2.1 Production of Fresh Fruit Bunches
(FFB)
The key sub-processes involved in the development of plantations for the production of fresh fruit bunches (FFB) are shown in Figure 3 and the main activities for each step are summarised below:
Figure
3: Processes in the Production of Fresh Fruit Bunches
Planning
Phase for the development of new plantations would involve the conduct for
feasibility studies and an environment impact assessment (EIA) if the area to
be developed is primary or secondary forest in excess of 500 hectares. An EIA
is also required if the development involves changes in the types of
agricultural use of land in excess of 500 hectares.
Figure
4: NREB’s EIA Process
The
EIA study would facilitate the identification potential environmental and
social impacts and development of management plans to mitigate the adverse
effects. The process for the approval of EIA reports is
shown in Figure 4 which is based on the approach adopted by the Natural
Resources and Environment Board, Sarawak.
Nursery
Establishment commences as soon as the land is found to be suitable and
approved by the respective agencies for development to proceed. Good quality
DxP seedlings are raised in a polybag nursery for about 12 months. Good nursery
practices such as adequate watering, manuring and culling of seedlings with
undesirable characteristics are essential for the production of vigorous
planting materials. A culling rate of up to 25% is commonly practised in well
managed nurseries.
Site
Preparation include land survey, clearing of existing vegetation, establishment
of a road and field drainage system, soil conservation measures such as
terracing, conservation bunds and silt pits and sowing of leguminous cover
crops. From the early 1990s, the zero burning technique for land clearing, from
logged-over forest areas and replanting from various plantation crops.
Field
Establishment activities are lining, holing and planting of polybag oil palm
seedlings at density of 136 to 148 palms per ha, depending on the soil type. It
is important that effort is made to obtain full ground coverage by leguminous
cover crops such as Pueraria javanica and Calopogonium caeruleum to minimise
soil loss through runoff as well as to improve the soil properties through
nitrogen fixation. (Plate 6)
Plate 6: Immature
oil palm with full cover of leguminous cover crops.
Field Maintenance operations include weeding, water management, pruning, pest and disease management and manuring. Integrated pest management involving a mix of cultural, physical, chemical
and biological control approaches to minimise crop losses to pests is commonly adopted in plantations. Examples of biological control measures applied include the use of baculovirus and Metarhizium anisopliae
to control the rhinoceros beetle (Oryctes rhinoceros),
control of leaf-eating bagworms and nettle caterpillars by their
natural predators and
parasitoids and the use of barn owls (Tyto alba) (Plates 7 and 8) as the biological
agent to control
rats. (Golden Hope Plantations Berhad, 1997). As the cost of fertilisers is the major component of field upkeep expenditure, plantation companies
generally undertake soil and foliar analyses of individual fields regularly to assess their nutritional status and determine the
appropriate types and quantities
of fertilisers required for optimal palm development and production.
Plate
7: Barn owls for rat control
Plate
8: Stakeholder advisory
booklet on
integrated pest management
Harvesting
and Collection
Harvesting
of FFB commences between 24 to 30 months after field planting, depending on the
soil type and agronomic and management inputs. Harvesting is done manually,
using a chisel in young palms and a sickle mounted on a bamboo or aluminum pole
in taller palms (Plate 9)
Various systems for in-field collection of FFB and transportation to the palm oil mill. In view of increasing shortage of workers as well as the need to increase worker productivity, mechanised approaches have been adopted by plantations, an example being the tractor-mounted ‘grabber’ (Plate 10). |
Plate 9: Harvesting of FFB
Plate 10: Tractor mounted
‘grabber’
years,
after which the old stand is replanted. The zero burning technique of
replanting is now common commercial practice. However, in some situations,
plantations consider underplanting, whereby new seedlings are planted under the
old palms which are thinned out progressively to allow the development of the
new stand.
2.2 Production of Crude Palm Oil (CPO) and Palm Kernel (PK)
After harvesting, it is important
that the fresh fruit bunches
(FFB) are processed
as soon as possible to prevent
a rapid rise in free fatty acids
(FFA) which could
adversely affect the quality of the crude palm oil (CPO). Palm oil mills are generally located in the plantations to facilitate timely transportation and effective processing of
FFB. In 2001, there were 352 palm oil
mills in Malaysia
(Table
10), of which about 70% were located in Peninsular Malaysia.
Table 10: Number of Oil Mills, Refineries and
Palm Kernel Crushing Factories in Operation
in 2001 in Malaysia
|
Region
|
Oil Mills
|
Refineries
|
Crushing Factories
|
|||
|
No
|
Capacity1
|
No
|
Capacity2
|
No
|
Capacity3
|
|
|
P. Malaysia
|
244
|
45,373,720
|
38
|
10,952,900
|
30
|
3,254,600
|
|
Sabah Sarawak
|
89
19
|
18,750,600
3,620,400
|
9
|
4,596,500
|
8
|
1,057,500
|
|
Malaysia
|
352
|
67,744,720
|
47
|
15,549,400
|
38
|
4,312,100
|
Source: MPOB Capacity: 1. Tonnes FFB / year
2. Tonnes CPO /
year
3. Tonnes Palm Kernel /year
The
palm oil milling process (Figure 5) involves the physical extraction of palm
products namely, crude palm oil and palm kernel from the FFB. The process
begins with sterilisation of the FFB. The fruit bunches are steamed in
pressurised vessels up to 3 bars to arrest the formation of free fatty acids
and prepare the fruits for subsequent sub-processes.
