IMPLICATIONS OF THE ABOVE HOLISTIC UNDERSTANDING OF HARMONY ON PROFESSIONAL E...
foaming and defoaming agent
1. Colorants and Auxiliaries
Foaming and De- Foaming agents
Course Manager : D.r Abera Kechei
By Asnake Ketema & Robel Legesse
BAHIR DAR UNIVERSITY (EiTEX)
First Year M.SC In Textile Chemistry
3. What is foam?
Foam is a dispersion of a gas in a liquid. Here
the liquid is generally water and the Gas is
generally air but it may also be an inert gas. It’s a
colloid system.
Structure of foam
a matrix of foam to transfer chemicals and colorants to textiles
5. Foaming Agent
Definition:
A foaming agent is a material that facilitates formation of foam such
as a surfactant or blowing agent that helps to maintain it’s integrity
by strengthening individual foam bubbles.
Example- sodium lauryl sulphate
(C12H25OSO3Na)
A foaming agent to give a reasonably stable honeycomb matrix of air
cells.
6. The two important steps the foam and applying it to the substrate
1). by high-speed rotors with metered air and liquid flows and
monitoring to control the density of the foam.
(2) controlled amounts of foam to the substrate is by knife-on roller,
floating knife, horizontal pad or furnishing roller with doctor blade.
7. The First Three Being Anionic And The Others Nonionic
Sodium lauryl sulphate
Ammonium lauryl sulphate
Sodium dioctylsulphosuccinate
Lauryl alcohol poly(oxyethylene)
Decanol poly(oxyethylene)
Tridecanol poly(oxyethylene).
8. Requirements of foaming agents:
1. generate consistent foam easily
2. show optimum and uniform wetting
3. It should show little or no effect on color fastness
4. be compatible with the other components
5. be biodegradable
9. Broadly there are 2 types of foam:-
1. Dispersion foam: It is produced by the introduction & mixing
of gas from an external source into a liquid phase. In textile
field dispersion foam is used.
2. Condensation foam: It results from the generation of a gas
within the liquid either by chemical or by a physical change.
This type pf foam is not used in textile field.
Types of Foam
10. Stabilizer
Definition:
Foam stabilizer slows down the drainage of liquids from the bubbles
& impart workable flow properties.
The basic role of a stabilizer in foam is to reinforce the bubble cell
wall to a controllable level or stabilize foam from decay.
Example:-
– Hydroxy-ethyl cellulose (HEC)
– Methyl cellulose
– Ammonium stearate.
11. Function and Requirements
Function:-
• Slow down drainage.
• Reinforce bubble cell-wall.
• Controls life time of foam.
Requirements of stabilizer:-
- Easy solubility.
- Compatible with a foam finishing system.
- Effective at low concentration.
- It should be easily soluble.
- It should be least affected by fabric handle.
- Resistance of bacterial attack.
13. Defoaming agents in Textile Wet-Processing
Problems due to foam in textile wet-processing :
Dense foam leads to serious entanglements of fabric with
consequences of stoppages of machines, uneven absorbency, and
patchy dyeing.
In the dyeing of hanks and knitted fabrics, foaming of the dye
liquor can cause the material to float resulting in uneven application
of dye.
The foam in printing paste, especially in rotary screen and roller
printing machine can cause ‘fish eye’ spots on printed fabrics.
Defoamer/anti-foaming agent
14. Defoaming agent
The inherent characteristic of a de-foaming agent is that it is
surface-active but highly insoluble in water, with an extremely high
surface area
it is dispersed as tiny droplets in the form of an emulsion.
The surface-active components provide it with the ability to spread
very rapidly into any air-water interface that it encounters.
The spreading action of de-foamer causes a chemical or mechanical
shock to the surface, which in turn destabilizes the foam.
15. Mechanism of defoamers:
The surface-active nature of the defoamer causes it to spread very rapidly
onto any air-water interface that it encounters.
The function of hydrophobic silica particles is to pierce the surfaces of
foam bubbles, causing them to coalesce when the defoamer spreads at the
interface. Depending on the particular antifoam and the foaming system,
one can expect differences in the relative importance of these factors:
16. 1. Dispersion of antifoam in the foaming solution
2. Transport of antifoam droplets from bulk to the bubble interface
3. Entry of the droplet into the gas/liquid interface
4. Spreading
5. Bubble rupture
17. Requirements
1. The state of the foaming system, its homogeneity
2. The solution viscosity
3. The surfactant concentration in relationship to the critical micelle
concentration (CMC)
4. The surfactant type: ionic, nonionic, or mixed
5. The solution surface tension
6. The operating temperature
7. The solution pH
18. De-foamers used in textile processing
(I) Non-silicone and
(II)Silicone oil-based de-foamers
Non-silicone oil de-foamers can be further classified as :
a) Mineral oil
b) Alkyl phosphate
c) Block copolymers of ethylene oxide/propylene oxide
a) Mineral oil
do not perform at high alkalinity and high temperature, The efficiency is lower
inexpensive as compared to silicone-based de-foamers.
functional finishes like flame retardants and, in most cases, with water-repellents
or fluorochemicals
19. Alkyl phosphate
Phosphates are insoluble in water and hence made dispersible by usage of selected
surfactants.
When such an emulsified product is added in water it rapidly causes
displacement of air and allows quick wetting and sinking, thus preventing
fabric floatation. They show excellent alkali stability as they are phosphate
esters. These foam-control agents are more accurately.
c) EO/PO Block Copolymers :
EO/PO copolymers normally have good dispersing properties and are often well
suited when deposit problems are an issue. These are organic surfactants, which
are essentially suitable to formulate no-foaming detergents. They are soluble in
aqueous media at room temperature. They can be used as shear-stable antifoams,
which are active as foam-control agents above their cloud point
20. Silicone defoamers :
Foam is difficult to break down because it is stabilized by the surface
elasticity and surface viscosity of its film. Silicones have low surface and
interfacial tensions. This enables them to flow easily over the film
They seek out openings between the foam-stabilizing surfactants at the liquid-air
interface and occupy them. Silicones’ low surface tension and interfacial
properties combined with their lack of foam-stabilization properties cause the
foam wall to thin and collapse.
21. They are highly efficient antifoams/de-foamers, showing excellent
performance even at low dosages; however due to the strong
hydrophobic nature of poly-dimethyl siloxane, these emulsions are
susceptible to shear, pH and temperature, resulting in difficult-to
remove oil stains. Hence these silicone de-foamers are best suited for
low-turbulence machines, ambient temperatures and weakly acidic to
weakly alkaline aqueous baths.
Silicone defoamers :