RFT in Reactive Dyeing
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Transcript of RFT in Reactive Dyeing
A Journey towardsRFT (Right First Time) Processing
in Exhaust Dyeing
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Industry Trends
Number of fashion Trends
Garment Manufacturers and Retailers Consumers
Range of fabricsColour changesEnvironmental pressure
Order sizeRepeat ordersLead times
Choice
Fabric performance
Colour fastness
Value for money
Decreasin
g
Increasing
Increasing
Which ultimately trends in increasing Production Cost and reducing Profit margins
Colour Fastness Requirements
Increasing
Effects on DyehouseEnergy costs
Water and effluent costs
Labour costsNumber of Competitors
Create additional pressure on Production Costs Retailer’s knowledge of process costs
‘Performance for Profit’
q How much is performance affecting the profitability?
-Impact of Right First Time performance
-Benefits of true dyestuffs & user friendly Processes
-Achieving high standards of process control
q Can we meet retailer needs with cost-effective approaches?
-Optimize dyestuffs Selection to meet exactly customer needs
Aiming at Blind Dyeing in Dye-houses
1. Review Industry Trends
2. Impact of RFT
3. Dyeing Performance
4. Optimizing dye selection
5. Process Technology for different Substrates
6. Process Selection
7. Process Control
8. Control Parameters
9. Test procedures
10. Determine effectiveness with ‘on-line’ control
11. Usage of software to make technology user friendly
Main Focus of Standard Operating Procedures
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q Assignable variables
Measurable factors that influence dye performance can be controlled:1. Liquor ratio2. Internal fabric pH3. Fixation temperature4. Specific gravity (salt concentration)5. Addition profile6. Fixation pH7. Time
q Random variables
Factors that require intervention of management to effect control of Impurities in:1. Cotton2. Water supply3. Chemicals eg QC of raw materials4. Controlled Coloration concept
Control Options
The Benefits Of Right-first-time
FinancialLower Costs per Batch
Increased Output
Improved Profit Margin
Non-financialEnhanced Customer Service
Improved Quality of Goods
Reduced Effluent Load
RFT (Right First Time) Performance & Setting Specifications
q Measures of performanceShade Reproducibility
- Lab to bulk CMC 2:1 delta E 1.0- Bulk to bulk CMC 2:1 delta E 1.0
Level Dyeing- Average throughout batch, piece to piece CMC 2:1 delta E 0.3
Colour Fastness- Customer specific- Washing, Repeat Washing, Rubbing, Light
q Non-conformance
- Off shade-Lab to Bulk-needs shading addition
- Off shade-Bulk to Bulk-needs shading addition
- Unleveled-side to side variation, shading or patchy
- Fails in Q.C Test-staining, fading
- Combinations of the above
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Process Cost Productivity Profit
Blind Dyeing 100 100 100
Small Addition 110 80 48
Large Addition 135 64 -45
Stripping & Re-dying 206 48 -375
Cost of Non-conformance-for Cotton Exhaust Processing
RFT Rate % 50 70 80 90 100Cost 167 143 125 111 100Additional Cost 12 9 6 3 0Total Cost 179 152 131 114 100Batches 7.0 8.4 9.8 11.2 14
Cost of Shading (30% of original batch cost)
Increasing Productivity
Increase in Productivity 10% 20% 30% 40%Reduction in total cost % 9 17 23 29Additional batches/week 1.4 2.8 4.2 5.6
Reducing dye costs
% dye costs -10 -20 -30 -40Saving on total cost % 2.5 5.0 7.5 10
1. Dyes 25%
2. Chemicals 15%
3. Wage & Salary 15%
4. Capital Investment& Other Overhead 13%
5. Energy 15%
6. Water 10%
7. Depreciation 7%
Model of costing for average colour Cotton Knit Processing
Capacity : 2 batches/day working 7 days a week
Cost control comes from optimization & profit comes from improved performance
Cost Management in Dye-houses
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Number of batches/week at % utilization 9.8
New Total Cost at % utilization 80.5
Actual number of RFT batches 8.8
Additional cost at 90% RFT rate 9.0
Total cost 89.3%
70% Plant Utilization @ 90% RFT
70% Plant Utilization @ 70% RFT
Number of batches/week at % utilization 9.8
New Total Cost at % utilization 80.5
Actual number of RFT batches 6.9
Additional cost at 70% RFT rate 12.0
Total cost 92.5%
Summary
q Increasing RFT from 70 to 90 % reduces costs by 32%
q Increasing Productivity by 30% reduces cost by 23%
q Reducing dye costs by 30% only saves 7%
q Combined effect of increasing RFT from 70 to 90% with increase in Productivity of 30%, even with 30% higher dye costs reduces total cost of production by 44%
q As a bonus additional ‘opportunity’ margin can be generated from increase in productivity.
