e?ects of concen-</p><p>　　tration of the

93、 sol on the crease recovery angle and</p><p>　　the tensile strength of the cotton fabric. The crease</p><p>　　recovery angle increased from 238.8 to 252.4? and</p><p>　　the tensile

94、strength increased from 578.2 to 635 N</p><p>　　Concentration of the sol/%</p><p>　　Fig. 4. E?ect of concentrations on the tensile strength</p><p>　　of fabrics treated with MPTS 0.0

95、2 mol/L and pH of the</p><p><b>　　sol 8.</b></p><p>　　by increasing the sol concentration from 50 to 100%.</p><p>　　These enhancements were acceptable, since increas-<

96、;/p><p>　　ing the sol concentration would increase the availabil-</p><p>　　ity of the sol, enhance the amount of the hydrolyzed</p><p>　　TEOS, improve the degree of the polymerization

97、and</p><p>　　consequently increase the thickness of the ?exible</p><p>　　?lm anchored onto the cotton fabric. The higher</p><p>　　the concentration of the sol, the thicker the ?exib

98、le</p><p>　　?lm. When the fabric was bended for outer forces,</p><p>　　the thick ?lm anchored onto the surface by MPTS</p><p>　　could trend the fabric to restore its original shape&

99、lt;/p><p>　　for its ?exibility. The thicker the ?lm, the stronger</p><p>　　the capacity of restoring its shape and the higher</p><p>　　the crease recovery angle. The ?lm also had some&

100、lt;/p><p>　　intensity for the silicon–oxygen–silicon bond formed</p><p>　　by polycondensating the hydrolyzed TEOS. When</p><p>　　the outer force was imparted, the silicon–oxygen–</p

101、><p>　　silicon bond of the ?lm could partly bear the internal</p><p>　　stress and less external stress would be applied to the</p><p>　　macromolecular chains of the cotton fabric, thus

102、 the</p><p>　　treated fabric could sustain greater external forces.</p><p>　　So the ?lm formed onto the surface of the ?ber could</p><p>　　Surface Treatment of Anti-Crease Finished

103、Cotton Fabric Based on Sol–Gel Technology</p><p><b>　　719</b></p><p>　　Table 2. E?ect of concentrations of the sol on the abra-</p><p>　　sion resistances of fabrics trea

104、ted with MPTS 0.02 mol/L</p><p>　　and pH of the sol 8.</p><p>　　Wloss/g/m2 (×10?4 )</p><p><b>　　280</b></p><p><b>　　260</b></p><

105、p><b>　　240</b></p><p><b>　　Cycles</b></p><p><b>　　40</b></p><p><b>　　1</b></p><p><b>　　4.10</b></p>

106、<p><b>　　2</b></p><p><b>　　1.50</b></p><p><b>　　3</b></p><p><b>　　1.35</b></p><p><b>　　4</b></p>

107、;<p><b>　　1.00</b></p><p><b>　　5</b></p><p><b>　　0.50</b></p><p><b>　　6</b></p><p><b>　　0.50</b></

108、p><p><b>　　7</b></p><p><b>　　0.50</b></p><p><b>　　220</b></p><p><b>　　200</b></p><p><b>　　80</b>&l

109、t;/p><p><b>　　4.92</b></p><p><b>　　2.60</b></p><p><b>　　2.30</b></p><p><b>　　2.45</b></p><p><b>　　2.32&l

110、t;/b></p><p><b>　　2.27</b></p><p><b>　　2.19</b></p><p><b>　　3</b></p><p><b>　　4</b></p><p><b>　　5&

111、lt;/b></p><p><b>　　6</b></p><p><b>　　7</b></p><p><b>　　8</b></p><p><b>　　9</b></p><p><b>　　10 11&l

112、t;/b></p><p><b>　　120</b></p><p><b>　　200</b></p><p><b>　　5.34</b></p><p><b>　　Destroy</b></p><p><b&

113、gt;　　3.10</b></p><p><b>　　9.10</b></p><p><b>　　3.11</b></p><p><b>　　8.70</b></p><p><b>　　3.20</b></p><p

114、><b>　　7.90</b></p><p><b>　　3.07</b></p><p><b>　　8.01</b></p><p><b>　　2.89</b></p><p><b>　　7.10</b></p&

115、gt;<p><b>　　2.88</b></p><p><b>　　6.90</b></p><p><b>　　pH</b></p><p>　　Fig. 5. E?ect of pH values on the crease recovery angles</p>

116、<p>　　1: Virgin (Anti-crease ?nished cotton fabric);</p><p>　　2, 3, 4, 5, 6, 7: Treated with sol concentrations 50, 60,</p><p>　　of fabrics with MPTS 0.02 mol/L and concentration of</p&g

117、t;<p>　　the sol 100%.</p><p>　　70, 80, 90, 100% respectively.</p><p>　　the value decreased. In the sol solution, the hydroly-</p><p>　　also improve the tensile strength of th

118、e cotton fab-</p><p>　　ric and the higher the concentration of the sol, the</p><p>　　greater the increase in the tensile strength. In other</p><p>　　words, improving the sol concent

119、ration was bene?cial</p><p>　　to enhance the crease recovery angle and the tensile</p><p><b>　　strength.</b></p><p>　　The abrasion resistance experiment results are</

120、p><p>　　presented in Table 2. The silica sol-treated sam-</p><p>　　ples did not show serious damages after frictions</p><p>　　in 200 cycles in comparison with the destruction of</p&

121、gt;<p>　　the sample only treated with BTCA in 127 cycles.</p><p>　　That might be because silicon–oxygen–silicon bond</p><p>　　of the ?lm formed on the surface was stronger than</p>

122、<p>　　the bonds between or in the macromolecular chains.</p><p>　　When the same external force was imparted to the</p><p>　　untreated and treated cotton fabrics, the damage of</p>&

123、lt;p>　　the sol-treated cotton fabric might be less severe. On</p><p>　　the other hand, the abrasion resistance was depen-</p><p>　　dent on the crease recovery angle and the tensile</p>