An optical scanning device includes a cleaning member held to a holing member and reciprocally moving on a surface of a transparent cover according to reciprocal movement of the holing member, thereby cleaning the surface. The cleaning member is configured such that a front side surface of the cleaning member in a progress direction during the reciprocal movement serves as an inclination surface obliquely crossing the progress direction when viewed from a direction vertical to the surface of the transparent cover, and at an outer side of the transparent cover in a direction perpendicular to the progress direction, a concave portion is formed to collect foreign matters moving to the outer side along the inclination surface according to the movement of the cleaning member.

An image forming apparatus includes a main body housing, a photosensitive drum, an exposure device, a developing device, a toner container, a transfer roller, a fixing device, a cleaner and a waste toner container. The main body housing includes a front wall and a rear wall opposite to the front wall in a horizontal direction. The photosensitive drum is located further from the front wall than the photosensitive being from the rear wall. The toner container includes a first front end. The waste toner container including a second front end. A distance between the second front end of the waste toner container and the front wall of the main body housing in the horizontal direction is smaller than a distance between the first front end of the toner container and the front wall of the main body housing in the horizontal direction.

An image forming apparatus has a photoconductive member and a cleaning member arranged to face the photoconductive member at a cleaning position and configured to be applied with a cleaning bias to collect residual developing agent on the photoconductive member after the developed image is transferred. A controller of the image forming apparatus controls a transferring bias so that a transferring current representing a current flowing between the photoconductive member and a transferring member is controlled to become a target current value. Further, the controller calculates a cleaning position potential representing a surface potential of the photoconductive member at the facing position based on the transferring current and a charge potential representing a surface potential of the photoconductive member immediately after being charged by the charging device, and controls the cleaning bias based on the cleaning position potential as calculated.

An optical scanning device (12) includes cleaning holders (511, 512), light transmitting members (52), a linear member (54), a winding motor (55), and stoppers (56a, 56b). The two cleaning holders (511, 512) are coupled to the linear member (54). The linear member 54 is driven to circulate by the winding motor (55), whereby the two cleaning holders (511, 512) move and each cleaning member slides on a corresponding one of the light transmitting members (52). When the cleaning holders (511, 512) come into contact with the respective stoppers (56a, 56b), the stoppers (56a, 56b) restrict movement of the respective cleaning holders (511, 512) in one of directions of extension of the light transmitting members (52). A contact determining section (913) determines, based on a current value of the winding motor (55), that the cleaning holder (511, 512) has come into contact with the stopper (56a, 56h).

An image forming apparatus includes a rotatable image bearer, a toner image forming device, a transfer device, a transfer bias power source, and a cleaner. The toner image forming device is to form a toner image on the image bearer. The transfer device contacts a surface of the image bearer to form a transfer nip between the transfer device and the image bearer. The transfer bias power source is to output a transfer bias to transfer the toner image from the image bearer onto a recording medium in the transfer nip. The cleaner is disposed downstream from the transfer nip in a direction of rotation of the image bearer, to electrostatically attract and remove toner from the surface of the image bearer to a surface of the cleaner. The transfer bias includes an alternating current component.

An image forming apparatus (1) includes a photosensitive drum (50), a cleaning blade (81), and a drive mechanism (90). The cleaning blade (81) is in pressed contact with a circumferential surface of the photosensitive drum (50). The drive mechanism (90) causes one of the photosensitive drum (50) and the cleaning blade (81) to reciprocate in a rotational axis direction (D) of the photosensitive drum (50). The drive mechanism (90) for example causes the photosensitive drum (50) to reciprocate in the rotational axis direction (D). The photosensitive drum (50) includes a photosensitive layer (85). An outermost layer of the photosensitive layer (85) contains a plurality of particles.

In an example implementation, a method of cleaning a silicon photoconductor includes contacting the silicon photoconductor with a base-peroxide solution, rinsing the silicon photoconductor with a liquid, and heating the silicon photoconductor to evaporate the liquid.

An image-forming apparatus includes an apparatus body and a process cartridge attachable to and detachable from the apparatus body. The apparatus body includes a sheet-feed roller and a body wall. The process cartridge includes: a photosensitive drum; a drum frame; a developing roller; a cleaner; a conveying pipe and a waste-toner container for storing waste toner removed from the photosensitive drum by the cleaner and conveyed by the conveying pipe. The waste-toner container is detachably mountable on the drum frame. The waste-toner container mounted on the drum frame is positioned opposite to the photosensitive drum with respect to the developing roller. The body wall of the apparatus body and a container wall of the waste-toner container constitute a part of a sheet-conveying guide for guiding conveyance of a sheet from the sheet-feed roller toward the photosensitive drum when the process cartridge is attached to the apparatus body.

The image forming apparatus includes a control unit that executes a supply operation to supply a toner charged with a regular charge polarity, to at least one abutting portion of a plurality of abutting portions, at the time of image non-formation, the plurality of abutting portions being formed by a plurality of cleaning members and a plurality of image bearing members, the control unit determining an image bearing member to which the most amount of the toner charged with the regular charge polarity is supplied, based on image formation information, the image formation information being information about an image formation executed before the supply operation is executed.

An electrophotographic image forming apparatus which sequentially performs charging, exposure, development, transfer and cleaning on each surface portion of a photoreceptor during rotation includes: a cleaning blade configured to scrape off toner from the surface of the photoreceptor; a detecting unit configured to detect a rotation angle of the photoreceptor; and a control unit configured to control each of a start process and an end process of rotation of the photoreceptor and charging, development and transfer of the photoreceptor, wherein, in the end process, the control unit estimates a position of a surface portion of the photoreceptor, at which a charged state caused by a peeling discharge remains even after the stop of the photoreceptor, from the rotation angle from the time of start of deceleration of the photoreceptor to the time of stop of the photoreceptor, and adjusts parameters necessary for the next start process or end process.