The
sterilised bunches are then stripped of the fruitlets in a rotating drum
thresher. The stripped bunches or empty fruit bunches (EFB) are transported to
the plantation for mulching while the fruitlets are conveyed to the press
digesters.
In
the digesters, the fruits are heated using live steam and continuously stirred
to loosen the oil-bearing mesocarp from the nuts as well as to break open the
oil cells present in the mesocarp. The digested mash is then pressed,
extracting the oil by means of screw presses. The press cake is then conveyed
to the kernel plant where the kernels are recovered.
The
oil from the press is diluted and pumped to vertical clarifier tanks. The
clarified oil is then fed to purifiers to remove dirt and moisture before being
dried further in the vacuum drier. The clean and dry oil is ready for storage
and dispatch.
The
sludge from the clarifier sediment is fed into bowl centrifuges for further oil
recovery. The recovered oil is recycled to the clarifiers while the
water/sludge mixture which is referred to as Palm Oil Mill Effluent (POME) is
treated in the effluent treatment plant.(ETP).
The
press cake is conveyed to the depericarper where the fibre and nuts are
separated. Fibre is burned as fuel in the boiler to generate steam. The nuts
are cracked and the shell and kernel are separated by means of a winnower and
hydro-cyclone. The clean kernels are dried prior to storage.
Figure 5: Palm Oil Milling Process
2.3 Production of Refined Edible Palm Oil
About
80% of the national production of crude palm oil is used for food purposes,
mainly as cooking oils. The CPO produced by the mills have to be refined to
meet the industry’s and international standards (FAO’s Codex Alimentarius) for
edible oils. The production of refined oil is undertaken in 57 refineries in
Malaysia (Table 10) with a total refining capacity of 15.5 million tonnes CPO
per year.
The
refining process removes free fatty acids, phosphatides, odouriferous matter,
water as well as impurities such as dirt and traces of metals from the CPO; the
objective being to produce an edible oil of consistent quality that meets
industry’s standards and satisfies customer requirements particularly in
respect of FFA, moisture and impurities, Iodine Value, Peroxide Value, melting
point, colour and flavour. The refined oil must tasteless and have a bland
flavour.
CPO
is processed by either physical or chemical refining to produce either refined,
bleached and deodourised palm oil (RBDPO) or neutralised, bleached and
deodourised palm oil (NBDPO). These are subjected to fractionation to obtain
the respective liquid olein fraction and the solid stearin fraction. (Figure
6). Of the two processes, physical refining is the predominant approach adopted
by the refineries as it is simpler, less capital intensive, more efficient and
produces a lower effluent load.
Physical
or steam refining begins with degumming when the CPO is treated with food grade
phosphoric acid or citric acid to remove natural gums in the form of
phosphatides , followed by bleaching with activated earth (Fuller’s Earth)
under vacuum to remove colouring matters as well as to adsorb any metal ions.
The treated oil is then heated to 240 C - 260 C under 2- 6 mm Hg (MEOMA, 2002)
for simultaneous deacidification and deodorisation. The FFA is stripped off by
live steam and is recovered together with the entrained oil is as palm fatty
acid distillate. The steam distillation process also removes odours and
off-flavors from the CPO (‘Deodorisation’). The oil is then cooled to 55°C
before polishing.
In
the chemical refining process, the FFA present in CPO is removed by
neutralisation with caustic soda (sodium hydroxide), the concentration of the
latter being dependent on the quality of the CPO feedstock. This chemical
reaction produces neutralised CPO and a soap stock; the latter is separated
from the oil by a high-speed separator. The neutralised oil is subjected to
earth bleaching to remove colour pigments and metal ions followed by
deodorisation - steam distillation under vacuum to remove odoriferous matters
such as aldehydes and ketones.
The
refined oil contains triglycerides of various compositions and melting points,
the main fractions being palm olein and palm stearin. These fractions can be
separated by dry fractionation, detergent fractionation and solvent
fractionation. Dry fractionation is
commonly
used whereby the refined oil is allowed to crystallise under controlled
temperature and the resultant slurry is pumped through a membrane filter press
to obtain the liquid olein fraction and the solid stearin portion. The olein
could also be fractionated for a second time (‘double fractionation’) to
produce a ‘super olein’ and a solid palm mid-fraction (PMF) which is the
feedstock for production of specialty fats and other products.
Figure 6: Palm Oil Refining Process
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