Any and all applications for which a foreign or domestic priority claim is identified in the Application Data Sheet as filed with the present application are hereby incorporated by reference under 37 CFR 1.57.
The present inventions relate to cutting machines.
Japanese Unexamined Patent Application Publication 1990-262995 discloses a method for controlling a blade of a cutting machine wherein, when changing the direction of the cutting blade, the cutting blade is first lifted away from the material being cut, and moved to the starting position for the next cut prior to execution of the next cutting operation in a different direction.
Japanese Unexamined Patent Application Publication 1995-39229 discloses a cutter which performs a so-called “perforation cut,” wherein perforations are formed along a line for making a sheet material tearable. In this publication, the perforations are formed in a sheet material by reducing, for a brief interval or regular time intervals, the tool pressure of a cutter that is pressed against the sheet, to produce a state wherein the cutter rides over the sheet surface or moves partially within the sheet.
With some known cutters, such as those described in Japanese Unexamined Patent Application Publication 1990-262995 and 1995-39229, when changing the direction along which the cutter cuts a sheet from one direction to another direction, if the angle of the change in direction is large, the blade of the cutter might get caught on the sheet, or it might not be possible to change the direction smoothly, or the blade of the cutter might become bound with the sheet material at the position where the direction is changed.
Cutting machines disclosed herein can comprise a supporting platform, a cutter, a cutter carriage, a moving mechanism, and a controlling device. The cutter can have a shaft and a blade that is formed at a tip end of the shaft. The cutter carriage can have a holding portion for holding the shaft of the cutter so as to enable rotation. The moving mechanism can be a mechanism for moving the cutter carriage relative to the supporting platform.
The controlling device can be configured so that the following processes (a) through (c) are executed:
Such a cutting machine can create a sharper, cleaner corner portion where a cutting line includes a corner.
Embodiments of cutting machines disclosed herein are explained below in reference to the drawings. Note that the embodiments explained herein are, of course, not intended to limit the present inventions.
The cutting machine 100 comprises a supporting platform 10, a cutter 20, a cutter carriage 30, a moving mechanism 40, and a controlling device 50. In
The supporting platform 10 is a member on which the cutting material is placed. The supporting platform 10 has, for example, a supporting face 11 on which is placed the material that is to be cut, which can be a sheet material. The cutter 20 is a member for cutting the material that is to be cut.
The cutter carriage 30 comprises a holding portion 31 and a solenoid 32.
In the explanation below,
In the present embodiment, the solenoid 32 has a bobbin 32a onto which a coil is wound, and a movable core 32b (plunger) that is inserted into the bobbin 32a. The stroke direction of the movable core 32b is oriented in the direction that is perpendicular to the supporting platform 10. In this embodiment, an arm 32c is attached to the movable core 32b. The arm 32c extends downward, on the outside of the bobbin 32a, from the top end of the movable core 32b. A clamp 32d, for gripping the bearing 31b of the holding portion 31, is attached to the bottom end portion of the arm 32c.
Moreover, the cutter carriage 30 further comprises a spring 33, a shock absorbing material 34, and a first substrate 35 on which is mounted circuitry for operating the solenoid 32. The electric circuit depicted in
The shock absorbing material 34 is disposed above the arm 32c. The shock absorbing material 34 may be, for example, rubber. When power is applied to the solenoid 32 so as to apply a force to pull the arm 32c upward, the arm 32c is pulled upward vigorously. The shock absorbing material 34 is attached to a member that is disposed above the arm 32c, to mitigate the noise that is produced when the arm 32c strikes the member that is disposed thereabove. Moreover, even when no power is applied to the solenoid 32, the arm 32c is pulled upward, through the effect of the spring 33, to a position wherein it strikes the shock absorbing material 34.
The moving mechanism 40 is a mechanism that can be configured to move the cutter carriage 30 relative to the supporting platform 10. In the moving mechanism 40, the cutter carriage 30 may be supported in respect to the supporting platform 10 so that the shaft 21 of the cutter 20 will face a direction that is perpendicular to the flat face of the supporting platform 10.
