Research Article Volume 4 Issue 6
1Bahir Dar Textile Share Company, Ethiopia
2Textile Chemistry Research and Innovation Centre, Ethiopian Institute of Textile and Fashion Technology, Bahir Dar University, Ethiopia
Correspondence: Nalankilli Govindan, Textile Chemistry Research and Innovation Centre, Ethiopian Institute of Textile and Fashion Technology, Bahir Dar University, Bahir Dar, Ethiopia, Tel 251 984624403
Received: September 21, 2018 | Published: December 10, 2018
Citation: Emrie YM, Govindan N. Reusing of pretreatment liquor bath in textile wet processing. J Textile Eng Fashion Technol. 2018;4(6):378-384. DOI: 10.15406/jteft.2018.04.00169
Textile industries are focusing on minimizing their production costs by using sustainable technologies and by inventing new methods. Pretreatment is the heart of textile wet processing. Most of the Textile Companies are using combined pretreatment process with exhaust and semi-continuous method. After the treatment is over, the bath with residual chemicals are drained out into effluent treatment plant. In this study, an attempt has been made to reuse the residual chemicals by replenishing the measured amounts of chemicals again for combined pretreatment process. The concentration of the main chemicals, after pretreatment, before draining was analyzed and quantified. In case of pretreatment process in a Jigger machine, the liquor is drained out after three turns (6 ends) with residual chemicals, then the concentrations of H2O2 and NaOH was assessed in that. In case of pad-roll bleaching, the fabric roll is rotated in the steaming chamber for twelve hours and washed in a counter current washing machine, then the concentration of chemicals were analyzed after washing is over. Based on the chemical analysis results, by replenishing with measured amounts of chemicals, pretreatment is done in both laboratory scales repeatedly up to four times without changing water and on the bulk production; it has been done by mixing used water and fresh water. The effectiveness of pretreatment was evaluated in terms of absorbency, whiteness, yellowness and the effect in subsequent reactive dyeing and pigment printing in terms of colour strength, colour difference and fastness properties after each pretreatment. It was observed that acceptable results which can fulfill the requirements of the products can be obtained by reusing the pretreatment bath.
Keywords: pretreatment, reuse, replenishing, jigger, pad-roll
To remove the impurities from cotton, a massive amount of water is required in this process per day. It is estimated that on an average, almost 100 liters of water is used to process only 1 kg of textile goods and thus the water consumption of an average sized textile mill having capacity only 8 tons/day is about 1.6 million liters per day.1 Among the textile fibers, about 48% are cotton fibers that we consume as clothing materials all over the globe.2 All the cotton goods as woven or knit, all goes through the pretreatment process like desizing, scouring, bleaching etc. before dyeing process. These pretreatment processes create huge pretreatment liquor and wash liquor which the industries discharge as textile effluent. All the chemicals used in desizing, scouring and bleaching of cotton fabric do not fully react with it. As a result, pretreatment liquor contains some residual chemicals like caustic soda, peroxide and other auxiliary chemicals.3,4 In a conventional process, scouring and bleaching is done once which results in underutilization of alkali and hydrogen peroxide. But in most of the companies, all these three processes are combined into one, which is a single stage pretreatment process by using jiggers and pad- roll bleaching machines. In case of Jiggers, all the liquor after six ends chemical rotation are drained out; and in case of pad- roll bleaching, after 6-12 hours of rotation in the reaction chamber, the residual chemicals are washed out in washing machine.
The textile industry utilizes abundant water in pretreatment, dyeing and finishing processes. There is a need to adopt economical practices for the use of water in textile industries. The quantity of water required for textile processing is large and varies from mill to mill depending on the fabrics produced and processed, the quantity and quality of the fabric, processes carried out and the sources of water. The longer the processing sequences, the higher will be the quantity of water required. Bulk of the water is utilized in washing at the end of each process.5
Recent experiences with water reuse in the textile industry indicate that recycled water, having impurity levels above historically accepted limits, can be used to produce first-quality goods. The minimum water quality for process reuse, therefore, is defined as the treated wastewater containing the highest level or concentration of impurities that will consistently produce an end-product of first quality.6The needs of water recycling & reuse in wet processing has necessitated an appropriate, cost effective water recycling method for reducing the pollution level and fresh water consumption rate.7 Conservation of water and chemicals by reusing the same bath for several times in cotton pretreatments as desizing, scouring and bleaching,8–10 reuse of clarified print washes water in washing blankets and screens of the print machine,11 alkali in mercerizing,12 chemicals in scouring and bleaching,13 bleaching bath for four times14 and eight times,15 unexhausted alkali and oxidizing agent in the scouring and bleaching,16 reuse of bleach liquour for eight times,15 bleaching liquor for scouring,8 washing water.9,17–19 are some of studies carried out with considerable success in industrial practice.
