The invention relates to window coverings and more particularly to an operating system for controlling the operation of the window covering. A window covering may comprise a head rail from which a panel is suspended. The head rail may be mounted to a window frame or other architectural feature. The panel may be supported by lift cords to raise and lower the panel relative to the head rail. The raising and lowering of the panel may be controlled using pull cords or the raising and lowering of the panel may comprise a “cordless” system where the panel is raised and lowered by direct manipulation of the panel.
In one embodiment, an operating system for a window covering comprises at least one spring motor, at least one variable force brake, and at least one lift spool assembly operatively coupled to a panel for raising and lowering a panel. An effective shaft is operatively coupled to and synchronizes the spring motor, the variable force brake, and the lift spool. The variable force brake comprises an outer race selectively coupled for rotation with the shaft by a one-way clutch where the outer race of the brake is in contact with a brake member such that the braking force applied by the brake member to the outer race varies as the panel is raised and lowered.
In some embodiments, a variable force brake for a window covering has a shaft operatively coupled to a panel for raising and lowering the panel. The variable force brake comprises a one-way clutch operatively coupled to the shaft. A brake member is operatively engaged with the one-way clutch to apply a brake force to the one-way clutch when the shaft is rotated. The magnitude of the brake force applied to the one-way clutch is determined by the rotational position of the shaft.
A cam may rotate when the effective shaft rotates, the cam moving a cam follower operatively engaged with the brake member to vary the force of the brake against the one-way clutch. The cam follower may move an adjustment mechanism that engages the brake member. The outer race may have a generally cylindrical shape that defines a cylindrical brake surface and the brake member may comprise a band brake that is in contact with the brake surface. The band brake may have a first end and a second movable end where the movable end is moved toward the second end to adjust the force applied by the brake to the one-way clutch by the adjustment mechanism. The adjustment mechanism may adjust the compression of a spring that exerts a variable force on the brake member. The magnitude of the braking force may be varied over a range and the range may be adjustable. The one-way clutch may comprise a one-way needle bearing comprising a plurality of needle bearings that receive the effective shaft where the one-way needle bearing is mounted for rotation with the outer race. The cam may be operatively connected to the effective shaft such that the cam rotates when the effective shaft rotates where the cam has a cam surface that is shaped to define a force curve where the force curve increases the braking force when the panel is moved in a first direction and decreases the braking force when the panel is moved in a second direction. The slope of the force curve may change over the extent of the cam surface. The brake member may have a first end and a second movable end where the movable end is moved toward the second end to adjust the force applied by the brake member to the one-way clutch by the adjustment mechanism.
Embodiments of the present invention will be described more fully hereinafter with reference to the accompanying drawings, in which embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like references numbers are used to refer to like elements throughout.
It will be understood that, although the terms first, second, etc. may be used herein to describe various elements, these elements should not be limited by these terms. These terms are only used to distinguish one element from another. For example, a first element could be termed a second element, and, similarly, a second element could be termed a first element, without departing from the scope of the present invention. As used herein, the term “and/or” includes any and all combinations of one or more of the associated listed items.
Relative terms such as “below” or “above” or “upper” or “lower” or “horizontal” or “vertical” or “top” or “bottom” or “front” or “rear” may be used herein to describe a relationship of one element, area or region to another element, area or region as illustrated in the figures. It will be understood that these terms are intended to encompass different orientations of the device in addition to the orientation depicted in the figures.
Referring to
The shade panel 4 may be supported by lift cords 21 that are connected to or near the bottom edge of the panel 4 or to the bottom rail 19. The lift cords 21 may be retracted toward the head rail 18 to raise the shade or extended way from the head rail to lower the shade. The lift cords 21 may be operatively connected to the operating system that may be used to raise and lower the shade panel as will hereinafter be described. In one type of window covering, known as a privacy panel, each lift cord extends down the outside of one side of the panel, around the bottom of the panel and up the outside of the other side of the panel, as shown in
For a slatted blind, the slats 17 are also supported by a tilt cord 20 that functions to tilt the slats 17 between open positions where the slats 17 are spaced from one another and closed positions where the slats 17 are disposed in an abutting, overlapping manner. The tilt cord 20 may comprise a ladder cord as shown that supports the individual slats 17 where manipulation of the ladder cord results in the tilting of the slats 17 between an open position, closed positions and any intermediate position. The tilt cord 20 may be controlled by a user control 25 such as a control wand or cord that is manipulated by the user to adjust the opening and closing of the slats. Each tilt cord 20 may comprise a ladder cord that has a plurality of rungs 26 that are connected to and supported at each end by vertical support cords 28 and 30. A slat 17 rests on top of is otherwise supported by each rung 26. A drum or other control device may be rotated by a user using a control 25 such that the front vertical support cord 28 may be raised or lowered while the back vertical support cord 30 is simultaneously lowered or raised, respectively, to tilt the rungs 26 and the slats 17. Typically, the slats will be supported by two or more tilt cords 20 and two or more lift cords 21 depending upon the width of the window covering. While specific embodiments of a window covering are disclosed, the window covering may have a wide variety of constructions and configurations.
The operating system for controlling movement (raising and lowering) of the panel uses a cordless design where the raising and lowering of the panel is adjusted by manually moving the panel into position and then releasing the panel. The operating system, if balanced properly, holds the panel in position without the panel sagging (lowering) or creeping (rising). The operating system described herein may be used to control the movement of the bottom edge of a traditional panel and/or the top edge of a top down panel. The operating system uses spring motors, take-up spools and brakes to balance the load of the panel such that it may be moved into a desired position without sagging or creeping. It is difficult to balance the load of a window covering panel because the forces exerted by the spring motor, brake and system friction must be balanced against the supported load of the panel where the load of the panel supported by the lift cords varies as the panel is raised and lowered. As a result, cordless window coverings have been limited to custom blinds where the window covering may be weighted to balance against the forces generated by the spring motor, brake and system friction. The operating system of the invention is an improved cordless operating system that is more easily and effectively balanced and is less expensive than existing systems. As a result, the operating system of the invention may be used with size-in-store window coverings, lower cost window coverings as well as custom blinds. With size-in-store blinds the operating system is located such that the width of the window covering may be cut down to a desired size outside of the factory without adversely affecting the operating system. The operating system may be easily tuned to balance the size of the panel even after being cut down in a size-in-store operation.
