DE2103514A1 - Dye for inverse block printing - Google Patents

Abstract

A water-absorbent dye/colouring mixture for printing in presence of a dye-repulsive, hydrophobic background (vapour) liquid with a water-miscible carrier containing a colouring agent, contains 0.1-20% by wt. of an additive having only limited solubility in the carrier but being substantially-miscible with the liquid. The dye mixture can be employed in lithio printing.

Description

Inverse planographic printing ink The invention relates to a water-receptive one Ink preparation for printing in the presence of an ink-repellent, water-repellent Liquid for the non-printing areas, which consists of a water-miscible, a dye-containing carrier.

The planographic printing is based on the mutual immiscibility of water-based and non-polar, organic liquids. With conventional planographic printing, a plate is used on which of the non-printing areas a water-based The dampening solution is attracted and held in place and the oily or greasy color only covers the printing areas, from which they are then either directly onto the material to be printed or, as in offset printing, onto a rubber blanket from which it is then transferred to the material to be printed. The 01 as Inks containing raw materials have unpleasant odors that conventional planographic printing does unsuitable for many purposes, notably in the food packaging industry do.

In reverse planographic printing, the printing plate or the duplicating stencil has non-printing areas, which are preferably water-soluble or water-miscible Attract paint-repellent liquid. A paint that can be mixed with water is made according to of the invention defined as a color that is mixed with water or with one with water miscible liquid such as glycol, which is miscible with water Color is preferably captured by the image areas and then applied to the Transfer material to be printed. Printing process, the plates for reverse Using planographic printing are described in German Offenlegungsschriften 1 671 526, 1 911 789 and 2 012 878 are proposed.

These printing processes use a printing plate or die that on a carrier sheet, suitably made of a small, thermoplastic resin, e.g. Polystyrene, consisting, is formed. The image pattern is carried by the arch and is composed of a material that is selectively attractive to liquid, Water-miscible printing inks are effective.

The non-printing areas of the carrier sheet become ink-repellent made by applying a film of a liquid immiscible with water to it becomes, e.g.

a nicilt-polar, water-repellent, liquid hydrocarbon. In practice it has been found that the liquid often re-hits the printing plate must be applied, usually after multiple copies have been reproduced or the non-printing areas take on some color, so that the background of the prints becomes unclean.

Therefore, according to the invention, a paint preparation is provided which useful in reverse planographic printing by eliminating the need for water-based, color-repellent liquid in the non-printing areas of the Reduced printing plate, and which is characterized by from 0.1 to 20 wt * one An additive which has only limited solubility in the carrier, but essentially is miscible with the liquid.

The invention is clarified by the following detailed description easier to understand in connection with the drawing.

These show: FIG. 1 a schematic view of a printing process usable printing form according to the invention; Fig. 2 is a schematic view of a Type of printing machine useful in connection with the invention, and Fig. 5 is a schematic view of another type of printing machine for use in FIG practicing the invention.

Printing method according to the invention can be with a printing plate or Working printing form 10, which is formed from a carrier sheet 12, which in a suitable Made of a light-colored thermoplastic resin, such as polystyrene, the one of a kind that selectively attracts water-miscible, liquid printing inks Pattern 14 carries. During printing, the non-printing areas 16 of the carrier sheet 12 for the printing inks by applying a film 17 of a non-water-miscible Liquid, such as a non-polar, water-repellent, liquid hydrocarbon, made repulsive.

The carrier sheet is formed from a material that is preferably by a liquid immiscible with water or water-miscible liquids is wettable. The carrier sheet is preferably made of synthetic, organic Resins formed because such resins are usually organic, water-immiscible liquids are compatible. The sheet can be made from thermosetting or thermoplastic resins are formed. Preferably it consists of bright, thermoplastic sheets of Hydrocarbon resins such as polystyrene, polyethylene or polypropylene, the easier by liquid hydrocarbons than by water or water-miscible ones Liquids such as

Glycols, are wettable. The carrier sheet can also be made of polyethylene terephthalate, Cellulose ethers or cellulose esters, such as ethyl cellulose, cellulose acetate, Cellulose butyrate or copolymers of hydrocarbon monomers, such as .3. Acrylonitrile styrene copolymer, Acrylonitrile-butadiene-styrene copolymer, ethylene-propylene copolymers, ethylene-vinyl acetate copolymers or monomer-modified, unsaturated polyesters.

