This application is the U.S. national phase of International Application No. PCT/JP2006/303445 filed 24 Feb. 2006 which designated the U.S. and claims priority to Japanese Patent Application No. 2005-049038 filed 24 Feb. 2005, the entire contents of each of which are hereby incorporated by reference.
The present invention relates to a ribbon cartridge having a ribbon guide for guiding a running path of an ink ribbon and a printing apparatus having the ribbon cartridge, and more particularly, to an arrangement for stabilizing a running path of an ink ribbon.
In the past, as a printing apparatus, a dot-impact printer has been known which is provided with a print head for impacting on a print wire and an ink ribbon cartridge for receiving an ink ribbon, and in which an image is printed on a print sheet by allowing the print wire to collide with the print sheet on a platen where the ink ribbon sent from the ink ribbon cartridge is interposed between the print sheet and the print wire. In such a printer, a ribbon guide is provided so as to securely move the ink ribbon sent from the ink ribbon cartridge to the front side of the print wire.
In general, the ribbon guide includes a pair of guide frames that are disposed on the left and right sides of an insertion hole into which the print head is inserted. The ribbon guide is configured to guide the ink ribbon so that the ink ribbon enters into one guide frame, passes through a front side of the print head, and exits from the other guide frame, and the upper and lower ends of the ink ribbon are guided by the upper and lower inner edges of the guide frames. Additionally, a slit is formed on each of the pair of guide frames so that the ink ribbon is inserted into the ribbon guide via the slit. In prior art arrangements, a slit has been formed on an upper surface of the guide frame so as to extend along the running direction of the ink ribbon (for example, see Japanese Patent Publication JP-A-7-89204). A slit has also been formed on the upper surface of each of the pair of guide frames so as to extend along the direction substantially perpendicular to the running direction of the ink ribbon (for example, see Japanese Patent Publication JP-A-238831); and the like.
However, when the slit is formed so as to extend along the running direction of the ink ribbon, the ink ribbon may slip out of the slit and derail from the ribbon guide when moving in the vertical direction perpendicular to the running direction in the course of running the ink ribbon.
Additionally, when the slit is formed on a portion of the guide frame so as to extend along the direction substantially perpendicular to the running direction of the ink ribbon, the guide frame has a cantilever shape. As a result, the running path of the ink ribbon becomes unstable, and a ribbon jam may occur.
The present construction is contrived in consideration of the above-mentioned problems, and an object is to provide a ribbon cartridge and a printing apparatus capable of preventing an ink ribbon from derailing while enabling stable running thereof.
In order to achieve the above-mentioned object, a ribbon cartridge includes a ribbon guide through which an ink ribbon is inserted, in which the ribbon guide includes a pair of plates limiting upper and lower ends of the ink ribbon, a guide member disposed between the pair of plates so as to guide a non-transfer surface of the ink ribbon, and a bar member suspended between the pair of plates so as to guide a transfer surface of the ink ribbon. A cutout through which the ink ribbon is inserted is formed at one of the pair of plates so as to surround one end portion of the bar member.
Since the cutout through which the ink ribbon is inserted is formed at one of the pair of plates so as to surround the bar member, the cutout is provided with a cutout portion extending with a predetermined slope relative to the running direction of the ink ribbon. Thus, it is possible to prevent the ink ribbon from derailing from the ribbon guide even when a vertical directional force is applied to the ink ribbon in the course of the running thereof.
Additionally, since the pair of plates does not have a cantilever shape, the running path of the ink ribbon does not become unstable. Thus, it is possible to enable stable running of the ink ribbon and thus to prevent occurrence of a ribbon jam.
In the ribbon cartridge of the invention, the ribbon cartridge may be configured with a plurality of the bar members disposed in a running direction of the ink ribbon, and the cutout through which the ink ribbon is inserted is formed at one of the pair of plates so as to surround one end portion of each bar member.
With such a configuration, since a plurality of the bar members are provided to the ribbon cartridge, even when a force is applied to the bar member in the direction in which the transfer surface of the ink ribbon presses the bar members, the load applied to the bar members is distributed to each bar member. Thus, it is possible to prevent bending of the bar members and thus to enable a stable running of the ink ribbon.
