EP0110220B1 - Transfer printing process - Google Patents

Description

The invention relates to a method for transfer printing onto objects which are made of plastic or which carry a surface coating, for example a varnish, made of plastic. In transfer printing, which is mainly known from the textile industry, a dye is transferred from a flat ink carrier at elevated temperature to the surface to be printed by sublimation. During the ink transfer, the ink carrier is pressed against the surface of the object to be printed.

State of the art

Transfer printing on painted surfaces of solid objects, e.g. Sheet metal strips is described in DE-A 29 14 704. The transfer printing takes place during the passage of the coated sheet and a transfer printing paper over a calender. According to DE-A 26 42 350, the transfer printing is combined with the coating of a solid object by laminating a thermoplastic plastic film onto the surface of the solid object and at the same time transferring dyes from an ink carrier into the applied plastic layer. Various common methods can be used for lamination, such as high-frequency or ultrasonic lamination or hot air welding. Since the lamination and color transfer take place in the thermoplastic state of the plastic layer, the original gloss of the plastic surface is not retained in this process.

Task and solution

When transfer printing onto objects made of plastic or those with a plastic surface layer or lacquer layer, the surface gloss should essentially be retained. A suitable method should be easy to carry out under technical conditions. It has been found that the object can be achieved in that the flat ink carrier is pressed onto the surface to be printed during the dye transfer by means of superatmospheric gas pressure, the surface being kept at a temperature below the thermoplastic range. Whereas, when the ink carrier is pressed mechanically onto the surface to be printed at the temperature suitable for transfer printing, zones inevitably occur in which the pressure between the ink carrier and the surface becomes so high that the surface gloss is permanently impaired, by the method of the invention achieves a much more uniform pressure effect, whereby the surface gloss is retained.

Commercial usability

The process of the invention can be used to print on all substrates whose surface has a sufficient affinity for the sublimable dyes used in transfer printing. The method of the invention is used with particular advantage for printing on objects with a glossy surface or with a surface which is pressure-sensitive for other reasons.

The objects to be printed

consist at least on the surface of a plastic, which forms a coherent, possibly porous layer or matrix, has a sufficient affinity for the dyes used in transfer printing and softens at the temperatures to be used, where appropriate, to the thermoelastic but not to the thermoplastic state. Particularly advantageous are those plastics which, owing to a very high molecular weight or strong branching or crosslinking, have no thermoplastic state range, but rather soften at most thermoelastically.

Objects made entirely of plastic with a closed plastic surface are preferred, in particular flat sheets, sheets or foils. The boards or sheets can e.g. B. have a thickness of 1 to 12, preferably 2-8 mm. You can also print curved, arched or otherwise three-dimensionally shaped objects according to the invention, e.g. Pipes, domes, sanitary parts, illuminated advertising signs, injection molded parts etc. Furthermore, foams of sufficient temperature resistance, e.g. B. polymethacrylimide foam, printed by the method of the invention.

Another class of printable items are those that have a plastic surface layer, e.g. a laminated film or a layer of lacquer on a base made of another material, such as metal (sheet metal), ceramic, glass, asbestos cement boards, leather, wood, chipboard or hardboard, paper or cardboard. The plastic layer to be printed should have a thickness of at least 10 µm, preferably 50 J.lm to 1 mm.

A particularly suitable plastic for the method of the invention is acrylic glass. This includes homopolymers of methyl methacrylate and copolymers of a predominant proportion of this monomer, preferably at least 70%, and the rest of other copolymers that can be copolymerized therewith, and also acrylonitrile-methyl methacrylate copolymers. The acrylic glass can be polymerized in plate form; this so-called «cast acrylic glass» has no thermoplastic range due to its molecular weight of over 1 million. However, the acrylic glass can also be extruded from a thermoplastic, meltable molding compound. In this case, the transfer printing process can be connected directly to the production of the plastic web by extrusion. Other suitable plastics are polyethylene, polypropylene, polyvinyl chloride, polystyrene and impact-resistant butadiene Styrene plastics, polyoxymethylene, polycarbonate, glass fiber polyester and aminoplast plastics.

Opaque colored plastics are generally preferred, but clear, translucent or differently colored plastics or plastic layers are also suitable.

The flat color carriers,

which are usually used in textile printing or in other transfer printing processes are also suitable for the process of the invention. They can be printed in one color or in one or more colors in any pattern or motif. They are usually produced on paper by gravure, offset or screen printing, but plastic or metal foils are also used as the carrier material. Special sublimation dyes are used for printing, which have sufficient affinity for the plastic to be printed.

