JP2012206335A - Manufacturing apparatus of continuous adhesive material strip or continuous adhesive article aggregate, and manufacturing method of the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a manufacturing apparatus capable of automatizing a manufacturing line of a continuous adhesive material strip (10).SOLUTION: The manufacturing apparatus (1) includes: a first supply means for supplying a first sticking member (12) to which a large number of adhesive articles (11) are stuck; a first conveying means for conveying the first stuck member (12); a stripping part (41) which folds the first stuck member (12) and strips the adhesive articles (11); a second supply means which supplies second sticking members (13, 76b) to a position lower than the stripping part (41); a second conveying means for conveying the second sticking members (13, 76b) at a speed lower than that of the first conveying means; and a control part which controls the drive of the first and the second conveying means, and is configured so that the continuous adhesive material strip (10) can be automatically manufactured on the second sticking members (13, 76b).

Description

  In the present invention, at least a part of a pressure-sensitive adhesive article such as a label is stacked on the front or back surface of another pressure-sensitive adhesive article, or the edge of the pressure-sensitive adhesive article is abutted against the other pressure-sensitive adhesive article, so The present invention relates to a manufacturing apparatus and a manufacturing method for manufacturing a connected continuous adhesive article strip or continuous adhesive article assembly.

  Conventionally, flaky labels and seals having an adhesive layer on the back side and a desired printing on the surface have been used for a wide range of applications such as commercial and office use, and demand for labels and the like has been increasing year by year. It is diversifying.

  In general, such a label has an adhesive layer formed on the back surface of a base material (eg, paper or resin sheet) constituting the label. In addition, for the purpose of supporting the label and the like and protecting the adhesive layer, a sheet-like release paper having a release layer on the surface (sometimes referred to as a mount or separator) is attached to the adhesive layer such as a label. Yes. On the other hand, a desired character or pattern is printed on the surface side of the substrate using a label printer or the like, and a protective layer or the like may be provided on the printed surface of the substrate.

  With labels and the like configured in this way, when the label is peeled off from the release paper and attached to an adherend such as a product, the release paper serves as a support part for the label or the like and a protective part for the adhesive layer. In many cases, it was discarded. Therefore, in recent years, in order to save resources and reduce waste from the viewpoint of environmental protection, and to reduce manufacturing costs, the amount of release paper discarded after peeling labels and the like has been reduced. There has been a demand for eliminating the release paper itself.

  In order to meet the above demand, for example, in Japanese Patent Laid-Open No. 11-249571 (Patent Document 1) and Japanese Patent Laid-Open No. 2009-199042 (Patent Document 2), as shown in FIG. A strip-shaped label continuous body (continuous label strip-shaped body) 80 is formed by pasting one end portion so as to overlap the other end portion of the other label 81 and connecting a plurality of labels 81 in succession. The label continuous body 80 of the form which wound the label continuous body 80 in roll shape is disclosed.

  More specifically, for example, in the roll-shaped label continuous body 80 described in Patent Document 1, each label 81 constituting the label continuous body 80 is formed in a predetermined shape (circular shape, square shape, etc.). The label base material, the adhesive layer disposed on the back surface of the label base material, and the release layer disposed on the surface of the label base material are provided.

  In Patent Document 1, one end of the adhesive layer in each label 81 is overlapped and attached to the other end of the release layer in the other label 81, so that the plurality of labels 81 are shifted from each other and connected in a row. The label continuum 80 is configured. In this case, the size of the width at which one end of the adhesive layer of each label 81 is overlapped with the other end of the release layer of another label 81 can be arbitrarily set.

In this case, a part of the adhesive layer disposed on the back surface of each label 81 is protected by being bonded to the release layer disposed on the surface of another label 81, but the other part of the adhesive layer is exposed. It becomes a state. For this reason, in Patent Document 1, in order to protect the entire adhesive layer of each label 81, the label continuous body 80 is wound in a roll shape, and the exposed portion of the adhesive layer of each label 81 is
It is made to affix on the peeling layer of the other label 81 wound inside.

  Therefore, according to the label continuous body 80 of Patent Document 1 wound in a roll shape, the adhesive layer of the label 81 can be protected without using release paper, and the label 81 is attached to an object to be adhered such as a product. When affixing to the label, the labels 81 can be peeled off from the label continuum 80 one by one. Furthermore, if it is the roll-shaped label continuous body 80 of patent document 1, since the shape of each label 81 is not limited, the effect that the shape of the label 81 can be selected freely is also acquired.

JP-A-11-249571 JP 2009-199042 A

  When manufacturing a roll-shaped continuous label strip as described in Patent Document 1 or Patent Document 2, first, a plurality of labels having a desired shape are attached to a mount (release paper). Manufactured by.

  For example, a strip-shaped label base material made of paper, synthetic resin, or the like is prepared, and an adhesive is applied to the back surface of the label base material to form an adhesive layer. Moreover, in order to support a label base material and to protect an adhesion layer after formation of an adhesion layer, a strip | belt-shaped mount is stuck on one surface of an adhesion layer. In this case, a release layer is provided on the surface of the backing sheet to which the adhesive layer is attached so that the adhesive layer can be easily peeled off.

  Next, printing is performed on the surface of the label base material to which the mount is attached via the adhesive layer, and a release agent is applied to the printing surface side of the label base material to form a release layer. Thereafter, the printed label base material is cut into a desired shape together with the adhesive layer and the release layer. Thereby, the some label which has a desired shape is manufactured on a strip | belt-shaped mount. In addition, such a label can be manufactured on a strip | belt-shaped mount by changing the order of the above-mentioned process, or using methods other than the above-mentioned process.

  When producing a label continuum using a plurality of labels produced in this way, conventionally, after the labels are peeled one by one from the mount by manual work, the labels partially overlap each other. In this way, the positions are shifted and connected.

  However, in the production of continuous label strips by manual work in this way, there are problems that work efficiency is poor and costs such as labor costs increase. Moreover, when manufacturing a continuous label strip | belt body by manual work, there also existed a problem that it was difficult to arrange | equalize the overlay dimension (overlap width) of the label in a continuous label strip | belt body, and it was easy to produce quality variation.

  The present invention has been made in view of the above conventional problems, and a specific object thereof is to realize automation of a production line for a continuous adhesive article strip or a continuous adhesive article assembly, and to the first adhesive member. A continuous adhesive article strip or continuous adhesive article assembly in which a plurality of adhesive articles are continuously connected from an adhesive article such as an attached label can be efficiently produced without causing quality variations. It is an object of the present invention to provide a possible manufacturing apparatus and manufacturing method.

In order to achieve the above object, the manufacturing apparatus provided by the present invention has, as a basic structure, stacking at least a part of a flaky adhesive article having an adhesive layer on the back surface on the surface of another adhesive article, or In a manufacturing apparatus that automatically manufactures a continuous adhesive article strip in which a large number of the adhesive articles are continuously connected in a band by abutting the edge of an adhesive article with the edge of another adhesive article, A first supply means for supplying a first adhesive member in which a large number of the adhesive articles are attached in a row at predetermined intervals; and a first transport means for transporting the first adhesive member at a first transport speed. And the first adhesive member to be conveyed is folded back to the second surface side at a predetermined position, and the adhesive article is peeled off from the first adhesive member one by one, and the multiple adhesives peeled off. The second adhering member for sequentially receiving and adhering articles is removed. A second supply means for supplying a lower position than the first part, a second transport means for transporting the second sticking member at a second transport speed slower than the first transport speed, the first transport means, and the And a control unit that controls the driving of the second conveying means.

  Moreover, the manufacturing apparatus according to another embodiment provided by the present invention has, as a basic configuration, stacking at least a part of a flaky pressure-sensitive adhesive article having an adhesive layer on the back surface on the surface of another pressure-sensitive adhesive article, or the pressure-sensitive adhesive. In a manufacturing apparatus that automatically manufactures a plurality of continuous adhesive article assemblies in which an edge of an article is abutted against an edge of another adhesive article, and a predetermined number of the adhesive articles are continuously joined together to form a group A first supply means for supplying a first adhesive member in which a large number of the adhesive articles are adhered to the first surface in a row at a predetermined interval; and the first adhesive member is conveyed at a first conveying speed. A first transporting means, a peeling part that folds the first sticking member to be transported to the second surface side at a predetermined position, and peels the adhesive article from the first sticking member one by one; Second paste for receiving and sticking a large number of adhesive articles A second supply means for supplying a member to a position lower than the peeling portion; a second transport means for transporting the second sticking member at a second transport speed slower than the first transport speed; and the first And a control unit that controls driving of the transport unit and the second transport unit.

  In the manufacturing apparatus according to the present invention, a guide portion that sequentially guides the adhesive article peeled from the first sticking member toward the second sticking member is predetermined with respect to the transport surface upstream of the peeling portion. It is preferable that the guide portion is arranged so as to be inclined downward at an angle of, and the adhesive article is guided along the guide portion by contacting the surface side of the adhesive article.

  In this case, the length from the position where the adhesive article is peeled off at the peeling portion to the position where the peeled adhesive article is in contact with the second sticking member is based on the size of the adhesive article along the transport direction. It is further preferable that the length is set shorter.

  Moreover, the manufacturing apparatus which concerns on this invention WHEREIN: The said 1st supply means is the adhesive article supply part which supplies many said adhesive articles in the state currently stuck on the said 1st sticking member, or said 1st sticking It is preferable to have an adhesive article manufacturing means for manufacturing the adhesive article on the member.

  Furthermore, in the manufacturing apparatus of the present invention, after the continuous adhesive article strip is manufactured on the second adhesive member, the continuous adhesive article strip is attached to the second adhesive member. It is preferable that the winding part wound up with the 2nd sticking member is arranged.

  Further, in the present invention, after the plurality of continuous adhesive article assemblies are manufactured on the second sticking member with a predetermined interval, the first region is formed in the interval region provided between the continuous adhesive article assemblies. The cutting part which cut | disconnects 2 adhering members, and the collection | recovery part which collect | recovers the said continuous adhesive article aggregate and the said 2nd adhering member after a cutting | disconnection may be arranged.

  Furthermore, in this invention, after the said continuous adhesive article strip | belt body is manufactured on the said 2nd sticking member, the said continuous adhesive article strip | belt body is peeled from the said 2nd sticking member, and the said continuous adhesive article strip | belt body is discharged | emitted. And a take-up unit that winds up the continuous adhesive article strip discharged from the discharge unit.

  Next, the manufacturing method provided by the present invention basically includes at least a part of a flaky pressure-sensitive adhesive article having a pressure-sensitive adhesive layer on the back surface, stacked on the surface of another pressure-sensitive adhesive article, or an edge of the pressure-sensitive adhesive article. In a manufacturing method for automatically manufacturing a continuous adhesive article strip in which a large number of the adhesive articles are continuously connected in a band shape by causing the end to butt against the edge of another adhesive article, a large number of the adhesive articles on the first surface Supplying the 1st sticking member stuck in the shape of a line at predetermined intervals, conveying the 1st sticking member at the 1st conveyance speed, peeling while conveying the 1st sticking member Folding the adhesive article one by one from the first sticking member, supplying the second sticking member to a position lower than the peeling part, the second sticking Carry the landing member at a second transport speed slower than the first transport speed And manufacturing the continuous adhesive article strip on the second adhesive member by sequentially delivering and adhering the peeled adhesive articles to the second adhesive member. The main feature is that it contains.

