This document discusses oil and fat processing, specifically refining of oils and fats. It describes the major steps in refining which include lecithin removal, degumming, neutralization, bleaching, and deodorization. The purpose of refining is to remove undesirable components from crude oils and produce an edible oil with desirable characteristics like clear appearance and stability. Key steps include degumming to remove phospholipids, neutralization to remove free fatty acids, bleaching to remove color, and deodorization to remove odors and flavors through steam distillation under vacuum. Proper processing refines crude oils into finished oils suitable for human consumption.
2. Introduction
Fats and oils comprises of 3 major classes of
foods –carbohydrates, proteins and fats.
It is chemically defines as the esters of the three
carbon trihydroxy alcohol, glycerol and various
monocarboxylic acids known as fatty acids.
All fats and oils are mixture of both saturated and
unsaturated fatty acids.
4. Variation in fats and oils
Fats Oils
Remains solid at room
temperature
Relatively more saturated
Relatively high melting
point
More stable
Remains liquid at room
temperature
Relatively more
unsaturated
Low melting point
Less stable
6. Oil refining objectives
1. Removal of undesirable products from crude
oil
• Free fatty acids(FFA)
• Phospholipids (gums)
• Oxidized products
• Metal ions
• Color pigments
• Other impurities
2. Preservation of valuable vitamins
vitamin E or Tocopherol- natural anti-
oxidants)
3. Minimizeoil losses
4.Improve shelf life of oil from degradation
7. Refining
Refining produces an edible oil with characteristics that consumers
desire such as bland flavor and odour, clear appearance, light color,
stability to oxidation and suitability for frying.
A refining process iscarried out following extraction of crude edible oils by meansof
screwpressesand/or solventextraction.
In refining, physicaland chemical processesare combined to remove undesirable
natural aswell asenvironmental-related components from the crudeoil.
Therefore, to obtain the above desired qualities following steps were
required namely:
1. Lecithin removal - to enrich the phospholipids
2. Degumming - Removal of phosphotides
3. Neutralization - removal of free fatty acids.
4. Bleaching - removal of color
5. Deodorization - To distill odors and flavors along with free
fatty acids.
6. Winterization - To separate the waxes
8. Lecithin removal
The processing step is primarily important
soybean which consist of high amount of
phosphotides.
During the process (2-3%) water is added to
crude oil, thereby enriching the phospholipids in
the oil/water interface.
The emulsion, thus formed is heated up to 80°C
and then separated or clarified by centrifugation.
9. Flow chart with equipment for Degumming - a. water degumming
b. acid degumming
c. enzyme degumming
10. Water-degumming
Water degumming is the initial
step for the refining
processing, used to separate
phospholipids, proteins etc.
which are insoluble in oil when
hydrated.
The emulsifying action of
phospholipids increases oil
losses during alkali refining.
Gums lead brown discoloration
of oil after heating during
deodouration.
Salts could be formed with cu,
mg, ca and iron accerlating
oxidative degradation of oil.
Certain phospholipids such as
lecithin, find widespread of
Untreated oil
Heat
In line mixer ( acid
addition)
Acid reacts with
phosphotides (gums) in
the oil to make
hydratable.
Water may be
added to
hydrate to
remove
phosphotides
before
removal in
the separator
oil may pass
straight to
neutralizing or
bleaching
without
removal of
gums ( acid
degumming)
Separator
degummed oil
Gums
11. Water-degumming
A large part of phosphotides (gums) can be hydrated
quickly and easily. If considerable amount of gums
are available, in pressed or extracted oil- it is
subjected to water degumming followed by extraction.
During this process, water is added to the oil. After
the reaction time, the hydrated phosphotides can be
separated either by decantation(settling) or by
centrifugation continuously.
In this process, large part of hydratable and even
small proportion of non hydratable phosphatides are
removed, the extracted could be processed to lecithin
for food feed or other applications.
Non hydratable
gums
Hydratable gums
12. Comparative study on degumming
Dry acid degumming Wet acid degumming
Suitable for processing oils of
low gum content.
It consists of palm oil, palm
kernel oil, animal fats, coconut
oils.
Intensive mixing is
implemented following addition
of acid to the preheated crude
oil.
The conditioned gums are
absorbed into the bleaching
earth and are separated by
filtration.
Low energy consumption,
maintenance and operational
cost.
Long service life.
Low investments and
environment friendly.
Suitable for processing oils
of high gum content.
It consists of soybean,
rapeseed, corn oil etc.
Water is added following to
Acid apportioning to
achieve gum hydration
therefore gums are
removed by separator prior
to bleaching.
Comparatively high energy
consumption
Long service life
Comparatively high
investment and
environmental friendly.
13. Enzymatic degumming
The prepared enzyme solution (i.e. aqueous solution of
citric acid, caustic soda and enzymes) is dispersed into
filtered oil @ mild temperature.
To attain conversion of non hydrated phospholipids to
hydrated phospho-lipids, a high speed mixer is utilized for
effective mising of enzyme.
Followed by separation of gums by mechanical
separator.
hence, the degummed oil is dried under vacuum and
suitable for further processing.Adjusting parameters during process:
1. Adjustment of citrate buffer and optimal temperature required.
2. Adjustment of enzyme solution
3. Time require for enzyme reaction time.
4. The reaction of lysophosphatide from the oil at 75°C
5. Enzymes name
• Lecitase®10L(pancreatic phospholipaseA2); Lecitase®Novo(microbiallipase)
• Lecitase®Ultra (microbiallipase)
14. NEUTRALIZATION
Alkali refining
Here, an alkali solution react
with oil and remove other
impurities such as
phosphatides, proteineceous
and mucilaginous
substances.
