• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    packaging structure and method for the manufacture of said packaging structure. the invention relates to a packaging structure (1) being formed of multilayer cardboard material (6) comprising an intermediate layer (8), a first outer layer (7) connected to the intermediate layer (8) and a second layer outer (9) connected to the intermediate layer (8), said packaging structure (1) defining a bottom side (3), an upper side (2) and a plurality of side panels (4) joining said bottom side (3) and said upper side (2) so as to form a closed structure, at least one edge (14) is defined between the adjacent side panels (4). the invention is arranged so that the second outer layer (9) has a flexural stiffness, according to the iso 5628 standard, less than the first outer layer (7), in such a way that said card (6) is curved out only in a direction that the second layer (9) faces, and in which said packaging structure (1) is formed with at least one side panel (4) being curved and / or at least one edge (14) being rounded.
    公开号:BR112014023432B1
    申请号:R112014023432-9
    申请日:2012-03-22
    公开日:2021-04-06
    发明作者:Magnus VISTRÖM;Rickard HÄGGLUND;Folke Österberg
    申请人:Sca Forest Products Ab;
    IPC主号:
    专利说明:

    [0001] [001] The present invention relates to a packaging structure being formed of multilayer cardboard material comprising an intermediate layer, a first external layer connected to the intermediate layer and a second external layer connected to the intermediate layer, said packaging structure defining a bottom side, an upper side, and a plurality of side panels joining said bottom side and said top side to form a closed structure, at least one edge of which is defined between adjacent side panels.
    [0002] [002] The present invention also relates to a process for manufacturing a packaging structure. BACKGROUND OF THE INVENTION
    [0003] [003] Today there is a desire for packaging, boxes and wraps designed in a unique way and having projects that are arranged in such a way as to attract customers, for example, in the form of developing eye-catching packaging for sales outlets. Examples of such packages are cylindrical or elliptical shaped packages or packages with rounded sides or edges.
    [0004] [004] Currently, packaging structures can be manufactured from cardboard or from various types of fluted paper. The problem with these materials is that they do not allow the packages to be curved without encountering problems. For example, packages made of cardboard or double-sided corrugated cardboard are rarely seen with rounded edges because heavyweight cardboard and double-sided corrugated cardboard will deform if flexed in a very small radius. Cardboard cards can be folded to some extent, but they are deficient in stability compared to double-sided fluted cardboard. The cartonboard also does not offer the cushioning feature that corrugated cardboard provides.
    [0005] [005] Cardboard for packaging and single-sided cardboard are deficient in stability. Because of the lack of stability, the single-sided corrugated board is not suitable for conversion operations.
    [0006] [006] It is possible to fold corrugated cardboard on a small scale, but the resulting tension in the cardboard implies a risk of folding when it is treated in a way that flexes it a little more. Some of today's corrugated cards can be folded into curved shapes, with a radius of about 400 to 440 mm, when curved perpendicularly to the corrugated tubes.
    [0007] [007] The single-sided corrugated board can be folded into a small radius, but because of the lack of stability, the single-sided corrugated board is not suitable for conversion operations. Without having an internal coating, the performance of a box made of such a material will be low (for example, stacking resistance and transport performance). In addition, the single-sided corrugated cardboard has only one flat side suitable for printing. The corrugated layer of the single-sided corrugated board is not very representative, either on the outside or on the inside of a package.
    [0008] [008] Packages that must withstand loads induced in transportation, transhipment and handling need certain performance requirements. For storage and transportation, it is important to have sufficient stacking strength and sufficient strength and stability with respect to the transport of related loads. The ability of a package to withstand transport loads is referred to herein as stability in transit. In addition, to protect the contents of the package from mechanical checks, it is often important that the package provides a cushioning feature. The stacking resistance can be measured by a BCT test (Box Compression Test -ISO12048) and provides a measure of the amount of load the package can have on itself before the side panels start to deform. The level of stability of packages in transit can be tested in a laboratory environment and it is also possible to test, for example, loading a truck with packages and then driving for a while with accelerating and decelerating moments.
    [0009] [009] It is known from the state of the art that it is possible, for example, using additional material, to reinforce the edges of a package in order to increase the level of BCT. The edges are specifically reinforced, since they support most of the load when the packages are stacked on top of each other. However, this type of reinforcement leads to an increase in the use of material, which implies a higher cost and heavier packaging, which, in the end, can have an effect on profitability and the environment. In addition, prior art solutions do not provide any good solution for providing curved shapes to satisfy the desire to introduce new curved packaging (for example, rounded side panels or curved edges between side panels) in order to attract customers. consumers, for example, at the point of purchase.
    [0010] [010] For example, there are a number of known types of packaging, for example, the so-called Bliss containers, which are provided with reinforced edges in order to withstand high compression loads, ie, the containers will have a higher stacking resistance elevated.
    [0011] [011] There are paper packages in the shape of a cylindrical tube, but these packages cannot be delivered in flat disassembled form, which means that the transportation of these packages is inefficient. With regard to recycling, cylindrical tubes can also be difficult to handle for the consumer after the content has been consumed, since they cannot be folded without damaging the material.
    [0012] [012] There is, therefore, a need for an improved and visually attractive packaging structure that can form a cylindrical packaging, through a package of curved side panels or with rounded edges between the adjacent side panels that can be transported as one. flat card. There is also a need for a packaging structure that minimizes the use of material, but still provides a high level of BCT and stability during transport. DESCRIPTION OF THE INVENTION
    [0013] [013] The object of the present invention is to provide a packaging structure with curved side panels or rounded edges between adjacent side panels, which has a light weight in relation to the BCT level and stability during transport and an attractive way to attract consumers' attention (for example, at the point of purchase).
    [0014] [014] An additional object of the present invention is to provide a packaging structure with curved side panels or rounded edges between adjacent side walls and which can be carried as a flat cardboard.
    [0015] [015] This objective is achieved by a packaging structure, as initially mentioned, in which the second outer layer has a flexural stiffness in accordance with ISO 5628 below that of the first outer layer so that said card and curved out only in one direction the second layer is facing, and in which said packaging structure is formed with at least one side panel being curved and / or at least one edge being rounded.
    [0016] [016] The term "smoothly foldable", or simply "foldable", refers, in this context, to a physical shape of the cardboard material that has a continuous curved shape, generally uniform and regular, generally without any irregularities, folds or curvature interruptions.
