Abstract: A fastening element includes a gripping portion having a gripping face and a back face opposite the gripping face, an anchoring portion comprising an anchor proximal end affixed to the gripping portion and an anchor distal end, the anchoring portion comprising at least one resilient clip configured to anchor the fastening element in a substrate with a retention force greater than an insertion force necessary for inserting the anchoring portion into a mounted position on a substrate.

Abstract: A fastening element (1) is provided having a gripping portion (5), a plurality of gripping elements (20, 20?) extending from the gripping portion (5), a supporting portion (10) being defined by at least one supporting-portion wall extending from the gripping portion (5) in a direction opposite that of the gripping elements (20, 20?), the supporting portion (10) having a supporting-portion width smaller than a gripping-portion width of the gripping portion (5), such that a top flange is formed by the gripping portion (5) relative to the supporting portion (10) on at least one side of the fastening element (1), and an anchoring portion (15) extending from a distal end of at least one supporting-portion wall and parallel to the gripping portion (5) so as to form a bottom flange relative to the supporting portion (10) on the at least one side corresponding to the top flange.

Abstract: The present disclosure relates to a method of fabricating a reflector, the reflector being at least partially reflective and at least partially transmissive for at least a wavelength of electromagnetic radiation; the method comprising: forming a first material layer defining a bottom layer; forming a sacrificial layer on the bottom layer; forming a second material layer defining a top layer on the sacrificial layer and a supporting structure connected to the bottom layer; and removing at least part of the sacrificial layer to form a cavity between the bottom layer and the top layer such that the supporting structure supports the top layer relative to the bottom layer and no further supporting structure is provided within the cavity, wherein after the at least part of the sacrificial layer is removed, at least the top layer has residual tensile stress.

Abstract: A fastening element includes a gripping portion having a gripping face and a back face opposite the gripping face, an anchoring portion comprising an anchor proximal end affixed to the gripping portion and an anchor distal end, the anchoring portion comprising at least one resilient clip configured to anchor the fastening element in a substrate with a retention force greater than an insertion force necessary for inserting the anchoring portion into a mounted position on a substrate.

Abstract: A fastening element is provided. The fastening element includes a gripping portion having a first face and a second face the first face of the gripping portion comprising a plurality of gripping elements, and an anchoring portion offset from the second face and extending parallel thereto so as to form a flange portion, wherein the flange portion comprises at least one chamfer located at a terminal section of the flange portion.

Abstract: A fastening element is provided. The fastening element includes a gripping portion having a first face and a second face the first face of the gripping portion comprising a plurality of gripping elements, and an anchoring portion offset from the second face and extending parallel thereto so as to form a flange portion, wherein the flange portion comprises at least one chamfer located at a terminal section of the flange portion.

Abstract: A fastening element is provided having a gripping portion, a plurality of gripping elements extending from the gripping portion, a supporting portion being defined by at least one supporting-portion wall extending from the gripping portion in a direction opposite that of the gripping elements, the supporting portion having a supporting-portion width smaller than a gripping-portion width of the gripping portion, such that a top flange is formed by the gripping portion relative to the supporting portion on at least one side of the fastening element, and an anchoring portion extending from a distal end of at least one supporting-portion wall and parallel to the gripping portion so as to form a bottom flange relative to the supporting portion on the at least one side corresponding to the top flange.

Abstract: A closable container is provided, including a first wall of flexible material having a first interior face, a second wall of flexible material having a second interior face, the first and second walls being laterally opposed and arranged to form an interior volume of the closable container with the first interior wall and the second interior wall at least partially defining the interior volume, a first cooperative panel having a first cooperating face and a first joining face opposite the cooperating face, at least a portion of the first cooperating face comprising a first fastener element, and a second cooperative panel having a second cooperating face and a second joining face opposite the second cooperating face, the second cooperating face comprising a second fastener element configured to engage with the first fastener element to form an interlocking connection, the second fastener element being substantially identical to the first fastener element.

Abstract: The present invention is directed to the fabrication of thin aluminum anode batteries using a highly reproducible process that enables high volume manufacturing of the galvanic cells. A thin aluminum anode galvanic cell having a meshed structure is provided which includes a catalytic metal layer positioned on a patterned silicon substrate, an etched dielectric layer positioned to cover the catalytic metal layer, the catalytic metal layer serving as an etch stop for the etched dielectric layer and an etched aluminum layer positioned to cover the dielectric layer, the dielectric layer serving as an etch stop for the etched aluminum layer.

Abstract: A fastening element (1) is provided having a gripping portion (5), a plurality of gripping elements (20, 20?) extending from the gripping portion (5), a supporting portion (10) being defined by at least one supporting-portion wall extending from the gripping portion (5) in a direction opposite that of the gripping elements (20, 20?), the supporting portion (10) having a supporting-portion width smaller than a gripping-portion width of the gripping portion (5), such that a top flange is formed by the gripping portion (5) relative to the supporting portion (10) on at least one side of the fastening element (1), and an anchoring portion (15) extending from a distal end of at least one supporting-portion wall and parallel to the gripping portion (5) so as to form a bottom flange relative to the supporting portion (10) on the at least one side corresponding to the top flange.

Abstract: An IR imaging system comprising microelectromechanical systems (MEMS) differential capacitive infrared sensors within a sensor array formed on a monolithic integrated circuit substrate, or flip chip bonded onto a signal processing chip fabricated separately, to include, a bimaterial deflectable element anchored to the substrate, a surface electrode fabricated on a top surface of the substrate and positioned below the deflectable element, the surface electrode and the deflectable element separated by a gap to form a first variable capacitor, a sealing ring surrounding the deflectable element and the surface electrode, an infrared transparent sealing cap electrode coupled to the sealing ring to form a vacuum cavity around the deflectable element and the surface electrode, the deflectable element and the sealing cap electrode separated by a gap to form a second variable capacitor and a micro-lens fabricated on the sealing cap electrode to focus the infrared radiation onto the bimaterial deflectable element.

