The following invention relates to lifting mechanisms for window coverings of various varieties. More particularly, this invention relates to lifting mechanisms for window coverings which automatically provide sufficient lifting force so that a bottom rail of the window covering will remain in a position where it is placed by a user until the bottom rail is again moved by a user to a new position, without requiring engaging or releasing of locking mechanisms through buttons, cords or other manually actuated locking mechanisms.
Window coverings are provided in a wide variety of styles and configurations to both provide the function of at least partially occluding the passage of light through a window and enhancing an appearance of a room in which the window is located. Such window coverings can include shades which are typically continuous from a top rail at an upper end of the window to a bottom rail at a bottom end of the shade. Such shades can be in the form of a single layer of material or multiple layers of material and can be pleated or smooth, and can optionally include cellular “hive-like” cavities within the window covering structure itself. Window coverings also include blinds which are typically formed of separate slats of rigid or flexible material which either have a fixed angle or can be adjusted in angle to allow some light to pass through the separate slats within the blind.
The entire assembly mounted within the window is referred to as the window covering assembly. The portion of the window covering assembly which acts to occlude the passage of light is referred to as the window covering or as the window covering structure. The entire window covering assembly thus includes the top rail, the bottom rail and the window covering structure extending between the top rail and the bottom rail.
While window coverings can be of fixed size, window coverings are usually desirably adjustable so that the window can be blocked when desired or exposed, depending on the needs of the user. Various different prior art window covering adjustment systems are known. Most typically, cords are provided which extend from the bottom rail, through the window covering structure up to the top rail, and then continue on an exterior side of the window covering structure. A user grasps the cords and pulls the cords to raise the bottom rail towards the top rail and expose the window. The user releases the cord and the weight of the bottom rail causes the window covering to cover the window. Often locking mechanisms are also provided to assist in locking the bottom rail of the shade at a desired position.
Such external cord based window covering adjustment mechanisms are less than entirely satisfactory. The cords can become entangled with themselves or other structures, rendering the cords non-functional in adjusting the position of the window covering. The cords present a safety risk for infants and toddlers. Also, the locking mechanisms for locking the cord in the desired position so that the window covering bottom rail is positioned where desired is often difficult to use effectively and is prone to wearing out, so that the window covering is effectively stalled in either the fully open or fully closed position.
The deficiencies in external cord systems for adjusting window covering position have led to the development of “cordless” window coverings. For instance, see U.S. Pat. No. 6,644,375. Such cordless window coverings include cords which are internal, extending between the top rail and the bottom rail but with no external cords. Some such cordless blinds utilize locking mechanisms adjacent the top rail or the bottom rail which are typically in the form of buttons. When the bottom rail is to be raised to expose the window, one or more buttons are pushed and the bottom rail is raised. When the button is released, the shade remains in the selected position. When the bottom rail is to be lowered, the button(s) can again be pushed and the bottom rail repositioned before releasing the button(s) with the bottom rail in the new desired position. In at least one window covering, included in Published Application No. US-2004-0007333-A1, the bottom rail can be pulled down without requiring that the buttons be pushed. Only when the bottom rail is to be raised do the buttons need to be pushed.
Other prior art window coverings have height adjustment mechanisms which rely on some form of balancing of the bottom rail so that adjustment of the height of the shade is somewhat automatic. Instead of requiring that buttons be pushed, the bottom rail is merely repositioned to a desired position. The shade then remains balanced in the new position. For instance, see U.S. Pat. No. 6,571,853.
While such balanced cordless shades are taught in the prior art, such balanced cordless shades have heretofore required complex mechanisms which have exhibited various undesirable performance characteristics. In particular, such cordless balanced shades have typically included some form of cord collecting structure, such as a spool which has been biased, such as with a spring to cause the cord running from the bottom rail up to the cord collector to be encouraged onto the spool. As the bottom rail moves downward, the strength of the spring increases, making it difficult to cause the bottom rail to remain fixed in the lower position. At a minimum, the bottom rail is inclined to bounce somewhat and not remain solidly in a fully down position. When a weaker spring or other biaser is used, it has insufficient force to keep the bottom rail from falling down at least somewhat when the user desires that the window covering be entirely open.
