CN221113331U - Simulated diamond metal ornament - Google Patents

Abstract

The utility model discloses a simulated diamond metal ornament, which comprises a simulated diamond main body, wherein the simulated diamond main body is provided with a decoration surface and a bottom plane, the decoration surface is provided with a concave central area, the central area is surrounded by a ring, a plurality of refraction units are distributed in a ring array, each refraction unit is connected with the central area, and the edges of every two adjacent refraction units are shared; the narrow end of the refraction unit is connected with the central area, and the wide end of the refraction unit extends to the edge of the decorative surface; the narrow end of the refraction unit is arranged in the wide end direction, and the refraction unit comprises a first refraction area, a second refraction area and a third refraction area which are sequentially connected; the first refraction area is a first concave area formed by four triangular surfaces; the second refraction area is a second concave area formed by eight triangular surfaces; the third refractive region is a third concave region composed of six triangular faces. The simulated diamond metal ornament provided by the utility model has the advantages that the plurality of refraction units are distributed in the outer ring array of the central area, and after the refraction units refract light, the decorative surface is bright and the color of the light is rich.

Description

Simulated diamond metal ornament

Technical Field

The utility model relates to an ornament, in particular to a simulated diamond metal ornament.

Background

The existing simulated diamond is often matched with other noble metals in the jewelry field such as gold, platinum and the like, but the manufacturing mode of embedding the simulated diamond in the metal has defects, and many noble metals have the defects of low hardness and poor toughness, so the simulated diamond cannot be used as an embedding substrate.

In addition, as the simulated diamond itself, the cutting process is used to reflect light rays on different sections of the diamond, and refract the light rays inside the simulated diamond, so that the simulated diamond presents a bright brilliance.

The refraction surface formed by the existing simulated diamond after cutting still has the defects of refraction effect, namely, the existing refraction structure has less dazzling light quantity, the color of the light formed by refraction is not rich enough, and the light emitted by the light is not bright enough.

Therefore, the refractive surface of conventional simulated diamond needs to be improved.

Disclosure of utility model

Aiming at the defects in the prior art, the utility model aims to provide the simulated diamond metal ornament, and the purpose of designing the simulated diamond metal ornament is to make the decorative surface bright and the light color rich.

In order to solve the technical problems, the utility model is realized by the following scheme: the utility model relates to a simulated diamond metal ornament, which comprises a simulated diamond main body, wherein the simulated diamond main body is provided with a decoration surface and a bottom plane, the decoration surface is provided with a concave central area, the central area is surrounded by a ring, a plurality of refraction units are distributed in a ring array, each refraction unit is connected with the central area, and the edges of every two adjacent refraction units are shared;

The narrow end of the refraction unit is connected with the central area, and the wide end of the refraction unit extends to the edge of the decorative surface;

The narrow end of the refraction unit is connected with the wide end of the refraction unit in a direction from the narrow end to the wide end, and the refraction unit comprises a first refraction area, a second refraction area and a third refraction area which are sequentially connected with each other;

the first refraction area is a first concave area formed by four triangular surfaces;

The second refraction area is a second concave area formed by eight triangular surfaces;

The third refractive region is a third concave region composed of six triangular faces.

Further, the central area is a round decoration area.

Further, the four triangular faces of the first concave region share a first common vertex, and the four triangular faces include:

Two 1 st triangular surfaces symmetrical with the first common vertex, the two 1 st triangular surfaces not having a common edge;

The three-angle-adjustable triangular support comprises two 2 nd triangular surfaces which are in common edge and are in common edge with the two 1 st triangular surfaces respectively, wherein a first included angle a between the 1 st triangular surfaces and the 2 nd triangular surfaces is a pure angle, and a second included angle b between the two 2 nd triangular surfaces is larger than 180 degrees.

Further, the eight triangular faces of the second concave region share a second common vertex and each two adjacent triangular faces in the second concave region share edges.

Still further, the eight triangular faces include:

the two third triangular surfaces are in common edge, and a third included angle c between the two third triangular surfaces is more than 180 degrees;

Two third triangular surfaces 4, wherein the two third triangular surfaces 4 are adjacent to the two third triangular surfaces 3 respectively, and a fourth included angle d between the third triangular surfaces 4 and the third triangular surfaces 3 is an obtuse angle in a group of adjacent third triangular surfaces 4 and 3;

Two 5 th triangular surfaces, wherein the two 5 th triangular surfaces are adjacent to the two 4 th triangular surfaces respectively, and a fifth included angle e between the 5 th triangular surface and the 4 th triangular surface is larger than 180 degrees in a group of adjacent 5 th triangular surfaces and 4 th triangular surfaces;

And the two 6 th triangular surfaces are in common edge and are adjacent to the two 5 th triangular surfaces respectively, a sixth included angle f between the 6 th triangular surface and the 5 th triangular surface is smaller than or equal to 90 degrees in a group of adjacent 6 th triangular surfaces and 5 th triangular surfaces, and a seventh included angle g between the two 6 th triangular surfaces is larger than 180 degrees.

Further, the six triangular faces of the third concave region have a third common vertex, and the six triangular faces of the third concave region include:

The two third triangular surfaces 7 are in common edge, and an eighth included angle h between the two third triangular surfaces 7 is larger than 180 degrees;

Two 8 th triangular surfaces, the two 8 th triangular surfaces are adjacent to the two 7 th triangular surfaces respectively, and a ninth included angle i between the 8 th triangular surface and the 7 th triangular surface is less than or equal to 90 degrees in a group of adjacent 8 th triangular surfaces and 7 th triangular surfaces;

And two 9 th triangular surfaces, wherein the two 9 th triangular surfaces are adjacent to the two 8 th triangular surfaces respectively, and a tenth included angle j between the 9 th triangular surface and the 8 th triangular surface in a group of adjacent 9 th triangular surfaces and 8 th triangular surfaces is larger than 180 degrees.

