1. Field of the Invention
The invention relates to an apparatus and method for making labels and for performing a plurality of half cuttings on a sheet before performing a full cutting, using one cutter.
2. Description of the Related Art
Label making apparatuses for processing a laminated tack sheet of an adhesive sheet and a releasable sheet are known. In such a label making apparatus, a rolled sheet unit that supports the sheet wound around a core is detachably attachable. The label making apparatus includes a transport roller for pulling out the sheet from the rolled sheet unit and transporting the sheet and a cutting mechanism that cuts the sheet transported by the transport roller.
The cutting mechanism generally includes a cutter that cuts the sheet, and a carriage that reciprocates the cutter in a direction substantially perpendicular to a sheet transport direction (a width direction of the sheet). Therefore, by normal and reverse rotation of the transport roller and the reciprocation of the carriage in the width direction of the sheet, the cutter can be placed at any position on the sheet and cut the sheet into a predetermined shape.
There is a label making apparatus capable of cutting the sheet in two different manners. One manner is a half cutting in which the sheet is cut partway in a direction of a thickness of the sheet, for example, only the adhesive sheet or the releasable sheet of the sheet is cut. Another manner is a full cutting in which the sheet is completely cut in the direction of the thickness of the sheet. Further, there is a label making apparatus provided with two cutters in which one cutter is for the half cutting and the other cutter is for the full cutting. Furthermore, a label making apparatus that can perform both the half cutting and the full cutting using one cutter exists, as disclosed in Japanese Utility Model Publication No. 2-14952.
However, the currently known label making apparatus that can perform both the half cutting and full cutting on a sheet using one cutter cannot perform a plurality of half cuttings on the sheet before performing the full cutting. Therefore, a plurality of labels made using such a label making apparatus are separated into pieces by a full cutting. Because of this, it becomes extremely inconvenient to handle these labels when printed contents of the labels are related to each other, such as when the labels are serially numbered.
On the other hand, in the label making apparatuses provided with two cutters in which one cutter is for half cutting and the other cutter is for full cutting, there is a label making apparatus that can perform a plurality of half cuttings before performing a full cutting on a sheet. However, in this case, the label making apparatus has two cutters, so that a structure of the apparatus becomes complicated. Further, the full cutting and the half cutting are performed at a different position, so that, for example, the sheet needs to be stopped at an appropriate position when any cutting is performed. Accordingly, a control of the apparatus also becomes complicated.
Japanese Utility Model Publication No. 2-14952 discloses a label making apparatus that can perform both the half cutting and the full cutting using one cutter. However, the label making apparatus is provided with an electric drive, such as a solenoid, in a cutting unit to adjust a vertical position of the cutter. Therefore, the structure of the label making apparatus is complicated.
A simple structure label making apparatus having one cutter that can make a plurality of labels which are easy to handle has not known yet been developed.
According to the invention, an apparatus and method for making labels are provided which can make a plurality of labels which are easy to handle using one cutter with a simple structure.
Further, according to the invention, an apparatus and method for making labels are provided which can switch a state of the one cutter back and forth between a full cutting state and a half cutting state with a simple structure.
In various exemplary embodiments of the invention, a label making apparatus that makes labels by performing a full cutting and a half cutting on a sheet includes a cutter that cuts the sheet along a desired line, a switching device that switches a state of the cutter capable of performing the full cutting and the half cutting on the sheet between a full cutting state and a half cutting state, and a controller that controls the switching device so that the half cutting is performed at least twice on the sheet before the full cutting is performed thereon.
Further, a label making method for making labels by performing a full cutting and a half cutting on a sheet using one cutter capable of selectively performing the full cutting and the half cutting includes repeatedly half cutting on the sheet along desired lines and transporting the sheet until the predetermined number of half cut lines are formed on the sheet, switching a state of the cutter to a full cutting state in which the cutter can perform the full cutting on the sheet, and full cutting the sheet along a desired line using the cutter.
