Motorized window treatments typically include a flexible fabric or other means for covering a window in order to block or limit the daylight entering a space and to provide privacy. The motorized window treatments may include roller shades, cellular shades, Roman shades, Venetian blinds, and draperies. The motorized window treatments include a motor drive for movement of the fabric in front of the window to control the amount of the window that is covered by the fabric. For example, a motorized roller shade includes a flexible shade fabric wound onto an elongated roller tube with an electronic drive unit installed in the roller tube. The electronic drive unit includes a motor, such as a direct-current (DC) motor, which is operable to rotate the roller tube upon being energized by a DC voltage.
A motorized window treatment may include a headrail, a covering material, a bottom bar, a motor drive unit, a drive shaft, a lift cord, and/or a lift cord spool assembly. The headrail may be elongate along a first direction. The headrail may be configured to be mounted to a structure. The headrail may define an internal cavity. The covering material may include a top end and a bottom end that is spaced from the top end along a second direction that is perpendicular to the first direction. The top end of the covering material may be attached to the headrail. The bottom bar may be attached to the bottom end of the covering material. The motor drive unit may be received within the internal cavity. The drive shaft may be coupled to the motor drive unit, for example, such that the motor drive unit is configured to rotate the drive shaft about a rotational axis. The lift cord may have a first end that is operatively attached to the drive shaft. The lift cord spool assembly may be coupled to the motor drive unit.
A lift cord spool assembly may be used in a motorized window treatment. The lift cord spool assembly may include a spool, a housing, and an end cap. The spool may be configured to windingly receive a lift cord of the motorized window treatment. The spool may be configured to rotate about a rotational axis. The spool may define a bore that extends therethrough along the rotational axis. The bore may be configured to receive a drive shaft of the motorized window treatment. The spool may define a protrusion that extends from a first end of the spool along the rotational axis. The spool may be cylindrical. A diameter of the spool may taper by approximately 0.5 degrees from the first end to an opposed second end. The housing may be configured to surround the spool.
The end cap may be configured to attach to the housing, for example, such that the spool is retained within the housing. The end cap may include an inner surface, a shoulder, an aperture, and a guide. The shoulder may be cylindrical. The shoulder may extend from the inner surface. The shoulder may be configured to abut the housing when the end cap is attached to the housing such that the lift cord is retained within the housing. The shoulder may comprise the aperture. The aperture may be configured to receive the lift cord.
The guide may be configured to push the lift cord onto the spool as the lift cord is wound onto the spool. The guide may extend from the inner surface and abuts the shoulder. The guide may define a gradual slope around a circumference of the shoulder, for example, such that the guide extends a first distance from the inner surface at a first location and a second distance from the inner surface at a second location. The second distance may be greater than the first distance. The first location may be defined proximate to a side of the aperture where the lift cord is wound onto the spool. The second location may be at least 270 degrees counter-clockwise from the first location along the circumference of the shoulder. The end cap may define an inner surface. The inner surface may include a hole therethrough, for example, at the rotational axis. The inner surface may be configured to abut the first end of the spool. The guide and the shoulder may intersect at a radiused edge.
The motorized window treatment 100 may include a motor drive unit 120 for raising and lowering the weighting element 116 and the cellular shade fabric 112 between the fully-open position PFULLY-OPEN and the fully-closed position PFULLY-CLOSED. By controlling the amount of the window covered by the cellular shade fabric 112, the motorized window treatment 100 may control the amount of daylight entering the room. The headrail 114 of the motorized window treatment 100 may include an internal side 122 and an opposite external side 124, which faces the window that the shade fabric 112 is covering. The motor drive unit 120 may include an actuator 126, which may be positioned adjacent the internal side 122 of the headrail 114 may be actuated when a user is configuring the motorized window treatment 100. The actuator 126 may be made of, for example, a clear material, such that the actuator 126 may operate as a light pipe to conduct illumination from inside the motor drive unit 120 to thus provide feedback to the user of the motorized window treatment 100. As shown in
The motorized window treatment 100 may include a plurality of batteries 138 (e.g., four D-cell batteries as shown in
The spool 220 may be configured to windingly receive the lift cord 210 (e.g., as the motorized window treatment is operated between a lowered position and a raised position). For example, the spool 220 may be configured to rotate about a rotational axis of the motorized window treatment. Rotation of the spool 220 may cause the lift cord 210 to be wound around and/or unwound from the spool 220. For example, the lift cord 210 may wind around the spool 220 as the motorized window treatment is raised (e.g., operated between a closed position and an open position). The lift cord 210 may unwind from the spool 220 as the motorized window treatment is lowered (e.g., operated between the open position and the closed position).
The spool 220 may define a bore 222 therethrough. The bore 222 may be located along the rotational axis of the motorized window treatment. The bore 222 may be configured to receive a drive shaft of the motorized window treatment. The spool 220 may define a cylindrical outer surface 224 that is configured to windingly receive the lift cord 210. The spool 220 may be configured to secure an end 212 (e.g., as shown in
The spool 220 may define a first end 226 and an opposed second end 228. The spool 220 may be tapered from the first end 226 to the second end 228. Stated differently, a diameter of the spool 220 may taper (e.g., by approximately 0.5 degrees) from the first end 226 to the second end 228. For example, the spool 220 may have a first diameter D1 at the first end 226 and a second diameter D2 at the second end 228. The spool 220 may gradually and/or evenly taper from the first diameter D1 at the first end 226 to the second diameter D2 at the second end 228. The taper of the spool 220 may be configured to guide the lift cord 210 across the outer surface 224 from the first end 226 toward the second end 228. The spool 220 may define a protrusion 221 that extends along the rotational axis beyond the first end 226. The protrusion 221 may be cylindrical. The protrusion 221 may be configured to be received by the end cap 240. In addition, the diameter of the spool 220 may taper by a different amount (e.g., by approximately 0.75 degrees). Further, the spool 220 may have sections (not shown) that are tapered by different amounts.
