EP2841283A1 - System and method for transferring images onto substrates - Google Patents

Abstract

The present invention relates to a system for transferring images onto substrates (transfer printing) such as textile substrates, particularly T-shirts, cups, magnetic foils, mirrors or other smooth surfaces made of metal, leather, ceramics, wood, Plexiglas, cardboard or plastic. The invention also relates to a corresponding method for transferring images onto substrates, and to a siliconised and corona-treated paper.

Description

 System and method for transferring images to substrates

The present invention relates to a system for transferring images to substrates (transfer printing), such as textile substrates, in particular T-shirts, cups, magnetic films, mirrors or other smooth surfaces of metal, leather, ceramic, wood, Plexiglas, cardboard or plastic. The invention also relates to a corresponding method for transferring images to substrates.

In transfer printing, i. the transfer of images to substrates, such as textile documents, with the help of so-called. Transfer papers on soft the image to be transferred is applied in advance, under increased pressure and temperature conditions, there is often an undesirable background transmission, namely for the transmission of parts of the coating Transfer papers that are not part of the picture. In order to prevent this, additional work steps, such as contour cutting on the transfer paper and subsequent weeding off are necessary and / or it must be worked with different temperatures in the preparation of the transfer paper and the actual transfer process.

The present invention therefore provides a system and method for transferring images to substrates that overcome the aforementioned disadvantages.

The system according to the invention comprising a combination of essentially two components A and B.

Component A, hereinafter also referred to as transfer sheet, has a layer structure and comprises a carrier and an at least partial toner layer arranged on one side.

The carrier is, e.g. a film, cardboard or paper, in particular a paper having a basis weight of z. B. about 80-150, preferably about 90-100 g / m2, such as

CONFIRMATION COPY a machine-smooth paper suitable for (color) copier or (color) laser printer.

At least one surface of said support or paper, i. at least the surface facing the toner has an anti-sticking property.

Under non-stick properties in the context of the present invention, a good toner adhesion to the surface in the hot state with good Trennbzw. Release properties, especially of the toner when cold

Transfer process to be understood. This is due to the fact that the component A component after transfer of the image to the substrate in the cold state, i. preferably in the range of room temperature, is removed.

The non-stick properties are particularly achieved by creating a hydrophobic and / or oleophobic surface by means of impregnation, coating, e.g. with polymers such as polyesters, polypropylenes or fluorocarbons, silicones or refractory waxes, and / or altering the surface structure, e.g.

by changing, in particular reducing the contact surface over certain roughness profiles obtained.

Preference is given to coatings with silicones or quilone products (commercial products from Zaclon LLC), the support being optionally subjected to a surface treatment in the uncoated or coated state.

Quilon products are chromium (III) -C ₄ -C ₈ fatty acid complexes, eg CAS 65229-24-5, CAS 15659-56-0, CAS 15242-96-3.

The siliconization takes place by means of, for example, thermal crosslinking or UV crosslinking to form a polydimethylsiloxane skeleton. Corresponding methods and products, which are for example also referred to as release papers, are familiar to the person skilled in the art. Preferably, a corresponding (silicone) coating has tion a separation value of about 100 cN / 20 mm, preferably about

100-200 cN / 20mm, especially about 100-150 cN / 20mm.

Method for changing the surface structure, e.g. by treatment of the surface by means of profile rollers or the like, the skilled person is also familiar.

To improve the wettability of the surface and the adhesion of the toner, the surface of the support may optionally be subjected to a further surface treatment to increase the surface tension, in particular according to the invention is a plasma or corona treatment.

On the correspondingly equipped surface, a toner layer is arranged. The toner is applied in the form of the desired image. The toner layer is at least partially arranged on the surface, i. that at least parts of the surface are covered with toner depending on the geometric shape of the image. Usually, parts of the surface remain free of toner. The application is advantageously carried out by means of digital printing, laser printing, in particular by means of (color) copiers or (color) laser printers with commercial toners are used. Such toners consist of the corresponding color pigments in a plastic matrix, usually polyester with a melting range of e.g. about 80 - 120 ° C and possibly excipients. Suitable toners in the context of the present invention also include water-soluble or solvent-containing inks or sublimation inks, polymer inks, so-called flexo inks, screen printing inks, offset inks or the like.

