The present disclosure relates generally to the field of architectural-structure coverings, and relates more particularly to a perimeter light blockout system that prevents unwanted light from passing through the gap created, for example, between the sides of the covering and the window frame, or between the covering and an outer surface of an interior wall.
Architectural-structure coverings, such as honeycomb shades, slat blinds, Venetian blinds, roller shades, blackout shades, Roman shades, etc. may be used to selectively cover a window to provide privacy and block incoming light from the window. In addition, architectural-structure coverings may also be used to selectively cover a doorway, a skylight, a hallway, a portion of a wall, etc. Horizontal architectural-structure coverings may include a covering that can be vertically extendable and retractable (e.g., able to be lowered or raised, respectively, in a vertical direction) relative to a horizontally-oriented headrail between an extended position and a retracted position for obscuring and exposing, respectively, an underlying architectural structure such as a wall or an opening (such as, for example, a window).
One common problem with architectural-structure coverings is that the mounting hardware and actuators needed for the architectural-structure covering to operate effectively typically require the covering of the architectural-structure covering to be slightly narrower than the underlying structure (e.g., window opening). For example, in the case of an interiorly mounted roller shade or honeycomb shade, mounting brackets are typically mounted at the top of the window opening (e.g., brackets may be attached to a top surface or jamb of the window opening or on opposite side surface or jambs thereof). In either event, for the shade to fit into the mounting bracket and function properly, the covering is offset from either side of the window opening, leaving a side gap along the length of the covering between the sides of the shade and the interior side surfaces of the window frame. The side gap enables unwanted light to pass therethrough. The same problem exists for Venetian blinds, Roman shades, and other architectural-structure coverings where the mounting hardware is placed inside the window frame. The gap at either side may be even more significant if the architectural-structure covering includes complex or large actuators such as tilt rods, operating cords, and the like that require additional space accommodations. The resultant side gap not only allows unwanted light to leak through but it also can result in an architectural-structure covering that appears unfinished or otherwise unsightly. Accordingly, there is a need in the art to provide a mechanism to prevent unwanted light from leaking through the sides along the length of the covering.
A similar problem exists in connection with exterior mounted architectural-structure coverings. For example, in exterior mounted architectural-structure coverings, the architectural-structure covering may be mounted to an outer surface of an interior wall adjacent to a window opening (e.g., mounted to the wall above the window opening). In this embodiment, the sides of the architectural-structure covering may extend laterally beyond the window frame. As a result, light gaps often exist that enable unwanted light to pass therethrough. For example, light gaps may exist between the covering and the outer surface of the interior wall.
In addition, the architectural-structure covering should provide a satisfactory and proper alignment with respect to the underlying architectural structure. While problems associated with an imperfect fit may be less critical for some architectural-structure coverings, other coverings such as, for example, shades require a rather precise alignment. A shade that does not fit properly within the window opening may be aesthetically deficient.
There may be any number of reasons for an unsatisfactory fit of a window covering system. Most obviously, the window opening or window frame may be out of alignment (e.g., an out-of-skew window frame). As an out-of-skew window frame may be out of the user's control, the need for an alignment adjusting mechanism or device becomes even more important. The need is particularly significant in connection with the installation of some modern, highly decorative window covering systems, where improper geometric alignment can result in an unsightly shade system. These aesthetic and function problems may be annoying and unsightly to the user.
It is with respect to the above and other considerations that the present improvements may be useful. As it would be desirable to provide a perimeter light blockout system that prevents unwanted light from passing through light gaps, such as, for example, to minimize the amount of light passing between a side of a covering and an interior side surface of a window frame, or to minimize the amount of light passing between the covering and an outer surface of an interior wall. In addition, the perimeter light blockout system preferably also facilitates alignment adjustment to facilitate proper alignment even when installed within an imperfect window frame (e.g., an out-of-skew window frame).
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended as an aid in determining the scope of the claimed subject matter.
Disclosed herein is an improved perimeter light blockout system for minimizing an amount of light passing between any light gaps, such as, for example, any gaps between a side of a covering and an interior side surface of a window frame, or between the covering and an outer surface of an interior wall. In one embodiment, the perimeter light blockout system includes a light blocking device and a mounting element for coupling the light blocking device to the interior side surface of the window frame, or the outer surface of the interior wall. In use, the light blocking device may be adapted and configured so as not to contact the covering as the covering moves between extended and retracted positions.
