Introduction of Wool | Bleaching Process of Wool | Bleaching Method ofWool Fiber/Fabrics

Introduction of Wool

Wool exhibits by nature a pronounced yellow color and also on exposure to light , alkali or by microbial degradation. Commercially, wool bleaching is carried out using either an oxidative or a reductive system, or a combined oxidation/reduction process. Oxidative bleaching in the dyebath is also possible .

In general, oxidative bleaching with hydrogen peroxide gives superior whiteness over reductive methods..Recent research also revealed the use enzymes to enhance the whiteness of bleached wool.

Wool cannot be bleached with sodium hypochlorite solutions, as for cotton, since it is extensively damaged to the point at which it even dissolves in the solution.

Oxidative Bleaching Method
A batch treatment with hydrogen peroxide is used for most bleaching applications.An activator (eg an alkali) is normally added to increase the rate of bleaching. Typically, wool is bleached at pH 8–9 for 1 h at 60◦C with a stabilized solution of hydrogen peroxide (0.75% w/w). It is generally accepted that, under alkaline conditions, the active bleaching species is the perhydroxy anion (OOH− ), the formation of which is encouraged by higher pH .

Peroxide bleaching of wool under mild acidic conditions (pH 5–6) can also be carried out using a peracid activator such as Prestogen W (BASF) or citric acid . As wool sustains some damage in the presence of alkali, this method is useful for bleaching delicate fabrics.

An undesirable side effect is the rapid decomposition of hydrogen peroxide to water and oxygen, a reaction catalyzed by transition-metal ions. A stabilizer, which sequesters these ions, is used to prevent this side reaction occurring. The most common stabilizers for alkaline wool bleaching are phosphates, particularly tetrasodium pyrophosphate. However, recent concerns over phosphates in effluents from textile treatment have led to the development of alternative stabilizers based on silicates .

Heavily pigmented fibers, such as Karakul wools, require a more severe approach known as mordant bleaching. In this method, the wool is treated with a metal salt and then with hydrogen peroxide. In the first step, the melanin pigment in the wool preferentially absorbs the metal cations; and in the second step, the cations catalytically decompose the peroxide to produce highly aggressive hydroxyl free radicals, which selectively attack and bleach the melanin.

Reductive Bleaching
The two most popular chemicals used for reductive bleaching of wool are stabilized sodium dithionite and thiourea dioxide. Most reductive bleaching of wool is carried out using stabilized dithionite (2–5g/L) at pH 5.5–6 and 45–65◦C for 1 h. Thiourea dioxide is more expensive than sodium dithionite, but is an effective bleach when applied (1–3 g/L) at 80◦C and pH 7 for 1 h. Whiter fabrics are produced when oxidative bleaching is followed by a reductive process—this is often referred to as “full bleaching.”

Reductive Bleaching with Sulfur Dioxide
In the early days sulfur dioxide was used to bleach wool , but disadvantage of this method of bleaching wool was that the white was not permanent when exposed to sun and air.

Disadvantage of reductive bleaching with hydro
1.It tends to part harsh handle to wool.
2.Reducing agents tend to break cystine cross links in protien fibers.

Full Bleaching Of Wool
However, with even the best oxidative bleaching processes, there is a limit to the whiteness that may be achieved on wool, within the limits of acceptable fibre damage.Whiter fabrics are produced when oxidative bleaching is followed by a reductive process(combined oxidative/reductive bleaching treatments)—this is often referred to as “full bleaching.”

Shrink Resistance Treatment of Wool
Felting in garments and fabrics that leads to excessive shrinkage is, however, undesirable. It occurs when the wet material is subjected to severe mechanical action, for example, in laundering or tumble drying . Shrink-resist treatments are directed at preventing felting shrinkage, whereas minimization of relaxation shrinkage requires careful control during fabric finishing.

The term shrink-resistant is preferred to “shrinkproofed,Shrink resist treatment of wool adds consumer desired properties to this superior natural fibre, the improved processing technology allows processors and retailers to offer fabrics and garments with added value and performance. The improved performance offered by the Total Easy Care range of processes includes machine washability and tumble dry qualities.

Principle of SR Treatment
A variety of methods produce wool fabrics that withstand repeated washing without shrinkage and felting. They are particularly important for knitted woollens and worsted fabrics. 

