A ventilator door brings fresh outside air into a structure through an outside grill and a blower pulls outside air into a duct in the door and the air flows through the duct and into the structure through an inside grill remote from the outside grill. Heat is transferred from the flow of air to a heat sink disposed against the duct to cool the fresh air flowing into the duct. A regenerative heat sink may be used to capture heat from a flow of air from inside the structure and transfer the captured heat to a flow of outside air flowing into the structure. With the regenerative heat sink, a second blower is used to blow the inside air through the duct and outwardly through the outside grill before the outside air is pulled into the duct and blown past the regenerative heat sink to warm the air flow in to the structure. Several embodiments are included.

A ventilator door brings fresh outside air into a structure through an outside grill and a blower pulls outside air into a duct in the door and the air flows through the duct and into the structure through an inside grill remote from the outside grill. Heat is transferred from the flow of air to a heat sink disposed against the duct to cool the fresh air flowing into the duct. A regenerative heat sink may be used to capture heat from a flow of air from inside the structure and transfer the captured heat to a flow of outside air flowing into the structure. With the regenerative heat sink, a second blower is used to blow the inside air through the duct and outwardly through the outside grill before the outside air is pulled into the duct and blown past the regenerative heat sink to warm the air flow in to the structure. Several embodiments are included.

The invention relates to a holder for one or more elongate elements (70, 72), particularly slats for shading systems and daylight control systems, comprising an elastic or resilient compensating unit having two profiles (50, 150) which are located opposite one another and engage in one another and are arranged such as to be movable relative to one another in the longitudinal direction of the elongate elements (70, 72), said two profiles forming a common interior (90). Accommodated in the interior (90) is a spring element (92) which is compressed when the elongate element (70, 72) expands under the effect of temperature and which relaxes when the elongate element (70, 72) contracts in the longitudinal direction of the elongate element (70, 72). The spring element is held in the interior (90) with a clamping fit or friction fit, a compensating movement in the longitudinal direction being possible. The profiles of the compensating unit each comprise, on the side facing away from the interior (90), a further profile (30, 130) which is formed in one piece therewith and is designed to hold the elongate elements (70, 72) or as a spacer from a window frame or carrier element (8). The components, consisting in each case of one profile (50, 150) of the compensating unit and a further profile (30, 130), are identical.

The present disclosure relates to sculptural slats, wherein varying orientations of sculptural slats within a sculptural slat structure may provide a range of one or both decorative or ambient variable impact. For example, sculptural slats may provide transitional states for a window covering, wherein if the covering is in an open position, the sculptural slat structure may provide an ambient variable impact, and wherein the ambient variable impact may change as the orientation of the sculptural slats is adjusted. In some aspects, the present disclosure provides variations on potential designs, smart technology integration, and applications to other types of slattable objects, including, for example, exterior and interior window coverings, architectural panels, dividers, screens; furniture; and automobiles components. Aftermarket solutions to upgrade traditional slatted structures and slattable objects are described, along with manufacturing methods to create customized sculptural slats and sculptural slat structures based on preferences, installation requirements, and slattable object.

A door assembly comprises a rectangular door frame that has a first, second, third, and fourth frame member. The first frame member has an outer surface that has a first pair of parallel slots. A first parallel flange protrudes from and perpendicular to the outer surface between the parallel slots. A vane extends from the first frame member to the second frame member between the third and fourth frame members. The vane has a first end that includes a pair of parallel flanges fitted into the parallel slots such that a rear surface of the first planar flange is arranged between rear edges of the first parallel flanges. A bar is mounted to the rear surface of the first planar flange and configured to hold the rear edges of the first parallel flanges in substantially the same plane as the rear surface of the first planar flange.

A door assembly comprises a rectangular door frame that has a first, second, third, and fourth frame member. The first frame member has an outer surface that has a first pair of parallel slots. A first parallel flange protrudes from and perpendicular to the outer surface between the parallel slots. A vane extends from the first frame member to the second frame member between the third and fourth frame members. The vane has a first end that includes a pair of parallel flanges fitted into the parallel slots such that a rear surface of the first planar flange is arranged between rear edges of the first parallel flanges. A bar is mounted to the rear surface of the first planar flange and configured to hold the rear edges of the first parallel flanges in substantially the same plane as the rear surface of the first planar flange.

An innovative, low-density, highly-insulating modular panel for use in many applications and industries. The panel has a frame that may be preformed or bent and may be made of rigid or flexible material, and a panel covering comprising at least one pocket of thin, low-density shade fabric that has the capability of sufficiently stretching to surround the frame when the pocket is pulled onto it. The pocket may be then secured, along any previously open end where the frame was inserted, by various fastening devices. The panel covering pocket may have additional features added, as described herein. The panel is durable and cost-effective, and has good solar-control and insulating qualities. It is also a windbreak panel, a noise-reduction panel, an impact protection panel, a water-resistant panel, a fall protection panel, and a pollution-control panel. Two or more panels can be joined to create a structure-protecting panel assembly or system.

The invention relates to a louvered separator for separating water from an air flow. The louvered separator comprises a number of vertical slat structures having a constant profile, horizontally spaced from each other so as to form horizontally tortuous separating channels (1) in the spaces between the slats. The slat structures are provided with water-collecting troughs (2,3). The slat structure comprises two separate slats having differing constant profiles; in the air flow direction (4) a foremost front slat (5) and a following back slat (6). The front slat comprises, in the flow direction, a leading edge (7), a middle area (8) and a trailing edge (9), and the back slat comprises, in the flow direction, a leading edge (10), a middle area (11) and a trailing edge (12). According to the invention, the water-collecting trough (2,3) is limited to the area of the trailing edge (12) of the back slat (6), so that the front slat (5) entirely, and the back slat (6) for more than a half of its length from the leading edge (10) towards the trailing edge (12), form only even surfaces to guide the flow.

This disclosure relates to a louvered patio cover. The louvered patio cover may comprise a frame with support beams, louvered panels, support beam couplers, an actuator, a gutter, and/or other components. The support beams may have angled ends. The louvered panels may be rotatably coupled to the support beams. A support beam coupler may comprise first and second receivers. The first receiver may be configured to receive an angled end of a first support beam, and the second receiver may be configured to receive an angled end of a second support beam. The angled ends of the first and second support beams may face, meet, and/or abut each other when received by the first and second receivers. The actuator may be configured to rotate the louvered panels. A gutter may comprise a lighting channel configured to hold a light source for lighting an area under the louvered patio cover.

Implementations of a portable soundproofing enclosure may include: four side panels coupled together, a top panel coupled to each of the four side panels, the four side panels and the top panel, the top panel including a fan. The panels may form a cavity sized to fully enclose a portable generator. At least two of the four side panels may include an air dam. At least one of the side panels may have a plurality of louvers configured to allow air to be drawn through the panel. The bottom edges of the sides may be configured to rest on a mat.