The present invention relates to a corrugated paperboard box, a perforation forming method for perforating a corrugated paperboard sheet, and a perforation forming device and a perforation forming unit for perforating a corrugated paperboard sheet
Generally, corrugated paperboard boxes include a peripheral wall formed by bending the corrugated paperboard into a tubular shape, and a plurality of flaps integrally connected to one end of the peripheral wall, and are formed with a normal scoreline at the boundary area between the flaps and the peripheral wall so that the flaps can be smoothly bent along the normal scoreline toward the inner surface of the peripheral wall. The corrugated paperboard, of which such a corrugated paperboard box is made, includes an outer linerboard, an inner linerboard, and a corrugated medium provided between the outer linerboard and the inner linerboard. The normal scoreline at the boundary area between the flaps and the peripheral wall is recessed on the side of the inner linerboard (i.e., on the inner side of the box).
When products are packed in such a corrugated paperboard box, in order to enable the products to be easily placed into the box, the flaps are bent toward the outer surface of the peripheral wall (i.e., bent outwardly) in some cases. Since the normal scoreline at the boundary area between the flaps and the peripheral wall is a groove-shaped scoreline recessed on the side of the inner linerboard, the flaps can be smoothly bent inwardly along the normal scoreline. However, the flaps are less likely to be bent outwardly. Therefore, when products are packed in such a corrugated paperboard box, it is necessary to hold the flaps by hand with the flaps bent outwardly such that the flaps do not elastically return.
In order to overcome such a problem, Japanese Unexamined Utility Model Application Publication No. S60-123317 proposes a corrugated paperboard box including a flap 201 and a peripheral wall 202, and formed, as illustrated in
In order to make it possible to easily open the corrugated paperboard box formed at the boundary area between the flap 201 and the peripheral wall 202 with the normal scoreline 203, along which the flap 201 can be bent toward the inner surface of the peripheral wall 202, and the reverse scoreline 204, along which the flap 201 can be bent toward the outer surface of the peripheral wall 202, as illustrated by the dashed line in
If the perforated line 205 is formed at the position of the normal scoreline 203, it is possible to easily open the corrugated paperboard box by separating the flap 201 along the perforated line 205 from the peripheral wall 202 with the box closed by the flap 201. Also, after separating the flap 201 along the perforated line 205 from the peripheral wall 202, it is possible to display products at a storefront with the products received in the corrugated paperboard box, namely, without taking the products out of the box.
However, when the inventors of the present application experimentally prepared in their company a corrugated paperboard box which is formed at the boundary area between the flap 201 and the peripheral wall 202 with the normal scoreline 203, along which the flap 201 can be bent toward the inner surface of the peripheral wall 202, and the reverse scoreline 204, along which the flap 201 can be bent toward the outer surface of the peripheral wall 202, and wall 202, and which is further formed at the position of the normal scoreline 203 with the perforated line 205, along witch the flap 201 can be separated from the peripheral wall 202, it turned out that when the flap 201 is bent along the normal scoreline 203 toward the inner surface of the peripheral wall 202, the perforated line 205 tends to break.
Therefore, the inventors of the present application investigated what causes the perforated line 205 to break when bending the flap 201 along the normal scoreline 203 in the above corrugated paperboard box, experimentally prepared in their company, and noticed the following point.
When the boundary area between the flap 201 and the peripheral wall 202 is sandwiched from the side of an outer linerboard 206 and the side of an inner linerboard 207, the normal scoreline 203 is formed. Similarly, when the boundary area between the flap 201 and the peripheral wall 202 is sandwiched from the side of the outer linerboard 206 and the side of the inner linerboard 207, the reverse scoreline 204 is formed. Namely, if both the normal scoreline 203 and the reverse scoreline 204 are formed, the boundary area between the flap 201 and the peripheral wall 202 is sandwiched twice, specifically, when the normal scoreline 203 is formed, and when the reverse scoreline 204 is formed, thereby receiving a large tensile load. This decreases, to a large degree, the tensile strengths of the portions of the linerboards 206 and 207 located at the boundary area between the flap 202 and the peripheral wall 202.
Therefore, it turned out that if both the normal scoreline 203 and the reverse scoreline 204 are formed, and further the perforated line 205 is formed at the position of the normal scoreline 203, the perforated line 205 tends to break. Namely, when the flap 201 is bent along the normal scoreline 203 toward the inner surface of the peripheral wall 202, the perforated line 205 tends to break due to the tension applied to the outer linerboard 206.
In order to make it possible to easily open the corrugated paperboard box, as illustrated in
However, when the inventors of the present application experimentally prepared a plurality of corrugated paperboard boxes in which the perforated line 17 is formed within the normal scoreline 208, along which the flap can be bent, and evaluated these boxes, it turned out that when the flap is bent along the normal scoreline 208 toward an outer linerboard 1 (i.e., bent in the reverse direction), the perforated line 17 tends to break.
Thereafter, when the inventors of the present application experimentally prepared a corrugated paperboard box so as to consider why the perforated line 17 tends to break, instead of forming the normal scoreline 208, recessed on the side of the inner linerboard 2 (i.e., on the inner side of the box) as illustrated in
As illustrated in
After bending the flap of this corrugated paperboard box along the perforated line 17, the inventors noticed that the perforated line 17 does not break both when the flap is bent along the perforated line 17 toward the outer linerboard 1, and when the flap is bent along the perforated line 17 toward the inner linerboard 2.
Moreover, the inventors considered why the perforated line 17 does not break in the above corrugated paperboard box, experimentally prepared in their company, and noticed the following point: If, as illustrated in
When the inventors of the present application experimentally prepared a plurality of corrugated paperboard boxes in which the perforated line is formed within the normal scoreline between the flap and the peripheral wall, and evaluated these boxes, it turned out that when products are packed in the boxes, the boundary area between the flap and the peripheral wall might break along the perforated line.
Namely, when products are packed in such a corrugated paperboard box, in order to enable the products to be easily placed into the box, the flaps are bent toward the outer surface of the peripheral wall (i.e., bent in the reverse direction) in some cases. Since the normal scoreline between the flap and the peripheral wall is a groove-shaped scoreline recessed on the side of the inner linerboard, when the flap is bent toward the inner surface of the peripheral wall, the flap can be bent naturally and accurately along the normal scoreline. However, a relatively large force is required to bend the flap toward the outer surface of the peripheral wall, namely, when the flap is bent outwardly, a large tension is applied to the inner linerboard. If the perforated line is formed within the normal scoreline between the flap and the peripheral wall, when the flap is bent along the normal scoreline toward the outer surface of the peripheral wall, the boundary area between the flap and the peripheral wall might break along the perforated line due to the tension applied to the inner linerboard.
It is an object of the present invention to provide a corrugated paperboard box in which when a flap is bent, a perforated line along which the flap can be separated from the box is less likely to break.
In order to achieve the above object, the present invention provides a corrugated paperboard box made of corrugated paperboard comprising an outer linerboard, an inner linerboard, and a corrugated medium provided between the outer linerboard and the inner linerboard, the corrugated paperboard box comprising: a peripheral wall formed by bending the corrugated paperboard into a tubular shape such that the inner linerboard constitutes an inner surface of the corrugated paperboard box; and flaps integrally connected to one of two ends of the peripheral wall. The corrugated paperboard box is formed, at a boundary area between the peripheral wall and the flaps, with a groove-shaped reverse scoreline recessed on a side of the outer linerboard, and a pair of groove-shaped recesses recessed on a side of the inner linerboard, and extending in parallel to each other so as to sandwich an area in which the reverse scoreline extends. The corrugated paperboard box is formed, in one of the groove-shaped recesses, with a perforated line along which the flaps can be separated from the peripheral wall, and which comprises a plurality of cuts extending to penetrate through the inner linerboard, the corrugated medium, and the outer linerboard, and wherein the corrugated paperboard is configured such that the flaps can be bent along the perforated line toward an inner surface of the peripheral wall.
In this corrugated paperboard box, the pair of groove-shaped recesses at the boundary area between the peripheral wall and the flaps are formed on the side of the inner linerboard at the same time as the corrugated paperboard sheet is sandwiched from the side of the outer linerboard and the side of the inner linerboard to form the reverse scoreline which is recessed on the side of the outer linerboard, and at the boundary area between the peripheral wall and the flaps, there is no normal scoreline which is formed independently of the reverse scoreline in conventional corrugated paperboard boxes. In the corrugated paperboard box, no such normal scoreline is necessary, because one of the groove-shaped recesses and the perforated line, along which the flaps can be separated from the peripheral wall, function as such a normal scoreline. Therefore, in this corrugated paperboard box, the tensile strengths of the portions of the outer and inner linerboards located at the boundary area between the peripheral wall and the flaps are less likely to decrease due to the tensile load applied when the reverse scoreline is formed, so that when the flaps are bent along the perforated line toward the inner surface of the peripheral wall, it is possible to prevent the breakage of the perforated line due to the tension applied to the outer linerboard.
