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Application of foam technology in textile wet processing
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Foam Technology
Reduce or eliminate the use of water
Conserving or saving energy
Developed in the 1980s
Water is used in foam technology but in a much smaller quantity than conventional coloration
methods.
CAV- Critical Application Value. CAV of 40
Pick up (%) is around 20. We need the liquor to transfer the dye inside the fiber interior. Not just
on the surface!
Spraying or padding involves using the pure liquid but when using foam for coloration, foam is
just going to be the transfer medium.
Types of Foam:-
- Solid foam (PU foam, PS insulation material etc.). Air is trapped inside in bubbles. Another
example includes cellular plastic where air cells are entrapped inside the expanded plastic.
Air is trapped inside in bubbles. Other examples of solid foam include bread, meringue etc.
which involves the disperse phase being gas and the dispersed medium being solid.
- Solid foams are used mainly in the preparation of insulation and in upholstery and even
found in pumice stone (lava; pumice stone being used in garment washing (denim washing))
- For textile use, we use “Gaseous foam” where the dispersed phase is water and the
dispersed medium is gas or air. E.g. of gaseous foams include egg whites, whipped cream,
beer. Here, Foam is a material of tiny air bubbles separated by fine films. The mass of air
bubbles are separated by thin films, being dispersed in liquid medium.
- Gaseous foams: Dispersed phase being gas and the continuous phase being water. Gaseous
foams serve as the transport medium or vehicle for textile chemicals like dyes or finishing
formulations to reach the substrate.
- Foams are more used in textile finishing than dyeing.
- Condensation Foams: This involves gas entrapment in a liquid. Eg. Soda pops. Or when
applying bicarbonate in a liquid, heating it to produce carbonate and CO2 gas. This gas forms
internally in the liquid being entrapped or dispersed in the liquid. [Carbonated drinks].
- “Generation of gas within the liquid either by chemical action or by physical by physical
means”. Eg. Changed in temperature and pressure.
*Remember, solubility increases with increasing temperature for a solid but for a gas,
solubility decreases with increasing temperature! So cool temperatures give higher
solubility.
- Solid foams like PU foams are a kind of condensation foam. Eg.
-N=C=O + H2O -NH2 + CO2
Here the CO2 gas gets entrapped in the PU, creating the solid PU foam.
- Dispersion Foams: These are produced by introducing and mixing a gas in a liquid phase.
E.g. whipped cream.
- Foams are applied in textiles as a dispersion type in which the liquid phase is water and the
gaseous phase is air.
- Due to buoyancy, just whisking isn’t enough to create the dispersion. A surfactant needs to
be added to hold these two phases from separating. This way the surfactant acts as a
‘foaming agent’. In textile foam processing, this foam is always used.
Important Aspects of Foam Processing:-
Reagent is applied to the fabric in the form of foam in contrast to conventional processed
impregnating the substrate in a solution of the reagent. As air replaces water as the transfer
medium for the reagents, the following advantages are gotten:-
- Reduced heating and drying costs of the fabric
- Saving chemicals, water and energy
- Less water to treat in the effluent
- Less waste disposal
- Improved quality of the product
Nature of Foams [Structure and Characteristics]:-
Foam is an agglomeration of gaseous bubbles (usually of air) dispersed in a liquid and separated
from each other by thin films or lamellae. It is these films which carry the dye finishing chemicals
or reagents.
There are two types of foams, spherical and polyhedral foams:-
Spherical Foam Polyhedral Foam
Spherical foams consist of individual, independent bubbles. Their creation doesn’t require the
use of a surfactant and their stability only depends on the viscosity of the dispersion medium.
At high viscosity, the lifetime of the foam is considerably lengthened.
Polyhedral foams only develop in the presence of surfactants.
Diagrammatic representation of foam structure:-
The
Spherical foams have 0.04 inch film thickness (1mm)
Polyhedral foams have 0.0004 inch film thickness. (0.01mm)
Spherical foams consist of a concentrated assembly of accumulation of discrete spherical
bubbles in a liquid spaced at distances greater than their diameter.
Polyhedral foams (most used is hexahedral) are aggregations of closely spaced polyhedral
shaped bubbles which burst almost immediately after they are formed.
Stable foams can be used in printing, sizing etc.
The bubbles vary in size from 50 mm to several millimeters. However for foams used for textile
purposes, size ranges from 50 – 100 m.
