DE102010055532A1 - A method for producing a multilayer packaging material and method for applying an adhesive, and apparatus therefor - Google Patents

Abstract

The invention relates to a method for producing a multilayer packaging material, in which a hot melt adhesive is provided, in which the hot melt adhesive is melted, in which the hot melt adhesive is applied to a first packaging material (10, 42, 62) and in which a second is applied to the hot melt adhesive Packaging material (14, 52, 68) is applied, the hot-melt adhesive being provided as an adhesive film (4, 44, 66) and the adhesive film (4, 44, 66) being exposed to a plasma jet (8, 32, 50, 70 , 78) is melted. The invention further relates to a device for applying an adhesive, with a housing (92, 122, 160, 176, 186), with an adhesive supply (96, 126) arranged on the housing (92, 122, 160, 176, 186) and with means for activating the adhesive (110, 130, 142, 196, 206) arranged on the housing (92, 122, 160, 176, 186), the housing (92, 122, 160, 176, 186) having an opening ( 94, 124) for the exit of the adhesive (110, 130, 142, 196, 206), the adhesive supply (96, 126) being designed as a supply for an elongated adhesive (110, 130, 142, 196, 206) and wherein the means for activating the adhesive (110, 130, 142, 196, 206) as at least one plasma nozzle (98, 100, 132, 144, 192, 202) for generating an atmospheric plasma jet (98, 104, 134, 158, 198, 208) are formed.

Description

The invention relates to a method for producing a multilayer packaging material in which a hot melt adhesive is provided in which the hot melt adhesive is melted, wherein the hot melt adhesive is applied to a first packaging material and in which a second packaging material is applied to the hot melt adhesive. Furthermore, the invention relates to a method and apparatus for applying an adhesive, in particular a hot melt adhesive, in which an adhesive is provided in which the adhesive is activated and in which the adhesive is applied to a surface. Furthermore, the invention relates to a method for producing a packaging by adhering at least two sections of the packaging material to at least one splice.

Multilayer packaging materials are used in the prior art, for example, if a single-layer packaging would not ensure sufficient stability or if the required material properties, in particular surface properties of the packaging with a single-layer packaging would not be attainable or only at great expense.

In order to ensure a sufficient connection of the individual packaging layers in a multilayer packaging, the above-mentioned method is frequently used in the prior art. For this purpose, first a pot of hot melt adhesive is heated until the hot melt adhesive is melted. The hot melt adhesive is then applied to a first packaging material, for example with a brush or a nozzle. Finally, a second packaging material is placed on the hot melt adhesive, so that the two packaging materials are firmly connected to each other after cooling of the hot melt adhesive. Comparable methods are used, for example, in US 2007/0243293 A1 or in the US 2006/0121245 A1 disclosed.

For bonding workpieces, adhesives in the form of hot melt adhesives are also generally used in the prior art. For example, hot glue guns are known with which a rod-shaped hot melt adhesive can be activated by melting and then applied to the surface to be bonded.

The prior art methods described above have the disadvantage that the melting of the hot-melt adhesive is time-consuming. Another problem is the exact dosage of the hot melt adhesive. Finally, this method can not always guarantee a full-surface adhesion of the packaging materials or of the surface to be bonded.

The present invention is therefore based on the object to provide a method and an apparatus with which the disadvantages of the prior art are at least partially avoided.

This object is achieved in a method for producing a multilayer packaging material, wherein a hot melt adhesive is provided in which the hot melt adhesive is melted, in which the hot melt adhesive is applied to a first packaging material and in which a second packaging material is applied to the hot melt adhesive according to the invention solved that the hot melt adhesive is provided as an adhesive film and that the adhesive film is melted by the application of a plasma jet.

It has been recognized that the production of a multilayer packaging material can be considerably simplified in this way. By providing the hot melt adhesive as an adhesive film, a simple and accurate dosage of the hot melt adhesive is ensured. Preferably, the adhesive film has a thickness adapted to the two packaging materials, so that the required amount of hot melt adhesive can be provided.

By applying the adhesive film to a plasma jet, the melting of the hotmelt adhesive can take place very quickly and in a metered manner, so that the operating speed of the process can be increased. In particular, eliminates an initial dead time for melting a larger melt adhesive mass. Compared with the melting of an adhesive film with hot air, with a continuous furnace or with a flame of the adhesive film can be melted faster with a plasma jet or with little equipment.

The method is basically not limited to two packaging materials. In particular, multi-layered packaging materials having three or more layers can also be produced.

In particular, plastic films, paper, cardboard, metal foils or composite films may be considered as packaging materials.

In the context of the invention, a plasma jet is understood in particular to mean an at least partially ionized gas stream due to an electrical discharge. Preferably, an atmospheric plasma jet is used.

In a preferred embodiment of the method, the plasma jet is generated by means of a high-frequency high voltage. The melting of an adhesive film with a plasma jet generated in this way has proved to be particularly effective. Furthermore, with such a plasma jet, an effective pretreatment of the surface of the packaging material can be achieved.