Further, the non-common edge of the 9 th triangular surface is the edge line of the simulated diamond metal ornament.

Compared with the prior art, the utility model has the beneficial effects that:

1. The simulated diamond metal ornament is characterized in that a plurality of refraction units are distributed on the outer ring array of the central area, each refraction unit is composed of a plurality of refraction areas, each refraction area is provided with a plurality of triangular surfaces, and different light rays are refracted out through the triangular surfaces, so that the purposes of bright decorative surfaces and rich colors of the light rays are achieved.

2. The triangular surface tangential plane angle distribution of the simulated diamond refraction area distribution is reasonable, and the manufacturing is convenient.

Drawings

Fig. 1 is a diagram showing a decorative surface structure of a first artificial diamond metal ornament according to embodiment 1 of the present utility model.

Fig. 2 is a diagram showing the structure of a refractive unit of a first simulated diamond metallic ornament in embodiment 1 of the present utility model.

Fig. 3 is a diagram showing the structure of the first refractive region in embodiment 1 of the present utility model.

Fig. 4 is a diagram showing the structure of a second refractive region in embodiment 1 of the present utility model.

Fig. 5 is a diagram showing the structure of a third refractive region in embodiment 1 of the present utility model.

Fig. 6 is a diagram showing a first embodiment of the present utility model for cutting a metal ornament by simulating diamond.

Fig. 7 is a diagram showing a second construction of a cutting step of the first simulated diamond metal ornament according to embodiment 1 of the present utility model.

Fig. 8 is a diagram showing a three-step structure of cutting a metal ornament of a first simulated diamond according to embodiment 1 of the present utility model.

Fig. 9 is a diagram showing a fourth construction of a cutting step of a metal ornament according to a first embodiment of the present utility model.

Fig. 10 is a diagram showing a fifth construction of a cutting step of a metal ornament according to a first embodiment of the present utility model.

Fig. 11 is a top view of a first simulated diamond metal ornament according to example 1 of the present utility model.

Fig. 12 is a diagram showing a structure of a decorative surface of a second type of artificial diamond metal ornament according to example 2 of the present utility model.

Fig. 13 is a diagram showing a construction of a cutting step of a second simulated diamond metal ornament according to embodiment 2 of the present utility model.

Fig. 14 is a diagram showing a second construction of a cutting step of a metal ornament according to a second embodiment of the present utility model.

FIG. 15 is a diagram showing a third construction of a cutting step of a second simulated diamond metal ornament according to embodiment 2 of the present utility model.

Fig. 16 is a diagram showing a fourth construction of a cutting step of a second simulated diamond metal ornament according to embodiment 2 of the present utility model.

Fig. 17 is a plan view of a second simulated diamond metal ornament according to example 2 of the present utility model.

Fig. 18 is a diagram showing a structure of a decorative surface of a third artificial diamond metal ornament according to example 3 of the present utility model.

Fig. 19 is a diagram showing a construction of a cutting step of a third simulated diamond metal ornament according to embodiment 3 of the present utility model.

FIG. 20 is a diagram showing a second construction of a third simulated diamond metal ornament according to embodiment 3 of the present utility model.

FIG. 21 is a diagram showing a third construction of a cutting step of a third simulated diamond metal ornament according to embodiment 3 of the present utility model.

FIG. 22 is a diagram showing a fourth construction of a cutting step of a third simulated diamond metal ornament according to embodiment 3 of the present utility model.

FIG. 23 is a diagram showing a fifth construction of a cutting step of a third simulated diamond metal ornament according to embodiment 3 of the present utility model.

FIG. 24 is a diagram showing a sixth construction of a cutting step of a third simulated diamond metal ornament according to embodiment 3 of the present utility model.

Fig. 25 is a top view of a third simulated diamond metal ornament according to example 3 of the present utility model.

The reference numerals in the drawings: the simulated diamond body 1, refractive element 2, central zone 3, first refractive zone 21, second refractive zone 22, third refractive zone 23, 1 st triangular surface 211, 2 nd triangular surface 212, 3 rd triangular surface 221, 4 th triangular surface 222, 5 th triangular surface 223, 6 th triangular surface 224, 7 th triangular surface 231, 8 th triangular surface 232, and 9 th triangular surface 233.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described in the following with reference to the drawings in the embodiments of the present utility model, so that the advantages and features of the present utility model can be more easily understood by those skilled in the art, and thus the protection scope of the present utility model is more clearly and clearly defined. It should be apparent that the described embodiments of the utility model are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In addition, the technical features of the different embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

Example 1: the specific structure of the utility model is as follows:

Referring to fig. 1-11, fig. 1-11 are block diagrams and steps for making the simulated diamond metal ornament of the present utility model. The utility model relates to a simulated diamond metal ornament, which comprises a simulated diamond main body 1, wherein the simulated diamond main body 1 is provided with a decoration surface and a bottom plane, the decoration surface is provided with a concave central area 3, the central area 3 is surrounded, a plurality of refraction units 2 are distributed in a ring array, each refraction unit 2 is connected with the central area 3, and the edges between every two adjacent refraction units 2 are shared;

The narrow end of the refraction unit 2 is connected with the central area 3, and the wide end of the refraction unit extends to the edge of the decorative surface;

a first refraction area 21, a second refraction area 22 and a third refraction area 23 which are sequentially connected are arranged from the narrow end of the refraction unit 2 to the wide end;

Wherein the first refraction area 21 is a first concave area formed by four triangular surfaces;

the second refractive region 22 is a second concave region composed of eight triangular faces;

the third refraction area 23 is a third concave area composed of six triangular faces.

