The present invention relates to an actuation system for a fenestration product adjustable covering, including a one-way drive mechanism used to reduce damage to the system due to a potentially damaging event during extension of the covering.
Within the art of fenestration products, such as windows and doors, it is well known that double panes of glass in a window provide better insulation than a single pane of glass. The provision of venetian type blinds or pleated shades between two panes of glass in a fenestration product is also known in the art to provide desired window or door coverage. A pleated blind between window panes is disclosed in the U.S. Pat. No. 4,913,213 to Schnelker. A venetian or slat blind between panes of glass is disclosed in the U.S. Pat. Nos. 4,687,040; 4,664,169 and 5,379,825. In order to utilize such blinds or shades effectively with the increased insulation of the double glass product, control mechanisms for lifting, lowering and tilting the blind or shade from one side of the window must be provided while maintaining the window seal. The art has provided cords and cables, sometimes driven by a motor or gear system, as the control mechanism. The most popular systems route the cord through an aperture drilled through the interior pane of glass.
U.S. Pat. No. 4,687,040 to Ball discloses a device for adjusting the tilt angle of slats of a slat blind positioned between the panes of glass. The device includes a hole in one pane of glass and a flexible cable passing through the hole. The cable is connected to a rectangular member which controls the rotation of the slats. When the cable is turned by external torque, the slats are tilted.
U.S. Pat. No. 4,913,213 discloses a pleated blind between double window panes and blind control means for raising and lowering the blind. One embodiment is comprised of an aperture in one pane of glass and a bolt with a center hole mounted in the aperture. An actuator cord passes through the bolt hole and further up and over a screen, if desired, thereby providing an external control mechanism.
U.S. Pat. No. 5,379,825 discloses a window blind between double panes of glass. One embodiment uses a lift cord and a control cord routed through a hollow screw passing through one of the panes of glass to provide external control of the blind.
The prior art has also developed more complicated control mechanisms that utilize cables and gear systems that pass through the window frame rather that the glass. U.S. Pat. No. 4,664,169 to Osaka et al. discloses a device for tilting slats of a venetian blind between double panes of glass. The device uses electrical power driving means to move a piezoelectric bimorph device in a horizontal plane. The piezoelectric bimorph device is mounted to a block having a threaded bore. The piezoelectric bimorph device mechanically moves an elongated V-shaped beam under two cross arms which control the rotation of the slats. When the beam is moved, the cross arms are tilted, thereby rotating the slats.
The complicated systems that require control mechanisms to be mounted in or routed through the window frame are relatively expensive to manufacture. Furthermore, in many of these systems gears and motors wear and then slip or fail. Many of these control devices require a head rail which is too wide to fit between the panes of those windows whose panes are not more than ¾ inches apart. Hence, these systems have never achieved the popularity of through the glass systems.
The problems of the prior art systems discussed above are not present if the control mechanism is a cord or cords routed between the edge of the interior glass panel and the window frame. In U.S. Pat. No. 4,913,213, Schnelker describes a pleated blind between window panes. In one preferred embodiment, the actuator cord is routed over the glass housing and any screen housing provided. An L-shaped guide having a single vertical and horizontal channel cut therein is fitted over the top edge of the glass housing. An actuator cord passes through the channel. A major problem with this system is that one cannot maintain a seal between the window frame and the edge of the glass housing. Another problem is that most blinds have four control cords, two lift cords and two tilt cords. If all four cords are routed through a single channel they tend to bind and interfere with one another.
In U.S. Pat. Nos. 5,611,381, 6,006,813 and 6,070,638, Jelic describes a window having a blind between two panes of glass. A cord guide is provided at the top edge of the housing, with the cord guide including multiple slots for the lift and tilt cords. The cord guide maintains a seal between the window frame and the window panes and keeps the cords separated. However, in this window system, the blind is still controlled by multiple cords routed around the window panes, which still tend to present problems for the user.
