DE19653829A1 - Roll offset printing ink suitable for high speed printing on all usual grades of paper with standard drying - Google Patents

Abstract

Printing ink, containing a rosin-modified phenolic resin (B), maleate resin (C) and/or hydrocarbon resin (D), contains fatty acid 1-9 carbon (C) monoalkyl ester(s) (E) and has a mineral oil content of 0-15 wt.%.

Description

The invention relates to a printing ink that a colophanium-modified phenolic resin (B) and / or a Maleinate resin (C) and / or a hydrocarbon resin (D) includes.

Corresponding printing inks contained in the prior art usually 25-40% by weight mineral oil.

However, there has been a need for mineral oil for a long time free or significantly reduced roles in the mineral oil content offset printing inks for heat drying (heatset process), to expand the raw material base to include renewable raw materials to be able to.

So were already mineral oil-free or in the mineral oil content reduced colors developed for web offset printing, however, this severely limits their scope of application that it is only based on absorbent printing substances, such as B. Newsprint or uncoated Recycled paper can be processed where drying only takes place in a setting. Than knocking away one denotes the process that immediately after printing low-viscosity paint components, primarily the minerals oils, into the surface structure of the substrate penetration. Such drying is called a coldset process referred to, the process by a heat supply, for example by infrared drying, supported can be without, however, an essential Solvent evaporation occurs.

In the case of the heatset process, the material can be dried run in so-called impingement dryers, in which to between 180 ° C and 250 ° C heated air on both sides the material web is blown. Not only the Solvent driven off but it also heats up the Material web strongly on, so that this then again must be cooled. To cool down the track and to Curing of the paint is done through a system of the web Chill rolls passed. The still brisk, d. H. sticky paint film and is mechanically resilient. The Web temperatures at the dryer outlet should be 130 ° C if possible do not exceed in order to protect the paper.

The mineral oils used are mostly non-polar Mixtures of hydrocarbons with a molecular weight range between 200 and 300. They are usually Naphthenic and low in aromatics or free of aromatics. The In addition to finely dispersed pigments, heatset inks contain Alkyd resins and additives based on binders various natural or synthetic resins. These are structured in such a way that specific properties such as the molecular weight range, the polarity, the soluble speed, compatibility or the melting range those of the solvent, d. H. to that of the mineral oils are adapted. This enables the necessary printing requirements in terms of speed and Viscosity of the printing ink can be brought about.

However, this increases the polarity of the resins limited that with increasingly higher polarity of the resins, by the hydroxyl number, the acid number and the ester number is determined, the solubility in the mineral oils decreases.

Mineral oil-free heatset printing inks that work on all practical usual, specially painted and not very absorbent Substrates can be processed, could so far because of the requirements for a dampening solution stable Printability, tack-free drying and the Further processing of the print products not implemented become.

The object of the present invention was therefore to mineral oil-free or greatly reduced in mineral oil content provide heat-drying web offset printing inks, which on all, the requirements of the web offset technology appropriate substrates can be processed.

The object of the invention is achieved by a printing ink which comprises a colophony-modified phenolic resin (B) and / or a maleate resin (C) and / or a hydrocarbon resin (D), which is characterized in that it contains one or more C ₁ -C ₉ monoalkyl esters of fatty acids and a mineral oil content of 0-15% by weight.

Preferred is a printing ink which is also a copolymer resin (A) comprises the at least one monomer component each from the group of phenolic compounds, the olefinic unsaturated, non-acidic terpene compounds and the contains polyunsaturated olefin compounds. A Printing ink with such a copolymer resin is used in the EP 0 610 632 A1 is described. With those named there Printing inks are printing inks with a for Offset printing inks usually contain mineral oil.

Printing inks whose mineral oil content is also preferred is limited to 5% by weight, preferably to 3% by weight.

A printing ink that is free from Mineral oils is.

The printing inks according to the invention can be used on all papers customary in practice without restrictions, also with high Web speeds, d. H. with web speeds of over 8 m / s can be processed. The one for drying required dryer and web temperatures those of the state of the art.

A particular advantage of the printing ink according to the invention consists in the fact that it is a markedly quick cut-off restrained and at the same time good partial evaporation the fatty acid ester and thus the drying shows.

Also preferred is a printing ink which is characterized in that the resins have a molecular weight M _w of 5500-120000, an acid number of 10-40, a hydroxyl number of 25-70 and a melting range of 140.degree. C.-190.degree. The determination of the melting range was based on the determination by the capillary method.

Resins with a viscosity of 60-90 Pa.s at 40% in mineral oil (Haltermann PKW-F 6/9) or with a viscosity of 50-70 Pa.s at 40% in Mineral oil (from Haltermann PKW-F 6/9 ar), measured in each case at 50 l / s and a temperature of 20 ° C.

Also preferred are resins having a cloud point of 80-120 ° at 10% in mineral oil (Haltermann PKW-F 6/9 af new) or with a cloud point of 100-150 ° C at 10% in Mineral oil (from Haltermann PKW-F 6/9).

