Manuscript accepted on : January 07, 2010
Published online on: 28-06-2010
Extraction of Natural Dyes for Textile Dyeing from the By-Products of the Timber Industry
J. O. Otutu1*, E. Osabohien1 and E. M. Efurhievwe2
1Department of Chemistry, Delta State University, PMB 1, Abraka. Delta Nigeria.
2Petroleum Products and Quality Control Laboratory, Nigerian National Petroleum Company, Ekpan, Warri Nigeria.
Corresponding Author email: osabohieneemma@yahoo.com
ABSTRACT: The timber industry releases considerable amount of wastes which contain natural dyes. Such wastes could serve as sources for the extraction of natural dyes for textile dyeing operations. The extraction of various shades of brown colours from the bark of woods meant for the timber industry is of interest. By-products such as barks of wood were collected from Abura (Bahia elolom) and Ghana obeche (Triplochiton scleroxylon). They were grounded into powder and extracted and test dyeing on cotton, nylon 66 and acrylic fabrics were performed. The extracts were applied as direct dyes and in the presence of copper Sulphate or iron (II) Sulphate, Tin (II) chloride and potassium dichromate as mordants. The results prove the potential of such waste as a source for dyestuff extraction. To obtain textile dyeing with acceptable fastness properties, however, rigorous selection of dyes and development of suited processes is required. A considerable number of brown natural dyes need further research to optimize the low level of fastness to light.
KEYWORDS: Timber industry; natural dyes; textile dyeing; fastness; natural and synthetic fibres
Download this article as:Copy the following to cite this article: Otutu J.O , Osabohien E,Efurhievwe E.M. Extraction of Natural Dyes for Textile Dyeing from the By-Products of the Timber Industry.Biosci Biotechnol Res Asia 2010;7(1) |
Copy the following to cite this URL: Otutu J.O , Osabohien E,Efurhievwe E.M. Extraction of Natural Dyes for Textile Dyeing from the By-Products of the Timber Industry.Biosci Biotechnol Res Asia 2010;7(1).Available from: https://www.biotech-asia.org/?p=8890 |
Introduction
Natural dyeing has been used by humans for many purposes varying from the coloration of textiles, food and cosmetics in order to impart other functions to them. However, natural dyes became progressively replaced by the1,2 emergent of synthetic dyes.
The future demand for more sustainable processes can be seen as a driving force for new strategies which could bring a revival of natural dyes in
textile dyeing. However, the costs of such dyes have to be lowered considerably and the quality level of the dyeing needs substantial improvement3,4.
There are many reasons why many people are now turning to natural dyes even though synthetic dyes are more convenient to purchase and dye with. Each plant provides an amazing diversity of shades. From one plant you may obtain between 5-15 varying colours and shades. These colours and shades are subtle and tend to harmonize with one another. The resulting fabrics or fibres are now original pieces – it is extremely difficult for anyone to duplicate exactly5.
Also, there is the question of ecology as people become more aware of environmental factors, dyers are searching for alternatives. Natural dyes are seen as more eco-friendly as, unlike their synthetic counterparts, since they are all derived from nature6,7. The dye baths can be neutralized through the addition of either acid or alkaline solution and then poured down the sink or onto the garden.
In addition, worldwide efforts to promote the cultivation of natural dye plants and their technical application for natural dyeing have been made by some projects such as the Pris CA in Italy and the INDINK in the UK8. A more efficient production process of natural dyeing is being developed by them. Also the re-evaluation of ecology is a major trend for influencing colour. Naturally dyed fabrics can meet the current global greening movement9.
In Nigeria, the timber industry releases considerable amounts of wastes containing extractable natural dyes. Thus, the huge amounts of by-products such as the barks of wood released from the timber industry could be an important sustainable source for extraction of natural dyes as colorants for textiles.
The work presented in this article focuses on the extraction of natural dyes from the barks of woods used in the timber industry. The article summarises an experimental evaluation of potential sources of natural dyes. Important aspects presented in this paper considered extraction of dyestuff, extraction time and determination of selected fastness properties (light fastness, wash fastness) as key properties for technical and commercial success. The study also tried to identify the effects of mordants on the colometric properties of the naturally and synthetic dyed fabrics.
Experimental
Materials
A scoured (100% cotton fabric) was used for the natural fibre. Nylon 66 (plain-weaved nylon 66 fabric having 3898 ends/in and 3307 picks/m) and acrylic fabrics were used for the synthetic dyeing.
