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Description  |
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An emulsion is defined as a continuous liquid phase in which a second phase
is dispersed. When one liquid phase is introduced with agitation into
another liquid phase with which it is immiscible, the introduced liquid
phase will disperse into discrete droplets. If the two liquid phases are
pure, the droplets will begin to coalesce when agitation is stopped and
two discrete layers will form. If, however, appropriate surface active
materials, generally referred to as emulsifiers, are present in the
system, coalescence will be prevented such that when agitation is stopped
a layer of droplets of the dispersed phase will form. If the droplets of
the dispersed phase, or internal phase, are small enough so that thermal
and Brownian forces overcome the settling effect of the gravity field,
then a stable emulsion results.
Emulsions comprising greater than about 75% by volume internal phase
(dispersed phase) are referred to as high-internal-phase-ratio emulsions
(HIPREs). The droplets present in HIPREs are deformed from the usual
spherical shape into polyhedral shapes and are locked in place. Thus,
HIPREs are sometimes referred to as "structured" systems and display
unusual rheological properties which are generally attributed to the
existence of the polyhedral droplets. For example, when HIPREs are
subjected to sufficiently low levels of shear stress, they behave like
elastic solids. As the level of shear stress is increased, a point is
reached where the polyhedral droplets begin to slide past one another
whereby the HIPRE begins to flow. This point is referred to as the yield
value. When such emulsions are subjected to increasingly-higher shear
stress, they exhibit non-Newtonian behavior, and the effective viscosity
decreases rapidly.
When the shear rate ranges between 3000-8000 sec.sup.-1, the effective
viscosity of the emulsion decreases and at increasingly higher rates of
shear, a point is reached where the emulsifying agents can no longer
maintain stable films. At this point the emulsion breaks and cannot be
reconstituted readily. The yield value and shear stability point, as well
as the shape of the viscosity versus shear rate curve, will vary with each
particular emulsion formulation.
Certain other emulsions behave in much the same manner as HIPREs. These
emulsions can be referred to as variable-phase-ratio emulsions and contain
an internal phase material, an external phase material and a modifying
component which is a solid below a certain transition temperature and a
liquid which is miscible with the external phase material above the
transition temperature. When these emulsions are made at a temperature
where the modifying component is a solid, the solid behaves as though it
were part of the internal phase for geometric considerations. If the total
volume ratio of the internal phase material and the solid are above about
75%, the emulsion then exhibits properties of a HIPRE. However, if the
emulsion is heated to a temperature above the transition temperature of
the modifying component or solid, the solid becomes a liquid and blends
with the external phase material whereby the internal to external phase
ratio falls below the HIPRE range of about 75% by volume. Where the
external and internal phase materials have viscosities which are
relatively similar, the emulsion will then be less viscous than a HIPRE
consisting of the same two phase materials. However, where the viscosities
of the two phases are highly disparate, the emulsion will continue to
behave similarly to a HIPRE even though the emulsion has less than about
75% by volume of internal phase material. Such HIPRE-like emulsions
typically contain from about 65% to about 75% (by volume) of internal
phase material. Thus, where the emulsion includes a modifying component
and internal and external phase materials having similar viscosities, such
emulsions will behave as a medium-internal-phase ratio emulsion at
temperatures above the transition temperature of the modifying component,
and will behave similarly to HIPREs where the modifying component remains
a solid. On the other hand, where the viscosities of the external and
internal phase materials are highly disparate, the emulsion will behave
similarly to a HIPRE regardless of whether the modifying component is in a
liquid or a solid state. In both cases, the emulsions having modifying
components which are in a solid state can technically be considered
HIPREs.
The "structured" nature of HIPREs and HIPRE-like emulsions, in addition to
providing an explanation for the unusual rheological properties displayed
thereby, also provides an explanation for the fact that special mixing
methods are required in order to prepare such emulsions.
If an attempt is made to mix two liquid phases of highly disparate
viscosity, one finds that the mixing process is difficult and inefficient.
When a small amount of low-viscosity liquid is added to a mass of
high-viscosity liquid, it is difficult to incorporate homogeneously with
conventional mixing means. Without appropriate mixing,a s more of the
low-viscosity liquid is added, the highly viscous phase tends to break up
and form a coarse dispersion in the thinner liquid. It is this fact which
makes the preparation of HIPREs and HIPRE-like emulsions difficult and
which has prevented development of successful continuous emulsification
processes for materials of this type. With the correct type and degree of
mixing, however, the low-viscosity liquid can be adequately dispersed
within the high-viscosity liquid as it is added to form a stable emulsion.