For example, the moving mechanism 40 can be structured so as to move the cutter carriage 30 to an appropriate position with respect to an XY coordinate system that is set parallel to the flat portion of the stationary supporting platform 10 onto which the cutting material 200 is placed. In some embodiments, a first mechanism is configured to move the cutter carriage 30 in the X direction, and a second mechanism is configured to move the cutter carriage 30 in the Y direction. The first and second mechanisms can be combined together. For example, in the first mechanism, the cutter carriage 30 can be attached to a first guide shaft that is disposed along the X direction. In the second mechanism, the first mechanism can be attached to a second guide shaft that is disposed along the Y direction.
Additionally, the configuration may be such that the cutter carriage 30 is moved also in respect to a Z-axis that is perpendicular to the flat portion whereon the cutting material 200 is placed. Note that the moving mechanism 40 is not limited to the form described above. The moving mechanism 40 can instead be a mechanism wherein the supporting platform 10 is moved relative to the cutter carriage 30. Moreover, it can instead be a mechanism for moving both the cutter carriage 30 and the supporting platform 10. For example, it may be a mechanism for moving the cutter carriage 30 in one or two of the directions of an XYZ coordinate system, and for moving the supporting platform 10 in the other direction or directions. Note that while here an orthogonal coordinate system is presented as an example, the movement need not necessarily be along an orthogonal coordinate system. Other coordinate systems can also be used.
The controlling device 50 can be embodied in, for example, a computer that is operated according to a program that has been established in advance. For example, the various functions of the controlling device 50 can be processed through various calculating devices of a computer (also known as a “processors,” “CPUs” (Central Processing Units) or “MPUs” (Micro Processing Units)), and storing devices (memories, hard disks, and the like), that define structures within the controlling device 50, in cooperation with software. For example, each of the structures and processes of the controlling device 50 may be embodied in a whole or in part by databases and data structures that store, in a predetermined form, data that is embodied by the computer, processing modules that carry out prescribed calculation processes following programs that have been established in advance, and the like. The controlling device 50 can also be referred to as a “controller”.
The first setting portion 50a1 can be programmed so as to set cutting lines S1 through S5 with respect to the cutting material 200 that is placed on the supporting platform 10.
Here the cutting lines S1 through S5 can each be set as paths for the shaft 21 of the cutter 20, in instructions for the cutter carriage 30, for example. In such embodiments, as depicted in
The position wherein the tip end 22a of the blade 22 contacts the cutting material 200 may be calculated from the position of the shaft 21 of the cutter 20. That is, the tip end 22a of the blade 22 will be to the rear of the centerline X1 of the shaft 21 of the cutter 20, in the direction of forward movement of the blade 22 of the cutter 20, by the offset distance (offset distance X2) of the tip end 22a of the blade 22. The controlling device 50 can store the offset distance X2 of the cutter 20 in advance. When the position of the shaft 21 of the cutter 20 is controlled by the movement of the cutter carriage 30, the position of the tip end 22a of the blade 22, with respect to the cutting material 200, is calculated depending on this offset distance X2. This enables control of the position at which the blade 22 of the cutter 20 contacts the cutting material 200.
With continued reference to
The first processing portion 71 can be structured so that a first step will be executed. If the cutting line S1 through S5 has at least one corner portion Sc wherein the direction changes, the first step can be a step for moving the blade 22 of the cutter 20 along one cutting line that arrives (or “ends”) at the corner portion Sc. In this first step, the blade 22 of the cutter 20 is pressed against the cutting material 200, at at least a portion of one cutting line that arrives at the corner portion Sc, with a force that is set in advance so that the cutting material 200 will be cut.
The second processing portion 72 can be structured so as to execute a second step. The second step can be a step for lifting the tip end 22a of the blade 22 of the cutter 20 away from the cutting material 200, after the first step.
In this second step, the tip end 22a of the blade 22 of the cutter 20 can be lifted away from the cutting material 200, that is, the tip end 22a of the blade 22 of the cutter 20 being separated from the cutting material 200. By separating the cutter 20 from the cutting material 200, the contact between the cutter 20 and the cutting material 200 can be suspended, temporarily. When the contact between the cutter 20 and the cutting material 200 is suspended, the shaft 21 of the cutter 20 becomes free to move in any direction with the holding portion 31.
