textile finishing materials · •textile wet processing can be thought of having three stages,...
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• Textile wet processing can be thought of having three stages, pretreatment (or
preparation), coloration (dyeing or printing) and finishing.
• Finishing in the narrow sense is the final step in the fabric manufacturing
process, the last chance to provide the properties that customers will value.
Finishing completes the fabric’s performance and gives it special functional
properties including the final ‘touch’. But the term finishing is also used in its
broad sense: ‘Any operation for improving the appearance or usefulness of a
fabric after it leaves the loom or knitting machine can be considered a finishing
step’.
• Physical properties such as dimensional stability and chemical properties such
as flame retardancy can both be improved with chemical finishing. Typically, the
appearance of the textile is unchanged after chemical finishing. Mechanical
finishing or ‘dry finishing’ uses mainly physical (especially mechanical) means to
change fabric properties and usually alters the fabric appearance as well.
Mechanical finishing also encompasses thermal processes such as heat
setting (thermal finishing).
• Textile Finishing is any operation (other than preparation and colouring) that
improves the appearance and/or usefulness of fabric after it leaves the loom or
knitting machine. Finishing is the final series of operations that produces
finished textile fabric from grey goods. Textile finishing usually includes
treatments such as scouring, bleaching, dyeing and/or printing, the final
mechanical or chemical finishing operations etc.
• Textile finishing usually includes treatments such as scouring, bleaching, dyeing and/or
printing,the final mechanical or chemical finishing operations, that during this stage are
carried out on textile products (staple, sliver or top, yarns or filaments, woven or
knitted fabrics) to enhance their basic characteristics like dye penetration, printability,
wettability, colour, hand, and appearance.
• By textile finishing, we also mean all the processing operations that, though included in
the so-called finishing stage, are generally applied to the fabrics to improve their
appearance, hand and properties, at times in accordance with their field of application.
• The finishing stage plays a fundamental role in the excellency of the commercial
results of textiles, which strictly depend on market requirements that are becoming
increasingly stringent and unpredictable, permitting very short response times for
textile manufacturers.
• Have you seen a fabric that comes from a loom? It is generally rough to feel,
dirty with stains and is known as ‘gray cloth’. The ‘markin’ fabric which we buy
for making quilt covers is off-white and dirty and is a gray fabric. But most of
the other fabrics that we buy from a shop are smooth, neat and clean. Why and
what happens in between? Yes, a finish has been applied.
A finish is anything that is done to a fabric after weaving or knitting, to changes
its appearance, hand and performance. When a finish is applied, say on cotton, it
might become more shiny, stronger or resist shrinking on washing. Similarly,
other finishes may make the fabric softer or stiffer; water or stain resistant;
coloured or designed.
Aim of Finishing
• The final chemical treatments of the fabric which are carried out to
impart special characteristics e.g. softening, stiffening, crease
resisting, flame retarding, soil release effect etc. is known as textile
finishing. The aim of the finishing is to improve the outward
appearance and the quality of the fabric, and impart its specific
properties.
Cycle of Finishing Process
• The whole cycle of finishing consists of mechanical and chemical processes,
which are used depending on the kinds and end uses of the fabric. Mechanical
processes include drying, calendaring, schreinering, embossing, sueding,
raisingetc and chemical processes include in the application of special
substances on the fabric, impregnation with size, starch, dextrin and other
polymeric substances. Plain fabrics (bleached, dyed and printed) are subjected
to finishing and other kinds of treatment. For instance white printed fabrics
with a white ground are passed through a padder containing a solution of
optical whitening agents for imparting glassy effect to the fabrics to be printed.
Mechanical treatments
• Drying
• Steaming
• Tentering
• Sanforizing
• Raising
• Calendaring/Schereinering/Embossing
• Perforating and slitting
• Shearing
Chemical Treatments
Temporary chemical treatments:
• Hardening
• Softening with non-fabric reactive finishes
Permanent chemical treatments:
• Anti-crease finish
• Anti stats
• Antimicrobials
• Lubricants
• UV absorbers add polymer stabilizers
• Thermoplastic binders, resins and emulsion polymers
• Thermosetting resins and crosslinking agents
• Softening with reactive polymer
• Durable flame retarding
• Durable water repelling etc.