In one embodiment, the light blocking device includes a U-shaped channel sized and shaped so as not to contact the covering received therein (e.g., portions (e.g., sides) of the covering received between the interior surfaces of the light blocking device) as the covering moves between the extended and retracted positions. That is, the interior surfaces may be separated by a distance greater than the depth or thickness of the covering received therein so that a space exists between interior surfaces of the light blocking device and the window side of the covering and the room side of the covering, respectively. In this manner, the light blocking device does not contact the covering and thus minimizes wear on the covering. In addition, because of the spaces formed between the interior surfaces of the light blocking device and the interior surfaces of the covering, air flow is enabled between the window side of the covering and the room side of the covering.
In another embodiment, disclosed herein is an improved perimeter light blockout system for minimizing an amount of light passing between any light gaps, such as, for example, any gaps between a side of a covering and an interior side surface of a window frame, or between the covering and an outer surface of an interior wall. The perimeter light blockout system includes a light blocking device and a mounting element for coupling the light blocking device to the interior side surface of the window frame, or the outer surface of the interior wall. The mounting element may provide a degree of adjustment so that the light blocking device can be aligned with an out-of-skew window frame. In use, the mounting element may releasably couple the light blocking device with respect to the window frame to enable a user to remove all or part of the light blocking device.
The light blocking device may include a channel for receiving a portion of the covering therein. The light blocking device may include a rear channel member releasably coupled to a front channel member. The light blocking device may be in the form of a U-shaped member so that portions of the covering may be received within the channel of the U-shaped member.
In one example embodiment, at least a portion of the channel includes a light absorbing/reflecting inner surface. The light absorbing/reflecting inner surface may include a plurality of serrations for reflecting light back in the direction from which it came, thereby minimizing the amount of light that may be transmitted through gaps between the light blocking device and the covering of the architectural-structure covering.
In one example embodiment, the perimeter light blockout system includes a cap coupled to the light blocking device. In use, the cap may be adjustably positioned with respect to the light blocking device to prevent any light seeping through a gap formed between, for example, a top edge of the light blocking device and a top edge of the window frame.
In one example embodiment, the perimeter light blockout system includes a bottom rail light blocking mechanism for coupling to a bottom rail of an architectural-structure covering so that, in the fully extended position, the bottom rail light blocking mechanism interacts with an interior bottom surface of the window frame for preventing light from passing between the bottom rail of the architectural-structure covering and the bottom surface of the window frame.
The present invention also discloses a method for minimizing an amount of light passing between any light gaps such as, for example, side gaps between a side of a covering and an interior side surface of a window frame, or between the covering and the outer surface of an interior wall. The method includes coupling one or more mounting elements to the interior side surface of the window frame, or the outer surface of an interior wall; releasably coupling a light blocking device to the one or more mounting elements; and adjusting the position of the light blocking device with respect to the one or more mounting elements. Releasably coupling the light blocking device to the one or more mounting elements may include ratchetably engaging one or more projections on the light blocking device with a pair of arms on the one or more mounting elements so that a position of the light blocking device can be incrementally adjusted with respect to the one or more mounting elements.
By way of example, a specific embodiment of the disclosed device will now be described, with reference to the accompanying drawings.
Embodiments of a perimeter light blockout system for architectural-structure coverings in accordance with the present disclosure will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the present disclosure are presented. The following disclosure is intended to provide illustrative embodiments of the disclosed apparatus, system, and method, and these example embodiments should not be interpreted as limiting. The perimeter light blockout system of the present disclosure may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will convey certain example aspects of the perimeter light blockout system to those skilled in the art. In the drawings, like numbers refer to like elements throughout unless otherwise noted. One of ordinary skill in the art will understand that the methods disclosed may easily be reordered and manipulated into many configurations, provided they are not mutually exclusive.
As will be described in greater detail below, the perimeter light blockout system of the present disclosure is configured to minimize light leakage between the sides of the covering (e.g., shade) and the interior side surfaces of the window frame or jamb, or between the covering and an outer surface of an interior wall depending on the type of perimeter light blockout system being utilized (interior mount or exterior mount system). In one embodiment, the light blocking device may be adapted and configured so as not to contact any portion of the covering as the covering moves between the extended and retracted positions. In addition, the perimeter light blockout system of the present disclosure may be configured to provide a degree of alignment when installed within an out-of-skew window frame. The perimeter light blockout system may include a light blocking device and a mounting element for coupling the light blocking device to the interior side surface of the window frame, or the outer surface of the interior wall. In one embodiment, the interaction between the mounting element and the light blocking device is arranged and configured to provide the degree of adjustment so that the light blocking device can be aligned with an out-of-skew window frame.