An embodiment of the operating system of the invention is shown in
According to one embodiment, the brake 42 may be a one-way brake that applies a braking force on the shaft 46 that resists rotation of the shaft in the lowering direction such that sagging of the window covering is prevented. When a user raises the panel 4, the spring motors 40 wind the lift cords on the spools of the lift spool assemblies 44 and assist the user in raising the panel. When the user releases the panel 4, the brake 42 holds the shaft 46 in the desired position and prevents sagging of the panel. To lower the panel 4, the user pulls down on the bottom of the panel 4 (or on the top of the panel in a top down shade) to overcome the brake force generated by brake 42 and the forces generated by the spring motors 40. However, as described further herein, a one-way brake may be applied in the opposite direction to resist rotation of the shaft in the raising direction.
Referring to
Description of the spring motor 40 will be described with reference to
The spring motor 40 comprises a power spool 60 having a drum 62 for receiving a spring 64. Although not required in all embodiments, according to one embodiment, the power spool 60 also comprises a gear 66 mounted for rotation with the drum 62. Power spool 60 rotates about an axis formed by axles 70 that are supported in apertures 72 formed in side plates 68. A through hole 74 extends through the power spool 60 and defines the axis of rotation of the spool (
The spring motor 40 also comprises a take-up spool 80 including a drum 82 for receiving the spring 64. The take-up spool 80 is mounted on an idler gear 84 such that the take-up spool 80 and idler gear 84 may rotate both together and relative to one another as will hereinafter be described. The idler gear 84 comprises a gear 86 that is mounted to a post 88 where the post 88 is received in and extends through a sleeve 90 in drum 82 and forms the rotational axis of the drum 82 and the idler gear 84. The post 88 and sleeve 90 frictionally engage one another but may rotate relative to one another when the friction between the post 88 and sleeve 90 is overcome. Post 88 freely rotates about an axis formed by pins 92 that extend from side plates 68. The pins 92 engage a bore 92 that extends through the post 88. Other mounting mechanisms for rotatably mounting the idler gear 84 may also be used.
The power spool 60 and the idler gear 84 are mounted between the side plates 68 such that the power spool 60 and idler gear 84 may freely rotate. The power spool 60 and the idler gear 84 are positioned such that gear 66 engages gear 86. Spring 64 is wound on the power spool 60 and take-up spool 80 such that as the panel 4 is lowered the spring 64 is wound onto the power spool 60 and is unwound from the take-up spool 80. Energy is stored in the spring 64 as it is wound on the power spool 60. As the panel is raised the spring 64 unwinds from the power spool 60 back onto the take-up spool to rotate the shaft 46 and wind the lift cords 21 on the spools of lift spool assemblies 44.
According to one embodiment, the spring 64 may comprise a variable force spring and may be designed such that maximum torque is generated when the panel is fully raised and the load on the lift cords 21 from supporting the full weight of the panel is greatest and a minimum torque is generated when the panel 4 is fully lowered and the load on the lift cords from supporting the panel is lowest. Because the spring force is relatively low when the panel 4 is initially raised from the fully lowered position, the possibility exists that the spring 64 will “billow” around the take-up spool 80 rather than being tightly wound around the spool. To prevent the billowing of the spring 64 the power spool 60 and take-up spool 80 may be geared together by gears 66 and 86 such that the take-up spool 80 is forced to rotate and wind the spring 64 when the panel 4 is initially raised. However, because the speed at which the spring 46 moves does not match the rotational speed of the take-up spool 80 over the entire range of motion, the take-up spool 80 and power spool 60 may spin at different speeds over the range of motion. Therefore, it may be preferable to allow the drums 82 and 62 to spin independently of one another over at least portions of the range of motion of the panel. By mounting the take-up spool drum 82 on post 88 of idler gear 84, the drum 82 may spin freely relative to the idler gear 84 when the friction between the idler gear 84 and drum 82 is overcome to allow independent rotation of the drum 80 relative to power spool 60. If the spring 64 does not billow or the billowing of the spring does not cause binding or otherwise interfere with the operation of the motor, the idler gear 84 and/or drive gear 66 may be eliminated and take-up spool 80 may be allowed to rotate independently of power spool 60 throughout the entire range of motion.
The arrangement of the spring 64 will be described. According to some embodiments, it may be desired to approximately match the output torque of the spring 64 to the load supported by the spring motor 40 over the entire range of motion of the panel 4 between the fully raised position and the fully lowered position. In a typical window covering the load supported by the lift cords increases as the panel is raised and decreases as the panel is lowered. This is because as the panel is raised the panel stacks on top of itself and on the bottom rail and the stacked load is supported by the lift cords. As the panel is lowered the panel unstacks such that more of the load of the panel is transferred to and supported by the tilt cords and/or head rail, depending on the style of window covering, and less of the load is supported by the lift cords. Thus, it may be desirable to increase the torque output of the spring motor 40 as the panel is raised and to decrease the torque output as the panel is lowered.
To provide a variable force output, a variable force spring 64 may be used. According to one embodiment, the natural diameter of the spring 64 varies along the length of the spring to produce a variable output. The variable force spring can be created by winding a metal strip into a coil where the spring has a smaller diameter on the inside end of the coil (higher spring force) and an increasingly larger diameter to the outside end of the coil (lower spring force). However, if the spring 64 is mounted on the motor 40 as coiled the smaller diameter would be on the inside of the spring coil and the torque output by the motor 40 would increase as the coil is extended (i.e. the torque would increase as the panel is lowered). This is the opposite force curve desired in the operation of a window covering. To achieve the desired force curve, the spring is mounted on the spools in a reverse manner such that the larger natural diameter is on the inside end of the coil at end 64a and the smaller natural diameter is on the outside end of the coil at end 64b (
It is appreciated that a variable force spring 64 can be generated in a number of other manners, which may also be utilized in the embodiments described herein. For example, a variable force spring may be formed by tapering the spring from a first end of the spring to a second end of the spring such that the thickness and/or width of the spring varies (rather than or in addition to its curvature) along its length. Another example of a variable force spring comprises a spring having a series of apertures or other cutouts formed along the length of the spring where the cutouts increase in size from a first end of the spring to a second end of the spring. Other embodiments for creating a variable force spring may also be used.
