The present invention relates generally to image forming devices, and in particular to a dual sliding shutter system for adding toner to an image forming machine.
Toner is a dry, powdered form of ink applied to media sheets in electrophotographic image forming devices. Toner is a consumable item, which must be replenished periodically. Pouring toner from a bottle into a toner reservoir in the image forming device is a notoriously messy operation, often staining a user's hands and clothes with toner, resulting in user dissatisfaction.
Cartridges that contain toner and are inserted as a unit into the image forming device to replenish its toner supply are known in the art. Typically, a toner cartridge is inserted using one motion, e.g., sliding the cartridge into place, and an integral door or shutter is opened using a different motion, e.g., twisting the cartridge about its axis, to open a passageway for toner to flow from the cartridge into a developer unit in the image forming device. These cartridges are difficult for inexperienced users to properly install, resulting in cartridges that are improperly inserted, inserted but not twisted properly such that the toner does not flow from the cartridge or only partially flows, and the like.
In another type of toner cartridge known in the art, shutters on the toner cartridge and/or the developer are held in a closed position by springs. When the toner cartridge is inserted into an image forming device, the shutters are opened, allowing toner to flow. Upon removal of the cartridge, the springs move the shutters to the closed positions. In these cartridges, the spring forces must be overcome upon inserting the cartridge. That is, the spring forces oppose the insertion of the cartridge into the image forming device, increasing the required insertion force. Additionally, the springs add cost and complexity to cartridge design.
In one embodiment, the invention relates to an image forming device. The image forming device includes a developer supplying toner to an image forming station, and a removable cartridge holding a supply of toner, in toner flow relationship with the developer when the cartridge is inserted into the image forming device. The developer includes a shutter operative to retain toner in the developer in a closed position, and operative to allow toner to flow into the developer in an open position. Both the developer shutter and the cartridge shutter are moved to the open position by inserting the cartridge into the image forming device, and both the developer shutter and the cartridge shutter are moved to the closed position by removing the cartridge from the image forming device.
In another embodiment, the invention relates to an image forming device The image forming device includes a protrusion connected to a static element in the image forming device, and a developer supplying toner to an image forming station. The image forming device also includes a removable cartridge holding a supply of toner, in toner flow relationship with the developer when the cartridge is inserted into the image forming device. The cartridge includes a shutter operative to retain toner within the cartridge in a closed position, and operative to allow toner to flow from the cartridge in an open position. The channel also has a channel having two side walls, within which the cartridge shutter moves between the closed and open positions, with a recess formed in at least one of the side walls. At least one deformable protrusion member is connected to the cartridge shutter, each disposed adjacent a side wall of the channel and, with the cartridge shutter in the closed position, operative to engage a corresponding static element protrusion by deforming outwardly from the cartridge shutter into a corresponding channel side wall recess as the cartridge is inserted into the image forming device. As the cartridge is inserted further into the image forming device, contact with the static member moves the cartridge shutter from the closed to the open position within the channel, and the deformable protrusion members are locked into engagement with the corresponding static element protrusions by the channel side walls.
An image forming device suitable for use with the present invention may include a laser printer (mono or color), facsimile, copier, or combination of two or more of these devices, which is often referred to as an al -in-one device. The device may be sized to fit on a workspace, such as a desktop. The device may further include accessible work areas for the user to insert and remove media sheets, replace components within the device, and clear media jams from within the device.
A first toner transfer area 20 includes one or more imaging units 21 that are aligned horizontally extending from the front 13 to a back 15 of the body 12. Each imaging unit 21 includes a charging roll 22, a developer 23 that includes various paddles and rollers for stirring and moving toner and a developer roll 24, and a rotating photoconductive (PC) drum 25. The charging roll 22 forms a nip with the PC drum 25, and charges the surface of the PC drum 25 to a specified voltage such as −1000 volts, for example. A laser beam from a printhead 26 contacts the surface of the PC drum 25 and discharges those areas it contacts to form a latent image. In one embodiment, areas on the PC drum 25 illuminated by the laser beam are discharged to approximately −300 volts. The developer roll 24, which also forms a nip with the PC drum 25, then transfers toner particles from a cartridge 27 containing a supply of toner to the PC drum 25, to form a toner image. The toner particles are attracted to the areas of the PC drum 25 surface discharged by the laser beam from the printhead 26.
A removable toner cartridge 27 is operatively connected to each of the developers 23 in toner transfer relationship, when the toner cartridge 27 is inserted into the imaging forming device 10. The toner cartridges 27 are sized to contain toner that is transferred to the developers 23 for image formation. The toner cartridges 27 may be mounted and removed from the device 10 independently from the imaging units 21. In one embodiment, the toner cartridges 27 each contain one of black, magenta, cyan, or yellow toner. Each of toner cartridges 27 may be substantially the same, or one or more of the toner cartridges 27 may hold different toner capacities. In one specific embodiment, the black toner cartridge 27 has a higher capacity than the others. The toner cartridges 27 may mount from a top 16 of the device 10, in a generally vertical direction, and may detach during removal with the imaging units 21 remaining within the device 10.