Variable resistance springs have been attempted, as one solution to this problem. Various cord handling mechanisms have been utilized including one-way brakes and one-way cord movement retarders to discourage such undesirable bounce. With each of these solutions, a need remains for a simple and reliable lifting mechanism for a window covering which allows a user to easily adjust a position of the bottom rail of the window covering merely by grasping the bottom rail and positioning it where desired, with confidence that the bottom rail will remain precisely where it has been left until it is again moved by the user.
This invention provides a lifting mechanism for a window covering which facilitates a cordless window covering to be easily positioned as desired and easily repositioned, by merely placing a bottom rail of the window covering where the user desires it to be. The window covering includes a top rail and a bottom rail with a window covering suspended therebetween. At least one cord, and typically two cords extend between the top rail and the bottom rail. A cord collector is located within one of the rails with the cord coupled to the cord collector at the end of the cord adjacent the cord collector. The cord collector is coupled to a biaser which biases the cord collector in a direction encouraging the cord collector to collect the cord thereon. The cord is routed so that the weight of the shade counteracts the forces exerted by the biaser so that the cord remains stationary and hence the bottom rail of the window covering remains stationary, unless external forces are applied to the system.
Additionally, a progressive resister is coupled to the cord collector. The progressive resister adds a progressive amount of resistance to motion of the cord collector as a greater amount of cord is taken away from the cord collector. Thus, when the bottom rail is most distant from the top rail and the cord is mostly off of the cord collector, the progressive resister exerts a maximum resistance force against collection of the cord by the cord collector, in effect resisting the action of the biaser upon the cord collector. When the bottom rail is closer to the top rail and a greater amount of the cord is collected with the cord collector, a relatively lesser amount of resistance is exerted upon the cord collector by the progressive resister, so that action of the biaser upon the cord collector is opposed to a lesser extent. The action of the progressive resister allows the window covering to avoid the “bounce” phenomena associated with the biaser, such as a spring, exerting an excessive force upon the cord collector when the cord is a maximum amount away from the cord collector. The amount of resistance added by the progressive resister is thus correlated with the amount of cord collected with the cord collector and by correlation, the position of the bottom rail relative to the top rail.
When two cords are provided between the bottom rail and the top rail, preferably two cord collectors are provided with the two cord collectors preferably linked together so that they collect common amounts of cord simultaneously and release common amounts of cord simultaneously. Thus, the bottom rail remains parallel with the top rail at all times. The progressive resister preferably acts upon both cord collectors.
In a most preferred arrangement, the cord collectors are in the form of spools with the biasers in the form of separate helical springs associated with each of the cord collectors. The spools are coupled to gears which mesh with each other and with a resistance gear coupled to the progressive resister.
While the progressive resister could take different forms, in a most preferred embodiment, the progressive resister includes a threaded shaft coupled to the resistance gear and with a bottom plate adjacent the resistance gear and a top plate spaced from the bottom plate. The top plate and bottom plate are preferably configured to avoid rotation and with the top plate coupled to a key with a threaded hole upon the threaded shaft so that the top plate moves toward and away from the bottom plate when the resistance gear rotates. A spring is interposed between the top plate and the bottom plate so that when the top plate moves toward the bottom plate, the spring is compressed and the bottom plate exerts a relatively greater amount of force against the resistance gear. The bottom plate thus resists rotation of the resistance gear and the other gears meshed therewith, including the gears coupled to the spools.
Accordingly, a primary object of the present invention is to provide a window covering without any external cords and which can be adjusted in height easily and reliably.
Another object of the present invention is to provide an adjustable height window covering which has a bottom rail which remains in a position in which it is placed and which can be easily moved by grasping the bottom rail and moving the bottom rail to the position where desired.
Another object of the present invention is to provide a “cordless” window shade which can be adjusted in height without requiring manual actuation of a locking mechanism.
Another object of the present invention is to provide a window covering which has a bottom rail which remains parallel with a top rail at all times and which bottom rail can be easily positioned where desired relative to the top rail.
Another object of the present invention is to provide a window covering which is both free of any external cords and balanced so that the bottom rail can be positioned where desired without requiring actuation of any locking mechanisms, and which bottom rail avoids a “bounce” phenomena throughout a range of motion of the bottom rail.
Another object of the present invention is to provide a window covering which does not have any external cords and which is balanced, and can be easily cut to different widths without interfering with lifting mechanism performance.
Another object of the represent invention is to provide a window covering which is free of external cords and is balanced, and which exhibits reliable performance for a long duration and with heavy use.
