CA1171743A - Apparatus and method for individually encapsulating magnetic particles - Google Patents

Abstract

ABSTRACT
An apparatus and method for encapsulating magnetic particles by enclosure within oil drops, mixing in an aqueous solution and dispersing the oil drops with the enclosed particles by applica-tion of an alternating magnetic field The dispersed and oil covered particles are microencapsulated with at least one type of polymer

Description

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This invention relates generally to magnetic particle dis-plays and particularly to apparatus and a method for individually encapsulating magnetic particles for use in such displays. Magne-tic particle displays are typically flat panel, matrix address-able display devices. The displays form images on a panel of freely rotating spherical particles, each of which is a tiny per-manent magnet, dark colored in one hemisphere and light colored in the other. Thus, the amount of ambient light reflected by the particles i8 a function of the particle orientation which is con-trolled by a magnetic field. Since the magnetic particles are generally spherical as opposed to disk shaped, the particles do not need to be pivoted for rotation. It is then practical to use very small particles on the order of l millimeter (mm) or less in diameter or linear dimension and in very large numbers. The mag-netic particles are typically smaller than can be resolved by the na~ed eye thus giving the display a high resolution.
Fabrication of a magnetic particle display requires combined efforts in four rather unrelated technological areas. First, one must ma~e the spherical particle. Second, one must impart to these particles the desired optical and magnetic properties.
Third, the particles must be encapsulated for positioning on the surface on which the image is to be produced; and fi~ally, a mag-netic field must be provided to control the orientation of the encapsulated particles. The method and apparatus of the present invention are concerned with and are directed to the foregoing noted third step of fabrication wherein the particles are encapsu-1171'~ '~3 lated for placement within the environment wherein the image isto be produced. More particularly, a method is needed to encapsu-late individual ones of the extremely small particles within a carrier fluid medium for rotatable installation within the dis-play. One of the more difficult problems involved in encapsula-tion i8 the dispersal of a large number of agglomerated magnetiz-ed spherical particles in such a manner that individual ones of the particles can be separately and uniquely placed within assoc-iated ones of the capsules. Since the particles are magnetized , they tend to attract each other due to the inherent magnetic for-ces and thus resist separation and dispersal for placement into individual capsules. Furthermore, surface tension of the sur-rounding liquid prevents the particles from being separated. In other words, the interfacial tension of the oil and water inter-face makes it difficult for larger oil drops to separate into smaller ones. The surface tension force can be characterized as a short range force that generally operates only when the parti-cles are in very close proximity to each other and is a relative-ly strong force to overcome. Thus, when the particles are so close to each other that the surrounding oil forms a continuous volume, there is usually a relatively strong force to overcome.
The magnetic force, in contrast, can be characterized as a long range force that tends to pull particles together from greater distances and is a relatively weak force, especially at large distances.
One method known in the prior art for providing dispersal of the agglomerated magnetized particles is the use of mechanical agitation devices which interact with and disperse the agglomer-ated particles when such particles are placed in a carrier fluid such as oil. In such a method, the degree to which the dispersal is accomplished largely depends on the intensity of the applied mechanical forces with the greater applied mechanical forces re-11717~3 sulting in the greater dispersal but also with the concurrent pos-sibility of removing all the oil surrounding the particles. The implementation of such a method requires a certain delicacy and sensitivity in impacting the particles with the agitating means so as to create a reasonable yield of oil covered useful parti-cles .
SUMMARY OF THE INVENTION
Accordingly, it is an object of the present invention to pro-vide an apparatus and a method for dispersing individual ones of magnetized particles by magnetic means to insure that each of the particles is fully coated with carrier fluid. Another object of the invention is to provide an apparatus and a method for dispers-ing individual ones of magnetic particles to produce a high yield of particles useful in a magnetic display. Yet another object of the invention is to provide a method fcr encapsulating magnetic particles in order to permit rotation of individual particles within associated capsules. Still another object of the inven-tion is to provide a method for encapsulating individual ones of magnetic particles for increasing the encapsulated particles re-sistance to impacting external forces and to provide for easier handling and placement of the encap~ulated particles in a dis-play. Another object of this invention is to combine with the magnetic means a mechanical stirring to accomplish dispersion of the particles and final smoothing of the particle shell. It is an o~ject of this invention to control the conditions of the fluid in which the particles are dispersed, e.g. fluid tempera-ture, pH, and concentrations, such that the capsule shell can be formed at precisely the moment oil drop~, in which the particles are contained, are properly dispersed. A further object of this invention is to provide a method and apparatus for continuously flowing suspended magnetic particles through a conduit and magnet-ically dispersing the particles while flowing.

