A flow path member includes a plurality of flow paths including a first flow path, a filter chamber which communicates with the first flow path and is provided with a filter, and a second flow path which communicates with the filter chamber, in which the filter is disposed so that a direction including a direction where liquid of the first flow path or the second flow path flows is a surface direction, and in which a plurality of filter chambers are disposed at positions where at least the filter chambers partially overlap each other in a normal direction with respect to the surface direction of the filter.

In one example, a printhead assembly includes a molding with multiple printhead dies exposed at a front part of the molding and channels in a back part of the molding to carry printing fluid to the dies. The printhead assembly also includes a printed circuit board affixed to the back part of the molding, not covering any of the channels, and an electrical connection between each die and the printed circuit board.

A recording element substrate for a liquid ejection head is provided with a storage section including an antifuse element and a first resistor connected in parallel with the antifuse element, and a second resistor that is connected in parallel with the storage section and serves as a reference in rating information of the antifuse element, and a second switch connected to the second resistor.

In a liquid ejection head in which ejection modules are arrayed on a flow path forming member, each ejection module includes a recording element substrate provided on a support member. The recording element substrate includes a liquid supply channel, a liquid collection channel, and ejection ports. The support member includes supply-side liquid communication ports communicating with the liquid supply channel and collection-side liquid communication ports communicating with the liquid collection channel. The supply-side liquid communication ports and the collection-side liquid communication ports are alternately provided along the direction in which the ejection modules are arrayed. The closest pair of liquid communication ports in the adjacent ends of two adjacent ejection modules are both supply-side or collection-side liquid communication ports.

Provided is a liquid ejection head that can suppress variation in the circulation flow rate or the pressure of the liquid among a plurality of pressure chambers and suppress a difference in temperature distribution between adjacent element substrates to suppress image unevenness. The liquid ejection head includes a plurality of ejection modules including an element substrate in which a plurality of ejection orifices that eject a liquid are aligned in an array. In one ejection module of the ejection modules adjacent to each other, the liquid is supplied from one side of an ejection orifice array, and the liquid is collected from the other side of the ejection orifice array, and in the other ejection module of the ejection modules adjacent to each other, the liquid is supplied from the other side, and the liquid is collected from the one side.

An inkjet print head includes a print element substrate having an ejection port array of a plurality of ejection ports arranged and an ink supply port that supplies the ink to the ejection ports. A support member has a partition and an opening that supplies the ink to the ink supply port, in which the print element substrate and the support member are bonded by an adhesive. The partition includes a first portion and a second portion. The second portion is located between individual extension lines of two surfaces of the first portion. An end of the surface of the print element substrate facing the second portion is located between an extension line of the surface of the first portion and an extension line of a surface of the second portion.

A multi-chip module (MCM) assembly comprising: a graphite substrate comprising a plurality of silicon chips directly attached to the graphite substrate, and a Printed Wiring Board (PWB) attached to the graphite substrate by means of a solvent-resistant adhesive glue and provided with openings surrounding outer profiles of the silicon chips. A printing bar comprising a plurality of the MCM assemblies is also disclosed.

An element substrate of a liquid ejection head includes an ejection opening array in which multiple ejection openings are arranged along a predetermined direction, pressure chambers communicating with the ejection openings, and heat generating elements for ejecting liquid, supplied to the pressure chambers, through the ejection openings. The element substrate also includes a predetermined supply path extending in the predetermined direction and communicating with the pressure chambers, a predetermined collection path communicating with the pressure chambers, multiple liquid supply ports communicating with the supply path at different positions in the predetermined direction, and a liquid collection port communicating with the collection path. Among the multiple liquid supply ports, at least a liquid supply port located at an end portion in the predetermined direction has an opening area larger than the opening area of the liquid collection port.

A liquid ejection head includes a recording element substrate including a plurality of ejection port arrays, a support member supporting the recording element substrate, and including a plurality of liquid chambers, and a channel member including a plurality of channels. Each of the plurality of liquid chambers includes an opening connected to one of the plurality of channels. Each of the plurality of channels is a channel that extends upward from the opening in a vertical direction, in a posture of the liquid ejection head in ejecting the liquid. A volume of the channel connected to the opening located at a central portion of the liquid chamber in the longitudinal direction, among the plurality of channels, is greater than a volume of the channel connected to the opening located on an end portion side apart from the central portion of the liquid chamber in the longitudinal direction.

Examples include a fluid ejection device comprising a carrier, at least one fluid ejection die, and conductive traces at least partially embedded in the carrier. The carrier has a first portion and a second portion, where an angle of orientation between the first portion and the second portion is nonparallel. The first portion includes an array of openings formed through a top surface of the carrier. The second portion includes at least one die opening through a bottom surface of the carrier. The fluid ejection die is coupled to the second portion of the carrier. Fluid passages formed in a back surface of the fluid ejection die are exposed through the at least one die opening formed through the bottom surface of the carrier. The conductive traces have an array of contact points at first ends of the conductive traces. The array of contact points align with the array of openings of the first portion of the carrier such that the array of contact points are exposed through the array of openings. The conductive traces connect the fluid ejection die and the array of contact points.