A preferred technical scheme of the embodiment is as follows: the central area 3 is a circular decoration area.

A preferred technical scheme of the embodiment is as follows: the four triangular surfaces of the first concave region share a first common vertex, and the four triangular surfaces comprise:

two 1 st triangular surfaces 211 symmetrical with the first common vertex, the two 1 st triangular surfaces 211 not having a common edge;

The two 2 nd triangular surfaces 212 are shared with the two 1 st triangular surfaces 211 respectively, a first included angle a between the 1 st triangular surfaces 211 and the 2 nd triangular surfaces 212 is a pure angle, and a second included angle b between the two 2 nd triangular surfaces 212 is more than 180 degrees.

A preferred technical scheme of the embodiment is as follows: the eight triangular surfaces of the second concave region share a second common vertex, and every two adjacent triangular surfaces in the second concave region share edges.

A preferred technical scheme of the embodiment is as follows: the eight triangular faces include:

Two 3 rd triangular surfaces 221, wherein the two 3 rd triangular surfaces 221 are co-edge and a third included angle c between the two 3 rd triangular surfaces 221 is larger than 180 degrees;

Two 4 th triangular surfaces 222, wherein the two 4 th triangular surfaces 222 are adjacent to the two 3 rd triangular surfaces 221 respectively, and a fourth included angle d between the 4 th triangular surfaces 222 and the 3 rd triangular surfaces 221 is an obtuse angle in a group of adjacent 4 th triangular surfaces 222 and 3 rd triangular surfaces 221;

Two 5 th triangular surfaces 223, the two 5 th triangular surfaces 223 are adjacent to the two 4 th triangular surfaces 222, respectively, and a fifth included angle e between the 5 th triangular surfaces 223 and the 4 th triangular surfaces 222 is greater than 180 degrees in a group of adjacent 5 th triangular surfaces 223 and 4 th triangular surfaces 222;

Two 6 th triangular surfaces 224, the two 6 th triangular surfaces 224 are co-edge and are adjacent to two 5 th triangular surfaces 223 respectively, a sixth included angle f between the 6 th triangular surfaces 224 and the 5 th triangular surfaces 223 is smaller than or equal to 90 degrees in a group of adjacent 6 th triangular surfaces 224 and 5 th triangular surfaces 223, and a seventh included angle g between the two 6 th triangular surfaces 224 is larger than 180 degrees.

A preferred technical scheme of the embodiment is as follows: the six triangular faces of the third concave region have a third common vertex, and the six triangular faces of the third concave region include:

Two 7 th triangular surfaces 231, wherein the two 7 th triangular surfaces 231 are co-bordered and an eighth included angle h between the two 7 th triangular surfaces 231 is larger than 180 degrees;

Two 8 th triangular surfaces 232, wherein the two 8 th triangular surfaces 232 are adjacent to the two 7 th triangular surfaces 231 respectively, and a ninth included angle i between the 8 th triangular surfaces 232 and the 7 th triangular surfaces 231 is less than or equal to 90 degrees in a group of adjacent 8 th triangular surfaces 232 and 7 th triangular surfaces 231;

Two 9 th triangular surfaces 233, the two 9 th triangular surfaces 233 are adjacent to the two 8 th triangular surfaces 232, respectively, and a tenth included angle j between the 9 th triangular surfaces 233 and the 8 th triangular surfaces 232 is larger than 180 ° in a group of adjacent 9 th triangular surfaces 233 and 8 th triangular surfaces 232.

A preferred technical scheme of the embodiment is as follows: the non-co-edge of the 9 th triangular surface 233 is the edge line of the simulated diamond metal ornament.

The following is the cutting steps of the first simulated diamond metal ornament of the utility model:

Step one, as shown in fig. 6, the first portion is completed with a 120 ° side tip knife along the line in fig. 6 for a total of 12 facets. Wherein the first line is a first tangential plane, the included angle is 75 DEG + -15 DEG, and the complement angle is 285 DEG + -15 DEG; wherein the second line is a second tangential plane, the included angle is 105 DEG + -15 DEG, and the complement angle is 255 DEG + -15 DEG; wherein the third line is a third tangential plane, the included angle is 135 degrees plus or minus 15 degrees, and the complement angle is 225 degrees plus or minus 15 degrees; wherein the fourth line is a fourth tangential plane, the included angle is 105 DEG + -15 DEG, and the complement angle is 255 DEG + -15 DEG; wherein the fifth line is a fifth tangential plane, the included angle is 135 degrees plus or minus 15 degrees, and the complement angle is 225 degrees plus or minus 15 degrees; wherein the sixth line is a sixth tangential plane, the included angle is 255 DEG + -15 DEG, and the complement angle is 135 DEG + -15 DEG; wherein the seventh line is a seventh tangential plane, the included angle is 105 DEG + -15 DEG, and the complement angle is 255 DEG + -15 DEG; wherein the eighth line is an eighth tangential plane, the included angle is 285 DEG+ -15 DEG, and the complement angle is 75 DEG+ -15 DEG; wherein the ninth line is a ninth tangential plane, the included angle is 135 degrees+ -15 degrees, and the complement angle is 45 degrees+ -15 degrees; wherein the tenth line is a tenth tangential plane, the included angle is 15 DEG + -15 DEG, and the complement angle is 345 DEG + -15 DEG; wherein the eleventh line is an eleventh tangential plane, the included angle is 345 DEG + -15 DEG, and the complement angle is 15 DEG + -15 DEG; wherein the twelfth line is a twelfth tangential plane, the included angle is 315 DEG + -15 DEG, and the complement angle is 45 DEG + -15 deg.