The present work is to find the possibilities of reusing the textile pretreatment liquor or wash liquor in disizing, scouring and bleaching of cotton fabric. It is an appropriate, cost effective recycling method for reduction in chemical consumption, fresh water and the pollution level. The pretreatment liquor or wash liquor from single bath was collected periodically and analyzed for presence of useful chemicals and their strength. Then, they will be used for the purpose of combined desizing, scouring and bleaching by replenishing with required quantity of necessary chemicals. Combined pretreated and subsequently dyed fabric samples were assessed for the performances and compared against the samples prepared by conventional method. The focus of this project is on recycling and reusing water and chemicals in the textile pre-treatment process without prior waste water treatment.
Materials
100% cotton fabric (plain-weave, 21 Ne, 24 ends per inch, 18 picks per inch, areal density of 147g/m2), Jiggers, pad-roll machine, chemicals such as hydrogen per oxide, caustic soda, Organic stabilizer, wetting agent, optical brightening agents, acetic acid, C.I Reactive Blue 19, C.I Pigment Blue 15, sequestering agent, iodine solution, phenolphthalein indicator, Sulphuric acid, hydrochloric acid, common salt, soda ash, potassium per manganate, binder, thickener, emulsifier were used for the study.
Methods
Method -1
Method - 2
To avoid and minimize contamination of the fabric due to degraded starch and other impurities in the used liquor, it is thought that better to mix used liquor and fresh water in different proportions. These mixing with fresh water can be used for full bleached fabric rather than the one to be dyed / printed. The following three blends of used and fresh water were used.
The chemical concentrations already analyzed in the above method 1 were used for calculating the requirements in this method. Combined pretreatment is done by different jiggers and pad-roll bleaching machine. The chemical recipes which are used in Jiggers 50 % concentrated H2O2 - 5gpl, Flake caustic soda (NaOH) - 4gpl, Organic Stabilizer- 1g/l, Wetting agent - 1gpl.
Evaluation
The fabric absorbency was assessed by the following three methods such as, water drop test (AATCC/ASTM Test Method TS-0180), wicking height (AATCC Test Method 197) and sinking time test (AATCC Test Method 17-1994) methods.
Desizing efficiency was evaluated for the presence of residual starch by Tegewa scale rating test which involves iodine absorption and change of colour from no colour change (no starch present) to pale blue to bluish violet (presence of starch size or a blend of starch and synthetic size) to Brown (presence of modified starch or a blend of starch/PVA size) and scale ranging from 8 (best, no starch) to Pale blue to Bluish violet to 1 (Brown). The whiteness index was evaluated as per CIE standard method. The CIE Whiteness Index value (CIE WI) will be determined for the bleached fabric using AATCC test method using a Colour eye Reflectance spectrophotometer 3100 under illuminants D-65, day light and TL84 at 2˚ Observer and Yellowness index as per ASTM method E313.
To understand the effect of the above results on the dyeing behavior, reactive dyeing has been done by using C.I Reactive Blue 19 by dyeing in 1% (on weight fabric) shade for all treated fabrics. As recommended by the dye supplier, the dyeing was done by exhaust dyeing method at 60˚C for 60 minutes. After dyeing is over, the samples were evaluated for color strength (K/S) value, color difference (ⵠE), percent reflectance using Colour eye Reflectance spectrophotometer 3100 and Wash fastness, rubbing fastness, Light fastness by following the standard procedures viz. IS: 764:79 Test Method 3, AATCC Test Method 8, AATCC Test Method 16 - Option 3 respectively.