If only part of the surface of the object is to be printed on, the ink carrier can be smaller than the surface of the object. In the case of objects that are not flat, it may be advisable to use colored supports made of individual parts, which can be better laid out as a coherent piece on the surface. The individual parts can be used for transfer printing at the same time or one after the other. Ink carriers made of elastic plastic films are sometimes advantageous for printing spherically curved surfaces.

The ink carrier should be selected so that it does not tend to wrinkle or blister under the printing conditions. It is advantageous to pre-dry ink carriers made of paper below the sublimation temperature. In order to avoid impairing the gloss of the surface to be printed, a liquid or finely divided release agent, such as talc, is advantageously powdered onto the ink carrier. Powdering the plastic surface has proven less successful.

It is advisable to stretch the ink carrier elastically at a short distance - about 1 to 2 mm - over the surface to be printed and to bring it into contact with the surface only in the zone that is currently being affected by the compressed gas.

The compressed gas

usually consists of air. In rare cases, inert gases such as nitrogen or carbon dioxide will be used. The compressed gas acts directly or indirectly on the back of the ink carrier with a slight over-atmospheric pressure and must not spread around the front of the ink carrier, which lies against the object to be printed. A pressurized gas cushion can be used, whereby the pressurized gas can be enclosed in a cushion made of a soft film or a textile fabric that is not stiffer than the ink carrier itself. The direct action of the compressed gas cushion on the ink carrier is more advantageous, it being possible for a bell enclosing the gas cushion to rest on the edge of the ink carrier or to form a narrow air gap. The compressed gas escaping through this gap must be constantly replaced in order to maintain the required gas pressure.

The gas pressure can be on the order of 3 to 200 mm water column (WS), preferably 5-50 mm WS. Higher prints are not necessary for flat substrates and flexible ink carriers and can lead to annoying impressions or gloss damage.

The gas pressure is preferably generated by a flowing gas. You can e.g. B. allow compressed air to flow from a variety of individual nozzles from a short distance of, for example, 5 to 50 mm to the back of the ink carrier. The nozzles can e.g. consist of holes in a perforated plate at mutual intervals of 10 to 50 mm or of appropriately spaced slots. It is particularly advantageous if the flowing compressed gas is only allowed to act on a part of the back of the ink carrier in a limited zone and this zone is shifted over the back of the ink carrier until the entire surface has been printed. At every point, the dwell time must be sufficient for the required color transfer. Compressed air is expediently let out of a slot nozzle, the width of which spans the surface to be printed and which is gradually moved over the substrate. The substrate can also be moved under the fixed slot nozzle.

The required flow rate of the flowing gas depends on the distance of the nozzle from the ink carrier, on its flexibility, on the dynamic pressure which is formed depending on the possibility of gas outflow and on other circumstances of the individual case. In any case, the flow rate must be sufficient to keep the ink carrier in contact with the substrate surface for a sufficiently long time. If the ink carrier lies flat and remains flat when the gas is inflated, a lower flow rate is sufficient than if the ink carrier tends to form waves, folds or bubbles. However, the flow rate must not be increased so that the pressure of the ink carrier causes impressions or gloss damage on the substrate. Good results are achieved with flow velocities of 5 to 20 m / sec. The relative speed between the nozzle and the substrate can range from 0.1 to 2.0 m / min.

The transfer printing temperature

Most transfer inks sublimate between 100 and 300 ° C, especially between 150 and 250 ° C. During the exposure to the compressed gas, the ink carrier must reach the sublimation temperature of the dye and maintain this temperature until the ge Desired dye transfer has taken place. The transfer takes place the better the higher the temperature of the surface to be printed is, but it should remain lower than the temperature of the ink carrier, preferably below the sublimation temperature of the dye. The general aim is for the dye to diffuse into the surface to be printed by about 20 to 100 μm.

Since the dye carrier is to be heated to the sublimation temperature only immediately before the dye transfer begins and the sublimation process itself consumes heat, the heat required to maintain the sublimation temperature must be supplied to the dye carrier from the rear during the dye transfer. You can e.g. Arrange heat radiators in a bell, which includes a compressed gas cushion, the radiation of which is directed onto the back of the ink carrier. If you are working with a flowing compressed gas, it can be heated itself and act as a heat transfer medium. Radiant heaters can also be used.