Step two, as shown in fig. 7, the second portion is completed with a 120 ° side tip knife along the line in fig. 7 for a total of 12 facets. Wherein the first line is a first tangential plane, the included angle is 10.78 DEG + -15 DEG, and the complement angle is 349.21 DEG + -15 DEG; wherein the second line is a second tangential plane, the included angle is 340.78 DEG + -15 DEG, and the complement angle is 19.21 DEG + -15 DEG; wherein the third line is a third tangential plane, the included angle is 310.78 DEG + -15 DEG, and the complement angle is 49.21 DEG + -15 DEG; wherein the fourth line is a fourth tangential plane, the included angle is 280.78 DEG + -15 DEG, and the complement angle is 79.21 DEG + -15 DEG; wherein the fifth line is a fifth tangential plane, the included angle is 250.78 DEG + -15 DEG, and the complement angle is 109.21 DEG + -15 DEG; wherein the sixth line is a sixth tangential plane, the included angle is 220.78 DEG + -15 DEG, and the complement angle is 139.21 DEG + -15 DEG; wherein the seventh line is a seventh tangential plane, the included angle is 10.78 DEG + -15 DEG, and the complement angle is 349.21 DEG + -15 DEG; wherein the eighth line is an eighth tangential plane, the included angle is 340.78 degrees+/-15 degrees, and the complement angle is 19.21 degrees+/-15 degrees; wherein the ninth line is a ninth tangential plane, the included angle is 130.78 degrees+ -15 degrees, and the complement angle is 229.21 degrees+ -15 degrees; wherein the tenth line is a tenth tangential plane, the included angle is 100.78 degrees+/-15 degrees, and the complement angle is 259.21 degrees+/-15 degrees; wherein the eleventh line is an eleventh tangential plane, the included angle is 70.78 DEG + -15 DEG, and the complement angle is 289.21 DEG + -15 DEG; wherein the twelfth line is a twelfth tangential plane, the included angle is 40.78 DEG + -15 DEG, and the complement angle is 319.26 DEG + -15 deg.

Step three, as shown in fig. 8, the third section is completed with a 120 ° side tip knife along the line in fig. 8 for a total of 12 facets. Wherein the first line is a first tangential plane, the included angle is 319.26 DEG + -15 DEG, and the complement angle is 40.78 DEG + -15 DEG; wherein the second line is a second tangential plane, the included angle is 289.21 DEG + -15 DEG, and the complement angle is 100.78 DEG + -15 DEG; wherein the third line is a third tangential plane, the included angle is 259.21 DEG + -15 DEG, and the complement angle is 100.78 DEG + -15 DEG; wherein the fourth line is a fourth tangential plane, the included angle is 229.21 DEG + -15 DEG, and the complement angle is 130.78 DEG + -15 DEG; wherein the fifth line is a fifth tangential plane, the included angle is 19.21 DEG + -15 DEG, and the supplementary angle is 340.79 DEG + -15 DEG; wherein the sixth line is a sixth tangential plane, the included angle is 349.21 DEG + -15 DEG, and the complement angle is 10.78 DEG + -15 DEG; wherein the seventh line is a seventh tangential plane, the included angle is 139.21 DEG+ -15 DEG, and the complement angle is 220.78 DEG+ -15 DEG; wherein the eighth line is an eighth tangential plane, the included angle is 109.21 degrees+/-15 degrees, and the complement angle is 250.78 degrees+/-15 degrees; wherein the ninth line is a ninth tangential plane, the included angle is 79.21 degrees+ -15 degrees, and the supplementary angle is 280.78 degrees+ -15 degrees; wherein the tenth line is a tenth tangential plane, the included angle is 49.21 DEG + -15 DEG, and the supplementary angle is 310.78 DEG + -15 DEG; wherein the eleventh line is an eleventh tangential plane, the included angle is 19.21 DEG + -15 DEG, and the complement angle is 340.78 DEG + -15 DEG; wherein the twelfth line is a twelfth tangential plane, the included angle is 349.21 DEG + -15 DEG, and the complement angle is 10.78 DEG + -15 deg.

Step four, as shown in fig. 9, the fourth part is cut with a 0.6 graver along the line in fig. 9 to form a circular structure of the central region 3.

And step five, forming a cutting surface shown in fig. 10 after cutting is completed.

Example 2:

Referring to fig. 12, fig. 12 is a diagram showing a decoration surface structure of a second type of artificial diamond metal ornament according to embodiment 2 of the present utility model.

The following is the cutting steps of the second simulated diamond metal ornament of the utility model:

Step one, as shown in fig. 13, the first portion is completed with a 120 ° side tip knife along the line in fig. 13 for a total of 12 facets. Wherein the first line is a first tangential plane, the included angle is 0 DEG + -15 DEG, and the complement angle is 360 DEG + -15 DEG; wherein the second line is a second tangential plane, the included angle is 30 DEG + -15 DEG, and the complement angle is 330 DEG + -15 DEG; wherein the third line is a third tangential plane, the included angle is 60 DEG + -15 DEG, and the complement angle is 300 DEG + -15 DEG; wherein the fourth line is a fourth tangential plane, the included angle is 90 DEG + -15 DEG, and the complement angle is 270 DEG + -15 DEG; wherein the fifth line is a fifth tangential plane, the included angle is 120 DEG + -15 DEG, and the complement angle is 240 DEG + -15 DEG; wherein the sixth line is a sixth tangential plane, the included angle is 150 DEG + -15 DEG, and the complement angle is 210 DEG + -15 DEG; wherein the seventh line is a seventh tangential plane, the included angle is 180 DEG + -15 DEG, and the complement angle is 180 DEG + -15 DEG; wherein the eighth line is an eighth tangential plane, the included angle is 210 DEG + -15 DEG, and the complement angle is 150 DEG + -15 DEG; wherein the ninth line is a ninth tangential plane, the included angle is 240 DEG+ -15 DEG, and the complement angle is 120 DEG+ -15 DEG; wherein the tenth line is a tenth tangential plane, the included angle is 270 DEG + -15 DEG, and the complement angle is 90 DEG + -15 DEG; wherein the eleventh line is an eleventh tangential plane, the included angle is 300 DEG + -15 DEG, and the complement angle is 60 DEG + -15 DEG; wherein the twelfth line is a twelfth tangential plane, the included angle is 330 DEG + -15 DEG, and the complement angle is 30 DEG + -15 deg.