In one embodiment, to create the spring motor 40, the coil spring 64 is wrapped on the storage spool 80 and the storage spool 80 and power spool 60 are mounted between the side plates 68. The spring 64 is then reverse wrapped on the power spool 80 to preload the spring. The power spool 80 is held in the reversed wrap condition such as by inserting a pin 99 that engages the power spool 60 and one of the side plates 68. The reverse wrapped (preloaded) spring motor 40 is inserted into the head rail of the blind and is connected to the shaft 46 when the panel 4 is in the in the fully lowered position.
It may be difficult to construct the spring motor 40 such that the torque generated by the spring motor exactly matches the varying load of the panel 4. As a result, the spring motor 40 may be designed such that it is intentionally either underpowered or overpowered relative to the load of the panel. If the spring motor 40 is slightly underpowered the panel will tend to sag and if the spring motor is slightly overpowered the panel will tend to creep. A one-way brake 42 is used to prevent the sagging or creeping of the panel 4 depending on whether an overpowered or underpowered spring motor is used. In the illustrated embodiment the spring motor 40 is designed such that the force generated by the spring motor is slightly underpowered relative to the load of the panel 4 and the brake 42 is used to prevent sagging. The operating system of the invention may also be used with an overpowered spring motor where the brake function is reversed to prevent creeping.
One embodiment of a brake 42 suitable for use in the operating system of the invention is shown in
The spring motor 40 and brake 42 may also be formed as separate units that are independently mounted to the shaft 46. The brake 42 comprises an outer race 106 and an inner race 108 where the inner race 108 is connected to the outer race 106 using a one-way clutch. The inner race 108 is mounted for rotation with the shaft 46 and the outer race 106 is in contact with an adjustable band brake 110. The brake force may be applied to the outer race using a mechanism other than a band brake such as a clamp brake, brake shoe and the like.
Referring to
The inner race 108 is rotatably mounted in the bore 118 of the outer race 106 such that the inner race 108 may rotate relative to the outer race 106. The inner race 108 comprises a first section 108a and a second section 108b that together form the inner race (
A ball bearing 128 is positioned in the each of the spaces defined between the outer recesses 122, 124 and 126 and the inner recesses 144, 146 and 148. The ball bearings 128 are trapped between the web 116 of the outer race 106 and the side walls 120 of the inner race but are free to move in the spaces defined by the inner recesses 144, 146 and 148 and the outer recesses 122, 124 and 126.
A brake member is provided that contacts the brake surface 114 on outer race 106 to apply the braking force to the system. Referring to
Reference will be made to
When the panel is lowered the shaft 46 rotates counterclockwise as shown in
To assemble the brake 42, three ball bearings 128 are inserted into the recesses 122, 124 and 126 on a first side of the outer race 106. The first inner race section 108a is inserted into the outer race 106 to hold the three ball bearings in place. The assembly is flipped over and three ball bearings are inserted into the recesses 122, 124 and 126 on the second side of the outer race 106. The second inner race section 108b is inserted into the outer race 106 to hold the three ball bearings in place. The assembled inner race 108 and outer race 106 are inserted into the band brake 110 and the brake assembly is trapped between the side plates 100 and 102. In the illustrated embodiment the side plates 100 and 102 are snap fit together by inserting pins 101 formed on one of the side plates into mating receptacles 103 formed on the other side plate. The side plates may also be connected using separate fasteners, adhesive or the like.
Variable Force Brake
The brake described above is a substantially constant force brake where the brake force applied to the shaft 46 remains constant during operation of the blind. While the brake force applied by the brake may be adjusted by turning screw 162 to adjust the force applied by the spring 168, once adjusted the force remains substantially constant or near constant as the panel 4 is raised and/or lowered. It will be understood that as the panel 4 is raised the amount of brake force required to hold the panel in position increases because as the slats are stacked on top of one another the weight of the stacked slats increases. The maximum load on the brake is when the panel is in the completely raised position where the lift cords support the weight of the entire stack of slats. As the panel is lowered the slats are sequentially supported by the tilt or ladder cords and removed from the stack of slats supported by the lift cords. As a result, the load on the lift cords lessens as the panel is lowered with the smallest load being when the panel is in the fully lowered position. With a constant force brake, the brake force applied to the system must be set to the highest value required to hold the maximum load (when the panel is completely raised). This brake force remains constant even as the panel is lowered and the brake force required to hold the panel progressively lessens. As a result, the user must apply increasing force to the panel as the panel is lowered. As the panel approaches the completely lowered position the amount of force required from the user to lower the panel may be approximately twice the force required from the user to lower the panel at the completely raised position. In addition to the increased force required to lower the panel, the use of a constant force brake may increase the wear on the brake components. As a result, the brake surfaces wear faster than necessary, resulting in the user having to adjust the screw 162 more frequently than may be desirable.
The variable force brake described herein varies the brake force applied to the system as the panel is raised and lowered. In accordance with one embodiment, the variable force brake is arranged such that the brake force increases as the panel is raised and the brake force decreases as the panel is lowered. In one embodiment the brake force may be at its maximum in the raised or nearly raised position, and at its minimum (or less than maximum) when the panel is in its lowered position. The brake force applied to the system may be varied over the range of motion of the panel to more closely align the applied brake force to the load supported by the system.
One embodiment of a variable force bake is shown in
An adjustment mechanism is provided for adjusting and varying the position of the movable end 1110b of the band brake 110 relative to the stationary end 1110a of the band brake to vary the force applied to the one-way clutch by the brake. The adjustment mechanism according to one embodiment may comprise a member 1200 (see
The head 1202 includes a flange 1205 that is dimensioned such that it can support a compression spring 1207 (see
With this construction the member 1200 may be moved relative to the band brake 110 such that the head 1202 is moved toward and away from the band brake to compress the spring 1207 to a greater or lesser degree to increase and decrease the force applied by the spring 1207 on the movable end 1110b of the band brake. When the spring 1207 is more compressed and the force applied by the spring 1207 to the movable end 1110b of the band brake increases the braking force applied by the band brake on the outer race 106 increases. Likewise, when the spring 1207 is less compressed and the force applied by the spring 1207 to the movable end 1110b of the band brake decreases the braking force applied by the band brake on the outer race 106 decreases. Thus, movement of the member 1200 varies the brake force applied by the variable force brake to the system.