The image pattern that occupies an area of the smooth carrier sheet, can be evenly coarse or roughened to produce a dull, grainy surface to form, which has an increased ability to hold on to the ink-repellent liquid in the canals, irregularities or Has cavities. The treatment can be chemical, thermal, mechanical Ways or by any combination of these procedures. For example can the sheet with sandpaper, wire brushes, abrasive powders, indenting a variety of needle-shaped projections into the surface, wire gauze or irradiation of an air or a liquid mixture of abrasive powder are roughened. The aforementioned Techniques can be used simultaneously with either thermal or chemical softening of the arch with solvent or after the arch has been softened by these treatments be performed.

The image pattern 14 or the printing areas are expediently made of one organic resin formed which has good affinity for a water-miscible one Liquid, such as glycols, and very low affinity for glycol repellants Liquids, such as hydrocarbon oils, shows. Suitable resins are copolymers vinyl acetate and ethylene and polyester resins, e.g.

the Goodyear product known under the trade name Vitel 222 Rubber Co.

The image areas may contain pigment particles dispersed in the resin film contained, resulting in a rough surface for holding the paint within the Gaps between the pigment particles can lead. The picture areas become functional by directly painting, writing or drawing a picture on the roughened Surface of the sheet with a solution of resin or resin and pigment or formed by applying said solution to the sheet through a sieve that has openings at the desired image areas to be reproduced. The solution is then used to drive off the solvent and anchor the resin or resin-pigment dispersion heated on the carrier sheet. Such printing forms have an image-free area, which consists of the treated carrier sheet, which is preferably immiscible with water Liquids adsorbed, while the printing surfaces are preferably those on with Attract water-miscible liquid-based paint.

The pigment dispersed in the resin is preferably photoelectric Conductive material, such as zinc, can also consist of other photoelectrically conductive materials Substances exist, such as selenium, cadmium sulfide or cadmium selenide. The printing form can then be produced by the process described in the German Offenlegungsschrift 1,671,526 and incorporated herein by reference.

According to this technique, the printing form is made by transferring the image areas the photoconductive layer an electrophotographically on a transfer sheet generated copy.

The transfer sheet is preferably transparent to infrared radiation, thermoplastic material that has a melting point close to that of the photoconductive layer Has. So when the transfer sheet to rest on the electrophotographically generated Arc is brought and radiation is passed through, the transfer sheet melts only slightly in the areas that correspond to the image areas, the more so those that have been removed Better to weld parts of the image of the photoconductive layer onto the transfer sheet. The procedure is usually carried out with a tone-giving bow, and these toning particles contribute to the selective application of radiation on the picture surfaces at; they can also be thermoplastic or fusible substances included, which are intended to participate in the transfer and melting of the photoconductive Slips on the transfer form to participate. The transfer preferably leads to sharply delimited, slightly raised image areas generated on the transfer sheet.

If water-mixable paints and non-water-mixable, liquid hydrocarbons When applied to these plates, the paint turns out to be the hydrocarbon replaced on the color-oxide image areas and removed from the roughened, non-printing Surfaces of the polystyrene carrier sheet is repelled.

This is apparently based on the respective heat of wetting and leads accordingly to the fact that the ink preferably wets the printing areas while the liquid hydrocarbon preferentially adheres to the non-printing areas.

The printing form can be used in the printing system illustrated in FIG use. In this case, the printing plate 10 is attached to a plate cylinder 20. A hydrophilic paint is supplied by an paint supply 22 and a group of paint rollers 24 applied to the printing plate 10. The water-repellent liquid is also applied separately to the printing plate 10 by dampening rollers 26 supplied by a container or supply 28 for water-repellent liquid be fed. A sheet of paper or other to be printed on or decorated Material is passed between the impression cylinder 32 and the plate cylinder 20. Notwithstanding this, the color can be applied to a blanket cylinder (not shown) transferred and printed on the paper by means of an offset printing process.

When the cylinders rotate, the water-repellent liquid becomes speed applied to the plate 10. If the paint is mixed on a water-based basis Plate 10 comes, it displaces the liquid hydrocarbon on the zinc oxide image areas and is from the non-image areas coated with liquid hydrocarbon of the polystyrene carrier sheet. The colored image material is transferred to the Transfer sheet of paper 30.