Step two, as shown in fig. 14, the second portion is completed with a 120 ° side tip knife along the line in fig. 14 for a total of 12 facets. Wherein the first line is a first tangential plane, the included angle is 328.01 DEG + -15 DEG, and the complement angle is 31.98 DEG + -15 DEG; wherein the second line is a second tangential plane, the included angle is 358.01 DEG + -15 DEG, and the complement angle is 1.98 DEG + -15 DEG; wherein the third line is a third tangential plane, the included angle is 28.01 DEG + -15 DEG, and the complement angle is 331.98 DEG + -15 DEG; wherein the fourth line is a fourth tangential plane, the included angle is 58.01 DEG + -15 DEG, and the complement angle is 301.98 DEG + -15 DEG; wherein the fifth line is a fifth tangential plane, the included angle is 88.01 DEG + -15 DEG, and the supplementary angle is 271.98 DEG + -15 DEG; wherein the sixth line is a sixth tangential plane, the included angle is 118.01 DEG + -15 DEG, and the complement angle is 241.98 DEG + -15 DEG; wherein the seventh line is a seventh tangential plane, the included angle is 31.98 degrees+ -15 degrees, and the complement angle is 328.01 degrees+ -15 degrees; wherein the eighth line is an eighth tangential plane, the included angle is 1.985 degrees+ -15 degrees, and the complement angle is 358.01 degrees+ -15 degrees; wherein the ninth line is a ninth tangential plane, the included angle is 331.98 degrees+/-15 degrees, and the complement angle is 28.01 degrees+/-15 degrees; wherein the tenth line is a tenth tangential plane, the included angle is 301.98 degrees+/-15 degrees, and the complement angle is 58.01 degrees+/-15 degrees; wherein the eleventh line is an eleventh tangential plane, the included angle is 271.98 degrees+/-15 degrees, and the complement angle is 88.01 degrees+/-15 degrees; wherein the twelfth line is a twelfth tangential plane, the included angle is 241.98 DEG+ -15 DEG, and the complement angle is 118.01 DEG+ -15 deg.

Step three, as shown in fig. 15, the third section is completed with a 120 ° side tip knife along the line in fig. 15 for a total of 12 facets. Wherein the first line is a first tangential plane, the included angle is 31.98 degrees plus or minus 15 degrees, and the supplementary angle is 328.01 degrees plus or minus 15 degrees; wherein the second line is a second tangential plane, the included angle is 241.98 DEG + -15 DEG, and the complement angle is 118.01 DEG + -15 DEG; wherein the third line is a third tangential plane, the included angle is 271.98 degrees+/-15 degrees, and the complement angle is 88.01 degrees+/-15 degrees; wherein the fourth line is a fourth tangential plane, the included angle is 301.98 DEG + -15 DEG, and the complement angle is 58.01 DEG + -15 DEG; wherein the fifth line is a fifth tangential plane, the included angle is 331.98 degrees+/-15 degrees, and the complement angle is 28.01 degrees+/-15 degrees; wherein the sixth line is a sixth tangential plane, the included angle is 1.985 DEG+ -15 DEG, and the complement angle is 358.01 DEG+ -15 DEG; wherein the seventh line is a seventh tangential plane, the included angle is 328.01 DEG + -15 DEG, and the complement angle is 31.98 DEG + -15 DEG; wherein the eighth line is an eighth tangential plane, the included angle is 118.01 degrees+/-15 degrees, and the complement angle is 241.98 degrees+/-15 degrees; wherein the ninth line is a ninth tangential plane, the included angle is 88.01 DEG + -15 DEG, and the supplementary angle is 271.98 DEG + -15 DEG; wherein the tenth line is a tenth tangential plane, the included angle is 58.01 degrees+ -15 degrees, and the complement angle is 301.98 degrees+ -15 degrees; wherein the eleventh line is an eleventh tangential plane, the included angle is 28.01 DEG + -15 DEG, and the complement angle is 331.98 DEG + -15 DEG; wherein the twelfth line is a twelfth tangential plane, the included angle is 358.01 DEG + -15 DEG, and the complement angle is 1.98 DEG + -15 deg.

Step four, after cutting, a decorative surface is formed as shown in fig. 6, and fig. 17 is a top view of a second simulated diamond metal ornament according to embodiment 2 of the present utility model.

Example 3:

As shown in fig. 18, fig. 18 is a diagram showing a decorative surface structure of a third artificial diamond metal ornament according to embodiment 3 of the present utility model.