Because the head 1202 is threaded onto the threaded portion 1201 the range of force applied by the spring 1207 to the system may be adjusted. Tightening the head 1202 onto the threaded portion 1201 compresses the spring between the head 1202 and the movable end 1110b of the band brake 110 to increase the range of the brake force and loosening the head 1202 on the threaded portion 1201 allows the spring 1207 to expand between the head and the movable end of the band brake to decrease the range of the brake force. The range of the magnitude of the force applied by the brake member to the one-way clutch is the range between the highest brake force and the lowest brake force for a particular panel. This range may be shifted higher or lower by adjusting head 1202 on member 1200.
The band brake 110 with the adjustment mechanism and one-way clutch are mounted between an outer support member 1100 and an inner support member 1210 and operate to apply a variable braking force to the shaft 46. A transmission 1211 is mounted between the inner support member 1210 and an outer support member 1212 that is operatively coupled to the shaft 46 for transmitting the rotary motion of the shaft to a cam 1213. A lever mechanism 1214 is mounted between the cam 1213 and the adjustment mechanism 1200 for transmitting the rotary motion of the cam 1213 to the adjustment mechanism 1200 to vary the force applied by the brake.
The transmission 1211 comprises a gear train for transmitting the rotary motion of the lift shaft 46 to the cam 1213. In one embodiment an input gear 1215 is mounted on the shaft such that the gear rotates with the shaft. The gear 1215 is keyed to the shaft 46 such as by teeth 1217 that mates with grooves or flat faces formed in the shaft 46. The shaft 46 also engages the inner race 108 as previously described such that the inner race 108 also rotates with shaft 46. In one embodiment the shaft 46, inner race 108 and gear 1215 are aligned such that the shaft 46 may be inserted through apertures formed in gear 1215 and inner race 108. Suitable apertures are formed in the supports 1212, 1210 and 1100 to allow passage of the shaft 46.
Cam 1213 is mounted on the output gear 1219 and a gear train comprising double gears 1220 operatively connects the input gear 1215 to the output gear 1219. The gear ratios are selected such the output gear 1219 and cam 1213 rotate less than 360 degrees in each direction as the panel 4 travels between its completely raised position and its completely lowered position. In some embodiments the cam rotates approximately between 270 and 340 degrees, such as in one embodiment between approximately 300 and 310 degrees, or in another embodiment the cam rotates approximately 307 degrees. The shaft 46 makes multiple revolutions as the panel 4 is moved between the completely lowered and completely raised positions. Using the gear train to reduce the rotation of the cam 1213 to less than 360 degrees allows the cam to be provided with a simple curve where less than 360 degrees of rotation of the cam adjusts the force applied by the brake 110 to the outer race 106 between a maximum value and a minimum value as will be described. While the use of gearing to limit the rotation of the cam 1213 to less than 360 degrees simplifies the construction of the assembly, the transmission may comprise other mechanisms than the gear train as shown herein. Moreover, limiting the cam to less than 360 degrees of rotation also simplifies the shape of the cam; however, the cam may rotate more than 360 degrees with the use of a more complex cam surface and follower.
The cam 1213 moves a cam follower 1221 (
The cam follower 1221 comprises an abutment 1230 that rides on the cam surface 1231 of cam 1213 such that as the cam 1213 rotates, the engagement of the curved cam surface 1231 with abutment surface 1231 moves the cam follower 1221 on track 1222 between the raised and lowered positions.
In operation, as the cam 1213 rotates the curved cam surface 1231 moves the cam follower 1221 in a linear reciprocating motion. The linear reciprocating motion of the cam follower 1221 is transmitted to the lever 1224 such that the end 1226 of the lever 1224 connected to the cam follower 1221 rises and falls with the cam follower 1221. In one embodiment, one rotation of the cam 1213 (e.g. 307 degrees of rotation) in a first direction raises the cam follower 1221 from the lowered position to the raised position which, in turn, lifts the end 1226 of the lever 1224 connected to the cam follower 1221. As the one end 1226 of the lever 1224 is lifted the opposite end 1229 of the lever 1224, connected to the adjustment member 1200, is lowered. As the opposite end of the lever 1229 is lowered the adjustment member 1200 is translated relative to the band brake such that the head 1202 is moved away from the band brake 110. As the head 1202 is moved away from the band brake 110 the spring 1207 expands and is under less compression such that the force applied by the spring 1207 on the band brake 110 and the corresponding brake force of the band brake 110 on the one-way clutch is reduced. When the cam 1213 is rotated one rotation in a second direction opposite to the first direction, the cam 1213 allows the cam follower 1221 to lower from the raised position to the lowered position which, in turn, lowers the end 1226 of the lever 1224 connected to cam follower 1221 from the raised position to the lowered position. As the one end 1226 of the lever 1224 is lowered, the opposite end 1229 of the lever 1224 is raised. As the opposite end 1229 of the lever 1224 is raised the adjustment member 1200 is translated relative to the band brake 110 such that the head 1202 is moved toward the band brake 110. As the head 1202 is moved toward the band brake, the spring 1207 is compressed such that the force applied by the spring 1207 on the band brake 110 and the corresponding brake force of the band brake on the one-way clutch is increased.
The operation of the variable force brake will be described with respect to the operation of a window covering. Assume that the panel 4 is in the fully raised position where the load on the lift cords is at a maximum. In this position the brake force applied by the variable force brake on the shaft 46 is also at, or near, a maximum, or at least greater than when the panel 4 is in a lower position. In this position the cam 1213 is positioned such that the cam follower 1221 is in the lowered position. With the cam follower 1221 in the lowered position the end 1229 of the lever 1224 connected to the adjustment member 1200 is in the raised position. In this position the lever 1224 pulls on the adjustment member 1200 such that the head 1202 is in a position closest to the band brake 110 where the spring 1207 is maximally compressed and the force applied by the band brake 110 to the one-way clutch is at a maximum value. It is appreciated that in other embodiments, the relationship between the cam 1213, the follower 1221, the lever 1224, and the adjustment member 1200 may differ from that described here and still achieve the same results of increasing brake force as the panel 4 is raised and decreasing braking force as the panel 4 is lowered as a result of the profile of the cam 1213 and follower in operable communication with the braking mechanism utilized.
