巴西专利BR112012024510A2 toner particle, and, methods for making toner particles and for forming a toner image

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专利摘要:
TORNER PARTICLE, AND, METHODS TO MANUFACTURE TONER PARTICLES AND TO FORM A TONER IMAGE. The present invention relates to a porous toner particle containing encapsulated metal flakes. The porous particle containing metallic flakes can be useful for the reproduction of a metallic tone when melting on a substrate, preferably a golden or silvery tone, and for the manufacture of printed circuits, by a printing process, especially electrophotography.
公开号:BR112012024510A2
申请号:R112012024510-4
申请日:2011-04-20
公开日:2020-07-28
发明作者:Mridula Nair；xXiqiang Yang；Joseph S. Sedita
申请人:Eastman Kodak Company；
IPC主号:

专利说明:

“TONER PARTICLE AND METHODS FOR MANUFACTURING TONER PARTICLES AND TO FORM A TONER IMAGE ”
FIELD OF THE INVENTION This invention relates to electrostatographic toners, more particularly to porous toner particles with encapsulated metal flakes for use in the reproduction of printed images having metallic tones, as well as for the manufacture of printed circuit boards, by a process of printing, such as electrophotography.
BACKGROUND OF THE INVENTION Electrophotographic images are typically produced first by uniformly loading a primary imaging element, such as a photoconductive screen or drum using known means such as a roller or corona loader. An electrostatic latent image is then formed by exposure to the image feature of the primary imaging element using means known as optical exposure, laser scanners, or LED arrays. The electrostatic imaging is then made a visible image, bringing the electrostatic imaging to a close proximity to the marking particles, alternatively referred to as toner particles, that have been electrically charged, so that they will be attracted to the regions of the primary imaging element carrying the electrostatic imaging. The loading of the marking particles, which may or may not comprise a dye, such as a dye or a pigment, and bringing the particles into close proximity to the primary imaging element, is generally performed using a magnetic brush development station. The marking particles are first made suitable for use in a magnetic brush development station, mixing the marking particles with so-called carrier particles. The carrier particles comprise appropriate material that will be attracted to the magnets at the magnetic brush development station and may comprise known materials, such as ferrites or iron oxides, etc.
The carrier particles often comprise different fillers that give them a controlled charge over the marking particles.
The marking particles can also comprise appropriate charge control agents, so that, when mixed with the carrier particles, the marking particles obtain an electrical charge of the appropriate magnitude and signal, so as to make them attractive in quantities appropriate for electrostatic imaging in appropriate quantities to allow various image densities to be developed in the electrostatic imaging.
In magnetic brush development, the toner particles are generally mixed in the reservoir of the magnetic brush development station with carrier particles at a predetermined level that is measured with a toner concentration monitor.
The marking particles are charged by contacting the carrier particles and brought into close proximity to the primary imaging element by carrying the electrostatic latent image by rotating the cylindrical envelope, the coaxial magnetic core, or both from the magnetic brush development station.
The brush is electrically polarized in such a way that, depending on the charge signal of the toner particles, the marking particles can be deposited on the primary image forming element in any of the electrically charged regions or those electrically discharged to make it visible electrostatic imaging.
The toned image is then transferred to a receiver, which can be either a final receiving material, such as paper, transparency, etc., or to an intermediate transfer element, as a compatible intermediate transfer element, and then from the element of intermediate transfer to the final receiver element.
The transfer can be achieved by applying pressure between the receiver and either the primary imaging element or the intermediate transfer element.
Most commonly, pressure is applied in conjunction with either an applied electrostatic field or with heat that softens the toner particles. 5 The image is then typically permanently attached to the final receiving element using pressure, heat, or solvent vapors.
Most commonly, the image is attached to the final receiver by pressing the final receiver element carrying the image against a heated fusion roller.
To prevent the final receiving element from gripping the heated melt roll, the heated melt roll is conventionally first coated with a release agent, such as silicone oil.
Alternatively, release agents, and in particular wax particles, can be incorporated into toner particles to facilitate the release of a fused toner image from the heated fusion roller.
In such systems, it is important that the marking particles are electrically insulating, when used in conjunction with magnetic brush development and electrostatic transfer.
If the particles are not electrically insulating, their charges may change when in contact with the receiver or at the development station.
This can impair transfer and development as the applied electrostatic force used to propel the marking particles towards the primary imaging element or from a receiving element can vary with the charge on the marking particles.
In addition, even if the charge has not reversed signal or has become so significantly altered, to prevent disclosure or transfer, control of one or both of these operations can be delayed, resulting in incorrect amounts of marking particles being deposited, correspondingly undesirable density variations and other artifacts.
The printing processes are used not only to reproduce and transmit objective information, but also to conduct aesthetic impressions, for example, when illustrated books for exhibition are printed or also in advertising with figures.
A huge problem here is posed in particular by the reproduction of metallic tones.
Metallic tones 5 are only imperfectly reproduced by a mixture of colors formed from primary colors, especially cyan, magenta, yellow and black (CMYK). A golden tone is particularly difficult to reproduce through a mixture of colors.
Thus, it has been proposed to incorporate metallic pigments or particles in printing inks, so that a metallic color can be presented directly.
This practice has been used in many commercial liquid printing inks.
However, in the case of electrophotographic toners, where magnetic and / or electrical and especially electrostatic properties are decisive, which is particularly problematic, since metallic components can have an adverse effect on these properties.
However, proposals have already been made in the art to impregnate toners with metallic constituents.
For example, US Patent 5,180,650 describes providing a toner composition, which contains lightly colored metallic constituents, such as copper, silver, or gold, for example, of a coating, which in turn was provided with an overcoat consisting of a metal halide.
But the appearance of the prints, in particular, can be adversely affected by chemical reactions of the metal constituents, due to the halides, which can promote the oxidation of the constituents, for example.
For example, the fog that everyone knows with copper or silver objects can occur, making the metallic quality unattractive or disappearing altogether.
In addition, these toners are colored only slightly metallic, which is insufficient to reproduce a golden tone in the printed material.