In the ribbon cartridge described herein, the ribbon cartridge may be configured such that the cutout has a side extending in a direction substantially perpendicular to the running direction of the ink ribbon.
With such a configuration, it is possible to prevent the ink ribbon from derailing from the cutout in a secure manner.
The ribbon cartridge may be configured such that a section, which is perpendicular to the running direction of the ink ribbon, of the end portion of the bar member surrounded with the cutout has a substantially L shape.
With such a configuration, the end portion of the ink ribbon is guided by the substantially L-shaped bar members as well as the plates.
The ribbon cartridge may be configured such that one end portion of the ribbon guide in the running direction of the ink ribbon is provided with the guide member, and a surface of the guide member coming in contact with the ink ribbon has a curvature.
With such a configuration, it is possible to smoothly guide the ink ribbon that enters in the ribbon guide or exits from the ribbon guide.
The ribbon cartridge may be configured such that the bar member and the guide member are disposed on both sides in the running direction of the ink ribbon.
With such a configuration, an entrance hole for allowing the ink ribbon to enter therein and an exit hole for allowing the ink ribbon to exit therefrom are formed in the running path of the ink ribbon.
Further, in order to achieve the above-mentioned object, the present invention provides a printing apparatus for printing an image on a print sheet by allowing a print head to impact on a print wire so as to collide with the print sheet supplied onto a platen with the ink ribbon sent from the ink ribbon cartridge interposed therebetween.
Hereinafter, an embodiment will be described with reference to the drawings. In the following embodiment, an example will be described in which the device is applied to a dot-impact printer.
The dot-impact printer 10 includes a print head 30 having a plurality of print wires (not shown), and is configured to print images including text on a print surface of a print sheet by allowing a print head 30 to protrude a print wire with an ink ribbon 52 interposed therebetween. In the below description, an example will be described in which a continuous-form paper is used as a print sheet.
As shown in
An upper-side cover 13 is disposed on a front upper surface of the upper case 11, and is configured to be opened upward when a ribbon cartridge 50 (
As shown in
In the rear surface of the upper case 11, a rear paper-feeding portion 112 is formed below the upper rear cover 14 in an open manner so as to supply the continuous-form paper to the printer part 20.
As shown in
As shown in
Next, a configuration of the printer part 20 will be described.
As shown in
The right-side frame 21 and the left-side frame 22 are fitted to both ends of the printer part 20 so as to be opposed to each other. The front frame 23 and the base frame 24 are suspended between the right-side frame 21 and the left-side frame 22. The front frame 23 is positioned in the front side of the printer part 20, and the base frame 24 is positioned in the lower rear side of the printer part 20.
A roller 25 is disposed on the front lower portions of the right-side frame 21 and the left-side frame 22, respectively, and the printer part 20 is supported by the lower case 12 with two rollers 25 interposed therebetween. Additionally, the roller 25 is configured to be rotatable. A maintenance operation can be performed to a control base (not shown) disposed below the printer part 20 where the printer part 20 is tilted upward about the roller 25.
The front paper-feeding mechanism 26 includes a front paper-feeding stand 261 disposed on the front lower portion of the printer part 20, a tractor support shaft 263, a tractor driving shaft 264, and a pair of left and right front tractors 262 horizontally suspended between the right-side frame 21 and the left-side frame 22, and a front tractor cover 266 fitted to each front tractor 262 in a single body.
The front paper-feeding stand 261 has a surface extending with its slope from a front lower portion of the printer part 20, and the surface upwardly supports the continuous-form paper supplied from the front paper-feeding portion 111 (
The front tractor 262 includes a tractor belt (not shown) having a plurality of pins 265. The tractor belt is suspended on the tractor support shaft 263 and the tractor driving shaft 264. The tractor support shaft 263 is rotatably disposed, and the tractor driving shaft 264 is driven to rotate by a transport motor. Additionally, the tractor belt is rotated with the rotation of the tractor driving shaft 264 and moves the pins 265 from below to above. The pins 265 are exposed from the plane of the front tractor 262 and engaged with a sprocket hole formed through both end portions of the width direction of the continuous-form paper. Further, when the pins 265 are moved by the rotation of the tractor belt, the continuous-form paper is transported upward, that is, toward the print head 30.