As plasma sources are in particular those in the publications DE 195,32,412 C2 . DE 10 2006 060 942 A1 and EP 1 236 380 B1 considered plasma nozzles into consideration.

Under a hot melt adhesive in the context of this application adhesives are understood which are solid at room temperature and melt by heating, so that they can be applied to a surface to be bonded. During cooling, the hot melt adhesive solidifies again. Hotmelt adhesives based on olefins, in particular amorphous poly-α-olefins (APAO), polyamides (PA), polyurethane elastomers (TPU), polyester elastomers (TPE), copolyamide elastomers (CoPa) and / or Ethylene / vinyl acetate copolymers (EVA) into consideration. These hot melt adhesives have been found to be particularly advantageous for plasma activation.

The adhesive film may preferably have a width of several millimeters, for example 5 mm or 10 mm, up to several centimeters, for example 2 cm or 5 cm. The adhesive film is preferably at least 1 m, more preferably several meters long. For example, the thickness of the adhesive film may be on the order of 100 μm to 1 mm.

In a preferred embodiment of the method, the adhesive film is provided by unwinding from a roll. In this way, the adhesive film can be stored to save space and easily provided in the required length.

The melting of the adhesive film can be accelerated in a further embodiment of the method in that the adhesive film is applied on both sides with a plasma, in particular with a plasma jet. In this way, the processing speed can be further increased. In particular, the adhesive film is melted on both sides so that a middle, non-molten layer of the adhesive film remains. This ensures that the adhesive film does not break off.

In a further preferred embodiment of the method, the plasma is simultaneously applied to the surface of the first and / or the second packaging material. In this way, in addition to a melting of the plastic film is achieved that the surface of the first and the second packaging material is pretreated by the plasma. By such a pretreatment, the adhesiveness of the surface of the packaging material is increased, thereby ensuring better adhesion with the adhesive film. For this purpose, for example with a plasma nozzle, a plasma jet can be introduced into the gap between the adhesive film and the first or the second packaging material. For improved melting of the adhesive film, a second plasma nozzle may additionally be provided on the other side of the adhesive film.

Preferably, the adhesive film can be adjusted specifically to the reactivity of the pretreated surface of the packaging material. For example, if the surface of the packaging material has a high adhesion after pretreatment with the plasma jet, a thinner adhesive film or a less adhesive hot melt adhesive may be used.

A further simplification of the method is achieved in a further embodiment in that the adhesive film is melted after application to the first packaging material. This makes it possible to melt the adhesive film only slightly and then gluing it to the packaging material. Unwanted solidification of the adhesive film before application to the first packaging material can thus be prevented.

This embodiment is particularly suitable for very thin adhesive films, since the adhesive film applied to the packaging material is stabilized by the packaging material and thereby tearing of the adhesive film is prevented.

The embodiment described in the previous paragraph shows a particular combination effect with the use of a plasma jet for melting the adhesive film, since the plasma jet does not damage the packaging surface, in contrast to a flame melting.

The flexibility of the method is increased in a further preferred embodiment by first packing an article with the first packaging material. The adhesive film is then subsequently applied to the first packaging material. In this way, the multilayer packaging material can be produced directly during the packaging process. Since the adhesive film with the plasma jet can be melted very easily and flexibly, is the Production of a multilayer packaging material in this embodiment directly adaptable to the needs. An intermediate storage of the multilayer packaging material is not required. Furthermore, the number of layers of the packaging material can be selected individually and customized.

The object underlying the invention is further in a device for applying an adhesive, in particular a hot melt adhesive, comprising a housing, with an adhesive reservoir disposed on the housing and arranged on the housing means for activating the adhesive, wherein the housing has an opening for Leaving the adhesive, according to the invention solved in that the adhesive supply is designed as a supply for an elongated adhesive and that the means for melting the adhesive are formed as at least one plasma nozzle for generating an atmospheric plasma jet.

By using an elongated adhesive, the amount of adhesive applied to the surface can be precisely metered. In particular, the amount to be applied can be determined by the thickness of the elongate adhesive. In addition, with the plasma jet, the elongated adhesive can be activated very quickly and in a metered manner, so that the device allows an economical and rapid application of adhesive.

By elongated adhesives are meant adhesives in a form having a large aspect ratio between the longitudinal extent and the transverse dimensions, in particular an aspect ratio of at least 10: 1, preferably at least 20: 1, more preferably at least 50: 1 or even 100: 1. These adhesives allow a basically continuous adhesive supply. In particular, adhesive fibers or adhesive films are understood as elongated adhesives. For better storage of the elongated adhesive is preferably reelable.

The adhesive reservoir may preferably be arranged in the housing. However, it is also conceivable that the adhesive reservoir is disposed upstream of the housing and in the housing an additional opening is provided, through which the adhesive can pass from the adhesive reservoir into the housing.

