Field of the Invention
The present invention relates generally to the art of shower door enclosures and more particularly to a shower door featuring a gravity hinge to provide the door with a self-closing action.
Background of the Invention
Bathroom design has achieved a significant level of importance in the overall appearance of a home. Architects and homeowners today are insisting that every detail of bathroom appearance be precise and decorative in nature. Unfortunately, when it comes to installing shower doors, available shower door binges are generally not in conformance with the otherwise highly decorative theme of the modern residential bathroom. Prior art shower door hinges are typically bulky, exposed mechanical devices that are decidedly not decorative its nature.
Most shower doors presently available are constructed of metal and glass and are of the swinging door type. Such doors usually are affixed to the shower enclosure at the pivoted edge of the door using piano style hinges which often extend the full height of the door. Prior art hinges typically connect the metal frame of the door to the enclosure jamb and are bolted to the jamb in several places as is required to adequately support the weight of the door. In a typical installation, the free edge of the door swings against a vertical metal strike plate which is bolted to the door jamb on that side of the enclosure. The strike plate serve as a positive stop to the door's travel. A spring biased latch is also often used in conjunction with the strike plate to keep the door in the closed position.
Traditional methods of affixing a shower door to an enclosure as described above have proven to be undesirable in modern high-end shower enclosures. Modern high-end shower enclosures typically feature a glass door set into a glass wall. In this style of installation, it is desirable to polish the vertical edges of the glass door and leave the vertical edges unframed to create the appearance of an unbroken glass wall.
Piano style hinges and most other prior art shower door hinges are poorly suited to the glass wall style of shower enclosure because the glass door lacks vertical frame rails and the glass wall lacks a jamb structure. Thus, no suitable structure is present within which to install the hinges on the pivoted edge of the door and the strike plate on the free edge of the door. While it may be possible to install the hinges and strike plate directly to the glass door and associated glass wall structure, any such installation would be unsightly and unacceptable to both architects and consumers.
What is needed therefore, is an alternative to the traditional piano style door hinge specifically designed to work with glass doors installed in glass wall shower enclosures. Any such hinge system should be sufficiently compact so that it may be hidden within relatively low profile bottom and top rails attached to the glass shower door to provide for an unbroken glass wall appearance. Ideally, the hinges would not attach to any part of the vertical surface of the glass door. It would further be desirable that the hinges incorporate a self-closing feature eliminate the need for a strike plate and latch on the free end of the door.
The present invention solves the problems of the prior art by providing a glass shower door, a sloping sill, a sill angle adapter, upper and lower horizontal door frame rails, and a shower door hinge assembly where the hinges include a self-closing feature and attach only to horizontal edge surfaces of the glass door, i.e. the hinges do not attach to any vertical surface of the door. The hinges of the present invention comprise a lower hinge with self-closing provisions which is used in conjunction with a pivot style upper hinge. The lower and upper hinges are sufficiently compact such that the upper hinge may be hidden within the upper horizontal rail of the door and the header of the shower enclosure and the lower hinge may be hidden within the lower horizontal rail of the door and the sill of the shower enclosure.
The gravity style lower hinge of the invention includes lower or fixed portion and an upper or rotating portion where the fixed portion mounts to the sill of the shower enclosure and the rotating portion mounts to a lower horizontal rail attached to the lower horizontal edge of the glass door. The fixed portion of the lower hinge includes a cylindrical receptacle for receipt of a pintle or pin fixed to the shower door. Arranged radially about an opening of the receptacle and spaced angularly from a longitudinal axis of the fixed half of the lower hinge are a pair of mutually opposed raised surfaces and a pair of mutually opposed grooves or low surfaces. Joining the each raised surface and each groove or low surface is an interconnecting ramp. The radial centers of the raised surfaces, grooves and interconnecting ramps are measured angularly from a longitudinal axis of the fixed portion of the lower hinge. The angular position of these futures are as follows: The raised surfaces are located at 0° and 180°. The grooves are located at 90° and 270°. The ramps are located at 45°, 135°, 225° and 315°.