It is preferable that each of the cuts of the perforated line comprises a first cut portion formed in the outer linerboard, and a second cut portion formed in the inner linerboard, and the perforated line is formed such that widths of the first cut portions in an orthogonal direction to a direction in which the perforated line extends are smaller than widths of the second cut portions in the orthogonal direction.
With this arrangement, when the perforated line is formed, the load applied to the joint portions between the adjacent pairs of first cut portions on the side of the outer linerboard is smaller than the load applied to the joint portions between the adjacent pairs of second cut portions on the side of the inner linerboard. Therefore, when the flaps are bent along the perforated line toward the inner surface of the peripheral wall, it is possible to effectively prevent the breakage of the perforated line due to the tension applied to the outer linerboard.
Preferably, the perforated line is formed such that each of the first cut portions on the side of the outer linerboard includes a peripheral edge portion having a protruding shape, and each of the second cut portions on the side of the inner linerboard includes a peripheral edge portion having a recessed shape.
With this arrangement, when the flaps are bent along the perforated line toward the inner surface of the peripheral wall, it is possible to effectively prevent the breakage of the perforated line due to the tension applied to the outer linerboard.
As a perforation forming method for perforating a corrugated paperboard sheet suitable for manufacturing the above corrugated paperboard box, the present invention provides a perforation forming method for perforating a corrugated paperboard sheet comprising an outer linerboard, an inner linerboard, and a corrugated medium provided between the outer linerboard and the inner linerboard. The perforation forming method includes providing: a first reverse scoreline ring formed on an outer periphery of the first reverse scoreline ring with a groove, and a pair of groove shoulders arranged on two axial sides of the groove, respectively; and a second reverse scoreline ring formed on an outer periphery of the second reverse scoreline ring with a protrusion opposed to the groove of the first reverse scoreline ring and continuously extending in a circumferential direction, and a pair of recesses arranged on two axial sides of the protrusion, respectively. The first and second reverse scoreline rings are arranged on a side of the inner linerboard and on a side of the outer linerboard, respectively; and the first and second reverse scoreline rings sandwich the corrugated paperboard sheet, while the corrugated paperboard sheet is being fed, from the side of the inner linerboard and the side of the outer linerboard, respectively, such that a groove-shaped reverse scoreline recessed on the side of the outer linerboard is formed in the corrugated paperboard sheet by being sandwiched between the groove of the first reverse scoreline ring and the protrusion of the second reverse scoreline ring. A pair of groove-shaped recesses recessed on the side of the inner linerboard, and extending in parallel to each other so as to sandwich an area in which the reverse scoreline extends are formed in the corrugated paperboard sheet by being sandwiched between the groove shoulders of the first reverse scoreline ring and the recesses of the second reverse scoreline ring; and a perforated line is formed in one of the groove-shaped recesses with a perforation forming knife arranged on a downstream side of the first and second reverse scoreline rings, the perforated line comprising a plurality of cuts extending to penetrate through the inner linerboard, the corrugated medium, and the outer linerboard.
If such a perforation forming method is used, by sandwiching the corrugated paperboard sheet from the side of the outer linear board and the side of the inner linerboard, the first and second reverse scoreline rings can simultaneously form the reverse scoreline on the side of the outer linerboard, and the groove-shaped recesses on the side of the inner linerboard. Since the reverse scoreline and the groove-shaped recesses are first formed by the first and second reverse scoreline rings, and then the perforated line is formed by the perforation forming knife, arranged on the downstream side of the first and second reverse scoreline rings, it is possible to prevent the breakage of the perforated line due to the pressing force of the first and second reverse scoreline rings. Namely, if the perforated line is formed before the reverse scoreline is formed, the perforated line might break due to the pressing force of the first and second reverse scoreline rings. In contrast thereto, by forming the perforated line after the reverse scoreline is formed, it is possible to prevent the breakage of the perforated line due to the pressing force of the first and second reverse scoreline rings.
It is preferable that the perforation forming knife is configured to cut the corrugated paperboard sheet from the side of the inner linerboard toward the side of the outer linerboard.
By use of such a perforation forming knife, it is possible to form the perforated line such that the widths of the first cut portions of the perforated line on the side of the outer linerboard are smaller than those of the second cut portions thereof on the side of the inner linerboard, and also such that the peripheral edge portions of the first cut portions on the side of the outer linerboard have a protruding shape, and the peripheral edge portions of the second cut portions on the side of the inner linerboard have a recessed shape.
It is preferable that if the perforation forming knife comprises a disk-shaped knife formed on an outer periphery of the disk-shaped knife with a plurality of cutting portions protruding radially outwardly, and equidistantly spaced apart from each other, each of the cutting portions comprises a radially outer cutting edge, a front cutting edge in a rotation direction of the perforation forming knife, and a rear cutting edge in the rotation direction.
With this arrangement, it is possible to prevent the occurrence of cracks in the outer linerboard or in the inner linerboard due to the resistance generated when the cutting portions cut the corrugated paperboard sheet. As a result thereof, it is possible to effectively prevent the breakage of the perforated line.
A perforation forming device for perforating a corrugated paperboard sheet suitable for manufacturing the above corrugated paperboard box comprising an outer linerboard, an inner linerboard, and a corrugated medium provided between the outer linerboard and the inner linerboard. The perforation forming device includes a first reverse scoreline ring arranged on a side of the inner linerboard, and formed on an outer periphery of the first reverse scoreline ring with a groove, and a pair of groove shoulders arranged on two axial sides of the groove, respectively; a second reverse scoreline ring arranged on a side of the outer linerboard, and formed on an outer periphery of the second reverse scoreline ring with a protrusion opposed to the groove of the first reverse scoreline ring, and continuously extending in a circumferential direction, and a pair of recesses arranged on two axial sides of the protrusion, respectively. The pair of first and second reverse scoreline rings are configured to sandwich the corrugated paperboard sheet, while the corrugated paperboard sheet is being fed, from the side of the inner linerboard and the side of the outer linerboard, respectively, such that a groove-shaped reverse scoreline recessed on the side of the outer linerboard is formed in the corrugated paperboard sheet by being sandwiched between the groove of the first reverse scoreline ring and the protrusion of the second reverse scoreline ring, and such that a pair of groove-shaped recesses recessed on the side of the inner linerboard, and extending in parallel to each other so as to sandwich an area in which the reverse scoreline extends are formed in the corrugated paperboard sheet by being sandwiched between the groove shoulders of the first reverse scoreline ring and the recesses of the second reverse scoreline ring. A perforation forming knife is arranged on a downstream side of the first and second reverse scoreline rings, and is configured to form a perforated line in one of the groove-shaped recesses, the perforated line comprising a plurality of cuts extending to penetrate through the inner linerboard, the corrugated medium, and the outer linerboard.
If such a perforation forming device is used, by sandwiching the corrugated paperboard sheet from the side of the outer linear board and the side of the inner linerboard, the first and second reverse scoreline rings can simultaneously form the reverse scoreline on the side of the outer linerboard, and the groove-shaped recesses on the side of the inner linerboard. Since the reverse scoreline and the groove-shaped recesses are first formed by the first and second reverse scoreline rings, and then the perforated line is formed by the perforation forming knife, arranged on the downstream side of the first and second reverse scoreline rings, it is possible to prevent the breakage of the perforated line due to the pressing force of the first and second reverse scoreline rings. Namely, if the perforated line is formed before the reverse scoreline is formed, the perforated line might break due to the pressing force of the first and second reverse scoreline rings. In contrast thereto, by forming the perforated line after the reverse scoreline is formed, it is possible to prevent the breakage of the perforated line due to the pressing force of the first and second reverse scoreline rings.
It is preferable that the perforation forming knife is configured to cut the corrugated paperboard sheet from the side of the inner linerboard toward the side of the outer linerboard.