    [0017] [017] Curved side panels of a package have an advantage over straight panels with respect to BCT and stability in transit. This is due to fundamental structural principles that imply that the curved panels are relatively more resistant to buckling compared to the flat panels and because the curved panels provide a greater relative resistance in relation to the structures with flat panels. In this regard, the publication entitled "The buckling behavior in axial compression of slightly-curved panels, including the effect of shear deformability", is endorsed, Int. J. Solids Struct. 4 (1968), pp .; G.G. Pope.
    [0018] [018] A panel in curved shape and beneficial in the load from top to bottom, but also in horizontal shear, which is related to stability during transport. A package that has, for example, a cylindrical shape or an oval shape consequently provides a high BCT value and a good performance in transport tests.
    [0019] [019] In addition, curved panels or rounded edges prevent the packaging structure from twisting, which improves handling aspects.
    [0020] [020] Through the invention, an improved packaging structure is provided by means of which packaging that has aesthetically appealing designs can be provided, that is, having, for example, circular or oval packaging, or practically any shape involving rounded edges and / or on the curved side panels. In addition, the invention provides an improvement in the ratio with respect to strength in relation to the weight of the package. For example, by introducing curved edges between adjacent side panels, it is possible to maintain an outer layer of heavy weight to provide a high quality printing surface and minimize the weight of the inner layer, while maintaining stacking strength.
    [0021] [021] One possible way of introducing curved side panels would be to introduce concave side panels giving the packaging the shape of the diamond symbol on a deck of cards. In the case of such a design, it is important to note that the upper and inner parts must be provided as separate handles which must be glued in order to form the complete package.
    [0022] [022] The circular shape may not be the most ideal packaging with regard to the degree of external filling. Degree of external filling relates to the degree that, for example, trucks or containers are full of products, packaging or finished products. A similar limitation exists with regard to the degree of internal filling. The degree of internal filling refers to how much of the interior space of a package can be filled with a product content. The degree of internal filling depends on the shape of the product that should fit the packaging. For packaging with a circular cross section, there will not be a degree of internal filling that is not optimal for products that have a square cross section.
    [0023] [023] Since the corners are supporting most of the load, a compromise to obtain a good degree of filling would be the introduction of curved edges. Compared to co-packaged circular packaging, co-packaged square packaging with rounded edges results in less unused space.
    [0024] [024] A feature of the present invention is that empty packages can be transported as flat sheets, which means that the degree of external filling would be high, thus resulting in efficient costs of transporting unfulfilled packages (ie. transport of empty packaging, from a packaging production plant, to a producer of the product, who is filling the packaging with its contents). Even if the joints of the manufactured packaging are sealed, it is possible to transport them empty, pre-assembled in a flat shape.
    [0025] [025] The structure of the packaging according to the invention can, moreover, be folded in an appropriate manner, so that it allows efficient transport when a certain number of pre-assembled packages must be shipped. Due to the fact that the packaging material can be folded, the marking of such folds will be very limited (or even invisible) since the packaging is unfolded, that is, raised, in order to assume its intended shape. This is particularly the case when the lid is made on one side of the flat panel of the packaging structure (see Figure 6, below), as opposed, for example, to a circular or oval side panel.
    [0026] [026] The marking of the fold (to make it flat) will not affect, or only slightly, the BCT value once the marking lines are in the same vertical direction as the force that comes from loading packages on each other .
    [0027] [027] New packaging standards where circular packaging containing products are co-packed with diamond-shaped packaging can be used to optimize the degree of external filling in transport.
    [0028] [028] In order to provide curved panels or rounded edges between adjacent side panels there is a need for a foldable material, for example, a smoothly foldable card. This material will be described in detail below. When referring to bending stiffness, measurements of bending stiffness are made in accordance with ISO 5628.
    [0029] [029] The term "easily foldable" is defined as the ability of a material to flex according to a continuous and smooth radius, in this case the ability of the first outer layer to bend according to a continuous and smooth radius. first outer layer, the first outer layer should not have any irregularities, such as, for example, folds. Instead, the final rounded or curved shape of the first outer layer of the package should have a continuous appearance and even without any folds or non-curved sections along the curvature.
    [0030] [030] Some of today's corrugated board can be curved into curved shapes, with a radius of about 400 to 440 mm, when curved perpendicularly to the corrugated tubes. Using this material, in addition to not reaching a radius less than about 400 mm, there are several other problems associated with the curvature of today's corrugated cardboard perpendicular to the corrugated tubes. Since a large amount of force is needed to bend the material, it is easy for folds to occur when approaching a 400 mm radius. To create a circular shape with this radius, a sheet of corrugated cardboard with a length of 2,760 mm is required excluding any necessary overlap. This sheet size is not available today.
    [0031] [031] Due to the stiffness of the corrugated board, it is also difficult to join the ends of the material in a way that will result in an acceptable circular shape. Another problem with regard to the folding of the material perpendicular to the corrugated tubes is that the material will have a low flexural stiffness in the vertical direction. Thus, the maximum load that a particular packaging structure can carry will be quite limited. If the corrugated cardboard was instead folded along the corrugated tubes, the radius should be about 3 to 4 times greater to avoid folds.
    [0032] [032] The invention preferably makes use of a smoothly folding carton where the intermediate layer is preferably, but not necessarily, corrugated, that is, that comprises flutes. However, the description for the outer layers is valid for cases where the intermediate layer comprises a different material than flutes, such as, for example, a thermoformed core.
    [0033] [033] A condition to obtain a smooth and continuous radius and that the second outer layer must flamble between each peak of the intermediate fluted layer, when the material is subjected to flexion in the foldable direction. When each section of the second outer layer has buckling, the curvature can be distributed between each section of the material. The above description can theoretically be described by Euler's fourth buckling case:
    [0034] [034] When the aforementioned smoothly folding carton and exposed to flexion, the material of the second outer layer will initiate the curvature between the tops of the fluted intermediate layer, if the flexure stiffness of the second outer layer is sufficiently low.
    [0035] [035] If the flexural stiffness of the second outer layer is too high, the second outer layer will preferably break, that is, have a torsion, when the applied force Pk reached the compression force of the material according to the compression test - short extension according to ISO 9895, hereinafter referred to as SCT. In the case of a very high flexural stiffness of the second outer layer, the second outer layer will not be subject to buckling and, consequently, the material will not necessarily bend according to a smooth and continuous radius.