Instruments
The Uv-visible spectra of the dye extracts were determined by a genesys IOS VL 200 series spectrophotometer. The melting point of the solid dye extracts were also carried out with the use of gallenkemp block melting point apparatus and are uncorrected. The infra-red spectra was determined by the Nicolet, Averser 300 series spectrophotometer.
Extraction of dye and purification
Samples of the relatively fresh wood barks were collected from two sawmills located at Sapele, Delta State, Nigeria. A weighed powdered amount of the plant bark was treated with ethanol in a beaker. In the standard procedure, the ratio mass of plant bark to volume of ethanol was set at 1:50 which means that 1.0g of plant bark was extracted with 50ml ethanol. The extraction was performed for two days at 65oC. The solvent (ethanol) was evaporated from the solution and the solid extract was purified by recrystallization from dimethylformamide in the case of abura. TLC analysis showed one spot for the abura dye extract and two spots for the Ghana Obeche dye extract.
Dyeing
Dyeings were performed by an exhaustion method using a liquor ratio of 1:20. For 1.0g of goods, a dyebath volume of 20ml was applied. The dyeing experiments were performed in aluminium vessels at 100oC dyeing temperature. 1.0g of scoured cotton, nylon 66 and acrylic fabrics were used. After dyeing, unfixed dyestuff was removed by soaping off using non-ionic detergent, rinsed with water and dried. The detailed dyeing procedure is given in the literature10
Mordanting
The mordants used were ferrous sulphate, copper’ sulphate, potassium dichromate and tin(II) chloride. The required amounts of mordant was dissolved in warm water and stirred till a clear solution was obtained. In premordanting, the fabric was first treated with the metal salt solution and then dyed. In post mordanting, the fabric was first dyed and then treated with the metal salt solution.
Fastness Properties
Light fastness
Light fastness was determined using artificial illumination with a zenon arc light according to DIN 54004 and AATCC 107-1997 (Xenotest, Hanau, Germany) and was related to the standard scale of blue dyeings11,12.
Wash fastness
The wash fastness of all the dyed samples was tested according to ISO washing test number 313. As a result of the high alkali sensitivity of natural dyes, it is recommended that these textiles be washed with non-alkaline soap only. Hence, non-ionic soap was used in this procedure. The composite samples measuring 10 x 4cm, were washed with 5g/L lissapol N at 50oC for 45min in a launderometer. The change in colour of the treated test specimens and the degree of staining of the two adjacent undyed fabrics was evaluated using the standard grey scale (marks 1-5, 1= poor, 5 = excellent)14.
Results and Discussion
The results of the UV-visible spectra (Table 1) of the dye extracts show strong broad absorption curves in the range 380 – 800nm with lmax 431 nm. This indicates that the area under the absorption curve, which is the true measure of tinctorial strength of a dye is large. The broad absorption curve is a characteristic typical of brown colours 15.
Table 1: Dyestuff extraction and spectroscopic properties
Source | Physical
state |
Wavelength
(nm) |
IR (KBr)cm-1 | MPoC |
Abura |
Solid |
431 |
3438(OH, NH)
1630 (C-O-C) 1072(S2-) 581(Ar-ring) |
>360oC |
Ghana Obeche |
Solid |
431 |
3442(OH,NH)
2931(C-H) 1631 (C-O-C) |
>360oC |
579 (Ar-ring) |
The infra-red spectra of the dye extracts (Table 1) showed broad bands at 3436cm-1 and 3442cm-1 indicating OH and possibly NH groups. There is absence of strong bands in the 1800-1650cm-1 regions which is indicative of the fact that there is no carbonyl group in the compounds. The band at 1630cm-1 suggests the presence of ethers (C-O-C). Band at 1072cm-1 suggests the presence of sulphur in the abura dye extract. The band at 2926cm-1 for the abura dye extract and at 2931cm-1 for the Ghana obeche dye extract are indicative of the presence of C-H stretching vibrations in aryl compounds16,17. The results of the meeting point determination of the dye extracts show that the compounds are very stable to heat.