The dye transfer can take place in a contact time between the surface to be printed and the ink carrier of 2 seconds to 5 minutes. The contact time preferably lasts from 5 to 15 seconds. Contact times in the range of seconds require not only a high temperature of the ink carrier, but also a preheating of the surface to be printed to the highest possible temperature. For thin-walled objects, such as Plates or foils made of plastics, plastic-coated sheets or laminates, it is usually sufficient to place the object on a heated surface some time before the transfer printing. Thicker or poorly heat-conducting objects are preheated in a heating cabinet or by means of radiant heaters.

When printing cast acrylic glass, it has proven useful to preheat the acrylic glass to 170-180 ° C and to blow hot air at a temperature of 250 to 350 ° C onto the back of the ink carrier. Under these conditions, a rich color transfer can be achieved in 5 to 15 seconds without affecting the surface gloss. Similar conditions come into consideration for thermosetting plastics or heat-crosslinked coating layers.

If thermoplastic plastics are printed with dyes whose sublimation temperature is in the plastic softening range, the temperature control requires careful control. The plastic may only be preheated to a temperature that is at most in the thermoelastic, but in any case clearly below the thermoplastic temperature range. During the contact time with the ink carrier, further heating of the plastic surface is unavoidable; however, this must be kept within such limits that the surface of the plastic does not become thermoplastic. Maintaining the surface gloss is a reliable indication of whether the boundary to the thermoplastic range has not been exceeded to such an extent that irreversible deformations of the surface could occur. The preheating temperature, the intensity of the heat during dye transfer and the duration of the contact time are coordinated so that rich ink transfer is achieved without the ink carrier starting to stick to the plastic surface, which can be seen as an indication of the thermoplastic state. The level of the gas pressure and the flow rate of the gas also influence the heat transfer to the plastic surface. If surface damage occurs as a result of the ink carrier sticking to the plastic surface, a lower preheating temperature or a reduction in pressure, flow velocity, temperature or the duration of exposure to the compressed gas or by throttling the supply of radiant heat can help.

Extruded acrylic glass, which is in the thermoplastic state above 150 ° C, can be printed according to the invention if it is preheated to 120-135 ° C and the ink carrier by means of a hot air jet with a temperature of 150-200 ° C and a flow rate of 5-20 m / sec during a contact time of 5 to 10 seconds. Pre-dried plastic sheets made of polycarbonate can be preheated to 180-200 ° C and allow a hot air temperature of up to 350 ° C.

Way of working

When the method is used in practice, care must be taken that the ink transfer can begin immediately as soon as the compressed gas acts. Either the surface to be printed must be sufficiently preheated before the pressure of the compressed gas or a suitable heat source must act on the ink carrier immediately. Preferably both requirements are met at the same time.

The object to be printed can be preheated in a circulating air cabinet and, if it softens thermoelastically, is placed on a suitable surface, preferably preheated to the same temperature. The object can also be heated lying on the support, for example by means of heat radiators. Now the ink carrier is applied cold and the pressurized gas is left to act. The ink carrier can be clamped in a frame for easy handling. After the ink transfer, the ink carrier is removed and the printed object may be left on the base until it has cooled below the softening temperature. For the continuous printing of an extruded plastic web, which is placed on an endlessly revolving steel band, it is placed on it at the point where it has cooled from the thermoplastic state to the temperature suitable for transfer printing ribbon-shaped ink carrier removed from a supply roll and pressed on with a slot nozzle arranged transversely to the flow direction by means of a hot air jet. If necessary, the web passes through several slot nozzles in succession. The ink sheet is then removed and the printed plastic sheet is cooled in a cooling zone.

Partial color transfer

In order to produce patterns from printed and unprinted partial areas on the object, the method of the invention can be carried out in such a way that the gas pressure is only allowed to act on a part of the back of the carrier in a limited zone.

According to the method of operation described so far, samples are only transferred from the ink carrier to the extent that they are already there.

In contrast, according to this embodiment, patterns are produced precisely by the fact that color is transferred from the ink carrier to the surface only from certain zones and these zones are selected such that a pattern of printed and unprinted partial areas results on the printed surface. The terms "printed" and "unprinted" refer only to the transfer prints produced by the present process. Of course, the surface to be printed can already contain patterns from unprinted and printed partial areas from a previous operation, which need not match the patterns to be produced.

For the purposes of the invention, a pattern is understood to be any arrangement of printed and unprinted surface parts which are attached to the object for technical or aesthetic reasons or for other reasons. It can be decorative ornaments, characters and symbols, guidelines for tool control and the like.