~1717~3 Briefly, these and other objects are accomplished by an ap-paratus and a method for encapsulating magnetic particles by im-mersion in oil drops, mixing the oil drops in an aqueous solution and causing individual ones of the agglomerated particles within the aqueous oil solution to individually disperse by application of an alternating magnetic field. The individually dispersed par-ticles, still under the influence of the magnetic field, are mi-croencapsulated with at least one type of polymer by means of the addition of a polymer forming material to the oil water suspen-sion to form a relatively hard, or solid, shell enclosing the mag-netized particle within the oil. Once coated with a solid cap-sule wall, the effects of surface tension, or tension of the two liquid in~erface, are removed, and the particles are relatively easy to separate again, even if they have been allowed to agglom-erate. The shell may be coated by additional polymer which pro-vides a yet thic~er capsule wall about the enclosed particle and which capsule is easily handled for placement within the magnetic display.
In a second embodiment, mechanical agitation, in the form of stirring, of the aqueous solution in which the oil drops are sus-pended is employed, in addition to the varying magnetic field, to assist in the dispersion of the encapsulated particles and to keep in dispersion the nonmagnetic materials such as the encapsul-ated oil drops without particles and excessive shell materials.
Also, control of temperature, pH, and/or concentrations of an aqueous shell forming solution is provided, prior to the immer-sion and suspension of the oil drops therein, the conditions be-ing such that shell starts to become formed only when the parti-cles are properly dispersed. Also, in the case of microencapsula-tion by gelatin coacervation, the solution is quenched after for-mation of ~he capsule wall, to prevent adhesion of the capsules.

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In a further embodiment, the suspended drops are flowed through a tube and a varying magnetic field of increasing frequen-cy is applied to the tube interior, the frequency increasing from upstream to downstream portions of the tube to provide a continu-ous process of encapsulation. Therefore, the particles will be carried through regions of lower magnetic field frequencies to re-gions of higher magnetic field freguency, the effects on disper-sion being the same as if the particles were contained in a sta-tionary beaker and magnetic fields of increasing frequencies applied.
For a better understanding of these and other aspects of the invention, reference may be made to the following detailed de-scription taken in conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWIN~S
Fig. 1 is a block diagram of the sequential steps of the method according to the present invention;
Fig~ 2 is a side elevation view of a container illustrating the dispersal of magnetic particles while under the influence of a magnetic field according to the invention;
Fig. 3 is a simplified illustration and block diagram of apparatus for dispersing the particles according to the method of the present invention;
Fig. 4 is a simplified perspective broken away partially schematic view of another embodiment of this invention;
Fig. 5 is a greatly enlarged perspective view of a magnetic particle;
Fig. 6 is a simplified perspective partially sectioned, par-tially broken away, partially block diagram view of a further em-bodiment of this invention; and Fig. 6A is a field vector diagram for the coils of Fig. 6.

117~7~3 DESCRIPTION OF THE PREFERRED EMBODIMENT
-According to the instant invention, a method is provided for dispersing oil covered magnetic particles in an aqueous medium such that each of the individually enclosed, or oil surrounded, magnetic particles is microencapsulated in a transparent solid shell that permits relatively easy handling for placement in a magnetic particle display.
Referring now to Fig. 1 there is shown a block diagram of the steps used in the encapsulation method of the present inven-tion. The method is useful with a variety of differing magnetic particle types and, in the preferred method of the present inven-tion, the particles used were of a strontium ferrite material en-closed in a polyethylene binder forming a spherical particle ap-proximately 200~m in diameter. The magnetic coercive force of the strontium ferrite is approximately 2000 oersted. The parti-cles are preferrably colored and encapsulated in a transparent shell for use in a magnetic particle display. Typically, one hemisphere of the particle is colored with a dark color and the remaining hemisphere of the particle is colored with a contrast-ing color. Various methods of manufacture of the particles and the coloring thereof are known in the art and the details thereof are not discussed herein. Block 10 of the diagram illustrates the first step of the method wherein the magnetized particles are first immersed in a carrier fluid such as oil or other oily fluids such as hydrocarbons, fluorocarbons, polysiloxanes, or es-ters. The purpose of the oil is to provide a fluid which sur-rounds the particle and permits rotation of the particle under the influence of a magnetic field. The oil which surrounds the particle is sometimes referred to in the art of microencapsula-tion, as the ~internal phase~. This is in contrast to another fluid medium in which the oil drop will be suspended and which is referred to as the ~continuous phase~. The oil is generally one of many transparent li~uids thA~ Ar~