The layer thickness of the toner layer is at the usual technical values and is typically 5 to 50, preferably 5 to 20 g / m 2 (in basis weight).

The support of component A is suitably designed so that under the pressure and temperature conditions of the transfer of the image on the Substrate, ie at temperatures of a minimum of about 100-150 ° C to a maximum of about 200-250 ° C, for example from about 100-250 ° C, especially from about 150 ° C to a maximum of about 200-250 ° C, in particular about 150 - 220 ° C, too

 180-220 ° C and a pressure of about 2-5 bar, no background transfer to the substrate takes place. Back-ground transfer in this case means that in the areas of the surface which are free of toner, parts of the possibly present coating of the carrier are transferred to the substrate. To prevent this, high melting point coating materials, especially silicones or quilon products, are used which have glass transition or softening temperatures in the range of preferably above about 250 ° C.

The use of appropriately high-melting coating materials also allows the use of commercially available (laser) printer / copier for applying the toner layer, as far as contamination of the (laser) printer / copier caused by peeling off parts of the coating.

In an advantageous embodiment, component A represents a siliconized paper with toner applied thereto in the form of the desired image.

Particularly preferably, the carrier of component A is a siliconized and corona-treated paper with a release value of the silicones of above

100 cN / 20 mm, preferably about 100-200 cN / 20 mm, in particular approximately

100 - 150 cN / 20mm. The paper may be pre-treated prior to siliconization, such as a coating with e.g. Polyvinyl alcohol or polyethylene.

The invention therefore also provides a siliconized and corona-treated paper having a basis weight of about 80-150 g / m 2 and a release value of the silicones of about 100-200 cN / 20 mm. The paper can be used especially in systems and methods for transferring images to substrates (transfer printing). The component B, hereinafter also referred to as opaque sheet, likewise has a layer structure and comprises a support, a polymer layer arranged on one side and at least one further layer.

The carrier is, e.g. a film, cardboard or paper, in particular a paper having a basis weight of z. Example, about 80-150, preferably about 90-100 g / m2, such as a machine-smooth, suitable for (color) copier or (color) laser printer paper.

At least one surface of said support or paper is provided with a polymer coating (also referred to below as extrusion layer) made of polyolefins, polyolefin copolymers or polyurethanes having a layer thickness of about 30-60, preferably 25-50 g / m2.

Examples of polyolefins which are used are LDPE with maleic anhydride, EVA with 7-28%, preferably 7-15% VA, ethylene-acrylic acid copolymers or ethylene-methyl acrylate copolymers with 5-12% acrylic acid, ethylene-butyl acrylate copolymers with 5-20% acrylate used, preferably one

Melt index according to ASTM-D-1238 (MFI) of 3.5-22, preferably 7-15 g / 10 min at 2.16 kg / 90 ° C.

Preferably, the extrusion layer is waxy. As waxes come e.g. Paraffins or paraffin waxes or mixtures of paraffin waxes with LDPE, into consideration. The waxes typically have melting points in the range of 60-100 ° C. In particular, a wax layer, which typically has a layer thickness of, for example, between the support surface and the extrusion layer, can be arranged. 10-20 g / m2.

The extrusion layer serves as an adhesive layer on the substrate in the process of transfer of the image to the substrate. Accordingly, the extrusion layer advantageously has a glass transition or softening temperature which, when separating the support of component B in the heat above the Softening range leads to a cohesive failure in the extrusion layer, so that parts of the extrusion layer adhere to the carrier and so a thin flexible plastic layer is transferred to the substrate.