Activation of the adhesive means that the adhesive is placed in a condition in which application of the adhesive to a surface and curing of the adhesive is possible. A preferably used hot melt adhesive is activated, for example, by melting. Due to the heat input of the plasma jet softens the hot melt adhesive, so that it can be applied after activation on the surface to be bonded and cured there on cooling. However, adhesives are also conceivable in which a chemical setting reaction is activated by the action of the plasma jet.

More preferably, an adhesive is used which has no adhesiveness prior to activation by the plasma jet, i. H. is not tacky. This facilitates storage and handling of the adhesive prior to activation.

When using a hot melt adhesive, the elongated hot melt adhesive is preferably not completely melted by the plasma jet, but only so far that the elongated hot melt adhesive does not melt or break. This can be done in particular by only superficial melting of the hot melt adhesive. In this way, the meterability of the hot melt adhesive and the continuity of its application can be further improved.

The plasma nozzle is preferably operated with a high-frequency high voltage. The atmospheric plasma jet is preferably non-thermal, that is, the ion temperature of the plasma jet is significantly below the electron temperature. In this way, a comparatively cool plasma jet, for example, of an ionic temperature of a few 100 ° C, preferably less than 500 ° C, are generated. This allows an economical and reliable operation of the device and prevents the decomposition or burning of the adhesive.

The device is preferably designed wearable. Preferably, the device is also suitable for manual operation.

In a preferred embodiment of the method, the adhesive supply has a roll for receiving the elongate adhesive. In this way, the elongated adhesive can be accommodated to save space. The elongate adhesive can be unrolled from the roll during operation and passed through the plasma jet to the opening of the housing.

The economy of the device is increased in a further embodiment in that the at least one plasma nozzle is arranged in the region of the opening of the housing. In this way, the elongated adhesive can be applied immediately after activation on the surface to be bonded, without causing premature solidification or setting of the adhesive.

If the plasma nozzle is also arranged so that the plasma jet at least partially emerges from the opening, the surface to be bonded can be treated simultaneously with the plasma jet.

A uniform activation and improved metering is achieved in a further embodiment of the device in that a plasma nozzle is designed as a slot nozzle or a plurality of plasma nozzles are arranged side by side. In this way, in particular an adhesive film-like adhesive can be economically, quickly and homogeneously activated, in particular melted.

In a further preferred embodiment of the device, the means for activating are formed as a plurality of plasma nozzles, which are preferably arranged so that the plasma jets act on the elongate adhesive from different directions. This allows a fast activation and a higher application speed of the adhesive can be achieved. Upon application of the elongate adhesive from different directions, melting that is more homogeneous over the thickness of the adhesive can be achieved. The latter embodiment is particularly suitable for thicker adhesive fibers or films or for higher melting hot melt adhesives.

A particularly compact construction of the device is achieved in a further preferred embodiment in that the elongate adhesive is passed through the plasma nozzle, preferably through a hollow center electrode of the plasma nozzle. Furthermore, it can be achieved that the adhesive enters into intense, possibly all-round contact with the plasma jet and can be activated so quickly. This allows an increased job speed.

In a further preferred embodiment of the device, a precursor feed is provided on the housing, preferably on a plasma nozzle. The precursor supply allows a precursor to be guided into the plasma jet. The precursor may be, for example, a precursor for plasma coating or plasma treatment. The plasma nozzle can in this case, for example, as in the WO 01/32949 A1 be formed described plasma nozzle.

The device described above can preferably be used to carry out the method described above or below.

The object underlying the invention is also in a method for applying an adhesive, in particular a hot melt adhesive, preferably using a device according to the invention, in which an adhesive is provided, in which the adhesive is activated and in which the adhesive on a surface is applied, according to the invention solved in that the adhesive is provided as an elongated adhesive and that the elongated adhesive is activated by the application of an atmospheric plasma jet.

In a preferred embodiment of the method, the adhesive is provided as an adhesive fiber or adhesive film, in particular by unwinding from a roll. In this way, the required amount of adhesive can be made available quickly and accurately.

The adhesive is crosslinked in a further preferred embodiment of the method by the plasma jet. In particular, the adhesive consists of a non-crosslinked or slightly crosslinked polymer, which is crosslinked by the influence of the plasma jet. In this way, the properties of the adhesive, for example the temperature resistance, can be improved by the plasma jet. The crosslinking can be carried out, for example, by radicals in the plasma jet or by the UV light produced by the plasma jet. Due to the UV component in the plasma jet, the UV crosslinking can also be carried out in particular in the bonding of intransparent materials, while transparent materials were required for the previously subsequent UV crosslinking.

The plasma activation of the elongate adhesive can be improved in a further embodiment of the method in that the elongated adhesive at least partially from olefins, in particular amorphous poly-α-olefins (APAO), polyamides (PA), polyurethane elastomers (TPU), polyester Elastomers (TPE), copolyamide elastomers (CoPa) and / or ethylene / vinyl acetate copolymers (EVA) consists.

