A hinge having a first hinge part and a second hinge part. The second hinge part has a hinge pin to which the first hinge part is connected for movement relative to the second hinge part about a hinge axis between a closed position. An over-close mechanism is provided comprising a catch member on the second hinge part arranged to co-operate with the first hinge part to urge the first hinge part towards the closed position during closing movement of the first hinge part and to retain the first hinge part arrange to co-operate with the hinge pin to urge the first hinge part towards the closed position during closing movement. A soft-close mechanism is provided comprising a damper member on the first hinge part arranged to co-operate with the hinge pin to provide a braking force in the direction of closing.

A sliding panel system is disclosed. The system includes a fitting assembly designed to fixedly secure a first panel to an elongate rail member, and a carrier assembly designed to moveably secure a second panel to the elongate rail member. The system facilitates the lateral movement of the second panel with respect to the first panel. The carrier assembly includes at least one carrier unit including a housing with an inner volume, at least one roller unit configured in an upper portion of the inner volume, at least one guide member configured in the inner volume, and an opening extending across the front of the housing and adapted to receive a longitudinal portion of the rail member. The at least one roller unit and the at least one guide member are concealed within the housing when the housing is viewed from a perspective perpendicular to the front of the housing.

An anti-derailing device for a sliding door, including slide rollers on upper edges of two sides of the sliding door, anti-bounce rollers below the slide rollers, rail supporting bases on a fixed door in front of the sliding door, and a rail fixed on opposite outer sides of the sliding door and the fixed door and clamped between the rollers. Each roller includes a fixed part and a first adjusting part which includes a first eccentric roller combined with the fixed part, each roller includes a fixing part and a second adjusting part which includes a second eccentric roller combined with the fixing part, and each rail supporting base includes a positioning part and a holding part for holding the rail. By adjusting positions of the rollers and without pre-machined holes, the sliding door can operate balanced and smoothly and prevent the rail from derailing.

A sliding door includes a frame and a slow close assembly. The frame is positioned along at least a portion of the sliding door and includes a protrusion configured to slide along with the sliding door. The slow close assembly is repositionable between an outward position and a compressed position. The slow close assembly includes a slow close mechanism, a spring, and a soft close latch. The slow close mechanism is laterally positioned within the slow close assembly. The spring is positioned at an end of the slow close assembly and provides an outward force onto the slow close assembly in an outward direction substantially perpendicular to the lateral direction. The soft close latch is configured to engage the protrusion as the protrusion slides along with the sliding door. The spring biases the slow close assembly into the outward position when the latch is not interfaced with the protrusion.

A museum showcase includes a guide system for a sliding door, including upper and lower guide mechanisms. The upper guide mechanism includes primary and secondary rails. The upper guide mechanism also includes a first slide unit and a second slide unit. The first slide unit has a rolling member on an upper horizontal track of the secondary rail, and a sliding block engaged on a vertical track of the secondary rail. The second slide unit has a rolling member on a lower horizontal track of the primary rail, and a sliding block engaged on a vertical track of the primary rail. Thereby, the upper guide mechanism is extremely strong. The weight of the door, entirely supported by the secondary rail, is discharged on the first rail by the two slide units to transmit both vertical and horizontal loads.

The present invention discloses a sliding rail type low-obstacle linkage shower room and an installation method thereof. The shower room includes an upper rail and a lower rail, a fixed glass, a primary shower glass and a secondary shower glass. The lower rail is correspondingly provided at the secondary shower glass. A sliding block unit is installed on the secondary shower glass. The sliding block unit includes a fixed portion, a sliding groove and a guidance sliding portion. The fixed portion is provided correspondingly to the secondary shower glass. The sliding groove is used for receiving the primary shower glass to form a linkage. The guidance sliding portion is glidingly engaged with the lower rail. The linkage shower room has a simple structure which can be easily manufactured.

This disclosure pertains to a pet door apparatus, and in particular, a pet door apparatus integrated within sliding glass door frames of apartment units and other enclosed building structures. A pet door apparatus consistent with the present disclosure comprises a plurality of panels which features a flap within one of the panels. The plurality of panels are coupled to each other by at least one attachment mechanism. The coupling between the first panel and the second panel and the coupling between the second panel and the third panel forms an assembled unit. The point of coupling between at least two of the panels is adjustable to extend the length of the assembled unit. An end of one of the panels is fitted within the first track of the slidable door frame. An end of one of the other panels is fitted within the second track of the slidable door frame.

Disclosed herein are glass articles and methods of manufacturing the same. The glass articles may include a glass layer comprising a first portion having a first thickness, a second portion having a second thickness, and a third portion disposed in between the first portion and the second portion. The third portion may form a living hinge. The living hinge may comprise a plurality of indentations such that a majority of the third portion has a third thickness that is less than the first thickness and the second thickness. In addition, the living hinge may comprise a plurality of protrusions such that a majority of the third portion has a third thickness that is greater than the first thickness and the second thickness.

A frame assembly with sliding panels is described. The frame assembly includes a frame having an upper section opposite of a lower section. The lower section of the frame defines a first channel and a second channel. A first sliding panel includes a first lower edge. A first panel support is removably engaged to the first lower edge. The first panel support includes a first holding member that engages to the first lower edge. The first panel support slides in the first channel. A second sliding panel includes a second lower edge. A second panel support is removably engaged to the second lower edge. The second panel support includes a second holding member that engages to the second lower edge. The second panel support slides in the second channel.

A furnishing is fitted with a rotating panel (5), in particular a transparent panel. The panel is mounted in the furnishing via at least a hinge (20), wherein the hinge comprises a first hinge part (21) for attaching close to the panel and a second hinge part (22) for attaching to the panel. A receivable member (25) extends from one of the two hinge parts (21,22) and is received in a receiving cavity (35) in another of the two hinge parts in order to connect the two hinge parts pivotally to each other. The respective other hinge part (22) comprises a holder part (30) with a holder body (33) which is accommodated while allowing freedom of movement in the receiving cavity. The holder body (33) comprises a bore in which the receiving member is received.