In addition, when metal components are incorporated into toners using conventional manufacturing processes, these metal flakes are typically randomly oriented along the toner particles. This random orientation leads to a loss of metallic tone, and causes a slightly dark appearance when such toners are attached to a receiving sheet 5 using heated melt rollers. More recently, proposals have been made to modify the surface of metal flakes so that it becomes hydrophobic and non-conductive in order to be used in electrophotography. US patent 7,326,507 describes the preparation of a toner to produce a metallic tone. The metal pigment particles are coated with a silicate, followed by an organic phase, and the resulting particles are combined with the toner materials. However, the toner has not been shown to contain metal flakes encapsulated in the polymeric resin. Thus, there is a possibility that the metallic pigment itself may be detached from the polymer during the particle making process, which results in the lack of homogeneity in the toner which can cause cleaning transfer problems.
SUMMARY OF THE INVENTION It is an object of the present invention to provide polymeric toner particles that can contain high concentrations of encapsulated metal flakes. It is another object of the present invention to provide porous toner particles that contain encapsulated metallic flakes that can effectively produce metallic tone by a printing process, such as electrophotography or electrography by fusing the toner particles onto a receiving substrate. It is yet another object of the present invention to provide porous polymer particles with conductive encapsulated metal flakes for printed circuit boards, using a process such as electrophotography or electrography.
It is an additional object of the present invention to provide an efficient and scalable process for the manufacture of the above toner particles. It is another object of the present invention to provide a method for producing an electrophotographic toner image with an improved metallic tone and gloss or gloss effect.
It is yet another object of the present invention to directly use commercial metal flakes in such particles and methods so that additional surface modifications are not necessary.
These and other objects can be achieved in accordance with the present invention described herein.
In one embodiment, the invention is directed to a toner particle having an outer particle surface and comprising a polymer binder phase and metal flakes encapsulated therein, wherein the toner particle further comprises discrete pores formed within the particle of toner, so that the toner particle has an internal porosity of at least 10 percent by volume.
In another embodiment, the invention is directed to a method of making such toner particles, comprising: providing a first aqueous phase comprising dispersed metal flakes; dispersing the first aqueous phase in an organic solution containing a polymer binder to form a first emulsion, dispersing the first emulsion in a second aqueous phase to form a second emulsion; shear the second emulsion in the presence of a particulate stabilizing agent to form droplets of the first emulsion in the second aqueous phase, and evaporate the organic solution from the droplets to form porous toner particles having metal flakes encapsulated therein.
In another embodiment, the invention is directed to a method for forming a toner image comprising: forming a toner image on a substrate, wherein the toner image comprises toner particles according to the invention, comprising porous particles of toner with metal flakes encapsulated in them, and fix the 5 toner particles to the substrate by applying heat to fuse the toner particles into the substrate, where the pores inside the toner particles provide space for the metal flakes to reorient within the binder phase of the toner particles so that they are relatively more parallel with the surface of the receiving substrate when melting. The porous structure of the toner particle also allows the use of a lower amount of binder compared to solid particles, allowing for finer fused images, still improving the alignment of the metal flakes with the substrate surface when melting.
BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a reflective optical image of a fused toner particle formed from a comparative solid toner particle comprising metal flakes; and Figure 2 is an optical reflective image of a fused toner image formed from a porous toner particle comprising metal flakes in accordance with an embodiment of the present invention. For a better understanding of the present invention, together with other advantages and scope of it, reference is made to the detailed description that follows in connection with the drawings described above.
DETAILED DESCRIPTION OF THE INVENTION The present invention provides a toner for reproducing a metallic tone, preferably golden or silver, by a printing process, especially for electrophotography, distinguished by at least one porous particle comprising at least one metallic flake type pigment. .
The convenience of using such toner has already been described.
In accordance with the present invention, voids are introduced into the toner particle to form a porous particle, and the voids provide space for the flake-type metal pigments to reorient themselves within the binder when melting at high temperature, producing prints that exhibit a metallic tone or gloss effect or greater shine.
The toner of the invention can be applied to a substrate (receiver) by a digital printing process, preferably an electrostatic printing process, more preferably by an electrophotographic printing process, as described, for example, in L. B.
Schein, Eletrophotography and Development Physics, 2nd Edition, Laplacian Press, Morgan Hill, California, 1996 (ISBN 1-885540-02-7), or through a coating process, preferably an electrostatic coating process, more preferably by a electromagnetic brush coating process, as described in US Patent 6,342,273. For fixing toner to the substrate surface, a contact fusion method, such as heated roller fusion, may preferably be used, or a non-contact fusion method such as oven, hot, radiant, instantaneous, solvent, or microwave.
The toner particles used in the invention have an external particle surface and comprise a polymer binder phase and metal flakes encapsulated therein.
Discrete pores are formed inside the toner particle, such that the toner particle has an internal porosity of at least 10 percent by volume.
The porous toner particles of the present invention can include “micro”, “meso” and “macro” pores which according to the International Union of Pure and Applied Chemistry are the recommended classifications for pores smaller than 2 nm, from 2 to 50 nm , and greater than 50 nm, respectively.
The term porous particles will be used here to include pores of all sizes, including open or closed pores.
According to one embodiment, a porous toner particle encapsulating metal flakes, according to the present invention, can be produced by a double water-in-oil 5 in water emulsion process of the type described, for example, in publications of US Patent 2008/0176157, 2008/0176164 and 2010/0021838. This double emulsion process basically involves a three step process.
The first step involves the formation of a stable water-in-oil emulsion, including a first aqueous solution finely dispersed in a continuous phase of a binder polymer dissolved in an organic solvent.
According to this particular embodiment, this first dispersed aqueous phase ultimately creates pores in the particles.
A pore stabilizing compound can be included in the first aqueous solution, to control the pore size and number of pores in the particle, while stabilizing the pores so that the final particle is not fragile or easily fractured.
Pore stabilizing hydrocolloids include both naturally occurring and synthetic polymers, water-soluble or water-swellable, and cellulose derivatives, for example, carboxymethylcellulose (CMC), also referred to as sodium carboxymethylcellulose, for example , gelatine, for example gelatine treated with alkali, like gelatine from bovine bone or skin, or gelatine treated with acid, such as pigskin gelatine, gelatine derivatives, for example, acetylated gelatine, phthalate gelatine, and the like, substances like proteins and protein derivatives, synthetic polymeric binders such as poly (vinyl alcohol), poly (vinyl lactams), acrylamide polymers, polyvinyl acetals, alkyl and sulfoalkyl acrylate and methacrylate polymers, hydrolyzed polyvinyl acetates, polyamides, polyvinyl pyridine, copolyses methacrylamide, water soluble microgels, polyelectrolytes, ionomers, and mixtures thereof.