In a further embodiment of the method, a setting process of the hot-melt adhesive is activated by the plasma jet. Under the Abbindevorgang is understood, for example, a chemical or physical reaction, which leads to a curing of the adhesive. For example, the adhesive may comprise a reaction inhibitor, preferably an organic reaction inhibitor, which is removed or deactivated by the action of the plasma jet. After deactivation or removal of the reaction inhibitor, the adhesive can then be crosslinked, for example. It is also conceivable that the adhesive as Two-component adhesive is formed, whose setting reaction is initiated by the plasma jet. It is also possible to use so-called "warm melts" as adhesives. These "warm melts" are adhesives which cure after a particular exceeding of a threshold temperature, in particular crosslinking.

A flexibilization of the method is achieved in a further preferred embodiment in that a precursor, in particular a silane precursor, is introduced into the plasma jet. The precursor is preferably activated and / or polymerized by the plasma jet. In this way, the adhesive or the surface to be bonded can be plasma-coated. It is also possible that the precursor initiates a setting reaction of the adhesive. Silanes are for example suitable for activating an initially non-adhesive adhesive. In this way, the adhesive can be activated shortly before the order on the surface to be bonded. Premature bonding is thus prevented and the handling of the adhesive is simplified.

Oxidation- or hydrolysis-sensitive precursors, such as, for example, silane precursors, are preferably introduced as aerosol directly into the plasma jet. In this way, an undesirable chemical reaction of the precursor can be avoided before entering the plasma jet. The plasma nozzle can be like a in the DE 10 2008 029 681 A1 be formed described plasma nozzle.

Alternatively or additionally, the activation and / or the application of the adhesive can take place under a protective gas, for example a nitrogen atmosphere. For this purpose, the device may for example have a corresponding protective gas supply.

Further embodiments of the method result from combination with features of the method described at the beginning. Thus, the method last described can be carried out in particular also for the production of a multilayer packaging material according to the method described first.

The method according to the invention and the device according to the invention are based on the common inventive principle that the combined use of an elongate adhesive, in particular a hotmelt adhesive, and a plasma jet for activating or melting the elongated adhesive provides better meterability and faster and more economical application of the adhesive is reached.

With the described method or with the device described in particular laminations can be applied to surfaces, for example laminations on glasses or mirrors, or textile lamination of plastic parts in car interiors. Furthermore, electrical components can be fixed with this method or with this device, window profiles can be encased or objects can be labeled. In particular, the methods and apparatus are suitable for small local adhesive applications.

The above object is achieved according to another teaching of the invention by a method for producing a package in which the packaging material is provided at a predetermined location with an adhesive film. The method is characterized in that the adhesive film is activated by the application of a plasma jet and that subsequently the point provided with the adhesive film is glued to another portion of the packaging material.

According to the invention, it has thus been recognized that, even in the production of packaging from single-layer or multi-layer packaging materials by means of splices, the packaging material is permanently connected to one another, the plasma technology can be used in an advantageous manner.

By way of example, the production of a folding box from a cardboard material and the production of a tubular bag may be mentioned here. In both cases, the packaging material is initially flat, so that it can be printed and cut or punched. Before, between or after the individual preparation steps, the adhesive film can be applied, wherein the adhesive film can be formed in any arrangement, so selectively, strip-shaped or flat, on the predetermined location.

During the completion of the packaging, the adhesive film is then activated first with the plasma jet, ie in particular in the case of a hot-melt adhesive, heated or melted. Subsequently, the two sections of the package to be joined are brought together and, if necessary, pressed together to produce a permanent connection by means of the adhesive action.

The method can be carried out in such a way that two different sections of a packaging material, for example a cardboard sheet or a tubular film, are glued together. It is also possible that two different packaging materials are glued together in sections. The can Packaging materials may be the same or different. For example, transparent window films can be bonded to a corresponding section of a packaging material, such as cardboard or tubular film, using the method according to the invention.

The properties and advantages of the materials and adhesives that can be used and the plasma generation described above for the method for producing a multilayer packaging material or for the method for applying an adhesive can be applied to the method last described and their advantages can be utilized.

Further features and advantages of the invention can be taken from the following description of several embodiments, reference being made to the accompanying drawings.

In the drawing show

1 a first embodiment of the method according to the invention,

2 A second embodiment of the method according to the invention,

3 A third embodiment of the method according to the invention,

4 A fourth embodiment of the method according to the invention,

5 A fifth embodiment of the method according to the invention,

6 A first embodiment of the device according to the invention and an embodiment of the method according to the invention,

7 A second embodiment of the device according to the invention and an embodiment of the method according to the invention,

8th A third embodiment of the device according to the invention and an embodiment of the method according to the invention,

9 A fourth embodiment of the device according to the invention and an embodiment of the method according to the invention,

10 A fifth embodiment of the device according to the invention and an embodiment of the method according to the invention,

11 A sixth embodiment of the device according to the invention and an embodiment of the method according to the invention,

12 a seventh embodiment of the device according to the invention and an embodiment of the method according to the invention and

13 an inventive embodiment of a method for producing a package.