An intermediate transfer mechanism (ITM) 30 is disposed adjacent to each of the imaging units 21. In this embodiment, the ITM 30 is formed as an endless belt trained about support roller 31, tension roller 32 and back-up roller 33. The belt may be constructed from a variety of materials including polyimide, Ethylene TetrafluoroEthylene (ETFE), nylon, thermoplastic elastomers (TPE), polyamide-imid, and polycarbonate alloy. During image forming operations, the ITM 30 moves past the imaging units 21 in a clockwise direction as viewed in
The ITM 30 rotates and collects the one or more toner images from the imaging units 21 and then conveys the toner images to a media sheet at a second transfer area. The second transfer area includes a second transfer nip 40 formed between the back-up roller 33 and a second transfer roller 41.
A media path 44 extends through the device 10 for moving the media sheets through the imaging process. Media sheets are initially stored in the input tray 11 or introduced into the body 12 through a manual feed 48. The sheets in the input tray 11 are picked by a pick mechanism 43 and moved into the media path 44. In this embodiment, the pick mechanism 43 includes a roller positioned at the end of a pivoting arm. The roller rotates to move the media sheets from input tray 11 towards the second transfer area. In one embodiment, the pick mechanism 43 is positioned in proximity (i.e., less than a length of a media sheet) to the second transfer area with the pick mechanism 43 moving the media sheets directly from the input tray 11 into the second transfer nip 40. For sheets entering through the manual feed 48, one or more rollers are positioned to move the sheet into the second transfer nip 40.
The media sheet receives the toner image from the ITM 30 as it moves through the second transfer nip 40. The media sheets with toner images are then moved along the media path 44 and into a fuser area 50. Fuser area 50 includes fusing rollers or belts 51 that form a nip to adhere the toner image to the media sheet. The fused media sheets then pass through exit rollers 45 that are located downstream from the fuser area 50. Exit rollers 45 may be rotated in either forward or reverse directions. In a forward direction, the exit rollers 45 move the media sheet from the media path 44 to an output area 47. In a reverse direction, the exit rollers 45 move the media sheet into a duplex path 46 for image formation on a second side of the media sheet.
As discussed above, replaceable toner cartridges 27 supply toner as needed to respective developers 23. The toner cartridge 27 is considered a consumable supply item to be replaced in several times over the life of the imaging unit 21. An interface between the cartridge 27 and the developer 23 must allow toner to pass from the cartridge 27 to the developer 23 when the cartridge 27 is seated in the image forming device 10. However, toner must not leak from the cartridge 27 or the developer 23 when the cartridge is not seated in an operative position in the image forming device 10. To prevent toner leakage, one or more “shutters” may be provided to selectively cover the passages through which toner is transferred from the cartridge 27 to the developer 23.
The shutters are movable between closed positions, where they retain toner within the cartridge 27 or developer 23, and open positions, where they allow toner to flow from the cartridge 27 into the developer 23 through passages in both units that are aligned when the cartridge 27 is seated in the image forming device 10. According to one or more embodiments disclosed herein, shutters on one or both of the cartridge 27 and the developer 23 are moved from a closed position to an open position as the cartridge 27 is inserted into the image forming device 10. Additionally, the shutters are positively moved from the open position to the closed position as the cartridge 27 is removed from the image forming device 10. Notably, no user action (other than instructing or removing the cartridge 27) is required to open or close either shutter.
According to one or more embodiments, the cartridge shutter 62 and the developer shutter 80—both of which are maintained in the closed position when the toner cartridge 27 is out of the image forming device 10—are moved from closed to open positions by contact with the developer 23 and cartridge 27, respectively, as the toner cartridge 27 is inserted into the image forming device 10 In particular, a lower edge of the cartridge shutter 62 contacts an upper edge of a shutter engagement element 86 formed on the developer 23. As the toner cartridge 27 is inserted into the image forming device 10, and moves in a generally downward direction as depicted in
In some embodiments, the cartridge shutter 62 may engage a static part in the image forming device 10—meaning a part that is rigidly fixed in the image forming device with respect to the removable cartridge 27—in lieu of the shutter engagement element 86 or other part of the developer 23. For the cartridge shutter 62 to move from the closed position covering the toner passage 63, the cartridge shutter detent 68 must be dislodged from the recess 72. As the toner cartridge 27 is fully seated in the image forming device, the cartridge shutter 62 is moved to the fully open position, where the detent 68 engages in the recess 74 to hold the cartridge shutter 62 in the open position.