Another object of the present invention is to provide a window covering which is free of external cords and balanced, and which can be readily manufactured from commonly available materials while still exhibiting reliable quality performance.
Other further objects of the present invention will become apparent from a careful reading of the included drawing figures, the claims and detailed description of the invention.
Referring to the drawings, wherein like reference numerals represent like parts throughout the various drawing figures, reference numeral 10 (
In essence, and with particular reference to
The cords 8 interface with the lifting mechanism 10 through spools 30 which are configured to collect the cords 8 thereon and release the cords 8 therefrom, depending on the position of the bottom rail 6 relative to the top rail 4. Springs 40 are coupled to each of the spools 30. The springs 40 bias the spools 30 toward collecting the cords 8 upon the spools 30. The springs 40 thus counteract gravity forces acting upon the bottom rail 6 and tending to pull the cords 8 off of the spools 30.
A progressive resister 50 is provided which exerts progressively greater resistance to spool 30 rotation as progressively greater amounts of cord 8 are released from the spools 30. The progressive resister 50 thus acts against the forces exerted by the springs 40 upon the spools 30. Preferably the progressive resister 50 is coupled to the spools 30 through a gear set 80.
More specifically, and with particular reference to
The top rail 4 is preferably a rigid elongate structure. The top rail 4 is fastened to an upper portion of a casing S surrounding a window W. The top rail 4 suspends the entire window covering assembly from the casing S. The top rail 4 can be fastened to the casing S with adhesive, with mechanical fasteners, or with other fastening methodologies known in the window covering arts. The top rail 4 can optionally include the lifting mechanism 10 therein (
The bottom rail 6 is an elongate substantially rigid structure. The bottom rail 6 is preferably hollow so that the lifting mechanism 10 can be placed therein. The bottom rail 6 preferably includes the lifting mechanism 10 therein, but can optionally be vacant with the lifting mechanism 10 included in the top rail 4 (
The window covering 2 extending between the top rail 4 and the bottom rail 6 can be any of a variety of different window coverings known in the art. For instance, the window covering 2 can be in the form of a continuous shade which is either pleated or unpleated, and can form either a single layer between the top rail 4 and the bottom rail 6 or include multiple layers. If multiple layers are included, these layers can be coupled together such that the window covering 2 takes on a cellular form with a “hive-like” cross-section. The window covering 2 could also be in the form of blinds made up of separate slats tethered together that may be fixed or rotatable to vary an amount of light passing therethrough.
At least one cord 8 extends between the top rail 4 and the bottom rail 6. Most preferably, two cords 8 are provided between the top rail 4 and the bottom rail 6. Optionally, more than two cords 8 could be provided. Each of the cords 8 is preferably circular in cross-section and formed of a flexible woven textile material or a flexible plastic material such as nylon or polyethylene. Alternatively, the cords 8 could be in the form of metal chain, plastic chain, fabric chain, flexible tape, flexible ribbon, or any other flexible elongate structure suitable for suspending the bottom rail 6 from the top rail 4 and being handled by the various cord handling mechanisms of this invention. When the term cords is used, it is used generally to refer to any such elongate flexible structures.
The window covering 2, top rail 4, bottom rail 6 and cords 8 together form the window covering assembly which includes the lifting mechanism 10 according to this invention. The entire window covering assembly is preferably configured to be readily adjusted in width to generally match a width of the casing S adjacent the window W. Specifically, the lifting mechanism 10 and the cord redirectors 20 are preferably located sufficiently near to a center of the window covering assembly so that about half of the overall width of the window covering assembly is between the cords 8 and about one-fourth of the window covering assembly is on either side of the cords 8. The window covering 2, top rail 4 and bottom rail 6 can thus be cut, typically with equal amounts being cut from each end of the widow covering 2, top rail 4 and bottom rail 6, to adjust to a width of the casing S up to nearly one-half of the original width of the window covering assembly.
Numerous different window cutting methodologies and cutting tools can be utilized to facilitate such cutting. One such tool and associated methodology is described in U.S. patent application Ser. No. 10/402,452 projected to publish on Sep. 30, 2004. The contents of U.S. patent application Ser. No. 10/402,452 are incorporated herein by reference.