Reducing dye costs and lower RFT (70 to 60%)
%Cost Reduction 10 20 30 40
Saving on total cost % 2.5 5.0 7.5 10
Additional cost at 60% RFT 24 25 28 29
0
50
1 00
1 50
2 00
2 50
50 5 5 6 0 65 7 0 7 5 8 0 85 9 0 9 5 1 0 0
R FT P erform a nce
Effe
ct o
n C
ost
S eries1
Impact of RFT on Cost
q Performance of dyestuff combinations is critical to cost and profitability of dyeing operation.
q Selection of the most suitable combination is essential for success.
Conclusions
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Audit and Trials Equipment1. Hardness Test Papers
2. pH Meter or pH Papers
3. Thermometer preferably an Infra Red one.
4. Peroxide Test Papers
5. Hydrometer 1.000-1.100
6. Universal Indicator Solution
Fibre pHA simple & quick spotting test with pH indicator solution is done. A slightly acidic state avoids premature fixation during migration phase of dye application. So, Ideal pH of fibre after neutralization is to be 5.0-6.0
Hydrogen Peroxide in dyebath can reduce dye yields and result in poor shade reproducibility. So, carry over of residual Hydrogen Peroxide to Zero.
Residual Hydrogen Peroxide
Fibre absorbency
Simple drop test with any temporary colouring liquid (i.e Potassium Permanganate Solution) can confirm fibre absorbency property.
Scouring and Bleaching Process
80°C X 10’
overflow40°C Acetic Acid
95-105°C
80°C
10’
Pre-dyeing Check:Ø Fabric temperature should be lower than dyeing temperature.Ø No H2O2 is left in fabric.Ø pH of fabric should be within 5.0-6.0.
30’10’ 10’
Peroxide Killer-Enzymatic (Catalase based)
Chemicals
1.0 g/l Anionic Detergent ( Remove dirt )
0.5 g/l Nonionic Detergent ( Remove Oil & Fat )
1.0 g/l Sequestrant-High alkali stable
1.0g/l H2O2 Stabilizer-Organic
3.0 g/l Hydrogen Peroxide(50%)
3.0 g/l Caustic Soda 38°Bé ( NaOH 38°Bé )
Salt Concentration
Confirm Salt concentration with a Hydrometer & SG Charts. Specific gravity is influenced by temperature, so always confirm with a thermometer with Tolerance +/- 5% from target SG
Note: ‘portion-wise’ salt process does not allow this test
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Controlling Liquor Ratio and Salt concentration optimizes shade reproducibilty ensuring highest RFT production performance.
Accurate control of dyebath temperature ensures best possible shade reproducibility. Every after certain period calibrate controller, adjustment needed with an Infra-red one if required.
Dye-bath Temperature
q Same fabric ?
q Same pretreatment (weight loss, ...) ?
q Same liquor ratio ?
q Same salt quality and concentration at same temperature ?
q Soda ash quality ok ?
q Same caustic soda concentration ?
q Temperature indicator at lab equipment and dyeing machine ok or regularly calibrated?
q Right lab method for simulating the bulk process
Reproducibility between lab and bulk
a) Fabric GSMb) Whiteness value of Scoured fabric depending on shade depth.c) Absorbency grade of Scoured fabric of specific GSM.d) Different metal ions contents & total hardness.
As per different impurities content in greige cotton, scouring recipe to be adjusted to achieve required scoured fabric. For this reason, depending on shade depth, required specification for scoured fabrics (ready for dyeing) to be numerically pre-determined. Such as:
Water quality & Standard Textile Process water
Ø pH: 6 - 8Ø Hardness: max. 5 °dHØ Suspended matter: < 1 mg/lØ Organic load: < 20 mg/lØ Residue on ignition: < 50 mg/lØ Iron: < 0.1 mg/lØ Manganese: < 0.05 mg/lØ Copper: < 0.01 mg/lØ Nitrate: < 50 mg/lØ Nitrite: < 5 mg/lØ Free CO2 0 if possible (risk of corrosion)
Water contamination is constantly varying, so check it timely. Is water treatment effective? Is water free from vegetable, suspended solids & other mineral impurities? Hardness contaminants in dyehouse water can adversely effect level dyeing, shade reproducibility & wash off performance.
