WO2018087065A1

WO2018087065A1 - Gemstone

Info

Publication number: WO2018087065A1
Application number: PCT/EP2017/078417
Authority: WO
Inventors: Michael Bonke
Original assignee: Realization Desal Ag
Priority date: 2016-11-11
Filing date: 2017-11-07
Publication date: 2018-05-17
Also published as: US20190298011A1; DE102016222189A1; EP3537919B1; EP3537919A1

Abstract

The invention relates to a gemstone (1) comprising: a crown (2) having a plurality of crown facets (11, 12) and a table (10); a girdle (3); and a pavilion (4) having a plurality of pavilion facets (13, 14). A crown angle (α) is between 34.5° and 35.5°, preferably 35°, and a pavilion angle (β) is between 40° and 41°, preferably between 40.2° and 40.8°, particularly preferably 40.5°.

Description

gemstone

description

The invention relates to a gemstone, in particular a diamond, but also other gemstones, such. Gemstones or semi-precious stones, or even synthetic gemstones.

From the state of the art gemstones are known with different cut shapes. In particular, gemstones have prevailed with a brilliant cut or octagonal cut. However, these cuts may have disadvantages. A major problem which gemstones, especially diamonds, have when they are e.g. are processed in a dial of a wristwatch, the size and interaction of the individual facets of the stones. A fully diamond-cut dial can hold up to eight hundred individual brilliants, which are very small with a single diameter of 1 mm or even less. If, in such a case, diamonds having the full facet count of the usual fifty-six facets, plus the tablet facet, then the reflected light splits into so many individual small flashes of light that they are no longer perceived by the viewer as sparkling, as they are lie below the optical sensation threshold. With the full number of facets of a diamond cut in the usual brilliant cut, an incident light beam is split into several hundred small light beams at most impact angles. If this happens with a stone of only 1 mm in diameter, in which the individual facets are only about 0.1 mm in size, the human eye can no longer perceive the individual light flashes as such and only sees a diffuse glow. Only with an extremely strong, punctiform light source, then sparkling and dispersion are perceptible. Thus, a gemstone with brilliant cut in small sizes of the gemstone on a non-optimal dispersion behavior and sparkle on.

The human perception usually works up to a size of 0.2 mm. This means that the viewer perceives two points that are 0.2 mm apart as two separate points. If the distance dwindles to 0.1 mm, the viewer only perceives the two points as one point. at the octagonal cut, which is characterized by the fact that it has only sixteen facets (eight facets in the upper part and eight facets in the lower part) and a Tafelfacette, the individual facets of the upper part of the gemstone are usually still above the individual perceptual size. This means that a viewer with the naked eye can make out a structure of the facet arrangement in the gemstone. On the one hand, it is very difficult for a jewel collector to make a specific arrangement of the individual gemstones, so that the individual stones, in their alignment of the eight facets, are in a certain rhythm with one another. Even if the Jewel-maker took the trouble to do so, and succeeded in enforcing such a unified rhythm in making eight hundred brilliants, in most cases such a uniform rhythm would be disturbing. The reason for this is that this uniform rhythm would optically collide with other design elements of the watch, for example, with a circular shape of the dial itself. However, if the individual octagonal stones are not ordered in their facet orientation, the impression of a restlessness in the dial is created. Furthermore, the octagonal cut has the disadvantage that the breaking of the circular structure in only eight segments brings a certain loss of light with it. At each "corner" of the stone, where the individual facets face each other at a certain angle, the stone loses some light, so an octagonal gemstone does not have an optimal light output optical properties, even with small sizes of the gemstone has.

The solution to these problems is provided by the feature combination of the independent claim.

