The present invention relates to a method for protecting the untrimmed edge of a paperboard or paper.
Good sealing is required of food packages; that is, they must prevent moisture, microbes and other sources of contamination from coming into contact with the product, as well as prevent the product from penetrating the package. A commonly used package material is paperboard whose barrier properties have been improved by adding various coating layers onto the surface of the paperboard. In food packages, plastic layers are generally used, whose material is, for example, polyethylene (PE) or polyethelene terephtalate (PET). When preparing blanks for paperboard packages, sheets are cut from a coated paperboard web, and the cut edges thus form a weak point in view of the package, the so-called untrimmed edge that is not protected with a coating layer. This untrimmed edge must be sealed to provide sufficient impermeability for the packages and to prevent the absorption of the material to be packed into the paperboard as well as to prevent sources of contamination from coming into contact with the material to be packed. Commonly used methods for sealing the untrimmed edge include taping, heat-sealing and skiving, that is, the milling of the edge to be thinner, and the double-bending of this feather edge to seal the untrimmed edge.
Document EP 0 152 616 discloses a method and an apparatus for protecting a raw edge in paper laminates. In this method, the edge of the paper laminate is treated with a laser beam, wherein part of the open paperboard layer between the laminate layers is removed with the laser beam. After this, the laminate layers remaining in the edge are pressed together, and the edge is sealed by heating. The method can be used either continuously or for single sheets.
U.S. Pat. Nos. 5,801,243 and 4,931,031 disclose methods for protecting the raw edge of coated paperboard, based on skiving, that is, the thinning of the edge, followed by bending of the feather edge. The edge of the paperboard is thinned by cutting off a thin slice, leaving the coating layer and a thin layer of the paperboard, and the feather edge is then folded so that the raw edge of the paperboard is protected. The method disclosed in U.S. Pat. No. 4,931,031 is suitable for continuous sealing of a raw edge.
International publication WO 99/25548 discloses yet another method for the manufacture of package blanks with protected raw edges. In the method, the coating of the paperboard and the protecting of the edges is started in a continuous web, after which the web is cut into sheets. All the edges of the paperboard sheets are protected so that the coating layer on the surface of the sheets extends over the edge to be protected, and this outreaching strip is folded over the edge and sealed onto the edge. Finally, package blanks are formed of the paperboard sheets by sealing the edges of the sheets together.
Publication GB 1 013 656 discloses the seaming of two adjacent edges abuttingly together by using a coating layer on the surface of the paperboard and heat-sealing it onto the surface of the adjacent paperboard.
In the above-mentioned methods, the raw edge of the paperboard or paper is protected by utilizing coating layers already provided on the surface of the paperboard or paper. The edge of the paperboard or paper is trimmed so that the raw edge can be closed by folding and sealing the coating layer over the raw edge to be protected. Such methods require several different work stages before the raw edge is protected.
The aim of the invention is to disclose a method for protecting the untrimmed edge of paperboard or paper, which method enables the continuous and quick sealing of the untrimmed edges and which can be simultaneously used for attaching two adjacent edges together. To achieve this aim, the method according to the invention is primarily characterized in that the protection of two adjacent untrimmed edges of paperboard or paper, and their attachment abuttingly together, are performed by sealing a separate profile onto both sides of the abutment of the edges by ultrasound.
In the method, the sealing of the untrimmed edge is performed in a continuous manner by introducing a separate profile to be sealed, in the form of a band with a suitable width or a profile with a finished shape, to the point to be sealed where it is sealed by ultrasound to the edge of the paperboard or paper. In this context, continuous ultrasound sealing means that the sealing takes place in a continuous manner over the whole length of the area to be sealed. The point at which the elongated band or profile is sealed onto the material will move on in the longitudinal direction of its edge or edges. Normally, this takes place in such a manner that the paperboard or paper moves forward in relation to the ultrasound sealing apparatus, and the band or profile is fed to the sealing point.
Paperboard or paper refers, in this context, to coated paperboard or paper. The profile to be sealed, used for sealing the edge, may consist of any material suitable for ultrasound sealing, particularly any thermoplastic material.
When it is entered to the ultrasound sealing, the paperboard or paper is in the form of a continuous web or a blank, and the profile to be sealed is entered in the form of a continuous band with a suitable width and shape. The ultrasound sealing is based on the melting of the material to be welded and the compression of the pieces to be attached together, to provide an impermeable and uniform seam. The method according to the invention is used particularly for protecting two adjacent edges and for attaching them together by means of one or two profiles, or for forming package blanks. The method according to the invention may also be used for the sealing of the untrimmed edge of a continuous web. The attaching of two adjacent edges is performed by means of a butt joint.
By the method according to the invention, the untrimmed edge of paperboard or paper can be protected from exposure to the inside as well as to the outside.