Chemical analysis
The residual liquor after 6 ends in Jigger were collected and analyzed for two main chemicals, hydrogen per oxide (H2O2) and caustic soda (NaOH) concentration by titration method. The results are presented in Table 1.As observed from Table 1, out of 5g/l H2O2 and 4g/l NaOH, 1.58g/l and 1.61g/l respectively are still present unutilized that can reused in a single Jigger treatment. The pH is in the acceptable range for of oxidative bleaching that is around 11.30. The treatment after replenishing is done based on the analysis results. The first analysis was done with the liquor after the conventional pretreatment is over and second analysis is also done with the liquor after first analysis is over, third and fourth analysis are also done from second and third liquor respectively. Above fourth analysis it was not possible as more than 90 % of the water was consumed in replenishing process from once up to four times. Without replacing water, by adding the above measured chemicals, combined pretreatment is done up to four times in the laboratory scale.
Parameters |
1st Analysis |
2nd Analysis |
3rd Analysis |
4th Analysis |
Average |
pH |
10.2 |
11.6 |
12.05 |
11.3 |
11.29 |
Amount of H2O2 in (g/l). |
1.64 |
1.4 |
1.62 |
1.66 |
1.58 |
Replenished H2O2 amount out of 5 (g/l) |
3.36 |
3.6 |
3.38 |
3.34 |
3.42 |
Amount of NaOH in (g/l) |
0.8 |
1.48 |
2.04 |
2.12 |
1.61 |
Replenished NaOH amount out of 4gpl (g/l) |
3.2 |
2.52 |
1.96 |
1.88 |
2.39 |
Table 1 H2O2 and NaOH analysis results
The results from Table 2 show that there is no significant difference between the conventional one and the replenished pretreatment in terms of absorbency which is in the order of acceptable level. The drop test results of all samples are less than five seconds. The sinking time test for the conventional and the average values of the replenished is similar. The Tegawa scale rating results shows 8 for the conventional and 5 to 6 for the replenished, the difference is because of hydrolysed starch in the form of dextrin or glucose present in used liquor that is interfering. However, it was found that the samples prepared with used liquor after replenishing can be used for full bleaching, dyeing and printing purpose.
Parameters |
Conventional |
Replenishment |
||||
1st |
2nd |
3rd |
4th |
Average |
||
Drop test (second) |
< 5 |
< 5 |
< 5 |
< 5 |
< 5 |
<5 |
Sinking time test (second) |
6.5 |
6.4 |
6.2 |
7.5 |
6 |
6.5 |
Wicking height test (cm) |
7.9 |
6.5 |
6.3 |
9.5 |
8 |
7.6 |
Residual starch (Tegawa rating) |
8 |
5 |
5 |
6 |
6 |
5.5 |
Table 2 Pretreatment test results
As shown in Table 3 and Figures 1 & 2, the conventional and the replenished average values are within the acceptable range for the degree of whiteness. In day light as illuminant, the whiteness index was 141.89 and 137.25 for conventional and replenished respectively. The yellowness index value is negative which shows that the whiteness index is higher and as whiteness index increases yellowness index decreases. The differences of yellowness index between conventional and replenished average graphs of two samples are almost over lapped, which means, the difference is insignificant.
Samples |
Illuminant |
Conventional |
Replenishment |
||||
1st |
2nd |
3rd |
4th |
Average |
|||
Whiteness index |
D65 |
140.09 |
129.19 |
136.34 |
143.91 |
133.16 |
135.65 |
TL84 |
136.3 |
126.65 |
132.76 |
140.16 |
129.48 |
132.26 |
|
Daylight |
141.89 |
130.38 |
138.12 |
145.67 |
134.85 |
137.25 |
|
Yellowness index |
D65 |
-26.45 |
-25.29 |
-26.15 |
-29.37 |
-25.2 |
-26.5 |
TL84 |
-33.55 |
-32.82 |
-33.55 |
-37.52 |
-31.96 |
-33.96 |
|
Daylight |
-26.66 |
-25.22 |
-26.35 |
-29.52 |
-25.37 |
-26.62 |
Table 3 Whiteness and Yellowness index
The dyeing performance of treated samples is evaluated with similar shade and dyestuff. Dyeing have also been done all the above pretreated fabrics by using, C.I Reactive Blue19 of 1% owf. The dyed samples are tested for K/S value (color strength), % Reflectance and Color difference values with 2˚ observer and under D65, TL84 and daylight light source by using spectrophotometer at 620nm wave length (λmax).
