Patent Application
20120177860
The present invention relates to an adhesive tape roll for cleaning wound with its adhesive face directed to a front side, and more specifically, to a technique of forming cut lines for cutting for every single circumferential length.
It is difficult to completely remove hairs, dust, or the like twined around carpets, etc., by the suction of vacuum cleaners because fibers are intertwined with each other. In order to address this problem, adhesive tape rolls for cleaning are used as a method for removing foreign particles of this type.
As illustrated in, for example, Patent Document 1, an adhesive tape roll is obtained by winding an adhesive tape having an adhesive part on one face of a substrate made of a sheet body like a paper such that the adhesive part is exposed to a front side. The adhesive tape roll is structured to rotate the adhesive face on a floor as an object face to be cleaned using a dedicated jig not illustrated, thereby forcibly removing dust or the like.
When an adhesive tape roll of this type is used a few times, the adhesion of an adhesive part is reduced due to smudges attached to the adhesive part. Accordingly, after the adhesion is reduced, a smudged face is torn off along cut lines such as perforations and discarded, which restores the adhesion again to make the adhesive tape roll set in a reusable state.
Conventionally, perforations of this type are formed, for example, by the insertion of a press-cutting blade into an adhesive tape roll. However, the formation of the perforations using the press-cutting blade causes, when the press-cutting blade is extracted, a part of an adhesive tape to be lifted up so as to be caught in the side face of the blade. Therefore, a part of the perforations is more projected than other parts, which may cause the whole adhesive tape roll to be deformed into an onion shape.
In order to prevent this deformation, there have been proposed a method for forming cut lines by laser beam machining, a method for providing a rotary blade on a rail for conveying an adhesive tape and winding the adhesive tape while forming cut lines, and the like. However, such methods have the following problems.
That is, according to laser beam machining, a part of an adhesive tape is burned off by a laser beam. Therefore, a scorch or the like is caused to ruin the appearance of the adhesive tape. Further, a substrate must be subjected to flame-resistant processing because it is made of a paper.
Further, in a case where cut lines are formed by the rotary blade, the rotary blade is rotated at a constant cycle using a clutch or the like, which makes it possible to form the cut lines. However, it is necessary to consider the thickness of an adhesive tape, which is increased for every single circumferential length, to arrange all the cut lines at the same position. Because of this, the control of the adhesive tape becomes cumbersome correspondingly, and productivity is decreased due to the reduction of a conveyance speed or the like.
Accordingly, the present invention has been made to address the above problems and has an object of providing a technique of manufacturing an adhesive tape roll by which cut lines for cutting an adhesive tape can be regularly formed at a constant position.
In order to achieve the above object, the present invention has some features described below. The invention according to claim 1 provides a method for manufacturing an adhesive tape roll which is obtained by winding an adhesive tape having an adhesive face formed on one face of a substrate such that the adhesive face is directed to a front side and in which cut lines for cutting are continuously formed in the adhesive tape at a predetermined interval along a feed direction of the adhesive tape, wherein a winding roller that winds the adhesive tape fed out from a mother roll and a cut-lines formation roller that is provided between the mother roll and the winding roller and forms the cut lines in the adhesive tape at the predetermined interval are provided, and the winding roller and the cut-lines formation roller are rotated in synchronization with each other via predetermined gears.
The invention according to claim 2 provides the method according to claim 1, wherein a gear ratio of a gear on a side of the winding roller to a gear on a side of the cut-lines formation roller is one to one.
The invention according to claim 3 provides the method according to claim 1, wherein a gear ratio of a gear on a side of the winding roller to a gear on a side of the cut-lines formation roller is less than one to one.
The invention according to claim 4 provides the method according to claim 1, wherein a gear ratio of a gear on a side of the winding roller to a gear on a side of the cut-lines formation roller is greater than one to one.