1 shows a first embodiment of a method according to the invention. From a roll 2 becomes an adhesive film 4 made of hot melt adhesive and thus provided. The adhesive film 4 is then through one of a plasma nozzle 6 generated plasma jet 8th guided. At the plasma nozzle 6 For example, it is one in the publication EP 1 236 380 B1 described plasma nozzle with which a broad plasma jet can be generated. The speed with which the adhesive film 4 through the plasma jet 8th is performed, is sized so that the adhesive film 4 is melted. Is the speed of the adhesive film 4 on the other hand, alternatively, the distance of the plasma nozzle can 6 or a parameter of the plasma nozzle 6 for plasma jet generation, for example, the frequency, the voltage or the gas flow can be adjusted. In particular, the plastic film 4 so through the plasma jet 8th that led the plastic film 4 Although sufficiently melted, but not melted or torn.

The melted adhesive film 4 is then on a first packaging material 10 applied, which in the present embodiment of a second role 12 is rolled off. On the adhesive film 4 will still be a second packaging material 14 applied, for example, by a third role 16 is rolled off. This results in a multilayer packaging material 18 ,

The application of the adhesive film 4 on the first packaging material 10 and applying the second packaging material 14 on the adhesive film 4 can be like in 1 displayed simultaneously or alternatively also successively.

To the stability of the packaging material 18 can increase pressure rollers 20 . 22 be provided, which are the first and the second packaging material 10 . 14 and the adhesive film 4 press against each other. Alternatively or additionally, pressure straps can also be provided for this purpose.

The multilayer packaging material 18 Finally, may be on another role 24 be rolled up. Alternatively, the multilayer packaging material 18 also directly further processed, in particular a packaging machine (not shown) to be supplied.

This in 2 illustrated, second embodiment of the inventive method differs from the first embodiment in that the adhesive film 4 on both sides with plasma jets 8th . 32 is charged. For this purpose, for example, an additional plasma nozzle 34 be provided. Furthermore, in this embodiment, the application of the adhesive film 4 on the first packaging material 10 and the order of the second packaging material 14 on the adhesive film 4 offset each other.

3 shows a third embodiment of the method according to the invention. On a first packaging material 42 becomes an adhesive film 44 applied. In the gap 46 between the adhesive film 44 and the first packaging material 42 comes with a plasma nozzle 48 a plasma jet 50 brought in. In this way, the plasma film of the adhesive film 44 before contact with the first packaging material 42 melted and at the same time the surface of the first packaging material 42 pretreated. By the pretreatment of the first packaging material 42 will the adhesion with the adhesive film 44 further increased. Finally, on the adhesive film 44 a second packaging material 52 applied, leaving a multi-layered packaging material 54 results. Alternatively or additionally, with a further plasma nozzle (not shown), a plasma jet into the gap 56 between the adhesive film 44 and the second packaging material 52 be introduced, so that the surface of the second packaging material 52 is pretreated.

This in 4 shown embodiment of the method differs from the embodiment described above by the arrangement of the plasma nozzle 48 , The adhesive film 44 is therefore with a plasma jet 50 after being put on the first packaging material 42 was applied. In this embodiment, for bonding the adhesive film 44 with the first packaging material 42 only a particularly low degree of melting required, since the melted adhesive film 44 immediately with the first packaging material 42 connects without causing premature solidification of the adhesive film 44 comes. The processing speed can be increased thereby.

5 shows a further embodiment of the method. For this purpose, first an object to be packaged 62 with a first packaging material 64 packed up. On the first packaging material 62 then becomes an adhesive film 66 and then a second packaging material 68 applied. The adhesive film 66 is through a plasma jet 70 melted, for example, by a plasma nozzle 72 in the gap 74 between the first packaging material 64 and the adhesive film 66 is introduced. Alternatively or additionally, one with a plasma nozzle 76 generated plasma jet 78 also in the gap 80 between the adhesive film 66 and the second packaging material 68 be introduced. Of course, the plasma jets can also be repositioned if necessary.

6 shows a first embodiment of a device according to the invention and an embodiment of a method according to the invention for applying an adhesive, in particular a hot melt adhesive. The device 90 has a housing 92 with an opening 94 , a glue supply 96 and two plasma jets 98 . 100 on. In the case 92 may also be provided only one or more than two plasma nozzles.

The plasma jets 98 . 100 are with a voltage source 102 connected, which can provide a high-frequency high voltage. Alternatively, several voltage sources 102 be used. When using a voltage source 102 can the device 90 be made more compact. The plasma jets 98 . 100 are preferably operated at a voltage of 1 kV to 100 kV and a frequency of 1 kHz and 100 kHz. Furthermore, the plasma nozzles 98 . 100 connected to a working gas source (not shown). As a working gas in particular air, nitrogen or Formiergas (mixture of nitrogen and hydrogen) or a noble gas into consideration. The plasma jets 98 . 100 For example, like those in the EP 1 335 641 A1 , of the WO 01/43512 A1 or the DE 10 2006 060 942 A1 be formed described plasma nozzles. The plasma jets 98 . 100 generate atmospheric, non-thermal plasma jets during operation 104 . 106 , The ion temperature is in these plasma jets 104 . 106 well below the electron temperature, so the plasma jets 104 . 106 having a low temperature compared to plasma discharge generated with an arc discharge.

