NZ621748B2 - Method of spray-drying and apparatus for spray-drying - Google Patents
Method of spray-drying and apparatus for spray-drying Download PDFInfo
- Publication number
- NZ621748B2 NZ621748B2 NZ621748A NZ62174812A NZ621748B2 NZ 621748 B2 NZ621748 B2 NZ 621748B2 NZ 621748 A NZ621748 A NZ 621748A NZ 62174812 A NZ62174812 A NZ 62174812A NZ 621748 B2 NZ621748 B2 NZ 621748B2
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- New Zealand
- Prior art keywords
- nozzle
- main surface
- fluid
- pressure difference
- outer main
- Prior art date
Links
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- 238000001694 spray drying Methods 0.000 title claims abstract description 22
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- 238000001035 drying Methods 0.000 claims abstract description 21
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- 238000005507 spraying Methods 0.000 claims abstract description 10
- 230000003247 decreasing effect Effects 0.000 claims description 7
- 235000013305 food Nutrition 0.000 abstract description 15
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- 239000007921 spray Substances 0.000 description 10
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Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J2/00—Processes or devices for granulating materials, e.g. fertilisers in general; Rendering particulate materials free flowing in general, e.g. making them hydrophobic
- B01J2/02—Processes or devices for granulating materials, e.g. fertilisers in general; Rendering particulate materials free flowing in general, e.g. making them hydrophobic by dividing the liquid material into drops, e.g. by spraying, and solidifying the drops
- B01J2/04—Processes or devices for granulating materials, e.g. fertilisers in general; Rendering particulate materials free flowing in general, e.g. making them hydrophobic by dividing the liquid material into drops, e.g. by spraying, and solidifying the drops in a gaseous medium
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J2/00—Processes or devices for granulating materials, e.g. fertilisers in general; Rendering particulate materials free flowing in general, e.g. making them hydrophobic
- B01J2/18—Processes or devices for granulating materials, e.g. fertilisers in general; Rendering particulate materials free flowing in general, e.g. making them hydrophobic using a vibrating apparatus
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B05—SPRAYING OR ATOMISING IN GENERAL; APPLYING FLUENT MATERIALS TO SURFACES, IN GENERAL
- B05B—SPRAYING APPARATUS; ATOMISING APPARATUS; NOZZLES
- B05B1/00—Nozzles, spray heads or other outlets, with or without auxiliary devices such as valves, heating means
- B05B1/02—Nozzles, spray heads or other outlets, with or without auxiliary devices such as valves, heating means designed to produce a jet, spray, or other discharge of particular shape or nature, e.g. in single drops, or having an outlet of particular shape
- B05B1/04—Nozzles, spray heads or other outlets, with or without auxiliary devices such as valves, heating means designed to produce a jet, spray, or other discharge of particular shape or nature, e.g. in single drops, or having an outlet of particular shape in flat form, e.g. fan-like, sheet-like
Abstract
Method and apparatus for spray-drying a high-viscosity fluid (4) is disclosed. A device with a nozzle plate (8) having at least one nozzle (14) extending through from the inner surface to the outer surface is provided. The high-viscosity fluid (4) is pressurized in a reservoir (6) to flow out of the at least one nozzle (14). After exiting the nozzle (14) the fluid forms a jet that breaks up into droplets (18) which are at least partially dried by a drying medium, such as air, to become particles. The particles may form a powdered product for example food, beverage or pharmaceutical ingredients. The area of the nozzle (14) is larger on the interior side of plate (8) that the exterior (see Fig. 2, 3) to decrease the pressure needed for spraying the high-viscosity fluid. he at least one nozzle (14). After exiting the nozzle (14) the fluid forms a jet that breaks up into droplets (18) which are at least partially dried by a drying medium, such as air, to become particles. The particles may form a powdered product for example food, beverage or pharmaceutical ingredients. The area of the nozzle (14) is larger on the interior side of plate (8) that the exterior (see Fig. 2, 3) to decrease the pressure needed for spraying the high-viscosity fluid.
Description
Title: Method of spray-drying and apparatus for spray-drying.
The invention relates to a method of spray-drying a high-viscosity fluid.
The invention also relates to an apparatus for spray-drying of a high-viscosity
fluid. The invention also relates to a product.
Spray drying of a high-viscosity fluid product through at least one nozzle can
be used for producing a product such as a food product in the form of a powder.
The fluid to be spray dried may comprise a dispersion and/or solution of the
product in a solvent, e.g. a liquid such as water. The fluid is fed from a fluid
reservoir through the nozzle. After the fluid flows out of the nozzle, it may
break up into droplets e.g. according to a Rayleigh breakup principle. The out-
flowing or ejected droplets may be dried using a drying medium such as air.
While the liquid is removed, particles forming the powder may remain after
drying of the droplets. The powdered product may e.g. comprise a powdered
food product containing food or beverage ingredients with proteins, carbon
hydrates, fats, or combinations thereof, more specifically e.g. dairy products,
liquid flavor compounds, etc.
Generally a wish for a high production rate of the product may exist.
Thereto a relatively high pressure difference over the nozzles may be
beneficial. However, such a high pressure difference may impose requirements
to an apparatus used for spray drying. For example, a nozzle plate containing
the nozzles should be strong enough to withstand the pressure difference.
Thereto the nozzle plate may be made relatively thick. However, using a
thicker nozzle plate in order to withstand a certain pressure difference over
the nozzle plate can be expected to diminish the flow rate through the nozzles,
because a thicker nozzle plate generally causes a longer nozzle. Such
diminishing of the flow rate however is contrary to the initial reason of
increasing the pressure difference over the nozzle. So, at least part, possibly a
significant part, of the effect of increasing the pressure may be lost.
Therefore, there exists a need for an improved method and apparatus
for spray drying a high-viscosity fluid, which at least partly meets the problem
mentioned above.
