The present invention relates to a mechanism and process for providing actuation of a single control in order to raise and lower window covering blind sets, as well as to control the angle of tilt of window covering blind sets. The structure and method enables elimination of user actuatable dangling cords and further pe nits simplification and mass automation of control and operation of a window covering blinds set to enhance safety.
Conventional window coverings which use a series of horizontally disposed, vertically arranged slats are available in a variety of styles. The typical structure for supporting the slats vertically spaced from each other includes an end ladder arrangement having a series of cross connectors upon which the slats rest. In the 1950's the ladder arrangement included a wide tape and the cross connectors included a series of generally horizontal tape sections joining the a front and rear vertical ladder tape. Movement of the front vertical ladder tape with respect to the rear vertical ladder tape caused a tilting of the horizontal tape section and consequent tilting of the supported louver or slat resting on the horizontal tape section.
The initial use of a soft vertical ladder tape enabled the lowest base louver or slat to be raised while sequentially collecting slats against the rising lowest base louver while enabling collapse of each vertical ladder tape section between adjacent horizontal tape sections as slats were collected together against the base slat. As the base slat was raised to its uppermost position, the slats would be collected into a closely adjacent group nearest an upper head rail which typically provided fittings for operating the window covering blinds set. Control of the operation of the window covering blinds set typically involved a lift cord for raising the base slat and collecting the slats in a group just underneath the head rail to place the window covering blinds set in a lifted, open position, and a tilt control used to raise or lower the front vertical ladder tape with respect to the rear vertical ladder tape to cause a tilting of the horizontal tape section to control the angle of tilt of the supported louvers resting on the horizontal tape sections.
Traditionally, two collections of cords were used to enable control of the lift control for opening the window covering blinds set and the tilt control, respectively. Tilt control was typically achieved by pulling one side of a looped cord to cause the front vertical ladder tape with respect to the rear vertical ladder tape with direct visual feedback. The lift control was achieved typically by pulling a pair of joined or length coordinated cords from one side of the head rail so that each side of base slat would be lifted evenly. Without length coordination of the lift cords, one side of the base slat would begin to raise higher than the other. Often the coordination was done with a metal slip buckle.
In the early days, the pair of cords which raised and lowered the blinds were a loop at the bottom, with the loop being lowered as the window covering set was raised, and raised as the window covering set was lowered. Children were known to play with the end of the lift cord, and the lower end of the lift cord was even more available when the window covering set was raised. Children were also known to accidentally become caught in the lower loop. In some cases choking can occur.
Other structures were recently employed to keep lift cords joined, including placing the coordination between the cords high and near the head rail. The head rail is a metal structure which may be high up and near a metal rail which provides support for the window covering as well as actuation hardware. This arrangement works less well with vertically tall window covering sets because the raising of the slat set puts even more loose cord at or near the ground. Further, where the window covering set was particularly vertically high, the user might find the uppermost starting position of the coordinated cords to be inaccessible.
In another configuration, the lift cords were separated into individual cord members and secured within a cord safety connector which is used to both tension, secure, collect and enable tension pulling and actuation either by grasping the safety connector or optionally by grasping a single cord which extends from the bottom of the safety connector. A safety connector acts to keep the cords coordinated if operated by direct manual grasping and actuation of the safety connector, or by a cord extending below it, but will break apart if an object enters between two cords and bears down upon the safety connector. Safety connectors which completely separate and leave only single dangling cords which are generally incapable of causing a choking or strangling hazard.
In the earliest window coverings, the control of the tilt of the louvers or slats was accomplished by using a pair of opposed cords. Unlike the lift cords which were better to be coordinated, the tilt cords were intended to work oppositely. When one cord is pulled, the other cord retracts, and vice versa. In some of the earlier window coverings an operable loop was possible, but it was generally preferred to have a pair of cords, each having its own terminus, especially also to distinguish it from the coordinated lift cord. The tilt mechanism basically consisted of the turning of a drum over one ladder tape set and which may have a shaft to transmit turning to a second and or subsequent ladder sets.