In this second step, the tip end 22a of the blade 22 of the cutter 20 would normally be separated or spaced from the cutting material 200. However, it is possible that in some circumstances, when the cutting material 200 is cut by the cutter 20 in the first step, the tip end 22a of the blade 22 of the cutter 20 can become wedged in the cutting material 200. When the tip end 22a of the blade 22 of the cutter 20 is wedged as such and lifted from the cutting material 200, a small frictional force may act between the tip end 22a of the blade 22 of the cutter 20 and the cutting material 200. When this frictional force is present, the cutting material 200 can be pulled upwardly together with the tip end 22a of the blade 22 that is pulled up, so that the cutter 20 and the cutting material 200 remain in contact.
In some embodiments, the structure is such that, in the second step, the cutter 20 is held for a predetermined time interval, in a state wherein it is lifted from the cutting material 200. Maintaining the state wherein the cutter 20 is lifted from the cutting material 200 enables the cutter 20 to be separated more reliably from the cutting material 200 despite the presence of a frictional force between the cutter 20 and the cutting material 200.
In some embodiments, the time interval during which the state wherein the cutter 20 is lifted from the cutting material 200 can be, for example, 10 ms or more. This time is not limited thereto, but can be, for example, 20 ms or more. In other embodiments, this time can be set to 50 ms or more. Note that the time interval during which the cutter 20 is lifted from the cutting material 200 is maintained can be set to a time that can sufficiently reliably separate the cutter 20 from the cutting material 200. The longer the time interval during which the state wherein the cutter 20 is lifted from the cutting material 200 is maintained, the longer the cycle time for cutting the cutting material 200. Because of this, the time interval during which the state wherein the cutter 20 is lifted from the cutting material 200 is maintained need not be set to a time that is longer than necessary.
The time interval during which the state wherein the cutter 20 is lifted from the cutting material 200 is maintained can be set to an appropriate time determined by carrying out testing in advance. Moreover, the configuration may be such that the time interval that is set in advance in the second step can be set by a user. The time interval during which the cutter 20 is lifted from the cutting material 200 is maintained may differ depending on the frictional force that acts between the cutter 20 and the cutting material 200. The separation of the cutter 20 from the cutting material 200 can be set more reliably through the time being set appropriately by the user.
Although not shown in the drawings, the cutting machine 100 can be provided with a detecting portion for detecting whether or not the cutter 20 has been separated from the cutting material 200. This detecting portion can comprise a distance measuring sensor provided on the cutter carriage 30, configured to measure the distance between the cutter carriage 30 and the cutting material 200. As such, the output of the sensor can used as an indication of whether or not the cutting material 200 has been pulled up together with the cutter 20. Moreover, the cutting material 200 being pulled up together with the cutter 20 may be detected instead based on an image captured by a camera that can be provided on the cutter carriage 30. Whether or not the cutter 20 has been separated from the cutting material 200 can instead be detected by detecting the reaction force received from the shaft 21 of the cutter 20 in the holding portion 31 that holds the shaft 21 of the cutter 20.
In some embodiments, the third processing portion 73 is structured so as to execute a third step. The third step can be a step wherein the blade of the cutter 20 is brought into contact with the cutting material 200 with a force that has been set in advance so that the cutting material 200 will not be cut, and is caused to face along the other cutting line of the corner portion Sc, following the second step. Because contact between the cutter 20 and the cutting material 200 was temporarily suspended in the second step, in the third step the blade 22 of the cutter 20 can be directed along the other cutting line of the corner portion Sc smoothly.
The fourth processing portion 74 can be structured so as to execute a fourth step. The fourth step can be a step for causing the blade 22 of the cutter 20 to press against the cutting material 200 with a force that has been set in advance, and moving along the other cutting line of the corner portion Sc so that the cutting material 200 will be cut at at least a portion of the other cutting line of the corner portion Sc, after the third step. In the fourth step, the cutting material 200 can be cut along the other cutting line of the corner portion Sc by the blade 22 of the cutter 20.