Ultrasound sealing is a quick method, wherein it is especially well suited for the continuous sealing of an untrimmed edge and for large series of package blanks, and it can be easily incorporated in an industrial packaging process. Ultrasound sealing is also flexible as a method, so that it is easy to change the thickness, width and material of the profile to be sealed, or the size of the package blank to be sealed. On the inside and outside of the package, it is possible to use profiles made of different materials, according to the desired properties of the package. Furthermore, protecting the seam with separate profiles on each side of the butt joint will also reinforce the package.
As to the purchase price, ultrasound apparatuses are considerably less expensive than laser apparatuses, and safer to use. Compared with skiving lines, in which the untrimmed edge is first milled thinner and then folded, the ultrasound apparatus is considerably smaller in size; and as a method, ultrasound sealing requires fewer working stages. Furthermore, ultrasound sealing is energy-efficient, because no extra heat needs to be applied to form the seam.
In the following, the invention will be described in more detail with reference to the appended drawings, in which
a, b show, in cross-sectional views, the formation of a profile strip at the edge of the paperboard or paper.
The method according to the invention can be used for sealing the untrimmed edge of a continuous web or for protecting two adjacent edges and attaching them together by means of one or two profiles. Furthermore, the method can be applied for forming package blanks, for example by sealing the edges of a folded web or a package blank together. A butt joint is used for attaching the edges together.
In the same way as in
In the above-presented
Two adjacent edges are attached together in a way shown in
The process steps shown in
The abutment joints shown in
As a working method, ultrasound welding is known as such, and it is widely used for joining plastic parts because of the firm joint formed by it and the simple hardware. In ultrasound sealing, the sealing of the profile to the edge of paper or paperboard equipped with a coating layer is based on the quick heating of the sealing surfaces caused by a vibrating sonic source that produces heat by internal friction in the seam to be welded. The sonic source vibrates at a frequency of 15 to 40 kHz. Thanks to this and the compression force applied to the sealing point, the material of the sealing surfaces melts, after which the pieces to be sealed are still pressed together for a short time during the cooling, to form an impermeable and strong seam. The total time used for the sealing is not more than in the order of a few seconds.
The compression force needed for the sealing can be provided by using an anvil that is embossed so that the welding energy can be transferred as well as possible to the seam to be formed. Alternatively, the sonotrode may also be embossed. However, the embossing must not disrupt the surface of the profile to be seamed. The embossing of the anvil or the sonotrode is provided by spark machining or by another corresponding method. A suitable average surface roughness (Ra) for the anvil or the sonotrode is, for example, 3 to 15 μm, but it varies to a great extent according to the materials to be sealed. The anvil used in the method is normally rotatable, because the anvil is used as a pulling roller and transfers the edge to be sealed forward and thereby enables the continuous sealing of the edge. For this reason, particularly the embossing of the anvil is important, to keep the edge to be sealed constantly in motion. By the rotating speed of the anvil, the sealing rate used can be adjusted to be suitable, depending on the materials to be sealed and their thickness. For example, the sealing rate may be in the order of 5 m/min. The sealing is performed continuously for the whole length of the edge to be sealed, and after the sealing, the profile band to be sealed is cut off at the edge of the package blank or web to be sealed.
In continuous ultrasound sealing, the anvil 7 used as a pulling counter element is normally rotating and the sonotrode 7 is stationary, but it is also possible that both the sonotrode 6 and the anvil 7 are rotating, or that the sonotrode 6 is rotating and the anvil is stationary during the sealing. Particularly when the sonotrode is rotating, its surface is embossed, because the sonotrode is thus used as a pulling element.
The paperboard or paper must consist of plastic coated paperboard or paper, so that the profile protecting the untrimmed edge can be fastened by ultrasound to the edge of the paperboard or paper. The profile used may consist of any material suitable for ultrasound sealing. In particular, many thermoplastic materials may be used, for example polyethylene (PE), polyethylene terephtalate (PET), polypropylene (PP), polybutene terephtalate (PBT), ethylene vinyl alcohol (EVOH), polyethylene vinyl acetate (EVA), or polyamide (PA). Profiles made of bioplastic may also be used. However, the use of the package to be manufactured sets the constraints on the material to be used for the sealing, to achieve sufficient protecting and attaching properties. Also, the thickness and width of the profile to be used vary according to the use and the sealing method. On the inside and outside of the package, it is possible to use profiles made of different materials, according to the properties set by the package. For example, in a profile to be used inside the package, it is possible to take food compatibility into account. The visual appearance of the package can also be improved, when some profile is seamed on both sides of the abutment.
The method makes it possible to manufacture packages which are impermeable to gas, liquid, grease and vapour, and which are typically used for packaging food. The invention can also be used for the packaging of other products, for example such products which must not lose their moisture or which contain substances that may evaporate from the product to the environment.
The invention is not intended to be limited to the embodiments presented as examples above, but the invention is intended to be applied widely within the scope of the inventive idea as defined in the appended claims.
Number | Date | Country | Kind |
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20065336 | May 2006 | FI | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FI2007/050273 | 5/14/2007 | WO | 00 | 3/3/2009 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2007/135234 | 11/29/2007 | WO | A |
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Number | Date | Country | |
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20090298662 A1 | Dec 2009 | US |