By use of such a perforation forming knife, it is possible to form the perforated line such that the widths of the first cut portions of the perforated line on the side of the outer linerboard are smaller than those of the second cut portions thereof on the side of the inner linerboard, and also such that the peripheral edge portions of the first cut portions on the side of the outer linerboard have a protruding shape, and the peripheral edge portions of the second cut portions on the side of the inner linerboard have a recessed shape.
It is preferable that if the perforation forming knife comprises a disk-shaped knife formed on an outer periphery of the disk-shaped knife with a plurality of cutting portions protruding radially outwardly, and equidistantly spaced apart from each other, each of the cutting portions comprises a radially outer cutting edge, a front cutting edge in a rotation direction of the perforation forming knife, and a rear cutting edge in the rotation direction thereof.
With this arrangement, it is possible to prevent the occurrence of cracks in the outer linerboard or in the inner linerboard due to the resistance generated when the cutting portions cut the corrugated paperboard sheet. As a result thereof, it is possible to effectively prevent the breakage of the perforated line.
In order to achieve the above object, the present invention provides a corrugated paperboard box made of corrugated paperboard comprising: an outer linerboard; an inner linerboard; a corrugated medium provided between the outer linerboard and the inner linerboard, the corrugated paperboard box comprising: a peripheral wall formed by bending the corrugated paperboard into a tubular shape such that the inner linerboard constitutes an inner surface of the corrugated paperboard box; and flaps integrally connected to one of two ends of the peripheral wall. The corrugated paperboard box is formed, at a boundary area between the peripheral wall and the flaps, with a groove-shaped reverse scoreline recessed on a side of the outer linerboard, and a perforated line along which the flaps can be separated from the peripheral wall, and which comprises a plurality of cuts extending to penetrate through the inner linerboard, the corrugated medium, and the outer linerboard, and the perforated line is formed within the reverse scoreline. Each of the cuts of the perforated line comprises a first cut portion formed in the outer linerboard, and a second cut portion formed in the inner linerboard, and the perforated line is formed such that widths of the first cut portions in an orthogonal direction to a direction in which the perforated line extends are smaller than widths of the second cut portions in the orthogonal direction.
With this arrangement, when the reverse scoreline is formed, a large load is applied to the outer linerboard, whereas when the perforated line is formed, a large load is applied to the inner linerboard on the opposite side of the outer linerboard. Namely loads do not concentrate on one of the outer and inner linerboards when the reverse scoreline and the perforated line are formed. Therefore, the perforated line is relatively less likely to break.
Preferably, the perforated line is formed such that each of the first cut portions on the side of the outer linerboard includes a peripheral edge portion having a protruding shape, and each of the second cut portions on a side of the inner linerboard includes a peripheral edge portion having a recessed shape.
With this arrangement, when the flaps are bent along the perforated line toward the inner surface of the peripheral wall, it is possible to effectively prevent the breakage of the perforated line due to the tension applied to the outer linerboard.
A perforation forming method is provided for perforating a corrugated paperboard sheet suitable for manufacturing the above corrugated paperboard box comprising an outer linerboard, an inner linerboard, and a corrugated medium provided between the outer linerboard and the inner linerboard. The perforation forming method comprises: a reverse scoreline forming step of forming in the corrugated paperboard sheet a groove-shaped reverse scoreline recessed on a side of the outer linerboard by sandwiching the corrugated paperboard sheet from the side of the outer linerboard and a side of the inner linerboard with a pair of reverse scoreline rings; and a perforation forming step of forming, after the reverse scoreline forming step, a perforated line in the reverse scoreline with a perforation forming knife, the perforated line comprising a plurality of cuts extending to penetrate through the inner linerboard, the corrugated medium, and the outer linerboard, wherein the perforation forming knife is configured to cut the corrugated paperboard sheet from the side of the inner linerboard toward the side of the outer linerboard.
If such a perforation forming method is used, since after the reverse scoreline rings form the reverse scoreline by sandwiching the corrugated paperboard sheet from the side of the outer linear board and the side of the inner linerboard, the perforation forming knife, arranged on the downstream side of the reverse scoreline rings, forms the perforated line, it is possible to prevent the breakage of the perforated line due to the pressing force of the reverse scoreline rings. Namely, if the perforated line is formed before the reverse scoreline is formed, the perforated line might break due to the pressing force of the reverse scoreline rings. In contrast thereto, if the perforated line is formed after the reverse scoreline is formed, it is possible to prevent the breakage of the perforated line due to the pressing force of the reverse scoreline rings. Since the perforation forming knife forms the perforated line by cutting the corrugated paperboard sheet from the side of the inner linerboard toward the side of the outer linerboard, it is possible to form the perforated line such that the widths of the first cut portions of the perforated line on the side of the outer linerboard are smaller than those of the second cut portions thereof on the side of the inner linerboard, and also such that the peripheral edge portions of the first cut portions on the side of the outer linerboard have a protruding shape, and the peripheral edge portions of the second cut portions on the side of the inner linerboard have a recessed shape.
It is preferable that if the perforation forming knife comprises a disk-shaped knife formed on an outer periphery of the disk-shaped knife with a plurality of cutting portions protruding radially outwardly, and spaced apart from each other at regular intervals, each of the cutting portions comprises a radially outer cutting edge, a front cutting edge in a rotation direction of the perforation forming knife, and a rear cutting edge in the rotation direction thereof.
With this arrangement, it is possible to prevent the occurrence of cracks in the outer linerboard or in the inner linerboard due to the resistance generated when the cutting portions cut the corrugated paperboard sheet. As a result thereof, it is possible to effectively prevent the breakage of the perforated line.
A perforation forming device for perforating a corrugated paperboard sheet suitable for manufacturing the above corrugated paperboard box comprises: an outer linerboard; an inner linerboard; and a corrugated medium provided between the outer linerboard and the inner linerboard. The perforation forming device comprising: a reverse scoreline forming device including a pair of reverse scoreline rings configured to sandwich the corrugated paperboard sheet from a side of the outer linerboard and a side of the inner linerboard, respectively so as to form in the corrugated paperboard sheet a groove-shaped reverse scoreline recessed on the side of the outer linerboard; and a perforation forming knife arranged on a downstream side of the reverse scoreline rings, and configured to form a perforated line in the reverse scoreline. The perforated line comprises a plurality of cuts extending to penetrate through the inner linerboard, the corrugated medium, and the outer linerboard, and the perforation forming knife is configured to cut the corrugated paperboard sheet from the side of the inner linerboard toward the side of the outer linerboard.
If such a perforation forming device is used, since after the reverse scoreline rings form the reverse scoreline by sandwiching the corrugated paperboard sheet from the side of the outer linear board and the side of the inner linerboard, the perforation forming knife, arranged on the downstream side of the reverse scoreline rings, forms the perforated line, it is possible to prevent the breakage of the perforated line due to the pressing force of the reverse scoreline rings. Namely, if the perforated line is formed before the reverse scoreline is formed, the perforated line might break due to the pressing force of the reverse scoreline rings. In contrast thereto, if the perforated line is formed after the reverse scoreline is formed, it is possible to prevent the breakage of the perforated line due to the pressing force of the reverse scoreline rings. Since the perforation forming knife forms the perforated line by cutting the corrugated paperboard sheet from the side of the inner linerboard toward the side of the outer linerboard, it is possible to form the perforated line such that the widths of the first cut portions of the perforated line on the side of the outer linerboard are smaller than those of the second cut portions thereof on the side of the inner linerboard, and also such that the peripheral edge portions of the first cut portions on the side of the outer linerboard have a protruding shape, and the peripheral edge portions of the second cut portions on the side of the inner linerboard have a recessed shape.
It is preferable that if the perforation forming knife comprises a disk-shaped knife formed on an outer periphery of the disk-shaped knife with a plurality of cutting portions protruding radially outwardly, and spaced apart from each other at regular intervals, each of the cutting portions comprises a radially outer cutting edge, a front cutting edge in a rotation direction of the perforation forming knife, and a rear cutting edge in the rotation direction thereof.
With this arrangement, it is possible to prevent the occurrence of cracks in the outer linerboard or in the inner linerboard due to the resistance generated when the cutting portions cut the corrugated paperboard sheet. As a result thereof, it is possible to effectively prevent the breakage of the perforated line.