Textile Finishing Processes
• The whole cycle of finishing consists of mechanical and chemical processes,
which are used depending on the kinds and end uses of the fabric. Mechanical
processes include drying, calendaring, schreinering, embossing, sueding,
raisingetc and chemical processes include in the application of special
substances on the fabric, impregnation with size, starch, dextrin and other
polymeric substances.
Steaming
• A fabric steamer uses steam rather than heat to remove wrinkles. The steam,
and slight pressure of the steamer's surface, relaxes the fibers rather than
flattening them. Because of this process, using a fabric steamer is gentler on
clothing, faster than using an iron, and eliminates scorching. The fabric steamer
is ideal for use on napped fabric, such as velvets and velveteen. A traditional
iron will crush the nap, unless used with a needle board, but the fabric steamer
doesn't exert pressure, preserving the luxurious look and feel of any material.
Even very delicate materials, such as satins and silks, benefit from the gentle
care of a fabric steamer.
Sanforizing
• It is a process whereby the fabric is run through a sanforizer; a machine that
has drums filled with hot steam. This process is done to control the shrinkage
of the fabric.
Tentering
• It is the mechanical straightening and dying of the fabric. Tenter fames hold the
fabric with special pins. The chain is spread apart to the desired width of the
fabric. The fabric is moved through dying units. Later the fabric is rolled on
cylinders.
Calendaring/Embossing/Crabbing
• Fabric calendaring is effected in special machines I.e. calendars, the main working
organ of which is rolls with smooth surface for normal calendaring engraved surface
for emboss calendaring and engraved finer lines for schreinering calendaring or for
getting crepe effect. The calendar may be 3 bowl or five bowl and the contacting one
bowl is plain steel roller and the other may be covered with rubber otherwise the
fabric at nip point will break if both bowls are hard.
• Glazing or rolling calendar: This method is not particularly important for nonwoven
fabrics, with occasional exceptions. The smooth surface can be obtained usually by
selecting an appropriate form of bonding and, especially, for drying a wet-bonded web.
Calendaring has not met with much success since it is often accompanied by
undesirable compression. The only time a rolling calendar is used is when two steel
rollers are paired to break the so-called 'blotches' in spun-bonded fabrics.
• Moiré or goffering calender: The calenders are common in nonwoven finishing and are
used in the compacting of the webs made of natural and synthetic fibers. This type of
calendering can be considered to be both a bonding and finishing process. Webs
composed of longitudinally oriented cotton or viscose fibers with a GSM of about 10-
30 g/m2 can be stiffened and compacted sufficiently by passing them through a
goffering calender when slightly damp. Hot embossing of synthetic fiber webs, even
when the fibers are longitudinally oriented, produces a product remarkably strong due
to the fibers melting at the embossed areas. The patterns can be of grid, webbed or
point type. The temperature of the heated rollers is generally 20-30°C above the
melting point of the fibers and the nip roll pressure 20-50dN/cm, depending on the
volume of the web and the proportion of synthetic fibers it contains. If the web is
cross-laid, point embossing results in maximum strength. If the fibers are arranged
lengthwise, webbed embossing is employed.
• The embossing effect is used to obtain special effects such as leather graining,
simulated weave, plaster, brush strokes, cord and mock tiling. Another area in
which heated calenders used is in the manufacture of laminates. Here
thermoplastic fibers, layers of thread or film are placed between two layers of
non-plastic web and are fused together by heat and pressure. Such laminates
are used as tablecloths, seat and cushion covers. Calenders are also used in the
transfer printing of the bonded webs.