  The manufacturing method according to another embodiment provided by the present invention includes, as a basic configuration, stacking at least a part of a flaky pressure-sensitive adhesive article having an adhesive layer on the back surface on the surface of another pressure-sensitive adhesive article, or the pressure-sensitive adhesive. In a manufacturing method of automatically manufacturing a plurality of continuous adhesive article assemblies in which an edge of an article is abutted with an edge of another adhesive article and a predetermined number of the adhesive articles are continuously gathered into a group Supplying a first adhesive member in which a large number of the adhesive articles are adhered to the first surface in a row at a predetermined interval, conveying the first adhesive member at a first conveying speed, While conveying the first adhesive member, it is folded back to the second surface side at the peeling part, and the adhesive article is peeled from the first sticking member one by one, and the second sticking is at a position lower than the peeling part. Supplying a member; and supplying the second sticking member to the first carrying member. A plurality of the above-mentioned second adhesive members on the second adhesive member by conveying at a second conveyance speed slower than the speed, and sequentially feeding and adhering the peeled adhesive article to the second adhesive member. The main feature is that the continuous adhesive article aggregate is manufactured with a predetermined interval between the continuous adhesive article aggregates.

  In the manufacturing method according to the present invention, the surface side of the adhesive article peeled off from the first sticking member on the guide portion arranged to be inclined downward at a predetermined angle with respect to the transport surface upstream of the peeling portion. It is preferable that the adhesive article is guided toward the second sticking member along the guide portion.

  In this case, the length from the position where the pressure-sensitive adhesive article peels at the peeling portion to the position where the peeled pressure-sensitive adhesive article contacts the second adhesive member is determined from the dimension of the pressure-sensitive adhesive article along the transport direction. More preferably, the adhesive article is brought into contact with the second adhesive member before the adhesive article completely peels from the first adhesive member.

  The manufacturing method of this invention includes winding up the said continuous adhesive article strip | belt together with the said 2nd sticking member in the state stuck on the said 2nd sticking member after manufacture of the said continuous adhesive article strip | belt. Preferably it is.

  Moreover, the manufacturing method of this invention cut | disconnects the said 2nd bonding member in the area | region of the said space | interval provided between each continuous adhesive article aggregate | assembly after manufacture of the said some continuous adhesive article aggregate | assembly, and The continuous adhesive article aggregate and the second sticking member may be collected after cutting.

  Furthermore, the manufacturing method of this invention peels the said continuous adhesive article strip from the said 2nd sticking member after manufacture of the said continuous adhesive article strip, discharges the said continuous adhesive article strip, and discharge | emission Winding the continuous adhesive article strip that has been made may be included.

As described above, the continuous adhesive article strip manufacturing apparatus according to the present invention is configured such that a large number of the adhesive articles are attached to the first surface of the first attaching member in a row at a predetermined interval. A first supply means for supplying the adhesive article; a first conveying means for conveying the first adhesive member at the first conveying speed; a peeling part for separating the adhesive articles one by one from the first adhesive member; A second supply means for supplying the sticking member to a position lower than the peeling portion; a second transport means for transporting the second sticking member at a second transport speed slower than the first transport speed; 2 having a controller for controlling the driving of the conveying means.

  In the manufacturing apparatus having such a configuration, the first adhering member is folded from the first adhering member at the peeling portion while the first adhering member is continuously conveyed by the first conveying unit, for example. Articles can be peeled one by one. Further, in the manufacturing apparatus, the second sticking member is supplied to a position lower than the peeling portion by the second feeding means and is continuously fed at the second feeding speed by the second feeding means, for example, while being continuously fed. The peeled adhesive article is sequentially delivered to and adhered to the attaching member.

  In addition, if a 2nd sticking member can be supplied to a position lower than a peeling part, the installation position of a 2nd supply means and a 2nd conveyance means will not be specifically limited, A 2nd supply means and a 2nd conveyance The means may be arranged at a position lower than the peeling portion, or may be arranged at a position higher than the peeling portion.

  At this time, in this invention, the 2nd conveyance speed which conveys a 2nd adhesion member is set slower than the 1st conveyance speed of a 1st adhesion member, and a 1st conveyance speed and a 2nd conveyance speed are set by the control part. There is a speed difference between the two.

  Thereby, when adhering an adhesive article to the second adhesive member, a part of the adhesive article is preceded by one on the surface of the adhesive article adhered to the second adhesive member. Stacking, or the edge of the adhesive article can be abutted against the edge of the adhesive article that is attached to the second adhesive member one prior to the adhesive article. For this reason, on the 2nd sticking member, the continuous adhesive article strip | belt body in which many adhesive articles were connected continuously in strip | belt shape can be manufactured stably.

  Thus, according to the manufacturing apparatus according to the present invention, since the continuous adhesive article strip can be automatically manufactured from the adhesive article attached to the first attaching member without manual operation, the manufacture thereof is performed. The line can be automated. Therefore, it is possible to continuously and efficiently manufacture the continuous adhesive article strip to improve the productivity, and to reduce the manufacturing cost by reducing the labor cost and the like. Furthermore, it is possible to prevent variations in the quality of the continuous adhesive article strip by mechanically manufacturing the continuous adhesive article strip.

  In the present invention, the continuous adhesive article strip is a strip-like connected body (continuous body) constituted by stacking a large number of adhesive articles together or connecting the edges together and continuously. One continuous adhesive article strip can be continuously produced on the second sticking member. Furthermore, as the first and second sticking members, a tape member such as a release paper, or a transport unit (endless belt member) such as a conveyor can be used.

  Moreover, in the first and second conveying means, it is preferable to continuously convey the first and second sticking members at a predetermined conveying speed, respectively. In the present invention, for example, the first and / or second elements are used. It is also possible to intermittently transport the first and second adhesive members by repeating the transport and stop of the adhesive members at a predetermined cycle, and to transport and stop the first and / or second adhesive members. It is also possible to convey the first and second sticking members by repeating the above in a short time (instantaneously). In this case, the average conveyance speed of the 2nd sticking member conveyed by the 2nd conveyance means should just be set slower than the average conveyance speed of the 1st adhesion member conveyed by the 1st conveyance means. .

  The manufacturing apparatus of the continuous adhesive article assembly which concerns on another form of this invention, as mentioned above, the 1st supply means which supplies the 1st sticking member to which many adhesive articles were stuck, and the 1st sticking A first conveying means for conveying the member at a first conveying speed; a peeling portion for peeling the adhesive article one by one from the first sticking member; and a second for supplying the second sticking member to a position lower than the peeling portion. A supply unit; a second conveyance unit that conveys the second sticking member at a second conveyance speed that is slower than the first conveyance speed; and a control unit that controls driving of the first and second conveyance units. Yes.

  In the manufacturing apparatus having such a configuration, the first sticking member is folded from the first sticking member at the peeling portion while the first sticking member is intermittently transported by the first transport unit, for example. Articles can be peeled one by one. Further, in the manufacturing apparatus, the second sticking member is supplied to a position lower than the peeling portion by the second feeding means and is continuously fed at the second feeding speed by the second feeding means, for example, while being continuously fed. The peeled adhesive article is sequentially delivered to and adhered to the attaching member.

  At this time, in this invention, the 2nd conveyance speed which conveys a 2nd adhesion member is set slower than the 1st conveyance speed of a 1st adhesion member, and a 1st conveyance speed and a 2nd conveyance speed are set by the control part. There is a speed difference between the two. Moreover, the 1st sticking member is intermittently conveyed by the 1st conveyance means.

  Thereby, at the time of conveyance of the 1st sticking member, an adhesive article can be peeled from the 1st sticking member in a peeling part, and the peeled adhesive article can be stuck on the 2nd sticking member, and in that case, 2 A part of the adhesive article to be adhered to the adhesive member is stacked on the surface of the adhesive article adhered to the second adhesive member one preceding the adhesive article, or the edge of the adhesive article is The adhesive article can be abutted against the edge of the adhesive article adhered to the second adhesive member one prior to the adhesive article.

  On the other hand, when the conveyance of the first adhesive member is stopped, the adhesive material is not delivered to the second adhesive member, but the second adhesive member is continuously conveyed by the second conveying means. A gap is formed on which the adhesive article is not stuck. For this reason, on the second adhesive member, a plurality of continuous adhesive article assemblies in which a predetermined number of adhesive articles are continuously connected and assembled into a group are provided with a predetermined interval between each continuous adhesive article assembly. It can be manufactured stably while being provided.

  Thus, according to the manufacturing apparatus according to the present invention, since a plurality of continuous adhesive article aggregates can be automatically manufactured from the adhesive article attached to the first adhesive member without manual labor, The production line can be automated. Therefore, it is possible to continuously and efficiently manufacture the continuous adhesive article assembly to improve productivity, and to reduce the manufacturing cost by reducing labor costs and the like. Furthermore, since the continuous pressure-sensitive adhesive article assembly is mechanically manufactured, it is possible to prevent variations in the quality of the continuous pressure-sensitive adhesive article aggregate.

  In the present invention, the continuous adhesive article aggregate is a group of connected bodies (continuous bodies) formed by stacking a predetermined number of adhesive articles or connecting the edges to each other continuously. A plurality of continuous adhesive article strips can be produced on the second sticking member at predetermined intervals.

Further, as described above, the first conveying member intermittently conveys the first adhering member at a predetermined conveying speed, and the second conveying unit continuously conveys the second adhering member at a predetermined conveying speed. However, in the present invention, for example, the first adhering member is continuously conveyed at a constant first conveying speed, and the second adhering member is conveyed to the second conveying speed and the second conveying. The conveyance speed different from the speed (for example, a speed higher than the second conveyance speed) is alternately and repeatedly conveyed, and the second adhesion member is repeatedly conveyed and stopped at a predetermined cycle. It is also possible to convey intermittently, or to convey a 2nd sticking member by repeating conveyance and a stop of a 2nd sticking member in a short time (instantly). In these cases, the 2nd conveyance speed says the speed which conveys the 2nd sticking member, when sticking an adhesive article to the 2nd sticking member.

  In such a manufacturing apparatus of the present invention, the guide part that sequentially guides the adhesive article peeled from the first sticking member toward the second sticking member is transported of the first sticking member upstream of the peeling part. It is arranged to be inclined downward with respect to the surface at a predetermined angle. Moreover, this guide part is comprised so that the adhesive article may be guided to the 2nd sticking member along the said guide part by making the surface side of an adhesive article contact.

  By providing such a guide part, the adhesive article peeled from the first sticking member at the peeling part can be reliably delivered and stuck to the second sticking member, so that the second sticking member On top, a continuous adhesive article strip or continuous adhesive article aggregate (hereinafter referred to simply as an adhesive article continuous body, including a continuous adhesive article strip and a continuous adhesive article aggregate) may be stabilized. Can be manufactured.

