A printing apparatus includes a feeding unit, a conveyance roller, a printing unit, a guide unit, a winding unit, and a control unit. The guide unit includes a heater (first heater) that heats a surface that comes into contact with a printing medium (medium), and applies a tensile force while heating the medium after printing by the first heater. The control unit controls a winding force of the winding unit to adjust the tensile force applied to the printing medium by the guide unit. The control unit performs the control to change the winding force of the winding unit and the heating temperature of the first heater in accordance with the type of the medium, the printing condition during the printing, or the environmental condition.

A printing apparatus includes a conveyance unit, a printing unit, a platen section facing the printing unit, a regulation unit arranged on a downstream side of the printing unit in the conveyance direction and configured to regulate a height position of the print medium, and a guide section arranged on a downstream side of the platen section. The guide section includes a first declined section declined, a second declined section arranged on the downstream side of the first declined section in the conveyance direction, and an inclined section inclined, from the second declined section to the downstream side in the conveyance direction. A declination of the second declined section is more moderate than the first declined section, and the regulation unit faces the guide section.

A printer includes a record section, a discharge section, a mount section, a movable rib, a move section, and a control section. The record section records on a sheet by ejecting an ink to the sheet. The discharge section discharges the sheet. The mount section has a mount surface on which the sheet discharged is mounted. A movable rib is configured to protrude from the mount surface and supports the sheet. The dimension of the movable rib in an A-direction is larger than the dimension thereof in a Y-direction. The move section moves the movable rib in a C-direction. The control section controls, based on temperature and humidity information, movement of the movable rib made by the move section.

According to examples, a heated system may include a heat generating device, a temperature sensor to detect temperature in the heated system, and a controller. The controller may store temperatures detected by the temperature sensor over time and based on a determination that the temperature in the heated system has reached a predefined temperature value, stop application of power to the heat generating device. The controller may also calculate a rate of change of the stored temperatures corresponding to a predefined period of time prior to the application of power to the heat generating device being stopped, may determine a seeding value for a control mechanism of the heat generating device based on the calculated rate of change, and based on aa determination that a predefined condition has occurred, control the control mechanism to apply power to the heat generating device beginning with the determined seeding value.

Method and devices for dynamically preventing printing errors caused by a media deformation are disclosed. In one example, a pen to print media space (PPS) distance is measured. A media deformation is identified in response to measuring the PPS distance. A corrective function is identified in response to identifying the media deformation. The corrective function identified is then performed. The proposed method provides for consistent quality across a print.

In one example, a heated pressure roller can include a structural element positioned within a belt roller, a platen coupled to the structural element, wherein the platen comprises: a first side to guide a belt of the belt roller to form a first angle on the first side, and a second side to guide the belt of the belt roller to form a second angle on the second side that is different than the first angle.

A recording device includes: a transport unit configured to transport a medium along a transport path, a recording unit configured to perform recording on the medium transported, a wrinkle forming mechanism configured to form wrinkles on a portion of the medium on the transport path before recording is performed, a detection unit configured to detect a state of the wrinkles, and a control unit, wherein the control unit is configured to calculate a rigidity characteristic of the medium based on detection data of the detection unit.

A transport unit includes a glue belt, a pressurizing roller, a roller driving unit, and a control unit. The glue belt includes an adhesive layer. The pressurizing roller presses a medium against the adhesive layer while reciprocating in a Y direction. The roller driving unit generates a driving force for the pressurizing roller to reciprocate. The control unit controls the roller driving unit. The pressurizing roller is separated from the adhesive layer along with reciprocation. The control unit is capable of detecting a load of the roller driving unit, and determines whether the magnitude of the adhesive force of the adhesive layer is less than a target value, based on the load.

A print target support assembly comprising a print platen structure providing an upper surface to support a print target as the print target passes under a print zone. The print zone is arranged across the surface perpendicular to a direction of print target advance. The surface comprises an inner belt area in the direction of print target advance, the inner belt area bounded on each side by an outer non-belt area. A belt advance mechanism, to advance a belt running across the inner belt area of the surface in the direction of print target advance, to advance the print target under the print zone. A flattening arrangement to flatten the print target onto the surface, under the print zone, across the inner belt area and the outer non-belt areas of the surface.

Examples of duplex printing and conditioning based on ink density are described. In an example, an ink density for a first printed side and an ink density for a second printed side of a duplex page are determined. The duplex page is printed and conditioned based on a highest ink density of the first printed side and the second printed side.