The present invention relates to a container for consumer goods and to a blank for forming such a container, which find particular application for holding elongate consumer goods, such as smoking articles (for example cigarettes). The present invention also relates to a method for forming such containers.
Consumer goods such as smoking articles are commonly packaged in rigid box shaped containers, such as hinged lid containers having a box portion and a lid connected to the box portion about a hinge line extending across the back wall of the container, a so called Flip-Top™ box. Such containers typically have a substantially parallelepiped shape comprising two-dimensional walls, including a front wall, a rear wall, two side walls, a top wall and a bottom wall. The manufacture of such containers using high speed manufacturing machines and processes is well established.
Sometimes it may be desirable to manufacture a container having a more complex shape. However, known processes for manufacturing containers having a more complex shape require specialised manufacturing machines that may substantially increase the cost of manufacturing the container and may require significant downtime when machines are changed to accommodate new shapes of container. For example, US 2004/0035723 A1 describes a method for manufacturing different cigarette containers having a variety of non-planar front walls. However, the method described in US 2004/0035723 A1 requires the use of a complex deformation device to modify the front wall of the container in a separate process after the container has been assembled.
It would be desirable to provide a container for consumer goods comprising a complex shape that can be assembled using existing high speed manufacturing machines and processes with minimal modification. It would be particularly desirable to provide such a container with at least one three-dimensional wall.
According to a first aspect of the present invention there is provided a container for consumer goods, the container being at least partially formed from a blank having a thickness (T). The container comprises a top wall comprising a top wall front edge, a top wall rear edge, and first and second top wall side edges. The container further comprises a bottom wall comprising a bottom wall front edge, a bottom wall rear edge, and first and second bottom wall side edges. A front wall extends from the top wall front edge to the bottom wall front edge, and a rear wall extends from the top wall rear edge to the bottom wall rear edge. A first side wall extends between the first top wall side edge and the first bottom wall side edge, the first side wall being connected to the front wall by a first side wall front edge and the first side wall being connected to the rear wall by a first side wall rear edge. A second side wall extends between the second top wall side edge and the second bottom wall side edge, the second side wall being connected to the front wall by a second side wall front edge, and the second side wall being connected to the rear wall by a second side wall rear edge. The top wall front edge, the bottom wall front edge, the first side wall front edge, and the second side wall front edge together extend along a first plane. The top wall rear edge, the bottom wall rear edge, the first side wall rear edge, and the second side wall rear edge together extend along a second plane. At least one of the front wall and the rear wall comprises an ablation area, wherein any ablation area on the front wall comprises at least one ablated line extending across the inner surface of the front wall to define a portion of the front wall that is spaced outwardly from the first plane, and wherein any ablation area on the rear wall comprises at least one ablated line extending across the inner surface of the rear wall to define a portion of the rear wall that is spaced outwardly from the second plane. Each ablated line has a residual thickness (RT1) that is less than the thickness (T) of the laminar blank.
In the following description of the invention the terms “side”, “top”, “bottom”, “front”, “rear” and other terms used to describe relative positions of the components of containers according to the invention refer to the container in an upright position with the lid portion, where present, at the top. When describing containers according to the present invention, these terms are used irrespective of the orientation of the container being described. In those embodiments in which the container comprises a lid with a lid portion back wall depending from a box portion back wall along a hinge line, the hinge line is located at the back of the container and allows opening of the lid portion by a pivotal movement about the hinge line.
The term “inner surface” is used to refer to the side of a portion of the blank that, once the container is assembled, faces towards the interior of the container, for example towards the consumer goods, when the container is in the closed position. Likewise, the term “outer surface” is used to refer to the side of a portion of the blank that, once the container is assembled, faces towards the exterior of the container.
The term “panel” is used herein to refer to a portion of the container formed from a single, continuous portion of material. A panel may depend from one or more other panels. The term “flap” refers to a panel that depends from only one other panel.
The term “wall” refers more generally to a facet of the container, and a wall may be formed from a single panel or flap, or a wall may be formed from two or more abutting or overlapping panels or flaps.
The term “ablation area” is used herein to refer to the minimum area of a wall that encloses all ablated lines on the wall.
