There are provided a liquid jetting apparatus and a method of coping with the floating of a medium where power at the time of coping with the floating of a medium can be suppressed. After the floating of a medium (36) is detected, a first movement parameter that represents the speed or acceleration of a first liquid jet head (56C) during movement is set, a second movement parameter that represents the magnitude of speed of a second liquid jet head (56M), which is smaller than the magnitude of the speed of the first liquid jet head, or a second movement parameter that represents a magnitude of acceleration of the second liquid jet head, which is smaller than the magnitude of the acceleration of the first liquid jet head, is set, an operation of the first liquid jet head is started at a first timing, and an operation of the second liquid jet head is started at the same timing as the first timing or at a second timing when the first liquid jet head does not yet reach a first retreat position.

An inkjet printing apparatus includes a mounting unit where a recording medium is mountable, a head unit that ejects ink droplets to the recording medium, a planar direction driving unit that drives at least one of the head unit ejecting the ink droplets and the mounting unit to move in a planar direction and that changes a relative positions of the head unit and the mounting unit in the planar direction, and a height direction driving unit that changes a relative positions of the head unit and the mounting unit in a height direction perpendicular to the planar direction. The planar direction driving unit has a moving speed changing mechanism that changes a carriage speed between the head unit and the mounting unit in the planar direction. The height direction driving unit has a distance changing mechanism that changes a distance between the head unit and the mounting unit.

An inkjet printer comprising: a carriage that carries an inkjet head and configured to scan a recording medium; a main circuit board with a controller that controls the carriage; a strap including a first cable that connects to a first circuit board disposed on the carriage and to the main circuit board, a second cable that connects to a second circuit board disposed on the carriage and to the main circuit board, and a clamp configured to bundle the first cable and the second cable; a support member configured to support the strap from vertically below; and an ink tube configured to connect to the inkjet head and to an ink tank located outside of the carriage; the ink tube disposed between the strap and the support member.

A liquid ejecting apparatus includes a carriage that mounts a liquid ejecting head provided with a nozzle surface in which nozzles to eject a liquid are formed, and is configured to move the liquid ejecting head between an ejection area used to cause the liquid ejecting head to eject the liquid onto a medium and a maintenance area used to perform maintenance of the liquid ejecting head, and a liquid receiving portion that has a size equal to or larger than the nozzle surface, is opposed to the nozzle surface located at a detachment position defined in the maintenance area, and receives the liquid discharged from the nozzles when detaching a liquid supply coupling portion detachably coupled to the liquid ejecting head.

The present disclosure provides an imaging apparatus (100) comprising a scanning printer carriage (110), a carriage motor (120), a transmission belt (130) between the carriage motor (120) and the scanning printer carriage (110), a data control unit (140) to provide print data (200) to the carriage motor (120) and the scanning printer carriage (110), and a power source (150) to provide power (300) to the carriage motor (120), and the scanning printer carriage (110). The data control unit (140) transmits print data (200) to the scanning printer carriage (110) by wireless data transfer (201), and the power source (150) transmits power (300) to the scanning printer carriage (110) through an electrically conductive element (302) in the transmission belt (130).

According to one embodiment, a tablet printing apparatus includes: a conveyer configured to convey a tablet along a line; an applicator head including a plurality of nozzles arranged in a direction crossing the conveyance direction of the tablet conveyed by the conveyer, configured to perform printing on the tablet by ejecting a liquid from the nozzles; and a controller configured to control the ejection of the liquid from the nozzles of the applicator head. The length of an array of the nozzles in a direction perpendicular to the conveyance direction is equal to or longer than the length of the tablet in the direction perpendicular to the conveyance direction. The controller is further configured to control switching of a nozzle used for printing on the tablet among the nozzles by a plurality of sections determined in advance.

A liquid discharge apparatus includes a liquid discharge head including a nozzle face in which a nozzle is formed and configured to discharge a liquid, a carriage on which the liquid discharge head is mounted, and a guide shaft configured to hold the carriage movably. The liquid discharge apparatus further includes a driver configured to move the carriage, and a coupling between the carriage and the driver. The coupling is disposed on an axis of the guide shaft in a direction orthogonal to the axis of the guide shaft.

A controller is configured to: when both a first conveyor and a second conveyor are operating concurrently, determine whether a reference current value exceeds a threshold value, the reference current value being obtained based on at least one of a first driving current that is a driving current of the first conveyor and a second driving current that is a driving current of the second conveyor; in response to determining that the reference current value exceeds the threshold value, continue an operation of an earlier-driven conveyor that is one of the first conveyor and the second conveyor that is started at earlier timing, and temporarily stop an operation of a later-driven conveyor that is one of the first conveyor and the second conveyor that is started at later timing; and after a driving current of the earlier-driven conveyor drops to a particular standard, restart the operation of the later-driven conveyor.

After an ejector passes an ejection end position, a controller controls a second conveyor to convey a sheet in a sub-scanning direction. The ejection end position is a position at which ink ejection by the ejector ends before reaching a turn position. An ejection start position is a position at which ink ejection by the ejector starts after turning at the turn position. Based on positional relationship between the ejection end position and a standard position, the controller adjusts timing of conveyance of the sheet or shift the turn position from the standard position in a direction of reducing an overlap between a sheet conveyance period after the ejector passes the ejection end position and an ejector deceleration period before the ejector reaches the turn position. The standard position is a standard turn position of the ejector and is determined from the ejection end position and the ejection start position.

A controller is configured to determine which of a first position and a second position is located at a farther downstream side in a moving direction of an ejector and to set a determined position as a turn position. The first position is a first distance away from an image formation end position in the moving direction. The second position is a second distance away from an image formation start position in the moving direction. The image formation end position is an end position of image formation onto a sheet in a conveyance process of the ejector before turning at the turn position. The image formation start position is a start position of image formation onto the sheet in a conveyance process of the ejector after turning at the turn position. The second distance is longer than the first distance.