Even when the cord routing has been improved, between the glass window covering product may still have problems, such as jamming, when the lift cords experience slack during operation. These problems may occur when the lift mechanism is used too briskly or quickly, or when the window covering encounters some type of obstruction. With the blind located between two glass panels, resolution of a jam in the lift cord is not an easy matter. Therefore, lift cord systems and blind actuation mechanisms that reduce the risk of slack and jamming are preferred.
The present invention provides a covering actuation system for an adjustable covering used with a fenestration product. The covering actuation system is configured to extend and contract the covering upon operation of a covering operator by a user to provide varying amounts of viewing coverage through the fenestration product. The covering actuation system includes a lift mechanism coupled to the operator such that operation of the operator by a user results in the extension and contraction of the covering by action of the lift mechanism. The lift mechanism also includes a drive system configured to temporarily decouple and later recouple the lift mechanism from the operator. The drive system is activated by a potentially damaging event during extension of the covering so as to reduce damage to the lift mechanism. The potentially damaging event may include slack in a lift cord during extension of the covering. The drive system is configured to retain rotational registration between multiple lift mechanisms of the covering actuation system upon recoupling of the lift mechanism to the operator.
With reference to the attached Figures, it is to be understood that like components are labeled with like numerals throughout the several Figures.
The panes of viewing material 41, 42, 43 are mounted within a sash 50 having a sash head 51, a sash sill 52 and sash jambs 53. The sash 50 is moveable to open the fenestration product 40 to allow for air flow into a building in which the fenestration product 40 is mounted. A handle 45 is commonly used to open and close the sash 50, when desired. Positioned between the exterior and interior panes of viewing material, 41 and 42, respectively, is a window covering 70 that may be adjusted by extending or contracting the covering 70 and/or by tilting components, such as slats 72, of the covering 70. Although the disclosed primarily between two sheets of viewing material, the present window covering 70 can also be used on the interior side of a fenestration product 40 adjacent a single pane of viewing material.
Although shown as a casement window, the fenestration product 40 may be any of a number of types products having windows, including but not limited to openable and non-openable windows, double-hung windows, windows within doors, sliding glass or patio doors, or other windows now known or later developed to be mounted in an architectural opening within a building. Although shown as a horizontal slat blind, it is to be understood that the window covering 70 may be any of a number of types of window coverings, including but not limited to horizontal blinds, vertical blinds, or other types of blinds, roman shades, pleated shades, honeycomb shades or other types of shades, any of which are capable of being extended and/or contracted to provide a desired amount of coverage for the window, and may be adjusted by tilting slats or other components of the covering. The window covering may be constructed from materials that are opaque, partially opaque, or translucent. For certain applications, the window covering may be constructed from a transparent material that is treated to block certain wavelengths of electromagnetic radiation, such as ultraviolet.
Referring now also to
Referring now also to
Along one panel jamb 63, (in this embodiment shown on the left side of the glass panel 60, however the other side may also be used), a sliding operator 80 is provided to control the extension/contraction and/or other adjustment of the window covering 70. The sliding operator 80 may be installed within the panel jamb 63 during formation of the glass panel 60 or, alternatively, the sliding operator 80 may be provided as an add-on accessory and attached to the panel jamb 63. In the latter situation, existing fenestration products 40 already installed in buildings may be retrofit with the present invention for added versatility for a consumer.
The sliding operator 80 includes a handle 87 that slidably moves along a slide channel 85 formed with a panel jamb 63. Although shown in one position that is generally perpendicular to the glass pane 42, the handle 87 may be repositioned generally parallel to the glass pane 42, if desired, or may be placed in any other suitable position or location for manipulation and control of the slide channel 85. The handle 87 is connected to a drive mechanism 86, such that generally linear movement of the handle 87 along the slide channel 85 results in movement of the drive mechanism 86. In one embodiment, the drive mechanism 86 includes a belt, such as a timing belt that may or may not include teeth. The belt 86 is shown mounted perpendicular to the glass pane 42, however other mounting configurations are also possible. Optionally, the drive mechanism 86 may be, but is not limited to, a chain, perforated tape, rope, cord, or other suitable driving component.