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and, in a preferred method, a silicone oil having a viscosity of 5 centisto~es (cst.) is used.
Once immersed in the oil, the particles are then suspended in the continuous phase which, in most cases, is an aqueous solu-tion as shown in the second step of the method as noted in block 12. The aqueous solution in this embodiment is a mixture of wa-ter and an additional appropriate amount of surfactant which is used to reduce interfacial tension. The surfactant in a prefer-red method is L77 surfactant available from Union Carbide Chemi-cals, New Yor~, and it is applied at a concentration of 0.03% in water. The immersed particles are transferred to the water solu-tion with an eye dropper or pipette and dropped into the water.
These drops are generally a few millimeters in diameter and may agglomerate into larger drops.
The suspended drops within the water solution are then expos-ed to a magnetic field as noted in the third step of the method in block 14. An alternating magnetic field having an amplitude of approximately 300 oersted, or gauss, is preferably used at a frequency of approximastely 150 Hertz (Hz). This frequency has been found sufficient for the initial dispersion in the case of the aforementioned materials. For higher viscosity oils, such as paraffin oil, the desired frequency is lower, such as, for exam-ple, 50 Hz. After the applied magnetic field has caused the lar-ger drops to brea~ up into smaller ones, the frequency may be in-creased and the process repeated, causing the drops to become smaller after each change of frequency. The frequency may be increased in discrete steps, in which case each step should repre-sent a frequency increase of not more than 50% in order to main-tain stability within the dispersal process. Moreover, in the case of discrete frequency changes, the applied magnetic field should be maintained at each frequency for at least two hundred cycles before being switched to a higher frequency. Gradual in-117~

crease of the frequency is necessary for dispersion of the oildrops because at each respectively differing frequency, only oil drops of a particular size range will disperse into smaller drops. For example, at 600 Hz frequency, drops of 5 cst. sili-cone oil of approximately 2 mm diameter containing hundreds of magnetic particles will not disperse. For silicone oils having a viscosity of 5 cst. a frequency of approximately 800 Hz will typi-cally be reached before the drops become so small that most all of the drops contain but one magnetic particle. Alternatively, the magnetic field dispersal process may be varied to control the size of the drops such that any desired average number of parti-cles are enclosed therein.
After dispersal by the magnetic field to the point where the desired average number of particles are contained within each drop, the microencapsulation step of the method may begin as not-ed in the fourth step of block 16 in the diagram. During the en-capsulation proces~, the magnetic field is maintained at the high-est frequency last used to disperse the drops in order to main-tain the drops in a dispersed relationshiup during the microencap-sulation process. The microencapsulation step is begun by appli-cation of a polymer coating on the drop surface between the oil and the water. In the preferred method, acid chlorides are first added to the oil to form the internal phase. The internal phase consists of a saturated solution of sebacoyl chloride, azelaoyl chloride, and trimesoyl chloride in silicone oil. After the mag-netic particles contained within the internal phase have been suf-A ficiently dispersed and are ready to be mi~erencapsulated, a suf-ficient quantity of diethylenetriamine i~ added to the aqueous solution to reach a final concentration of approximately 5~, and as low as .5%, with the result that an interfacial film of polya-mide is thus rapidly formed. The polyamide polymer coating is formed due to the interfacial reaction between the amine in the .

water and the acid chlorides in the oil. The interfacial reac-tion is accomplished, or solid film is formed, in less than a second. The resultant polymer coating, although encapsulating the entrapped particle within the oil carrier fluid, is usually relatively thin and at this point may not withstand the rough handling encountered in further processing. Accordingly, it may be necessary to optionally build up and increase the thickness and strength of the capsule by the application of an additional coating in the microencapsulization step of the method.
Various microencapsulation techniques are known in the art and are disclosed, for example, in the text "Microcapsules and Mi-croencapsulation Techniques~ by M. Gutcho, Noyes Data Corpora-tion, Park Ridge, New Jersey (1976). During the latter optional portion of the microencapsulation step, the magnetic field force may be substantially reduced inasmuch as dispersion may be more easily maintained due to the previously applied polymer coating which enables redispersion of the agglomeration of the enclosed particles.
Once microencapsulated, the magnetic particles are entrapped in transparent shells having at least one polymer coating. The capsules are sufficiently strong so as to withstand normal hand-ling for placement into a magnetic particle display. The place-ment of the particles in the display may be done in any well known fashion such as by adhesion onto a substrate.
Fig. 2 illustrates a side view of a container 18 such as a glass beaker which is used to hold the aqueous solution 20. More clearly illustrated is a particular one of the oil immersed drops 22 having a number of particles enclosed therein. As the drop 22 gravitates downward within the container 18 and comes within the influence of a magnetic field shown applied about the container, the single drop 22 disperses into a plurality of smaller drops 24 each having enclosed therein a single particle. The particles 11717~1~