Two main principles are used:
(1) modification of the scale structure of the fibre cuticle to decrease the directional friction effect – this can be achieved by chemical treatments that either partially remove the scales or cover them with a smooth film of polymer;

(2) reduction of fibre mobility by adhesion of fibres and yarns at their points of contact and by decreasing fibre elasticity by means of intermolecular crosslinking.

Chlorine SR Treatment
Chlorine-Based Shrink-Resist Treatments. The principal oxidizing agent used in degradative shrink-resist treatments is chlorine. Free chlorine reacts very rapidly with wool; hence, it is difficult to treat a mass of wool fibers evenly. Two different types of chlorination methods are used commercially: continuous treatment and batch treatment. In the continuous method, top or loose wool is reacted with an aqueous solution of chlorine gas for a short time (
Chlorine Free SR treatment
Chlorine-Free Shrink-Resist Treatments. Commercially, the only other oxidizing agent used to any extent is permonosulfuric acid (PMS; HOOSO3H). This is used in the form of its potassium triple salt, containing potassium sulfate and bisulfate. It is employed in batch processes at elevated temperatures, because it reacts more slowly with wool than chlorine. The process sequence is similar to that used for chlorine-based treatments. It involves degradative oxidation with PMS, followed by neutralization with sodium sulfite and then application of a resin. Unlike chlorine, however, PMS does not remove the bound lipid or oxidize cystine to cysteic acid. The main product of the reaction is cystine sulfonic acid or Bunte salt groups.

Plasma Treatment in SR wool
There is an enormous potential in the plasma treatment of natural fibre fabrics. Plasma treatment has proved to be successful in the shrink-resist treatment of wool with a simultaneously positive effect on the dyeing and printing.

Additive Shrink-Resist Treatments

The principal additive shrink-resist treatment for wool fabrics uses the polymer Synthappret BAP (Bayer AG). This is a poly(propylene oxide) polyurethane, containing reactive carbamoyl sulfonate (bisulfite adducts of isocyanate) groups, ie NHCOSO3 − Na+. An aqueous solution of this polymer is padded onto woven fabrics. The polymer cross-links on drying to form flexible linkages between fibers and yarns . Other polymers may be applied at the same time to modify the handle. 

Optical Brightening Agents (OBA) | Properties of Fluoroscent WhiteningAgents for Textiles

The coloring matter ,whether it is natural or present as a contaminant in the fiber is generally decolorized by different bleaching methods. However the appearance of the textile substrate is somewhat creamish after the bleaching, therefore chemical treatments are become necessary to neutralize the yellow tint of the textile fibers.

There are two methods ,which are generally used for this purpose. By using a blue tinting agent , which absorbs the yellow part of the light and reflected light appears to be of bluish tint. The total light reflected by this mean is less than the total incident light.

By using fluorescent optical brightening agents :-
The OBA s (optical brightening agents ) are most widely used in textiles , paper, detergents and plastics . The optical brightening effect is obtained by the addition of light , which means that the amount of light reflected by the Fluorescent Whitening Agents (also called optical brightener) absorb high energy radiation in the ultraviolet to violet region (330nm-380nm) on the part of characteristic molecules and emit lower energy radiation in blue region in visible spectrum (400nm-450nm), which yields the counteracting the yellowing appearance. FWA should be transparent on the substrate and should not absorb the visible region of the spectrum. The OBAs are effective only when the incident light has a significance proportion (such as daylight) of UV rays. When material treated with OBAs are exposed to UV black light source , it glows in the dark.Anionic OBA’s exhaust on cotton, wool and silk., cationic OBA’s exhaust on acrylic and certain polyesters and nonionic OBA’s are exhaust on all synthetics.

Desired Properties of Fluoroscent Whitening Agents for Textiles Use:
Before selecting an optical brightener for textile application we must look for following properties,
1.it should have good solubility , should not have its own color and good substantivity for the textile substrate under OBA application.
2.OBA’s should have good light as well as wet fastness properties.
3.Its rate of strike on the substarte.
4.Build up and exhaustion properties.
5.Requirement of electrolytes and its sensitivity towards different exhausting agents.
6.Effect of temperature on the exhaustion and build up properties.
7.Application pH range and sensitivity towards change in pH.
8.Effect of water hardness.
9.It should have good leveling and penetrating properties.
10.Should not decompose to colored products on exposure to atmospheric conditions as well as storage , and it should not absorb light in the visible region.
11.it should be compatible and stable with finishing chemicals, auxiliary and process such as heat and temperature.
12.It should be stable and fast to the common oxidative and reductive bleaching chemicals and bleaching systems.