Accordingly, according to an aspect of the invention, there is provided a
method of spray-drying a high-viscosity fluid that e.g. comprises a food
product, using a spraying device, the method comprising: - providing a nozzle
plate wherein at least one nozzle is provided, said nozzle plate having an inner
main surface and an outer main surface, the least one nozzle extending
through the nozzle plate from the inner main surface to the outer main
surface; - providing the high-viscosity fluid in a reservoir that is in fluidum
connection with at least one nozzle; - pressurizing the high-viscosity fluid in
the reservoir, wherein the fluid flows, as a result of said pressurizing, towards
the nozzle plate, thus creating a pressure difference over the at least one
nozzle so that the fluid flows out of the at least one nozzle, thereby passing the
outer main surface after passing the inner main surface; wherein the fluid
flowing out of the nozzle forms a jet that breaks up into droplets; and at least
partially drying the droplets in a drying medium, such as air, to become
particles; wherein a cross-sectional area of the at least one nozzle in the inner
main surface exceeds a cross-sectional area of the at least one nozzle in the
outer main surface thereby decreasing a pressure difference over the at least
one nozzle needed for spraying the high-viscosity fluid.
A technical effect of having the cross-sectional area of the at least one
nozzle in the inner main surface larger that the cross-sectional area of the at
least one nozzle in the outer main surface, is that a pressure differential over
the at least one nozzle can be relatively low. Hence, a desired flow rate through
the at least one nozzle, and hence a desired production rate, may be reached at
a relatively low pressure difference over the at least one nozzle. Consequently,
the nozzle plate can be designed relatively thin and/or a number of nozzles in
the nozzle plate can be relatively high. Hence, said production rate may be
relatively high.
The inventors thus realized an inventive thought that adapting a shape of the
at least one nozzle can be used for decreasing a pressure difference over the at
least one nozzle needed for spraying the high-viscosity fluid and/or increasing
a production rate of the at least one nozzle, with only a limited impact on
strength of the nozzle plate and on a volume of a produced droplet. Further
advantages and/or technical effects may include a stronger nozzle, a drop in
necessary pressure, and/or the possibility for spray drying relatively higher
viscosity fluids.
The high-viscosity fluid, or, in other words, viscous fluid, may have a shear
viscosity larger than 0.1 pascal·second, preferably larger than 0.2
pascal·second, more preferably larger than 1 pascal·second. Said viscosity may
be determined at a shear rate of 1 s and a temperature of 20 degrees Celsius,
using a cone-plate rheometer.
Preferably, during pressurizing, the pressure difference over the at least
one nozzle is kept at at most 15 bar, preferably at at most 12 bar. Conversely,
WO2008/069639 relates to a method of spray drying of a high-viscosity fluid.
According to WO2008/069639, a pressure drop over a nozzle in order to force
the fluid out of the nozzle is larger than 15 bar. Then, a substantially mono-
disperse stream of droplets may be generated from the fluid that flows out of
the nozzle. By means of the at least one nozzle, a substantially mono-disperse
stream of droplets may be generated from the fluid that flows out of the nozzle,
even when the pressure difference over the at least one nozzle is kept at
pressures below 15 bar, or even below 12 bar. It is to be appreciated, that a
required pressure difference is lowered compared to the known spray drying
method of WO2008/069639 through the currently disclosed nozzle design.
Alternatively, higher viscosity fluids may be spray-dried using the same
pressure, e.g. also at 15 bar or higher.
Preferably, the method comprises drying the fluid after it has passed the
outer main surface. Preferably, the method comprises collecting the dried food
product, thus obtaining the food product in the form of a powder.
According to a further aspect of the invention, there is provided an
apparatus for spray-drying of a high-viscosity fluid that e.g. comprises a food
product, the apparatus comprising: - a reservoir for containing the high-
viscosity fluid; and - a nozzle plate that is in fluidum connection with the
reservoir, has an inner main surface and an outer main surface, and is
provided with at least one nozzle extending through the nozzle plate from the
inner main surface to the outer main surface; and drying means; the
apparatus being arranged for pressurizing the fluid in the reservoir so that, in
use, the fluid flows towards the nozzle plate, thus creating a pressure
difference over the at least one nozzle so that the fluid flows out of the at least
one nozzle, thereby passing the outer main surface after passing the inner
main surface; wherein the fluid flowing out of the nozzle forms a jet that
breaks up into droplets; wherein the drying means is arranged for causing
and/or allowing the droplets to dry to become particles; wherein a cross-
sectional area of the at least one nozzle in the inner main surface exceeds a
cross-sectional area of the at least one nozzle in the outer main surface thereby
decreasing a pressure difference over the at least one nozzle needed for
spraying the high-viscosity fluid.
Preferably, the apparatus comprises pressurizing means for
pressurizing the fluid in the reservoir so that the fluid flows towards and/or is
pressurized against the nozzle plate and out of the at least one nozzle, thereby
passing the outer main surface after passing the inner main surface.
Preferably, the pressurizing means are arranged for keeping a pressure
difference over the at least one nozzle at at most 15 bar, preferably at at most
12 bar. Additionally, a lower pressure difference over the at least one nozzle,
e.g. at most 15 bar or at most 12 bar, may result in a lower strain on the fluid
and on relatively vulnerable parts of the apparatus.
Preferably, the apparatus is arranged for carrying out a method
according to the invention.
In said aspect and said further aspect, preferably, an area ratio, being equal to
the cross-sectional area of the at least one nozzle in the inner main surface
divided by the cross-sectional area of the at least one nozzle in the outer main
surface, is at least five and/or is at most fifty.
In said aspect and said further aspect, preferably, the at least one nozzle
comprises a substantially non-widening, e.g. cylindrical, part that extends
from the outer main surface, and comprises a substantially widening, e.g.
tapered, optionally frustoconical, part that extends from the substantially non-
widening part to the inner main surface. Optionally, the at least one nozzle is
substantially trumpet-shaped.
In said aspect and said further aspect, preferably, in use a pressure
difference ratio, being equal to a pressure difference over the substantially
widening part divided by a pressure difference over the substantially non-
widening part, is at most 1, preferably at most 0.5, more preferably at most
0.3, e.g. at most 0.2.
In said aspect and said further aspect, preferably, a length of the
substantially non-widening part of the at least one nozzle, measured along an
outflow direction of the high-viscosity fluid through said non-widening part, is
at least equal to a diameter of the at least one nozzle, preferably at least three
times a diameter of the at least one nozzle in the outer main surface. As a
result, a relatively stable jet and/or droplet formation may be obtained by the
fluid flowing out of the at least one nozzle 14. E.g. in an embodiment, the
length of the substantially non-widening part is at least 60 micrometer,
preferably 180 micrometer and/or at most 250 micrometer.
In said aspect and said further aspect, preferably, the at least one nozzle
widens gradually from the outer main surface to the inner main surface.
