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. 

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

Scouring Process in Textile | How to Scouring Textile Fabric | AlkalineEnzyme Scouring of Cotton Textiles

Yarns and fabrics may be dirty, contain natural waxes or oils, or have been treated with size or lubricants used in spinning, weaving or knitting. These can all interfere with dyeing, often leading to non-level results. Scouring is a large topic, and the process used depends on the fibre type and its condition. “True” scouring of greige cellulosic fabrics is typically done, after desizing, at the boil or at higher temperature in pressure vessels, with as much as 10 grams sodium hydroxide per litre of water, plus surfactants, and the process may last for several hours. Commercial scouring of wool may use solvents, similar to dry cleaning, as part of the process. White fabrics sold at retail have normally be scoured at the mill; “natural” fabrics usually have not (some “natural” fabrics have been scoured but not bleached).

Art dyeing literature often refers to what amounts to laundering as scouring. This is inadequate for greige fabrics, but often quite acceptable for “white goods”. A long machine wash with the hottest water possible, about a gram of soda ash per litre of water (about a teaspoon per gallon) and some (preferably optical brightener free) detergent, followed by two rinses is usually acceptable. Sodium hexametaphosphate may be helpful if the water is hard. Woven white cottons often contain starch that will not be removed by such a limited process.

Alkaline Enzyme Scouring of Cotton Textiles
The invention relates to a process for treatment of cellulosic material, as for example, knitted or woven cotton fabric, comprising the steps of preparing an aqueous enzyme solution comprising pectinase, treating the cellulosic material with an effective amount of the aqueous enzyme solution under alkaline scouring conditions; e.g., pH of 9 or above and a temperature of 50° C. or above, in a low calcium or calcium-free environment, yielding a modification of the cellulosic material such that exhibits an enhanced respond to a subsequent chemical treatment.

Traditionally, cotton scouring has required the use of harsh alkaline chemicals (caustic), extreme temperatures and large volumes of water. Expenses include not only the cost of the caustic and energy, but also the cost of treating waste water to remove residual caustic and by-products.

Today, textile producers have a new, effective alternative to chemical scouring with the advent of the Cottonase™ enzyme. This novel enzyme not only cleans better than chemical scouring, but also greatly reduces the need for extensive waste water treatment and energy consumption. The Cottonase™ enzyme is a versatile, economically viable and environmentally friendly alternative to chemical scouring in cotton preparation.

How to Scouring Textile Fabric:

1. Simply wash your fabric, this includes PFD fabric, in the washing machine in hot water with Soda Ash. Do not add any fabric softeners to the wash. If you must dry your fabric do so without any fabric softener sheets
2. Using an large enamel or stainless steel pot, fill the pot at least half full and place one ounce of soda ash into the pot per pound of cotton or linen fabric/fiber.
3. Place fabric into water, swish it around using a stainless steel spoon.
4. Bring water to a boil!!!
5. Adjust heat to a low boil/hard simmer and allow to boil for two hours. stir the fabric every 15 minutes or so t make sure that the fabric is being adequately scoured
6. After two hours remove from heat source, allow fabric to cool down until the fabric is at room temperature. 
7. Remove the fabric from the water and rinse.

Scouring Treatments of Cotton, Silk, Wool and Synthetics Materials

Natural fibers contain oils, fats, waxes, minerals, leafy matter and motes as impurities that interfere with dyeing and finishing. Synthetic fibers contain producer spin finishes, coning oils and/or knitting oils, Mill grease used to lubricate processing equipment, mill dirt, temporary fabric markings and the like may contaminate fabrics as they are being produced.

The process of removing these impurities is called Scouring. Even though these impurities are not soluble in water, they can be removed by Extraction, dissolving the impurities in organic solvents, Emulsification, forming stable suspensions of the impurities in water and Saponification, Converting the contaminates into water soluble components.

Scouring is usually carried out by means of continuous or discontinuous systems, with the same machines used for downstream treatments; temperature, processing time, pH, concentration of reagents, depend on the fibre,whiteness required and on the machine used.Incomplete scouring processes usually originate dyeing and printing defects due to different degrees of wettability and to inconsistent affinity for dyes of the material.

Types of Scouring Treatments
1.Scouring By Chemicals Means
2.Bio scouring or scouring with Enzymes

Scouring of Cotton
In the scouring process the cotton cellulose material is treated with a solution containing alkali ( soda ash and caustic soda), an anionic and/or nonionic detergent, a wetting agent, a complexing and sequestering for the removal of metal ions and polyacrylates or polyphosphonates as special surfactant free dispersing agents, at high temperature.

The scouring operation was conventionally done in kier machines and hence the process was called kier boiling , but now a days the scouring is done mostly in the dyeing machines itself as a part of combined or single operation such as scouring and bleaching.

