The present invention relates to a method and an apparatus for joining paper material, in particular paper, cardboard or paperboard or the like, wherein the joining process may be carried out without additional auxiliary materials, in particular in a manner that is free of plastics materials and/or adhesive.
EP 0 340 334 A2 discloses an apparatus which joins paper products by means of ultrasonic. The paper used in said document has a thermoplastic coating. This thermoplastic coating is melted on during the joining process. After cooling and curing, the joining regions of the paper layers are then interconnected. Furthermore, DE 10 2013 225 745 A1 discloses an ultrasonic joining method for connecting paper material, in which method ultrasonic friction welding is carried out. These known methods have proven themselves in principle, but there is an urgent need, in particular due to stricter environmental regulations, for packaging, for example, to be made entirely of paper material that is recyclable and contains no other additional ingredients, in particular plastics materials or adhesives or the like, which can result in environmental pollution.
By way of contrast, the method according to the invention for joining paper materials has the advantage that untreated paper material can be used to produce packaging, for example. This is achieved according to the invention in that the method for joining paper material, which has a first and a second joining region, comprises the following steps: roughening the first and/or second joining region, moistening the first and/or second joining region and joining the first and second joining region between a sonotrode and an anvil of an ultrasonic unit by means of ultrasonic friction welding, wherein a vibration direction of the sonotrode is not parallel to a joining force direction of a joining force. The first and second joining region can be provided on a single paper material, or one joining region is provided on a separate paper material. Roughening the joining region ensures that a three-dimensional increase of the joining region is achieved at the joining surface. The additional provision of water on the joining surface allows a hydrogen bridge bond to be formed during the joining process. The joining process is carried out using pressure and ultrasonic action.
The clever concept of roughening the paper surface increases the strength of the connection produced. During the roughening process, individual paper fibers are released from the paper composite and brought to the surface of the joining region. This increases the roughness of the joining surface.
The method according to the invention can be carried out in various ways.
In a first step, the joining region of the paper material is preferably roughened and then the roughened joining region is moistened with water or another liquid. The second joining region remains untreated. The joining process can then be carried out.
Alternatively, the first joining region is roughened and the second joining region is moistened. The roughened joining region and the second moistened joining region are then joined together.
According to a further alternative, the first joining region of the paper material is moistened and then the moistened first joining region is roughened. The second joining region can remain untreated or alternatively be roughened or alternatively only moistened or further alternatively both roughened and moistened.
Due to the heat introduced during the ultrasonic friction welding, the water applied by the moistening evaporates and a stable connection between the two paper materials can be achieved.
The invention is particularly preferably carried out on only the first joining region, wherein further preferably first roughening and then moistening being carried out. The second joining region can thus be left untreated and a joining process can then be carried out.
By carrying out the roughening process before the joining step, a significantly improved connection between the two joining regions of the paper materials is thus achieved. The step of roughening is preferably carried out by machine so that the joining region is always uniformly roughened.
The dependent claims show preferred further developments of the invention.
Preferably, a particularly good ultrasonic friction welding process is ensured if a vibration direction of the sonotrode is perpendicular or substantially perpendicular to the joining force direction. This ensures high energy input into the joining region, and therefore the joining time can be significantly shortened.
The method is preferably carried out continuously. In this way, for example, a closed seam, which is used in particular in packaging or the like, can be produced. Continuous execution of the method also ensures a linear joining connection in the joining regions. Alternatively, the method is carried out discontinuously if, for example, no closed joining connection is to be produced.
Particularly good joining results are obtained if the roughening of the first joining region and/or the second joining region is carried out in such a way that a roughness in a range of ±20 μm, in particular ±10 μm, around a central plane of the paper material is achieved. As a result, substantially consistent roughening of the surface of the joining region can be achieved, which leads to excellent joining results.
Further preferably, a width of the roughened joining region is equal to a width of the moistened joining region. The joining process is further preferably carried out entirely without additives, in particular thermoplastic plastics materials or adhesives or the like. In particular, the paper materials to be joined are free of plastics material and adhesive. Furthermore, the paper materials do not have any plastics material coating or the like.