At an intersection of panel jamb 63 and the panel head 61, a pulley enclosure 81 is mounted. Referring now also to
Drive mechanism 86 is routed about a pair of pulleys 84, also mounted within pulley enclosure 81, which guide the drive mechanism 86 from the shaft pulley 83 toward the slide channel 85. In this embodiment, guiding of the drive mechanism 86 by the pulleys 84 results in about a 90 degree direction change for the driving mechanism 86. Adjacent to the panel sill 62, a third pulley 88 is positioned so that the drive mechanism 86 routes around it at an opposite end of the glass panel 60. In this embodiment, the drive mechanism 86 is configured as a continuous loop, however other configurations are also possible and within the scope of the present invention.
Referring to
Adjacent panel head 161, a pulley enclosure 181 is mounted such that the drive mechanism 186 is routed around a shaft pulley 183 and a pair of pulleys 184. The shaft pulley 183 is mounted on a shaft 182 that passes through the glass pane 142. In this embodiment, with the sliding operator 180 mounted on the glass pane 142, the sliding operator 180 may be substantially aligned with the shaft 182, thereby removing the need for a 90 degree direction change of the driving mechanism 186, as was described above with respect to driving mechanism 86.
Adjacent panel sill 162, a second pulley enclosure 190 is mounted to the glass pane 142. Within this second pulley enclosure 190, a second pair of pulleys 192 and a third pulley 191 are positioned to route the drive mechanism 186 in an aligned manner with respect to the first pulley enclosure 181 and the shaft 182. In one embodiment, the drive mechanism 186 forms a continuous loop by attachment at the handle 187, such that movement of the handle 187 generally parallel to the member 163 results in smooth, direct movement of the drive mechanism 186 and rotation of the shaft 182.
Although the sliding operator 180 will partially obstruct the view through the glass pane 142 to some extent, in contrast to the offset sliding operator 80 located on a panel jamb 63, the on-glass sliding operator 180 has other advantages. In particular, although the sliding operator 180 mounted to the glass pane 142 may be used with any type of fenestration product, it is especially useful with sliding glass doors, double-hung type windows or other sliding-type fenestration products. The on-glass mounting of the sliding operator 180 provides a lower profile for the fenestration product, and thus accommodates the passing of one component of a fenestration product relative to a closely adjacent component of that fenestration product.
Referring to
A pulley enclosure 281 attached to the other end of the slide channel 285 is mountable adjacent a panel head (not shown) at an opposite end from the lower pulley 290. The timing belt 286 is routed around a corresponding timing belt sprocket 283 and a pair of pulleys 284 mounted within a pulley housing 296 that is enclosed by cover 294. The sprocket 283 is mountable to a shaft (not shown), such as previously described shaft portion 82 that passes through the glass pane 42. In this embodiment, the sprocket 283 is mounted on bearings 295 within a shaft housing 297 to facilitate routing and function of the timing belt 286, which is also aided by roller 299 attached by pin 298 to the shaft housing 297.
Referring now to
In this embodiment, the plurality of slats 91 may be contracted by retraction of a plurality of lift cords 92, as will be described in more detail below. The plurality of slats 91 may also be rotated or tilted from a generally horizontal position (as shown) to an angled orientation that is somewhat less than vertical, in either direction, by movement of a plurality of ladder cords 93, which will also be described in more detail below. Extension/contraction and angular adjustment or tilting of the blind slats 91 allows an operator to provide desired light passage through and coverage of the glass pane 42 of the fenestration product 40.