In view of the foregoing, the area inside the head rail had two sets of distributive controls. Taken from the upper front of a head rail and looking to the right, a double or triple or quadruple coordinated cord set would enter into the head rail and each would be distributed to locations directly over the ladder tape or ladder cord, extend through apertures in the head rail and then typically through individual slat apertures in the lateral centers of the slats and finally to some fixed position on the bottom slat. As the lift cords were taken in toward the head rail, the bottom fixed slat would rise to collect the other slats near the underside of the head rail.
Some window coverings have “rootless” or “no-holes” slat sets which either route the lift cord through some structure located to a rear side of the slat, or which may use a pair of guided lift cords which are held relatively closely to the ladder cord matrix. The so-called “routless” feature was developed primarily to eliminate the aperture from the center of the slats. In other slat sets, a center aperture is set to be of a diameter for fitting closely around a lift cord. Window covering sets which are “routless” generally still typically use a lift cord set which can come into contact near the floor and create a danger for children and pets.
At the other end of the head rail, the pair of tilt cords would operate a drum to cause the raising or lowering of the front vertical ladder tape or member with respect to the rear vertical ladder tape or member to cause a tilting of the horizontal tape section to control the angle of tilt of the supported slats resting on the horizontal tape or horizontal ladder cord sections. In later models of the window coverings, a wand was provided with a reduction gear so that a user could easily manipulate the wand by turning it with fingers to cause the raising or lowering of the front vertical ladder member with respect to the rear vertical ladder member to cause tilting of the horizontal ladder section to control the angle of tilt of the supported slats as previously described. However there has been no effective substitute for the operation of the lift cord sets.
In the traditional slat window covering, tilt was able to occur independently of lift. Although with some friction, the slats could be lifted while they were in a forward, rearward or neutral tilt angle. Likewise, a tilt adjustment could occur regardless of whether the slat set was fully extended or closed, whether it was half way open, or whether it was at the full open position. Exact simultaneous activation is not an overriding advantage, but the main objective is safety and elimination of the lift cord set has been viewed as the major objective in making window covering slats safer.
Even in conventional manually operated window covering sets, the concern over safety is so high that even those structures with hanging slat lift cords often have stops mounted on the manually operable lift cords near the points of entry into the head rail and that will prevent children and pets from “fishing out” any appreciable extra length of lift slat cord from in between any two adjacent slats, as such pick might form a potentially dangerous loop. Slat angle adjustment cords have separate ends an are typically short and located near the top of the window covering blind set which makes it a solution which is limited by the height of the blind set. Elimination of the ability to tamper with the window covering blind set so as to form a dangerous loop is a high priority.
What is needed is a window covering slat set which can be manually or electrically actuated and having a control input which eliminates as much as possible any potential for unwanted, dangerous entanglement with humans. The needed solution should eliminate all dangling control cords extending from the head rail. The needed solution should permit a slat-type window covering to be opened and closed and have the angle of tilt of the slats adjusted regardless of the degree to which the slat set is raised.
A novel and nonobvious structure and method for operation of a window covering set, and which permits actuation, manually or by machine, of a single control, is disclosed. The single control structure may preferably be a single wand, with or without a lower angled member and fitting to facilitate cranking, or it may be used as an interface for a single motorized and preferably controllable driver to enable complete control of the lift and slat tilt functions through a single mechanical interface.
Control is had by creating a three segment relative control logic. The three segment relative control logic can be visualized by a contiguous segments where movement within in the middle segment controls the angle of the slats, and movement to and beyond the position where the slats are maximally angled in one direction results in at least one of opening (raising) or closing (lowering) of the slat set by “winding up” a lift cord set which may operate on the interior or exterior of the slat set.
If the raising of the window covering slat set is in progress and the control input is reversed, the slat angle will begin to change from the one angular extreme it assumed when it began to be lifted, and once the angle reaches the other angular extreme, continued control input will cause the slat set to begin to be lowered. Likewise where the lowering of the window covering slat set is in progress and the control input is reversed, the slat angle will begin to change from the other angular extreme at which it was raised and back to the one angular extreme which was previously associated with lowering and further continued control input will cause the slat set to again be raised.
