DE1963785A1 - Electrographic pigment images from pigment - resin images - Google Patents

Abstract

Pure electrophotographic pigment images are obtd. by treating image obtd. with conventional pigment toner in resin binder with solvent for resin only. Pigment image has more uniform props. than pigment/resin image and is suitable for prodn. of printing plate or as cover material for etch processes; pigment image can be transferred easily.

Description

Imaging method The invention relates to an imaging method, with the aid of a toner made of pigment material distributed in resin on a base a toner image is produced.

In electrophotographic imaging processes such as those taught by U.S. Pat 2,297,691 discloses an electrophotographic imaging plate with a photosensitive insulating layer first evenly charged so as to cover its entire surface to sensitize. The optical disk is then exposed to a source of activating electromagnetic Radiation, such as light or X-rays, exposes that is, selectively the charges in degrades the illuminated areas of the non-sensitive layer, so that an electrostatic Charge image remains in the non-illuminated areas.

This charge image is then developed and made fine by deposition distributed marking particles or toner visible on the photosensitive layer made. If desired, the toner particles can be deposited on a second surface, e.g. a sheet of paper, transferred and affixed to it, in order to be permanently visible To produce a reproduction of the original.

The charge image can be formed by any suitable development method developed will. Typical methods apply e.g.

Cascading, a so-called magnetic brush, aerosol or a Hand pollination.

Usually the toner is composed of one or more organic resins as a powder base and a dye for the desired coloration of this powder and for permanent marking of the area to be developed. Typical toners and development processes are for example in U.S. Patents 2,297,691, Re 25,136, 2,618,551, 2,618,552, 2,638,415, 2,659,670, 2,788,288, 2,917,460, 3,041,169, 3,179,342 and 3,212,888.

From the foregoing, it can be seen that the finished one formed by the toner Image usually consists of a resinous binder in which the marking material or the color pigments are dispersed. Since suitable triboelectric relationships are necessary are, for example, with the cascading brushes, with magnetic brushes or in another Wise working development process is required in which the carrier beads The pigment-resin-toner particles electrostatically attract, a pigment-resin-toner mixture preferred to ensure a suitable triboelectric behavior between the developer mixture Easily set from carrier material and toner as well as the charge image to be developed to be able to. However, there is a need for an imaging method with which a pigment image can be produced free of the resinous base material, as a Pigment image has uniform properties that are different from those of pigment-resin toner images differentiate advantageously. For example, a pure pigment image is for special applications suitable, e.g. for the production of printing plates or as a cover material for Etching techniques. In addition, a pigment image can be moistened or transferred according to processes which differ advantageously from those used for pigment-resin images. A pure one created from a pigment-resin image Has pigment image the further advantage that first a pigment-resin image is produced and then to each the time desired by the user can be converted into a pure pigment image.

The object of the invention is therefore to find a new imaging method to create a pigment image from a pigment-resin image can.

In the case of an imaging method, this task becomes the one mentioned at the beginning Type solved according to the invention in that to produce a pure pigment image the pad is immersed in a resin dissolving solvent.

With the help of this procedure, it is made in an amazingly simple manner the resinous basic component of the toner by dissolving it in a pigment and removes non-corrosive solvents from the base. All conventional Pigment-resin toners can be used, such as those described in the numerous above mentioned patents are given. Any kind of softenable resin, which sinu suitable for toner can be used. Typical materials are e.g. Staybelite Ester 10, a 50 hydrogenated glycerine rosin from Hercules Powder Co., Piccotex 100, a styrenic resin from Pemisylvania Industrial Chemical CoO, Araldite 6060 and 6071, an epoxy resin from CIBA, and Velsicol X-37., Are available from Velsicol Chemical Corp., 5 weight percent polycarbonate in CHCl2, 20 weight percent Piccodione in toluene, 20 percent by weight silicone resin in toluene; also polyolefins like polyethylene; Polypropylene; chlorinated polyethylene; chlorosulfonated polyethylene; Vinyl and vinylidenes such as polystyrene; Polymethylstyrene; Acrylic polymers such as polymethyl methacrylate, Polyacrylic acid, polyacrylonitrile; Polyvinyl esters such as polyvinyl acetate, polyvinyl alcohol, Polyvinyl butyral; Polyvinyl chloride; Polyvinyl carbazole; Polyvinyl ether, Polyvinyl ketones; Fluorocarbons such as polytetrafluoroethylene; Polyvinyl fluoride; Polyvinylidene fluoride; Polychlorotrifluoroethylene; different chain thermoplastic materials, e.g.

Polyamides such as polycoproloctam, polyhexamethylene adipomide; polyester such as polyethylene terephthalate; Polyurethane; Polypeptides such as casein, zein; Ether and Acetal polymers such as polyoxymethylene, polyglycol, polysulfide; Polycarbonates; Cellulosic polymers such as viscose, cellophane, cellulose acetates as well as mixtures and copolymers them.