are suspended in the solution and exhibit apparently random mo-tion due to the influence of the applied magnetic field.
Fig. 3 illustrates the apparatus used in the dispersal and encapsulation process of a preferred method. An eye dropper 26 having a quantity of oil immersed particles therein is activated to cause a number of the immersed particles to form into the drops 22 which are dropped into the container 18. The container is used to hold the aqueous solution noted hereinbefore in the operation of the preferred method during dispersal and microencapsulation. As also noted hereinbefore, a selected amount of surfactant is added to the water in combination with the oil drops containing the enclosed particles. An alternating magnetic field is applied to the aqueous solution by a means of a field coil 28 driven by a variable audio frequency (AF) generator 30 whose output is coupled to a variable power amplifier 32 whose output drives the coil. The field intensity and frequency are conveniently varied for purposes of implementation of the inventive method by conventional means in adjusting the generator 30 and the amplifier 32.
A Although the dropper means have ~been illustrated as an eye dropper 26, it will be appreciated that alternate means such as a pipette, spatula, or a spoon may be utilized in the method of the present invention to achieve economies of scale in production and efficiency.
Referring to Fig. 4, container 40, in this embodiment a 150 ml glass beaker, contains a continuous phase ~h~ll,f~rming mix-ture 41 of 60 grams of 2% solution of 290 Bloom, pig-skin gelatin and .15 cc of 40~ sodium hexameta phosphate. The mixture is ini-tially at an elevated temperature, e.g. in a range of 50 C.
to 55 C., and is cooled by natural convection of ambient air, with the help, if necessary, of temperature control coil jacket 42, which is wrapped around container 40, at a rate of .8 C.