When the slat set is closed and in a position where the window covering is at its maximum lowered extent and covering the window opening, a control input in one direction will change the slat angle to one extreme, and thereafter continued control input in that direction will result in raising of the slat set. But also, when the slat set is closed and in a position where the window covering is at its maximum lowered extent and covering the window opening, a control input in the other direction will change the slat angle to the other extreme, and thereafter continued control input in that direction will also result in raising of the slat set. In essence, spools which have the capability to take up the lift cords can be actuated in either direction onto the spool. As before, during lifting or lowering, a change in rotational input will halt such lifting or lowering and begin to control the angle of the slats.
Slat angle can be adjusted while the window covering is located at any position between fully lowered and fully raised. Any control input that is applied which goes beyond either of two extremes in angling the slats will begin or continue lifting or lowering of the slat set. A coordinating mechanical rod may be arranged to extend the length of the head rail to mechanically connect and coordinate multiple combination slat angle adjustment and window covering opening lift sets, especially for long slats and wide window covering slat sets. In this fashion, very wide horizontal slat window covering sets having long head rails can simultaneously coordinate multiple combination angle adjustment and lift sets for adequately and evenly supporting long slats so that coordinated and even degrees of light blockage will occur at all adjustment settings.
The ability to raise, lower, and adjust the slat angle of a window covering slat set using a single mechanical input which is simple enough to have only two logic inputs, either a turning motion in one direction or the other direction enables the elimination of control cords and allows a single wand to complete all of the standard slat window covering adjustments. The single mechanical input can be operated with the turning of a manual wand or more automatically and remotely with a simple bi-directional motor. Either the manual or electrically driven embodiments enable complete elimination of manually grasped lift cords which must be pulled down by the user, as well as complete elimination of manually grasped slat angle adjustment cords.
The invention herein is applicable to use both with a central lift cord which extends through apertures in the blind slats as well as the case of a pair of cords which lift from the outside. The manner and details of operation of a pair of outside lift cords may vary widely. Generally is desired that the lift cord remain fairly close to the structure which forms the ladder which both supports and enables the slats to tilt. As before, it is desired that the lift cord not be enabled to be “picked” from any structure so as to enable children and pets to extract a significant sized loop from the ladder.
Because the ladder structure and its relationship with the lift cord can have a number of realizations, all possible combinations should be considered in conjunction with the invention. The lift cord should be able to lift the bottom slat and allow the ladder structure to collapse to enable all lower slats to be stackably collected closely atop a growing bottom stack as the combination slat angle adjustment and window covering opening lift set is opened. The slat lift cords should be able to slidably translate with respect to the slat ladder support structure. This slidable translation may occur via a number of possible structures including the use of a ladder with vertical enclosed structures which surround the lift cord, or fittings on the vertical ladder structure which enable the lift cord to slidably translate with respect to the vertical ladder structure, or with loops formed by the same or different material of the vertical ladder structure which closely guide the lift cord and allow it to slidably translate with respect to the vertical ladder structure.
A slip fitting is used within a slat tilt fitting to limit the movement of the slat tilt fitting as at least one take up drum enables the lift function. The limited motion of the slat tilt fitting is sufficient to enable the slats to move through a range of tilt upon actuation. In one embodiment a pair of take up spools is rotatably connected with a central turn axle which may extend generally parallel to a head rail. The lift cord take up drum or drums may be positively rotationally engaged with the central turn axle. Turning of the central turn axle causes the take up drums to begin to wind up the lift cord which causes the bottom slat to be lifted or lowered. A slat tilt fitting is also rotatably operably connected to turn with the central turn axle to a limited extent, but sufficiently to enable the slats to be tilted as desired upon turning of the central turn axle. The ability of the slat tilt fitting to turn with the central turn axle is angularly limited to occur only over the range of angular tilt displacement of the slats.
As an example, consider a window covering slat set utilizing the combination slat angle adjustment and window covering opening lift set of the invention in a completely lowered state with the angle of tilt of the slats being horizontal, with the tilt fitting being at a center of its angular tilt range. If a user begins to input a mechanical turning force into the central turn axle, both the slat tilt fitting and at least one take up drum start to turn. The turning of the slat tilt fitting will turn with the central turn axle because it has not reached the limit of its tilt operation range. The turning of the slat tilt fitting involves both movement front vertical ladder member and the rear vertical ladder member so that significant slat tilt is achieved with a relatively slight movement of the slat tilt fitting.