In use, the mounting element is arranged and configured to mount to either the interior side surface of the window frame for interior mounted systems, or the outer surface of the interior wall for exterior mounted systems, to facilitate mounting of the light blocking device thereto. The light blocking device is arranged and configured to interact with the covering of the architectural-structure covering to prevent or minimize the amount of light passing through gaps between the light blocking device and the covering such as, for example, through the sides of the covering (e.g., shade) and the interior side surfaces of the window frame or jamb, or between the covering and the outer surface of the interior wall.
In one embodiment, the mounting element releasably couples the light blocking device to the window frame or interior wall to enable a user to remove all or part of the light blocking device. That is, the mounting element may releasably couple the light blocking device to the window frame or interior wall so that, as needed, the light blocking device can be temporarily removed to, for example, facilitate cleaning of the window. The mounting element could be any device for coupling, and more preferably, releasably coupling, the light blocking device to the window frame or interior wall. For example, the mounting element may be Velcro, magnets (e.g., magnetic members may be attached to the window frame or interior wall, and to the light blocking device), etc. In one embodiment, for example, the mounting element may be a mounting extrusion for releasably coupling the light blocking device to the window frame or interior wall. In another embodiment, the mounting element may be or one or more clips for releasably coupling the light blocking device to the window frame or interior wall.
In one embodiment, the mounting extrusion includes first and second arms for engaging a portion of the light blocking device. The associated clips include first and second arms for engaging a portion of the light blocking device. The light blocking device may include one or more projections extending from the light blocking device. In one embodiment, the light blocking device includes first and second projections extending away from the light blocking member. The first and second projections may include a plurality of serrations. In use, the first and second arms of the mounting extrusion or clips engage the first and second projections of the light blocking device, respectively. The first and second arms may engage the plurality of serrations formed on the projections so that the first and second arms are incrementally adjustable with respect to the projections, thus allowing the user to adjust the position of the light blocking device with respect to the mounting element and hence with respect to the interior side surface of the window frame, or outer surface of the interior wall. In addition, the first and second arms may be arranged and configured to disengage from the projections extending from the light blocking device so that the light blocking device can be selectively decoupled from the mounting extrusion or clips if desired.
In one embodiment, the light blocking device includes a channel for receiving a portion of the covering therein. The light blocking device may include a rear channel member releasably coupled to a front channel member. When coupled, the light blocking device may be in the form of a U-shaped member so that portions of the covering may be received within a U-shaped channel of the light blocking device. The front channel member may be coupled to the rear channel member by any mechanism. For example, the front channel member may include an internal recess for receiving a longitudinally extending portion of the rear channel member. The longitudinally extending portion may include a detent for contacting the internal recess.
In one embodiment, the channel of the light blocking device may include a light absorbing/reflecting inner surface. The light absorbing inner surface may include a plurality of serrations, each serration including an angled first surface and a second surface, the first and second surfaces terminating in a tip. In use, the angled surfaces of the serrations reflect the light back in the direction of its source.
The perimeter light blockout system may include a bottom rail light blocking mechanism for coupling to a bottom rail of an architectural-structure covering so that, in the fully extended position, the bottom rail light blocking mechanism interacts with an interior bottom surface of the window frame for preventing light from passing between the bottom rail of the architectural-structure covering and the bottom surface of the window frame. The bottom rail light blocking mechanism may include a semi-circular flexible dome for contacting the bottom surface of the window frame.
Referring to
Referring to
Referring to
The perimeter light blockout system 100 generally includes a mounting element 120 and a light blocking device 150. Referring to
Referring to
Referring to
As will be described in greater detail below, the first and second arms 140, 142 of the mounting extrusion 130 are configured to receive a projection 154 formed on or connected to the light blocking device 150. In one embodiment, the projection 154 includes a plurality of serrations 156 formed thereon so that the first and second arms 140, 142 may incrementally engage the projection 154, similar to a ratchet-type connection. In this manner, by incrementally adjusting the position of the projection 154 with respect to the arms 140, 142, the user can adjust the position of the light blocking device 150 with respect to the window frame 60 to assist with proper alignment of the light blocking device 150, for example, with respect to an out-of-skew window frame 60. In addition, by incorporating the mounting extrusion 130, the process of coupling the light blocking device 150 is substantially hands free (e.g., no need for extra tools, such as, a wrench, a screwdriver, etc., to tighten; the user just presses the light blocking device 150 into contact with the mounting extrusion 130).