A particularly compact apparatus for carrying out the method is achieved if the step of roughening is also carried out by means of ultrasonic. In this case, two ultrasonic units can then be arranged one after the other, the first ultrasonic unit for roughening at least one joining region and then the second ultrasonic unit for carrying out the joining step.
The roughening process is preferably carried out continuously or alternatively discontinuously. If the roughening process is to be carried out by means of ultrasonic, a sonotrode of an ultrasonic unit is preferably designed such that the sonotrode has a flat sonotrode surface directed toward the paper material. As a result, excellent roughening can be obtained in a predetermined range.
The present invention also relates to an apparatus for joining paper materials, comprising
Thus, the ultrasonic friction welding apparatus ensures that a vibration direction of the sonotrode and a joining force direction of the joining force are not parallel, and thus increased heat input is achieved by the ultrasonic friction welding process.
The anvil is preferably a roller or roll. In this way, it is easily possible for the joining force or the roughening force to have a different direction to the direction of vibration.
The roughening apparatus is further preferably an ultrasonic generator. A separate ultrasonic generator is preferably used here.
According to a further preferred embodiment of the invention, the roughening apparatus ensures a roughness which is in a range of ±20 μm, preferably ±10 μm.
The present invention also relates to paper packaging which is produced by the method according to the invention. The paper packaging is particularly preferably food packaging. Since the paper packaging can be produced so as to be free of plastics material and also free of other foreign matter, the paper packaging can be completely recycled.
Preferred embodiments of the invention are described in detail below with reference to the accompanying drawings, in which:
An apparatus 1 and a method for joining paper material according to a first embodiment of the invention are described in detail below with reference to
In this embodiment, a first paper material 2 and a second paper material 3 are intended to be joined together at a joining region, in particular an edge region of the paper materials. The paper materials can, for example, be removed from a roller as continuous goods. The paper materials are free of plastics material and adhesive and have no coating at all.
A first joining region 20 is provided on the first paper material 2. A second joining region 30 is provided on the second paper material 3. This is shown schematically in the representation of the method according to the invention in accordance with the first embodiment in
In the first embodiment, only the first joining region 20 is treated with a plurality of method steps, whereas the second joining region 30 remains without treatment. I.e., the second joining region 30 corresponds to the surface of the planar paper material.
As can be seen from
In this embodiment, the roughening apparatus 4 is an ultrasonic roughening apparatus, which is shown in detail in
When roughening by means of the roughening apparatus 4, the roughness of the surface of the first joining region 20 can be selectively influenced by means of the vibration duration and the vibration amplitude. The longer the vibration period, the more the surface of the first joining region 20 is changed and roughened. If the amplitude of the vibration of the sonotrode is reduced, the peel strength of the joined connection goes.
A contact surface of the sonotrode 70 with the first paper material 2 is preferably somewhat roughened, for example by means of glass bead blasting, such that better results are obtained during the roughening process.
As can also be seen from
In particular, no additives or plastics material coatings of the paper materials 2, 3 or the like are possible due to the roughening process. Untreated paper materials can be used for the joining process. As a result, the method according to the invention can be used universally.
In the next step, the roughened first joining region 201 is moistened by means of the moistening apparatus 5. This creates a roughened, moistened first joining region 202. The second joining region 30 remains untreated.
The two paper materials 2, 3 are then fed to the ultrasonic friction welding apparatus 6, and the connection 11 between the first and second paper material is produced by ultrasonic friction welding. The roughening and moistening of the first joining region 20 can provide an excellent connection of paper materials. The second joining region 30 did not have to be processed in any way. As a result, this method according to the invention can be carried out particularly inexpensively.
For the production of a tubular bag, it should be noted that the variants described in
It should also be noted that, according to the invention, different variants of the invention can be carried out as long as at least one moistening step and one roughening step are carried out on one or both joining regions 20, 30 of the paper materials 2, 3.
Number | Date | Country | Kind |
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10 2019 202 850.0 | Mar 2019 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/054278 | 2/19/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/178024 | 9/10/2020 | WO | A |
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Number | Date | Country | |
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20220048271 A1 | Feb 2022 | US |