  In this case, the length from the position where the adhesive article is peeled off at the peeling portion to the position where the peeled adhesive article contacts the second adhesive member is set to be shorter than the dimension of the adhesive article along the transport direction. ing.

  For example, when the adhesive article peeled from the first adhesive member is sent to the second adhesive member, the adhesive article is separated from the first adhesive member and is also separated from the second adhesive member. Then, static electricity is generated, and high-voltage static electricity is easily charged on the adhesive article itself. If the adhesive article is charged with static electricity in this way, a repulsive force is generated between the adhesive article and the second sticking member, and the sticking of the sticky article is not stable. May be attracted and stick to the adhesive layer, causing problems such as reducing the adhesive strength of the adhesive layer.

  On the other hand, from the first sticking member, the length from the position of the peeling portion to the position where the adhesive article contacts the second sticking member as described above is made shorter than the size of the sticking article. Before the adhesive article completely peels, the adhesive article can be brought into contact with the second adhesive member, and the adhesive article is separated from both the first adhesive member and the second adhesive member. Absent. Thereby, since the adhesive article can maintain a state where it is grounded to at least one of the first adhesive member and the second adhesive member, and can prevent static electricity from being charged to the adhesive article, during the production of the adhesive article continuum, The above-described problems caused by static electricity do not occur.

  Moreover, in the manufacturing apparatus of this invention, the said 1st supply means adheres on the adhesion article supply part which supplies many adhesion articles in the state currently affixed on the 1st adhesion member, or on the 1st adhesion member. It has an adhesive article manufacturing means for manufacturing an article.

  Thus, by providing the adhesive article supply unit in the manufacturing apparatus of the present invention, a large number of adhesive articles in a state of being adhered to the first adhesive member can be smoothly and stably directed toward the peeling portion. Can be supplied. Further, by providing the adhesive article manufacturing means, it becomes possible to automate and continuously manufacture the adhesive article and the adhesive article continuum, and more efficiently manufacture the adhesive article continuum. be able to.

  In the manufacturing apparatus of the present invention, after the continuous adhesive article strip is manufactured on the second adhesive member, the continuous adhesive article strip is adhered to the second adhesive member together with the second adhesive member. A winding unit for winding is arranged. Thereby, the manufactured continuous adhesive article strip can be recovered and provided in a form wound in a roll together with the second sticking member, and the adhesive layer of the continuous adhesive article strip can be provided at the time of recovery. Two sticking members can be stably protected.

  Further, in the manufacturing apparatus of the present invention, after a plurality of continuous adhesive article assemblies are manufactured on the second sticking member with a predetermined interval, the second is provided in the region of the interval provided between the continuous adhesive article assemblies. A cutting part for cutting the sticking member and a recovery part for collecting the continuous adhesive article aggregate and the second sticking member after cutting may be arranged. Thereby, the manufactured continuous adhesive article aggregates can be recovered and provided in the form of strips while being attached to the second adhesive member, and each continuous adhesive article aggregate can be provided. Can be stably protected by the second adhesive member.

  Furthermore, in the manufacturing apparatus of the present invention, after the continuous adhesive article strip is manufactured on the second adhesive member, the continuous adhesive article strip is peeled from the second adhesive member and the continuous adhesive article strip is discharged. And a winding unit that winds up the continuous adhesive article strip discharged from the discharging unit. Thereby, it can collect | recover and provide with the form which wound only the manufactured continuous adhesive article strip | belt body in roll shape. For this reason, for example, the second sticking member can be recycled and used repeatedly, and the cost of the continuous adhesive article strip can be further reduced.

  Next, in the method for manufacturing a continuous adhesive article strip according to the present invention, first, a first adhesive member in which a large number of adhesive articles are attached to a first surface in a row at a predetermined interval is supplied. While the first adhesive member is continuously conveyed at the first conveyance speed, the adhesive article can be peeled from the first adhesive member one by one by folding back the first adhesive member at the peeling portion. .

  Moreover, in the manufacturing method of this invention, while supplying a 2nd sticking member to a position lower than a peeling part, the 2nd sticking member is continuously conveyed by the 2nd conveyance speed slower than a 1st conveyance speed. On the other hand, a large number of adhesive articles peeled off at the peeling part are sequentially sent to the second sticking member for sticking.

  Thereby, when sticking an adhesive article to the 2nd sticking member using the speed difference between the 1st conveyance speed of the 1st sticking member and the 2nd conveyance speed of the 2nd sticking member, A part of the pressure-sensitive adhesive article is stacked on the pressure-sensitive adhesive article that has been attached to the second sticking member one prior to the pressure-sensitive adhesive article, or the edge of the pressure-sensitive adhesive article is one piece than the pressure-sensitive adhesive article. Since it can be made to butt against the edge of the adhesive article previously attached to the second adhesive member, a continuous adhesive article belt in which a large number of adhesive articles are connected in a row on the second adhesive member. Can be manufactured.

  Thus, according to the manufacturing method according to the present invention, since the continuous adhesive article strip can be automatically manufactured on the second adhesive member without manual labor, the continuous adhesive article strip is continuously manufactured. Efficient and efficient, and productivity can be greatly improved, and labor costs can be reduced to reduce manufacturing costs. Furthermore, it is possible to prevent variations in the quality of the continuous adhesive article strip by mechanically manufacturing the continuous adhesive article strip.

  In the method for producing a continuous adhesive article assembly according to another aspect of the present invention, first, a first adhesive member in which a large number of adhesive articles are attached to the first surface in a row with a predetermined interval is provided. While the first sticking member is intermittently transported at the first transport speed, the first sticking member is folded back at the peeling portion, so that the first adhesive member is conveyed one by one when the first sticking member is transported. It can peel from a sticking member.

  Moreover, in the manufacturing method, while supplying a 2nd sticking member to a position lower than a peeling part, conveying the 2nd sticking member continuously at a 2nd conveyance speed slower than a 1st conveyance speed. Then, the adhesive article peeled off at the peeling portion is sequentially delivered to the second sticking member for sticking.

Thereby, at the time of conveyance of the 1st sticking member, an adhesive article can be peeled from the 1st sticking member in a peeling part, and the peeled adhesive article can be stuck on the 2nd sticking member, and in that case, 2 A part of the adhesive article to be adhered to the adhesive member is stacked on the surface of the adhesive article adhered to the second adhesive member one preceding the adhesive article, or the edge of the adhesive article is The adhesive article can be abutted against the edge of the adhesive article adhered to the second adhesive member one prior to the adhesive article.

  On the other hand, when the conveyance of the first adhesive member is stopped, the adhesive material is not delivered to the second adhesive member, but the second adhesive member is continuously conveyed by the second conveying means. A gap is formed on which the adhesive article is not stuck. For this reason, on the second adhesive member, a plurality of continuous adhesive article assemblies in which a predetermined number of adhesive articles are continuously connected and assembled into a group are provided with a predetermined interval between each continuous adhesive article assembly. It can be manufactured stably while being provided.

  Thus, according to the manufacturing method according to the present invention, a plurality of continuous adhesive article aggregates can be automatically manufactured on the second sticking member without manual labor. Can be performed continuously and efficiently to significantly improve productivity, and labor costs can be reduced to reduce manufacturing costs. Furthermore, since the continuous pressure-sensitive adhesive article assembly is mechanically manufactured, it is possible to prevent variations in the quality of the continuous pressure-sensitive adhesive article aggregate.

  In such a manufacturing method of the present invention, the surface side of the adhesive article peeled off from the first sticking member is placed on the guide portion arranged to be inclined downward at a predetermined angle with respect to the transport surface upstream of the peeling portion. Contact is made and the adhesive article is guided along the guide. Thereby, since an adhesive article can be reliably delivered and stuck to a 2nd sticking member, a continuous adhesive article strip | belt body or a continuous adhesive article aggregate | assembly can be stably manufactured on a 2nd sticking member.

  In this case, the length from the position where the adhesive article is peeled off at the peeling portion to the position where the peeled adhesive article is in contact with the second adhesive member is shorter than the dimension of the adhesive article along the transport direction, Before the adhesive article completely peels from the first adhesive member, the adhesive article is brought into contact with the second adhesive member. As a result, static electricity can be prevented from being charged to the adhesive article, so that dust and dust can be prevented from being attracted to the adhesive layer by static electricity, and the adhesive article can be stably adhered to the second adhesive member. .

  The manufacturing method of the present invention includes winding the continuous adhesive article strip together with the second adhesive member in a state of being adhered to the second adhesive member after the continuous adhesive article strip is manufactured. Thereby, it is possible to collect and provide the continuous adhesive article strip in the form of a roll wound together with the second adhesive member, and to stabilize the adhesive layer of the continuous adhesive article strip with the second adhesive member. Can be protected.

  Moreover, the manufacturing method of this invention cut | disconnects a 2nd sticking member in the area | region of the space | interval provided between each continuous adhesive article aggregate | assembly after manufacture of several continuous adhesive article aggregate | assembly, and is continuous after a cutting | disconnection. Collecting the adhesive article aggregate and the second sticking member may be included. Thereby, the continuous adhesive article aggregate can be recovered and provided in the form of a strip while being stuck to the release paper, and the adhesive layer of the continuous adhesive article strip can be provided as the second adhesive member. Can be protected stably.

  Furthermore, the manufacturing method of this invention peels a continuous adhesive article strip from a 2nd sticking member after manufacture of a continuous adhesive article strip, discharges the continuous adhesive article strip, and the discharged continuous adhesive It may include winding up the article strip. Thereby, it can collect | recover and provide in the form which wound only the continuous adhesive article strip | belt-shaped body in roll shape. For this reason, for example, the second sticking member can be recycled and used repeatedly, and the cost of the continuous adhesive article strip can be further reduced.

It is a schematic diagram which shows roughly the manufacturing apparatus of the continuous label strip | belt body which concerns on Example 1 of this invention. It is an enlarged view which expands and shows the principal part of the manufacturing apparatus. In the manufacturing apparatus, it is a schematic diagram which shows the state which delivers a label to peeling paper from a peeling part. It is a schematic diagram which shows the state in which a label bends, when sending a label from a peeling part to peeling paper in the manufacturing apparatus. In the manufacturing apparatus, it is a schematic diagram which shows the state which a label is delivered to a release paper and sticks. In the same manufacturing apparatus, it is a schematic diagram which shows the state which delivers the label peeled off from the base_sheet | mounting_paper so that a part of the said label may be piled up on the label previously affixed on the release paper. It is a schematic diagram which shows roughly the principal part of the manufacturing apparatus of the continuous label aggregate | assembly which concerns on Example 2 of this invention. It is a schematic diagram which shows the continuous label aggregate | assembly manufactured with the manufacturing apparatus. It is a schematic diagram which shows roughly the principal part of the manufacturing apparatus of the continuous label strip | belt shaped material which concerns on Example 3 of this invention. It is a schematic diagram which shows roughly the principal part of the manufacturing apparatus of the continuous label strip | belt shaped material which concerns on Example 4 of this invention. It is a perspective view which shows the conventional continuous label strip | belt body wound by roll shape.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to the embodiments described below, and various modifications are possible as long as they have substantially the same configuration as the present invention and have the same effects. Is possible.