The term “ablated line” is used herein to refer to an area of the blank from which material has been ablated (removed by means of a laser beam or a blade, for example) from a surface of the laminar blank or container. Accordingly, the residual thickness of an ablated line is less than the thickness (T) of the laminar blank. Preferably, an ablated line is provided as a groove within the blank. This may be formed with a linear ablation tool, such as a laser or a blade and preferably is a laser. Laser ablation may be performed using any suitable equipment, preferably a 1000 Watt carbon dioxide laser as commercially available from DIAMOND, such as the E-1000, for example. Ablation may be performed in the machine direction of the laminar blank or the cross direction.
The “thickness” (T) of the blank is the thickness of the blank after it has been manufactured, but before any ablation lines or creasing lines have been formed in the blank. That is, the thickness (T) of the blank is the thickness in any region of the blank not containing an ablated line or a crease line.
The term “residual thickness” is used herein to refer to the minimum distance measured between two opposite surfaces of the laminar blank or a panel of the container formed from the blank. In practice, the distance at a given location is measured along a direction locally perpendicular to the opposite surfaces. The residual thickness of each ablated line can be determined by using an Optical Profilometer for 2D Non-Contact Surface Metrology, such as the MicroSpy™ Profile commercially available from Fries Research & Technology GmbH, Bergisch Gladbach, Germany, or a 3D laser scanning confocal microscope, such as the VK-X series of microscopes commercially available from Keyence Corporation of America, New Jersey, United States of America. Preferably, several points of residual thickness are measured over the length of an ablated line, wherein the points of measurement are evenly spread over the length of one ablated line and the arithmetic mean is calculated. More preferably, to obtain the residual thickness according to the present invention, five measurements, evenly spread over the length of an ablated line, are performed and then the arithmetic mean is calculated.
For example, if the length of the ablated line is 80 millimetres, the residual thickness is measured at both ends of the ablated line and at three further points distanced 20 millimetres, 40 millimetres and 60 millimetres respectively from one end of the ablated line, preferably from the lower end of the ablated line.
The “residual thickness” of an ablated line may be constant over the ablated line if material is removed homogenously substantially all over the ablated line (flat profile). Alternatively, the residual thickness of the ablated line may vary across a width of the ablated line, if material is removed non-homogeneously over the ablated line (e.g. V-shaped, U-shaped grooves).
In contrast to conventional substantially parallelepiped containers, containers according to the present invention comprise a front wall, a rear wall, or both a front wall and a rear wall comprising a portion that is spaced outwardly from a plane defined by the edges bounding the wall. That is, in containers according to the present invention, at least one of the front wall and the back wall is three-dimensional.
By forming each three-dimensional wall using at least one ablation area comprising at least one ablated line, containers according to the present invention can be formed on existing high speed manufacturing machines with minimal modification. In particular, as a result of removing material from the blank to form the ablated lines, the three-dimensional features of at least one of the front wall and the rear wall are formed automatically by virtue of the normal folding forces that are applied to the blank during manufacture of the container. That is, folding the blank to create the edges bounding the front wall, the rear wall, the top wall, the bottom wall and the side walls automatically deforms the blank along the ablated lines of the ablation areas so that no further processes are required to form the three-dimensional features of the front wall, the rear wall, or the front wall and the rear wall. This is in contrast to known processes for forming containers having three-dimensional walls, such as the process described in US 2004/0035723 A1, which requires the use of a complex deformation device to modify the front wall of the container in a separate process after the container has been assembled.
Advantageously, if the overall size (maximum width and depth) of a container according to the present invention is not significantly altered, the blank can be adapted easily to form containers having different shapes without the need for major modifications of the packing machine used to assemble and pack the container.
Forming the ablated lines by removing material from the surface of the blank that forms an inner surface of the container advantageously maintains a smooth outer surface of the container, which may provide a desirable appearance of the container upon visual and tactile inspection.
At least one ablated line of any ablation area on the front wall preferably extends from at least one of the top wall front edge, the bottom wall front edge, the first side wall front edge, and the second side wall front edge. Similarly, at least one ablated line of any ablation area on the rear wall preferably extends from at least one of the top wall rear edge, the bottom wall rear edge, the first side wall rear edge, and the second side wall rear edge. Forming an ablated line that extends from an edge of the wall can advantageously facilitate deformation of the blank along the ablated line by transferring at least some of the folding force from the edge from which the ablated line extends when the blank is folded to form the container.
In some embodiments, forming an ablated line extending from an intersection between two edges of a wall may further enhance the effect of transferring at least some of the folding force along the ablated line when the blank is folded to form the container. Therefore, preferably, at least one ablated line of any ablation area on the front wall extends from an intersection of one of the top wall front edge and the bottom wall front edge with either the first side wall front edge or the second side wall front edge. Similarly, at least one ablated line of any ablation area on the rear wall preferably extends from an intersection of one of the top wall rear edge and the bottom wall rear edge with either the first side wall rear edge or the second side wall rear edge.