The aforementioned separation of the support of component B in the heat takes place after the combination of component A (transfer sheet) and component B (opaque sheet), which by pressing at about 2 - 5 bar in the temperature range of at least about 130 - 150 ° C. to a maximum of about 200-250 ° C, for example from about 130-250 ° C, especially from about 150 ° C to at most about 200-250 ° C, especially from about 150-220 ° C, especially from about 150-200 ° C , Also 180 - 220X, typically for a minimum of about 15 - 20 sec. To a maximum of about 60 sec, in particular about 15 - 45 sec, preferably 15 - 30 sec done. The separation of the support of component B in the heat typically takes place in the range of about 0-15 seconds after the pressing process.

The extrusion layer therefore advantageously has glass transition or softening temperatures in the range of about 60-80 ° C.

The further layer serves as a background layer for the toner layer of component A. Accordingly, the further layer is advantageously opaque and is referred to below as an opaque layer.

The opaque layer may be a metal coating applied, for example, by means of a transfer metallization or transfer metallization familiar to the person skilled in the art, in which case a thin (eg 0.05 gm ² ) metal layer (eg aluminum) is applied to a coated film by means of a vacuum is laminated to the substrate. After a controlled drying process, the carrier film is removed, the metallization remains on the substrate. Advantageously, a primer or lacquer may be applied to the metal coating which is optionally corona treated to increase toner adhesion. To increase color brilliance, the opaque layer is preferably a white layer.

The white layer contains 25-75% of a white pigment, for example titanium dioxide, chalk, barium sulfate, zinc sulfide, zinc sulfate or kaolin, preferably titanium dioxide, 75-25% of a plastic binder, which may be a polyolefin, polyolefin copolymer or polyurethane, with reference to the above list referenced by possible substances.

Preferably, the white layer additionally contains an inorganic crystalline substance, in particular silicic acid but also calcium carbonate or benzonite. The content of the inorganic crystalline substance is typically about 10 to 30% based on the dry amount of the white layer.

It has been shown that the opaque layer is advantageously less elastic and possibly has a certain brittleness.

The layer thickness of the opaque layer is about 2 to 15 g / m 2, preferably 4 to 12 g / m 2, especially 2 to 8 g / m 2, especially 3 to 5 g / m 2.

The opaque layer advantageously has glass transition or softening temperatures in the range of about 160-180 ° C.

According to the invention, the opaque layer may also be a combination of metallized coating and white layer.

In addition, according to a preferred embodiment of the present invention, component B comprises a transparent layer disposed over the opaque layer. The transparent layer suppresses a mixing of the toner with the opaque layer and thus serves to further increase the color brilliance.

The transparent layer consists of plastics, which have a certain affinity to the toner dyes, that is to record them in their matrix and on the other hand do not give it off again during washing. Plastics with softening temperatures above 80 ° C, preferably above 100 ° C, which do not become tacky at usual washing and use temperatures, are preferred. Optionally, additives such as silica or cellulose esters or other known processing aids can be added. Particularly suitable plastics are polyesters, polyurethanes, polyacrylates and other compounds, for example homopolymers or copolymers of vinyl acetate, vinyl alcohol, vinyl chloride, vinylidene chloride, methyl and / or ethylacrylic acid or methacrylic acid, maleic acid compounds, styrene and the like

Also suitable are cellulose esters and cellulose ethers such as ethyl cellulose, benzyl cellulose, cellulose propionates or acetates or butyrates or also polyesters of terephthalic acid or polyamides such as nylon or perlon.

The layer thickness of the transparent layer is about 2 to 15 g / m 2, preferably 4 to 12 g / m 2, especially 2 to 8 g / m 2, especially 3 to 5 g / m 2.

For the purpose of transferring an image to a substrate, the component A (transfer sheet) and the component B (opaque sheet) of the system according to the invention are first joined together under pressure and temperature. This is expediently carried out by pressing at about 2 to 5 bar in the temperature range from a minimum of about 130 to 150 ° C. to a maximum of about 200 to 250 ° C., for example from about 130 to 250 ° C., especially from about 50 ° C. to a maximum of about 200 - 250 ° C, especially from about 150 - 220 ° C, especially from about 150 - 200 ° C, typically for a minimum of about 15 - 20 sec. To a maximum of about 60 sec, in particular about 15 - 45 sec, preferably 15 - 30 sec.