In the embodiment shown and described, as a user lowers the panel 4 from the fully raised position to the lowered position the lift shaft 46 is rotated by the unspooling lift cords. The force to lower the panel and unwind the lift cords is provided by the user pulling down on the end of the panel 4. As the panel is lowered the rotation of the lift shaft 46 rotates the cam 1231 via the transmission 1211. As previously explained, the gear train is configured such that the cam 1231 rotates less than 360 degrees between the completely raised position of the panel 4 and the completely lowered position of the panel 4 even though the shaft 46 rotates through multiple revolutions.
The cam surface 1231 is shaped such that as the cam 1213 rotates the cam follower 1221 is moved upward such that the end 1229 of the lever 1224 connected to the adjustment member 1200 is moved downward. The cam surface 1231 is shaped to define a force curve where the force curve increases the braking force when the panel is moved in a first direction and decreases the braking force when the panel is moved in a second direction. The slope of the force curve changes over the extent of the cam surface by varying the distance of the cam surface 1213 from the axis of rotation of the cam along the extent of the cam surface. For example, the cam surface may comprise a curved surface that generally extends away from the axis of rotation of the cam from one end of the cam surface to the opposite end of the cam surface such that the cam surface defines generally a spiral. The spiral may comprise a variety of shapes and the slope of the curve may change over the length of the cam surface. Moreover, other shapes may be used and the cam surface may comprise flat portions arcs of a circle where the force does not change for a portion of the cam surface.
As the end of the lever 1224 moves downward the head 1202 is moved away from the band brake such that the spring 1202 is less compressed and the force applied by the spring 1207 on the movable part 1110b of the band brake 110 is lowered to thereby lower the braking force applied to the system. When the panel 4 is raised the operation of the mechanism is reversed such that the cam 1213 rotates in the opposite direction and the cam follower 1221 is moved downward such that the distal end 1229 of the lever 1224 is moved upward. As the distal end 1229 of the lever 1224 moves upward the head 1202 is moved toward the band brake 110 such that the spring 1207 is increasingly compressed and the force applied by the spring 1207 on the movable part 1110b of the band brake 110 increases to thereby increase the braking force applied to the system.
Thus, increasing braking force is applied to the system as the panel is raised until the maximum (or at least greater) brake force is applied at the fully raised position and decreasing braking force is applied to the system as the panel is lowered until the minimum (or at least lesser) brake force is applied at the fully lowered position. The change in the braking force as the panel is raised and lowered may be controlled by the shape of the cam surface 1231. The steeper the curve of the cam surface the faster the change in force over one rotation of the cam. Thus the cam may be designed to accommodate different types of window coverings having different weight slats and different drop lengths. The force curve may change continuously over the range of motion of the panel or it may be made variable by changing the slope of the curve of the cam surface over its length. The force applied may be varied to a greater or lesser degree at different points in the travel of the panel.
Because the braking force may be controlled to better respond to the load on the system from the panel, the variable force brake does not have to operate at the maximum or increased value throughout the entire range of motion of the panel. The application of a variable brake force also minimizes wear on the brake components. The application of a variable brake force also minimizes the force that the user must overcome as the user moves the panel to the completely lowered position providing better “feel” to the user and making operation of the window covering easier. For example in some embodiments of a window covering with a constant force brake the torque required to lower the panel at the fully lowered position is approximately 17.4 in-lb while for the same window covering using the variable force brake of the invention the torque required to lower the panel at the fully lowered position is approximately 3.8 in-lb.
Because the head 1202 is threaded on the threaded portion 1201 of the adjustment member 1200, the range of force applied by the brake may be increased or decreased based on how far the head 1202 is threaded onto the adjustment member 1200 and correspondingly how much the spring 1207 is compressed. To adjust the position of the head on the adjustment member the head may be formed with a keyed surface 1231 that may be engaged by a tool. In one embodiment the keyed surface 1231 may comprise a slot suitable to be engaged by a tool such as a screwdriver although other keyed connections may be used. The brake may apply a variable brake force without using the threaded engagement between the head and the adjustment member by fixing the head in position on the adjustment member; however, this arrangement would not allow adjustment of the applied range of force. Thus, for any given style and material of window covering the range of force applied by the variable brake may be modified to correspond to the load of the specific panel.
An alternate embodiment of the variable force brake is shown in
An alternate embodiment of the brake is shown in
An alternate embodiment of a one-way brake is shown in
The one-way clutch comprises a one-way needle bearing assembly 318 that is trapped between the blocks 302 and 304 such that the pressure created by the clamping action of the blocks 302 and 304 is applied to the external brake surface 321 of the needle bearing assembly 318. The blocks 302 and 304 may include cradles or brake surfaces 320 or other similar structures for retaining the needle bearing assembly 318 that act on the external brake surface 321 of the needle bearing assembly. The needle bearing assembly 318 comprises an annular housing 322. A plurality of one-way needle bearings 324 are positioned around the interior opening of housing 322. The one-way needle bearings 324 may rotate in a first direction relative to the housing 322 but are prevented from rotating in the opposite direction. The shaft 46 is inserted through the needle bearing assembly 318 such that it engages and rides on the needle bearings 324. When the shaft 46 is rotated in a first direction (corresponding to raising the panel) the needle bearings 324 are free to rotate relative to the housing 322 and the brake has no effect on the rotation of shaft 46. When the shaft is rotated in a second direction (corresponding to lowering the panel) the needle bearings 324 are locked between shaft 46 and the housing 322 causing the housing 322 to rotate with shaft 46 against the brake force generated by the blocks 302 and 304 on the brake surface 321.
