1. Technical Field
This invention generally relates to the construction of staircase balustrades and, more particularly, to components and systems for pivotally attaching a baluster to a hand rail, a shoe rail or a cap rail in a staircase rail system so as to adjust for the rake angle of an individual staircase.
2. Background
Staircases typically include a staircase rail system for decoration and safety. In the staircase rail system, a row of vertical posts is conventionally topped by a hand rail along the edge of the staircase. These posts, commonly termed balusters, are supported by relatively larger posts known as newels. The staircase member upon which a user places his or her foot is referred to as a tread. The angle of incline of a staircase is referred to as the rake. Thus, a staircase in which successive treads ascend steeply is said to have a high rake.
Each baluster is fixed to the hand rail at its upper end and to the shoe rail or tread at its lower end. This arrangement is termed an open tread staircase. Alternatively, each baluster may be fixed at its lower end to a cap rail on the staircase. This arrangement is properly termed a closed tread staircase.
In the past, it was necessary for a worker at the jobsite to accurately measure the angle between the hand rail, shoe rail or cap rail, and each of the balusters and to hand fit the balusters individually to match the rake of the particular staircase. The construction of a staircase in this traditional manner results in a high quality product with a very desirable finished appearance that has consumer appeal. However, traditional construction requires a great deal of skill and care and can be quite time consuming.
To facilitate staircase construction, systems of adjustable balusters which are pivotally attached to their rails have been disclosed, many of which can be pre-assembled for delivery to the jobsite. While offering significant improvements over traditional systems which require hand-fitting each baluster, previous adjustable balustrade systems are relatively complicated to manufacture and assemble. Also, the finished staircase produced with these previous adjustable systems does not have the same quality finish or precisely resemble the decorative appearance of traditional staircases. Consequently, these previous adjustable systems fall short of the high quality, finished appearance of a traditional hand-crafted stair rail.
Additionally, most of the previous adjustable systems are limited to use with balusters of rectangular cross-section. Because pin top balusters are associated with very fine traditional staircases, they are generally preferred by consumers.
Therefore, a need still exists for an improved hinge assembly for pivotally attaching balusters to handrails and shoe rails in a pre-assembled adjustable staircase rail system. The improved hinge assembly and staircase system should be relatively easy to manufacture and assemble, and preassembled for delivery to the jobsite. Ideally, the improved hinge assembly and staircase system presents a quality finished appearance similar to traditional hand-fitted staircases, and performs well with pin top balusters.
The invention provides hinge assemblies for insertion into a mating groove defined by a hand rail, a shoe rail or cap rail. Such assemblies permit balusters to pivot with respect to the rail before and during staircase installation, in order to adjust the rake of the balusters to the rake of a particular staircase. The hinge assemblies are not readily apparent in the finished staircase containing the hinge assembly, require no external modifications to the normally visible surfaces of the baluster, and are easily concealed in the groove of the rail. The assemblies and the rails can be preassembled as an adjustable staircase rail system for delivery to a jobsite.
In a preferred form, the hinge assembly is assembled by snapping together two identical, moldable half-cap pieces about the end of a baluster, which is pierced through by a hole. The half-caps are fixed together by press-fit mating surfaces, and fit flush within a mating groove defined by a hand rail or shoe rail. In a finished staircase containing the hinge assembly, the hole which pierces the baluster cannot be seen, and the half-caps are normally out of sight.
In a preferred embodiment, the half-caps are identical to each other, and are manufactured from a moldable polymer material using the same mold. Each of the half caps includes two substantially parallel and opposite faces. Each of the faces is generally flat and extends lengthwise along the respective half-cap. One of the faces of each half cap surrounds a recessed wall that forms a spindle projecting generally transversely relative to the plane of the face. The recessed wall also defines an ellipsoidal cavity surrounding the spindle. Each of the half-caps is fixed to the other, with the respective spindles positioned substantially in line. When the half-cap pieces are press-fit together, the spindles are inserted into the hole in the baluster to form an axis on which the baluster pivots.
With the half-caps and the pierced baluster positioned as described, wood screws are used to fasten the half-caps to the rail. This staircase rail system can be preassembled for delivery to a jobsite, and easily adjusted at the jobsite to any particular staircase rake within a range of about 32 degrees to about 45 degrees. This staircase rail system performs well with pin top balusters.
