A heating device includes a support member including a support face, a first heating unit heating the support face, a second heating unit heating the support face, and a control unit independently controlling an output of the first heating unit and an output of the second heating unit. A second heated region is positioned adjacent to a first heated region. The first heating unit and the second heating unit are arranged, in order, from a center, in the width direction, of the support face toward an end thereof. A second detection unit detecting a temperature of the support face is provided in the second heated region, at a location further to an opposite side from the first heating unit than a center, in the width direction, of the second heated region. The control unit controls an output of the second heating unit based on detection of the second detection unit.

A heating device includes a first heat member and a second heat member. The first heat member is configured to heat a sheet on a liquid applied face. The second heat member is configured to heat the sheet on an opposite face opposite the liquid applied face of the sheet. A temperature of the second heat member to heat the sheet is higher than a temperature of the first heat member to heat the sheet.

A drying device includes a contact heater unit to contact and heat a medium. The contact heater unit includes a plurality of heating members each having a curved contact face to contact the medium among plural heating members of the plurality of heating members to contact a first surface of the medium opposite a second surface of the medium on which liquid is applied. The plurality of heating members includes a first heating member and a plurality of second heating members. The first heating member has a maximum contact distance to contact the medium. The plurality of second heating members is disposed upstream from the first heating member in a direction of conveyance of the medium. Two heating members of the plurality of second heating members immediately upstream from the first heating member in the direction of conveyance of the medium contact the first surface of the medium.

In some examples, a media conditioner includes a heated conveying component to convey a sheet of printable media, the conveying component including a first portion extending widthwise, and a second portion extending widthwise from the first portion. The media conditioner also includes a first temperature sensor to measure temperature of the first portion of the conveying component; a second temperature sensor to measure temperature of the second portion of the conveying component; and a controller to produce a determination involving a first temperature at the first portion of the conveying component, a second temperature at the second portion of the conveying component, a reference temperature of the first portion, and a reference temperature of the second portion, and a threshold value. The controller is to produce a result indicator based on the comparison

A heating device includes a pre-heater configured to pre-heat a medium, onto which a liquid is discharged from a liquid discharger, at a first position upstream of the liquid discharger in a conveyance direction of the medium, a print-heater configured to heat the medium at a second position opposite the liquid discharger, a post-heater configured to post-heat the medium at a third position downstream of the second position in the conveyance direction, and circuitry configured to control a temperature of each of the pre-heater, the print-heater, and the post-heater. The pre-heater includes a first pre-heater and a second pre-heater disposed closer to the print-heater than the first pre-heater, and the circuitry controls a temperature of the second pre-heater to be between a temperature of the first pre-heater and the temperature of the print-heater.

In some examples, a system is disclosed that includes a roller assembly for a printer. The roller assembly includes a pressure roller, a belt coupled, a drive assembly to rotate the pressure roller and to urge the pressure roller into the belt, a heater to apply heat to the belt, and a temperature sensor to detect a temperature of the belt. In addition, the roller assembly includes a controller to increase a pressure applied to the pressure roller from a first to a second pressure in pressure in response to a temperature of the belt being greater than or equal to a first temperature threshold. Also, the controller is to initiate an advance of a print media to contact the belt in response to the temperature of the belt being greater than or equal to a second, higher temperature threshold.

The disclosure relates to a rendering apparatus, method and non-transitory machine-readable storage medium for determining a speed of a carriage during rendering of an image. A plurality of swaths of rendering fluid are deposited on a print target using a set of printheads moving across the print target. A temperature of a curing module is measured at a respective time of depositing each respective swath. An arrival time for each deposited swath to respectively arrive at the curing module is predicted. The speed of the carriage during depositing the plurality of swaths is determined based on the measured temperature of the curing module and predicted arrival time for each respective swath.

A printing device includes a printing section including an inkjet head configured to eject ink onto a conveyed roll paper, a conveying section configured to convey the conveyed roll paper, and a control section configured to print an image on the conveyed roll paper with the printing section and the conveying section. The control section has a normal printing mode for printing the image with a plurality of operations based on the printing section and the conveying section and a high-speed printing mode for, during first print, printing the image while omitting or changing a part of the plurality of operations included in the normal printing mode according to the operation.

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.

The invention relates to a method and an assembly for producing a flat printed packaging material, having the steps of:providing a quasi-endless web of the packaging material on a first web roller orproviding a sheet of the flat packaging material on a first sheet stack,unwinding or receiving and transporting the packaging material by means of at least one printing station for printing a surface of the packaging material,subsequently transporting the packaging material through at least one drying station in order to dry the printing on the packaging material, andwinding the printed and dried packaging material onto a second web roller ordepositing the printed and dried packaging material onto a second sheet stack, wherein the drying process in the drying station comprises an irradiation process using electromagnetic radiation with a radiation density maximum in the near-infrared range and with a high power density, in particular between 100 and 800 kW/m2, and the packaging material is transported at least through the drying station on a thermally conductive carrier with an adjustable temperature.