    [0036] [036] If the flexural stiffness of the first outer layer is high enough, despite the fact that the second outer layer is not subject to deformation, it may still be possible to bend the material in the form of a more or less exact curve. However, the result will not be as good as if the second outer layer has been subjected to buckling.
    [0037] [037] In order to obtain sections of the second outer layer to present buckling, the compressive strength (SCT) of the second outer layer must be greater than the buckling Pk (measured in N / m), that is, Pk <SCT. Using this inequality and rearranging equation 1 we get:
    [0038] [038] In order to have a material that curves in a smooth and continuous radius, a second condition is necessary. The flexural stiffness of the second outer layer must be less than the flexural stiffness of the first outer layer. When the smoothly folding carton is subject to flexing, the second outer layer should deform or curve inward between the peaks of the corrugated intermediate layer. The place where a bending moment is applied will determine where the second outer layer will first begin to bend or curve. If the flexural stiffness of the second outer layer is too high in relation to the first outer layer, the material will not curve in a radius that remains smooth. A high curvature stiffness of the second outer layer requires a high bending moment in order to fold / bend the second outer layer and, consequently, the smoothly foldable card. When the second outer layer begins to curve / bend between two flutes in the intermediate layer, that is, having a high moment applied, the first outer layer will be easily twisted if its flexural stiffness is not high enough, due to a sudden drop flexural stiffness of the second outer layer, when the second outer layer curves. Once the first outer layer is twisted, the material will not bend in a smooth radius and continue. If the second outer layer was folded, that is, curved, between two of the peaks of the corrugated intermediate layer, the difference in relation to the necessary moment between the flexion / folding of the next section of the second outer layer and the reflection / folding of the already curved section of the second outer layer, it should be as small as possible.
    [0039] [039] Thus, the drop in the flexural stiffness of the second outer layer between two peaks after flexing / folding should be as low as possible. In other words, the flexural stiffness should be as low as possible. However, if the first outer layer has a higher flexural stiffness, it would be possible to allow a higher flexural stiffness of the second outer layer.
    [0040] [040] If all sections of the second outer layer have buckling and the flexural stiffness of the first outer layer is sufficiently high compared to the second outer layer, (as mentioned above), the smoothly folding card will fold in a smooth radius and continues. However, the different sections of the second outer layer will eventually pleat as the radius of curvature decreases. These pleats will not affect the function of the material. However, if the second outer layer is somehow exposed to the consumer, it can be advantageous from a design point of view, if there are no folds. To avoid these folds, the following condition is necessary: σMAx <SCT, (Equation 3), Where
    [0041] [041] As both sides of the smoothly folding carton, as used in a structure according to the invention have smooth surfaces, while the single-sided corrugated carton has flutes facing one side, the smoothly folding carton is less likely getting stuck in conversion equipment.
    [0042] [042] Compared to single-sided corrugated cardboard, a smoothly foldable cardboard, as described here and compatible with conventional converting machines, such as those for printing and cutting.
    [0043] [043] Other possible applications would be to use the recessed spring feature, since the material returns to its original position after bending, to build intelligent opening devices, such as automatic opening packages.
    [0044] [044] In addition, it is possible to obtain unique curved structures and designs using the smoothly folding carton compared to ordinary corrugated cardboard or packaging carton without having deformation of the material. This can be interesting in a packaging context, since the possibility of making a curved shape with a small radius can be attractive to consumers.
    [0045] [045] The smoothly folding carton may have an intermediate layer, which is a corrugated carton layer that comprises flutes. The easily foldable card can be curved outward only in a direction that the second layer is facing, in which the direction is essentially perpendicular to the flutes of the intermediate layer.
    [0046] [046] The smoothly folding card may have a flexural stiffness of the second outer layer chosen in such a way that each section of the second outer layer presents deformation according to the equation:
    [0047] [047] The first and / or second outer layer can be made of a material that has a suitable surface for printing.
    [0048] [048] As mentioned earlier an application of the card gently folding and using it in a packaging structure. Having surfaces adapted for this purpose, it simplifies production and handling.
    [0049] [049] The first outer layer may be formed from one of a covering plate, paper or plastic or a laminate of any two or more from a covering plate, paper or plastic or a composite material. This applies, as long as certain requirements relating to the various layers are met, as described above and as will be further described below.
    [0050] [050] These materials have the desired characteristics of flexural stiffness for the first outer layer and are easily adaptable to suit the different requirements needed, in order to vary the smoothly folding card for different uses. For example, any type of printing surface that can be attached to the flutes directly or laminated on another surface connected to the flutes or another form of intermediate and conceivable layer, Depending on the characteristics (for example, weight) of the cardboard and the desired radius of curvature (examples of minimum radius of cardboard can be seen in Table 1, below), grades of packaging cards can be used as the first outer layer.
    [0051] [051] The second outer layer may be formed by a covering plate, paper or plastic or a laminate of any two or more of a coating, paper or plastic or a composite material, provided that certain requirements relating to the various layers are met. answered.
    [0052] [052] The first outer layer and / or the second outer layer may be formed of thin paper, supercalendered paper, satin paper, greaseproof paper, newsprint or machine finished paper, coating, sheet metal , metallized film or a composite material or a laminate of any two or more of thin paper, supercalendered paper, satin paper, greaseproof paper, newsprint or machine finished paper, coating, metal foil, metallized film or a composite material, such as cellulose fiber reinforced polymers (for example, including nano-cellulose).
    [0053] [053] These materials have the desired characteristics of flexural rigidity for the second outer layer and are easily adaptable to suit the different requirements required, in order to vary the smoothly folding card for different uses.
    [0054] [054] The corrugated intermediate layer may comprise any of the flute sizes A, B, C, D, E, F, G or K or consist of another suitable core material such as a thermoformed structured core, containing cavities. It could, for example, be a core material with cup-shaped prints (point support). The thermoformed core can form a continuous intermediate layer or it can form an intermediate layer, where the core material is present thermoformed intermittently between the first and second layers. The thermoformed core can, for example, be made of plastic or a cellulose-based material. If a thermoformed core is used, the thermoformed core must be foldable in order to be able to follow the curvature of the first and second outer layers. The corrugated intermediate layer can comprise any other flute size (in addition to those listed above) larger than E flute.
