This application relates to capacitors that resist deformation because of the configuration of their conductive and dielectric layers. The capacitors are multilayer capacitors that include multiple dielectric and conductive layers. The dielectric layers can be arranged in a way that creates a rigid barrier or dead zone, which can resist mechanical deformation when the multilayer capacitor is charged. In some embodiments, two or more multilayer capacitors are stacked together in an arrangement that causes each of the multilayer capacitors to cancel any deformations of the other when the multilayer capacitors are charged. In this way, noise exhibited by the multilayer capacitors can be reduced.

Fire-fighting wall casing for closed environments, constituted of a frame (4) housing, in its upper portion, a soffit (3) which slides downwards by way of a system of pulleys placed within the frame (4), in its central portion a shutter (1) which may be opened by a side-hinge system, in its lower portion a railing (2) sliding upwards by way of a side guide (8) a protection grid (7) which, after being disconnected from the railing, may be removed by way of side retainers; a magnetic switch (6) and a smoke and/or seismic detector being positioned in its upper portion; a fume deflector (9), intended for extracting fumes from the upper floors, being positioned above the casing.

A ventilation panel for an enclosure of an industrial machine is disclosed herein. In embodiments, the ventilation panel includes a panel silencer and a fire damper assembly. The panel silencer includes a number of panels joined together to form an internal cavity and a front panel opening that provides access into the internal cavity. The fire damper assembly partially inserts into the panel silencer. The fire damper assembly includes a plurality of isolation louvers and an actuation assembly. The plurality of isolation louvers are rotatably affixed within the fire damper assembly. The actuation assembly rotates the plurality of isolation louvers into a closed position when activated.

A door assembly includes: a rotatable curtain deployment member positionable about a structure opening; a curtain panel fixed to the curtain deployment member, the curtain being movable, upon rotation of the curtain deployment member, between a retracted position and an extended position, the curtain panel having at least one portion of increased thickness; a rotatable balancing strip member configured to substantially parallel with the curtain deployment member, and configured to rotate synchronously therewith in a common rotational direction, and a balancing strip having a first end attached to the balancing strip member, and a second end attached to the curtain deployment member and axially spaced from the portion of increased thickness. When the curtain panel deploys to the retracted position, the balancing strip deploys to the curtain deployment member, and when the curtain panel deploys to the extended position, the balancing strip deploys to the balancing strip member.

A fire door utilizing a pair of frame members each having cases forming opposing open chambers. The open chambers are filled with fire resistant material and include structural plates that do not contact the cases. Holders attach to the cases support a fire resistant glazing unit.

A nozzle access device is configured to be installed in a structural element and to accept connection by a fire hose nozzle to introduce firefighting fluid into an enclosed space. The device has a housing configured to be inserted in a hole formed in the structural element. The housing has a cylindrical body and a first face with an opening surrounded by an inwardly extending cylindrical socket. The housing has a second face, with an opening, which is attached to the cylindrical body. A movable nozzle connector in the housing has a connection portion configured to receive an inserted fire hose nozzle in a locking connection and a cylindrical nozzle stop portion extending from the connection portion. The nozzle stop portion is movably coupled within an interior of the socket of the first face.

Fire-fighting wall casing for closed environments, constituted of a frame (4) housing, in its upper portion, a soffit (3) which slides downwards by way of a system of pulleys placed within the frame (4), in its central portion a shutter (1) which may be opened by a side-hinge system, in its lower portion a railing (2) sliding upwards by way of a side guide (8) a protection grid (7) which, after being disconnected from the railing, may be removed by way of side retainers; a magnetic switch (6) and a smoke and/or seismic detector being positioned in its upper portion; a fume deflector (9), intended for extracting fumes from the upper floors, being positioned above the casing.

This application relates to capacitors that resist deformation because of the configuration of their conductive and dielectric layers. The capacitors are multilayer capacitors that include multiple dielectric and conductive layers. The dielectric layers can be arranged in a way that creates a rigid barrier or dead zone, which can resist mechanical deformation when the multilayer capacitor is charged. In some embodiments, two or more multilayer capacitors are stacked together in an arrangement that causes each of the multilayer capacitors to cancel any deformations of the other when the multilayer capacitors are charged. In this way, noise exhibited by the multilayer capacitors can be reduced.

A shelter for protecting a person from fire and heat. The shelter has an inner door and an outer door and an outer door. The shelter has a roof, and front, right, left, and rear walls, each of which having a core made of a three-dimensional metal matrix embedded in insulation with concrete positioned about the walls and the roof. The concrete forming a fire-resistant seal with the base about the walls, and roof which protects the person in the chamber from fire and heat at least more than 700 degrees Fahrenheit for at least 4 hours. A method for protecting a person from fire and heat. A method for building a shelter for protecting a person from fire and heat external to the shelter.

A closing body allows closing and opening an access opening or a passage of a room in case of a pressure difference between an interior and exterior of the room. A closing fitting set and a door leaf are disclosed, by means of which closing fitting set and door leaf a closing body can be formed. The closing body is in the form of a pivotable door, a pivotable window or a pivotable flap. A valve device is provided on the closing body, which valve device effects a temporary pressure equalization during the opening or closing of the closing body. The valve device is in the form of a valve flap, and a release mechanism is provided, which opens the valve device. A locking fitting is provided for the closing body, and the release mechanism is coupled, for actuation, to the locking fitting of the closing body.