From the results presented in Table 4 and in Figure 3, it is clear that pretreatment with replenished liquor gives little lesser colour strength. The conventional showed a % Reflectance of 10.78 % and replenished average was 11.41 %, due to the fact that, as the K/S value increases percent reflectance decreases. The Colour strength was 3.69 for the conventional and ranging from 3.30 to 3.61 with average of 3.44 for the replenished pretreated & dyed. Color difference between conventional and replenished pretreated was 1.61 to 2.32 with average of 1.7 to 1.9 under all light sources which is quite significant.
Samples/Factors |
Illuminant |
Conventional |
Replenishment |
||||
|
|
|
1st |
2nd |
3rd |
4th |
Average |
K/S value |
D65 |
3.69 |
3.43 |
3.3 |
3.43 |
3.61 |
3.44 |
% Reflectance |
10.78 |
11.44 |
11.78 |
11.43 |
10.97 |
11.41 |
|
Color Difference |
D65 |
Reference |
1.82 |
2.31 |
2.05 |
1.63 |
1.95 |
TL84 |
1.61 |
2.02 |
1.81 |
1.48 |
1.73 |
||
Daylight |
1.88 |
2.32 |
2.06 |
1.65 |
1.98 |
Table 4 K/S value, % Reflectance and Color difference of the dyed samples
The fastness properties of both the conventional and replenished pretreated & dyed samples have good results as it is shown by the grey scale readings in Table 5. The washing fastness results of both staining and fading rating was in the range of 4-5 and 4-5 dry & 4 wet rubbing values for both conventional and replenished average.
Parameters |
Conven-tional |
Replenishment |
|||
1st |
2nd |
3rd |
4th |
||
Washing fastness |
4/4.5 |
4/4.5 |
4/4.5 |
4/4.5 |
4/4.5 |
Dry rubbing fastness |
4-5 |
4-5 |
4-5 |
4-5 |
4-5 |
Wet rubbing fastness |
4 |
4 |
4 |
4 |
4 |
Table 5 Fastness of dyed fabrics
The laboratory results are not reproducible in bulk stage in general. The main reasons are:
Bulk results
Keeping the laboratory results in mind and considering contamination of water because of decomposed starch present in liquor, the following experiments have been done on the mass production machines by using small jiggers. The drained out liquor was used for pretreatment again in Jigger that had a capacity of 300liters of solution and can load 135kg of fabric.
The collected liquor had 1.6g/l of H2O2 out of 5/l and 1.4g/l of NaOH out of 4g/l. The remaining amounts of chemicals and other auxiliary chemicals were added to make up the conventional recipe before using again jigger. Then, as shown in the Table 6, the pretreatment was carried out and the performance was assessed and compared with conventional. The chemical amounts in Table 6 are based on the standard recipe, H2O2 -5g/l, NaOH - 4g/l, Organic stabilizer- 20% of H2O2, wetting agent- 1g/l and OBA - 0.6g/l. With these, after doing pretreatment on jigger, whiteness and yellowness index are checked and compared with the conventional with same chemical recipes. In addition to this, on the treated fabrics, pigment printing has been done with C.I Pigment Blue 15 and the performance was assessed in terms of fastness, color strength, color difference and percent reflectance.
The whiteness and yellowness index values of the bulk samples are summarized in Table 7 and in Figure 4. It is clear that the whiteness index is decreasing and yellowness index is increasing from the conventional to fourth replenished pretreated. The reason for this is the decomposed starches in the used liquor are reacting with per oxide and interfering in the overall process. Even though, it was a decreased result, the variation is not too much and it can be used for printing, grounding and off-white fabric. To make more white fabric per oxide amount must be increased to compensate the reaction. C.I Pigment Blue 15 printed samples K/S value (color strength); % reflectance and Color difference values were tested at 600nm wavelength (λmax) (Figure 5) (Table 8) (Table 9).