In order to stabilize the first initial stage of water-in-oil emulsion, so that it can be maintained without maturation or coalescence, if desired, it is preferable that the hydrocolloid in the aqueous phase has a higher osmotic pressure than the binder in the oil phase, depending solubility of water in oil.
This dramatically reduces the diffusion of water 5 to the oil phase and, therefore, the maturation caused by water migration between the water droplets.
A high osmotic pressure can be achieved in the aqueous phase, either by increasing the concentration of the hydrocolloid or by increasing the charge on the hydrocolloid (the counterions of the dissociated charges on the hydrocolloid increase the osmotic pressure of the hydrocolloid). It may be advantageous to have portions of weak base or weak acid in the hydrocolloid stabilizing the pores that allow the osmotic pressure of the hydrocolloid to be controlled by changing the pH.
Applicants will call these hydrocolloids "weakly dissociating hydrocolloids". For those weakly dissociating hydrocolloids, the osmotic pressure can be increased by using pH buffer to favor dissociation, or by simply adding a base (or acid) to change the pH of the aqueous phase to favor dissociation.
A preferred example of such a weakly dissociating hydrocolloid is CMC having a pH sensitive dissociation (carboxylate is a weak acid portion). By CMC the osmotic pressure can be increased by buffering the pH, for example, using a pH 6-8 phosphate buffer, or simply by adding a base to raise the pH of the aqueous phase to favor dissociation (for CMC the osmotic pressure increases rapidly as the pH is increased by 4-8). Other synthetic polyelectrolyte hydrocolloids such as polystyrene sulfonate (PSS) or poly (2-acrylamido-2-methylpropanesulfonate) (PAMS) or polyphosphates are also possible hydrocolloids.
These hydrocolloids have strongly dissociating portions.
Although pH control of osmotic pressure, which may be advantageous, as described above, is not possible due to the strong charge dissociation of these strongly dissociating polyelectrolyte hydrocolloids, these systems will be insensitive to the varying level of acid impurities.
This is a potential advantage for these highly dissociating polyelectrolyte hydrocolloids particularly when used with binder polymers that have different levels of 5-acid impurities, such as polyesters.
Desired properties of pore-stabilizing hydrocolloids include water solubility, with no negative impact on the multiple emulsification process, and no negative impact on the melting rheology of the resulting particles, when they are used as electrophotographic toners.
The pore stabilizing compounds can optionally be crosslinked in the pore to minimize the migration of the compound to the surface affecting the triboelectrification of the toners.
The amount of hydrocolloid used in the first step will depend on the amount of porosity and pore size desired and the molecular weight of the hydrocolloid.
A particularly preferred hydrocolloid is CMC and in an amount of 0.5-20 weight percent of the binder polymer, preferably in an amount of 1-10 weight percent and more preferably in an amount of 2-10 weight percent. weight of the binder polymer.
The first aqueous phase can additionally contain, if desired, salts to buffer the solution and, optionally, to control the osmotic pressure of the first aqueous phase, as described above.
For CMC the osmotic pressure can be increased by buffering with a pH 7 phosphate buffer. It may also contain additional porogen or pore-forming agents, such as ammonium carbonate.
The dual emulsion process embodiment is applicable for the preparation of porous polymeric toner particles of any type of polymeric binder or resin binder that is capable of being dissolved in a solvent that is immiscible with water in which the binder itself is substantially insoluble in water. Useful binder polymers include those derived from vinyl monomers, such as styrene and acrylic monomers, and condensation monomers such as esters and mixtures thereof. As the bonding polymer, known bonding resins 5 are usable. Concretely, these binder resins include homopolymers and copolymers, such as polyesters and polymers derived from styrene, for example, styrene and chloro-styrene; monoolefins, for example, ethylene, propylene, butylene and isoprene; vinyl esters, for example, vinyl acetate, vinyl propionate, vinyl benzoate, and vinyl butyrate; aliphatic α-methylene monocarboxylic acid esters, for example, methyl acrylate, ethyl acrylate, butyl acrylate, dodecyl acrylate, octyl acrylate, phenyl acrylate, methyl methacrylate, ethyl methacrylate, butyl methacrylate and methacrylate dodecyl, vinyl ethers, for example, methyl vinyl ether, ethyl vinyl ether and vinyl butyl ether; and vinyl ketones, for example, vinyl methyl ketone, vinyl hexyl ketone and vinyl isopropenyl ketone, and mixtures thereof. Particularly desirable binder polymers / resins include polystyrene resin, polyester resin, styrene-derived copolymers and acrylic monomers such as styrene / alkyl acrylate copolymers and styrene / alkyl methacrylate, styrene / acrylonitrile copolymer, copolymer butadiene, styrene / maleic anhydride copolymer, polyethylene resin, and polypropylene resin. They additionally include polyurethane resin, epoxy resin, silicone resin, polyamide resin, modified rosin rosin, paraffins and waxes. In addition, aromatic or aliphatic dicarboxylic acid polyesters with one or more aliphatic diols, such as isophthalic or terephthalic acid polyesters or fumaric acid with diois, such as ethylene glycol, cyclohexane dimethanol, and oxides of bisphenol oxides are especially useful. ethylene or propylene. Specific examples are described in US Patents
5,120,631; 4,430,408, and 5,714,295, and include propoxylated bisphenol-A fumarate, such as FINETONE ES 382 from Reichold Chemicals, formerly ATLAC ES 382 from ICI Americas Inc.
Preferably, the acid indices (expressed as milligrams of potassium hydroxide per gram of resin) of the polyester resins are in the range of 2 to 100. The polyesters can be saturated or unsaturated.
Among these resins, poly (styrene-co-acrylate) and polyester resins are particularly preferred.
In the practice of this invention, it is particularly advantageous to use resins having a viscosity in the range of 1-200 centipoises, when measured as a 20 weight percent solution in ethyl acetate at 25 ° C.