  For example, in each of the following examples, a case where an adhesive article is constituted by a label and a continuous label strip or a continuous label aggregate is manufactured by connecting a plurality of labels will be described. However, the adhesive article of the present invention is not limited to a label, and may be a thin piece having an adhesive layer such as a building material such as a decorative panel. In each of the following examples, the continuous adhesive article strip or continuous adhesive article assembly is manufactured by superimposing a part of each adhesive article on the surface of the preceding adhesive article. It is also possible to produce a continuous adhesive article strip or continuous adhesive article assembly by causing the edge of each adhesive article to abut the edge of the preceding adhesive article.

FIG. 1 is a schematic diagram illustrating an outline of a continuous label strip manufacturing apparatus according to the first embodiment, and FIG. 2 is an enlarged view illustrating an essential part of the manufacturing apparatus.
The manufacturing apparatus 1 for the continuous label strip 10 according to the first embodiment is arranged on the upstream side (left side in FIG. 1) of the manufacturing apparatus 1 and is attached to a mount (first adhesive member) 12. An upstream portion 20 serving as a supply side, a downstream portion 30 disposed on the downstream side (right side in FIG. 1) of the manufacturing apparatus 1 and serving as a side for collecting the manufactured continuous label strip 10, and the upstream portion 20 And an intermediate portion 40 that peels off the label 11 from the mount 12 conveyed to the downstream portion 30 and delivers it to the downstream portion 30.

  In the first embodiment, the upstream portion 20 of the manufacturing apparatus 1 is supplied from a label supply unit 21 serving as a supply unit that supplies a large number of labels 11 attached to a sheet-like mount 12, and a label supply unit 21. The first roller unit 22 that can change the transport direction of the label 11 and the mount 12 and adjust the tension of the mount 12 and a detection roller unit 23 that detects the transport speed (first transport speed V1) of the mount 12 A mount recovery unit 24 that recovers the mount 12 from which the label 11 has been peeled off, a first motor unit 25 that rotates the mount recovery unit 24, and a first control unit (not shown) that controls the drive of the first motor unit 25. And have.

  The label supply unit 21 in the upstream portion 20 has a shaft portion that is rotatably arranged, and the sheet-like mount 12 is set on the shaft portion in a state of being wound in a roll shape. A plurality of labels 11 are affixed in rows at a predetermined interval to the mount 12 set in the label supply unit 21. In addition, after the roll body of the mount 12 is attached to the label supply unit 21, one end of the mount 12 is pulled out from the roll body, and further, a first roller unit 22, a peeling unit 41 to be described later of the intermediate unit 40, Then, after passing through the detection roller unit 23 in order, the detection roller unit 23 is attached to the shaft of the mount collecting unit 24.

  In this case, although the material and structure of the mount 12 used as the first sticking member are not particularly limited, in the first embodiment, the mount 12 is configured in a belt-like sheet form. The mount 12 includes a mount base material that is a main part of the mount 12 and a release layer disposed on one surface (front surface) of the mount base material, and is configured as a release paper. The mount base material is made of a conventionally used material such as various kinds of paper (for example, glassine paper or clay coated paper) or a resin film. Further, the release layer is formed by applying a release agent such as a silicone compound or a fluorine compound to the surface of the mount base material.

  The first roller unit 22 includes a pair of upper and lower rollers 22a and 22b, and is arranged so as to hold the transport surface of the mount 12 horizontally with the peeling unit 41. The first roller unit 22 applies resistance to the mount 12 passing between the upper and lower rollers 22a and 22b, and applies a predetermined tension to the mount 12 between the first roller unit 22 and the mount collecting unit 24. It is configured.

The detection roller unit 23 includes a pair of left and right rollers 23a and 23b, and detects the conveyance speed of the mount 12 by passing the mount 12 around the left and right rollers 23a and 23b. It is configured to output a signal of the conveyed speed. In this case, the conveyance speed signal output from the detection roller unit 23 is input to a first control unit (not shown) of the upstream unit 20.
The mount collection unit 24 includes a shaft portion that is rotatably arranged. As described above, one end of the mount 12 is attached to the shaft portion of the mount collection unit 24.

  The first motor unit 25 constitutes a transport unit for the mount 12 together with the mount collection unit 24. That is, the first motor unit 25 is connected to the shaft part of the mount collecting unit 24 via a belt or a chain, and by driving the first motor unit 25, the shaft part of the mount collecting unit 24 is moved in a predetermined direction. (In the case of FIG. 1, the paper 12 is rotated in the clockwise direction), and thereby the paper 12 is pulled from the label supply unit 21 toward the paper collection unit 24 while the paper 12 is wound around the shaft. The

  A first control unit (not shown) disposed in the upstream unit 20 controls the driving of the first motor unit 25 based on the conveyance speed signal input from the detection roller unit 23, and thereby the mount 12 and the label. 11 is adjusted to a predetermined speed (first transport speed V1).

  The downstream portion 30 in the manufacturing apparatus 1 of the first embodiment is configured to change the conveyance direction of the release paper supply unit 31 that supplies the release paper 13 serving as the second sticking member and the release paper 13 supplied from the release paper supply unit 31. The conversion roller 32 to be converted, and after the label 11 is attached to the release paper 13 (after the continuous label strip 10 is manufactured), the transfer direction of the release paper 13 is changed and the transfer speed of the release paper 13 (first 2 a second roller part 33 for detecting the transport speed V2), a winding part 34 for winding the continuous label strip 10 together with the release paper 13, a second motor part 35 for rotating the winding part 34, and a second motor. And a second control unit (not shown) that controls the driving of the unit 35.

The release paper supply unit 31 in the downstream portion 30 has a shaft portion that is rotatably arranged, and the release paper 13 in a state where the label 11 is not attached is wound around the shaft portion in a roll shape. It is set in the state that has been set. In addition, after the roll body of the release paper 13 is attached to the release paper supply unit 31, one end of the release paper 13 is pulled out from the roll body, and further passed through the conversion roller 32 and the second roller unit 33 in order. Then, it is attached to the shaft part of the winding part 34.

  In this case, the material and structure of the release paper 13 are not particularly limited, but in the first embodiment, the release paper 13 is configured in a belt-like sheet form. Further, the release paper 13 has a release paper base material that is a main part of the release paper 13 and a release layer disposed on one surface (front surface) of the release paper base material. The release paper base is composed of various papers (for example, glassine paper and clay coated paper) and materials such as a resin film. The release layer is formed by coating a release agent such as a silicone compound or a fluorine compound on the surface of the release paper substrate.

  The conversion roller 32 is arranged so as to hold the transport surface of the release paper 13 transported horizontally with the second roller portion 33. In this case, the conveyance surface of the release paper 13 between the conversion roller 32 and the second roller portion 33 is adjusted by adjusting the arrangement positions of the conversion roller 32 and the second roller portion 33, so that the conveyance surface of the mount 12 in the upstream portion 20. In other words, the height in the direction of gravity is set lower than the position of the transporting surface of the mount 12 between the first roller section 22 and the peeling section 41 and the position of the peeling section 41 of the intermediate section 40. Has been. Therefore, in the first embodiment, the release paper supply unit 31 and the conversion roller 32 constitute supply means for supplying the release paper 13 to a position lower than the release unit 41.

The second roller unit 33 includes a pair of upper and lower rollers 33a and 33b. By passing the release paper 13 between the upper and lower rollers 33a and 33b, the conveyance speed of the release paper 13 is detected and detected. It is configured to output a conveyance speed signal. In this case, the conveyance speed signal output from the second roller unit 33 is input to a second control unit (not shown) of the downstream unit 30.
The winding portion 34 includes a shaft portion that is rotatably arranged. As described above, one end portion of the release paper 13 is attached to the shaft portion of the winding portion 34.

  The second motor unit 35 constitutes a conveying unit for the release paper 13 together with the winding unit 34. That is, the second motor part 35 is connected to the shaft part of the winding part 34 via a belt or a chain, and by driving the second motor part 35, the shaft part of the winding part 34 is made a predetermined part. The release paper 13 is rotated from the release paper supply unit 31 to the take-up unit 34 to rotate in the direction (clockwise in the case of FIG. 1), thereby pulling the release paper 13 while winding the release paper 13 around the shaft portion. It is conveyed toward.

  A second control unit (not shown) disposed in the downstream unit 30 controls the driving of the second motor unit 35 based on the conveyance speed signal input from the second roller unit 33, thereby releasing the release paper 13. Is adjusted to a predetermined magnitude (second conveyance speed V2). In this case, the second transport speed V2 of the release paper 13 is set to a speed slower than the first transport speed V1 of the mount 12. In the present invention, the first control unit and the second control unit may be configured integrally or may be configured separately.

  As shown in the enlarged view of FIG. 2, the intermediate unit 40 in the manufacturing apparatus 1 of the first embodiment folds the mount 12 conveyed in the upstream section 20 and peels the label 11 from the mount 12. 41 and a guide portion 42 for guiding the label 11 peeled off by the peeling portion 41 toward the release paper 13 conveyed between the conversion roller 32 and the second roller portion 33.

The peeling portion 41 in the intermediate portion 40 has a cross-sectional shape in which one end portion is narrowed, and is configured so that the mount 12 is folded at an acute angle toward the back surface at one end of the peeling portion 41. In this case, the peeling portion 41 has a folding angle of the mount 12 of 5 ° or more and 45 ° or less, preferably 15 °.
The shape is such that it is 30 ° or less and particularly preferably 20 °.

  That is, by setting the folding angle of the mount 12 to 5 ° or more, it is possible to secure a space in which the peeling portion 41 can be inserted between the folded mounts 12. 41 can stably obtain such strength that it can withstand use. Further, by setting the folding angle of the mount 12 to 45 ° or less, the label 11 can be stably peeled from the mount 12 when the mount 12 is folded by the peeling portion 41.

  In addition, the peeling portion 41 is made of a material having a small surface friction coefficient so that the backing paper 12 is not caught when the backing paper 12 is folded, or the surface of the peeling portion 41 is coated with excellent sliding properties. It is preferable that the layer is arranged.

  The guide portion 42 disposed in the intermediate portion 40 forms the bottom surface of the guide portion 42 in a flat surface, and the bottom surface of the guide portion 42 is a conveyance surface (the first roller portion 22 and the peeling portion 41 between the upstream portion 20 and the upstream surface 20). It is configured to be inclined downward with respect to the transport surface of the mount 12 in the middle. Such a guide part 42 makes the surface of the label 11 come into contact with the bottom surface side of the guide part 42 as the label 11 is gradually peeled off from the mount 12, and is pushed along the bottom surface of the guide part 42. The label 11 can be stably guided toward the release paper 13.