Liquor RatioConfirming Liquor Ratio
Assumed volume X Expected salt ConcentrationActual Volume = ---------------------------------------------
Measured Salt Concentration
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Common Observations in Bangladeshi Dye-houses:Usual phenomena :qCold water temperature about 40°C-50°C
=All in method needs 25°C-30°Cq Bicarbonates in water about 0.3-0.5 g/l up to 1.0 g/l
=Bad reproducibility in Exhaust method=Alteration of final shade after wash-off (Chromophore sentitivity)
q Poor quality Common & Glauber’s salt : high presence of impurity and Ca, Mg :=Bad reproducibility in Exhaust method=Big problems with Turquoise (Phthalocyanine) & Royal Blue (Anthra-quinone)
q Low quality auxiliaries with insufficient Wetting & Cleaning propertyIn pretreatment phases :
=Incomplete oil, fat, dirt elimination, consequently lead to bad leveled dyeingq No controls after bleaching :
=Peroxide residuals destroy dyestuffs=Out of right pH range (=6.5-8) gives bad reproducibility=Hardness neutralize alkali (NaOH)
q Large use of non-ionic auxiliaries agents in high amount :=These kinds of auxiliaries are difficult to be washed out.=Levelling problem especially with Phthalo-cyanine dyestuffs(Turquoise type)
q Insufficient knowledge about microprocessors in dye machinery :=People often have new technologies but do not accurately know how to use.=A program mistake means a bad dyeing e.g. during alkali dosing.
Check List in Exhaust Dyeing-Reactive1. Water Hardness Test : With Hardness Test-strips.
2. Bicarbonate in dye-bath : Can be tested with Methyl-Orange + HCI Test. Sodium bicarbonate presence in dye-bath water can work as a buffer; increase caustic soda 38°Bé at 0.1 ml/l for each 0.1 g/l sodium bicarbonate.
3. Salt Hardness Test : With Hardness Test-strips and NaOH TestIf total amount of hardness from water, salt & material is more than 10°dH, try to reduce.For water : Increase SequestrantFor salt : Change salt to good qualityFor material : Demineralization can solve it.If not possible, try to dye with Only Soda ash method.
4. Residual Peroxide : With Peroxide test-strips ( if just bleached material )5. Alkali Concentration : Correct concentration to be used ( if different, convert it)
6. Recipe Calculation : Should be done for dyes & auxiliaries, Control workman
-To measure weight, he has to use a balance.
-To measure volume, he has to to use a cylinder or pipette.7. Material quality Checking :
- pH with pH test paper-Hardness with Hardness test-strips
8. Machine parameters :-Dependability of thermometer-Circulation pump’s pressure (in package dyeing of yarn)-Winch speed (in rope dyeing for knit goods)
9. Dyeing Liquor Ratio :The amount of water in Dyeing machine,=Total amount of water - Water needed for (dyestuffs + Alkali) Solution
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Determination of Fibre contaminationSimple extraction technique enables fibre hardness level can be determined after pretreatment. Effective pretreatment reduces carrying over of alkaline earth element contamination of dye-bath.
Ø Extract fibre sample at liquor ratio 20:1, 95°C for 30mins in 100g/l Analytical Salt (Pure NaCl)
Ø Cool solution and test with hardness paper
Ø Calculate approximate hardness level:
1°German Hardness = 17ppm Calcium/Magnesium
So, 5° German Hardness = 85ppm Calcium/Magnesium
Fabric contamination = 85 X 20 ( LR 20:1 )
= 1700ppm
Being a natural fibre, cotton’s contamination levels can vary. So, check regular basis & accordingly dematerialize, if needed & adjust Sequestrant dosing in pretreatment.
Determination of hardness from saltØ Make a solution about 80 g/l Salt( Salt dosing that is used in dye-bath)Ø Check solution hardness with Hardness Test strip or by titration.Ø To confirm, add some ml. of NaOH 38°Bé to solution. If there is any hardness in salt, an opal white snow of Mg(OH)2 Ca(OH)2 can be seen.Ø Consequently in dye bath from 1/2 to approximately same hardness is found from salt.
Determination of total amount of Bicarbonate in waterØ Put 100 ml of water (the same water to be used in dyeing) in a beaker.Ø Add 1-2 drops of Methyl-orange and mix.Ø The water will turn to a pale yellow solution.Ø Start adding drops of 0.1 N of HCl (never stop shaking) till last drop that changes solution colour from yellow to orange-red.Ø Stop immediatelyØ Write down the amount of HCl solution used and put it in the calculation bellow:Ø Bicarbonate in water(gm/l) =(ml) of 0.1N HCl X0.084
Soda Ash pH to be able to reach pH 10.8 to 11.2 in salt solution to reach optimum fixation conditions.
Check Soda Ash Quality
q Hardness adversely effects level dyeing, shade reproducibility and wash off
q Fibre, salt and water contamination all contribute to dyebath hardness
q Measuring levels of contamination of the above allows us to determine required sequestrant concentration to protect & overcome it’s adverse effects
Hardness contamination
Calculating required concentration of dye-bath SequestrantsHardness from prepared Fabric
+Hardness from process Water
+Hardness fro Salt
Total dyebath Hardness
Required Amount of Dye-bath Sequestering agent
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Conversion of Caustic soda soln. with Sodium Bicarbonate
Temporary hardness and it’s neutralization :NaHCO3 + NaoH = Na2CO3 + H2O
Mg 84 40 106 181° dH = 0.03 g/l NaHCO3
10° dH = 0.30 g/l NaHCO3
16.7° dH = 0.50 g/l NaHCO3
20° dH = 0.60 g/l NaHCO3
33.4° dH = 1.00 g/l NaHCO3
+ 0.48 g/l Caustic soda1 g/l NaHCO3 + 1.09 g/l Caustic soda 1.26 g/lNa2CO3
+ 0.62 g/l Caustic sodaNote: Sodium Bicarbonate is generated only by the components in water that cause temporary hardness, not by total hardness of water.
