Not Applicable.
The present invention relates to printer drive trains, and more particularly to a printer drive train for providing and maintaining ribbon tension upstream and downstream of a print head.
Many printers incorporate a ribbon used as a carrier or substrate for the print material (e.g., ink) that is transferred to a print media during the printing process. For example, thermal transfer printers include a thermal print head that selectively heats the ribbon to transfer ink onto a print media, such as a label. During a typical printing cycle, the ribbon is unwound from a supply spool, directed downstream between the thermal print head and a drive roller where it comes into contact with and prints to the print media, and is subsequently wound about a take-up spool.
To move the print media and ribbon upstream and downstream of the print head, a drive motor (e.g., a stepper motor) is engaged to a drive train that in turn is coupled via gears to the drive roller, supply spool, and/or take-up spool. This complex series of gears creates several challenges related to providing and maintaining the optimal tension in the ribbon both during and between printing cycles.
Improper tension in the ribbon may cause slack in the ribbon both upstream and downstream of the print head. A ribbon exhibiting excessive slack can degrade print quality and lead to other issues with the operation of the printer. For instance, if the tension of the ribbon drops below an operational threshold, creases or wrinkles may develop in the ribbon resulting in print defects. Moreover, slack ribbon is increasingly susceptible to thermal distortion resulting from the heat of the thermal print head and/or may result in drag on the print media resulting in visible scuff marks formed on the print media.
Another challenge arises between printing cycles in maintaining ribbon tension such that a subsequent printing cycle begins with a properly tensioned ribbon. This issue is exacerbated when the direction the ribbon cartridge is being driven is reversed (i.e., from downstream to upstream and vice versa). Moreover, backlash inherent in the gear train also presents a challenge to ensure that the ribbon is tensioned before the print cycle begins. Without the appropriate tension applied to the ribbon, excess ribbon slack may be introduced causing any of the issues discussed above.
Present designs incorporate tensioning elements within the ribbon cartridge to prevent freewheeling of the supply spool and take-up spool when not being driven by the drive motor. However, internal tensioning elements in the ribbon cartridge are less than ideal because of the added costs each element adds to the ultimately disposable ribbon cartridge.
In light of the above challenges, a need exists for a drive train that provides and maintains proper tensioning of a ribbon. In particular, a need exists for a drive train that provides and maintains sufficient, but not excessive, tension in multiple ribbon feed directions and properly coordinates with the rotation of the drive roller.
The present invention generally provides a drive train for a printer that provides and maintains a desired tension in the ribbon during transfer of the ribbon between a supply spool and a take-up spool. The drive train is configured to pre-tension the ribbon proximate the driven spool prior to driving the drive roller. During operation, the drive train provides and maintains the requisite tension in the ribbon proximate the driven spool with use of a slip-overdrive assembly. Additionally, the drive train induces a drag on the spool from which ribbon is being unwound with the use of a drag-overrun assembly.
In one aspect, the present invention provides a drive train for a printer that comprises a drive motor for selectively driving a drive roller and a take-up spool to unwind a ribbon from a supply spool and wind the ribbon about the take-up spool. A take-up slip-overdrive assembly is operationally engaged with the drive motor and the take-up spool to maintain a take-up tension in the ribbon downstream of the drive roller by overdriving the take-up spool relative to the drive roller to wind the ribbon about the take-up spool. A supply drag-overrun assembly is operationally engaged with the supply spool to maintain a supply tension in the ribbon upstream of the drive roller by resisting unwinding of the ribbon from the supply spool.
In another aspect, the invention provides a drive train for a printer that comprises a drive motor for driving a drive roller about a drive axis and at least one of a supply spool and a take-up spool to wind and unwind a ribbon about the supply spool and the take-up spool depending upon a direction of rotation of the drive motor. A drive direction assembly is operationally coupled to the drive motor and pivotable about the drive axis between a downstream direction, at which the drive motor drives the take-up spool to unwind the ribbon from the supply spool and wind the ribbon about the take-up spool, and an upstream direction, at which the drive motor drives the supply spool to unwind the ribbon from the take-up spool and wind the ribbon about the supply spool. A take-up slip-overdrive assembly is operationally engaged with the take-up spool and selectively engaged with the drive direction assembly when the drive direction assembly is in the downstream direction. A supply drag-overrun assembly is operationally engaged with the supply spool. The take-up slip-overdrive assembly maintains a take-up tension in the ribbon downstream of the drive roller by overdriving the take-up spool relative to the drive roller to wind the ribbon about the take-up spool, the supply drag-overrun assembly maintains a supply tension in the ribbon upstream of the drive roller by resisting unwinding of the ribbon from the supply spool.