The dye carrier used can contain the transferable dye over the entire surface in a homogeneous distribution. In this case, the printed areas produced by the method of the invention are uniformly colored in themselves. If, on the other hand, an ink carrier is used which already contains a pattern of one or more colors or of ink-bearing and dye-free partial areas, the printed areas are patterned accordingly and possibly interrupted by non-colored areas within the zone affected by the gas pressure.

To create a line pattern according to the method of the invention one can e.g. blow a hot, sharply delimited gas jet from a short distance using a nozzle onto the selected zones on the back of the ink carrier and move it uniformly along the line to be generated. In this case, a line with a diffuse side boundary is usually created. Correspondingly, flat patterns are created by gradually letting the gas jet sweep over a larger zone.

A sharper delimitation of the printed areas can be achieved if the zone on the back of the ink carrier, which is affected by the gas pressure, is delimited by means of a template. Suitable as a template is a sheet metal cut out according to the pattern to be produced or another body which is not substantially deformable by the gas pressure which acts and which prevents the action of the gas pressure on other zones on the back of the ink carrier.

The areas of the back of the ink carrier that are left free from the stencil can be gradually covered with a hot gas jet until the entire pattern has been transferred. The gas space above the template can also be sealed off from the atmosphere and filled with a hot compressed gas, whereby the whole pattern is transferred at the same time.

A template suitable for the method of the invention is shown in cross section in FIG. In order to avoid uncontrolled color transfer under the covered surfaces (21) of the stencil (22), which can be caused by escaping hot gas, it is advantageous to enclose the open surfaces (23) of the stencil in a funnel shape (24) so that the escaping compressed gas finds sufficient space (25) for unpressurized escape. Sharp boundaries of the printed areas are achieved when the lower edge of the funnel-shaped borders (24) of the open areas (23) ends in a sharp cutting edge (26). If the stencil comes close to the ink carrier (10) and the surface to be printed (9), the funnel-shaped stencil walls (24) can be perforated with holes (28) through which cooled compressed gas can escape and be replaced by inflowing hot compressed gas. The heat required for the color transfer can also be applied to the back of the color support by means of a radiator (7) which is arranged in the closed compressed gas space (5).

Instead of an emitter, a laser can also be used, which is guided along the line to be generated or gradually covers a larger area. A sharp contour can also be created without a template.

example 1

A device according to FIG. 1 is used for printing on plastic plates, consisting of a table (1) through which a vacuum line (2) leads and on which a heating plate (3) is placed, a paper tenter (4), composed of an upper and a lower one lower frame half (4 ') and (4 "), as well as a heating bell (5) with compressed air connection (6) and a number of radiant heaters (7). The bell can be raised and lowered by means of a lifting cylinder (8).

A cold plate (9) made of 5 mm thick, white, cast acrylic glass is placed on the heating plate (3), which is heated to 150 ° C, during the Tenter frame (4) is not yet inserted. The bell (5) is lowered so far that the radiators (7) come sufficiently close to the plate (9) to heat it.

As soon as the surface of the plate (9) has reached a temperature of 150 ° C, which is the case after 5 minutes, the heating bell is raised, the paper tenter (4) is inserted so that it rests on the table (1) and the plate (9) without touching it. Between the frame halves (4 ') and (4 ") a transfer printing paper (10) is clamped with the color side down. The printed side of the paper (10) is powdered thinly with talc. The thickness of the lower frame half (4") is so dimensioned so that the paper (10) hovers at a distance of 0.1 to 0.5 mm above the plate (9). Due to the heat of the radiant heater (7), the paper tightens completely without wrinkles.

As soon as the frame (4) is placed on the table (1), the heating bell (5) is lowered by means of the lifting cylinder (8) until its edge (11) sits on the frame (4) and the interior of the bell (5) seals. By opening the compressed air valve (12) an excess pressure of 50 to 100 mm water column (compared to the atmospheric air pressure) is generated under the bell, whereby the paper (10) lies against the plate (9). This can be promoted by simultaneously evacuating the space below the paper (10) via the vacuum line (2); a negative pressure of 50 to 100 mm water column (compared to atmospheric air pressure) is sufficient.

The radiant heater (7) heats the paper (10) to the sublimation temperature of the dye of approximately 220 to 240 ° C. After 60 to 90 seconds, sufficient dye transfer into the plate (9) has occurred to a depth of penetration of 50 μm. Now the overpressure or underpressure is released, the bell (5) is lifted, the tensioning frame (4) is removed and the plate (9) is placed on a flat surface for cooling. If desired, it could also be inserted directly into a forming device. After cooling, the surface of the plate (9) bears the color pattern transferred from the paper (10) in strong colors and has a high-gloss surface.