Also particularly preferred is a printing ink in which the resins A: B: D in an amount ratio of 22-41: 41-46: 16-33 are present, as well as an ink in which the resins A: C in a proportion of 55-65: 35-45 are present.

Also preferred is a printing ink in which the Fatty acids have a carbon chain length of 8-24 carbons have material atoms. These fatty acids can get saturated or be unsaturated. They can be herbal or be of synthetic origin and in combinations are present. For example, you can choose from soybean oil, canola oil, Linseed oil, castor oil, dehydrated castor oil, wood oil, Safflower oil, sunflower oil, rapeseed oil, tall oil, oiticika oil, Corn oil, perilla oil or hemp seed oil can be produced.

The fatty acids used for esterification can also be oxidatively drying, semi-drying and non-drying.

Typical fatty acids are oleic acid, linoleic acid, linolenic acid, Elaostearic acid, licanic acid, ricinic acid, erucic acid, Lauric acid, myristic acid, palmitic acid, stearic acid and Arachidic acid.

The alcohols used for esterification are monohydric C ₁ -C ₉ alcohols, preferably C ₁ -C ₅ alcohols.

Fatty acid esters in the iodine number range between 20 and 150.

There is a major advantage of the new printing ink in that by the selection according to the invention of the fat acid ester both the solvent properties and the binder properties that promote printability can be significantly improved.

To produce the binders for the inventive Printing ink are the resins described in the cited Fatty acid esters and, if necessary, dissolved in mineral oil at approx. 200 ° C.

It is essential that the resins in the above Fatty acid esters or fatty acid ester combinations a have appropriate solubility and compatibility. The compatibility of a resin solution or a bandage is defined by the hex number HEZ. The Compatibility should be in a HEZ range between +3 and +10 lie.

The ratio of viscosity to tack should be in the range of 50-60 Pa.s (50 l / s, 20 ° C) to 8-9 Inko (26 ° C; measuring speed 200 rpm; 1.3 m ^{3 of} paint) , the tack being measured on an Inkomat test construction from Dürner.

The rheological data of the printing ink are transferred to the application requirements and substrates in an set in a known manner.

Decisive for the good drying properties of the The printing inks according to the invention are markedly fast Absorption properties, the partial evaporation of Components of the fatty acid ester combination as well as the increased compared to a conventional heatset printing ink Affinity to the substrate.

The positive surprising properties of the printing ink are the result of the inventive combination of Resin selection with the fatty acid ester selection. The printable speed, drying and print quality also corresponds to high-speed web offset presses at least that Quality standard of the colors of the state of the art - whereby however, the possibility of using the colors according to the invention was opened, on renewable raw materials as a starting point to use substances for a printing ink component.

Examples

Web offset printing inks for heatset drying were produced in a manner known per se:

• a) Manufacture of a binding agent
  The solid components of the printing ink were dissolved in the solvent component or the solvent components with a concentration of approx. 50% at approx.
• b) Manufacture of the printing ink
  The solid components were predispersed in about 30% concentration on the dissolver. After adding the remaining amount of binder, the mixture was finely dispersed in a stirred ball mill. The required viscosity / tack ratio was set using the amount of residual solvent. The completely mixed components were deaerated using a three-roll mill.

The following printing inks were produced in this way:

example 1

13.0% by weight Sicoechtgelb D 1361® - P.Y. 13, BASF 0.1 wt% Irgalithorange F2G® - P.O. 34, from Ciba-Geigy 6.0 wt% kaolin 0.5 wt% Printplex 28.0® - disodium salt of ethylenediaminetetraacetic acid, Deurex Wachs Chemie 0.3 wt% Butylated hydroxytoluene 1.0 wt% Ceridust 9205® - micronized PTFE wax, Hoechst 8.0 wt% Setalin V 407® -isophthalic acid-soy-alkyd, Akzo-Nobel 14.0% by weight Soybean oil 20.6% by weight Texaprint SDM 100® methyl dodecanoate, from Henkel 12.0% by weight Nevroz 1520® - modified hydrocarbon resin, Nevcin Polymers 16.5% by weight Tergraf ND 1243® rosin-modified phenolic resin, Resisa 8.0 wt% Alsynol ZW 3282® - copolymer resin according to EP 0 610 632 A1 from DSM N.V. 100% by weight

Example 2

18.0% by weight Irgalith Rubin L4BK® - P.R. 57: 1, from Ciba-Geigy 4.0% by weight kaolin 0.5 wt% Printplex 28.0® 0.3 wt% Butylated hydroxytoluene 1.0 wt% Ceridust 9205® 12.0% by weight Valkeset 5088® -tall oil-based binder, Fa. Arizona 5.0% by weight Valkeset 5® - modified tall oil fatty acid ester, Arizona 22.2% by weight Crodamol BM® - butyl myristate, Croda 22.0% by weight Alsynol ZW 3282® 15.0% by weight Mitchanol 57® - maleinate resin, Mitchanol 100% by weight