Preferably, any ablation area on the front wall comprises a first front ablated line extending from the intersection of the top wall front edge and the first side wall front edge, and a second front ablated line extending from the intersection of the top wall front edge and the second side wall front edge. Preferably, any ablation area on the rear wall comprises a first rear ablated line extending from the intersection of the top wall rear edge and the first side wall rear edge, and a second rear ablated line extending from the intersection of the top wall rear edge and the second side wall rear edge. Providing such first and second ablated lines on one or both of the front and rear walls may advantageously result in the formation of a substantially bevelled portion along part of the respective wall when the blank is folded to form the container.
In some embodiments, any first front ablated line may extend to the intersection of the bottom wall front edge and the first side wall front edge, and any second front ablated line may extend to the intersection of the bottom wall front edge and the second side wall front edge. Similarly, any first rear ablated line may extend to the intersection of the bottom wall rear edge and the first side wall rear edge, and any second rear ablated line may extend to the intersection of the bottom wall rear edge and the second side wall rear edge. Providing such first and second ablated lines on one or both of the front and rear walls may result in the formation of a substantially bevelled portion down each side of the respective wall when the blank is folded to form the container.
Alternatively, the blank may be configured so that any ablation area on the front wall further comprises: a third front ablated line extending from the intersection of the bottom wall front edge and the first side wall front edge; a fourth front ablated line extending from the intersection of the bottom wall front edge and the second side wall front edge; and a fifth front ablated line intersecting each of the first, second, third and fourth front ablated lines. Similarly, the blank may be configured so that any ablation area on the rear wall further comprises: a third rear ablated line extending from the intersection of the bottom wall rear edge and the first side wall rear edge; a fourth rear ablated line extending from the intersection of the bottom wall rear edge and the second side wall rear edge; and a fifth rear ablated line intersecting each of the first, second, third and fourth rear ablated lines. Providing such ablated lines on one or both of the front and rear walls may result in the formation of a substantially bevelled portion extending around the outside of the respective wall when the blank is folded to form the container. Providing such ablated lines may also result in the formation of a central portion of the wall that is bound by the substantially bevelled portion. In embodiments in which the first, second, third and fourth front or rear ablated lines have substantially the same length so that the width of the substantially bevelled portion is substantially constant around the front or rear wall respectively, the central portion may be substantially parallel to, but spaced outwardly from, the first plane or the second plane respectively.
In those embodiments comprising a fifth front ablated line, the fifth front ablated line may define a continuous loop, such as a rectangle or a square. Additionally, or alternatively, in those embodiments comprising a fifth rear ablated line, the fifth rear ablated line may define a continuous loop, such as a rectangle or a square.
In any of the embodiments described above, some or all of the first side wall front edge, the first side wall rear edge, the second side wall front edge and the second side wall rear edge may be a substantially straight edge. Additionally, or alternatively, some or all of the first side wall front edge, the first side wall rear edge, the second side wall front edge and the second side wall rear edge may comprise a bevelled or rounded edge. Preferably, any bevelled or rounded edges are formed by a plurality of spaced apart and substantially parallel ablated lines. The plurality of ablated lines may have any suitable extension profile in the longitudinal direction of the bevelled or rounded edge. For example, an ablated line may follow a curved trajectory over at least a portion of its extension profile in the longitudinal direction of the bevelled or rounded edge. In such embodiments, the facet created by such an ablated line will have a non-linear perimeter.
A “bevelled edge”, is used herein to refer to an edge of the container that has, as viewed in cross-section, one or more substantially straight shapes forming an angle between 0 and 90 degrees with the adjacent walls of the container. The bevelled edge can be measured using visual inspection by one or more test persons or microscopic measurement followed by statistical analysis, for example using a NIKON SMZ800 microscope on the outer surface of the laminar blank. X-Y-coordinates can be recorded on a fine grid (10 contour points) for each sample. The recorded X-Y-coordinates can be used for a linear spline interpolation and the profile of the resulting first derivative can be captured. For an almost constant first derivative the evaluated sample can be classified as a bevel.