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per minute to a temperature of 41 C. Temperature control 44 is manually or automatically adjustable to control the cooling rate provided by jacket 42, and provides the coils in jacket 42 with a coolant fluid in a manner well known in the art. Thermo-meter 46 is used to monitor the mixture temperature and is remov-ed after the temperature of 41 C. is reached.
Drop 48 i8 of an internal phase oil mixture 53 containing magnetic particles 50, each drop 48 containing in the order of 500 particles. Six drops 48 are dropped into mixture 41 as by an eyedropper 52, or other drop forming member, after mixture 41 has reached a temperature of 41 C. The oil mixture 53 is a mixture of, by weight, 4 parts paraffin oil and 1 part kerosene, with 5% Trimesoyl Chloride and 4% Alrosperse 100, a surfactant manufactured by the Ciba-Geigy Corporation, Dye and Chemical Divi-sion, 1410 Swing Road, Greensboro, North Carolina 27407, by weight, added to the mixture of paraffin oil and kerosene. The particles 50 are 120 ~m diameter spheres of a polyethylene and ferrite magnetic material, silver coated on one hemisphere 50a, Fig. 5, and dark colored on the other hemisphere 50b, and are mag-netized to saturation, and have been pre-soaked for several hours in the oil mixture 53.
A stirrer 54 has a motor 56 which turns shaft 58 at approxi-mately 1000 rpm. A six blade turbine 60 is affixed to the end of shaft 58 and the diameter of turbine 60 is preferably greater than 70~ of the diameter of container 40. Shaft 58 and turbine 60 are of a nonmagnetic dielectric material such as glass.
A field coil 62 having electrical leads 64, 66 i8 placed about jacket 42 and container 40 and is coupled through lead 64 to power amplifier 68 through on-off switch 70. Feedback circuit 72 i8 placed across the input and output of amplifier 68. Capaci-tance 74 is coupled between lead 66 and ground. Resistance 76 is coupled to lead 66 and, through switch 78 and capacitance 80, to ground. Switches 70, 78 may be of solid state construction, with appropriate well known circuitry for their operation. Thus con-nected, amplifier 68 acts as an oscillator, having a first oscil-latory or resonant frequency of 430 Hz and first power output to coil 62 to provide a magnetic field strength of 400 gauss in con-tainer 40, when switch 70 is closed and switch 78 is open. With switches 70, 78 closed, a second oscillatory or resonant frequen-cy of less than 100 Hz and a second power output to coil 62 to provide a magnetic field of less than 100 gauss in container 40, are provided. The circuit components to obtain these frequencies and fields are as follows: audio amplifier 68, 750 watts; coil 62, 60 mh, coil resistance 5 ohms; resistance 76, 5 ohms; capaci-tance 74, 2.3 ~f.; capacitance 80, 20 ~f.
After stirrer 54 has been operated for a brief period, e.g.
a second, switch 70 i8 closed, switch 78 being open, to provide a magnetic field having a frequency of 430 Hz and a field strength of 400 gauss in container 40 for about one second to disperse par-ticles 50, drops 48 becoming smaller, and particles per drop be-coming fewer, viz. one particle per drop. Then .6 cc of 204 ace-tic acid solution~is injected into container 40, using syringe 82 or other volumetrically accurate fluid dispenser, changing the pH
of the mixture in container 40 from approximately 5 to 4. This change results in the formation of two phases, phase one being a A dilute solution of gelatin in water, and phase two being a coacer-vation which contains a much higher concentration of gelatin than phase one. The coacervate gathers on the surface of the oil drops and forms the ~hell of the capsules.
Switch 78 is then closed to connect resistance 76 and capaci-tance 80 in the amplifier 68 circuit, reducing the magnetic field frequency to less than ~00 Hz, and the field strength to less than 100 gauss. At this point, the capsule walls are initially rough, but become smooth after about 11 minutes of stirring by turbine 60 in combination with the weaker magnetic field. The 1~7174~
-turbine 60 is operated continuously from its start point in the cycle.
The required power and frequency of the magnetic field to ob-tain dispersion depends upon several factors. If particle 50 sizes are larger, the required power and frequency to field coil 62 are decreased; if interfacial tension between the oil mixture and the water in the continuous phase mixture is increased, the required power is increased, while the reql~ired frequency is un-changed; if viscosities of the internal and continuous phases are increased, the required power is increased and the required fre-quency is decreased; if particle magnetic intensity is increased, the required power may be decreased and the required frequency is unchanged. The magnetic field can have a dc component, as well as an ac component, and the dc component can be generated by a permanent magnet.
The previously described embodiments are batch type embodi-ments wherein the microencapsulation takes place in situ. To pro-vide a uniform magnetic field throughout the batch, as the batch size is increased, the field power required is also increased.
In the next de~cribed embodiment of this invention, the power re-quirements are minimized since only a relatively small field area is required for a relatively high rate of encapsulated particle output.
Referring to Fig. 6, continuous phase reservoir 90, which is maintained with a continuous phase of a mixture 41 having a compo-sition as in the previous embodiment~ has o tlet 92 which feeds Pe ~e ~iY~
horizontal pipe section s4h. Diagonal elongated tube 96 connects section 94 and spherical chamber 98, which is provided with out-let 100 having manually or automatically adjustable valve 101 to control the flow volume in outlet 100, and, as will be understood by those in the art, in tube 96. Section-94 is provided with tem-perature regulating coil jacket 42 wrapped around portion 95 of li ~ 17 ~ ~
section 94, and temperature control 44 is coupled to jacket 42 to control the continuous phase temperature in the manner of the Fig. 4 embodiment, reducing the temperature from an initial range of about 50 C. to ~5 C., which is mixture 41 temperature as it enters portion 95, at a rate of .8 C. per minute as the mixture flows through portion 9~ to a temperature of 41 C. as the mixture leaves portion 95.
Field coils 102, 104, 106, 108, 110, 112, 114 are longitudi-nally spaced along, from upstream to downstream, respectively, and are formed around tube 96, each providing a varying magnetic field uniformly across the tube 96 section encircled by the re-spective coil, according to the power and frequency supplied to each coil by Frequency and Power Control circuit 116, to which each coil is separately coupled. In this embodiment, the frequen-cy of each coil increases by a factor of preferably less than twice the next previous upstream coil, coil 114 having the final frequency in the range of 1 kHz in this embodiment, and the field strength provided in tube 96 by each coil being as high as pos-sible without demagnatizing the particles 50, and in this embodi-ment being in the 1.0 kgauss range, for the mixtures 41, 53 compo-sitions of the embodiment of Fig. 4, which compositions are also used for the embodiment of Fig. 6.
Coils 102, 108, 114 are wound to provide an axial magnetic field in tube 96 in the z direction, Fig. 6A; coils 104, 110 are wound ~o provide ~ magnetic field in tube 96 in the y direction, Fig. 6A, which is perp~ndicular to the z direction; and coils 106, 112 are wound to provide a magnetic field in tube 96 in the x direction, Fig. 6A, which is perpindicular to both the z and y directions. Circumferential coil gaps 118 are placed in coils 104, 106, 110, 112, and are circumferentially positioned to ob-tain the aforementioned field directions. In this way, mutual 11>~ ~ 7 ~ ~

