Abstract: An integrated cell separator adapted for use with one or more battery cells. The separator includes a thermal isolation/flame-resistant layer and a compliant layer. The compliant layer is adjacent to the thermal/isolation/flame resistant layer. The thermal isolation/flame-resistant layer and the compliant layer are adhered to each other, the compliant layer is adapted to contact the one or more battery cells, and the separator is adapted to provide thermal runaway isolation of the one or more battery cells. A method for separating one or more battery cells.

Abstract: Systems and methods of a battery assembly are disclosed. The battery assembly includes an extruded housing, a plurality of battery cells within the extruded housing forming a plurality of cell blocks, and a circuit coupled to the cell blocks and configured to connect one or more of the cell blocks selectively in parallel or series. A cell block within the plurality of cell blocks may be selectively isolated from each other cell block within the plurality of cell blocks using the circuit. The cell block within the plurality of cell blocks may include a series connected string of battery cells. The cell block within the plurality of cell blocks may include parallel connected battery cells.

Abstract: An integrated energy storage unit includes a container and a battery housed within the container. The battery includes a positive battery terminal, a negative battery terminal, and a battery electrolyte. A capacitor is housed within the container, separate from the battery. The capacitor includes a positive capacitor terminal, a negative capacitor terminal, and a capacitor electrolyte. A plurality of connectors electrically couple the battery and the capacitor in parallel. A positive lead is electrically coupled to the positive battery terminal and the positive capacitor terminal. The positive lead extends from the container. A negative lead is electrically coupled to the negative battery terminal and the negative capacitor terminal. The negative lead extends from the container.

Abstract: A current isolation contactor includes a first contact, a second contact movable between an engaged position with the first contact and a disengaged position away from the first contact, and a cam being movable between a biased position wherein the second contact is in the engaged position with the first contact and an unbiased position wherein the second contact is able to move to the disengaged position away from the first contact. A retaining pin retains the cam in the biased position. A drive system is operatively associated with retaining pin to move the retaining pin, allowing the cam to rotate to the unbiased position such that the second contact is moved to the disengaged position.

Abstract: An integrated energy storage unit includes a container and a battery housed within the container. The battery includes a positive battery terminal, a negative battery terminal, and a battery electrolyte. A capacitor is housed within the container, separate from the battery. The capacitor includes a positive capacitor terminal, a negative capacitor terminal, and a capacitor electrolyte. A plurality of connectors electrically couple the battery and the capacitor in parallel A positive lead is electrically coupled to the positive battery terminal and the positive capacitor terminal. The positive lead extends from the container. A negative lead is electrically coupled to the negative battery terminal mi{acute over (?)} the negative capacitor terminal. The negative lead extends from the container.

Abstract: An electrokinetic pump and fluid delivery system is provided that may include any of a number of features. One feature of the fluid delivery system is that it can deliver a fixed volume of fluid with each stroke of the electrokinetic pump. Another feature of the fluid delivery system is that it can accurately deliver fluid at a target flow rate over time. Methods associated with use of the electrokinetic pump and fluid delivery system are also covered.

Abstract: A current isolation contactor includes a first contact, a second contact movable between an engaged position with the first contact and a disengaged position away from the first contact, and a cam being movable between a biased position wherein the second contact is in the engaged position with the first contact and an unbiased position wherein the second contact is able to move to the disengaged position away from the first contact. A retaining pin retains the cam in the biased position. A drive system is operatively associated with retaining pin to move the retaining pin, allowing the cam to rotate to the unbiased position such that the second contact is moved to the disengaged position.

Abstract: A thermal management battery pack system includes a containment box having a plurality of sides located around a perimeter of the bottom and a hermetically sealed cell box containing at least one energy cell located within the cell box. The cell box has a cover and a plurality of sides. The sides of the cell box are located away from the sides of the containment box. A plurality of external power connection points are located on the cover of the cell box. A dielectric fluid fills the cell box around the at least one energy cell. A sufficient amount of a phase-change material is located in the dielectric fluid to maintain a temperature within the cell box to within about five degrees Celsius of a temperature exterior to the containment box.

Abstract: An integrated energy storage unit includes a container and a battery housed within the container. The battery includes a positive battery terminal, a negative battery terminal, and a battery electrolyte. A capacitor is housed within the container, separate from the battery. The capacitor includes a positive capacitor terminal, a negative capacitor terminal, and a capacitor electrolyte. A plurality of connectors electrically couple the battery and the capacitor in parallel. A positive lead is electrically coupled to the positive battery terminal and the positive capacitor terminal. The positive lead extends from the container. A negative lead is electrically coupled to the negative battery terminal and the negative capacitor terminal. The negative lead extends from the container.

Abstract: An integrated energy storage unit includes a container and a battery housed within the container. The battery includes a positive battery terminal, a negative battery terminal, and a battery electrolyte. A capacitor is housed within the container, separate from the battery. The capacitor includes a positive capacitor terminal, a negative capacitor terminal, and a capacitor electrolyte. A plurality of connectors electrically couple the battery and the capacitor in parallel. A positive lead is electrically coupled to the positive battery terminal and the positive capacitor terminal. The positive lead extends from the container. A negative lead is electrically coupled to the negative battery terminal and the negative capacitor terminal. The negative lead extends from the container.

Abstract: An electrokinetic pump and fluid delivery system is provided that may include any of a number of features. One feature of the fluid delivery system is that it can deliver a fixed volume of fluid with each stroke of the electrokinetic pump. Another feature of the fluid delivery system is that it can accurately deliver fluid at a target flow rate over time. Methods associated with use of the electrokinetic pump and fluid delivery system are also covered.

Abstract: A method of separating an IC. The method includes dicing a semiconductor wafer. The semiconductor wafer includes multiple ICs. The diced wafer is secured to a stretchable substrate. The stretchable substrate can be stretched so as to form corresponding spaces between each of the ICs. The corresponding spaces are filled with a support material. A system for separating ICs on a semiconductor wafer is also disclosed.

Abstract: A method of manufacturing RFID inlay structures includes providing a strap substrate containing an RFID chip. Strap pad patterns are formed adjacent said recessed regions over contacts of the RFID chip using a directly electroplateable resin (DER). The strap substrate is attached to an inlay substrated having an electrically conductive antenna and antenna contact patterns. The DER strap pad patterns, antenna pattern, antenna contacts and chip contacts are electroplated, thereby forming a metal interconnect between the contacts of the RFID chip and the antenna contacts on the inlay substrate. The strap substrate may be obtained from a web of strap substrates formed by a casting process. The DER material may be in the form of a DER ink and applied using a pen-plotter apparatus to form strap pad patterns or antenna coil patterns on the strap substrate, and to form antenna features and antenna contact patterns on the inlay substrate.

Abstract: A method of manufacturing RFID inlay structures includes providing a strap substrate containing an RFID chip. Strap pad patterns are formed adjacent said recessed regions over contacts of the RFID chip using a directly electroplateable resin (DER). The strap substrate is attached to an inlay substrate having an electrically conductive antenna and antenna contact patterns. The DER strap pad patterns, antenna pattern, antenna contacts and chip contacts are electroplated, thereby forming a metal interconnect between the contacts of the RFID chip and the antenna contacts on the inlay substrate. The strap substrate may be obtained from a web of strap substrates formed by a casting process. The DER material may be in the form of a DER ink and applied using a pen-plotter apparatus to form strap pad patterns or antenna coil patterns on the strap substrate, and to form antenna features and antenna contact patterns on the inlay substrate.