Referring now also to
As shown in
In this embodiment, the components 203 of the actuation system 200 include two driving shafts, a rotating lift shaft 210 and a rotating tilt shaft 212. For embodiments using a only a non-tilting window covering, such as a shade, the tilt shaft 212 may be eliminated or provided, but not utilized. The components 203 also include a gear box 220 mounted to the head channel 204 and coupled to at least the lift shafts 210 at a first end 214. The actuation system 200 connects to shaft 82 at gear box 220, the shaft 82 passing through the glass pane 42. The shaft 82, in turn, is coupled to and driven by sliding operator 80, such that linear motion of sliding operator 80 results in rotational motion of shaft 82 and corresponding operation of the actuation system 200 by rotational motion of lift shaft 210.
Referring now to
The combination of the bevel gears 224, 225 and sliding operator 80 preferably includes an amount of gear reduction, such that a full range of motion of the window covering 90 is achieved by relatively less motion of the sliding operator 80. In one embodiment, this ratio of handle travel to covering travel is about 70 percent. The gear ratio of the gears 224, 225 contributes in part to this travel ratio. However, also contributing to this travel ratio is the relationship of the sliding operator 80 structure to the covering actuation structure, as described below.
Referring to
Referring again to
A protective shroud 243 is preferably positioned over the lift spool 241 to protect the spool 241 and lift cord 92 during operation, such as from dirt/dust contamination. In addition, the shroud 243 keeps the lift cord 92 on the spool 241 in the desired location, thereby minimizing unwanted unwinding and tangling of the lift cord 92. As the spool 241 rotates, it shifts back and forth along the lift shaft 210 with respect to the location of the lift cord 92. As a result, the lift spool 241 retracts into and emerges out of the shroud 243 as the lift cord 92 winds up or unwinds. The protective shroud 243 is optionally positioned over only a portion of the lift spool 241. For example, the protective shroud 243 can be a discontinuous configuration, such as a plurality of elongated members or a perforated structure.
The actuation system 200 further includes a plurality of tilt drum assemblies 250, preferably in a number equal to the number of ladder cords 93. Each tilt drum assembly 250 includes a tilt drum 252 supported by a tilt drum support cradle 251 mounted to the head channel 204. The tilt shaft 212 passes through each tilt drum 252 with the tilt drum 252 coupled to the tilt shaft 212 such that rotation of the tilt shaft 212 results in corresponding rotation of the tilt drum 252. Each tilt drum assembly 250 is positioned adjacent to a lift spool assembly 240 to facilitate routing of the adjacent lift cords 92 and ladder cords 93 from the blind 90, as will be described in more detail below.
Referring now to
In order to accommodate the routing requirements of the lift cord 92, including its passage through aperture 209, the lift cord 92 is preferably formed from monofilament material, including but not limited to fluorocarbon, nylon, and polyester. The monofilament produces less friction than conventional cordage materials used for window coverings, thus resulting in less binding and snagging of the lift cord 92 during operation of the window covering 90. In addition, use of monofilament material results in less wear and thus longer life for the lift cords 92, thereby increasing the overall life of the window covering 90 itself As the lift shaft 210 rotates, the lift spool 241 also rotates causing the lift cord 92 to wind up or unwind about the spool 241, depending on the direction of rotation. With the lift cord 92 attached to a lower most slat or bottom rail 97 of the blind 90, movement of the lift cord 92 results in retraction or extension, respectively, of the blind 90. In order to control the rotation of the lift shaft 210 in both directions, a clutch/brake mechanism 270 is coupled to the lift shaft 210 at a second end 215. In this embodiment, the clutch/brake mechanism 270 is supported by a mechanism support 271 mounted to the head channel 204 at shelf 207. In one embodiment, the clutch/brake mechanism 270 is a spring clutch, however, other types or configurations of clutch and brake mechanisms may also be used.