The ink and the printing matrix according to the invention can be used for printing of multiple copies in a direct and convenient way using common planographic printing equipment to be used.

The printing plate and the ink according to the invention can also to make prints made by direct application of the color in a system in which the ink and the ink-repellent liquid of the non-image areas are intimately mixed before application on the printing plate. Such a technique is proposed in German Offenlegungsschrift No. 20 12 878.

According to FIG. 3, the plate cylinder carrying the printing plate 10 20 Hydrophilic paint is supplied by a series of paint rollers 34. A water repellent Liquid for the non-image areas, such as a hydrocarbon oil, is used onto one of the rollers 36 dripped from an oil dripping device 38. The oil dropped on the roller 36 is mixed into the paint by the following rollers or rolled so that it is evenly dispersed in the ink when it hits the plate cylinder 20 reached.

The roller 36 onto which the oil is dropped must follow the rollers far enough back so that the oil is rolled evenly into the paint. Two or more rollers behind the plate cylinder 20 appear appropriate. The required The amount of oil is very small, it varies with the viscosity of the color, the higher the color Viscosity, the smaller the amount of oil that has to be used. For example, if a Paint that has an average viscosity of about 120 poise is used, 0.03 cm3 of oil is needed for 5 to 10 prints each. With a higher viscosity, such as 300 poise, only about 0.02 cm of oil is needed.

The vehicle for the paint generally comprises a water-receptive one Liquid that is thinner than e.g. water or a polyhydric alcohol, and a Binder resin. Examples of polyhydric alcohols are glycerine, ethylene glycol, diethylene glycol, Dipropylene glycol, tetraethylene glycol, pentaethylene glycol, hexaethylene glycol, triethylene glycol, Propylene glycol and polyethylene glycols of molecular weight 100 to 500. The preferred The diluent is triethylene glycol as it differs well from the pigment-in-resin dispersion separates and has a low toxicity. The color composition typically contains Case about 10 to 45, and preferably 15 to 40 parts by weight of resin solids.

The binder is useful as an oil that is indelible in the thinning agent, However, organic resin insoluble in the hydrocarbon background liquid. A preferred resin is a shellac soluble in glycol. Other resins made with the shellac solution are blended or can replace them aliphatic and aromatic ketone resins, alkyd resins, phenolaldehyde resins, ureaaldehyde resins, Dicyandiamidaldehyde resins, melamine aldehyde resins, zein resins, adducts of rosin (technical Dehydroabietylamine; see Römpp 1962, Bd.D, Sp.

4553) with fumaric acid, maleic acid or other unsaturated acids, Yacca resin, Damar resin, Manila resin, copolymers of vinyl monomers and alpha-beta unsaturates Acids or the like, polyamines and polymeric imines such as polyethyleneimine.

Examples of resins are polyamines such as PEI-6, PEI-12 and PEI-18 (Dow Chemical), Albertol 387, a phenol aldehyde resin (American Hoechst), Manila Loba resin, Dicyandiamidiormaldehyde resin, melamine formaldehyde resin, modified with fumaric acid Rosin, FCD Resin 788 an alkyd resin, FCD Resin X 4259, an alkyd resin, or FCD 4153, a rosin ester (France Darling and Campbell) or Cymel 301, a hexamethoxymethylene melamine (American Cyanamid).

To improve the press stability of the color, the Acidity of the essentially anhydrous system, the glycol and acidic film formers includes acid numbers above fifty to values close to neutrality reduced or made alkaline. The pH of the system is preferred held at values of about 6 to 9. With systems that make a substantial contribution of water, the preferred pH is greater than 7. However, if the press stability is not particularly critical, as is the case with high-speed printing, wherein the paint on the rollers is quickly renewed, or with little moisture or in the case of presses with few rollers, the color can tolerate a pH value of less than 7.

Appropriate reagents for reducing the acidity of the paint mixture are amines, imines or hydroxides starting with 1 to 8 wt. And preferably 2 to 5 wt. Of the mixture are present. A preferred reagent is an aliphatic one Amine, such as a lower alkyl primary amine containing 1 to 10 carbon atoms, such as ethylene diamine. Other suitable substances are ammonia, ethylamine, dimethylamine, Trimethylamine, ethylamine, diethylamine, triethanolamine, quaternary amines, morpholine, Pyridine, ethylene imine, propylene imine, lithium hydroxide, sodium hydroxide, potassium hydroxide, Ammonium hydroxide or the like.

