Abstract: A formulation delivery system configured for outdoor use. The formulation delivery system includes a cleaning composition comprising chlorine, wherein the composition is in a form of a solid chemistry, and an outdoor cleaning device that is a spray wand having the cleaning composition positioned within a dispensing cartridge housed within the outdoor cleaning device.

Abstract: An integrated circuit package may be fabricated by disposing an underfill material between an electronic substrate and an integrated circuit device through an opening in the electronic substrate. In one embodiment, an integrated circuit assembly may include an electronic substrate having a first surface and an opposing second surface, wherein the electronic substrate includes at least one opening extending from the first surface to the second surface. The integrated circuit assembly may further include an integrated circuit device, wherein the integrated circuit device is electrically attached to the electronic substrate with at least one interconnect, and an underfill material may be disposed between the first surface of the electronic substrate and the integrated circuit device, wherein a portion of the underfill material extends into the opening in the electronic substrate.

Abstract: A method of casting an assembly is provided that includes forming a structural insert, over-molding the structural insert with a temporary core, and positioning the over-molded structural insert within a cavity of a casting die. The over-molded structural insert is cast within a part, to form the assembly, and the temporary core is removed. The method may also include a temporary core configured to define an alloy flash trim location or locating features to position the structural insert within the cavity of the casting die. Further, the temporary core may define shared features with the structural insert. The part and structural insert may be dissimilar materials such as a part of an aluminum alloy material and a structural insert of a steel alloy material.

Abstract: Disclosed herein are arrangements for shielding in electronic assemblies, as well as related methods and devices. In some embodiments, an electronic assembly may include a circuit board having a first face and a second opposing face, and a shield coupled to the second face of the circuit board. The circuit board may have a hole extending therethrough, and the shield may extend into the hole towards the first face.

Abstract: A method of casting an assembly is provided that includes forming a structural insert, over-molding the structural insert with a temporary core, and positioning the over-molded structural insert within a cavity of a casting die. The over-molded structural insert is cast within a part, to form the assembly, and the temporary core is removed. The method may also include a temporary core configured to define an alloy flash trim location or locating features to position the structural insert within the cavity of the casting die. Further, the temporary core may define shared features with the structural insert. The part and structural insert may be dissimilar materials such as a part of an aluminum alloy material and a structural insert of a steel alloy material.

Abstract: Systems and methods may provide for a device including a housing, one or more electronic components positioned within the housing, and a first cured resin composition positioned within the housing, the first cured resin composition including a thermal energy storage material and a first filler material. The device may also include a second cured resin composition positioned within the housing, the second cured resin composition including the thermal energy storage material and a second filler material. The first filler material and the second filler material may be different, wherein the first cured resin composition and the second cured resin composition may encompass at least one of the one or more electronic components. In other examples, the electronic components include a power supply and the device complies with an ATEX equipment directive for explosive atmospheres. Moreover, component underfill and/or assembly overmold processes may be used to fabricate the device.

Abstract: Disclosed herein are arrangements for shielding in electronic assemblies, as well as related methods and devices. In some embodiments, an electronic assembly may include a circuit board having a first face and a second opposing face, and a shield coupled to the second face of the circuit board. The circuit board may have a hole extending therethrough, and the shield may extend into the hole towards the first face.

Abstract: Systems and methods may provide for a device including a housing, one or more electronic components positioned within the housing, and a first cured resin composition positioned within the housing, the first cured resin composition including a thermal energy storage material and a first filler material. The device may also include a second cured resin composition positioned within the housing, the second cured resin composition including the thermal energy storage material and a second filler material. The first filler material and the second filler material may be different, wherein the first cured resin composition and the second cured resin composition may encompass at least one of the one or more electronic components. In other examples, the electronic components include a power supply and the device complies with an ATEX equipment directive for explosive atmospheres. Moreover, component underfill and/or assembly overmold processes may be used to fabricate the device.

Abstract: A standoff contact array is disposed between a mounting substrate of a flip-chip package and a board. The standoff contact array is formable by mating a low-profile solder bump on the mounting substrate with a low-profile solder paste on the board. Thereafter, the standoff contact array is formed by reflowing the low-profile solder paste on the board against the low-profile solder bump on the mounting substrate.

Abstract: A standoff contact array is disposed between a mounting substrate of a flip-chip package and a board. The standoff contact array is formable by mating a low-profile solder bump on the mounting substrate with a low-profile solder paste on the board. Thereafter, the standoff contact array is formed by reflowing the low-profile solder paste on the board against the low-profile solder bump on the mounting substrate.

Abstract: A microelectronic package and a method of forming the package. The package includes a first level package mounted to a carrier. The first level package includes a package substrate having a die side and a carrier side; and a microelectronic die mounted on the package substrate at the die side thereof. The carrier has a substrate side, and the first level package is mounted on the carrier at the substrate side thereof. A rigid body is attached to the carrier side of the substrate at an attachment location of the substrate and to the substrate side of the carrier at an attachment location of the carrier, the attachment location of the carrier being electrically unconnected, the rigid body being configured and disposed to provide structural support between the substrate and the carrier.