A magnetically levitating door is disclosed herein. The door may have a magnet that is repelled from a magnet of a track. The track may be disposed adjacent to a door opening. The track may have a stabilizing roller to maintain vertical alignment of the magnets used to levitate the door off of the track.

A magnetically levitating door is disclosed herein. The door may have a magnet that is repelled from a magnet of a track. The track may be disposed adjacent to a door opening. The track may have a stabilizing roller to maintain vertical alignment of the magnets used to levitate the door off of the track.

A magnetically levitating door is disclosed herein. The door may have a bracket having a magnet that is repelled from a magnet of a track. The magnet field of the bracket and the magnet field of the track may have different widths. The track may be disposed adjacent to a door opening. The bracket may have a guard in slidable engagement with the track to limit lateral movement of the magnet of the bracket disposed above and repelling the magnet of the track to levitate the door off of the track while preventing excessive lateral forces on the guard. The bracket may have at least one guide in slidable engagement with the track to secure the engagement of the bracket to the track and maintain vertical alignment of the bracket to the track.

A magnetically levitating door is disclosed herein. The door may have a magnet that is repelled from a magnet of a track. The track may be disposed adjacent to a door opening. The track may have a stabilizing roller to maintain vertical alignment of the magnets used to levitate the door off of the track.

A guide (10) for a liftable sliding leaf comprises at least two guide bars (14, 16), a first bar (14) of which can be connected movably to a support (24), fixed with respect to the leaf, and a second bar (16) can be connected integrally to a top part (12) of the leaf (11) so that both the bars (14, 16) are movable in a vertical plane.

An easily displaceable sliding door configured to be installed in an opening of a partition wall includes a shutter having an upper edge, a carriage secured to the shutter at the upper edge, a guiding member configured to be secured to the opening substantially parallel to the upper edge to allow sliding of the carriage, a magnetic unit having a lower portion integral with the shutter and an upper portion configured to be secured to the guiding member to reduce the weight force of the shutter to facilitate displacement, wherein the upper and a lower portions are separated by an air gap. The guiding member is of linear type and includes a straight cavity with an upper wall for supporting the upper portion of the magnetic unit, the upper edge and the a carriage being entirely embedded in the cavity to be hidden from external view.

The present sliding door system is designed to reduce opening and closing sliding resistance using magnetic force applied in opposition to the weight of the door. The present system has a particular configuration which is designed to achieve significant magnetic force attraction to overcome the weight of the door despite having compact configuration and which has a mechanism in the form of the horizontal rollers designed to overcome unwanted lateral magnetic force caused by the maximisation of the width of the permanent magnets within the confines of the channel.

A damping or return device for sliding door leaves, particularly for furniture, is provided. The device includes a rectilinear hollow body made of plastic material, which is slideably associated with a profile that is integral with the top of the piece of furniture and can be coupled automatically and with a snap action to an entrainer. The entainer is fixed to one of the door leaves by way of an adapted carriage. The rectilinear hollow body accommodates a bidirectional shock absorber and interacts selectively with a first or a second magnetized stroke limiting pivot which are associated with a first guide or with a second guide.

The present sliding door system is designed to reduce opening and closing sliding resistance using magnetic force applied in opposition to the weight of the door. The present system has a particular configuration which is designed to achieve significant magnetic force attraction to overcome the weight of the door despite having compact configuration and which has a mechanism in the form of the horizontal rollers designed to overcome unwanted lateral magnetic force caused by the maximisation of the width of the permanent magnets within the confines of the channel.

A magnetic levitation system for sliding door and window, includes at least a movable module for the lower part of the sliding door and window which includes one or more permanent magnets; several fixed modules for the lower part of the frame of the sliding door and window, which includes one or more electromagnets to produce a variable repulsive magnetic field of the magnetic field of said magnets of the movable module. It has the advantage of eliminating the friction, mechanical wear and noise associated to the sliding, allowing, when deactivated, a greater air and water tightness and terminal and acoustic insulation, allowing the electromagnetic closure or locking of the door and window, increasing the security, and as is a modular system its operation and construction are simpler and more economical.