The following is the cutting procedure for the third simulated diamond metallic ornament in example 3 of the present utility model:

Step one, as shown in fig. 19, the first portion is completed with a 120 ° side tip knife along the line in fig. 19 for a total of 14 facets. Wherein the first line is a first tangential plane, the included angle is 0 DEG + -15 DEG, and the complement angle is 360 DEG + -15 DEG; wherein the second line is a second tangential plane, the included angle is 25.71 DEG + -15 DEG, and the complement angle is 334.28 DEG + -15 DEG; wherein the third line is a third tangential plane, the included angle is 51.42 DEG + -15 DEG, and the complement angle is 308.57 DEG + -15 DEG; wherein the fourth line is a fourth tangential plane, the included angle is 77.14 DEG + -15 DEG, and the complement angle is 282.85 DEG + -15 DEG; wherein the fifth line is a fifth tangential plane, the included angle is 102.85 DEG + -15 DEG, and the complement angle is 257.14 DEG + -15 DEG; wherein the sixth line is a sixth tangential plane, the included angle is 128.57 DEG + -15 DEG, and the complement angle is 231.42 DEG + -15 DEG; wherein the seventh line is a seventh tangential plane, the included angle is 154.28 DEG + -15 DEG, and the complement angle is 205.71 DEG + -15 DEG; wherein the eighth line is an eighth tangential plane, the included angle is 180 DEG + -15 DEG, and the complement angle is 180 DEG + -15 DEG; wherein the ninth line is a ninth tangential plane, the included angle is 205.71 degrees+ -15 degrees, and the complement angle is 154.28 degrees+ -15 degrees; wherein the tenth line is a tenth tangential plane, the included angle is 231.42 DEG + -15 DEG, and the complement angle is 128.57 DEG + -15 DEG; wherein the eleventh line is an eleventh tangential plane, the included angle is 257.14 DEG + -15 DEG, and the complement angle is 102.85 DEG + -15 DEG; wherein the twelfth line is a twelfth tangential plane, the included angle is 282.85 DEG + -15 DEG, and the complement angle is 77.14 DEG + -15 DEG; wherein the thirteenth line is a thirteenth tangential plane, the included angle is 308.57 DEG + -15 DEG, and the complement angle is 51.42 DEG + -15 DEG; wherein the fourteenth line is a fourteenth tangential plane, the included angle is 334.28 DEG + -15 DEG, and the complement angle is 25.71 DEG + -15 deg.

Step two, as shown in fig. 20, the second portion is completed with a 120 ° side tip knife along the line in fig. 20 for a total of 14 facets. Wherein the first line is a first tangential plane, the included angle is 30.68 DEG + -15 DEG, and the complement angle is 329.31 DEG + -15 DEG; wherein the second line is a second tangential plane, the included angle is 56.40 DEG + -15 DEG, and the complement angle is 303.59 DEG + -15 DEG; wherein the third line is a third tangential plane, the included angle is 82.11 DEG + -15 DEG, and the complement angle is 277.88 DEG + -15 DEG; wherein the fourth line is a fourth tangential plane, the included angle is 107.83 DEG + -15 DEG, and the complement angle is 252.16 DEG + -15 DEG; wherein the fifth line is a fifth tangential plane, the included angle is 133.54 DEG + -15 DEG, and the complement angle is 226.45 DEG + -15 DEG; wherein the sixth line is a sixth tangential plane, the included angle is 159.26 DEG + -15 DEG, and the complement angle is 200.73 DEG + -15 DEG; wherein the seventh line is a seventh tangential plane, the included angle is 4.97 DEG + -15 DEG, and the complement angle is 355.02 DEG + -15 DEG; wherein the eighth line is an eighth tangential plane, the included angle is 210.68 degrees+/-15 degrees, and the complement angle is 149.31 degrees+/-15 degrees; wherein the ninth line is a ninth tangential plane, the included angle is 236.40 degrees+ -15 degrees, and the complement angle is 123.59 degrees+ -15 degrees; wherein the tenth line is a tenth tangential plane, the included angle is 262.11 DEG + -15 DEG, and the complement angle is 97.88 DEG + -15 DEG; wherein the eleventh line is an eleventh tangential plane, the included angle is 287.83 DEG + -15 DEG, and the complement angle is 72.16 DEG + -15 DEG; wherein the twelfth line is a twelfth tangential plane, the included angle is 313.54 DEG+ -15 DEG, and the complement angle is 46.45 DEG+ -15 DEG; wherein the thirteenth line is a thirteenth tangential plane, the included angle is 339.26 DEG + -15 DEG, and the complement angle is 20.73 DEG + -15 DEG; wherein the fourteenth line is a fourteenth tangential plane, the included angle is 355.02 DEG + -15 DEG, and the complement angle is 4.97 DEG + -15 deg.

Step three, as shown in fig. 21, the third section is completed with a 120 ° side tip knife along the line in fig. 21 for a total of 14 facets. Wherein the first line is a first tangential plane, the included angle is 329.31 +/-15 DEG, and the complement angle is 30.68+/-15 DEG; wherein the second line is a second tangential plane, the included angle is 303.59 +/-15 DEG, and the complement angle is 56.40 +/-15 DEG; wherein the third line is a third tangential plane, the included angle is 277.88 DEG + -15 DEG, and the complement angle is 82.11 DEG + -15 DEG; wherein the fourth line is a fourth tangential plane, the included angle is 252.16 DEG + -15 DEG, and the complement angle is 107.83 DEG + -15 DEG; wherein the fifth line is a fifth tangential plane, the included angle is 226.45 DEG + -15 DEG, and the complement angle is 133.54 DEG + -15 DEG; wherein the sixth line is a sixth tangential plane, the included angle is 200.73 DEG + -15 DEG, and the complement angle is 159.26 DEG + -15 DEG; wherein the seventh line is a seventh tangential plane, the included angle is 355.02 DEG + -15 DEG, and the complement angle is 4.97 DEG + -15 DEG; wherein the eighth line is an eighth tangential plane, the included angle is 149.31 degrees+/-15 degrees, and the complement angle is 210.68 degrees+/-15 degrees; wherein the ninth line is a ninth tangential plane, the included angle is 123.59 degrees+ -15 degrees, and the complement angle is 236.40 degrees+ -15 degrees; wherein the tenth line is a tenth tangential plane, the included angle is 97.88 DEG + -15 DEG, and the supplementary angle is 62.11 DEG + -15 DEG; wherein the eleventh line is an eleventh tangential plane, the included angle is 72.16 DEG + -15 DEG, and the complement angle is 287.83 DEG + -15 DEG; wherein the twelfth line is a twelfth tangential plane, the included angle is 46.45 DEG+ -15 DEG, and the complement angle is 313.54 DEG+ -15 DEG; wherein the thirteenth line is a thirteenth tangential plane, the included angle is 20.73 DEG + -15 DEG, and the complement angle is 339.26 DEG + -15 DEG; wherein the fourteenth line is a fourteenth tangential plane, the included angle is 4.97 deg. + -15 deg., and the complement angle is 355.02 deg. + -15 deg..

