Direct printing method for printing a cover layer onto containers
Method for direct printing on containers via a direct printing machine, with a print layer printed onto the container, in a first predefined area, in a first device, and a cover layer applied to the container in a second device, the cover layer applied to a second predefined area. A surface area of the second predefined area is larger than that of the first predefined area. The cover layer coalesces with the printing ink in the first predefined area, creating a first connection, and coalesces with the container in parts of the second predefined area differing from the first predefined area, creating a second connection. The first and second connections are insoluble in aqueous solutions having a pH value between 3 and 10 and easily soluble in aqueous solutions having a pH value in a range of less than 3 and/or higher than 10.
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The present application claims the benefit of priority of German Application No. 10 2013 207 799.8, filed Apr. 29, 2013. The application is incorporated herein by reference in its entirety.
FIELD OF THE DISCLOSUREThe disclosure relates to a direct printing method and a corresponding direct printing machine for printing different layers onto containers, such as bottles.
BACKGROUNDPrinting on containers, such as bottles, is known from the prior art to a sufficient extent. Also the use of a plurality of print layers is disclosed e.g. in DE 10 2010 044 243 A1, where an intermediate or base layer is provided, which is first applied to the container surface, whereupon the print layer is applied to this base layer. Physical properties, such as adhesion strength and migration properties, are determined by the respective parameters between the print layer and the intermediate layer on one hand and the intermediate layer and the container surface on the other.
SUMMARY OF THE DISCLOSURETaking this prior art as a basis, it is one aspect of the present disclosure to improve existing direct printing methods, in particular with respect to the recyclability of the products produced by this method.
The direct printing method according to the present disclosure used for printing on containers, such as bottles, with the aid of a direct printing machine by which a print layer is printed onto the container, at least in a first predefined area thereof, in a first device in a first step and a cover layer is applied to the container in a second device in a second step, the cover layer being applied to a second predefined area, which comprises the first predefined area and the surface area of which is larger than that of the first predefined area, the cover layer coalescing with the printing ink in the first predefined area thus creating a first connection, the cover layer coalescing with the container in parts of the second predefined area which differ from the first predefined area thus creating a second connection, and the first and second connections being insoluble in first aqueous solutions having a pH value between 3 and 10 and easily soluble in second aqueous solutions having a pH value in a range of less than 3 and/or higher than 10. Through this cover layer the printing ink can, on the one hand, be fixed to the surface of the container without having to adhere strongly to the container and, on the other hand, the print layer is thus protected against environmental influences, such as scratches or the like. Furthermore, the recycling properties of the printed containers are improved, since the fact that the cover layer is soluble in basic solutions facilitates the separation of the underlying print layer from the container.
According to one embodiment, the direct printing method includes that the cover layer is applied to the second area with the aid of a rolling device or a flushing device or a spraying device or a dipping device or a direct printing device or a plasma coating device or a flame pyrolysis device. Due to these manifold possibilities of applying the cover layer, flexible methods for applying the cover layer are available, in particular as regards the shape that can be produced as well as specific properties of the cover layer.
According to a further embodiment, the direct printing method includes that the cover layer is easily soluble in the second aqueous solutions at a temperature of at least 70° C. The solubility of the cover layer, in particular at high temperatures, substantially improves the recyclability of a container that has been printed on in this way, since in normal scrubbing solutions the pH value is significantly lower than 3 or higher than 10 on the one hand and the temperature often lies in the range between 70 and 100° C. on the other. An advantageous aspect is here that only the cover layer must have these properties with respect to solubility. The print layer or the print layers need not have these properties and, consequently, the materials used for the print layers can be provided more easily.
Furthermore, the print layer according to the present disclosure may easily be soluble in the second aqueous solutions. The result is that not only the cover layer can be detached during a recycling process but also the print layer can be removed in the aqueous solution used.
Moreover, the second predefined area and the first predefined area may be geometrically similar. A cover layer applied in such an accurate fashion reduces the cost of material and is more eco-friendly and more ecological.
