A spring drive system for a window shade includes a housing, a first and a second gear engaged with each other and respectively assembled about a first and a second pivot axis, two springs respectively assembled at two opposite sides of the second gear and respectively connected with two take-up reels provided on the first gear, a first cord drum and a third gear fixedly connected with each other and assembled about a third pivot axis, the first and third gears being respectively located at different levels along the first and third pivot axes and respectively engaged with a first gear train, a second cord drum and a fourth gear fixedly connected with each other and assembled about a fourth pivot axis, the second and fourth gears being respectively located at different levels along the second and fourth pivot axes and respectively engaged with a second gear train.

A spring drive system for a window shade includes a housing, a first and a second gear engaged with each other and respectively assembled about a first and a second pivot axis, two springs respectively assembled at two opposite sides of the second gear and respectively connected with two take-up reels provided on the first gear, a first cord drum and a third gear fixedly connected with each other and assembled about a third pivot axis, the first and third gears being respectively located at different levels along the first and third pivot axes and respectively engaged with a first gear train, a second cord drum and a fourth gear fixedly connected with each other and assembled about a fourth pivot axis, the second and fourth gears being respectively located at different levels along the second and fourth pivot axes and respectively engaged with a second gear train.

A reeling device for a window covering is disclosed, including a base having a perforation, an end cap, and a rotating member engaged to the base. The rotating member is rotatable around an axis, and has a body portion having a first end and a second end. An end of the lifting cord is engaged to the body portion near the first end, while another end passes through the perforation and winds around the second end. The end cap is engaged to the first end and is rotatable, which includes a tapered sleeve and a tubular body fitting around the body portion to cover a cord segment engaged to the body portion; the tapered sleeve is connected to the tubular body, and an outer diameter thereof decreases in a direction away from the first end. Such structure is helpful to control a lifting cord to smoothly operate a shade material.

An apparatus for installing a window covering is disclosed. In one embodiment, such an apparatus includes a stationary portion for attachment to an end of a headrail of a window covering, and a moveable portion to contact an inside of a window casing. A threaded member is provided that, when rotated, translates the moveable portion relative to the stationary portion. A manual actuator is provided to rotate the threaded member. In certain embodiments, the actuator is a thumb wheel configured to rotate the threaded member. In other embodiments, the actuator is a lever arm, such as a ratcheting lever arm, configured to rotate the threaded member. A corresponding method is also disclosed and claimed herein.

An apparatus for installing a window covering is disclosed. In one embodiment, such an apparatus includes a stationary portion for attachment to an end of a headrail of a window covering, and a moveable portion to contact an inside of a window casing. A threaded member is provided that, when rotated, translates the moveable portion relative to the stationary portion. A manual actuator is provided to rotate the threaded member. In certain embodiments, the actuator is a thumb wheel configured to rotate the threaded member. In other embodiments, the actuator is a lever arm, such as a ratcheting lever arm, configured to rotate the threaded member. A corresponding method is also disclosed and claimed herein.

A motorized window treatment may provide a low-cost solution for controlling the amount of daylight entering a space through a window. The window treatment may include a covering material (e.g., a cellular shade fabric or a roller shade fabric), a drive assembly for raising and lowering the covering material, and a motor drive unit including a motor configured to drive the drive assembly to raise and lower the covering material. The motorized window treatment may comprise one or more battery packs configured to receive batteries for powering the motor drive unit. The batteries may be located out of view of a user of the motorized window treatment (e.g., in a headrail or in a battery compartment). The motorized window treatment may use various power-saving methods to lengthen the lifetime of the batteries, e.g., to reduce the motor speed to conserve additional battery power and extend the lifetime of the batteries.

A motorized window treatment may provide a low-cost solution for controlling the amount of daylight entering a space through a window. The window treatment may include a covering material (e.g., a cellular shade fabric or a roller shade fabric), a drive assembly for raising and lowering the covering material, and a motor drive unit including a motor configured to drive the drive assembly to raise and lower the covering material. The motorized window treatment may comprise one or more battery packs configured to receive batteries for powering the motor drive unit. The batteries may be located out of view of a user of the motorized window treatment (e.g., in a headrail or in a battery compartment). The motorized window treatment may use various power-saving methods to lengthen the lifetime of the batteries, e.g., to reduce the motor speed to conserve additional battery power and extend the lifetime of the batteries.

A rail for a covering for an architectural opening is provided. The rail may be attachable to a shade member of the covering. The rail may include a magnet assembly that is at least partially positioned within a retention channel formed in the rail to releasably secure the rail to a head rail. The magnet assembly may be positionable along a longitudinal axis of the rail and may include a cam lock assembly that releasably secures the magnet assembly within the retention channel of the rail. According to the present disclosure, the head rail and the rail are held in close proximity to each other to inhibit the passage of light between the rail and a head rail.

A rail for a covering for an architectural opening is provided. The rail may be attachable to a shade member of the covering. The rail may include a magnet assembly that is at least partially positioned within a retention channel formed in the rail to releasably secure the rail to a head rail. The magnet assembly may be positionable along a longitudinal axis of the rail and may include a cam lock assembly that releasably secures the magnet assembly within the retention channel of the rail. According to the present disclosure, the head rail and the rail are held in close proximity to each other to inhibit the passage of light between the rail and a head rail.

In the screening arrangement a screening device provided with end pieces is adapted to be mounted on mounting brackets (6). Locking means are provided on the end pieces and the mounting brackets for providing engagement, between these. The locking means include mutually cooperating female and male locking means, of which the mounting brackets (6) are provided with two female locking means (12, 14) to cooperate successively with one male locking means of the respective end piece, so that it is possible to provide engagement between each end piece and the respective mounting bracket in at least two positions including a first, temporary position and a second, terminal position on the mounting bracket, when the end pieces are moved with the screening device in the third direction from the point distant from the pane to the point proximate to the pane.