The invention according to claim 5 provides the method according to any one of claims 1 to 4, wherein three types of gears having a gear ratio of one to one, less than one to one, and greater than one to one, respectively, are provided about one of the winding roller and the cut-lines formation roller and provided in such a manner as to be capable of selectively engaging with a gear of the other of the winding roller and the cut-lines formation roller.
The invention according to claim 6 provides the method according to any one of claims 1 to 5, wherein, when a single circumferential length of the adhesive tape of an n-th (where n is a positive integer) turn is L, a radius of the winding core is r, a thickness of the adhesive tape is t, a deviation between cut lines of an n-th layer and cut lines of an n+1-th layer is Δd, and an interval between the cut lines of the adhesive tape of the n-th turn and the cut lines of the n+1-th layer is expressed by an angular difference θ, following Equations 1 to 3 are satisfied:
L
n=2π{r×(n−1)×t} Equation (1);
L
n+1
=L×(360−θ)/360 Equation (2); and
L
n+1
=L
n
+Δd Equation (3).
The invention according to claim 7 provides the method according to claim 6, wherein the angular difference θ is in a rage of equal to or greater than 6° and equal to or less than 19°.
The present invention also provides an adhesive tape roll manufactured using the method for manufacturing the adhesive tape roll according to any one of claims 1 to 7.
With the invention according to claim 1, there is provided a method for manufacturing an adhesive tape roll which is obtained by winding an adhesive tape having an adhesive face formed on one face of a substrate such that the adhesive face is directed to a front side and in which cut lines for cutting are continuously formed in the adhesive tape at a predetermined interval along a feed direction of the adhesive tape, wherein a winding roller that winds the adhesive tape fed out from a mother roll and a cut-lines formation roller that is provided between the mother roll and the winding roller and forms the cut lines in the adhesive tape at the predetermined interval are provided, and the winding roller and the cut-lines formation roller are rotated in synchronization with each other via predetermined gears. In this manner, only with the synchronization of the rotations of a winding roller and a cut-lines formation roller via gears, cut lines can be regularly formed at a constant position.
With the invention according to claim 2, a gear ratio of a gear on a side of the winding roller to a gear on a side of the cut-lines formation roller is one to one. In this manner, cut lines can be regularly formed at the same position in an overlapped state. Therefore, the deformation of an adhesive tape roll into an onion shape can be reliably prevented.
With the invention according to claim 3, a gear ratio of a gear on a side of the winding roller to a gear on a side of the cut-lines formation roller is less than one to one. In this manner, an interval between cut lines is set at a position greater than 360° on the basis of a circumferential length. Therefore, when a used adhesive face and a part of an adhesive tape including a boundary part are removed, an unused adhesive tape roll can be exposed over its whole circumference.
With the invention according to claim 4, a gear ratio of a gear on a side of the winding roller to a gear on a side of the cut-lines formation roller is less than one to one. In this manner, an interval between cut lines is set at a position less than 360° on the basis of a circumferential length, and a previous used adhesive face remains at the tip end part of an unused adhesive tape face. Therefore, because adhesion at the tip end part of the unused adhesive tape face is reduced, a rail drawing phenomenon can be prevented.
With the invention according to claim 5, three types of gears having a gear ratio of one to one, less than one to one, and greater than one to one, respectively, are provided about one of the winding roller and the cut-lines formation roller and provided in such a manner as to be capable of selectively engaging with a gear of the other of the winding roller and the cut-lines formation roller. In this manner, three types of cut lines can be easily manufactured with a single apparatus.
With the invention according to claim 6, when a single circumferential length of the adhesive tape of an n-th (where n is a positive integer) turn is Ln, a radius of the winding core is r, a thickness of the adhesive tape is t, a deviation between cut lines of an n-th layer and cut lines of an n+1-th layer is Δd, and an interval between the cut lines of the adhesive tape of the n-th turn and the cut lines of the n+1-th layer is expressed by an angular difference θ, following Equations 1 to 3 are satisfied:
LL
n=2π{r×(n−1)×t} Equation (1);
L
n+1
=L×(360−θ)/360 Equation (2); and
L
n+1
=L
n
+Δd Equation (3).