In any of the embodiments described above, each ablated line preferably has a residual thickness (RT) of at least about 5 percent, more preferably at least about 10 percent, more preferably at least about 15 percent, more preferably at least about 20 percent, more preferably at least about 25 percent and even more preferably at least about 30 percent of the thickness (T) of the blank. In addition, or as an alternative, each ablated line preferably has a residual thickness of less than about 50 percent, more preferably less than about 45 percent and even more preferably less than about 40 percent of the thickness (T) of the blank.
The present inventors have found that, if the ablated line extends too far into the thickness of the laminar blank (that is, too deep) then the resultant outer surface of the container can be undesirably affected. For example, the outer surface can appear cracked or broken. Furthermore, the present inventors have found that, if an ablated line does not extend far enough into the thickness of the laminar blank (that is, too shallow) then the resultant outer surface of the container can also be undesirably affected. In particular, the present inventors have found that the turning points of the container along the ablated lines may be poorly defined on the container outer surface, and/or may follow an unintended trajectory along the outer surface of the container. For example, if an ablated line extends in a straight line along the inner surface of the container, the present inventors have found that the corresponding turning point that is produced on the outer surface of the container may be non-linear, or uneven. The present inventors have therefore identified that a cleaner looking, more well-defined container can be produced when each of the ablated lines has a residual thickness as specified above.
In any of the embodiments described above, the ablated width (X) of each ablated line is preferably at least about 0.1 millimetres. More preferably, the ablated width of each ablated line is at least about 0.2 millimetres. Most preferably, the ablated width of each ablated line is at least about 0.3 millimetres. In addition, or as an alternative, the ablated width of each ablated line is less than about 0.5 millimetres. More preferably, the ablated width of each ablated line is less than about 0.45 millimetres. In some preferred embodiments, the ablated width of each ablated line is from about 0.1 millimetres to about 0.5 millimetres. Even more preferably, the ablated width of each ablated line is from about 0.2 millimetres to about 0.45 millimetres, more preferably from about 0.3 millimetres to 0.4 about millimetres.
In any of the embodiments described above, the thickness (T) of the laminar blank is preferably between about 200 micrometres and about 350 micrometres, more preferably between about 250 micrometres and about 300 micrometres. The thickness (T) of the laminar blank can be measured in accordance with ISO 534:2011.
Testing and conditioning at 23 degrees Celsius, 50% relative humidity according to ISO 187 two weeks after ablation.
In any of the embodiments described above, the laminar blank preferably has a basis weight of between about 100 grams per square metre and about 350 grams per square metre, more preferably between about 150 grams per square metre and about 350 grams per square metre, more preferably between about 200 grams per square metre and about 300 grams per square metre. Basis weight is calculated using ISO 536 and may vary from plus ten percent to minus ten percent, preferably from plus five percent to minus five percent.
In any of the embodiments described above, the laminar blank preferably has a spring-back force of less than 10 milliNewton metres between adjacent walls. The term “spring-back force” is a known term of art for referring to a particular property of a laminar blank. It is sometimes referred to as ‘the crease recovery’ and means the force (Newtons) required to hold a scored sample that is folded at 90 degrees for a 15-second period. The measurement is made at the end of the 15-second period. The spring-back force of a portion of a laminar blank can be measured using a known PIRA Crease and Board Stiffness Tester (commercially available for example from Messmer and Buchel, UK). As is known in the art, to measure the spring-back force of a curved edge portion of a container, a sample of the portion to be tested should first be removed from the laminar blank. For round corner packs, for the purposes of the present invention the spring-back force of a pack is assessed using a sample measuring 38±1 millimetres by 38±0.5 millimetres, with the corner forming portion being positioned 21±0.5 millimetres from one side of the blank. The blank should be conditioned at 22 degrees Celsius and 60 percent relative humidity for at least 24 hours prior to testing.
Preferably, the laminar blank has a stiffness in the bending direction of at least about 50 milliNewtons, preferably at least about 75 milliNewtons, most preferably at least about 90 milliNewtons. In addition, or in the alternative, the laminar blank preferably has a bending stiffness of less than about 500 milliNewtons, preferably less than about 200 milliNewtons, more preferably less than about 160 milliNewtons. The laminar blank preferably has a bending stiffness from about 50 milliNewtons to about 200 milliNewtons. More preferably, the laminar blank has a stiffness in the machine direction of from about 75 milliNewtons to about 160 milliNewtons. Stiffness in the “bending direction” means that the bending stiffness is measured in the direction that the finished board is intended to be folded about an ablated line.