With particular reference to
The housing 12 is an elongate rigid structure which supports the various different components of the lifting mechanism 10 to securely hold these components in precise position relative to each other to maximize desirable function for the lifting mechanism 10. The housing 12 thus includes a generally flat horizontal floor 14 with walls 16 extending perpendicularly up from front and rear sides of the floor 14. A cover 18 is separately provided which spans upper edges of the walls 16 to close the housing 12 (
The housing 12 preferably includes multiple holes through which various different components are supported. These holes include alignment holes 15 for maintaining alignment of the spools 30 and associated structures. The housing 12 also includes gear clearance holes 17 which allow the gears such as the spool gears 82 coupled to the spools 30 and the resistance gear 84 coupled to the progressive resister 50 to have a maximum diameter and to allow the housing 12 to be formed by bending the walls 16 up from the floor 14 without concern for any curvature where the walls 16 and floor 14 are joined together. An alignment hole 19 is further provided to maintain alignment of the progressive resister 50 relative to the housing 12.
Additional holes are provided on the housing 12 such as to facilitate the inclusion of the auxiliary springs 90 and associated equipment for the alternative embodiment of
The cord redirectors 20 (
As particularly shown in
Preferably, a cord tensioner 24 is located adjacent the pulley 22. Specifically, the tensioner 24 is in the form of a resilient structure such as a piece of spring steel which includes a base 25 fastened to the floor 14 of the housing 12. A finger 26 extends up from the base 25 resiliently and presses the cord 8 against the pulley 22 (along arrow D of
Preferably, a cord guide 28 is located adjacent each of the cord redirectors 20. The cord guides 28 include a groove 29 therein which can capture the cord 8 therein but freely allow the cord 8 to pass linearly therethrough. The cord guides 28 can be provided at various different positions along the housing 12 and between the lifting mechanism 10 and the cord redirectors 20. The cord guides 28 generally help to keep the cord 8 in a desired position and decrease the opportunity for the cords 8 to become entangled, knotted, or otherwise out of position.
With particular reference to
Most preferably, two spools 30 or other cord collectors are provided with each of these spools 30 coupled to a separate one of the two cords 8 of the preferred embodiment. It is conceivable that a single spool 30 could be coupled to a single cord 8 or that a single spool 30 could simultaneously gather two or more cords 8 and still function according to this invention. Also, more than two spools 30 could be provided and more than two cords 8.
Other forms of cord collectors which can function as a means to collect cords within the lifting mechanism 10 of this invention could include cord gathering cavities into which the cord 8 could be fed and released without winding of the cord, or multiple axle cord collection spindles, or other components capable of gathering up the cord 8 and containing the cord 8 in a defined region until the cord 8 is to be released.
According to the preferred embodiment, each of the spools 30 includes a central post 32 rigidly coupled thereto. The post 32 includes a slit 33 therein for connection to an associated spring 40 or other biaser, discussed in detail below. The spools 30 include an upper wall 34 spaced from a lower wall 35, with each of the walls 34, 35 defining portions of the spools 30 which extend radially away from the post 32 and a rotational central axis of the spools 30, a greater amount than other portions of the spools 30. A space between the walls 34, 35 defines a cord collection region for the spool 30. The walls 34, 35 keep the cord 8 from working its way off of the spools 30 and becoming entangled within other portions of the lifting mechanism 10.
A lower bearing 36 is provided with a generally doughnut shape and which supports a lower end of the post 32 in a rotating fashion. The lower bearing 36 preferably remains stationary, but could optionally rotate, and rests within a hole in the floor 14 of the housing 12 (
An upper bearing 37 adjacent the upper wall 34 separates rotating portions of the spool 30, including the upper wall 34 from portions of the spring 40 adjacent thereto, so that friction contact and associated resistance is minimized between the spool 30 and the adjacent spring 40. Gear screws 38 attach the spool gear 82 (described in detail below) to the lower wall 35 of the spool 30. Thus, the spool 30 and associated post 32 are caused to rotate along with the spool gear 82.
The springs 40 provide a preferred form of biaser for the spools 30 or other cord collectors. Preferably, one spring 40 is provided for each spool 30. However, multiple springs 40 can be provided for each spool 30, or a single spring 40 could be provided for multiple spools 30. The springs 40 act as a preferred form as a means to bias the spools 30 or other cord collection means toward collecting more of the cord 8 upon the spool 30. Thus, the springs 40 tend to cause the cord 8 to be wound up onto the spools 30.