In order to achieve the above object, the present invention provides a corrugated paperboard box made of corrugated paperboard comprising an outer linerboard, an inner linerboard, a corrugated medium provided between the outer linerboard and the inner linerboard. The corrugated paperboard box comprises a peripheral wall formed by bending the corrugated paperboard into a tubular shape such that the inner linerboard constitutes an inner surface of the corrugated paperboard box; and flaps integrally connected to one of two ends of the peripheral wall. The corrugated paperboard box is formed, between the peripheral wall and the flaps, with a groove-shaped normal scoreline recessed on a side of the inner linerboard so that the flaps can be bent along the normal scoreline toward an inner surface of the peripheral wall. The corrugated paperboard box is further formed with a perforated line which is located within the normal scoreline, and along which the flaps can be separated from the peripheral wall, and the corrugated paperboard box is further formed, at a position spaced apart from the normal scoreline toward the flaps, with a groove-shaped reverse scoreline extending in parallel to the normal scoreline, and recessed on a side of the outer linerboard so that the flaps can be bent along the reverse scoreline toward an outer surface of the peripheral wall.
With this arrangement, since the normal scoreline and the perforated line are formed between the peripheral wall and the flaps such that the perforated line is located within the normal scoreline, it is possible to smoothly separate the flaps along the normal scoreline and the perforated line from the peripheral wall. Since the reverse scoreline, formed at a position spaced apart from the normal scoreline toward the flaps, is a groove-shaped scoreline recessed on the side of the outer linerboard, when the flaps are bent toward the outer surface of the peripheral wall (i.e., bent in the reverse direction), the flaps are not bent along the normal scoreline, in which the perforated line is formed, but bent along the reverse scoreline, in which no perforated line is formed. Therefore, when products are packed in the box, it is possible to prevent the box from breaking along the perforated line between the peripheral wall and the flaps.
It is preferable that a depth of the reverse scoreline is equal to or larger than a depth of the normal scoreline.
With this arrangement, when the flaps are bent toward the outer surface of the peripheral wall, the flaps are not bent along the normal scoreline, and can be more reliably bent along the reverse scoreline.
It is preferable that the reverse scoreline is arranged such that a distance between a center of the normal scoreline and a center of the reverse scoreline is set within 5 mm to 20 mm.
With this arrangement, since the distance between the center of the normal scoreline and the center of the reverse scoreline is set to be 5 mm or over, when the flaps are bent toward the outer surface of the peripheral wall, the flaps are not bent simultaneously along both the normal scoreline and the reverse scoreline. Since the distance therebetween is set to be 20 mm or less, it is possible to effectively prevent the flaps from being bent not along the reverse scoreline but along the normal scoreline when the flaps are bent toward the outer surface of the peripheral wall.
As a perforation forming method for perforating a corrugated paperboard sheet suitable for manufacturing the above corrugated paperboard box, the present invention provides a perforation forming method for perforating a corrugated paperboard sheet comprising an outer linerboard, an inner linerboard, a corrugated medium provided between the outer linerboard and the inner linerboard, the perforation forming method comprising: a scoreline forming step of forming in the corrugated paperboard sheet a groove-shaped normal scoreline recessed on a side of the inner linerboard, and a groove-shaped reverse scoreline recessed on a side of the outer linerboard such that the normal scoreline and the reverse scoreline extend in parallel to each other while spaced apart from each other; and a perforation forming step of forming a perforated line in the normal scoreline such that the perforated line extends in a same direction as the normal scoreline, while located within the normal scoreline. After the normal scoreline is formed in the scoreline forming step, the perforated line is formed in the perforation forming step.
If such a perforation forming device is used, since after the normal scoreline is formed, the perforated line is formed in the normal scoreline, it is possible to prevent the inner linerboard from breaking along the perforated line due to the pressing force applied when the normal scoreline is formed. Namely, if the perforated line were first formed, and then the normal scoreline were formed on the perforated line, the inner linerboard might break along the perforated line due to the pressing force applied when the normal scoreline is formed. In contrast thereto, by forming the normal scoreline first, and then forming the perforated line in the normal scoreline, since the corrugated paperboard is collapsed at the normal scoreline before the perforated line is formed, it is possible form the normal scoreline and the perforated line such that the inner linerboard does not break and such that the perforated line is located within the normal scoreline.
It is preferable that after the reverse scoreline is formed in the scoreline forming step, the perforated line is formed in the perforation forming step.
In this way, if the reverse scoreline is first formed in the scoreline forming step, and then the perforated line is formed in the perforation forming step, it is possible to prevent the outer linerboard from breaking along the perforated line due to the tension applied to the outer linerboard when the reverse scoreline is formed. Namely, if the perforated line were first formed, and then the reverse scoreline were formed, the outer linerboard might break along the perforated line due to the tension applied to the outer linerboard when the reverse scoreline is formed. In contrast thereto, if the reverse scoreline is first formed, and then the perforated line is formed, it is possible to form the reverse scoreline and the perforated line such that the outer linerboard does not break.
As a perforation forming unit suitable for manufacturing a corrugated paperboard sheet from which the above corrugated paperboard box is formed, the present invention provides a perforation forming unit for perforating a corrugated paperboard sheet comprising an outer linerboard, an inner linerboard, and a corrugated medium provided between the outer linerboard and the inner linerboard, the perforation forming unit comprising: a scoreline forming device including normal scoreline rings configured to form in the corrugated paperboard sheet a groove-shaped normal scoreline recessed on a side of the inner linerboard, and reverse scoreline rings configured to form in the corrugated paperboard sheet a groove-shaped reverse scoreline recessed on a side of the outer linerboard so as to extend in parallel to, while spaced apart from, the normal scoreline; and a perforation forming device configured to form a perforated line located within, and extending in a same direction as, the normal scoreline, wherein the perforation forming device includes a disk-shaped, perforation forming knife arranged on a downstream side of the normal scoreline rings so that after the normal scoreline is formed, the perforated line is formed.
Since this perforation forming unit is configured such that the normal scoreline rings first form the normal scoreline, and then the perforation forming knife, arranged on the downstream side of the normal scoreline rings, forms the perforated line, it is possible to prevent the inner linerboard from breaking along the perforated line due to the pressing force applied when the normal scoreline is formed. Namely, if the perforation forming knife were arranged on the upstream side of the normal scoreline rings, the perforation forming knife would first form the perforated line, and then the normal scoreline rings would form the normal scoreline on the perforated line, so that the inner linerboard might break along the perforated line due to the pressing force applied when the normal scoreline is formed. In contrast thereto, if the perforation forming knife is arranged on the downstream side of the normal scoreline rings, it is possible to form the normal scoreline and the perforated line such that the inner linerboard does not break.
It is preferable that the perforation forming knife is arranged on a downstream side of the reverse scoreline rings so that after the reverse scoreline is formed, the perforated line is formed.
With this arrangement, since the reverse scoreline rings first form the reverse scoreline, and then the perforation forming knife, arranged on the downstream side of the reverse scoreline rings, forms the perforated line, it is possible to prevent the outer linerboard from breaking along the perforated line due to the tension applied to the outer linerboard when the reverse scoreline is formed. Namely, if the perforation forming knife were arranged on the upstream side of the reverse scoreline rings, the perforation forming knife would first form the perforated line, and then the reverse scoreline rings would form the reverse scoreline, so that the outer linerboard might break along the perforated line due to the tension applied to the outer linerboard when the reverse scoreline is formed. In contrast thereto, if the perforation forming knife is arranged on the downstream side of the reverse scoreline rings, it is possible to form the reverse scoreline and the perforated line such that the outer linerboard does not break.
The above perforation forming unit may be provided at a midway portion of a corrugator configured to manufacture a corrugated paperboard sheet, or may be provided as a part of a cutting machine configured to cut sheets cut off from the corrugated paperboard sheet by the corrugator.
The perforation forming unit provided at a midway portion of a corrugator configured to manufacture a corrugated paperboard sheet may be configured such that the scoreline forming device is a scorer which is a portion of a corrugator, wherein the corrugated paperboard sheet is a continuously extending strip-shaped member, wherein the scorer is configured to form the normal scoreline in the corrugated paperboard sheet, wherein the scorer includes the normal scoreline rings and the reverse scoreline rings, and wherein the perforation forming device is mounted to the scorer.
The perforation forming unit provided as a part of a cutting machine configured to cut sheets cut off from the corrugated paperboard sheet by the corrugator may be configured such that the scoreline forming device is a cutting machine configured to cut a cut sheet cut off from the corrugated paperboard sheet to a predetermined width size, wherein the cutting machine includes the normal scoreline rings and the reverse scoreline rings, and wherein the perforation forming device is mounted to the cutting machine.
The corrugated paperboard box according to the present invention is configured such that when the flaps are bent, the perforated line, along which the flaps can be separated from the box, is less likely to break.