    [0055] [055] The invention also relates to a method for producing a packaging structure of the type mentioned above. Consequently, a softly foldable carton material can be provided, which comprises an intermediate layer, a first outer layer, and a second outer layer. In addition, the method can comprise the steps of: connecting the first outer layer to the intermediate layer, producing a single-sided card; and fix the second outer layer to the intermediate layer, where the second outer layer has a flexural stiffness, according to ISO 5628, lower than that of the first outer layer in such a way that the card is smoothly foldable and curved out only in a direction that the second layer faces.
    [0056] [056] Alternatively, the process may comprise connecting the second outer layer to the intermediate layer, producing a single-sided card; and then fix the first outer layer to the middle layer.
    [0057] [057] According to another alternative manufacturing process, the first and second outer layers can be added to the intermediate layer simultaneously.
    [0058] [058] The method preferably further comprises providing single-sided card such that it is flat before attaching the second outer layer to the intermediate layer. This ensures that the smoothly folding card does not bend in an unwanted direction.
    [0059] [059] When using a single-sided corrugated cardboard initially curved in the direction of the corrugated intermediate layer, and making sure that it is flat before fixing the second outer layer, it is more difficult for the smoothly folding cardboard to bend spontaneously in the direction in which the second layer is facing. By using this production method, it is possible to add flexural strength to the material (in the direction of the second outer layer).
    [0060] - fixar a primeira camada externa a camada intermediaria, produzindo um cartão de face única; - dispor o papelão ondulado face única de tal modo que seja curvado em uma direção para a qual a segunda camada está voltada; -fixar a segunda camada externa a camada intermediaria canelada curva. [060] The method may also include: - fix the first outer layer to the intermediate layer, producing a single-sided card; - arrange the single-sided corrugated board in such a way that it is curved in a direction towards which the second layer is facing; -fix the second outer layer to the curved corrugated intermediate layer.
    [0061] [061] The result will be an initially curved material that is prevented from returning to a flat phase, but still more foldable in relation to the direction in which the second layer is facing and perpendicular to the flutes of the corrugated intermediate layer.
    [0062] [062] The method can be used when the intermediate layer of the smoothly folding cardboard and a layer of corrugated cardboard, comprising flutes or other suitable core material such as a thermoformed core. For the method as described above, the second outer layer can be bonded to the intermediate layer before the first outer layer is bonded to the intermediate layer. The first outer layer and the second outer layer can also be connected to the intermediate layer simultaneously. This means that the described material can be used to produce the packaging structure according to the invention, said packaging structure having the advantages indicated above. BRIEF DESCRIPTION OF THE DRAWINGS
    [0063] [063] The invention will now be described with reference to certain embodiments and with reference to the drawings.
    [0064] [064] Figure 1a shows a packaging structure to be designed in accordance with the principles of the present invention.
    [0065] [065] Figure 1b shows a preformed material designed to form the original material to form said packaging structure.
    [0066] [066] Figure 2a shows, schematically, a foldable material card, which can easily be used for the invention, said card being in a flat state.
    [0067] [067] Figure 2b shows schematically the card shown in Figure 2a and being curved outward.
    [0068] [068] Figure 3 shows schematically the concept of flexing or bending the cardboard material according to Figures 2a and 2b.
    [0069] [069] Figure 4a shows a packaging structure, in the form of a second embodiment of the invention.
    [0070] [070] Figure 4b shows a preformed material to be designed to form the original material to form said packaging structure according to the second embodiment.
    [0071] [071] Figure 5a shows a packaging structure, in the form of a third embodiment of the invention.
    [0072] [072] Figure 5b shows a preformed material to be designed to form the original material to form said packaging structure according to the third embodiment.
    [0073] [073] Figure 6 shows a preformed handle that corresponds to the embodiment shown in Figures 1a and 1b, but in a flattened condition, that is, in collapse, in which it is suitable to be transported.
    [0074] [074] Figure 7 shows a card that can be used for the so-called dynamic impact test, as will be described below. DESCRIPTION OF ACCOMPLISHMENTS OF THE INVENTION
    [0075] [075] In the following, the present invention will be described with reference to an embodiment of the invention, which is also shown in the accompanying drawings.
    [0076] [076] Figure 1a schematically shows a packaging structure (1) designed in accordance with the principles of the present invention. Consequently, the packaging structure (1) defines an upper side (2), a bottom side [3] (not visible in Figure 1a) and a side panel element (4) forming a plurality of side panels, of which two side panels (4a), (4b) are visible in Figure 1a. The side panels (4a), (4b) extend from the bottom side (3) to the upper side (2) In this way, the packaging structure (1) can form a closed structure that involves an interior space. Figure 1 a shows the packaging structure (1) in its upright position in which it was (or is intended to be) filled with content of some kind.
    [0077] [077] Figure 1b shows schematically an original preform (5) to be used to form the packaging structure (1). The preformed handle (5) is suitably formed to include two flaps (2a), (2b), which can be folded to form the aforementioned upper side (2), when the frame (1) and , in its assembled state. In addition, the preformed handle (5) comprises more tabs (3a), (3b), which can be folded to form the aforementioned bottom side (3), when the structure (1) is in its state mounted.
    [0078] [078] Consequently, in Figure 1b, the reference number (5) refers to the preformed handle that constitutes the preformed material for the manufacture of the packaging structure (1) according to the embodiment. The preformed handle (5) is made of a cardboard material (6), which is preferably a multilayer cardboard material, which will now be described as an example, with reference to Figures 2a and 2b.
    [0079] [079] Figure 2a schematically describes the material of the card (6), which in particular is in the form of a smoothly folding card (6). More precisely, the smoothly folding carton (6) comprises a first outer layer (7), an intermediate layer (8) and a second outer layer (9) made of a material with less flexural stiffness than the first outer layer ( 7),
    [0080] [080] Although the smoothly folding carton in Figure 2 shows a corrugated intermediate layer (8), the invention is not limited to a packaging structure made from a cardboard material that has an intermediate layer (8) in the form of a layer of corrugated cardboard. The following description also applies to a smoothly foldable card having an intermediate layer made of, for example, a thermoformed core. When the term "corrugated intermediate layer" is used, it is conceivable to have a thermoformed core instead. The first outer layer (7) and the second outer layer (9) of the smoothly folding carton (6) according to the invention can be a single layer or a laminate of two or more layers having the aforementioned characteristics. The outer layers can also be coated or laminated together with another layer, such as a film to achieve barrier properties, such as a barrier against moisture, water vapor, fat, aroma, oxygen, or migration of volatile substances, such as as components of mineral oil and free radicals of UV inks or other volatile substances.