In this manner, cut lines can be arbitrarily formed at a predetermined interval on the condition that the angular difference θ or the deviation Δd is made constant.
With the invention according to claim 7, the angular difference θ is in a rage of equal to or greater than 6° and equal to or less than 19°. When the angular difference θ is less than 6°, the deviation Δd becomes equal to or less than 2 mm. Therefore, the reduction of adhesion cannot be prevented, which may cause a rail drawing phenomenon to occur. On the other hand, when the angular difference θ is greater than 19°, the deviation Δd becomes greater than 10 mm. Therefore, an unused adhesive tape must be wastefully torn off, which is economically disadvantageous.
Next, an embodiment of the present invention will be described with reference to the drawings, but the present invention is not limited to the embodiment. As illustrated in
In this example, a paper winding core such as a cardboard is used as the winding core 3, but a synthetic-resin winding core may be used instead. Further, the adhesive tape roll 1 may have, i.e., a coreless structure in which the adhesive tape roll 1 is wound without using the winding core 3. Thus, according to the present invention, the winding core 3 is arbitrarily configured.
The tape substrate 21 is made of, for example, a paper and has a laminate film not illustrated on its rear face to reinforce the tape substrate 21 and separate from the next layer. According to the present invention, the presence or absence of the laminate film, the material of the laminate film, and the like are arbitrary matters. For example, the use of a resin film as the tape substrate 21 eliminates the need for the laminate film.
The adhesive face 22 is uniformly coated with an adhesive formed by predetermined adhesive coating and has non-adhesive parts 23 and 23 with no adhesive property at its both ends. According to the present invention, the type and form of the adhesive on the adhesive face, the coating method and coating conditions thereof, and the like may be arbitrarily set.
In this example, the adhesive face 22 is made of so-called a solid adhesive layer that extends along the feed direction of the adhesive tape 2 but may be formed to have a complicated shape such as a streaky shape and a dot shape. Further, for example, two or more adhesives may be used in combination to laminate a stripe-shaped adhesive layer on a solid adhesive layer. The configuration of the adhesive face 22 can be arbitrarily changed according to specifications.
In the adhesive tape 2, cut lines 4 for cutting the adhesive tape 2 are formed at a predetermined interval. The cut lines 4 are so-called perforations where cutting parts and non-cutting parts are alternately continuously formed, and are formed in a straight line along the width direction of the adhesive tape 2 in this example.
In this example, the cut lines 4 are the perforations where the cutting parts and the non-cutting parts are alternately continuously formed, but micro-cuts or the like may be used instead. That is, the mode of the cut lines 4 is arbitrarily set so long as they are weaker than other parts of the adhesive tape 2 and can be easily cut by hand or the like.
The cut lines 4 are formed for every about single circumferential length when the adhesive tape 2 is wound in a roll shape.
In other words, cut lines 4a formed in an outermost layer and cut lines 4b formed in the next layer are arranged at a predetermined interval L. The interval L is changed according to the number of turns of the adhesive tape 2.
More specifically, when the single circumferential length of the adhesive tape of the n-th (where n is a positive integer) turn is Ln, the radius of the winding core is r, the thickness of the adhesive tape is t, a deviation between the cut lines of the n-th layer and the cut lines of the n+1-th layer is Δd, and an interval between the cut lines of the adhesive tape of the n-th turn and the cut lines of the n+1-th layer is expressed by an angular difference θ, the cut lines are formed so as to satisfy the following Equations 1 to 3.