According to one embodiment, the distance of a point on the edge of the first predefined area to the edge of the second predefined area is identical for any point on the edge of the first predefined area. The result is that the print layer is uniformly enclosed by the cover layer on all sides and that weak points, which might already occur during the production process, will be avoided.
In addition, the material of the cover layer may, when exposed to radiation of a specific wavelength, react with a change of at least one of the properties adhesion strength, color, barrier properties, migration properties, the container being irradiated with radiation of this specific wavelength with the aid of an irradiation unit arranged downstream of the second device, when seen in the conveying direction. The containers printed on can thus be provided with cover layers having specific properties, which exceed an improved recyclability. For example, the cover layer may thus have specific optical characteristics or specific degrees of hardness.
According to one embodiment, the cover layer is applied to the container depending on sensor data indicative of the geometrical shape of the print layer. Making use of the respective sensor data, the cover layers can be applied to each container in a customized manner, and this can contribute to further economization and to a more eco-friendly and more ecological recycling.
According to a further embodiment, at least one further print layer is applied to a third predefined area between the first step in the second step, the third predefined area being at least partially congruent with the first predefined area, or the third predefined area being different from the first predefined area, the first and the third predefined areas defining a printed region and the second predefined area comprising the printed region and the surface area of the second predefined area being larger than the printed region. A direct printing machine having this kind of structural design can apply a cover layer to a container that has already been printed on, said cover layer being able to protect the print layer against environmental influences.
In addition, a direct printing machine is provided for printing on containers such as bottles, the direct printing machine comprising a conveyor device for conveying the containers through the printing machine along a conveying direction, a first device for applying a print layer to a first predefined area of the container and a second device for applying a cover layer to a second predefined area of the container, the first device being arranged upstream of the second device when seen in the conveying direction, characterized in that the second device is suitable for applying the cover layer to the second predefined area, the second predefined area comprising the first predefined area and the second predefined area being larger than the first predefined area. Depending on process parameters and on the demands to be satisfied by the cover layer, the use of one or more of these devices for applying the cover layer may be of advantage. The printing machines in question may be configured as linear-type or carousel-type machines.
In the direct printing machine, the second device may comprise a rolling device or a flushing device or a spraying device or a dipping device or a direct printing device or a plasma coating device or a flame pyrolysis device, said devices being capable of applying the cover layer. Depending on process parameters and on the demands to be satisfied by the cover layer, the use of one or more of these devices for applying the cover layer may be of advantage.
In addition, the direct printing machine may comprise an irradiation unit arranged downstream of the second device when seen in the conveying direction, said irradiation unit being capable of emitting radiation in a specific wavelength region and the material of the cover layer reacting to an irradiation with radiation in this specific wavelength region. When the cover layer is irradiated in this way, it can have imparted thereto special characteristics such as a specific degree of hardness/dryness or optical characteristics.
According to a further embodiment, the direct printing machine includes a sensor, which is arranged downstream of the first device and upstream of the second device when seen in the conveying direction and which is capable of measuring the geometrical shape of the print layer and of transmitting to a data processing unit a signal indicative of the geometrical shape of the print layer, the data processing unit being capable of generating a signal for controlling the second device, the signal being indicative of the second predefined area and the second device being controllable in response to this signal. The provision of adequate sensors and control units for controlling the second device, which applies the cover layer, allow and ecological and effective application of the cover layer.
Furthermore, means suitable for applying at least one further print layer to a third area may be arranged downstream of the first device and upstream of the second device when seen in the conveying direction. The application of a plurality of print layers below the cover layer allows the production of a great variety of print images, which may also consist of more than one layer.
In this device, the cover layer is applied via additional treatment units 121. Since the cover layer may perhaps not be a substance or a mixture of substances corresponding to conventional printing inks, the treatment units 121 are specially suitable for applying the substances used for the cover layer. Also for this purpose, the treatment units 121 of the second device 102 are connected via lines 123 with storage tanks 122, in which the material or the mixtures of substances for the cover layer are stored. In the second device 102, the cover layer is applied via the treatment units 121 at least to areas which have previously been printed on in the first device 101, so that the print layer or the print layers are fully covered by the cover layer. The containers 133 which have thus been printed on and provided with the cover layer then leave the second device 102 via an additional conveyor.