Comparison test

• a) ein Filztuch von feiner Struktur
• b) eine weisse, 5 mm dicke, gegossene Acrylglasscheibe
• c) ein Transferdruckpapier mit der Farbseite nach unten; die Farbseite wurde vorher mit Talkum eingepudert
• d) ein nicht gefärbtes Schutzpapier
• e) ein Filztuch feiner Struktur

For comparison, transfer printing is carried out on a similar acrylic glass plate using a heatable press. The press contains a flat lower table and an upper table that can be raised and lowered in parallel, which is heated to 220 ° C by means of an electric heating device. In the open press, the following parts of approximately the same size are successively stacked on the lower table:

• a) a felt cloth of fine structure
• b) a white, 5 mm thick, cast acrylic glass pane
• c) a transfer printing paper with the color side down; the color side was previously powdered with talc
• d) a non-colored protective paper
• e) a felt cloth of fine structure

Then the upper table of the press is lowered so that the stack is pressed together with light pressure. After 5 minutes the top of the acrylic sheet has reached a temperature of 214 ° C and the bottom has reached a temperature of 158 ° C. Then the press is opened, the stack is taken apart and the acrylic glass plate is placed on a flat surface to cool off. The color pattern has been transferred from the transfer printing paper as vigorously as in Example 1, but the surface of the acrylic glass plate is matt.

Example 2

To produce a color pattern by partially transferring dye from a uniformly colored transfer printing paper, a device according to Figure (2) is used, which largely corresponds to the device according to Example 1, but with a template (22) on the underside of the bell (5) with covered areas ( 21) and open surfaces (23) is arranged. In this case, the heating plate (3) can be omitted.

An acrylic glass plate (9) as in Example 1 is used, but this is preheated outside the device to 60 to 70 ° C. and placed on the table (1) as long as the bell (5) is raised by means of the lifting device (8). The frame (4) with the transfer printing paper (10) - as described in Example 1 - is then placed on top and the bell (5) is lowered by means of the lifting device (8) until the cutting edges (26) of the template walls (24) hold the paper Touch (10). About 250 ° C hot compressed air is blown into the bell (5) through the line (12), so that there is an excess pressure of 50 to 100 mm water column. As a result of this pressure, which acts on the surface of the paper (10) through the open spots (23), this is applied to the plate (9). Compressed air can escape through the openings (28) in the template walls (24), so that hot air flows continuously from the bell (5) into the open positions (23).

After an exposure time of 2 minutes, sufficient dye transfer has occurred and the color has penetrated deep into the plate (9) by about 10 J.lm. Now the bell (5) is raised, the frame (4) is removed and the plate (9) is placed on a flat surface for cooling. It has a color pattern that corresponds exactly to the arrangement of the open spaces (23) and has a high-gloss surface.

With this method of operation, the radiant heater (7) did not need to be switched on. However, it is also possible to work with a non-heated compressed gas and to heat the paper (10) to the sublimation temperature of the dye by means of the radiant heater (7). With this method of operation, the openings (28) are unnecessary.

Example 3

A device is used for printing on plastic plates using a continuous process used according to Figure 3. It contains a horizontally movable table (31) heated to 130 ° C, which can be moved on rails (33) by means of a pushing device (32). The table is rounded at the front edge (39) and carries a clamping jaw (40) at a distance from the edge, which can be pressed on by means of pneumatics (41). The device also contains an emitter screen (34), a feed device (35) for the transfer printing paper, and a compressed air nozzle (36) which is connected to a compressed air line (37). A deflection roller (43) for the paper web is arranged under the feed device (35) so that it is at a distance from the table (31) that is 0.5 to 1 mm larger than the thickness of the plastic plate to be printed.

A 5 mm thick plate (38) made of white, extruded acrylic glass, which had previously been heated to 80 ° C. for a few hours to remove absorbed water, is placed on the table (31) and moved with it under the lamp screen (34). After 4 minutes the surface of the plate (38) has a temperature of 140 ° C. The radiation power of the radiator screen (34) is then reduced so that the surface temperature of the plate (38) located underneath remains constant.

During the preheating time, the edge (39) of the table (31) is under the feed device (35). There, the end of the paper web (42) is clamped between the edge (39) and the clamping jaw (40) by actuating the pneumatics (41). The printed side of the paper web is powdered thinly with talc. Now the table (31) is moved forward at a speed of 0.2 m / min in the direction of the compressed air nozzle (36). The paper web (42) rolls off the supply roll (44) in the feed device (35) and lies behind the deflection roll (42) closely over the plate (38). The color side of the paper web is directed downwards. The table (31) moves gradually under the nozzle (36), the paper web being pressed against the plate (38) by the air flow emerging there.