The paint mixture can contain a pigment, such as carbon black, the large one Particle dimensions of about 24 m2 surface per gram of pigment. The pigment if present, can have a concentration of about 5 to 35 wt. The preferred one The range is 15 to 30% by weight. If similar soot of smaller particle dimensions is needed, it is preferably present in a concentration of less than 30%, while soot particles of larger dimensions are used in larger concentrations could.

Other black pigments, such as charcoal, lamp soot, graphite, Molybdenum oxide, iron oxide can take the place of all or part of the carbon black step. Colored pigments, such as phthalalocyanine blue, poluidine red, chrome yellow, Hansa yellow, titanium oxide or the like. can be used.

The dye can be acidic or basic and for coloring the Used to mix colors or to intensify the color of a pigment suspension. the Dyes can be used in a narrow range of 0.1 to 30% by weight, preferably 0.5 to 10% by weight, to be present. A further reduction in the need for water-repellent background liquid, more intense color effect and less harmful effect on the printing plate detected when using acidic dyes.

The acidic dyes can be organic, azo, triaryl methane or Anthraquinone series, the nitro, carboxyl or sulfonic acid groups, preferably the latter contain. The dyes are in the aqueous or polyhydric alcoholic Soluble diluent. As the sulfonic acid group in the acidic dye usually is more reactive than the acid group in the film-forming or binder resin preferably with the alkaline reagent first, and their color will be fully developed.

In the case of a color mixture containing a suspension of a pigment, such as carbon black, are acidic dyes such as e.g.

Losol Black, known under the following American trade names BC 40620, Acid Violet 12B (Acid Violet 12B), Acid Alizarin Violet N (Fast Green Extra Blueish) (Acid Alizarin Violet N (Real Green Extra Bluish)), Violamines B (Fast Acid Violet B) (true acid violet 3), Violamine R (Fast Acid Violet R) (true acid violet R), Fast Acid Blue R, Diamond Black F, Naphthol Black 3, Naphthylamine Black B, Benzopurpurin 4B, Indigo Disulpho Acid, Anthracene Blue WR, Acid Alizarin Blue 2B, Diamine Violet N, Diamine Black RO, Congo Violet, Hessian Bordeaux, Acid Blue, Acid Fast Navy Blue (Sulfacyanine 5R EX), Wool Violet 4 BN, Benzyl Violet (Acid Violet 6B) or the like, preferably in the range from 0.5 to 8 wt. the color mix present.

To stain colors other than black, you can use other acidic dyes as the sole colorant or in combination with various other colored ones Pigments are included in the color mixture. When the dyes are the only ones coloring substance are used, they are preferably used in combination with an aniphoteric or alkaline film former, such as casein, gelatin or Polyalkylenimine Resins such as polyethyleneimine, polypropyleneimine or the like., used.

Acid dyes suitable for this purpose are, for example known under the following American trade names: Acid Alizarin Red B (also Solochrome Red B), Acid Brown, Acid Cyanine, Acid Fast Red 3B, Acid Fuchsin (acidic fuchsin), Acid Green G (also Light Green SF Yellowish), Acid Milling Red RN (also called Cyanine E'ast Scarlet 33), Acid Orange (also known as Orange II), Acid Orange G, Acid Phloxin GR, Acid Rhodamine B, Acid Yellow (also known as Orange IV), Acid Yellow R (also known as Metanil Yellow known) or the like.

The water-repellent liquid for the non-image areas should compared to the paint thinner, no solubility exceeding 0.5 molar fraction exhibit. The ink-repellent liquid is expediently a hydrocarbon oil, a silicone oil or other water-absorbing, paint-repellent liquid.

A very satisfactory operation on typical planographic printing presses can be achieved with kerosene oil fractions that pass between 200 and 3200C. A commercial material, Deodorized 520 Oil from Magie Brothers Co., is a kerosene oil fraction, which passes between 270 and 300 ° C. Another product, Deodorzed 400 Oil, works 2 between about 205 and 2300C, and Isopar G is a mineral oil fraction that is between passes around 155 and 1700C.