Referring now also to
Clutch/brake mechanism 270 also includes the support housing 271 that is mountable to the head channel 204. Configured to mount within the support housing 271 are a clutch drum 276, coupled to a brake drum 278. The brake drum 278 also couples with a brake spring 279 that is, in turn, keyed to the support housing 271. The clutch drum 276 also couples to a clutch spring 277 that is in frictional contact with the brake drum 278 and the clutch drum 276. When the window covering 90 is being lowered or trying to lower itself under its own weight, the clutch spring 277 cinches down on the brake drum 278, resulting in the rotation of the brake drum 278 and subsequent cinching of the brake spring 279. The brake spring 279 applies enough resistance to prevent the window covering 90 from dropping under its own weight, but does not inhibit deliberate lowering of the window covering 90 by a user using the slide operator 80. When the window covering 90 is being raised or operated in the other direction, the clutch spring 277 spreads open, disengaging the brake drum 278 from the clutch drum 276. Alternatively, the engagement between the lift shaft 210 and tilt shaft 212 may occur at the gear box, as will be described in more detail below with respect to
As described above, each tilt drum assembly 250 is preferably positioned adjacent a lift spool assembly 240 to facilitate routing of the lift and ladder cords 92, 93, as stated above. Referring now also to
When the tilt drum 252 is rotated by rotation of the tilt shaft 212, one side cord 94 will lift upward and the other cord 94 will move downward. As a result, the cross cord 95 will tilt, causing the slat 91 supported by the cross cord 95 to tilt, as well. Depending on the direction of rotation of the shaft 212 and drum 252, the slat 91 will tilt in either direction.
As was described above, in the present invention, rotation of the tilt shaft 212 results from rotation of the lift shaft 210 due to coupling of the shafts 210, 212 together, such as by gears located at the clutch/brake mechanism or at the gear box. In the embodiment shown in
Referring to
The present invention provides a fenestration product having a window covering that is operated and adjusted by a sliding operator on the interior side of the product. No interior cords are provided or required to operate or adjust the window covering. The window covering of the present invention is particularly well suited for between-the-glass applications, but can also be used on the interior of a fenestration product. The present invention thus simplifies the window covering's operation and eliminates unsightly and potentially hazardous cords. By operation of the single sliding operator, both expansion/contraction and tilt adjustment of the window covering may be achieved.
With many types of window coverings usable with a fenestration product, lift or contraction of the covering is achieved by using lift cords, such as lift cords 92 described above. In the situation where control cords are provided, the control cords are commonly usable to adjust both the position and level of the bottom rail, such as bottom rail 97 shown in
Referring now to
Cord adjuster 304 is mounted within bottom rail channel 301 adjacent to and engaged with a locking mechanism 306. Locking mechanism 306 is configured to allow the cord adjuster 304 to move in one direction and to prevent movement in the other direction. Alternatively, the locking mechanism 306 may be configured for releasable engagement of the cord adjuster 304, so that movement of the cord adjuster 304 may occur in more than one direction upon release of the locking mechanism 306. In one embodiment, the locking mechanism 306 is a locking tab (not shown), either fixed or releasable, that engages the notches or teeth 305 of the cord adjuster 304. This locking mechanism 306 may be formed from plastic, nylon, metal or other light, but suitable materials. Alternatively, the locking mechanism 306 may be configured for use with a cord adjuster 304 without notches or teeth 305, and may be either fixed or releasable. This mechanism 306 may be formed from plastic, metal or other suitable materials.
In the embodiment shown in
In operation, once the window covering is mounted in place, the lift cords 302 may be adjusted by movement of the cord adjusters 304, so as the shorten or lengthen the lift cords 302. Adjustment of the lift cords 302 results in leveling adjustment of the bottom rail 300, as desired.
As shown in
Referring now to
When the screen assembly 400 is positioned against the glass panel 60, the coupler 420 engages slide operator handle 87. As best shown in
In one embodiment, as shown in
In one embodiment, shown best in
The present invention provides numerous advantages over other window covering systems. The present invention includes a number of subsystems, such as the sliding operator, the window covering and the window covering actuation system coupled together by a shaft passing through the glass panel for between-the-glass applications. These subsystems may be decoupled for ease of maintenance, repair, removal, cleaning, etc. The glass panel may be removed from the window sash and frame, with the sliding operator, the window covering actuation system and the window covering being removed along with the panel. Any of these subsystems may thus be dealt with as needed.