Any suitable solvent that will dissolve the binder polymer and which is also immiscible with water can be used in the dual emulsion process embodiment of this invention, such as, for example, chloromethane, dichloromethane, ethyl acetate, vinyl chloride, trichloromethane , carbon tetrachloride, ethylene chloride, trichloroethane, toluene, xylene, cyclohexanone, 2-nitropropane, and the like.
Particularly useful solvents are ethyl acetate and propyl acetate because both are effective solvents for many polymers and, at the same time, are poorly soluble in water.
In addition, their volatility is such that they are easily removed from the droplets of the discontinuous phase, as described below, by evaporation.
Optionally, the solvent that will dissolve the binder polymer and that is immiscible with water can be a mixture of two or more water immiscible solvents chosen from the list above.
Optionally, the solvent may comprise a mixture of one or more of the above-mentioned solvents and a water-immiscible non-solvent for the binder polymer, such as heptane, cyclohexane, diethyl ether, and the like, which is added in a proportion that is not sufficient to precipitate the binder polymer before drying and isolation.
The second step in the formation of porous particles according to the double emulsion process involves the formation of a water-in-oil in water emulsion dispersing the aforementioned water-in-oil emulsion in a second aqueous phase containing either stabilizing polymers such as polyvinylpyrrolidone or polyvinyl alcohol, or, more preferably, colloidal silica, such as Ludox or NALCO or latex particles in a modified ELC process, as described in US Patents
4,833,060; 4,965,131; 2,934,530; 3,615,972; 2,932,629, and 4,314,932. Specifically, in the second step, the water-in-oil emulsion is preferably mixed with a second aqueous phase containing colloidal silica stabilizer to form an aqueous droplet suspension that is subjected to shear or extension mixture or flow processes or the like, preferably through an orifice device to reduce the size of the droplets, still above the particle size of the first water-in-oil emulsion, and obtain droplets of narrow size distribution through the limited coalescence process. The pH of the second aqueous phase is generally between 4 and 7, when using silica as the colloidal stabilizer. The suspension resulting from droplets of the first water-in-oil emulsion in the second aqueous phase forms a double emulsion, containing the first aqueous phase as finer droplets within the larger droplets of binder / resin polymer solution, which, upon drying, produces porous domains in the resulting binder polymer / resin particles. The actual amount of silica used to stabilize the droplets depends on the desired final porous particle size as with a typical limited coalescence process, which in turn. depends on the volume and weight ratios of the various phases used to obtain the multiple emulsion. Any type of mixing and shearing equipment can be used to perform the first step described above, such as a batch mixer, planetary mixer, single or multiple screw extruder, static or dynamic mixer, colloid mill, high pressure homogenizer, sonicator, or a combination thereof.
Although any high shear stirring type device is applicable to this step, a preferred homogenization device is the MICROFLUIDIZER as Model No. 110T produced by Microfluidics.
Manufacturing.
In this device, the droplets of the first aqueous phase (discontinuous phase) are dispersed and reduced in size in the oil phase (continuous phase), in an agitation zone with high shear and, when leaving this zone, the particle size of the dispersed phase is reduced to dispersed droplets of uniform size in the continuous phase.
The process temperature can be modified to achieve optimum viscosity for droplet emulsification to control solvent evaporation.
For the second step, in which the water-in-water-in-water emulsion is formed, the shear or extension mixture or flow process is controlled in order to avoid rupture of the first emulsion and reduction of the droplet size is preferably obtained by homogenizing the emulsion through a capillary orifice device, or other suitable flow geometry.
The appropriate backpressure range to produce the acceptable particle size and size distribution is between 7 and 351 kg / cm2 (100 and 5000 psi), preferably between 35 and 210 kg / cm2 (500 and 3000 psi). The flow rate is preferable between 1000 and 6000 ml per minute.
The final particle size, the final pore size, and the surface morphology of the particle can be impacted by the osmotic incompatibility between the osmotic pressure of the internal aqueous phase, the oily phase of the binder polymer / resin and the outer aqueous phase.
At each interface, the greater the osmotic pressure gradient present, the faster the diffusion speed at which the water will diffuse from the low osmotic pressure phase to the higher osmotic pressure phase, depending on the solubility and diffusion coefficient of water in the oily phase.
If you want the outer water phase, or the inner water phase has a lower osmotic pressure than the oily phase, then the water will diffuse inward and saturate the oily phase. 5 For the preferred ethyl acetate solvent of the oil phase, this can result in approximately 8% by weight of water dissolved in the oil phase.
If the osmotic pressure of the outer aqueous phase is greater than the binder phase, then the water will migrate out of the particle's pores and reduce the porosity and particle size.
In order to increase porosity, osmotic pressures are preferably controlled, so that the osmotic pressure of the external phase is lower, while the osmotic pressure of the internal aqueous phase is higher.
Thus, the water will diffuse following the osmotic gradient from the external aqueous phase to the oily phase and, then, in the internal aqueous phase, swelling the pore size and increasing the porosity and particle size.
If it is desirable to have small pores and maintain the initial small droplet size formed in the emulsion step, then the osmotic pressure of the aqueous phase both inside and outside should preferably be combined, or have a small osmotic pressure gradient.
It is also preferable that the osmotic pressure of the outer and inner aqueous phases is greater than the oily phase.
When hydrocolloids using weakly dissociating agents, such as CMC, the pH of the outer aqueous phase can be changed using acid or a buffer, preferably a pH 4 citrate buffer. The hydrogen and hydroxide ions diffuse rapidly into the inner aqueous phase and balance the pH with the outer phase.
The drop in pH of the inner aqueous phase containing CMC, therefore, reduces the osmotic pressure of the CMC.
By correctly designing a balanced pH, you can control the hydrocolloid osmotic pressure and thus the final porosity, pore size, and particle size.
Porous toner particles, prepared according to the double emulsion process, comprise a compositionally solid solid polymer binder phase having an external particle surface and discrete pores dispersed within the compositionally continuous solid phase.
According to the present invention, the porous toner particles further comprise particles similar to metal flakes, and optionally, other additives, encapsulated therein.
Such metallic flakes, and other additives, may be present, primarily in the internal pores, and / or in the polymer binder phase.