In particular, the solution is provided by a gemstone comprising a top having a plurality of top facets and a panel, a crimp, and a bottom having a plurality of bottom facets. Advantageously, a top angle is between 34.5 ° and 35.5 °, preferably 35 °, with a bottom angle between 40 ° and 41 °, preferably between 40.2 ° and 40.8 °, particularly preferably 40.5 °. In other words, the angle of the outer upper facets to the circularist plane of the gem, which is perpendicular to a vertical axis of the gemstone or longitudinal axis of the gem, between 34.5 ° and 35.5 °, preferably 35 °. The angle of the lower part facets to a horizontal axis of the gemstone is between 40 ° and 41 °, preferably between 40.2 ° and 40.8 °, particularly preferably 40.5 °. In particular, the top angle is 35 ° and the bottom angle is 40.5 °. By this determination of the upper part angle and the lower part angle, the light guide within the stone runs off in such a way that the total reflection angles are utilized correctly and do not work against the luminous efficiency of the gemstone. A total reflection takes place when a light beam falls below the total reflection angle when attempting to exit from a more dense optical medium into an optically thinner medium. If the light beam strikes the boundary of the two optical media within the total reflection angle, it is "totally" reflected, which means that it loses zero percent of the light in the process, and note that the border areas of the gems are the sensitive areas The proposed angle arrangement avoids any loss of light in the light incident on the gemstone at the edge of a gemstone, thus resulting in greater loss of light than in light incident on the interior of the panel facet the gemstone an optimal overall yield of the incident light.

Furthermore, the described gemstone, in particular due to its top angle, has the advantage of a high dispersion. Dispersion is understood as the decomposition of the white light into its spectral colors. In other words, the term dispersion means different refraction according to the different indices of refraction of the different wavelengths of light. Due to the high degree of dispersion of the gemstone, the gem gets life and a natural color of the gemstone recedes into the background. This is a great advantage especially for gemstones with a "low" color level, because a viewer is thus not able to perceive the low color level and therefore classifies the gemstone as very interesting.The reason is that the impression of the in the Spectral colors decompose white light, ie the simultaneous occurrence of the different spectral colors (rainbow colors) makes it impossible for the viewer to recognize the original color., In other words, the spectral colors dominate the visual impression and drown out the color sensation of the gemstone.

Even with other peculiarities of a gemstone, for example, if a stone is not flawless, but has inclusions that you might recognize with the naked eye, these inclusions with strong dispersion and strong overall light output will not be recognizable.

Furthermore, the proposed gemstone has the advantage that the gem represents an aesthetically interesting and clearly recognizable pattern of light under a kaleidoscope magnifying glass. In particular, due to the upper part angle determined according to the invention and the total light output thereby optimized, it is avoided that the light pattern loses its optical effect and does not appear to be concise. This creates a clear Light pattern, which results in a star of arrows in most Facettierungen the gems in the supervisory view. In the backside view of the gem, the light pattern may yield a flower or arrangement of hearts. The principle of a kaleidoscope magnifying glass, sometimes called the "Hearts &Arrows" magnifying glass, is that the light incident from above, perpendicular to the horizontal axis of the stone, is a white, unfiltered light, but the "scattered light" is , which is incident on this at an angle of greater than 20 ° to the vertical axis of the gem, is filtered through the colored inner wall of the magnifying glass color and comes in a striking color (red or blue) in the stone, and by the color filtering with reduced luminosity , As a result, the incident from above directly above, white light is dominant and optically differs from the more side incident light. This separation of strong white light incident on the stone and reduced colored, side-incident light results in the light-guiding of the white light leaving up to 10 times the optical impression, as compared to the result of the somewhat more oblique colored lighting.

The round list corresponds to a circumferential edge or a separating edge between the upper part (crown) and the lower part (pavilion) in polished gemstones. The top is the upper part of the gem, which is located above the girdle. Accordingly, the lower part of the lower part of the diamond, which is below the Rundiste. The blackboard (plate facet) is the largest facet of the top part of the gemstone. The crown angle (crown angle) is the angle that results in a side view of the gemstone between the lateral boundary line of the top and the circular plane, this boundary line results by an orthogonal projection of a Oberteilfacette on a plane containing the longitudinal axis of the gem. The circular plane is the plane that is parallel to the board and in which the gemstone has the largest cross-sectional dimension. The Rundistenebene is aligned perpendicular to the longitudinal direction of the gem. The base angle (pavilion angle) is that angle which results in a side view of the gemstone between the lateral boundary line of the base and the circular plane, this boundary being obtained by an orthogonal projection of a base facet on a plane containing the longitudinal axis of the gemstone.

