The present invention relates to an apparatus and method for emulsifying and dispersing a desired material in a base liquid to form an emulsified/dispersed liquid, and more particularly to an apparatus and method for giving a shearing force to a liquid so as to facilitate emulsification/dispersion.
Heretofore, there have been known various types of emulsification/dispersion apparatuses. Irrespective of the types, such as rotary and high-pressure types, all of these emulsification/dispersion apparatuses are intended to perform emulsification/dispersion while giving a high shearing force to a liquid. For example, a high-pressure type homogenizer is designed to perform emulsification/dispersion by converting a pressure into a jet flow, and bringing the jet flow into collision with a wall or reversing its course to convert the kinetic energy of the jet flow into shear energy.
If a liquid receives such a high shearing force in a site having some heterogeneity or unevenness, such as difference in pressure or flow velocity (under off-balanced conditions), air dissolved in the liquid or air remaining in the system will become bubbles or cause a bubbling phenomenon to undesirably form large particles. In this context, a technique of introducing a backpressure has been employed to prevent the bubbling from occurring. For controlling the backpressure, a Gaulin-type homogenizer is provided with a two-way valve, and a microfluidizer is provided with a backpressure chamber.
In conjunction with recent developments of an apparatus capable of injecting higher energy in response to the need for higher emulsification/dispersion performance, the bubbling phenomenon comes to the front as a serious problem. While bubbling likely to occur within an apparatus can be suppressed by increasing a backpressure, another bubbling will be caused by pressure drop immediately after the liquid is discharged from the apparatus.
In case where a target material is power or fine particles, upon occurrence of the bubbling, the resulting bubbles attached onto the surfaces of the particles cause poor wettability, and an aerosol is liable to be formed even in an emulsion state. The bubbles also absorb energy to cause energy loss, and oxidization in a treated material. For example, in case of unsaturated fatty acid, an oxidative reaction under a high temperature causes deterioration in product quality. Moreover, if the amount of an emulsifying agent and/or a dispersing agent is increased to reduce the interfacial tension of aquatic systems, small bubbles generated in the shear region will further attach onto the interface to cause the deterioration in release of the bubbles.
As above, the conventional concept is directed to injecting higher energy so as to facilitate micronization, and prevent bubbling by means of increased backpressure, or is based on an idea giving greater importance to the upstream of an emulsification/dispersion process. Such an approach cannot effectively prevent the occurrence of bubbling.
A fundamental object of the present invention is to provide an emulsification/dispersion system and method capable of fully eliminating bubbles, or obtaining an emulsified/dispersed liquid as a product free from the risk of its deterioration even if some bubbles exist therein.
A fundamental idea of the present invention is originated on the basis of the time point when a created emulsified/dispersed liquid is released to atmosphere, and formulated to prevent the bubbling phenomenon from being induced by a pressure drop inevitably occurring at that time point. That is, the origin of conception is set at the downstream of an emulsification/dispersion process, and then various conditions in the upstream, such as the amount of energy to be injected, are adjusted accordingly.
An emulsification/dispersion system according to a first aspect of the present invention comprises a combination of a multistage emulsification/dispersion module and a multistage depressurization module.
The multistage emulsification/dispersion module includes first to third absorption cells axially connected in series with each other through a seal. Given that the inner diameters of the first, second and third absorption cells are D1, D2 and D3, respectively, the following relationship is satisfied: D2>D3>D1. The seal has an inner diameter DS satisfying the following relationship: DS≧D2.
The multistage depressurization module is connected to the multistage emulsification/dispersion module through a communication passage. This multistage depressurization module fundamentally comprises at least two depressurization cells (depressurization members) axially connected with one another in a multistage manner through a seal (connecting member) having an inner diameter greater than that of the depressurization member. The multistage depressurization module is operable to provide a required backpressure to the multistage emulsification/dispersion module, and to reduce the backpressure through the depressurization cells in a stepwise manner so that the depressurization cell in the final stage provides a reduced pressure causing no bubbling when an emulsified/dispersed liquid is released to atmosphere.