L
n=2π{r×(n−1)×t} Equation (1)
L
n+1
=L×(360−θ)/360 Equation (2)
L
n+1
=L
n
+Δd Equation (3)
That is, when the angular difference θ is set to be equal to 0° (θ=0°), the cut lines 4 can be arranged, as illustrated in
When the angular difference θ is set to be greater than 0° (θ>0°), the cut lines 4 are formed, as illustrated in
In this manner, the used adhesive face of the previous adhesive tape emerges at the tip end of the adhesive tape 2 of the next layer. Therefore, adhesion at the tip end part of the adhesive tape 2 can be reduced, and a rail drawing phenomenon likely to occur when a new adhesive face is rotated on a floor can be prevented.
When the angular difference θ is set to be less than 0° (θ<0°), the cut lines 4 are formed, as illustrated in
In this manner, a used adhesive face and an unused adhesive face including a boundary part can be removed, and an unused adhesive tape roll can be reliably exposed over its whole circumference.
Here, the angular difference θ is preferably in the range of equal to or greater than 6° and equal to or less than 19° (6°≦0≦19°) and more preferably in the range of equal to or greater than 9° and equal to or less than 12° (9°≦θ≦12°). According to this relational expression, when the angular difference θ is set to be less than 6°, the deviation Δd becomes equal to or less than 2 mm. Therefore, the reduction of adhesion cannot be prevented, which may cause a rail drawing phenomenon to occur. On the other hand, when the angular difference θ is set to be greater than 19°, the deviation Δd becomes greater than 10 mm. Therefore, an unused adhesive tape must be wastefully torn off, which is economically disadvantageous.
Next, a process for forming the cut lines 4 will be described with reference to
In this example, two feed rollers 34 and 35 and a receive roller 36 arranged facing the cut-lines formation roller 33 are also provided on the conveyance path. According to this embodiment, the specific configurations of the mother roll 31, the feed rollers 34 and 35, and the receive roller 36 may be arbitrarily set.
The winding roller 32 is a roller that is rotated and driven by drive means not illustrated and winds the adhesive tape 2 around its circumference. In this example, the winding roller 32 winds the adhesive tape 2 with the adhesive face 22 directed to the front side in order to be formed simultaneous with the formation of the cut lines 4. However, the adhesive face 22 may be directed to either the front side or a rear side.
The cut-lines formation roller 33 has a blade plate 37 for forming the cut lines 4 integrally formed at a part of its cylindrical roller-main-body and inserts the blade plate 37 into the adhesive tape 2 with its rotation. In this example, a wavy blade for forming the simple cut lines 4 is used as the blade plate 37, but the blade plate 37 may be processed to have more complicated cut lines 4. Thus, the shape of the blade plate 37 may be arbitrarily changed according to specifications.
According to the present invention, the winding roller and the cut-lines formation roller 33 are rotated in synchronization with each other via gears 40. In other words, the winding roller 32 has three types of gears 41 to 43 coaxially provided about its drive shaft, and the cut-lines formation roller 33 has a gear 44 coaxially provided about its drive shaft (both not illustrated). These gears 40 selectively engage with each other via predetermined selection means.
Among the three types of gears 41 to 43, the first gear 41 (hereinafter referred to as the first gear 41) is formed to have a gear ratio of one to one with the gear 44 (hereinafter referred to as the fourth gear 44). In this example, the number of teeth of both of the first gear 41 and the fourth gear 44 is 87.
In this manner, the winding roller and the cut-lines formation roller 33 are synchronously linked to each other with the gear ratio of one to one. Therefore, the cut lines 4 can be easily formed that satisfies the relational expression θ=0° described.
Among the three types of gears 41 to 43, the second gear (hereinafter referred to as the second gear 42) is a gear that has a larger outer diameter than that of the first gear 41 and is formed to have a gear ratio of greater than one to one with the fourth gear 44. In this example, the number of teeth of the second gear 41 is 90, and the number of teeth of the fourth gear 44 is 87.