In a particular embodiment, such metal flakes can conveniently be introduced by incorporation into the first dispersed aqueous solution, because the metal flakes can have hydrophilic surfaces, making them difficult to incorporate into the hydrophobic binder phase.
Such an embodiment of the invention consequently allows the effective incorporation of metal flakes, at a relatively higher concentration than generally obtained by direct dispersion in the organic phase.
For the purposes of the present invention, being primarily present in the internal pores requires that the metallic flake additive (or other specific additive) be present in the internal pores of the particle in an amount greater than that present in the compositionally continuous polymer binder phase.
This can be achieved by incorporating a greater part of the additive specific to the first aqueous phase, and having only a minority (and, in the extreme, no part) of the additive being incorporated into the oil phase in the double emulsion process described above.
According to a particular embodiment of the invention, it may be preferred that the additive primarily present in the internal pores of the particle is also substantially absent from the surface of the external particles.
This can be allowed by restricting the additive to be present in the first aqueous phase only in the process described above.
One way to further control the particle surface morphology, to allow the formation of an external particle surface substantially free of additive in the process described above, is by controlling the osmotic pressure of the two aqueous phases.
If the osmotic pressure in the inner water phase is too low 5 in relation to the outer water phase, for example, pores formed close to the surface can rupture to the surface and create an “open pore” surface morphology (craters on the surface), during drying in the third stage of the process, thus resulting in the presence of the additive included in the first aqueous phase being potentially deposited on the external surface of the particles.
The process is thus preferably controlled to minimize the formation of such open pores, thus forming particles with primarily closed pores and a substantially free pore surface and an additive-free external particle surface.
A third step in the preparation of porous particles, according to the double emulsion process, involves removing the solvent that is used to dissolve the binder polymer in order to produce a suspension of uniform porous polymer particles in aqueous solution.
The rate, temperature, and pressure during drying also impact the final particle size and surface morphology.
The details of the importance of this process depend on the solubility in water and the boiling point of the organic phase in relation to the temperature of the drying process.
A solvent removal apparatus, such as a rotary evaporator or an instant evaporator can be used in the practice of this method of this invention.
The polymer particles can be isolated after removal of the solvent by filtration or centrifugation, followed by drying in an oven at 40 ° C which also removes any water remaining in the pores from the first aqueous phase.
Optionally, the particles are treated with alkali to remove the silica stabilizer.
Optionally, the third step in the preparation of porous particles described above can be preceded by the addition of additional water before removing the solvent, isolation and drying, in order to increase the pore size and the overall level of porosity.
In an alternative process for the formation of porous particles, the first aqueous solution, comprising at least one additive (in addition to any pore stabilizing hydrocolloid) can be emulsified in a mixture of water immiscible polymerizable monomers and a polymerization initiator to form the first water-in-oil emulsion.
The resulting emulsion can then be dispersed in an aqueous phase containing stabilizer, as described in the second step of the process to form a water in oil in water emulsion, preferably during the limited coalescence process.
The monomers in the emulsified mixture are polymerized in the third step, preferably through the application of heat or radiation.
The resulting suspended polymerized particles can be isolated and dried as described above to give porous particles.
In addition, the mixture of water immiscible polymerizable monomers may contain the binder polymers listed previously.
The average particle diameter of the porous particles of the present invention can be, for example, from 2 to 100 micrometers, preferably from 3 to 50 micrometers, and more preferably from 5 to 20 micrometers.
The porosity of the particles is at least 10%, more preferably between 20 and 90%, and most preferably between 30 and 70%, where such porosity value represents the volume percentage of the internal void space within the external surface of the particle.
As described above, the porous particles according to the invention may comprise a solid compositionally continuous polymer binder phase having an external particle surface, and discrete pores dispersed within the compositionally continuous solid phase,
forming the inner pore surfaces.
Additives, other than and in addition to any pore stabilizing compound, which can be employed in the porous particle deformation process described above, may be present primarily in the discrete internal pores of such particles, and, furthermore, may be substantially absent from the surface of the external particles.
Such additives may comprise, for example, a functional additive employed in toner or other marking particles, such as at least one of a colorant, a release agent, such as a wax, a magnetic particle, or an opacifying agent.
When additives are conventionally used in toners, their presence on the surfaces of the toner particles can be inconsistent and cause possible adverse effects, in control of the triboelectric load and material handling properties, together with other properties of electrophotographic performance.
By limiting the additive's location to be primarily in the internal pores contained within the compositionally continuous polymer binder phase, the impact of these additives on the triboelectric charge and electrophotographic performance of such particles can be minimized, so that a toner set comprising toners different with different additives, while advantageously exhibiting consistent loading and transfer properties, can be activated.
Porous particles according to the invention can be formed by incorporating an additive that should desirably be located in the formed porous particles, but this is desired to be substantially absent from the surface of the outer particle, in the first aqueous solution in the process described above.
In addition, many desired additives are more readily available as aqueous dispersions, and a viable route for incorporating them into chemically prepared toners or other polymer particles is to incorporate them into the first aqueous phase of the multiple emulsion process according to a shape. of carrying out the present invention.
Many dispersions of wax and pigment, especially dispersions of wax, for example, are easier to make in water and most are commercially available.
The double emulsion process 5 consequently opens a wider window of dyes and other additives for incorporation in toners and other polymeric particles.
The dyes suitable for use in toner particles of the present invention may comprise, for example, a pigment or dye, as described, for example, in reissued US Patents 31072 and US Patents 4,160,644; 4,416,965; 4,414,152 and 4,229,513. Like dyes, known dyes can be used.
Colorants include, for example, carbon black, aniline blue, Calcoil blue, chrome yellow, ultramarine blue, Du Pont oil red, yellow quinoline, methylene blue chloride, phthalocyanine blue, malachite green oxalate, Lamp Black pigment , Bengal rose, red pigment 48: 1, pigment CI red 122, pigment CI red 57: 1, pigment CI yellow 97, pigment CI yellow 12, pigment CI yellow 17, pigment CI blue 15: 1, and pigment CI blue 15: 3. Dyes can generally be used in the range of 1 to 40 weight percent relative to the total weight of a toner powder, and preferably in the range of 2 to 30 weight percent, and more preferably from 4 to 20 weight percent in the practice of this invention.