Countervailing forces including the weight of the bottom rail 6 and associated components located within the bottom rail 6, as well as friction induced into the system, counteract this biasing force of the spring 40. The bottom rail 6 of the window covering assembly thus remains stationary in a position where it is placed by a user, unless a user adds a lifting force upward (along arrow B of
While the springs 40 provide a preferred form of biaser, other forms of biasers could similarly be utilized to provide a means to bias the spool 30 or other cord collector toward collecting more of the cord 8. For instance, the biaser could be in the form of a resilient structure such as a rubber band. The biaser could also be in the form of various different configurations of springs, rather than merely the helical spring 40 of the preferred embodiment.
The spring 40 of the preferred embodiment resides within a cavity 42 which acts as a housing for the spring 40 to keep the workings of the spring 40 from being obstructed. The cavity 42 includes a generally flat floor 43 with a post hole 44 therein which allows the post 32 to extend up through the cavity 42. The cavity 42 additionally includes sides 45 which are generally cylindrical in form facing the cavity 42.
A gap 46 is formed in one of the sides 45. This gap 46 helps to anchor one end of the spring 40 in a stationary fashion while an opposite end of the spring 40 is coupled to the post 32. Specifically, the spring 40 is preferably in the form of a helical spring having an outer tab 47 at an outermost end of the spring 40 and an inner tab 48 at an innermost end of the spring 40. The outer tab 47 is configured to pass through the gap 46 and be secured to the cavity 42 structure.
Because the cavity 42 is generally square in form, it is not capable of rotating within the housing 12 (
The inner tab 48 is oriented within the slit 33 in the post 32. Hence, when the spool 30 rotates and the post 32 rotates along with the spool 30, the inner tab 48 of the spring 40 is also caused to rotate. Such rotation of the inner tab 48 causes the spring 40 to be wound up or wound down, depending on the direction of rotation of the spool 30. In this way, the spring 40 acts according to the preferred embodiment to bias the spool 30 or other cord collector toward collecting greater and greater amounts of the cord 8 upon the spool 30 or other cord collector.
With particular reference to
The progressive resister 50 of the preferred embodiment preferably is provided as a single unit which acts upon a pair of spools 30 with each of the spools 30 acting upon a separate one of two cords 8 within the window covering assembly. Alternatively, a single progressive resister 50 could act upon a single spool 30 or other cord collector in a single cord version of the window covering assembly. Similarly, multiple progressive resisters 50 could be provided acting upon a single spool 30 or upon multiple spools 30. In embodiments where multiple progressive resisters 50 are utilized, each spool 30 can have its own progressive resister 50. The multiple spools 30 can either be linked together by gears or otherwise, or the spools 30 can be independent of each other.
The progressive resister 50 according to the preferred embodiment includes a base bearing 52 which supports other portions of the progressive resister 50 above the floor 14 of the housing 12. The base bearing 52 preferably extends at least partially into a hole in the floor 14 of the housing 12 (
The base bearing 52 includes a bore 54 in an upper end thereof. The bore 54 is aligned with a central axis of the base bearing 52 and supports a threaded shaft 55 of the progressive resister 50 extending vertically up from the bore 54 of the base bearing 52. Particularly, the threaded shaft 55 preferably includes a lower tip 56 which extends down into the bore 54. An upper tip 57 of the threaded shaft 55 extends into the alignment hole 19 and the cover 18 of the housing 12 (
The lower tip 56 of the threaded shaft 55 can be keyed and have a contour matching that of the bore 54 so that the threaded shaft 55 rotates with the base bearing 52. Alternatively, or in addition a fastener can be utilized to secure the lower tip 56 of the threaded shaft 55 within the base 24. When the base bearing 52 is fastened to the resistance gear 84 with the bearing screw 53 (
Alternatively, the lower tip 56 of the threaded shaft 55 can rotate relative to the bore 54. In such an embodiment (
A bottom plate 60 of the progressive resister 50 is oriented directly adjacent the resistance gear 84. The bottom plate 60 provides a preferred form of brake with a lower surface of the bottom plate 60 abutting the resistance gear 84 and with this abutment imparting a resistance force against free rotation of the resistance gear 84, which is proportional to a force with which the bottom plate 60 is pressed against the resistance gear 84. The bottom plate 60 has a generally square form so that it is prevented by the walls 16 of the housing 12 from rotating. Hence, the bottom plate 60 does not rotate along with the resistance gear 84 and the threaded shaft 55.
