Aspects of the present disclosure describe a rechargeable door that includes at least one internal rechargeable battery and at least one further DC component powered by such rechargeable battery, wherein the at least one internal rechargeable battery is configured to be recharged via a physical connection, such as wired connections, or other contacts such as magnetic contacts or pogo pins or spring contacts, in the door via a second rechargeable battery or via wireless recharging, for example magnetic inductive or resonance charging, via placement of the second rechargeable battery on or within the door.

Embodiments herein relate to fenestrations, such as windows and doors, exhibiting coastal impact performance. In a first aspect, an impact-resistant fenestration unit can be included having a frame and a bottom sash. The bottom sash can have a bottom rail, a check rail, and opposed stiles and can be configured to pivot inward away from the frame assembly such that the check rail moves away from the frame assembly. A first side bracket can define a cavity to receive a portion of a bolt from a sash tilt bolt assembly. The first side bracket can be mounted on one of the two opposed side jambs at a height corresponding to a position of the check rail when the bottom sash can be in a closed position. The bolt can include a metal inner support member and a polymeric overmold portion. Other embodiments are also included herein.

Embodiments herein relate to fenestrations, such as windows and doors, exhibiting coastal impact performance. In a first aspect, an impact-resistant fenestration unit can be included having a frame and a bottom sash. The bottom sash can have a bottom rail, a check rail, and opposed stiles and can be configured to pivot inward away from the frame assembly such that the check rail moves away from the frame assembly. A first side bracket can define a cavity to receive a portion of a bolt from a sash tilt bolt assembly. The first side bracket can be mounted on one of the two opposed side jambs at a height corresponding to a position of the check rail when the bottom sash can be in a closed position. The bolt can include a metal inner support member and a polymeric overmold portion. Other embodiments are also included herein.

A security panel mounting system having a mounting unit configured to attach to a mounting surface; a securing unit configured to engage with the mounting unit wherein the engagement of the securing unit with the mounting unit forms a base fixture; a first narrow gasket and a second narrow gasket, each narrow gasket having: a narrow gasket body; a T-shaped narrow gasket handle attached to the narrow gasket body; and a gasket hollow nested within the narrow gasket body; wherein each narrow gasket handle is configured to engage with a corresponding structure within the base fixture to secure a security panel within the base fixture; and a cover configured to engage with the base fixture. An advantage is that the hollow within each narrow gasket may allow an impact to the panel to be responded more flexibly, reducing the likelihood of the mounting system being damaged from the impact.

A security panel mounting system having a mounting unit configured to attach to a mounting surface; a securing unit configured to engage with the mounting unit wherein the engagement of the securing unit with the mounting unit forms a base fixture; a first narrow gasket and a second narrow gasket, each narrow gasket having: a narrow gasket body; a T-shaped narrow gasket handle attached to the narrow gasket body; and a gasket hollow nested within the narrow gasket body; wherein each narrow gasket handle is configured to engage with a corresponding structure within the base fixture to secure a security panel within the base fixture; and a cover configured to engage with the base fixture. An advantage is that the hollow within each narrow gasket may allow an impact to the panel to be responded more flexibly, reducing the likelihood of the mounting system being damaged from the impact.

Systems and methods are provided for facilitating automated and manual segregation of internal areas within structures in response to active shooter warnings, or other triggering events. Embodiments may provide automated systems and methods, to facilitate simplified and automated (1) deployment of mechanized safety and/or security (bulletproof) curtains, including certain safety curtains comprising, or otherwise formed of, replaceable bulletproof and/or other penetration-resistant materials, and/or (2) actuation of mechanized safety and/or security (bulletproof) doors, to effectively segregate open areas and hallways in buildings. Exemplary embodiments may: (a) limit lines of sight of a perpetrator; (b) interdict bullet flight paths; (c) restrict or eliminate a perpetrator's freedom movement; (d) confine areas of detected explosive ordnance detonations or dispersal of contaminants; (e) provide a means of trapping/isolating a perpetrator; and/or (f) provide local safe havens in active shooter, gunfire, explosive detonation, contaminant dispersal, and like threat scenarios/situations.

Embodiments herein relate to fenestrations, such as windows and doors, exhibiting coastal impact performance. In a first aspect, an impact-resistant fenestration unit can be included having a frame assembly including a sill, a head jamb, and two opposed side jambs. A bottom sash can be included having a bottom rail, a check rail, and two opposed stiles. A first corner key can be configured to engage the bottom sash at a first lower corner. The first corner key can include a support arm extending in a first direction onto or into a first stile of the two opposed stiles. A first reinforcement member disposed on or within the first stile. The first reinforcement member can include a first end and a second end. The first end can overlap a portion of the support arm of the first corner key. Other embodiments are also included herein.

Embodiments herein relate to fenestrations, such as windows and doors, exhibiting coastal impact performance. In a first aspect, an impact-resistant fenestration unit can be included having a frame assembly including a sill, a head jamb, and two opposed side jambs. A bottom sash can be included having a bottom rail, a check rail, and two opposed stiles. A first corner key can be configured to engage the bottom sash at a first lower corner. The first corner key can include a support arm extending in a first direction onto or into a first stile of the two opposed stiles. A first reinforcement member disposed on or within the first stile. The first reinforcement member can include a first end and a second end. The first end can overlap a portion of the support arm of the first corner key. Other embodiments are also included herein.

In a conventional fine particle detection device that vaporizes fine particles attached to the object of examination by heating, processing capability decreases as the processing time elapses due to the influence of deposition of fine particles other than the object of examination, dirt/dust, a residue of the fine particles as the object of examination, or residual matter. A fine particle detection device according to the present invention includes: a vaporization device that vaporizes the fine particles trapped by a trap device by vaporization or decomposition; a first flow passageway in which a mixture of a component vaporized by the vaporization device and another component flows; a second flow passageway branching from the first flow passageway in a direction of inertial force acting on the other component; a third flow passageway branching from the first flow passageway in a direction different from the direction of the inertial force; and an analysis device that analyzes a component introduced into the third flow passageway.

In a conventional fine particle detection device that vaporizes fine particles attached to the object of examination by heating, processing capability decreases as the processing time elapses due to the influence of deposition of fine particles other than the object of examination, dirt/dust, a residue of the fine particles as the object of examination, or residual matter. A fine particle detection device according to the present invention includes: a vaporization device that vaporizes the fine particles trapped by a trap device by vaporization or decomposition; a first flow passageway in which a mixture of a component vaporized by the vaporization device and another component flows; a second flow passageway branching from the first flow passageway in a direction of inertial force acting on the other component; a third flow passageway branching from the first flow passageway in a direction different from the direction of the inertial force; and an analysis device that analyzes a component introduced into the third flow passageway.