When the dye content is 4% or more by weight, sufficient coloring power can be obtained, and when it is 20% or less by weight, effective transparency can be obtained.
Dye mixtures can also be used.
The non-aqueous soluble dyes used as an additive according to the invention can be pre-dispersed from the first aqueous phase before the formation of the first emulsion.
Metal flakes, or platelets, suitable for use in the porous toner particles and electrophotographic printing process used in the present invention can be from any of the commercially available sources of powdered or suspended metal flakes.
The flakes or platelets are substantially two-dimensional particles, having opposite main surfaces or faces separated by a dimension of relatively less thickness.
The flakes used are preferably primarily in the range of 2 to 50 microns of main surface equivalent circular diameter (ECD), where the equivalent circular diameter is the diameter of a circle having the same area as the main face.
More preferably, the metal flakes have an equivalent circular diameter of the main surface primarily in the range of 2 to 20 microns and, even more preferably, in the range of 3 to 15 microns.
Particles in the form of flakes or platelets are further characterized by having an aspect ratio (ratio of the equivalent circular diameter of the main face to thickness) of at least 2, and more preferably at least 5. Commercially available metal flakes can typically have aspect ratios of 5 to 40, or even greater.
The concentration of the metal flakes preferably ranges from 3% to 30% by weight, based on the total weight of solids.
More preferably, the metal flakes are used in the amount of 4% to 25% by weight, based on the total weight of solids.
Examples of usable metal flakes include those from Ciba Specialty Chemicals, a division of BASF, such as METASHEEN 91-0410 aluminum flakes in ethyl acetate, and NanoDynamics, such as copper flakes type C1-4000F, 4 μm, solid powder.
Other metal flakes include, but are not limited to, tin, gold, silver, platinum, rubidium, brass, bronze, stainless steel, zinc, and mixtures thereof.
In addition to pure metal flakes, materials coated with metal or metal oxide, such as mica coated with metal oxide, glass coated with metal oxide, and mixtures thereof can be used as metal flakes.
A golden tone can be achieved with real gold, however, copper and zinc, preferably in the form of an alloy, which depending on the composition can thus be referred to as brass or bronze, can alternatively be used.
Preferably, the ratio of copper to zinc fractions in the alloy ranges from 90:10 to 70:30. As the fraction of zinc in the alloy increases, the metallic gold tone changes from a more reddish golden tone to a more yellowish or even greenish tone.
The color of the golden tone can be enhanced by means of a controlled oxidation of the metal.
A silver tone can result from metallic flakes containing, among other possibilities, aluminum.
The metal flakes can be pre-treated with compatibilizing materials before incorporation into the first aqueous or oil phase.
Such materials can be fatty acids, amides, anhydrides, epoxides, phosphates or amines.
The compatibilizer can also be a dispersant having an HLB index of at least 8. The dispersant's HLB index is a measure of the hydrophilic / lipophilic balance of the dispersant and can be determined as described in “Polymeric Surfactants”, Surfactant Science Series, volume 42 , page 221, by I.
Piirma.
The general classes of preferred dispersants are water-soluble or water-dispersible surfactant polymers.
Preferred dispersants are by nature amphipathic.
This dispersant comprises in its molecule both an oleophilic group and a hydrophilic group of sufficient lengths to provide a stereochemical barrier large enough for interparticle attraction.
The dispersant can be non-ionic or ionic in nature.
These amphipathic dispersants are generally block copolymers, both linear and branched and having segmented hydrophilic and oleophilic moieties.
The hydrophilic segment may or may not include ionic groups and the oleophilic segment may or may not comprise polarizable groups.
Such dispersants are believed to function essentially as stereo-chemical stabilizers in protecting the dispersion against the formation of elastic and other flakes leading to an increased viscosity of the aqueous dispersion.
Ionic groups, if present, in the hydrophilic segment of the dispersant provide greater colloidal stabilization through ionic repulsion between the dispersed particles. The polarizable groups, if present, in the oleophilic segment of the dispersant further improve the association of the dispersant through these anchorage sites 5 with any metal particles prone to flocculation, which may be of a polar nature. Preferred dispersants comprise various poly (ethylene oxide) containing non-ionic and anionic block copolymers. Dispersants having anionic groups are particularly preferred. Most preferred are phosphated alkyl or aryl phenol alkoxylates such as SYNFAC 8337 obtained from Milliken Chemical, Spartanburg, SC. Various additives generally present in electrophotographic toner can also be added to the continuous polymer phase of the porous toner particles used in the present invention, such as charge control agents, waxes and lubricants. Appropriate cargo control agents are disclosed, for example, in US Patents 3,893,935;
4,079,014; 4,323,634; 4,394,430 and GB Patents 1,501,065 and 1,420. 839. Additional charge control agents, which are useful, are described in US Patents 4,624,907; 4,814,250; 4,840,864; 4,834,920; 4,683,188 and
4,780,553. Mixtures of charge control agents can also be used. Load control agents are generally employed in small amounts, such as from 0.1% to 10% by weight based on the weight of the total solids and preferably from 0.2% to 3.0%. Waxes usable in the present invention include low molecular weight polyolefins, such as polyethylene, polypropylene and polybutene, silicone resins, which can be softened by heating; fatty acid amides, such as oleamide, erucamide, ricinoleamide, and stearamide; vegetable waxes such as carnauba wax, rice wax, candelilla wax, Japanese wax, and jojoba oil; animal waxes, such as beeswax; mineral and petroleum waxes, such as montana wax, ozokerite,
ceresin, paraffin wax, microcrystalline wax, and Fischer-Tropsch wax, and modified products thereof.
Regardless of the origin, waxes having a melting point in the range of 30 to 150 ° C are preferred and those having a melting point in the range of 40 to 140 ° C are more preferred.
Wax 5 can be used in the amount of, for example, 1 to 20% by weight, and preferably 2 to 15% by weight, based on the total weight of the particles.
The wax can be incorporated into the toner in several ways.
The wax can first be dispersed in an appropriate polymer binder by melting composition and then mixed with the solvent to form the organic phase.
It can also be processed separately in a dispersion form in an organic solvent, with suitable dispersion aids for incorporation into the organic phase, or in water for incorporation into the first aqueous phase.