In addition, decoupling of the sliding operator from the window covering actuation system at the shaft allows for adjustment/readjustment of the sliding handle position relative to the overall window/fenestration product. In operation, a user may tip the window covering to disengage the shaft from the sliding operator, move the handle to a desired position, and then re-engage the shaft and sliding operator. With the gear reduction built into the sliding operator and window covering actuation system interface, the sliding handle may be repositioned along the length of the sliding channel to accommodate the user's needs. For example, in tall windows, the sliding operator handle may be positioned at the lower end of the channel because the upper end is out of reach of the average user. Alternatively, in doors, the sliding operator handle maybe positioned at the upper range of the channel because it is harder to stoop down low near the floor. For standard windows, on the other hand, it may be desirable to have the handle positioned in the middle of the available range of channel length. With the insect screen sliding operator of the present invention, the range of motion and position of the screen sliding handle may also be readjusted to match the range and position of the sliding operator on the fenestration product.
Fenestration products with adjustable coverings, also known as window coverings, for example those shown and described above, are commonly subjected to various forces that may cause problems with the lift and tilt mechanism. Such forces may result in the window covering becoming jammed or stuck during upward or downward travel. In particular, the lift cord may slacken when the window covering encounters an obstacle or the actuation system is actuated too quickly. Slack in the lift cord may cause it to become disengaged with the winding mechanism and tangle or snarl. Attempts to rectify the situation may additionally cause damage to the lift cords, or other actuation system components. For window coverings mounted between glass window panels, jamming of the window covering and component damage cause further problems because the window covering is not readily accessible by the user for readjustment and/or repair.
Referring now to
In this embodiment, however, the lift spool 241 is replaced by a lift spool drive system 500, including a modified lift spool 501. The modified lift spool 501 includes an exterior thread or groove 502 similar to the spiral groove 244. In addition, the modified lift spool 501 includes a hollow bore 503 extending throughout a length 506 the spool 501. A plug 510 is configured to be inserted into a first end 504 of the modified spool 501. The plug 510 has an interior center bore hole 511 extending through it, sized to allow for free rotation of the lift shaft 210 as it passes through the plug 510. In addition, it includes an axially extending notch 512 configured to allow passage of the lift cord 92 while capturing a knot (not shown) at the end of the lift cord 92. This notch 512 also provides a keying function for the plug 510 relative to the spool 501 to ensure angular alignment of the plug 510. In one embodiment, the plug 510 is formed from a polymer, such as an equivalent material to that used for the modified lift spool 501; however, other suitable materials may also be used, as would be known by one skilled in the art.
At a second end 505, the modified spool 501 includes an edge notch 507 configured to mate with a spool stop 516 on a nut 515. The spool stop 516 extends radially from the nut surface, as well as axially from a leading edge 519 of the nut 515. A slightly undercut flat region 518 is formed adjacent the spool stop 516. The nut 515 is received within and adhered to the bore 503, such that it is generally flush with the second end 505, except for the spool stop 516. An interior threaded bore 517 extends through the nut 515, with the interior threads configured to mesh with exterior threads 521 on a drive rod 520. The nut 515 and drive rod 520 are preferably formed from brass or other suitable materials, including but not limited to plastic or zinc die cast construction.
The rod threads 521 extend along a majority of a rod length 522, except for an end region 523. In one embodiment, this end region 523 is preferably knurled, however, a smooth end region 523 may alternatively be provided. The drive rod 520 has an interior bore 524 extending the length 522 of the rod 520. At least a portion of the bore 524 is configured to mate with the lift shaft 210, so that rotation of the lift shaft 210 results in rotation of the rod 520 in either direction. In this embodiment, the bore 524 is generally square in cross-section to accommodate the generally square lift shaft 210, at least in the area of the end region 523.
