The present invention relates to an improvement in providing a more customized window covering valence fit while eliminating the need for an exacting miter box with exacting dimensioning and custom installation.
Valence structures have traditionally been utilized to complete a window treatment. Custom installed valences require ordering and custom cutting of what is typically a linear molding. Of course, non-extruded style valences can be used which have specific decorative patterns or lengths of constant cross sectional area punctuated with an intermittent pattern, such as a flower or the like. Custom installations with high cost and high labor rates have the relative luxury of custom cutting and fitting and significant scrap. For custom installations, a high scrap rate is tolerable both economically and in terms of availability of a large supply of materials. Conversely, for home installation a high scrap rate creates an intolerable rise in cost, and an impossible expectation that the home installer will have the tools necessary to cut and fit the valence members.
One technique for valence joinder at the corners has been to form a 45° miter cut on each end of the meeting valence so that the outside or inside corners form a 90° angle. A cut also means that a thin, black crack will be left between the two members. The thin, black crack can occur through the edge effect of the saw on cutting, as well as any deviation from a completely planar cut. The alternatives to eliminate the crack are associated with further time and effort on the part of the custom installer. Putty, followed by spot painting can be performed. Complete re-painting of the valence can be accomplished, as well as installation of un-painted valence followed by initial painting.
Another problem with valences is the manner of joining of the segments. Glue can be unsatisfactory and can leave an unsightly appearance. Some valence hardware can include right angle supports which are attached with threaded members. Others utilize slots which accommodate right angle hardware. With these latter two cases, any deviation by the installer can leave a mis-matched angle or mis-matched gap which will require filler, painting, or other space and color correction.
Another problem with the 45° miter cut is the necessity to re-perform this cut for each 90° angle. Where the cut is too short, even by a millimeter, the length of valence must be discarded. Attempted use of any length which is too short or too long will result in corner angles deviating from 90°. Where the ends are 45° miter cut, even larger gaps will result.
Most people who self-install lack a high precision miter saw, but have the ability to cut at an angle orthogonal to the main extent of the valence. Most cuts are not high precision, and self-installers very likely lack the ability to finely sand the ends to insure a match fit. Even where precision cut and sanding are present, the use of a 45° sharp end is more susceptible to dents and nicks during cutting. The production of a sharp edge, especially with the fanciful shape of most valences has the potential to produce even more scrap and wasted time.
What is needed is a simple valence system for self-installers which can utilize cuts orthogonal to lengths of molding, regardless of the shape of the molding. The system should be forgiving of small errors in measurement and sawing, and should provide a finish which is compatible with the molding used and which eliminates open gaps. The system should also be forgiving of angularity and should facilitate an angle which deviates slightly from 90° where needed.
A specialized angle valence junction fitting forms a joint for connecting two lengths of valence molding. The fitting has a pair of openings directed 90° apart and has an internal shape matching an external shape of the molding utilized. The specialized angle joint may have a color to match or accent two lengths of molding and has an external dimension which is only about 1.5 millimeters greater than the dimension of the molding which it surrounds. Valence junction fitting can have an end edge which is straight, or beveled to imply a more stabilized or substantial relationship to the molding. The fitting can have channels which are uneven to assist in the order of attachment, with the shorter fitting providing the necessity for lesser deflection of a first member to which it is attached in order to interfit with another section of molding, when a shape is being completed. Further, the longer channel can be used to better support a length of molding which is cut slightly short of the target.
The fitting can be affixed by the addition of a threaded member, staple, glue, or an interference fit.
The invention, its configuration, construction, and operation will be best further described in the following detailed description, taken in conjunction with the accompanying drawings in which:
The description and operation of the valence junction fitting of the invention will be best begun with reference to
The valence 21 is typically made of wood and may be formed by moving a plank through a shaped planer which selectively removes the wood to yield the shape seen in
Referring to
The flanges 33 and 35 seen in
The thickness of the wall of the flange 33 can vary based upon the material utilized. One possibility to make the valence junction fitting 31 out of plastic and this may require a thickness of from one to one and a half millimeters. The flange 33 can be made of thin aluminum or other metal. The material selected may be specially prepared to support paint, appliques or other color and pattern bearing structures.
The inside of the bore 37 may be so open as to allow the material of the valence 21 to continue into the flange 33 and extend to the outer wall of the flange 35, or an interference structure could be added within the bore 37 to cause the valence 21 to stop short of any potential interference with the section of valence 21 extending through the flange 35 which might otherwise extend through to contact with the inner wall of the flange 33.
Where the path of occupation of the lengths of valence material can interfere, the individual cutting the valence 21 may take to account which valence sections are to be made to overlap. Further, in terms of layout, the valence material 21 may be cut so that one flat cut end of one length of material will touch the side of another. This will aid in layout and cutting, and will preclude the individual installing the valence system from having to add or account for an inner dimension within the valence junction fitting 31 in which the valence 21 may not extend.