The voltage source 102 may preferably provide an AC voltage or a pulsed DC voltage. At an AC voltage, the plasma jets 98 . 100 preferably so to the voltage source 102 be connected to that first plasma nozzle 98 with the upper half-waves and the second plasma nozzle 100 is acted upon by the lower half-waves of the high-frequency AC voltage.

The glue supply is preferred as a roll 108 formed on which an elongated adhesive 110 can be wound up as an adhesive fiber or adhesive film or wound up. The elongated glue 110 is through the plasma jets 104 . 106 and through the opening 94 of the housing 92 guided. By the action of the plasma jets 104 . 106 becomes the elongated glue 110 activated, leaving it after exiting the opening 94 can be applied to a surface to be bonded. At the glue 110 it may in particular be a hot melt adhesive, which by the plasma jet 104 . 106 is melted on its surface.

The elongated glue 110 may be preferred before activation in the plasma steel 104 . 106 especially by in the housing 92 pre-heated heating means are arranged.

The plasma jets 98 . 100 are preferably arranged so that the elongated adhesive 110 from several sides with the plasma jets 104 . 106 acted upon and activated more uniformly and faster than unilateral loading, in particular, is melted. Furthermore, the plasma jets 98 . 100 be arranged so that the plasma jets 104 . 106 out of the opening 94 emerge from the housing. In this way, the surface to be bonded by the exiting plasma jets 104 . 106 be treated. Alternatively, the plasma jets 98 . 100 arranged so that the plasma jets 104 . 106 not through the opening 94 occur, so that, for example, a sensitive surface to be bonded before exposure to the plasma jets 104 . 106 is protected.

The housing 92 can be formed in one piece or multiple parts. In particular metals, ceramics and / or plastics come into question as materials. The housing preferably has a compact size, so that it is portable, particularly preferably operated in manual mode. In the area of the opening 94 For example, the housing may be metallic to shield electrical fields. The area of the opening 94 may also be formed of insulating material to the plasma jets 104 . 106 not to influence.

7 shows a second embodiment of a device according to the invention and an embodiment of a method according to the invention. The device 120 has a housing 122 with an opening 124 on. In the case 122 is a glue supply 126 as a role 128 formed on which an elongated adhesive 130 wound up as an adhesive film or as an adhesive fiber. Furthermore, a plasma nozzle 132 in the area of the opening 124 of the housing 122 arranged. The elongated glue 130 is unwound from the roll and through the with the plasma nozzle 132 generated plasma jet 134 led and thereby melted. The molten elongated glue 130 can after exiting the case 122 be applied to the surface to be bonded. The plasma nozzle 132 is preferably arranged so that the plasma jet is not out of the opening 124 exit. This can damage surfaces outside the case 120 be avoided.

The device 120 Optionally, a Precursorzuführung 136 have, with which a precursor 138 from a precursor supply 140 into the plasma jet 134 can be performed. The precursor 138 is through the plasma jet 134 preferably activated and / or polymerized. Preferably, in this way a layer on the adhesive 130 be deposited. It is also conceivable that the adhesive effect of the adhesive 130 only activated by the precursor. For this purpose, preferably a silane precursor can be used.

8th shows a third embodiment of a device according to the invention and an embodiment of a method according to the invention. In the device 140 becomes the elongated glue 142 through the plasma nozzle 144 guided. The plasma nozzle 144 preferably has a nozzle channel 146 , a hollow center electrode 148 and at least one counter electrode 150 on. Between the hollow center electrode 148 and the counter electrode 150 a high-frequency high voltage is applied, so that between them to electrical discharges 152 comes in 8th schematically represented by arrows). Through the nozzle tube 146 will be in the direction of the arrow 154 a working gas, such as air, nitrogen or forming gas, led, which with the electrical discharges 152 interacts. This interaction leads to the formation of a nozzle opening 156 of the nozzle tube 146 emerging plasma jet 158 , The elongated glue 142 is through the center electrode 148 guided and thus enters the plasma jet 158 in which the adhesive is activated or melts. The housing 160 the device 140 is formed by the nozzle tube. Alternatively, the device 140 also around the plasma nozzle 144 arranged housing (not shown).

In particular, the high voltage between the hollow center electrode 148 and the counter electrode 150 be created that the center electrode 148 or the counter electrode 150 is grounded. In particular, the nozzle tube can also 146 be designed as a counter electrode, wherein the nozzle tube 146 then on the center electrode 148 facing side except for an area near the nozzle opening 156 is isolated.

