DE102006048958A1 - DEvice for heat input for printing with printing ink in flexo or offset printing process, comprises inflatable elements for volume expansion unDEr influence of heat in sheet processing machine in multiple work stations - Google Patents

Abstract

The DEvice comprises inflatable elements for volume expansion unDEr influence of heat in sheet processing machine in multiple work stations. A sheet processing machine or multiple infrared emitters are proviDEd in printing work stations. An independent claim is also incluDEd for a printing machine for producing print product.

Description

The The invention relates to a device and a printing press according to the preambles of the claims 1 and 10.

It is known from the prior art printing inks containing a blowing agent and foam under heat to print. The DE 25 29 043 C2 describes a process that has also become known under the heading "Kiwoprint." In this process, a very high layer (eg 200 .mu.m) is applied to a printing material containing a pore-forming agent by means of the screen-printing process.This layer is then pressurized to 185.degree For 10 minutes, the printed surface is gelled and, thanks to the pore-forming agent, foamed to about three times as high a layer thickness (eg 500 to 700 .mu.m.) The disadvantage of this method lies in the required long heat exposure time in order to achieve the desired effect It is obvious that this method is suitable for one-off production or production of smallest editions, but not for modern printing processes with a throughput rate on a printing machine up to 18,000 sheets / h The selected printing process, the screen printing, combined with the high required layer thicknesses, includes one industrial production, since the layer thicknesses before storage after de m pressure must be dried or stored individually in suitable drying devices.

Methods have become known in which a thermo-expansive printing substrate is partially coated with an absorber material which absorbs the heat radiation and expands the thermo-expansive printing material at the printed areas and thus forms a relief. The US 5 122 430 A describes a method in which a thermo-expansive printing material is applied to a high-density ink with, for example, aluminum or metal components.

at Exposure with a heat radiator the color gives the absorbed heat to the underground, whereupon the underground expands. The metallic constituents ensure that the exposed IR radiation is better absorbed.

The US 5 650 217 A describes an identical process wherein the absorbing ink does not contain any metallic constituents but is a high density or, ideally, black color. A comparable procedure describes the US 5639540 , wherein the absorbent high-density or black color is applied by means of a ribbon on the ground. The disadvantage of this method is that the user is bound to specific, thermo-expansive substrates. Classic and well-established substrates, such as paper and cardboard, can not be used for this process. In addition, the inclusion of non-transparent absorbers in the ink, such as metal particles or black pigments, limits the user in the design of the print engine, since these printed areas and elements are clearly visually recognizable and therefore included in the design of the print product Need to become.

The EP 0 340 898 B1 describes a security coding for an article wherein a colorless or slightly colored material with a significant absorption in the near infrared region is applied. The material containing the infrared absorber may also be an ink. The addition of an infrared absorber in a printing ink is therefore previously known. The aim of the invention is, inter alia, to encode a printed product in the sense of protection against counterfeiting by absorbing a suitable laser beam at specific points of the product.

The EP 1 302 735 A1 suggests using radiant energy to dry inks and varnishes which emit at a wavelength that is substantially unabsorbed by water. This is to avoid that substrates under the action of radiation dehydrate and become brittle. In order to improve the coupling of the radiation energy into the printing ink or varnish, it is proposed to add to the printing ink or varnish an infrared absorber which absorbs in the near infrared.

The DE 10 2004 011 347 A1 describes another group of infrared absorbers attached to printing inks and varnishes. The aim of both patents is to improve the drying of printing inks. Add ink and varnish infrared absorber, is therefore previously known. These were previously used exclusively in printing inks to improve the drying of these paints or varnishes.

It is known to add plastics to infrared absorbers. In the DE 100 22 037 A1 For example, a thermoplastic resin is disclosed to which infrared absorber has been added. Plastics are added to infrared absorbers, for example, to reduce the thermal conductivity of plastic discs. Another known application of infrared absorbers in plastics is to improve the weldability of plastics with NIR lasers. Both known applications have no connection with the field of the invention, the printing ink technology and the printing technique.

As intumescent substances in printing inks microspheres are known. Microspheres are small plastic spheres that are best made from a polymer capsule in which a gas is trapped. As this gas is heated, the pressure increases and the thermoplastic shell softens. This increases the volume of the microspheres by 40 times. Unexpanded microspheres can be used as blowing agents in printing inks, paper and technical textiles and plastics.

Printed images, which was printed with a printing ink with microspheres can, under the effect of heat expand and form a relief. As a result, so-called pseudo-impressions can be achieved, which find use in the design of printed matter, as well in the training of braille and pictures. Preserved printed areas by the expansion also a velvety, soft surface. One tactile effect, which also likes to be used in the packaging setting becomes. The disadvantage of the hitherto known printing inks, however, is that the printed area must be heated to at least 75 ° Celsius to the full To achieve expansion. Such a high heating is with the known Devices for heating of the printing sheet in printing presses, such as infrared radiators and hot-air swords, while of the print run can only be achieved if the print speed is drastically reduced reduced and the acting heat output maximum chosen becomes. This high heat input has but definitely negative consequences for the printed product: The paper or cardboard may dry out and also other printed areas can become sticky and in the worst case lay down or on machine elements Lubricate. It is also known sheets of paper with a printing ink were printed, the microspheres included, after printing by the printing press a separate touching Supply heating device, the the inflatable Ink film heats up. However, such an approach is not especially economical, because you have to invest in a separate heater. Here too becomes a relatively long time for heating the ink layer with microspheres needed so that the throughput of such a device is limited.