Mineral oil, animal oil or petroleum fractions of higher or higher lower boiling point range can also be used. For example, can Mineral oil distillates, luminous oil or polymethyl siloxane oils as the water or polar Liquid repellent substance can be used. More prints each printing plate and better operating results can be obtained when in the non-polar liquid the material forming the carrier sheet is also not soluble. For this reason are preferably liquids that have a high percentage of aromatic hydrocarbons have, then if polystyrene is the sheet material, avoided a To reduce swelling and dissolution of the plate.

The liquid should consist essentially of aliphatic hydrocarbons consist, which are generally free of aromatic hydrocarbons.

The one used to reduce the need for a water-repellent background liquid The additives used are compatible with the resin, but have limited solubility in the carrier diluent. The film-forming binder resin is preferably im substantially insoluble and soluble in the background water-repellent liquid in the diluent. However, the additive has significant solubility in or Miscibility with the water-repellent background liquid. The addition is present in the color mixture with 0.1 to 15 wt.%, preferably from 6.2 to 8 wt.%.

The additives according to the invention are generally substituted, long chain hydrocarbons or esters of inorganic acids. The substituted one Hydrocarbon can be an aliphatic hydrocarbon of 6 to 24 carbon atoms which contains at least one substituent selected from the carboxyl, estes * hydroxyl, Amino and amido existing group is selected. The esters of inorganic acids can be an ester of an alcohol containing 1 to 10 carbon atoms and a Acid such as silica, phosphoric acid, or sulphurous acid.

The additive is preferably a synthetic or natural saponifiable one Oil, such as a fatty acid or a polymer of such. Since the alcohol, amino or amido derivatives in general by reducing the corresponding fatty acid esters are obtained, they can be classified precisely as oleic or fatty acid derivatives.

The vegetable oil can expediently include linseed oil, castor oil, soybean oil, Be safflower oil, coconut oil, or tung oil. Good results can also be achieved with fatty acids achieve, e.g.

with lauric acid, coconut oil fatty acid, oleic acid, hydroxystearic acid, Stearic acid, tall oil acid, dimerized or trimerized C16 to C18 acids, castoroleic acid, ealmitic acid, caprylic acid, pelargonic acid, capric acid, myristic acid, arochidonic acid, Behenic acid and lignoceric acid.

The addition can also be an ester of one of the fatty acids with an alcohol or low molecular weight glycol containing 1 to 10 carbon atoms, such as methyl alcohol, ethyl alcohol, butyl alcohol, amyl alcohol, ethylene glycol, Diethylene glycol, propanol or the like. Examples of esters are methyl ricinoleate, ethyl palmitate, butyl caprilate, amyl pelargonate, glycol oleate, diglycol oleate, hydroxypropyl laurate, Hydroxyethyl hydroxystearate, hydroxyhexyl capramate, methyl laurate, esters of ricinoleic acid and trimethylol propane or ethane, isoctyl epoxystearate, esters of soybean fatty acid and pentaerythritol, esters of tall oil acid and sorbitol.

Long chain alcohols containing 6 to 24 carbon atoms gave also a reduction in the need for a water-repellent background liquid. Examples of such alcohols are hexyl alcohol, octyl alcohol, cetyl alcohol, pine needle oil, which is a terpene alcohol, and the like.

Other derivatives of fatty acids, such as i3. the amides also showed an improvement in the printability of the color mixture. Suitable amides are caprilamide, Pelargonamide, Capramid, Lauramid, Nyristamid, Palmitamid, Stearamid, Arachamide, behenamide, ricinolamide, linolamide, linolenamide, oleamide, erucaamide, N- (beta-hydroxyethyl ) ricinolamide, N, N'-ethylene-bis-ricinolamide, N-stearyl-1 2-hydroxystearamide, N- (2-hydroxyethyl) -12-hydroxystearamide, N, N'-ethylene-bis-hydroxystearamide, ricinolçlalanid, erucaamide and the like.

The high molecular weight amines, also called fatty amines known can be used in a similar manner.

These amines are usually made by reacting a fatty acid synthesized with ammonia or an amine to form the amide, which is then synthesized with Hydrogen is reduced to obtain the corresponding E'ettsäureamin. Suitable Amines are hexadecylamine, octadecylamine and the like.

The following specific examples are given for illustration only cited without any limiting intention.

The color mixing is preferably done by hand or in a mechanical way Mixer mixed and then on a three or five roll mill or a ball impact mill treated. The alkaline reagent or the alkaline resins, such as the polyalkali amines, are mixed with the glycol prior to adding the other ingredients.