9 shows a perspective view of a fourth embodiment of a device according to the invention and an embodiment of a method according to the invention. In the device 170 becomes the elongated glue 142 as with the in 8th illustrated device 140 through the plasma nozzle 144 guided. The same components are provided with the same reference numerals. The nozzle tube 146 and the hollow electrode 148 show in 9 a substantially round cross section. The elongated glue 142 is as an adhesive fiber 172 formed and is through the hollow electrode 148 into the plasma jet 158 guided. The adhesive fiber is thereby activated or melted and can be applied to the surface to be bonded 174 be applied. The counter electrode 150 is in 9 formed substantially cylindrically symmetrical. Of course, there are other shapes or more counterelectrodes 150 possible. In. the device 170 forms the nozzle tube 146 the housing 176 , Alternatively, an additional housing (not shown) may be provided.

10 shows a perspective view of a fifth embodiment of a device according to the invention and an embodiment of a method according to the invention. In the device 180 becomes the elongated glue 142 also like in the 8th illustrated device 140 through the plasma nozzle 144 guided. Like components are again provided with the same reference numerals. The nozzle tube 146 and the hollow electrode 148 show in 10 a substantially rectangular cross section. The elongated glue 142 is as an adhesive film 182 formed and is through the hollow electrode 148 into the plasma jet 158 guided. The adhesive film is thereby activated or melted and can be applied to the surface to be bonded 184 be applied. In 9 are two elongated counter electrodes 150 intended. Of course, there are other shapes or a different number of counter electrodes 150 possible. In the device 180 forms the nozzle tube 146 the housing 186 , Alternatively, an additional housing (not shown) may be provided.

11 shows a sixth embodiment of a device according to the invention and an embodiment of a method according to the invention. In the device 190 are only the plasma nozzles 192 and as an adhesive film 194 trained elongated adhesive 196 shown. The glue supply and the housing are in 11 not shown. The adhesive film 194 gets at the device 190 by the of several, preferably juxtaposed plasma nozzles 192 generated plasma jets 198 guided. In this way, a uniform and rapid activation or melting of the adhesive film 194 reached. The plasma jets 192 can also be used on both sides of the adhesive film 194 be arranged.

12 shows a seventh embodiment of a device according to the invention and an embodiment of a method according to the invention. As in 11 are also in the device 200 only the plasma nozzle 202 and as an adhesive film 204 trained elongated adhesive 206 shown. The adhesive film 204 gets through by the plasma nozzle 202 generated, wide plasma jet 208 passed through and is thereby activated or melts on. The width of the plasma jet 208 is preferred to the width of the adhesive film 204 customized. There may also be several plasma jets 202 be provided. In particular, a plasma nozzle 202 also on the other side of the adhesive film 204 be arranged. As a plasma nozzle 202 comes for example in the WO 01/43512 A1 described plasma nozzle in question.

13 shows in four steps an embodiment of a method according to the invention for producing a package 300 , wherein in the present case the manufacture of a folding box is explained by way of example.

13a shows the packaging material 302 in the form of a cardboard box in a top view. The box 302 is partially provided with texts. Along predetermined dashed lines 304 The cardboard is punched and along the dash-dotted lines 306 provided with folds.

13b shows the back of the box 302 , At predetermined points an adhesive film is applied. At the in 13b left section 308 of the cardboard, the adhesive film is selectively at predetermined locations 310 applied while on the right section 312 strip-shaped adhesive films 314 be applied.

13c shows the next process step, the cardboard 302 is shown without the punched corner sections, so that at each corner of the carton to be bonded section 316 is formed in the form of tabs. The adhesive films 310 and 314 are now using a plasma nozzle 320 that have a plasma jet 322 produced, activated, in particular melted at a hot melt adhesive, then the sections 316 with the adhesive films 310 respectively. 314 to stick together.

13d shows the finished carton 300 , with the inside of the section 308 glued section 316 can be seen.

The preparation of the box 302 with punches, introducing folds and attaching the adhesive films happens with temporal Distance before the completion of the packaging. The distance depends on the individual case, with a directly subsequent completion as well as a longer time interval and possibly at another location is possible.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2007/0243293 A1 [0003]
• US 2006/0121245 A1 [0003]
• DE 19532412 C2 [0014]
• DE 102001060942 A1 [0014]
• EP 1236380 B1 [0014, 0074]
• WO 01/32949 A1 [0040]
• DE 102008029681 A1 [0048]
• EP 1335641 A1 [0084]
• WO 01/43512 A1 [0084, 0097]
• DE 102006060942 A1 [0084]

Claims (15)

