In accordance with an embodiment, an inkjet head comprises a pressure chamber configured to house ink; an actuator configured to be arranged corresponding to the pressure chamber; a plate configured to have a nozzle communicating with the pressure chamber; and a driving circuit configured to drive the actuator, wherein the drive circuit applies an auxiliary pulse signal which contains an expansion pulse for expanding the volume of the pressure chamber and a contraction pulse for contracting the volume of the pressure chamber in such a degree as not to eject an ink drop from the nozzle to the actuator before enabling the ink drop to be ejected from the nozzle communicating with the pressure chamber by applying the expansion pulse and the contraction pulse as a drive pulse signals.

An inkjet head comprises a pressure chamber into which ink is filled, a nozzle connected with the pressure chamber, an actuator which changes volume of the inside of the pressure chamber to eject an ink droplet from the nozzle connected with the pressure chamber, and a drive circuit which outputs a drive signal which contains an expansion pulse for increasing the volume of the pressure chamber and a contraction pulse for decreasing the volume of the pressure chamber when an ink droplet is ejected and outputs a precursor signal for changing the volume of the pressure chamber to a level at which the ink droplet is not ejected from the nozzle at the time of a precursor minute vibration for minutely vibrating ink.

A head chip, a liquid jet head, a liquid jet recording device, and a method of manufacturing a head chip each capable of suppressing the variation in ejection performance between the ejection channels without changing the shape of a channel (a drive wall) are provided. In the head chip according to an aspect of the present disclosure, when a region in which the first common electrode part and a second common electrode part are opposed in an X direction to each other across the drive wall, and which is configured to generate an electrical field in the drive wall is defined as an opposed region, a dimension in a Z direction in a first upside common part is formed so as to decrease in a direction from the drive wall located at the first side in the X direction toward the drive wall located at the second side in the X direction among the plurality of drive walls, a dimension in the Z direction in a second upside common part is formed so as to decrease in a direction from the drive wall located at the second side in the X direction toward the drive wall located at the first side in the X direction among the plurality of drive walls, and a dimension in a Y direction in the opposed region decreases in directions from the drive walls located at both end sides in the X direction toward the drive wall located in a central portion in the X direction.

A liquid ejection head includes a nozzle, a pressure chamber that is capable of storing liquid and communicates with the nozzle, a volume of the chamber being variable to eject the liquid from the nozzle, an actuator configured to vary the volume in response to a drive signal, and a drive circuit configured to generate the signal. The chamber has one of states including a steady state in which the volume is unchanged, an expanded state in which the volume is expanded, a first contracted state in which the volume is contracted, and a second contracted state in which the volume is further contracted. The drive signal comprises a first waveform for transitioning from the steady state to the first contracted state, a second waveform for transitioning from the first to second contracted states, and a third waveform for transitioning from the second contracted state to the steady state.

There are provided a head chip, a liquid jet head, a liquid jet recording device, and a method of manufacturing a head chip each capable of ensuring an inter-electrode distance of each of channels while achieving narrowing of a pitch of the channels. In the head chip according to an aspect of the present disclosure, an electrical conducting material removal area in which laser irradiation scars are formed throughout an entire area in an X direction of a portion located between a lower end opening of an ejection channel and a lower end opening of a non-ejection channel is disposed in a portion located between the lower end opening of the ejection channel and the lower end opening of the non-ejection channel in a lower surface of an actuator plate.

A head chip, a liquid jet head, and a liquid jet recording device which effectively transfer elastic energy to ink in a pressure chamber to increase pressure to be generated in the pressure chamber are provided. The head chip according to an aspect of the present disclosure includes an actuator plate provided with a pressure chamber in which a liquid is contained, a jet hole plate which has a jet hole communicated with the pressure chamber, and which is overlapped on the actuator plate in a thickness direction of the actuator plate, and a drive electrode which is configured to generate an electric field in the actuator plate to thereby deform the actuator plate in the thickness direction and a crossing direction crossing the thickness direction to expand or contract a volume of the pressure chamber.

According to one embodiment, a liquid ejection head includes a substrate with an opening through which a first liquid can pass. An actuator is on a first side of the substrate and has a plurality of pressure chambers. A manifold is on a second side of the substrate. The manifold forms a first flow path for a second fluid. The liquid ejection head has first electrode with portions formed on an upper surface of the actuator, a surface on the first side of the substrate, an inner wall of the opening, and a surface on the second side of the substrate in a region outside the first flow path.