The color mixture became more repellent in terms of the relative need for color Liquid examined by letting two grams of the paint over 0.186 m2 (2 square feet) a glass plate with a hand roller. 0.1% Deodorized 400 Oil was added to the paint layer by hand roller rolling. The hand roller was then rolled over a 114 mm wide strip of polystyrene sheet which with slightly raised markings of a zinc oxide peeled off by heat Layer was provided. Additional portions of Deodorized 400 oil have been added, until the Non-image areas of the plate and the impression disappeared.

Prints of good density were obtained by placing paper on top placed on the colored surface of the plate and a hand roller with light pressure over it its upper surface was guided.

Example I Ingredients Amount in weight yó Iosol Black BC 40620 4 4 above Shellac solution in diethylene glycol 60 ethylenediamine 4 triethylene glycol 8 carbon black pigment 22 If this mixture was brought into the form of a homogeneous pigment dispersion, it could be mixed with 20 ml Deodorized 400 oil. If the so received When scrap was rolled onto a polystyrene plate, the non-image areas encountered the pigment dispersion, while the zinc oxide image areas on the polystyrene plate took on the color. Good prints, with no background coloring in the non-image areas were available.

When 2 p of the homogeneous pigment dispersion by rolling over a surface of 0.186 m2 (2 square feet) and then 0.8 ml of Deodorized 400 oil are spread over the paint by rolling, the mixture of oil and pigment dispersion colors the sheer, non-image polystyrene surfaces of the plate are not one, but the light ones raised zinc oxide image surfaces. After covering the plate with paint, they show Polystyrene surfaces have a slippery texture. The 400 oil separates themselves apparently from the mixture in a selective manner, the hydrocarbon oil being from is attracted to the polystyrene surfaces, while the water-absorbing color mixture is repelled from these surfaces. The water-absorbing scar preferably adheres only on the zincoid coatings.

When the 400 oil is mixed into the paint, 2 grams of this will require Paint 1.6 ml of the 400 oil to free the non-image areas of the plate from paint keep.

Example II Ingredients Amount in% by weight losol Black BC 40620 4 40% Shellac solution in triethylene glycol 60 ethylenediamine 4 triethylene glycol 8 linseed oil (technical) 2 carbon black (United Carbon Black 3020 L) 22 100 2 grams of the Spread out with a hand roller over an area of 0.186 m2 resulting in homogeneous Pigment dispersion required only 0.8 ml Deodorized 400 dl to adhere the color on the non-image areas of the plate, and the resulting imprint was denser than that with the paint mixture according to Example, which did not contain linseed oil I received.

Example III Ingredients Amount by weight, losol Black BC 40620 6 Molacco Carbon Black (Columbian Carbon Company) 24 Polyethylene Glycol-200 (Average Molecular weight of -200) 7.5 40, shellac solution in polyethylene glycol 200 Diethylenetriamine Castor Oil 0.5 100 The addition of castor oil made it possible only Consume 0.2 ml of Deodorized 400 oil to make a good impression.

More examples showing the use of other binders, diluents and additives show follow: Example IV Ingredients Amount in wt. D Iosol Black BC 40620 6 Molacco carbon black 23 Polyethylene glycol 400 (average molecular weight of 400) 3.4 30% shellac solution in polyethylene glycol 400 62 ethylenediamine 4.6 castor oil 1.0 100 Example V Ingredients Amount in% by weight of Iosol Black BC 40620 6.0 Molacco carbon black 23 30% shellac solution in polyethylene glycol 400 51.5 polyethylene glycol 400 9.3 Diethylenetriamine 7.8 j'i "'inusdl 2.4 100 Example VI Ingredients Amount in% by weight carbon black (UN No. 39207) 30 40, partial shellac solution in propylene glycol, propylene glycol 10 Castor oil 8 Example VII Ingredients Amount in% by weight Empol No. 1043 Trimeric acid 20 triethylene glycol 26 PEI-12, a liquid polyethyleneimine (Dow Chemical) 20 Irpacet Black PL (Geigy Chemical) 10 ethanolamine 4 Example VIII Ingredients Amount in% by weight carbon black (UN No. 30201) 30 polyethyleneimine 1000 (33% solution in water) 40 Sutra 250, a polyhydroxy alcohol (Atlas Chemical) 29 This paint only needs 0.10 ml Deodorized 400 oil and 0.05 ml Deodorized 520 oil, according to the above Investigation method the color adhering to the non-image areas of the polystyrene plate to prevent.