Another embodiment of a one-way brake is shown in
Another embodiment of a one-way brake is shown in
One embodiment of a lift spool system 44 suitable for use in the operating system of the invention is shown in
Referring to
The base 170 includes a first offset surface 176 and a second offset surface 178 arranged below spools 160 and 164, respectively. The spools 160 and 164 are arranged such that the drive spool 160 is disposed over one offset surface 176 and the driven spool 164 is disposed over the other offset surface 178. The offset surfaces 176 and 178 are disposed a distance from the surfaces of the spools 160 and 164 that, in one embodiment, can be less than two times the diameter of the lift cords to guide the lift cords onto the spools in a non-overlapping manner. The spools 160 and 164 are formed with a sloped arcuate receiving end 192, which may have an arcuate shape in one embodiment, at the end of the spool that receives the lift cord. The receiving end 192 narrows to opposite end 194 such that the spools have a tapered shape. The arcuate sections of spools 160 and 164 force the cords to slip downward toward the slightly tapered end 194 of the spools. Decreasing the surface friction of the spool material or increasing the slope of the arcuate section makes the cord slide down the spool more easily. However, if the curvature of the arcuate section is too steep the cord may be more likely to wind on top of itself. The slight taper of the spools ensures that the cord sections already wrapped on the spool remain looser than the cord sections being wrapped on the spools to allow the cords to be pushed down the spool with minimum force with each winding of the cord. The tapered shape of the spools 160 and 164 facilitates the orderly winding of the lift cords on the spools such that as each cord is wound on a spool the cord is moved from the wider receiving end 192 toward the narrow end 194 such that the cord does not wind on itself.
Referring to
To further maintain the cord on the spools a cradle cover 720 may be provided on the top of the spools that is spaced from the spools a distance such that the cord is constrained to wrap onto the spools rather than jumping off the spools as shown in
The illustrated embodiment shows a two spool arrangement that is used with a privacy-type lift cord. A privacy-type lift cord is wound around one spool, extends down the front side of the panel, wraps under or through the bottom rail and extends up the back side of the panel 4 where it is wound around the second spool as shown in
Assembly of the operating system will now be described according to one example embodiment. A head rail 18 is provided that may have an interior space for receiving the operating system as shown in
As previously described, the brake 42 and one of the motors 40 may be combined into a single unit if desired. In one embodiment, the components of the system snap into the head rail such that separate fasteners are not required, however, other mounting mechanisms including the use of separate fasteners may be used. While an embodiment of a lift system is shown in
The lift spool systems 44 are arranged in a one to one relationship with the lift cords 21 such that for a typical window covering where two lift cords are used, two lift spool systems 44 are also used. For larger window coverings, three or more lift cords may be used and a corresponding number of lift spool systems 44 are also used. Each lift spool system 44 can be arranged proximate to (i.e. approximately above) the associated lift cord such that the lift cord is wrapped onto the spool at the large diameter receiving end 192 of the spool. Apertures are provided in the head rail 18 and cradle 168 to receive the lift cords.
The assembly of a privacy-type lift cords will now be described with reference to
A first end of the lift cord 21 is threaded through an aperture in the head rail and through an aperture 714 in the lift spool cradle 168. The cord is operatively coupled to the drive spool 160 such that rotation of the spool winds the lift cord on the spool. In one embodiment a knot is tied in the first end of the lift cord 21 and the cord is inserted into a slot 199 on the drive spool 160 (
The panel 4 is then suspended vertically from the head rail 18 by the lift cords. The lift cords 21 are wound on the spools 160 and 164 to take the slack out of the lift cords such that the panel is suspended at its full length and there is no slack in the lift cords. The shaft 46 is inserted through the mating keyed receptacles on the motor(s) 40, brake(s) 42 and drive spool(s) 160 to create the lift system as shown, for example, in
In addition to adjusting the brake force during manufacture of the window covering or as part of a size-in-store operation the adjustment mechanism allows a user to adjust the braking force during use of the window covering. For example, a user may adjust the brake force if the system ever becomes out of balance during use. For example, if the force output by the spring motors changes over time, the user can loosen or tighten the brake to accommodate the change in motor output without returning the blind to the manufacturer or even removing the blind from the window. Moreover the adjustment of the brake force may be used to adjust the operating parameters of the window covering. For example if the user does not require the window covering to be raised completely to the head rail the brake force may be lowered. One example of such a use would be in a situation where an eight foot tall window covering is installed but a user can only reach six feet. As a result the user will not be raising the window covering the full eight foot height of the panel. Because the panel is not fully raised the full eight feet the brake never needs to hold the full weight of the stacked panel. As a result the brake force may be lowered such that the maximum brake force applied to the system is set to hold six feet of panel rather than the maximum eight feet. The user may want to lower the maximum brake force in this situation to lower the force that needs to be applied to the panel by the user to lower the panel.
For a top down shade, where the top edge of the panel may be raised and lowered relative to the head rail, the operating system may be connected to the top edge of the panel 4 to control the movement of the top edge of the panel. In top down shades the top edge of the panel may include a middle rail. The lift cords are connected to the top edge or middle rail rather than to the bottom edge of the panel or bottom rail. In a top down shade the load on the system increases as the panel is raised because as the top of the panel is raised more of the shade panel is suspended from the top rail (rather than resting on the bottom rail) such that the operating system operates in the same manner to support the load and facilitate the raising and lowering of the top edge of the panel as previously described. “Top down/bottom up” shades are also known where the top edge/middle rail and the bottom edge/bottom rail are independently movable. In such systems two operating systems may be used where one operating system is connected to the top edge/middle rail and the other operating system is connected to the bottom edge/bottom rail. The two operating systems operate independently to control the movement of the panel.
An example embodiment of a top down/bottom up window covering is shown in
Referring to
In one embodiment a single shaft 46 extending through all of the components may be used; however, in other embodiments the shaft may be provided as multiple segments where a segment extends between the components such as between the motors, cradle, and brake. For example, a first shaft segment may extend from the left end of the head rail through spool system 44a and motor 40a and terminate inside of the drive spool of spool system 44b where the shaft is operatively coupled to the drive spool. A second shaft segment may extend from, and be operatively coupled to, the drive spool of spool system 44b and extend through the remaining components. In such an embodiment, the shaft segments function as a single shaft because the shaft segments are operatively coupled to one another by the common component(s) (the drive spool of spool system 44b in the present example). While a system with a single shaft 46 and a two segment shaft have been described other embodiments using a greater number of shaft segments may be used where the shaft segments are coupled in series by the common components such that the shaft segments are operatively coupled to one another to form an effective shaft that synchronizes the movement of the components.