The depressurization cells may have the same size having a given inner diameter, or may have different inner diameters which are stepwise increased. The seal interposed between the depressurization cells has a function of shutting off the respective depressurizing functions in the adjacent depressurization cells. In other words, the entire reduced pressure of the multistage depressurization module can be considered as the sum of the respective reduced pressures in the depressurization cells, and the respective inner diameters and the number of the depressurization cells may be determined depending on a backpressure required for the multistage emulsification/dispersion module.
Given that the respective absorption cells forming a passage in the multistage emulsification/dispersion module, the communication passage, and the respective depressurization cells forming a passage in the multistage depressurization module are defined as individual passage units, and the entire passage from the inlet of the multistage emulsification/dispersion module to the outlet of the multistage depressurization module is constructed by these passage units, the entire passage is defined by the passage units having in combination at least three different passage diameters, and the combination is determined according to the following rules.
(1) Each of the passage units has either one of at least three different passage diameters DS, DM, DB (DS<DM<DB). When the passage unit with the passage diameter DM is connected to the downstream of the passage unit with the passage diameter DS, the passage unit with the passage diameter DB is connected between these two passage units.
(2) The rule (1) is not essentially applied when any of the passage units is connected to the upstream side of the passage unit with the smallest passage diameter.
The multistage depressurization module according to the present invention can also be applied to a conventional rotary or high-pressure-type emulsification/dispersion apparatus. In this case, the multistage depressurization module gives a required backpressure to the emulsification/dispersion apparatus to prevent bubbling in the emulsification/dispersion apparatus, and reduces the backpressure in a stepwise manner to finally have a reduced pressure causing no bubbling even if an emulsified/dispersed liquid is released to atmosphere.
A method for producing an emulsified/dispersed liquid, according to a second aspect of the present invention, comprises the steps of giving a shearing force to a liquid to emulsify/disperse the liquid while applying a backpressure thereto, and reducing the backpressure in a stepwise manner using a plurality of depressurization cells so as to allow the liquid to finally have a reduced pressure causing no bubbling even if it is released to atmosphere.
Further, in case of an integrated multistage emulsification/dispersion apparatus, the emulsification/dispersion operation can be performed while maintaining a liquid in its critical state. Specifically, a method for producing an emulsified/dispersed liquid, according to a third aspect of the present invention, comprises the steps of pressurizing and heating a dispersion liquid up to its critical pressure or more and its critical temperature or more, to achieve the critical state, on the upstream side of an integrated multistage emulsification/dispersion apparatus, and supply the dispersion liquid to the integrated multistage emulsification/dispersion apparatus. If the dispersion liquid is in the critical state, the solubility and/or dispersibility of a material to be emulsified/dispersed will be increased to provide further enhanced emulsification/dispersion performance.
In the integrated multistage emulsification/dispersion apparatus, the emulsification/dispersion operation in the critical state allows the backpressure to be given to the dispersion liquid at a sufficient high value, and the backpressure is reduced in a stepwise manner using multistage depressurization cells. Even through the critical state is released to transform the emulsified/dispersed liquid into the liquid phase through the depressurization, the pressure can be reduced in a stepwise manner while appropriately assuring an internal backpressure, to obtain a desired emulsified/dispersed liquid without bubbling.
In this manner, the system of the present invention is constructed based on the pressure causing no bubbling even if an emulsified/dispersed liquid is released to atmosphere. That is, in accordance with this pressure, the multistage depressurization module is designed to provide a backpressure required for the emulsification/dispersion apparatus, or a backpressure required for suppressing the occurrence of bubbling in the apparatus.
This approach makes it possible to reliably suppress not only bubbling in the emulsification/dispersion apparatus, but also bubbling which would otherwise occur when the emulsified/dispersed liquid is released to atmosphere in the final stage.
Generally, in case where a high shearing force is applied to a liquid in this type of emulsification/dispersion system or apparatus, if the site has some heterogeneity or unevenness, (if the balance of flow velocity or pressure is lost), bubbling will occur to cause uneven distribution of particles or formation of large particles. The conventional tourniquet is directed to increase the liquid pressure at a high value so as to prevent this bubbling phenomenon. However, this measure inevitably involves a large amount of unprofitable energy consumption. By contrast, the emulsification/dispersion apparatus according to the present invention is intended to prevent the occurrence of bubbling without applying an excessively high pressure to a liquid, based on the aforementioned construction. This makes it possible to evenly disperse particles so as to prevent the formation of large particles, while reducing energy consumption.