I. Saponification of fats into water soluble soap and water miscible glycerin under alkaline conditions.
II. Hydrolysis of proteins into water soluble degradation products.
III. Dissolution of amino compounds.
IV. Solubilising of pectose and pectins by converting into soluble salts .
V. dissolution and extraction of mineral matter.
VI. Emulsification and solubilisation of natural oils and waxes.
VII. removal and dispersion of dirt particles and kitty by the action of alkali and detergent.

The material after scouring is more absorbent , free from natural impurities and coloring matter.This treatment can be carried out on filaments, yarns and fabrics.

Scouring of Silk
The scouring of pure silk is a degumming process used to remove sericin (silk gum) from fibroin floss. Sericin is the gummy element which keeps together the fibroin floss and gives the silk a hard hand and dull appearance. It is carried out on yarn, on dyed yarn, piece-dyed fabric or on products ready for printing. The treatment, which causes a loss of weight ranging between 24 and 28%, gives the degummed silk a lustrous appearance and a soft hand; the treatment is carried out with soapy solutions or with buffer dissolving agents. It is also possible to use enzymes (protease), which hydrolyses sericin.

Scouring of Wool
On wool, the scouring process removes oils and contaminants accumulated during upstream processing steps and can be carried out on slivers, yarns and fabrics with solutions containing sodium carbonate with soap or ammonia, or anionic and non-ionic surfactants, which carry out a softer washing to avoid any damage to the fibres.

Scouring of Synthetics
The scouring process applied to synthetic fibres removes oils, lubricants and anti-static substances, dust, contaminants and can be carried out on yarns and fabrics (when warp yarns have been bonded, the treatment is called debonding). It is carried out by means of surfactants, detergents and emulsifying agents.

What is Pretreatment? | Objective of Pretreatment | PretreatmentProcess of Cotton and Natural Fibers

Pretreatment:

Natural fibers and synthetic fibers contain primary impurities that are contained naturally, and secondary impurities that are added during spinning , knitting and weaving processes.Textile pretreatment is the series of cleaning operations.All impurities which causes adverse effect during dyeing and printing is removed in pretreatment process.

Pretreatment machine

Pretreatment processes include desizing, scouring, and bleaching which make subsequent dyeing and softening processes easy. Uneven desizing, scouring, and bleaching in the pretreatment processes might cause drastic deterioration in the qualities of processsed products, such as uneven dyeing and decrease in fastness.

Objective of Pretreatment:

• To Convert fabric from hydrophobic to hydrophilic state.
• To remove dust, dirt etc from the fabric.
• To achieve the degree of desire whiteness.

Steps in Pretreatment Process of Cotton and Natural Fibers:

Major steps involved in textile pretreatment are,

1. Singeing
2. Desizing,
3. Scouring,
4. Mercerization
5. Bleaching.

Steps in Pretreatments for Wool:

1. Raw wool scouring; aqueous and/ or solvent washing
2. Carbonizing
3. Scouring (desizing)
4. Fulling /crabbing/thermo fixing
5. Easy-care treatments
6. Anti-felting anti-shrinking treatments
7. Wool Bleaching

Steps in Pretreatment of Silk:
To prepare a silk yarn for dyeing and silk fabrics for dyeing and printing, it is necessary to partially or completely remove sericin, as well as natural oils and organic impurities. Depending on the percentage of sericin removed during scouring (sericin is present in raw silk in a ratio between 20 % to 25 %), the end-product is defined as unscoured (used only for shirts and suits), `souple’ or degummed.

1. Degumming
2. Scouring
3. Bleaching

Pretreatment Of Synthetic Textile Materials:
Although mots of the synthetics do not need to be given a very strong pretreatment however the possible steps in pretreatment of synthetics are

1. Desizing
2. Heat setting
3. Washing
4. Bleaching if necessary

Process of Cotton Desizing | Oxidative Desizing | Enzymatic Desizing |Acid Desizing

Desizing

Desizing is the process of removing the size material from the warp yarns in woven fabrics. Sizing agents are selected on the basis of type of fabric, environmental friendliness, ease of removal, cost considerations, effluent treatment, etc.

Desizing, irrespective of what the desizing agent is, involves impregnation of the fabric with the desizing agent, allowing the desizing agent to degrade or solubilise the size material, and finally to wash out the degradation products. 