The non-stick properties of the component A ensure that only a connection between the toner layer of the component A and the opaque layer of the component B, or the optionally arranged above transparent layer takes place, but not between the toner-free areas of the component A and the opaque layer of component B, or the optionally arranged above transparent layer.

Subsequently, a separation of the support of component B in the heat, typically in the range of about 0-15 sec. After the pressing process, under cohesive failure of the extrusion layer. As a result, the parts of the coating of the component B, which cover the toner-free regions of the component A, are separated or drawn off together with the carrier of the component B. The result is a sandwich structure of component A with layer layer structure of component B arranged only over the toner layer: support A -> toner layer -> optional transparent layer -> opaque layer -> extruded layer optionally containing wax (after cohesive failure). Depending on the composition of the extrusion layer, the optional wax layer (which may be disposed between the extrusion layer and backing B) and the opaque layer, the cohesive fracture may also be present in the optional wax layer or in a blend region of opaque layer and extrusion layer or extrusion layer and optional wax layer respectively. Accordingly, the structure of the obtained sandwich structure may vary.

In this state, the system according to the invention is ready for the transfer of the image to a substrate by applying the sandwich structure with the remaining extrusion layer to the substrate and the process being particularly advantageous under pressure and temperature conditions analogous to the printing process. and temperature conditions of the compound of component A and component B. This is therefore preferably carried out by pressing at about 2-5 bar in the temperature range of a minimum of about 100-150 ° C to a maximum of about 200-250 ° C, for example from about 100-250 ° C, especially from about 150 ° C to a maximum of about 200-250 ° C, especially from about 150-220 ° C, especially from about 50-200 ° C, also 180-220 ° C, typically for minimal about 15-20 seconds up to a maximum of about 60 seconds, in particular about 15-45 seconds, preferably 15-30 seconds.

The carrier of component A is then separated or withdrawn in the cold state. In this case, "cold state" means below the glass transition or softening temperatures of the layers, preferably in the region of room temperature.

The system according to the invention preferably consists of a combination of components A and B.

The method of the invention for transferring images to substrates comprises

the provision of a system according to the invention comprising the components A and B;

- The compound of component A and component B under pressure and temperature by pressing at about 2 - 5 bar in the temperature range of a minimum of about 130 - 150 ° C to a maximum of about 200 - 250 ° C, for example from about 130 - 250 ° C. , especially from about 50 ° C to a maximum of about

200-250 ° C, especially from about 150-220 ° C, especially from about 150-200 ° C, also 180-220 ° C, typically for a minimum of about

 15 to 20 seconds to a maximum of about 60 seconds, especially about 15 to 45 seconds, preferably 15 to 30 seconds;

the separation of the support of component B in the heat, advantageously above the softening range of the extrusion layer of component B, typically in the range of about 0-15 sec. After the pressing process, to obtain a sandwich structure; the application of the sandwich structure with the extrusion layer of component B to the substrate, wherein, depending on the composition of the extrusion layer, the optional wax layer and the opaque layer of component B, a cohesive fracture also optionally in the optional wax layer or in a blending area of opaque Layer and extrusion layer or extrusion layer and optional wax layer take place. Accordingly, the structure of the obtained sandwich structure and insofar as the layer to be applied to the substrate can vary;

- Subsequent pressing at about 2 - 5 bar in the temperature range of

 at least about 100-150 ° C to at most about 200-250 ° C, for example from about 100-250 ° C, especially from about 150 ° C to at most about 200-250 ° C, especially from about 150-220 ° C, especially about

150-200 ° C, also 180-220 ° C, typically for a minimum of about

 15 to 20 seconds to a maximum of about 60 seconds, in particular about 15 to 45 seconds, preferably 15 to 30 seconds, the image being transferred to the substrate; and

Separating the support of component A at a temperature below the glass transition or softening temperatures of the layers, preferably in the region of room temperature.

