Abstract: A sensor chip formed from a plurality of sensor chips fabricated on a wafer, the wafer including a top surface, a bottom surface opposite the top surface and a thickness between the top and bottom surfaces, the sensor chip including an active area formed on the top surface, a first sacrificial edge including a first fiducial and a second fiducial, and a first score line formed in a first portion of the thickness on the top surface between the first sacrificial edge and the active area.

Abstract: A sensor chip formed from a plurality of sensor chips fabricated on a wafer, the wafer including a top surface, a bottom surface opposite the top surface and a thickness between the top and bottom surfaces, the sensor chip including an active area formed on the top surface, a first sacrificial edge including a first fiducial and a second fiducial, and a first score line formed in a first portion of the thickness on the top surface between the first sacrificial edge and the active area.

Abstract: A cooling system comprising of a coolant manifold, a heat sink configured to fit in the coolant manifold, a plurality of cooling fins formed in the heat sink, and a coolant configured to flow through the coolant manifold to the heat sink. Diamond shaped pin fins associated with the heat sink create a series of divergent fluid paths for the cooling fluid that helps to create turbulence and improved heat transfer.

Abstract: An apparatus includes a heater for converting a filament of extrusion material into thermoplastic material. The heater has a channel configured to change the cross-sectional shape of the filament to a cross-sectional shape that has a greater surface area than the surface area of the filament before the heater receives the filament. The channel of the heater can also be configured to drive the center portion of the filament toward the heated walls of the channel and to mix thermoplastic material in the channel while exposing the center portion of the filament to the heated wall of the channel.

Abstract: A print head includes a substrate having a hole, a circuit on the substrate, the circuit having traces and a hole corresponding to the hole in the substrate, the hole forming a fluid path, and a raised structure on the substrate around the fluid path, the raised structure positioned to seal the circuit from the fluid path.

Abstract: A print head includes a substrate having a hole, a circuit on the substrate, the circuit having traces and a hole corresponding to the hole in the substrate, the hole forming a fluid path, and a raised structure on the substrate around the fluid path, the raised structure positioned to seal the circuit from the fluid path.

Abstract: A print head includes a substrate having a hole, a circuit on the substrate, the circuit having traces and a hole corresponding to the hole in the substrate, the hole forming a fluid path, and a raised structure on the substrate around the fluid path, the raised structure positioned to seal the circuit from the fluid path.

Abstract: A method for forming piezoelectric transducers for inkjet printheads includes: forming at least one piezoelectric layer on a substrate; forming at least one electrode pattern by depositing a conductive material on an exposed surface of the at least one piezoelectric layer; and forming a plurality of individual piezoelectric elements from the at least one piezoelectric layer before or after the forming of the at least one electrode pattern.

Abstract: A pin actuated printhead includes an orifice through which a material is ejected, a chamber to hold the material to be ejected, a channel connecting the chamber to the orifice, and an actuated pin, to enter the orifice and to eject the material from the orifice. The printhead is configured to eject a material with a viscosity of 10,000 cP or more at an elevated temperature.

Abstract: A multi-nozzle extrusion printhead includes a chamber with an inlet to receive an extrusion material and a plurality of outlets fluidly coupled to the chamber. The printhead also includes a plurality of valves that control flow of extrusion material through the fluid outlets to nozzles in the printhead. Each valve includes a member and an electromechanical actuator configured to move the member to a first position to block a flow of the extrusion material through one of the fluid outlets and nozzles and to a second position to enable the flow of the extrusion material through the fluid outlet and nozzles.

Abstract: A pin actuated printhead includes an orifice through which a material is ejected, a chamber to hold the material to be ejected, a channel connecting the chamber to the orifice, and an actuated pin, to enter the orifice and to eject the material from the orifice. The printhead is configured to eject a material with a viscosity of 10,000 cP or more at an elevated temperature.

Abstract: A print head includes a substrate having a hole, a circuit on the substrate, the circuit having traces and a hole corresponding to the hole in the substrate, the hole forming a fluid path, and a raised structure on the substrate around the fluid path, the raised structure positioned to seal the circuit from the fluid path.