Desizing Process:

The major desizing processes are:

1. Enzymatic desizing of starches on cotton fabrics
2. Oxidative desizing
3. Acid desizing
4. Removal of water soluble sizes

Enzymatic Desizing
Enzymatic desizing is the classical desizing process of degrading starch size on cotton fabrics using enzymes. Enzymes are complex organic, soluble bio-catalysts, formed by living organisms, that catalyze chemical reaction in biological processes. Enzymes are quite specific in their action on a particular substance. A small quantity of enzyme is able to decompose a large quantity of the substance it acts upon. Enzymes are usually named by the kind of substance degraded in the reaction it catalyzes. Amylases is the enzyme that hydrolyses and reduces the molecular weight of amylose and amylopectin molecules in starch, rendering it water that is soluble enough to be washed off by the fabric. Effective enzymatic desizing require strict control of pH, temperature, water hardness, electrolyte addition and choice of surfactant.

Advantages of Enzymatic Desizing

• No damage to the fibre
• No usage of aggressive chemicals
• Wide variety of application processes, and
• High biodegradability 

Disadvantages Enzymatic Desizing
Lower additional cleaning effect towards other impurities, no effect on certain starches (e.g. tapioca starch) and possible loss of effectiveness through enzyme poisons.

Oxidative Desizing
In oxidative desizing, the risk of damage to the cellulose fiber is very high, and its use for desizing is increasingly rare. Oxidative desizing uses sodium or potassium persulphates or sodium bromite as an oxidizing agent.

Advantages of Oxidative Desizing

• Supplementary cleaning effect
• Effectiveness for tapioca starches
• No loss in effectiveness due to enzyme poisons. 

Some disadvantages of oxidative desizing include possibility of fibre attack, use of aggressive chemicals and less variety of application methods.

Acid Desizing
Cold solutions of dilute sulfuric or hydrochloric acids are used to hydrolyze the starch, however, this has the disadvantage of also affecting the cellulose fiber in cotton fabrics.

Removal of Water-soluble Sizes
Fabrics containing water soluble sizes can be desized by washing using hot water, perhaps containing wetting agents and a mild alkali. The water replaces the size on the outer surface of the fiber, and absorbs within the fiber to remove any size residue.

Mercerizing | Object of Mercerizing | Mercerizing Treatment onCellulosic Materials

A treatment of cotton yarn or fabric to increase its luster and affinity for dyes. The material is immersed under tension in a cold sodium hydroxide (caustic soda) solution in warp or skein form or in the piece, and is later neutralized in acid. The process causes a permanent swelling of the fiber and thus increases its luster.It is the process of treatment of cellulosic material with cold or hot caustic conditions under specific conditions to improve its appearance and physical as well as chemical properties.

Purpose of mercerizing
1.To improve the lusture
2.To improve the strength
3. To improve the dye uptake and moisture regain.

What is the mercerizing process
The mercerizing involves these three subsequent steps,

a. Impregnation of the material in in relaxed state,cold caustic solution of required strength and wettability..
b. Stretching while the material is still impregnated in the caustic solution.
c. Washing off the caustic soda from the material while keeping the material still in the stretch state.

Fig.The material flow chart in yarn mercerizing

            

Theory of mercerizing
Neales theory in Broad
The hydroxyl groups on long cellulose chains attract the water molecules when cellulose takes up water, the structure expands transversily as some of the mutual secondary valency linkages are replaced by water hydroxyl linkages.Now in alkali solution ,some of the hydroxyl hydrogen atoms are replaced by sodium atoms and a system of high ionic concentration is established.Owing to osmosis ,water tends to enter this system and more secondary linkages are broken and are replaced by linkages with alkali in water.When the alkali cellulaose is washed the sodium ions and the hydroxyl ions are diffused away, and the osmotic pressure falls, the cellulose gel contracts by virtue of its elasticity.

During this contraction , hydroxyl –hydroxyl linkages are reform but not in such a great number as before and the orientation of the micells is more random.The greater proportions of free hydroxyl groups accounts for the increase in the reactivity and absorptive capacity.The decrease in this high absorptive capacity on drying,particularly at high temperature ,is due to the formation of new secondary linkages on account of greater amplitude of thermal vibrations of hydroxyl groups as suggested by Urqhart.

Changes during mercerizing process

A. Fiber level
1.Swelling
2.Cross sectional morphology changes from beam shape to round shape.
3.Shrinkage along with longitudinal direction.

B. Molecular level
1.Hydrogen bond readjustment
2.Orientation (parallelization) of molecular chains in amorphous region along the direction of fiber length.
3.Orientation of the crystallinity in the direction of the fiber length.
4.Increased crystallinity

C. Chemical Changes
1.Increased rate of reaction on hydrolysis and oxidation
2.Liberation of heat during the caustic treatment.(heat of sorption and heat of reaction)
3.Increase in the alkali absorption.
4.Increase in the absorption of iodine.

Q.Why there is a swelling in cellulose?