The rotating portion of the lower hinge contains essentially the same features as the fixed portion, except that the features are clocked 90 degrees from those of the fixed portion. In particular, the rotating portion of the lower hinge includes raised surfaces, grooves, and ramps which interconnect the raised surfaces and the grooves. The angular position of these features on the rotating portion of the lower hinge, with respect to a longitudinal axis of the rotating portion of the lower hinge, are as follows: The raised surfaces are located at 90° and 270°. The grooves are located at 0° and 180°. The camming ramps are located at 45°, 135°, 225° and 315°.
The fixed and rotating portions of the lower hinge are configured to be engaged when installed. At all times, the fixed portion of the lower hinge remains in a fixed position attached to the sill, whereas the rotating portion of the lower hinge is attached to the shower door and rotates as the door is opened or closed. The grooves define the self-centering or closed position of the door. With the door is at rest in the closed position, the raised surfaces of the rotating portion of the lower hinge rest in mating grooves in the fixed portion of the lower hinge. Likewise, the raised surfaces of the fixed portion of the lower hinge will rest in mating grooves of the rotating portion of the hinge. When the door is pushed outwardly, the raised surfaces of the rotating portion of the lower hinge ride upwardly along the ramps of the fixed portion of the hinge. When the raised surfaces of the rotating portion are positioned on the ramps of the fixed portion, the weight of the door will bias the raised surfaces towards the self-centered or closed position in the grooves. Thus, if the door is released, the door will close of its own accord.
Continued pushing of the shower door outwardly, will cause the raised surfaces of the rotating portion of the hinge to continue to ride up the ramps on the fixed portion of the hinge until the raised surfaces of the rotating portion of the hinge rest upon the raised surfaces of the fixed portion of the hinge. Once the raised surfaces of the rotating portion of the hinge rest upon the raised surfaces of the fixed portion of the hinge, the door will then open freely, i.e. the bias due to the weight of the door is then removed and the door will not close of its own accord. If the open door is then pushed inwardly, once the raised surfaces of the rotating portion slide off those of the fixed portion and begin descending the ramps of the fixed portion, the door will again be biased to the self-centered or closed position. The arc width of the ramps and the raised surfaces controls the range of motion for which the door will be biased to a closed position or allowed to travel freely.
In at least the region spanned by the shower door, the sill of the shower door and hinge assembly of the present invention is configured to slope downwardly towards the drain (inwardly) of the shower enclosure. The downward angle of the sill assists in preventing water from escaping the shower enclosure via the opening for the shower door. To allow for installation of the lower door hinge and the lower horizontal frame rail on the shower door, a sill adapter is provided to create a level surface. On the portion of the lower horizontal frame rail adjacent the lower door hinge, a sweep seal is provided to seal the gap between the lower frame rail of the door and the sill or sill angle adapter. The above and other advantages of the shower door system of the present invention will be described in more detail below.
The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. The invention may, however, may 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 be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numbers refer to like elements throughout.
With reference to
With reference to
Arranged radially about an opening 36 of the receptacle 32 of the fixed portion 28 of the lower hinge 24 and spaced angularly from a longitudinal axis 38 of the fixed portion 28 are two pairs of mutually opposed inclined surfaces referred to as ramps or camming ramps 40, a pair of raised surfaces 42 and two grooves 44. The radial centers of the ramps 40, raised surfaces 42 and grooves 44, measured angularly from a longitudinal axis 38 of the fixed portion 28 of the lower hinge 24, are as follows: The raised surfaces 42 are located at 0° and 180°. The grooves 44 are located at 90° and 270°. The two pairs of mutually opposed camming ramps 40 are located at 45°, 135°, 225° and 315°. The arc width 41 of the camming ramps 40 controls the range of motion through which the shower door 12 will be biased to a closed position, while the arc width 43 of the raised surfaces 42 controls the range of motion for which the shower door 12 will be able to travel freely.
The fixed portion 28 of the lower hinge 24 also features a water management dam 46, which assists in preventing water from escaping the shower enclosure. Also included in the fixed portion 28 are a pair of aced apart alignment holes 48 which are configured as elongated slots. The alignment holes 48 allow for the fixed portion 28 to be attached to the sill 16 of the shower enclosure mechanical fasteners typically screws.