In use, after the mounting extrusion 130 has been coupled to the interior side surface 62 of the window frame 60 via, for example, one or more fasteners 135, the light blocking device 150 is coupled to the mounting extrusion 130. For example, the projection 154 formed on or connected to the light blocking device 150 may be coupled to the first and second arms 140, 142 formed on or extending from the mounting extrusion 130. In one embodiment, the second portions 140b, 142b of the first and second arms 140, 142 may ratchetably couple to the plurality of serrations 156 formed on the projection 154 formed on or connected to the light blocking device 150.
In use, applying a force to the light blocking device 150 causes the first and second arms 140, 142 to move (e.g., separate) with respect to each other. In this manner, the light blocking device 150 may be coupled to and removable from the mounting extrusion 130. That is, for example, the first and second arms 140, 142 of the mounting extrusion 130 may be arranged so that applying a compressive force against the light blocking device 150 (e.g., pressing the light blocking device 150 against the mounting extrusion 130 with the projection 154 located between the first and second arms 140, 142), causes the first and second arms 140, 142 to move away from each other so that the light blocking device 150 can be coupled to the mounting extrusion 130. Similarly, applying a pulling force to the light blocking device 150, causes the first and second arms 140, 142 to move away from each other so that the light blocking device 150 can be decoupled from the mounting extrusion 130.
Referring to
Referring to
The rear channel member 160 may include a base member 162 that when installed extends generally parallel to the interior side surface 62 of the window frame 60 and a rear wall portion 164 that extends generally perpendicular from the base member 162. Similarly, the front channel member 180 includes a base member 182 that when installed extends generally parallel to the interior side surface 62 of the window frame 60, and a front wall portion 184 that extends generally away from the base member 182. As shown, the front wall portion 184 of the front channel member 180 may initially extend perpendicularly from the base member 182. However, the front wall portion 184 may be angled inwardly towards the rear channel member 160. However, it should be understood that the front wall portion 184 may have any profile to provide alternative aesthetic appearances. In this manner, the end portion of the covering 52 may reside within the U-shaped channel 152. As such, the rear wall portion 164 of the rear channel member 160 and the front wall portion 184 of the front channel member 180 may extend beyond (e.g., overlap with) the end portions of the covering 52 of the architectural-structure covering 50, and hence, extend across the light gap formed between the sides of the covering 52 and the interior side surfaces 62 of the window frame 60, and thereby prevents light from seeping through.
Referring to
The front and rear channel members 160, 180 may be coupled to each other by any means now known or later developed. As shown in
Each of the rear and front channel members 160, 180 includes an interior surface 170, 190 (e.g., surface that faces the covering 52 of the architectural-structure covering 50) and exterior surface 172, 192 (e.g., surface opposite the interior surface). As previously mentioned, the U-shaped channel 152 may be sized and shaped so as not to contact the covering 52 received therein (e.g., portions (e.g., sides) of the covering 52 received between the interior surfaces 170, 190 of the light blocking device 50) as the covering 52 moves between the extended and retracted positions. That is, as illustrated in
One or both of the interior surfaces 170, 190 of the rear and front channel members 160, 180 may include a light absorbing surface 200. In use, the light absorbing surface 200 acts to absorb, refract, reflect, or break-up (herein “absorb” for the sake of convenience without intent to limit) the light that may be transmitted through gaps between the rear channel member 160 and the front channel member 180, and the covering 52 of the architectural-structure covering 50. In use, the entire interior surface of the U-shaped channel 152 may be covered by the light absorbing surface 200. Alternatively, only a portion of the interior surface of the U-shaped channel 152 may be covered by the light absorbing surface 200.
Collectively, the rear and front channel members 160, 180 and the light absorbing inner surfaces 200 act to minimize the amount of light passage therethrough or reflected therefrom. In one non-limiting example, the light absorbing inner surfaces 200 may have a substantially flat black coloration. A substantially flat black coloration means nearly black or a dark shade of a color that is dark enough to absorb a substantial portion of incident light, such that the surface is substantially non-reflective. The light absorbing inner surface 200 may be formed in any manner now known or hereafter developed. For example, the light absorbing inner surfaces 200 may be formed by a layer such as a tape, fabric, flocking, anti-reflective coating, or paint coating. Alternatively, light absorbing inner surface 200 may be formed as a co-extruded (dark) layer with side channel, resulting in the side channel being one color and the light absorbing inner surfaces being another color. In another example, the light absorbing inner surfaces 200 may be formed by a thermal alteration of a surface of the channel, e.g., blackening by heating or burning.
