Abstract: A control section of a recording apparatus is configured to execute control of overlapping transportation in which a preceding medium and a following medium are transported in a state in which a rear end region of the preceding medium and a leading end region of the following medium overlap at least in a partial section in an upper transport route, and determines an overlapping dimension Lk that is a dimension, by which the rear end region of the preceding medium and the leading end region of the following medium overlap, in accordance with a route dimension Ld from a third feed roller pair to an edge of an introducing port in a second direction, when executing the control of the overlapping transportation.

Abstract: An oil-based inkjet ink containing a pigment, a pigment dispersant and a non-aqueous solvent, wherein the non-aqueous solvent contains a silicone oil and a fatty acid ester having 10 to 40 carbon atoms per molecule and having a ratio of (total number of atoms in side chains/total number of atoms in main chain) of at least 0.20.

Abstract: A froth coalescing device comprises a froth receiving chamber with a vent and an umbrella valve arranged between the vent and a gas out port. The vent may be arranged to vent gas in a direction different from a direction of travel of froth in the receiving chamber.

Abstract: A device for generating an output signal, formed as a pulse sequence, with a sensor and a controller. The sensor generates a sensor signal based on a measurand determined by the sensor. The controller determines a number of pulses of a timing signal that are generated chronologically between two pulse edges of the sensor signal, the timing signal being generated by a timing signal generator. The controller also generates an intermediate timing signal formed as a pulse sequence, where the period duration of the intermediate timing signal is equal to the period duration of the timing signal multiplied with a factor that is equal to the determined number of pulses of the timing signal, divided by a predetermined divisor. The controller generates the output signal based on the intermediate timing signal.

Abstract: A medium conveying apparatus includes a driving force transmitting mechanism to transmit a driving force from a first motor to a brake roller and a pair of conveyance rollers located on the downstream side of the brake roller, and a processor to rotate the first motor forward to control so that a medium separated by the brake roller is conveyed by the pair of conveyance rollers, in a separation mode. The processor rotates the first motor backward to perform a feed operation by the brake roller and rotate the pair of conveyance rollers backward until a front edge of the medium passes through a position of the brake roller, and rotates the first motor forward to control so that the medium is conveyed by the pair of conveyance rollers after the front edge of the medium passes through the position of the brake roller, in a non-separation mode.

Abstract: A liquid ejection head includes a substrate; an energy generating member provided on the substrate to generate energy for liquid ejection; a terminal part provided on the substrate to be electrically connected with an outside, the terminal part including at least an electrode for supplying electric power to the energy generating member; a wiring layer provided on the substrate to electrically couple the energy generating member and the electrode; a nozzle member provided on the substrate, the nozzle member including a liquid ejection port and a liquid flow path, the liquid ejection port being arranged to correspond to the energy generating member, and the liquid flow path communicating with the liquid ejection port; and a metal structure provided to cover the wiring layer in a region where neither the nozzle member nor the electrode is provided, and the metal structure is electrically independent of the terminal part.

Abstract: Methods, systems, and devices related to a printer system that includes a first primary ink tank holding a dark-colored ink, a second primary ink tank holding a light-colored ink, a first selector valve configured to change a state, a first secondary ink tank connected to the first primary ink tank via the first selector valve, a second secondary ink tank connected to the first and second primary ink tanks via the first selector valve, a second selector valve connected to the first primary ink tank configured to return the dark-colored ink from the print heads to the first primary ink tank, and a third selector valve connected to the second selector valve and the second primary ink tank configured to either return the light-colored ink from the print heads to the second primary ink tank or to direct the dark-colored ink to the second selector valve.

Abstract: A recording-medium transport device includes a first pressed portion, a second pressed portion, a mover, and a sensor. The first pressed portion moves by being pressed by a transported recording medium. The second pressed portion is disposed at a different position from the first pressed portion in a width direction of the transported recording medium. The second pressed portion moves by being pressed by the transported recording medium. The mover moves in association with the first pressed portion and the second pressed portion. The mover moves in response to the recording medium being pressed by at least one of the first pressed portion and the second pressed portion. The sensor detects movement of the mover.

Abstract: A purge cycle is performed with an ink delivery system of an inkjet printer by applying a pressure pulse to a printhead in the printer that is substantially shorter than pressure pulses previously used. A pressure at a predetermined threshold is generated behind a valve and then release to the printhead. The duration of the pressure application is in a range of about 150 milliseconds to about 250 milliseconds. This pressure pulse substantially reduces the amount of ink emitted during the purge. A bidirectional wipe of the printhead face is effective for restoring inkjets in the printhead even though the amount of emitted ink is substantially reduced.

Abstract: A head unit includes: X (X?2) of first type nozzles configured to discharge a first type liquid droplet, and W (1?W<X) of a second type nozzle configured to discharge a second type liquid droplet. The head unit generates first data forming a first dot pattern and indicating a preceding first type dot area as an area in which the first type liquid droplet is to be discharged, and a preceding second type dot area as an area in which the second type liquid droplet is to be discharged; and second data for forming a second dot pattern and indicating a succeeding first type dot area as an area in which the first type liquid droplet is to be discharged, and a succeeding second type dot area as an area in which the second type liquid droplet is to be discharged.