Bleaching Process for Full Whites and OBA application | Desiredproperties of Good OBA | Mechanism of Fluorescent Whitening

Introduction

The coloring matter ,whether it is natural or present as a contaminant in the fiber is generally decolorized by different bleaching methods. However the appearance of the textile substrate is somewhat creamish after the bleaching, therefore chemical treatments are become necessary to neutralize the yellow tint of the textile fibers.

There are two methods ,which are generally used for this purpose,
By using a blue tinting agent , which absorbs the yellow part of the light and reflected light appears to be of bluish tint. The total light reflected by this mean is less than the total incident light.

By using fluorescent optical brightening agents :- 

The OBA s (optical brightening agents ) are most widely used in textiles , paper, detergents and plastics . The optical brightening effect is obtained by the addition of light , which means that the amount of light reflected by the substrate is more than the incident light , due to which the object appears brighter.

Desired properties of Good OBA
Before selecting an optical brightener for textile application we must look for following properties, it should have good solubility , should not have its own color and good substantivity for the textile substrate under OBA application.  

1. OBA’s should have good light as well as wet fastness properties.
2. Its rate of strike on the substarte.
3. Build up and exhaustion properties.
4. Requirement of electrolytes and its sensitivity towards different exhausting agents.
5. Effect of temperature on the exhaustion and build up properties.
6. Application pH range and sensitivity towards change in pH.
7. It should have good leveling and penetrating properties.
8. Should not decompose to colored products on exposure to atmospheric conditions as well as storage , and it should not absorb light in the visible region.
9. it should be compatible and stable with finishing chemicals, auxiliary and process such as heat and temperature.
10. It should be stable and fast to the common oxidative and reductive bleaching chemicals and bleaching systems.

Chemical Constitution of Optical Brighteners
Optical brighteners are usually derivatives of

• Triazine-stilbenes (di-, tetra- or hexa-sulfonated)
• Coumarins
• Imidazolines
• Diazoles
• Triazoles
• Benzoxazolines
• Biphenyl-stilbenes

Brighteners can be “boosted” by the addition of certain polyols like high molecular weight polyethylene glycol or polyvinyl alcohol. These additives increase the visible blue light emissions significantly. Brighteners can also be “quenched”. Too much use of brightener will often cause a greening effect as emissions start to show above the blue region in the visible spectrum. Besides the formation of cis isomer in stilbene-containing brighteners (only the trans isomer is optically active), continued exposure to UV-containing light will actually cleave the molecule and start the process of degradation.

Mechanism of Fluorescent Whitening

Fluorescent Whitening Agents (also called optical brightener) absorb high energy radiation in the ultraviolet to violet region (330nm-380nm) on the part of characteristic molecules and emit lower energy radiation in blue region in visible spectrum (400nm-450nm), which yields the counteracting the yellowing appearance. FWA should be transparent on the substrate and should not absorb the visible region of the spectrum. The OBAs are effective only when the incident light has a significance proportion (such as daylight) of UV rays. When material treated with OBAs are exposed to UV black light source , it glows in the dark.Anionic OBA’s exhaust on cotton, wool and silk., cationic OBA’s exhaust on acrylic and certain polyesters and nonionic OBA’s are exhaust on all synthetics.

Bleaching with Peroxides | Bleaching Process with Hydrogen Peroxide

Bleaching with Peroxides
The bleaching bath is composed of hydrogen peroxide (35% or 50% by wt.) as the bleaching agent, an activator (usually alkali) and stabilizers.

Bleaching Process with Hydrogen Peroxide
Hydrogen peroxide bleaching can be done by

1.Batch wise,
2.Continuous
3.Semi continuous method.