In said aspect and said further aspect, preferably, a width, a length, and
a thickness of the nozzle plate, a composition of the nozzle plate, as well as a
size, a number, and a distribution of nozzles in the nozzle plate, are arranged
for withstanding a pressure difference over the at least one nozzle of at least
12 bar, preferably at least 15 bar.
The invention also provides a food product that is produced by means of
a method according to invention and/or an apparatus according to the
invention.
Embodiments of the invention will now be described with reference to
the accompanying drawings, in which corresponding reference symbols
indicate corresponding parts, and in which:
Figure 1 shows a schematic cross-section of an apparatus for spray-
drying of a high-viscosity fluid, in a first embodiment according to the
invention;
Figure 2 schematically shows a cross section of a nozzle plate provided
with at least one nozzle, in a second embodiment of an apparatus according to
the invention;
Figure 3 schematically shows a cross section of a nozzle plate provided
with at least one nozzle, in a third embodiment of an apparatus according to
the invention;
Figure 4A schematically shows a front view of a nozzle plate provided
with a plurality of nozzles, in a fourth embodiment of an apparatus according
to the invention; and
Figure 4B schematically shows a front view of a nozzle plate provided
with a plurality of nozzles, in a fifth embodiment of an apparatus according to
the invention.
Figure 5A shows a side view of an embodiment of a pressure varying
means.
Figure 5B shows a top view of Figure 5A.
Figure 6A shows a side view of another embodiment.
Figure 6B illustrates a top view of Figure 6A.
Figure 7A shows a side view of another embodiment.
Figure 7B illustrates a top view of Figure 7A.
Figure 1 shows a schematic cross-section of an apparatus 2 for spray-
drying of a high-viscosity fluid 4, in a first embodiment according to the
invention. The apparatus 2 may comprise a reservoir 6 for containing the high-
viscosity fluid 4. The apparatus may further comprise a nozzle plate 8. The
nozzle plate 8 may be in fluidum connection with the reservoir 6. The nozzle
plate 8 may have an inner main surface 10 in contact and/or connection with
the fluid 4 and an outer main surface 12. The nozzle plate may be provided
with at least one nozzle 14, preferably a plurality of nozzles 14 that extend
through the nozzle plate 8 from the inner main surface 10 to the outer main
surface 12.
More in general, the term ‘nozzle plate’ may be interpreted broadly. The
nozzle plate may be composed of a plurality of parts. Said parts may be
mutually attached, thus forming a structure provided with nozzles. The term
‘nozzle’ may refer to an opening through the nozzle plate from which fluid may
be ejected. A thickness D of the nozzle plate 8 may be measured in a direction
perpendicular to the inner and/or outer main surface 10, 12. Said thickness D
of the nozzle plate may be uniform, i.e. may vary at most 10 percent of a
maximum thickness of the nozzle plate, apart from the nozzles. Alternatively,
the thickness D of the nozzle plate may be non-uniform, i.e. may vary along
the nozzle plate more than 10 percent of a maximum thickness of the nozzle
plate. Hence, said structure may vary in a direction transverse to the nozzle
plate, e.g. may be provided with recesses or cavities and/or projections, in
addition to the nozzles. Optionally, a disc-shaped end part of a tube that forms
a nozzle, or a plurality of said disc-shape end parts optionally spaced apart
from each other, may be regarded as a nozzle plate. In other variations
however, the term ‘nozzle plate’ may be interpreted more narrowly. Then, the
nozzle plate may comprise a plate structure, preferably made out of one piece,
provided with at least one nozzle. Said plate structure may have a length L
and a width W (see e.g. figure 4A) being larger, e.g. at least five or at least ten
times larger, than a maximum thickness of the plate structure. Said thickness
D may be measured in a direction perpendicular to directions in which said
length L respectively said width W of the plate structure are measured.
The apparatus 2 may be arranged for pressurizing the fluid in the
reservoir 6. Thereto the apparatus 2 may comprise pressurizing means such as
a pump 16 for pressurizing the fluid in the reservoir 6 and/or further pressure
varying means 50 for varying a pressure near the nozzles in the nozzle plate
for stimulating a controlled breakup of the ejected fluid jet. As a result of said
pressurizing, in use, the fluid may flow towards the nozzle plate 8. Thus, said
pressurizing may create a pressure difference over the at least one nozzle so
that the fluid flows out of the at least one nozzle and thus is sprayed out of the
at least one nozzle. Thereby, the fluid passes the outer main surface after
passing the inner main surface. Hence, the fluid may flow out of the reservoir
6. Thus, a jet and/or droplets 18 may be formed from a nozzle 14.
Once ejected from the nozzle 14, the droplets 18 may be at least
partially dried using a drying medium, such as air, to remove the liquid
solvent such as water or other dissolving medium. The drying medium may be
heated for accelerating an evaporation process of the liquid solvent. In this
way the droplets may become particles and/or a powder of a dried food product.
The drying medium may be provided e.g. by a drying means (not shown) such
as a gas supply, heater, and/or fan for causing and/or allowing the droplets 18
to dry to become particles of the dried food product. Alternatively, the drying
means may simply be provided by the air between the point of ejection from
the nozzle and a destination position e.g. on a transporter 20.
The pressurizing means may generally comprise a pump 16 and/or a
vibrating element 50 e.g. a piezo-electric element. By means of the pump 16, a
base pressure may be generated. By means of the piezo-electric element 50, a
variation on the base pressure may be generated. Such a variation may be
used for controlling droplet formation from the fluid that flows out of the
nozzle.
Advantageously, a cross-sectional area of the at least one nozzle in the
inner main surface exceeds a cross-sectional area of the at least one nozzle in
the outer main surface. Further details of embodiments and variations of the
at least one nozzle are described with reference to figures 2-4B.
Preferably, the pressurizing means are arranged for keeping a pressure
difference over the at least one nozzle at at most 15 bar, preferably at at most
12 bar. Said pressure difference may be equal to a pressure in the reservoir
adjacent to the at least one nozzle, e.g. in (a center of) the cross-sectional area
of the at least one nozzle in the inner main surface, minus a pressure in an
environment of the at least one nozzle, e.g. in (a center of) the cross-sectional
area of the at least one nozzle in the outer main surface.
In a variation of the first embodiment, an apparatus 2 according to the
invention may be provided with a transporter 20. The apparatus may further
be provided in assembly with a substrate 22. The transporter 20 may be
arranged for moving the substrate 20 with respect to the at least one nozzle,
and/or vice versa. Thereto the transporter may be provided with rollers 26.