All of the components of the system may be disposed inside of the ends of the head rail 18 such that the head rail extends beyond each end of the lift system a desired length L. In one embodiment length L may be approximately 3 inches; however, length L may be varied to accommodate various cut down lengths. The length the head rail extends beyond the ends of the operating system may be cut off in a size-in-store operation such that the window covering may be sized to a customer desired size. While size-in-store systems and cutting machines are known, the operating system of the invention allows a window covering with a cordless operating system to be used in a size-in-store system.
Because the components are modular and independent from one another, the motors 40 may be positioned anywhere along the length of the shaft 46 and the motors do not have to be co-located with one another. This provides an advantage because the torques exerted on the shaft 46 by the motors 40 may be spread out along the length of the shaft 46 to shorten the length of the shaft over which the torques are applied. In systems that place all of the motors at one end of the shaft significant twisting forces are accumulated over the length of the shaft. In the system of the invention, where the motors 40 may be placed anywhere along the length of the shaft 46, the load accumulation may be minimized. For example, if four lift spool systems 44 are used and three motors 40 are required to handle the load of the panel 4, the motors 40 may be alternated with the lift spool systems 44 along the length of the shaft 46 such that the torsional load on the shaft is minimized. Moreover, the number of motors 40 is not tied to the number of lift cords 21, lift spool systems 44 or brakes 42 such that the motors, lift cords, lift spool systems and brakes may be provided as needed.
Additional lift spool systems 44, brakes 42 and motors 40 may also be added to the system by simply adding more components into the head rail before inserting the shaft 46. As a result, the system may be easily scaled to work with larger or smaller or heavier or lighter window coverings. Because all of the components are synchronized through the shaft 46, it is possible to scale up the system by multiplying the number of motors 40 by the factor of the window width. For example, for a particular window covering style the motor may be sized for a particular span (e.g. 12 inches) and then propagated in multiples of that basic span to create larger span window coverings or window coverings having a greater mass (e.g. panel mass may change with slatted blind compositions, such as real wood, faux wood, composites etc.). The length of the shaft 46 may be increased for larger and/or heavier window coverings to accommodate additional components but because the components may be located at any location along the length of the shaft excessive twisting loads are not created on the shaft. The operating system may also be scaled to very short spans, as small as 6 inches, by locating all of the components in close proximity to one another. The modular system simplifies the manufacture of the window covering, is scalable, allows easy replacement of components and is relatively inexpensive.
The operating system also accommodates a tilt system for use with slatted blinds where the slats may be tilted for light control and privacy in addition to being raised and lowered. The tilt system may be omitted in window coverings such as cellular shades or Roman shades or the like where tilting of slats is not required. Referring to
With any shade panel it is desirable to have the bottom edge of the panel and/or bottom rail level during use of the window covering. When the panel is in any raised position, the levelness of the bottom edge of the panel and/or bottom rail is directly related to the variation in lengths of the lift cords spanning the width of the window covering. Where one lift cord is shorter than the other lift cord, the bottom of the panel will angle upward toward the shorter lift cord. A system for equalizing the lengths of the lift cords to provide a level bottom rail is described with reference to
An adjustment assembly 200 (
Referring to
To use the adjustment assembly, a bore or hole 203 is formed on the bottom rail 19 that is dimensioned to receive the sleeve anchor 202. Typically, the sleeve anchor 202 is mounted on the bottom rail 19 so as to be vertically aligned with the lift spool assembly 44 and the lift cord 21. The portion of the lift cord 21 that passes below or through the bottom rail 19 (
The window covering is then supported from the head rail and the bottom rail 19 is checked for level. If it is not level, the longer lift cord (the lower end of the bottom rail) is adjusted. The length of the cord is adjusted by rotating the plug 216 in the sleeve anchor 202. As the plug 216 rotates, the cord 21 is wrapped around the plug 216 in drum 224 to shorten its effective length. The plugs 216 are rotated until the bottom rail is level. As the plug 216 is rotated projections 223 on the plug 216 ratchet over the projections 212 on the anchor sleeve 202 such that when the plug 216 is released the engaging projections hold the plug 216 in position relative to the anchor sleeve 202. Each “click” of the plug 216 over projections 212 may shorten or lengthen the lift cord a predetermined distance such as one-eighth of an inch such that if the user needs to shorten a lift cord a quarter of an inch the plug 216 is rotated two “clicks”. The ratcheting movement may provide tactile and audible feedback to the user. Once the lift cords are properly adjusted, the bottom of the tilt cord (if a tilt cord is used such as in a slatted blind) is inserted into one of the slots 226 or 227 on the head 220 of the plug 216. A cap 230 is then inserted over and engages the head 220 of the plug 216 and the rim 222 of sleeve anchor 202. The cap 230 holds the tilt cord in place and fixes the position of the plug 216 relative to the sleeve anchor 202. The cap 230 is provided with cross-members 231 that engage slots 226 and 227 and tabs 232 that engage mating surfaces on the sleeve anchor 202 to connect these components together. The cap 230 is also provided with slots 234 for receiving the tilt cords.
Specific embodiments of an invention are disclosed herein. One of ordinary skill in the art will recognize that the invention has other applications in other environments. Many embodiments are possible. The following claims are in no way intended to limit the scope of the invention to the specific embodiments described above.
The present application claims benefit of priority to the filing date of U.S. Provisional Application No. 61/877,788 filed on Sep. 13, 2013, the contents of which are hereby incorporated by reference herein in its entirety, and is a continuation-in-part of U.S. patent application Ser. No. 13/939,699 filed on Jul. 11, 2013, the contents of which are hereby incorporated by reference herein in its entirety, which, in turn, claims the benefit of U.S. Provisional Application No. 61/671,212 filed on Jul. 13, 2012, the contents of which are hereby incorporated by reference herein in its entirety.