In some embodiments, the tip end 22a of the blade 22 is offset from the shaft 21, as depicted in
Note that the cutter 20 is actually in a state wherein the shaft 21 of the cutter 20 is perpendicular to the cutting line Sc21, erect in respect to the cutting material 200. For convenience in explanation,
As depicted in
The first step ends when the tip end 22a of the blade 22 of the cutter 20 has arrived at the corner portion Sc2, as depicted in
Following this, in the third step, the blade of the cutter 20 is caused to contact the cutting material 200 with a force that is set in advance so that the cutting material 200 will not be cut.
At this time, as depicted in
Following this, in the third step, the blade 22 of the cutter 20 is caused to face the other cutting line Sc22 of the corner portion Sc2 in a state where, in this way, the tip end 22a of the blade 22 of the cutter 20 is in contact with the cutting material 200. In this embodiment, as depicted in
In this way, given the cut processing portion 70, in the first step, the blade 22 of the cutter 20 is pressed against the cutting material 200 with a force that is set in advance so that the cutting material 200 will be cut, and moved along one cutting line Sc21 that arrives at the corner portion Sc2. Through the second step, the blade 22 of the cutter 20 is lifted from the cutting material 200, to be separated from the cutting material 200, causing the shaft 21 of the cutter 20 to be free. Thereafter, in the third step, the blade 22 of the cutter 20 is caused to contact the cutting material 200 with a force that is set in advance so that the cutting material 200 will not be cut. Following this, the blade of the cutter 20 is caused to face the other cutting line Sc22 of the corner portion Sc2. Through the second step and the third step, the blade 22 is faced smoothly in the direction along the other cutting line Sc22 of the corner portion Sc2. The fourth step is executed thereafter. In the fourth step, the blade 22 of the cutter 20 is pressed against the cutting material 200 with a force that is set in advance so that the cutting material 200 will be cut, and moved along the other cutting line Sc22 of the corner portion Sc2. As a result, the corner portion Sc2 of the cutting material 200 will be cut cleanly along the cutting lines Sc21 and Sc22.
Here the first step and the fourth step may be structured so that die cuts and half cuts are repeated sequentially.
Here a “die cut” is a process wherein the blade 22 of the cutter 20 is caused to contact the cutting material 200 with a force that is set in advance so that the cutting material 200 will be cut fully through the thickness of the material 200 or through only a predetermined number of distinct layers of the sheet material, for example, cuts that define intended contours of the edges of one, a plurality, or all of the layers of the sheet material 200. A “half cut” or “superficial cut” is a process wherein the blade of the cutter 20 is caused to contact the outer surface of the cutting material 200 with a force that is set in advance so that the cutting material 200 will not be cut completely through the full thickness of the material 200 or any layer of the material 200, thereby either not cutting at all or only superficially cutting the outer surface of the material 200. That is, in a “die cut” the cutting material 200 is cut. In contrast, the cutting material 200 is not cut in a “half cut.”
Repeating die cuts and half cuts will result in perforations wherein locations that are cut completely though the thickness of one or more layers the material 200 and locations that are not cut completely through the thickness of any layer of the material 200 will be produced alternatingly. In this way, the first step and the fourth step may be configured so that perforations are formed in the cutting material 200 along the cutting line. That is, when the cutting lines S1 through S5 form a closed region, as depicted in
Note that in the perforations, the places wherein the cutting material 200 is not cut, through the half cuts, should be set so as to be adequately short when compared to the places wherein the cutting material 200 is cut by the die cuts. For example, the lengths of the places that are not cut, through the half cuts (the half cut lengths) may be about 1/10, or more preferably, 1/50, or even more preferably 1/100 the lengths of the places in the cutting material 200 that are cut through die cuts (die cut length). For example, if the die cut length is 50 mm, the half cut length may be 0.5 mm. The configuration may be such that the user is able to set appropriate lengths for the die cut length and the half cut length.