Table 2: Fastness properties of dye extracts on nylon 66 fabric
Light fastness | Wash fastness
Abura Ghana Obeche |
||||||||
Mordant | Sample colour on fabric | Abura | Ghana Obeche | CC | SC | SA | CC | SC | SA |
CuSO4 | UM
PreM PostM |
1
2 2 |
1-2
2 2-3 |
2
3 3-4 |
3-4
4 5 |
3
5 4-5 |
2-3
3-4 4 |
3-4
4-5 4 |
4-5
3-5 4-5 |
SnCl2 | PreM
PostM |
2-3
2-3 |
2
3 |
3
4 |
4-5
5 |
4-5
4-5 |
3-4
3-4 |
4-5
4 |
5
4 |
K2Cr2O7 | PreM
PostM |
2
3 |
2-3
2-3 |
3-4
4 |
4-5
4-5 |
4-5
4-5 |
4-5
4 |
4-5
4-5 |
4-5
4-5 |
FeSO4 | PreM
PostM |
2
2-3 |
2
2 |
3-4
3 |
4
4-5 |
4-5
4-5 |
3
3-4 |
4
4-5 |
4
4 |
CC = Colour change, SC = staining on cotton, SN = staining on nylon, UM = Unmordanted, PreM = premordanted, PostM = postmordanted.
Light and Wash fastness
Light-fastness was identified to be the major hint for a general introduction of all tested natural dyes. A light fastness of at least 2-3 was set as a lower limit, for positive selection; however, values of light-fastness of 2 perhaps could be increased by further research activities to exceed the lower limit of 2-3.
In many cases, light fastness of natural dyeings is strongly influenced by the type of mordant used. For the results shown in Tables 2, 3 and 4, significant improvement of light fastness is found when mordants were added. The light fastness gradings show that unmordanted samples gave very poor fastness to light. This agrees with other unmordanted natural dyes such as munjistin that had earlier been reported18,19. However, the dye extract from abura gave moderate fastness on cotton and acrylic fabrics. It was also observed, that mordanting generally improved light fastness but postmordanting was found to be much more effective.
The results of the wash fatness of the two colorants obtained (Tables 2, 3 and 4) also showed that mordanting in general enhanced wash fastness. Mordanting with tin (ii) chloride or iron (ii) sulphate also gave an improvement in wash fastness but not as high as those of copper sulphate and potassium dichromate as mordants.
Table 3: Fastness properties of dye extracts on cotton fabric.
Light fastness | Wash fastness
Abura Ghana Obeche |
||||||||
Mordant | Sample | Abura | Ghana Obeche | CC | SN | SA | CC | SN | SA |
CuSO4 | UM
PreM PostM |
2
3 2-3 |
1-2
2-3 2-3 |
2
4 3-4 |
2-3
4 4 |
3
4-5 4-5 |
2
3 4 |
4
4-5 4 |
4-5
4-5 4-5 |
SnCl2 | PreM
PostM |
2-3
3 |
2-3
3 |
4
3 |
4-5
4-5 |
4
4 |
3
3-4 |
4-5
4-5 |
4
4 |
K2Cr2O7 | PreM
PostM |
3
3 |
2-3
2-3 |
4
4-5 |
4
4 |
4-5
4-5 |
4-5
4-5 |
4
4 |
4-5
4 |
FeSO4 | PreM
PostM |
1-2
2 |
2
2 |
3-4
3 |
4-5
4-5 |
4
4-5 |
3
3-4 |
4
4-5 |
4
4-5 |
CC = Colour change, SN = staining on nylon, SA = staining on acrylic.
Table 4: Fastness properties of dye extracts on acrylic fabric
Light fastness | Wash fastness
Abura Ghana Obeche |
||||||||
Mordant | Sample | Abura | Ghana Obeche | CC | SN | SA | CC | SN | SA |
CuSO4 | UM
PreM PostM |
2
3 3 |
1-2
2-3 3 |
2
3 3-4 |
2-3
4-5 4 |
3
4 4-5 |
2
3 3-4 |
4
5 5 |
4
5 4-5 |
SnCl2 | PreM
PostM |
2-3
3 |
2-3
2-3 |
3-4
4-5 |
4-5
4-5 |
4-5
4-5 |
4
4-5 |
5
5 |
5
4-5 |
K2Cr2O7 | PreM
PostM |
2-3
3 |
2-3
2-3 |
4-5
4-5 |
4-5
4-5 |
4
4-5 |
4-5
4-5 |
5
4-5 |
5
5 |
FeSO4 | PreM
PostM |
2
2 |
2
2 |
3-4
3 |
4-5
4 |
4-5
4 |
3-4
4-5 |
5
5 |
4-5
5 |
CC = Colour change, SN = staining on nylon, SC = staining on cotton.
Effects of mordanting on colour
Mordating has been applied to improve colour fastness of naturally dyed fabrics. In addition it is well-known that colour characteristics of the fabrics may change after mordating20. Therefore, we observed the effects by investigating the samples dyed with two different colorants (dye extracts) without any mordants and other samples dyed with the same colorants to those above followed by mordanting before and after dyeing with one of copper, or iron, tin and chrome.