Number | Name | Date | Kind |
---|---|---|---|
2119550 | Loughridge | Jun 1938 | A |
2663368 | Walker | Dec 1953 | A |
2701611 | Griesser | Feb 1955 | A |
3180400 | Rau | Apr 1965 | A |
3194343 | Sindlinger | Jul 1965 | A |
3289739 | Hensel | Dec 1966 | A |
3352349 | Hennequin | Nov 1967 | A |
3404504 | Taylor | Oct 1968 | A |
4042075 | Hehl | Aug 1977 | A |
4200135 | Hennequin | Apr 1980 | A |
4372432 | Waine et al. | Feb 1983 | A |
4498517 | Mase | Feb 1985 | A |
4697630 | Rude | Oct 1987 | A |
5154558 | McCallion | Oct 1992 | A |
5228491 | Rude et al. | Jul 1993 | A |
5328113 | De Chevron Villette et al. | Jul 1994 | A |
5375643 | Rude | Dec 1994 | A |
5482100 | Kuhar | Jan 1996 | A |
5531257 | Kuhar | Jul 1996 | A |
5725040 | Domel | Mar 1998 | A |
5799342 | Last | Sep 1998 | A |
5908062 | Fun | Jun 1999 | A |
5927370 | Judkins | Jul 1999 | A |
6012506 | Wang | Jan 2000 | A |
6056036 | Todd | May 2000 | A |
6116323 | Huang | Sep 2000 | A |
6149094 | Martin et al. | Nov 2000 | A |
6530863 | Balli | Mar 2003 | B2 |
6536503 | Anderson et al. | Mar 2003 | B1 |
6571853 | Ciuca | Jun 2003 | B1 |
6601635 | Ciuca | Aug 2003 | B2 |
6644375 | Palmer | Nov 2003 | B2 |
6675861 | Palmer | Jan 2004 | B2 |
6718707 | Marshall | Apr 2004 | B2 |
6792997 | Damiano | Sep 2004 | B2 |
6915831 | Anderson | Jul 2005 | B2 |
6945302 | Nien | Sep 2005 | B2 |
6948216 | Gaudyn et al. | Sep 2005 | B2 |
6968884 | Anderson et al. | Nov 2005 | B2 |
6986378 | Beaudoin | Jan 2006 | B2 |
7096917 | Ciuca | Aug 2006 | B2 |
7137430 | Fraczek | Nov 2006 | B2 |
7168476 | Chen | Jan 2007 | B2 |
7178577 | Liu | Feb 2007 | B2 |
7210646 | Hsu | May 2007 | B2 |
7254868 | Mullet | Aug 2007 | B2 |
7287569 | Lin | Oct 2007 | B2 |
7311133 | Anderson et al. | Dec 2007 | B2 |
7389956 | Hung | Jun 2008 | B2 |
7428918 | Martin | Sep 2008 | B2 |
7540315 | Chen | Jun 2009 | B2 |
7543625 | Beaudoin | Jun 2009 | B2 |
7740045 | Anderson et al. | Jun 2010 | B2 |
7802608 | Anderson | Sep 2010 | B2 |
7832450 | Brace et al. | Nov 2010 | B2 |
7832453 | Lin | Nov 2010 | B2 |
7886803 | Anderson et al. | Feb 2011 | B2 |
8006735 | Collum et al. | Aug 2011 | B2 |
8051960 | Nakajima | Nov 2011 | B2 |
8356653 | Fu-Lai | Jan 2013 | B2 |
8622184 | Sakai | Jan 2014 | B2 |
8723466 | Chambers | May 2014 | B2 |
8887788 | Toti | Nov 2014 | B2 |
8893766 | Bohlen | Nov 2014 | B2 |
8939190 | Mullet | Jan 2015 | B2 |
9103157 | Mullet | Aug 2015 | B2 |
9217282 | Defenbaugh | Dec 2015 | B2 |
9217284 | Panseri | Dec 2015 | B2 |
9663986 | Mullet | May 2017 | B2 |
9670724 | Oakley | Jun 2017 | B2 |
9695633 | Morris | Jul 2017 | B2 |
20020046817 | Last | Apr 2002 | A1 |
20030221799 | Cross | Dec 2003 | A1 |
20040177933 | Hillman et al. | Sep 2004 | A1 |
20050217805 | Strand et al. | Oct 2005 | A1 |
20060000561 | Anderson | Jan 2006 | A1 |
20060108076 | Huang | May 2006 | A1 |
20060118248 | Anderson et al. | Jun 2006 | A1 |
20060249264 | Lin | Nov 2006 | A1 |
20070023149 | Lamars et al. | Feb 2007 | A1 |
20070039696 | Strand | Feb 2007 | A1 |
20090120592 | Lesperance | May 2009 | A1 |
20090242332 | Anderson et al. | Oct 2009 | A1 |
20090294076 | McNiel | Dec 2009 | A1 |
20100206492 | Shevick | Aug 2010 | A1 |
20110000628 | Anderson | Jan 2011 | A1 |
20110277943 | Lin | Nov 2011 | A1 |
20120048485 | Fu-Lai | Mar 2012 | A1 |
20120145335 | Panseri | Jun 2012 | A1 |
20130248125 | Lin | Sep 2013 | A1 |
20140014279 | Defenbaugh | Jan 2014 | A1 |
20140083631 | Huang | Mar 2014 | A1 |
20140262062 | Higgins | Sep 2014 | A1 |
20150028144 | Defenbaugh | Jan 2015 | A1 |
20150308186 | Mullet | Oct 2015 | A1 |
20160201389 | Oakley | Jul 2016 | A1 |
20160222722 | Schulman | Aug 2016 | A1 |
20160369558 | Kirby | Dec 2016 | A1 |
20170183904 | Schulman | Jun 2017 | A1 |
20170254143 | Guan | Sep 2017 | A1 |
Number | Date | Country |
---|---|---|
19505824 | Aug 1996 | DE |
1748144 | Jan 2007 | EP |
Entry |
---|
Newell Window Furnishings, Inc., International Application No. PCT/US2013/50080, International Search Report and Written Opinion, dated Nov. 22, 2013. |
Number | Date | Country | |
---|---|---|---|
20150028144 A1 | Jan 2015 | US |
Number | Date | Country | |
---|---|---|---|
61877488 | Sep 2013 | US | |
61671212 | Jul 2012 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 13939699 | Jul 2013 | US |
Child | 14481152 | US |