Step four, as shown in fig. 22, the fourth section is completed with a 120 ° side tip knife along the line in fig. 22 for a total of 14 facets. Wherein the first line is a first tangential plane, the included angle is 328.16 DEG + -15 DEG, and the complement angle is 31.83 DEG + -15 DEG; wherein the second line is a second tangential plane, the included angle is 353.88 DEG + -15 DEG, and the complement angle is 6.12 DEG + -15 DEG; wherein the third line is a third tangential plane, the included angle is 19.59 DEG + -15 DEG, and the complement angle is 340.40 DEG + -15 DEG; wherein the fourth line is a fourth tangential plane, the included angle is 45.30 degrees+ -15 degrees, and the complement angle is 314.69 degrees+ -15 degrees; wherein the fifth line is a fifth tangential plane, the included angle is 71.02 DEG + -15 DEG, and the complement angle is 288.97 DEG + -15 DEG; wherein the sixth line is a sixth tangential plane, the included angle is 96.73 DEG + -15 DEG, and the complement angle is 263.26 DEG + -15 DEG; wherein the seventh line is a seventh tangential plane, the included angle is 122.45 DEG+ -15 DEG, and the complement angle is 237.54 DEG+ -15 DEG; wherein the eighth line is an eighth tangential plane, the included angle is 328.16 degrees+/-15 degrees, and the complement angle is 31.83 degrees+/-15 degrees; wherein the ninth line is a ninth tangential plane, the included angle is 6.12 degrees+ -15 degrees, and the supplementary angle is 353.88 degrees+ -15 degrees; wherein the tenth line is a tenth tangential plane, the included angle is 340.40 DEG + -15 DEG, and the complement angle is 19.59 DEG + -15 DEG; wherein the eleventh line is an eleventh tangential plane, the included angle is 314.69 degrees+/-15 degrees, and the complement angle is 45.30 degrees+/-15 degrees; wherein the twelfth line is a twelfth tangential plane, the included angle is 288.97 DEG+ -15 DEG, and the complement angle is 71.02 DEG+ -15 DEG; wherein the thirteenth line is a thirteenth tangential plane, the included angle is 263.26 DEG + -15 DEG, and the complement angle is 96.73 DEG + -15 DEG; wherein the fourteenth line is a fourteenth tangential plane, the included angle is 237.54 DEG + -15 DEG, and the complement angle is 122.45 DEG + -15 deg.

Step five, as shown in fig. 23, the fifth section is completed with a 120 ° side tip knife along the line in fig. 23 for a total of 14 facets. Wherein the first line is a first tangential plane, the included angle is 31.83 DEG + -15 DEG, and the complement angle is 328.16 DEG + -15 DEG; wherein the second line is a second tangential plane, the included angle is 237.54 DEG + -15 DEG, and the complement angle is 122.45 DEG + -15 DEG; wherein the third line is a third tangential plane, the included angle is 263.26 DEG + -15 DEG, and the complement angle is 96.73 DEG + -15 DEG; wherein the fourth line is a fourth tangent plane, the included angle is 288.97 degrees plus or minus 15 degrees, and the supplementary angle is 71.02 degrees plus or minus 15 degrees; wherein the fifth line is a fifth tangent plane, the included angle is 314.69 degrees plus or minus 15 degrees, and the complement angle is 45.30 degrees plus or minus 15 degrees; wherein the sixth line is a sixth tangential plane, the included angle is 340.40 DEG + -15 DEG, and the complement angle is 19.59 DEG + -15 DEG; wherein the seventh line is a seventh tangential plane, the included angle is 6.12 DEG + -15 DEG, and the complement angle is 353.88 DEG + -15 DEG; wherein the eighth line is an eighth tangential plane, the included angle is 328.16 degrees+/-15 degrees, and the complement angle is 31.83 degrees+/-15 degrees; wherein the ninth line is a ninth tangential plane, the included angle is 122.45 degrees+ -15 degrees, and the complement angle is 237.54 degrees+ -15 degrees; wherein the tenth line is a tenth tangential plane, the included angle is 96.73 degrees+/-15 degrees, and the complement angle is 263.26 degrees+/-15 degrees; wherein the eleventh line is an eleventh tangential plane, the included angle is 71.02 DEG + -15 DEG, and the complement angle is 288.97 DEG + -15 DEG; wherein the twelfth line is a twelfth tangential plane, the included angle is 45.30 degrees+ -15 degrees, and the complement angle is 314.69 degrees+ -15 degrees; wherein the thirteenth line is a thirteenth tangential plane, the included angle is 19.59 DEG + -15 DEG, and the complement angle is 340.40 DEG + -15 DEG; wherein the fourteenth line is a fourteenth tangential plane, the included angle is 353.88 DEG + -15 DEG, and the complement angle is 6.12 DEG + -15 deg.

