A panel assembly for a window shade includes a first and a second elongate strip adjacent to each other that are bonded to a support sheet. Each elongate strip has a first and a second edge opposite to each other, and a main strip portion between a first and a second margin, the first and second margin respectively adjoining the main strip portion along a first and a second folding line, the first margin extending between the first folding line and the first edge, the second margin extending between the second folding line and the second edge, the second margin including a third folding line substantially parallel to the second folding line. The first margin is bonded to the support sheet, and the second margin is bonded to the support sheet or the second elongate strip at a margin portion between the third folding line and the second edge.

Disclosed is a roller blind with a heat insulation function. The roller blind with a heat insulation function of the present disclosure includes a roller rotatably mounted in a frame, a heat insulation sheet configured to be wound and unwound on the roll, a plurality of tubular sheets attached to one surface of the heat insulation sheet and formed to have openings at both ends thereof, and a pair of rail members provided to extend in a direction in which the heat insulation sheet is unwound so as to block air from moving through the openings at both ends of the plurality of tubular sheets. According to the present disclosure, the roller blind with a heat insulation function is configured to effectively block heat in hot weather or cold in cold weather from being transferred to a room through a window.

A window covering is described. The window covering has a first tube and a second tube rotatably coupled to the first tube. The first tube and the second tube are disposed along parallel axes. A fabric is fastened at a first end to the first tube and at a second end to the second tube. A tensioning bar is slidably disposed along the fabric in between the first end and the second end. A bracket suspends the first tube and the second tube above the tensioning bar. The described window covering can be made to provide varying levels of privacy along an upper portion or lower portion of a window to be covered.

A vertical cellular drape configured for use as a covering for an architectural structure may include a front drape panel and a rear drape panel. The front and rear drape panels may be coupled to each other so that the drape panels are configured to be moved laterally between an extended position and a retracted position to cover or expose an adjacent architectural structure, as desired. In addition, the drape panels may be configured to be positioned relative to each other such that a plurality of vertically oriented, internal cells are defined between the drape panels.

The present disclosure relates to multi-layered fabrics and coverings for architectural features and methods for manufacturing the same. More particularly, the present disclosure relates to a three-dimensional multi-layered fabric having a first or front exterior layer, a plurality of intermediate or interior layers, and a second or back exterior layer, which are separable from one another, and their method of manufacture, and panels and/or coverings for architectural features having or comprised of a multi-layered fabric, and methods of making the same. The plurality of interior layers extends between the exterior layers, and the separation and stitching of the two paired intermediate layers from at least one of the front exterior layer and back exterior layer are at different locations (points), respectively, which facilitates the formation of a cell, and controls the size and shape of the cell that may form between the two paired, intermediate layers.

An architectural-structure covering and corresponding method of manufacturing, assembly, or the like is disclosed. The architectural-structure covering including a covering comprising a front layer, a rear layer, and an intermediate barrier layer, wherein the intermediate barrier layer is coupled to a rear side of the front layer and to a front side of the rear layer so that the intermediate barrier layer is positioned between the front and rear layers. The architectural-structure covering further comprising a plurality of lift elements arranged and configured to move the covering between extended and retracted positions. The lift elements being positioned being the intermediate and rear layers. In this manner, the lift elements may be sandwiched between the intermediate and rear layers thus rending the lift elements inaccessible, or at least greatly limiting accessibility, to an end user.

A winding structure includes two automatic winding mechanisms each including a side plate, a rotary member and an elastic member. The rotary member is provided with a receiving space, a through hole and a first fitting portion. The elastic member is mounted in the receiving space and is disposed at a one way helical state. The elastic member is provided with a clamping portion secured on the side plate and a second fitting portion secured on the first fitting portion of the rotary member. The side plate is provided with an extending portion extending through the through hole of the rotary member. The rotary member is rotated on the extending portion of the side plate and is returned to an original position automatically by the restoring force of the elastic member.

A covering for an architectural feature having generally horizontal vane elements coupled to and located between generally front and rear generally vertical support members, which in preferred embodiments are adjustable to control the amount of light transmitted through the covering. In one embodiment the covering has three dimensional multi-layered, cellular vanes, and in another embodiment, the one or more support members are formed of a dark color, the rear support member(s) may be formed of material that is darker than the front support member(s), or vise versa. In another embodiment, the support members, e.g., sheers, have an openness factor, preferably as low as about sixty-five percent (65%) to as large as about ninety percent (90%). Other embodiments include structure, assemblies and methods for controlling the closure of the covering as well as embodiments of bottom rail assemblies. Also provided is a method of manufacturing the covering.

In one aspect, a covering for an architectural structure may include a shade panel and a bottom rail assembly coupled to the shade panel. The bottom rail assembly may include a rail housing and a roller extending within the rail housing, with the shade panel being looped around the roller such that the bottom rail assembly is vertically supported by the shade panel as the panel is moved between extended and retracted positions. In addition, the relative positioning of the roller within the rail housing may be adjusted, as desired, between the top and bottom ends of the bottom rail housing.

A covering for an architectural feature having generally horizontal vane elements coupled to and located between generally front and rear generally vertical support members, which in preferred embodiments are adjustable to control the amount of light transmitted through the covering. In one embodiment the covering has three dimensional multi-layered, cellular vanes, and in another embodiment, the one or more support members are formed of a dark color, and the rear support member(s) may be formed of material that is darker than the front support member(s), or vise versa. In another embodiment, the support members, e.g., sheers, have an openness factor, preferably as low as about sixty-five percent (65%) to as large as about ninety percent (90%). Other embodiments include structure, assemblies and methods for controlling the closure of the covering as well as embodiments of bottom rail assemblies. Also provided is a method of manufacturing the covering.