Bubbles MUST break up during application.
Properties of Foam:-
1) Foaming Degree
- Gives a measure of the extent of foaming. Its an indication of the volume of foam produced
from one liter (1 L) of liquor. Liquor is not just water. It consists of water + dyestuff +
auxiliaries or finishing formulation.
- Foaming degree is usually expressed in terms of foam density (g/L).
Foam density lies from (0.07 – 0.14 g/L) for Foam Finishing.
Foam density lies from (0.20 – 0.33 g/L) for Foam Printing.
- Another expression for Foaming Degree is ‘’Blow ratio” or
“Expansion ratio”.
- Blow ratio is defined as the ratio of mass of a given volume of
liquid before foaming to the mass of the same volume of foam.
Eg.
- For example, if 100ml of a foam weighs 10g and 100ml of the liquid weights 100g-
- For textile purposes, the blow ratio is 10:1 – 12:1
2) Foam Stability
- Change in density of the foam per unit time.
- Foam stability is a measure of the time taken for a foam to maintain it’s initial properties
(foam density, blow ratio etc.) after being generated.
- Foams that are very stable are difficult to collapse or rupture cause poor penetration of
formulation into the fabric.
- Similarly foams that are relatively unstable collapses before printing applications can begin,
resulting in uneven distribution of chemicals on the substrate surface.
- Half-life of foam :-
Foam stability can be expressed in terms of half-life t1/2
Half –life of foam is the time required for half the volume of the liquid contained in the foam
to drain to the bulk-liquid phase.
- Shorter the half-life lower the stability of the foam.
- Half-life of foam in other words can be defined as the time taken for half the contained
liquid in the foam to drain down to the bulk-liquid phase.
- Too high a stability of the foam and an anti-foaming agent is required.
- Foam’s half-life range:
- Foam’s half-life range according to the type of process making use of foam technology:
3) Foam Viscosity
- Measure of the foam’s resistance to flow.
- Foam viscosity is an important parameter as it influences foam performance. Eg. In coating
application, ease with which it can be handled, processed or used.
- Spray gun is often fitted in applicators in order to dilute or “thin” the foam or reduce the
thick foam’s viscosity when required.
4) Foam Wetting Power
- For an even surface distribution
- Rapid wetting by foam or rather by the liquid formulation collapsed and released by the
foam upon contact with the textile material, is a very important property where application
in textile finishing is concerned.
5) Bubble Size and Distribution
- Narrow range or distribution of bubble size is required (less variations = better dispersion).
Foam Processing (Block Diagram)
Sequence of Processing:-
1) Liquor Preparation
Essential ingredients go into the recipe for the preparation of the liquor to be used. Careful
attention is needed with regard to the individual components mixed.
Recipe for liquor :-
- Functional reagents (Colorants like dyes or pigments, finishing formulation chemicals etc.)
- Foaming agents (Surfactants)
- Viscosity modifiers (Thickener)
- Foam stabilizer (Stabilizer)
- An emulsion polymer copolymer
- Other additives, e.g. catalyst, wetting agent, fillers, pH buffer, biocides, bactericides,
insecticides etc.
(l) Functional Reagents
Includes colorants and finishing chemicals
(ll) Foaming Agents (Surfactants)
Use of a mixture of surfactants of different ionic nature in the liquor helps to obtain synergistic
effects in the foam to be produced.
Surfactants help promote foam generation under mechanical action. It helps to hold the two
phases together and prevents their separation.
Surfactants used. E.g. Anionic, Cationic, Non-Ionic, Amphoteric (or zwitterionic) – All are suitable
as foaming agents.
Class Surfactant
Anionic
Sodium or Ammonium Stearate
Sodium Oleate
Sodium Dodecyl (or Lauryl) Sulphate
Sodium Dodecyl Benzenesulphonate
Cationic Dodecylamine hydrochloride
Non-ionic Polyethylene oxide condensates / ethoxylated
alcohols, carboxylic acids, amines, amides etc.
Amphoteric Alkyl betaine surfactant
(lll) Viscosity Modifier
Thickeners are used which modify the viscosity so that the bubbles remain separate and
homogeneous.
Thickeners increase the viscosity of the compound thus slow down the drainage of the
interlamellar liquid (increase foam stability). Foam life is thus prolonged.