Here the first storing portion 50b1 of the controlling device 50 (referencing
Moreover, the second storing portion 50b2 stores a force that is set in advance so that the cutting material 200 will not be cut. The force that is set in advance so that the cutting material 200 will not be cut may be, for example, stored in advance in the second storing portion 50b2. A plurality of forces, set in advance so that the cutting material 200 will not be cut, depending on the cutting material 200, the cutter 20, and conditions such as the temperature, may be stored in the second storing portion 50b2 in advance. Moreover, the configuration may be such that the force that is set in advance so that the cutting material 200 will not be cut may be set as appropriate by a user depending on the cutting material 200, the cutter 20, and conditions such as the temperature. Note that the force that is set in advance so that the cutting material 200 will not be cut may be termed the “half-cut pressure” arbitrarily.
Additionally, the force that is set in advance so that the cutting material 200 will be cut may be determined depending on the cutting material 200. For example, the cutting material 200 may be a backing sheet with a seal affixed thereto. In this case, a first force that is set so as to cut only the seal that is affixed to the backing sheet, and a second force that is set so as to cut, for the individual backing sheet, the backing sheet to which the seal is affixed, may be set as respective forces that are set in advance so that the cutting material 200 will be cut. The first force and the second force may be selected as appropriate following a program that is established in advance. This enables the seal to be cut alone, or to be cut together with the backing sheet. In this case as well, when there is at least one corner portion Sc1, Sc2 wherein the cutting line S1 changes direction, the second step, for lifting the blade of the cutter 20 from the cutting material 200, should be performed at the corner portion Sc1, Sc2. In this way, the force that is set in advance so that the cutting material 200 will be cut may be set with a plurality of forces. This enables cutting the cutting material 200 appropriately, depending on a variety of cutting materials 200.
The steps performed by the cut processing portion 70 are explained below.
With continued reference to
The second setting portion 50a2, as depicted in
The configuration can be such that, after the second step, when the blade turning path Sd1 is set in this way, then in the third step by the cut processing portion 70, the blade 20 of the cutter is caused to contact the cutting material 200 with a force that has been set in advance so that the cutting material 200 will not be cut, and is moved so as to arrive at the other cutting line Sc12 of the corner portion Sc1 following the blade turning path Sd1.
In the example depicted in
Note that the blade turning path Sd1 should be a path such that the tip end 22a of the blade 22 of the cutter 20 follows smoothly in the blade turning process, to change the direction from the one cutting line Sc11 to the other cutting line Sc12 of the corner portion Sc1. From this perspective, the blade turning path Sd1 should be set to a curve that connects smoothly the one cutting line Sc11 and the other cutting line Sc12 of the corner portion Sc1. The blade turning path Sd1 is not limited to the shape depicted in
In this embodiment, the first processing portion 71 is structured so as to execute the first step for pressing the blade 22 of the cutter 20 against the cutting material 200 with the force that has been set in advance so that the cutting material 200 will be cut, and moving the blade 22 of the cutter 20 along the one cutting line Sc11 that arrives at the corner portion Sc1.
The second processing portion 72 is structured so as to execute the second step for lifting the tip end 22a of the blade 22 of the cutter 20 from the cutting material 200 after the first step.
In this second step, the tip end 22a of the blade 22 of the cutter 20 should be lifted away from the cutting material 200, that is, the tip end 22a of the blade 22 of the cutter 20 should be separated from the cutting material 200. Through separating the cutter 20 from the cutting material 200, the contact between the cutter 20 and the cutting material 200 is removed temporarily. When the contact between the cutter 20 and the cutting material 200 is eliminated temporarily, the shaft 21 of the cutter 20 becomes free to rotate within the holding portion 31.
The third processing portion 73 is structured so as to execute a third step wherein, following the second step, the blade 22 of the cutter 20 is brought into contact with the cutting material 200 with a force that has been set in advance so that the cutting material 200 will not be cut, and is caused to move along the blade turning path Sd1, to arrive at the other cutting line of the corner portion Sc1. After contact between the cutter 20 and the cutting material 200 temporarily removed in the second step, the blade 22 of the cutter 20 is directed along the path Sd1 smoothly when entering into the blade turning path Sd1 in the third step.