Continuing with the example, further continued turning of the central turn axle causes the slat tilt fitting to quickly reach its rotational limit which is the limit of tilt of the slats in the direction in which the central turn axle began turning. Once the limit of the slat tilt fitting is reached, continued turning of the central turn axle only causes the take up spool(s) to turn to continue to take up lift cord to cause the bottom slat to be lifted. Considering again the combination slat angle adjustment and window covering opening lift set in its completely lowered state with the angle of tilt of the slats being horizontal, it is clear that enabling the lift cords to have less than one inch of additional length will delay the action of the start of lift of the slats while the angle of tilt is being adjusted. Some of this “play” can be accomplished not only by additional length, but also by providing an attachment which enables delayed engagement of the take up spools after an amount of turning of the central turn axle. Such provision would prevent even a small loop the size of a pencil to be pulled from a section of lift cord whether it is in between or outside of the vertical ladder member. Many mechanical realizations can be implemented that would give nearly a full turn of the central turn axle before the take up spool(s) are positively rotationally engaged with the central turn axle.
In the embodiment illustrated a combination slat angle adjustment and window covering opening lift set is provided as a housing which can be multiply mounted in a head rail. A pair of take up spool are mounted on either side of slat tilt fitting to (1) provide a pair of take up spools which have separation to reduce the potential for tangles in the pair of lift cords as they are doubly taken up, (2) provide a balancing of forces on the pair of take up spools as they wind and lift the lift cords, (3) allow the slat tilt fitting to be positioned directly over the vertical ladder cords to more directly provide the tilt function, and (4) to place the slip fitting of the slat tilt fitting in a controlled, protected space to insure that the carefully pre-selected slip forces can operate freely without binding through contact with other members, including the combination slat angle adjustment and window covering opening lift set housing walls.
The invention, its configuration, construction, and operation will be best further described in the following detailed description, taken in conjunction with the accompanying drawings in which:
The description and operation of the environment, apparatus and method of the invention will be best described with reference to
Although not separably discernible in
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Housing support 51 is typically snap-fitted into the head rail 23, which is typically available in standard sizes, is utilizing the size match and engagement with the downwardly directed top curled metal edge 29. The main holding force for the housing support 51 to secure it within head rail 23 is between uppermost extents 61 of the pair of oppositely located side walls 55, 57 which contain a number of features for interfitting with the downwardly directed top curled metal edge 29 of the head rail 23. An upper projection 63 having a depth in a direction along the side walls 55, 57 which is about the same width between the side wall 27 and downwardly directed top curled metal edge 29. The upper projection rises from a top area 65 of the side walls 55, 57. Underneath the upper projection 63 and top area 65, the side walls 55, 57 contain a flexion relief slot 67 to enable the upper projection 63, and to a lesser extent top area 65 to be pressed down to enable the housing support 51 to be engaged and disengaged from the head rail 23. The opposite point of pressure for the housing support 51 may include a pair of pressure tabs 69 which may be sized to enable some deformation.
The pair of oppositely located side walls 55, 57 each contain an bearing opening 71, having a portion of its inner arced surface formed circularly cylindrical, for receiving a rotational member that will be rotationally supported by the bearing opening 71. Into the side walls 55, 57 adjacent the bearing opening 71, a flexion relief slot 75 to facilitate loading a structure to be bearingly and rotationally supported. Side walls 55, 57 may also have reinforcing structures 77 which increase the area of contact of the side walls 55, 57 with the base 53.
The base 53 of the housing support 51 includes a number of features which contribute to the operation of the combination slat angle adjustment and window covering opening lift sets 31. At the center of the base 53 is an aperture 79 which can be utilized for a number of purposes including marking and alignment as well as for securing the housing support 51 to a head rail 53 if such is needed. In some cases, the aperture 79 may be used for a center lift cord, but inasmuch as the embodiment shown ideally operates with a pair of outside lift cords, the configuration shown will not use the center aperture 79 for passing a single lift cord, and an inside lift cord may either result in a shift of position of the center aperture underneath a take up spool, or an arrangement which would locate a take up spool over the aperture 79. An opening, or openings in the head rail 23 may be had that will enable the individual components of the lift/ladder cord set 39 to enter the head rail 23 either separately or together, are not shown.