• Crabbing is a preliminary treatment for both un-dyed and dyed woven fabrics
with differing objectives. In the case of un-dyed woven material the crabbing
process serves to fix the fabric so as to avoid too intensive creasing and felting
at the subsequent dyeing stage. After being dyed the woven fabric is smoothed
and leveled by crabbing. Silicone blankets are used in this process.
Perforating and Slitting
• The nonwoven bonded fabrics produced are too stiff and are, therefore, unsuitable for clothing.
This is because the individual fibers are not free to move in relation to one another, as are
threads in woven or knitted fabrics. Perforating and slitting are two methods practiced to
improve the fall or drape of nonwoven bonded fabrics.
Perforating:
• The Artos method is a method of perforating in which the web, which has been bonded by
using chemicals, is perforated with hot needles. This process not only punches holes but also
reinforces as a result of cross-linking and condensation of the bonding agent. The Hungarian
firm Temaforg uses a similar method to perforate webs made of synthetic fibers to produce
nonwoven bonded fabrics which are strong and yet supple enough for use as building and
insulation materials.
Slitting
• Slitting originally developed to improve the softness and drape of films was
used by the Breveteam Company for interlinings, in particular for adhesive
fixable interlinings. The optimum cut length and distance between the slits to
get maximum softness and fall without serious reduction of strength can be
calculated. The effect of slitting allows greatest flexibility at right angles to the
direction of the slit.
• The slitting is accomplished by a roller with small blades mounted on it, for
example, in an off-set arrangement 1.7 mm apart, making slits of a maximum
length of 6.5mm. Rotary knives with spreaders can be fitted to the roller, thus
making an interrupted cutting edge. Polyethylene or polyamide film shaped by
splitting or embossing and stretching by the Xironet and Smith-Nephew
methods make good air permeable bonding layers.
Anti-crease finish
• For getting anti crease effect usually melamine formaldehyde, urea formaldehyde and
dimethylol dihydroxy ethylene urea (DMDHEU), butane tetra carboxylic acid (BTCA) etc. can
be used. At very high temperature, they react with cellulose and give permanent anti crease
effect.The following reactions take place between the cellulose macromolecule and DMDHEU
• The usual method is Padding with DMDHEU and Catalyst -> Drying at (90-100)
degree C for 5 minutes -> Curing at (140-150) degree C 5-3 minutes
The following recipe can be used:
• Stabitex FRD/Fixapret CPN (DMDHEU) = 75 g/L
Ploy Vinyl acetate = 20 g/L
Ammonium sulphate = 10 g/L Or Magnesium Cholride = 10 g/L
Sodium perborate = 0.3 g/L
• The fabric is padded with the above solution and then dried at 100 degree C following curing
at 160 degree C for 3 minutes. Curing can be carried out in the stentering machine or curing
chamber.
Antistats
• Static electricity tends to build up in nonwovens made of synthetic fibers due to their lack of
moisture regain and conductivity. This can cause problems such as clinging and dragging during
processing, apparel that clings and crackles, dangerous discharge of static electricity in
explosive atmospheres and tendency to attract airborne dirt and soil in processing and use.
• The antistats work in three basic ways. They improve the conductivity of the fibers, coat the
fiber with a thin layer of material that will attract a thin layer of moisture, and finish the fabric
such that it holds a charge opposite to that normally accumulated on the fiber to neutralize
the static charge. Antistats can be either durable or non-durable. Examples of durable antistats
include vapor deposited metals, conductive carbon or metallic particles applied by binders,
polyamines, polyethoxylated amine and ammonium salts and carboxylic salts. Non-durable
antistats usually consist of inorganic or organic salts or hygroscopic organic materials.
Examples are quaternary ammonium salts, imidazoles and fatty amides which are cationic.
Anionic antistats include phosphates, phosphate esters, sulfonates, sulfates and phosphonates.
Examples of nonionic antistats include glycols, ethoxylated fatty acids, ethoxylated fatty
alcohols and sorbitan fatty acid esters.