The subclaims contain advantageous developments and aspects of the invention.

Preferably, the upper part of the gemstone has an angle plane or two angle planes. "Angled plane" is understood to mean a number of facets that run in the direction of the circumference of the gemstone, ie the outer boundary circle, to the Center of the stone, as the center of the panel, have a very specific angle in relation to the horizontal plane. By providing one or two angle levels instead of three angles as in a gemstone brilliant cut increases the sparkle of the gem. This advantage is of particular importance in the case of small gemstones, since in the first place the problem of a disappearance of the radioactivity of the individual facets due to their small size occurs. Furthermore, the provision of one or two angle levels achieves an aesthetically interesting and valuable light pattern under a kaleidoscope magnifying glass. In addition, the liveliness of the gem is optimized in the critical areas of a flat viewing angle. Thus, it is achieved that the gemstone not only in the plan view sparkles brightly and lively, and that the flashes of light of red and blue light, which are caused by a dispersion of light in the gemstone, are clearly visible even from a flat viewing angle. This advantage unfolds not only in the individual gemstone, but is particularly interesting when it comes to a whole area with many smaller gemstones. This is the case, for example, with a Pavee-designed surface of a piece of jewelery or with a dial of a clock. Due to the reduced number of angle levels, it is achieved that such, usually diamond-shaped areas of a piece of jewelry or a wristwatch from the flat side view look particularly attractive because the eye of the beholder can clearly see the flashes of light. Both the "sparkle" with white light and the flashes of light due to the dispersion are clearly recognizable in such, designed with gemsteinen area.

Preferably, the board is a regular dodecagon. This means that the gemstone is ground in a 12-time rhythm. The 12-he division increases the overall light output of the gemstone. In particular, a combination of a 12 division and one or two angle levels in the top of the gemstone a higher sparkle is achieved while maintaining the overall light output.

Further preferably, the sum of the top facets and the bottom facets is forty-eight or thirty-six or twenty-four facets. Thus, the upper facets are reduced compared to a gemstone brilliant cut. This contributes to increasing the spark of the gemstone. Furthermore, the reduced number of Oberteilfacetten and consequently the reduced total number of facets of the gem leads to a visually impressive or concise perceived light pattern under a kaleidoscope magnifying glass. In addition, the specific number of facets of the upper part makes it possible to optimize the liveliness of the gemstone in the critical areas of a flat viewing angle. The sub-facets preferably include lower circular facets and the upper facets upper circular facets, each of the lower circular facets being precisely aligned with one of the upper circular facets. The juxtaposition of the lower circular facets and the upper circular facets avoids a flash of light being divided into two parts by striking a double facet in the stone. Thus, the sparkle of the gem is increased. In addition, the alignment of the upper round facets to the lower round facets achieves a clear light pattern of the gemstone under a kaleidoscope magnifying glass.

Another aspect of the invention relates to a watch with at least one gemstone, which is arranged in particular in a dial-pointer space. As a dial-pointer room is the space or the receiving space of the clock in which a dial and / or at least one pointer of the clock are arranged. Particularly preferably, the gemstone is arranged in the dial. In the dial are preferably more than two hundred gems, more preferably more than four hundred to eight hundred gems provided. In particular, each of the gemstones have a diameter of less than 2 mm, more preferably equal to or less than 1 mm, on.

The gemstone described above with reference to the above are also given here. In particular, the gemstone described above optimizes the optical properties that are important for a gemstone in the dial-pointer space of the watch, that is, under a watch glass of the watch.

By a 12-he division of the facets in a preferred embodiment of the gem disappears the impression of unrest in the dial.

By reducing the total number of facets in each stone and reducing the angle planes of the top facets to two or one angle, a diamond-finished dial appears calm and homogeneous on the one hand. On the other hand, in any position, even at shallower viewing angles, clear flashes of light from both the white light and the split spectral colors of the light can be seen.