The fourth processing portion 74 is structured so as to execute, after the third step, a fourth step wherein the blade 22 of the cutter 20 is brought into contact with the cutting material 200 with a force that has been set in advance so that the cutting material 200 will be cut, and is moved along the other line of the corner portion Sc1.
In the fourth step, the cutting material 200 can be cut along the other cutting line of the corner portion Sc1 by the blade 22 of the cutter 20.
In this way, when the cutting line S1 has at least one corner portion Sc1 wherein the direction changes, the blade turning path Sd1 that is made from a curve that connects together the one cutting line Sc11 and the other cutting line Sc12, which intersect at the corner portion Sc1, set in the vicinity of the corner portion Sc1. Additionally, after the first step, the configuration should be such that, in the second step, the tip end 22a of the blade 22 of the cutter 20 is lifted away from the cutting material 200. Additionally, the configuration should be such that, in the third step, the blade of the cutter 20 is caused to contact the cutting material 200 with a force that is set in advance so that the cutting material 200 will not be cut, and such that the blade of the cutter 20 will follow the blade turning path Sd1 to arrive at the other cutting line Sc12 of the corner portion Sc1.
Through this, the direction of the blade 22 of the cutter 20 will change smoothly, at the corner portion Sc1, from the direction of the one cutting line Sc11 to the direction of the other cutting line Sc12. Note that there may be programming in advance so that the blade turning path Sd1 will be set as appropriate depending on conditions that are determined in advance, such as the angle of the corner portion Sc1. Consequently, the direction of the blade may be changed without setting the blade turning path as the path for the tip end 22a of the blade 22 of the cutter 20 depicted in
In the mode depicted in
Following this, the blade 22 is moved, with a half-cut pressure, along the blade turning path Sd1 in the third step, moving the blade so as to arrive at the other cutting line Sc12 of the corner portion Sc1. Through this, the blade 22 will be in the direction of the other cutting line Sc12. Moreover, in the fourth step, perforations are first formed, with the half-cut pressure, along the other cutting line Sc12 from the point of intersection at the corner portion Sc1. Through this, perforations are cut with a part Sc14, along the other cutting line Sc12 from the point of intersection at the corner portion Sc1, connected, as depicted in
In the mode depicted in
Following this, the blade is moved, with a half-cut pressure, along the blade turning path Sd1 in the third step, moving the blade so as to arrive at the other cutting line Sc12 of the corner portion Sc1. Through this, the blade 22 will be in the direction of the other cutting line Sc12. Moreover, in the fourth step, perforations are first formed, with the die-cut pressure, along the other cutting line Sc12 from the point of intersection at the corner portion Sc1. Through this, perforations are cut with a part Sc13, along the one cutting line Sc11 from the point of intersection at the corner portion Sc1, connected, as depicted in
In the mode wherein cutting is as in
In the mode depicted in
Following this, the blade is moved, with a half-cut pressure, along the blade turning path Sd1 in the third step, moving the blade so as to arrive at the other cutting line Sc12 of the corner portion Sc1. Through this, the blade 22 will be in the direction of the other cutting line Sc12. Moreover, in the fourth step, perforations are first formed, with the half-cut pressure, along the other cutting line Sc12 from the point of intersection at the corner portion Sc1. Through this, perforations are cut with parts Sc13 and Sc14, along both the cutting lines Sc11 and Sc12 from the point of intersection with the corner portion Sc1, connected, as depicted in
In the mode depicted in
Following this, the blade is moved, with a half-cut pressure, along the blade turning path Sd1 in the third step, moving the blade so as to arrive at the other cutting line Sc12 of the corner portion Sc1. Through this, the blade 22 will be in the direction of the other cutting line Sc12. Moreover, in the fourth step, perforations are first formed, with the die-cut pressure, along the other cutting line Sc12 from the point of intersection at the corner portion Sc1. Through this, as depicted in
In this case, the corner portion Sc1 of the cutting material 200 is cut, so the corner portion Sc1 will tend to be cut apart cleanly. Note that the shorter the distance to the place that is connected by the half-cut pressure from the point of intersection at the corner portion Sc1 that is set, the less the likelihood of the corner portion Sc1 of the cutting material 200 will shift during processing by the cut processing portion 70. In this case, the configuration may be one wherein the distance on the one cutting line Sc11 from the point of intersection at the corner portion Sc1 to the place Sc15 that is connected with the half-cut pressure, and the distance on the other cutting line Sc12 from the point of intersection at the corner portion Sc1 to the place Sc16 that is connected with the half-cut pressure are each set as appropriate by the user.
