Patent Grant
10981395
The present invention relates to a printer.
JP2009-179010A discloses a thermal transfer printer including a ribbon supply shaft that holds an ink ribbon to be supplied to a printing portion in a roll form, and a ribbon roll up shaft that rolls up the used ink ribbon, wherein the ink ribbon is heated and inks of the ink ribbon are transferred to a print medium, so that printing is performed.
In the above printer, at the time of replacing the ink ribbon, there is a need for rotating the ribbon supply shaft or the ribbon roll up shaft to eliminate looseness of the ink ribbon. Therefore, a task of replacing the ink ribbon is troublesome.
The present invention is achieved in consideration with such a technical problem, and an object of the present invention is to efficiently perform a task of replacing an ink ribbon.
According to an aspect of the present invention, a printer includes a printing portion configured to print on a print medium, a ribbon supply shaft configured to hold an ink ribbon to be supplied to the printing portion, and a ribbon roll up shaft configured to roll up the used ink ribbon, wherein the ribbon supply shaft is provided movably between a ribbon supply position where the ink ribbon is supplied to the printing portion, and a ribbon replacement position where the ribbon supply shaft is attachable to and detachable from the printer, and rotated in the direction in which the ink ribbon is rolled up in the middle of moving from the ribbon replacement position to the ribbon supply position is provided.
With this aspect, when the ribbon supply shaft is brought from the ribbon replacement position to the ribbon supply position, the ribbon supply shaft is automatically rotated and the ink ribbon is rolled up. Therefore, there is no need for performing a task of rotating the ribbon supply shaft or the ribbon roll up shaft in order to eliminate looseness of the ink ribbon. Thus, it is possible to efficiently perform a task of replacing the ink ribbon.
Hereinafter, a printer 100 according to an embodiment of the present invention will be described with reference to the attached drawings.
The printer 100 is a thermal transfer printer in which an ink ribbon R is heated and inks of the ink ribbon R are transferred to a print medium M, so that printing is performed. The print medium M is, for example, a label continuous body in which plural labels are continuously temporarily attached to a band-shaped liner sheet.
As shown in
As shown in
A one-end side end portion of the cover 11 is supported by a support shaft 13 provided in the casing 10 so that the cover is swingable. By swinging with the support shaft 13 as a supporting point, it is possible to switch the cover 11 between an open state where the opening portion of the casing 10 is opened (see
A lock mechanism (not shown) that maintains the close state of the cover 11 is provided in the casing 10. The lock mechanism is cancelled by operating a lever 14 shown in
Between an other-end side end portion of the cover 11 and the casing 10, an outlet port 16 that discharges the print medium M to which printing is already performed by a printing portion 15 shown in
A cutter 17 facing the outlet port 16 is attached to the cover 11 of the present embodiment. Thereby, it is possible to cut the printed print medium M discharged from the outlet port 16. Note that it is possible to attach various other units to the cover 11 instead of the cutter 17.
An operation unit 19 for operating the printer 100 is also provided in the cover 11. The operation unit 19 has various operation buttons, a display, a near-field communication module, LEDs, etc. The display may be a touch panel.
Inside the printer 100, a printing unit 30 for performing printing to the print medium M, a controller 40 that controls actions of the printer 100, etc. are accommodated.
The printing unit 30 includes a main body portion 31 whose one end side is supported by the support shaft 13 so that the main body portion 31 is swingable, and a thermal head 32 attached to the main body portion 31.
The thermal head 32 constitutes the printing portion 15 that performs printing to the print medium M together with a platen roller 20 provided on the casing 10 side.
The printing unit 30 also includes a ribbon supply shaft 33 that holds the ink ribbon R to be supplied to the printing portion 15 in a roll form, a ribbon roll up shaft 34 that rolls up the used ink ribbon R, a partition member 35 that partitions the ink ribbon R and the print medium M, a guide shaft 36 that defines a feed passage of the ink ribbon R from the ribbon supply shaft 33 to the printing portion 15, and a guide shaft 37 that defines a feed passage of the ink ribbon R from the printing portion 15 to the ribbon roll up shaft 34. The ribbon supply shaft 33 is detachably attached to the partition member 35. Note that the ink ribbon R of the present embodiment is an outside wound ink ribbon in which a surface where inks are applied are on the outside.