Said movement of the substrate is indicated, as an example, with arrow 24. A
possible rotation direction of the rollers 26 is indicated with arrow 30. The
substrate may be positioned with respect to the at least one nozzle for
receiving the jet and/or droplets. After drying the droplets, dried food product
may be collected from the substrate 22. Thus, the food product may be
obtained in dried form, e.g. in the form of a powder.
In another embodiment, the transporter may cause a further drying of
the powder, e.g. when the droplets are only partially dried before landing on
the transporter. For example the transporter may be provided with a heating
means for further evaporating any remaining liquid in the droplets.
Alternatively the transporter may comprise air blowers that blow the semi-
dried droplets in the transport direction 24. In another example, the
transporter may be formed by an air cushion with an upward flow to lift the
particles and a sideways flow to move the particles in the transport direction
24. The air cushion may also be provided with heated air for further
stimulating an evaporation of the liquid.
Figure 2 schematically shows a cross section of a nozzle plate 8 provided
with at least one nozzle 14, in a second embodiment of an apparatus 2
according to the invention. Figure 2 also shows the reservoir 6. In a variation,
the detail I indicated in figure 1 may correspond to the part of the nozzle plate
8 shown in figure 2 (rotated). However, nozzles 14 in the first embodiment of
figure 1 may alternatively be shaped differently.
Figure 2 shows the cross-sectional area A of the at least one nozzle 14
in the inner main surface 10 (further also referred to as the first cross-
sectional area A ). Figure 2 also shows a cross-sectional area A of the at least
one nozzle 14 in the outer main surface 12 (further also referred to as the
second cross-sectional area A ). The first cross-sectional area A , of the at least
one nozzle in the inner main surface 10 exceeds the second cross-sectional area
A , of the at least one nozzle 14 in the outer main surface 12.
The at least one nozzle 14 may comprises a substantially non-widening
part 32. Said substantially non-widening part may be cylindrically shaped.
The substantially non-widening part may extend from the outer main surface
12, in a direction towards the inner main surface 10, without reaching the
inner main surface. The at least one nozzle further comprises a substantially
widening part 34. Said substantially widening part 34 may be frustoconically
shaped. The substantially widening part may extend from the substantially
non-widening part to the inner main surface 10. By said extending the
substantially widening part 34 may reach the inner may surface 10. In the
substantially non-widening part, in an embodiment, a shear rate of the fluid
10 -1
may, in use, be typically in a range from 5·10 to 5·10 s . Such shear rates
may be reached when the pressure difference over the at least one nozzle 14 is
kept at at most 12 bar.
In an embodiment, an angle a of the substantially widening part 34, e.g.
frustoconically shaped, may be in a range from 30 to 60 degrees, e.g.
approximately 45 degrees. Said angle a may be measured between a surface 35
of the substantially widening part 34, and an outflow direction 36 of the high-
viscosity fluid through said substantially non-widening part 32 or an axis of
symmetry 37 of the at least one nozzle.
In a typical embodiment, the nozzle geometry comprises a tapered
and/or cylindrical channel in a thin plate, e.g. created using laser cutting
technology in a 250 micrometer thick stainless steel plate. A cylindrical hole is
provided with a diameter of 50 micrometers and a length X = 80 micrometer.
This is connected upstream (i.e. on the side of the inner main surface 10) to a
tapered cone, i.e. frustoconical shape, with top angle of 90 degrees (i.e. α=45
degrees) and diameter of 480 micrometer. This results in a cylindrical part of
the channel with length of 50 micrometers and a conical part with length of
Y=200 micrometers. In a single thin plate many of these channels may be
placed in parallel, preferably more than 500. A typical cross-sectional area A
may e.g. be in the range 0.1 – 5 mm . while a typical cross-sectional area A
may be in the range 0.001 – 1 mm .
In an embodiment, the spray drying apparatus or method may comprise
a pressure varying means 50. Advantageously, the pressure varying means 50,
e.g. comprising a vibrating element, generates pressure waves or dynamic
pressure variations in the fluid. The pressure waves may propagate through
the nozzle and cause a controlled breakup of the fluid jet ejected from the
nozzle 14. This controlled breakup is in contrast to a chaotic breakup process
such as may be employed in an apparatus wherein droplet poly-dispersity is
not important such as a high pressure spray cleaning apparatus.
The pressure varying means 50 may be controlled by a controller (not
shown) arranged for controlling a frequency and/or amplitude of the pressure
varying means in such a way that a controlled Rayleigh breakup of the ejected
fluid jet occurs. A frequency may be chosen e.g. near a natural breakup
frequency of the ejected fluid jet into droplets. In such a way a substantially
mono-disperse jet of particles may be created, i.e. the size and/or volume of the
particles is distributed over a relatively narrow range. Because the pressure in
the fluid may be kept low, the pressure varying means 50 may positioned at a
further distance from the nozzle than in a corresponding high pressure fluid
where pressure variation may be more damped. The pressure varying means
50 may be positioned e.g. at a distance of r=2-1000 μm, e.g. around r=40 μm
from the nozzle. Typical actuating frequencies of the pressure varying means
may be in the range 500-200000 Hz, which frequency may correspond to a
droplet ejection frequency from the nozzle. The pressure variation may in the
range 1 – 15 bar.
In an embodiment, the apparatus is characterized in that the pressure
varying means comprises a movable pressure focusing member such as a
control pin, which control pin can be moved in a longitudinal direction
towards/away from the outflow opening of the nozzle 14, so that an end of the
control pin can be placed at a predetermined distance, for instance in the
distance interval of 2-1000 μm, from the outflow opening, for varying the
pressure adjacent the outflow opening. In an embodiment a pressure focussing
member is placed with an end at a predetermined distance, for instance in the
distance interval of 2-1000 μm, from the outflow opening and the pressure
focussing member and/or the nozzle plate are arranged for vibrating with
respect to each other for varying the pressure adjacent the outflow opening. In
use, the control pin vibrates with the desired actuating frequency for varying
the pressure adjacent the outflow opening such as to effectuate a controlled
Rayleigh breakup mechanism of the ejected fluid stream. The control pin is
situated, for instance, in the fluid reservoir, the longitudinal direction being
directed preferably substantially perpendicular to nozzle plate. The control of
the control pin in the distance interval is preferably carried out with a
relatively accurate pressure regulating mechanism, in view of the relatively
small distances and for creating a desired Rayleigh breakup of the fluid. The
precise frequency and distance interval in which the control pin is operatively
regulated may depend on the viscosity of the fluid. Preferably an end of the
control pin has a relatively small surface area of, for instance, 1-5 mm ,
preferably still larger than the surface area A . Accordingly, it is possible, with
a relatively small driving force of up to, for instance, 30-150 N on the control
pin, to effect a relatively large pressure variation of, for instance, 15 bar.