Examples of suitable thickeners (both natural and synthetic) include:-
- Locust bean gum
- Guar gum
- Methyl cellulose
- Hydroxy methyl cellulose
- Polysaccharides
- Sodium alginate
- Xanthan gums (These give highest thickening ability)
(IV) Stabilizers
These are used in combination with thickeners.
These are substances that doesn’t thicken but are added to improve foam stability
further, through enhancing thickening ability.
Eg. Sodium polyphosphates and Dodecanol (Lauryl alcohol) C12H25 –OH
(V) Emulsion Polymers or Copolymers
Colloidal dispersions (aqueous or water based) used to modify physical properties of
finished fabrics (these are only used in special cases when processing with foam).
E.g. Common types of polymer emulsions used include PVC and Polyacrylates
2) Foam Generation
Considered to be the heart of foam processing
There are various foam generations that are available and principles on which they
operate.
Quality of foamed compounds is influenced by the quality of air dosing. An accurate
blow ratio is required. Smallest fluctuations in air content changes the liter weight of the
foam and consequently the quality of the product.
Air injections have to be controlled with the liquor being flowed in at the same time.
Measurement of the flow rate is of equal importance in controlling the foam quality and
thus the end product as well.
Foam generator: used for the mixing of both air and liquor to create the foam.
Sample diagram of a foam generator:
There are two methods available
- Air blowing method
- Stirring method
Foam generation is achieved by vigorous mechanical agitation, air being supplied or injected at
high pressure (Air Blowing) or captured from the atmosphere by the turbulence of the liquid
(through agitation by the stirrer), a combination of these two methods may also be used.
Air Blowing type of foam generation may be either static or dynamic.
In the static mixer, a stream of air under pressure is
introduced into the liquor to produce irregular
shaped bubbles. Liquor & air are brought into
contact with each other in a mixing head containing
glass beads / stainless steel shavings/ plastic
shavings.
The static mixer can also have a vertical arrangement too instead of a horizontal one.
In this static foam generator, a stream of air under pressure is introduced to the liquor to
produce irregular shaped foam bubbles. Foam can also be generated by feeding a liquor
together with air through a chamber containing a number of closely packed glass balls, stainless-
steel shavings, plastic or chips.
Both air and liquid are metered into the head where they are mixed to produce the foam.
The liquid and air pressure push the foam out- to the point of application.
A dynamic mixer or foam generator consists of a stator and a rotor as shown:
Air under pressure + liquor are metered into the mixing head and the foam exits after
getting produced .
The rotor and stator are constructed to have a close arrangement by which the
air+liquor mixture is repeatedly sheared and mixed during this mixture’s passage
through the head.
Speed of the rotor, Clearance between the protruding components, Input rate of air and
liquor are factors influencing the pressure developed in the mixing head.
Equally important is the hose length between the foam generator and the application
point to provide sufficient back pressure.
Size of this system is somewhat reduced, the ease of cleaning is improved and the
system offers more constant conditions that the static mixer.
This system has better control over foam supply quantity, air dosing and gelling agent
quantities according to the speeds of the coating plant.
These computer assisted systems represent the present state-of-the-art.
Stirring Method
Combination of Air-
Blowing and Stirring
Method
*Note that all methods of foam generation mentioned so far are all batch methods.
3) Foam Application
- The systems of foam application include:
Direct System (Pressurized and Non-Pressurized)
Indirect System
Direct systems involve foam directly being applied to the fabric with this foam being held under
pressure in the distribution box. Foam application to the fabric is done through a variable-dimensional
slot applicator or through a rotary screen with the fabric pressed against a backing roller.
1. Direct system (Pressurized System)
2. Direct system (Non- Pressurized System)
- In the non-pressurized system, the reservoir of foam is not maintained under pressure, but
this doesn’t mean that there is no pressure involved during application. The foam gets
applied to the fabric by a horizontal pad or by a knife-over-roller, knife-on-air or knife-over-
blanket application system.
- In the horizontal pad-system, the fabric is introduced vertically through the nip point
between two rotating rollers and the foam can be fed at the appropriate rate to either or
both sides of the moving fabric. This allows simultaneous application of different finish on
both sides of the fabric!