The print medium M is supplied from the medium supply shaft 12 to the printing portion 15, and nipped between the thermal head 32 and the platen roller 20 together with the ink ribbon R.
When electricity is distributed through to a heating element of the thermal head 32 in a state where the print medium M and the ink ribbon R are nipped between the thermal head 32 and the platen roller 20, the inks of the ink ribbon R are transferred to the print medium M by heat of the heating element, so that printing is performed to the print medium M.
When the platen roller 20 is rotated forward by a platen drive motor (not shown), the print medium M and the ink ribbon R are fed to the downstream side in the feed direction, and the print medium M is discharged to the outside of the printer 100 from the outlet port 16.
As shown in
The partition member 35 is swingably supported on the main body portion 31 by the shaft portion 35b.
As shown in
In such a way, by engaging the engagement portion 35e with the engaged portion 11a, the partition member 35 is maintained at the close position where the ribbon supply shaft 33 is placed at the ribbon supply position. The printing unit 30 and the cover 11 are combined with each other.
At the time of performing printing by the printer 100, the cover 11 is brought into the close state, and the engagement portion 35e of the partition member 35 is engaged with the engaged portion 11a of the cover 11.
Therefore, when the cover 11 is brought into the open state from the close state, the printing unit 30 is swung integrally with the cover 11, and as shown in
Thereby, it is possible to perform settings of the print medium M to the printer 100 and maintenance of portions in the casing 10.
Further, when engagement between the engagement portion 35e and the engaged portion 11a is cancelled from the state shown in
Following the state that the partition member 35 is brought to the open position, the ribbon supply shaft 33 and the roll-form ink ribbon R held by the ribbon supply shaft 33 are moved with respect to the ribbon roll up shaft 34, and exposed to the outlet port 16 of the print medium M. Note that the ribbon roll up shaft 34 is attached to the main body portion 31 and is not movable with respect to the printing unit 30.
Thereby, the ribbon supply shaft 33 is brought to a ribbon replacement position where the ribbon supply shaft 33 is attachable to and detachable from the printer 100, and it is possible to perform a task of replacing the ink ribbon R.
In such a way, in the present embodiment, the ribbon supply shaft 33 is movable with respect to the ribbon roll up shaft 34. At the time of replacing the ink ribbon R, it is possible to move the ribbon supply shaft 33 to the ribbon replacement position where the task can be easily performed.
The ribbon supply shaft 33 is exposed to the outlet port 16 side of the print medium M, that is, to the side of a position where a user performs tasks. Thereby, it is possible to improve workability more.
In a state where the ribbon supply shaft 33 is placed at the ribbon replacement position, as shown in
When the partition member 35 is swung to the casing 10 side with torque which is predetermined torque or more, the engagement portion 35e and the engaged portion 11a are elastically deformed and the engagement between the engagement portion 35e and the engaged portion 11a is cancelled.
Note that by cancelling the engagement between the engagement portion 35e and the engaged portion 11a, the printing unit 30 itself is swung to a predetermined position toward the casing 10 side. The predetermined position is a position where a swing regulating portion (not shown) provided in the vicinity of the support shaft 13 in the casing 10 and the main body portion 31 are abutted with each other.
When the printing unit 30 is swung to the casing 10 side with torque which is predetermined torque or more, the swing regulating portion is elastically deformed, the main body portion 31 goes over the swing regulating portion, and the positioning of the printing unit 30 by the swing regulating portion is cancelled.
As shown in
The reflection sensor 21 is a sensor that detects eye marks which are preliminarily printed on a surface of the print medium M opposite to a printed surface at predetermined intervals. Thereby, it is possible to detect a position of the print medium M in the feed direction.
In the present embodiment, by the partition member 35 guiding the print medium M, the print medium M is stably fed within a fixed distance from the reflection sensor 21. Thereby, it is possible to improve detection precision of the reflection sensor 21.
Note that when the printer 100 is brought into a printable state, that is, into the state shown in
In such a way, since the print medium M is guided by the partition member 35, there is no need for separately providing a guide member for feeding the print medium M within a fixed distance from the reflection sensor 21, and a task of inserting the print medium M into the guide member is also not required.