A stop collar 525 is fitted about the end region 523 of the drive rod 520 by insertion of the end region 523 into an interior through-bore 526 of the stop collar 525. The stop collar 525 is prevented from rotating due to attachment to the rod 520, such as by a press-fit between the collar 525 and end region 523, adhesive or by other suitable methods. A knurled end region 523 aids in securing the stop collar 525 to the rod 520. The stop collar 525 includes a drive stop 527 that extends radially from the outer collar surface, as well as axially from a back edge 529 of the collar 525. A slightly undercut flat region 528 is formed adjacent the drive stop 527. The stop collar 525 is also preferably formed from brass, or from another suitable material.
The drive rod 520 threads into and out of the modified spool 501 upon rotation of the lift shaft 210. In this embodiment, inward movement is caused by clockwise rotation and outward movement is caused by counter-clockwise rotation; however, reversed threads are also possible. Near the clockwise/inward rotational limit of the drive rod 520 into the spool 501, the drive stop 527 of the stop collar 525 encounters the spool stop 516 as the spool stop 516 passes over the flat region 528 on stop collar 525. Rotation of the drive rod 520 relative to the spool 501 then ends, and continuing rotation of the lift shaft 210 in the clockwise direction results in generally simultaneous rotation of both the drive rod 520 and the spool 501.
A reversal in the direction of rotation of the lift shaft 210, that is a change to a counter-clockwise direction in this embodiment, causes a disengagement of the spool stop 516 and drive stop 527. As a result, the lift shaft 210 and drive rod 520 freely rotate with respect to the spool 501, such that the spool 502 is not driven by the lift shaft 210 in a counter-clockwise direction. Another change in rotational direction and movement of the drive rod 520 back to its limit, such that the drive stop 527 and spool stop 516 engage, are required before the lift shaft 210 again drives the spool's rotation.
In operation, the drive rod 520 is preferably at its inward most position with respect to the modified spool 501, such that the drive stop 527 and spool stop 516 are engaged. As the window covering 90 is lifted or opened, the lift shaft 210 rotates clockwise, also rotating the drive rod 520 and modified lift spool 501 causing the lift cord 92 to be wound up about the thread or groove 502 under the shroud 243. As the window covering 90 is lowered or closed, the lift shaft 210 rotates counter-clockwise, releasing the clutch/brake 270 and allowing the window covering 90 to drop under its own weight. As a result, the lift cord 92 unwinds from the modified lift spool 501 causing it to rotate counter-clockwise in conjunction with the rotation of the lift shaft 210. Therefore, the drive rod 520 rotates along with the spool 501 and the drive stop 527 and spool stop 516 remain engaged.
During lowering of the window covering 90, the window covering 90 may encounter an obstruction, such as a loose muntin bar or other object, or the window covering 90 may be operated too quickly, such that slack is formed in the lift cords 92. In other embodiments of the window covering actuation system 200, the continuing movement of the operator causes the lift shaft 210 to continue rotating and the lift spool 241 to also continue rotating. As a result, the lift cords 92 wound around the lift spools 241 get snarled, tangled, jammed and/or otherwise messed up, which may cause permanent damage to the cords or the system. In this embodiment, however, once slack is encountered in the lift cords 92, the modified lift spool 501 stops rotating, but the lift shaft 210 continues to rotate along with the drive rod 520. The drive rod 520 unscrews from the modified lift spool 501 as long as the lift shaft 210 continues to rotate in that direction due to continued operation of the window covering operator. The drive rod 520, as shown in this embodiment, is configured with fine enough threads so that, should a problem be encountered at the top most position of the window covering 90, there are sufficient threads to allow for complete operation of the window covering operator to its lowermost limit on smaller fenestration products or up to five feet (1.52 meters) of travel on larger units. More threads may be provided for larger fenestration products, as desired.