1.Due to Swelling
Swelling is due to molecular attraction with associated hydration in this instance.

Since the alkali cellulose is more hydrated than native cellulose ,maximum swelling concentration is result of attraction of alkali cellulose in solution on one hand and free alkali on the other. Hydration of the cellulose increases with increased fixation of alkali in solution of rinsing concentration upto a certain limit, after which the free alkali exerts a dehydrating effect on alkali cellulose to a greater extent.

Dissociation of alkali ions from the alkali cellulose compound corresponds to an absorption of OH- ions ,and in this manner a negative charge results.The cellulose molecules repel each other and absorb water ,this absorption being greater, the greater is the charge. If however the dissociation of alkali cellulose salt is forced back ,then there is reduction in the charge. Further if the concentration of the electrolyte is high in swelling liquor ,then charge of cellulose particles is shielded by free ions and force of repulsion is diminished.

2.Due to osmotic phenomenon.
The fiber is surrounded by a hardened euticle which acts as a dialyzing membrane to induce osmotic action ,which is better explained with the help of Neales theory

Q.Why there is a rise in temperature of caustic solution during mercerization?
Ans ;-Because when cellulose is treated with a moderately concentrated caustic solution ,the heat is evolved due to heat of sorption and heat of reaction.

Q.Why there is increase in luster of yarn after mercerization?
Ans:-The cotton hair swells in strong caustic soda solution ,which change its cross section from squashed circular pipe shape to an oval shaped . if the fibers are placed under a tension or stretched position in the swollen state and then washed to reduce the caustic concentration below a particular limit, then there is an increase in the luster of the fiber.

Q.What should be caustic concentration for yarn mercerization?
Ans:-Although mercerization can be done with the caustic concentration ranging between 150Be to 380Be, As for as the economy of the process and optimum mercerizing effect in yarn , the concentration of the caustic used is 250Be(225 gpl) to 32 0Be(325 gpl) at room temperature.

Q. What shall be the ideal temperature for mercerization?
Ans:- The relation between the shrinkage of cotton fiber, the concentration of alkali and the processing temperature was studied by H. Flecken, and the result is shown in this Figure.

He treated cotton yarn at 0°C to 40°C, using 30°/38° Bé caustic soda and measured the shrinkage by mercerization, and found that the least shrinkage variation is obtained at 10°C and 30° Bé. Therefore, robust conditions insensitive to the concentration of alkali and temperature must be selected for stable mercerization.

Q.Whether the recovered caustic from mercerizing process is reusable?
Ans:-The caustic soda from the washing process is recoverable and can be reusable ,but it has to be free from the contaminants and must be purified to remove the undesirable impurities.

Q.What is the mercerizing cycle for yarn mercerizing?

A typical mercerizing cycle in yarn mercerizing is having following steps,
1. Loading of material on the rollers in rest position.
2. Lowering of rollers
3. Caustic tray movement
4. Pre tensioning
5. Free shrinkage
6. Lye tensioning
7. Squeezing
8. Washing tray movement
9. First wash and tensioning
10. Second wash
11. Third wash
12. Final wash
13. Squeezing
14. Lifting Of Rollers
15. Unloading the hanks.

What is the significance of different steps in mercerizing cycle?
1.Pre tensioning
This is the first step in yarn mercerizing cycle ,which runs to uniformly distribute the greig yarn hanks on the rollers in combination with reversal of direction of motion of rollers, without any entanglement. The material should become completely wet in this step.

2.Shrinking
This is the actual caustic treatment step or the mercerizing step in which the yarn is allowed to shrink freely , the yarn runs for sufficient time in relaxed state to react completely with the caustic , higher the shrinkage achieved better will be the mercerizing.

3. Lye tensioning
The lye tensioning is done to stretch the yarn back to original length.

4.Squeezing
To remove the unbound caustic solution from the material, so that the material can be washed effectively, and quickly to reduce the caustic content . This step also ensure the to minimize the wastage of excess caustic liquor during washing.

5. Washing and tensioning
The stretch applied to get the maximum luster , material is washed along with stretching beyond its original length produce better luster. The amount of stretch applied depends upon the luster required and quality of yarn. The washing temperature is kept near boil to make washing efficient and short. Time or sequence of washing is so adjusted to reach a residual caustic content below 10% within a shortest possible time.

6.Final caustic content
The final caustic content should be below 10% ,because if it is more it will be sufficient to carry out further mercerizing effect and the material will shrink back. During the storage of mercerized material , the water from the exposed areas will evaporate and got concentrated locally causing mercerizing effect ,which is called local mercerizing and will lead to patchy dyeing.

The level of residual caustic in the yarn is achieved less than 3% , if it is on the higher side ,then the washing is not effective.