As illustrated in
At the boundary area between the top flaps 11, 12, 13 and 14 and the side panels 5, 6, 7 and 8, the blank of the box 401 is formed with a groove-shaped reverse scoreline 16 recessed on the side of the outer linerboard 1 so that the top flaps 11, 12, 13 and 14 can be bent along the reverse scoreline 16 toward the outer linerboard 1 (i.e. toward the outer surface of the peripheral wall 41 illustrated in
The reverse scoreline 16 is formed at a position displaced from the proximal ends (roots) of the top flaps 11, 12, 13 and 14 (i.e., displaced from the straight line connecting the terminal ends of the slits 15) toward the distal ends of the top flaps 11, 12, 13 and 14.
The perforated line 17 coincides in position with the roots of the top flaps 11, 12, 13 and 14. As used herein, the word “coincides” does not require that the perforated line 17 completely and strictly coincide in position with the roots of the top flaps 11, 12, 13 and 14 in the mathematical sense, but should be understood to permit a manufacturing error of, for example, about 1 mm.
The side panels 6 and 8 are each formed with an opening assisting cut line 18 having a central portion located at a lower level than the perforated line 17, and connected at both ends thereof to the perforated line 17.
The blank of the box 401 further includes bottom flaps 21, 22, 23 and 24 integrally connected to the respective lower edges of the side panels 5, 6, 7 and 8. The bottom flaps 21, 22, 23 and 24 are separated from each other by slits 25 formed between the respective adjacent pairs of bottom flaps 21, 22, 23 and 24 to extend in the direction parallel to the corrugations of the corrugated paperboard.
As illustrated in
The second groove-shaped recess 19b, which is more remote from the distal ends of the top flaps 11, 12, 13 and 14 than is the first groove-shaped recess 19a, is formed and arranged such that the terminal ends of the slits 15 exist within the second groove-shaped recess 19b. Namely, the groove-shaped recess 19b is arranged to coincide in position with the roots of the top flaps 11, 12, 13 and 14, illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
For example, the blank illustrated in
As illustrated in
In this state, products 43 (see
Therefore, in order to enable products 43 to be easily placed into the corrugated paperboard box 401, the top flaps 11, 12, 13 and 14 are bent toward the outer surface of the peripheral wall 41 (i.e., bent outwardly) as illustrated in
Since the groove-shaped recesses 19a and 19b are recessed on the side of the inner linerboard 2 as illustrated in
Therefore, when the top flaps 11, 12, 13 and 14 are bent toward the outer surface of the peripheral wall 41 (i.e. toward the outer linerboard 1) as illustrated in
Though, in
Thereafter, the top flaps 11, 12, 13 and 14 are bent toward the inner surface of the peripheral wall 41 (i.e., bent inwardly) as illustrated in
For example, the corrugated paperboard box 401 constructed in this way can be opened as described below.
A user severs the box along the opening assisting cut lines 18 of the respective side panels 6 and 8 illustrated in
As described above, since this corrugated paperboard box 401 is formed with a groove-shaped reverse scoreline 16 located at the boundary area between the peripheral wall 41 and the top flaps 11, 12, 13 and 14, and recessed on the side of the outer linerboard 1, it is possible to smoothly bend the top flaps 11, 12, 13 and 14 toward the outer surface of the peripheral wall 41, and thus to easily pack products 43 in the box 401.
This corrugated paperboard box 401 also allows the top flaps 11, 12, 13 and 14 to be easily separated along the perforated line 17, formed in the groove-shaped recess 19b.
In this corrugated paperboard box 401, as described below, the pair of groove-shaped recesses 19a and 19b at the boundary area between the peripheral wall 41 and the top flaps 11, 12, 13 and 14 are formed on the side of the inner linerboard 2 at the same time as the corrugated paperboard sheet is sandwiched from the side of the outer linerboard 1 and the side of the inner linerboard 2 to form the reverse scoreline 16 which is recessed on the side of the outer linerboard 1, and at the boundary area between the peripheral wall 41 and the top flaps 11, 12, 13 and 14, there is no normal scoreline (corresponding to the normal scoreline 203 in
A corrugator is now described which is suitable for manufacturing a corrugated paperboard sheet from which the corrugated paperboard box 41 is formed. The corrugator includes, from the upstream side toward the downstream side, a single facer (not shown), a double facer (not shown), a slitter scorer 50 (see
As illustrated in
The upper normal scoreline ring 58 is formed on its outer periphery with a protrusion 60 continuously extending circumferentially over the entire circumference of the ring 58, and a pair of recesses 61 arranged on the respective axial sides of the protrusion 60. The lower normal scoreline ring 59 is formed on its outer periphery with a groove 62 opposed to the protrusion 60 of the upper ring 58, and a pair of groove shoulders 63 arranged on the respective axial sides of the groove 62. The upper normal scoreline ring 58 and the lower normal scoreline ring 59 sandwich the corrugated paperboard sheet 55 between the protrusion 60 of the upper ring 58 and the groove 62 of the lower ring 59, thereby forming in the corrugated paperboard sheet 55 the groove-shaped normal scoreline 26 (see
As illustrated in
As illustrated in
As illustrated in
The slitter 54 includes a rotary shaft 75 arranged over the corrugated paperboard sheet 55, a rotary shaft 76 arranged under the corrugated paperboard sheet 55, a knife receiver 77 fixed to the upper rotary shaft 75, and a slitter knife 78 fixed to the lower rotary shaft 76. The slitter knife 78 is a rotary blade formed on its outer periphery with a cutting edge continuous circumferentially over the entire circumference of the slitter knife 78, and configured to slit the corrugated paperboard sheet 55 from the lower side of the sheet 55 (i.e., from the side of the outer linerboard 1), and cut the corrugated paperboard sheet 55 along the conveying direction (direction perpendicular to the corrugations of the sheet 55).
The slitter scorer 50 includes a frame 79 supporting the upper rotary shafts 56 and 75 and the lower rotary shafts 57 and 76, a base member 80 fixed to the floor F, and linear guides 81 provided between the frame 79 and the base member 80. The linear guides 81 support the frame 79 such that the frame 79 is movable in the horizontal direction orthogonal to the direction in which the corrugated paperboard sheet 55 is conveyed. The slitter scorer 50 further includes a frame moving device 82 mounted to the frame 79, and configured such that if, while passing through the slitter scorer 50, the corrugated paperboard sheet 55 is displaced in the direction orthogonal to the direction in which the corrugated paperboard sheet 55 is conveyed, the frame 79 is moved by the frame moving device 82 to follow the displacement of the corrugated paperboard sheet 55
The reverse scoreline forming device 64 includes an auxiliary frame 83 supporting the upper rotary shaft 65 and the lower rotary shaft 66, a base member 84 fixed to the floor F, and linear guides 85 provided between the auxiliary frame 83 and the base member 84. The linear guides 85 support the auxiliary frame 83 such that the auxiliary frame 83 is movable in the horizontal direction orthogonal to the direction in which the corrugated paperboard sheet 55 is conveyed. The reverse scoreline forming device 64 further includes a coupling bracket 86 which is mounted to the auxiliary frame 83, and through which the auxiliary frame 83 and the frame 79 of the slitter scorer 50 are coupled together. Since the auxiliary frame 83 and the frame 79 are coupled together through the coupling bracket 86, when the frame moving device 82 moves the frame 79 of the slitter scorer 50, the auxiliary frame 83 is also moved together with the frame 79.
The perforation forming device 51 is arranged on the downstream side of the scorer 53, and includes a rotary shaft 87 arranged over the corrugated paperboard sheet 55, a rotary shaft 88 arranged under the corrugated paperboard sheet 55, a disk-shaped, perforation forming knife 89 fixed to the upper rotary shaft 87, and a knife receiver 90 fixed to the lower rotary shaft 88. The perforation forming knife 89 is a rotary blade configured to cut the corrugated paperboard sheet 55 from the upper side of the sheet 55 toward the lower side thereof (i.e., from the side of the inner linerboard 2 toward the side of the outer linerboard 1), thereby forming the perforated line 17 (see
As illustrated in
The perforation forming device 51 includes a frame 91 supporting the rotary shafts 87 and 88, a base member 92 fixed to the floor F, and linear guides 93 provided between the frame 91 and the base member 92. The linear guides 93 support the frame 91 such that the frame 91 is movable in the horizontal direction orthogonal to the direction in which the corrugated paperboard sheet 55 is conveyed. The perforation forming device 51 further includes a coupling bracket 94 which is mounted to the frame 91, and through which the frame 91 and the frame 79 of the slitter scorer 50 are coupled together. Since the frames 79 and 91 are coupled together through the coupling bracket 94, when the frame moving device 82 moves the frame 79 of the slitter scorer 50, the frame 91 of the perforation forming device 51 is also moved together with the frame 79.