The front tractor cover 266 is disposed on the front tractor 262 so as to cover the pins 265 from their up direction. By covering the front tractor 262 loaded with the continuous-form paper with the front tractor cover 266, the sprocket holes of the continuous-form paper are maintained in engagement with the pins 265.
The rear paper-feeding mechanism 27 includes a tractor support shaft 272 and a tractor driving shaft 273 suspended between the right-side frame 21 and the left-side frame 22, a pair of left and right rear tractors 271, rear tractor covers 275 integrally fitted to the rear tractors 271, a rear tractor 271, and a sprocket wheel 276.
As shown in
The tractor support shaft 272 and the tractor driving shaft 273 are disposed substantially horizontal to each other. Two rear tractors 271 are inserted through the tractor support shaft 272 and the tractor driving shaft 273.
Each of the rear tractors 271 includes a tractor belt (not shown) having a plurality of pins 274 arranged at the same gap as sprocket holes disposed on both ends of the continuous-form paper. The tractor belt is suspended on the tractor support shaft 272 and the tractor driving shaft 273. The pins 274 of the tractor belt are exposed on the transport surface 271A of the rear tractor 271 so as to be inserted into the sprocket holes (not shown) of the continuous-form paper. Additionally, when the tractor belt is rotated by rotation of the tractor driving shaft 273, the continuous-form paper is transported by the rotation of the tractor belt.
A sprocket wheel 276 is formed downstream in the transport direction of the continuous-form paper relative to the rear tractor 271. The sprocket wheel 276 is disposed below a transport mechanism 34 (described later) so as to transport the continuous-form paper transported by the rear tractor 271 to the transport mechanism 34. Specifically, a plurality of pins 277 arranged at the same gap as the sprocket holes are formed on the circumference surface of the sprocket wheel 276. The pins 277 are inserted into the sprocket holes of the continuous-form paper transported by the rear tractor 271. Additionally, the sprocket wheel 276 and the rear tractor 271 are driven in synchronization with each other so as to transport the continuous-form paper to the transport mechanism 34. In such a synchronized state, the sprocket wheel 276 and the rear tractor 271 are driven by a transport motor (not shown) during printing so as to transport the continuous-form paper.
A rear tractor cover 275 for pressing the continuous-form paper is openably formed on the rear tractor 271 so as to cover the upper portion of the transport surface 271A. That is, when the continuous-form paper is set to the rear tractor 271, the rear tractor cover 275 is opened, the transport surface 271A is exposed, the sprocket holes of the continuous-form paper are inserted into the pins 277, and the rear tractor cover 275 is then closed. With such a configuration, an upper-surface position of the continuous-form paper is limited by the rear tractor cover 275, thus preventing the sprocket hole from getting out of the pins 274.
The transport mechanism 34 includes a first transport roller 341 and a second transport roller 342 that are opposed to each other so as to transport the continuous-form paper to the print head 30, a second transport roller shaft 343 for supporting the second transport roller 342, and a platen 31 opposed to the print head 30.
The first transport roller 341 is disposed above the sprocket wheel 276 while coming in contact with the other surface of the continuous-form paper. The second transport roller shaft 343 is disposed at a position opposed to the first transport roller 341 with the continuous-form paper interposed therebetween. The second transport roller shaft 343 is rotatably suspended between the right-side frame 21 and the left-side frame 22 so as to insert through a plurality of second transport rollers 342. The second transport roller shaft 343 is movable within a predetermined range by an operation of a roller opening/closing motor. When the roller opening/closing motor performs an opening operation, the second transport rollers 342 are detached from the first transport roller 341. When the roller opening/closing motor performs a closing operation, the second transport rollers 342 are biased toward the first transport roller 341.
