The continuous belt described in this disclosure includes a wide range of applicable belts including systems using media belts, photoconductor belts, photoreceptor belts, intermediate transfer belts, electrostatic belts and transport belts. While the present invention can be used in all of these above-noted systems, it will be described herein for clarity as used in electrostatic marking systems.
By way of an example, in one color system, an array or series of different color imaging stations are aligned above an endless belt. Each imaging station contains a raster output scanner (ROS), photoreceptor drum, development station and cleaning station. The ROS emits an electronic beam (laser) which impinges on the rotating photoconductive drum thereby causing that location on the drum to undergo a change in electrical charge. As the drum continues to rotate past the development station, toner particles of a color which is unique to that imaging station will attach to the drum at the location charged by the ROS. This colored image is then transferred to an intermediate transfer belt that is passing by and in contact with the photoreceptor drum. As the intermediate belt passes by the different imaging stations (each usually containing a different color), it picks up subsequent color layers to create a complete color image which is then transferred to media.
In today's high speed systems, the intermediate belt is in contact with several abrading components of the marking system such as other belts, drums, rolls, cleaning blades/brushes, etc. and frequently needs replacement. Care must be taken when installing new belts since even minor damage to the belt could cause it to lose functionality totally or partially. Current methods require handling of exposed and/or loose belt to place belt over a series of rollers. Removal/handling of a belt module and removal/handling of the belt increases probability of module/belt damage. The complication of the current prior art approach restricts continuous belt replacement to a technical service call.
In these electrostatic marking systems, a photoreceptor belt surface is generally arranged to move in an endless path through the various processing stations of the xerographic process. Sometimes, the photoreceptor or photoconductor surface is in the form of an endless belt and in other systems it is in the form of a drum. In this endless path, several xerographic-related stations are traversed by the photoconductive belt, which becomes worn as are belts in several of these stations in various belt configurations. In addition to photosensitive belts included for use in this invention are transfer belts, intermediate transfer belts, and the like. Each of these belts is exposed to friction and moved by rollers that provide the belt movement to accomplish the belt purpose. After awhile, the belt needs to be replaced. Since the intermediate transfer and photoreceptor surface in particular are reusable, the surface of the belts is constantly abraded and cleaned by a blade and/or brushes and prepared to be used once again in the marking process.
Image-carrying belts such as intermediate or photoreceptor belts used in color printing processes can be especially difficult to replace and install. In some machines, the horizontal intermediate transfer belt is over 6-10 feet long; however, any suitable length belt may be used in the present invention. Belt installation requires careful alignment with the belt module to prevent belt damage. At even longer belt lengths, the replacement operation is extremely difficult to install without belt damage occurring.
Even in monochromatic marking systems that use shorter belts for various functions, extreme care must be taken not to damage the belts during installation. In some instances, the belts are constructed of thin flexible polymeric materials that can easily scratch or be damaged during belt replacement or even during original installation.
Embodiments of belt installation of this invention in marking systems provide belt alignment during the installation process with a minimum of belt damage.
The present invention provides a cartridge or kit and a system for installing continuous belts in a marking or non-marking system. As noted above for clarity, the present invention will be described with reference to a xerographic color or monochrome marking system.
The present invention addresses the problem of installing a long continuous belt such as may be required for present day high speed marking systems. Current prior art methods require handling of the exposed or loose stationary holder belt to place it over a series of rollers with risk of damage and normally requires a service call. The present invention consists of a self-contained cartridge or kit with a rolled or coiled continuous belt. The cartridge would be installed on one of the print device drive or idler rolls at one end of the belt path. The outer covering of the belt cartridge would be removed to allow access to a traveling roller containing one end of the continuous belt. The traveling roller would be engaged to a pair of mating gear tooth racks in the printer. The traveling roller would be turned or translated to advance the belt to the opposite end of the printing device for belt installation to a print device roller that mounts the belt. The traveling roller may be moved manually or mechanically depending on design embodiment. The empty cartridge would then be removed. This invention addresses the difficult problem of how to install a very long belt through a complex set of imaging modules in some instances obstructed by the machine components. The method will require the rollers, backer bars and other components that operate inside the belt during running of the machine to be easily removed or moved out of the way while the belt is being deployed. The method has the advantage of scaling well to very long belts.
In
In
The cartridge 26 will be placed in the print device between two frame members on one of the main drive/idler rolls 16. (See
The belt 3 stationary loop (end) is mounted on the center roll 18A in the belt cartridge 26. The belt 3 is then coiled around the two outside rolls 18 to enable cartridge rotation as the traveling roll 21 is moved laterally across the print device. The three roll 18 concept is employed to avoid the possibility of a kink in the continuous belt 3.