A suitable vibrating element 50 may comprise e.g. a piezo-electric, acoustic
and/or electromagnetic actuating means, for actuating a vibrating element 50
near the nozzle 14. Alternatively or in conjunction, e.g. the nozzle plate 10
itself may be actuated by a vibrating element such as a piezo element.
Alternatively or in conjunction, a back plate of the fluid reservoir in contact
with the fluid may be actuated. A vibration actuator such as a piezo element
may be limited to a specific operable range of pressures. In particular, this
pressure may not be too high. Advantageously, the current nozzle design may
allow for a lower pressure in the fluid reservoir thus providing a synergetic
combination e.g. with a piezo vibrating element.
In an embodiment, the nozzle plate 8 can be a plate manufactured from
thin metal foil, e.g. of a thickness of 0.25 mm. Advantageously, the nozzle plate
8 may further be provided with an optional supporting plate 51 which supports
the nozzle plate 8, so that it does not collapse under a high pressure in the
reservoir. The supporting plate 51 is provided with an opening 52 which is
situated opposite the outflow opening 14. The diameter of the opening 52 can
be e.g. an order of magnitude greater than the diameter of the outflow opening
14 so as not to disturb the out flowing fluid jet.
Figure 3 schematically shows a cross section of a nozzle plate 8 provided
with at least one nozzle 14, in a third embodiment of an apparatus 2 according
to the invention. Figure 3 shows the cross-sectional area A of the at least one
nozzle 14 in the inner main surface 10 (also referred to as the first cross-
sectional area A ). Figure 3 also shows a cross-sectional area A of the at least
one nozzle 14 in the outer main surface 12 (also referred to as the second cross-
sectional area A ). Figure 3 also shows part of the reservoir 6. It may be clear
that a channel provided in the apparatus adjacent to and in fluidum
connection with the at least one nozzle 14, may be regarded as forming at least
part of the reservoir 6.
The at least one nozzle 14 may be substantially trumpet-shaped, as
schematically indicated in figure 3. The at least one nozzle 14 may the
substantially non-widening part 32 and the substantially widening part 34.
The substantially non-widening part may be defined as a part of the at least
one nozzle 14 wherein a cross-section area of the at least one nozzle is at most
1.2 times a minimum cross-section area of said part of the at least nozzle 14.
Thus, in said substantially non-widening part, a maximum cross-sectional area
A may be approximately equal to 1.2 times a minimum cross-sectional
nw,max
area A , which in this case equals A Said minimum cross-section area
nw, min 2
A may e.g. be equal to the second cross-sectional area A .
nw, min 2
More in general, with respect to the nozzles 14 shown in figures 2 and 3,
and optionally with respect to other nozzles, at least the following six aspects
may be appreciated.
Firstly, an area ratio, being equal to the first cross-sectional area A of
the at least one nozzle in the inner main surface 10 divided by the second
cross-sectional area of the at least one nozzle A in the outer main surface 12,
is at least five, preferably at least ten, more preferably at least fifteen. As a
result, an effective decrease of the pressure difference over the substantially
widening part 34 may be obtained, in comparison to the pressure difference
over the substantially non-widening part 32. Additionally or alternatively, the
area ratio is at most fifty, preferably at most thirty, more preferably at most
twenty. Such maxima for the area ratio may enable positioning nozzles
relatively close together. Thus, a production rate may be increased.
Secondly, in an embodiment, a length X of the substantially non-
widening part 32 of the at least one nozzle 14, measured along an outflow
direction 36 of the high-viscosity fluid through said substantially non-widening
part, may be at least equal to a diameter of the at least one nozzle, preferably
at least three times the diameter of the at least one nozzle in the outer main
surface 12. E.g. in an embodiment wherein the nozzle has diameter of 40
micron, the length of the substantially non-widening part is at least 40
micrometer, preferably at least 120 micrometer. As a result, a relatively stable
jet and/or droplet formation may be obtained by the fluid flowing out of the at
least one nozzle 14. Alternatively or additionally, said length X may be at most
five times the nozzle diameter, preferably at most four times the nozzle
diameter... As a result, a pressure difference over the substantially non-
widening part 32 may be limited. Thus, said length X may be in a range from
40 micrometer to 120 micrometer, preferably in a range from 40 micrometer to
100 micrometer or from 60 micrometer to 120 micrometer, more preferably in a
range from 60 micrometer to 100 micrometer. Said length X may e.g. be
approximately 50 micrometer or approximately 80 micrometer.
Thirdly, in an embodiment, a length Y of the substantially widening
part 34 of the at least one nozzle 14, measured along the outflow direction 36
of the high-viscosity fluid through said substantially widening part, may be at
least 100 micrometer, preferably at least 150 micrometer. Alternatively or
additionally, said length Y may be at most 300 micrometer, preferably at most
250 micrometer. Said length Y may e.g. be approximately 200 micrometer.
Fourthly, a pressure difference ratio, being equal to a pressure
difference over the substantially widening part divided by a pressure
difference over the substantially non-widening part, is at most 1, preferably at
most 0.5, more preferably at most 0.3, e.g. at most 0.2. Such pressure ratio’s
may be achieved by adapting a shape of the at least one nozzle and the area
ratio. By choosing such pressure ratios, the thickness of the nozzle plate may
be increased without decreasing the production rate too much. The pressure
difference over the substantially non-widening part may be equal to a pressure
at a (center of) a transition plane 38 between the substantially widening part
and the substantially non-widening part, minus a pressure in an environment
40 of the at least one nozzle, e.g. in (a center of) the cross-sectional area of the
at least one nozzle 14 in the outer main surface. The pressure difference over
the substantially widening part may be equal to a pressure in the reservoir
adjacent to the at least one nozzle, e.g. in (a center of) the cross-sectional area
of the at least one nozzle 14 in the inner main surface, minus a pressure at (a
center of) the transition plane 38 between the substantially widening part and
the substantially non-widening part.