As can be seen in
In the alternative, small stop structures can be molded or added to the inside of the valence junction fitting 31 to force the inside corner of the valence junction fitting 31 to remain unoccupied. It may be useful to have an indication of the un-occupied space indicated to the user or perhaps faintly marked on the outside of the valence junction fitting 31.
As by example, a typical valence 21 having a width of about three to four centimeters and a thickness at its shortest dimension of about 0.7 cm will give a difference of about 0.5 cm. In other words when one valence 21 is backed out of the common space to an extent that such movement just clears the common space, the other valence 21 can move forward by the same amount, which is about 0.5 cm for a valence 21 and the valence junction fitting 31.
Referring to
Comparing
For example, where a valence box structure is made by extending two lengths of valence 21 from the wall and joining the front length of valence, the longer flanges 33 might be directed in the direction toward the wall and perpendicular to the plane of the wall, so that a smaller angular deflection of the lengths of valence 21 extending from the wall could be used to make the final inserted construction. Regardless of the lengths of the flanges 33 and 35, the arrangement of which of two competing ends of two valences 21 which occupy the corner of the valence junction fitting 31 is made by the installer by simply backing one of the valences 21 from the corner most position and allowing the other valence 21 to occupy the corner. The slightly greater width of flange 33 with respect to flange 35 is normally not visually discernible in a rectangular valence application.
A second reason for having different flange lengths may relate to a competing occupancy within the valence junction fitting 31 where the inside of the valence junction fitting 31 allows extruded valence 21 inserted within the valence junction fitting 31 to compete for the space at the apex of the two flange bores 37 and 51. Where it is desired to have equal support of the valence 21 by the valence junction fitting 31, a longer flange should be provided to secure the section of valence 21 not occupying the corner-most occupancy within the valence junction fitting 31. This side is the “backed off” section of valence, and by providing it a longer flange 33 it will derive about the same support as the shorter flange 35. Again, the slightly greater length of flange 33 with respect to flange 35 is normally not visually discernible in a rectangular valence application.
Again, both flanges 33 and 35 can be of the same length, and where the length of the flanges 33 and 35 are more than sufficient to support the valence material 21, the use of even length flanges will give a more balanced appearance. Further, the use of flanges 33 and 35 which are of the same length, and which are more than sufficient for support of either the backed off valence 21 or the valence 21 occupying the corner position of the valence junction fitting 31, enables a user to select which of the valences 21 which will occupy the corner-most position in the valence junction fitting 31 in order to make a final adjustment for any length of valence 21 which was cut inadvertently too long or too short. For example, where the lengths of two valences 21 line up to complete a corner where one is slightly longer than the other, it can be selected to occupy the “common space” or corner-most section of the valence junction fitting 31.
The valence junction fitting 31 of
Also shown is a pair of optional internal depth limiting members 55 which may be employed where it is desired to limited the extent to which the valence 21 can be inserted into the valence fitting 31. The depth limiting members 55, based upon their corner position within the valence fitting 31 will also act to limit the depth to which valence 21 can be inserted into flange 33.
Referring to
Referring to
Referring to
Another desirable effect for the valence junction fittings 31 and 61 is the use of a high finish. A high finish can be achieved by utilizing a metallic material of construction and applying a high polish. Brass, silver, gold or other material can be used. Vacuum metalization can be applied to plastic to give the same high reflective finish as metal, and will give a wider range of color choice. In this case, the valence junction fittings 31 and 61 will appear as if they were binding fittings. Other finishes can be applied to the valence junction fittings 31 and 61 to help match the pattern of the valences 21 and 81.
While the present invention has been described in terms of a valence junction fitting having a pair of orthogonally extended flanges, the present invention can be used in any situation where a balance between ease of structural construction is to be struck with providing a high degree of the appearance of a custom finish. One skilled in the art will realize that the structure and techniques of the present invention can be applied to many structures, including any structure where the above goals can be achieved by the above goals in an interfitting manner.
Although the invention has been derived with reference to particular illustrative embodiments thereof, many changes and modifications of the invention may become apparent to those skilled in the art without departing from the spirit and scope of the invention. Therefore, included within the patent warranted hereon are all such changes and modifications as may reasonably and properly be included within the scope of this contribution to the art.
Number | Name | Date | Kind |
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1952069 | Hoffheimer et al. | Mar 1934 | A |
4827683 | Poole | May 1989 | A |
5383508 | Pavlica et al. | Jan 1995 | A |
6094796 | Biro | Aug 2000 | A |
6526712 | Brooks et al. | Mar 2003 | B2 |
6539675 | Gile | Apr 2003 | B1 |
6659154 | Bergeron et al. | Dec 2003 | B2 |
Number | Date | Country | |
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20070094970 A1 | May 2007 | US |