1°dH = 10 mg/l CaO= 22.5 mg/l Ca(HCO3)2
= 30 mg/l NaHCO3
Scouring & Bleaching chemicals:
q Anionic detergent - To remove dirt
q Nonionic detergent - To remove FAT & OIL
Caustic soda:q Proper amount of caustic soda should be used aiming at avoiding oxycellulose
Hydrogen Peroxide:q Cotton should not be over bleached
Hydrogenperoxide Killer:q Good Peroxide killer to be selected that has no effect on both dyestuffs & environment.
Fabric condition to be ensured before dyeing that:q pH on fabric is about be 5.0-6.0 & must be bellow 7.
q No Hydrogen peroxide left in the fabric.
q Fabric temperature is lower than dyeing temperature.
Pre-treatment processing time should not be over 2 hours.
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A brief idea about different types of Textile ColourantsMany years of research have been put into the development and synthesis of dyes. Based on research, there are eight general classes of dyes used to colour different textile fibres. As per their chemical structures & application, they’re described shortly as in the following ways:
1. Acid dyes:It is referred to as anionic dyes, are applied under acidic conditions. Acid dyes are typically used for polyamides (nylon), wool, and silk.
2. Azoic dyes:They are known as developed dyes because they are built from two smaller molecules. They are used for dyeing and printing cellulose fibres.
3. Basic dyes:Due to a net positive ion that is active anchoring portion of dye, they are referred to as cationic dyes. Acrylic and cationic-dye-able polyester fibres are main targets for these dyes, but they were originally designed for silk and wool.
4. Direct dyes:The first dyes to color fibres directly, used without a mordant. They are used for cellulose fibres.
5. Disperse dyes:Disperse dye class does not contain water-solublizing groups & so remains as finely-dispersed particles, were developed for synthetic fibres & are used mainly for polyester, but are also used for acetate, polyamide & acrylic fibres.
6. Reactive dyes:Fibre-reactive dyes are the only dyes that form a covalent bond with fibre. Are primarily used for cellulose fibres, but some of them can also be used for polyamide and wool.
7. Sulfur dyes: These are sulfur-containing dyes with high molecular weights. They are normally insoluble dyes but become soluble & form leuco compound by reduction. Once applied to the fibre, they are oxidized to become insoluble again. They are used for cellulose fibres.
8. Vat dyes:Vat dyes are similar to sulfur dyes as they start as insoluble, become soluble upon reduction, & are oxidized to become insoluble after application. They are used for cellulose dyeing & printing.
9. PigmentOne additional colourant class for fibres is pigments-are not soluble & do not dye fibres; are normally applied in printing process along with a binder which fix the pigment particles on the fabrics & show colour effects. Used on all fibre types, but are only attached to the surface of fibre.
Trichromatic View of Colourants
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Group Type Brand
Vinylsulfone
Monochlorotriazine
Dichloroquinoxaline
Diflourochlorpyrimidine
Monofluorotriazine
Company
ICI
Hoechst
Bayer
Name
Monochlorotriazine&
Vinyl sulfone
Monofluorotriazine&
VinylsulfoneBi-functional
Bayer&
Sandoz
Year
Sumitomo
Ciba Geigy
Ciba Geigy
Ciba Geigy 2000Cibacron L-SMFT/MFT
Cibacron S
Bi-functionalMonofluorotriazine
&Monofluorotriazine
1960
1970
1990
1970
1970
1960
1950
2000Ciba Geigy
Monofluorotriazine+
Monochlorotriazine +
Vinylsulfone
Multi-functionalMFT/MCT/VS
Mono-functional
Bi-functional
Procion H-E
Remazol
Levafix E
Levafix E-A
Sumifix Supra
Cibacron F
Cibacron FN
Mono-functional
Mono-functional
Mono-functional
Mono-functional
BIS-MCT
VS
DCC
DFCP
MCT/VS
MFT
MFT/VS
Drimarene K
Reactive Dyestuffs Details-with it’s major historical landmarks
New Chemical Structure Leading to Higher Colour Value & Fastness
Cibacron SMulti-functional 2000
C (Chromophores) : 2-3 R (Reactive group) : 3
Features of new structureq High fixation rate (>90%)qMedium-high affinityq Flexible moleculesq Good wash-off propertyq Excellent build-up ability
Insertion of two Chromophores & more than two Functional Groups in Dye molecular structures leads to increasing of both Colour value & all round fastness.
