An image forming apparatus includes at least an image bearer; an electrostatic latent image former to form an electrostatic latent image on the image bearer; an image developer to develop the electrostatic latent image with a toner to from a toner image; a first transferer to transfer the toner image from the image bearer onto an intermediate transfer belt; and a cleaner including a cleaning blade having a Martens hardness of from 0.8 to 10.0 N/m.sup.2, to clean the intermediate transfer belt while contacting the surface of the intermediate transfer belt. The intermediate transfer belt includes a thermoplastic resin and a conductive resin, and has a surface concentration of oxygen atoms derived from the conductive resin, measured by XPS, of from 1.0% to 3.0% by atom.

An image forming apparatus (1) includes image bearing members (31), transfer members (52), and a power supply section (57). The image bearing members (31) each bear one of toner images in different colors from one another. The transfer members (52) are located opposite to the image bearing members (31). The power supply section (57) charges the transfer members (52). Through the above, the toner images on the respective image bearing members (31) are transferred to a moving transfer target (51). The power supply section (57) includes a power supply device (58 or 58a) connected to at least two of the transfer members (52). The transfer members (52) connected to the power supply device (58 or 58a) are each located at a position shifted upstream or downstream of a corresponding one of the image bearing members (31) in a moving direction (X) of the transfer target (51).

An image forming apparatus (1) includes photosensitive drums (41y, 41c, 41m, and 41k), static eliminators (45y, 45c, 45m, and 45k), transfer rollers (54y, 54c, 54m, and 54k), a power source (55a) for transfer, and load resistors (47y, 47c, 47m, and 47k). The static eliminators (45y, 45c, and 45m) perform static elimination on adjacently upstream or downstream photosensitive drums (41y, 41c, 41m, and 41k) in a movement direction of a transfer target. The transfer rollers (54y, 54c, 54m, and 54k) are disposed opposite to the respective photosensitive drums (41y, 41c, 41m, and 41k). The power source (55a) for transfer applies potential to the transfer rollers (54y, 54c, 54m, and 54k). The load resistors (57y, 57c, 57m, and 57k) are respectively connected in parallel to one another and in series between the power source (55a) for transfer and the respective transfer rollers (54y, 54c, 54m, and 54k).

A transfer apparatus includes a transfer unit, a detector, a supplying unit, and a controller. The transfer unit transfers a toner image onto an object onto which transfer is to be performed. The detector detects humidity. The supplying unit includes a constant voltage supplying unit that supplies a transfer voltage that is a constant voltage to the transfer unit, and a constant current supplying unit that supplies a transfer current that is a constant current to the transfer unit. The controller controls the supplying unit such that the transfer voltage is supplied from the constant voltage supplying unit to the transfer unit when transfer is performed in a case where the detected humidity is not greater than a threshold, and the transfer current is supplied from the constant current supplying unit to the transfer unit when transfer is performed in a case where the detected humidity exceeds the threshold.

Printers comprising a plurality of imaging units are described. In an example, each imaging unit selectively deposits at least one printing substance and an intermediate transfer member cooperates with the imaging units such that, in use of the printer, a printable image may be formed thereon, the printable image comprising printing substance from at least two imaging units.

There is provided an image forming apparatus including: an intermediate transfer belt; a photosensitive drum; a primary transfer member; a secondary transfer member; a first backup member; a first power supply electrically connected to the primary transfer member and to the secondary transfer member; and a first resistor electrically connected to the first power supply and to the primary transfer member. A first current route, in which the first resistor, the primary transfer member, and the photosensitive drum are connected in series in that order, is connected to the first power supply and to a basis potential. A second current route, in which the secondary transfer member and the first backup member are connected in series, is connected to the first power supply and to the basis potential. The first current route is connected in parallel to the second current route.

A high-quality electrophotographic endless belt and a method capable of efficiently producing the belt are provided. A method for producing an electrophotographic endless belt comprising a base layer including a thermoplastic resin composition and an inner-surface layer, which includes: (1) forming an energy curable film having a glass transition temperature on an inner surface of a test tube-shaped preform including a thermoplastic resin and then subjecting the preform to blow molding to obtain a blow-molded bottle; (2) irradiating the blow-molded bottle with energy rays to cure the film to form an inner-surface layer; and (3) cutting out an endless belt from the blow-molded bottle having the inner-surface layer obtained in (2).

An image forming apparatus according to an embodiment includes a first image forming unit that forms a transparent toner image and a second image forming unit that forms a color toner image. The transparent toner image and the color toner image are transferred onto an intermediate transfer belt. A secondary transfer unit transfers the toner images from the intermediate transfer belt to a recording medium. A control unit controls the first image forming unit and the second image forming unit so that the transparent toner image is formed before the color toner image is formed when the recording medium is a specialty paper having an adhesive.

An image forming apparatus includes an apparatus body having an image forming unit that is configured to an image on a recording material, and a fixing unit removably attached to the apparatus body to fix the image on the recording material. The fixing unit includes a roll member having a roll body and a bearing provided at each end of the roll body to support the roll body rotatably, a pressurizing member provided in contact with the roll member to form a fixing pressurizing portion through which the recording material passes, and a storage member that stores the roll member and the pressurizing member in a state in which the roll member and the pressurizing member are pressed with a predetermined pressure. The apparatus body includes a positioning member that is in contact with the bearing to position the roll member in a transport direction of the recording material.

A belt device includes a belt member, a detected unit, a window, an optical detector, and a regulation member. The belt member is movable in a direction of belt movement. The detected unit disposed on at least one side of the belt in a width direction of the belt intersecting with the direction of belt movement and extending in the direction of belt movement. The window transmits detection light emitted toward the detected unit and reflected light from the detected unit. The optical detector detects the detected unit. The regulation member is disposed on at least one side in a width direction of the window to keep the detected unit away from the window.