Example IX Ingredients Amount in% by weight carbon black (UN No. 30201) polyethyleneimine-600, a polymer of ethylene imine as a 33% solution in water (Dow Chemical) 40 glycerine 29.5 Esters of ricinoleic acid and trimethylolpropane 0.5 with this color were sufficient 0.5-0.10 ml Deodorized 400 oil to remove background staining. This success is on the printing press both through lower consumption of aliphatic hydrocarbons as well as better printing performance is remarkable.

Example X Ingredients Amount in% by weight losol Black BC 40620 2.0 Molacco flow 27.0 40% shellac solution in triethylene glycol 60.0 triethylene glycol 5.0 ethylene diamide (98-100%) 4.0 Example X (continued) Ingredients Amount in% by weight -Oleic acid 2.0 The addition of oleic acid allows the background to be reduced Deodorized 400 oil to 0.4 ml for background-free prints. The effects other fatty acids and derivatives are essentially the same.

Example XI Ingredients Amount in wt.

Iosol Black BC 40620 4.0 United Carbon Black 22.0 goat shellac solution in triethylene glycol 60.0 triethylene glycol 8.0 ethylenediamine 4 ° cetyl alcohol 2.0 This color mix required only 0.2 ml of Deodorized 400 oil to keep the background clear.

Example XII Ingredients Amount in% by weight losol Black BC 40620 2.0 Molacco carbon black 27.0 goat shellac solution in triethylene glycol 60.0 triethylene glycol 5.0 Ethylenediamine (98-100%) 4.0 Erucaamide 2.0 With this color, 0.4 ml Deodorized 400 oil will get good prints. In addition, the erucaamide apparently improved the abrasion resistance of the dry print.

Example XIII Ingredients Amount in% by weight losol Black BC 40620 2.0 example XIII (continued) Ingredients Amount in% by weight Nolacco Ru 27.0 40% shellac solution in triethylene glycol 60.0 triethylene glycol 5.0 ethylenediamine (98-100%) 4.0 diglycoleate 2.0 Just 3.4 ml of Deodorized 400 Oil were needed to make impressions without a background to obtain.

Example XIV Ingredients Amount in% by weight Iosel Black BC 40620 2.0 Molacco carbon black 27.0 40% shellac solution in triethylene glycol 60.0 triethylene glycol 5.0 Ethylenediamine (98-100%) 4.0 Isooctyl epoxystearate 2.0 Just 0.4 ml Deodorized 400 oils were required to obtain sharp, background-free prints.

The isooctyl epoxystearate additive mentioned above is a modified fixed one Fatty acid that is synthesized into another derivative by esterification with an alcohol became. Another modification of the epoxy compound can be made in the pigment dispersion expect; since the epoxy group is reactive with amines, carboxyl and hydroxyl groups. A high molecular weight hydroxyaminostearate ester may be formed in the mixture will.

Example XV Ingredients Amount in% by weight Iosol Black BC 40620 Molacco Soot 27.0 Example XV (continuation of the constituents, amount in% by weight, 40% Shellac solution in triethylene glycol 60.0 triethylene glycol 5, o ethylenediamine (98-100%) 4.0 Hexadecylamine 2.0 Just 0.4 ml of 400 oil was given a clearer background Imprints required.

Example XVI Ingredients Amount in% by weight Iosol Black BC 40620 2.0 Molacco carbon black 27.0 40% shellac solution in triethylene glycol 60.0 triethylene glycol 5.0 Ethylenediamine (98-100) 4.0 Span 60 (Atlas Powder Company) 2.0 Span 60 is the Trade name for monostearate sorbitol. The paint made according to Example XVI required 0.2 ml 400-l.

Other sorbic acid esters such as those under the trade name Span 20 (sorbic acid monolaurate), Span 80 (sorbic acid monooleate), Span 40 (sorbic acid monopalmitate), Span 85 (sorbic acid trioleate), Substances known to Span 65 (orbic acid tristearate) also reduced the amount required 400 amount of oil.

Span 60 is preferred because it is excellent on dry paint film Slipperiness bestowed.