One attempt at developing a continuous process for the production of HIPREs
is disclosed in U.S. Pat. No. 3,565,817 and is directed at achieving
sufficient mixing by providing shear rates high enough to reduce the
effective viscosity of the emulsified mass near to the viscosities of the
less viscous external and internal phases. Another attempt is disclosed in
U.S. Pat. No. 4,018,426 which is also directed at achieving sufficient
mixing by providing shear rates high enough to reduce the effective
viscosity of the emulsified mass near to the viscosities of the less
viscous external and internal phases.
However, for certain types of emulsions, it is not possible to apply enough
shear thereto to effect an apparent viscosity near the viscosities of the
external and internal phases without going above the shear stability point
of the emulsion. Emulsions wherein the viscosities of the external and
internal phases are highly disparate, such as, for example, certain
low-fat spread emulsions, are examples of such emulsions.
Furthermore, although a variety of systems are capable of producing shear
rates sufficient to reduce the effective viscosity of the emulsion phase
to near the external and internal phase viscosities thereby allowing the
phases to be mixed to a certain degree, such systems do not provide
complete mixing of the phases as evidenced by the fact that there is
always some non-emulsified liquid present in the prepared emulsion.
It has now been discovered that complete mixing can be effected without
applying sufficient shear to reduce the effective viscosity of the
emulsified mass to near the viscosities of the external and internal
phases. Furthermore, it has now been discovered that by providing complete
mixing, the presence of non-emulsified liquid in the prepared emulsion is
significantly reduced or eliminated whereby improvements in the quality of
emulsions, in terms of texture, is achieved. This is important in the
cosmetics and food industries, as well as others, where produce appearance
is a major marketing factor.
1. Field of the Invention
Accordingly, the present invention relates to a system for producing HIPREs
and HIPRE-like emulsions on a continuous basis. More particularly, the
present invention relates to a system for producing HIPREs and HIPRE-like
products wherein the viscosities of the internal and external phases are
highly disparate.
According to the present invention, complete mixing of the internal and
external phases, particularly where the viscosities of the two phases are
highly disparate, to prepare a HIPRE or a HIPRE-like emulsion is
accomplished by providing a continuous process wherein the internal and
external phases are introduced into a recirculation line and wherein
continuous direct recycling of a portion of the prepared emulsion is
achieved. The internal and external phases are fed into an inlet pipe by
high-pressure metering pumps. The mixture of phases is propelled to a
recirculation loop where a variable-speed pump forces it through a
shearing device. A major portion of the resulting emulsion is drawn back
into the pump for additional passes through the shearing device and the
remaining portion is continuously propelled out of the loop. In this
manner preformed emulsion having the desired ratio of internal to external
phase materials is continuously circulated throughout the loop. The
external phase material is dissolved in the external phase of the
recirculated emulsion and the internal phase is dispersed thereinto in the
form of small droplets when the combination of materials passes through
the shearing device.
2. Prior Art
Lage U.S. Pat. No. 3,661,634 discloses a mixing system for easily mixed
materials which includes means for recirculating product and means for
introducing materials into the low pressure side of a circulating pump.
Amer U.S. Pat. No. 4,307,125 discloses a process wherein products from
mixing tanks are in part recycled to the tanks and some of the feed
materials are introduced into the low pressure side of the recycling
lines.
Melnick U.S. Pat. No. 2,973,269, Josefowicz et al U.S. Pat. No. 3,457,086,
Elwood et al U.S. Pat. No. 3,217,632, Galusky U.S. Pat. No. 3,993,580,
Spitzer et al U.S. Pat. No. 3,360,377 and Patil U.S. Pat. No. 4,229,501
disclose systems wherein a portion of a product is recirculated.
U.S. Pat. No. 3,565,817 discloses a process for the continuous preparation
of high-internal-phase-ratio emulsions. U.S. Pat. No. 4,018,426 discloses
a process wherein internal and external phase materials are introduced
into a preformed emulsion while maintaining sufficient shear on the
preformed emulsion to reduce the effective viscosity thereof to near that
of the external phase material. U.S. Pat. No. 4,443,487 discloses a
process for producing variable-phase-ratio emulsions.