Thus, the above-described gemstone represents a significant improvement in the effect of the gemstone, in particular a diamond, within the dial-pointer space. This is all the more true, as the watch glass, which is located above the dial, or an inner bezel, yes reduced some of the light effect. Both the light incident on the diamonds is reduced by the watch glass and the light emerging from the diamonds is largely swallowed by the watch glass at shallow exit angles, and reduced by approximately 10% to 30% at steep exit angles. Due to the optimization of dispersion, glittering and improving the firing of the gem, especially at low viewing angles, the reduction of light caused by the watch glass is "compensated", so that the gemstone unfolds a good effect under the watch glass Gemstones in watches or watches a special meaning.

Further details, advantages and features of the present invention will become apparent from the following description of exemplary embodiments with reference to the drawing, wherein identical or functionally identical parts are each denoted by the same reference numerals. 1 (a) - (d) show different views of a gemstone according to a first one

Embodiment of the present invention

Fig. 2 (a) - (d) different views of a gem according to a second

Embodiment of the present invention

Fig. 3 (a) - (e) different views of a gem according to a third

Embodiment of the present invention

4 (a) - (d) show different views of a gem according to a fourth

Embodiment of the present invention

Fig. 5 (a) - (d) show different views of a gem according to a fifth

Embodiment of the present invention, and Fig. 6 (a) - (d) different views of a gem according to a sixth

Embodiment of the present invention.

Hereinafter, a gem 1 according to a first embodiment of the present invention will be described in detail with reference to FIG.

In particular, Fig. 1 (a) is a plan view, Fig. 1 (b) is a side view, and Fig. 1 (c) is a bottom view of the gemstone 1. Fig. 1 (d) shows a light pattern of the gemstone 1 from above under a kaleidoscope loupe.

As can be seen from FIG. 1 (b), the gemstone 1 has a top part 2, a round strip 3 and a bottom part 4.

An upper angle α of the gem 1 is between 34.5 ° and 35.5 °, preferably 35 °. Furthermore, a lower part angle β of the gemstone 1 is between 40 ° and 41 °, preferably between 40.2 ° and 40.8 °, particularly preferably 40.5 °. In particular, the upper angle α is 35 ° and the lower angle ß 40.5 °. The upper part 2 comprises a panel 10 and a plurality of upper facets 1 1, 12, wherein the lower part 4 has a plurality of lower part facets 13,14. In particular, the top facets 11, 12 include first top facets 1 1 and second top facets 12 (upper circular facets) 12. Further, the bottom facets 13, 14 include first bottom facets 13 and second bottom facets 14.

Preferably, the panel 10 is formed as a regular dodecagon.

The first upper facets 11 each adjoin the panel 10 with one broad side, with the second upper facets 12 extending from the panel 10 to the circular strip 3 and adjoining the circular strip 3 with a broad side. Thus, in the plan view of Fig. 1 (a), the shape of an inner star is obtained.

The first upper facets 11 have the shape of a pentagon and the second upper facets 12 the shape of a triangle. The first lower part facets 13 have the shape of a triangle and the second lower part facets 12 the shape of a pentagon.

In particular, this embodiment of the gem 1 has twelve such first top facets 1 1 and twelve such second top facets 12. Thus, a total of twenty-four upper facets are provided in the gem 1.

The first lower part facets 13 each adjoin the panel 10 with one broad side, the second lower part facets 14 extending from the panel 10 to the circular strip 3. In particular, this embodiment of the gemstone 1 has twelve such first lower part facets 13 and twelve such second lower part facets 14. Thus, a total of twenty-four lower part facets are provided in the gemstone 1.

The total number of facets of gemstone 1 is 49 facets (48 top and bottom facets plus the board 10).

The upper part 2 of the gemstone 1 has two angle planes, wherein the one angle plane, the first upper facet 12 and the other angle plane, the second upper facet 13 includes.

Correspondingly, the lower part 3 has two angle levels, wherein one angle plane comprises the first lower part facets 13 and the other angle plane comprises the second lower part facets 14.

