Patent application number | Description | Published |
20090091604 | PROCESS FOR MAKING A MICRO-FLUID EJECTION HEAD STRUCTURE - A method of making a micro-fluid ejection head structure and micro-fluid ejection heads made by the method. The method includes applying a tantalum oxide layer to a surface of a fluid ejection actuator disposed on a device surface of a substrate so that the tantalum oxide layer is the topmost layer of a plurality of layers including a resistive layer, and a protective layer selected from a passivation layer, a cavitation layer, and a combination of a passivation layer and a cavitation layer. The tantalum oxide layer has a thickness (t) that satisfies an equation t=(¼*W/n), wherein W is a wavelength of radiation from a radiation source, and n is a refractive index of the tantalum oxide layer. A photoimageable layer is also applied to the substrate. The photoimageable layer is imaged with the radiation source and then developed. | 04-09-2009 |
20090233386 | METHOD FOR FORMING AN INK JETTING DEVICE - A method for forming an ink jetting device includes providing a silicon substrate having a first surface having formed thereon a plurality of electrical heater elements to form a first upper exposed surface; depositing a polymer over the first upper exposed surface to form a sacrificial polymer layer; patterning the sacrificial polymer layer to form a second exposed upper surface; depositing a conformal material over the second exposed upper surface to form a conformal nozzle layer; patterning the conformal nozzle layer to form a plurality of nozzle holes located over the electrical heater elements; patterning a mask layer to form an exposed region of the second surface of the silicon substrate that defines a location of a central ink via; etching the exposed region to form the central ink via; and removing a portion of a remainder of the polymer layer to form ink ejection chambers. | 09-17-2009 |
20090256891 | HEATER CHIPS WITH SILICON DIE BONDED ON SILICON SUBSTRATE AND METHODS OF FABRICATING THE HEATER CHIPS - A heater chip has a substrate and at least one die, made of silicon, and a bond non-adhesively attaching them. The substrate, thick enough to resist bowing, has ink supply vias from back to front surfaces. The die has ink flow vias from back to front surfaces and circuitry including heater elements adjacent the front surface interspersed with ink flow vias. The at least one die is superimposed on the substrate such that ink supply vias of the substrate align with ink flow vias of the die and portions of substrate front surface and die back surface are aligned, disposed adjacent and facing one another. The bond formed between substrate and die facing surface portions is hermetic and equal in strength to a Si—O bond. By separate processing of carrier and device wafers, size and features of substrate and die can be tailored to provide a desired heater chip construction. | 10-15-2009 |
20100110145 | HEATER STACK AND METHOD FOR MAKING HEATER STACK WITH HEATER ELEMENT DECOUPLED FROM SUBSTRATE - A heater stack includes first strata configured to support and form a fluid heater element responsive to repetitive electrical activation and deactivation to produce cycles of fluid ejection and second strata overlying the first strata to protect the heater element. A decomposed sacrificial layer of a preselected polymer between the substrate and a heater substrata containing the heater element provides a decoupled relationship between them which, during a heat-up period of each cycle, results in the heater element buckling out of physical contact with substrate enabling the heater element to transfer heat energy for producing fluid ejection into the fluid without transferring any into the substrate whereas the decoupled relationship, during the next following cool-down period of each cycle, results in the heater element de-buckling back into physical contact with the substrate enabling the heater element transfer residual heat energy to the substrate. | 05-06-2010 |
20100110146 | HEATER STACK AND METHOD FOR MAKING HEATER STACK WITH CAVITY BETWEEN HEATER ELEMENT AND SUBSTRATE - A heater stack includes first strata configured to support and form a fluid heater element responsive to repetitive electrical activation and deactivation to produce repetitive cycles of fluid ejection from an ejection chamber above the heater element and second strata overlying the first strata and contiguous with the ejection chamber to protect the heater element. The first strata includes a substrate with a cavity formed either in or above the substrate, a heater substrata overlying the cavity and substrate, and a decomposed layer of material between the substrate and heater substrata and processed to provide the cavity substantially empty of the layer of material such that the cavity provides a means which, during repetitive electrical activation, enables the heater element to transfer heat energy into the fluid in the ejection chamber for producing ejection of fluid therefrom substantially without transferring heat energy into the substrate. | 05-06-2010 |
20100111509 | PLANAR HEATER STACK AND METHOD FOR MAKING PLANAR HEATER STACK WITH CAVITY WITHIN PLANAR HEATER SUBSTRATA ABOVE SUBSTRATE - A heater stuck includes first strata having a planar configuration supporting and forming a fluid heater element responsive to repetitive electrical activation and deactivation to produce repetitive cycles of fluid ejection from an ejection chamber above the heater element and second strata having a planar configuration coating the heater element of the first strata and being contiguous with the ejection chamber to protect the heater element. The first strata include a substrate and heater strata disposed on it and forming a cavity above the substrate and encompassed on three sides by the heater substrata. The heater substrata includes a pair of conductive layer portions constituting terminal leads disposed on the substrate at opposite sides of the cavity and a resistive layer disposed on the conductive layer portions and defining the fluid heater element that spans the top of the cavity. | 05-06-2010 |