  In this case, there is a label 11 between the bottom surface of the guide part 42 and the mount 12 conveyed at the upstream part 20 and between the bottom surface of the guide part 42 and the release paper 13 conveyed at the downstream part 30. A gap is provided through which can be inserted. Further, the downstream end of the guide portion 42 is stably attached to the release paper 13 and a partial surface of the preceding label 11 when the label 11 is delivered to the release paper 13. It plays the role of holding down the surface of the label 11 so as to be worn.

  Such a guide part 42 is made of a material having a small coefficient of friction on the surface so that the label 11 can be smoothly guided to the release paper 13, or a coating layer having excellent slidability is provided on the bottom surface of the guide part 42. It is arranged. For example, in the first embodiment, the guide part 42 is made of polytetrafluoroethylene or silicone.

  Further, the downward inclination angle on the bottom surface of the guide portion 42 varies depending on the material of the guide portion 42 or the material of the bottom surface coating layer, but is 10 ° or more and 45 ° or less with respect to the transport surface of the mount 12 in the upstream portion 20, Preferably, it is set to be 20 ° or more and 40 ° or less.

  That is, by setting the downward inclination angle to 10 ° or more and 45 ° or less, the label 11 peeled from the mount 12 is smoothly guided without being caught on the bottom surface of the guide portion 42, and the upstream portion 20 to the downstream portion 30. The label 11 can be delivered stably (that is, the label 11 can be delivered from the mount 12 to the release paper 13).

  In particular, in the first embodiment, as shown in FIG. 2, the length from the position where the label 11 peels at the peeling portion 41 to the position where the peeled label 11 contacts the release paper 13 is expressed as “between delivery Further, the length along the transport direction of the label 11 (for example, when the label 11 is formed in a circle, the length of the diameter of the circular label 11) is defined as “the length of the label L1”. When the length L1 is defined as “L2”, the length L1 between the delivery is 80% or more of the label length L2 by adjusting the positional relationship between the upstream portion 20 and the downstream portion 30 and the downward inclination angle in the guide portion 42. The size is set to 95% or less.

That is, by setting the length L1 between the delivery to be 80% or more of the label length L2, the label 11 is released when the label 11 is delivered from the mount 12 to the release paper 13.
3, the label 11 is prevented from being clogged due to being caught by 3 or being excessively bent, and the delivery of the label 11 can be performed more smoothly.

  On the other hand, when the label 11 is delivered from the mount 12 to the release paper 13 by setting the length L1 between the deliveries to 95% or less of the label length L2, the label 11 is removed from the mount 12 The label 11 can be reliably brought into contact with the release paper 13 before completely peeling. This prevents the label 11 from being separated from the mount 12 and the release paper 13 when the label 11 is delivered, and ensures that the label 11 is always in contact with at least one of the mount 12 and the release paper 13. can do. For this reason, it is possible to prevent static electricity from being charged to the label 11 and to prevent the occurrence of problems caused by the static electricity.

Next, a method of manufacturing the continuous label strip 10 from a large number of labels 11 attached to the mount 12 using the manufacturing apparatus 1 described above will be described in detail.
First, the mount 12 to which a large number of labels 11 are attached is set in the label supply unit 21. At this time, the mount 12 is composed of a strip-shaped sheet (release paper) having the mount base material and the release layer as described above as the first sticking member, and is wound in a roll shape. In addition, a large number of labels 11 are attached to the surface of the mount 12 on the release layer side in a state where the labels 11 are arranged in a line at predetermined intervals in the length direction of the mount 12.

  Here, the length along the transport direction in the label 11 attached to the mount 12 (or the length along the longitudinal direction of the mount 12) is defined as “label length L2” as described above. Further, the length of the interval provided between the labels 11 along the conveyance direction is defined as “interval length L3”. Moreover, the label non-sticking part used as the area | region where the label 11 is not stuck is provided in the one end part side of the mount 12 used for the present Example 1. FIG.

  In this case, the label 11 attached to the mount 12 is disposed on the label base material, the adhesive layer disposed on one surface (back surface) of the label base material, and the other surface (front surface) of the label base material. And a release layer disposed on the other surface (front surface) of the label substrate so as to cover the print surface, and is described in, for example, Patent Document 1 Each label is configured in substantially the same manner. In addition, the shape of each label 11 in this invention is not specifically limited, Various shapes, such as a circle, a triangle, and a rectangle, are employable.

  Furthermore, in the first embodiment, a plurality of labels 11 are attached to the mount 12 in a single row with a predetermined interval, but in the present invention, the number of labels 11 to be attached to the mount 12 is one. It is not limited to a column, and may be a plurality of columns of two or more. Further, in the present invention, the plurality of labels 11 are in a state where the edges of the adjacent labels 11 are abutted with each other without providing a predetermined interval between the labels 11 attached in a row in the length direction of the mount 12. May be attached in a row in the length direction of the mount 12.

  When the roll body of the mount 12 to which the plurality of labels 11 are attached in this way is set in the label supply section 21, the roll body of the mount 12 is attached to the shaft section of the label supply section 21. Further, one end portion of the mounted mount 12 where the label non-sticking portion is formed is pulled out from the roll body, and one end portion of the mount 12 is separated from the first roller portion 22 as shown in FIG. After passing through the part 41 and the detection roller part 23 appropriately, they are attached to the shaft part of the mount collecting part 24. Thereby, the mount 12 and the label 11 are set in the upstream part 20 of the manufacturing apparatus 1.

  In this case, the mount 12 and the label 11 are set between the first roller portion 22 and the peeling portion 41 so that the label 11 is exposed on the surface side of the transport surface of the mount 12. Moreover, it is preferable that the label unattached portion of the mount 12 is formed so that the label 11 is positioned on the upstream side of the peeling portion 41 when the mount 12 is set on the upstream portion 20.

  Next, the release paper 13 is set in the release paper supply unit 31. At this time, the release paper 13 is constituted by a belt-like sheet having the release paper base material and the release layer as described above as the second sticking member, and is wound in a roll shape. When the roll body of the release paper 13 is set in the release paper supply unit 31, the roll body of the release paper 13 is attached to the shaft portion of the release paper supply unit 31.

  Further, one end portion of the attached release paper 13 is pulled out from the roll body, and the one end portion of the release paper 13 is appropriately passed through the conversion roller 32 and the second roller portion 33 as shown in FIG. Later, it is attached to the shaft part of the winding part 34. Thereby, the release paper 13 is set in the downstream part 30 of the manufacturing apparatus 1.

  At this time, the release paper 13 is provided between the conversion roller 32 and the second roller portion 33 so that the release paper 13 can be supplied to a position lower than the release portion 41 and the label 11 can be stably received by the release paper 13. The position of the transport surface 13 is set at a position where the height in the direction of gravity is lower than the position of the peeling portion 41.

  As described above, after the label 11 and the mount 12 serving as the first sticking member and the release paper 13 serving as the second sticking member are set in the manufacturing apparatus 1 respectively, the first and second control units perform the first operation. The first and second motor portions 25 and 35 are driven to rotate the shaft portion of the mount collecting portion 24 and the shaft portion of the winding portion 34. As a result, the mount 12 and the release paper 13 are taken up by the mount collection unit 24 and the take-up unit 34, respectively. The paper is conveyed from the unit 31 toward the mount collecting unit 24 and the winding unit 34.

  At this time, the mount 12 passes through the detection roller unit 23, so that the detection roller unit 23 detects the first transport speed V 1 of the mount 12, and the signal of the detected first transport speed V 1 is the first transport speed V 1 of the upstream unit 20. 1 is input to the control unit. Then, the first control unit controls the drive of the first motor unit 25 based on the input signal so that the first transport speed V1 of the mount 12 becomes a speed set in advance by the user, and the mount The first transport speed V1 of 12 is maintained constant.

  Further, when the release paper 13 passes through the second roller portion 33, the second roller portion 33 detects the second conveyance speed V2 of the release paper 13, and the signal of the detected second conveyance speed V2 is the downstream portion. 30 input to the second control unit. Based on the input signal, the second control unit controls the driving of the second motor unit 35 so that the second conveyance speed V2 of the release sheet 13 is a speed set in advance by the user, The second conveyance speed V2 of the release paper 13 is kept constant.

  Thereafter, as shown in FIG. 2, a label 11 (hereinafter, this label 11 is referred to as a first label 11 a) attached to the most leading side of the mount 12 is transferred to the peeling portion 41 by transporting the mount 12. At the same time, the mount 12 is folded back at an acute angle by the peeling portion 41, and at the same time, the first label 11a is gradually peeled from the mount 12 due to the folding of the mount 12.

  Further, in this case, since the mount 12 is continuously conveyed, the first label 11 a is pushed out toward the guide portion 42 while being peeled from the mount 12. Thereby, the surface side of the first label 11a (the surface side on which the release layer is formed) is in contact with the bottom surface of the guide portion 42, and further, the first label 11a slides along the bottom surface of the guide portion 42, Guided toward the release paper 13 being conveyed in the downstream portion 30. In addition, by guiding the first label 11a while being in contact with the guide portion 42, it is possible to prevent the first label 11a from warping in a concave shape on the surface side, for example.

And, as shown in FIG. 3, the first label 11a is gradually pushed out,
One end (tip) of the first label 11a reaches the release paper 13 and comes into contact therewith. At this time, as described above, since the length L1 between the delivery is set to 95% or less of the label length L2 (see FIG. 2), the first label 11a is completely removed from the mount 12. One end of the first label 11a can be brought into contact with the release paper 13 before peeling. Thereby, it is possible to prevent the first label 11a from being charged with static electricity.

  After one end of the first label 11 a comes into contact with the release paper 13, the first label 11 a is adhered to the release paper 13 and is conveyed toward the winding unit 34 along with the release paper 13. At this time, the first label 11a is pushed out from the mount 12 at the first transport speed V1, and one end side of the label 11 adhered to the release paper 13 is transported at the second transport speed V2. However, in this case, the second transport speed V2 of the release paper 13 is slower than the first transport speed V1 of the mount 12, and there is a speed difference between the first transport speed V1 and the second transport speed V2. As shown in FIG. 4, the first label 11 a is delivered to the release paper 13 while being gradually bent downward so as to be separated from the guide portion 42.

  After that, when the first label 11a is pushed out from the mount 12 and completely peeled off, the first label 11a slides down from the mount 12 and the guide part 42 as shown in FIG. At this time, for example, even when the first label 11a is caught by the folding position of the mount 12 and does not fall from the mount 12 and the guide portion 42, the first label 11a is pulled downstream by the conveyance of the release paper 13. In order to physically push out the first label 11a from behind when the next label 11 (hereinafter referred to as the second label 11b) following the first label 11a is peeled off from the mount 12, One label 11a can be reliably dropped from the mount 12 and the guide part 42 and transferred to the release paper 13.

  Further, the first label 11a delivered to the release paper 13 is attached to the release paper 13 via the adhesive layer of the first label 11a. In particular, in this case, the first label 11a is peeled from the label surface side by the downstream end of the guide portion 42 when the first label 11a is conveyed to the downstream side together with the release paper 13, so that the first label 11a is peeled off. The paper 13 can be stably adhered.