Other mixes were made that basically matched the composition according to Example I, which was modified by adding the content of the diluent Triethylene glycol reduced from 10 to 8% and 2% one of the following additives was attached. The corresponding reduction in the amount of Background Deodorized 400 oil, that was needed in the above-described spreading and mixing techniques, is tabulated as follows: Table I addition amount required Magic oil for: A. Spread over B. Mixture in 0.186 m² Per @ film 2p pigment disperser -sion 1. none (TEG instead) 0.80 ml 1.2 to 1 6 2. coconut oil 0.40 "0.80 ml 3. Safflower oil 0.80 "0.80" 4. Linseed oil 0.10 "0.30" 5. Castor oil 0.40 "0.40" 6. Tung oil 0.80 "0.80" '7. Cetyl alcohol 2.20 "0.30 1l 8. oleyl alcohol 0.10 n 0.30 9. Octyl alcohol 10. Methyl ricin oleate 0.80 "0.80 11. Methyl laurate 12. Condensed Ethyl silicate 0.80 "0.80" 3. Tetra (2-ethylbutyl) silicate 0.80 "0.80" 14. Ethyl silicate 40 0.20 "0.20" (Union Carbide Corp.) 15. Tetraethylorthosilicate 0.80 "0.80" 16. Trimethyl phosphate 0.80 "0.80 17. Coconut oil fatty acid 0.40" 0.40 "18. Empol 1040 Trimeric acid 0.40 "0.80" The need for background liquid is further increased by Use of acidic dyes in contrast to basic ones kept low.

Example XVII Ingredients Amount% by weight Molacco carbon black 27.0 goat shellac solution in triethylene glycol 60.0 triethylene glycol 5.0 ethylenediamine (98-100%) 4.0 castor oil (USP) 2.0 Without any dye, this color mixture requires 0.4 ml Deodorized 400 oil to keep the background color-free. When two (2) parts of a basic Dye, such as methyl violet base of nigrosine base B, are increased The need for Deodorized 400 oil is 0.8 ml. However, if two (2) parts of one acidic dye, such as Iosol Black BC 40620, Acid Violet 12 B (acidic violet 12B) or Fast Green Extra Blueish (Real-Grcin-Extra-B1äulich) of the color mixture are added, the need for Deodorized 400 oil is reduced to about 0.2 to 0.3 ml.

It should be noted that only preferred embodiments of the Invention have been specified and that numerous exchange and change options exist within the scope of the invention.

Claims (7)

Patent claims: 1. Water-accepting ink mixture for printing in the presence of a color-repellent, water-repellent background (wet) liquid with a water-miscible, a carrier containing colorant, g e k e n n z e i c h -n e t d u r c h 0.1 up to 20% by weight of an additive which has only limited solubility in the carrier, however, is substantially miscible with the liquid. 2. Color mixture according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the additive is an aliphatic hydrocarbon which 6 to 24 carbon atoms and at least one from the group consisting of carboxyl, ester, Hydroxy, amino and amido groups, contains selected substituents. 3. Color mixture according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the additive is an ester of an alcohol having 1 to 10 carbon atoms contains as well as one of the consisting of silica, phosphoric acid and sulfurous acid Group selected acid. 4. color mixture according to claim 2, d a d u r c h g e k e n n -z e i n e t that the additive is a saponifiable oil. 5. Color mixture according to claim 4, d a d u r c h g e k e n n -z e i c h n e t, that they 0.1 to 15 wt.% of a vegetable oil or a derivative one of these contains. 6. color mixture according to claim 5, d a d u r c h g e k e n n -z e i c h n e t that it contains 0.2 to 8 wt.% of an additive derived from the castor oil, Linseed oil, soybean oil, Safflower oil, coconut oil, tung oil, lauric acid, Coconut oil fatty acid, oleic acid, hydroxystearic acid, stearic acid, tall oil fatty acid, dimerized and trimerized C 16 to C18 acids, ricinoleic acid, palmitic acid, Caprylic acid, pelargonic acid, capric acid, myristic acid, arachidonic acid, behenic acid and lignoceric acid is selected from existing groups. 7. paint mixture according to claim 1, wherein the carrier is an alkylene glycol contains as a thinning agent it also contains 1 to 8 percent by weight of an alkaline reagent, which is derived from the amines, Group consisting of imines and hydroxyl groups is selected. L e r s e i t e