A liquid ejection head includes: a first head unit; a second head unit disposed adjacent to the first head unit in a first direction and located on a first side of the first head unit in a second direction; and a heat uniforming unit shared by the first head unit and the second head unit. Each of the first head unit and the second head unit includes: a unit body including an actuator; and a first driver integrated circuit disposed on the first side of the unit body in the second direction. The heat uniforming unit includes a first heat uniforming member disposed on the first side of the first head unit and the second head unit in the second direction. The first heat uniforming member includes a first protrusion located next to the second head unit in the first direction and protruding toward the first head unit.

A fluid ejection device may include a fluid ejection die embedded in a moldable material, a number of fluid recirculation pumps within the fluid ejection die to recirculate fluid within a number of firing chambers of the fluid ejection die, and a number of heat exchangers thermally coupled to a fluid channel side of the fluid ejection die.

A thermal bubble inkjet print head chip has a substrate (11), a heating resistor (12) formed at a first side of the substrate, and an ink accommodating cavity (13) formed at one side of the heating resistor distant from the substrate. A low heat conduction cavity (14) is formed in the substrate; the low heat conduction cavity is located at one side of the heating resistor distant from the ink accommodating cavity; the low heat conduction cavity is filled with a material having a heat conduction efficiency lower than the substrate. By means of the low heat conduction cavity, the amount of heat generated by the heating resistor and diffusing to the substrate is reduced, and the heating efficiency of the heating resistor is improved; therefore, the working current of the heating resistor can be correspondingly lowered.

A liquid ejection head includes: a first head unit; a second head unit disposed adjacent to the first head unit in a first direction and located on a first side of the first head unit in a second direction; and a heat uniforming unit shared by the first head unit and the second head unit. Each of the first head unit and the second head unit includes: a unit body including an actuator; and a first driver integrated circuit disposed on the first side of the unit body in the second direction. The heat uniforming unit includes a first heat uniforming member disposed on the first side of the first head unit and the second head unit in the second direction. The first heat uniforming member includes a first protrusion located next to the second head unit in the first direction and protruding toward the first head unit.

A liquid ejection head includes an element substrate including an energy-generating element that applies ejection energy to liquid, a first electric wiring board electrically connected to the element substrate, and a second electric wiring board on which an integrated circuit element is mounted and which is electrically connected to the first electric wiring board. An electric signal is supplied to the integrated circuit element mounted on the second electric wiring board through the first electric wiring board, processed by the integrated circuit element, and supplied to the energy-generating element through the second electric wiring board and the first electric wiring board.

A method for processing water-based low-viscosity liquid inkjet inks for digital, contactless inkjet printing, wherein the inkjet ink is applied from systematically arranged nozzles in a time-dependent and location-dependent manner and divided into individual volume units, characterized in that the inkjet ink at the nozzle outlet is or is being cooled to temperatures below the temperature of the ambient air. A device for processing water-based low-viscosity liquid inkjet inks for digital, contactless inkjet printing, comprising at least one print head, whereby inkjet inks are applicable from systematically arranged nozzles in a time-dependent and location-dependent manner and divided into individual volume units, characterized in that the print head and/or the inkjet ink supplied to the print head is coolable.

A liquid jetting apparatus includes: a liquid jetting module having drive elements; a wiring member including: a base material having a first surface; wirings formed on the first surface of the base material; and a protective film configured to covers the first surface of the base material and the wirings; and a heat sink. One of the protective film and the base material, of the wiring member, is formed with an opening through which at least some of the wirings are partially exposed, the wirings of the wiring member are electrically connected to terminals of the drive elements, and the heat sink is joined to the at least some of the wirings via the opening of the wiring member.

A fluid ejection device may include a fluid ejection die embedded in a moldable material, and a number of heat exchangers thermally coupled to an ejection side of the fluid ejection die. Further, the fluid ejection device may include a number of cooling channels defined in the moldable material thermally coupled to the heat exchangers.

To provide an inkjet recording method capable of recording images with good ink ejection stability and excellent abrasion resistance while circulating ink between the ink storage portion and the recording head over a long period of time. An ink jet recording method in which an aqueous ink is ejected from a recording head and applied to a recording medium to record an image, the ink jet recording method uses an ink jet recording apparatus equipped with an ink circulation flow path for circulating the aqueous ink from an ink storage portion to the recording head, including the ink storage portion for storing the aqueous ink, the recording head of an ink jet system for ejecting the aqueous ink, a cooling portion for cooling the aqueous ink, a heating portion for heating the aqueous ink, and a pump for circulating the aqueous ink.

An occurrence of leakage is prevented. An inkjet head jets ink. The inkjet head is provided with a head main body, a cooling pipe, a jet-side coupling member, and a cooling-side coupling member, wherein the head main body has a jet flow path through which the ink passes, the cooling pipe has a cooling flow path through which the ink passes as a cooling medium for cooling a drive circuit, the jet-side coupling member is coupled to the head main body, a jet-side branch path branches from an ink flow path into which the ink inflows from an outside of the inkjet head, or from which the ink outflows, the jet-side branch path is communicated with the jet flow path, the jet-side branch path is provided to the jet-side coupling member, and the cooling-side coupling member is coupled to the jet-side coupling member, and is provided with a cooling-side branch path which branches from the ink flow path, and which is communicated with the cooling flow path. The cooling-side coupling member has a coupling surface along one surface of the jet-side coupling member, and along a direction perpendicular to the cooling pipe.