Most closely adjacent the apertures 79 are a pair of stops 81. Stops 81 each have a vertical surface 83 facing away from the aperture 79 and a curved surface 85 facing toward aperture. The curved surface 85 transitions from a vertical surface to a near horizontal surface and is meant to make an accommodation space for accommodating a turning member (not yet shown). An abbreviated small surface exists between the uppermost extent of the vertical surface 83 and the uppermost extent of the curved surface 85 to provide a substantial force resisting surface as a stopping index.
The base 53 of the housing support 51 includes four major openings including a pair of tilt cord openings 91 and a pair of lift cord openings 93. The tilt cord openings 91 are located directly on either side of the aperture 79 and each is on the other side of its respective closer stops 81. The tilt cord openings 91 are rectangular with the longer dimension being collinear with each other and also parallel to the plane of the side walls 55, 57. The pair of lift cord openings 93 are rectangular with the longer dimension being perpendicular to the plane of the side walls 55, 57 and parallel but displaced axially from each other. Because pair of lift cord openings 93 are offset from the center, they may preferably have some roller support and wear structures 95, with those wear structures closer to the center of housing support 51 more likely to be subjected to lift cord wear.
Referring to
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To the left of the first take up spool, bearing, and axle member 103, and adjacent first take up spool structure 107, a rotational support bearing member 121 is seen. The rotational support bearing member 121 has a surface and radius to match an associated one of the bearing openings 71 of the housing support 51. The rotational support bearing member 121 has a square bore 123 to accept the central turn axle 49 extend completely through the first take up spool, bearing, and axle member 103 and across the housing support 51 to enable the central turn axle 49 to transmit mechanical power among multiple combination slat angle adjustment and window covering opening lift sets 31. The first take up spool structure 107 is shown as having a hub 125, spokes 127 which extend the axial length of the first take up spool structure 107, and connect to the inside 129 of the cylindrical structure 111, although other configurations are possible.
Immediately to the right of the first take up spool structure 107, a slip bearing structure 131 is seen. Slip bearing structure has an outer bearing surface 133. Slip bearing structure 131 is a land which circumferentially arises from an axle member 135. The axle member 135 has a key rib 137. To the right of the axle member 137, a further rotational support bearing member 139 also has a surface and radius to match the other associated one of the bearing openings 71 of the housing support 51. The rotational support bearing member 139 is adjacent the opening of the square bore 123 which cannot be seen in
To one side of the first take up spool, bearing, and axle member 103, a ladder cord engagement structure is seen as a combination slat tilt fitting and slip fitting housing 141 is seen. The exterior of the slat tilt fitting and slip fitting housing 141 has a pair of oppositely positioned tilt cord supports 143 which extend circumferentially above a generally circular housing 145 both in the interior and exterior. The pair of oppositely positioned tilt cord supports 143 have a split, angled structure 147 which extends from adjacent the generally circular housing 145 at one end and terminate at a split pair of stop engagement structures 149. Beyond the stop engagement structures 149, the tilt cord supports 143 include a gently arced structure 151 which is circumferentially outward of the generally circular housing 145 and include a central groove 155.
The central groove 155 and pair of stop engagement structures 149 help to accommodate and grasp the terminating ends of the vertical ladder cords of the lift/ladder cord set 39. Rotation of the slat tilt fitting and slip fitting housing 141 about the slip bearing structure 131 will cause movement of the front vertical ladder member with respect to the rear vertical ladder member caused a tilting of the horizontal member underneath each slat 41 and consequent tilting of the supported slat 41. The split pair of stop engagement structures 149 help to stabilize a knot or other enlarged structure on a cord, as well as to generally be compatible with the top of pair of stops 81 of the housing support 51. Thus, the slat tilt fitting and slip fitting housing 141 has a range of movement to a position where stop engagement structures 149 on one side of the slat tilt fitting and slip fitting housing 141 contacts one of the pair of stops 81 on its side of the housing support 51, to a position where the stop engagement structures 149 on the other side of the slat tilt fitting and slip fitting housing 141 contacts one of the pair of stops 81 on its side of the housing support 51.
