The present application claims priority from Japanese Patent Application No. 2017-141376, which was filed on Jul. 20, 2017, the disclosure of which is incorporated herein by reference in its entirety.
The present disclosure relates to a cutting apparatus cutting a print-receiving medium including an adhesive layer, and a printer including the cutting apparatus.
A printer (tape printer) is known that includes a cutting apparatus (cutter unit) cutting a print-receiving medium (roll sheet) including an adhesive layer. In this printer according to the prior art, the print-receiving medium cut by a movable blade and a fixed blade of the cutting apparatus is finally discharged through a discharge path part.
In the printer of the prior art, the discharge path part includes a projecting part, a regulating member, a roll-sheet receiving part, a rib, etc., and even if the cut print-receiving medium moves while adhering to the movable blade, the medium comes into contact with the members and thereby peels off from the movable blade. However, when the length of the cut print-receiving medium is short, the medium may stay in the discharge path part without being discharged.
An object of the present disclosure is to provide a cutting apparatus and a printer capable of reliably discharging a cut print-receiving medium.
In order to achieve the above-described object, according to the aspect of the present application, there is provided a cutting apparatus comprising a feeder configured to feed a print-receiving medium including an adhesive layer along a predetermined transport direction, a fixed blade that has a shape like a flat plate and includes a first blade edge at a lower end, a movable blade that has a shape like a flat plate, includes a second blade edge having a substantially V-like shape in a view from the transport direction at an upper end, is disposed downstream from fixed blade in the transport direction, and is configured to slide in a sliding direction crossing the transport direction against the fixed blade and to move along the sliding direction from a standby position on a lower side to a cutting position on an upper side, and a guide device that includes an upper guide part and a lower guide part that respectively is disposed downstream from the fixed blade in the transport direction and is configured to guide the print-receiving medium being cut further downstream, the upper guide part including a contact part that is disposed at a position separated from the first blade edge of the fixed blade by a first distance in the transport direction and by a second distance in an upper direction and is configured to make point contact or line contact with an upper surface of the print-receiving medium when a cut-side end portion of the print-receiving medium being cut deforms in an upwardly-bending manner along with the movable blade moves upward, and the lower guide part including at least one guide surface that inclines in an inclination direction in which the at least one guide surface inclines downward at a predetermined angle toward a downstream in the transport direction, is disposed to have an interval of a third distance against the contact part in a direction orthogonal to the inclination direction, and is configured to make contact with a lower surface of the print-receiving medium being cut along with the movable blade moving upward.
The cutting apparatus of the present disclosure is provided with the fixed blade and the movable blade sliding against the fixed blade. The fed print-receiving medium is cut by the movable blade moving from the standby position on the lower side to the cutting position on the upper side and sliding against the fixed blade. In this regard, in the present disclosure, a guide device is disposed to further guide the print-receiving medium cut as described above to the downstream side. This guide device includes the upper guide part disposed on the upper side and the lower guide part disposed on the lower side.
The upper guide part includes the contact part at a position separated from the first blade edge of the fixed blade by the first distance in the transport direction and by the second distance in the upper direction. The lower guide part includes the guide surface inclined downward at a predetermined angle toward the downstream side in the transport direction at an interval of the third distance from the contact part. The print-receiving medium usually has a certain degree of rigidity (so-called stiffness), and therefore, when being cut as the movable blades ascends, the medium comes into point contact or line contact from below with the contact part so that the contact portion is restrained from further moving upward, and the medium elastically deforms such that the end portion on the cut side (the upstream side in the transport direction) gradually bends upward. Furthermore, the print-receiving medium comes into contact from above with the guide surface so that the contact portion is thereby restrained from further moving downward, and therefore, an amount of the elastic deformation in the upwardly-bending form significantly increases as the cutting progresses.
As a result, when the print-receiving medium is completely cut, and the elastic deformation rapidly returns to the original state, the end portion of the cut print-receiving medium on the cut side (the upstream side in the transport direction) presses the side surface of the movable blade on the upstream side in the transport direction, and the cut print-receiving medium is discharged due to the reaction force in a pop-out manner from the discharging exit. As a result, according to this embodiment, the cut print-receiving medium can reliably be discharged from the discharging exit without staying in the guide part or the discharging exit.
An embodiment of the present disclosure will now be described with reference to the drawings.
<General Structure of Label Producing Apparatus>
First, an appearance general structure of a label producing apparatus 1 of this embodiment will be described with reference to
In
The housing 2 includes a housing main body 3 and a front panel 6 disposed on a front upper portion of the housing main body 3.