Similarly, as the toner cartridge 27 is inserted into the image forming device 10, a lower edge or lip 71 of the cartridge 27 abuts an upper edge 81 of the developer shutter 80, and pushes the developer shutter 80 downwardly from the closed position to the open position. To dislodge the developer shutter 80 from the closed position, the developer detent 88 must be deformed. The detent 88 also holds the developer shutter 80 in the open position when the cartridge 27 is fully inserted in the image forming device 10.
According to one or more embodiments, when the toner cartridge 27 is removed from the image forming device 10, both the cartridge shutter 62 and the developer shutter 80 are moved from their respective open positions to closed positions, covering the toner passages 63, 82, to retain toner in the cartridge 27 and developer 23, respectively. To accomplish this, each shutter 62, 80 releasably engages the opposite structure, which “pulls” the shutter 62, 80 to the closed position prior to releasing, as the cartridge 27 is withdrawn from the image forming device 10.
In particular, a resilient cartridge shutter engagement arm 64, including a protrusion 66, is attached to the cartridge shutter 62. As the cartridge 27 is inserted into the image forming device 10, and a force FC-COUPLE is applied, the cartridge shutter engagement arm 64 is deflected around, and engages with, a corresponding lip 83 on the developer engagement member 86. As the cartridge 27 is removed from the image forming device 10, the lip 83 of the developer engagement member 86 pulls the cartridge shutter 62 from the open to the closed position (disengaging the cartridge shutter detent 68 from the recess 74 in the open position and engaging it with the recess 72 in the closed position). As the toner cartridge 27 is further removed from the image forming device 10, and a force FC-DECOUPLE is applied, the cartridge shutter engagement arm 64 of the cartridge shutter 62 disengages from the toner engagement member 86, freeing the toner cartridge 27 for complete removal As discussed above, based on the relative angles of surfaces 66a and 66b, FC-COUPLE≠FC-DECOUPLE.
Also as the toner cartridge 27 is inserted into the image forming device 10, dual resilient developer shutter engagement arms 76, each including a protrusion 78, are displaced outwardly by a sloped surface 83 formed in the developer shutter 80, requiring an applied force FD-COUPLE, and then move down to engage with developer shutter engagement recesses 84. When the toner cartridge 27 is removed from the image forming device 10, the developer shutter engagement arms 76 pull the developer shutter from the open position (overcoming the force FD-LOCK exerted by developer detent surface 88a) to the closed position (where developer detent surface 88b retains the developer shutter 80 in the closed position). As the toner cartridge 27 is further removed from the image forming device 10, and a force FD-UNCOUPLE is applied, the developer shutter engagement arms 76 disengage from the developer shutter engagement recesses 84 As discussed above, based on the relative angles of surfaces 88a and 88b, FD-COUPLE≠FD-DECOUPLE. Note that in other embodiments, only one developer shutter engagement arm 76, and one corresponding sloped surface 83 and developer shutter engagement recesses 84 may be provided on the cartridge shutter 62 and developer shutter 80, respectively.
The developer 23 (or other static part in the image forming device 10) includes a cartridge engagement member 94 having a recess 96 formed in either side thereof, shaped and positioned to receive the developer engagement arm protrusions 91. Stated another way, each recess 96 forms a protrusion 99 in the cartridge engagement member 94. Formed in the side walls 61 are recesses 98, shaped and positioned to receive the developer engagement arm protrusions 92 only when the cartridge shutter 62 is in the fully closed position.
As the toner cartridge 27 is inserted into the image forming device 10, with the cartridge shutter 62 in the fully closed position, the surfaces 91a of the developer engagement arm 90 are brought into contact with an angled surface 95 of the cartridge engagement member 94, displacing the developer engagement arms 90 outward, as depicted in
As the toner cartridge 27 is inserted further into the image forming device 10, the upper surface 97 of the cartridge engagement member 94 abuts the lower surface of the cartridge shutter 62, and pushes the cartridge shutter 62 toward open position. This movement is resisted by the surface 92b of the protrusion 92 on each developer engagement arm 90, in contact with a corresponding surface of the side wall recess 98, requiring the application of a force FC-UNLOCK to deform the protrusion 92 and move the shutter 62 from the closed position. As discussed below, since the surface 91a forms a lesser angle with the direction of the applied force (vertical in
Once displaced from the fully closed position, the developer engagement arms 90 are locked into engagement with the cartridge engagement member 94 by the side walls 61, as depicted in
As the cartridge 27 is withdrawn from the image forming device 10, the cartridge engagement member 94 pulls the cartridge shutter 62 from the fully open position to the closed position (
The embodiment depicted in
In an image forming device 10 having the above-described features, according to either embodiment of the cartridge shutter 62 (both of which, like the disclosed embodiment of the developer shutter, are representative only and not limiting), toner is retained in the toner cartridge 27 and the developer 23 when the cartridge 27 is not seated in the image forming device 10. Upon inserting a new cartridge 27, the cartridge shutter 62 is opened by abutment against the developer 23, and the developer shutter 80 is opened by abutment against the cartridge 27, as the cartridge 27 moves into the image forming device 10. The cartridge shutter 62 also releasably engages the developer 23, and the developer shutter 80 releasably engages the cartridge 27. As the cartridge 27 is fully seated in the image forming device 10, both the cartridge shutter 62 and the developer shutter 80 are in their respective open positions, and toner may freely flow from the toner cartridge 27, through the cartridge toner passage 63, the developer toner passage 82, and into the developer 23.
