Abstract: A conductive paste comprising a flexible elastomer, an electrically conductive particulate material and, optionally, a solvent is disclosed. This paste is used for providing flexible, electrically conductive bonding between materials. In a preferred embodiment, conductive paste of the present invention is used in a flexible doctor blade to provide bonding and an electrical connection between the support member and the portion of the blade which contacts the developer roller.

Abstract: The conductive film (3) of a compliant doctor blade has dispersed particles of molybdenum disulfide, as well as dispersed particles of grit and conductive filler. The molybdenum disulfide eliminates filming of toner. The molybdenum disulfide may be a surface powder since the anti-film action occurs at the pre-nip and therefore is not lost by the molybdenum disulfide wearing away at the nip.

Abstract: A compliant doctor blade having excellent toner metering capabilities is disclosed. The doctor blade includes a compliant laminate (3) having a resin film backing layer and carrying a binder which contains abrasive particles, such as silicon carbide particles, and a conducting means. In a preferred embodiment the conducting means are conductive carbon black particles which are contained in the resin binder which also includes the abrasive silicon carbide. The compliant laminate is supported on an aluminum bar (1). The bar has fastened to its bottom face a compliant foam layer (2) which includes on its bottom face a shim (10) having a stiffness of from about 0.5 to about 31.0 inches of deflection/inch of length/pounds of force. The laminate is bent under the foam layer and shim where it contacts the developer roller (6). The conductive layer remains conductive as it wears during use.

Abstract: Doctor blade 1 has a compliant lamination (4) having a resin film backing layer (4a) and conductive layer (4b) abrasive silicon carbide particles and conductive carbon black in a resin binder. The compliant lamination is supported on an aluminum bar 2, having a downwardly extending wall 2b. In use lamination 2 is bent under the support bar at the end of the wall, a direct turn which avoids a wedge configuration where the lamination contacts the developer roller (7). The conductive layer remains conductive as it wears during use and the avoidance of the wedge prevents a build-up of toner at the nip during use, both of which make possible long effective useful operation of this doctor blade.

Abstract: The charging roller (42) and push plates (44) are spring mounted to the lid (36) of the printer. When the lid is closed, the plates push plungers (11) down to rotate crank arms (23), which open a shutter (7) in electrophotographic cartridge (1). This holds the cartridge in place and provides both a resilient, protective cushion for the cartridge and a pop-up action to the lid.

Abstract: A toner cartridge having no toner pump with the toner adding roller (11 ) positioned horizontal to the developer roller (3), the toner chamber (9) located predominantly below the developer roller, the photoconductive drum located 120 degrees from the top of tile developer roller, and the doctor blade (5) is located near the top. The cartridge has a minimal number of operational parts.

Abstract: In a toner cartridge, photoconductor drum (11) is driven by a gear (3) which is in the printer, toner adder roller (48) is driven independently by a face coupling (5) which is in the printer. On the opposite side, a gear train from toner adder roller (48) drives developer roller (42) and toner paddle (52). The two systems permit the cartridge to function in different printers requiring different ratios of speeds. Stiffness requirements of the cartridge are reduced. Movements are more consistent, and space utilization is enhanced.