Before printing has been finally completed, an irradiation unit 104 may be provided, the containers 133, which have been printed on and provided with the cover layer, being moved into and irradiated in said irradiation unit 104. This irradiation may e.g. change the chemical properties or the physical properties of the cover layer applied. It can, for example, be used for finally curing the cover layer. To this end, the irradiation unit 104 preferably emits radiation or light of a specific wave length. This may be radiation in the visible range (light) or in the invisible range, such as IR radiation or UV radiation. When the irradiation has been completed, the container 132 can be transferred to further devices. Transport can be achieved by, for example, a further conveyor 105.
Irrespectively of the here described specific embodiment of the printing machine or direct printing machine 100, it should be mentioned that said machine may generally be configured as a linear-type or a carousel-type machine.
In the next step, the cover layer 253 is applied in the second device which is shown in
In a further method step, the substrate 230 with the print layer 251 and the cover layer 253 can then be irradiated with irradiation 241 from an irradiation source 204. This irradiation may e.g. be an input of heat energy or light energy, such as UV radiation or visible light. Such irradiation 241 may be used in the event that the cover layer 253 applied in the preceding step should, immediately after its application, not yet have the properties required. If the cover layer is applied e.g. with the aid of an inkjet process or screen printing or with the aid of plasma coating processes or e.g. by means of flame pyrolysis, a subsequent treatment may be necessary. For levelling e.g. irregularities in the cover layer in a controlled manner, the heat treatment may be used, whereby a smoother surface will be accomplished by superficially fusing and subsequently curing the cover layer. It is thus also guaranteed that the print layer 251 will preferably be covered by a cover layer 253 having the same thickness throughout its whole area. Furthermore, the degree of hardness of the cover layer may be changed through irradiation, using e.g. UV light, after application of the layer, so that specific demands on the cover layer can be fulfilled.
Since the cover layer is configured for being soluble in aqueous solutions having an pH value of less than 3 and/or higher than 10, suitable materials for such cover layers being e.g. polymers, a container printed on in this way will be particularly easy to recycle. Especially when the print layers or the printing inks used for these layers do not strongly adhere to the container, but are encapsulated and fixed to the container by the overlying cover layer, the cover layer and the print layers located therebelow can, when the container is shredded into plastic flakes, as is normally done in recycling processes, easily be removed from the plastic flakes in a suitable basic solution, since the disintegration of the container into plastic flakes and especially the use of a basic solution have the effect that the cover layer will be dissolved or at least broken open, and this will lead to dissolving of the print layers in the aqueous solution. The cover layer may also adhere very strongly to the print layer, so that the print layer may be entrained by the cover layer when the latter is separated from the container, and this can increase the efficiency of the recycling process still further. In addition, the cover layer may preferably consist of UV inks or water- and solvent-based lacquers. Also hot melt inks may be used here. Known primer materials of the type disclosed e.g. in DE 10 2010 044 243 A1 may be used as a cover layer as well. Also flame-pyrolytic layers consisting preferably of silicon oxide layers are advantageous. Depending on the material used, also the barrier properties of the container or at least of the area in which the cover layer is provided can be improved in this way. This applies especially to the diffusion of gases, such as oxygen or carbon dioxide, or of other substances, which should not penetrate into the material with which the container is filled.