20100165052 | Heater Stack Having Resistive Layer with Underlying Insulative Gap and Method for Making Heater Stack - A heater stack includes first strata configured to support and form a fluid heater element responsive to energy from repetitive electrical activation and deactivation to fire repetitive cycles of heating and ejecting fluid from an ejection chamber above the fluid heater element and second strata overlying the first strata and contiguous with the ejection chamber to provide protection of the fluid heater element. The first strata includes a substrate and a heater substrata overlying the substrate and including a resistive layer having lateral portions spaced apart, a central portion extending between the lateral portions and defining the fluid heater element, and transitional portions interconnecting the central portion and lateral portions and elevating the central portion relative to the lateral portions and above the substrate to form a gap between the lateral portions and between the central portion and substrate insulating the substrate from the fluid heater element. | 07-01-2010 |
20100165054 | Fin-Shaped Heater Stack And Method For Formation - A fin-shaped heater stack includes first strata configured to support and form fluid heater elements responsive to repetitive electrical activation and deactivation to produce repetitive cycles of ejection of a fluid, and second strata on the first strata to protect the fluid heater elements from adverse effects of the repetitive cycles of fluid ejection and of contact with the fluid. The first strata include a substrate having a front surface, and heater substrata supported on the front surface. The heater substrata have opposite facing side surfaces which extend approximately perpendicular to the front surface and an end surface interconnecting the side surfaces which extends approximately parallel to the front surface such that the heater substrata is provided in either an upright or inverted fin-shaped configuration on the substrate with the fluid heater elements forming the opposite facing side surfaces of the heat substrata. | 07-01-2010 |
20100229392 | PROCESS FOR MAKING A MICRO-FLUID EJECTION HEAD STRUCTURE - A method of making a micro-fluid ejection head structure and micro-fluid ejection heads made by the method. The method includes applying a tantalum oxide layer to a surface of a fluid ejection actuator disposed on a device surface of a substrate so that the tantalum oxide layer is the topmost layer of a plurality of layers including a resistive layer, and a protective layer selected from a passivation layer, a cavitation layer, and a combination of a passivation layer and a cavitation layer. The tantalum oxide layer has a thickness (t) that satisfies an equation t=(¼*W/n), wherein W is a wavelength of radiation from a radiation source, and n is a refractive index of the tantalum oxide layer. A photoimageable layer is also applied to the substrate. The photoimageable layer is imaged with the radiation source and then developed. | 09-16-2010 |
20100321447 | PROTECTIVE LAYERS FOR MICRO-FLUID EJECTION DEVICES AND METHODS FOR DEPOSITING SAME - Heater chips for a micro-fluid ejection device, such as those having a reduced energy requirement and more efficient production process therefor. One such heater chip includes a resistive layer deposited adjacent to a substrate and a protective layer deposited adjacent to the resistive layer. The protective layer can be a tantalum oxide protective layer, which has a high breakdown voltage. An optional cavitation layer of tantalum, which bonds well with the tantalum oxide layer, may be deposited adjacent to the protective layer. Alternatively, for example, the tantalum oxide layer may serve as both the protective layer and the cavitation layer. | 12-23-2010 |
20110123932 | METHOD FOR FORMING A FLUID EJECTION DEVICE - Methods are described for forming a fluid ejection device on a substrate having a first surface and a second surface, the first surface having plurality of electrical heater elements. A sacrificial polymer layer is added over the first surface, a conformal material over the sacrificial polymer layer forms a nozzle layer, the sacrificial polymer is then removed to form ink ejection chambers, the nozzle layer is removed to form nozzle holes, a mask layer is used to form an exposed region and an unexposed region, the exposed region defining a central ink via, which is then etched to form the central ink via. | 05-26-2011 |
20110205305 | HEATER CHIPS WITH SILICON DIE BONDED ON SILICON SUBSTRATE - A heater chip has a substrate and at least one die, made of silicon, and a bond non-adhesively attaching them. The substrate, thick enough to resist bowing, has ink supply vias from back to front surfaces. The die has ink flow vias from back to front surfaces and circuitry including heater elements adjacent the front surface interspersed with ink flow vias. The at least one die is superimposed on the substrate such that ink supply vias of the substrate align with ink flow vias of the die and portions of substrate front surface and die back surface are aligned, disposed adjacent and facing one another. The bond formed between substrate and die facing surface portions is hermetic and equal in strength to a Si—O bond. A metal through the die connects a conductor on a front of the substrate to a heater element on a front of the die. | 08-25-2011 |
20130076837 | PLANAR HEATER STACK AND METHOD FOR MAKING PLANAR HEATER STACK WITH CAVITY WITHIN PLANAR HEATER SUBSTRATA ABOVE SUBSTRATE - A heater stuck includes first strata having a planar configuration supporting and forming a fluid heater element responsive to repetitive electrical activation and deactivation to produce repetitive cycles of fluid ejection from an ejection chamber above the heater element and second strata having a planar configuration coating the heater element of the first strata and being contiguous with the ejection chamber to protect the heater element. The first strata include a substrate and heater strata disposed on it and forming a cavity above the substrate and encompassed on three sides by the heater substrata. The heater substrata includes a pair of conductive layer portions constituting terminal leads disposed on the substrate at opposite sides of the cavity and a resistive layer disposed on the conductive layer portions and defining the fluid heater element that spans the top of the cavity. | 03-28-2013 |