The compressed air nozzle (36) has an outlet slot (45) of 50 millimeters in width, which extends over the entire width of the table (31). Using a blower (not shown), air is passed through line (37) through a heating register (46) and heated to 225 ° C. The outlet slot (45) is at a distance of 0.5 to 1 mm from the top of the plate (38) or the paper web (42) resting thereon. He must not touch the paper web at any point. The entry speed of the air in the tube (37) is regulated so that an excess pressure of 10 to 15 mm water column is established in the nozzle (36). The action time of the nozzle opening on each plate point is about 15 seconds. The dye transfer is effected during this time; a depth of penetration of the paint into the plate (38) of 20 to 50 µm is obtained.

As soon as the plate (38) has passed completely under the nozzle (36), the paper web (42) is severed at the deflection roller (43), the cut-off part is removed from the plate (38) after opening the clamping device (39/40) and place the plate on a flat surface to cool it down. The color pattern has been transferred from the paper web (42) to the plate (38) in a strong, uniform color with a sharp outline; it has an unchanged high-gloss surface.

Example 4

The process according to Example 1 is repeated using a 5 mm thick, white polycarbonate plastic plate which had been predried at 120 ° C. for a few hours. The heating plate on which the plastic plate is placed has a temperature of 170 ° C. Under the conditions specified in Example 1, the surface of the plastic plate reaches a temperature of 180 ° C. after 4 minutes. Now the frame with the transfer printing paper is put on and the heating bell is lowered. After 1.5 minutes, the dye transfer is complete, the bell is raised, the frame is removed and the printed plate is allowed to cool. It has a high-gloss surface.

Example 5

A colored line pattern is created on a non-preheated acrylic glass plate by placing a uniformly colored transfer printing paper on the plate and moving a hot air nozzle along a contour template at a distance of 10 mm from the paper web. The hot air nozzle has an inner diameter of 5 mm. The air speed is regulated so that it creates a dynamic pressure of 40 mm water column at a distance of 10 mm from the nozzle opening. The air temperature is 300 ° C. The nozzle is moved at a speed of 2 to 4 mm / sec, whereby the paper turns slightly brown. After removing the transfer printing paper, the plastic surface shows a sharply contoured line pattern corresponding to the template used.

Claims (10)

1. Process for transfer printing on solid objects made of plastics or with a surface covering of lacquer or plastics, from a flat ink carrier at a temperature suitable for ink transfer, the ink carrier being pressed against the surface of the object which is to be printed, characterised in that the flat ink carrier is pressed against the surface to be printed during the ink transfer by means of a pressure of gas above atmospheric pressure, this surface being maintained at a temperature below the thermoplastic range.

2. Process as claimed in claim 1, characterised in that the gas pressure is produced by a gas flowing onto the back of the ink carrier.

3. Process as claimed in claim 2, characterised in that the gas pressure is allowed to act only in a restricted zone on part of the back of the ink carrier and this zone is gradually moved to other parts of the back of the ink carrier.

4. Process as claimed in claim 3, characterised in that the ink carrier is kept at a small spacing from the surface of the object which is to be printed outside the zone in which the gas pressure is acting and in said zone it is applied to and pressed against the surface by the gas pressure.

5. Process as claimed in claims 1 to 3, characterised in that before the gas pressure acts on the surface of the ink carrier a liquid or finely divided solid is applied as a parting agent.

6. Process as claimed in claims 1 to 5, characterised in that the object which is to be printed or at least the surface which is to be printed is preheated to a temperature suitable for ink transfer before the gas pressure is applied.

7. Process as claimed in claims 1 to 6, characterised in that a non-flat object is printed.

8. Process as claimed in claim 7, characterised in that a plurality of ink carriers, each covering only part of the surface which is to be printed, are applied to the non-flat object simultaneously or one after another.

9. Method as claimed in claims 1 to 8, characterised in that in order to produce patterns consisting of printed and unprinted areas on the surface, the gas pressure is applied only in a restricted zone to part of the back of the ink carrier.

10. Process as claimed in claim 9, characterised in that the part of the back of the ink carrier on which the gas pressure acts is limited by means of a template or stencil which prevents the gas pressure from acting on other parts of the back of the ink carrier.

Images