When the toner cartridge 27 is depleted of toner and removed from the image forming device 10, the cartridge shutter 62 is pulled to the closed position by the developer engagement member 86, and the developer shutter 80 is pulled to the closed position by the developer shutter engagement arms 76. When both shutters are closed, as the cartridge 27 is further removed from the image forming device 10, the cartridge shutter 62 disengages from the developer 23 and the developer shutter 80 disengages from the cartridge 27, and the cartridge 27 is removed. Notably, for both insertion and removal of the toner cartridge 27, only a single motion is required by a user: vertical, in the embodiments depicted above. That is, no twisting or other motion other than insertion/removal of the toner cartridge is required to actuate the cartridge and developer shutters. Additionally, no springs are required to close the shutters, resulting in a lower-cost design.
In one embodiment, the engagement of the cartridge shutter 62 to the developer 23 and the engagement of developer shutter 82 the cartridge 27 upon inserting the cartridge 27, as well as the relative disengagement of these parts upon removing the cartridge 27, do not occur simultaneously, to avoid large forces (i.e., FC-COUPLE+FD-COUPLE and FC-DECOUPLE+FD-DECOUPLE) associated with simultaneous engagement/disengagement deflection. The relative timing of the coupling engagements can be controlled by the relative positioning of the engagement points along the length of the cartridge 27 travel.
For the step-by-step sequence of events described above to occur in the proper order, some relationships among the various forces imposed by detents and coupling members must be observed. In particular, upon inserting the cartridge 27 into an image forming device 10, each shutter should couple to its corresponding part prior to being dislodged from the closed position, to ensure that it will be returned to the closed position when the cartridge 27 is removed from the image forming device 10. That is, for each shutter, FUNLOCK>FCOUPLE. Similarly, upon removing the cartridge 27, each shutter should be locked into the fully closed position prior to decoupling from the corresponding part moving it, to ensure that toner is sealed within the part. That is, for each shutter, FUNCOUPLE>FLOCK. Accordingly, for proper operation, FUNLOCK>FLOCK, FUNCOUPLE>FCOUPLE, or both.
One way to control the different lock/unlock forces imposed by a detent and the different couple/decouple forces imposed by a releasable engagement mechanism is by varying the angles of contact with the corresponding surface. As an example, consider FD-UNCOUPLE, controlled by the surface 78b of the developer shutter engagement arm 76, depicted as a free body diagram having a horizontal orientation in
The magnitude of the force F required to deflect the engagement arm 76 is known (determined by, e.g., the length and resilience of the arm 76, the depth of the developer shuttle engagement recess 84, and the like). If the angle of surface 78b with the horizontal is ⊖, then the applied force FAPPLIED=FD-UNCOUPLE necessary to deflect the arm 76 is F*tan(⊖). If ⊖=0, FD-UNCOUPLE=0. If ⊖=90, FD-UNCOUPLE=∞. Thus, for a given force F, the force required to uncouple the developer shuttle may be varied between 0 and ∞ by varying the angle ⊖ of contact (of course, with respect to this particular example, the fact of two developer shutter engagement arms 76 must be taken into account).
Similarly, if surface 78a makes an angle φ with the horizontal, then FD-COUPLE=F*tan(φ) is required to deflect the developer shutter engagement arm 76 by the angled developer shutter surface 83 upon inserting the cartridge 27 into the image forming device 10. In similar fashion, the relative couple/decouple forces imposed by the cartridge shutter engagement arms 64, 90 may be controlled by the relative angles of surfaces 66a and 66b, and 91a and 91b, respectively. The relative lock/unlock forces imposed by the detents 68, 88, 92 may be controlled by the relative angles of surfaces 70b and 70a, 88b and 88a, and 92a and 92b, respectively.
The present invention may, of course, be carried out in other ways than those specifically set forth herein without departing from essential characteristics of the invention. The present embodiments are to be considered in all respects as illustrative and not restrictive, and all changes coming within the meaning and equivalency range of the appended claims are intended to be embraced therein.