RR RR RRCC CC
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Chemical structure of Cellulose & Dyestuffs-Fibre bonding
OH
O
C H 2 O H
H O H
H
HO H H
O
OH
H
C H 2 O H
H
O H
HO HH
OH
O
C H 2 O H
H O H
H
HO H H
OH
H
C H 2 O H
H
O H
HO HH
O
C6H10O5
Mechanisms of Reactive Dye Fixation
F -SO2-CH2-CH2 -OSO3Na
+ Alkali
F -SO2-CH=CH2
+ HO-Cellulose
+ H2O F -SO2-CH2-CH2-O-Cell
F -SO2-CH2-CH2-OH
Ether Bond Additions mech.
VS Dyes
Fibre Reaction 70-95% Hydrolysis 5-30%Hydrolysis
Resistant to Acid
Sensitive to Alkali
F
Vinyl Sulphone Based: Chloro Triazine Based:
F -HN- -NH-R
+ Alkali+ HO-Cellulose
+ H2O
Ester Bond Substitutions mech.
N
N NCl
F -HN- -NH-RN
N NOH
F- HN- - NH-RN
N NO
Cell
Hydrolysis
MCT Dyes
Resistant to Alkali
Sensitive to Acid
F
Reactive Dyes-Cellulose Reaction in brief
-SO2-CH2-CH2-OSO3Na
ß-sulphato ethyl sulphoneF
-SO2-CH=CH2
Reactive vinyl sulphone
-SO2-CH2-CH2-O-CellFibre Reaction
F
FHydrolysis
-SO2-CH2-CH2-OH
+ Alkali
F
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O
NN
H
OO
O
NN
OO
H
O
O
NN
+
OH
l Singulet-O2 reacts with Hydrazone-tautomer of Azo Dye
Griffiths & Hawkins JCS Perkin II 1977, 747
i) Photo Oxidation
Destruction of Chromophores group (Azo Group) resulting in affecting Light or Light Perspiration Fastness of Reactive Dyestuffs in following two ways:
NN
NHN
.+ H - D o n o r NH
N H
N H 2
N H 2•
ii) Photo Reduction
Light Perspiration Fastness of Reactive Dyestuffs
Reactive dyes Fixation
pH value
Temperature
Time
Reactive Dyestuffs Fixation Parameters
OH
HOH2C
O
CH2
O
O
O
O
HOH2C
OH
OHO
OH
OHO
N
NN
Cl
O
HN
NaO3S N
SO3Na
OH
N SO3Na
Reactive Red: Cellulose- dyestuff bonding
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Lower Temperature Sensitivity
Dependence of Colour Strength on Different Dyeing Parameters for Different Anchor Systems
110
100
90
80
70
60
50
4030 40 50 60 70 80
Dyeing Temperature in °C
Rel
ativ
e C
olou
r St
ren
gth
in
%
MCT
MCT-VS
VS
Temperature Sensitivity of Different Functional Groups
Acid Alkali
Stability of dye-fibre bond
pH
VS
MCT/MFT
Bi-functional
SYSTEM - BALANCE
MCT / VSDyeing-Temperature
Relative Fixing RateMCT Dyeing-Temperature
Relative Fixing RateVS
65 °C
65 °C
60 °C
55 °C
60 °C
55 °C
Temperature Sensitivity of different Functional Groups
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Dyeing Parameters in Reactive Dyeing
Liquor ratio
Dyeing temperatureElectrolyte Concerntration
Alkali Concerntration
All reactive dyestuffs are sensible to the above parameters & show differences, more or less. Dyestuffs selection of showing same behaviour can reduce sensitivity to different dye parameters, but decisive for a good reproducibility is a conscientious working method !