Antimicrobials
• These are used to control populations of bacteria, fungi, algae and viruses on the substrate. The
treatment usually prevents the biological degradation of the product or prevents the growth of
undesirable organisms. Broadly classed, the antimicrobials are either fixed or leachable. The
fixed treatments are durable, but the leachable treatments may transfer to the surrounding
environment through migration, solubility or abrasion. A generic list of the treatments include
alcohols such as isopropanol or propylene glycol, halogens such as chlorine, hypochlorite,
iodine, N-chloramine and hexachlorophene, metals such as silver nitrate, mercuric chloride and
tin chloride, various peroxides, phenols quaternary ammonium compounds, pine oil derivatives,
aldehydes and phosphoric acid esters. Care should be taken in the application of these
compounds to prevent inactivation, loss of durability or masking of the active ingredient with
other finishes.
Lubricants
• Lubricants or slip agents are generally applied as processing aids to help in
stretching or to improve the process ability of nonwovens. They are also
applied to aid in sewing, quilting, tufting or other processes where needles
penetrate the fabric. Lubricants impart the same properties as softeners but
specifically reduce fiber friction. Common chemicals include sulphonated oils,
oil emulsions, silicones, esters, polyethylene dispersions and fatty acid soaps.
Many surfactants may also be used. Care should be taken to avoid excessive
strength loss.
UV absorbers and polymer stabilizers
• Ultraviolet light can do great damage to the polymers causing photo-
degradation, yellowing, loss in strength and fading of the colors. The damage is
generally due to the formation of destructive free radicals in the polymer. The
finish can protect the fabric by shielding the fiber or absorbing the light or by
chemically quenching the free radicals. The three main classes of products used
are, substituted benzotriazoles, benzophenones which are UV absorbers, and
hindered amines which are free radical reactants. They are applied from a bath
or added to the polymer.
Thermoplastic binders, resins and emulsion polymers
• Binders and resins are widely used in the finishing of nonwovens to add
strength, control stiffness, add mold ability or pleat ability, provide durable
flame retardants, color, reduce linting and control shrinkage. They soften when
exposed to heat and return to their original state when cooled and, hence, can
be set. Emulsion polymers are also called latexes. The common binders, resins
and polymers include acrylics, PVC, poly-acrylic acid, urethanes, starch, vinyl
acetate etc.
Thermosetting resins and crosslinking agents
• These are used to produce wrinkle resistant or permanent-press textiles. They
are used to crosslink cellulose for wrinkle resistance, crosslink binders for
wash durability and solvent resistance. The technology is based on the ability of
formaldehyde to react with cellulose and nitrogen containing resins. The
important resin types are melamine-formaldehyde, urea formaldehyde and
dimethyloethylene urea. The reaction is usually catalyzed by acids, such as
Lowry-Bronsted or Lewis acids. Problems encountered include formaldehyde
generation, tensile loss, discoloration and amine odor.
Softening
To impart softness, smoothness and flexibility it is necessary to apply a softening
agent. According to ionic nature softener can be classified into:
• Anionic softener
• Cationic softener
• Amphoteric softener
• Non ionic softener
• Among them, cationic softeners are mostly used because most of the textile is
anionic in nature. Therefore cationic softeners have a god affinity towards
textile fibers.
The following recipes can be used:
Basosoft 8 kg
Glycerine 1 kg
Water as required
Stentering speed 45-60 m/min
Temperature in different chambers of the stenter m/c
1st chamber 180°C
2nd chamber 180°C
3rd chamber 190°C
4th chamber 210°C
5th chamber 170°C
Stiffening Treatment
To impart hard or stiff handle it is necessary to apply a softening agent .For stiffening treatment
the following chamber chemicals can be used.
• Starch or modified starch
• Polyvinyl acetate(PVA)
• Polyethylene Emulsion
Recipe:
• Perapet PE 40(polyethylene) 10 Kg
• Water 90 Kg
• Temperature 220 °C
• Fabric speed in stenter 40-60 m/min
• Pressure in Padder 4.5 kg/cm
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