The lower part 2 merges into a tip (calotte) 5. The tip 5 is formed by the second bottom facets 14. Advantageously, each of the second upper facets 12 is precisely aligned with a first lower facet 13.

FIG. 2 shows a gem 1 according to a second exemplary embodiment of the present invention. In particular, FIG. 2 (a) is a plan view, FIG. 2 (b) is a side view, and FIG. 2 (c) is a bottom view of the gemstone 1.

The second embodiment differs from the first embodiment in principle in that the first upper facets 1 1 each adjoin the panel 10 with one broad side and extend from the panel 10 to the circular strip 3. The second upper facets 12 each adjoin the circular strip 3 with one broad side.

Furthermore, the first upper facets 11 each have the shape of a triangle and the second upper facets 12 have the shape of a pentagon.

Thus, in the plan view of Fig. 2 (a), the shape of an outer star is obtained.

FIG. 2 (d) shows a light pattern of the gemstone 1 from above when the gemstone 1 is viewed under a kaleidoscope magnifying glass.

FIG. 3 shows a gem 1 according to a third exemplary embodiment of the present invention.

In particular, FIG. 3 (a) shows a plan view, FIG. 3 (b) shows a side view, and FIG. 3 (c) shows a bottom view of the gemstone 1. In this embodiment, the first shell facets 1 1 each border the panel 10 with one broad side and extending from the panel 10 to the round list 3 as in the second embodiment.

However, in the third exemplary embodiment, the second upper facets 12 each adjoin the round strip 3 with one broad side and extend from the panel 10 to the circular strip 3. Thus, both the first upper facets 11 and the second upper facets 12 extend from the panel 10 to the upper side Round list 3.

The first upper facets 1 1 and the second upper facets 12 are triangular in shape.

Thus, in the plan view of Fig. 3 (a), the shape of a full star is obtained. The upper facets 1 1, 12 result in this embodiment, only a single angle plane in the upper part 2 of the gem 1, since all Oberteilfacetten 1 1, 12 go from the round list 3 to panel 10. This means that all upper facets 1 1, 12 have the same angle of attack, which is the same as the upper part angle. FIGS. 3 (d) and (e) show light patterns of the gemstone 1 from above and below under a kaleidoscope magnifying glass.

FIG. 4 shows a gem 1 according to a fourth exemplary embodiment of the present invention.

In particular, FIG. 4 (a) is a plan view, FIG. 4 (b) is a side view, and FIG. 4 (c) is a bottom view of the gemstone 1.

In this embodiment, the upper part 2 only a plurality of first Oberteililfacetten 1 1. That is, the top facets include only the first top facets 11. The first upper facets 1 1 are each formed in the shape of a quadrilateral and adjoin the panel 10 and the Rundist 2 at. Thus, the gemstone 1 in the upper part 2 only one angle level.

When gemstone 1 twelve Oberteilfacetten or twelve first Oberteilfacetten 1 1 and twenty-four lower facets 13,14 are provided.

The total number of facets of gemstone 1 is 37 facets (36 top and bottom facets plus the board 10). Each of the first upper facets 11 is advantageously juxtaposed with a first lower facet 13.

FIG. 4 (d) shows a light pattern of the gemstone 1 from above when the gemstone 1 is viewed under a kaleidoscope magnifying glass.

FIG. 5 shows a gem 1 according to a fifth embodiment of the present invention.

More specifically, Fig. 5 (a) is a plan view, Fig. 5 (b) is a side view, and Fig. 5 (c) is a bottom view of the gemstone 1.

The difference between the gemstone 1 according to the fifth embodiment and the gemstone 1 according to the fourth embodiment is that the first upper facet 1 1 are arranged in the fifth embodiment in the circumferential direction or in the direction of the Rundist 3 with respect to the first Unterteililfacetten 13 twisted. As in the fourth embodiment, the gemstone 1 of Figure 5 on an angle plane in the upper part 2.

FIG. 5 (d) shows the resulting light pattern of the gemstone 1 from above when the gemstone 1 is viewed under a kaleidoscope magnifying glass. FIG. 6 illustrates a gem 1 according to a sixth embodiment of the present invention.