The center cartridge roll 18A and the traveling roll 21 will act as a temporary belt mount to allow the belt 3 to be transitioned to the print device drive/idler rolls 16 and 14. The traveling roll 21 will be located through the insertion of the machine drive/idler roll 14. The cartridge roll 18 with end cap 19 and traveling roll 21 will be removed to allow the print device shafts/rolls to engage the inner surface of the media/photoconductor belt. The inboard belt cartridge end cap 20 will be removed after installation is complete and all additional backer rolls and belt module components will be placed in working position to complete belt alignment and tensioning. (See
In
Once the travel roll 21 reaches its destination (in this case roller 14 of
Each module (six modules in
In summary, this invention provides a kit or cartridge useful in installing an endless belt in a module(s) of a belt-containing system. This cartridge comprises, in addition to a belt to be installed, a sheath to cover and contain cartridge components, at least two internal cartridge rolls around which the belt is wound, a traveling roll around which the belt is positioned and gear racks on which the traveling roll will move. The belt is enabled to be movably connected on one end to one of the internal cartridge rolls and on an opposite end to the traveling roll. The end caps have conduits located at each end of the internal cartridge rolls.
The gear racks are enabled to be connected to internal sides of frame members located in the module. The at least two internal cartridge rolls are preferably from 2 to 5 internal cartridge rolls; however, any suitable number of cartridge rolls may be used
The traveling roll is configured to move on and along the racks from one end of the module to an opposite end. The conduits are adapted to receive therein a drive/idler roll and are enabled to rotate around the drive/idler roll during a belt installation process. The belt is configured to unwind from around the internal cartridge rolls as the travel roll moves away from the cartridge rolls. The cartridge is useful in systems having from 1 to a plurality of modules. Any suitable number of modules may be used.
All components of the cartridge except the endless belt are enabled to be disposed of and removed from the module after a belt installation. The cartridge is configured to be mounted on an original print engine drive/idler roll.
The cartridge is especially useful in a belt installation of a xerographic marking system. The cartridge wherein the belt is configured to be installed in a xerographic marking system uses this belt to replace a belt selected from the group consisting of media belts, photoconductor belts, photoreceptor belts, intermediate transfer belts, electrostatic belts, transport belts, cleaning belts and mixtures thereof.
The embodiments of this invention comprise a kit or cartridge especially useful in installing an endless belt in a module(s) of a xerographic marking system. The cartridge comprises, in addition to a belt to be installed, a sheath to cover and contain cartridge components, at least two internal cartridge rolls around which the belt is wound, a traveling roll around which the belt is positioned and gear racks on which the traveling roll will move. The belt is enabled to be movably connected on one end to one of said internal cartridge rolls with end caps with conduits that are located at each end of the internal cartridge rolls and on an opposite end to the traveling roll. The traveling roll comprises a turn knob for moving the traveling roll along these gear racks through an entire path of the traveling roll. The cartridge contains three internal cartridge rolls.
The endless belt is enabled to be looped at one terminal end around one of the internal cartridge rolls and at an opposite terminal end around the traveling roll enabled to thereby cause the belt to unwind from around the three internal cartridges as the traveling roll moves away from the internal cartridge rolls.
The belt-installing method of this invention in an embodiment comprises in a modular apparatus the use of an endless belt. The apparatus contains a plurality of belt-supporting and driver/idler rolls. This method comprises connecting a cartridge with at least two internal cartridge rolls to a first occurring of the rollers. The cartridge comprises a wound up endless belt, removing all other rollers except the first occurring roller from the apparatus, positioning a traveling roller at an original position on supporting racks adjacent the first occurring of the rollers, moving the traveling roller away from the cartridge and the first occurring of the rollers until it causes the endless belt to unwind from around the internal cartridge rolls.
The last occurring roller is inserted through or in front of the traveling roller where the unwound endless belt is looped around the last occurring roller. Subsequently, the cartridge is removed and the traveling roller are removed from the apparatus to thereby result in an installation of the endless belt in place in the apparatus. In one embodiment, the apparatus is an electrophotographic marking apparatus. In this method, the endless belt is looped around the first occurring and the last occurring rollers before all other removed rollers are replaced in the apparatus. The apparatus comprises any suitable number of modules greater than 1.
It will be appreciated that several of the above-disclosed and other features and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Various presently unforeseen or unanticipated alternatives, modifications, variations, or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.