With this arrangement, before a full cutting is performed on a sheet, a half cutting is performed at least twice. Therefore, when making a plurality of labels whose printed contents are related to each other, such as serially numbered labels, the labels do not come apart. Consequently, a strip of labels that is convenient to handle can be obtained. Further, a strip of labels including a plurality of labels that are continuously connected to each other by half cut lines without wasted portions therebetween can be obtained. Therefore, the sheet can be prevented from being wasted.
Further, the label making apparatus performs the full cutting and the half cutting using one cutter by switching the state of the cutter. Therefore, only one drive source is needed, so that the structure of the label making apparatus can be simplified. In addition, the full cutting and the half cutting are performed at the same position, so that the control, such as stopping the sheet when cutting, can be performed with relative ease.
In various exemplary embodiments of the invention, the cutter can be supported by a self-propelled cutting unit, the state of the cutter can be switched between the full cutting state and the half cutting state at ends of a traveling path of the self-propelled cutting unit, the switching device can achieve one of the full cutting state and the half cutting state at least two positions, and the two positions that achieve one of the states exist on both sides of a position that achieves another state. Switching of the state of the cutter between the full cutting state and the half cutting state can be performed, for example, by directly bumping the self-propelled cutting unit against a wall at the end of the traveling path.
With this arrangement, the state of the cutter can be switched between the full cutting state and the half cutting state at the ends of the traveling path of the self- propelled cutting unit supporting the cutter. Therefore, the state of the cutter can be easily switched back and forth between the full cutting state and the half cutting state by a drive source for moving the cutting unit, without providing an electric drive, such as a solenoid.
Further, because the two positions that achieve one of the states exist on both sides of a position that achieves the other state, the cutting unit does not need to be unnecessarily moved only for switching from one state to the other state. Furthermore, when switching from one state to another state, the cutting unit also does not need to be moved only to switch the state. Therefore, a time involved in making a label can be reduced.
In various exemplary embodiments of the invention, the switching device can achieve the full cutting state at least two positions and two positions that achieve the full cutting state exist on both sides of the position that achieve the half cutting state.
With this arrangement, two positions that achieve the full cutting state exist on both sides of the position that achieves the half cutting state, so that a time involved in making a label can be reduced. Further, the half cutting state, which requires fine dimension control of the amount of protrusion of the cutter, can be achieved at one position, so that variation in depth of the half cuttings does not occur and the depth of the half cutting can be always maintained constant.
In various exemplary embodiments of the invention, a label making method includes changing the position that achieves the one state from one of two positions to another position while the full cutting or the half cutting is not performed on a sheet.
According to this, by changing the position that achieves the one state from one of two positions to another position, switching from one state to another state can be achieved by bumping the cutting unit at the end of the traveling path without the need to run the cutting unit unnecessarily. Therefore, time in making a label can be saved.
Further, the cutting unit does not need to be unnecessarily moved, so that a mechanism, such as the solenoid, that lifts the cutting unit is unnecessary. Therefore, the structure of the label making apparatus can be simplified.
Various exemplary embodiments of the invention will be described in detail with reference to the following figures wherein:
Various exemplary embodiments of the invention will be described with reference to the accompanying drawings.
A label making apparatus 100 of the embodiment shown in
The cutting printer 11 shown in
As shown in
First, the transport mechanism 15 will be described. As shown in
Further, the driving from the first drive motor 21 is transmitted to a gear 59 provided to a flange (not shown) of the rolled sheet unit 14, via a second gear train 27, including a planet gear mechanism 26. The planet gear mechanism 26 engages the gear 59 only when the tack sheet 13 is transported in the reverse direction, and does not engage the gear 59 when the tack sheet 13 is transported in the forward direction. Therefore, when the tack sheet 13 is transported in the forward direction, the rolled sheet 51 is rotated by a force of pulling the tack sheet 13 out by the rotation of the platen roller 24 and the discharge roller 25. On the other hand, when the tack sheet 13 is transported in the reverse direction, the rolled sheet 51 is rotated in the reverse direction by the driving of the first drive motor 21.