This process results in large
reduction of FFA through
their coversion in to high
specific gravity soaps.
Still minor impurities present
, soluble in the oil only in
anhydrous form and upon
hydration with caustic or
other refining solution it
would be separated.
After this Alkali refining,
oil/fat is water washed to
remove residual soap
Physical refining
The physical-refining is done
to oil containing low in
phosphatide content(palm
oil,, palm kernel oil and
coconut oil).
Here the FFA is removed by
Evaporation rather than by
Neutralization and soap
removal by alkali refining
process.
15. Bleaching-removal of color
Principle-adsorption
Mathematical representation
log(x/m) = logK + nlogc
Process would continue till thermodynamic
equilibrium is attained.
Here in this process trace metals, color bodies
likewise chlorophyll, soaps and oxidised products
are removed using bleaching clays, which absorb
impurities.
16. Parameters required :
Temperature-90-110°C
Reduced pressure
Acid activated bleaching
earth/clay or bentonite.
Time period-20-30
minutes
A : Bleacher A1 : Oil inlet
B : Barometric condenser B1 : Oil adsorbent outlet
C : Vacuum pump C1 : Steam inlet
D1: Condensate outlet
E1 : Bleaching Material inlet F1: Water Inlet
17. Importance of bleaching
agent
Fuller’s earth- natural clay-
adsorbtive (aluminum silicate
family-bentonite)
The bentonite should contain
surface area and pores.
Activation is done by acid
Acid activated bleaching earth-
self explained by acid status.
(degradation of P.V-form trans fatty
acids).
Activated carbon-derived from
coal- consists of micropores,
mesopores and macropores.
It has large adsorbent surface
relatively in a small volume.
18. Deodourisation
Deodorization is steam distillation process carried
out in a vacuum, to remove the volatile
compounds in the oil.
The process may be continuous, semi-continuous
and batch.
The end product would be bland oil with low level
of FFA and zero P.V.
This step also removes residual metabolites or
pesticides.
19. Deodourisation process
Deodourization is a vaccum stripping process in which neutral oil is
treated to remove malodorous compound ( volatile compound in
general) to obtain fully refined oil.
This process is similar to steam refining of neutral oil where along
with malodorous compound even fatty acids are also removed.The
above process is then known as steam deodourization.
• Deodorization is actually a combination of Two different effects on
oil
1) Stripping
• Temperature effect
• Deodorization is a multi-step process
comprising de-aeration, heating,
deodorization- deacidification, and cooling of
the oil.
20.
21. De-aeration
1. Carried out in order to avoid oxidation and hence avoid
risk of polymerization.
2. Oil is heated to 800c and sprayed in a tank, which is
kept at a pressure below 50 mbar.
3. Lower the pressure lower is residual air left in the oil.
Heating and cooling
• The subsequent heating of the oil is usually accomplished in two stages.
• In the first stage, the incoming oil is heated counter currently in an oil-oil
heat exchanger (economizer), with the finished oil leaving the deodorizer.
• Finally, the oil is heated under reduced pressure to the final deodorization
temperature with a high-temperature source.
• Source of Heating in the final stages are
1) High-pressure steam boilers
2) Thermal Oil Heaters
3) Downtherm A (diphenyl/diphenyloxide)
22. In this process the heat recovery, has become an important industrial
application, since it minimizes the cost of additional heating of the oil to
the deodourisation temperature.
Hence to obtain above conditions following heat exchangers were
evolved
1. External heat exchanger
2. Internal heat exchanger
Final cooling of the oil is usually conducted under reduced pressure to
prevent the possible production of degradation by products
As a result of the technological complexity and for cost reasons,
cooling under vacuum is usually applied only in a large capacity
deodorizer. Small capacity plants often make use of external oil–oil
heat-exchanging devices.
23. Steam stripping
• Amount of stripping agent is proportional to its
molecular weight.
• Hence steam is being used for stripping.
• But N2 is being experimented to be used as stripping agent.
• studies have indicated that color, residual
FFA, oxidative stability, as well as the formation of trans-fatty
acids and the stripping of tocopherols are not affected by the
nature of the stripping agent.
• Stripping agent must be dry and free from oxygen.
• Deodorization only occurs at the vapor-liquid contact zone
where the lowest operating pressure exists.
• Hence there are different Deodorizer design which attempt to
provide the best contact between the gas phase and the oil
phase by creating a large contact surface, together with an
optimal sparge steam distribution.
27. Vapor scrubbing system
• Composition of vapor phase
- Volatile components (FFA, odor
components)
- Stripping steam
- Non condensable gases(air,…).
• The volatile substances are condensed by
creating an intimate contact between the
vapor and the fatty acid distillate circulating
in the scrubber.
28. Vapor scrubbing
system
• Condensation of vapour phase is achieved by
1. series of sprayers or packed bed in vacuum
duct.
2. Installation of demister at the top.
3. improved scrubbers operating at two different
temperatures (so-called dual condensation
principle) have been introduced.
30. Vacuum
systems
• Combination of steam jet ejectors
(boosters), vapor condensers and
mechanical (liquid-ring) vacuum pump
• High motive steam consumption (60-
85% of total steam).
Steps in Acid Degumming
Heat oil to 60 -70 °C
Acid addition and mixing
Hydration mixing 30 minutes
Centrifugal separation of hydrated gums
Vacuum drying of degummedoil
Gums -recombined in meal