- In the knife-over-roller, the knife- on- air and the knife-over-blanket techniques, the foam
is supplied to the moving fabric at a certain point against the knife, and the gap between the
knife and the fabric controls the application of foam. These techniques require the use of
stable foams which are to be destroyed after its application because the gap setting is the
major controller of pick-up (%) and the foam must not collapse and wet the fabric before
reaching the doctor knife, since otherwise a higher wet pick-up (%) may result.
3. Indirect system
- The first indirect system involves the use of a carrier/transfer or kiss roller. This carries the
foam along the circumference of the roller and transfers it onto the fabric.
The foam is metered by some means which is transferred to the fabric by the carrier roller.
The carrier doesn’t necessarily have to be a roller but can also a drum or a blanket.
Transfer of the foam is achieved as the carrier and fabric come into contact.
- Other systems have a similar approach. Foam is metered by some means on a carrier before
being transferred to the fabric. The carrier can be a drum (Janus) or blanket (Monforts), and
both there applicators are shown as follows:-
- Transfer of foam is achieved as the carrier and fabric come into contact. In the Monfort’s
system, transfer of foam is assisted by vacuum through the perforations of the carrier drum.
Monforts Vacu-Foam System
- The Monforts Machine, also known as Vacu-Foam, uses a knife-over-roller to meter a
uniform layer of foam on a rubber blanket.
- Transfer of the foam to the fabric occurs when the blanket makes contact with the fabric.
- Penetration of the foam into the fabric is assisted by vacuum as the fabric passes round a
perforated drum.
- Add-on is controlled by the foam density and knife clearance.
- Rate of foam collapse is depends on capillary forces, the vacuum created inside the
perforated drum and the pressure on the fabric.
- Wpu (%) for cotton is 35-40% and that for PET fabric is 10%.
- Even elastic warp-knitted fabrics and pile fabrics can be treated by this system. Its been
claimed that crease-recovery angle and abrasion resistance of the cotton fabrics treated
with foam were much better than conventional padding techniques.
Janus Mini-Foam System
- Kusters developed two foam processing systems, the Mini-Foam applicator for woven,
knitted and non-woven fabrics and the Maxi-Foam system for carpets and heavy pile fabrics.
- The Mini-Foam system is built in three standard models, for one sided application on the
face side of the fabric, for one-sided application on the back side of the fabric, and for
simultaneous two-sided application. The latter model being called “Janus Mini-Foam
applicator”.
- In the Janus Mini-Foam system, the foam is fed into the foam through a trough by an
oscillating feed pipe.
- The trough has adjustable sides, set to appropriate fabric width.
- An adjustable doctor roller at the lower end of the trough controls the amount of foam and
thickness of the foam layer (0.4 – 40 mm) on the rotating application roller.
- Foam is transferred and pressed into the fabric as it passes 180° around the application
roller. The foam is collapsed by capillary forces and pressure.
- The two distinct mechanisms involved are the application of foam to the application roller
and the transfer of foam to the fabric.
- The twin-roller Janus machine consists of two such applicators, enabling both face and back
of the fabric to be treated. Two different foam liquors can be applied separately but
simultaneously to the two sides of the fabric.
Parameters affecting the wet pick-up are
Speed of the application roller
Width of the gap between the doctor roller and the application roller
Foam density
Speed of the fabric
- Wet pick-up ranges from 15-30%
- Certain finishing chemicals are applied at a wet pick-up of about 35%.
- The two-sided application with one or two different foams is normally recommended for
woven and knitted fabrics of 150 gsm and above.
4) Foam Destruction
Foam needs to be destroyed on the fabric shortly after it is applied, releasing the
finishing liquor contained to take over as the transport medium. This allows the
reagents to penetrate and spread on the fabric before any fixation treatment is applied.
Manner of destroying the foam depends according to the method of application and
depends on the actual conditions of use.
Foam destruction is carried out mainly by
- Squeeze rollers of a conventional padder installed in front of a stenter
- Vacuum application
- Combination of these two methods
Foam destruction is promoted by:
- Capillary forces withdrawing the liquid from the foam lamellae and so reduces their film
thickness until the bubbles burst.
- Pressure, occurring during direct and indirect application, bringing the bubbles into close
contact with fibers, promoting bubble penetration and destruction.
- High drying or ambient temperatures causes lowered foam viscosity, increasing motion of
molecules in the lamellae and increasing the bubble volume. Plus, when surfactants are
heated beyond their turbidity point/ cloud point, they close their foaming ability and instead
function as destabilizers.