The process according to the invention can be carried out with customary devices, so-called transfer presses. Particularly advantageously, the step of connecting component A and B and transferring the image to the substrate can be carried out under the same pressure and temperature conditions, which requires particularly simple and rapid process control, since no additional cooling and / or heating phases are necessary , Accordingly, it is advantageous to make no changes to the settings of the transfer press used. Unless otherwise stated or necessarily different from the context, percentages are based on weight, in case of doubt on the total weight of the mixture.

The invention also relates to all combinations of preferred embodiments, as far as these are not mutually exclusive. The information "about" or "approx." in conjunction with a numerical indication, means that at least 10% higher or lower values or 5% higher or lower values and in any case 1% higher or lower values are included.

Claims

claims

A system for transferring images to substrates comprising a combination of two components A and B, wherein

 the component A comprises a carrier and an at least partial toner layer arranged on one side thereon and at least the toner-facing surface of the carrier has an equipment with non-stick properties,

 the component B comprises a carrier, a polymer layer arranged on one side and at least one further layer,

 wherein at least one surface of the support is provided with a polymer coating (extrusion layer) of polyolefins,

 Polyolefin copolymers or polyurethanes with a layer thickness of about 30 - 60 g / m2 is equipped, and

 the further layer is an opaque layer, the layer thickness of the further layer being approximately 2 to 15 g / m 2.

A system according to claim 1, characterized in that the equipment of the component A carrier is a coating of silicones or quilon products which is optionally additionally corona treated.

System according to claim 1 or 2, characterized in that the carrier of component A is a siliconized and corona-treated paper having a release value of the silicones of more than 100 cN / 20 mm, preferably about 100-200 cN / 20 mm, in particular about 00-150 cN / 20mm is.

System according to one of claims 1-3, characterized in that the opaque layer comprises a metal coating and / or a white layer containing 25-75% of a white pigment such as titanium dioxide, chalk, barium sulfate, zinc sulfide, zinc sulfate or kaolin, preferably titanium dioxide, and 75 - 25% of one Plastic binder, which is a polyolefin, polyolefin copolymer or polyurethane, wherein advantageously additionally an inorganic crystalline substance, such as in particular silica but also calcium carbonate or benzonite is included.

5. System according to any one of claims 1-4, characterized in that the component B additionally comprises a transparent layer which is disposed over the opaque layer.

6. System according to any one of claims 1-5, characterized in that the components A and B are designed to be connected to one another under pressure and temperature.

7. Siliconized and corona-treated paper with a basis weight of approx. 80-150 g / m2 and a release value of the silicones of approx

 100-200 cN / 20mm.

8. A method of transferring images to substrates comprising

 Provision of a system according to one of claims 1 - 6, comprising the components A and B,

 Connecting the component A and the component B under pressure and temperature by pressing at about 2 - 5 bar in the temperature range of about 130 - 250 ° C, typically for about 15 - 60 sec,

 Separating the carrier of component B in the heat typically in the range of about 0-15 seconds after the pressing process, to obtain a sandwich structure,

 Applying the sandwich structure with the uppermost layer remaining after separation of the carrier of component B, preferably the excitement layer of component B onto the substrate,

subsequent pressing at about 2 - 5 bar in the temperature range of about 00 - 250 ° C, typically for about 15 - 60 sec, and Separating the support of component A at a temperature below the glass transition or softening temperatures of the layers, preferably in the region of room temperature.

9. The method according to claim 8, characterized in that the joining of the component A and the component B and / or subsequent to the application of the sandwich structure pressing at about

 150-250 ° C., in particular at 150-220 × for about 15-45 seconds, preferably 15-30 seconds. 0. The method of claim 8 or 9, characterized in that the

 Separating the support of the component B in the heat above the softening of the extrusion layer of the component B takes place.

11. The method according to any one of claims 8 -10, characterized in that the step of connecting the component A and the component B and subsequent to the application of the sandwich structure pressing at the same temperature conditions, preferably at about

 180-220 ° C.