A transportable folding door includes a folding door body and a door handle bar arranged on a side of the folding door body. A handle is arranged on the door handle bar. The folding door body is made of a flexible polyester material. The door handle bar is formed by splicing a plurality of supporting bars, and a connecting assembly is arranged between two adjacent supporting bars. Connecting holes are separately formed at a connection of the two adjacent connected supporting bars, and the connecting assembly is fixedly connected to the connecting holes of the two adjacent connected supporting bars. The connecting assembly includes a clamping bar with a U-shaped cross section, connecting columns, and a connecting piece. Both ends of the clamping bar are separately provided with receiving holes corresponding to the connecting holes on the two adjacent connected supporting bars.

A folding wall partition includes foldable panel assemblies. Each panel assembly includes an upper panel and a lower panel. The upper and lower panels extend substantially in a common vertical plane when in a deployed position, and extend laterally outwardly of the common vertical plane in a stacked relationship when in a stored position. A moving mechanism engages the panel assemblies to displace them between the stored and deployed positions. A cover assembly has cover panels. The cover panels extend in a first common horizontal plane when in the deployed position and are substantially coplanar with the ceiling to conceal a cavity. The cover panels extend in a second common horizontal plane higher than the first common horizontal plane and within the cavity when the cover panels are in the stored position.

A folding wall partition includes foldable panel assemblies. Each panel assembly includes an upper panel and a lower panel. The upper and lower panels extend substantially in a common vertical plane when in a deployed position, and extend laterally outwardly of the common vertical plane in a stacked relationship when in a stored position. A moving mechanism engages the panel assemblies to displace them between the stored and deployed positions. A cover assembly has cover panels. The cover panels extend in a first common horizontal plane when in the deployed position and are substantially coplanar with the ceiling to conceal a cavity. The cover panels extend in a second common horizontal plane higher than the first common horizontal plane and within the cavity when the cover panels are in the stored position.

An extendable arm structure includes: an upper extendable arm and a lower extendable arm which extend parallel in a same direction; and a vertical coupling member that couples the upper and lower extendable arms. Each of the extendable arms includes a plurality of X-shaped cross units each formed by pivotally coupling two rigid members via a middle coupling shaft, and two end coupling shafts that pivotally couple ends of adjacent ones of the cross units. The extendable arm structure further includes: a planar member that closes, in a planar fashion, a space between the rigid member of the upper extendable arm and the rigid member of the lower extendable arm which extends parallel to the rigid member of the upper extendable arm in a same direction.

A motor control system comprises a motor control circuit, a non-transitory storage medium and a processing circuitry. The storage medium is configured to store a current threshold profile that is indicative of a current requirement of the motor control circuit for an operational cycle of a motor. The processing circuitry is configured to adjust the stored current threshold profile based on a change to the operational cycle of the motor (e.g., from standard to non-standard).

Embodiments of motorized window coverings are described herein. Various embodiments may include a shade, a shade deployment assembly, one or more batteries, and wiring. The shade may include an upper end and a lower end opposite the upper end. The shade deployment assembly may be disposed at the upper end and may deploy the shade. The shade deployment assembly may comprise a rotatable element, a motor that rotates the rotatable element, and one or more mounting brackets. The mounting brackets may mount the shade deployment assembly to a surface. The shade may be directly connected to the shade deployment assembly, such as to the rotatable element. The battery may be removably connected to the shade at the lower end. The one or more batteries may power the motor. Wiring may be disposed in the shade. The wiring may electrically couple the motor to the one or more batteries.

In one aspect, a shade assembly may generally include a shade fabric having a front side and a back side. The shade assembly may also include two or more batten spacers, with each batten spacer being coupled to the shade fabric at spaced apart locations along a vertical length of the fabric. Moreover, the batten spacers may be substantially aligned with one another horizontally along the back side of the shade fabric. When the shade fabric is moved to an opened position, the batten spacers may be configured to vertically engage one another to form a vertical spacer stack along the back side of the shade fabric.

A motor control system comprises a motor control circuit, a non-transitory storage medium and a processing circuitry. The storage medium is configured to store a current threshold profile that is indicative of a current requirement of the motor control circuit for an operational cycle of a motor. The processing circuitry is configured to adjust the stored current threshold profile based on a change to the operational cycle of the motor (e.g., from standard to non-standard).

A collapsible wall including a support frame and a first series of panels configured to suspend from the support frame with at least one pair of adjacent panels pivotally connected to each other. A second series of panels are configured to suspend from the support frame opposite the first series of panels and include at least one pair of adjacent panels pivotally connected to each other. A bottom sill opposite the support frame is pivotally connected to a bottom portion of the first series of panels and to a bottom portion of the second series of panels. A motor assembly is mounted on the support frame and configured to raise or lower at least one lifting element to raise or lower the bottom sill to collapse or extend the panels in the first and second series of panels.

A collapsible wall including a support frame and a first series of panels configured to suspend from the support frame with at least one pair of adjacent panels pivotally connected to each other. A second series of panels are configured to suspend from the support frame opposite the first series of panels and include at least one pair of adjacent panels pivotally connected to each other. A bottom sill opposite the support frame is pivotally connected to a bottom portion of the first series of panels and to a bottom portion of the second series of panels. A motor assembly is mounted on the support frame and configured to raise or lower at least one lifting element to raise or lower the bottom sill to collapse or extend the panels in the first and second series of panels.