A side wall of the housing main body 3 is provided with a release knob 17 manually operated to the front side by a user to release locking of the upper cover 5 to the housing 2 to make the upper cover 5 openable. A rear wall of the housing main body 3 is provided with an inlet 9 and USB ports 11A, 11B.
The front panel 6 is provided with a discharging exit 6A discharging a print-receiving tape with print (described later) from the inside to the outside of the housing 2. An operation part 7 is disposed on a front upper surface of the front panel 6 and includes buttons such as a power button 7A, a feed button 7B for discharging the print-receiving tape by a predetermined length, and a cutter button 7C causing a cutter unit (described later) to cut the print-receiving tape.
The upper cover 5 includes a roll cover 5A and a side cover 5B attached to the roll cover 5A. The roll cover 5A is pivotally connected at a rear end portion to the housing 2, so that the upper cover 5 has an openable/closable structure with respect to the housing 2.
<Internal Structure of Label Producing Apparatus>
An internal structure of the label producing apparatus 1 will be described with reference to
A roller shaft 66A of a platen roller 66 is rotatably supported by a bracket 65 disposed to both axial ends on the lower side of a front end portion of the roll cover 5A. The platen roller 66 feeds the print-receiving tape 100A fed out from the roll 100 stored in the roll storage part 4. A gear (not shown) driving the platen roller 66 is fixed to one shaft end of the roller shaft 66A.
As shown in an enlarged view of
A print-receiving tape also usable in the label producing apparatus 1 other than the “non-fixed length label” described above is a “die-cut label” having multiple pieces of thermal paper preliminarily cut into a predetermined shape and affixed to a separation sheet by an adhesive layer.
This roll 100 is configured as the print-receiving tape 100A wound into a roll shape such that the print surface of the thermal paper 100a faces radially inward. Consequently, the print-receiving tape 100A is fed out from the upper side of the roll 100 with the print surface of the thermal paper 100a facing downward and is printed by a printing head 61 arranged on the lower side of the print-receiving tape 100A.
The printing head 61 is pivotally supported at an intermediate portion thereof and is fixed to one end of a support member 62 urged upward by a spring member 64. In the figure, a dashed-dotted line indicates a transport path of the print-receiving tape 100A fed out from the roll 100 and fed for receiving a print formed by the printing head 61.
The attachment position of the platen roller 66 in the upper cover 5 corresponds to a position at which the printing head 61 is disposed in the housing 2, and when the upper cover 5 is closed, an urging force of the spring member 64 causes the printing head 61 to press and urge the print-receiving tape 100A to the platen roller 66. Consequently, the print-receiving tape 100A is sandwiched by the platen roller 66 disposed on the upper cover 5 and the printing head 61 disposed on the housing 2 so that a print can be formed by the printing head 61. When the upper cover 5 is closed, the gear of the platen roller 66 meshes with a gear train not shown on the housing 2 side, so that the platen roller 66 can rotationally be driven by a platen-roller motor (not shown) including a stepping motor etc. to feed the print-receiving tape 100A. On the other hand, when the upper cover 5 is opened by the release knob 17, the printing head 61 is separated from the platen roller 66.
A cutter unit 8 is disposed on the downstream side in the transport direction of the printing head 61. The cutter unit 8 includes a fixed blade 46, and a movable blade 47 (see also
An upper guide part 200 and a lower guide part 300 are disposed on the front side of the cutter unit 8 (in other words, on the downstream side in the transport direction). The upper guide part 200 is disposed on a lower portion of the front panel 6, and the lower guide part 300 is disposed on a front-side portion of the housing main body 3. The print-receiving tape 100A having a print formed thereon passes through between the upper guide part 200 and the lower guide part 300 and is fed to the discharging exit 6A while being guided by the guide parts.