The Expansion speed of the ink layer with the integrated Microspheres also depend very dependent on which pigments the printing ink or varnish colored is. Black or blue colored Printing ink expands faster with the same power effect as transparent or light shades. This phenomenon can be explained attributed that blue or black pigments absorb the IR rays better and the heat be forwarded to the embedded in the ink microspheres. The design possibility However, a printed product is significantly limited if the effect of expansion economical only with dark colors works. The observed effect, however, shows that by a improved absorption of the IR rays in the ink film the Expansion significantly accelerated.

task It is therefore an object of the present invention to provide a device in the pseudo-imprints and other changes the tactile surface from sheet in economic Way can be produced.

Is solved this task by means of a device and a printing machine according to the features of the claims 1 and 10.

further developments The invention will become apparent from the respective dependent claims.

The Invention is characterized in that a device for carrying out a Method is applied, in which by planar printing a Printing ink that is swollen under heat Substances and optionally organic or inorganic IR absorbers contains on a substrate, the printed with this ink Bow afterwards fed to an IR radiation source is and by the induced in the ink and by the IR absorber absorbed IR radiation by heat input the inflatable ones Bloat fabrics, the ink layer is changed in their tactile properties.

A change the tactile properties in the sense of the invention can be a noticeable relief formation, a velvety surface or a matte effect. Furthermore, the invention describes Devices for carrying out of such a method and particular embodiments of swellable substances.

In In a first embodiment of the invention, the expansion of Improved ink layers with microspheres embedded therein, in which the printing ink or the paint is preferably transparent or only slightly colored organic or inorganic infrared absorbers are added to the coupling of the heat radiation to improve in the ink film.

The organic infrared absorbers may be those in the EP 1 302 735 A1 proposed cyanine dyes or the in the DE 10 2004 011 347 A1 for printing inks proposed infrared absorber group of cyanines, naphthalocyanines, squaraine and croconates or other known organic infrared absorbers.

There are also mixtures of different infrared absorbers in the ink conceivable. However, the IR absorber should have no or only a slight absorption in the visible range in order to avoid a color impairment of the printing inks or of the coating film. Naturally, the IR absorbers absorb more in the visible spectral range, if the color strength and hue allow this. For the purposes of the invention, therefore, all known organic infrared absorbers are permissible as long as the color impression of the ink film is not significantly affected by the addition of the infrared absorber.

In contrast to the technology EP 1 302 735 A1 and DE 10 2004 011 347 A1 The infrared absorbers are added in the ink, not primarily to achieve the drying of the ink, but to achieve a faster and thus more economical expansion of the microspheres in the ink.

alternative or in addition to organic infrared absorbers, the printing ink can also inorganic infrared absorber are attached. A well-known, largely transparent inorganic infrared absorber is exemplified by iridium tin oxide (ITO), which can absorb infrared radiation very well.

The However, the invention also includes all other known inorganic Infrared absorbers, if the condition is met is that for a given ink of a hue with a certain color strength in color by the addition of the inorganic infrared absorber not essential and disturbing being affected. As the color impression of an expanded Ink surface change can (for example, from transparent to white), this condition of the not falsified Color impression in the first place for apply the expanded state.

In a second embodiment the printing ink called microspheres, which is a polymeric capsule comprising a gas and provided with a coating containing infrared absorber. Thereby becomes a microsphere itself to an infrared absorber element and the heat radiation will be at the microsphere directly and largely lossless converted into heat. Especially in mineral oil colors is the heat conduction not ideal, allowing the direct coupling of the infrared rays at the microspheres brings significant advantages in the expansion speed.

In In a third aspect of the invention, the polymer containing the capsule the microsphere forms, itself an organic or inorganic infrared absorber. The Admixture of infrared absorbers in plastics is from the thermal insulation and the Plastic Welding Technology well known. Due to the fact that the polymer of the microsphere has a Contains infrared absorber, will also be through this solution the infrared radiation is absorbed directly at the microsphere and largely lossless in heat implemented. Also this solution increases the speed of expansion in an advantageous manner.

Of Furthermore, the invention comprises a printed product and devices for producing such a printed product.