Next, the cutting mechanism 16 will be described. The cutting mechanism 16 includes a cutting bed 29, a self-propelled cutting unit 30, and a carriage 31. The cutting bed 29 receives the tack sheet 13 at the lower position of the cutting mechanism 16. The self-propelled cutting unit 30 is opposed to the cutting bed 29, sandwiching the tack sheet 13 therebetween. The cutting unit 30 is detachably attached to the carriage 31. At a position opposed to the cutting unit 30, a slit is formed in the cutting bed 29 in a width direction of the cutting bed 29, so that a tip of a cutter 43 can penetrate thereinto.
As shown in
As shown in
The lower end of the cutting unit 30 is urged by an urging force from a spring (not shown) to press against the upper surface of the cutting bed 29.
As shown in
Next, a structure of the cutting unit 30 of the cutting mechanism 16 will be described. The label making apparatus 100 is structured to cut the tack sheet 13 by the cutting unit 30 in two different states. One is a half cutting state in which the cutting unit 30 can cut the tack sheet 13 partway in a direction of a thickness of the tack sheet 13, for example, the cutting unit 30 cuts only the adhesive sheet 18 or the releasable sheet 19 of the tack sheet 13. Another is a full cutting state in which the cutting unit 30 can completely cut the tack sheet 13 in the direction of the thickness of the sheet.
A flat plate shaped lever 154 in which three holes are formed is provided above the cutter supporting portion 150. Two large-diameter balls 156 and 157, which both have the same diameter, and one small-diameter ball 158 are inserted in the respective holes formed in the lever 154. The lever 154 has a length that its ends can protrude from right and left side walls of the housing 152 of the cutting unit 30, and is upwardly urged by a spring (not shown). A cover 164 has two projections 161a, 161b and three flat portions 162a, 162b, 162c on its upper surface and is fastened to the upper surface of the lever 154.
The small-diameter ball 158 is disposed between the large-diameter balls 156 and 157. The cover 164 is formed so that the flat portions 162a and 162c are positioned above the large-diameter balls 156 and 157, respectively, and the flat portion 162b is positioned above the small-diameter ball 158. A cutter adjustment screw 166 for adjusting the tip protrusion amount of the cutter 43 is provided at the upper end of the cutting unit 30. The cutter adjustment screw 166 is rotated to press the cover 164, thereby the tip protrusion amount of the cutter 43 is adjusted.
In the half cutting state shown in
In the full cutting state shown in
Switching between the full cutting state and the half cutting state will be further described with reference to
To switch the state of the cutter 43 from the half cutting state shown in
As opposed to this, to switch the state of the cutter 43 from the half cutting state shown in
To switch the state of the cutter 43 from the full cutting state shown in
To switch the state of the cutter 43 from the full cutting state shown in
As described above, the standby positions are provided on both sides of the cutting position and the switching positions are provided outside of each standby position. Accordingly, the full cutting and the half cutting can be arbitrarily switched and performed by moving the cutting unit 30 to a desired position.
In the embodiment, because two large-diameter balls 156 and 157 that achieve the full cutting state are provided on both sides of the small-diameter ball 158 that achieves the half cutting state, the switching from the half cutting state to the full cutting state can be performed anytime at either of the right and left switching positions shown in
Therefore, according to the embodiment, the cutting unit 30 does not need to be unnecessarily run to switch between the full cutting state and the half cutting state, so that a time involved in making a label can be reduced. Further, the structure of the cutting printer 11 can be simplified because it is unnecessary to use a solenoid that vertically moves the cutting unit 30 and lifts the cutter 43 so that the tip of the cutter 43 does not penetrate into the slit of the cutting bed 29 at the time of not cutting the tack sheet 13.
Further, in the embodiment, the half cutting state, which requires fine dimension control of the tip protrusion amount of the cutter 43, is achieved by only one small-diameter ball 158. Therefore, variation in the depth of the half cutting does not occur and the depth of the half cutting can be always maintained constant.