Abstract: A printing fluid container (100) for use in a printing system is described. An example container includes a base (110) and a light transmissive side wall (120). The side wall extends from the base to define a chamber (130) for receiving and storing printing fluid within the container. The side wall has an internal surface (122) facing the chamber, said internal surface comprising a channel (140). The channel comprises a portion (142) indicating a height from the base, the height representing a predetermined fill amount. The channel is configured such that when the chamber contains printing fluid, printing fluid resides within the channel (140) and indicates the predetermined fill amount.

Abstract: An example laser assembly for a laser printer may include a plurality of lasers to emit respective photons; a prism to redirect the respective laser beams emitted from the plurality of lasers toward a collimator lens of the laser printer to generate a photon beam; and one or more processors to: determine a timing schedule for individually activating the plurality of lasers based on a resolution setting of the laser printer, and when printing at a resolution corresponding to the resolution setting, control activation of each of the plurality of lasers to emit the respective photons according to the timing schedule to form the photon beam.

Abstract: A base material processing apparatus includes a transport mechanism, a mark detector, and a calculating unit. The transport mechanism transports an elongated strip-shaped base material in a longitudinal direction thereof along a predetermined transport path. The mark detector acquires a detection result by detecting a mark continuously at a detecting position on the transport path. The mark is applied previously to an end of the base material in a width direction thereof. The calculating unit calculates a transport speed of the base material, the amount of positional deviation of the base material in a transport direction, and tension on the base material applied in the transport direction on the basis of the detection result and information about the mark applied previously to the base material.

Abstract: The medium detection unit is a component constituting an optical path of the detection light, and includes a first optical element disposed on an upper side of the medium transport path and a second optical element disposed on a lower side of the medium transport path so as to face the first optical element, the second optical element has a facing surface that faces the first optical element, the facing surface being located at a position that is not in contact with a medium nipped by both the first roller pair and the second roller pair, and a medium feeding direction by the first roller pair is a direction by which a leading edge of a medium fed out abuts a position upstream in the medium transport direction relative to a position where the detection light is received on the facing surface.

Abstract: A liquid ejecting apparatus includes a liquid container and a control unit. The liquid container has an upper limit mark. The upper limit mark is arranged so that in a first case where an entire amount of liquid stored in a refilling container is injected into a storage portion when a notification unit notifies of a first state, a liquid level of the liquid in the storage portion is located between an inlet port and the upper limit mark, and in a second case where the entire amount of liquid stored in the refilling container is injected into the storage portion when the notification unit notifies of a second state, the liquid level overlaps with the upper limit mark.

Abstract: A recording condition determining method executed by a recording device performing recording by a main scanning, in which while moving a recording head in a main scanning direction, dots are ejected from nozzles onto a recording medium, and a sub scanning, in which the recording medium is transported in a sub scanning direction. The method includes a patch recording step, the patch recording step being performed by recording patches at a plurality of different positions in the sub scanning direction by a plurality of types of overlap-processing under respectively different recording conditions, in a single recording job performed by the recording device. The method further includes a selection accepting step, and a determination step of determining, as a recording condition of the overlap-processing of an actual recording, the recording condition of the overlap processing corresponding to the patch selected in the selection accepting step.

Abstract: A printing apparatus has a conveyance roller configured to convey a sheet in a first direction, an encoder provided at the conveyance roller, a head having a plurality of nozzles aligned in a second direction intersecting with the first direction and being configured to jet liquid to the sheet which is conveyed in the first direction by the conveyance roller and a controller having a power circuit configured to apply voltage to the head for jetting the liquid. The controller is configured to: determine a jetting frequency for the head based on a signal outputted from the encoder; and change an output voltage of the power circuit depending on the determined jetting frequency.

Abstract: A recording condition determining method is executed by a recording device performing recording by a main scanning and a sub scanning. The method includes a patch recording step of recording patches onto a recording medium by the overlap-processing in which the main scanning is performed on a partial region of the recording medium in an overlapping manner a plurality of times, the patch recording step including recording the patches at a plurality of different positions in a main scanning direction by a plurality of types of the overlap-processing under respectively different recording conditions. The method further includes a selection accepting step of accepting selection of a patch from among a plurality of the recorded patches, and a determination step of determining, as the recording condition of the overlap-processing of an actual recording, the recording condition of the overlap-processing associated with the patch selected in the selection accepting step.

Abstract: According to one embodiment, a fluid circulation apparatus includes a first tank to store fluid to be supplied to a fluid ejection head, a circulation path including a first flow path portion to provide fluid from the first tank to a supply port of the fluid ejection head, and a second flow path portion to return fluid from a collection port of the fluid ejection head to the first tank, a bypass flow path to connect the supply port to the collection port outside of the fluid ejection head, and a pressure sensor configured to measure pressure of the bypass flow path.

Abstract: A liquid ejecting system includes a liquid ejecting head having a nozzle ejecting liquid, a supply channel communicating with the nozzle, and a recovery channel communicated with the nozzle, and circulates the liquid in the liquid ejecting head through the supply channel and the recovery channel. The supply channel includes a pressurizing section and a first buffer mechanism disposed between the nozzle and the pressurizing section. The recovery channel includes a decompression section and a second buffer mechanism disposed between the nozzle and the decompression section. The first buffer mechanism is configured to increase a buffer capacity as the supply channel is pressurized. The second buffer mechanism is configured to reduce a buffer capacity as the recovery channel is decompressed.