In all cases, the wax exists in the final particle as fine solid particles.
In an alternative process, porous particles containing encapsulated metal flakes can be formed by a spray and freeze drying process, as described in US Serial No. 12 / 766,944. In this process, a polymer material is dissolved in an organic solvent to form an organic phase to which metal or metal flakes are added to form a suspension, and droplets of the resulting suspension are formed by, for example, spraying the suspension through a capillary beak.
The droplets are spray-frozen to a cold environment where the solvent in the droplets is quickly frozen to form frozen solvent domains within the polymer, and the resulting cold solid droplets are dried, preferably under reduced pressure, so that the solvent is removed and porous polymer particles are collected.
The inventive metal flake containing porous toner particles can be applied to a substrate by a digital printing process, preferably an electrostatic printing process, more preferably by an electrophotographic printing process, as described in LB Schein, Electrophotography and Development Physics, 2nd Edition, Laplacian Press, Morgan Hill, California, 1996 (ISBN 1-885540-02- 5 7), or, by a coating process, preferably an electrostatic coating process, more preferably by an electromagnetic brush coating process, as described in the US Patent
6,342,273, published on January 29, 2002. The method for producing an electrophotographic image according to an embodiment of the invention, in particular, can comprise the steps of: producing an electrostatic latent image in a forming element primary image; developing the electrostatic imaging by taking the imaging in close proximity to the porous toner particles containing encapsulated metal flakes to form a developed image comprising the porous toner particles; electrostatically transfer the developed image to an appropriate substrate, and permanently fix the developed image to the substrate by fusing the porous toner particles to the substrate. The porous toner particles containing metal flakes used in the invention are suitable for both bicomponent and monocomponent development agents. The visible or developed toned image can be transferred from the primary imaging element directly to a final receiver, such as paper, transparency material, metal, various polymers and thermoset materials, etc. Although transfer can be carried out using an assisted thermal or thermal process, as is known in the art, it is preferable to use electrostatic transfer. While this can be accomplished using known means, such as a corona charger, it is preferable to use an electrically polarized transfer roller to press the receiver in contact with the primary imaging element containing the image while applying an electrostatic field.
In an alternative way of practicing this invention, the revealed toner image can be first transferred to an intermediate transfer element, which can serve as a receiver, but not as a final receiver, and then from the intermediate element 5 of transfer to the final receiver.
For fixing the toner image to the substrate surface of the final receiver, a contact fusion method, such as heated roller fusion, can be used, or a non-contact fusion method such as oven fusion, hot air, radiant, instant, solvent, or microwave.
The image is typically fixed to the final receiver by heating the marker particles to a temperature above the glass transition temperature of the toner particles.
The glass transition temperature of the toner particles can preferably be between 45 ° C and 70 ° C, more preferably between 50 ° C and 65 ° C, and more preferably between 50 ° C and 58 ° C.
According to an embodiment of the invention, the use of porous toner particles comprising empty, encapsulated metal flakes provides space for the flake-type pigments to be reoriented within the binder so that they are more parallel with the surface of the receiver substrate when fusing at high temperature, giving prints that exhibit a greater metallic tone and gloss or shine effect.
According to a further embodiment, the use of such porous toner particles containing metallic flakes can be employed to form a patterned image with relatively electrically conductive motifs, such as a printed circuit, by a similar electrophotographic printing process.
In such another embodiment, the reorientation of the metal flakes by melting similarly results in the flakes being aligned more parallel to the substrate, resulting in better electrical contact between metal flakes, and increased conductivity of the printed circuits.
For even greater reflectivity or when decreased electrical resistance is desired, the image can be molded against a soft heated roller or screen, using known techniques described in the literature.
The process of the present invention will now be more particularly described with reference to some examples that may reveal other additional aspects of the invention, but to which the present invention is not limited in scope.
The Kao Binder N polyester resin used in the examples below was obtained from Kao Specialties Americas LLC, a division of Kao Corporation, Japan.
Carboxymethyl cellulose of molecular hair of approximately 250K as the sodium salt, was obtained from Aqualon (Hercules). NALCO 1060, a colloidal silica, was obtained from Nalco as a 50 weight percent dispersion.
The OBRON SF-121 aluminum flakes (mean particle size 9 microns) were obtained from Cameo Chemicals.
SYNFAC 8337 was obtained from Milliken Chemical, Spartanburg, SC.
The wax used in the examples was the WE-3 ® ester wax from NOF Corporation.
The load control agent was FCA 2508N obtained from Fujikura Kasei, Japan.
Other chemicals were purchased from Aldrich and used as received.
Preparation of the wax dispersion: To a glass bottle containing a mixture of WE-3 wax (Nippon Oil and Fats, 25.0 g), TUFTEC P2000 dispersant (AK Elastomer, 5.0 g) and ethyl acetate (70, 0 g) zirconia beads (1.2 mm in diameter, 100 mL) were added. The container was then placed on a powder crusher (Sweco) and the wax was ground for three to five days.
Then, the beads were removed by filtration through a sieve and the resulting dispersion of solid particles recovered and particles have an average diameter of 0.55 microns.
EXAMPLE 1: (Invention) Porous toner containing aluminum flakes
A multiple emulsion process in conjunction with an evaporative limited coalescence (ELC) process, as described above, was used to prepare the porous toner in this example.
The first aqueous phase (W1) was prepared using 37.5 g of a 4% by weight solution of carboxymethylcellulose 5 cellulose in water, together with 34.6 grams of water, and a 2.5 gram OBRON premixed paste SF 121, aluminum flakes and 5 grams SYNFAC 8337. The oil phase was made using 141.7 g of 29.6% solution of Kao N resin in ethyl acetate, 16.4 g of a dispersion of 24.4 % WE-3 wax in ethyl acetate, containing 20% by weight P2000 dispersant based on wax, 0.75 g of an FCA 2508N load control agent and 88.5 g ethyl acetate.
For this oil phase, phase W1 was added followed by mixing with a Silverson L4R mixer equipped with a large bore disintegration head.
A portion (326 g) of the resulting water-in-oil emulsion (W1 / O) was gently stirred into 544 grams of an aqueous phase (W2), comprising 10.4 grams of NALCO 1060 in a pH 4 citrate / phosphate buffer using stirring magnetic.