In this manner, the winding roller 32 and the cut-lines formation roller 33 are synchronously linked to each other with the gear ratio of greater than one to one. In other words, they are linked to each other with a gear teeth ratio of 90 to 87 (with an angular ratio of 360° to 348°). Therefore, the cut lines 4 of the reverse step structure can be easily formed with an angular difference of 12° (θ=12°) that satisfies the relational expression θ>0° described above.
Among the three types of gears 41 to 43, the third gear (hereinafter referred to as the third gear 43) is a gear that has a smaller diameter than that of the first gear 41 and is formed to have a gear ratio of less than one to one with the fourth gear 44. In this example, the number of teeth of the third gear 41 is 84, and the number of teeth of the fourth gear 44 is 87.
In this manner, the winding roller and the cut-lines formation roller 33 are synchronously linked to each other with the gear ratio of less than one to one. In other words, they are linked to each other with a gear teeth ratio of 84 to 87 (with an angular ratio of 348° to 360°). Therefore, the cut lines 4 of the forward step structure can be easily formed with an angular difference of −12° (θ=−12) that satisfies the relational expression θ<0° described above.
In this example, as the gears 40, the three types of gears 41 to 43 are provided on the side of the winding roller 32, and the fixed fourth gear 44 is provided on the side of the cut-lines formation roller 33. Alternatively, the fourth gear 44 may be provided on the side of the winding roller 32, and the three types of gears 41 to 43 may be provided on the side of the cut-lines formation roller 33.
Next, a more specific embodiment of the present invention will be described. The positions of the cut lines 4 were calculated on the condition that the radius r of the winding core 3 was 20 mm, the thickness t of the adhesive tape 2 was 0.1 mm, and the angular differences θ when the adhesive tape was wound by 90 turns were set to be equal to 0° (θ=0°), +12° (θ=12°), and −12° (θ=−12°).
(When the angular difference θ is set to be equal to 0° (θ=0°))
When the angular difference θ is set to be equal to 0° (θ=0°), the length Ln at the first turn is 125.60 mm according to the equation Ln=2π{r×(n−1)×t}. Because the deviation Δd is not caused, the length L is gradually increased in proportion to the number of turns of the adhesive tape 2. Table 1 illustrates calculation results. According to the results, it is found that the cut lines 4 can be arranged at the same position when the length L is gradually made larger as the number of the turns increases.
(When the angular difference θ is set to be equal to +12° (θ=+12°))
When the angular difference θ is set to be equal to +12° (θ=+12°, the length Ln at the first turn is 125.60 mm according to the equation Ln=2π{r×(n−1)×t}. The length of the subsequent second layer is 126.228 mm when it is calculated according to this equation. However, in order to cause a deviation where the angular difference θ is set to be equal to +12° (θ=+12°), the length of the second layer must be 122.02 mm according to the equation L2=L1×(360−12)/360 and the deviation Δd must be 4.208 mm. Thus, the cut lines 4 are formed to have a reverse step. Table 2 illustrates calculation results.
(When the angular difference θ is set to be equal to −12° (θ=−12°))
Similarly, when the angular difference θ is set to be equal to −12° (θ=−12°, the length Ln at the first turn is 125.60 mm according to the equation Ln=2π{r×(n−1)×t}. The length of the subsequent second layer is 126.228 mm when it is calculated according to this equation. However, in order to cause a deviation where the angular difference θ is set to be equal to −12°(θ=−12°), the length of the second layer must be 130.436 mm according to the equation L2=L1×(360−12)/360 and the deviation Δd must be −4.208 mm. Thus, the cut lines 4 are formed to have a forward step. Table 3 illustrates calculation results.
In this manner, the positions of the cut lines can be arranged in an overlapped state and can be shifted back and forth only with a change in a gear ratio between the winding roller 32 and the cut-lines formation roller 33. Therefore, the adhesive tape roll 1 having the cut lines 4 according to use can be easily manufactured with a single apparatus.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/JP2010/002358 | 3/31/2010 | WO | 00 | 3/16/2012 |