Preferably, the laminar blank has a residual stiffness in the bending direction of at least about 10 milliNewtons, preferably at least about 12 milliNewtons, more preferably at least about 15 milliNewtons and even more preferably at least about 20 milliNewtons. In addition, or in the alternative, the laminar blank preferably has a residual stiffness in the bending direction of from about 60 milliNewtons or less, more preferably 50 milliNewtons or less, even more preferably 40 milliNewtons or less.
Preferably, the laminar blank has a surface roughness of from about 0.5 micrometres to about 1.5 micrometres. More preferably, the laminar blank has a surface roughness of from about 0.75 micrometres to about 1.25 micrometres. The surface roughness is measured in accordance with ISO 8791-4.
Preferably, the laminar blank has a surface strength of from about 0.25 metres per second to about 1 metre per second. More preferably, the laminar blank has a surface strength of from about 0.5 metres per second to about 0.8 metres per second. The surface strength is measured in accordance with ISO 3783.
In any of the embodiments described above, the laminar blank is preferably a cellulose-fibre-based laminar blank. A cellulose-fibre-based blank comprises at least 50 weight-percent cellulose, preferably wood fibres, based on the total fibre content of the laminar blank. A cellulose-fibre-based laminar blank may include other types of fibres, such as polymer fibres.
In any of the embodiments described above, the container may comprise a box portion and a lid portion depending along a hinge line from a top edge of the box portion, the lid portion being moveable about the hinge line between an open position and a closed position. Preferably, the lid portion comprises a lid portion top wall, a lid portion front wall, a lid portion rear wall, a first lid portion side wall and a second lid portion side wall. Preferably, the box portion comprises a box portion front wall, a box portion rear wall, a box portion bottom wall, a first box portion side wall and a second box portion side wall. The lid portion top wall forms the container top wall and the box portion bottom wall forms the container bottom wall. The lid portion and box portion front walls together form the container front wall, and the lid portion and box portion rear walls together form the container rear wall. A bottom edge of the lid portion rear wall depends along the hinge line from a top edge of the box portion rear wall. The first lid portion and box portion side walls together form the container first side wall, and the second lid portion and box portion side walls together form the container second side wall.
Containers according to the present invention find application as containers for consumer goods, in particular elongate consumer goods such as smoking articles. Therefore, in any of the embodiments described above, the container may contain smoking articles.
The present invention also extends to a method of manufacturing the container in accordance with any of the embodiments described above. Therefore, according to a second aspect of the present invention there is provided a method of forming a container for consumer goods in accordance with any embodiment of the first aspect of the present invention, the container being at least partially formed from a blank having a thickness (T), the method comprising a step of providing a laminar blank having a thickness (T), the laminar blank having a first set of ablated lines defining a plurality of panels of the laminar blank, each ablated line having a residual thickness (RT1) that is less than the thickness (T) of the laminar blank. The laminar blank is then folded about the first set of ablated lines to form a container having a top wall comprising a top wall front edge, a top wall rear edge, and first and second top wall side edges. The container further comprises a bottom wall comprising a bottom wall front edge, a bottom wall rear edge, and first and second bottom wall side edges. A front wall extends from the top wall front edge to the bottom wall front edge and a rear wall extends from the top wall rear edge to the bottom wall rear edge. A first side wall extends between the first top wall side edge and the first bottom wall side edge, the first side wall being connected to the front wall by a first side wall front edge, the first side wall being connected to the rear wall by a first side wall rear edge. A second side wall extends between the second top wall side edge and the second bottom wall side edge, the second side wall being connected to the front wall by a second side wall front edge, the second side wall being connected to the rear wall by a second side wall rear edge. The laminar blank is folded such that top wall front edge, the bottom wall front edge, the first side wall front edge, and the second side wall front edge together extend along a first plane. The laminar blank is also folded such that top wall rear edge, the bottom wall rear edge, the first side wall rear edge, and the second side wall rear edge together extend along a second plane. The laminar blank further comprises at least one ablation area so that at least one of the front wall and the rear wall of the container comprises the at least one ablation area, wherein any ablation area on the front wall comprises at least one ablated line extending across the inner surface of the front wall, and wherein any ablation area on the rear wall comprises at least one ablated line extending across the inner surface of the rear wall. Each ablated line has a residual thickness (RT1) that is less than the thickness (T) of the laminar blank. During the step of folding, the laminar blank is at least partially folded along the at least one ablated line of each ablation area, so that any ablation area on the front wall defines a portion of the front wall spaced outwardly from the first plane and so that any ablation area on the rear wall defines a portion of the rear wall spaced outwardly from the second plane.