<Detailed Structure of Upper Guide Part>
A detailed structure of the upper guide part 200 will be described with reference to
<Detailed Structure of lower Guide Part>
A detailed structure of the lower guide part 300 will be described with reference to
The front region 300A is configured in a form of a substantially rectangular parallelepiped box body, and at least a portion (in this example, the whole) of the inside of the box body is partitioned into multiple spaces D in the left-right direction (in other words, the longitudinal direction of the rectangular parallelepiped) by multiple partition walls 300a each extending in the front-rear direction and arranged in the left-right direction. An upper end portion of each of the partition walls 300a is inclined downward from the rear side toward the front side (see
The rear region 300B is provided with multiple ribs 300c each extending in the front-rear direction and arranged in the left-right direction and has flat plate-like portions 300d between the adjacent ribs 300c, 300c. The ribs 300c and the flat plate-like portions 300d are inclined upward from the rear side toward the front side (see also
<Detailed Structure of Cutter Unit>
A detailed structure of the cutter unit 8 will be described with reference to
The fixed blade 46 has a flat plate shape and includes a blade edge 46a at a lower end (see also
The movable blade 47 has a flat plate shape and includes a substantially V-shaped blade edge 47a at an upper end in a front view (in other words, when viewed in the transport direction of the print-receiving tape 100A). The movable blade 47 is arranged to be made slidable by a cutting motor (not shown) in a cutting direction (from below to above in
<General Operation of Label Producing Apparatus>
When the upper cover 5 is closed and, subsequently, the platen roller 66 is rotationally driven by the platen motor in the label producing apparatus 1 configured as described above, the print-receiving tape 100A is pulled. As a result, the print-receiving tape 100A is fed out from the roll 100. The print-receiving tape 100A fed out from the roll 100 is fed through the transport path to a contact position between the platen roller 66 and the printing head 61. At this point, the printing head 61 is driven and controlled to form a print on the print surface of the thermal paper 100a of the print-receiving tape 100A. Subsequently, the print-receiving tape 100A having the print formed on the thermal paper 100a passes through between the upper guide part 200 disposed on the lower portion of the front panel 6 and the lower guide part 300 disposed on the housing main body 3 and is discharged from the discharging exit 6A onto the front panel 6 while being guided by the guide parts. When the print-receiving tape 100A is extended outward by a predetermined length from the cutter unit 8, the user operates the cutter button 7C, and the print-receiving tape 100A is cut by the cutter unit 8. The user peels off the separation sheet 100c of the cut print-receiving tape 100A and uses the printed heat-sensitive paper 100a as a print label to be affixed to an object (an article etc.).
<Behavior of Adhesive Layer in Cutter Unit>
As described above, in the operation, the movable blade 47 moves from the standby position on the lower side to the cutting position on the upper side and slides against the fixed blade 46 in the cutter unit 8, and the print-receiving tape 100A is thereby cut. In this case, as described above, the print-receiving tape 100A has the thermal paper 100a, the adhesive layer 100b, and the separation sheet 100c laminated in this order from the lower side to the upper side. Therefore, when ascending from the standby position shown in
<Scraping Off of Adhesive Layer>
In this embodiment, regarding the above description, a mechanism scraping off the adhesive adhering to the movable blade 47 is disposed as a first feature. The details thereof will hereinafter be described.
<Scraping-Off Mechanism Disposed on Front Side of Movable Blade>
In this embodiment, a mechanism scraping off the adhesive having adhered to the movable blade 47 is first disposed on the front side relative to the movable blade 47 (in other words, on the downstream side in the transport direction), or specifically, on the lower guide part 300, for example. This scraping-off mechanism of the lower guide part 300 will be described with reference to
As shown in
The lower guide part 300 has a slope part 320 formed on an end portion (a lower end portion in this example) on the one side (the lower side in this example) of the extension part 310. As shown in
Additionally, on the front side relative to the extension part 310 of the lower guide part 300 (in other words, on the downstream side in the transport direction), an accumulating part 330 is disposed as a space opened downward for introducing upward from below and accumulating an adhesive scraped off as described later.