The printer 100 also includes a light transmission sensor 22 that detects the position of the print medium M in the feed direction.
The light transmission sensor 22 is a sensor having a light emitting unit 22a which serves as a light emitting portion that emits predetermined light, and a light receiving unit 22b which serves as a light receiving portion that receives the light emitted from the light emitting unit 22a and outputs an electric signal corresponding to intensity of the received light.
For example, in a case where the print medium M is a label continuous body in which plural labels are continuously temporarily attached to a band-shaped liner sheet at predetermined intervals, there is an only-liner part between two adjacent labels.
Between the label part and the only-liner part, a transmission amount of the light emitted from the light emitting unit 22a is different, and hence the intensity of the light received by the light receiving unit 22b is changed. Thereby, the light transmission sensor 22 can detect the position of the print medium M in the feed direction.
In the present embodiment, as shown in
As described above, the task of setting the print medium M in the printer 100 is performed in a state where the printing unit 30 is placed at a non-printing position and the opening portion of the casing 10 is opened.
That is, in the present embodiment, it is possible to set the print medium M in the printer 100 in a state where a portion between the light emitting unit 22a and the light receiving unit 22b is widely opened. Thus, it is possible to easily perform the task of setting the print medium M in the printer 100. Note that the position of the light emitting unit 22a may be exchanged with the position of the light receiving unit 22b.
The printer 100 activates any of the reflection sensor 21 and the light transmission sensor 22 in accordance with a type of a print medium M to be used, and detects the position of the print medium M in the feed direction.
For example, in a case where a print medium M provided with no eye marks is used, the printer 100 detects the position of the print medium M by the light transmission sensor 22.
The controller 40 is constituted by a microprocessor, storage devices such as a ROM and a RAM, an input/output interface, buses that connect these members, etc. Print data from external computers, signals from the reflection sensor 21, signals from the light transmission sensor 22, etc. are inputted to the controller 40 via the input/output interface.
The controller 40 executes a print control program stored in the storage device by the microprocessor, and controls electricity distribution to the heating element of the thermal head 32, electricity distribution to the platen drive motor, etc.
Successively, the printing unit 30 will be described in detail with reference to
As shown in
As shown in
As shown in
Rotation of the ribbon supply shaft 33 and the ribbon roll up shaft 34 is controlled by the controller 40 in synchronization with rotation of the platen roller 20. Note that the ribbon supply shaft 33 and the ribbon roll up shaft 34 may be driven by one drive motor.
As described above, the printing unit 30 includes the partition member 35 whose one end side is supported on the main body portion 31 by the shaft portion 35b so that the partition member is swingable. The ribbon supply shaft 33 is attached to the partition member 35.
Thereby, as shown in
As shown in
As shown in
In a case where the ink ribbon R is replaced, etc., as shown in
Meanwhile, in the present embodiment, when the partition member 35 is brought from the open position to the close position and the ribbon supply shaft 33 is brought from the ribbon replacement position to the ribbon supply position, the ribbon supply shaft 33 is automatically rotated in the direction in which the ink ribbon R is rolled up, so that the ink ribbon R is rolled up and the looseness of the ink ribbon R is removed.
According to this, there is no need for performing a task of rotating the ribbon supply shaft 33 or the ribbon roll up shaft 34 in order to eliminate the looseness of the ink ribbon R. Thus, it is possible to efficiently perform the task of replacing the ink ribbon R. Since the looseness of the ink ribbon R is eliminated, it is possible to prevent occurrence of printing failure due to the looseness of the ink ribbon R.
Note that meshing between the gear 33a and the rack 31a is cancelled immediately before the ribbon supply shaft 33 is brought to the ribbon supply position. That is, in a state where the ribbon supply shaft 33 is placed at the ribbon supply position, the rack 31a does not mesh with the gear 33a. Therefore, the rack 31a does not inhibit rotation of the ribbon supply shaft 33 at the time of printing.
Immediately after the meshing between the gear 33a and the rack 31a is cancelled, the gear 33a meshes with the gear 38. Thus, it is possible to suppress that the ribbon supply shaft 33 is rotated in the direction in which the ink ribbon R is supplied to the printing portion 15 within a period from cancellation of the meshing between the gear 33a and the rack 31a to meshing between the gear 33a and the gear 38.