SUMMARY OF THE INVENTION
This invention provides a novel system for preparing HIPREs and HIPRE-like
emulsions wherein the internal and external phase materials have highly
disparate viscosities. The subject system comprises introducing an
internal and an external phase material into either the high or low
pressure region of a recirculation loop. Such phase materials are then
introduced into a mixing zone and caused to pass therethrough at a flow
rate sufficient to cause a pressure drop of sufficient magnitude to
thereby emulsify said phase materials. A portion of such emulsion is
caused to pass out of the system while the remaining portion there of is
recycled whereby continuous direct recycling of prepared emulsion is
achieved.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic diagram of a system in accordance with the present
invention.
FIG. 2 is a schematic diagram of apparatus arranged in accordance with the
present invention.
DESCRIPTION OF A PREFERRED EMBODIMENT
Referring to the drawings wherein like numerals designate like parts, there
is illustrated in FIG. 1 a flow diagram wherein an internal phase material
is introduced into a flow line 10 by way of a first pumping means 12 which
is preferably a positive displacement metering pump. Similarly, the
external phase material is introduced into a the flow line 10, downstream
from the point at which the internal phase material is introduced
thereinto, by way of a second pumping means 14 which is also preferably a
positive displacement metering pump.
Introduction of the external phase material can be downstream, upstream or
at the same point in the flow line 10 where the internal phase material is
introduced thereinto so long as continuous flow therethrough is achieved.
The external phase material is shown in FIG. 1 for illustrative purposes
only as being introduced into the flow line 10 downstream of the point
where the internal phase material is introduced. Alternatively, the
external and internal phase materials may be directly introduced into a
recirculation loop 16 as hereinafter described.
The phase materials, as combined in the flow line, are propelled to the
recirculation loop 16 where recirculating means 18, which is preferably a
variable flow rate pump, forces such combination through a shearing device
20. Alternatively, the phase materials may be combined in the loop 16 and
forced through the shearing device 20 by the recirculating means 18.
The recirculation loop 16 is adapted to provide for partial recirculation
of processed phase materials as they exit the shearing device 20 whereby
the recirculating means 18 draws a major portion of the processed
materials through the loop 16 for additional passes through the system.
The remaining portion of the processed phase materials is continuously
propelled from the loop 16 as emulsion product.
Referring to FIG. 2, there is shown preferred apparatus for use in the
system of the present invention wherein an external phase pumping means 22
draws an external phase material from an external phase material tank 24.
A heating device 26, such as, for example, a heating mantle, can be
utilized to apply heat to the external phase material, or to the internal
phase material, as required. Similarly, an internal phase pumping means 28
draws an internal phase material from an internal phase material tank 30.
Pumping means 22 and 28 may be the same or different. Suitable pumping
means include positive displacement metering pumps which are adapted to
provide variable flow rates. Such pumping means are typically
reciprocating piston pumps with pulse dampeners. Suitable pumping means
are commercially available from Bran & Lubbe, Inc.
For the application shown in FIG. 2, the unemulsified phases are pumped
into the low pressure side of a recirculation loop 40. The outlet portion
30 of the pumping means 22 is routed to the inlet portion 32 of the
pumping means 28, and the pumping means 28 is calibrated to deliver both
phase materials to a flow line 34. Valve member 38 is closed during system
start up and is open during normal operation. This arrangement may be
modified by pumping the phases into a recirculation loop 40 separately, or
by pumping the phases into the high pressure portion of the recirculation
loop 40, provided that the pumping means 22 and 28 are capable of
developing pressures exceeding the pressure existing in the recirculation
loop 40.
The combined phase materials are then propelled into a recirculation loop
40 wherein a pumping means 42 serves as recirculating means and forces
such combination into and through a shearing device 44 which is adapted to
emulsify the combined phase materials without excessively heating the
emulsion prepared thereby and without applying shear rates thereto which
break the emulsion once it is formed. Pressure gauge 36 is used to
calibrate the flow rate of the recirculating means 42.
A preferred shearing device is a static low to medium shear mixer of
sanitary design. Such devices are available commercially such as, for
example, the HYDROSHEAR devices available from Gaulin Corporation and the
Ross Mixer Emulsifiers available from Charles Ross and Son Company.
The recirculation loop 40 is provided with a "T" to thereby provide means
adapted to allow a portion of the emulsion which exits from the shearing
device 44 to be drawn back into the pumping means 42 for additional passes
through the recirculation loop 40. Since the loop 40 is completely filled
with fluid at all times, the production rate will be equal to the flow
rates of the internal and external phases.