    [0081] [081] The intermediate fluted layer (8) comprises flutes and may comprise a single flute layer or two or more flute layers, where each layer may be the same or different flute sizes.
    [0082] [082] The first outer layer (7) and the second outer layer (9) may have a surface suitable for printing, as is known in the art.
    [0083] [083] Figure 2b schematically shows the smoothly folding card (6) in a shape in which it is to be folded out (that is, defining a convex shape) in a direction facing the second outer layer (9 ) and perpendicular to the flutes of the corrugated intermediate layer (8). The low flexural stiffness of the second outer layer (9) in combination with the high flexural stiffness of the first outer layer (7) makes this possible. The same characteristics make it difficult for the smoothly folding card (6) to fold in the opposite direction, without deforming one or more of the layers <7), (8) or (9).
    [0084] [084] The board (6) shown in Figure 2b can be manufactured by applying a second outer layer (9) to the single-sided corrugated board. The second outer layer (9) is suitably applied to the single-sided corrugated board by means of starch glue, molten adhesive or any other type of fixing medium suitable for fixing a layer to a fluted layer. The fixing means may center other functional components, for example, in order to obtain barrier properties according to what has been mentioned previously.
    [0085] [085] Alternatively, the card shown in Figure 2 can be manufactured by applying the first outer layer (7) to a single-sided card, which was formed by joining the second outer layer (9) to the intermediate layer (8). According to another alternative, the first and second outer layers can be applied simultaneously to the intermediate layer (8) in order to produce said card.
    [0086] [086] The second outer layer (9) is usually applied while the single-sided corrugated cardboard is placed on a flat surface. In order to ensure that the smoothly folding carton (6) remains flat, it may be appropriate to use a single-sided corrugated carton initially curved towards the fluted intermediate layer (8), and lay it flat before attaching the second outer layer ( 9). Then, it will be more difficult for the smoothly folding card (6) to bend spontaneously in the direction in which the second layer is facing. By using this production method, it is possible to add flexural strength (in the direction of the second outer layer) for the material.
    [0087] [087] With regard to suitable materials, it can be noted that the material for the first outer layer (7) should have sufficient flexural stiffness in comparison with the second outer layer (9). Preferably, paper or fine card can be used as a material for the first outer layer (7). It is also possible to use plastic material or a laminate of different layers of material, or a composite material. Generally, the materials used for the first outer layer (7) and the second outer layer (9) must be able to be shaped into a curved shape or folded, without being damaged.
    [0088] [088] The adhesive used to laminate the three components together can consist of starch glue, hot melt glue, PVA (polyvinyl acetate) glue or any other adhesive suitable for lamination. For the present innovation, it is also possible to use a modified starch glue. By adding various polymeric materials to the starch glue, it is possible to give the glue a better resistance against moisture, which can be an advantage if the packaging structure will be used in humid environments or in environments where the level of humidity and high.
    [0089] [089] It should be possible to bend the smoothly folding card (6) in a radius that corresponds to less than the minimum radius in which the standard corrugated card can be bent. After bending the smoothly folding card (6) there will be no wrinkles, that is, folds in the first outer layer (7) of the card. The first outer layer (7) of the smoothly folding card (6) becomes convex after flexing. In Figure 2b, the curving of the second outer layer (9) is not present for the sake of illustration.
    [0090] [090] The intermediate layer (8) comprises flutes and the card (6) is curved outwards only in one direction towards which the second outer layer (9) faces, in which the direction is essentially perpendicular to the flutes of the intermediate layer (8), that is, essentially perpendicular to an imaginary direction along which the flutes extend.
    [0091] [091] The concept of buckling or flexing, of the softly folding cardboard material (6), d shown in Figure 3, which shows a close-up of the cardboard (6) in Figure 2b. In Figure 3, the first outer layer has a continuous and smooth radius without creasing. The corrugated intermediate layer (8) comprises a number of peaks (10) facing the second outer layer (9) and a series of valleys (11) facing the first outer layer. Between the peaks (10), the second outer layer comprises sections (12). A condition for obtaining a smooth and continuous radius is that the second outer layer 9 must flamble between each peak (10) of the corrugated intermediate layer (8) when the material is flexed in the foldable direction. When each section (12) of the second outer layer (9) has buckling, the curvature can be distributed between each section of the material. In Figure 3, the size of the deformation of the second outer layer (9) is shown for illustrative purposes and may vary depending, for example, on the degree of curvature and the choice of materials.
    [0092] [092] When the card is gently folding (6) and exposed to flexing, the material of the second outer layer (9) will begin to curve between the peaks (10) of the corrugated intermediate layer (8), if the flexural stiffness of the second layer external (9) and low enough. It is an important feature of the card (6) that the deformation of the second outer layer (9) is carried out in a controlled manner.
    [0093] [093] Suitably, the packaging structure (1) according to the invention is arranged so that a rounded edge between two adjacent side panels (for example, the side panels (4a), (4b) in Figure 1a) has a radius 6 about 5 mm or more. In particular, it has been found that particularly advantageous results can be provided with respect to BCT and stability in transport properties, if the radius is approximately in the range of 10 to 150 mm. The optimum radius depends, for example, on the length of the side panels. It should be noted, however, that the invention is not limited to any special radius, but other radius values are possible within the scope of the invention.
    [0094] [094] In order to test the minimum radius that the smoothly folding card can be folded without receiving material damage, a special test equipment has been developed. The test device comprises six tubes with a smooth surface, having diameters 102 mm, 75 mm, 34 mm, 33 mm, 20 mm and 12 mm. The tubes are preferably made of metal and are mounted on a base, such as a beam or table for stability.
    [0095] [095] The width of the test handles on all cards is 105 mm, that is, the size of an A4 sheet cut in two halves. The length of the test handles is 297 mm, that is, the length of an A4 sheet. All test handles are conditioned according to ISO 187 (preconditioned at 30% RH, 23 degrees C, and then conditioned at 50% RH, 23 degrees C).