By performing the closing operation of the roller opening/closing motor, the continuous-form paper is sandwiched between the first transport roller 341 and the second transport rollers 342. The first transport roller 341 is driven by the transport motor and a toothed driving wheel portion 33. By rotating the first transport roller 341, the continuous-form paper sandwiched between the first transport roller 341 and the second transport rollers 342 is transported in the upper direction, that is, toward the print head 30.
A carriage 28 is inserted through a carriage shaft 29 suspended between the right-side frame 21 and the left-side frame 22. A belt suspended on a carriage driving motor 32 and a carriage driving pulley (not shown) is fitted to the carriage 28. When the belt is driven by an operation of the carriage driving motor 32 and the carriage driving pulley, the carriage 28 is moved along the carriage shaft 29.
The print head 30 is mounted on the carriage 28. The print head 30 is opposed to a print surface of the continuous-form paper in the upper direction of the transport mechanism 34. An ink ribbon 52 drawn out from a ribbon cartridge 50 (described later) is disposed between the print surface of the continuous-form paper and the print head 30. Additionally, images including text are printed on the print surface of the continuous-form paper by allowing the print head 30 to hit the print wire (not shown) toward the print surface of the continuous-form paper so as to attach ink to the print surface.
In a position opposed to the print head 30, a platen 31 is disposed on the other surface of the continuous-form paper. The platen 31 is a flat platen in which a portion coming in contact with the continuous-form paper is a flat surface. This flat surface supports the ejection force of the print wire ejected from the print head 30. The platen 31 is configured to be movable in the vertical direction relative to the continuous-form paper and biased toward the continuous-form paper by means of a spring (not shown).
The paper ejecting mechanism 35 includes a first paper ejecting roller 351 that comes in contact with the continuous-form paper printed by the print head 30 from the rear direction, a movable frame 353 that is suspended from the right-side frame 21 to the left-side frame 22, a movable shaft 354 and a unit support shaft 355 that support the movable frame 353, a spring 356 that is suspended between the movable frame 353 and the left-side frame 22, a plurality of paper ejecting roller units 357 that are fixed to the movable frame 353, and a second paper ejecting roller 358 that is fitted to a paper ejecting roller unit 357.
The first paper ejecting roller 351 comes in contact with the other surface of the continuous-form paper in the upper direction of the print head 30 and rotates by means of the driving operation of the transport motor and the toothed driving wheel portion 33. The movable shaft 354 and the unit support shaft 355 are disposed in a position opposed to the first paper ejecting roller 351 with the continuous-form paper interposed therebetween. The movable shaft 354 and the unit support shaft 355 are suspended between the right-side frame 21 and the left-side frame 22. The unit support shaft 355 is fixed to the right-side frame 21 and the left-side frame 22. Additionally, the movable shaft 354 is configured to be movable in the circular direction about the unit support shaft 355. Further, the movable frame 353 is fixed to the movable shaft 354 and the unit support shaft 355 and is configured to be movable with the movable shaft 354.
A plurality of paper ejecting roller units 357 that are arranged in the axis direction of the movable shaft 354 and the unit support shaft 355 are fitted to the movable frame 353. A second paper ejecting roller 358 is fitted to the paper ejecting roller units 357 in a position apart from the unit support shaft 355.
The movable frame 353 is biased toward the direction close to the first paper ejecting roller 351 about the unit support shaft 355 by the spring 356 suspended between the left-side frame 22 and the movable frame 353. For this reason, the second paper ejecting roller 358 of the paper ejecting roller units 357 is biased toward the pressing direction of the first paper ejecting roller 351. Due to the bias force, the continuous-form paper is inserted between the first paper ejecting roller 351 and the second paper ejecting roller 358. The movable shaft 354 is thus moved while resisting the bias force of the spring 356 due to the operation of the roller opening/closing motor. That is, when the roller opening/closing motor performs an opening operation, the movable shaft 354 is moved while resisting the bias force of the spring 356 due to the driving force of the roller opening/closing motor, and the second paper ejecting roller 358 is detached from the first paper ejecting roller 351. Further, when the roller opening/closing motor releases the driving force (closing operation), the second paper ejecting roller 358 is pressed by the first paper ejecting roller 351 due to the bias force of the spring 356.