Abstract: A method for forming a plurality of electrostatic actuator membranes for an electrostatically actuated ink jet printhead. The method can include forming a blanket actuator membrane layer on an etch stop layer, where the etch stop layer is interposed between the blanket membrane layer and a handle layer such as a semiconductor wafer. The blanket actuator membrane layer is patterned to form a plurality of actuator membranes. The plurality of actuator membranes is attached to a printhead drive assembly that includes circuitry for actuating the plurality of actuator membranes. Subsequently, the handle layer and etch stop layer are removed, thereby leaving the plurality of actuator membranes attached to the printhead drive assembly.

Abstract: An electrostatic ink jet printhead having an electrostatic actuator with improved resistance to adverse effects resulting from misalignment of a body layer to a gap standoff layer. In an embodiment, first and second portions of the gap standoff layer each have a first width and first and second sections of the body have each have a second width that is wider than the first width. Even with an amount of misalignment, the first and second sections of the body layer define nodes for an actuator membrane, thereby maintaining an effective width (WE) of the actuator membrane that is equal to a target width (WT) of the actuator membrane.

Abstract: A method for forming a plurality of electrostatic actuator membranes for an electrostatically actuated ink jet printhead. The method can include forming a blanket actuator membrane layer on an etch stop layer, where the etch stop layer is interposed between the blanket membrane layer and a handle layer such as a semiconductor wafer. The blanket actuator membrane layer is patterned to form a plurality of actuator membranes. The plurality of actuator membranes is attached to a printhead drive assembly that includes circuitry for actuating the plurality of actuator membranes. Subsequently, the handle layer and etch stop layer are removed, thereby leaving the plurality of actuator membranes attached to the printhead drive assembly.

Abstract: An electrostatic actuator for a printhead. The electrostatic actuator may include a substrate. A dielectric layer may be disposed on the substrate. An electrode layer may be disposed on the dielectric layer. A first standoff layer may be disposed at least partially on the electrode layer. A second standoff layer may be disposed at least partially on the electrode layer and at least partially on the first standoff layer. A portion of the second standoff layer disposed on the electrode layer may be removed to form one or more landing pads. A membrane may be disposed at least partially on the second standoff layer.

Abstract: A printer includes a printhead configured to eject high viscosity material and refill a manifold in the printhead with high viscosity material. The printhead includes a layer having an opening to form a reservoir to hold a volume of a high viscosity material and at least one member positioned within the receptacle formed by the opening in the layer. The at least one member has an electroactive element mounted to the member, and an electrical signal generator is electrically connected to the electroactive element. A controller operates the electrical signal generator to activate selectively the electroactive element with a first electrical signal to move the at least one member and thin the high viscosity material adjacent the at least one member to enable the thinned material to move away from the at least one member.

Abstract: A flex circuit board provides islands of electrically isolated material surrounding openings in the flex circuit board to preserve fluid integrity of passageways passing through an electrically insulating layer of the flex circuit board. The electrically isolated islands surround exits of the passageways through the electrically insulating material and extend the passageways through an electrically conductive layer of the flex circuit board. Consequently, fluid passing through the passageways and electrically isolated islands in the flex circuit board is not subjected to electrical current.

Abstract: A flex circuit board provides islands of electrically isolated material surrounding openings in the flex circuit board to preserve fluid integrity of passageways passing through an electrically insulating layer of the flex circuit board. The electrically isolated islands surround exits of the passageways through the electrically insulating material and extend the passageways through an electrically conductive layer of the flex circuit board. Consequently, fluid passing through the passageways and electrically isolated islands in the flex circuit board is not subjected to electrical current.

Abstract: An ink jet printhead includes a nozzle plate including a nozzle, a recess in the nozzle plate, and a compliant layer that covers the recess and forms a sealed pocket that may be filled with air or another gas during use of the printhead. During actuation of a piezoelectric element during the ejection of ink from the nozzle, the sealed pocket attenuates an acoustic energy generated by the piezoelectric element, thereby reducing crosstalk to adjacent nozzles by the acoustic energy.