The pigment material for the pigment-resin-toner can be any pigment which does not dissolve in the solvent for the resin. Typical pigments are z0B. Soot, garnet, iron oxide and all insoluble in the respective solvent Colors, such as Prussian blue.

The solvent can consist of any suitable liquid, in which the resin of the toner dissolves, the carrier base and the pigment but remain unaffected.

If desired, it can be used to soften the resin before dipping it in the solvent heat will be applied. In addition, prior treatment can be used be made with solution vapors. The only requirement for the solvent is that only the resin dissolves in it and that it has an electrically insulating effect, so that the charge image cannot be discharged through the solvent0 Typical Solvents include cyclohexane, Freon 113, Sohio Odorless Solvent 3440, pentane, Heptane, toluene, trichlorethylene, methyl ethyl ketone, methylol chloride, acetone and others.

A few seconds of immersion in the solvent is usually sufficient to in order to remove the resin, however, the immersion time is not critical, as the base and the pigment are chosen so that they do not dissolve in the solvent.

Although the particle size of the pigment-resin-toner used is not is critical, the particle size is usually between about 1 to 30 microns in diameter. These substances can be produced in any process, e.g. in the patents previously cited0 U.S. Patent 2,917,460 describes, for example, a suitable method for making pigment-resin toner.

The advantages of the new imaging method specified according to the invention and further details can be found in the following description with reference to the drawing emerged. In detail: FIG. 1 shows a schematic sectional illustration of one of FIG a pigment-resin-toner image formed on a base, Fig.2 the same Underlay in the solvent and Fig. 3 the underlay with the picture after application of the solvent 0 in Fig. 1 is on an insulating base 10 is an electrostatic charged pigment-resin toner image 11 is applied, which consists of a resin 12, in which a pigment 13 is distributed, which is in image configuration on the base As shown in Fig. 2, the charged toner image is placed in a bath 14 immersed in a solvent that acts only on the resin 12. The insoluble one Pigment remains to adhere electrostatically to the insulating substrate 10, while the soluble resin is dissolved in the liquid. In Fig. 3 is the emerging To see pigment image 13, which remains on the base 10, the resin 12 is completely dissolved. By the treatment sequence shown in Figures 1 to 3 Thus, a pigment-resin toner image can be effective by using one only for the resin Solvent into a pure pigment image being transformed. To the solvent treatment, the pigment image remains on the substrate without any noticeable loss of original image resolution and density.

At this point, however, the pigment is not yet chemically fixed, but is only bound electrostatically to the base. If desired, can the pigment image can be made more permanent with any suitable fixative.

The base on which the pigment-resin-toner image turns into a pure pigment image converted can be made of any material that is present in the solvent does not solve.

It can be an insulator or a conductor, as is commonly used in electrophotography be used. The base can be a metallic sheet, fabric, foil, Be cylinders or the like; it can be a glass plate with an electrically conductive one Coating or a conductive coated sheet of paper or sturdy plastic sheet. Typical insulators are paper and plastics such as Mylar.

The pigment image produced according to the invention can be used in conjunction can be used with any process to produce a pigment-resin toner image, that is electrostatically bound to a surface, such as z0B. in electrophotography, in the case of an electrophotographic described, for example, in the aforementioned patents Image generated on a photosensitive plate and then on a suitable surface, as shown in Figures 1 to 3, is transmitted. The transferred pigment-resin toner image is then, as already described, into a pure by using a resin solvent Pigment image converted.

However, the invention is also for converting such pigment-resin toner images suitable, which are produced on a substrate coated with a soluble resin. This coating can be made of the same material as the resin or the toner the end another soluble resin. Of course, the backing itself must be insoluble while both resins are dissolved upon immersion in the solvent.

The invention is also in connection with those produced by other methods Applicable to images. These images can be on an insulator or a conductor like aluminized mylar, created by first covering the entire panel surface a uniform pigment-resin-toner layer is applied. A selective mask in the form of the desired image is placed therein over the toned plate. An electrostatic charge, e.g. a corona charging device described in US Pat. No. 2,777,957 upset. Depending on the particular pigment-resin-2oner, the toner is either to a positive or negative charge with a permanent potential of about 2 charged to 160 volts or higher. The uncharged and electrostatic not Bound toner is then removed from the conductive surface by mechanical effects, like z0B. an air stream, removed so that the charged toner particles are in an image configuration lag behind. After that, the pigment-resin toner image is treated with a solvent for treated the resin as previously described.

In another embodiment, the conductive support plate or Pad evenly with an adhesive or sticky material such as Vaseline, Fingerprint grease, Kodak photoresist available from Eastman Kodak Co., or one other adhesive material coated. Subsequently, the toner is selective through a Mask or stencil applied through to the adhesive material, so that the Toner adheres to the adhesive material in an image configuration. Then will then created a pure pigment image with the help of a solvent. With another Design of this embodiment, the adhesive material is already selective in Image configuration applied to the substrate, whereupon the toner is spread evenly over the entire surface, but only in the adhesive areas the document is bound.