The perforation forming device 51 further includes a driving device 95 configured to move up and down the perforation forming knife 89. The driving device 95 moves up the perforation forming knife 89 when no perforated line 17 needs to be formed in the corrugated paperboard sheet 55, and moves down the perforation forming knife 89 when the perforated line 17 needs to be formed in the corrugated paperboard sheet 55.
As illustrated in
As illustrated in
When this corrugator is used to manufacture the corrugated paperboard sheet 55, by sandwiching the corrugated paperboard sheet 55 from the side of the outer linear board 1 and the side of the inner linerboard 2, the first and second reverse scoreline rings 67 and 68 can simultaneously form the reverse scoreline 16 on the side of the outer linerboard 1, and the groove-shaped recesses 19a and 19b on the side of the inner linerboard 2. Since the reverse scoreline 16 and the groove-shaped recesses 19a and 19b are first formed by the reverse scoreline rings 67 and 68, and then the perforated line 17 is formed by the perforation forming knife 89, arranged on the downstream side of the reverse scoreline rings 67 and 68, it is possible to prevent the breakage of the perforated line 17 due to the pressing force of the reverse scoreline rings 67 and 68. Namely, if the perforated line 17 is formed before the reverse scoreline 16 is formed, the perforated line 17 might break due to the pressing force of the reverse scoreline rings 67 and 68. In contrast thereto, by forming the perforated line 17 after the reverse scoreline 16 is formed, it is possible to prevent the breakage of the perforated line 17 due to the pressing force of the reverse scoreline rings 67 and 68.
When this corrugator is used to manufacture the corrugated paperboard sheet 55, since the perforation forming knife 89 cuts the corrugated paperboard sheet 55 from the side of the inner linerboard 2 toward the side of the outer linerboard 1, as illustrated in
If the auxiliary frame 83 of the reverse scoreline forming device 64 is formed separately from the frame 79 of the slitter scorer 50 as illustrated in
While, in
While, in
The inventors of the present application experimentally prepared multiple of corrugated paperboard boxes 41 as illustrated in
In Tables 1 to 3, “perforation position” means the distance L between the center of the perforated line 17 and the center of the reverse scoreline 16 illustrated in
The symbols “⊚”, “◯” and “Δ” in Tables 1 to 3 are described below.
The symbol “⊚” means “extremely good”, namely means that the top flaps 11, 12, 13 and 14 were bent not along the perforated line 17 but along the reverse scoreline 16 when bent toward the outer surface of the peripheral wall 41; that the top flaps 11, 12, 13 and 14 were bent not along the reverse scoreline 16 but along the perforated line 17 when bent toward the inner surface of the peripheral wall 41; and that the perforated line 17 did not break when the top flaps 11, 12, 13 and 14 were bent toward the inner surface of the peripheral wall 41.
The symbol “◯” means “good”, namely means that the top flaps 11, 12, 13 and 14 were bent not along the perforated line 17 but along the reverse scoreline 16 when bent toward the outer surface of the peripheral wall 41; that the top flaps 11, 12, 13 and 14 were bent not along the reverse scoreline 16 but along the perforated line 17 when bent toward the inner surface of the peripheral wall 41; and that the perforated line 17 did not break when the top flaps 11, 12, 13 and 14 were bent once toward the inner surface of the peripheral wall 41, but slight cracks occurred in the perforated line 17 when the top flaps 11, 12, 13 and 14 were bent two or three times toward the inner surface of the peripheral wall 41.
The symbol “Δ” means “relatively good”, namely means that the top flaps 11, 12, 13 and 14 were bent not along the perforated line 17 but along the reverse scoreline 16 when bent toward the outer surface of the peripheral wall 41; that when bent toward the inner surface of the peripheral wall 41, the top flaps 11, 12, 13 and 14 were bent not along the reverse scoreline 16 but along the perforated line 17, but were bent at two portions, i.e., along both the perforated line 17 and the groove-shaped recess 19a, in which no perforated line 17 is formed; and that the perforated line 17 did not break when the top flaps 11, 12, 13 and 14 were bent toward the inner surface of the peripheral wall 41.
The above experimental results show that when the distance L between the center of the perforated line 17 and the center of the reverse scoreline 16 was set within the range of 4.5 to 8.0 mm (preferably 5.0 to 7.0 mm) in the corrugated paperboard box 401, the top flaps 11, 12, 13 and 14 were bent not along the perforated line 17 but along the reverse scoreline 16 when bent toward the outer surface of the peripheral wall 41; the top flaps 11, 12, 13 and 14 were bent not along the reverse scoreline 16 but along the perforated line 17 when bent toward the inner surface of the peripheral wall 41; and the perforated line 17 was less likely to break when the top flaps 11, 12, 13 and 14 were bent toward the inner surface of the peripheral wall 41.
While the perforation forming device 51 of the corrugator shown in
The perforation forming device 51 shown in
The perforation forming device 51 of
It is now described how this perforation forming device 51 is used. First, when a cut corrugated paperboard sheet 55 supported by the sheet feed table 48 is fed to the downstream side, and sandwiched between the upper reverse scoreline ring 67 and the lower reverse scoreline ring 68, the reverse scoreline rings 67 and 68 form the reverse scoreline 16 recessed on the lower side of the cut sheet 55 (i.e., on the side of the outer linerboard 1) by sandwiching the cut sheet 55 between the groove 72 of the upper reverse scoreline ring 67 and the protrusion 70 of the lower reverse scoreline ring 68, and simultaneously form the pair of groove-shaped recesses 19a and 19b recessed on the upper side of the cut sheet 55 by sandwiching the cut sheet 55 between the groove shoulders 73 of the upper reverse scoreline ring 67 and the recesses 71 of the lower reverse scoreline ring 68. Thereafter, the perforation forming knife 89 forms the perforated line 17 in the groove-shaped recess 19b.
While, in
While
While
As illustrated in
As illustrated in
As illustrated in
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As illustrated in
As illustrated in
For example, the blank of
As illustrated in
In this state, products 43 are packed in the corrugated paperboard box 402. At this time, in order to enable the products 43 to be easily placed into the corrugated paperboard box 402, the top flaps 11, 12, 13 and 14 are bent toward the outer surface of the peripheral wall 41 (i.e., bent outwardly) as illustrated in
Thereafter, the top flaps 11, 12, 13 and 14 are bent toward the inner surface of the peripheral wall 41 (i.e., bent inwardly) as illustrated in
For example, the corrugated paperboard box 402 constructed in this way can be opened as described below.
A user severs the box along the opening assisting cut lines 18 of the respective side panels 6 and 8 illustrated in
This corrugated paperboard box 402 is configured such that, as described later, when the reverse scoreline 16 is formed, a large load is applied to the outer linerboard 1, whereas when the perforated line 17 is formed, a large load is applied to the inner linerboard 2 on the opposite side of the outer linerboard 1, namely loads do not concentrate on one of the outer and inner linerboards 1 and 2 when the reverse scoreline 16 and the perforated line 17 are formed. Therefore, the perforated line 17 is relatively less likely to break. This can prevent the perforated line 17 from breaking both when the top flaps 11, 12, 13 and 14 are bent along the perforated line 17 toward the outer surface of the peripheral wall 41 (i.e., toward the inner linerboard 1), and when the top flaps are bent along the perforated line 17 toward the inner surface of the peripheral wall 41 (i.e., toward the outer linerboard 2).
Since the perforated line 17 of this corrugated paperboard box 402 is formed such that as illustrated in
It is possible to suitably manufacture the corrugated paperboard box 402 of the second embodiment by use of a corrugator similar to the one described in the first embodiment. As for the elements of this corrugator corresponding to those of the corrugator described in the first embodiment, the same reference numerals as used in the first embodiment are used below, and their description is omitted.