The Printed product is characterized by the fact that at least parts printed in the offset printing process, the used Printing ink is not inflatable Contains elements and another part of the print image printed with a printing ink become, the inflatable Contains elements. These inks with expandable Elements can be over Offset inking unit or over a coating unit or flexo printing unit are to be printed. characteristic for the Printed product is that the printed product, partially with printing inks intumescent Elements and partially printed with inks that are not inflatable elements contains arises in a printing pass in the passage through a printing press. The volume change of the partial image that was printed with the inks with inflatable elements, can be due to the heat a suitable device, for example one or more infrared emitters, one or more hot air blowing devices, by microwave radiation and / or by contact with a heated one Cylinder or roller during the printing run are inflated by the printing press. The effect can be provided zonally aligned.

alternative the print image can also be outside the press are inflated by a separate device, those with devices for heat Is provided. This offline attachment can work with the same devices be equipped as they are in-line during the process Print run used by the printing press. This offline attachment outside the printing press can be a separate device, exclusively the the effect of heat serves for Relienstzeugung. This offline systems are conceivable, the Whole sheet or partial sheet or use after cutting or punching process a printed product. As an alternative, the or can the devices for heat treatment the printed product according to the invention also part of a cutting device, a punch, a gluing machine or a carton erecting machine, as is conventional be used in postpress after finishing.

A particular embodiment of the printed product according to the invention consists in first applying the printing ink or lacquer layer which contains the intumescent elements and subsequently overprinting this layer with at least one conventional printing ink and / or lacquer layer. In this case, the flatulence of the inflatable Elements which are contained in the pre-printed ink or varnish layers, before the subsequent overprinting with at least one conventional printing ink and / or at least one varnish layer with a suitable device for effecting heat, or the printed product is completely printed and optionally varnished and then the expandable elements expanded by the action of a suitable device for the action of heat.

conventional Printing inks according to the invention are printing inks that are not inflatable elements contain, that is they include offset inks that oxidatively and / or by wegschlag Dry, continue to water-based paints, but also inks and paints by radiation curing cure. This type of design allows a velvety surface with a high matte value. In the subsequent overprinting can by overprinting the parts of the printed image with an ink or varnish layer, the inflatable Contains elements With parts of the print image very good matt / gloss effects can be achieved. Such matt / gloss effects are often used for decorative design of printed products. The method disclosed here provides a matte / gloss effect, the one without a big one up effort to achieve the printing press. He is also characterized by a good register to the other parts of the printed image. The matte effect can be further enhanced by adding the ink with the inflatable elements even in small amounts silicone or silicone oil is added. This method of achieving of matt / gloss effects is also very easy to represent economically, there swelling Elements, such as microspheres, in big Quantities are produced and thus are available at low cost.

The The invention also describes a printing machine for the production of printing products according to the invention, wherein the printing press comprises at least one offset printing unit. In the case that the inflatable Printing layers are inflated in the printing press by the action of heat are intended, the printing press also includes devices for heat input in the printed product. This can Infrared radiator, hot air swords or heated rollers or cylinders that are in direct contact stand with the substrate. The rollers or cylinders can be direct be heated by flowing through a heating fluid or include an electric heater. You can also indirectly through a Irradiation by a heat radiator Working temperature to be brought.

Claims (12)

Device for the heat input to carry out a method for printing ink by flexo or offset printing with inflatable ones included Elements for volume expansion under heat in a plurality of workstations comprehensive sheet processing machine, characterized by that in the sheet processing machine one or more infrared radiators provided after the ink processing workstations are. Device for the heat input according to claim 1, characterized in that it is a or several infrared laser sources, preferably as Semiconductor laser or Nd-Yag laser or CO2 laser are formed. Device for the heat input according to claim 1, characterized in that it is a or several thermal air sources, such as fan heater or Thermo air swords. Device for the heat input according to claim 1, characterized in that it is a Roller, a cylinder or a plate, which during the heat transfer in contact with the printed product, and the roller, the cylinder or the plate directly, for example via an electric heater, or indirectly a heat radiator are heated. Device for the heat input according to claim 1 to 5, characterized in that the device in a sheet punch or a sheet-fed press associated therewith is integrated. Device for the heat input according to claim 1 to 5, characterized in that the device in a cutting machine or an associated sheet-fed printing machine is integrated. Device for the heat input according to claim 1 to 5, characterized in that the device in a folding machine or an associated sheet-fed printing machine is integrated. Device for the heat input according to claim 1 to 5, characterized in that the device in a collating machine or an associated sheet-fed printing machine is integrated. Device for the heat input according to claim 1 to 5, characterized in that the device in a Faltschachtelklebemaschine or an associated sheetfed press is integrated. Printing machine for producing a printed product consisting of a first partial image that is at least partially printed in offset printing and a second sub-image that is printed in offset printing and / or flexographic printing and optionally subsequently varnished, characterized in that in a sheet-fed rotary printing press one or more first printing units are provided for generating an offset printing sub-image that in the printing press one or more second printing units for generating a second sub-image with one or more inks or varnishes containing heat-inflatable elements are provided, and that the one generated from the first and the second partial image in a printing pass on the printing substrate generated by the printing machine image under heat irradiation converting device is provided. Printing machine according to claim 10, characterized in that that it is a sheet-fed rotary printing press with double-sized printing cylinders and grab transport. Printing machine according to claim 10, characterized in that that the sheet-fed rotary printing machine devices for heat input in the inflatable Contains ink layers, that make it possible these to each of the specific operating temperature, preferably between 60 and 150 degrees Celsius, too heat.