As described above, the printer 100 of the present embodiment includes the printing portion 15 that performs printing to the print medium M, the ribbon supply shaft 33 that holds the ink ribbon R to be supplied to the printing portion 15, and the ribbon roll up shaft 34 that rolls up the used ink ribbon R. The ribbon supply shaft 33 is provided movably between the ribbon supply position where the ink ribbon R is supplied to the printing portion 15 and the ribbon replacement position where the ribbon supply shaft 33 is attachable to and detachable from the printer 100, and rotated in the direction in which the ink ribbon R is rolled up in the middle of moving from the ribbon replacement position to the ribbon supply position.
Specifically, the gear 33a is provided in the ribbon supply shaft 33, and the printer 100 includes the rack 31a to mesh with the gear 33a in the middle of the ribbon supply shaft 33 moving from the ribbon replacement position to the ribbon supply position.
According to this, when the ribbon supply shaft 33 is brought from the ribbon replacement position to the ribbon supply position, the ribbon supply shaft 33 is automatically rotated, so that the ink ribbon R is rolled up. Therefore, there is no need for performing the task of rotating the ribbon supply shaft 33 or the ribbon roll up shaft 34 in order to eliminate the looseness of the ink ribbon R. Thus, it is possible to efficiently perform the task of replacing the ink ribbon R.
The rack 31a does not mesh with the gear 33a in a state where the ribbon supply shaft 33 is placed at the ribbon supply position.
Therefore, the rack 31a does not inhibit the rotation of the ribbon supply shaft 33 at the time of printing.
The printer 100 includes the swingably provided partition member 35 that partitions the ink ribbon R and the print medium M. The ribbon supply shaft 33 is attached to the partition member 35.
According to this, at the time of replacing the ink ribbon R, it is possible to move the ribbon supply shaft 33 to the ribbon replacement position where the task can be easily performed.
The printer 100 includes the swingably provided printing unit 30 having the thermal head 32 that constitutes the printing portion 15, the ribbon supply shaft 33, the ribbon roll up shaft 34, and the partition member 35 are provided in the printing unit 30, and the ribbon roll up shaft 34 is not movable with respect to the printing unit 30.
According to this, the ribbon roll up shaft 34 is not moved with respect to the printing unit 30. Thus, when the ribbon supply shaft 33 is brought to the ribbon supply position and the ink ribbon R is rolled up, it is possible to efficiently eliminate the looseness of the ink ribbon R.
The printer 100 includes the casing 10 and the cover 11 that covers the opening portion of the casing 10, and the partition member 35 has the engagement portion 35e to be engaged with the engaged portion 11a provided in the cover 11. When the engagement portion 35e and the engaged portion 11a are engaged with each other, the partition member 35 is maintained at the close position where the ribbon supply shaft 33 is placed at the ribbon supply position, and the printing unit 30 and the cover 11 are combined with each other.
According to this, when the cover 11 is brought from the close state to the open state, the printing unit 30 is swung integrally with the cover 11. Therefore, at the time of performing settings of the print medium M and maintenance of portions in the casing 10, there is no need for individually opening the cover 11 and the printing unit 30, and it is possible to efficiently perform the task.
The embodiment of the present invention is described above. However, the above embodiment only shows one of application examples of the present invention and there is no intention to limit the technical scope of the present invention to the specific configurations of the embodiment described above.
For example, in the above embodiment, by swingably providing the partition member 35 in the printing unit 30, the ribbon supply shaft 33 attached to the partition member 35 is moved with respect to the ribbon roll up shaft 34. However, as in a printing unit 50 shown in
In the above embodiment, the printer 100 includes the cover 11. However, the printing unit 30 may function as a cover without providing the cover 11. In this case, an engaged portion to be engaged with the engagement portion 35e of the partition member 35 is provided in the main body portion 31 of the printing unit 30, etc.
The present application makes a priority claim based on Japanese Patent Application No. 2017-185378 filed in the Japan Patent Office on Sep. 26, 2017, and the entire disclosure of this application is incorporated herein by reference.
| Number | Date | Country | Kind |
|---|---|---|---|
| JP2017-185378 | Sep 2017 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2018/035515 | 9/25/2018 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2019/065654 | 4/4/2019 | WO | A |
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