The bottom plate 60 includes a center hole 61 through which the threaded shaft 55 is allowed to pass without contact or obstruction. A recess 62 is preferably formed in an upper surface of the bottom plate 60. The recess 62 facilitates support of a compression spring 65 adjacent the upper surface of the bottom plate 60. A perimeter 64 of the recess 62 is generally cylindrical and has a diameter similar to a lower portion of the compression spring 65. Thus, the compression spring 65 is held within the recess 62 and is prevented from translating laterally relative to the bottom plate 60 and other portions of the progressive resister 50.
The compression spring 65 includes an upper end spaced from a lower end 68. The lower end 68 abuts the bottom plate 60 within the recess 62. The upper end 66 abuts a top plate 70 of the progressive resister 50.
The compression spring 65 is preferably generally helical in form and particularly configured so that a spring force of the compression spring 65 increases as the compression spring 65 is compressed between the upper end 66 and the lower end 68, such as by moving the top plate 70 toward the bottom plate 60.
To maximize a degree of travel between the upper end 66 and the lower end 68, the compression spring 65 can be slightly conically tapered with the upper end 66 having a slightly smaller diameter than the lower end 68. In this way, the compression spring 65 can be collapsed with turns in the compression spring 65 being progressively inboard of each other and maximizing a degree of collapse which can be experienced by the compression spring 65. Alternatively, the compression spring 65 could be replaced with other forms of springs or resilient structures which would be capable of exerting a force down upon the bottom plate 60 when the top plate 70 is lowered against upper portions of the force applying structure, such as the compression spring 65.
The top plate 70 is generally planar with a lower surface of the top plate 70 adapted to abut the upper end 66 of the compression spring 65. A center hole 71 passes through the top plate 70, allowing the threaded shaft 55 to pass therethrough. The top plate 70 preferably includes a depression 72 therein which is shaped to support a threaded key 75 within the top plate 70. Alternatively, a threaded key 75 can be integrally formed with other portions of the top plate 70. The depression 72 is sized to allow the threaded key 75 to fit snugly therein so that the threaded key 75 and top plate 70 act together as a single unit. By making the threaded key 75 from a separate structure from other portions of the top plate 70, the threaded key 75 can be formed of a harder material than the top plate 70 to maximize performance of the top plate 70 and coaction with the threaded shaft 55.
The top plate 70 includes arms 74 which extend away from the center hole 71 and are adapted to abut the walls 16 of the housing 12. The top plate 70 is thus held by the arms 74 so that the top plate 70 cannot rotate. Rather, the top plate 70 can only translate vertically along a central axis of the threaded shaft 55.
The threaded key 75 includes a perimeter contour 76 matching that of the depression 72 so that the threaded key 75 fits securely within the depression 72. A threaded hole 78 passes through the threaded key 75. The threaded hole 78 includes threads therein which match a pitch of the threaded shaft 50.
To maximize a range of travel of the top plate 70, the threaded shaft 55 and threaded key 75 preferably have a very shallow pitch to their corresponding threads. When the resistance gear 84 rotates, the threaded shaft 55 rotates along with the resistance gear 84. The threaded key 75 translates vertically (along arrow H of
When such rotation is in a direction causing the top plate 70 to move toward the bottom plate 60, the compression spring 65 is compressed a greater and greater amount. As the compression spring 65 is compressed, it exerts a progressively greater force vertically down upon the bottom plate 60. The bottom plate 60 is thus urged with greater and greater force against the resistance gear 84. This in turn makes it progressively more difficult for the resistance gear 84 to rotate along with the spool gear 82 coupled to the spool 30.
With particular reference to
As an alternative, the gear set 80 could include idler gears between the adjacent gears 82, 84, or additional gears could be provided with additional function associated with such additional gears.
In the preferred embodiment, the spool gears 82 preferably rotate in a common direction (about arrows G and E of
While the gear set 80 provides the preferred form of coupling the progressive resister 50 to the spools 30, other forms of coupling could be provided. For instance, the progressive resister 50 could act directly upon the spools 30. For instance, in place of the springs 40, a progressive resister 50 could press directly against the upper wall 34 of the spool 30 through the bottom plate 60 so that resistance to spool 30 rotation would result. In such an arrangement, the springs 40 or other biasers would likely need to be geared to the spools 30 so that appropriate biasing forces tending to collect cord 8 upon the spool 30 would be provided.