Further,
Next, a control system of the label making apparatus according to the embodiment will be described with reference to
The computer 110 includes a keyboard 141, a mouse 142, a main unit 130 and a display 132. The main unit 130 has a CPU 134, a RAM 136, and a ROM 138, which are connected to each other by a bus and are also connected to an I/O interface 140.
In the ROM 138, data on fonts of characters and figures is stored as well as programs such as editor software for making a label. The editor software is the software for printing an image on a sheet and cutting the sheet at a desired position. By using the editor software, a user can input and edit a content of an image to be printed on a sheet or a cutting position using the keyboard 141 or the mouse 142 while observing the display 132.
The CPU 134 performs a predetermined operation based on the programs and data read from the ROM 138 and data provided from the cutting printer 11. The RAM 136 temporarily stores operation results of the CPU 134.
An I/O interface 112 of the cutting printer 11 is connected to the I/O interface 140 of the personal computer 110. Further, a head drive circuit 120 that drives the thermal head 44 (see
In the ROM 116, necessary data is stored as well as a program that controls operation of the cutting printer 11. The CPU 114 performs the predetermined operation based on the program and the data read from the ROM 116 and the data provided from the personal computer 110 and sends control signals to the head drive circuit 120. The RAM 118 temporarily stores the data provided from the personal computer 110 and the operation results of the CPU 114.
Next, a detailed procedure for making a label using the label making apparatus 100 according to the embodiment will be described with reference to
First, an initialization of the cutting printer 11 will be described with reference to
Next, at step S2, the cutting unit 30 moves to a standby position adjacent to the wall opposed to the present position. Thus, the cutting unit 30 is switched to a half cutting state. Then, at step S3, an absolute position counter stored in the RAM 118 is initialized to zero. The absolute position counter counts a transport amount of the tack sheet 13 per dot, as described later.
As a user enters commands to the editor software installed in the personal computer 110, the cutting printer 11 performs printing and cutting. That is, the user enters contents to be printed onto a label or shape data (a full cutting position and a half cutting position) while observing the indication on display 132 displayed by the editor software. The entered data is stored in the RAM 136. Then, after the data entry as to the label is completed, at step T1, a string of data is captured by the cutting printer 11 one after another.
An exemplary embodiment of the string of data is shown in
The data shown in
Then, at step T2, a command in the first column of each line of the captured data from the personal computer 110 is analyzed by the CPU 114. As a result, when the analyzed command is not the print command, flow proceeds to step T6. When the analyzed command is the print command, flow proceeds to step T3, and the data in the second through seventh columns in the print command line are captured from the personal computer 110 and are stored in the RAM 118.
Then, at step T4, according to the data stored in the RAM 118, the tack sheet 13 is transported and one dot line is printed. That is, the first drive motor 21 is driven by the motor drive circuit 122 and thus the platen roller 24 and the discharge roller 25 transports the tack sheet 13. Heating elements of the thermal head 44 are applied electric current, so that the heating elements generate heat. Therefore, the tack sheet 13 disposed between the thermal head 44 and the platen roller 24 pigments, whereby a predetermined image is formed on the tack sheet 13. Next, at step T5, one is added to a count value of the absolute position counter, and then flow proceeds to step T10.
At step T6, as is the case with step T2, a command in a first column of one dot line of the captured data from the personal computer 110 is analyzed. As a result, when the analyzed data is a move command, flow proceeds to step T7. When the analyzed data is the full cutting command or the half cutting command, flow proceeds to step T9.
At step T7, the first drive motor 21 is driven by the motor drive circuit 122, and thus the tack sheet 13 is transported to the absolute position stored in a cutting command buffer at step T9 where the full cutting is performed. Therefore, when the full cutting is performed at step T13, a strip of printed label including a plurality of labels connectedly separated by half cut lines each other is discharged. Next, at step T8, the transport amount of the sheet at step T7 is added to the count value of the absolute position counter, and then flow proceeds to step T10.