An adhesive scraping-off and accumulating behavior by the extension part 310, the slope part 320, and the accumulating part 330 will be described with reference to
From this state, when the movable blade 47 moves upward toward the cutting position to newly cut the print-receiving tape 100A, a lower end portion of the extension part 310 comes into contact with the adhesive Ad having adhered to the side surface 47b (see
After the adhesive Ad is scraped off as described above, the movable blade 47 subsequently comes into contact with the adhesive layer 100b of the print-receiving tape 100A to be cut at the time of cutting as described above, so that a new adhesive Ad adheres to the side surface 47b of the movable blade 47 (see
Subsequently, when the blade ascends again to cut the new print-receiving tape 100A, the adhesive Ad is scraped off by the lower end portion of the extension part 310 through the same behavior shown in
<Scraping-off Mechanism Disposed on Rear Side of Movable Blade>
In this embodiment, a mechanism scraping off the adhesive having adhered to the movable blade 47 is also disposed on the rear side relative to the movable blade 47 (in other words, the upstream side in the transport direction). Therefore, as shown in
As shown in
Instead of disposing the rectangular extension part 310 elongated in the left-right direction as shown in
<Behavior during Discharge of Print-Receiving Tape>
On the other hand, the print-receiving tape 100A described above usually has a certain degree of rigidity (so-called stiffness). Since the blade edge 47a of the movable blade 47 is substantially V-shaped as described above, the blade edge 47a first starts cutting in the print-receiving tape 100A on both sides in the left-right direction and then gradually cuts through toward the center in the left-right direction, instead of cutting the entire area of the print-receiving tape 100A in the left-right direction at a time. Therefore, after the start of the cutting, the print-receiving tape 100A has a portion on the front side relative to the movable blade 47 and a portion on the rear side relative to the movable blade 47 partially connected to each other until the cutting is completely finished. Thus, as schematically shown in
Subsequently, as schematically shown in
Subsequently, when a portion in contact with the contact part 200p is restrained from further moving upward due to the contact part 200p as the movable blade 47 further ascends, the print label L elastically deforms such that the end portion on the cut side (the upstream side in the transport direction) gradually bends upward as schematically shown in
Subsequently, as the movable blade 47 further ascends, as shown in
As the movable blade 47 further ascends, when the print label L is completely cut, and the elastic deformation rapidly returns to the original state, as schematically shown in
The present inventors found out that, as shown in
As shown in
In the case of the inclination angle θ=15 [°], the print label L was not dischargeable from the discharging exit 6A in the case of the L3=2 [mm], 7 [mm], and 8 [mm]; however, the print label L was favorably dischargeable from the discharging exit 6A in the case of the L3=4 [mm] and 5 [mm]. In the case of the L3=3 [mm] and 6 [mm], both the case of favorable discharge of the print label L from the discharging exit 6A and the non-dischargeable case were mixed.
In the case of the inclination angle θ=25 [°], the print label L was not dischargeable from the discharging exit 6A in the case of the L3=2 [mm], 7 [mm], and 8 [mm]; however, the print label L was favorably dischargeable from the discharging exit 6A in the case of the L3=3 [mm], 4 [mm], 5 [mm], and 6 [mm].
In the case of the inclination angle θ=35 [°], the print label L was not dischargeable from the discharging exit 6A in the case of the L3=2 mm, 3 mm, 7 mm, and 8 mm; however, the print label L was favorably dischargeable from the discharging exit 6A in the case of the L3=4 [mm], 5 [mm], and 6 [mm].
In the case of the inclination angle θ=45 [°], the print label L was not dischargeable from the discharging exit 6A in any case at the L3=2 [mm], 3 [mm], 4 [mm], 5 [mm], 6 [mm], 7 [mm], and 8 [mm].
From the results shown in
3 [mm]≤L1≤4 [mm],
2 [mm]≤L2≤3 [mm],
15 [°]≤θ≤35 [°], and
3 [mm]≤L3≤6 [mm] are more preferable.
As described above, in this embodiment, the scraping-off mechanism is disposed in proximity to the movable blade 47 separately from the movable blade 47 and the fixed blade 46. As a result, the adhesive having adhered to the movable blade 47 is brought into contact therewith and scraped off when the movable blade 47 moves from the lower side to the upper side. Consequently, the adhesive adhering to the movable blade 47 can be reduced by a simple and inexpensive configuration without disposing multiple tapered through-holes in the fixed blade and the movable blade as in the conventional case.
Particularly in this embodiment, the substantially flat plate-like extension part 310 is disposed on the front side of the movable blade 47 to face the movable blade 47, and the slope part 320 is formed on the lower end portion of the extension part 310 and is inclined toward the movable blade 47 while extending to the lower side. As a result, when the movable blade 47 moves from the lower side to the upper side as described above, the adhesive having adhered to the movable blade 47 can be scooped by the extension part 310 and the slope part 320 to scrape off more adhesive.
Particularly in this embodiment, the movable blade 47 is substantially V-shaped when viewed from the front or the rear, and the extension part 310 has a rectangular shape elongated in the left-right direction orthogonal to the sliding direction when viewed from the front or the rear. Therefore, while the movable blade 47 is substantially V-shaped, the extension part 310 has a rectangular shape, which is a different shape. This results in a form of sequentially scraping off the adhesive having adhered to the movable blade 47 along the V shape, rather than scraping off the adhesive having adhered to the movable blade 47 at one time, when the extension part 310 scrapes off the adhesive having adhered to the movable blade 47. Consequently, the weight (load) acting on the extension part 310 can be prevented from being excessively increased during scraping off.