inductance between adjacent coils is minimized, reducing the prob-lem of driving these coils electronically.
Internal phase mixture reservoir 120 is maintained with an internal phase mixture 53 composition of the Fig. 4 embodiment, and has outlet 122 feeding pipe 124, in which is placed adjusta-ble flow rate metering pump 125, and which has adjustable drop rate drop forming nozzle 126 at its end, the drop rate being con-trollable by the flow rate in pump 125, and being selected accord-ing to the flow rate in tube 96 to obtain the desired concentra-tion. Valve 101 in outlet 100 is manually or automatically adjus-table to control the flow rate in tube 96. Port 128 in tube 96 downstream of portion 95 receives, in fluid tight relation, noz-zle 126 from which oil drops 48 containing particles S0 are admit-ted into tube 96, which drops are continuously dispersed into smaller drops containing fewer particles by the varying magnetic fields of coils 102-114, until only one particle per drop is ob-tained, at which point the drops enter chamber 9~.
Acetic acid reservoir 130 is maintained with a supply of ace-tic acid solution 84 having the composition of the Fig. 4 embodi-ment solution, and has outlet 132 feeding into pipe 96 through ad-justable flow rate metering pump 133 which is placed in pipe 134, which has an adjustable nozzle 136 at its end, the adjustments of pump 133 and nozzle 136 controlling the flow of acetic acid solu-tion into port 138 which receives, in fluid tight relation, noz-zle 136 and is formed in the wall of tube 96 between coils 112, 114, or further upstream in tube 96, so that the acid will be well mixed with the rest of the continuous phase solution by the time the mixture reaches coil 114. The flow rate of acetic acid through nozzle 136 may also be controlled by reservoir 130 pres-sure, the acetic acid flow rate being adjusted according to the flow rate in outlet 100. As in the embodiment of Fig. 4, the ad-11 71'7~3 dition of the acid solution results in coacervation, the coacer-vate coating the particle containing oil drops.
The shell walls thus formed become smoothed as they pass slowly through chamber 98. Stirrer turbine 60 is driven by motor 56 through driveshaft 58 maintaining the capsules separated while the capsule or shell walls become smooth. Thus, reagglomeration i8 prevented by the turbine 60. Motor 56 is mounted exteriorly of chamber 98 and shaft 58 extends in fluid tight relation through opening 140 in the wall of chamber 98, and rotates at A about 1000 rpm. Driveshaft 58 and turbine~are of a nonmagnetic dielectric material such as glass. Cooling jacket 144 is placed around outlet 100 and is coupled to Temperature Control 146, which provides jacket 144 with cooling fluid to bring the temperature in outlet 100 to about 10 C. causing the coacervate to become a ~olid gel. The encapsulated particles exit chamber 98 through chamber port 142 into outlet 100, where they are cooled and piped to the next step in preparing them for their ultimate use.
Thus an embodiment is provided having relatively small coils and correspondingly lower power requirements to provide a high volume rate of encapsulated particle output. Power requirements can be further reduced by utilizing ferromagnetic cores in the coils 102-114.
Thus there may be seen that there has been provided a novel apparatus and method for dispersing and encapsulating magnetic particles to insure placement of a desired average number of par-ticles within an associated capsule.
Obviously, many modifications and variations of the inven-tion are possible in light of the above teachings. It is there-fore to be understood that within the scope of the appended claims the invention may be practiced otherwise than as specifi-cally described. ^

Claims (40)

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. Apparatus for dispersing a preselected average number of magnetic particles in discrete amounts of liquid internal phase and microencapsula-ting said amounts, comprising: first means for forming drops of liquid internal phase having a relatively large number of the magnetic particles immersed in substantially each drop of said drops; second means for recei-ving said drops; said second means adapted to confine a liquid continuous phase having a consistency to suspend said drops; third means operatively associated with said second means for dispersing said particles and forming successively smaller drops with corresponding successively reduced number of particles in each said smaller drop; said third means comprising means for applying a varying magnetic field to said second means, the frequency of said field variations being selected according to the desired number of particles in said smaller drops, the characteristics of the particles and the internal and continuous phases.