    [0096] [096] A selected test handle is first folded around the larger tube and subsequently visually inspected for damage to the material. The test handle is folded 180 °, that is, in such a way that both ends of the handle test points point in the same direction. If no damage is visually detectable, the test handle is folded around the second largest tube and evaluated in the same way. This procedure is repeated, using a tube with a smaller diameter until the material is damaged by the bending operation or until the material successfully passes around the tube with the least curvature of 12 mm. In addition to testing the different types of smoothly folding corrugated board, a selection of cardboard grades is chosen. In addition to the PE-laminated corrugated board, and tested grade 483E (flute E used for outdoor displays, 610 g / m, where the flutes are laminated in coating + PE layer + MG paper).
    [0097] [097] Table 1 illustrates the result of the flexion test. OK! means that no damage is seen visually. Failure! means that damage, such as folds, is visually observed in any of the outer layers. A * before the grade indicates that the card was made as described above, that is, with a single face material to which an additional layer is attached, as described with reference to Figures 2a and 2b.
    [0098] [098] As can be seen from Table 1, all smoothly folding cartons that must be used for the structure of a carton according to the invention are capable of folding according to a radius that is smaller than conventional cartons. without displaying visual damage on any of the outer layers. As can be seen in Table 1, grade 483E already fails in the 102 diameter tube.
    [0099] [099] Again with reference to Figures 1a and 1b, it is observed that the structure of the packaging (1) according to the invention and formed from a preformed handle (5) being manufactured from cardboard material smoothly foldable (6), as described above with reference to Figures 2a, 2b and 3.
    [0100] [0100] In particular, the side panel element (4) is formed to define four different side panels (4a), (4b), (4c), (4d) (of which only two side panels (4a), (4b) are visible in Figure 1a), curving the side panel element (4) and attaching its ends to each other, for example, by means of gluing. In addition, the two main side flaps (2a), (2b) are folded to form the upper side (2), and the interfering side flaps (3a), (3b) are folded to form the bottom side (3). Before the folding of the lower side flaps (3a), (3b) and the upper side flaps (2a), (2b), an additional number of flaps of the side panels (13a), (13b), (13c), (13d) are folded inwards into the packaging structure (1) in order to define the support area in which the lower side flaps (3a), (3b) and the upper side flaps (2a), (2b) can be fixed. In this way, the complete packaging structure (1) can be formed in a stable and strong manner.
    [0101] [0101] With reference to Figures 2a and 2b, it is important to note that the embodiment of the invention shown in Figure 1a is based on the principle that the second outer layer material (9) (see Figure 2b) faces the interior of the structure of finished packaging (1). This allows the structure (1) to be designed in a way with its rounded ends (14), as shown in Figure 1 a. In particular, an edge (14) forms a transition between a side panel and an adjacent side panel, for example, between the side panel (4a) and the side panel (4b). In this respect, the term "rounded edges" refers to edges that do not have any folds or similar interruptions in the curvature. The washboard-like marks on the first outer layer (ie, marks that indicate the peaks of the flutes in the intermediate layer ), in this context, are not considered as interruptions.
    [0102] [0102] The structure of the packaging according to the invention can also be formed in a configuration in which the rounded edges between the adjacent side panels or curved side panels are intentionally provided with irregularities, for example, to provide a visual effect.
    [0103] [0103] It should also be noted that the smoothly folding carton can be processed in various production equipment (for example, cutting, printing, gluing, wrinkling and folding), in order to produce a packaging structure, as described .
    [0104] [0104] A second embodiment of the packaging structure according to the invention will now be described with reference to Figures 4a and 4b. The packaging structure (1 ') according to this second embodiment has a design that has four side panels, of which only two side panels (4a'), (4b ') are visible in Figure 4a. These side panels are designed with a curved shape, which can be said to be concave, that is, their average section closer to the center of the packaging structure (1 ') than their end sections. In addition, the package structure (1 ') has an upper side (2') and a bottom side (3 ') (not visible in Figure 4a).
    [0105] [0105] The packaging structure (1 ') according to the second embodiment and formed by the same material as the cardboard (6), as described above and as shown in Figures 2a, 2b and 3. However, it should be noted it is here that, according to this second embodiment, that the cardboard material (6) is arranged so that the second outer layer (9) (see Figure 2b) is placed so that it faces outwardly from the packaging structure (1 '), that is, facing the opposite direction in comparison to the embodiment shown in Figures 1a, 1b.
    [0106] [0106] Figure 4b shows a preform (5 ') for the packaging structure (!') According to Figure 4a. More precisely, the preform (5f) and consists of a side panel element (4 ') that is intended to be folded to form four side panels (4a'), (4b '), (4c1), ( 4d '), and a separate upper side and (2') bottom side (3 ') side that are intended to be fixed, appropriately by means of glue, to the side panel element (4').
    [0107] [0107] Another embodiment of the invention is shown in Figures 5a and 5b. This embodiment corresponds to a packaging structure (1 ’’) that has a generally circular cross-sectional shape in its raised, finished state. This means that it comprises a single side panel element (4 '') which defines a curved side panel surface. The packaging structure (1 ’’) also has an upper side (2 ’’) and a lower side (3 ’’) (not visible in Figure 5a).
    [0108] [0108] Figure 5b shows a preform (5 '') that is used to form the package structure (17 ') shown in Figure 5a. The preform (5 '') comprises a side panel element (4 ''), two upper side flaps [2a ''), (2b ''), two lower side flaps (3a ''), (3b ' ') and corresponding side panel flaps (13a'), (13b '), (13c'), (13d '). The packaging structure (l77) shown in Figures 5a and 5b and made from cardboard material, as described above with reference to Figures 2a, 2b and 3.
    [0109] [0109] A particular feature of the packaging structure according to the invention and that it can be transported - after the manufacture of the preformed original, but before it is erected to be filled with suitable content - in a folded state, ie , collapsed. Such a condition of the original preform (5) is shown in Figure 6, which is a perspective view of a preform (5) as shown in Figures 1a and 1b. As seen from Figure 6, the side panel (4) has been folded so that its end sections have been bonded together, suitably by means of glue. Thereafter, the side panel flaps (13a), (13b), (13c), (13d) (and corresponding side panel sections (4)) were all folded so that the entire preform (5) it is in a flattened state, collapsing. In this condition, a large number of preforms (5) can be transported in an efficient manner. When the preforms have been transported to a type of production unit in which they must be filled with suitable content, they are lifted, filled with the content and, finally, sealed to form a finished package.