In another preferred form, the hinge assembly can be inserted into the bore of an end-bored baluster, fastened to the inside of the bore, and pivotally attached to a flange suitable for attachment to a rail. The hinge assembly requires no external modification to the externally visible surfaces of the baluster. The flange includes an H-shaped foot that is easily concealed in a groove defined by a hand rail, shoe rail or cap rail. The pivot point is raised slightly above the inner surface of the groove to prevent any unsightly gap, termed “birds' mouth”, adjacent the baluster.
In this embodiment, the hinge assembly includes a plate member for inserting into and generally across an interior surface of the bore of an end-bored baluster. The plate has a face which includes a hole suitable for receiving a wood screw to fasten the plate to the inside surface of the bore. At least one tab extends from the plate at approximately a right angle to the plate face. The hinge assembly also includes a flange member having an H-shaped foot suitable for attachment to a rail. The flange defines a port providing access to the hole in the plate face. A rivet passes through a hole in the plate tab and a corresponding hole in the flange so as to pivotally attach the tab to the flange. In this way, the end-bored baluster is pivotally attached to the flange, which is secured to the rail.
The hinge assembly described above can be used to pivotally attach an end-bored baluster to a grooved rail to produce a staircase rail system that is adjustable over a range of staircase rakes. With the end-bored baluster pivotally attached to the flange as described, wood screws are used to attach the flange to an inside surface of the groove. This staircase rail system can be preassembled for delivery to a jobsite, and easily adjusted at the jobsite to any particular staircase rake within a range of about 32 degrees to about 45 degrees. This adjustable staircase rail system is a good choice for attaching rectangular balusters to hand rails, shoe rails or cap rails.
Either of the hinge assemblies described above, or variations and modifications of these assemblies, can be used alone or in combination with the others to produce a variety of adjustable staircase rail systems. Practitioners will appreciate that one or more of these adjustable staircase rail systems can facilitate the construction of almost any staircase.
In a preferred embodiment, hinge assembly 100 as depicted in
Elements of half-cap 140 that correspond to like elements of half-cap 120 have numbers which are greater than the corresponding element by 20. For example, protuberance 157 of half-cap 140 corresponds to protuberance 137 of half-cap 120, and conforms to the description of protuberance 137. As another example, passage 159 of half-cap 140 corresponds to passage 139 of half-cap 120, and conforms to the description of passage 139.
Half-cap 120 includes two substantially parallel and opposite faces 122 and 124 which extend lengthwise along half-cap 120. Face 122 substantially surrounds a recessed wall 126 of half-cap 120. Recessed wall 126 forms spindle 128 and defines cavity 130 adjacent to and surrounding spindle 128. Spindle 128 projects generally transversely relative to face 122. Cavity 130 cooperates with cavity 150 of half-cap 140 to provide ellipsoidal protected space 132 in which pierced baluster 110 is free to turn about an axis of rotation formed by spindle 128 and passing through orifices 112 and 114.
Similarly, half-cap 140 includes two substantially parallel and opposite faces 142 and 144 which extend lengthwise along half-cap 140. Face 142 substantially surrounds recessed wall 146 (not shown) of half cap 140. Recessed wall 146 forms spindle 148 (not shown) and defines cavity 150 (see
With the pair of half-caps abutting at faces 122 and 142, lips 134 and 154 of recessed walls 126 and 146, respectively, form an oval-shaped mouth through which baluster 110 extends into space 132. Adjacent the major axis of the oval-shaped mouth, lips 134 and 154 slope away from spindles 128 and 148 in order to match the arc described by baluster 110 as it turns. Adjacent the minor axis of the mouth, lips 134 and 154 fit closely with the one end of the baluster which extends into space 132. These details contribute to the high quality and finished appearance of hinge assembly 100, because the half-caps 120 and 140 fit relatively closely to baluster 110 as it pivots.
Half-caps 120 and 140 are preferably composed of a moldable polymer which accepts stain so as to blend in with the color of rail 102 (see
In order to fix half caps 120 and 140 in place relative to each other, half cap 120 defines aperture 136 for receiving and producing an interference fit with protuberance 157 of half-cap 140. For the same purpose, half-cap 140 defines aperture 156 (not shown) for receiving and producing an interference fit with protuberance 137 of half-cap 120. These interference fits enable half-caps 120 and 140 to literally snap together (see
Passages 139 and 159 extend completely through half-caps 120 and 140, respectively, to receive wood screws 193 and 194 for attaching the half caps to rail 102 (see
When assembled for use as shown in
As shown in
Baluster 110 is depicted in
It is also contemplated in another embodiment that only one of the half-caps 120 or 140 comprises a spindle, such as spindle 128 or 148, for pivotally securing the pierced end of baluster 100. That is, a spindle 128 or 148 would project from the interior surface of only one of the half-caps 120 or 140, respectively, through an orifice provided in the top of baluster 110. It is also contemplated in yet another embodiment that only one of the half-caps comprises a means for attaching the hinge assembly to a rail, such as passage 139 or 159.