Other features and advantages of the present invention will be apparent from the detailed description and from the accompanying drawings. In the accompanying drawings, a common element or component is defined by the same reference numeral or code.
[First Embodiment]
As shown in
A liquid to be emulsified/dispersed, which is stored in a material supply tank 5, is supplied to the multistage emulsification/dispersion controller 1, in the state after the liquid is pressurized at a given high pressure by a high-pressure pump 6. As described in detail later, the multistage emulsification/dispersion controller 1 is operable to perform an emulsification/dispersion operation based on liquid-liquid shear caused by a jet flow. The multistage depressurization module 3 on the downstream thereof is operable to apply a given backpressure to the multistage emulsification/dispersion controller 1 through the heat exchanger 2 so as to prevent the occurrence of bubbling in the multistage emulsification/dispersion controller 1.
The heat exchanger 2 is operable to cool the liquid heated at a high temperature during the emulsification/dispersion operation based on the shear, so as to prevent the occurrence of bubbling. Depending on an intended product, it is required to avoid such a high temperature. In this case, the heat exchanger 2 is may be omitted, and the multistage depressurization module 3 may be connected directly to the multistage emulsification/dispersion controller 1.
In the first embodiment, in order to add an auxiliary material necessary for the emulsified/dispersed liquid, a liquid contained in a second supply tank 7 is supplied to the inlet side of the multistage depressurization module 3 through a supply pump 8 and a supply valve 9, at a given pressure equal to or greater than a backpressure.
The multistage depressurization module 3 is operable to reduce the pressure (backpressure) of the emulsified/dispersed liquid in a stepwise manner, to the extent of causing no bubbling even if the liquid is released to atmosphere at an outlet portion of the multistage depressurization module 3. The emulsified/dispersed liquid depressurized by the multistage depressurization module 3 may be taken out of the system as a final product, or may be returned to the first supply tank 6 and re-emulsified/dispersed according to need.
One specific example of the multistage emulsification/dispersion controller 1 is shown in
The first end of the body 11 is formed with a threaded hole for threadingly engaging with the outer periphery of the connector 12, and a hole 15 steppedly formed to continue from the threaded hole 14 and have a smaller inner diameter than that of the threaded hole 14. A nozzle member 16 is fitted into the hole 15. The-nozzle member 16 is pressingly held on the bottom of the hole 15 by a shoulder of the connector 12 formed at the inner edge thereof. The body 11 is internally formed with an axial hole 19 extending coaxially with a nozzle 17 held by the nozzle member 16, to define a first passage 18 (inner diameter: D0), and a second axial hole 20 axially continuing from the first axial hole 19 and having an inner diameter greater than that of the first axial hole 19.
Six absorption cells 21 are inserted from the second axial end into the second axial hole 20 in a multistage manner while interposing a ring-shaped seal 22 therebetween. The final-stage absorption cell 21-6 is fittingly held by an axial hole 23 formed in the end cap 13 connected to the second end of the body 11.
The 4-th absorption cell 21-4 has an inner diameter D2 greater than an inner diameter D1, and each of the 5-th and 6-th absorption cells 21-5, 21-6 adjacent to the 4-th absorption cell 21-4 has an inner diameter D3 less than the inner diameter D1 of each of the three absorption cells 21-1, 21-2, 21-3 (D2, D0>D1>D3).
In the above arrangement, the absorption cells 21-1, 21-2 and 21-3 are operative to apply a backpressure to the first passage 18, and the absorption cells 21-5, 21-6 with the smallest inner diameter are operative to apply a given backpressure to the 4-th absorption cell 21-4 with the relatively large inner diameter D2.
Each of the ring-shaped seals 22 has an inner diameter Ds greater than the largest inner diameter D2. Thus, the ring-shaped seals 22 can instantaneously absorb or relax a pressure so as to allow each of the absorption cells 21 to reliably bring out a depressurizing effect.
