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40 Separation Technology in Food Processing 773
as particle shape and size distribution, porosity and pore size dis-
tributions, surface area, and moisture content influence solubility
and mass transfer. The presence of water (moisture content) in
the sample matrix during supercritical extraction also has an
effect on the extraction outcome. In order to improve the yield
and quality of the extracted high-value food components from
raw material, a pretreatment of the raw material is an essential
process (Yang et al. 2008, Zheng et al. 2009, Nagendra et al.
2010). Cell disruption is the most important pretreatment, and
this procedure can be conducted by several processes such as
mechanical, ultrasonic, high electronic field pulse, and nonme-
chanical treatments. With improved processing conditions and
reduced cost, high-value components extracted from natural ma-
terials by supercritical CO 2 extraction process will become even
more economical at high throughput.
Membrane-Based Separation Technology
Membrane-based technology is a rising separation technology.
At present, more and more fields use membrane technology to
separate the fluids and get good results. With the principal devel-
opment of membrane technology, the applications are expand-
ing much wider and the technology brings remarkable economic
benefits. Now, many countries in the world have noticed the im-
portance of membrane technology in the food processing field,
especially since we are short of energy and resources and the
deteriorating environment all exist in our lifetime. So, industries
regard membrane-based separation technologies as important
technologies in food processing areas.
The common membrane-based separation process is usually
run under pressure. A membrane can be described as a thin
barrier between the two bulk phases, and it is either a homoge-
neous phase or a heterogeneous collection of phases. In mem-
brane separations, each membrane has the ability to transport one
component more readily than the others because of differences
in physical and chemical properties between the membrane and
the permeating components. Furthermore, some components can
freely permeate through the membrane, while others will be
retained. The stream containing the components that pass
through the membrane is called the permeate, and the stream
containing the retained components is called the retentate. The
flow of material across a membrane is kinetically driven by the
application of pressure concentration, vapor pressure, hydro-
static pressure, or electrical potential (Mulder 1996, Cheryan
1998).
Membrane separation technology adopts a selective multi-
hole membrane as the separation medium. The separated fluid,
driven by the outside pressure, goes through the surface of
the membrane with different pore sizes. The molecules will
pass the membrane but larger molecules will be rejected. There-
fore, the fluid can be separated into different molecular weights
with high efficiency (Cheryan 1998).
Compared with the traditional separation process technolo-
gies, membrane-based separation processes can run under nor-
mal temperatures, so are especially good for separating and
concentrating heat-sensitive materials such as juices, enzymes,
or phytochemicals (Vaillant et al. 2001, Enevoldsen et al.
2007, Pouliot 2008). Moreover, membrane-based processes are
energy-efficient processes that do not involve phase change or
heat input; thus, the processes do not require ancillary equipment
such as heat generator, evaporator, and condenser. They offer
ease of operation and great flexibility, and do not require the
addition of any chemical agents. The process also provides for
minimal thermal degradation, occurs at ambient temperatures,
and is used both to filter molecular-sized particulates and also to
concentrate an isolate of interest, such as lycopene. Determina-
tion of the optimum operating conditions is vital importance.
Membrane-based processes are usually more energy efficient
than distillation, adsorption, and chromatography. Furthermore,
membrane-based separation has the advantage of compatibility
with a wide range of solvents and chemical products, an ability
to process thermally sensitive compounds and easy amenabil-
ity to automation. These advantages open up several possibil-
ities of membrane application in the production of bioactive
compounds in the areas of energy-efficient pre-concentration of
dilute solutions, fractionation of diverse classes of compounds
from complex mixtures, recovery of intermediates, and recy-
cling of solvents. The challenges posed by a membrane-based
separation process are limited selectivity, fouling leading to per-
formance decline, and a necessary and occasionally difficult
periodic cleaning process. The performance of a membrane can
be distinguished by two simple factors: flux (or product rate) and
selectivity through the membrane. Flux is defined as the perme-
ation capacity that refers to the quantity of fluid permeating per
unit area of membrane per unit time. Flux depends linearly on
both the permeability and the driving force. The flux also de-
pends inversely upon the thickness of the membrane (Yang et al.
2001, Bhanusali and Bhattacharyya 2003, Kert ́esz et al. 2005).
Figure 40.5 shows a classification of various separation-based
processes that are based upon particle or molecular size. The
five major membrane separation processes, including microfil-
tration, ultrafiltration, nanofiltration, reverse osmosis, and elec-
trodialysis, cover a wide range of particle sizes according to the
Water
Reverse osmosis (RO)
Nano filtration (NF)
Ultrafiltration (UF)
Microfiltration (MF)
Membrane separation
Figure 40.5.Schematic diagram of membrane molecular cut
property.