The ethyl acetate was evaporated using a Buchi ROTA VAPOR RE 120, at 30 ° C under reduced pressure to obtain porous particles with discrete pores and multiple domains of metallic flakes in the particle.
The internal pore structure of the particles made by such a multiple emulsion process is illustrated in the Figures of US Patent Application Publications 2008/0176157, 2008/0176164, and 2010/0021838. The silica on the toner surface was removed at pH 12 using IN potassium hydroxide for 15 minutes.
The particles were then washed and dried.
The median particle size measured using Horiba LA-920 was 56 micrometers.
EXAMPLE 2 (Comparative): Solid toner containing aluminum flakes Kao N resin was dissolved in ethyl acetate and added as a 29.6% solution of a pre-mixed 2.5 gram OBRON SF 121 aluminum flakes paste and 5 grams SYNFAC 8337. To this was added and mixed in 16.4 grams of a dispersion of 24.4% WE-3 wax in ethyl acetate containing 20% by weight of P2000 dispersant based on wax followed by 0.75 grams of a load control agent 5 FCA 2508N.
This resulting oil phase was dispersed in 534 grams of a pH 4 citrate / phosphate buffer comprising 10.5 grams of NALCO 1060 followed by magnetic stirring.
The ethyl acetate was evaporated using a Buchi ROTA VAPOR RE 120, at 30 ° C under reduced pressure to give solid particles of metal flakes containing Kao N.
The silica on the surface of the toner was removed by stirring for 15 min at pH 12.5 using potassium hydroxide.
The particles were then washed and dried.
The median particle size measured using Horiba LA-920 was 67 micrometers.
FUSION: Solid versus porous toners containing metal flakes In order to demonstrate the ability of metal flakes to reflect light upon melting, porous (Example 1) and solid (Example 2) samples were first prepared by spreading an excess of particles over the substrate surface 118 gsm lustrogloss using a conventional stainless steel casing block and a separating blade 10 having a 0.254 mm gap.
The use of the spatula ensured that a uniform layer of particles was created on each substrate.
After the samples had been produced, they were passed through an experimental setup with an offline melter, internally heated to 185 C.
This experimental set-up of the smelter consisted of an upper, internally heated smelter roller having a spray-coated fluoropolymer coating and a stainless steel lower pressure roller.
To maintain the melting consistency, the upper casting roller was driven by a commercially available gear motor and the steel pressure roller spun freely.
After this fusion step, the two samples were examined with reflected light optical microscopy.
Special attention was paid to the orientation of the metal flakes within the molten regions.
Figures 1 and 2 are reflective optical images of a fused 5 toner particle formed from the comparison of solid toner particles (Example 2) and from porous toner particles comprising metal flakes, according to the invention (Example 1 ), respectively.
As is evident from these reflective optical images, the toner particle according to the present invention exhibited greater reflectivity due to the increased alignment of the metal flakes with the substrate surface, which results in an improved metallic appearance for images formed with such toner particles.

权利要求:
Claims (10)
[1]
1. Toner particle, characterized by the fact that it has an external particle surface and comprises a phase of polymer binder and metal flakes encapsulated therein, in which metal flakes 5 or platelets are substantially two-dimensional particles, having opposite main surfaces separated by a dimension of relatively smaller thickness, and having an equivalent circular diameter of main surface, primarily in a range of 2 microns to 50 microns, and an aspect ratio of at least 2, in which the toner particle further comprises discrete pores formed within the toner particle, such that the toner particle has an internal porosity of at least 10 percent by volume.
[2]
Toner particle according to claim 1, characterized in that the polymer binder phase comprises a solid compositionally continuous phase, and the discrete pores are dispersed within the solid compositionally continuous phase.
[3]
Toner particle according to claim 2, characterized in that the metal flakes are present primarily in the discrete pores.
[4]
Toner particle according to claim 2, characterized in that it additionally comprises a hydrophilic pore stabilizing colloid.
[5]
5. Toner particle according to claim 1, characterized in that it additionally comprises a charge control agent.
[6]
6. Toner particle according to claim 1, characterized by the fact that metallic flakes are substantially two-dimensional particles, having opposite main surfaces separated by a dimension of relatively less thickness, and having an equivalent circular diameter of main surface, primarily in a range from 2 microns to 20 microns, and an aspect ratio of at least 5.
[7]
7. Toner particle according to claim 1, characterized by the fact that the metal flakes are present in a concentration of 3% to 30% by weight, with respect to that of the polymer binder.
[8]
8. Toner particle according to claim 1, characterized by the fact that the particle has an internal porosity of 20 to 90 percent.
[9]
9. Method for making toner particles as defined in claim 1, characterized in that it comprises: providing a first aqueous phase comprising dispersed metallic flakes; dispersing the first aqueous phase in an organic solution containing a polymer binder to form a first emulsion; dispersing the first emulsion in a second aqueous phase to form a second emulsion; shearing the second emulsion in the presence of a particulate stabilizing agent to form droplets of the first emulsion in the second aqueous phase; and evaporating the organic solution from the droplets to form porous toner particles with metal flakes encapsulated therein.
[10]
10. Method for forming a toner image, characterized in that it comprises: forming a toner image on a substrate, wherein the toner image comprises toner particles as defined in claim 1 comprising porous toner particles with metal flakes encapsulated in the same; and fixing the toner particles on the substrate by applying heat to fuse the toner particles on the substrate, where pores within the toner particles provide space for the metal flakes to reorient themselves within the binder phase of the toner particles to become relatively more parallel with the surface of the receiving substrate when fusing.

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法律状态:
2020-08-11| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

2020-08-18| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

2020-12-08| B11B| Dismissal acc. art. 36, par 1 of ipl - no reply within 90 days to fullfil the necessary requirements|

2021-11-03| B350| Update of information on the portal [chapter 15.35 patent gazette]|

优先权:

申请号 | 申请日 | 专利标题

US12/766,939|US8614039B2|2010-04-26|2010-04-26|Toner containing metallic flakes and method of forming metallic image|

US12/766939|2010-04-26|

PCT/US2011/033155|WO2011136997A1|2010-04-26|2011-04-20|Toner containing metallic flakes|

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