Provided is an inkjet application device (1) including a distribution flow path for the liquid material, the distribution flow path including a first flow channel (4) configured to supply the liquid material pumped with a pump (2) to a supply tank (3) and a second flow channel (6) configured to supply the liquid material in the supply tank (3) to the inkjet head (5), wherein the supply tank (3) accommodates a filter (40), which is configured to allow the particles in the liquid material to pass therethrough without allowing air bubbles in the liquid material, which are generated by the pumping of the pump (2), to pass therethrough.

A method and an arrangement for calibrating a delivery rate of an ink pump of a printing device with the aid of an ink container including a sensor unit for detecting at least a first fill level value. Based on the initial fill level of the ink container below the first fill level value, the ink pump conveys ink from an ink reservoir into the ink container up to a final fill level above the first fill level value, so that at least a predetermined volume between the initial fill level and the first fill level value is filled. Upon conveying the ink into the ink container, an ink pump parameter is determined as of reaching the initial fill level and until the first fill level value is reached. A delivery rate of the ink pump is determined based on the predetermined volume and the ink pump parameter.

A detection method for a liquid level of a storage tank is provided. The detection method determines that an optical sensor is for a liquid level detection purpose when a sensing value to a tank object is consistent with a first threshold condition. The detection method further determines the optical sensor as valid on liquid level detection when sensing values respectively corresponding to statuses of print material and non-print-material are consistent with a second threshold condition. During printing, the detection method starts/stops pouring print material into a storage tank when the sensing value of the optical sensor is consistent with a third threshold condition correspondingly.

A fluid container that includes body that provides a fluid reservoir. Additionally, the fluid container can also include an outlet structure. The outlet structure can include a conduit that extends from an outlet of the fluid container to the fluid reservoir. Moreover, the fluid container can include an outlet barrier and an interior barrier. The outlet barrier can be positioned within the conduit of the outlet structure in proximity to the outlet of the fluid container. Additionally, the outlet barrier can be structured to receive an inlet extension of a container device. The interior barrier can be positioned within the conduit of the outlet structure in proximity to the fluid reservoir. Additionally, the interior barrier can be displaceable relative to the outlet structure by the inlet extension.

A pressure regulating valve for an inkjet printhead. The valve includes: a valve inlet connect to a valve outlet; via a flow path; a first orifice positioned in the flow path having a sealable first seat; a movable first valve member configured for sealing engagement with the first seat; a second orifice positioned in the flow path; a movable second valve member configured for regulating a fluid flow rate through the second orifice; a regulator chamber having the valve outlet and comprising a diaphragm operatively connected to the second valve member, such that movement of the diaphragm moves the second valve member relative to the second orifice; and a biasing mechanism for resiliently biasing the diaphragm away from the second orifice.

A liquid ejecting apparatus including a liquid ejecting portion that ejects a liquid in a pressure chamber from a nozzle that communicates with the pressure chamber, a liquid supply flow path that supplies the liquid stored in a liquid storing portion to the liquid ejecting portion, a degas module provided in the liquid supply flow path, a vacuum degree adjustment mechanism configured to adjust a vacuum degree of the degas module, a state detecting mechanism configured to detect a state inside the pressure chamber, and a control portion that drives and controls the vacuum degree adjustment mechanism based on a detecting result of the state detecting mechanism.

Provided is a liquid storage container that allows for a simplified structure and a reduction in the size and the cost of a printing apparatus. To this end, the liquid storage container includes: two liquid chambers partitioned from each other; a flow path through which liquid can move between the liquid chambers; a valve configured to open and close the flow path; a refilling port that is configured to be opened and closed and through which a liquid chamber can be refilled with the liquid; and a pressure adjustment mechanism that is provided in a liquid chamber configured not to be refilled with the liquid through the refilling port and that adjusts a pressure in the printing head.

According to examples, an apparatus may include a chassis having an interior region and a first printing fluid reservoir arranged within the interior region of the chassis. The chassis may fix the first printing fluid reservoir relative to a second printing fluid reservoir. The apparatus may also include a bottle seat that may define a charging port in fluidic communication to the first printing fluid reservoir to convey refill printing fluid received at the charging port to the first printing fluid reservoir. A fluidic interface may be arranged on the chassis and fluidically coupled to the first printing fluid reservoir to convey the printing fluid outside the chassis to a print head.

The idle operation is performed before time t1. The supply amount of the ink from the main tank 95 to the collection sub-tank 92 can be increased with the passage of time while the supply of the ink from the main tank 95 to the collection sub-tank 92 is continued before and after a transition to the print starting operation from the idle operation. Therefore, it is possible to deal with the start of ink discharge from the discharge head H. That is, the ink is already supplied to the collection sub-tank 92 by the supply pump 962 before the start of printing, and the start of ink discharge can be dealt with by increasing the ink supply amount. Therefore, the ink can be stably discharged by suppressing an output variation of the circulation pump 93 at the start of printing.

There is provided an ink replenishment container for replenishing ink into an ink tank via an ink inlet flow path member, the ink replenishment container including a container main body, an ink outlet forming portion having a tubular portion, a spring valve having a valve body mounted in the tubular portion and a spring for urging the valve body toward the ink outlet, and a sealing member mounted in the tubular portion and having a sealing end configured to contact with the valve body in a valve close state, in which the sealing member has a cylindrical inner peripheral wall and an elastic membrane portion extending from the inner peripheral wall toward a center, and the elastic membrane portion is formed with a slit-shaped gap passing through a center portion including the center.