Factors of Peroxide Bleaching:
a.Quantity of peroxide required in Bleaching
 
b.Temperature
Cotton and Bast fibers are bleached at 80 - 95°C in bath processes, while blends of cotton and regenerated cellulose fibers are bleached at 75 - 80°C. The bleaching time is generally between 2 and 5 hours. In a pressurized high temperature (HT) apparatus cotton can also be bleached at temperatures of 110 - 130°C in only 1 to 2 hours.

c.Time
During the impregnation processes the temperature and as well the retention time varies widely. During a cold bleach process a dwell time of 18 to 24 hours is necessary. In the pad steam process under atmospheric pressure the bleaching time is generally between 1 to 3 hours. The above mentioned processes describe batch processes. Today a lot of continuously, intelligent finishing equipment exists in which the bleaching step is only one of some other treatments and the reaction time of the impregnated material in such steamer is only between 7 to 20 minutes. In general these bleaching process correspond to a preliminary bleach.

d.pH:- 
The pH value depend on the fibres to be bleached and pre-treatment.

NaOH is used in case of H2O2 bleaching. This is used to bring the PH upto 9-10 because H2O2 become active at this PH or oxidation is start at this PH.

For the bast fibres, such as linen, weaker alkaline or soda alkaline baths are used in order to avoid a cottonizing. Regenerated cellulose fibres are more sensitive. Therefore, they are only bleached in weak alkaline baths.

Alkali sensitive animal fibers must be bleached in very weak alkaline solutions. Phosphates and ammonia are most widely used as alkalization source. With tetrasodium pyrophosphate simultaneously a stabilization of the bleaching liquor can be attained.

e.Water Quality
Soft Water free of iron and copper impurities is recommended for peroxide bleach treatment.

f.Peroxide Stabilizers
High pH and temperature lead to the faster decomposition of peroxide bleaching liquor and degradation of cellulose.The role of the stabilizer is simply to control or regulate these effects the act as buffers, sequestrates and in special cases, enhancing performance of the surfactant used in the bleach bath.

For caustic alkaline bleach sodium silicate, organic stabilizers or the combination of both are suitable. In weak alkaline baths the addition of tetrasodium pyrophosphates can be used alone or together with an organic stabiliser.

Advantages of Peroxide Bleaching:
1.Among the oxidizing bleaching agents, only hydrogen peroxide provides a high bleaching effect at reasonable costs, especially if modern short-term bleaching processes are used with only a few minutes bleaching time.

2.Peroxide bleaching keeps the fibre quality intact.

3.Cotton can be bleached with peroxide in a single stage. Other processes require two or three bleaching stages,(desize with scour, scour with bleach and desize with scour and bleach).

4.No separate pre treatment is necessary because hot, alkaline bleaching has not only a bleaching but also a cleaning effect, it therefore combines the advantages of an alkaline extraction with the bleaching treatment.

5.Animal fibres can only be bleached with peroxide to a high and stable degree of whiteness.
- Corrosion of stainless steel equipment does not occur during peroxide bleaching.

6.The spent peroxide baths still contain residuals of hydrogen peroxide which fever the degradation of the organic impurities in the effluent, and this helps to decrease the chemical oxygen demand (COD).

Bleaching of Wool with Hydrogen Peroxide
After scouring, wool may be bleached by immersion or pad and dry techniques, using alkaline or acid solutions.

Bleaching of Silk with Hydrogen Peroxide
Prior to bleaching, silk is usually degummed. Hydrogen Peroxide addition assists this process and it is universally used as the bleaching agent for natural silk, usually in an alkaline solution.

Bleaching of synthetic fibres Hydrogen Peroxide
When used alone, synthetic fibers do not normally require bleaching. However, blends of synthetic fibers with natural or regenerated fibers, e.g. cotton-polyester are frequently bleached. The most popular bleaching agent is Hydrogen Peroxide and it is used in both batch and continuous processes.

Advantages and disadvantages of peroxide over hypochlorite bleaching.

Bleaching with Sodium Perborate
Sodium perborate (PBS, NaBO3.nH2O where n=1 or 4) can readily be incorporated. It has been described as a stable, solid form of hydrogen peroxide allowing its introduction into the wash at the same time as the detergent. Sodium perborate is a gentler bleach than sodium hypochlorite, causing less damage to fabrics and dyes, but by itself is only effective at high (>60ºC) temperatures. Although solid chlorine bleaches exist, they are rarely used in laundry detergents.