The gear set 80 advantageously links the spools 30 together so that in window coverings with two or more cords 8, the cords 8 are gathered in equal amounts onto the spools 30 and the bottom rail 6 remains horizontal and parallel to the top rail 4. Such linking is not required however. Also, linking of the spools 30 as well as other components could be provided with alternative means to link the components together. For instance, belts, chains, sprockets, shafts and other mechanical couplings could be utilized to link the components together.
If sufficient height were available within the rails 4, 6 housing the lifting mechanism 10, it is conceivable that both the spools 30, springs 40 and progressive resisters 50 could all be stacked together vertically. If a particularly low profile rail 4, 6 is desired, the spools 30, springs 40 and progressive resisters 50 could all be laterally spaced from each other and geared together to an appropriately modified gear set 80. If the progressive resister is to be shortened to less than an overall height of the rails 4, 6 in which the lifting mechanism 10 is located, multiple progressive resisters 50 could be provided and configured so that progressively greater and greater resistance would be provided through multiple separate progressive resisters 50 having a shorter overall profile.
With particular reference to
Each auxiliary spring 90 includes a housing 92 generally similar to the cavity 42 for the springs 40 of the preferred embodiment. Each auxiliary spring 90 includes an outer end 94 spaced from an inner end 95 which can coact with posts 32′ including slits 33′ coupled to auxiliary spring gears 98. The housings 92 generally define deep cavities 96 in which the auxiliary springs 90 are located.
In this embodiment the auxiliary springs 90 have generally twice the height of the springs 40 of the preferred embodiment. Hence, significantly greater biasing forces can be provided when the auxiliary springs 90 are added to the lifting mechanism 10′. Auxiliary spring bearings 99 allow the auxiliary spring gears 98 to float slightly above the floor of the housing 12 to allow the auxiliary spring gears 98 to freely rotate. The spool gears 82 rotate in a similar direction to that of the preferred embodiment. however, the auxiliary gears 98 rotate in an opposite direction (along arrows I and J of
The auxiliary springs 90 provides significantly greater force tending to cause the spools 30 to collect the cords 80 thereon. Such an arrangement is desirable in situations such as where the window covering 2 is formed of an exceptionally heavy material so that additional lifting force and cord collection force is required to balance the weight of the window covering 2. Similarly, if a heavy bottom rail 6 is provided, or if the entire window covering assembly is configured for use in an exceptionally tall window W (
With particular reference to
Placing the lifting mechanism 110 within the top rail 4 allows the bottom rail 6 to have a smaller configuration. Preferably, when the bottom rail 6 has a lower profile, the bottom rail 6 is provided with sufficient weight so that gravity forces tending to pull the cords 8 out of the cord collector are sufficient to overcome the biasing forces such as those provided by the springs 40, to keep the lifting mechanism 10 in appropriate equilibrium. In addition to adding weights to the bottom rail 6, or as an alternative thereto, the springs 40 or other biasers can be provided with a lighter force. Additionally, resistance added to the system through the tensioners 24 (
With particular reference to
Before applying this downward force, the bottom rail 6 is in equilibrium. Particularly, the lifting mechanism 10 has a portion of the cord 8 wound upon the spools 30. The springs 40 are applying a force on the spools 30 tending to gather additional cord 8 onto the spools 30. A weight of the bottom rail 6 is acting through the pulleys 22 at the cord redirector 20, tending to cause the bottom rail 6 to move downward and causing the cords 8 to be played off of the spools 30.
These gravitational forces and spring 40 or other biasing forces are in equilibrium so that the spools 30 are at rest and the bottom rail 6 is at rest. Additionally, the progressive resister 50 as well as the tensioner 24 are adding additional resistance to cord 8 movement in either direction and spool 30 rotation in either direction to assist in maintaining equilibrium and stationary positioning of the spool 30.
When the user applies a downward force upon the bottom rail 6, this equilibrium is disturbed. Specifically, now both the gravitational forces acting downward on the bottom rail 6 and the forces applied by the user work together to overcome the biasing forces acting upon the spools 30 through the springs 40 and to overcome resistance forces applied by the tensioner 24 and the progressive resister 50. The bottom rail 60 moves down and cord 8 is played off of each of the spools 30.