The slat tilt fitting and slip fitting housing 141 has an overall annular face 157 on both sides, and a circumferentially inwardly disposed inside 159 extending between the annular faces 157 and which is sized to support a coiled tension spring 161. Features of the circumferentially inwardly disposed inside 159 include an inside surface 165 into which the coiled tension spring 161 can fit, and an extended portion 167 which accommodates an upper “T” shaped slot 169 for securing and interfitting with generally axially parallel angled ends 171,173 of tension spring 161, each of which depend from a circumferentially outwardly extending transition length 175 (only one of which is seen in the perspective view of
The coiled tension spring 161 operates differently than most springs used for frictional tension. Usually a friction mounted coil spring grasps a bearing area tightly until an external force urges a slight uncoiling of the spring sufficient to break a coiled grip force. The coiled tension spring 161 of the invention works somewhat in reverse, in that the coiled tension spring 161 is used to apply a slip engagement to the slip bearing structure 131. However, it is the slip bearing structure 131 which is providing an input force to the coiled tension spring 161 while it is secured within the slat tilt fitting and slip fitting housing 141. The description of a structure which can move with another structure but which can provide slippage where the force on a structure such as slat tilt fitting and slip fitting housing 141 can be realized in a wide variety of configurations. Any structure which can move with another structure but which can provide slippage where the force or angular displacement (which will result in limited relative movement of a pair of vertical ladder cords, such as lift ladder cord set 39) has reached a threshold limit can be utilized.
First, the generally axially parallel angled ends 171,173 of tension spring 161 are brought together and made to stably rest within the upper “T” shaped slot 169. Note that the direction of coil of the coil structure 177 is such that when generally axially parallel angled ends 171,173 of coiled tension spring 161 are brought together that the coil structure 177 tightens. The width of the upper “T” shaped slot 169 is of a dimension to exactly determine the degree to which the coil structure 177 contracts. The vertical part of the upper “T” shaped slot 169 is wide enough to facilitate entry of the generally axially parallel angled ends 171,173 and circumferentially outwardly extending transition length 175 of the coiled tension spring 161 into and through the upper “T” shaped slot 169.
Seen to the right of coiled tension spring 161 is a second take up spool structure 191, second take up spool structure 191 includes, as was the case for first take up spool structure 103, a cylindrical structure 111, first flange 113 and a second flange 115, key slot 117, 119, and hub 125. However, the hub 123 includes an axial bore 193 which is sized to fit over axle member 135. Axial bore 193 further includes a key slot 195 which interfits with key rib 137 so that rotational movement of the axle member 135 causes second take up spool structure 191 to turn positively. As such, the second take up spool structure 191 moves along with the first take up spool structure 107 when the second take up spool structure 191 is keyably engaged with the axle member 135.
Referring to
Referring to
Referring to
Many of the structures of the combination slat angle adjustment and window covering opening lift set of the second embodiment and other component structures have common structure with the combination slat angle adjustment and window covering opening lift sets 31 and will be numbered in common. A housing support 251 has a base 253 and a pair of side walls 255 and 257, but side wall 257 is seen as being close to aperture 79. The relationship between aperture 79, pair of stops 81, vertical surface 83, curved surface 85 and pair of tilt cord openings 91 remains the same. Compared to base 53, it is seen that the area of the base 51 of
The other of the pair of lift cord openings 93 seen in
Referring to
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Within the first and second tubular vertical ladder cords 305 and 307, a first lift cord 311 and a second lift cord 313, are seen. Lift cords 311 and 313 can be the same as lift cords 203 and 205. First and second tubular vertical ladder cords 305 and 307 can be equivalent to ladder cords 207 and 209 shown engaging the combination slat angle adjustment and window covering opening lift sets 31 as seen in
Upward displacement of the first and second lift cords 311 and 313 will cause the base slat 317 to lift upwardly. The weight of the slat 41 nearest the base slat 317 on the horizontal connector cords 309 will cause the segments of the first and second tubular vertical ladder cords 305 and 307 which are between the lowermost slat 41 and the base slat 317 to annularly collapse about their respective first and second lift cords 311 and 313, causing the lowermost slat 41 to stackably collect atop the base slat 317. As the first and second lift cords 311 and 313 continue upward, this causes the base slat 317 to continue to lift upwardly to cause the second lowest slat 41 and the base slat 317 to annularly collapse about their respective first and second lift cords 311 and 313, causing the second lowest slat 41 to stackably collect atop the lowermost slat 41. This action either continues until the window covering window blind set 21 are fully raised or until the user stops the process of opening the window covering window blind set 21 and leaves it partially open. Lowering the first and second lift cords 311 and 313 will cause the process described to reverse, namely that each successive slat 41 will be lifted from the stack and suspended by the horizontal connector cords 309 in a spaced vertical array typical of a window covering window blind set 21.