In another example, the light absorbing inner surfaces 200 may be formed by a texturing of a surface of the channel 152. That is, as will be described in greater detail below in connection with
One or both of the rear and front channel members 160, 180 may also include a light blocking strip (not shown) to further assist in preventing light leakage. As will be described in greater detail below, the light blocking strip serves to block light from passing between the interior side surfaces 62 of the window frame 60 and the light blocking device 150. In one embodiment, the light blocking strips may be received within one or more grooves formed in the front and rear channel members 160, 180.
As previously described, the light blocking device 150 may include a projection 154 for engaging with the mounting extrusion 130. Referring to
In one example embodiment, the plurality of serrations 156 formed on the first and second projections 154a, 154b extending from the light blocking device 150 enable approximately one-quarter inch adjustment. In this manner, the perimeter light blockout system 100 can accommodate approximately one-half inch adjustment for out of square windows. Alternatively, instead of using interconnecting arms and projections to form a ratchet-type connection, the light blocking device may be coupled to the mounting extrusion via an adjustable screw-type mechanism. It will be appreciated that these dimensions are merely examples, and that other adjustment magnitudes can be achieved using the disclosed mounting extrusion.
Referring to
In the embodiment of
The first upstanding arm 340 may be integrally formed with the base member. Alternatively, the first upstanding arm 340 may be coupled to the base member 332 by any means now known or hereafter developed, including, but not limited to, an adhesive, welding, fasteners, etc. Similarly, the second upstanding arm 342 may be integrally formed with the tab member 336. Alternatively, the second upstanding arm 342 may be coupled to the tab member 336 by any means now known or hereafter developed, including, but not limited to, an adhesive, welding, fasteners, etc.
As will be described in greater detail below, the first and second arms 340, 342 may be configured to receive a projection 354 formed on or connected to the light blocking device 350. Preferably, the projection 354 includes a plurality of serrations 356 formed thereon so that the first and second arms 340, 342 may incrementally engage the projection 354, similar to a ratchet-type connection. In this manner, by incrementally adjusting the position of the projection 354 with respect to the arms 340, 342, the user can adjust the position of the light blocking device 350 with respect to the window frame 60 to assist with proper alignment of the light blocking device 350, for example, with respect to an out-of-skew window frame 60. In addition, by incorporating clips 330, the process of coupling the light blocking device 350 is substantially hands free (e.g., no need for extra tools, such as, a wrench, a screwdriver, etc., to tighten; the user just presses the light blocking device 350 into contact with the clips 330).
Referring to
While the clips 330 have been illustrated, and described as being used for coupling the light blocking device 350 to the window frame 60, it is envisioned that the clips 330 may be used in other applications, for example, for mounting a decorative element or trim piece, mounting a headrail or a bottom rail of the architectural-structure covering to the window frame, mounting a frame element for a skylight, etc.
Referring to
The rear channel member 360 may include a base member 362 that when installed extends generally parallel to the interior side surface 62 of the window frame 60 and a rear wall portion 364 that extends generally perpendicular from the base member 362. Similarly, the front channel member 380 includes a base member 382 that when installed extends generally parallel to the interior side surface 62 of the window frame 60 and a front wall portion 384 that extends generally away from the base member 382. As shown, the front wall portion 384 of the front channel member 380 may initially extend perpendicularly from the base member 382. However, the front wall portion 384 may be angled inwardly towards the rear channel member 360. However, it should be understood that the front wall portion 384 may have any profile to provide alternative aesthetic appearances. In this manner, the end portion of the covering 52 may reside within the U-shaped channel 352. As such, the rear wall portion 364 of the rear channel member 360 and the front wall portion 384 of the front channel member 380 may extend beyond (e.g., overlap with) the end portions of the covering 52 of the architectural-structure covering 50, and hence, extend across the light gap formed between the sides of the covering 52 and the interior side surfaces 62 of the window frame 60, and thus prevent light from seeping through.