With reference to
With reference to
The rotating portion 30 of the lower hinge 24 also includes a cylindrical opening 56 through which the pivot pin 34 (see
With reference to
With reference to
With reference to
In other words, when the shower door 12 is in the closed position, the grooves 54 of the rotating portion 30 of the lower hinge 24 located at 0° and 180° will be engaged with the raised surfaces 42 of the fixed portion 28 of the lower hinge 24 which are also located at 0° and 180°. Similarly, the raised surfaces 55 of the rotating portion 30 of the lower hinge 24 located at 90° and 270° are engaged with the grooves 44 of the fixed portion 28 of the lower hinge 24 also located at 90° and 270°.
With reference to
When the raised portions 55 of the rotating portion 30 of the lower hinge 24 are at rest in the grooves 44 of the fixed portion 28, the shower door 12 is in the closed or self-centered position. When the shower door 12 is pushed outwardly, the raised surfaces 55 of the rotating portion 30 of lower hinge 24 ride upwardly along the camming ramps 40 of the fixed portion 28 of the lower hinge 24. When the raised surfaces 55 of the rotating portion 30 are positioned on the camming ramps 40 of the fixed portion 28, the weight of the door 12 biases the raised surfaces 55 towards the grooves 44. Thus, if the door 12 is released when the raised surfaces 55 are riding upon the camming ramps 40, the door 12 will close of its own accord.
Continued pushing of the door 12 outwardly, will cause the raised surfaces 55 of the rotating portion 30 of the lower hinge 24 to continue to ride up the camming ramps 40 of the fixed portion 28 until they reach the raised surfaces 42 of the fixed portion 28. Once the raised surfaces 55 of the rotating portion 30 of the lower hinge 24 are on the raised surfaces 42 of the fixed portion 28 of the lower hinge 24, the door 12 will then open freely, i.e. the bias due to the weight of the door is then removed and the door will not close of its own accord.
If the open door is then pushed close, once the raised surfaces 55 of the rotating portion 30 traverse the raised surfaces 42 of the fixed portion 28 and begin descending the camming ramps 40 of the fixed portion 28, the door 12 will again be biased to the self-centered or closed position and the raised surfaces 55 of the rotating portion will again come to rest in the grooves 44 of the fixed portion 28.
Other features of the shower door and hinge assembly of the present invention 10, include the sill 16 which is configured to slope downwardly towards the drain of the shower enclosure. The downward angle of the sill 16 assists in preventing water from escaping the shower enclosure via the opening for the shower door. To allow for installation of the fixed portion 28 of the lower door hinge 24 on the sill 16, the sill adapter 18 is provided to create a level surface.
The lower and upper horizontal door frame rails 20 and 22 of shower door and hinge assembly 10, are extrusions which feature a generally u-shaped channel section 60 and a sweep seal retaining section 62 for retention of a sweep seal 64. The sweep seal 64 is provided to seal a gap between the shower door 12 and the sill 16.
The u-shaped channel sections 60 of the lower and upper horizontal frame rails 20 and 22 are configured to receive the lower and upper horizontal edges of the glass door 12, respectively. The lower and upper horizontal frame rails 20 and 22 are bonded to lower 94 and upper 92 horizontal edges of the glass door 12 via structural adhesive placed within u-shaped channels 60.
The component parts of the shower door and binge assembly of the present invention 10 may be made from a number of materials. In the exemplary embodiment, the rotating portion 30 and fixed portion 28 of the lower hinge 24, as well as the still angle adapter 18, are made from a structural grade thermoplastic material having excellent dimensional stability. Suitable thermoplastic materials such as polyoxymethylene (“POM”) materials are widely available from a number of manufacturers under the trade names Delrin, Celcon, Ramtal and Duracon, among others. In the exemplary embodiment, the lower and upper horizontal frame rails 20 and 22 are made from aluminum and will typically feature stainless steel decorative cladding. These components may also be made from other extrudable metallic materials.
With reference to
The foregoing detailed description and appended drawings are intended as a description of the presently preferred embodiment of the invention and are not intended to represent the only forms in which the present invention may be constructed and/or utilized. Those skilled in the art will understand that modifications and alternative embodiments of the present invention which do not depart from the spirit and scope of the foregoing specification and drawings, and of the claims appended below are possible and practical. It is intended that the claims cover all such modifications and alternative embodiments.
This application claims priority from U.S. Provisional Application Ser. No. 62/293,202 entitled “Shower Door System With Gravity Hinge,” filed on Feb. 9, 2016, the contents of which are incorporated herein, in their entirety.
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