Abstract: A method of reducing air in an ink passageway in an inkjet printer by pressurizing a thermally actuated degassing unit that includes an air chamber, venting air through a check valve configured to allow air to vent from the air chamber to ambient when the pressure in the air chamber exceeds ambient air pressure by a predetermined amount The pressurizing is performed by heating an element inside the air chamber. A power supply is connected to the heating element, and power is applied to the heating element during a first time interval to increase the pressure in the air chamber above ambient pressure. Gas is vented from the check valve which allows the heating element to cool during a second time interval to reduce the pressure in the air chamber below ambient pressure. Gas is then drawn from the ink passageway through the membrane into the air chamber.

Abstract: An inkjet printhead having a drop ejector array, an ink passageway for providing ink to the drop ejector array, and a thermally actuated degassing unit. The degassing unit itself includes a body enclosing an air chamber, a check valve configured to allow air to vent from the air chamber to ambient when the pressure in the air chamber exceeds ambient air pressure by a predetermined amount. The thermal degassing unit includes a thermally-induced pressure build-up time to increase the pressure in the air chamber. The air chamber is allowed to cool which causes internal pressure to drop below ambient and draws gas out of the ink.

Abstract: An ink tank including a reservoir for holding ink, the reservoir including a flexible wall for adjusting an internal volume of the reservoir; a biasing element for applying a force to the flexible wall that tends to increase the internal volume of the reservoir; an ink supply port for delivering ink from the reservoir to a printhead; and a breather element, at least a portion of which is disposed inside the reservoir, including a capillary material in contact with ink in the reservoir, wherein the breather element is configured to allow air to enter the reservoir in response to an internal pressure of the reservoir being less than atmospheric pressure outside the ink tank by an amount that is related to a property of the biasing element and a capillary pressure of the breather element.

Abstract: An inkjet printhead including a drop generator includes: a substrate including a surface; a chamber disposed on the surface of the substrate, the chamber including: an inlet having a first edge and a second edge, the second edge being separated from the first edge by an inlet width along an inlet width direction; and a chamber center, wherein the first edge and the second edge of the inlet are disposed on a same side of the chamber center relative to the inlet width direction.

Abstract: The present invention relates to an ink tank for an ink jet printer. The invention further relates to a method of manufacturing the ink tank, as well as well as a method of refilling the ink tank. The ink tank includes an ink tank body and an ink tank lid bonded to the ink tank body at a bond joint. The ink tank lid comprises an opening that leads to a holding area that is adapted to contain a capillary media therein. The holding area comprises a wall that forms a boundary between the capillary media and an enclosure defined by the ink tank body and the ink tank lid. The opening is sized to permit an insertion and removal of the capillary media to and from the holding area when the ink tank lid is bonded to the ink tank body at the bond joint.

Abstract: A method of printing with an inkjet printhead, the method includes providing an ink source that is fluidically connected to the printhead; filling a chamber of a drop generator of the inkjet printhead with ink; ejecting a drop of ink from the chamber of the inkjet printhead; and refilling the chamber with ink, wherein refilling the chamber comprises: providing an influx of ink into the chamber; and providing a circulating flow of ink around a periphery of the chamber.

Abstract: An inkjet printhead including a drop generator includes: a substrate including a surface; a chamber disposed on the surface of the substrate, the chamber including: an inlet having a first edge and a second edge, the second edge being separated from the first edge by an inlet width along an inlet width direction; and a chamber center, wherein the first edge and the second edge of the inlet are disposed on a same side of the chamber center relative to the inlet width direction.

Abstract: A method for forming an ink tank for an inkjet printhead, the method includes providing a housing including a back wall, a side wall extending from the back wall, and an ink supply port for providing ink to the inkjet printhead; providing a convex-shaped flexible wall including a peripheral bonding region; inserting a first capillary member into the housing, the first capillary member including a first surface and a second surface opposite the first surface; inserting a spring into the housing such that a first portion of the spring contacts the back wall; affixing the peripheral bonding region of the flexible wall to an edge of the side wall of the housing to form a reservoir for holding ink; removing air from the reservoir such that the flexible wall is drawn toward the back wall; and adding liquid ink to the reservoir such that the liquid ink contacts the first surface of the first capillary member and such that air from outside the housing contacts the second surface of the first capillary member.

Abstract: An ink tank including a reservoir for holding ink, the reservoir including a flexible wall for adjusting an internal volume of the reservoir; a biasing element for applying a force to the flexible wall that tends to increase the internal volume of the reservoir; an ink supply port for delivering ink from the reservoir to a printhead; and a breather element, at least a portion of which is disposed inside the reservoir, including a capillary material in contact with ink in the reservoir, wherein the breather element is configured to allow air to enter the reservoir in response to an internal pressure of the reservoir being less than atmospheric pressure outside the ink tank by an amount that is related to a property of the biasing element and a capillary pressure of the breather element.

Abstract: An inkjet printhead having a drop ejector array, an ink passageway for providing ink to the drop ejector array, and a thermally actuated degassing unit. The degassing unit itself includes a body enclosing an air chamber, a check valve configured to allow air to vent from the air chamber to ambient when the pressure in the air chamber exceeds ambient air pressure by a predetermined amount. The thermal degassing unit includes a thermally-induced pressure build-up time to increase the pressure in the air chamber. The air chamber is allowed to cool which causes internal pressure to drop below ambient and draws gas out of the ink.