The pumping means 42 is preferably a variable flow rate pump which is
adapted to deliver variable flow rates and has at least 300 psi
capability. Such pumps are typically non-centrifugal and are commercially
available such as the VIKING.RTM. rotary pumps available from Houdaille
Industries and the MOYNO.TM. progressive cavity pumps available from
Robbins and Myers.
The pumping means 42 draws a major portion of the emulsion exiting from the
shearing device 44 back into the recirculation loop 40 by way of the "T"
and back into and through the pumping means 42 to thereby cause such
emulsion to again pass through the shearing device 44. The remaining
portion of such emulsion is continuously propelled from the system as
emulsion product.
Temperature probes 46 are also provided to aid in monitoring the
temperature of the phase materials and of the emulsion, if desired. Means
for controlling the temperature of the phase materials and/or the emulsion
product can include heating mantels and heating or cooling jackets. Other
means are also available and are well known in the art.
The following examples are for illustrative purposes only and illustrate
the best mode for preparing HIPREs and HIPRE-like products utilizing the
system of the present invention.
EXAMPLES
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% (by weight)
______________________________________
External Phase:
Hydrogentated corn stick oil
67.6
Liquid corn oil 29.2
Santone 10-10-0 (decaglycerol decaoleate)
1.7
Emphos D-70-30-C (monosodium phosphate
0.8
derivative of mono and diglycerides)
color and flavor 0.7
Internal Phase:
Water 97.9
NaCl 2.0
Sodium Benzoate 0.1
Citric Acid to pH 4.2
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The start-up procedure utilized consisted of filling the recirculation loop
40 with external phase material while the recirculating pump 42 ran
slowly. The recirculating pump 42 was then brought to full speed and the
external phase material and the internal phase material were introduced
into the flowline at the appropriate rates for producing a final emulsion
having a composition of about 73% (by volume) internal phase material and
about 27% (by volume) external phase material. A period of about three
minutes was required to get within about 10% of the target phase ratio.
The ratio of the recirculation flow rate to product flow rate was about 5.
The emulsion product produced is technically a HIPRE due to the
solidification (crystallization) of the corn oil materials at room
temperature. The emulsion being produced within the system at temperatures
above room temperature is a HIPRE-like emulsion due to (1) the fact that
the modifying component is dissolved in the external phase; and (2) the
viscosity of the external oil phase is drastically different than the
viscosity of the internal water phase. It is contemplated that other
HIPREs and HIPRE-like emulsions can also be produced utilizing the system
of the present invention. It should be recognized, however, that
crystallization does not occur in all emulsion systems utilizing corn oil,
but this occurrence is easily determined by one skilled in the art.
Best results are achieved when the combination of phase materials is forced
through the shearing device 44 (along with recycled prepared emulsion) at
a flow rate which results in a pressure drop of about 120 psi. It has been
found for this particular emulsion system that flow rates which result in
pressure drops of less than about 80 psi are not suitable for adequately
mixing the phase materials. Furthermore, where the flow rates result in
pressure drops of greater than about 130 psi, the shear stability point of
this particular emulsion system was exceeded. Determining suitable
parameters for other emulsion systems and other types of shearing devices
is well within the skill of one in the art.
TABLE 1
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Pressure
Exam-
Ext. Phase
Int. Phase
Product
Drop Across
ple
Temp. Temp. Temp.
Hydroshear
Flowrate
# (.degree.C.)
(.degree.C.)
(.degree.C.)
(psi) (ml/min)
Quality*
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1 26.6 21.0 27.0 60 218 2 D 4
2 26.5 21.0 27.8 80 218 2 D 4
3 26.5 21.0 26.3 100 218 2 D 4
4 26.5 21.0 25.8 120 218 2 D 4
5 29.3 21.0 26.6 60 340 2 B 2
6 28.9 21.0 25.8 80 340 2 B 2
7 27.2 21.0 26.0 100 340 2 A/B 1/2
8 30.4 21.0 24.7 60 420 3 B/C 2/3
9 30.2 21.0 25.3 80 420 3 B 2
10 28.5 21.0 25.2 100 420 2 B 2
11 29.6 21.0 25.9 120 420 2 A/B 1/2
12 30.2 21.0 24.5 80 593 3/4 C 3
13 30.0 21.0 24.9 100 593 3 B 2/3
14 29.1 21.0 25.1 120 593 2 B 2
15 32.0 21.0 inverted
100 700 inverted
16 32.5 21.0 25.3 120 700 4 C 3/4
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*Quality Evaluation Firmness/Texture/Water Release
Product was judged subjectively on three criteria--firmness, texture, and
water release--which are coded as follows:
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Best Worst
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Firmness 1 (soft) to 4 (hard)
Texture A (smooth)
to D (coarse)
Water release
1 (none) to 4 (max)
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These examples illustrate that different qualities of emulsion product may
be obtained by varying phase temperatures, pressure drop (across the
Hydroshear) and flow rate. These examples also illustrate that emulsions
comprising very little or no non-emulsified liquid (water) can be obtained
utilizing a system according to the teachings of the present invention.