Influence of diffusion, substantivity as a function of temperature in fastness washingRel. diffusion
40 50 60 70 80 90 100°C
Temperature
DS
Substantivity
Ø The ‘right profile’ represents the best balance of cost and performance
Ø Preservation of Standardized dye quality
Ø Protection from decomposition Reactions
Ø Reasonable recipe cost according to buyers price
Ø Higher Solubility
Ø Higher Acid & Alkali stability
Ø Excellent dyebath stability
Ø Shade, tinctorial strength, viscosity
Ø Good technical performance to meet the most tailor made requirements
1. Substantivity in neutral electrolyte2. Exhaustion after the addition of alkali3. Fixation efficiency4. Migration Index5. Level Dyeing Factor6. Unfixed dye to be removed in the first hot rinse bath
70 – 80%Above 90%80 - 90%Above 90%Above 70%Above 60%
Target Profiles for Dyestuffs Selection
Influence of dye compatibilityLevel dyeing factor : LDF = S/E X MI
Standard Requirements for Selection of Dyestuff:
Lower Substantivity + Moderate Reactivity + Lower dye-hydrolysate & Rapid washing-off
Correct Profile Reactive dyestuffs aiming at better dyeability
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An Ideal Orange Combination
Reactive Orange 107
Reactive Red 198
Reactive Blue 220
Reactive Yellow 176
Reactive Red 238
Reactive Black 5
Yellow component very low substantivityYellow very high secondary exhaustion – unlevel riskExhaustion in alkali ‘on tone’Rapid fixation of yellow and slow of blue
Yellow and red medium substantivity, blue lowRed slow to fixExhaustion in alkali ‘on tone’Final fixation of yellow low, fixation greener paler when compared to final exhaustion
Increased compatibility during salt exhaustionExceptional ‘on tone’ exhaustion and fixation in alkaliFinal exhaustion and fixation ‘on tone’
Compatibility Study a Trichromate Dyestuffs
Robustness Study Reactive Orange 107
Reactive Red 198
Reactive Blue 220
Reactive Yellow 176
Reactive Red 238
Reactive Black 5
An Ideal Orange Combination
20% Underfill/20% Overfill
-10% Salt/+10% Salt
-10% Alkali/+10% Alkali
45 mins Fix/75 mins Fix
-Temperature/+Temperature
-2:1 Liquor Ratio/+2:1Liquor Ratio V.Yellower Redder
V.Yellow Bluer
Yellower Stable
Stable Stable
Stable Yellower
Yellower Redder
Redder Bluer
Bluer V.Yellow
Stable Less Blue
Bluer Yellower
Less Blue Bluer
Less Blue Redder
Stable Stable
Stable Stable
Change in Hue
Stable Stable
Little Stable
Redder
Stable Stable
Stable Stable
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Migration and Compatibility studies : Orange – Red - Navy
Migration
D1 D2 B1 Final
Migration index 93.4%
Orange : 1.41%Red : 0.60%Navy : 0.65%Salt : 80 g/lSoda ash : 15 g/lLR : 10 : 1Fixation temperature : 60°C
30°C
40°C
50°C
60°C
15’
15’ 15’ 5’ 5’ 5’ 5’ 20’20’ 20’
1
2
3 4 5 6 7 8 9 10 11 12
10% Alkali 20% Alkali 70% Alkali
Exhaustion
Fixation
Compatibility
Compatibility Study a Trichromate Dyestuffs
Combinations in Ternary Shade (Olive)
CIELab Color Difference DE*
C.I. Yellow 145
C.I. Red 195
C.I. Blue 222
Compatibility Study a Trichromate Dyestuffs
STD. A B C D STD. A B C D E F G HE F G H
A : Alkali -20%B : Alkali +20%C : Salt -20%D : Salt +20%
E : Temp. 50F : Temp. 70G : L.R. 1:8H : L.R. 1:12
Standard. RecipeChemicals Requirement : Glauber’s salt 60g/l, Soda ash 20g/lLiquor ratio : 1:10Dyeing Temp. : 60Exhaustion time 20min., Fixation time 60min.
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Performance of a Standard Trichromatic Dyestuffs
CompatibilityØ‘On Tone’ exhaustion in saltØMedium substantivity with high migration in neutral exhaustion conditions Ø Good levelling abilityØ Lower E-S leading to better levelling on alkali additionØ Exhaustion remains ‘on tone’ after alkali addØ Exhaustion and fixation are the same shade through out
RobustnessØ Most stable only small variations in hue and depth
For Production of Deep and Color fast BlacksqMixture of Soda Ash/Caustic Soda gives highest fixationq 60’C application ensures good diffusion and penetrationq Highest fixation and diffusion reduce ‘bronzing’ effectq Best process for fixation and reproducibility is automet
Conclusion
Traditional combinations are sensitive with large changes in hue, especially to time & temperature
Influence of Chemicals, Processes & Substrates:
For Production of Bright Greens and Turquoiseq Best preparation – fibre hardness contamination needs to be minimizedqMigration (Temperature raising) Method would give better levelling.q Avoid using non-ionic chemicals in dyebathq Good anticreasant with emulsifying propertiesq Best quality (pH lower than 8 & zero hardness) Glauber’s Saltq Use clean Machine
Possible problems and causes
Potential problemsØ Unlevelness, Shade Variation-Long variation/Short VariationsØ Poor penetrationØ Surface depositionPossible causesØ Wrong or poor quality ancillary equipment (e. g. pumps)Ø Problems due to improper synchronization of winch speed & fabric string speedØ Sub-optimized dyeing processØ Incorrect dye selectionØ Improper Auxiliaries selection & Inefficient pretreatment
For Production of ready for dis-charge print fabricq Required dischargeable plus highly pure Reactive dyes to be selectedq Cationic Finishes to be avoided for white dis-chargeabilityq Careful usage of Activator: to be added to ink just before printing-should not be pre-mixed earlier
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Rubbing fastness affected by the following factors:q Substrateq Dye concentrationq Water hardnessq Improper finishing of the dyeingq Inadequate liquor flow rateq Lower colour yieldq Poor reproducibility of the dyeingsq Dusting of the yarn, particularly when rewinding onto another bobbinq Poor fastness propertiesq Harsh handleq Poor wettabilityq Deposits on the machinesq Poor levelling-out properties, particularly with wound packagesq Formation of spots
These problems can be avoided byGood pretreatment of the fabricProper usage of sequestering and complexing agents in the dyeing process
These problems can be avoided byGood pretreatment of the fabricProper usage of sequestering and complexing agents in the dyeing process
Possible Problems with hardness
q Poor liquor circulation-Too low circulation results in-Unlevelness due to insufficient liquor flowq Poor temperature controlq Contaminated addition tanks or dyeing equipments (dyes, O.B.A, Softeners, oligomer)q Flooded seals at reduced liquor levels
By Dyeing Machine
In Reactive Dyeingq Inefficient pretreatment.q Inefficient rinsing after pretreatment.q Inappropriate dosing cycle times for the dyes used.q Inefficient rinsing after dyeing.q Unleveled application of cationic products to the goods (especially in pale shades).q Inappropriate dye selection for down-stream processes (eg., post-bleach, post-merc.).