The thickness of the pigment-resin toner image is not particularly critical and can take any suitable dimension and have layers about 1 to 50 microns thick proved to be satisfactory. That changes after using the solvent The resulting pure pigment image is correspondingly thinner compared to the specified dimensions.

The following examples are intended to further illustrate the invention which the pigment images are made. The percentages in the description, the examples and claims always relate to weight, if not expressly is stated otherwise. The following examples are intended to illustrate various preferred embodiments to convert a pigment-resin toner image into a pure toner image give example I An electrophotographic imaging plate with a glass shape approximately 40 microns thick Selenium layer on an aluminum backing made according to the specifications of U.S. Patent 2,970,906 is uniformly applied with a corona charger in U.S. Patent 2,777,957 to a positive potential of about 600 volts. The plate is then under darkroom conditions with a light image at about 107 Luxsec exposed so that an electrostatic image is created. The charge image is then developed by cascading, using a standard substrate of glass beads U.S. Patents Re 25,136, 2,788,288 and 2,618,551. The toner consists of about 40 parts polystyrene, 15 parts poly-N-vinyl methacrylate and 5 parts Soot. A toner image is created in the charged areas the Image plate.

Example II The toner image of the electrophotographic imaging plate Example I is electrostatically transferred to a sheet of aluminized nylar, that of a 5 micron thick Mylar base and a sub-micron thick aluminum coating consists.

The charged toner image is then placed in a bath of liquid trichlorethylene Immersed for about 2 seconds, pulled out, and dried. In the end it remains a pigment image of good resolution and high density on the Mylar backing, while the resin parts of the toner were dissolved away. Example III On a conventional one electrophotographic imaging plate with a vitreous selenium layer of about 40 Micron thickness on an aluminum base according to Example I, a toner image is produced. A toner made from 9 parts of 35:65 copolymer of n-butyl methacrylate is used and styrene, one part polyvinyl butyral and one part carbon black Example IV The toner image according to example III is electrostatically applied to aluminized Mylar according to example II transfer. The transferred toner image is placed in a container with its backing immersed in liquid cyclohexane for three seconds. The pad then becomes pulled out and dried. It shows a good resolution and high pigment image Image density.

Example V A sheet of conventional rice burlap becomes even dusted with a toner composed of 9 parts of polyvinyl toluene and one part of carbon black, so that sioh results in an even layer of toner on the paper. A selective mask in the form of the The image is then placed on the paper. A positive one electrostatic charge is generated through the openings of the mask with the help of a Corona charging device of U.S. Patent 2,777,957 applied to a permanent Generate potential of about 100 volts in image configuration. The loading device The device and the stencil are removed and the sheet is shaken several times to remove the Remove toner from uncharged areas. The toner image is then saved in immersed a bath of methyl ethyl ketone for about four seconds. The misery is pulled out and dried. A good pigment image whence the resolution quality and density is obtained.

Example VI A sheet of paper becomes even with a thin film Vaseline covered. A stencil in the form of the picture is then placed over the sheet. A thermoplastic resin made from 30 parts of polystyrene, 10 parts of methyl polymethacrylate, 30 parts of butyl polymethacrylate, 20 parts of o-acetoacetotoluidide and 10 parts of carbon black is dusted over the stencil, so that a toner image on the adhesive Vaseline arises in the template configuration. The stencil is removed and the toner image charged to about 80 volts. The pad is then immersed in a bath of liquid aoetone immersed for five seconds 0 The pad is pulled out and dried. A pigment image of high resolution quality and density is created.

Although certain substances and compositions are mentioned in the foregoing Descriptions of the preferred embodiments have been given, others may appropriate materials and procedures are used to achieve similar results will. In addition, other materials can be applied and changes made that perfect, improve or otherwise modify the pigment image.

Claims (6)

Claims 'Imaging process in which with the aid of a toner made from dispersed in resin A toner image is produced on a base pigment, characterized in that that in order to produce a pigment image, the substrate (10) dissolves in a resin Solvent (14) is immersed. 2. Imaging method according to claim 1, characterized in that the base (10) is provided with a coating which is detachable in the solvent (14) will. 3. Imaging method according to claim 1, characterized in that the toner image (11) formed on an electrophotographic imaging plate and electrostatically is transferred to the base (10) 0 4. Imaging method according to claim 1, characterized in that the base (10) is uniformly coated with a resin (12) distributed pigment (13) containing toner (11) is coated that by charging an electrostatic image on the coated surface through an image stencil Base (10) is produced and that the non-charged toner particles (11) of the pad (io) must be removed. 50 imaging method according to claim 1, characterized in that the base (10) is provided with a uniform coating of an adhesive substance and that this surface is stenciled through a picture with a toner (11) is dusted, which has pigment (13) distributed in resin (12). 6. Imaging method according to claim 1, characterized in that that the base (10) is provided with an adhesive substance in the image configuration, that the base (10) is uniformly coated with a pigment (13) distributed in resin containing toner (11) is dusted and that the toner (11) does not form the image contributing areas is removed.