The front and rear channel members 360, 380 may be coupled to each other by any means now known or later developed. As shown in
Each of the rear and front channel members 360, 380 includes an interior surface 370, 390 (e.g., surface that faces the covering 52 of the architectural-structure covering 50) and exterior surface 372, 392 (e.g., surface opposite the inter surface). As previously mentioned, the U-shaped channel 352 may be sized and shaped so as not to contact the covering 52 received therein (e.g., portions (e.g., sides) of the covering 52 received between the interior surfaces 370, 390 of the light blocking device 350) as the covering 52 moves from between the extended and retracted positions. That is, as illustrated in
Similar to the embodiment described above in connection with
One or both of the rear and front channel members 360, 380 may also include a light blocking strip (not shown) to further assist in preventing light leakage. The light blocking strip may be in the form of a light tube or a light blocking strip of material, such as, a strip of light-blocking bristles, a strip made from a variety of natural or synthetic materials (similar to weather stripping), a strip made from a woven or non-woven textile material, and/or a strip made from a flexible material that can be easily deflected and compressed, etc. The light blocking strip may be a single strip of material or a plurality of strips arranged together.
As shown, the light blocking strip may be received in a groove 420 formed in the rear channel member 360 and the front channel member 380 to prevent light leakage between the window frame 60 and the light blocking device 350. In use, the light blocking strip may be coupled to the rear and front channel members 360, 380 by feeding, pressing, or forming the light blocking strip into the groove 420. In use, the light blocking strips serve to block light from passing between the interior side surfaces 62 of the window frame 60 and the light blocking device 350.
Similar to the embodiment described above in connection with
In one example embodiment, similar to the embodiment described above in connection with
Referring to
Referring to
In use, the mounting extrusion 630 may be coupled to the outer surface of the interior wall 70 by any coupling mechanism known including, but not limited to, adhesive strips, two-face backing tape, Velcro, magnetics, etc. In one embodiment, the base member 632 may include one or more holes (not shown) or other features for receiving fasteners 635 for coupling the mounting extrusion 630 to the outer surface of the interior wall 70. The holes may be slotted to enable additional lateral adjustability. In one embodiment, the mounting extrusion 630 may extend the entire height of the window frame. In this manner, the mounting extrusion 630 helps to prevent or minimize the amount of light seeping through the gap formed between the covering 52 and the outer surface of the interior wall 70.
In use, the first and second arms 640, 642 may be configured to receive a projection 654 formed on or connected to the light blocking device 650. In one embodiment, the projection 654 includes a plurality of serrations 656 formed thereon so that the first and second arms 640, 642 may incrementally engage the projection 654, similar to a ratchet-type connection. In this manner, by incrementally adjusting the position of the projection 654 with respect to the arms 640, 642, the user can adjust the position of the light blocking device 650 with respect to the outer surface of the interior wall 70 (or the interior side surface 62 of the window frame 60 if used as an inside mount) to assist with proper alignment of the light blocking device 650. In addition, by incorporating the mounting extrusion 630, the process of coupling the light blocking device 650 is substantially hands free (e.g., no need for extra tools, such as, a wrench, a screwdriver, etc., to tighten; user just presses the light blocking device 650 into contact with the mounting extrusion 630).
In use, after the mounting extrusion 630 has been coupled to the outer surface of the interior wall 70 via, for example, one or more fasteners 635, the light blocking device 650 may be coupled to the mounting extrusion 630. For example, the projection 654 formed on or connected to the light blocking device 650 may be coupled to the first and second arms 640, 642 formed on or extending from the mounting extrusion 630. In one embodiment, the second portions 640b, 642b of the first and second arms 640, 642 may ratchetably couple to the plurality of serrations 656 formed on the projection 654 formed on or connected to the light blocking device 650.
In use, applying a force to the light blocking device 650 causes the first and second arms 640, 642 to move (e.g., separate) with respect to each other. In this manner, the light blocking device 650 may be couplable to, and removable from, the mounting extrusion 630. That is, for example, the first and second arms 640, 642 of the mounting extrusion 630 may be arranged so that applying a compressive force against the light blocking device 650 (e.g., pressing the light blocking device 650 against the mounting extrusion 630 with the projection 654 located between the first and second arms 640, 642), causes the first and second arms 640, 642 to move away from each other so that the light blocking device 650 can be coupled to the mounting extrusion 630. Similarly, applying a pulling force to the light blocking device 650, causes the first and second arms 640, 642 to move away from each other so that the light blocking device 650 can be decoupled from the mounting extrusion 630.