The invention will be further described, by way of example only, with reference to the accompanying drawings in which:
The top wall 12 comprises a top wall front edge 22, a top wall rear edge 24, and first and second top wall side edges 26, 28. The bottom wall comprises a bottom wall front edge 30, a bottom wall rear edge 32, and first and second bottom wall side edges 34, 36. The first side wall 18 is connected to the front wall 14 by a first side wall front edge 38 and to the rear wall 16 by a first side wall rear edge 40. The second side wall 20 is connected to the front wall 14 by a second side wall front edge 42 and to the rear wall 16 by a second side wall rear edge 44. The top wall front edge 22, the bottom wall front edge 30, the first side wall front edge 38 and the second side wall front edge 42 together extend along a first plane. The top wall rear edge 24, the bottom wall rear edge 32, the first side wall rear edge 40 and the second side wall rear edge 44 together extend along a second plane.
The front wall 12 comprises an ablation area including a first front ablated line 46, a second front ablated line 48, a third front ablated line 50, a fourth front ablated line 52 and a fifth front ablated line 54 each formed on the inner surface of the front wall 12. The fifth front ablated line 54 is a rectangular ablated line that forms a continuous loop connected to each of the first, second, third and fourth front ablated lines. When the laminar blank is folded to form the container 10 at least some of the folding force is transferred along the first to fifth front ablated lines so that the laminar blank automatically deforms along the ablated lines. The deformation along the first to fifth front ablated lines creates a central portion 56 of the front wall 12 that is substantially parallel to and spaced outwardly from the first plane.
Similarly, the rear wall 16 comprises an ablation area including a first rear ablated line 58, a second rear ablated line 60, a third rear ablated line 62, a fourth rear ablated line 64 and a fifth rear ablated line 66 each formed on the inner surface of the rear wall 16. The fifth rear ablated line 66 is a rectangular ablated line that forms a continuous loop connected to each of the first, second, third and fourth rear ablated lines. When the laminar blank is folded to form the container 10 at least some of the folding force is transferred along the first to fifth rear ablated lines so that the laminar blank automatically deforms along the ablated lines. The deformation along the first to fifth rear ablated lines creates a central portion 68 of the rear wall 16 that is substantially parallel to and spaced outwardly from the second plane.
The laminar blank 100 comprises a box portion bottom panel 152, a box portion front panel 154 depending along an ablated line 156 from the box portion bottom panel 152, and a box portion rear panel 158 depending along an ablated line 160 from the box portion bottom panel 152. First box portion side panels 162 depend along ablated lines 164 from the box portion rear panel 158 and second box portion side panels 166 depend along ablated lines 168 from the box portion front panel 154. Two box portion dust flaps 170 depend along ablated lines 172 from the first box portion side panels 162. When the laminar blank 100 is folded to form the container 10, the box portion bottom panel 152 in combination with the box portion dust flaps 170 forms the container bottom wall.
The laminar blank 100 further comprises a lid portion rear panel 174 depending along an ablated line 176 from the box portion rear panel 158, a lid portion top panel 142 depending along an ablated line 178 from the lid portion rear panel 174, and a lid portion front panel 180 depending along an ablated line 182 from the lid portion top panel 142. A lid portion front under panel 184 depends along an ablated line 186 from the lid portion front panel 180.
The laminar blank 100 also comprises first lid portion side flaps 188 depending along ablated lines 190 from the lid portion rear panel 174, first and second dust flaps 138, 140 depending along ablated lines 194 from the respective first lid portion side flaps 188, and second lid portion side flaps 196 depending along ablated lines 198 from the lid portion front panel 180. When the laminar blank 100 is folded to form the container 10, the lid portion top panel 142 in combination with the first and second dust flaps 138, 140 forms the container top wall 12. Each first box portion side panel 162 in combination with the respective second box portion side panel 166, first lid portion side flap 188 and second lid portion side flap 196 forms the respective container side wall 18, 20. The box portion rear panel 158 and the lid portion rear panel 174 together form the box portion rear wall 16. The box portion front panel 154 in combination with the lid portion front panel 180 and the lid portion front under panel 184 forms the container front wall 14.
Number | Date | Country | Kind |
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15174620.3 | Jun 2015 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2016/065393 | 6/30/2016 | WO | 00 |