- Shear forces cause foam bubbles to burst by increasing their volume and weakening their
walls
- Defoamers; these are emulsions of an insoluble substance that contains organic solvents to
cause rapid spreading of the defoamer, as the defoamer is adsorbed onto the lamellae there
is a local increase in surface tension! The defoamer spreads out, carrying with it a thin film
of underlying liquid , therby thinning the lamella until it finally bursts.
5) Drying and Fixation
Drying and curing/fixation of foam-impregnated fabrics are usually done on traditional
machines (curing chambers and stenters).
Higher speeds and lower temperatures should be used since amounts of water to be
evaporated are much lower than those with a conventional pad-mangle finish
application system.
Advantages of Foam-application Techniques
Drying-energy costs are lowered due to low- add-on techniques used in foam application.
Drying-energy costs can be reduced by about 50%. The actual savings differ considerably and
range from as little as 15% to as high as 80%.
Drying temperature can be reduced considerably (by 65°C). Its also possible to maintain a
relatively high drying temperature but to increase the processing speed.
Water consumption is reduced by 30-90%. Reduction in the volume of effluent water. Effluent
treatment costs could be reduced by 50-80%. Air pollution is also reduced.
Chemicals are utilized more productively. Chemical consumption costs are reduced. Reduced
concentrations of auxiliary chemicals like printing thickeners. In some cases, some auxiliaries can
be completely removed from the formulation. Less dyestuff can be used than in conventional
padding processes. Chemical savings of less than 10% to up to as high as 50%.
Migration of DP or CRF resin finishes during drying is one of the most serious problems with
conventional finishing methods of cotton fabrics. This migration effect is reduced if wet pick-up
is reduced. Foam application this way reduces or eliminates this migration to produce a uniform
distribution of chemical on the fabric. This improves qualities like crease-recovery angle,
abrasion resistance, tear strength, tensile strength, bursting strength and resistance to flex
abrasion. Width shrinkage during washing can be reduced. Handle and wash-and-wear
properties of the fabric are also improved.
Elimination of pre-drying, making it possible to do wet-on-wet applications.
Different finishes can be applied to the face and back of a fabric. It is possible to dye the two
sides of a fabric independently in one process, for example, applying a basic dye to an acrylic
fiber pile face and a direct dye to a cotton back. Alternatively, one sided application is possible
too.
Delicate fabrics can be processed under low tensions by foam-application techniques.
Dye-yield can be improved. Rate of fixation of dyes is higher. Steaming times reduced. Washing-
off process time shortened. Rubbing fastness can be improved.
Volume of dye liquor can be reduced by 25-35%.
Printing with foam gives better quality, good definition with less strike-through and softer
handle. Washing-off of the printed fabrics can be reduced or even eliminated.
Disadvantages of Foam Application Techniques
Its essential to have well prepared fabric for foam processing. Variations in fabric absorbency
causes variations in wet pick-up leading to an inadequate and non-uniform chemical application.
At very low wet pick-up values, uniformity of application is critical and penetration of the
chemical into the fabric can be inadequate.
In cases where production speeds could be increases as a result of the lower wet pick-up,
certain drying units are not designed for such high running speeds.
In any low add-on application system, it is more critical. To maintain the same solids- add-on
level, concentration of chemical in these liquors are normally considerably higher than those in
conventional liquors!
Solvents and mineral oils used in certain processes will inhibit foam formation.
Certain optical brightener and softeners and the presence of sulfate ion from reagents reduces
foam stability.
Foams should generally be applied to both sides of a fabric.
Shades are difficult to match at low add-on levels.
It is difficult to produce deep shades at low wet pick-up (%) because of the limitations of
dyestuff solubility.
One important application method for chemical finishes is the use of
foam to apply the finish to the fabric. By replacing part of the water in
the chemical formulation with air, the amount of water added to the
fabric can be significantly reduced!
Surfactants are included in the formulation to be foamed.
The chemical formulation is mixed with air in a foam generator
producing high volumes of foam that can be applied to fabrics in a
number of ways.
The ratio of liquid to air in a foam is referred to as the ‘blow ratio’,
determined by the equation:-
Foam densities in the order of 0.1 g/cm3 are routinely used.
Stability of the foam is influenced by the components of the chemical
system, the viscosity of the foam and the method of foam preparation.