As shown in
As shown in
The ink ribbon 52 is inserted through the ribbon guide 51 outside the casing 53. As shown in
As shown in
Each of the guide bodies 80 includes an upper plate 83 and a lower plate 84 for guiding the upper and lower end portions of the ink ribbon 52, a ribbon guide plate 85 and a ribbon guide pole 86 that are disposed facing a non-print-side surface of the ink ribbon 52, and two ribbon press bars 87A and 87B that are disposed facing a print-side surface of the ink ribbon 52. Additionally, an insertion hole 95 is formed in each of the guide bodies 80 so as to pass through the upper and lower plates 83 and 84 and be fitted to the pin (not shown) vertically provided on the carriage 28.
Each of the ribbon guide plates 85 and the ribbon guide bars 86 is integrally formed with the upper and lower plates 83 and 84 so as to connect the upper and lower plates 83 and 84 to each other in a rear surface side of the guide member 80, that is, a side of the print head 30. The ribbon guide plate 85 and ribbon guide pole 86 are sequentially disposed in this order from the side of the head insertion hole 82. Each of the ribbon guide plates 85 has a plane surface coming in contact with the non-transfer surface of the ink ribbon 52, and guides the non-transfer surface of the ink ribbon 52 in the guide body 80. Further, each of the ribbon guide bars 86 has a circumference surface formed with a smooth curvature and guides the non-transfer surface of the ink ribbon 52 that enters from the ribbon cartridge 50 to the guide body 80 when the ink ribbon 52 runs or exits from the guide body 80 to the ribbon cartridge 50.
Two ribbon press bars 87A and 87B are formed on the front side of the guide body 80, that is, the print sheet side so as to be suspended from the upper plate 83 to the lower plate 84 and configured as a bar member for pressing the transfer surface of the ink ribbon 52. Specifically, the ribbon press bars 87A and 87B are configured such that upper end portions of the ribbon press bars 87A and 87B are connected to the upper plate 83. Additionally, as shown in
When the ink ribbon 52 is inserted into the ribbon guide 51, the ink ribbon 52 is inserted via the cutouts 100A and 100B. That is, when the ink ribbon 52 is inserted into the ribbon guide 51, the ink ribbon 52 is adjusted to a shape of the cutouts 100A and 100B as depicted by an imaginary line in
Additionally, because the cutouts 100A and 100B are formed in a substantial U-shape on the lower plate 84, the lower end portions 91A and 91B of the ribbon press bars 87A and 87B have a substantial L-shape as viewed in the section. Accordingly, the ink ribbon 52 is inserted into the guide bodies 80 of the ribbon guide 51, and its lower end is guided by the lower end portions 91A and 91B of the ribbon press bars 87A and 87B as well as the lower plate 84.
A side plate 88 is integrally formed with the upper and lower plates 83 and 84 in the sides in which the pair of guide bodies 80 are opposed to each other. The running path of the ink ribbon 52 is formed in each of the guide bodies 80 by sequentially disposing the ribbon press bar 87A, the ribbon guide plate 85, the ribbon press bar 87B, and the ribbon guide pole 86 on both sides of the running direction from the side in which the side plate 88 in the running direction of the ink ribbon 52 is disposed. A first opening portion 89 formed between the side plate 88 and the ribbon press bar 87A and a second opening portion 90 formed between the ribbon guide pole 86 and the ribbon press bar 87B function as an entrance hole for inserting the ink ribbon 52 into the guide bodies 80 or an exit hole for drawing out the ink ribbon 52, respectively.
In such a configuration, during a printing operation, as shown in
In a printing operation state, the running operation of the ink ribbon 52 and the moving operation of the carriage 28 may cause a shock to the ribbon guide 51. Particularly, in a high-speed printing state, the high-speed moving carriage 28 largely causes the shock. Examples of such shock include an up-down force on the ink ribbon 52, a direction force that the transfer surface of the ink ribbon 52 presses the ribbon press bars 87A and 87B, and the like.
