An inkjet recording apparatus includes an ink container. The ink container stores an ink for printing on a printing object. The inkjet recording apparatus also includes a stirring mechanism. The stirring mechanism stirs the ink stored in the ink container. The stirring mechanism includes a stationary shaft and a rotating body. The rotating body rotates around the stationary shaft. The stationary shaft and rotating body are placed in a lower part of the ink container.

An inkjet recording apparatus includes an ink container. The ink container stores an ink for printing on a printing object. The inkjet recording apparatus also includes a stirring mechanism. The stirring mechanism stirs the ink stored in the ink container. The stirring mechanism includes a stationary shaft and a rotating body. The rotating body rotates around the stationary shaft. The stationary shaft and rotating body are placed in a lower part of the ink container.

A recording apparatus includes an electric field forming section including a conductive member and configured to form an electric field, and the conductive member includes at least one first portion and a second portion, each of the at least one first portion being disposed at a position being nearer the recording head than a position of the second portion and included in a corresponding one of at least one liquid discarding region each of which, in an execution of borderless recording, is used for the ejection of the liquid onto an outside of a corresponding one of at least one edge whose position corresponds to each of at least one predetermined size of a medium, the second portion being disposed in a recording region other than the at least one liquid discarding region.

A printer having: an ink nozzle; an extractor laterally spaced from the ink nozzle; a plurality of gas nozzles arranged around the ink nozzle; and three modes of operation, including an electrohydrodynamic mode, an aerodynamic mode, and a combined mode. The modes operate as follows: a voltage is applied across the ink nozzle and the extractor in the electrohydrodynamic mode; a jet of gas is discharged from each of the gas nozzles in the aerodynamic mode; and the voltage is applied and the jets of gas are discharged in the combined mode.

A printer having: an ink nozzle; an extractor laterally spaced from the ink nozzle; a plurality of gas nozzles arranged around the ink nozzle; and three modes of operation, including an electrohydrodynamic mode, an aerodynamic mode, and a combined mode. The modes operate as follows: a voltage is applied across the ink nozzle and the extractor in the electrohydrodynamic mode; a jet of gas is discharged from each of the gas nozzles in the aerodynamic mode; and the voltage is applied and the jets of gas are discharged in the combined mode.

In order to make it possible to inform as apparatus handler through a simple, means of precautions to take in handling ink of the correct ID number when an inputted ink ID number is correct, this inkjet recording apparatus is provided with a print head having; a nozzle part, an ink container that houses ink supplied to the nozzle part, information reading unit for reading information that distinguishes the type of ink accompanying an ink supply container that supplies ink to the ink container, a determination unit for determining from the read information whether the ink housed in the ink supply container is the correct ink, a storage unit for storing ink-related information in correlation with the ink-type-distinguishing information, a stored-information extraction unit for extracting from the storage unit the ink-related information corresponding to the ink-type-distinguishing information read by the information reading unit when the ink is determined to be correct by the determination unit, and a display unit for displaying the ink-related information extracted toy the stored-information extraction unit on a screen.

A binary array ink jet printhead assembly includes a cavity for containing ink, nozzle orifices in fluid communication with the cavity for passing the ink from the cavity to form droplets, the nozzle orifices extending along a length of the cavity, and an electrode assembly. The electrode assembly includes a front face configured to be disposed generally parallel to a plurality of droplet paths of droplets from the nozzle orifices. A plurality of charge electrodes are disposed on the front face, each charge electrode corresponding to a droplet path and disposed parallel to the droplet path. Circuitry is disposed on the electrode assembly, wherein each electrode is electrically connected to the circuitry. The circuitry is further in electrical connection to a connector for connecting the electrode assembly to a controller for the printhead.

A binary array ink jet printhead assembly includes a cavity for containing ink, nozzle orifices in fluid communication with the cavity for passing the ink from the cavity to form droplets, the nozzle orifices extending along a length of the cavity, and an electrode assembly. The electrode assembly includes a front face configured to be disposed generally parallel to a plurality of droplet paths of droplets from the nozzle orifices. A plurality of charge electrodes are disposed on the front face, each charge electrode corresponding to a droplet path and disposed parallel to the droplet path. Circuitry is disposed on the electrode assembly, wherein each electrode is electrically connected to the circuitry. The circuitry is further in electrical connection to a connector for connecting the electrode assembly to a controller for the printhead.

The jetting frequency of droplets of printing fluid from a nozzle of an electrohydrodynamic printer is increased by 50% or more over previous e-jet printers. The charging electrode is strategically arranged to locate layers of material in the gap between the electrode and an extraction surface to provide a breakdown voltage in the gap that is higher than that of air. By locating a tip of the charging electrode inside the ink nozzle, non-conductive printing fluid in the nozzle and/or a non-conductive nozzle wall can provide dielectric strength in the gap that is relatively high, thereby increasing the maximum voltage of the extraction field. The printer offers other advantages, even when there are no high breakdown voltage materials in the gap between the electrode and extraction surface.

The jetting frequency of droplets of printing fluid from a nozzle of an electrohydrodynamic printer is increased by 50% or more over previous e-jet printers. The charging electrode is strategically arranged to locate layers of material in the gap between the electrode and an extraction surface to provide a breakdown voltage in the gap that is higher than that of air. By locating a tip of the charging electrode inside the ink nozzle, non-conductive printing fluid in the nozzle and/or a non-conductive nozzle wall can provide dielectric strength in the gap that is relatively high, thereby increasing the maximum voltage of the extraction field. The printer offers other advantages, even when there are no high breakdown voltage materials in the gap between the electrode and extraction surface.