Particularly in this embodiment, when the movable blade 47 is at the standby position in the case of the configuration in which the extension part 310 has a substantially inverted-triangular shape in the front view, the lower end portion of the extension part 310 is located at a position lower than the upper end portion (i.e., the blade edge 47a) of the movable blade 47. This has the following technical significance.
The adhesive scraped off from the movable blade 47 as described above stays at the lower end portion of the extension part 310 (see
In this embodiment, since the lower end portion of the extension portion 310 is located at a position lower than the upper end portion of the movable blade 47, the adhesive staying at the lower end portion of the extension portion 310 does not reattach to the blade edge 47a of the movable blade 47. Consequently, contamination of the blade edge 47a of the movable blade 47 can be prevented, so that the cutting performance of the movable blade 47 can favorably be maintained.
Particularly in this embodiment, the accumulating part 330 introducing and accumulating the scraped adhesive is disposed. Therefore, the accumulating part 330 can sequentially introduce and accumulate the adhesive scraped off from the movable blade 47, so that even in the case that the cutting operation is performed a number of times and the adhesive has adhered to the movable blade 47 each time, the remaining adhesive having adhered to the movable blade 47 can be reduced.
Particularly in this embodiment, the extension portion 310 and the slope part 320 are disposed for scraping off the adhesive on the front side of the movable blade 47 (in other words, on the side of the movable blade 47 opposite to a surface rubbed with the fixed blade 46) as described above, along with the scraping-off plate 400 for scraping off the adhesive on the rear side of the fixed blade 46 (in other words, on the side of the fixed blade 46 opposite to a surface rubbed with the movable blade 47). Therefore, the adhesive having adhered to both sides of the movable blade 47 can be scraped off by both the parts and the plate.
Particularly in this embodiment, the lower guide part 300 including the extension part 310 and the slope part 320 as well as the scraping-off plate 400 all have the function as a guide part guiding the feeding of the print-receiving tape 100A. As a result, the structure can be miniaturized as compared to the case that the guide part is separately disposed.
In this embodiment, the upper guide part 200 has the contact part 200p disposed in a position separated from the blade edge 46a of the fixed blade 46 by L1 in the transport direction and by L2 in the upper direction, and the lower guide part 300 has the guide surface 300s inclined downward by θ toward the downstream side in the transport direction and disposed at a distance of L3 from the contact part 200p in the direction perpendicular to the inclined direction.
As a result, as described above with reference to
Particularly in this embodiment, on the basis of the results of study on discharge performance of the print label L described above shown in
Particularly in this embodiment, the contact part 200p includes the corner portion on the rear side of the lower end surface of the rear wall part 201 of the upper guide part 200 that is a substantially rectangular parallelepiped box body partitioned by the multiple partition walls 200a (see
Particularly in this embodiment, the guide surface 300s of the lower guide part 300 includes surfaces comprising the upper slopes of the partition walls 300a of the front region 300A that is a substantially rectangular parallelepiped box body partitioned by the multiple partition walls 300a (see
Particularly in this embodiment, the print-receiving tape 100A printed and fed through cooperation between the platen roller 66 and the printing head 61 can be cut by the cutter unit 8 to produce the print label L in the label producing apparatus 1.
It is noted that terms “vertical”, “parallel”, “plane”, etc. in the above description are not used in the exact meanings thereof. Specifically, these terms “vertical”, “parallel”, “plane”, etc. allow tolerances and errors in design and manufacturing and have meanings of “substantially vertical”, “substantially parallel”, and “substantially plane”, etc.
It is noted that terms “same”, “equal”, “different”, etc. in relation to a dimension and a size of the appearance in the above description are not used in the exact meaning thereof. Specifically, these terms “same”, “equal”, and “different” allow tolerances and errors in design and manufacturing and have meanings of “substantially the same”, “substantially equal”, and “substantially different”.
The techniques of the embodiment and modification examples may appropriately be utilized in combination other than those described above.
Number | Date | Country | Kind |
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2017-141376 | Jul 2017 | JP | national |
Number | Name | Date | Kind |
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8506190 | Kohira | Aug 2013 | B2 |
8662771 | Kawaguchi | Mar 2014 | B2 |
8702331 | Suzuki | Apr 2014 | B2 |
20090025524 | Kasugai et al. | Jan 2009 | A1 |
20170144457 | Hoshino | May 2017 | A1 |
Number | Date | Country |
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2009-045921 | Mar 2009 | JP |
Number | Date | Country | |
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20190023032 A1 | Jan 2019 | US |