In the embodiment, since the cutouts 100A and 100B for inserting ink ribbon 52 into the guide body 80 are formed in a substantial U-shape in the lower plate 84 and has the cut-out side 101 extending in a direction substantially perpendicular to the running direction of the ink ribbon 52, the ink ribbon 52 does not derail from the guide body 80 when an up-down force on the ink ribbon 52 is generated. Additionally, since the upper and lower ends of the ink ribbon 52 are guided by the upper and lower plates 83 and 84, it is possible to prevent the ink ribbon 52 from derailing in the vertical direction.
Still further, since the upper and lower plates 83 and 84 do not have a cantilever shape, the running path of the ink ribbon 52 does not become unstable. Accordingly, it is possible to enable a stable running of the ink ribbon 52 and thus to prevent occurrence of a ribbon jam.
Furthermore, since two ribbon press bars 87A and 87B are provided to the ribbon cartridge, even when a force is applied to the ribbon press bars 87A and 87B in the direction in which the transfer surface of the ink ribbon 52 presses the ribbon press bars 87A and 87B, the load applied to the ribbon press bars 87A and 87B is distributed to each ribbon press bar. With such a configuration, it is possible to stabilize the running of the ink ribbon 52 without causing bending of the ribbon press bars 87A and 87B.
The above-mentioned embodiment shows a first exemplary aspect of the invention and may be modified as any forms within the scope of the invention.
For example, although in the above-mentioned embodiment the guide body 80 is configured to include two ribbon press bars 87A and 87B, the guide body 80 may be configured to include a plurality of lines such as three ribbon press bars.
Further, although in the above-mentioned embodiment the cutouts 100A and 100B for inserting the ink ribbon 52 are formed in a substantial U-shape in the lower plate 84 so as to surround the lower end portions 91A and 91B of two ribbon press bars 87A and 87B, the shape of the cutouts 100A and 100B is not limited to the substantial U-shape. That is, the cutouts 100A and 100B may be formed in arbitrary shapes such as a shape having a cut-out side 101 extending in a direction substantially perpendicular to the running direction of the ink ribbon 52, or a shape having a cut-out side extending in a slight slope relative to the running direction of the ink ribbon 52.
Furthermore, although in the above-mentioned embodiment the ribbon press bars 87A and 87B are integrally formed with the upper plate 83, the ribbon press bars 87A and 87B may be integrally formed with the lower plate 84, and the cutouts 100A and 100B may be formed in the upper plate 83.
When the ribbon press bars 87A and 87B are integrally formed with the upper plate 83 or the lower plate 84, it is possible to increase the strength of the ribbon press bars 87A and 87B by properly modifying a shape or a thickness of its connection portion.
According to the embodiments described herein, since a cutout through which an ink ribbon is inserted is formed at one of a pair of plates so as to surround a bar member, it is possible to prevent the ink ribbon from derailing from a ribbon guide.
This application claims the benefit of Japanese Patent Application No. 2005-049038 filed Feb. 24, 2005, the entire contents of which are incorporated herein by reference.
Number | Date | Country | Kind |
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P2005-049038 | Feb 2005 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2006/303445 | 2/24/2006 | WO | 00 | 8/22/2007 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/090842 | 8/31/2006 | WO | A |
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4402621 | Abell et al. | Sep 1983 | A |
4856923 | Smith | Aug 1989 | A |
4948278 | Schiffmacher et al. | Aug 1990 | A |
5366304 | Sheehan et al. | Nov 1994 | A |
Number | Date | Country |
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64-26490 | Jan 1989 | JP |
01026490 | Jan 1989 | JP |
03007374 | Jan 1991 | JP |
7-89204 | Apr 1995 | JP |
7-251553 | Oct 1995 | JP |
8-90888 | Apr 1996 | JP |
8-238831 | Sep 1996 | JP |
2004-351689 | Dec 2004 | JP |
2004351689 | Dec 2004 | JP |
Number | Date | Country | |
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20090202283 A1 | Aug 2009 | US |