A door assembly of a vehicle includes a first door panel movable at least partially across a door opening from a first side of the door opening toward a second side of the door opening, a second door panel spaced apart from the first door panel and movable at least partially across the door opening from the first side toward the second side. A first magnetic element is located at the first door panel and a second magnetic element is located at the second door panel. The second magnetic element is interactive with the first magnetic element such that moving of the first door across the door opening causes movement of the second door panel across the door opening.

A fitting arrangement for a leaf of a sliding window or door that can be moved away in parallel, includes a control unit having a mounting part for fixing on the leaf and an adjusting part which is displaceable relative to the mounting part for moving the leaf away in parallel. A movement unit is fastened to the control unit and has an energy storage device and an activation element for the energy storage device. A closure arrangement for a building opening, includes a frame, the control unit and the adjusting part. The leaf which, in a closed position, can, by means of the control unit, be brought up to the frame and be moved away from the frame in parallel, so the leaf is displaceable along a guide rail of the frame. The movement unit supports an automatic movement of the leaf along the guide rail.

Disclosed is a hidden shower door with a low-rail sliding assembly, including an upper rail assembly (10), a movable door assembly (20), a vertical frame assembly (30), and a bottom guide part (40), wherein the upper rail assembly (10) includes an upper rail (1010), a damping trigger (1020), and sliding assemblies (1030), and the sliding assemblies (1030) each are mounted in the upper rail (1010); the sliding assemblies (1030) each include pulleys (10311), pulley brackets (1060), adjusting screws (10312), a damper (1050), and a damper bracket (1040); the pulleys (10311) are mounted on the pulley brackets (1060). The two pulley brackets (1060) are connected and fixed to two ends of the damper bracket (1040) respectively, and the damper (1050) is mounted in a damper accommodating groove (1041) of the damper bracket (1040); the upper rail (1010) is provided with a first bottom plate (1011).

An exemplary closure assembly includes a rail assembly and a door assembly movably mounted to the rail assembly. The door assembly includes a rotary damper having a pinion, and the rail assembly includes a rack member operable to engage the pinion. As the door moves from first position to a second position, the rack member engages the pinion, thereby causing the pinion to rotate in a first rotational direction. The rotary damper resists rotation of the pinion in the first direction, thereby slowing movement of the door toward the second position. The rotary damper may be a one-way damper that does not resist rotation of the pinion in a second rotational direction such that the rotary damper does not resist movement of the door from the second position toward the first position.

A window vent stop is disclosed having a housing with a peripheral flange defining an opening, and a body depending from the peripheral flange. A stop block is mounted within the body of the housing for movement between an open position wherein a portion of the stop block protrudes above the peripheral flange and a closed position. A spring leg is located on a bottom end of the housing and flexes toward the housing when under compression, providing compressive force along a line parallel to a longitudinal axis of the housing when the window vent stop is inserted into an opening in a window sash. By applying force to further compress the spring leg, the vent stop can be readily removed from the window sash without damage.

A door damper assembly that includes a housing, a damper that includes a fixed end and a movable end disposed within the housing, a carriage assembly that is movable within the housing between a closed position and an open position, a claw assembly pivotably attached to the carriage assembly, and a spring positioned to bias the carriage assembly to the closed position. The movable end of the damper is secured to the carriage assembly. The claw assembly is movable with the carriage assembly between the closed position and the open position. The claw assembly is movable relative to the carriage assembly between a non-toggle position and a toggle position. The claw assembly includes a pin receiving space defined therein that defines a claw axis that is generally vertical when the claw is in the non-toggle position and not vertical when the claw assembly is in the toggle position.

A shock-absorbing braking device (10) for sliding doors (88) or for wardrobe panels is combined with a carriage (12) provided with rollers (14) sliding in an extruded profile (16), with a bottom base provided with a longitudinally extending slot (18) from which a pin or bolt (20) protrudes suitable to connect said carriage (12) to the sliding door or panel (88). The device comprises a containment shell (24), formed of opposite and complementary elements (28), in which at least one helical spring (26) and a shock-absorbing piston (30) acting in conjunction with a shaped cam (56) are placed, provided with an appendage forming a traction hook (62) suitable to abut with an activator (78) extending in said extruded profile (16). The shaped cam (56) is provided on opposite sides with a pin (64), destined to slide along a mixtilinear cavity (66, 66) extending longitudinally along the inner face of each of the elements (28) forming the containment shell (24).

An apparatus for moving sliding doors and wardrobe doors fixed to the inner face of the top of a door includes at least one carriage and at least one braking device with a slider pulled by at least one coil return spring. The door is hung from a beam made up of two extruded profiles, the first of which is fastened to the wall with screws and relative plugs; the second extruded profile is fastened to the first profile with snap-in couplings. These coupled profiles define a cavity in which the braking device is housed and stabilised with screws, fixed on a cantilevered bracket of the second extruded profile. The latter defines a sliding track for the wheels or bearings of the carriage(s), fixed to the door at a recess.

A sliding door includes a door panel that has a first face, a second face that is opposite to the first face, and a top edge that defines first and second raised portions of the door panel and an open space that extends between the first and second raised portions. The sliding door includes a plurality of rollers affixed to the door panel by first and second mounting assemblies. Each of the plurality of rollers has an axis of rotation that is normal to the first face of the door panel. The sliding door includes a soft-close assembly secured to the first and second mounting assemblies at opposing ends thereof, such that the soft-close assembly is positioned within the open space between the first raised portion of the door panel and the second raised portion of the door panel.

A bidirectional damper comprises a mounting bracket, a tension spring, two damping cylinders and two engaging members; the mounting bracket comprises a first bracket plate, a second bracket plate and a connecting plate connected between the first bracket plate and the second bracket plate, the connecting plate comprises a main body section and extension sections at two ends of the main body section; the damping cylinder, the tension spring and the two engaging members are located between the first bracket plate and the second bracket plate, the damping cylinder and the tension spring are respectively arranged at two sides of the connecting plate, and the two extension sections are bent from the main body section towards the tension spring.