That is, the above arrangement is designed such that the first passage 18, in which the strongest shearing force is to be generated, is applied with a backpressure sufficient to prevent bubbling likely to be induced by the strong shearing force, and the 4-th absorption cell 21-4, in which the pressure relaxation is to be induced, is applied with a backpressure from the 5-th and 6-th absorption cells with the smaller diameter to prevent the occurrence of bubbling due to the pressure relaxation. A second passage 25 connected with the 6-th absorption cell 21-6 has an inner diameter sufficiently greater than the inner diameter D3 of the 6-th absorption cell 21-6. The second passage 25 is connected to the heat exchanger 2 in the subsequent stage.
A liquid pressurized by the high-pressure pump 6, for example, at 2,000 bar or more, is injected into the first passage 19 through the axial hole 24 of the connector 12 in the form of a high-speed jet flow. The jet flow injected into the first passage 19 gives a large sharing force to the liquid residing therearound while losing its own kinetic energy, so as to induce emulsification/dispersion therein, and flows into the absorption cells 21 to give a shearing force to the liquid residing in the absorption cells 21 so as to induce emulsification/dispersion therein.
Each of the absorption cells 21 herein means a type having a small-diameter axial hole in which the kinetic energy of a jet flow flowing along the axis of the axial hole is gradually lost while being converted into shear energy and thermal energy due to the liquid-liquid shear between the jet flow and a liquid residing around the jet flow. The respective inner diameters and the stage-number of the absorption cells 21 are critical design factors to obtain a strong emulsification/dispersion function without bubbling.
The end cap 31 is formed with an inlet 34 connected to a heat exchanger (2 in
In order to construct a suitable system for an intended product, either one of a pipe 40, a plug 41 and a relief valve 42 is attached to the first side port 36, and either one of a plug 41 and a relief valve 42 is attached to the second side port 39.
While the six depressurization cells 33 used in this example have the same inner diameter, the same outer diameter and the same axial length, it is not essential to design them in the same size.
The depressurizing function (downstream end) and the pressurizing function (upstream end) of the depressurization cells will be verified below.
As the depressurizations cells 33 for use in the test, two type: one having an inner diameter of 0.75 mm and a length of 10 mm, and the other having an inner diameter of 1.0 mm and a length of 10 mm, were prepared. The seal 34 was prepared to have an inner diameter of 2.6 mm and a thickness of about 1.5 mm.
The diameter of the line extending from the high-pressure pump 6 to the depressurizations cells 33 through the heat exchanger 2, the inlet-side passage 53 of the testing unit body 50 was set at 2.7 mm. The diameter of the outlet-side passage was also set at 2.7 mm.
The test was carried out while changing the number and the order of the depressurization cells 33, and a pressure just before the testing unit body 50 was measured using a pressure gauge 58 under the conditions of the flow volume of water: 250, 360 and 440 cc/min. The temperature of the water was maintained at 25° C. by the heat exchanger (cooler) to avoid influence of temperature change.
The test result is shown in Tables 1 and 2, and
Given that a liquid flows at a flow volume Q by a pressure difference h (converted into height) between the upstream end and the down stream end (atmosphere) of a cell having a passage sectional area A,
Q=cA{square root}{square root over (2gh)}
, wherein c is flow coefficient. Therefore, the pressure difference h is expressed as follows:
h=(Q/cA)2/2g
This height h is converted into the unit of pressure, and the converted value is defined as X. The value X indicates a pressure difference (pressure drop) when the liquid passes over the cell.
Further, a pressure loss caused by passing over the cell is determined by the following formula:
h′=f·(L/D)·(V2/2g)
, wherein f: friction loss coefficient, L: length of the cell, D: inner diameter of the cell, and V: flow velocity.
Given that a value obtained by converting h′ into pressure is ΔY, a pressure drop caused by one cell is derived from X+ΔY. In case of two cell, it is expressed by X+2ΔY. In case of n cell, it is expressed by X+nΔY. The theoretical value was calculated based on the above process.