  On the other hand, since the mount 12 is transported at the first transport speed V1 even after the first label 11a slips, the next second label 11b following the first label 11a reaches the peeling portion 41, and the mount 12 (See FIG. 5).

  Then, the second label 11 b is pushed out while being peeled from the mount 12, so that the second label 11 b is guided while sliding along the bottom surface of the guide portion 42. At this time, since the second transport speed V2 of the release paper 13 is slower than the first transport speed V1 of the mount 12, the second label 11b is guided to the release paper 13 by the guide unit 42, and thus the second label 11b. As shown in FIG. 6, one end (front end) of the first plate 11a contacts the surface of the preceding first label 11a (or the front end edge of the second label 11b is abutted against the rear end edge of the preceding first label 11a. )

  After that, the second label 11b is sent while being bent away from the guide portion 42, as in the case of the preceding first label 11a, and when the second label 11b is completely peeled from the mount 12, The second label 11b is attached to the release paper 13 in a state where a part of the second label 11b overlaps the surface of the preceding first label 11a.

In this way, by sequentially repeating the transfer operation of the label 11 from the mount 12 to the release paper 13 while transporting the mount 12 and the release paper 13 at a predetermined speed, each label 11 becomes the preceding label 11. It is stuck in order on the release paper 13 while superposing a part on the surface. Thereby, the continuous label strip | belt body 10 by which at least one part of the label 11 was piled up on the surface or back surface of the other label 11 on the release paper 13, and many labels 11 were connected in strip shape can be manufactured.

  In this case, in the obtained continuous label strip 10, when the dimension along the transport direction in the region where each label 11 and the preceding label 11 overlap is defined as “wrap dimension Lp”, the size of this Lp is The first transport speed V1 of 12, the second transport speed V2 of the release paper 13, the label length L2, and the interval length L3 have a relationship of “Lp = L2−V2 / V1 (L2 + L3)”. Yes.

  That is, when the continuous label strip 10 is manufactured from a plurality of labels 11 attached to the mount 12 with a predetermined interval, the first transport speed V1 of the mount 12 and the second transport speed V2 of the release paper 13 are set. By changing the setting speed while maintaining the relationship of V1> V2, the lap dimension Lp of the continuous label strip 10 to be manufactured can be controlled to a desired size.

  And the continuous label strip | belt body 10 manufactured on the release paper 13 as mentioned above remains in the winding part 34 via the 2nd roller part 33 with the release paper 13 in the state affixed on the release paper 13. FIG. It is conveyed and collected by being wound by the winding unit 34. In this way, the continuous label strip 10 is collected together with the release paper 13 in a state where the continuous label strip 10 is adhered to the release paper 13, so that the adhesive label of the continuous label strip 10 is protected by the release paper 13. It becomes possible to supply the strip 10 to the market.

  As described above, according to the first embodiment, the labels 11 peeled one by one from the mount 12 at the peeling portion 41 of the upstream portion 20 are sequentially delivered to the peeling paper 13 conveyed at the downstream portion 30. By sticking, the continuous label strip 10 in which a large number of labels 11 are continuously connected to the release paper 13 while being shifted by a fixed lap dimension Lp is manufactured and collected without manual operation. be able to.

  By automating the production line of the continuous label strip 10 in this way, the continuous label strip 10 can be produced continuously and efficiently, so that the productivity can be greatly improved and the production cost can be reduced. Moreover, it can also prevent that the quality of the manufactured continuous label strip 10 varies.

  In the first embodiment described above, the roll body of the mount 12 on which the plurality of labels 11 are attached is set in the label supply unit 21 arranged in the upstream part 20 of the manufacturing apparatus 1, and the continuous label strip 10 Is manufactured. However, the present invention is not limited to this. For example, by providing a label manufacturing means for manufacturing the plurality of labels 11 on the mount 12 upstream of the peeling portion 41, It is also possible to continuously produce the continuous label strip 10.

  In this case, a conventionally known label manufacturing apparatus can be used as the label manufacturing means. An example of the label manufacturing apparatus will be specifically described. For example, the label manufacturing apparatus includes an adhesive layer forming unit that forms an adhesive layer on the back surface of a label base material such as paper constituting the label 11, and an adhesive layer side of the label base material. A backing paper sticking portion for sticking the backing paper 12, a printing portion (for example, a label printer) for printing on the surface of the label base material, and a peeling layer forming portion for forming a peeling layer on the printing surface side of the label base material. And a die-cutting part for producing the label 11 by die-cutting the label base material on which the mount 12 is adhered together with the adhesive layer and the release layer into a predetermined shape.

When manufacturing the some label 11 using such a label manufacturing apparatus, first, the strip | belt-shaped label base material which consists of paper, a resin film, etc. is prepared, and the label base material is conveyed to the adhesion layer formation part. In this adhesive layer forming part, an adhesive layer is formed on the label substrate by applying an adhesive to the back surface of the label substrate.

  Next, the label base material on which the adhesive layer is formed is transported to the backing paper sticking portion, and the belt-like backing paper 12 is stuck on one surface of the sticking layer at this backing paper sticking portion. Thus, the label base material can be supported by the mount 12 and the adhesive layer can be protected. In this case, as described above, a peeling layer is provided on the label-attached surface of the mount 12 so that the label 11 can be smoothly peeled from the mount 12 at the peeling portion 41 in the manufacturing apparatus 1 for the continuous label strip 10. It has been.

  Subsequently, the label base material to which the mount 12 is attached via the adhesive layer is conveyed to the printing unit, and printing is performed on the surface of the label base material on which the adhesive layer is not disposed. Note that this printing step can be omitted when the label 11 is not printed.

  After the printing process is performed in the printing unit, the label base material is conveyed to the release layer forming unit. In this release layer forming part, the release layer is formed on the surface of the label base material on which the adhesive layer is not disposed by applying a release agent to the printing surface side of the label base material. By having such a release layer, for example, when the continuous label strip 10 connected so that the labels 11 overlap with each other as described above, each label 11 is separated from the surface of the label 11 adjacent to the back side. It can be easily peeled off and used.

  Thereafter, the label base material on which the adhesive layer and the release layer are formed is transported to the die-cutting part, and the label base material is cut into a desired shape together with the adhesive layer and the release layer at the die-cut part. As a result, a large number of labels 11 having a desired shape are manufactured in a state where they are stuck in a line on the belt-like mount 12. In addition, it is possible to easily change the size of the label length L2 of each label 11 stuck on the mount 12 and the interval length L3 provided between the labels 11 at this die cutting part. is there.

  By providing a label manufacturing apparatus that can be manufactured with a plurality of labels 11 attached to the mount 12 as described above so as to be connected to the upstream portion 20 side of the manufacturing apparatus 1 of the continuous label strip 10, continuous labels are provided. A large number of labels 11 can be continuously supplied toward the peeling portion 41 in the manufacturing apparatus 1 of the belt-like body 10.

  Thereby, since it becomes possible to manufacture the continuous label strip | belt body 10 continuously using the manufactured label 11, producing the many labels 11 on the mount 12, manufacture of the continuous label strip | belt body 10 is possible. Can be performed more efficiently. In the present invention, the configuration of the label manufacturing means is not particularly limited, and other manufacturing apparatuses can be used as long as a plurality of labels 11 can be manufactured on the mount 12.

FIG. 7 is a schematic diagram schematically illustrating a main part of the continuous label assembly manufacturing apparatus according to the second embodiment.
The manufacturing apparatus 2 for the continuous label assembly 15 according to the second embodiment manufactures the continuous label assembly 15 on the release paper 13, and then the obtained continuous label assembly 15 is stuck on the release paper 13. It is configured to collect in the form of a strip. In addition, in Example 2 and Examples 3 and 4 to be described later, those having the same configurations as the parts and members described in Example 1 are represented by using the same reference numerals, and the description thereof will be given. Will be omitted.

The manufacturing apparatus 2 according to the second embodiment is arranged on the upstream side of the manufacturing apparatus 2, and on the upstream side 20 serving as a side for supplying the label 11 attached to the mount 12, and on the downstream side of the manufacturing apparatus 2. A downstream part 50 on the side of collecting the manufactured continuous label assembly 15, and an intermediate part 40 that peels the label 11 conveyed in the upstream part 20 from the mount 12 and sends it to the downstream part 50. Have. In this case, the upstream portion 20 and the intermediate portion 40 in the second embodiment are configured in the same manner as the manufacturing apparatus 1 in the first embodiment.

  The downstream part 50 in the present embodiment 2 changes the transport direction of the release paper 13 (not shown) that supplies the release paper 13 that is the second sticking member and the release paper 13 that is supplied from the release paper supply unit. A roller 52, a transport roller unit 53 that transports the release paper 13 at the second transport speed V 2, and discharges the manufactured continuous label aggregate 15 in a state of being attached to the release paper 13, and a transport roller unit 53. A second motor unit (not shown) that rotates, a second control unit (not shown) that controls driving of the second motor unit, and a cutting unit that cuts the release paper 13 discharged from the transport roller unit 53 by a predetermined length. 56 and a collection unit 57 that collects the continuous label aggregate 15 and the release paper 13 that have passed through the cutting unit 56.

  In Example 2, the release paper supply unit (not shown) and the conversion roller 52 are configured in the same manner as in Example 1 described above, and the conversion roller 52 is between the transport roller unit 53, It arrange | positions so that the conveyance surface of the peeling paper 13 conveyed may be hold | maintained horizontally. In this case, the conveyance surface of the release paper 13 between the conversion roller 52 and the conveyance roller unit 53 is set at a position lower than the position of the separation unit 41 of the intermediate unit 40.

  The conveyance roller unit 53 in the downstream unit 50 includes a pair of upper and lower rollers. The release paper 13 and the continuous label aggregate 15 are sandwiched between the upper and lower rollers, and at least one of the upper and lower rollers is a second motor unit. The release paper 13 and the continuous label aggregate 15 are conveyed at the second conveyance speed V2.

The cutting unit 56 is disposed on the front side of the release paper 13 discharged from the transport roller unit 53 and on the back side of the release paper 13, and cooperates with the first cutter to release the paper 13. The 2nd cutter part which cuts.
The collection unit 57 is configured in a tray shape that can sequentially place and store the continuous label aggregates 15 attached to the release paper 13 cut to a predetermined length by the cutting unit 56. ing.

  The manufacturing apparatus 2 according to the second embodiment having such a downstream portion 50 sequentially feeds the labels 11 from the mount 12 conveyed at the upstream portion 20 toward the release paper 13 conveyed at the downstream portion 50. By passing, the continuous label aggregate | assembly 15 with which the some label 11 was connected on the release paper 13 is manufactured.

  In particular, in the second embodiment, when the continuous label aggregate 15 is manufactured on the release paper 13, the upstream portion 20 is intermittently operated, and the transport and stop of the label 11 and the mount 12 are repeated at predetermined intervals. At the same time, the label 11 is delivered from the upstream portion 20 to the downstream portion 50 while the downstream portion 50 is continuously operated and the release paper 13 is continuously conveyed at a predetermined speed.

