A piezoelectric speaker-forming laminate (10) includes: a piezoelectric film (35); a pressure-sensitive adhesive face (17); an interposed layer (40) being a porous body layer and/or a resin layer disposed between the piezoelectric film (35) and the pressure-sensitive adhesive face (17); and a release layer (20) joined to the pressure-sensitive adhesive face (17). The pressure-sensitive adhesive face (17) is disposed in such a manner that at least a portion of the piezoelectric film (35) overlaps the pressure-sensitive adhesive face (17) when the piezoelectric film (35) is viewed in plan. The piezoelectric film (35) and the interposed layer (40) are allowed to be fixed to a support (80) as a piezoelectric speaker or a portion of a piezoelectric speaker by sticking the pressure-sensitive adhesive face (17) from which the release layer (20) has been removed to the support (80).

The present disclosure provides descriptions of configurations for noise reducing and cooling enclosures and enclosure material. The noise reducing and cooling enclosures seal and passively acoustically quiet acoustic energy generated by one or more noise emitting devices within the enclosure, and dissipate heat generated by the devices through conduction by use of composite enclosure materials.

A fire protection element contains a layered body for sealing passage openings in components, such as building components, through which lines are guided. A method can be used for producing the fire protection element and the fire protection element can be used for sealing passage openings and/or joints in components against fire and flue gases.

A laminate having: an electrode for electrolysis, and a membrane laminated on the electrode for electrolysis, wherein when the laminate is wetted with a 3 mol/L NaCl aqueous solution, and under a storage condition at ordinary temperature, an amount of a transition metal component (with the proviso that zirconium is excluded), detected from the membrane after storage for 96 hours, is 100 cps or less; and A protective laminate having: a first electrode for electrolysis, a second electrode for electrolysis, a membrane disposed between the first electrode for electrolysis and the second electrode for electrolysis, and an insulation sheet that protects at least one of the surface of the first electrode for electrolysis and the surface of the second electrode for electrolysis.

A display module and display device that may suppress a greenish defect and reduce a bezel area while improving a heat-dissipation performance and a shock absorption function include an integral cushion plate including at least one protrusion protruding from and extending along an edge portion of a body with the cushion plate placed on a lower surface of a display panel, and the protrusion brought into contact with a cover member. Further, the protrusion of the cushion plate is bent to have an inclined part so that the protrusion does not contact the side surface of the display panel and contacts the cover member.

Reusable transporters for removable housing of radioactive materials and configured for safely containing the radioactive materials during transportation operations of the transporters are described. A given transporter may have at least four layers, an outermost structural-jacket, an innermost liner, a containment layer, and a radiation shielding layer. The structural-jacket is made from strong materials like steel and/or titanium, but not stainless steel. The containment layer and/or the radiation shielding layer may have one or more sub-layers. The containment layer is stretchable and designed to completely enclose the internally stored radioactive materials even in the event of a serious impact event to the overall transporter. The radioactive materials are removably stored within an inner cavity of the transporter, within the liner. The inner cavity may be accessible from at least one terminal end of the transporter. The at least one terminal end is removably closeable via use of closure means.

A method of forming a sandwich structure including at least partially filling an open volume of an open cellular core with a sacrificial mold material, consolidating the sacrificial mold material to form a sacrificial mold, laying up a composite facesheet on each of at least two surfaces of the open cellular core, co-curing the composite facesheets by applying a consolidation temperature and a compaction pressure to the composite facesheets to form the sandwich structure, and removing the sacrificial mold. The compaction pressure is greater than a compressive strength of the open cellular core and less than a combined compressive strength of the open cellular core and the sacrificial mold.

The invention relates to thermal management systems for devices that generate heat, including electronic devices such as portable electronics, for example, cell phones, electronic components, and/or battery systems. A multilayer phase change material composite structure may include multiple layers having different properties. For example, a PCM material composite layer may include a supporting structure having pores and a phase change material. Further, a layer of fire retardant material may be used in the multilayer phase change material. In some embodiments, additional layers such as coatings, thermal interface materials, and/or high thermal conductivity material may be present. A matrix formed from a porous supporting structure and a phase change material may be used to control and/or dissipate heat in a thermal management system. Support elements may provide stability. The thermal management system may mitigate conditions that could lead to a thermal runaway event and/or may influence conditions within the system during a potential thermal runaway event to reduce risk of fire. The thermal management system may include water, flame- and/or fire-retardant materials to control temperatures of an energy storage device and/or system. A housing may be used to surround a portion of a heat generating device such as an energy storage device or system, for example, an individual battery or a group of batteries, respectively. The housing or enclosure may include interior structures that surround and in some cases electrically isolate batteries from a thermal sink that includes a porous flame- and/or fire-retardant material having water in the pores.

The present application relates to an asymmetry composite material and a method for preparing the same, which provides a composite material comprising a metal porous body (metal foam or the like) and a polymer component, and provides a method for preparing a composite material, wherein the polymer component is formed in an asymmetrical structure on both sides of the metal porous body (metal foam or the like), and a composite material prepared in such a manner.

A multi-threat security apparatus system for critical infrastructure protection is disclosed having an above-ground concrete base, a vertical post system adapted to be attached to the above-ground concrete base and to receive a plurality of louvers. The plurality of louvers provides the necessary ballistic protection for and air flow through to the critical infrastructure. The louvers may include a composite of aluminum foam, a resin impregnated ballistic material and an aluminum foam. The composite structure may be used on doors, panels or building walls.