Referring to
Similar to the embodiments described above, for example, in connection with
Similar to the embodiments shown above, the rear and front channel members 660, 680 may each have an approximate L-shape so that when the front channel member 680 is coupled to the rear channel member 660, the light blocking device 650 has an approximate U-shaped channel 652 for receiving the architectural-structure covering (e.g., shade) therein. That is, the rear channel member 660 includes a base member 662 that when installed extends generally perpendicular to the outer surface of the interior wall 70 and a rear wall portion 664 that extends generally perpendicular from the base member 662 (e.g., generally parallel to the outer surface of the interior wall 70). In use, the outermost edge 664a of the rear wall portion 664 may be installed so that it substantially aligns with the interior side surface 62 of the window frame 60.
Similarly, the front channel member 680 includes a base member 682 that, when installed, extends generally perpendicular to the outer surface of the interior wall 70, and a front wall portion 684 that extends generally away from the base member 682. As previously mentioned, the front wall portion 684 of the front channel member 680 may initially extend perpendicularly from the base member 682. It will be appreciated that the front wall portion 684 may, however, in some example embodiments, be angled inwardly towards the rear channel member 660. However, it should be understood that the front wall portion 684 may have any profile to provide alternative aesthetic appearances. In this manner, the end portion of the covering 52 may reside within the U-shaped channel 652. As such, the rear wall portion 664 of the rear channel member 660 and the front wall portion 684 of the front channel member 680 may extend beyond (e.g., overlap with) the end portions of the covering 52 of the architectural-structure covering 50 to prevent light from seeping between the end of the covering 52 and the interior surface of the U-shaped channel 652.
The front and rear channel members 680, 660 may be coupled to each other by any means now known or later developed. Referring to
The longitudinally extending portion or stem 688 of the front channel member 680 and/or the end of the base member 662 of the rear channel member 660 may include a detent, either coupled thereto or integrally formed therewith, so that the front channel member 680 is positively coupled to the rear channel member 660, thus minimizing the possibility that the front channel member 680 may become inadvertently disengaged from or shift (e.g., move) with respect to the rear channel member 660. Alternatively, the front channel member 680 may be additionally coupled to the rear channel member 660 by any other means now known or later developed. As will be appreciated by one of ordinary skill in the art, the internal recesses and the longitudinally extending portion or stem portion may be interchangeable.
Each of the rear and front channel members 660, 680 may include an interior surface 670, 690 (e.g., surface that faces the covering 52 of the architectural-structure covering 50) and an exterior surface 672, 692 (e.g., surface opposite the interior surface). Similar to the embodiments described above, the U-shaped channel 652 may be sized and shaped so as not to contact the covering 52 received therein (e.g., portions (e.g., sides) of the covering 52 received between the interior surfaces 670, 690 of the light blocking device 650) as the covering 52 moves between the extended and retracted positions. In this manner, the light blocking device 650 is spaced from, and does not contact the covering 52, such configuration may minimize wear on the covering 52. In addition, air flow is enabled between the window side of the covering 52 and the room side of the covering 52.
The exterior surfaces 692 of the front channel member 680 and the exterior surface 635 of the mounting extrusion 630 may include a finished outer surface so that, in use, the perimeter light blockout system 600, and specifically, the visible exterior surfaces have a pleasing aesthetic appearance.
Similar to the embodiments described above, and as previously described in greater detail in connection with
Similar to the embodiments described above, the light blocking device 650 may include a projection 654 for engaging with the mounting extrusion 630. The rear channel member 660 may include first and second projections 654a, 654b extending from the exterior surface of the base member 662 for coupling with the mounting extrusion 630. The first and second projections 654a, 654b preferably include a plurality of serrations 656 so that the first and second arms 654a, 654b can be incrementally positioned with respect to the mounting extrusion 630. In this manner, the user can incrementally adjust the position of the light blocking device 650 with respect to the outer surface of the interior wall 70.
Referring to
The cap 900 may include an exterior surface 902, an interior surface 904, and a top surface 906. The interior and exterior surfaces 904, 902 of the cap 900 may substantially correspond with the shape of the light blocking device 650, and more specifically with the shape of the front channel member 680. In use, the cap 900 may be coupled to the light blocking device by any means now known or hereafter developed, including for example, a friction-fit connection. Referring to
Referring to
The cap 1000 may include an outer surface 1002 and an inner surface 1004. As shown, the inner and outer surfaces 1002, 1004 of the cap 1000 may have a shape that substantially corresponds with the shape of the light blocking device 650, although it is envisioned that other shapes may be used, such as, for example, a rectangular shape. In use, the cap 1000 may be coupled to the light blocking device 650 by any means now known or hereafter developed. Referring to
Contrary to the embodiment of the cap 900 described above in connection with
In one embodiment, it is envisioned that a plurality or kit of end caps 1000a, 1000b, 1000c, 1000d may be provided with varying thicknesses ranging from, for example, 1/16″ to ¼″, although these dimensions are merely exemplary and other thicknesses may be used. For example, caps 1000a-d may be provided in thicknesses of, for example, 1/16″ (1.6 mm), ⅛″ (3.2 mm), 3/16″ (4.8 mm), and ¼″ (6.4 mm).