Potential Problems-In Processing
q Lack of heat-setting of Yarn or fabric leads to shrinkage on dyeing q Unevenly heat set of the substrateq Poor temperature control
- Dispersion stability problems- Unleveled dyeing
q Incorrect dye selection q Insufficient dispersing agent with highly concentrated dyestuffs q Too much auxiliary (less is better)q Waxes, oils, hydrocarbons on the substrates.
In Polyester Dyeing
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Wash Off
Main items before startü Is the dyeing process ok?
ü Is the dyestuff properly desolved?
ü Is the dyeing machine & other used vessels clean or free from any technical problem?
Check-list before starting a Winch/Batch dyeing machine
Main vesselØ Inside or outside lying pump with engine control or not.Ø Different kind of level control making variable kind of liquor levels possible or not.Ø Overpressure devices.Ø Overpressure devices, different kind of valves, heating & cooling device.Ø Different kind of sealings.Peripheral vesselsØ Expansion vessel with heating, automatic dosing system to regulate pH & stirrer.Ø Preparation vessel with heating and stirrer.Ø Dosing system for solid material.Ø Dosing or cycle pump.Ø Connection to an automatic dosing system for bulk chemical and auxiliaries.
Main elements of a Winch/Batch Dyeing machine
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Precautions for Finishing of different shades to achieve required quality
Carefulness to be needed to ensure for achieving better wet rubbing, staining or wash fastness of the darkest Shades:
Cotton: Ø As required Dye amount is very high, dye selection is to be optimized between Quality & Prices.
Ø Total Shade depth should not exceed total standard depth of it’s different dye components. i.e try to use as less dyestuffs% as possible.
Ø Any sort of “Micro or Nano” Silicon finish adversely affect wet rubbing, staining or wash fastness of the finished RMG.
Ø Be sure of removing maximum hydrolyzed dyes from the substrates with efficient wash off process. Specially for dischargeable dyeing as hydrolyzed dyes do not leave white ground.
Polyester:Ø Proper Pre-heat set needed to evenly rearrange the fibre structure.
Ø For polyester-filament, lower filament no. containing substrates give better wash, sublimation & other fastness.
Ø A non-ionic wetting agent to be used with other reduction cleaning recipe.
Ø A post-heat set with subsequent further reduction cleaning may ensure the best wash, sublimation & other fastness of polyester apart from dyestuffs quality.
Conclusion
Pre-cautions to be ensured for achieving required light fastness, shades changes possibilities & other pale shade related fastness:
Cotton:
Ø As dyestuffs amount is very low, usually the best quality dyestuffs to be chosen.
Ø Avoid matching any light shades without dyestuffs-mostly by scouring as colour fastness of natural Chromophores & different contamination of scoured fabrics change in time & do not give permanent effect.
Ø Select equal light & other fast dyes components for on tone fading.
Ø Avoid using any “Cationic finish” or Fixatives as they adversely affect Light fastness
Ø Removal of maximum hydrolyzed dyestuffs from substrates with efficient wash off process.
Polyester:
Ø Proper Pre-heat set needed to evenly rearrange the fibre structure.
Ø For polyester-filament, applicable dyes energy level is inversely proportionate to filament no.
Ø A non-ionic wetting agent to be used with other reduction cleaning recipe.
Ø A post-heat set is not always necessary.