These and still other aspects of the present invention will be apparent from the description that follows. In the detailed description, a preferred example embodiment of the invention will be described with reference to the accompanying drawings. This embodiment does not represent the full scope of the invention; rather the invention may be employed in other embodiments. Reference should therefore be made to the claims herein for interpreting the breadth of the invention.
The preferred example embodiment of the invention will be described in relation to a thermal transfer printer. However, the present invention is equally applicable to other types and styles of printers that may benefit from the incorporation of a drive train that provides and maintains an appropriate tension in the print ribbon and/or print media.
With initial reference to
The user interface 14 may include, but is not limited to, a display 26 for displaying information, a keypad 28 and a keyboard 30 for entering data, and function buttons 32 that may be configured to perform various typical printing functions (e.g., cancel print job, advance print media, and the like) or be programmable for the execution of macros containing preset printing parameters for a particular type of print media 11. The user interface 14 may be supplemented by or replaced by other forms of data entry or printer control such as a separate data entry and control module linked wirelessly or by a data cable operationally coupled to a computer, a router, or the like. Additionally, the user interface 14 is operationally coupled to a controller (not shown) for controlling the operation of the printer 10.
Referring now to
With additional reference to
Attached to the upper print frame 36 are the ribbon cartridge 50 and a print head 52. The print head 52 is moveably coupled to a bracket 54 such that the print head 52 is biased toward the drive roller 47 by a group of springs 49 when the upper print frame 36 is in the closed position (shown best in
The ribbon cartridge 50 includes a supply spool 56 and a take-up spool 58 that are rotatably coupled to a ribbon 57. With specific reference to
The ribbon 57 (shown only in
With specific reference to
During printing, the print media 11 moves along a path 60 (best shown in
The translation of the print media 11 and the driving of the supply spool 56 and take-up spool 58 are controlled by the controller. The controller is also in communication with an upstream sensor 96 and a downstream sensor 62 to detect the presence of the print media 11 along the path 60. As best shown in
With the operation of the printer 10 described generally, the configuration, structure, and operation of the drive train 44 is discussed in detail. The drive train 44 has four main functions. First, the drive train 44 drives the ribbon 57 either upstream or downstream relative to the print head 52 by selectively engaging the supply spool 56 and take-up spool 58, respectively. Second, the drive train 44 provides a delay between rotation of the drive motor 45 and the drive roller 47 while concurrently imparting an initial tension in the ribbon 57. Third, the drive train 44 provides and maintains the appropriate ribbon tension via the driven spool (i.e., either the supply spool 56 or the take-up spool 58, whichever is being driven by the drive motor 45) by overdriving the driven spool to prevent slack in the ribbon 57 and allowing slip (i.e., relative rotation of selected gears) to limit the maximum tension in the ribbon 57. Fourth, the drive train 44 provides and maintains sufficient drag tension on the ribbon 57 via the non-driven spool (i.e., the supply spool 56 or the take-up spool 58 that is driven by the unwinding of ribbon 57) by imparting resistance to the rotation of the non-driven spool via selected gears. Notably, the ribbon cartridge 50 of the example embodiment does not include any type of tensioning element; the tension of the ribbon 57 is independently provided and maintained by the drive train 44. However, internal tensioning elements may be incorporated if desired.
The drive train 44 incorporates three main components to provide the various functions discussed above. A drive direction assembly 72 transfers rotation of the drive motor 45 between the supply spool gear 64 and the take-up spool gear 66 during a change in the direction of rotation of the drive motor 45, while simultaneously providing a delay between the rotation of the drive motor 45 and the drive roller 47 to pre-tension the ribbon 57. A take-up drag-overrun assembly 78 and a similar supply drag-overrun assembly 80 provide drag and overrun functions depending on location and direction of the drive motor 45. And, a take-up slip-overdrive assembly 74 and a similar supply slip-overdrive assembly 76 provide slip and overdrive functions depending on location and direction of the drive motor 45.
In general,
The operation of the drive train 44 is best understood by mapping the engagement between the various gears of the drive train 44. However, as one skilled in the art will appreciate, a variety of gear ratios and configurations are possible to implement the present invention and are dependent upon the specific application requirements.
For purposes of explanation, the operation and force transfer of the drive train 44 begins with the assumption that the drive direction assembly 72 is originally in the upstream direction configuration shown in
The drive motor 45 is coupled to and rotates a drive motor gear 82 that meshes with an outer reduction gear 84 of a reduction gear assembly 86. A coaxial inner reduction gear 88 rotates in unison with the outer reduction gear 84 in a counterclockwise direction, effectively reducing the angular velocity of the drive train 44 as compared to the drive motor 45. The inner reduction gear 88 then meshes with the drive direction assembly 72.