    [0110] [0110] In particular, it should be noted that the folds that form on the flaps of the side panels (13a), (13b), (13c), (13d) and the side panel (4) will be practically invisible in the structure (1 ) of finished packaging (see Figure 1a).
    [0111] [0111] In addition, as an example of how the BCT value is affected by the introduction of curved panels and rounded edges or between adjacent panels, BCT measurements of three different geometries are shown in Table 2. All tested geometries were conditioned accordingly with the ISO 187 standard (preconditioned to RH 30%, 23 degrees C, and subsequently conditioned to RH 50%, 23 degrees C). In the test, the same amount of material and identical material (smoothly folding cardboard) was used for each geometry. Thus the perimeter of each geometry is kept constant (perimeter = 880 mm). First, the shorter ends of a 900 mm x 200 mm handle of the smoothly folding cardboard (corrugated tubes pointing parallel to the shorter sides) were joined by applying hot melt glue between 20 mm overlap of material. Subsequently, the handle was positioned on a frame of corrugated cardboard at a depth of 6.5 mm placed horizontally, in order to mold the material into a structure with a desired shape. The different shapes of the pictures were circular, square and square with rounded edges between the adjacent sides. The radius of the rounded edges is 30 mm. In this test, the material was arranged in such a way that said second outer layer (9) was turned inside said structure.
    [0112] [0112] The result of this example shows (see Table 2 below) that the BCT value has increased by about 35% through the introduction of rounded edges between adjacent edges and that the BCT value has increased by about 80% by preparing a shape circular, compared to square-shaped geometry.
    [0113] [0113] The material components in the smoothly folding cardboard were lwc 65 g / m2 as the second outer layer, white top coat 228 g / m2 as the first outer layer and semi-chemical fluted material 112 g / m2 as the intermediate layer (flute b). The thickness of the smoothly folding cardboard is 3 mm and the distance between the corrugated tubes was 6.4 mm. The material was produced in a laminating machine, where the first outer layer was first applied over a corrugated intermediate layer using a standard single-sided corrugated material formation process. In this process, the first outer layer and the intermediate layer were fed as blankets. After that, the second outer layer was laminated on the other side of the intermediate layer sheet by sheet.
    [0114] [0114] To give another example of how the BCT value is affected by the introduction of curved panels, BCT measurements of a diamond-shaped geometry and a symmetrical square-shaped geometry are shown in Table 3 below. The same amount of material and identical material (smoothly folding cardboard) as for the previous tests were used in this test. In this case too, the perimeter is kept constant. Firstly, on a 900 mm x 200 smoothly folding cardboard handle (corrugated tubes pointing in the direction parallel to the shorter sides) sharp marks were made (parallel to the direction of the corrugated tubes) on the first outer layer, in order mark the corners of the diamond shape in a symmetrical shape. Second, the shorter ends of the 900x200 softly folding cardboard handle were joined by applying hot glue between a 20 mm overlap of material, on a panel. Subsequently, the panel was maintained in a standing position and positioned on a 6.5 mm deep corrugated cardboard frame placed horizontally, in order to shape the material in the shape of a diamond. The radius of curvature for each concave side panel was 610 mm. The geometry in the form of a reference square was also given crease marks to form the corners.
    [0115] [0115] The material used in this test was arranged so that the first outer layer was facing the interior of the structure. The result of this test showed that the BCT value increased by 33% compared to the referenced geometry in the form of a square.
    [0116] [0116] To give an example of a possible difference in flexural stiffness between the first outer layer and the second outer layer, the material used in the example above had a first outer layer with a flexural stiffness of 8.7 mNm, and a second outer layer with a flexural stiffness of 0.13 mNm).
    [0117] [0117] According to another example, and regarding the production process of the material, the second outer layer of the smoothly folding cardboard used in the tests described above was already cut into sheets, when applied over the intermediate layer. Table 4 below shows the results of a second test, using the smoothly folding cardboard produced by applying the second outer layer in a blanket feeding process, running at a normal production speed in a corrugating machine (160 m / min) . Thus, it has been tested that the material can be produced in a normal manufacturing process at a relatively high speed. In this test lwc 65 g / m2 was used as the second outer layer, white top coat was used, 200 g / m2 as the first outer layer and semi-chemical flutes 127g / m 2 were used as an intermediate layer. The thickness of the smoothly folding carton was 2.5 mm and the distance between the corrugated tubes was 4.5 mm. The result showed that the BCT value of the structure increased by 133% in relation to circular geometry compared to square geometry. In this test, the material was arranged so that the second outer layer was facing the interior of said structure.
    [0118] [0118] Dynamic impact tests of the square shape packaging (side length = 220 mm, height = 100 mm), comparing the standard box 0201 (box according to the FEFCO code (FEFCO: Federation of Corrugated Board Manufacturers) with a box having edges between adjacent rounded sides (according to Figure 7, which shows a preform (5), which generally corresponds to Figure 1a, but which has the dimensions according to box 0201 mentioned above), were made of according to the method described in patent application PCT / EP2011 / 073964. The results showed that the box having rounded edges (r = 30 mm) could carry about 80% higher load before the packaging structure was damaged. loads was made according to Table 5.
    [0119] [0119] The referendum signs mentioned in the claims should not be seen as a limitation on the extent of the matter protected by the claims, and their sole function is to make the claims easier to understand.
    [0120] [0120] Furthermore, the invention is not limited to any particular shape or shape of the packaging structure or its parts. For example, the side panels can be arranged to form a square, rectangular or triangular shape, or any other shape that involves a number of side panels. In addition, in the event that only one side of the panel is used, a circular, oval, drop or half-moon structure can be provided, or, in fact, in general, any side panel design that involves the ends being joined to form a closed structure.
    [0121] [0121] As will be perceived, the invention is capable of modifications in several obvious aspects, all without departing from the scope of the attached claims. Consequently, the drawings and the description of the same will be considered as illustrative and not restrictive in nature.
