In one example In accordance with the present disclosure, a fluid ejection device is described. The fluid ejection device Includes a number of nozzles to eject fluid. Each nozzle Includes multiple firing chambers to hold fluid. The multiple firing chambers are separated: by a chamber partition. Each nozzle also includes a shared nozzle orifice in a substrate through which to dispense fluid. Each nozzle also Includes multiple ejectors, at least one ejector disposed in each firing chamber, in a common channel of the nozzle, fluid from the multiple firing chambers Is mixed, A height of the common channel is defined by the substrate and the chamber partition and is less than a width of the shared nozzle orifice.

In one example in accordance with the present disclosure, a fluidic ejection die is described. The die includes an array of nozzles. Each nozzle includes an ejection chamber and an opening. A fluid actuator is disposed within the ejection chamber. The fluidic ejection die also includes an array of passages, formed in a substrate, to deliver fluid to and from the ejection chamber. The fluidic ejection die also includes an array of enclosed cross-channels. Each enclosed cross-channel of the array of enclosed cross-channels is fluidly connected to a respective plurality of passages of the array of passages.

Provided is a liquid discharging head including: a nozzle discharging a liquid; a chamber plate having a plurality of pressure chambers, drive elements provided in correspondence with each pressure chamber, and a plurality of lead electrodes for supplying electric signals to the drive elements; and a circuit substrate having terminals coupled to the lead electrodes. A first pressure chamber and a second pressure chamber communicate with the nozzle in common. A first segment electrode is formed so as to overlap the first pressure chamber and is not to overlap the second pressure chamber in plan view. A second segment electrode is formed so as to overlap the second pressure chamber and is not to overlap the first pressure chamber in plan view. The first segment electrode and the second segment electrode are coupled to the same lead electrode.

A liquid ejection head includes a plurality of sets of a first row, a second row, and a flow path in communication with the first row and the second row. Each of the plurality of sets is provided for each respective one of a plurality of kinds of liquids different from one another. The first row includes a plurality of first pressure chambers. The second row includes a plurality of second pressure chambers. The second row is positioned beside the first row. The flow path is in communication with the plurality of first pressure chambers and the plurality of second pressure chambers. The flow path includes a plurality of first communication passages, a plurality of second communication passages, a plurality of third communication passages, a plurality of fourth communication passages, a first manifold, a second manifold, and a common manifold.

A liquid discharge head includes: a substrate; pressure chambers provided on a surface of the substrate and through which a first liquid and a second liquid flow; a pressure generating element configured to pressurize the first liquid; and a discharge port communicating with at least one pressure chamber and through which the second liquid is discharged. First and second supply channels, first and second collecting channels, third and fourth supply channels, and third and fourth collecting channels are formed on the substrate. A common channel is formed between a first pressure chamber row and a second pressure chamber row. The common channel communicates with the first supply channel and the third supply channel, or communicates with the second supply channel and the fourth supply channel, or communicates with the first collecting channel and the third collecting channel, or communicates with the second collecting channel and the fourth collecting channel.

A liquid discharge head includes a substrate, pressure chambers, a pressure generating element, a discharge port, and a liquid channel. First and second communication supply channels and first and second communication collecting channels are formed in the substrate. A central axis of a first communication supply opening is located closer to the corresponding pressure chamber than a central axis of a first common supply opening, or a central axis of a second communication supply opening is located closer to the corresponding pressure chamber than a central axis of a second common supply opening, or a central axis of a first communication collecting opening is located closer to the corresponding pressure chamber than a central axis of a first common collecting opening, or a central axis of a second communication collecting opening is located closer to the corresponding pressure chamber than a central axis of a second common collecting opening.

the first nozzle channel includes a first portion including an end of the first nozzle channel and a second portion including another end of the first nozzle channel, and a width of the second portion in the second direction is larger than a width of the first portion in the second direction.

a first sloped portion that is provided between the first wall surface and the third wall surface includes a first constituting surface that extends in a third direction between the first direction and the second direction.

An apparatus includes a reservoir and a printhead. The printhead includes a support structure including a deformable portion defining at least a top surface of a pumping chamber, a flow path extending from the reservoir to the pumping chamber to transfer fluid from the reservoir to the pumping chamber, and an actuator disposed on the deformable portion of the support structure. A trench is defined in a top surface of the actuator. Application of a voltage to the actuator causes the actuator to deform along the trench, thereby causing deformation of the deformable portion of the support structure to eject a drop of fluid from the pumping chamber.

According to an example, a printing apparatus may include two drop ejecting elements, a fluid circulating element, and a logic device. The logic device may determine whether one or both of a first drop ejecting element and a second drop ejecting element have been fired within a predetermined period of time prior to a current time. In response to the determination, the logic device may selectively transmit an output signal that is to cause the fluid circulating element to be selectively fired, in which the fluid circulating element is positioned to circulate fluid adjacent to both the first drop ejecting element and the second drop ejecting element.