Claims
1. A direct printing method for printing on containers with the aid of a direct printing machine, comprising printing a print layer onto the container, in a first predefined area thereof, in a first device in a first step, and applying a cover layer to the container in a second device in a second step, the cover layer being applied to a second predefined area, which comprises the first predefined area and the surface area of which is larger than that of the first predefined area, the cover layer coalescing with the printing ink in the first predefined area thus creating a first connection, the cover layer coalescing with the container in parts of the second predefined area which differ from the first predefined area thus creating a second connection, and the first and second connections being insoluble in first aqueous solutions having a pH value between 3 and 10 and easily soluble in second aqueous solutions having a pH value in a range of less than 3 and/or higher than 10, wherein the second connection between the cover layer and the container is stronger than a connection between the print layer and the container and the first connection is stronger than the connection between the print layer and the container.
2. The direct printing method according to claim 1, and applying the cover layer to the second area with the aid of one of a rolling device, a flushing device, a spraying device, a dipping device, a direct printing device, a plasma coating device, and a flame pyrolysis device.
3. The direct printing method according to claim 1, the cover layer being easily soluble in the second aqueous solutions at a temperature of at least 75° C.
4. The direct printing method according to claim 1, the print layer being easily separated from the container in the second aqueous solutions.
5. The direct printing method according to claim 1, the second predefined area and the first predefined area being geometrically similar.
6. The direct printing method according to claim 5, the distance of a point on the edge of the first predefined area to the edge of the second predefined area being identical for any point on the edge of the first predefined area.
7. The direct printing method according to claim 1, such that, when exposed to radiation of a specific wavelength, the material of the cover layer reacts with a change of at least one of the properties adhesion strength, color, barrier properties, migration properties, and wherein the container is irradiated with radiation of this specific wavelength with the aid of an irradiation unit arranged downstream of the second device when seen in the conveying direction.
8. The direct printing method according to claim 1, and between the first step and the second step, at least one further print layer is applied to a third predefined area, the third predefined area being at least partially congruent with the first predefined area, or the third predefined area being different from the first predefined area, the first and the third predefined areas defining a printed region and the second predefined area comprising the printed region and the surface area of the second predefined area being larger than the printed region.
9. A direct printing machine for printing on containers, comprising a conveyor device for conveying the containers through the printing machine along a conveying direction, a first device for applying a print layer to a first predefined area of the container and a second device for applying a cover layer to a second predefined area of the container, the first device being arranged upstream of the second device when seen in the conveying direction, wherein the second device suitable for applying the cover layer to the second predefined area, the second predefined area comprising the first predefined area and the second predefined area being larger than the first predefined area wherein: the first device applies the print layer to the container establishing a connection between the print layer and the container, the second device applies the cover layer to the print layer establishing a first connection between the cover layer and the print layer and applies the cover layer to the container establishing a second connection between the cover layer and the container; and wherein the second connection between the cover layer and the container is stronger than the connection between the print layer and the container and the first connection is stronger than the connection between the print layer and the container.
10. The direct printing machine according to claim 9, the second device comprising one of a rolling device, a flushing device, a spraying device, a dipping device, a direct printing device, a plasma coating device, and a flame pyrolysis device, and such respective devices being capable of applying the cover layer.
11. The direct printing machine according to claim 9, the direct printing machine comprising an irradiation unit arranged downstream of the second device when seen in the conveying direction, the irradiation unit being capable of emitting radiation in a specific wavelength region and the material of the cover layer reacting to an irradiation with radiation in this specific wavelength region.
12. The direct printing machine according to claim 9, and means suitable for applying at least one further print layer to a third area are arranged downstream of the first device and upstream of the second device when seen in the conveying direction.
13. The direct printing method according to claim 1, the containers comprising bottles.
14. The direct printing machine according to claim 9, the container comprising bottles.
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Type: Grant
Filed: Feb 20, 2014
Date of Patent: Nov 24, 2015
Patent Publication Number: 20140320574
Assignee: KRONES AG (Neutraubling)
Inventor: Andreas Kraus (Lappersdorf)
Primary Examiner: Jannelle M Lebron
Assistant Examiner: Jeremy Bishop
Application Number: 14/185,046
International Classification: B41J 2/00 (20060101); B41J 3/407 (20060101); B41J 11/00 (20060101); B41M 5/00 (20060101); B41M 7/00 (20060101);