1. Field of the Invention
This invention relates to an improved gem or synthetic stone setting for an inside bezel mounting that results in considerable time and cost savings in order to provide a precisely calculated bezel angle face and contiguous finish on the inside bezel face for enhanced light brilliance.
2. Description of Related Art
In the world of setting stones, either gem stones or synthetic stones, for an inside bezel setting, conventionally the stones were mounted from the top down. The conventional gem setting for an inside bezel setting is expensive and time consuming due to the difficult task of trying to maximize the refractive light out or in to the crown of the stone. The present invention dramatically improves the setting for either gem or synthetic stones (regardless of their shapes) for the inside bezel mounting. The present invention provides a major aesthetic advantage of pre-establishing the bezel angle face which can be precisely calculated and maximized for refracted light out or reflected light in through the crown of the stone before permanently completing the setting.
The present invention is an improved setting for either gem or synthetic stones, round, oval or pear-shaped either faceted or cabochon utilizing the aesthetic and inherently protective (shielding) properties associated with the classic inside bezel mounting. The invention, self-centering setting provides for the stone to be permanently set with minimum risk to the stone during the actual setting process. Additional advantages associated with the present invention are the considerable labor and time savings, resulting in reduced costs, reduced breakage and more importantly providing a cost effective method to obtain the predictable angle and contiguous finish on the inside bezel face. This action can be accomplished by finishing and polishing the bezel face pre-stone setting which previously was an impossible task due to the nature of the top down inside bezel setting techniques. The major aesthetic advantage of pre-establishing this bezel angle face is that this angle can be precisely calculated thus maximized for the refracted light out or the reflected light in through the crown of the stone using the present invention.
In the present art of inside bezel setting, stones are mounted and set from the top down. As for round stones, the process typically involves drilling a hole approximately 2/3 the diameter of the stone and then cutting a seat the diameter of stone at a depth commensurate with the table sitting flush with the top of the mounting. The seat and/or new bearing surfaces are at a pitch, which reflects the pavilion angles and/or the lower half of the stone.
After the stone is placed into its seat from above, the metal corner at the top of what was of the open cylinder is then “hammered” down in a series of progressive spiral rotations. Through each rotation, the metal spreads in the direction of the center of the interior forming the bezel. This action effectively terminates at the crown of the stone typically reducing the interior diameter by 10%. The result is covering the stone and preventing the stone from coming out of its setting. The bezel is then carefully trimmed at the stone and metal interface paying particular attention not to nick and damage the stone, then polished to blend the peens from hammering.
Additionally, it should be noted that there are other styles included in the present art of stone setting. The most popular are “prong” and their variations, two, three, four, six or more prongs. This popularity is due primarily to the manufacturing considerations and the associative costs.
Currently, prong settings are the least labor consuming technique in production. After the seat has been cut and the stone placed into position from the top, the prongs are then bent in the direction of the center of the stone until the prongs lie on top of the crown surfaces of the stone. The prongs are then trimmed and then polished.
However, there are compromises for the consumer in conjunction with the prong set mountings. This is due in part to the nature of the prong itself. The prong typically is an extruded form of half round or rectangularly shaped wire that extends from the girdle to the table usually at a height that is eight percent (8%) of the diameter of the stone, or half way up the main bezel facet. The prong, a key component to keeping the stone in place is however subject to misalignment, shifting, being snagged on clothing, hair or other objects and ultimately lost.
Additionally, environmental exposure for primarily colored stones and diamonds is risky. The only protection afforded the crown from side impacts are the prongs, which collectively represent twelve percent (12%) of the surface area in a typical four prong setting. Abrasion at the facet junctions, and fracturing at the girdle are typical problems associated for colored stones in “prong” mountings.
Furthermore, present “inside bezel” settings require exceptionally fine detailed workmanship by those highly skilled in the art, hence labor costs are very prohibitive in a production environment. Secondarily “prong” style mountings are inexpensive to produce but ultimately leave the consumer with problems of durability, and potential loss of investment. The present invention is an improved method for setting stones which is attractive, durable and easy to implement.
While several types of settings exist, none securely fixes a gem within a setting while maximizing the visible area of external reflection with the adjunct concentric bezel face thus enhancing the results of internal refraction too. Also, none is as easy to install as the present invention.
In accordance with these and other objects which will become apparent hereinafter, the instant invention will now be described with particular reference to the accompanying drawings.
a is a top plan view of the present invention including a gem.
b is a left side perspective view of the present invention including a gem.
c is a right side perspective view of the present invention including a gem.
d is a front perspective view of the present invention including a gem.
a is a side elevation view (exploded) of the invention before a gem is set.
b is a side elevation view in cross section of the present invention including a gem at a point where a gem is being placed within the setting.
c is a cross section side elevation view of the present invention including a gem at a point after a gem is placed inside a setting and before it is secured
e is a bottom plan view of the present invention including a gem at a point after a gem is secured within a setting.
a is a bottom, perspective (exploded) view of the invention before a gem is set.
b is a bottom perspective view of the invention with a spring mount in place.
c is a side perspective (exploded) view of the invention before a gem is set.
d is a bottom perspective view of the invention with a spring mount in place.
a is a bottom plan view of an alternative embodiment containing a gem.
b is a bottom perspective view of an alternative embodiment containing a gem.
c is a (partial) bottom perspective and enlarged detail view of an alternative embodiment with the gem and spring in place.
d is a bottom perspective view of an alternative embodiment.
e is a bottom perspective view of an alternative embodiment at a point when a gem is inside the setting and before it is secured within the setting.
f is a (partial) bottom perspective view cut away in detail of an alternative embodiment at a point after a gem is secured within the setting.
g is a (sectional) bottom enlarged cut away perspective view in detail of a fastener of an alternative embodiment after a gem is placed in the setting and secured.
The present invention is an improved setting for a gem. The invention is also a method for placing a gem in a setting.
The invention is shown as 10 in
a-2e illustrate the inventive process for securing a gem within a setting. A circular spring 20 is used to secure the gem 12 within a cavity 22 in the setting 14. As shown, the spring 20 is generally circular in shape with a gap 24 which allows the spring 20 to be compressed to fit within the circumference of the cavity 22, as illustrated in
As shown in
The countersunk prongs 26 (
The preferred embodiment of the setting is shown in
The countersunk prongs 26 are preferred to be located on the setting itself, as shown in
An alternative embodiment is shown in
Therefore, the invention includes a countersunk prong stone mount comprising:
The invention is also a method for mounting a gem using countersunk prongs in a setting from the bottom of the setting, comprising the steps of:
The instant invention has been shown and described herein in what is considered to be the most practical and preferred embodiment. It is recognized, however, that departures may be made therefrom within the scope of the invention and that obvious modifications will occur to a person skilled in the art.