Printing device comprising an ink reservoir that supplies ink to an exit of a nozzle forming an ink drop and comprising also a power supply that creates an electrostatic field which generates an inkjet, said inkjet carrying a net electrostatic charge and being deposited on a substrate for printing a three-dimensional item by means of a continuous fiber, characterized in that the printing device also comprises one or a plurality of electrodes that deflect said inkjet from a default trajectory in a continually controlled manner through modifying the voltage applied to each jet-deflection electrode. The printing method comprises the step of deflecting said inkjet from a default trajectory by continually modifying the electrostatic field generated around the inkjet by one or a plurality of electrodes.

Printing device comprising an ink reservoir that supplies ink to an exit of a nozzle forming an ink drop and comprising also a power supply that creates an electrostatic field which generates an inkjet, said inkjet carrying a net electrostatic charge and being deposited on a substrate for printing a three-dimensional item by means of a continuous fiber, characterized in that the printing device also comprises one or a plurality of electrodes that deflect said inkjet from a default trajectory in a continually controlled manner through modifying the voltage applied to each jet-deflection electrode. The printing method comprises the step of deflecting said inkjet from a default trajectory by continually modifying the electrostatic field generated around the inkjet by one or a plurality of electrodes.

A head chip, a liquid jet head, and a liquid jet recording devices each capable of increasing the generated pressure while achieving an increase in manufacturing efficiency and yield ratio are provided. The head chip includes a flow channel member provided with a pressure chamber containing a liquid, an actuator plate on the flow channel member in a state of being opposed in a first direction to the pressure chamber, and a drive electrode configured to deform the actuator plate in the first direction to change a volume of the pressure chamber. A recessed part is formed in a portion of the actuator plate, the portion overlapping the pressure chamber when viewed from the first direction. The drive electrode includes a first electrode formed on an inner surface of the recessed part, and a first opposed electrode which is formed on an upper surface of the actuator plate.

A head chip, a liquid jet head, and a liquid jet recording devices each capable of increasing the generated pressure while achieving an increase in manufacturing efficiency and yield ratio are provided. The head chip includes a flow channel member provided with a pressure chamber containing a liquid, an actuator plate on the flow channel member in a state of being opposed in a first direction to the pressure chamber, and a drive electrode configured to deform the actuator plate in the first direction to change a volume of the pressure chamber. A recessed part is formed in a portion of the actuator plate, the portion overlapping the pressure chamber when viewed from the first direction. The drive electrode includes a first electrode formed on an inner surface of the recessed part, and a first opposed electrode which is formed on an upper surface of the actuator plate.

An electrohydrodynamic printer has a fluidic extractor. A stream of liquid or carrier fluid at a different electrical potential than the printing fluid passes by an extraction opening to extract printing fluid from the extraction opening. The stream of liquid can be a continuous stream, a uniform stream of droplets, or a non-uniform stream of droplets. The extracted printing fluid can merge with the extraction fluid to be carried to a printing surface for deposition. The stream of extraction fluid can be intermittently charged to intermittently extract printing fluid such that selective portions of the stream do not extract printing fluid.

An electrohydrodynamic printer has a fluidic extractor. A stream of liquid or carrier fluid at a different electrical potential than the printing fluid passes by an extraction opening to extract printing fluid from the extraction opening. The stream of liquid can be a continuous stream, a uniform stream of droplets, or a non-uniform stream of droplets. The extracted printing fluid can merge with the extraction fluid to be carried to a printing surface for deposition. The stream of extraction fluid can be intermittently charged to intermittently extract printing fluid such that selective portions of the stream do not extract printing fluid.

An apparatus for aligning dipoles is provided. The apparatus includes: an electric field forming unit including a stage and a probe unit, the probe unit being configured to form an electric field on the stage; an inkjet printing device including an inkjet head, the inkjet head being configured to spray ink including a solvent and dipoles dispersed in the solvent onto the stage; a light irradiation device configured to irradiate light onto the stage; and a temperature control device including a temperature control unit, the temperature control unit being configured to control a temperature of the solvent sprayed on the stage.

An apparatus for aligning dipoles is provided. The apparatus includes: an electric field forming unit including a stage and a probe unit, the probe unit being configured to form an electric field on the stage; an inkjet printing device including an inkjet head, the inkjet head being configured to spray ink including a solvent and dipoles dispersed in the solvent onto the stage; a light irradiation device configured to irradiate light onto the stage; and a temperature control device including a temperature control unit, the temperature control unit being configured to control a temperature of the solvent sprayed on the stage.