Once the obstruction is cleared or the problem is otherwise resolved, operation of the window covering 90 may proceed. As stated above, reversal of direction of the operator results in reversed rotation of the lift shaft 210, along with the drive rod 520. The modified spool 501 does not start rotating until the drive rod 520 reaches its inward limit and the drive stop 527 engages the spool stop 516. As a result, the angular orientation of the modified spool 501 remains in sync with the other lift spools 501 within the overall actuation system 200, and thus rotation registration between the separate lift spool assemblies 240 is maintained. Therefore, misalignment of the window covering 90 is avoided.
In this embodiment, one way drive of the modified spool 501 is provided by the nut 515 and spool stop 516 working in conjunction with stop collar 525 and drive stop 527. However, it is to be understood that other mechanisms for limiting rotational movement of the drive rod 520 in one direction may also be provided. One alternative embodiment includes configuration of the mechanism with left hand threads for rotation in an opposite direction from the mechanism set forth above. Other embodiments of the mechanism include, but are not limited to, construction of the spool 501, nut 515 and spool stop 516 as one integral unit or single part, and/or the construction of the drive rod 520, stop collar 525 and drive stop 527 as one integral unit or single part. These types of parts may be molded and/or machined. Variations of this same concept are also possible. In addition, other embodiments, in which the spool 501 and drive rod 520 interconnect for coordinated rotation in one direction, yet are separate for independent rotation in an opposite direction, are within the skill of those in the art and are covered by this invention.
The lift spool drive assembly of the present invention provides the benefit of resolving a problem frequently encountered with window covering operation, while fitting within the confines of the current actuation system. In particular, in actuation systems provided for between-the-glass window coverings, the available envelope of space for the components of the actuation system is very limited. Therefore, the provision of a mechanism for resolving this problem is most useful and efficient if it is confined to the provided space and does not extend beyond the existing actuation components. In addition, when used with between-the-glass window coverings having the sliding operator, as described above, the tilt function of the window covering may be operated without raising or lowering the covering at its lower limit of travel. When the window covering reaches its lower limit, continuing movement of the sliding operator results in disengagement of the drive screws from the lift spools and permits the operator handle to travel in either direction without raising or lowering the shade.
Although generally described with respect to between-the-glass window covering products, use of the present invention is not limited to between-the-glass window coverings units, but may used and benefit other type of window covering configurations. For example, the overall height tolerance of a window covering is much greater when the present invention drive system is used, since there is no negative consequence to continued operator handle movement after the window covering reaches the lower limit of the glass. This improves the manufacturability of the window covering and/or fenestration product because the window covering length becomes less critical and could be made a little longer than conventionally would be provided to account for variables in the manufacturing process, such as the uncertain effective spring constant of pleated shade material, for example.
All of the patents and patent applications disclosed herein, including those set forth in the Background of the Invention, are hereby incorporated by reference. Although the present invention has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention. In addition, the invention is not to be taken as limited to all of the details thereof as modifications and variations thereof may be made without departing from the spirit or scope of the invention. Thus, the scope of the present invention should not be limited to the structures described in this application, but only by the structures described by the language of the claims and the equivalents of those structures.
This application is a divisional application of co-pending U.S. patent application Ser. No. 10/437,773, filed on May 14, 2003 and entitled ONE-WAY DRIVE FOR WINDOW COVERINGS, which was a continuation-in-part of U.S. Pat. No. 6,736,185, filed on Jul. 22, 2002 and entitled SLIDING OPERATOR FOR BETWEEN THE GLASS WINDOW COVERINGS, both of which are herein incorporated by reference.
Number | Date | Country | |
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Parent | 10437773 | May 2003 | US |
Child | 11214493 | Aug 2005 | US |
Number | Date | Country | |
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Parent | 10200579 | Jul 2002 | US |
Child | 10437773 | May 2003 | US |