As illustrated in
As illustrated in
The perforation forming knife 89 is arranged so as to correspond to the position of the protrusion 70 such that the perforated line 17 is formed within the reverse scoreline 16, which has been formed by sandwiching the corrugated paperboard sheet 55 between the groove 72 of the upper reverse scoreline ring 67 and the protrusion 70 of the lower reverse scoreline ring 68. The perforation forming knife 89 is aligned in the conveying direction with the area E of the protrusion 70 (area of the lower ring 68 protruding from the outer peripheral cylindrical surfaces of the recesses 71 illustrated in
When this corrugator is used to manufacture a corrugated paperboard sheet 55, since the perforation forming knife 89 cuts the corrugated paperboard sheet 55 from the side of the inner linerboard 2 toward the side of the outer linerboard 1, as illustrated in
Since the reverse scoreline 16 and the perforated line 17 are formed in this way, when the reverse scoreline 16 is formed, a large load is applied to the outer linerboard 1, whereas when the perforated line 17 is formed, a large load is applied to the inner linerboard 2 on the opposite side of the outer linerboard 1. Thus, the perforated line 17 is relatively less likely to break. Namely, if, as illustrated in
The blank of the box 403 is formed between the side panels 5, 6, 7 and 8 and the top flaps 11, 12, 13 and 14 with a normal scoreline 29 along which the top flaps 11, 12, 13 and 14 can be bent inwardly, and which extends in the direction perpendicular to the corrugations of the corrugated paperboard. The blank of the box 403 is further formed between the side panels 5, 6, 7 and 8 and the 11, 12, 13 and 14 with a perforated line 17 which is located within the normal scoreline 29, and along which the top flaps 11, 12, 13 and 14 can be separated from the box.
The blank of the box 403 is further formed at the proximal end portions (roots) of the top flaps 11, 12, 13 and 14 (i.e., at the end portions thereof close to the normal scoreline 29) with a reverse scoreline 16 along which the top flaps 11, 12, 13 and 14 can be bent outwardly. The reverse scoreline 16 extends in parallel to the normal scoreline 29, and thus, in the direction perpendicular to the corrugations of the corrugated paperboard, while spaced apart from the normal scoreline 29 toward the top flaps 11, 12, 13 and 14.
The side panels 6 and 8 are each formed with an opening assisting cut line 18 having a central portion located at a lower level than the perforated line 17, and connected at both ends thereof to the perforated line 17. In the drawings, the central portion of the cut line 18 is constituted by a single continuous cut, and both end portions thereof are each constituted by a perforated line comprising disconnected perforations. The side panels 6 and 8 are each formed with a hand hole 34 located outside of the area of the side panel 6, 8 surrounded by the perforated line 17 and the cut line 18.
As illustrated in
As illustrated in
As illustrated in
As illustrated in
The distance between each adjacent pair of cut portions 31a on the side of the outer linerboard 1 (i.e., the length of the joint portion therebetween) is set within 2 mm to 4 mm (preferably 2.5 mm to 3.5 mm). By setting this distance to be 2 mm or over (preferably 2.5 mm or over), it is possible to prevent the breakage of the outer linerboard 1 along the perforated line 17 due to the tension applied to the outer linerboard 1 when the top flaps 11, 12, 13 and 14 (see
As illustrated in
For example, the blank illustrated in
As illustrated in
Products 43 are then packed in the thus formed corrugated paperboard box 403. At this time, in order to enable the products 43 to be easily placed into the box 403, the top flaps 11, 12, 13 and 14 are bent toward the outer surface of the peripheral wall 41 (i.e., bent in the reverse direction) as illustrated in
Therefore, when the top flaps 11, 12, 13 and 14 are bent toward the outer surface of the peripheral wall 41 as illustrated in
Thereafter, as illustrated in
As illustrated in
For example, the corrugated paperboard box 403 formed in this way can be opened as described below.
A user severs the box along the opening assisting cut lines 18 of the respective side panels 6 and 8 illustrated in
Since this corrugated paperboard box 403 is configured such that when the top flaps 11, 12, 13 and 14 are bent toward the outer surface of the peripheral wall 41, the top flaps are bent not along the normal scoreline 29, in which the perforated line 17 is formed, but along the reverse scoreline 16, in which no perforated line 17 is formed, when products 43 are packed in the box 403, it is possible to prevent the breakage of the boundary area between the peripheral wall 41 and the top flaps 11, 12, 13 and 14 along the perforated line 17.
Since the depth A2 of the reverse scoreline 16 (see
Since the distance B (see
Since the perforated line 17 is formed in this corrugated paperboard box 403 such that the lengths of the joint portions between the adjacent pairs of cut portions 31a on the side of the outer linerboard 1 are larger than those of the joint portions between the adjacent pairs of cut portions 31b on the side of the inner linerboard 2, when the top flaps 11, 12, 13 and 14 are bent toward the inner surface of the peripheral wall 41 to form the box, the outer linerboard 1 is less likely to break.
In order to confirm that by setting the depth A2 of the reverse scoreline 16 (see
The symbols “◯”, “Δ” and “X” in Table 4 are described below.
The symbol “◯” means that the top flaps of all of the five samples were bent only along the reverse scoreline.
The symbol “Δ” means that the top flaps of three or four of the five samples were bent only along the reverse scoreline, but the top flaps of the remaining sample or samples were bent only along the normal scoreline or bent both along the reverse scoreline and along the normal scoreline.
The symbol “X” means that the top flaps of none, one or two of the five samples were bent only along the reverse scoreline, but the top flaps of the remaining samples were bent only along the normal scoreline or bent both along the reverse scoreline and along the normal scoreline.
The above experimental results show that by setting the depth A2 of the reverse scoreline 16 to be equal to, or preferably larger than, the depth A1 of the normal scoreline 29, it is possible to prevent the top flap 11 from being bent along the normal scoreline 29 when bent toward the outer surface of the peripheral wall 41.
Also, in order to confirm that by setting the distance B between the center of the normal scoreline 29 and the center of the reverse scoreline 16 to be within 5 mm to 20 mm, the reverse scoreline 16 performs its expected function more effectively when the top flap 11 is bent toward the outer surface of the peripheral wall 41, the inventors of the present application prepared, for each of the materials shown in the below Table 5 and for each of the different values of the distance B shown in Table 5, five corrugated paperboard box samples, and performed experiments to examine along which of the normal scoreline 29 and the reverse scoreline 16 the top flap 11 of each sample is bent when bent toward the outer surface of the peripheral wall 41. The experimental results are shown in Table 5.
The symbols “◯”, “Δ” and “X” in Table 5 are described below.
The symbol “◯” means that the top flaps of all of the five samples were bent only along the reverse scoreline.
The symbol “Δ” means that the top flaps of three or four of the five samples were bent only along the reverse scoreline, but the top flaps of the remaining sample or samples were bent only along the normal scoreline or bent both along the reverse scoreline and along the normal scoreline.
The symbol “X” means that the top flaps of none, one or two of the five samples were bent only along the reverse scoreline, but the top flaps of the remaining samples were bent only along the normal scoreline or bent both along the reverse scoreline and along the normal scoreline.
The above experimental results show that by setting the distance B between the center of the normal scoreline 29 and the center of the reverse scoreline 16 within 5 mm to 20 mm (more preferably 5 mm to 10 mm), the reverse scoreline 16 performs its expected function more effectively when the top flap 11 is bent toward the outer surface of the peripheral wall 41.
It is possible to suitably manufacture the corrugated paperboard box 403 of the third embodiment by use of a corrugator similar to the one described in the first embodiment. As for the elements of this corrugator corresponding to those of the corrugator described in the first embodiment, the same reference numerals as used in the first embodiment are used below, and their description is omitted.
As illustrated in
The scorer 53 includes an upper first rotary shaft 105 and an upper second rotary shaft 106 which are arranged over a corrugated paperboard sheet 55, a lower first rotary shaft 107 and a lower second rotary shaft 108 which are arranged under the corrugated paperboard sheet 55, upper scoreline rings 109 fixed to the upper first rotary shaft 105, lower scoreline rings 110 fixed to the lower first rotary shaft 107, upper normal scoreline rings 111 fixed to the upper second rotary shaft 106, and lower normal scoreline rings 112 fixed to the lower second rotary shaft 108. The upper first rotary shaft 105 is vertically opposed to the lower first rotary shaft 107. The upper second rotary shaft 106 is vertically opposed to the lower second rotary shaft 108. The upper second rotary shaft 106 is arranged on the downstream side of, and adjacent to, the upper first rotary shaft 105. The lower second rotary shaft 108 is arranged on the downstream side of, and adjacent to, the lower first rotary shaft 107.