    权利要求:
    Claims (8)
    [0001]
    PACKAGING STRUCTURE (1), - said packaging structure (1) defining a bottom side (3) an upper side (2) and a plurality of side panels (4) joining said bottom side (3) and said top side (2) so as to form a closed structure, - at least one edge (14) is defined between adjacent side panels (4), - at least one edge (14) being rounded and comprising a radius between 10 and 150 mm; on what: - the packaging structure (1) is formed of multilayer cardboard material (6) comprising an intermediate layer (8), a first outer layer (7) connected to the intermediate layer (8) and a second external layer (9) connected the intermediate layer (8), - said intermediate layer (8) comprising a plurality of peaks (10) facing the second outer layer (9) and a plurality of valleys (11) facing the first outer layer; and - said outer layer comprises sections (12) between the peaks (10); and - said first outer layer (7) of at least one edge (14) comprises a continuous and smooth radius without creases, the packaging structure (1) being characterized by: - said second outer layer (9) is formed of thin paper; and - said second outer layer (9) has less flexural stiffness according to ISO 5628 than the first outer layer (7), and - said second outer layer (9) is curved between each peak (10) of the intermediate layer (8) when the material is subjected to bending in the folding direction and not being foldable between each peak (10) when the material is in a state plane, each foldable section of the second layer (9) showing buckling according to:
    [0002]
    Packaging structure (1) according to claim 1, characterized by said cardboard material (6) is arranged so that said second outer layer (9) faces inwards of said structure (1), in its state finished.
    [0003]
    Packaging structure (1) according to claim 1, characterized by said cardboard material (6) and arranged so that said second outer layer (9) faces outwards from said structure (1), in its state finished.
    [0004]
    PROCESS FOR MANUFACTURING A PACKAGING STRUCTURE (1) as defined in any one of claims 1 to 3, from a smoothly folding cardboard (6) comprising an intermediate layer (8), a first outer layer (7) and a second outer layer (9), the process being characterized by comprising the steps of: - Fix the first outer layer (7) to the intermediate layer (8), producing a single-sided card; and - Fix the second outer layer (9) to the intermediate layer (8), in which the second outer layer (9) has a lower flexural stiffness according to ISO 5628 than the first outer layer (7) to allow the folding said material into cardboard (6) according to a radius that remains smooth; and for also understanding the stage of: - Form the packaging structure to have at least one curved side panel (4) and / or at least one rounded edge (14), in which the first outer layer (7) of the curved panel (4) and / or rounded edge ( 14) exhibits a continuous and smooth radius without creasing, in which said second outer layer (9) begins to flicker when exposed to flexion, and in which both sides of the smoothly folding cardboard material (6) have smooth surfaces before bend the card.
    [0005]
    PROCESS FOR MANUFACTURING A PACKAGING STRUCTURE (1) as defined in any one of claims 13 from a smoothly folding carton (6) comprising an intermediate layer (8), a first outer layer (7) and a second layer external (9), the process being characterized by understanding the steps of: - Fix the second outer layer (9) to the intermediate layer (8) producing a single-sided card; - Attach the first outer layer (7) to the intermediate layer (8), where the second outer layer (9) has a lower flexural stiffness according to ISO 5628 than the first outer layer (7) to allow the folding said material into cardboard (6) according to a radius that remains smooth; - Form the packaging structure to have at least one curved side panel (4) and / or at least one rounded edge (14), in which the first outer layer (7) of the curved panel (4) and / or rounded edge ( 14) exhibits a continuous and smooth radius without creasing, in which said second outer layer (9) begins to flicker when exposed to flexion, and in which both sides of the smoothly folding cardboard material (6) have smooth surfaces before bend the card.
    [0006]
    PROCESS according to claim 4, characterized in that it comprises the step of: - Use an initially curved single-sided card curved in the direction that the first outer layer (7) is facing, and arrange the initially curved single-sided card to be flat before attaching the second outer layer (9).
    [0007]
    PROCESS according to claim 4, characterized by comprising the steps of: - Arrange the single-sided corrugated board in such a way that it is curved in a direction towards which the second outer layer is facing; - Fix the second outer layer (9) to the curved intermediate layer (8) curved.
    [0008]
    PROCESS according to claim 4, characterized by the fact that the intermediate layer (8) and a corrugated cardboard layer comprising flutes.
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    同族专利:
    公开号 | 公开日
    US9505515B2|2016-11-29|
    PL2828172T3|2019-05-31|
    EP2828172A4|2015-11-25|
    ZA201407515B|2018-09-26|
    AU2012374120B2|2015-12-03|
    PT2828172T|2019-03-01|
    WO2013141769A1|2013-09-26|
    HRP20190258T8|2019-04-19|
    EP3415443A1|2018-12-19|
    AU2012374120A1|2014-10-16|
    CA2867392C|2018-03-13|
    ES2716227T3|2019-06-11|
    HUE042544T2|2019-07-29|
    KR20140138309A|2014-12-03|
    MX2014011173A|2014-11-14|
    US20150048152A1|2015-02-19|
    EP2828172A1|2015-01-28|
    RU2598996C2|2016-10-10|
    CN104334456A|2015-02-04|
    IN2014DN08644A|2015-05-22|
    CN104334456B|2016-12-14|
    RU2014142539A|2016-05-20|
    EP2828172B1|2019-01-16|
    JP6321620B2|2018-05-09|
    JP2015516337A|2015-06-11|
    HRP20190258T1|2019-03-22|
    CA2867392A1|2013-09-26|
    MX345869B|2017-02-21|
    DK2828172T3|2019-03-11|
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    法律状态:
    2018-12-18| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2019-09-17| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2020-05-05| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2020-06-09| B09W| Decision of grant: rectification|Free format text: REFERENTE A RPI 2574 DE 05/05/2020 |
    2020-11-17| B09W| Decision of grant: rectification|Free format text: O PRESENTE PEDIDO TEVE UM PARECER DE DEFERIMENTO NOTIFICADO NA RPI NO 2574 DE 05/05/2020,TENDO SIDO CONSTATADO QUE ESTA NOTIFICACAO FOI EFETUADA COM INCORRECOES NA INDICACAO DAS VIASDO PEDIDO QUE DEVEM INTEGRAR A CARTA PATENTE, ASSIM RETIFICA-SE A REFERIDA PUBLICACAO. |
    2020-12-08| B09W| Decision of grant: rectification|Free format text: REFERENTE AO 9.1.4 DA RPI 2602 DE 17/11/2020. |
    2021-04-06| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 22/03/2012, OBSERVADAS AS CONDICOES LEGAIS. |
    优先权:
    申请号 | 申请日 | 专利标题
    PCT/SE2012/050321|WO2013141769A1|2012-03-22|2012-03-22|Packaging construction and method for manufacturing said packaging construction|
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