As the bottom rail 6 moves downward (along arrow A of
So that a new equilibrium condition can be achieved by the lifting mechanism 10, the progressive resister 50 is provided which is progressive in nature. Particularly, with the bottom rail 6 in a lower position, and with more of the cord 8 played off of the spool 30, the springs 40 are applying a greater biasing force upon the spools 30. Also, to some extent a weight of the window covering 2 is partly suspended from the top rail 4 directly, rather than suspended through the bottom rail 6 and the cords 8.
Without the progressive resister 50, the bottom rail 6 would tend to bounce upward and not remain in a fully closed position covering the window W. However, with the progressive resistance 50 provided by the progressive resister 50, the progressive resister 50 is applying a progressively greater amount of resistance to spool 30 rotation as the cord 8 is played off of the spools 30. This resistance applied by the progressive resister 50 is thus sufficient to counteract the biasing forces applied by the springs 40 or other biasers upon the spools 30. Equilibrium is then maintained when the bottom rail 6 is at the lower position.
When the user wishes to raise the bottom rail 6, the user grasps the bottom rail 6 and lifts upward on the bottom rail 6. The user is now applying forces which counter gravity forces acting on the system and working with the forces applied by the springs 40 upon the spools 30. These forces together are sufficient to overcome the forces remaining, including gravity forces acting upon the bottom rail 6 and the resistance forces applied by the progressive resister 50. Hence, as the user lifts the bottom rail 6, the cord 8 is gathered upon the spools 30. When the user releases the bottom rail 6, at any position, after movement upward along arrow B of
While a user's hand is typically considered to be the control force which causes adjustment of the bottom rail 6 of the window covering assembly, other control forces could cause adjustment of the position of the bottom rail 6. For instance, an automatic window covering assembly could be provided where the bottom rail 6 would be raised or lowered by moving along a track, or by the action of separate cords coupled to a control mechanism such as a servo motor and a separate spool to position the bottom rail 6 where desired, such as through use of a remote control assembly. In such a configuration, the lifting mechanism 10 would sufficiently balance the window covering assembly so that a control mechanism could most easily manipulate the position of the bottom rail 6.
The progressive resister preferably provides progressively greater resistance along an entire range of motion of the cords 8 onto the spools 30 and off of the spools 30. The resistance force provided by the progressive resister 50 is preferably generally a linear function of the amount of cord upon the spool 30 and a generally linear function of the position of bottom rail 6 between the top rail 4 and a lowermost position spaced from the top rail 4. As an alternative, the progressive resister 50 could be configured so that it applies no resistance except when needed. For instance, the progressive resister 50 could be configured so that it provides no resistance until the bottom rail 6 is at a middle position, and then provides progressively greater resistance only for a lower half of bottom rail 6 travel. Similarly, the progressive resister 50 could provide progressively greater resistance in a non-linear fashion, such as proportional to a square of the amount of cord upon the spools 30 or other cord collectors. Some other function than a linear function could similarly be provided, with the goal being to allow the bottom rail 6 to remain in equilibrium and stationary at all positions for the bottom rail 6, between a lowermost position most distant from the top rail 4 and an uppermost position closest to the top rail 4. If a window covering 2 having a non-uniform weight distribution is provided, the progressive resister 50 can be appropriately configured to provide resistance when desired to maintain smooth operation of the lifting mechanism 10 for all different positions for the bottom rail 6.
The progressive resister 50 provides a degree of resistance to rotation of the spool 30 which is similar in both directions for the spool 30. Hence, whether the spool 30 is to rotate to gather additional cord 8 thereon or is to rotate to play additional cord 8 off of the spool 30, a similar amount of resistance is provided. The amount of resistance is correlated with the amount of cord 8 which is on the spool 30, which itself correlates with the position of the bottom rail 6 relative to the top rail 4. The progressive resister 50 thus provides resistance in a similar amount in both a lifting direction (along arrow B of
This disclosure is provided to reveal a preferred embodiment of the invention and a best mode for practicing the invention. Having thus described the invention in this way, it should be apparent that various different modifications can be made to the preferred embodiment without departing from the scope and spirit of this invention disclosure. When structures are identified as a means to perform a function, the identification is intended to include all structures which can perform the function specified. When structures of this invention are identified as being coupled together, such language should be interpreted broadly to include the structures being coupled directly together or coupled together through intervening structures. Such coupling could be permanent or temporary and either in a rigid fashion or in a fashion which allows pivoting, sliding or other relative motion while still providing some form of attachment, unless specifically restricted.
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