By providing a plurality of caps 1000 with varying thicknesses, an installer can select the best-fitting cap 1000 for their particular application. In this manner, the system can accommodate measurement discrepancies in the height of the light-blocking device, architectural-structure covering and/or windows where, for example, one side may be longer than the other. Moreover, the system can create a tight-fit between the top and bottom edges 1050, 1060 of the light-blocking device 650 and the top and bottom edges 64, 66 of the window frame 60 thereby preventing light from seeping through and providing a nicer aesthetic finish. In use, while it is envisioned that top and bottom caps 1000 may be provided on the top and bottom edges 1050, 1060 of the light blocking device, respectively, it is envisioned that a single cap 1000 may only be used on the top edge or the bottom edge. In addition, it is envisioned that some or all of the measurement discrepancies may be accommodated by either the top cap, bottom cap, or both.
Referring to
In use, the bottom rail light blocking mechanism 550 may be coupled to the bottom rail 54 of the architectural-structure covering 50 by any mechanism now known or later developed including, for example, an adhesive, a fastener, Velcro, magnets, etc. In addition, one of ordinary skill in the art will appreciate that while the bottom rail light blocking mechanism 550 has been described as being affixed to the bottom rail 54 of the architectural-structure covering 50 for movably contacting the bottom window sill, the bottom rail light blocking mechanism 550 may be affixed to the bottom window sill for contacting the bottom rail 54 of the architectural-structure covering 50.
Alternatively, referring to
Referring to
In use, the perimeter light blockout system 100, 300, 600 of the present disclosure substantially minimizes or eliminates any light leakage, for example, between the existing gap between the end of the covering (e.g., shade) and the interior side surface of the window frame, or between the covering and the outer surface of the interior wall. As such, the perimeter light blockout system 100, 300, 600 provides a solution for use in home theater rooms, bedrooms, etc. In addition, the design of the perimeter light blockout system 100, 300, 600 allows it to be installed without requiring the user to replace their existing architectural-structure coverings. As such, the perimeter light blockout system 100, 300, 600 minimizes or prevents light leakage while not altering the basic functionality of the covering, affecting the thermal properties and heat movement past the sides of the shades, etc.
While various embodiments of the perimeter light blockout system having certain features have been described and illustrated, it should be understood that the embodiments should not be so limited and that features may be interchangeable between the various embodiments. For example, while the first and second embodiments of the perimeter blockout system 100, 300 have been described as being for interior mounted systems, one of ordinary skill in the art will appreciate that the systems may be easily modified for exterior mounted systems.
As used herein, an element recited in the singular and proceeded with the word “a” or “an” should be understood as not excluding plural elements, unless such exclusion is explicitly recited. Furthermore, references to “one embodiment” of the present disclosure are not intended to be interpreted as excluding the existence of additional embodiments that also incorporate the recited features. In addition, while components may have been described in connection with one embodiment but not another, one of ordinary skill in the art will appreciate that such components may be interchangeable and used in connection with other embodiments.
While the present disclosure makes reference to certain embodiments, numerous modifications, alterations, and changes to the described embodiments are possible without departing from the sphere and scope of the present disclosure, as defined in the appended claim(s). Accordingly, it is intended that the present disclosure not be limited to the described embodiments, but that it has the full scope defined by the language of the following claims, and equivalents thereof.
This is a non-provisional of, and claims the benefit of the filing date of, pending U.S. provisional patent application No. 62/479,500, filed Mar. 31, 2017, titled “Perimeter Light Blockout System,” and a non-provisional of, and claims the benefit of the filing date of, pending U.S. provisional patent application No. 62/622,990, filed Jan. 29, 2018, titled “Perimeter Light Blockout System,” the entirety of which applications are incorporated by reference herein.
Number | Date | Country | |
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62479500 | Mar 2017 | US | |
62622990 | Jan 2018 | US |