Fifthly, the at least one nozzle may widen gradually from the outer main
surface to the inner main surface. Thus, a cross-sectional area of the at least
one nozzle increases continually from the outer main surface towards the inner
main surface.
Sixthly, the at least one nozzle 14 may be suitable for creating a
substantially mono-disperse stream of droplets. This may be further aided e.g.
by a vibrating element 50 such as discussed with Figure 2. In such a
substantially mono-disperse stream, generated droplets formed from the fluid
that in use flows out of the at least one nozzle (i.e. is sprayed out of the at least
one nozzle), have a size that is within 0.01 to 10 percent, preferably within 1
percent of a mean droplet volume of said generated droplets. Thus, an
advantage over conventional spray nozzles may be reached. Using such
conventional spray nozzles usually results in a poly-disperse spray of droplets.
Is will be appreciated that, as a result of at least one nozzle shaped according
to the invention, a substantially mono-disperse stream of droplets may be
generated while the pressure difference over the at least one nozzle is kept at
at most 12 bar. Generating a substantially mono-disperse stream of droplets
usually costs less energy than generating a poly-disperse stream of droplets.
In general, a method of manufacturing the at least one nozzle in the
nozzle plate may e.g. comprise laser cutting. By means of laser cutting, the at
least one nozzle may be cut in the nozzle plate. A thickness (see figures 2 and
3) of the nozzle plate 8 D of the nozzle plate may e.g. be in a range from 200
micrometer to 300 micrometer, typically approximately 250 micrometer. Said
nozzle plate may be substantially made of steel. For example, a method for
producing the desired nozzle shape may involve the use electro sparking. An
advantage of this method is that a nozzle shape may be precisely determined.
Other materials besides steel may be copper, titanium, and molybdenum. An
alternative method may employ etching techniques, e.g. in silicon.
Alternatively still, laser light may be used to cut the nozzles either in metal or
in a ceramic material, e.g. through laser ablation. Advantages of ceramic
materials may be a longer lifetime and/or durability of the nozzles compared to
metal.
Figure 4A schematically shows a front view of a nozzle plate 8 provided
with a plurality of nozzles 14, in a fourth embodiment of an apparatus 2
according to the invention.
Figure 4B schematically shows a front view of a nozzle plate 8 provided
with a plurality of nozzles 14, in a fifth embodiment of an apparatus 2
according to the invention.
In the nozzle plates of figures 4A and 4B, a width W, a length L, and the
thickness D (see figures 2 and 3) of the nozzle plate 8, a composition of the
nozzle plate, as well as a size, a number, and a distribution of nozzles in the
nozzle plate, may be arranged for withstanding a pressure difference over the
at least one nozzle of at least 12 bar, preferably at least 15 bar.
In an example, the width W of the nozzle plate is in a range from 5 to 25
mm and/or the length L of the nozzle plate is in a range from 5 to 250 mm. The
nozzle plate 8 may have a substantially rectangular shape. However, other
shapes are also possible. The thickness D of the nozzle plate may be in a range
from 150 micrometer to 400 micrometer. The number of the nozzles in the
nozzle plate may be larger than or equal to 500. A density of the nozzle in the
nozzle plate may be such that a center to center distance of the nozzles is
preferably higher than twice the nozzle diameter, preferably higher than three
times the nozzle diameter. As a result, the jets ejected from the nozzles may be
far enough apart not to interfere with each other. The nozzle plate may, e.g.,
be substantially made of steel or silicon. A size, for example a diameter Z, of
the nozzles 14 may be in range from 10 micrometer to 200 micrometer,
typically approximately 80 micrometer.
In an embodiment, the distribution of the nozzles in the nozzle plate
may be uniform, i.e. the nozzle may be uniformly distributed over the nozzle
plate. Such a uniform distribution is shown in figure 4A. Alternatively, the
distribution of the nozzles in the nozzle plate may be non-uniform. E.g., a
central region R of the nozzle plate comprising least three nozzles and having
a minimal boundary B , may be larger than a surrounding area R that
comprises the same numbers of nozzles as the central area R and has a
minimal boundary B . Thus, in a central region of the nozzle plate a density of
the nozzles may be lower than in a surrounding region of the nozzle plate. Said
surrounding region of the nozzle plate may be closer to an edge 44 of the nozzle
plate 8 than a central region of the nozzle plate 8. It may be appreciated when
the nozzle density in the central region is relatively low, as in this region a
load on the nozzle plate may be relatively high. Thus, an optimum between
productivity, e.g. number of nozzles in the nozzle plate or average nozzle
density over the whole nozzle plate, and strength of the nozzle plate may be
achieved.
An apparatus according to the invention, e.g. an apparatus in one of the
embodiments and variations described above, may be used in a first
embodiment of a method of spray-drying a high-viscosity fluid that comprises a
food product, according to the invention (the first method). The first method
may comprise providing a nozzle plate 8 wherein at least one nozzle 14 is
provided, said nozzle plate having an inner main surface 10 and an outer main
surface 12. The least one nozzle 14 may extend through the nozzle plate 8 from
the inner main surface 10 to the outer main surface 12. The first method may
further comprise providing the high-viscosity fluid in a reservoir 6 that is in
fluidum connection with the at least one nozzle 14.
The first method may comprise pressurizing the high-viscosity fluid in
the reservoir 6, e.g. by means of a pump. In an advantageous variation of the
first method, during pressurizing, the pressure difference over the at least one
nozzle is kept at at most 15 bar, preferably at at most 12 bar. As a result of
said pressurizing, the fluid flows towards the nozzle plate, thus creating a
pressure difference over the at least one nozzle so that the fluid flows out of
the at least one nozzle. By such flow out of the at least one nozzle, the fluid
passes the outer main surface after passing the inner main surface.
A cross-sectional area of the at least one nozzle in the inner main
surface exceeds a cross-sectional area of the at least one nozzle in the outer
main surface. Such is e.g. described with reference with figures 2 and 3.
The first method may further comprise drying the fluid after it has
passed the outer main surface. Thereto air may be guided towards a substrate
on which the fluid may be sprayed. Additionally, the first method may
comprise collecting the dried food product. Such may be achieved e.g. by
scraping and/or blowing the dried food product from the substrate. Thus, the
food product may be obtained in the form of a powder. Thus, a food product
according to the invention may be obtained.