2. The apparatus of claim 1 wherein said third means comprises agitating means for physically agitating said internal and continuous phases to obtain smaller drops, each drop having a reduced number of par-ticles therein.

3. The apparatus of claim 2 wherein said agitating means comprises a stirrer for physically stirring said internal and continuous phases.

4. The apparatus of claim 1 comprising fourth means for injecting encapsulation compositions into said continuous phase after said smaller drops have been formed to provide encapsulation of said smaller drops.

5. The apparatus of claim 1 wherein said third means further com-prises means for varying the intensity and frequency of said magnetic field.

6. The apparatus of claim 1 wherein said third means is for progres-sively increasing the frequency of said field variations with respect to time to progressively disperse said particles and progressively reduce the number of particles in individual drops.

7. The apparatus of claim 6 wherein said number of particles in each drop is reduced to one.

8. The apparatus of claim 1 wherein said third means is for increas-ing the frequency of said field variations with respect to time in discrete steps, each step being of an increased frequency over the frequency of the next previous step.

9. The apparatus of claim 8 wherein said third means increases the frequency of said field variations an amount less than 50% of the frequency of the next previous step, and there is a period corresponding to at least 200 cycles of said varying magnetic field between successive increases.

10. The apparatus of claim 1 wherein said third means applies a varying magnetic field of alternating magnetic polarity.

11. The apparatus of claim 1 wherein said second means comprises a container; said third means comprises a coil placed about said container;
fourth means coupled to said coil for applying variable electrical power of variable frequency to said coil.

12. The apparatus of claim 11 wherein said third means comprises first and second resonating circuits for controlling the frequency of said magnetic field variations; said first circuit having a higher resonating frequency than said second resonating circuit; switch means for switching between said first and second resonating circuits.

13. The apparatus of claim 1 wherein said second means comprises an elongated tubular member having an upstream end and a downstream end for carrying liquid from said upstream end to said downstream end; said tubular member having a first section and a plurality of sequential longitudinally spaced transverse sections downstream of said first section; said third means for applying varying magnetic fields in said member in each of said sections.

14. The apparatus of claim 13 wherein said third means comprises a series of coils longitudinally spaced along and about said tubular member;
fourth means for applying a varying electrical power to each of said coils to provide a varying magnetic field within said coils and said tubular member.

15. The apparatus of claim 13 wherein said third means is for apply-ing a different frequency magnetic field in each of said sections; said fields in said sections being of progressively higher frequency as section position changes from said upstream end to said downstream end, each down-stream section having a higher frequency than the next previous upstream section, the frequency in said first section depending on the particle size, interfacial tension between the internal phase and continuous phase mix-tures, the viscosity of said mixtures, and the magnetic intensity of the particles.

16. The apparatus of claim 15 wherein the frequency in each downstream section is less than twice greater than the frequency in the next previous upstream section.

17. The apparatus of claim 15 wherein said third means applies a plurality of field directions in said tubular member, the fields in adjacent sections being in different directions to minimize inductance between adjacent sections.

18. The apparatus of claim 14 including an encapsulation chamber at the downstream end of said tubular member; fifth means for injecting encap-sulation compositions into said tube upstream of the last downstream coil;
sixth means for outflow of encapsulated particles that are formed in said chamber.

19. The apparatus of claim 18 including seventh means for mechanically agitating the liquids in said chamber, to keep the capsules separated while the capsule shell walls become smooth.

The apparatus of claim 19 wherein said seventh means comprises a rotatable turbine driven by a shaft rotatably mounted in a wall of said chamber; a motor mounted exteriorly of said chamber and mechanically coupled to said shaft for rotating said shaft.

21. The apparatus of claim 13 wherein said first means comprises a drop former positioned upstream of said first section for introducing par-ticle containing drops into said member; eighth means for supplying a con-tinuous phase liquid mixture flow through said tubular member.