  As a result, during the operation of the upstream portion 20, a group of continuous label assemblies 15 in which a predetermined number of labels 11 are sequentially overlapped and connected to the release paper 13 of the downstream portion 50 are manufactured. On the other hand, while the operation of the upstream portion 20 is stopped, although the delivery of the label 11 from the upstream portion 20 to the downstream portion 50 is not performed, the release paper 13 is continuously conveyed in the downstream portion 50. A gap to which the label 11 is not attached is formed on 13. Therefore, in the manufacturing apparatus 2 of the second embodiment, as shown in FIG. 8, a plurality of continuous label assemblies 15 in which a predetermined number of labels 11 are connected as a set on the release paper 13 in the downstream portion 50 are provided. , Manufactured continuously with a predetermined interval.

Then, the plurality of continuous label assemblies 15 manufactured on the release paper 13 are discharged together with the release paper 13 through the transport roller unit 53. At this time, the release roller 13 from the transport roller unit 53
Is discharged to a predetermined length, the first and second cutter portions arranged in the cutting portion 56 move toward the release paper 13, and each continuous label as shown by a two-dot chain line in FIG. The release paper 13 is cut in a region where the labels 11 arranged between the aggregates 15 do not exist (that is, a region having a gap formed between the continuous label aggregates 15).

  Thereafter, the continuous label assembly 15 and the release paper 13 are dropped and placed on the collection unit 57 and are sequentially stacked in the collection unit 57. Thereby, the continuous label aggregate | assembly 15 which has predetermined | prescribed length is collect | recovered in the state affixed on the release paper 13 cut | disconnected in strip shape.

  As described above, by using the manufacturing apparatus 2 of the second embodiment, it is easy to manufacture a continuous label assembly 15 in which a predetermined number of labels 11 are continuously connected and assembled into a group without any manual work. Can be recovered. In particular, in Example 2, the continuous label assembly 15 can be provided on the release paper 13 while the adhesive layer of the continuous label assembly 15 is protected.

  In the second embodiment, a plurality of continuous label assemblies 15 are manufactured in a row on the release paper 13. However, in the present invention, the continuous label assemblies 15 are arranged in two or more rows in the width direction of the release paper 13. It is also possible to manufacture in a plurality of rows. In this case, after the continuous label assembly 15 is manufactured, each continuous label assembly 15 is attached to the release paper 13 by cutting not only the release paper 13 in the width direction but also the length direction in the cutter unit. It is possible to collect it in the state that has been done.

FIG. 9 is a schematic diagram schematically illustrating a main part of the continuous label strip manufacturing apparatus according to the third embodiment.
The manufacturing apparatus 3 of the continuous label strip 10 according to the third embodiment manufactures the continuous label strip 10 on the release paper 13, and then peels the obtained continuous label strip 10 from the release paper 13, The continuous label strip 10 is wound into a roll and collected in the form of a roll.

  More specifically, the manufacturing apparatus 3 according to the third embodiment is disposed on the upstream side of the manufacturing apparatus 3 and the upstream portion 20 serving as a side for supplying the label 11 attached to the mount 12, and the same manufacturing process. The downstream part 60 which is arranged on the downstream side of the apparatus 3 and becomes the side for collecting the manufactured continuous label strip 10 and the label 11 conveyed in the upstream part 20 are peeled off from the mount 12 and sent to the downstream part 60. And an intermediate part 40 to be passed.

  The downstream portion 60 in the third embodiment is configured to change the conveyance direction of the release paper 13 (not shown) that supplies the release paper 13 serving as the second sticking member and the release paper 13 supplied from the release paper supply unit. A roller 62, a second roller part 63 for detecting the second conveyance speed V2 of the release paper 13 and sending the release paper 13 and the continuous label strip 10 to the downstream side, and a downstream side of the second roller part 63, A peeling portion 66 that peels the continuous label strip 10 from the release paper 13 by folding the release paper 13, a first winding portion 67 that winds the continuous label strip 10 peeled by the peeling portion 66, and a continuous label strip A second winding unit (not shown) that winds the release paper 13 from which the body 10 has been peeled off, a second motor unit (not shown) that rotates the first and second winding units, respectively, and driving the second motor unit. A second control unit (not shown) to be controlled It is.

  In the third embodiment, the release paper supply unit, the conversion roller 62, the second roller unit 63, and the second winding unit are the release paper supply unit 31, the conversion roller 32, and the second roller in the first embodiment. The part 33 and the winding part 34 are configured similarly.

The peeling portion 66 disposed in the downstream portion 60 of the third embodiment has a cross-sectional shape with one end narrowed, and is configured such that the release paper 13 is folded at an acute angle at one end of the peeling portion 66. . The continuous label strip 10 can be stably peeled from the release paper 13 by folding back the release paper 13 with the continuous label strip 10 attached thereto at the peeling portion 66.

  The 1st winding part 67 is provided with the shaft part arranged so that rotation was possible, and the shaft part of this 1st winding part 67 is connected to the 2nd motor part which is not illustrated. For this reason, by rotating the shaft portion of the first winding portion 67 by the second motor portion, the continuous label strip 10 can be wound around the shaft portion and collected.

  In the third embodiment, the second motor unit constitutes a transport unit that transports the release paper 13 together with the second winding unit that winds up the release paper 13, and the first winding that winds up the continuous label strip 10. Together with the take-up section 67, a conveying means for conveying the continuous label strip 10 peeled from the release paper 13 is configured.

  In the manufacturing apparatus 3 according to the third embodiment having the downstream portion 60 as described above, the release paper 13 is transported at a second transport speed V2 that is lower than the first transport speed V1 of the mount 11 as in the first embodiment. Thereby, the continuous label strip | belt body 10 with which many labels 11 were connected by strip | belt shape can be manufactured on the release paper 13 without manual operation.

  The continuous label strip 10 manufactured on the release paper 13 is then peeled off from the release paper 13 by a peeling portion 66 disposed on the downstream side of the second roller portion 63. Further, the peeled continuous label strip 10 is taken up by the first winding unit 67 and collected in a roll form.

  In this case, the adhesive force between the labels 11 due to the adhesive force of each label 11 is set larger than the tension that the continuous label strip 10 receives when the continuous label strip 10 is collected. When the paper is wound up, it is possible to prevent peeling between the labels 11 constituting the continuous label strip 10, and to smoothly wind up the continuous label strip 10 in the form of a roll without dividing the continuous label strip 10 in the middle.

  Further, the release paper 13 from which the continuous label strip 10 has been peeled off by the peeling portion 66 is wound and collected by the second winding portion on the downstream side of the peeling portion 66. For this reason, in the third embodiment, since the release paper 13 can be recycled and repeatedly used, the manufacturing cost can be greatly reduced, and resource saving and dust reduction can be achieved.

FIG. 10 is a schematic diagram schematically illustrating a main part of the continuous label strip manufacturing apparatus according to the fourth embodiment.
The continuous label strip 10 manufacturing apparatus 4 according to the fourth embodiment includes a winding unit that winds the release paper 13 and a conveyor unit 76 that includes an endless belt member 76b as a conveying unit that conveys the release paper 13. Have. In addition, after manufacturing the continuous label strip 10 on the release paper 13, the manufacturing apparatus 4 peels the obtained continuous label strip 10 from the release paper 13 and winds the continuous label strip 10 in a roll shape. It is configured to rotate and collect.

  More specifically, the manufacturing apparatus 4 according to the fourth embodiment is arranged on the upstream side of the manufacturing apparatus 4, and the upstream portion 20 serving as a side for supplying the label 11 attached to the mount 12, and the same manufacturing process. The downstream part 70 which is arranged on the downstream side of the apparatus 4 and becomes the side for collecting the manufactured continuous label strip 10 and the label 11 conveyed in the upstream part 20 are peeled off from the mount 12 and sent to the downstream part 70. And an intermediate part 40 to be passed.

The downstream portion 70 in the fourth embodiment includes a release paper supply unit 71 that supplies the release paper 13, a conveyor unit 76 that conveys the release paper 13 supplied from the release paper supply unit 71, and a continuous label belt shape from the release paper 13. The discharge part 77 which peels the body 10 and discharges the continuous label strip 10, the first winding part 78 which winds the continuous label strip 10 discharged from the discharge part 77, and the continuous label strip 10 are peeled off. And a second winding unit 79 for winding the release paper 13.

  In the fourth embodiment, the release paper supply unit 71 and the second winding unit 79 are configured in the same manner as the release paper supply unit 31 and the winding unit 34 in the first embodiment, respectively. For example, the second winding portion 79 of the fourth embodiment includes a shaft portion that is rotatably arranged, and the shaft portion of the second winding portion 79 is connected to a second motor portion (not shown). Yes.

  The conveyor section 76 disposed in the downstream section 70 of the fourth embodiment includes a plurality of rollers 76a and an endless belt member 76b wound around these rollers 76a. In the conveyor unit 76, at least one of the plurality of rollers 76a functions as a driving roller, and rotates the endless belt member 76b at a constant second transport speed V2.

  The discharge unit 77 is composed of a pair of upper and lower rollers using one of the rollers 76a arranged on the conveyor unit 76 as a lower roller. The discharge unit 77 is configured to peel and discharge the continuous label strip 10 from the release paper 13 by changing the transport direction of the endless belt member 76b and the release paper 13 by the lower roller 76a.

  In addition, in the discharge unit 77, when it is difficult to peel the continuous label strip 10 from the release paper 13 only by changing the conveying direction by the lower roller 76a, the above-described third embodiment is provided on the downstream side of the discharge unit 77, for example. It is also possible to peel the continuous label strip 10 by disposing the peeling portion 66 used in the above and folding the release paper 13 at the peeling portion 66.

  The 1st winding part 78 is provided with the axial part arranged so that rotation was possible, and the axial part of this 1st winding part 78 is connected to the 2nd motor part which is not illustrated. Therefore, by rotating the shaft portion of the first winding portion 78 by the second motor portion, the continuous label strip 10 can be wound around the shaft portion and collected.

  In the manufacturing apparatus 4 according to the fourth embodiment having the downstream portion 70 as described above, the release paper 13 is transported at the second transport speed V2 that is slower than the first transport speed V1 of the mount 11 as in the third embodiment. Thus, the continuous label strip 10 is produced on the release paper 13. Further, the manufactured continuous label strip 10 is peeled off from the release paper 13 by the discharge unit 77 and then wound by the first winding unit 78 and collected in a roll form. Furthermore, since the release paper 13 from which the continuous label strip 10 has been peeled off by the discharge unit 77 is wound up and collected by the second winding unit 79, the release paper 13 can be recycled and used repeatedly. it can.

  In addition, in the manufacturing apparatus 4 of the fourth embodiment, the release paper 13 is used as the second sticking member that sequentially receives and sticks the labels 11 peeled by the peeling portion 41. For example, the conveyor portion 76 in the fourth embodiment. By using the endless belt member 76b as the second sticking member, it is possible to configure the manufacturing apparatus according to the modification of the fourth embodiment.