The test result shows that the actual measurement value is approximately matched with the theoretical value. Specifically, it means that when the number of the depressurization cells 33 is N, a pressure difference (backpressure) corresponding to N+ΔY is generated. The backpressure is proportional to the number of the depressurization cells 33.
Table 3 shows the test result for the depressurization cell having an inner diameter of 0.5 mm and a length of 10 mm. As with the above case, the actual measurement value in this case is adequately matched with the theoretical value. The error would be caused by the error in metering of the height pressure pump and/or the error in accuracy of the pressure gauge.
As seen in the above result, according to the cell type, the pressure difference (backpressure) caused by flow can be advantageously calculated using the hydrodynamic fundamental theoretical formula without difficulties. This can be achieved only if the seal interposed between the depressurization cells 33 has a larger inner diameter to block the correlation or interference between the adjacent depressurization cells 33.
For example, in case where a combination of six depressurization cells each having an inner diameter of 1 mm and a length of 10 mm is used in this multistage depressurization module, if the flow volume is 250 cc/min, one of the depressurization cells can depressurize by 0.11 kg/cm2 corresponding to the pressure difference therein.
When the outlet side is opened to atmosphere, the depressurizing function of the depressurization cell on the side of the outlet is preferable to be minimized.
The inventors checked up the possibility of the occurrence of bubbling in the multistage depressurization module using various combinations of depressurization cells different in passage diameter. As a result, it was found that the combinations determined in conformity with the following rules have no bubbling, and the combinations against the rules have bubbling.
(Rule 1) In a combination of cells each having either one of at least three different passage diameters with a relationship of DS<DM<DB, when a first cell with the passage diameter DM is connected to the downstream of a second cell with the passage diameter DS, a third cell with the passage diameter DB is interposed between the fist and second cells. That is, the first cell with the passage diameter DM should not be connected directly to the downstream of the second cell with the passage diameter DS, but must be connected to the downstream of the second cell with the passage diameter Ds through the third cell with the passage diameter DB.
(Rule 2) The Rule 1 is not essentially applied when any of the cells is connected to the upstream side of a cell with the smallest passage diameter.
Dc≧DQ>DB≧DM≧Ds
Further, these cells are connected with each other in a relationship of Ds→DB→DM, which is satisfy the relationship defined in the above (Rule 1).
The inventors have also been experimentally verified that the above Rules are applicable to a combination of the absorption cells of the multistage emulsification/dispersion controller as well as the multistage depressurization module, and any combination of the absorption cells different in passage diameter, unconformable to the above Rules has bubbling in the outlet of the multistage emulsification/dispersion controller.
For example, in case of the multistage emulsification/dispersion module illustrated in
As a conclusion, the above Rules are applicable to the entire assembly composed of all passage elements interposed in the passage ranging from the multistage emulsification/dispersion controller to the multistage depressurization module. More specifically, given that each of the respective absorption cells, the inlet passage of the multistage emulsification/dispersion controller, the outlet passage of the multistage emulsification/dispersion controller, the communication passage connecting between the multistage emulsification/dispersion controller and the multistage depressurization module (including the passage of the heat exchanger), the respective depressurization cells, the inlet passage of the multistage depressurization module, and outlet passage of the multistage depressurization module, is defined as a passage unit, the above Rules are applied to any connection relationship of these passage units.
From this point of view, the above Rules are further generalized as follows.
(Rule 1) Each of the passage units has either one of at least three different passage diameters DS, DM, DB (DS<DM<DB), wherein when the passage unit with the passage diameter DM is connected to the downstream of the passage unit with the passage diameter DS, the passage unit with the passage diameter DB is connected between the above two passage units.
(Rule 2) The (Rule 1) is not essentially applied when any of the passage units is connected to the upstream side of the passage unit with the smallest passage diameter Ds (exceptional rule for the (Rule 1)).
In either case, the respective inner diameter and/or the number of the depressurization cells may be selectively determined optimally to a required depressurization treatment and/or characteristics of a product to be treated. In some cases, two or three depressurization cells may be used as a single depressurization cell unit without interposing any seal 34 therebetween. Even in such a case, if two of the depressurization cells have different passage diameters, they must be connected with one another through the seal 34.