Note that while here an example is presented as a cutting machine 100, the cutting machine 100 that is disclosed here may be applied appropriately to a printer. In this case, the cutting material 200 may be any of a variety of types of media that are printed by the printer.
This enables achievement of perforation cutting wherein only the seal is cut, and perforation cutting wherein the backing sheet 201 and the seal 202 are cut, and, through combining the processes for the cut processing portion 70, described above, even when a corner portion exists in a cutting line that has been set, the corner portion can be processed cleanly.
When a cutting machine 100 is incorporated into a printer in this way, the platen upon which the medium is placed in the printer may be used as the supporting platform 10 for the cutting machine 100. The cutter carriage 30 may be installed on the carriage for moving the printer head. This enables the moving mechanism that moves the carriage of the printer head in respect to the media to be used as the moving mechanism 40 for the cutting machine 100.
The printer into which the cutting machine 100 is incorporated, as described above, is able to form perforations along the cutting lines. The medium is not cut completely through the perforations. Because of this, the printing may be carried out on the medium after formation of the perforations along the cutting lines of the medium made in advance, through the functions of the cutting machine 100. Moreover, instead the perforations may be formed along the cutting lines that have been set for the medium, or the medium may be cut at prescribed positions, through the functions of the cutting machine 100 after printing has been performed on the medium.
The cutting material 200 of the cutting machine 100 may be include a seal with a backing sheet. In order to handle such a case, a plurality of different forces may be set in advance in the controlling device 50 of the cutting machine 100, for cutting of the cutting material 200.
As described above, in the cutting machine 100 or printer that is disclosed here, the controlling device 50 may be configured so as to execute the following steps (a) through (c), for example, in the process for cutting a corner portion. Additionally, the disclosure here, as another aspect thereof, may be a program for causing the controlling device of the cutting machine 100 or the printer to execute the steps of (a) through (c), below. Furthermore, this program may be recorded on a non-transitory computer readable medium. The explanation here will be based on the drawings presented in
Steps (a) through (c) (referencing
Moreover, as depicted in
Steps for (b) through (c):
Given this cutting machine, for one cutting line, of a first cutting line Sc11 and a second cutting line Sc12 that form a corner portion Sc1, a part Sc13 is left connected, without the cutting material being cut, for a distance that is set in advance from the point of intersection of the corner portion. From this point of view, there is no particular limitation on how the cutting material 200 controls the sequence or blade for cutting the cutting line.
In
In
In
In step (b), a connected part is left, without the cutting material being cut, for a distance that is set in advance from the point of intersection with the corner on a cutting line that is either the first cutting line or the second cutting line that form the corner portion of the cutting material, and the cutting material is cut along the one cutting line, except for the connected part. In step (c), the cutting material is cut along the other cutting line so as to not leave a connected part up to a distance that has been determined in advance from the point of intersection of the corner. In these steps (b) and (c), there is no particular limitation in how the blade is moved, or the sequence in which the first cutting line and the second cutting line are cut, and these may be modified as appropriate.
While, in the above, various explanations have been made regarding one embodiment of the cutting machine that is disclosed here, the cutting machine that is disclosed here is not limited to the embodiment described above. Moreover, the cutting machine disclosed here may be modified in a variety of ways, insofar as no particular problems are produced, and the various structural elements and various steps referenced here may be omitted as appropriate or combined as appropriate.
Number | Date | Country | Kind |
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2018-225391 | Nov 2018 | JP | national |
Number | Date | Country | |
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Parent | PCT/JP2019/046435 | Nov 2019 | US |
Child | 16874487 | US |