A method of installing a printhead in a print module includes the steps of: positioning the printhead in a nest of the print module; moving first and second ink couplings towards the nest and into engagement with complementary first and second ink ports positioned at opposite ends of the printhead; and moving a depressor towards the nest and into urging engagement with a portion of the printhead positioned between the first and second ink ports. The first ink coupling, the second ink coupling and the depressor are moved simultaneously, linearly and parallel to each other, thereby to datum the printhead against the nest.

According to examples, an apparatus may include a processor and a memory on which are stored machine readable instructions. The instructions, when executed by the processor, may cause the processor to access a property value respectively corresponding to each of a plurality of firing actuators in a printing system and determine a count of the firing actuators having property values that are outside of a predefined threshold value range. Based on the count exceeding a predefined maximum threshold value, the instructions may cause the processor to determine locations of the plurality of the firing actuators having property values that are outside of the predefined threshold value range, determine a standard deviation of the determined locations, and based on the determined standard deviation being below a predetermined threshold, output an indication concerning a potential printhead strike.

A liquid ejection head is provided with a recording element substrate, and the recording element substrate includes an ejection port member, an electric wiring layer including a pressure generating element array and electric connection portions, and a silicon substrate including the ejection port member and the electric wiring layer on a front surface. The silicon substrate includes a first through hole and a second through hole that protrude the electric connection portions. The rear surface of the silicon substrate is a (100) surface. An extension line of a side extending along the [110] direction, out of sides of the opening of the first trough hole and an extension line of a side extending along the [110] direction, out of sides of the opening of the second through hole are displaced from each other in a direction orthogonal to the [110] direction.

A liquid ejection head is provided with a recording element substrate, and the recording element substrate includes an ejection port member, an electric wiring layer including a pressure generating element array and electric connection portions, and a silicon substrate including the ejection port member and the electric wiring layer on a front surface. The silicon substrate includes a first through hole and a second through hole that protrude the electric connection portions. The rear surface of the silicon substrate is a (100) surface. An extension line of a side extending along the [110] direction, out of sides of the opening of the first trough hole and an extension line of a side extending along the [110] direction, out of sides of the opening of the second through hole are displaced from each other in a direction orthogonal to the [110] direction.

A liquid ejecting unit includes: a print head having a first electrically coupling portion and configured to eject ink; an electric member having a second electrically coupling portion configured to couple the first electrically coupling portion; a support portion for supporting the print head; a shaft protruding from the support portion in a protruding direction; and a fixing member, the print head has a head through hole, the electric member has a first through hole, and the print head and the electric member are fixed to the support portion by engagement between the shaft and the fixing member in a state in which the shaft is inserted into the head through hole and the first through hole in this order.

A liquid ejecting unit includes: a print head having a first electrically coupling portion and configured to eject ink; an electric member having a second electrically coupling portion configured to couple the first electrically coupling portion; a support portion for supporting the print head; a shaft protruding from the support portion in a protruding direction; and a fixing member, the print head has a head through hole, the electric member has a first through hole, and the print head and the electric member are fixed to the support portion by engagement between the shaft and the fixing member in a state in which the shaft is inserted into the head through hole and the first through hole in this order.

A method of engaging a supply module with a printhead includes the steps of: moving an actuator handle in a first motion along a first axis, thereby linearly sliding the supply module along the first axis towards the printhead and engaging ink couplings of the supply module with complementary ink ports of the printhead; and moving the actuator handle in a separate second motion along a second axis perpendicular to the first axis, thereby moving a PCB of the supply module towards the printhead and engaging PCB contacts with complementary printhead contacts.

To stabilize image quality of a printed image. A thermal transfer printing apparatus according to the present invention includes a thermal head and a platen roll and forms an image on printing paper by causing the thermal head to heat an ink ribbon including a plurality of consecutive ink layers, each of which includes sequential panels of a yellow layer, a magenta layer, and a cyan layer and thereby transfer ink while transporting, between the thermal head and the platen roll, the ink ribbon and the printing paper that are superimposed on each other. The thermal transfer printing apparatus includes a sensor that detects ink content of the ink layers and a controller that controls energy applied to the thermal head during image formation on a basis of a result of the detection of the sensor.

To stabilize image quality of a printed image. A thermal transfer printing apparatus according to the present invention includes a thermal head and a platen roll and forms an image on printing paper by causing the thermal head to heat an ink ribbon including a plurality of consecutive ink layers, each of which includes sequential panels of a yellow layer, a magenta layer, and a cyan layer and thereby transfer ink while transporting, between the thermal head and the platen roll, the ink ribbon and the printing paper that are superimposed on each other. The thermal transfer printing apparatus includes a sensor that detects ink content of the ink layers and a controller that controls energy applied to the thermal head during image formation on a basis of a result of the detection of the sensor.

A method of installing a printhead in a print module includes the steps of: positioning the printhead in a nest of the print module; moving first and second ink couplings towards the nest and into engagement with complementary first and second ink ports positioned at opposite ends of the printhead; and moving a depressor towards the nest and into urging engagement with a portion of the printhead positioned between the first and second ink ports. The first ink coupling, the second ink coupling and the depressor are moved simultaneously, linearly and parallel to each other, thereby to datum the printhead against the nest.