The force supplied by the inner reduction gear 88 of the reduction gear assembly 86 causes the drive direction assembly 72 to toggle from the upstream direction configuration (shown in
A direction arm 104 includes a direction arm hub 106 and a spring clip slot 108 that extends proximate the direction arm hub 106. The direction arm hub 106 is fit over the drive gear hub 100, and then a spring clip 110 is inserted in the spring clip slot 108 to ride along drive gear hub 100. Therefore, rotation of the outer drive gear 92, inner drive gear 94, and drive gear hub 100 causes the direction arm 104 to rotate along with the drive gear hub 100 due to the frictional engagement of the spring clip 110 with the drive gear hub 100. The direction arm 104 rotates until the downstream drive gear 112 that is rotatably coupled to the direction arm 104 meshes with the take-up drag-overrun assembly 78, ultimately resulting in the take-up spool 58 being driven.
Similarly, reversing direction of the drive motor 45 to a counterclockwise rotation will result in the direction arm 104 rotating with the drive gear hub 100 in the counterclockwise direction (shown in
As a result of the above operation shown in
With continued reference to
The drive direction assembly 72 further includes a back leg 132 that captures the delay disk 122 to the second outer drive gear face 118 via a snap fitting 134. The snap fitting 134 has a pair of bores 136 that receive mating posts (not shown) extending from the direction arm 104. The back leg 132 also includes a bore 138 aligned with the drive axis 90 when installed proximate the drive roller 47. A tab 140 extends from an end of the back leg 132 to prevent over-rotation of the drive direction assembly 72 as the tab 140 bears against a downstream notch face 142 formed in the lower print frame 38 (shown in
With the drive direction assembly 72 toggled to the downstream direction configuration, we return to
With reference to
To install the inner torsion spring 160, the inner torsion spring 160 is wound and the drive leg 162 is aligned with the slot 150 in the standoff 152 (as shown in
An outer torsion spring 170 includes a fixed leg 172 and a free leg 174 and is unwound before being slid over the outer surface 156 of the hub 154. The outer torsion spring 170 generally provides an inward radial force that causes friction between the outer torsion spring 170 and the outer surface 156 of the hub 154. When the take-up drag-overrun assembly 78 is installed to the lower print frame 38, the fixed leg 172 is slid into a recess 176 (shown in
Returning to
Returning again to
With additional reference to FIGS. 5 and 15-16, the take-up slip-overdrive assembly 74 includes an outer slip-overdrive gear 180, similar to the drag-overrun gear 148, which is meshed with the drag-overrun gear 148 to transmit rotation to the take-up slip-overdrive assembly 74. The outer slip-overdrive gear 180 includes a standoff 182 having a slot 184. An inner slip-overdrive gear 186 is aligned adjacent the outer slip-overdrive gear 180 and defines a bore 188 having an inner surface 190. A torsion spring 192 includes a gear leg 194 and a free leg 196. As with the take-up drag-overrun assembly 78, the torsion spring 192 is wound to frictionally fit the torsion spring 192 to the inner surface 190 of the bore 188. The gear leg 194 of the torsion spring 192 is aligned during installation with the slot 184 such that the gear leg 194 is linked to the rotation of the outer slip-overdrive gear 180. An end cap 198 is secured via clips 200 in openings 202 to help axially restrain the torsion spring 192. The take-up slip-overdrive assembly 74 is rotatably coupled to the lower print frame 38 about spindle 204, which is engaged with opening 203, allowing the take-up slip-overdrive assembly 74 to selectively rotate about a slip-overdrive axis 206.
In operation, as the outer slip-overdrive gear 180 is driven counterclockwise by the drag-overrun gear 148, the slot 184 of the outer slip-overdrive gear 180 will urge the torsion spring 192 in a direction tending to wind the torsion spring 192 and therefore decrease the friction between the torsion spring 192 and the inner surface 190 of the inner slip-overdrive gear 186. However, the friction between the torsion spring 192 and the inner surface 190 is sufficient to drive the take-up spool gear 66 so as to produce the desired amount of tension in the ribbon 57. As the tension in the ribbon 57 increases, given that the drive train 44 is geared such that the take-up spool 58 winds ribbon 57 faster than it is fed by the drive roller 47, the friction between the torsion spring 192 and the inner surface 190 of the inner slip-overdrive gear 186 is overcome by the resistance caused by the tension in the ribbon 57. Thus, the torsion spring 192 slips relative to the inner slip-overdrive gear 186 to allow the outer slip-overdrive gear 180 and the inner slip-overdrive gear 186 to rotate at different rates. As a result, the outer slip-overdrive gear 180 maintains the rate of the drag-overrun gear 148 and the inner slip-overdrive gear 186 is allowed to decrease the rate of rotation of the take-up spool 58 ultimately maintaining the desired tension in the ribbon 57. The configuration also accommodates for the pre-tension imparted at the start of a printing cycle before the drive roller 47 is rotationally engaged by the drive direction assembly 72.
