Abstract: In a copier, printer, or similar device, paper is loaded in large quantities. To separate a top sheet of a stack of sheets from the next adjacent sheet, a dam is used, which is an element having an inclined surface in the path of the top sheet. This invention addresses devices with variably compliant separation strips, preferably a thermoplastic polyurethane elastomer such as Pellethane®, that are part of the dam, so that the leading edge of a media sheet will strike the inclined surface of the separation strip. By adjusting the compliance of the separation strip, different weights of media may be accommodated while minimizing the multi-feeds that may cause jamming of the device.

Abstract: In a copier, printer, or similar device, paper is loaded in large quantities. To separate a top sheet of a stack of sheets from the next adjacent sheet, a dam is used, which is an element having an inclined surface in the path of the top sheet. This invention addresses devices with variably compliant separation strips, preferably a thermoplastic polyurethane elastomer such as Pellethane®, that are part of the dam, so that the leading edge of a media sheet will strike the inclined surface of the separation strip. By adjusting the compliance of the separation strip, different weights of media may be accommodated while minimizing the multi-feeds that may cause jamming of the device.

Abstract: The present application is directed to sensors and methods of use to determine a width of a media sheet moving along a media path. In one embodiment, the sensor includes a shaft that extends at least partially across the media path. First and second paddles may extend outward from the shaft and into the media path. The paddles may be axially spaced apart along a length of the shaft, and the first paddle may be positioned upstream along the media path from the second paddle. A flag may extend outward from the shaft. A detector may be positioned in proximity to the shaft. In use, the shaft may rotate during contact between the media sheets and the paddles to move the flag. The detector may be able to differentiate between a first amount of rotation due to contact with a wide media sheet and a second amount of rotation with a narrow media sheet to determine a width of the media sheets.

Abstract: A fuser assembly includes a fuser housing, a fuser roller rotatably mounted to the fuser housing, an actuator mechanism, and a fuser detack mechanism. The fuser detack mechanism includes a detack housing pivotably mounted to the fuser housing. The fuser detack mechanism is pivoted from a first position to a second position when the actuator mechanism is actuated. A plurality of detack fingers is mounted to the detack housing. Each of the plurality of detack fingers has a distal end, wherein when the fuser detack mechanism is in the first position, the distal end of each of the plurality of detack fingers is positioned to be disengaged from an exterior surface of the fuser roller, and when the fuser detack mechanism is in the second position, the distal end of each of the plurality of detack fingers is positioned to be engaged with the exterior surface of the fuser roller.

Abstract: A fuser assembly includes a fuser housing, a fuser roller rotatably mounted to the fuser housing, an actuator mechanism, and a fuser detack mechanism. The fuser detack mechanism includes a detack housing pivotably mounted to the fuser housing. The fuser detack mechanism is pivoted from a first position to a second position when the actuator mechanism is actuated. A plurality of detack fingers is mounted to the detack housing. Each of the plurality of detack fingers has a distal end, wherein when the fuser detack mechanism is in the first position, the distal end of each of the plurality of detack fingers is positioned to be disengaged from an exterior surface of the fuser roller, and when the fuser detack mechanism is in the second position, the distal end of each of the plurality of detack fingers is positioned to be engaged with the exterior surface of the fuser roller.

Abstract: The present application is directed to methods of determining a width of a media sheet moving along a media path of an image forming apparatus. The methods may include moving the media sheet along the media path and past a media width sensor that includes a shaft with a first upstream paddle positioned away from a reference location of the media path and a second downstream paddle positioned in closer proximity to the reference location. The first paddle is positioned a first distance from the first sensor, and the second paddle is positioned a second distance from the first sensor. As the media sheet moves along the media path, a first signal may be received when the media sheet contacts the first sensor, and a second signal when the media sheet is at the media width sensor. The distance the media sheet travels between contacting the first sensor and being at the second sensor may be determined.

Abstract: The present application is directed to sensors and methods of use to determine a width of a media sheet moving along a media path. In one embodiment, the sensor includes a shaft that extends at least partially across the media path. First and second paddles may extend outward from the shaft and into the media path. The paddles may be axially spaced apart along a length of the shaft, and the first paddle may be positioned upstream along the media path from the second paddle. A flag may extend outward from the shaft. A detector may be positioned in proximity to the shaft. In use, the shaft may rotate during contact between the media sheets and the paddles to move the flag. The detector may be able to differentiate between a first amount of rotation due to contact with a wide media sheet and a second amount of rotation with a narrow media sheet to determine a width of the media sheets.