The half-life of a foam is the time in which 50% of the liquid is a given
foam has been drained from the foam to the bulk-liquid phase. Foams
for textile applications can have half-lives from a few seconds to
several hours.
One side applicators apply foam to only one side of the fabric, leaving
open the possibility of two different finishes on different sides of the
fabric. The two side applicators, on the other hand, apply the same
foam to both sides of the treated fabric.
Two side applicators normally employ two slots to apply the foam to
the fabric. Two distinctly different finishes can be applied to different
sides of the same fabric simultaneously.
Foam application on fabrics with large open spaces or non-uniform
porosity often causes uneven finish distribution.
Foam application systems also include horizontal pad mangles, kiss
coating systems, knife-over-roller or knife-on-air systems, screen
printing and slot applicators.
Proper fabric preparation is required in order to achieve uniform
finish distributions. A well-absorbent fabric is the best guarantee of a
proper finish application.
To maintain the same chemical add-on with lower wet pickups, the
concentrations of the finish bath components must be increased
according to the equation:-
conc2 = component concentration at the lower wet pick
conc1 = original concentration
density2 and density1 are the densities of the modified and original
solutions, respectively.
wpu2 and wpu1 are the lower and the original wet pickups
respectively.
Since the density of the more concentrated solution cannot be
determined until after the solution has been made, an initial estimate
of density2 is used in the equation, to calculate the approximate conc2.
Through successive iterations, more accurate values of density2 and
conc2 can be obtained if necessary.
Foam applicators:-
Foam applicators limit the amount of water added to the fabric by
replacing a portion of the water in the formulation with air.
A chemical formulation is mixed with air in a foam generator to create
a foam usually having fine bubble size.
Incorporating air into the formulation creates a large volume which
can be spread on the textile fabric more uniformly than can the
unfoamed liquid.
Relative amount of liquid and air in the foam are usually expressed as
the “blow ratio” of the foam. Blow ratio is the reciprocal of specific
gravity of foam. For instance, if a foam (made of only air and water)
weighs 0.1g/ml, the blow ratio is said to be 10:1 or 10 to 1. This
means that a foam having 10:1 blow ratio is 90% air and 10%
chemical formulation by volume.
Foams are inherently unstable and will separate into gaseous and
liquid phases as the foam ages. Relative stability of a foamed
formulation is important in foam application systems. Some methods
require very stable foams while others require very unstable foams.
Stability of a foam has to be tailored for the particular application.
Foam stability is expressed in terms of the half-life the foam. Half-life
of a foam is the time length of time required for half of the liquid in
the foam to drain out and become a separate liquid phase. Half-lives
of foams used in textile applications range from a few seconds to
many hours.
Two general types of foam applicators are called “open foam” and
“closed foam” processes. An open foam process is one in which the
foam leaves the particular generator and come in contact with the
atmosphere before being applied to the fabric.
In a closed foam process, the foam is trapped in the applicator under
pressure up to the point at which it contacts the fabric being treated.
Open foam applicators include knife coaters which spread the foam on
the fabric surface and the horizontal nip pad which coats the fabric
with foam and crushes the foam into the fabric as the fabric passes
through the nip of the rolls.
Wet pickup is determined mainly by the blow ratio of the foam.
An open foam process requires a foam of relatively long half-life since
the blow ratio must remain essentially constant at all times.
The closed foam applicator forces the foam under presser through a
slot, which is sealed by the fabric passing continuously across the slot.
The wet pickup is determined by the feed rate of the foam generator
and the speed of the fabric crossing the slot.
Foam having a relatively short half-life is preferred because the foam
should collapse upon contact with the fabric! The blow ratio and foam
pressure affect the degree of penetration of formulation into the
fabric.
Curved Blade Applicator
This applicator is designed for application of chemicals using limited
amounts of water, meters formulation onto the fabric at a
predetermined rate.
Formulation is delivered to the curved blade through a perforated
distribution pipe. Formulation accumulates in the weir (barrier or
block) and overflows down the blade to be deposited on the fabric
passing the tip of the blade.
Wet pickup is determined by the relative
rates of formulation feed and speed of the
fabric passing the blade.
Flow characteristics of the formulation are
critical since the blade must be completely
wet by the formulation to prevent
occurrence of untreated spots on the fabric.
Recommended