Chemicals |
Conventional |
100% used liquor |
70% used + 30% fresh |
50% used + 50% fresh |
30% used + 70% fresh |
H2O2 (g) |
1500 |
1020 |
1165 |
1260 |
1355 |
NaOH (g) |
1200 |
780 |
905 |
990 |
1075 |
Organic Stabilizer (g) |
300 |
205 |
230 |
250 |
270 |
Wetting agent (g) |
300 |
300 |
300 |
300 |
300 |
OBA (g) |
180 |
180 |
180 |
180 |
180 |
Table 6 Replenished amounts of chemicals in the bulk trial
Samples/ Factors |
Illuminant |
Conventional |
70 % fresh & 30 % used |
50% fresh & 50% used |
30% fresh & 70% used |
100% used |
Average |
Whiteness index |
D65 |
101.26 |
88.64 |
86.74 |
82.62 |
65.15 |
80.79 |
Daylight |
102.62 |
89.8 |
87.83 |
83.74 |
65.67 |
81.76 |
|
S |
99.13 |
87.5 |
85.86 |
81.76 |
65.85 |
80.24 |
|
Yellowness index |
D65 |
-9.41 |
-4.63 |
-3.44 |
-2.88 |
4.22 |
-1.68 |
Daylight |
-9.71 |
-4.94 |
-3.74 |
-3.22 |
3.96 |
-1.99 |
|
TL84 |
-9.9 |
-4.83 |
-3.56 |
-2.97 |
4.56 |
-1.7 |
Table 7 Whiteness and Yellowness index value of the bulk trial
Samples |
Illuminant |
Conventional |
Replenishment |
||||
1st |
2nd |
3rd |
4th |
Average |
|||
K/S value |
D65 |
4.81 |
4.57 |
4.57 |
4.7 |
4.52 |
4.59 |
% Reflectance |
8.67 |
9.05 |
9.05 |
8.84 |
9.13 |
9.02 |
|
Color difference |
D65 |
Reference |
0.77 |
1.01 |
1.29 |
1.62 |
1.17 |
Daylight |
0.78 |
1 |
1.33 |
1.54 |
1.16 |
||
TL84 |
0.8 |
1.06 |
1.28 |
1.65 |
1.2 |
Table 8 K/S value, % Reflectance and Color difference of the printed samples
Fastness/Parameters |
Conventional |
100% used |
50% used & 50% fresh |
70% used & 30% fresh |
30% used & 70% fresh |
Washing fastness* |
4/4.5 |
4/4.5 |
4/4.5 |
4/4.5 |
4/4.5 |
Dry rubbing fastness* |
4 |
4 |
4 |
4 |
4 |
Wet rubbing fastness* |
3 |
3 |
3 |
3 |
3 |
Table 9 Pigment printing parameter test results of the bulk product
*Both Change in colour and staining on white
The K/S values of the printed samples showed very minor variation between conventional and replenished pretreated. It is 4.80 for the reference and 4.59 for the replenished (average). The reflectance values showed a little increase, but the difference is less than 1. The color difference was around 1.1 under three light sources. The fastness properties of the printed samples are within acceptable range based on gray scale value. Both staining and fading of washing fastness it 4; dry rubbing and wet rubbing staining values have 4 and 3 respectively.
Based on the results, it can be concluded that pretreatment liquor and wash liquor can be reused in the pretreatment process of cotton instead of fresh water. The pretreatment liquor and wash liquor can safely be reused after replenishing with measured amounts of H2O2, NaOH and other auxiliary chemicals based on the analysis results for the scouring-bleaching purpose of next batch with satisfactory bleaching, printing and dyeing performance. As a result, the reuse of pretreatment liquor ensures saving of a lot of chemicals consumption, water consumption as well as reduce waste water discharge and effluent load and the reuse of wash liquor ensures the reduced consumption of huge amount of fresh water.
None.
Author declares there is no conflict of interest in publishing the article.
©2018 Emrie, et al. This is an open access article distributed under the terms of the, which permits unrestricted use, distribution, and build upon your work non-commercially.