An inkjet printer is configured with capping stations for covering printheads during periods of printer inactivity. Each capping station has a printhead receptacle that encloses a volume, at least two members pivotably mounted to the printhead receptacle so the members can move between a first position where the members are adjacent a wall of the receptacle and a second position where the members extend across the volume of the printhead receptacle, and an actuator operatively connected to the pair of members to move the members between the first position and the second position. A thermoelectric device is mounted to each member. A controller is operatively connected to the actuator to operate the first actuator to move the members between the first position and the second position and to the thermoelectric devices to selectively apply an electrical current to the devices.

An inkjet printer is configured with capping stations for covering printheads during periods of printer inactivity. Each capping station has a printhead receptacle that encloses a volume, at least two members pivotably mounted to the printhead receptacle so the members can move between a first position where the members are adjacent a wall of the receptacle and a second position where the members extend across the volume of the printhead receptacle, and an actuator operatively connected to the pair of members to move the members between the first position and the second position. A thermoelectric device is mounted to each member. A controller is operatively connected to the actuator to operate the first actuator to move the members between the first position and the second position and to the thermoelectric devices to selectively apply an electrical current to the devices.

Provided is a droplet discharging device that can efficiently couple a droplet discharging head and a head driving circuit by a cable. A droplet discharging device includes a droplet discharging head, a head driving circuit configured to drive the droplet discharging head, a carriage configured to move while supporting the droplet discharging head and the head driving circuit, and a cable configured to electrically couple a head connector of the droplet discharging head and a circuit connector of the head driving circuit, the cable being detachably coupled to the head connector and to the circuit connector. The droplet discharging head and the head driving circuit are disposed such that the head connector and the head driving circuit do not overlap in a direction of pull-out of the cable from the head connector and the circuit connector and the droplet discharging head do not overlap in a direction of pull-out of the cable from the circuit connector.

There is provided a liquid discharge apparatus including: a discharging member including a plurality of individual electrodes arranged side by side in a first direction, a plurality of individual channels arranged side by side in the first direction, a plurality of nozzles arranged side by side in the first direction, a common channel communicating with the plurality of individual channels, and an opening communicating with the common channel; and a heating member at least a part of which makes contact with the discharging member. An individual electrode, included in the plurality of individual electrodes and located at an end in the first direction, and the opening are apart from each other in the first direction. At least the part of the heating member is a part making contact with the discharging member, at a location between the opening and the individual electrode located at the end in the first direction.

A liquid discharge apparatus includes a plurality of heads configured to discharge a liquid, a liquid supply manifold configured to distribute the liquid to the plurality of heads, and a temperature-controlled liquid supply manifold configured to supply a temperature-controlled liquid to the plurality of heads. The temperature-controlled liquid supply manifold is thermally coupled to the liquid supply manifold.

A liquid discharge apparatus includes a head configured to discharge a liquid, a circulation passage through which a temperature-controlled liquid circulates, at least two heat generation portions different in heat generation amount from each other, and a cooler configured to cool the temperature-controlled liquid. The circulation passage is coupled to the head. The at least two heat generation portions are thermally coupled with the circulation passage in an ascending order of heat generation amount and downstream from the cooler in a direction of flow in the circulation passage.

A head module includes: a plurality of heads, a base on which the plurality of heads is arrayed in a head array direction, a plurality of individual heatsinks respectively attached to the plurality of heads, and a common heatsink standing on the base, the common heatsink including a connector thermally connected to each of the plurality of individual heatsinks. The connector of the common heatsink is along the head array direction and is adjacent to each of the plurality of individual heatsinks in a direction perpendicular to the head array direction.

A liquid ejection head includes: head units arranged in a first direction; first individual heat dissipators each corresponding to one of the head units and disposed on a first side of the head unit in a second direction; and a first common heat dissipator disposed on the first side of the head units in the second direction. The first common heat dissipator extends in the first direction and shared among the head units. Each 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. Each of the first individual heat dissipators is disposed between the first driver integrated circuit and the first common heat dissipator of the head unit so as to be in thermal contact with the first driver integrated circuit and the first common heat dissipator.

An inkjet printhead includes: a support structure having a plurality of printhead chips mounted thereto; and a shield plate bonded to the support structure, the shield plate having a slot aligned with the printhead chips, the slot having a perimeter edge. A sealant is disposed on all exposed portions of the support structure adjacent the perimeter edge of each slot.

A liquid ejection head includes a supply channel structure and a heater. The supply channel structure has a supply channel configured to allow liquid to flow therefrom to ejection channels that are configured to lead liquid to nozzles aligned in a first direction. The heater is configured to heat liquid. Assuming that a side of the liquid ejection head, in which the nozzles are provided, is defined as a lower side of the liquid ejection head, the heater is disposed above the supply channel structure.