Dark Shades:
Pale Shades:
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Details for Silicon Based Product application-with Types
Silicon emulsion is of three kinds according to its molecular size:
Ø Nano Type :
Amino Silicon Nano-emulsion, having particle size up to 10nm, is physically water like transparent. Because of their finest particle size, they can easily penetrate right in to the core of fibre very easily and after cross-linking; they make the fabrics soft handled and elastomeric. Due to their penetration in side the core of fibres & cross-linking there, they push out the rest hydrolyzed dyestuffs particles resulting in negatively affect the rubbing, staining, washing & other fastness properties of fabrics. So, it is advisable to avoid using comparatively loser particles sized silicone emulsion in darker shaded fabrics.
Ø Micro Types:
Amino Silicon Micro Emulsion, containing particle size above 10nm & up to 50-100nm, is also physically transparent looking. Because of their smaller particle size, they can penetrate into the inner parts of the fabrics and with the effect of the temperature; the silicon particles cross-link themselves with the presence of amino-based emulsifier and hence impart permanent elastomeric type softness. This type of silicone particle sized emulsion also contributes to the deteriorations of rubbing, staining, washing & other fastness properties due to the same reason as nano type silicones sized particles do.
Ø Semi-Micro Types:
Silicon Emulsion containing particle size above 100nm & up to 150nm, are physically translucent looking. Because of their comparatively smaller particle size than the macro emulsion but larger than the nano & micro-emulsion, they cannot fully penetrate into the inner part of the substrate and hence remain submerged in the fabric surface and get cross-linked there. That’s why they impart both elastomeric and slippery type softness on the surface of the fabrics. They deteriorate the fastness of dyed fabrics to a few extent.
Ø Macro Type:
Amino Silicon Macro Emulsion, containing particle size above 150nm, is physically opaque looking. Usually, they’re less shear force stable and emulsion can easily break. So, they can’t be applied in exhaust process. Because of their comparatively larger particle size, they cannot penetrate into the inner parts of the fabrics and remain on the surface of the fabrics and then during drying they cross-link and impart permanent slippery type smooth softness effect on the surface of the fabrics. So, it also helps in developing rubbing fastness of the substrate.
Ionic Characteristics:Silicon Emulsions are made by Silicon particles with amine-based emulsifiers and are given either Anionic or Cationic or Non-ionic nature during manufacturing. So, all kinds of silicon can be usually of two kinds according to the ionic nature:
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q Cationic:
Has more affinity towards the substrate and thus more reactive to the fabrics. It leaves some yellowing effect after application and so is not suitable for use in the white/light shades.
q Non-ionic:
Has less affinity towards the substrate and thus are less reactive to the fabrics. Leaves no yellowing effect after application and thus does not make any change in white/light shades application.
q Besides, there are some other silicones of different kind, which impart cotton like hydrophilic nature of different hydrophobic fabrics, creating some capillary pores on the surface of the fabrics. There are also some other silicones which are more robust towards alkali i.e remains active in pH of above 7 and thus make it user friendly.
Ø Because of lower stability of Silicon emulsion i.e, easily breakable emulsion, they should not be given high sheer-force which might result in breaking of silicone emulsion & thus it is usually not suitable for use in Exhaust application but in Padding application. While using in Padding, the concentration of pad-liquor is to be kept constant to avoid “Tailing effect”. If it is used in Winch, the nozzle pressure is to be reduced remarkably to avoid silicon emulsion breakage.
Ø As it is very sensitive to alkali, specially cationic one, here padding liquor pH should never exceed 6.5.
Ø As cationic silicone emulsion reacts with different radicals like Ca++, Mg++ and specially Fe+++, the presence of any kind of the above radicals might make some precipitation & so water to be softened carefully before applying silicon.
Ø Usually the Cross-linking Temperature of Silicone emulsion is about 45-50° C so, to avoid Pre-mature cross-linking, the cross linking of silicone emulsion is to let happen in the next subsequent processes, i.e.. Drying/Calendaring period, not during application.
Over-coming problems of Silicon Spot (pre-matured cross-linking of Silicones):
Using of both silicon emulsion and fatty acid based softener:
Carefulness in Silicon based product application:
If accidentally any premature cross-linking happens, there creates some silicon spot on the fabrics surface & it is very hard to remove. Only some Organic solvent type emulsions (mostly organic solvent based) can dissolve these spot. So, if these types of problems occur accidentally during application, some AEPO/NEPO free organic solvent-based detergent can be applied (with temp. 80-90° C) to overcome it.
For special softness, combination of both silicon & fatty acid softener can be applied. Some manufacturers have developed some products of this kind readily usable for this purpose. But while using combination, it is suitable to use them in padding application:
q Making combination of Fatty acid stock solution+ Silicon Emulsion→Applying in padding
q Silicon Emulsion to be applied first and then Fatty acid softener but because of coating & washibility nature, fatty acid softener should not be used first.
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