  In the manufacturing apparatus according to the modified example of Example 4 as described above, the endless belt member 76b is configured to have a release layer, for example, provided on the release paper 13 on the surface, and the endless belt member 76b. Is rotated by the roller 76a at a second transport speed V2 that is slower than the first transport speed V1 of the mount 11.

Thereby, since many labels 11 peeled in the peeling part 41 can be sequentially sent and stuck to the endless belt member 76b used as the 2nd sticking member, it is a continuous label on the endless belt member 76b. The belt-like body 10 can be manufactured. Further, in the manufacturing apparatus according to this modification, the continuous label belt 10 manufactured on the endless belt member 76 b is taken up by the first winding unit 78 after being peeled from the release paper 13 by the discharge unit 77. Collected in roll form.

  Further, in this case, the release paper 13 required in the manufacturing apparatus 4 of Example 4 is not necessary, and the release paper supply unit 71 for supplying the release paper 13 shown in FIG. The manufacturing apparatus according to the modified example can be configured by eliminating the second winding unit 79 for winding and collecting the paper 13. For this reason, the manufacturing cost of the continuous label strip 10 can be further reduced, and environmental protection can be achieved through resource saving.

DESCRIPTION OF SYMBOLS 1 Manufacturing apparatus 2 Manufacturing apparatus 3 Manufacturing apparatus 4 Manufacturing apparatus 10 Continuous label strip 11 Label 11a, 11b 1st and 2nd label 12 Mount 13 Release paper 15 Continuous label aggregate 20 Upstream part 21 Label supply part 22 1st roller part 22a Upper roller 22b Lower roller 23 Detection roller part 23a Left roller 23b Right roller 24 Mount paper collection part 25 First motor part 30 Downstream part 31 Release paper supply part 32 Conversion roller 33 Second roller part 33a Upper roller 33b Lower roller 34 Winding Part 35 second motor part 40 intermediate part 41 peeling part 42 guide part 50 downstream part 52 conversion roller 53 conveying roller part 56 cutting part 57 collecting part 60 downstream part 62 conversion roller 63 second roller part 66 peeling part 67 first winding Section 70 Downstream section 71 Release paper supply section 76 Conveyor section 76a Roller 7 b endless belt member 77 discharging unit 78 first winding portion 79 second winding portion

Claims (15)

At least a part of the flaky pressure-sensitive adhesive article (11) having a pressure-sensitive adhesive layer on the back surface is stacked on the surface of another pressure-sensitive adhesive article (11), or the edge of the pressure-sensitive adhesive article (11) is the edge of the other pressure-sensitive adhesive article (11). In a manufacturing apparatus (1, 3, 4) for automatically producing a continuous adhesive article strip (10) in which a large number of the adhesive articles (11) are continuously joined in a band by being abutted to the edge,
A first supply means for supplying a first adhesive member (12) in which a large number of the adhesive articles (11) are adhered to the first surface in a row at a predetermined interval;
First conveying means (25) for conveying the first sticking member (12) at a first conveying speed;
The peeling part (1) by which the said 1st sticking member (12) conveyed is turned in the 2nd surface side in a predetermined position, and the said adhesive article (11) is peeled from the said 1st sticking member (12) one by one. 41) and
A second supply means for supplying a second sticking member (13, 76b) for sequentially receiving and sticking a large number of peeled adhesive articles (11) to a position lower than the peeling portion (41);
Second transport means (35) for transporting the second sticking member (13, 76b) at a second transport speed that is slower than the first transport speed;
A controller for controlling the driving of the first transport means (25) and the second transport means (35);
Having
An apparatus for producing a continuous adhesive article strip. At least a part of the flaky pressure-sensitive adhesive article (11) having a pressure-sensitive adhesive layer on the back surface is stacked on the surface of another pressure-sensitive adhesive article (11), or the edge of the pressure-sensitive adhesive article (11) is the edge of the other pressure-sensitive adhesive article (11). In the manufacturing apparatus (2) for automatically manufacturing a plurality of continuous adhesive article aggregates (15) that are joined together in a group by joining a predetermined number of the adhesive articles (11) in a continuous manner,
A first supply means for supplying a first adhesive member (12) in which a large number of the adhesive articles (11) are adhered to the first surface in a row at a predetermined interval;
First conveying means (25) for conveying the first sticking member (12) at a first conveying speed;
The peeling part (1) by which the said 1st sticking member (12) conveyed is turned back to the 2nd surface side in a predetermined position, and the said adhesive article (11) is peeled from the said 1st sticking member (12) one by one. 41) and
A second supply means for supplying a second sticking member (13) for sequentially receiving and sticking a large number of peeled adhesive articles (11) to a position lower than the peeling portion (41);
Second transport means for transporting the second sticking member (13) at a second transport speed that is slower than the first transport speed;
A controller for controlling the driving of the first transport means (25) and the second transport means;
Having
An apparatus for producing a continuous pressure-sensitive adhesive article assembly. A guide part (42) for sequentially guiding the adhesive article (11) peeled from the first sticking member (12) toward the second sticking member (13, 76b) is provided by the peeling part (41). Is also arranged to be inclined downward at a predetermined angle with respect to the upstream conveying surface,
The guide part (42) is configured to contact the surface side of the adhesive article (11) and guide the adhesive article (11) along the guide part (42).
The manufacturing apparatus according to claim 1 or 2.   The length (L1) from the position where the adhesive article (11) peels off at the peeling portion (41) to the position where the peeled adhesive article (11) contacts the second sticking member (13, 76b) ) Is set shorter than the dimension (L2) of the adhesive article (11) along the conveying direction.   The first supply means is a pressure-sensitive adhesive article supply unit (21) that supplies a large number of the pressure-sensitive adhesive articles (11) in a state of being stuck to the first sticking member (12), or the first sticking member. (12) The manufacturing apparatus according to any one of claims 1 to 4, further comprising an adhesive article manufacturing means for manufacturing the adhesive article (11).   After the continuous adhesive article strip (10) was manufactured on the second adhesive member (13), the continuous adhesive article strip (10) was adhered to the second adhesive member (13). The manufacturing apparatus according to claim 1, wherein a winding unit (34) for winding together with the second sticking member (13) in a state is arranged.   After the plurality of continuous adhesive article aggregates (15) are manufactured on the second sticking member (13) at a predetermined interval, the interval area provided between the continuous adhesive article aggregates (15) A cutting part (56) for cutting the second sticking member (13) at a point, and a collecting part (57) for collecting the continuous adhesive article assembly (15) and the second sticking member (13) after cutting. The manufacturing apparatus according to claim 2, wherein   After the continuous adhesive article band (10) is manufactured on the second adhesive member (13, 76b), the continuous adhesive article belt (10) is removed from the second adhesive member (13, 76b). A discharge section (66,77) for peeling and discharging the continuous adhesive article strip (10), and a winding for winding the continuous adhesive article strip (10) discharged from the discharge section (66,77) The manufacturing apparatus according to claim 1, further comprising a portion (67, 78). At least a part of the flaky pressure-sensitive adhesive article (11) having a pressure-sensitive adhesive layer on the back surface is stacked on the surface of another pressure-sensitive adhesive article (11), or the edge of the pressure-sensitive adhesive article (11) is the edge of the other pressure-sensitive adhesive article (11). In a manufacturing method for automatically manufacturing a continuous adhesive article strip (10) in which a large number of the adhesive articles (11) are continuously joined in a band by being abutted against an edge,
Supplying a first adhesive member (12) in which a large number of the adhesive articles (11) are adhered to the first surface in a row at a predetermined interval;
Conveying the first adhering member (12) at a first conveying speed;
Folding the adhesive article (11) one by one from the first adhesive member (12) one by one by folding back to the second surface side at the peeling part (41) while conveying the first adhesive member (12). ,
Supplying the second sticking member (13, 76b) to a position lower than the peeling portion (41);
Transporting the second sticking member (13, 76b) at a second transport speed that is slower than the first transport speed; and
The continuous adhesive article is transferred onto the second adhesive member (13, 76b) by sequentially delivering and adhering the peeled adhesive articles (11) to the second adhesive member (13, 76b). Producing a strip (10),
A process for producing a continuous adhesive article strip comprising At least a part of the flaky pressure-sensitive adhesive article (11) having a pressure-sensitive adhesive layer on the back surface is stacked on the surface of another pressure-sensitive adhesive article (11), or the edge of the pressure-sensitive adhesive article (11) is the edge of the other pressure-sensitive adhesive article (11). In the manufacturing method of automatically manufacturing a plurality of continuous adhesive article aggregates (15) that are joined to the edge and gathered together in a group of a predetermined number of the adhesive articles (11),
Supplying a first adhesive member (12) in which a large number of the adhesive articles (11) are adhered to the first surface in a row at a predetermined interval;
Conveying the first adhering member (12) at a first conveying speed;
Folding the adhesive article (11) one by one from the first adhesive member (12) one by one by folding back to the second surface side at the peeling part (41) while conveying the first adhesive member (12). ,
Supplying the second sticking member (13) to a position lower than the peeling portion (41);
Conveying the second sticking member (13) at a second conveying speed slower than the first conveying speed; and
The peeled adhesive article (11) is sequentially delivered to and pasted onto the second sticking member (13), and a plurality of the continuous sticky article aggregates (15) are placed on the second sticking member (13). ) With a predetermined interval between each continuous adhesive article assembly (15),
A process for producing a continuous adhesive article assembly comprising: A guide part arranged to be inclined downward at a predetermined angle with respect to the transport surface upstream of the peeling part (41).
(42) is brought into contact with the surface side of the adhesive article (11) peeled from the first adhesive member (12), and the adhesive article (11) is placed along the guide portion (42) with the second adhesive article. The method according to claim 9 or 10, comprising guiding toward the landing member (13, 76b).   The length (L1) from the position where the adhesive article (11) peels off at the peeling portion (41) to the position where the peeled adhesive article (11) contacts the second sticking member (13, 76b) ) Shorter than the dimension (L2) of the adhesive article (11) along the conveying direction, and before the adhesive article (11) completely peels from the first sticking member (12), the adhesive article The manufacturing method according to claim 11, comprising bringing (11) into contact with the second sticking member (13, 76b).   After the continuous adhesive article strip (10) is manufactured, the continuous adhesive article strip (10) is wound together with the second adhesive member (13) in a state of being adhered to the second adhesive member (13). 10. A method according to claim 9, comprising taking. Cutting the second sticking member (13) in the region of the space provided between the continuous adhesive article assemblies (15) after the production of the plurality of continuous adhesive article assemblies (15); and ,
Collecting the continuous adhesive article assembly (15) and the second adhesive member (13) after cutting;
The manufacturing method of Claim 10 which comprises these. After manufacturing the continuous adhesive article strip (10), the continuous adhesive article strip (10) is peeled off from the second sticking member (13, 76b), and the continuous adhesive article strip (10) is discharged. And
Winding the discharged continuous adhesive article strip (10);
The manufacturing method of Claim 9 which comprises these.

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