Step six, after cutting, a decorative surface is formed as shown in fig. 24, and fig. 25 is a top view of a third simulated diamond metal ornament according to embodiment 3 of the present utility model.

In summary, the simulated diamond metal ornament of the present utility model has a plurality of refraction units distributed in the outer ring array of the central area, the refraction units are composed of a plurality of refraction areas, the plurality of refraction areas have a plurality of triangular surfaces, and different light rays are refracted out through the plurality of triangular surfaces, so that the purposes of bright decorative surface and rich light ray colors are achieved. The triangular surface tangential plane angle distribution of the simulated diamond refraction area distribution is reasonable, and the manufacturing is convenient.

The foregoing description is only of the preferred embodiments of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes using the descriptions and the drawings of the present utility model or directly or indirectly applied to other related technical fields are included in the scope of the utility model.

Claims (7)

1. The simulated diamond metal ornament comprises a simulated diamond main body (1), wherein the simulated diamond main body (1) is provided with a decoration surface and a bottom plane, and is characterized in that the decoration surface is provided with a concave central area (3), the central area (3) is surrounded, a plurality of refraction units (2) are distributed in a ring array, each refraction unit (2) is connected with the central area (3), and the two adjacent refraction units (2) are in sharing edges;

The narrow end of the refraction unit (2) is connected with the central area (3), and the wide end of the refraction unit extends to the edge of the decorative surface;

The narrow end of the refraction unit (2) is arranged in the wide end direction, and the refraction unit comprises a first refraction area (21), a second refraction area (22) and a third refraction area (23) which are connected in sequence;

Wherein the first refraction area (21) is a first concave area formed by four triangular surfaces;

The second refraction area (22) is a second concave area formed by eight triangular surfaces;

the third refraction area (23) is a third concave area composed of six triangular faces.

2. A simulated diamond metal ornament as in claim 1, wherein said central zone (3) is a circular ornamental zone.

3. A simulated diamond metal as claimed in claim 1, wherein said four triangular faces of said first recess share a first common apex, said four triangular faces comprising:

two 1 st triangular surfaces (211) symmetrical with the first common vertex, the two 1 st triangular surfaces (211) not having a common edge;

Two 2 nd triangular surfaces (212) which are shared by the edges and are respectively shared with the two 1 st triangular surfaces (211), wherein a first included angle a between the 1 st triangular surfaces (211) and the 2 nd triangular surfaces (212) is a pure angle, and a second included angle b between the two 2 nd triangular surfaces (212) is larger than 180 degrees.

4. A simulated diamond metal as claimed in claim 1, wherein said eight triangular faces of said second recess share a second common vertex and each adjacent two triangular faces of said second recess are co-located.

5. A simulated diamond metal as claimed in claim 4, wherein said eight triangular faces comprise:

Two third triangular surfaces (221), wherein the two third triangular surfaces (221) are co-edge, and a third included angle c between the two third triangular surfaces (221) is more than 180 degrees;

Two 4 th triangular surfaces (222), wherein the two 4 th triangular surfaces (222) are adjacent to the two 3 rd triangular surfaces (221), and a fourth included angle d between the 4 th triangular surfaces (222) and the 3 rd triangular surfaces (221) is an obtuse angle in a group of adjacent 4 th triangular surfaces (222) and 3 rd triangular surfaces (221);

Two 5 th triangular surfaces (223), wherein the two 5 th triangular surfaces (223) are adjacent to the two 4 th triangular surfaces (222), and a fifth included angle e between the 5 th triangular surfaces (223) and the 4 th triangular surfaces (222) in a group of adjacent 5 th triangular surfaces (223) and 4 th triangular surfaces (222) is larger than 180 degrees;

Two 6 th triangular surfaces (224), wherein the two 6 th triangular surfaces (224) are co-edge and are adjacent to two 5 th triangular surfaces (223) respectively, a sixth included angle f between the 6 th triangular surfaces (224) and the 5 th triangular surfaces (223) is smaller than or equal to 90 degrees, and a seventh included angle g between the two 6 th triangular surfaces (224) is larger than 180 degrees in a group of adjacent 6 th triangular surfaces (224) and 5 th triangular surfaces (223).

6. A simulated diamond metal as claimed in claim 1, wherein said six triangular faces of said third concave region have a third common vertex, said six triangular faces of said third concave region comprising:

two 7 th triangular surfaces (231), wherein the two 7 th triangular surfaces (231) are co-edge and an eighth included angle h between the two 7 th triangular surfaces (231) is more than 180 degrees;

Two 8 th triangular surfaces (232), wherein the two 8 th triangular surfaces (232) are adjacent to the two 7 th triangular surfaces (231) respectively, and a ninth included angle i between the 8 th triangular surfaces (232) and the 7 th triangular surfaces (231) in a group of adjacent 8 th triangular surfaces (232) and 7 th triangular surfaces (231) is less than or equal to 90 degrees;

Two 9 th triangular surfaces (233), the two 9 th triangular surfaces (233) are adjacent to the two 8 th triangular surfaces (232), respectively, and a tenth included angle j between the 9 th triangular surfaces (233) and the 8 th triangular surfaces (232) is larger than 180 DEG in a group of adjacent 9 th triangular surfaces (233) and 8 th triangular surfaces (232).

7. A simulated diamond metal as in claim 6, wherein said non-co-border of said 9 th triangular surface (233) is a border line of the simulated diamond metal.