Abura dye extract
Unmandated, this type dye extract gave brown colour on cotton, nylon and acrylic fabrics. Postmording with potassium dichromate cause the colour to become deeper shade on acrylic fabric whereas premording with copper salt and tin (II) salt gave brown shade, the depth of colour increased on the three fabrics in the order nylon<cotton<acrylic. Thus, postmordating and premordanting are much more effective on the acrylic fabric.
Ghana Obeche dye extract
Nylon, cotton and acrylic fabrics dyed with these two dye extracts was light brown in colour without mordanting. Premordanting with copper salt and tin II salt caused the colour to become deeper brown shade. Postmordanting with potassium dichromate also gave brown shade on nylon, cotton and acrylic fabrics respectively. Thus, premordanting with copper salt and tin salt are more effective on the three substrates. The iron-mordant did not produce any reasonable change in shade on the three substrates except on cotton fabrics.
Conclusions
The presented results prove the possibility of using the by-products of the timber industry as a source for the dyeing of natural and synthetic textiles. The type of substrates used for dyeing affected the shade and fastness of the dye extracts. Nylon fabric for instance, gave lighter shades of brown whereas cotton and acrylic gave deeper shades respectively. Fastness to water was also observed to be higher on acrylic fabric than on nylon and cotton fabrics. The type of mordant and method of mordanting seemed to have also affected the colour shades of the dyed fabrics. Thus, potassium dichromate produced more pronounced shades especially on acrylic fabric in postmordanting than the other metal salts used. Hence, postmording is more effective on the acrylic fabric.
References
- B. Noah, Dyes from Plants. Lagos. Jide publishing house, 1995.
- B. Glover and J.H. Pierce. Are natural colorants good for your health? Journal of Society of dyers and colourist 109 (1) 1993.
- G.W. Taylor. Natural dyes in textile application, Rev. Prog. Coloration 16(5) 59-64, 1986.
- I.A. Syed Revival of natural dyes in Asia. J. Soc. Dyers and colourists 109 (1), 1993.
- J.O. Otutu. Light fastness of natural dyes from danta (Nesogodia papaverifera and Elem (Nimbodia nivea) on cotton, nylon and acrylic fabrics. J. Chem. Soc. Nig., 33(2) 135-138, 2008.
- P. Guinot, A. Roge; A Gargadennec, C. Andry. Dyeing plants screening: An approach to combine past heritage and present development, coloration technol 122-93-101, 2006.
- S. Paul, E. Glover and A. Sharma. Eco-friendly dyeing of wool with Jatropha dye. Int. Dyer 188:55-60, 2003.
- E. Tsatsaromi and M. Liakopoulou-Kyriakides. Effects of enymatic treatment on the dyeing of cotton and wool fibres with natural dyes. Dyes and Pigments 29(3) 203-209, 1995.
- Y. Eunjou and C. Ju-Yeon. Color analysis of natural-dyed fabrics. Wiley periodicals. 33(2), 2008.
- T. Bechtold, A. Turcanu E. Ganglberger and S. Geissler, Natural dyes in modern textile dye-houses: how to combine experiences of two centuries to meet demands of the future. J. Cleaner production 11(2)499-509, 2003.
- D. Cristea and G. Vilarem. Improving light fastness of natural dyes of cotton yarn. Dyes and pigments, 70 238-245, 2006.
- American Association of Textile chemists and colourists, AATCC technical manual, Vol. 75, Research triangle park, NC, 2000.
- P.O. Nkeonye, Fundamental principles of textile dyeing, printing and finishing zaria; Ahmadu bello university press, 1987.
- B.S 1006; CO2 Colour fastness to washing; Test 3-Standard methods for the determination of the colour fastness of textiles and leather. 5th edn. The society of dyers and colourists, 1990.
- P. Gregor, in the chemistry and application of dyes, eds R.W. David and H. Geoffrey. New York and London. Plenum press, 1994.
- A.M. James, L.D. David and R.R. Osca, Experimental methods in organic chemistry. New York, Saunders pub. 1982.
- K. Venkataraman. The analytical chemistry of synthetic dyes, New York. John Wiley and Sons., 1977.
- D. Gupta, M.L. Gulrajani and S. Kumari. Light fastness of naturally occurring anthraquinone dyes on nylon. Coloration technol, 120(5), 205-266, 2004.
- J. Kim and J. Lee. Natural dyeing in Korea. Seoul National University Press, 2003.
- M.L. Gulrajani R.C. Srivastava and M. Goel colour gamut of natural dyes on cotton yarns. Coloration Technol 117(4)225-228, 2001.
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