Abstract: A method of reducing air in an ink passageway in an inkjet printer by pressurizing a thermally actuated degassing unit that includes an air chamber, venting air through a check valve configured to allow air to vent from the air chamber to ambient when the pressure in the air chamber exceeds ambient air pressure by a predetermined amount The pressurizing is performed by heating an element inside the air chamber. A power supply is connected to the heating element, and power is applied to the heating element during a first time interval to increase the pressure in the air chamber above ambient pressure. Gas is vented from the check valve which allows the heating element to cool during a second time interval to reduce the pressure in the air chamber below ambient pressure. Gas is then drawn from the ink passageway through the membrane into the air chamber.

Abstract: The present invention relates to an ink tank for an ink jet printer. The invention further relates to a method of manufacturing the ink tank, as well as well as a method of refilling the ink tank. The ink tank includes an ink tank body and an ink tank lid bonded to the ink tank body at a bond joint. The ink tank lid comprises an opening that leads to a holding area that is adapted to contain a capillary media therein. The holding area comprises a wall that forms a boundary between the capillary media and an enclosure defined by the ink tank body and the ink tank lid. The opening is sized to permit an insertion and removal of the capillary media to and from the holding area when the ink tank lid is bonded to the ink tank body at the bond joint.

Abstract: The present invention relates to an ink tank for an ink jet printer. The invention further relates to a method of manufacturing the ink tank, as well as well as a method of refilling the ink tank. The ink tank includes an ink tank body and an ink tank lid bonded to the ink tank body at a bond joint. The ink tank lid comprises an opening that leads to a holding area that is adapted to contain a capillary media therein. The holding area comprises a wall that forms a boundary between the capillary media and an enclosure defined by the ink tank body and the ink tank lid. The opening is sized to permit an insertion and removal of the capillary media to and from the holding area when the ink tank lid is bonded to the ink tank body at the bond joint.

Abstract: A valve includes a stem, a cap, and a deformable lip. The stem includes a first sealing portion and has a longitudinal axis. The cap is connected to the stem and includes a passageway. The deformable lip extends from a periphery of the cap and includes a second sealing portion. The stem is displaceable relative to the deformable lip along the longitudinal axis of the stem to open the first sealing portion and close the second sealing portion to allow fluid to move through the passageway in the cap.

Abstract: A method for filling an ink tank to one of several selectable ink fill volumes, by providing an ink tank including an ink reservoir having a maximum fill volume V and selecting an ink fill volume Vi to store in the ink reservoir. One subsequently determines a quantity of pellets to add to the ink reservoir, wherein the total pellet volume Vp>(V?Vi?2) cubic centimeters. Upon adding the determined quantity of pellets to the ink reservoir, the ink reservoir is sealed with a lid. Whereupon, ink, in the amount Vi, is added to the ink reservoir.

Abstract: A method of regulating pressure in an ink tank including biasing an aperture of the ink tank to a closed position, withdrawing ink from an outlet port of the ink tank to provide a reduced internal pressure in the ink tank. The aperture is opened in response to the reduced internal pressure in the ink tank. The aperture leads to ambient atmospheric pressure outside the ink tank. The biasing step can include using biasing a valve member with a predetermined force against a valve seat at a contact region between the valve member and the valve seat. Opening of the aperture can include moving the member away from the valve seat in response to a difference in pressure between ambient atmospheric pressure and the reduced internal pressure in the tank.

Abstract: An ink tank having a tank body and an aperture leading to an outside of the tank body. A valve is biased to close the aperture but is movable to open the aperture by a reduced pressure within the tank body relative to an external pressure outside the tank body. The valve contacts a valve seat and is biased with a predetermined force against the valve seat by a spring. The predetermined force and the area of a contact region between the closing member and the valve seat determine how much pressure difference is needed to open the aperture.

Abstract: An ink reservoir that contains ink and is detachably mountable to a printhead, the ink reservoir includes a free ink chamber for containing the ink; a valve assembly extending into the free ink chamber and including a first position for permitting ink to flow from the ink reservoir and a second position for stopping the flow of ink from the ink reservoir; and a wick that receives ink from the ink reservoir for transfer to the printhead.

Abstract: A method for filling an ink tank to one of several selectable ink fill volumes, by providing an ink tank including an ink reservoir having a maximum fill volume V and selecting an ink fill volume Vi to store in the ink reservoir. One subsequently determines a quantity of pellets to add to the ink reservoir, wherein the total pellet volume Vp>(V?Vi?2) cubic centimeters. Upon adding the determined quantity of pellets to the ink reservoir, the ink reservoir is sealed with a lid. Whereupon, ink, in the amount Vi, is added to the ink reservoir.

Abstract: A liquid tank for storing liquid includes a liquid chamber, a vent, and a pressure regulator. The liquid chamber includes a wall and the vent leads to atmosphere. The pressure regulator includes an enclosure, a first capillary media member, and a second capillary media member. The enclosure extends into the liquid chamber from the wall of the liquid chamber and includes a hole opening into the liquid chamber. The first capillary media member has a first pore size and is located in the enclosure proximate to the vent. The second capillary media member has a second pore size and is located in the enclosure adjacent to the hole. The second pore size is less than the first pore size.