[Second Embodiment]
In this embodiment, an apparatus body 110 is formed as a long columnar body, and formed with an axial hole 120 extending from the rear end thereof to be brought into communication with a first passage 18 continuing to a nozzle 17 provided at the front end thereof. Five absorption cells 21-1, - - - , 21-5 with inner diameters having the same relation as that in
The series of absorption cells 21-1, - - - , 21-5 and depressurization cells 33-1, - - - , 33-7 are pressingly held in the axial direction by an end cap 13 threadingly engaged with the outlet side of the apparatus body 110.
Except for being devoid of a heat exchanger (2 in
Based on the embodiment illustrated in
Given that a pressure in the upstream of the nozzle 17 (nozzle diameter: 0.14 mm, length: 1.5 mm): 1000 kg/cm2, a flow volume: 340 cc/min, a flow coefficient: 0.9, and a friction loss coefficient: 0.032.
Each of the cells is set to have a length of 10 mm, and the pressure is reduced to an atmospheric pressure in the outlet passage.
In
Mode 1 is designed such that an emulsified/dispersed liquid or a product is taken out directly from the outlet of the integrated multistage emulsification/dispersion apparatus 100. In case where a product can be taken out in its high-temperature state without any problems, or it is desired to take out a product in its high-temperature state, this system may be employed.
The emulsified/dispersed liquid may be retuned to a supply tank 5 and re-emulsified/dispersed, according to need.
Mode 2 is designed such that the integrated multistage emulsification/dispersion apparatus 100 is connected to a heat exchanger to allow a product to cooled to an appropriate temperature by the heat exchanger and then taken out. The cooling is effective to prevent the occurrence of bubbling.
In Mode 2, the emulsified/dispersed liquid may also be retuned to the supply tank 5, and re-emulsified/dispersed.
Mode 3 is a system arranged such that the multistage depressurization module 3 is connected to the downstream of the heat exchanger 2. Mode 3 may be effectively used in case where there is the need for applying a higher backpressure to the integrated multistage emulsification/dispersion apparatus 100.
As described in connection with
The liquid discharged from the multistage depressurization module 3 may be taken out as a final product, or may be returned to the supply tank 5 and re-emulsified/dispersed.
[Third Embodiment]
As shown in
The dispersion liquid in the critical state is supplied to a multistage emulsification/dispersion controller 1. If water serving as a solvent is in its critical state, even an insoluble material such as lecithin can have solubility and/or dispersibility. Thus, when the dispersion liquid is injected into the multistage emulsification/dispersion controller 1 at a high speed, the emulsification/dispersion of the liquid is further accelerated by a string shearing force. This provides a possibility of achieving the emulsification/dispersion between water and oil without using any surfactant.
The inner space of the multistage emulsification/dispersion controller 1 has a high temperature and a high pressure, and a required backpressure is assured by a multistage depressurization module 3 provided in the subsequent stage of a heat exchanger 2 and/or another multistage depressurization module 3′ provided in the further subsequent stage. The emulsified/dispersed liquid discharged from the multistage emulsification/dispersion controller 1 is cooled by the heat exchanger 2, and the cooled emulsified/dispersed liquid is depressurized by the multistage depressurization module 3. In case where a desired result cannot be sufficiently obtained only by one cycle of cooling and depressurization, or the temperature/pressure conditions still involve the risk of causing bubbles if the emulsified/dispersed liquid is released directly to atmosphere, another heat exchanger 2′ and multistage depressurization module 31 are additionally connected to provide sufficient cooling and depressurization so as to prevent the occurrence of bubbling.
In this manner, after the emulsification/dispersion in the critical state based on shearing force, a final product can be obtained without bubbling while maintaining an adequate emulsified/dispersed state.
According to need, the emulsified/dispersed liquid may be returned to the supply tank 5 and re-emulsified/dispersed, and/or an additive may be additionally supplied from a second supply tank 7 to the inlet side of the multistage depressurization module 3 through a supply pump 8 and a valve 9.