Method for producing a multilayer packaging material, - in which a hotmelt adhesive is provided, - in which the hotmelt adhesive is melted, - in which the hotmelt adhesive is applied to a first packaging material ( 10 . 42 . 62 ) is applied and - in which on the hot melt adhesive, a second packaging material ( 14 . 52 . 68 ), characterized in that - the hotmelt adhesive is used as the adhesive film ( 4 . 44 . 66 ) and that the adhesive film ( 4 . 44 . 66 ) by the application of a plasma jet ( 8th . 32 . 50 . 70 . 78 ) is melted. Method according to claim 1, characterized in that the adhesive film ( 4 . 44 . 66 ) by rolling from a roll ( 2 ) and that preferably the adhesive film ( 4 . 44 . 66 ) on both sides with a plasma jet ( 8th . 32 . 50 . 70 . 78 ) is applied. Method according to claim 1 or 2, characterized in that with the plasma jet ( 8th . 32 . 50 . 70 . 78 ) simultaneously the surface of the first ( 10 . 42 . 62 ) and / or the second packaging material ( 14 . 52 . 68 ) is applied. Method according to one of claims 1 to 3, characterized in that first an object ( 62 ) with the first packaging material ( 10 . 42 . 62 ) is packed. Device for applying an adhesive, in particular a hotmelt adhesive, with a housing ( 92 . 122 . 160 . 176 . 186 ), - with one on the housing ( 92 . 122 . 160 . 176 . 186 ) arranged adhesive stock ( 96 . 126 ) and - with on the housing ( 92 . 122 . 160 . 176 . 186 ) means for activating the adhesive ( 110 . 130 . 142 . 196 . 206 ), - the housing ( 92 . 122 . 160 . 176 . 186 ) an opening ( 94 . 124 ) to the exit of the adhesive ( 110 . 130 . 142 . 196 . 206 ), characterized in that - the adhesive stock ( 96 . 126 ) as a supply for an elongated adhesive ( 110 . 130 . 142 . 196 . 206 ) and - that the means for activating the adhesive ( 110 . 130 . 142 . 196 . 206 ) as at least one plasma nozzle ( 98 . 100 . 132 . 144 . 192 . 202 ) for generating an atmospheric plasma jet ( 98 . 104 . 134 . 158 . 198 . 208 ) are formed. Device according to claim 5, characterized in that the glue supply ( 96 . 126 ) a roll for receiving the elongated adhesive ( 110 . 130 . 142 . 196 . 206 ) having. Apparatus according to claim 5 or 6, characterized in that the at least one plasma nozzle ( 98 . 100 . 132 . 144 . 192 . 202 ) in the region of the opening ( 94 . 124 ) of the housing ( 92 . 122 . 160 . 176 . 186 ) is arranged. Device according to one of claims 5 to 7, characterized in that the means for activating as a plurality of plasma nozzles ( 98 . 100 . 132 . 144 . 192 . 202 ), which are preferably arranged so that the plasma jets ( 98 . 104 . 134 . 158 . 198 . 208 ) the elongated adhesive ( 110 . 130 . 142 . 196 . 206 ) from different directions. Device according to one of claims 5 to 8, characterized in that the elongate adhesive ( 110 . 130 . 142 . 196 . 206 ) through the plasma nozzle ( 98 . 100 . 132 . 144 . 192 . 202 ), preferably by a hollow central electrode ( 148 ) of the plasma nozzle ( 98 . 100 . 132 . 144 . 192 . 202 ), to be led. Device according to one of claims 5 to 9, characterized in that on the housing ( 92 . 122 . 160 . 176 . 186 ), preferably at a plasma nozzle ( 98 . 100 . 132 . 144 . 192 . 202 ) a precursor feed ( 136 ) is provided. Method for applying an adhesive, in particular a hot-melt adhesive, preferably using a device according to one of Claims 5 to 10, - in which an adhesive ( 110 . 130 . 142 . 196 . 206 ), - in which the adhesive ( 110 . 130 . 142 . 196 . 206 ) is activated and - in which the adhesive ( 110 . 130 . 142 . 196 . 206 ) on a surface ( 174 . 184 ), characterized in that - the adhesive ( 110 . 130 . 142 . 196 . 206 ) as an elongated adhesive ( 110 . 130 . 142 . 196 . 206 ) and that the elongated adhesive ( 110 . 130 . 142 . 196 . 206 ) by exposure to an atmospheric plasma jet ( 98 . 104 . 134 . 158 . 198 . 208 ) is activated. Method according to claim 11, characterized in that the elongated adhesive ( 110 . 130 . 142 . 196 . 206 ) as an adhesive fiber ( 172 ) or adhesive film ( 182 . 194 . 204 ), in particular by rolling from a roll ( 108 . 128 ), provided. A method according to claim 11 to 12, characterized in that the adhesive ( 110 . 130 . 142 . 196 . 206 ) through the plasma jet ( 98 . 104 . 134 . 158 . 198 . 208 ) or through the plasma jet ( 98 . 104 . 134 . 158 . 198 . 208 ) a setting process of the adhesive ( 110 . 130 . 142 . 196 . 206 ) is activated. Use of a device according to one of Claims 5 to 10 for carrying out a method according to one of Claims 1 to 4. Method for producing a packaging, - in which the packaging material ( 302 ) at a predetermined location ( 308 . 312 ) with an adhesive film ( 310 . 314 ), characterized in that - the adhesive film ( 310 . 314 ) by the application of a plasma jet ( 322 ) is melted and - then that with the adhesive film ( 310 . 314 ) with a further section ( 316 ) of the packaging material is glued.

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