The housing 230 may be configured to surround the spool 220 (e.g., the outer surface 224). For example, the housing 230 may enclose the spool 220 therein. The housing may define a flange 232. The flange 232 may be configured to attach to the end cap 240. For example, the flange 232 may attach to complimentary features of the end cap 240. The housing 230 (e.g., the flange 232) may define a seat 234.
The end cap 240 may be configured to attach to the housing 230 such that the spool 220 is retained within the housing 230. The end cap 240 may include an inner surface 242, a shoulder 244, an aperture 250, and a guide 260. The inner surface 242 may be proximate to the spool 220 when the end cap 240 is attached to the housing 230. The inner surface 242 may define a hole 246 therethrough. The hole 246 may be configured to receive the protrusion 221 of the spool 220. The hole 246 may be configured to receive the drive shaft of the motorized window treatment. The shoulder 244 may be cylindrical. The shoulder 244 may extend from the inner surface 242. The shoulder 244 may be configured to abut the housing 230 when the end cap 240 is attached to the housing 230. The shoulder 244 may be received by the seat 234 of the housing 230 when the end cap 240 is attached to the housing 230.
The aperture 250 may be configured to receive the lift cord 210, for example, as the lift cord 210 is wound and/or unwound from the spool 220. The aperture 250 may extend from the shoulder 244 of the end cap 240. The aperture 250 may be sloped to reduce friction on the lift cord 210 as the lift cord 210 is wound and/or unwound from the spool 220.
The guide 260 may be configured to direct (e.g., kick) the lift cord 210 onto the spool 220. The guide 260 may extend from the inner surface 242. The guide 260 may be proximate to the shoulder 244. For example, the guide 260 may abut the shoulder 244. The guide 260 may define a gradual slope around a circumference of the shoulder 244 such that the guide 260 extends a first distance from the inner surface 242 at a first location and a second distance from the inner surface 242 at a second location. The second distance may be greater than the first distance.
The aperture 310 may be configured to receive a lift cord (e.g., the lift cord 210) of the motorized window treatment, for example, as the lift cord is wound onto and/or unwound from the spool. The aperture 310 may extend from the shoulder 304 of the end cap 300. The aperture 310 may be sloped to reduce friction on the lift cord as the lift cord is wound and/or unwound from the spool. The aperture 310 may be configured such that a metallic part (e.g., a metal eyelet) is not needed. The aperture 310 may define cord inlet portion 312 and an opposed portion 314. The inlet portion 312 may be configured to receive the lift cord. The inlet portion 312 and/or the opposed portion 314 may define a radiused connection between the aperture 310 and the shoulder 304.
The guide 320 may be configured to direct (e.g., kick) the lift cord onto the spool, for example, as the lift cord is wound onto the spool. Stated differently, the guide 320 may be configured to push the lift cord away from the end of the spool as the lift cord is wound onto the spool. At least a chord length of the guide 320 (e.g., measured from the aperture 310) may be configured to kick the lift cord onto the spool. For example, one and a half chord lengths of the guide 320 may be configured to kick the lift cord onto the spool. Stated differently, the lift cord may not abut the guide 320 past a chord length of the guide 320.
The guide 320 may extend from the inner surface 302. For example, the guide 320 may extend from the inner surface 302 proximate to the shoulder 304. For example, the guide 320 may abut the shoulder 304. The guide 320 may have varying thickness around the circumference of the guide 320. The guide 320 may define a gradual slope around a circumference of the guide 320. For example, the guide 320 may extend a first length L1 from the inner surface 302 at a first location and the guide 320 may extend a second length L2 from the inner surface 302 at a second location. The second length L2 may be greater than the first length L1. The guide 320 may increase (e.g., at a constant rate) in thickness from the first location to the second location. The first location may be defined proximate to a side (e.g., the inlet portion 312) of the aperture 310 where the lift cord is wound onto the spool. The second location may be at least 180 degrees (e.g., at least 270 degrees) counter-clockwise from the first location along the circumference of the shoulder 304.
The guide 320 may decrease (e.g., gradually) in thickness from the second location to a third location that is proximate to the opposed portion 314 of the aperture 310. For example, the guide may extend a third length L3 from the inner surface 302 at the third location. The third length L3 may be less than the second length L2. The gradual decrease in thickness of the guide 320 from the second location to the third location may be configured to prevent the lift cord from catching as the lift cord is unwound from the spool.
The guide 320 and shoulder 304 may intersect at a radiused edge 308 along the outer perimeter of the guide 320. The radiused edge 308 may reduce friction on the lift cord as the lift cord is wound and/or unwound from the spool.
Although the figures show an example geometry of the guide 260, 320, it should be appreciated that the guide 260, 320 is not limited to this example geometry. Stated differently, the guide 260, 320 may have alternative geometry to that shown in the figures and still push the lift cord away from the end of the spool without compressing the lift cord.
It should further be appreciated that configuring the lift cord spool assembly 200 such that the end cap 240, 300 is configured to push the lift cord 210 onto the spool 220 without compressing the lift cord 210 may provide one or more advantages. For example, so configuring the lift cord spool assembly may reduce manufacturing complexity, increase design flexibility, and/or increase reliability of a motorized window treatment.
This application is a continuation of U.S. patent application Ser. No. 16/870,279, filed May 8, 2020, which claims the benefit of U.S. Provisional Patent Application No. 62/844,979, filed May 8, 2019, the entire disclosures of which are hereby incorporated by reference.
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Number | Date | Country | |
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Parent | 16870279 | May 2020 | US |
Child | 17929436 | US |