A single pass inkjet printer that utilizes a modular printing system with one or more self-contained printing modules, where each printing module is easy to remove and replace from a large printing machine, thus resulting in an overall system that is easy to service and maintain Each module is a self-contained printer including an ink supply, printhead drive electronics, and printhead assembly in order to provide one color or fluid of inkjet printing capability. Each module includes a precise three-point compliant self-aligning mount system to obtain accurate printhead positioning, and a unique integrated printhead tending system that includes a compact movable vacuum knife for cleaning the printheads, and a printhead capping station for sealing and protecting the printheads from the ambient environment when not in use.

A system is disclosed. The system includes at least one physical memory device to store compensation logic and one or more processors coupled with the at least one physical memory device to execute the compensation logic to generate first ink deposition function representing a first output ink amount versus input digital count for each of a plurality of color planes, generate second ink deposition function representing a second output ink amount versus input digital count for each of the plurality of color planes and generate transfer functions for each of the plurality of color planes based on the first ink deposition function and the second ink deposition function, wherein the transfer functions transform input digital counts.

Some embodiments relate to printing system is described that has an intermediate transfer member (ITM) in the form of a seamed endless belt for transporting an ink image from an image forming station, at which an ink image is deposited on ITM, to an impression station, where the ink image is transferred onto a printing substrate. Two drive members are provided for movement in synchronism with one another. Rotation of the drive members during installation of a new ITM serves to thread the strip through the printing system by pulling the strip from its leading end. Alternatively or additionally, indirect printing system comprising the ITM and an image forming station at which droplets of ink are applied to the ITM to form ink images thereon is disclosed. One or more blowing mechanisms (e.g. associated with the image forming station) are disclosed herein.

An apparatus includes: a transport path 3 that is provided in an apparatus main body 7 to transport a medium; a recording section 5 that is movable in a direction toward and away from the transport path 3; and a rack and pinion mechanism 9 that moves the recording section 5 in the direction toward and away from the transport path 3, wherein the rack and pinion mechanism 9 includes a rack 11 that is provided in the recording section 5 and is formed along a movement direction of the recording section 5 and a pinion 13 that is provided on the apparatus main body 7 and meshes with the rack 11, the recording section 5 can be attached to and detached from the apparatus main body 7, and a positioning section 19 is provided in the recording section 5 and the apparatus main body 7 for positioning so that the reference tooth 15 of the pinion 13 meshes with the reference groove 17 of the rack 11 when the recording section 5 is returned from the detached state to the attached state.

Printing system including at least a first and a second print head in which the printing system is configured in such a way that the first and second print heads can be adjusted actuator-based with respect to a printing medium by positioning and orienting using an adjustment actuator The printing system includes at least one adjustment actuator less than the number of print heads provided in the printing system, and an auxiliary device is provided in the printing system such that with the aid thereof an operative connection of the at least one adjustment actuator with the first print head can be released and/or created, and an operative connection with the second print head can be created and/or released, preferably also actuator-based or in a pneumatic and actuator-based manner, and particularly preferably automatically.

A method of printing an image from a printhead module having a plurality of horizontal ink planes M supplied with a same ink. Each ink plane has a nozzle row and the nozzles rows of all ink planes have vertically aligned nozzles. The method includes the steps of: defining contiguous span groups along each nozzle row, each span group containing N nozzles; allocating dot data for each image line of the image to a predetermined number of nozzles P in each span group of each nozzle row; sending the dot data to the printhead module and firing nozzles sequentially from the ink planes to print the image line. Only one nozzle from each span group in a same nozzle row is fired simultaneously, N is an integer multiple of M, and P is N divided by M.

A head lifting lowering device includes: a lifting lowering mechanism that moves a liquid ejecting head, which ejects a liquid, in a first direction in which the liquid ejecting head is lifted/lowered; a frame that supports the lifting lowering mechanism; and an adjusting member that moves the lifting lowering mechanism relative to the frame in a second direction different from the first direction.

Provided are a printing apparatus, a reading method, and a program capable of stably acquiring a high-quality read image. Provided are a printing section (102) that performs printing on a transparent base material to generate a printed matter; a reading section (40) that is disposed on one surface side of the base material and reads reflected light or transmitted light; an illumination section (122) including a reflective illumination part (122) that is disposed on the one surface side of the base material and irradiates the base material with illumination light and a transmissive illumination part (124) that is disposed on the other surface side of the base material and irradiates the base material with illumination light; an inspection information acquisition section (120) that acquires inspection information on an inspection performed on the printed matter; and an illumination control section (120) that selectively controls at least one of the reflective illumination part or the transmissive illumination part on the basis of the inspection information.

There is provided a head bar unit including a head bar, an adjuster and a movement. The head bar includes a plurality of heads. The adjuster is supported by the head bar, and is configured to adjust positions in a vertical direction of the heads. The movement is configured to move the head bar and the adjuster in the vertical direction. The adjuster includes a motor, a rotator and a stopper. The rotator includes a plurality of contact portions. The rotator is configured to be rotated by the motor around a rotating shaft. The stopper is located at a position facing the rotator in the vertical direction, and is configured to position the rotator in the vertical direction, by making contact with one of the contact portions.

A system is disclosed. The system includes at least one physical memory device to store calibration logic and one or more processors coupled with the at least one physical memory device to execute the calibration logic to receive an image having a blended input color comprising a first primary color value and a second primary color value, generate blend weights for the blended input color based on the first primary color value and the second primary color value, receive a plurality of transfer functions corresponding to each of the first primary color value and the second primary color values and apply the blend weights and the plurality of transfer functions to the first primary color value and the second primary color value to generate a uniformity corrected first primary color value and a uniformity corrected second primary color value associated with the blended input color.