(For example, Examples 7, 8, 12 and 16).
It should be noted that the total combined flow rate of external phase
material and internal phase material can be varied to achieve an emulsion
of a desired composition. Also, the recirculation rate of prepared
emulsion through the recirculation loop can be varied by way of the
recirculating means and the amount of recirculated product can be varied
by adjusting the flow rates of the internal and external phases.
Furthermore, it should be noted that this particular system heats the
product 6.degree.-9.degree. C. and that air must be excluded from the
recirculation loop. Processor plumbing must allow for the displacement of
all air in the system upon initial filling to facilitate this. Phases
should enter the recirculation loop at its lowest point, and the product
should exit at the highest point.
It should also be noted that more than one shearing device may be utilized
and that it is possible to utilize two or more shearing devices in
parallel relationship or in series. The optimal total recirculation flow
rate is a function of the number and arrangement of shearing devices in
the plumbing loop. Each arrangement will require a different recirculation
rate which rate can readily be determined by one skilled in the art. Also,
it should be noted that introduction of the internal and external phase
materials into the high pressure side of the recirculating means will
accomplish similar results.
As pointed out above, best results are achieved for this emulsion system
when the combination of phase materials and recycled emulsion is forced
through the shearing device at a flow rate which results in a pressure
drop of about 120 psi per Hydroshear. Where two shearing devices are
utilized, best results are achieved when there is a total pressure drop of
from about 200 to about 250 psi.
The following examples are for illustrative purposes only and demonstrate
the best mode for utilizing two shearing devices (Hydroshears) in series
to produce an emulsion of a desired quality.
TABLE 2
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Pressure
Exam-
Ext. Phase
Int. Phase
Product
Drop Across
ple
Temp. Temp. Temp.
Hydroshear
Flowrate
# (.degree.C.)
(.degree.C.)
(.degree.C.)
(psi) (ml/min)
Quality
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17 43.0 14.8 21.7 150-240
865 2/3 B 2/3
18 47.5 13.9 21.7 100-150
865 3 B/C 3
19 48.7 14.0 24.0 200-275
865 3 B 3
20 49.8 14.4 22.8 150-225
1145 3 B 1
21 50.5 14.4 22.8 100-200
1145 3 B 2
22 37.0 31.0 26.0 200-250
1200 2 B/C 1
23 36.0 28.0 26.0 200-250
1200 2 B/C 1
24 36.0 23.4 24.5 175-225
1540 2 C 3
25 35.0 23.0 26.5 200-260
1540 2 B/C 2
26 35.0 27.5 27.5 200-260
1540 1/2 B 1
27 35.0 25.1 29.1 200-260
1540 2 B/C 1
28 43.0 25.2 26.4 200-250
1385 1/2 B 1
29 38.5 23.3 26.0 200-250
1385 1/2 B/C 1
30 34.7 23.4 25.4 200-250
1385 2 B/C 1
31 33.3 21.1 23.4 200-250
1385 2 B/C 1
32 34.0 20.6 23.5 200-250
1600 2 B 1
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These examples further illustrate the capability of the system of the
present invention to produce an emulsion which contains little or no
non-emulsified liquid (water).
While the illustrative embodiments of the invention have been described
with particularity, it will be understood that various other modifications
will be apparent to and can be readily made by those skilled in the art
without departing from the spirit and scope of the invention. Accordingly,
it is not intended that the scope of the claims appended hereto be limited
to the examples and descriptions set forth herein but rather that the
claims be construed as encompassing all the features of patentable novelty
which reside in the present invention, including all features which would
be treated as equivalents thereof by those skilled in the art to which
this invention pertains.
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