Figure 5A shows a side view of an embodiment of a pressure varying
means 50 that is arranged as a single (pressure) focusing member to
pressurize a plurality of nozzles 14. Alternatively, the pressure varying means
50 may be arranged such that such as indicated in Figure 1, wherein each
focusing member is arranged to pressurize a single nozzle.
Figure 5B shows a top view along the view direction V-V indicated in
Figure 5A. In the top view it is illustrated how the fluid to be sprayed through
the nozzle 14 may be brought to a side of the nozzles 14 via a flow 55 that is
provided in between the (elongated) pressure varying means 50 that
pressurizes a row of nozzles 14. In an embodiment the pressure varying means
are preferably wider on the ends to provide a more even flow to the nozzles 14.
Figure 6A shows a side view of an embodiment of the nozzle 14 in a
nozzle plate 8 wherein a cross-sectional area of the nozzle 14 in the inner main
surface 10 of the nozzle plate 8 exceeds a cross-sectional area of the nozzle in
the outer main surface 12 of the nozzle plate 8. The nozzle comprises a
substantially widening part 34 and a substantially non-widening part 32.
Figure 6B illustrates a top view of Figure 6A along a viewing direction
VI-VI. As is shown in this top view, the substantially widening part 34 in this
embodiment of the nozzle is shaped like a cut-off four sided pyramid. An
advantage for a pyramid shape with straight instead of round edges may be
that it could be more easily manufacturable e.g. using etching techniques.
Alternative to the shown four-sided pyramid, e.g. other pyramids or shapes
may be possible, e.g. three sided pyramids, cone-shaped figures or
combinations thereof.
Figure 7A shows a side view of another embodiment of the nozzle 14 in a
nozzle plate 8. Figure 7B illustrates a top view of Figure 7A along a viewing
direction VII-VII. As is shown in these figures 7A and 7B, the nozzle 14 of this
embodiment comprises two substantially non-widening parts 32a and 32b,
wherein the part 32a that is on an inner main surface 10 of the nozzle plate 8
has a larger diameter than the part 32b that is on an outer part of the nozzle
plate 8. An advantage of the current embodiment of the nozzle 14 may be that
it is more easily manufacturable than a nozzle with sloped sides. However, an
advantage of a sloped side, e.g. in a widening part such as shown in Figure 6A
may be an advantageous pressure or force distribution across the nozzle 14
and or nozzle plate 8. Alternative to having two parts 32a and 32b, the nozzle
14 may comprise additional parts with intermediate diameters between those
of 32a and 32b, e.g. the nozzle may comprise three steps of non-widening parts
with different diameter. An advantage may be an improved tunability of the
pressure drop across the nozzle 14 versus a strength of the nozzle plate 8 to
withstand pressure differences. Alternatively, a combination of several
widening and/or non-widening parts with different diameters and/or slopes
may be possible.
Without being bound by theory, a technical effect of the present nozzle
design may be understood as follows. The flow rate through a nozzle of a fluid
of certain viscosity for a given pressure differential over the nozzle is related to
a flow resistance of the nozzle which in turn correlates with the length and
cross-section of the nozzle. In general, a long and/or narrow nozzle may have a
higher flow resistance than a short and/or wide nozzle. To achieve a higher
flow rate at the same pressure differential or the same flow rate at a lower
pressure differential, the nozzle may thus be shortened and/or widened.
However, a shorter nozzle generally corresponds to a thinner nozzle plate,
meaning that the plate can handle lower pressures which may in turn
correspond to a lower flow rate. On the other hand a wider nozzle may result
in undesired characteristics with respect to the jet flowing from the wider
nozzle, e.g. a larger particle size.
In an aspect of the present nozzle design, the above identified problem is
remedied at least partially by maintaining an output cross-section of the
nozzle for maintaining a desired jet characteristic and widening the input
cross-section thereby decreasing an overall flow resistance of the nozzle
compared to a straight nozzle having equal input and output cross-sections.
This in turn may result in increasing a flow rate of fluid through the nozzle for
a given pressure differential and viscosity; and/or lowering a required pressure
differential for a given viscosity and desired flow rate of the fluid; and/or an
ability to spray-dry higher viscosity fluids for a given flow rate and pressure
differential. Other effects may include a stronger nozzle plate compared to a
(thinner) nozzle plate having straight nozzles of equal flow resistance.
It is thus to be appreciated that, for a given cross-sectional area of the at
least one nozzle in the outer main surface, the exceeding cross-sectional area of
the at least one nozzle in the inner main surface positively correlates with a
flow rate through the at least one nozzle and/or negatively correlates to a
required pressure differential over the at least one nozzle and/or positively
correlates with a viscosity of a fluid that can be spray dried through the at
least one nozzle. In other words, when the cross-sectional area of the inner
main surface is increased with respect to the cross-sectional area of the outer
main surface, the flow rate through the nozzle may increase and/or the
required pressure differential over the nozzle may decrease and/or the
viscosity of the fluid that can be spray dried may increase compared to a
straight nozzle, i.e. a nozzle having the same cross-sectional area at the inner
and outer main surface. Increasing the flow rate may yield an increased
production rate of the material to be spray dried. The production rate may also
be increased by increasing a density of the material to be spray dried in the
fluid, which may correspond to an increased viscosity of the fluid.
The various elements of the embodiments as discussed and shown offer
certain advantages e.g. for spray drying food products. Of course, it is to be
appreciated that any one of the above embodiments or processes may be
combined with one or more other embodiments or processes to provide even
further improvements in finding and matching designs and advantages.
Embodiments of the invention are not limited to the foregoing description and
drawings. For example, suitable products that may be spray dried with the
currently proposed nozzle include high viscosity fluids e.g. comprising food
products, pharmaceutical products, fertilizer/manure products, etc.
Furthermore, the teachings of the invention may find further application in
other high-viscosity fluid spraying applications.
The description of the exemplary embodiments is intended to be read in
connection with the accompanying drawings, which are to be considered part
of the entire written description. In the description, relative terms as well as
derivative thereof should be construed to refer to the orientation as then
described or as shown in the drawing under discussion. These relative terms
are for convenience of description and do not require that the apparatus be
constructed or operated in a particular orientation unless expressly indicated
or obvious from general considerations. Terms concerning attachments,
coupling and the like, such as "connected" and "interconnected," refer to a
relationship wherein structures are secured or attached to one another either
directly or indirectly through intervening structures, as well as both movable
or rigid attachments or relationships, unless expressly described otherwise. It
is noted that also any kinematic inversions having similar functionality as
described in the embodiments are considered as part of the disclosure.