22. The apparatus of claim 18 having ninth means for cooling the liquid in said sixth means.

23. The apparatus of claim 11 comprising: fifth means for mechanically agitating the liquids in said container, for initial dispersing of said particles into smaller drops, each drop after said initial dispersing having a lesser number of magnetic particles therein.

24. The apparatus of claim 23 wherein said fifth means comprises a rotatable turbine having a shaft mounted for rotation in a wall of said cham-ber; a motor mounted exteriorly of said container and mechanically coupled to said shaft for rotating said shaft.

25. The apparatus of claim 1 including fourth means for lowering the temperature of the contents of said second means.

26. A method for dispersing a preselected average number of magnetized particles, the particles being enclosed in a discrete amount of internal phase, comprising the following steps: immersing the particles in a liquid internal phase; suspending internal phase drops containing the immersed particles in a liquid continuous phase; mechanically agitating the con-tinuous phase to provide initial dispersing of said particles and forming smaller drops with a reduced number of particles in each drop; applying a varying magnetic field to said suspension for further dispersing of said particles into smaller drops with a reduced number of particles in each drop, the frequency of said field variations being selected according to the desired number of particles in individual drops; microencapsulating individual ones of said drops to form capsules containing drops in which said particles are rotatable.

27. The method of claim 26 including the step of mechanically agita-ting the continuous phase after the microencapsulating step, to keep the capsules separated while the capsule shell walls become smooth.

28. The method of claim 26 wherein said mechanical agitating step comprises stirring said continuous phase.

29. A method for dispersing a preselected average number of magnetized particles, the particles being enclosed in a discrete amount of internal phase, comprising the following steps: immersing the particles in a liquid internal phase; suspending internal phase drops containing the immersed particles in a liquid continuous phase; controlling at least one of the temperature, pH, and concentrations of the continuous phase in order to initiate formation of the capsule shell walls; varying the magnetic field to said suspension for further dispersing of said particles into smaller drops with a reduced number of particles in each drop, the frequency of said field variations being selected according to the desired number of particles in individual drops; microencapsulating individual ones of said drops to form capsules containing drops in which said particles are rotat-able; strengthening the capsule walls.

30. The method of claim 29 wherein the controlling step comprises reducing the temperature of the continuous phase from an initial tempera-ture to a lower second temperature prior to suspending the internal phase drops in the continuous phase.

31. The method of claim 30 wherein said strengthening step comprises quenching the continuous phase containing the drops from said second tem-perature to a final temperature lower than said second temperature whereby the coacervate capsule shell walls become a gel.

32. The method of claim 30 wherein said initial temperature is in the range of 50°C. to 55°C., said second temperature is approximately 41°C
and said final temperature is about 10°C.

33. The method of claim 26 wherein said microencapsulation step comprises injecting an acidic composition into said continuous phase to form a two phase mixture, one phase being a first solution of the capsule shell forming material and a second phase being a coacervation of a more concentrated solution than said first solution of a capsule shell forming material.

34. The method of claim 29 wherein said step of varying the magnetic field comprises applying an initial field frequency and strength and after the microencapsulation step, applying a second field of reduced frequency and reduced field strength.

35. The method of claim 34 wherein said initial frequency is about 430 Hz and said initial field strength is about 400 gauss and said second frequency is less than 100 Hz and said second field strength is less than 100 gauss.

36. The method of claim 26 including the step of flowing said inter-nal phase drops suspended in the continuous phase through a magnetic field of increasing frequency.

37. The method of claim 26 wherein said internal phase comprises by weight 4 parts of paraffin oil and 1 part kerosene, with 5% trimesoyl chloride and 4% Alrosperse 100 by weight added, and the continuous phase comprises 60 gm of 2% solution of 290 Bloom, pig-skin gelatin and .15 cc of 40% sodium hexameta phosphate.

38. The method of claim 26 wherein the step of applying a varying magnetic field comprises the continuous flow step of flowing said internal phase drops suspended in the continuous phase through an elongated tube and applying a separate varying magnetic field to each of a plurality of longitudinally spaced portions of said tube, the magnetic field frequency applied to said portions sequentially downstream of said tube being cor-respondingly sequentially increasing.

39. The method of claim 38 wherein said continuous flow step includes increasing the magnetic field frequency of each of said portions to the next successive of said portions downstream of said tube by a factor of less than two.

40. The method of claim 26 wherein said step of mechanically agita-ting the continuous phase continues throughout the steps of applying a varying magnetic field and microencapsulating.