Bleaching with Sodium Chlorite.(NaClO2 )
The sodium chlorite is available as a powder , and it is applied under strongly acidic conditions to textiles. Its application produce a toxic and corrosive gas.

a. bleaching mechanism
b. effect of pH.
c. effect of temperature.
d. effect of metals

Bleaching with Peracetic Acid
Peracetic acid is produced by the chemical reaction of acetic acid and hydrogen peroxide. It works in a very narrow pH range of 7 to 8. Below pH 7.0 the bleaching is not proper and above pH 9.0 fiber degradation takes place. Peracetic acid is used a bleaching agent for nylon and acetate where hydrogen peroxide can not be used.

Reductive Bleaching Systems
Reductive bleaches work by reducing colored impurities into colorless forms.

1.sodium hydrosulphite.
Sodium hydrosulphite is available as free flowing powder and a strong reducing agent. This is explosive in nature when come into contact with water. It is available in different purity ranges.

2.sodium sulphide.
Sodium sulphide is also a strong reducing agent

3.sulphur dioxide
Sulphur dioxide was used as a bleaching agent in early 20th century for bleaching of wool.
 

Reductive Bleaching of silk
Commonly Sodium hydrosulphite, Sulfurdioxide and sodium sulphoxylates are the reductive bleaching agents which are used for silk.

Reductive bleaching of nylon
Oxidative bleaching isn’t suitable for polyamides as H2O2 attacks the polymer, instead reductive dyeing using sodium hydrosulphite is used.

Hypochlorites Bleaching Process | Bleaching with Hypochlorites

Bleaching with Hypochlorites

Bleaching Powder
Calcium hypochlorite is usually a white or grayish-white powder, but it is also available as tablets. It is a strong oxidizer and is considered more stable than sodium hypochlorite. It is also believed to provide more chlorine.

Sodium Hypochlorite
Sodium Hypochlorite is a greenish-yellow liquid commonly referred to as “Bleach.” The chemical compound formula for Sodium Hypochlorite is NaOCl.Sodium Hypochlorite is prepared by reacting dilute caustic soda solution with liquid or gaseous chlorine, accompanied by cooling. It is used extensively as a bleaching agent in the textile, detergents, and paper and pulp industries.

The active ingredients in hypochlorite bleaches vary with pH. At pH 2 is the main component in solution; at pH 4 to 6, HOCl is the dominant species; at pH > 9, OCl − is the only component present. It is the hypochlorite ion in basic solution that is the active ingredient in household bleach, which is typically about 5 to 6 percent NaOCl. The OCl − ion oxidizes chromophores in colored materials, and is itself reduced to chloride and hydroxide ions.

Hypochlorite Bleaching Process
The conditions of the bleaching agent varies according to the result required, the concentration depends upon the fabric quality, degree of whiteness required, types of machine and next operation.

Quantity Required:-
Normally 2.5-3.0 gpl of available chlorine is sufficient for good bleaching , but it is necessary to optimize it on a possible lower value for safe bleaching process.

Analysis Method
Determination of available Chlorine.
Method : Iodometric(Standard)

Apparatus :

• Erlemeyer flask(100 ml) -I
• Burette stand -I
• Pipette(50 ml) -I
• Spatula -I
• Measuring Cylinder -I
• Micro burette(10ml.) -I
• Measuring Cylinder. -I

Reagent

• Sodium Thio Sulphate Solution(.1N)
• Glacial acetic acid
• Pottassium Iodide(KI crystal)
• Starch indicator solution.

Typical Bleaching Recipe for Hypochlorites

Wetting agent                                        0.3-0.5g/l

Caustic Soda                                        0.5-1.0g/l

Soda ash                                              2.0-4.0g/l

Sodium hypochloride solution                5.0-15.0ml/l

Temperature                                         25-60C

Time                                                     30-60 mins

pH                                                       10.5 
M:L                                                      1:10

Procedure :-
1) Collect sample solution ( Sodium hypo chlorite ) in an air-tight bottle.

[NOTES / CAUTION
a) Keep sample solution away from excessive light and do not agitate the sample solution.
b) Start chlorine determination IMMEDIATELY after sampling. ( i.e. do not store sample to be analysed for chlorine ).]