Example 3

15.0% by weight Irgalith Blau LGE® - PB 15: 3, from Ciba-Geigy 5.0% by weight kaolin 0.5 wt% Printplex 28.0® 0.3 wt% Butylated hydroxytoluene 1.0 wt% Ceridust 9205® 6.0 wt% Setalin V 407® 15.0% by weight Soybean oil 22.7% by weight Valkeset 102® - tall oil fatty acid butyl ester, Arizona 5.5% by weight Albertol VKC 1231® - hydrocarbon-modified phenolic resin, Vianova 16.0% by weight Albertol KP 351® - colophony-modified phenolic resin, Vianova 13.0% by weight Asynol ZW 3282® 100% by weight

Example 4

14.0% by weight Irgalith Yellow LBE® - P. Y. 174, from Ciba-Geigy 10.0% by weight Lithosperse 7015 HS® - kaolin + SiO ₂ , Lehmann & Voss 0.5 wt% Printplex 28.0® 0.3 wt% Butylated hydroxytoluene 1.0 wt% Ceridust 9205® 6.0 wt% Setalin V 439® - isophthalic acid-linseed oil alkyd, Akzo-Nobel 14.0% by weight Soybean oil 21.6% by weight Sovermol Pol 1058 / III® - fatty acid methyl ester, from Henkel 10.0% by weight Sheberez 68160B® - modified hydrocarbon resin, from Arizona 18.03 wt% Alsynol RL 56® - rosin-modified phenolic resin, Arizona 4.3% by weight Alsynol ZW 3282® 100% by weight

Example 5

18.0% by weight Irgalith Rubin LPBC® - P.R. 57: 1, from Ciba-Geigy 8.0 wt% Lithosperse 7015 HS® 0.5 wt% Printplex 28.0® 0.3 wt% Butylated hydroxytoluene 1.0 wt% Ceridust 9205® 11.0 wt. Trionol 7® - isophthalic acid-linseed oil alkyd, Lawter 8.0 wt% Valkeset 5® 22.2% by weight Nirez 9012 E® - tall oil fatty acid butyl ester, Arizona 8.0 wt% Alsynol RL 42® - rosin-modified phenolic resin, Arizona 15.0% by weight Alpharez 92® - hydrocarbon-modified phenolic resin, Lawter 8.0 wt% Alsynol ZW 3282® 100% by weight

Example 6

15.0% by weight Irgalith Blue GLG® - P.B. 15: 3, from Ciba-Geigy 8.0 wt% Lithosperse 7015 HS® 0.5 wt% Printplex 28.0® 0.3 wt% Butylated hydroxytoluene 1.0 wt% Ceridust 9205® 16.0% by weight Soybean oil 14.0% by weight Nirez EXP 9007® - tall oil fatty acid ester, from Arizona 10.7% by weight Estisol 256® - 3-ethylhexyl-2-ethylhexanoate, from Haltermann 6.3 wt% Albertol VKC 1236® - hydrocarbon-modified phenolic resin, Vianova 14.0% by weight Jonrez RP 363® - acrylic acid modified Phenolic resin, Westvaco 14.2% by weight Alsynol ZW 3282® 100% by weight

The processing of the printing inks of Examples 1 to 6 took place on a printing machine of the Rotoman C type a machine speed of 35000-40000 copies plaren / h, a web temperature in the dryer of 120 ° C Using a Dahlgren dampening system and using a dampening solution with 3.5% isopropanol.

It was printed on newsprint, B-material paper and coated paper.

In all cases the printability was excellent speed. The drying corresponded to the standard in all cases, with no higher web speeds required were. The rub resistance of the prints was good in every case Good.

Claims (9)

1. Printing ink comprising a rosin-modified phenolic resin (B) and / or a maleate resin (C) and / or a carbon hydrogen resin (D), characterized in that it comprises one or more C ₁ -C ₉ monoalkyl esters of fatty acids and one Has mineral oil content of 0-15% by weight. 2. Printing ink according to claim 1, characterized in that that it further comprises a copolymer resin (A) containing at least a monomer component each from the group of Phenolic compounds, the olefinically unsaturated ones, are not acidic terpene compounds and the polyunsaturated ones Contains olefin compounds. 3. Printing ink according to claim 1 or 2, characterized shows that it has a mineral oil content of 0-5% by weight having. 4. Printing ink according to one of the preceding claims 1 to 3, characterized in that it is a mineral oil has a content of 0-3% by weight. 5. Printing ink according to one of the preceding claims 1 to 4, characterized in that they are free from mineral oils is. 6. Printing ink according to one of the preceding claims 1 to 5, characterized in that the fatty acids a Carbon chain length from 8 to 24 carbon atoms exhibit. 7. Printing ink according to one of the preceding claims 1 to 6, characterized in that the resins have a molecular weight M _W of 5500-120000, an acid number of 10-40, a hydroxyl number of 25-70 and a melting range of 140 ° C-190 ° C. 8. Printing ink according to one of the preceding claims 2 to 7, characterized in that the resins A: B: D in one The proportions are 22-41: 41-46: 16-33. 9. Printing ink according to one of the preceding claims 2 to 7, characterized in that the resins A: C in one Quantity ratio of 55-65: 35-45 are present.