[Applications of Multistage depressurization Module]
The multistage depressurization module 3 according to the present invention can control a backpressure required for the emulsification/dispersion apparatus or a backpressure capable of suppressing the occurrence of bubbling therein, and can reduce the backpressure in a stepwise manner to allow an emulsified/dispersed liquid to finally have a reduced pressure causing no bubbling even if it is released to atmosphere. Further, the respective inner diameters/lengths and the number of the depressurization cells can be variously combined to control the backpressure and the depressurization of the backpressure with high flexibility.
Thus, this multistage depressurization module can be effectively combined with conventional high-pressure or rotary type emulsification/dispersion apparatuses.
Examples of such an application are shown in FIGS. 12 to 16.
The DeBEE 2000 is a type designed to inject a high-speed jet of 500 feet/sec or more into absorption cells arranged in series in a multistage manner, and emulsify/disperse a liquid by means of liquid-liquid shear in the interface between the high-speed jet and a low-speed liquid flow formed around the high-speed jet. The details can be referred to Japanese Patent Laid-Open Publication No. 09-507791. The dual type herein means a type in which a liquid is supplied from the side of a jet flow by use of a suction force of the jet flow, and the reverse type means a type in which the emulsification/dispersion is induced by means of liquid-liquid shear between a jet flow and a low-speed liquid flow flowing back from a closed downstream end.
In
In the dual type illustrated in
In the reverse type illustrated in
In both the types, the multistage depressurization module 3 is operable to provide a backpressure required for preventing bubbling in the emulsification module 303 likely to be induced by a strong shearing force, and to reduce the backpressure in a stepwise manner to prevent the occurrence of bubbling when a product is taken out.
In these conventional homogenizers, the problem of bubbling due to a strong shearing force comes to the front as the rotation speed and/or pressure are increased. The multistage depressurization module 3 can be used therewith to provide a required backpressure for preventing the occurrence of bubbling and allow a product to be taken out without bubbling.
In FIGS. 14 to 16, the same element as or a corresponding element to that in
As can be understood from the above description, the multistage depressurization module according to the present invention can apply a high backpressure to the emulsification/dispersion apparatus according to need, and can reduce the high backpressure in a stepwise manner to reliably prevent the occurrence of bubbling when a dispersed/emulsified liquid is released to atmosphere.
The emulsification/dispersion apparatus may be any commonly used or conventional type. They can be combined with the multistage depressurization module of the present invention to set up an allowable speed and/or pressure at a higher value so as to obtain an enhanced performance for creating emulsified/dispersed liquids.
The multistage emulsification/dispersion module according to the present invention can be constructed by combining a plurality of absorption cells different in inner diameter, to allow a high backpressure for preventing the occurrence of bubbling to be achieved in a liquid passage so as to perform the emulsification/dispersion using on a high shearing force while suppressing the occurrence of bubbling.
The multistage emulsification/dispersion module and the multistage depressurization module may be integrated as a single unit. In this case, a product can be taken out from the unit without the occurrence of bubbling.
In addition, a multistage depressurization system using the multistage depressurization module may be employed. In this case, after a dispersion liquid is highly pressurized and heated to achieve its critical state, a multistage emulsification/dispersion module is preferably used to perform emulsification/dispersion. While the emulsification/dispersion is required to be performed under a sufficiently high backpressure because the high-temperature heating is liable to cause bubbling or flushing, cooling and depressurization can be reputed as needed to prevent the occurrence of bubbling even if an emulsified/dispersed liquid is released to atmosphere. In a critical state, an enhanced solubility, which cannot be observed in the liquid phase, is obtained. Thus, it can be expected to obtain an emulsion of water/lecithin or water/oil without any surfactant by applying a high shearing force to the dispersion liquid in the critical state.
Industrial Applicability
As mentioned above, the emulsification/dispersion system using the multistage module according to the present invention is useful particularly in the emulsification/dispersion requiring a high shearing force, and suitable for use in homogenizers or the like.
Number | Date | Country | Kind |
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2002-2447 | Jan 2002 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP03/00091 | 1/9/2003 | WO |