Another preferred embodiment is substantially the same as hinge assembly 100, except that the half-caps include receptacles rather than spindles and the baluster includes projections rather than orifices. Hinge assembly 199 as depicted in
As shown in
It is also contemplated that only one of the half-caps may comprise a receiving receptacle, such as receptacle 129 or 149, and baluster 111 includes only one projection 117 or 119 for cooperation with the receiving receptacle. Also, only one of the half-caps may comprise a means for attaching the hinge assembly to a rail, such as passage 139 or 159.
Attaching either hinge assembly 100 or 199 to a rail, such as rail 102, provides an adjustable staircase system. One such adjustable staircase system, designated system 200, is depicted in
Although baluster 110 is depicted as a having a pin top in
In yet another preferred embodiment, hinge assembly 300 as depicted in
Face 362 defines a hole 366 for receiving a wood screw (not shown) for fastening plate 360 to the inside surface of the bore 318 of baluster 310. Alternatively, the plate member 360 can be fastened to the inside surface by a nail, a molly bolt, a fluke, a grapple, or a barb. From these examples, it should be apparent that a user of hinge assembly 300 may require access to hole 366 at times when flange 380 is substantially obstructing bore 318.
Flange member 380 comprises generally H-shaped foot 394 and a pair of tabs 396, and defines port 382 for providing access to hole 366. The H-shape of foot 394 permits fillet 306 to be used full depth in groove 304, while also permitting fillet 306 to slide up to and abut baluster 310. Tabs 396 extend generally transversely and in parallel relationship from flange foot 394, each of the tabs 396 defining a second hole (not shown) for receiving rivet 386.
As best seen in
A wood screw (not shown) is passed through port 382 and into hole 366 for attaching plate 360 to the inside surface 317 of baluster 310. The wood screw (not shown) is self-centering in bore 318, and may be accessed through port 382 for final assembly adjustment of baluster 310 to rail 102. The first and second holes defined respectively by tabs 368 and tabs 396, receive a pair of rivets 386 to pivotally attach plate 360 to flange 380. Alternatively, tabs 368 and tabs 396 can be pivotally attached by, for example, a cotter pin or a screwed fastener.
An adjustable staircase system is provided by attaching hinge assembly 300 to a rail, such as rail 302. One such adjustable staircase system, designated system 400, is depicted in
Either of the hinge assemblies 100 and 300 described above, or variations and modifications of these assemblies, can be used alone or in combination with each other to produce a variety of adjustable staircase rail systems. For example, adjustable staircase rail system 500, which is depicted in
Baluster 110 is a pierced baluster having an upper end of circular cross-section (widely referred to as a “pin top”) and a lower end which is end-bored and rectangular in cross-section. In this manner, system 500 combines the beauty of pin top balusters with the strength of rectangular balusters in a preassembled, adjustable system. System 500 can be stained and otherwise finished either before or after final adjustment and installation at the jobsite.
While a few, preferred aspects of the invention have been described above, those of ordinary skill in the art will recognize that any or all of these aspects may be modified without departing from the spirit and scope of the invention. The preferred aspects described above are to be considered as illustrative and not restrictive, the scope of the invention being indicated by the appended claims.
This application is a divisional of prior U.S. patent application Ser. No. 10/118,884, filed Apr. 9, 2002, for ADJUSTABLE STAIRCASE RAIL SYSTEM co-pending herewith.
Number | Name | Date | Kind |
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1234674 | Lachman | Jul 1917 | A |
2767959 | Schott | Oct 1956 | A |
3004751 | Woodward | Oct 1961 | A |
3007678 | Buehler | Nov 1961 | A |
3516644 | Horgan, Jr. | Jun 1970 | A |
4125249 | Zen | Nov 1978 | A |
4150907 | Thurnauer | Apr 1979 | A |
4886245 | Manzo | Dec 1989 | A |
5404682 | West | Apr 1995 | A |
5557893 | Bowls | Sep 1996 | A |
6145814 | Perrot | Nov 2000 | A |
6341764 | Conner | Jan 2002 | B1 |
Number | Date | Country | |
---|---|---|---|
Parent | 10118884 | Apr 2002 | US |
Child | 10979436 | US |