An image forming apparatus includes: an image carrier that carries a toner image; a cleaning unit that collects a toner on the image carrier; and a hardware processor that controls the cleaning unit, wherein the cleaning unit includes a first cleaner brush and a second cleaner brush that remove the toner from the image carrier, and the hardware processor applies bias voltages having opposite polarities to the first cleaner brush and the second cleaner brush, and determines whether life is ended with respect to each of the first cleaner brush and the second cleaner brush.

Novel materials and devices can remove small defects from long rolls of flexible electronics material while they are in continuous motion. The cleaning materials are designed to remove small particles without transferring defects or damaging the flexible electronics. The device generally consists of variable speed, motor-driven cylinders mounted on movable brackets. The cylinders are capable of matching the speed of the cleaning material such that the cleaning material is always in contact with the web roll to be cleaned. The brackets are capable of rotating so the same material can be used more than once. Another material is used to remove debris from the cleaning material. A similar device consisting of motor-driven cylinders and movable is used to apply the debris removal film to the cleaning film, allowing the cleaning film to be used multiple times.

Novel materials and devices can remove small defects from long rolls of flexible electronics material while they are in continuous motion. The cleaning materials are designed to remove small particles without transferring defects or damaging the flexible electronics. The device generally consists of variable speed, motor-driven cylinders mounted on moveable brackets. The cylinders are capable of matching the speed of the cleaning material such that the cleaning material is always in contact with the web roll to be cleaned. The brackets are capable of rotating so the same material can be used more than once. Another material is used to remove debris from the cleaning material. A similar device consisting of motor-driven cylinders and moveable is used to apply the debris removal film to the cleaning film, allowing the cleaning film to be used multiple times.

Novel materials and devices can remove small defects from long rolls of flexible electronics material while they are in continuous motion. The cleaning materials are designed to remove small particles without transferring defects or damaging the flexible electronics. The device generally consists of variable speed, motor-driven cylinders mounted on moveable brackets. The cylinders are capable of matching the speed of the cleaning material such that the cleaning material is always in contact with the web roll to be cleaned. The brackets are capable of rotating so the same material can be used more than once. Another material is used to remove debris from the cleaning material. A similar device consisting of motor-driven cylinders and moveable is used to apply the debris removal film to the cleaning film, allowing the cleaning film to be used multiple times.

Novel materials and devices can remove small defects from long rolls of flexible electronics material while they are in continuous motion. The cleaning materials are designed to remove small particles without transferring defects or damaging the flexible electronics. The device generally consists of variable speed, motor-driven cylinders mounted on moveable brackets. The cylinders are capable of matching the speed of the cleaning material such that the cleaning material is always in contact with the web roll to be cleaned. The brackets are capable of rotating so the same material can be used more than once. Another material is used to remove debris from the cleaning material. A similar device consisting of motor-driven cylinders and moveable is used to apply the debris removal film to the cleaning film, allowing the cleaning film to be used multiple times.

A cleaning device cleans a surface of a toner carrier carrying a toner, and the cleaning device includes: a first blade in contact with the surface of the toner carrier; a second blade made of a material harder than a material of the first blade and in contact with the surface of the toner carrier; and a lubricant applicator that applies a lubricant to the surface of the toner carrier, wherein the first blade, the second blade and the lubricant applicator are arranged in this order from an upstream side in a moving direction of the toner carrier based on a transfer position of the toner.

In one example, a method for calibrating a position of a charge roller is described. The method may include a processor positioning a first end of a charge roller to a first plurality of index positions, determining a capacitance between the charge roller and a photoconductor imaging plate at each of the first plurality of index positions, determining a first index position of the first plurality of index positions with a greatest change in capacitance, and calibrating a position of the charge roller based upon the first index position.

An image carrying member unit has an image carrying member, a charging member, a pair of first bearing members, a biasing member, and a supporting frame. The image carrying member is rotatable, and an electrostatic latent image is formed on it. The charging member is arranged in contact or close to the image carrying member, and electrostatically charges the image carrying member. The first bearing members support the charging member movably in directions to and away from the image carrying member. The biasing member biases the charging member toward the image carrying member. The supporting frame supports the image carrying member and the first bearing members. The first bearing members each have a fulcrum rotatably supported on the supporting frame, an arm extending radially from the fulcrum, and a bearing portion formed at a tip end of the arm and supporting axially either end of the charging member.

Examples of refreshing a photoconductive layer in an image forming apparatus are described. In one example, a method includes performing a first refreshing cycle comprising applying, at a first refresh unit, a first refresh voltage to the photoconductive layer and applying, at a second refresh unit, a second refresh voltage to the photoconductive layer. A second refreshing cycle is performed including applying, at the first refresh unit, a third refresh voltage to the photoconductive layer, the third refresh voltage being higher than the first refresh voltage and higher than the second refresh voltage. Each of the first and second refreshing cycles electrically bias the photoconductive layer to a refresh polarity opposite to a print polarity applied during a print routine of the image forming apparatus.

An image forming apparatus includes an image bearing member to form a toner image on a recording material with a liquid developer containing a toner and a carrier liquid, wherein the carrier liquid contains a first substance, charged to an opposite polarity to a charge polarity of the toner, for imparting an electrical polarity to the toner, and a second substance, higher in volume resistivity than the first substance, a cleaning portion to collect the liquid developer remaining on the image bearing member after the toner image is transferred onto the recording material, a toner separating device to separate the collected liquid developer into the toner and the carrier liquid, and a carrier separating device to separate the carrier liquid into the carrier liquid containing the first substance and the carrier liquid containing the second substance by applying an electric field to the carrier liquid.