Abstract: A fastening element is provided having a gripping portion, a plurality of gripping elements extending from the gripping portion, a supporting portion being defined by at least one supporting-portion wall extending from the gripping portion in a direction opposite that of the gripping elements, the supporting portion having a supporting-portion width smaller than a gripping-portion width of the gripping portion, such that a top flange is formed by the gripping portion relative to the supporting portion on at least one side of the fastening element, and an anchoring portion extending from a distal end of at least one supporting-portion wall and parallel to the gripping portion so as to form a bottom flange relative to the supporting portion on the at least one side corresponding to the top flange.

Abstract: The present invention is directed to the fabrication of thin aluminum anode batteries using a highly reproducible process that enables high volume manufacturing of the galvanic cells. A method of fabricating a thin aluminum anode galvanic cell is provided, the method including, depositing a layer of catalytic metal on a surface of a first substrate, depositing and patterning a benzocyclobutene layer to form a reservoir having four sidewalls of benzocyclobutene on the surface of the catalytic layer, depositing a layer of aluminum on a surface of a second substrate and bonding the first substrate to the second substrate to form a galvanic cell bounded by the catalytic metal layer and the aluminum layer and separated by the reservoir walls of benzocyclobutene, the second substrate positioned in overlying relation to contact the four sidewalls of the reservoir with the aluminum layer facing the catalytic layer.

Abstract: The present invention is directed to the fabrication of thin aluminum anode batteries using a highly reproducible process that enables high volume manufacturing of the galvanic cells. A thin aluminum anode galvanic cell having a meshed structure is provided which includes a catalytic metal layer positioned on a patterned silicon substrate, an etched dielectric layer positioned to cover the catalytic metal layer, the catalytic metal layer serving as an etch stop for the etched dielectric layer and an etched aluminum layer positioned to cover the dielectric layer, the dielectric layer serving as an etch stop for the etched aluminum layer.

Abstract: The present invention is directed to the fabrication of thin aluminum anode batteries using a highly reproducible process that enables high volume manufacturing of the galvanic cells. A method of fabricating a thin aluminum anode galvanic cell is provided, the method including, depositing a layer of catalytic metal on a surface of a first substrate, depositing and patterning a benzocyclobutene layer to form a reservoir having four sidewalls of benzocyclobutene on the surface of the catalytic layer, depositing a layer of aluminum on a surface of a second substrate and bonding the first substrate to the second substrate to form a galvanic cell bounded by the catalytic metal layer and the aluminum layer and separated by the reservoir walls of benzocyclobutene, the second substrate positioned in overlying relation to contact the four sidewalls of the reservoir with the aluminum layer facing the catalytic layer.

Abstract: The present invention is directed to the fabrication of thin aluminum anode batteries using a highly reproducible process that enables high volume manufacturing of the galvanic cells. A method of fabricating a thin aluminum anode galvanic cell is provided, the method comprising, forming a recess in the silicon wafer, the recess having no more than three sidewalls, depositing a catalytic metal layer on a bottom surface of the recess, positioning a double-side sticky tape layer having a bottom side positioned to contact the no more than three sidewalls of the recess and positioning an aluminum foil layer to contact a top side of the double-side sticky tape layer and in overlying relation to the recess, thereby forming the galvanic cell.

Abstract: The present invention is directed to the fabrication of thin aluminum anode batteries using a highly reproducible process that enables high volume manufacturing of the galvanic cells. A method of fabricating a thin aluminum anode galvanic cell is provided, the method comprising, forming a recess in the silicon wafer, the recess having no more than three sidewalls, depositing a catalytic metal layer on a bottom surface of the recess, positioning a double-side sticky tape layer having a bottom side positioned to contact the no more than three sidewalls of the recess and positioning an aluminum foil layer to contact a top side of the double-side sticky tape layer and in overlying relation to the recess, thereby forming the galvanic cell.

Abstract: The present invention is directed to the fabrication of thin aluminum anode batteries using a highly reproducible process that enables high volume manufacturing of the galvanic cells. In the present invention, semiconductor fabrication methods are used to fabricate aluminum galvanic cells, wherein a catalytic material to be used as the cathode is deposited on a substrate and an insulating spacing material is deposited on the cathode and patterned using photolithography. The spacing material can either be used as a sacrificial layer to expose the electrodes or serve as a support for one of the electrodes. Similarly, the aluminum anode may be deposited and patterned on another substrate and bonded to the first substrate, or can be deposited directly on the insulating material prior to patterning. The cell is packaged and connected to a delivery system to provide delivery of the electrolyte when activation of the cell is desired.

Abstract: In accordance with an embodiment of the present invention, a thermally induced single-use valve is provided including a silicon wafer having a top surface and a bottom surface and at least one cavity formed in the bottom surface of the wafer, a thermally deformable membrane suspended across the cavity on the top surface of the wafer and at least one resistive element patterned on top of the thermally deformable membrane.

Abstract: Halogenated organic compounds that are inexpensive and are readily available have been used to present the examples of the invention. These chemicals, when in contact with water experience a reaction that releases oxy-halogenated acid. These compounds are weak acids and release hydrogen ions according to their ionization constant keeping a constant level of oxy-halogenated ion. These ions are capable of reacting with catalytic cathodes and can be coupled with anode materials to fabricate galvanic cells. Exemplary embodiments of the present invention include cells with flat and cylindrical form factors having a variety of anodes.