Given that the process of opening the window covering window blind set 21 involves the collapse of an annular tubular structure instead of the simple relaxation of a segment of ladder cord string between horizontal connector cords 309, the material of the first and second tubular vertical ladder cords 305 and 307 should be selected to be soft and deformable enough to allow the slats 41 to stack. The first and second tubular vertical ladder cords 305 and 307 may be made of thin, synthetic material which will readily deform. Failure of the ladder cord segments to deform will lengthen the effective stack of slats 41 near the head rail when the window covering window blind set 21 is in the open position. Free movement of the first and second lift cords 311 and 313 should also preferably enable the horizontal connector cords 309 to be effectively and sturdily connected between the first and second tubular vertical ladder cords 305 and 307 to give support to the slats 41 in the spaced vertical array position.
This does not mean that the first and second tubular vertical ladder cords 305 and 307 need be longitudinally homogeneous. The length of the first and second tubular vertical ladder cords 305 and 307 may include short distance stiffening reinforcement or placement of fittings at or near the point of support for the horizontal connector cords 309.
Preferably such fittings will facilitate close stacking of slats 41, provide for insulation of any propensity for undue wear near the points of attachment of the horizontal connector cords 309, and provide for some orderly movement of the segments of the first and second tubular vertical ladder cords 305 and 307 into an orderly orientation during stacking of the slats 41 which occurs during opening of the window covering window blind set 21. In some cases segments of the first and second tubular vertical ladder cords 305 and 307 may have an accordion-like partially controlled or planned deformation. With the use of the first and second tubular vertical ladder cord segments 305 and 307, a child cannot “fish out” a segment of either the first or second lift cords 311 and 313 to form a dangerous noose or loop.
Referring to
Referring to
The manner of supporting the first and second tubular vertical ladder cord 305 and 307 at the top of the window covering window blind set 21 near or within the head rail 23 can be performed in a number of ways. Referring to
The overall idea to be emphasized is that where the physical separation of the first lift cord 311 and first tubular vertical ladder cord 305 is expected to occur a few centimeters below the head rail 23, so that the combination slat angle adjustment and window covering opening lift set 31, 231 will have any lift cord (such as lift cords 203, 205, 311, or 313 or other lift cords which may be shown below), separate and apart from any ladder cord (such as the ladder cord 207, 209, 305, 307, or other ladder cords which may be shown below), supplied to such combination slat angle adjustment and window covering opening lift set 31, 231 in a separated manner. Such separation of any lift cord and any ladder cord can be configured to occur within head rail 23.
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While the present invention has been described in terms of a system and method which facilitates bi-directional single control input which can be utilized for both slat tilting adjustment as well as for raising and lowering the slats of a window covering, one skilled in the art will realize that the structure and techniques of the present invention can be applied to many structures, including any structure or technique where the actuation force and control input is preferably limited to a single structure located at a single point of input and where cords and lines are to be kept away from inadvertent contact with children and pets.
Although the invention has been derived with reference to particular illustrative embodiments thereof, many changes and modifications of the invention may become apparent to those skilled in the art without departing from the spirit and scope of the invention. Therefore, included within the patent warranted hereon are all such changes and modifications as may reasonably and properly be included within the scope of this contribution to the art.
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Number | Date | Country | |
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