The use of expressions like: "preferably", “in particular”, “especially”,
“typically” etc. may relate to optional features. The term “comprising” does not
exclude other elements or steps. The indefinite article “a” or “an” does not
exclude a plurality. Features which are not specifically or explicitly described
or claimed may be additionally comprised in the structure according to the
present invention without deviating from its scope. Any of the disclosed
devices or portions thereof may be combined together or separated into further
portions unless specifically stated otherwise. Several "means" may be
represented by the same or different item(s) or implemented structure or
function. No specific sequence of acts or steps is intended to be required unless
specifically indicated; and no specific ordering of elements is intended to be
required unless specifically indicated.
Claims (21)
1. Method of spray-drying a high-viscosity fluid using a spraying device, the method comprising: - providing a nozzle plate wherein at least one nozzle is provided, said nozzle plate having an inner main surface and an outer main surface, the at least one nozzle extending through the nozzle plate from the inner main surface to the outer main surface; - providing the high-viscosity fluid in a reservoir that is in fluidum connection with the at least one nozzle; - pressurizing the high-viscosity fluid in the reservoir, wherein the fluid flows, as a result of said pressurizing, towards the nozzle plate, thus creating a pressure difference over the at least one nozzle so that the fluid flows out of the at least one nozzle, thereby passing the outer main surface after passing the inner main surface; wherein the fluid flowing out of the nozzle forms a jet that breaks up into droplets; and - at least partially drying the droplets in a drying medium, such as air, to become particles; - wherein a cross-sectional area of the at least one nozzle in the inner main surface exceeds a cross-sectional area of the at least one nozzle in the outer main surface thereby decreasing a pressure difference over the at least one nozzle needed for spraying the high-viscosity fluid.
2. Method according to claim 1, wherein an area ratio, being equal to the cross-sectional area of the at least one nozzle in the inner main surface divided by the cross-sectional area of the at least one nozzle in the outer main surface, is at least five and is at most fifty.
3. Method according to claim 1 or 2, wherein the at least one nozzle comprises a substantially non-widening part that extends from the outer main surface, and comprises a substantially widening part that extends from the substantially non-widening part to the inner main surface.
4. Method according to claim 3, wherein the substantially non-widening part is cylindrical.
5. Method according to claim 3 or 4, wherein the substantially widening part is frustoconical.
6. Method according to one of claims 3-5, wherein a pressure difference ratio, being equal to a pressure difference over the substantially widening part divided by a pressure difference over the substantially non-widening part, is at most 1.
7. Method according to claim 6, wherein the pressure difference ratio is at most 0.5.
8. Method according to claim 7, wherein the pressure difference ratio is at most 0.3.
9. Method according to claim 8, wherein the pressure difference ratio is at most 0.2.
10. Method according to one of claims 1-9, wherein, during pressurizing, the pressure difference over the at least one nozzle is kept at at most 15 bar.
11. Method according to claim 10, wherein, during pressurizing, the pressure difference over the at least one nozzle is kept at at most 12 bar.
12. Method according to one of claims 1-11, further comprising the step of generating dynamic pressure variations in the fluid near the nozzle that propagate through the nozzle and cause a controlled breakup of the fluid jet flowing out of the nozzle, the broken up fluid jet forming substantially mono- disperse droplets.
13. Apparatus for spray-drying of a high-viscosity fluid, the apparatus comprising: - a reservoir for containing the high-viscosity fluid; - a nozzle plate that is in fluidum connection with the reservoir, has an inner main surface and an outer main surface, and is provided with at least one nozzle extending through the nozzle plate from the inner main surface to the outer main surface; and - drying means; - the apparatus being arranged for pressurizing the fluid in the reservoir so that, in use, the fluid flows towards the nozzle plate, thus creating a pressure difference over the at least one nozzle so that the fluid flows out of the at least one nozzle, thereby passing the outer main surface after passing the inner main surface; wherein the fluid flowing out of the nozzle forms a jet that breaks up into droplets; wherein the drying means is arranged for causing and/or allowing the droplets to dry to become particles - wherein a cross-sectional area of the at least one nozzle in the inner main surface exceeds a cross-sectional area of the at least one nozzle in the outer main surface thereby decreasing a pressure difference over the at least one nozzle needed for spraying the high-viscosity fluid.
14. Apparatus according to claim 13, wherein an area ratio, being equal to the cross-sectional area of the at least one nozzle in the inner main surface divided by the cross-sectional area of the at least one nozzle in the outer main surface, is at least five and is at most fifty.
15. Apparatus according to claim 14, wherein the at least one nozzle comprises a substantially non-widening part that extends from the outer main surface, and comprises a substantially widening, part that extends from the substantially non-widening part to the inner main surface.
16. Apparatus according to claim 15, wherein the substantially non- widening part is cylindrical.
17. Method according to claim 15 or 16, wherein the substantially widening part is frustoconical.
18. Apparatus according to one of claims 15-17, wherein a length of the substantially non-widening part of the at least one nozzle, measured along an outflow direction of the high-viscosity fluid through said non-widening part, is at least equal to three times a diameter of the at least one nozzle in the outer main surface.
19. Apparatus according to one of claims 13-18, comprising pressurizing means for pressurizing the fluid in the reservoir so that the fluid flows towards the nozzle plate and out of the at least one nozzle, thereby passing the outer main surface after passing the inner main surface.
20. Apparatus according to claim 19, wherein the pressurizing means are arranged for keeping a pressure difference over the at least one nozzle at at most 15 bar.
21. Apparatus according to claim 20, wherein the pressurizing means are arranged for keeping a pressure difference over the at least one nozzle at at most 12 bar.
Applications Claiming Priority (3)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| EP11177656.3 | 2011-08-16 | ||
| EP11177656A EP2559480A1 (en) | 2011-08-16 | 2011-08-16 | Method of spray-drying and apparatus for spray-drying. |
| PCT/NL2012/050568 WO2013025102A1 (en) | 2011-08-16 | 2012-08-15 | Method of spray-drying and apparatus for spray-drying |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| NZ621748A NZ621748A (en) | 2016-02-26 |
| NZ621748B2 true NZ621748B2 (en) | 2016-05-27 |
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