Notably, the engagement between the take-up spool gear 66 and the inner slip-overdrive gear 186 results in a force component biasing the take-up spool 58 toward the take-up spool saddles 70. This is accomplished by arranging the take-up spool gear 66 and the inner slip-overdrive gear 186 such that the meshing forces, in sum, establish the biasing force. This biasing force is achieved in either direction of rotation as shown in
With the issue of providing and maintaining tension in the ribbon 57 downstream of the drive roller 47 addressed, we return again to
As the ribbon 57 is unwound from the supply spool 56, the supply spool 56 rotates clockwise as shown in
The counterclockwise rotation of the idler gear 117 is transferred to the supply slip-overdrive assembly 76, which is rotatably coupled to the lower print frame 38 via spindle 204 at opening 119, to rotate the supply slip-overdrive assembly 76 in a clockwise direction, thus opposite to the direction of rotation of the take-up slip-overdrive assembly 74. The supply slip-overdrive assembly 76 functions similar to a stacked idler gear generally transferring rotation from the idler gear 117 to the supply drag-overrun assembly 80.
With specific reference to FIGS. 5 and 15-16, the idler gear 117 meshes with and drives the inner slip-overdrive gear 186. The interaction between the inner slip-overdrive gear 186 and the outer slip-overdrive gear 180 tends to cause the torsion spring 192 to compress or wind, therefor decreasing the outward radial force supplied by the torsion spring 192 on the inner surface 190. However, the outward radial force supplied by the torsion spring 192 is sufficient to allow the outer slip-overdrive gear 180 and the inner slip-overdrive gear 186 to rotate substantially in unison, even after the reduction in outward radial force. In other words, the torque supplied by the driven supply spool 56 is insufficient to result in slip between the torsion spring 192 and the inner slip-overdrive gear 186, thus preventing relative movement between the inner slip-overdrive gear 186 and the outer slip-overdrive gear 180.
The supply drag-overrun assembly 80 functions in the downstream direction configuration (shown in
Friction between the inner torsion spring 160 and the inner surface 158 causes resistance or drag as the drag-overrun gear 148 rotates in the counterclockwise direction, as a result, the supply spool 56 is prevented from freewheeling as the ribbon 57 is unwound. Additionally, a tension is provided and maintained in the ribbon 57 while the supply slip-overdrive assembly 76 may be configured to slip prior to the tension in the ribbon 57 reaching a damaging level. For completeness, the drag-overrun gear 148 meshes with the idler gear 116 in the downstream drive configuration shown in
Changing the direction of rotation of the drive motor 45 alters the operation of the drive train 44 such that the supply spool 56 is driven and the take-up spool 58 is unwound by the ribbon 57. However, the drive train 44 is configured such that the appropriate tension is provided and maintained in the ribbon 57 in either the downstream drive configuration or the upstream drive configuration.
The function and operation of the drive train 44 is dependent on the direction of the drive motor 45 and thus the rotation of each component. More specifically, when the direction of the drive motor 45 is reversed (e.g., from the downstream driving configuration of
With specific reference to
In general, changing the direction of rotation of the drive train 44, and hence drive train 44 components, results in the structurally related components (i.e., the take-up slip-overdrive assembly 74 and the related supply slip-overdrive assembly 76, and the take-up drag-overrun assembly 78 and the related supply drag-overrun assembly 80) providing complementary functions in the respective downstream drive configuration and the upstream drive configuration. As a result, the drive train 44 provides and maintains the desired tension on the ribbon 57 in both operating configurations.
In light of the above, the present invention provides a printer drive train 44 that provides and maintains sufficient tension on the ribbon 57 to prevent excess slack in the ribbon 57. The drive train 44 provides a delay between engagement of the driven spool and the drive roller 47 to allow the ribbon 57 to be pre-tensioned prior to a printing or back-feeding. Furthermore, the drive train 44 provides tension on the ribbon 57 with both overdriving and dragging selected gears depending on the rotation of the drive train 44.
While there has been shown and described what is at present considered the preferred embodiment of the invention, it will be obvious to those skilled in the art that various changes and modifications can be made therein without departing from the scope of the invention defined by the following claims. For example, the outer torsion spring 170 and inner torsion spring 160 may be wound in the opposite direction and coupled to the drag-overrun gear 148 and lower print frame 38 to exchange the functionality of the outer torsion spring 170 and inner torsion spring 160 from that described in the preferred example embodiment.
Moreover, as illustrated in
This application claims priority to U.S. provisional application No. 61/061,432 filed Jun. 13, 2008, which is hereby incorporated by reference as if fully set forth herein.
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