At step T9, the half cutting command or the full cutting command is stored in the cutting command buffer of the RAM 118 with the absolute position, and then flow proceeds to step T10.
Next, at step T10, the present count value of the absolute position counter is determined as to whether it is within the absolute position of the half cutting command or the full cutting command stored in the cutting command buffer at step T9. When it is within the absolute position, flow proceeds to step T11. When it is out of the absolute position, flow returns to the start.
At step T11, the present count value of the absolute counter is determined as to whether it is in the half cutting position or the full cutting position which is stored in the cutting command buffer at step T9. As a result, when it is the full cutting position, flow proceeds to step T12. When it is the half cutting position, flow proceeds to step T16.
At step T12, in order to perform the full cutting, the cutting unit 30 is moved to the nearest switching position and is switched from the half cutting state to the full cutting state. At this time, because the two large-diameter balls 156 and 157 that achieve the full cutting state exist on both sides of the small-diameter ball 158 that achieves the half cutting state as shown in
Then, at step T13, the cutting unit 30 is moved to the full cutting position and fully cuts the tack sheet 13. After the full cutting is performed, at step T14, the cutting unit 30 is moved to the standby position and is switched to the half cutting state. After that, at step T15, the absolute position counter is cleared and flow returns to the start.
At step T16, the cutting unit 30 is moved to the cutting position and half cuts the tack sheet 13. After the half cutting is performed, at step T17, the cutting unit 30 is moved to the standby position. While the cutting unit 30 is kept in the half cutting state, flow returns to the start.
With such a procedure, the labels connected by the half cut lines shown in
To make a curved half cut line as shown in
In the label making apparatus 100 of the exemplary embodiment, the full cutting and the half cutting are performed using one cutter 43 by switching the state of the cutter 43. Therefore, only one drive source is needed for the cutter 43, so that the structure of the label making apparatus 100 can be simplified. In addition, the full cutting and the half cutting are performed at the same position, so that the control, such as stopping the sheet when cutting, can be performed with relative ease.
Next, another exemplary embodiment of the switching mechanism for switching the state of the cutter between the half cutting state and the full cutting state in the label making apparatus of the invention will be described with reference to
As shown in
To put the cutter 190 into the half cutting state, as shown in
On the other hand, to put the cutter 190 into the full cutting state, as shown in
Accordingly, the label making apparatus having the structure like this embodiment can speedily perform the full cutting and the half cutting when the tack sheet 13 is cut along its width direction.
Various exemplary embodiments of the invention have been described. However, it is to be understood that the invention is not restricted to the particular forms shown in the foregoing exemplary embodiments. Various modifications and alternations can be made thereto. For example, in the aforementioned exemplary embodiments, the label making apparatus 100 includes the cutting printer 11 and the personal computer 110. However, the label making apparatus 100 may include only the cutting printer 11 that has all functions of the personal computer 110. Further, in the aforementioned exemplary embodiments, the full cutting and the half cutting are performed along the width direction of the tack sheet 13. However, the half cutting may be performed surrounding a character printed on the tack sheet 13.
Number | Date | Country | Kind |
---|---|---|---|
11-261688 | Sep 1999 | JP | national |
Number | Name | Date | Kind |
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4391168 | Gerber et al. | Jul 1983 | A |
4524894 | Leblond | Jun 1985 | A |
4608891 | Frisby et al. | Sep 1986 | A |
4624169 | Nelson | Nov 1986 | A |
4920495 | Pilkington | Apr 1990 | A |
5038654 | Mackey | Aug 1991 | A |
5056295 | Williams | Oct 1991 | A |
6341548 | Hirahata et al. | Jan 2002 | B1 |
Number | Date | Country |
---|---|---|
195 21 604 | Apr 1997 | DE |
0 956 930 | Nov 1999 | EP |
2 313 081 | Nov 1997 | GB |
2-14952 | Apr 1990 | JP |