In the sixth embodiment, the upper part 2 of the gemstone 1 corresponds to the structure in terms of the upper part 2 of the gemstone 1 according to the fourth embodiment. In particular, Fig. 6 (a) is a plan view, Fig. 6 (b) is a side view, and Fig. 6 (c) is a bottom view of the gemstone 1.

In the exemplary embodiment of FIG. 6, however, the lower part 4 has only one angle plane, which comprises a plurality of first lower part facets 13. This means that the lower part facets comprise only the first lower part facets 13. In particular, the lower part 4 has twelve lower part facets or twelve first lower part facets 13.

The first lower part facets 13 are each configured in the shape of a triangle and extend from the top 5 (caliber) to the circular strip 3. The first lower part facets 13 adjoin the round strip 3 with one broad side.

Furthermore, the tip 5 is formed by the first lower part facets 13. The total number of facets of gemstone 1 is 25 facets (24 top and bottom facets plus the board 10).

FIG. 6 (d) shows the resulting light pattern of the gemstone 1 from above when the gemstone 1 is viewed under a kaleidoscope magnifying glass.

The above-described embodiments of the gemstone 1 have a variety of advantages simultaneously.

In particular, the gemstones 1 described above reflect a very high percentage of the light impinging on them back into the eye of the beholder. Further, the gems 1 fanned as high a proportion of the incident white light in the spectral colors fanned back into the eye of the beholder. Furthermore, in the gemstones 1, a high proportion of the incident light is reflected as a single flash of light. This means that the gemstones do not convert concentrated light into a scattered diffused light. Furthermore, the gems 1 are such designed so that they return the incident light to the viewer so that the gems from as many as possible (even shallow) positions strongly shine, have dispersion and sparkle. In addition, the gemstone 1 are optimized for use in a watch. This means that the gemstones 1 have less in their sparkling and dispersion behavior but thereby stronger flashes of light, the gems 1 sparkle even in shallow viewing angles and disperse dispersion bundles. Furthermore, make the gems 1 according to the illustrated embodiments, a quiet, not design dominant impression. Finally, the gemstones are 1 kaleidoscope-capable. That is, the gems 1 produce an aesthetically pleasing and clearly recognizable light symbol when viewing the gems 1 under a kaleidoscope magnifying glass.

In other words, the interaction of individual optimized optical properties is optimized in the above-described gemstones 1.

In addition to the above written description of the invention, reference is hereby made explicitly to the drawings of the invention in FIGS. 1 to 6 for their supplementary disclosure.

LIST OF REFERENCE NUMBERS

1 gemstone

2 top (crown)

3 round list

4 lower part (pavilion)

5 tip (calette)

10 blackboard

1 1 first top facets

12 second shell facets

13 first lower part facets

14 second upper facets α upper part angle (crown angle) ß lower part angle (pavilion angle)

Claims

claims

1 . Gemstone (1) comprising:

a top (2) having a plurality of top facets (1 1, 12) and a panel (10),

a round list (3), and

a lower part (4) having a plurality of lower part facets (13, 14),

characterized in that

a top angle (a) is between 34.5 ° and 35.5 °, preferably 35 °, and a bottom angle (β) between 40 ° and 41 °, preferably between 40.2 ° and 40.8 °, particularly preferably 40 , 5 °.

2. gem stone according to claim 1, characterized in that the upper part (2) of the gemstone (1) have an angle plane or two angle planes.

3. gem stone according to one of the preceding claims, characterized in that the board (10) is a regular dodecagon.

4. Gemstone according to one of the preceding claims, characterized in that the sum of the upper facet parts (1 1, 12) and the lower part facets (13, 14) is forty-eight or thirty-six or twenty-four facets.

5. Gemstone according to one of the preceding claims, characterized in that the lower part facets lower Rundistfacetten (13) and the Oberteilfacetten upper Rundistfacetten (12), each of the lower Rundistfacetten (13) is precisely aligned with one of the upper Rundistfacetten (12).

6. Clock with at least one gemstone (1), which is arranged in a dial-pointer room or in a watch glass.