2) Introduce 10ml of glacial acetic acid and about 0.5 g of Pottassium Iodide (Spatula full ) crystal into a 100ml erlemeyer flask.
3) Withdraw y ml of sample solution with bulb pipette and introduce into above Solution.
4) Swirl the flask to well mix the solution.
5) Titrate with 0.1N Sodium Thio Sulphate Solution from upto a light Yellow Colour.
6) Add 1 ml of starch indicator solution and continue to titrate until the last drop of titrant causes the solution to turn colourless.

% active chlorine = 3.545 x N x V/y (i;e 3.545 x N x V divided by y)
Where :
V = Volume of (N ) Na2S2O3
N = Normality of Na2S2O3
y = Sample amount


Important Factors for Bleaching:
pH :-

General PH range is 10-11 or 10.5-11.5 during bleaching if PH reaches 9 then it is a danger level and at 7 PH the bleaching is worse and causes extreme damage to the cloth.The PH value is maintained by adding sod ash or by buffering agent.

Temperature:-

The suggested temperature for hypochlorite bleaching is 37-40oC. Generally reaction is accelerated with increases of temperature.

Water Quality:-

Water for bleaching should be soft and even hard water can be used but should be free from Cu++ and Fe++.

Effect of Metals:-
The bleaching equipment should be made of stainless steel , to avoid the catalytic degradation of the cellulose in the presence of copper and iron.

Substrate Preparation
The substrate must be pre scoured in the presence of chelating agents , it should be free from rust spots and traces of metallic impurities when bleaching with hypochlorites.

Bleaching Time :-

The time factor depends upon the following consideration.

(a) Concentration.
(b) PH value.
(c) Degree of Whiteness.
(d) The type of machine used in bleaching.

Roughly for normal machine the time is 2-3 hrs is required for completion of bleaching process antichlor and proper neutralization treatments should be followed by proper wash for removal of reagents after hypochlorite bleaching process.

Textile Bleaching | Object of Bleaching | Bleaching Agent | Recipe forBleaching

Bleaching

Bleaching is chemical treatment employed for the removal of natural coloring matter from the substrate. The source of natural color is organic compounds with conjugated double bonds , by doing chemical bleaching the discoloration takes place by the breaking the chromophore , most likely destroying the one or more double bonds with in this conjugated system. The material appears whiter after the bleaching.

Natural fibres, i.e. cotton, wool, linen etc. are off-white in colour due to colour bodies present in the fibre. The degree of off-whiteness varies from batch-to-batch. Bleaching therefore can be defined as the destruction of these colour bodies. White is also an important market colour so the whitest white has commercial value. Yellow is a component of derived shades. For example, when yellow is mixed with blue, the shade turns green. A consistent white base fabric has real value when dyeing light to medium shades because it is much easier to reproduce shade matches on a consistent white background than on one that varies in amount of yellow.

Bleaching may be the only preparatory process or it may be used in conjunction with other treatments, e.g. desizing, scouring and mercerizing. The combination of such treatments for an individual situation will depend on the rigorousness of the preparation standard and economic factors within the various options. Other chemicals will be used in addition to the bleaching agent. These serve various functions such as to activate the bleaching system, to stabilize or control the rate of activation, to give wetting and detergent action, or to sequester metallic impurities. This section gives consideration to the selection of bleaching agents and to the role of the various chemicals used in conjunction.

The purpose of bleaching is to remove coloured impurities from the fibre and increase the whiteness level of fabric.

The aim of bleaching can be described as following:

• Removal of coloured impurities. 
•  Removal of the seed coats. 
•  Minimum tendering of fibre. 
•  Technically reliable & simple mode of operation. 
•  Low chemical & energy consumption. 
•  Increasing the degree of whiteness.

Bleaching Agent
A bleaching agent is a substance that can whiten or decolorize other substances.Bleaching agents essentially destroy chromophores (thereby removing the color), via the oxidation or reduction of these absorbing groups. Thus, bleaches can be classified as either oxidizing agents or reducing agents .

Type of Bleaching Agents
a.Oxidative Bleaching Agents
b.Reductive Bleaching Agents
c.Enzymatic Bleaching Agents

Recipe for Bleaching:
 

  NaOH                               17ml/kg

SOAP (DTC)                    2ml/kg

STABILIZER                    5ml/kg

 H2O2                               30ml/kg

Reaction time                     25min.

       speed                                50-70m/min