Each upper scoreline ring 109 is formed on its outer periphery with a protrusion 113 continuously extending circumferentially over the entire circumference of the ring 109. Each lower scoreline ring 110 is formed in its outer periphery with a recess 114 continuously extending circumferentially over the entire circumference of the ring 110. Each upper normal scoreline ring 111 is formed on its outer periphery with a protrusion 115 continuously extending circumferentially over the entire circumference of the ring 111. Each lower normal scoreline ring 112 is formed in its outer periphery with a recess 116 continuously extending circumferentially over the entire circumference of the ring 112.
The scorer 53 sandwiches the corrugated paperboard sheet 55 between the protrusions 113 of the upper scoreline rings 109 and the recesses 114 of the respective lower scoreline rings 110, thereby forming in the corrugated paperboard sheet 55 scorelines extending in the conveying direction (direction perpendicular to the corrugations of the corrugated paperboard sheet 55). Similarly, the scorer 53 sandwiches the corrugated paperboard sheet 55 between the protrusions 115 of the upper normal scoreline rings 111 and the recesses 116 of the respective lower normal scoreline rings 112, thereby forming in the corrugated paperboard sheet 55 normal scorelines 29 extending in the conveying direction (direction perpendicular to the corrugations of the corrugated paperboard sheet 55).
The scorer 53 further includes a reverse scoreline forming device 117. The reverse scoreline forming device 117 includes an upper rotary shaft 118 arranged over the corrugated paperboard sheet 55, a lower rotary shaft 119 arranged under the corrugated paperboard sheet 55, upper reverse scoreline rings 120 fixed to the upper rotary shaft 118, and lower reverse scoreline rings 121 fixed to the lower rotary shaft 119. The upper rotary shaft 118 is vertically opposed to the lower rotary shaft 119. Each upper reverse scoreline ring 120 is formed in its outer periphery with a recess 122 continuously extending circumferentially over the entire circumference of the ring 120. Each lower reverse scoreline ring 121 is formed on its outer periphery with a protrusion 123 continuously extending circumferentially over the entire circumference of the ring 121. The reverse scoreline forming device 117 sandwiches the corrugated paperboard sheet 55 between the recesses 122 of the upper reverse scoreline rings 120 and the protrusions 123 of the respective lower reverse scoreline rings 121, thereby forming in the corrugated paperboard sheet 55 reverse scorelines 16 extending in the conveying direction (direction perpendicular to the corrugations of the corrugated paperboard sheet 55).
The reverse scoreline forming device 117 further includes a driving device 124 configured to move up and down the upper reverse scoreline rings 120. The driving device 124 moves up the upper reverse scoreline rings 120 when no reverse scorelines 16 need to be formed in the corrugated paperboard sheet 55, and moves down the upper reverse scoreline rings 120 to form the reverse scorelines 16 in the corrugated paperboard sheet 55.
The slitter 54 includes a rotary shaft 125 arranged over the corrugated paperboard sheet 55, a rotary shaft 126 arranged under the corrugated paperboard sheet 55, knife receivers 127 fixed to the upper rotary shaft 125, and slitter knives 128 fixed to the lower rotary shaft 126. Each slitter knife 128 is a rotary blade formed on its outer periphery with a cutting edge continuous circumferentially over the entire circumference of the slitter knife 128, and configured to slit the corrugated paperboard sheet 55 from the lower side of the sheet 55 (i.e., from the side of the outer linerboard 1), and cut the corrugated paperboard sheet 55 along the conveying direction (direction perpendicular to the corrugations of the sheet 55).
The slitter scorer 50 includes a frame 79 supporting the upper rotary shafts 105 and 106 and the lower rotary shafts 107 and 108, a base member 80 fixed to the floor F, and linear guides 81 provided between the frame 79 and the base member 80.
The reverse scoreline forming device 117 includes an auxiliary frame 83 supporting the upper rotary shaft 118 and the lower rotary shaft 119, a base member 84 fixed to the floor F, and linear guides 85 provided between the auxiliary frame 83 and the base member 84.
The perforation forming device 51 of this corrugator includes perforation forming knives 89 arranged such that each perforation forming knife 89 and the corresponding normal scoreline rings 111 and 112 lie on a common straight line extending in the direction in which the corrugated paperboard sheet 55 is conveyed so that the perforated lines 17 are formed within the respective normal scorelines 29, which have been formed by the normal scoreline rings 111 and 112.
As illustrated in
When this corrugator is used to manufacture the corrugated paperboard sheet 55, since as illustrated in
When this corrugator is used to manufacture the corrugated paperboard sheet 55, since the reverse scorelines 16 are first formed by the reverse scoreline rings 120 and 121, and then the perforated lines 17 are formed by the perforation forming knives 89, arranged on the downstream side of the reverse scoreline rings 120 and 121, it is possible to prevent the outer linerboard 1 from breaking along the perforated lines 17 due to the tension applied to the outer linerboard 1 when the reverse scorelines 16 are formed. Namely, if the perforation forming knives 89 were arranged on the upstream side of the reverse scoreline rings 120 and 121, the perforated lines 17 would be first formed by the perforation forming knives 89, and then the reverse scorelines 16 would be formed by the reverse scoreline rings 120 and 121, so that the outer linerboard 1 might break along the perforated lines 17 due to the tension applied to the outer linerboard 1 when the reverse scorelines 16 are formed. In contrast thereto, by arranging the perforation forming knife 89 on the downstream side of the reverse scoreline rings 120 and 121 as in the above corrugator, it is possible to form the reverse scoreline 16 and the perforated line 17 without the possibility of the breakage of the outer linerboard 1.
While the reverse scoreline forming device 117 is arranged on the upstream side of the slitter scorer 50 in
While, in
As illustrated in
The perforation forming device 51 may not be arranged on the downstream side of the slitter scorer 50 as shown in
While, in
With this alternative arrangement too, it is possible prevent the breakage of the inner linerboard 2 due to the pressing force applied when the normal scorelines 29 are formed. Namely, if the perforated lines 17 were first formed, and then the normal scorelines 29 were formed on the perforated lines 17, the inner linerboard 2 might break due to the pressing force applied when the normal scorelines 29 are formed. In contrast thereto, by forming the normal scorelines 29 first, and then forming the perforated lines 17 in the normal scorelines 29, since the corrugated paperboard is collapsed at the normal scorelines 29 before the perforated lines 17 are formed, it is possible to prevent the breakage of the inner linerboard 2.
In
The perforation forming unit illustrated in
This perforation forming unit includes a sheet feed table 152 arranged on the upstream side of the upper and lower reverse scoreline rings 120 and 121, and supporting cut corrugated paperboard sheets 55, and a sheet discharge table 153 arranged on the downstream side of the perforation forming knives 89 and the knife receivers 90.
It is now described how this perforation forming unit is used. First, when a cut corrugated paperboard sheet 55 supported by the sheet feed table 152 is fed into the space between the upper reverse scoreline rings 120 and the lower reverse scoreline rings 121, the reverse scorelines 16 (
While, in
While, in
Number | Date | Country | Kind |
---|---|---|---|
2015-113283 | Jun 2015 | JP | national |
2015-234482 | Dec 2015 | JP | national |
2016-008010 | Jan 2016 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2016/064591 | 5/17/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2016/194602 | 12/8/2016 | WO | A |
Number | Name | Date | Kind |
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1288132 | Nagle | Dec 1918 | A |
1758230 | Lange | May 1930 | A |
2173927 | Allen | Sep 1939 | A |
3526566 | McIlvain, Jr. | Sep 1970 | A |
4623072 | Lorenz | Nov 1986 | A |
4905864 | Balin | Mar 1990 | A |
6189780 | Kanter | Feb 2001 | B1 |
9573722 | Capogrosso | Feb 2017 | B1 |
20020166887 | Matsuoka | Nov 2002 | A1 |
Number | Date | Country |
---|---|---|
54-7930 | Jan 1979 | JP |
58-104739 | Jun 1983 | JP |
60-123317 | Aug 1985 | JP |
3-11626 | Feb 1991 | JP |
4-113927 | Oct 1992 | JP |
3036775 | May 1997 | JP |
2003-26153 | Jan 2003 | JP |
2014-151582 | Aug 2014 | JP |
Entry |
---|
International Search Report dated Aug. 2, 2016 in corresponding International (PCT) Application No. PCT/JP2016/064591. |
Extended European Search Report dated Mar. 21, 2018 in European Application No. 16803037.7. |
International Preliminary Report on Patentability dated Dec. 5, 2017 in International (PCT) Application No. PCT/JP2016/064591. |
Number | Date | Country | |
---|---|---|---|
20170349323 A1 | Dec 2017 | US |