CN114916753B - Concealed inlaying method for pavilion of precious stone - Google Patents

Abstract

The application provides a hidden type inlaying method for a pavilion part of a precious stone, which belongs to the technical field of precious stone inlaying, and comprises the following steps: cutting and grinding precious stones; manufacturing a computer digital inlay model; manufacturing a mouth-inlaid die; pouring through a inlaid opening; polishing and polishing the inlaid opening for the first time; expanding, grinding and polishing the inside of the inlaid opening until the cut and ground precious stone can fall into the inlaid opening; and (3) embedding the cut and ground precious stone into the embedded opening to obtain the embedded opening embedded with the precious stone. The application can make 100% of the crown of the inlaid precious stone visible, so as to solve the problem that the prior art can not fully reveal the crown of the precious stone, realize that the crown of the precious stone is free from metal covering, ensure that the inlaid metal used for fixing the precious stone does not have adverse effects on the shape and the display area of the crown of the precious stone, furthest present the practical maximum size of the crown of the precious stone, and give consumers more novel product forms and better use experience.

Description

Concealed inlaying method for pavilion of precious stone

Technical Field

The application relates to the technical field of precious stone inlaying, in particular to a concealed inlaying method for a precious stone pavilion.

Background

At present, the existing stone setting method can shield the crown of the stone, visually reduce and weaken the characteristics of the stone such as size, luster, fire color and the like, and cannot optimally display the actual magnificent effect of the stone, such as wrapping, setting with holding claws, forcing setting (clamping setting) and other processes, and only can ensure that the table top part at the center of the crown of the stone is completely displayed, but cannot completely and completely display the most main crown of the stone, and the aim that the crown of the stone is not covered by metal and is completely displayed can not be realized.

In addition, several popular stone setting techniques are available to fix stones, which have a large loss in stone weight compared to the prior art, which is a significant waste and cost waste for the jewelry industry.

Disclosure of Invention

The application provides a concealed inlaying method for a pavilion of a gemstone, which is used for solving the technical problem that the prior inlaying technology cannot fully reveal the crown of the gemstone.

In order to solve the above problems, the present application provides a concealed setting method for a pavilion of a gemstone, comprising the steps of:

S ₁ cutting and grinding precious stones;

S ₂ manufacturing a computer digital inlay model;

S ₃ manufacturing an inlay die;

S ₄ pouring through a inlaid opening;

S ₅ polishing the inlaid opening for the first time;

S ₆ expanding, grinding and polishing the inside of the inlaid opening until the cut and ground precious stone can fall into the inlaid opening;

S ₇ : and (3) embedding the cut and ground precious stone into the embedded opening to obtain the embedded opening embedded with the precious stone.

Further, in step S ₁ Wherein, the gemstone cutting grinding tool body comprises the following steps:

S ₁₁ : setting a precious stone setting groove;

S ₁₂ : polishing the gemstone setting groove.

Further, in step S ₁₁ Wherein the position of the gemstone setting groove is located at 35% -40% of the depth of the gemstone pavilion part which is moved upwards in the vertical direction by taking the point of the gemstone pavilion as a reference, and the height of the groove of the gemstone setting groove is 0.3mm.

Further, in step S ₂ Wherein, the making of the computer digital inlay model specifically comprises the following steps:

S ₂₁ : implanting an electronic model of the gemstone into three-dimensional modeling software through 3D scanning;

S ₂₂ : manufacturing a metal acting layer 301;

S ₂₃ : a metal substrate 302 is fabricated.

Further, in step S ₂₃ The thickness of the metal substrate in the inlaid opening is not less than 0.7mm.

Further, in step S ₂₃ Wherein the height of the inner side of the metal substrate in the setting opening is not lower than the vertical distance from the setting groove to the pavilion tip of the gemstone plus the extension in the vertical direction1.5mm distance.

Further, in step S ₆ Wherein, the specific steps of expanding, grinding and polishing the inside of the inlay port comprise:

S ₆₁ : the first attempt to fall the stone;

S ₆₂ : performing first diameter expansion on the metal action layer 301;

S ₆₃ : a second attempted stone fall;

S ₆₄ : performing second diameter expansion on the metal action layer 301;

S ₆₅ : polishing;

S ₆₆ : polishing;

S ₆₇ : and (5) falling rocks.

Further, in step S ₇ Wherein, inlay the precious stone that the cutting and grinding is accomplished in the mouth of inlaying, the concrete step of obtaining the mouth of inlaying with precious stone includes:

S ₇₁ : wrapping edges;

S ₇₂ : and polishing the outer part of the inlaid opening inlaid with the precious stone for the second time.

Further, in step S ₇₂ Wherein, the specific step of polishing the outside of the diamond-embedded diamond comprises the following steps:

S ₇₂₁ : filing and repairing

Sequentially using a file No. 2 and a file No. 5, and performing the step S ₇₁ Trimming the outside of the obtained diamond-embedded port;

S ₇₂₂ : polishing

Sequentially using 320-mesh sand paper, 600-mesh sand paper and 1200-mesh sand paper to perform the step S ₇₂₁ Polishing the outside of the obtained diamond-embedded rabbet;

S ₇₂₃ : polishing

Step S is conducted by using polishing cloth wheel and polishing wax ₇₂₂ The outside of the obtained setting with the gem is polished to achieve the mirror effect, thereby obtaining the final product with the setting with the gem.

Further, the metal acting layer and the metal substrate are made of silver, gold or platinum.

Compared with the prior art, the application has remarkable advantages and beneficial effects, and is specifically embodied in the following aspects:

1. the application realizes that the precious stone crown is free of metal shielding, solves the problem that the shape and the display area of the precious stone crown are adversely affected by the metal used for inlaying the precious stone in the prior inlaying technology, breaks through the technical barriers, and adopts the precious stone product inlaid by the application to maximally present the practical maximum size of the precious stone crown, thereby giving consumers more novel product forms and better use experience.

2. The precious stone inlays the groove and sets up on precious stone pavilion portion, compares in prior art and inlays the groove and set up on the girdle, and precious stone weight loss is minimum, and the loss that the technical scheme of this embodiment appears for seting up the groove is the minimum scheme under the condition of guaranteeing to satisfy inlaying.

Drawings

FIG. 1 is a schematic diagram of a gemstone according to an embodiment of the present application;

FIG. 2 is a schematic view of a structure of a setting groove formed in a pavilion of a gemstone according to an embodiment of the present application;

FIG. 3 is a schematic view of setting positions of a stone setting groove and a setting die in an embodiment of the application;

FIG. 4 is a schematic diagram of the combination of a gemstone and setting model in accordance with an embodiment of the present application;

FIG. 5 is a schematic perspective view of a bezel structure according to an embodiment of the present application;

FIG. 6 is a schematic view of the direction of expansion and the hammering of the metal working surface of the inlaid opening in the embodiment of the present application;

FIG. 7 is a schematic diagram showing the effect of the top view angle of a gemstone fitted to a setting in an embodiment of the present application;

FIG. 8 is a schematic perspective view of a gemstone fitted to a setting in accordance with an embodiment of the present application;

FIG. 9 is a schematic view of a structure in which the depth of the inner side of the bezel is equal to the height from the pavilion tip to the diamond setting groove in the embodiment of the present application;

FIG. 10 is a schematic view of a setting model of a square faceted cut gemstone according to yet another embodiment of the present application;

FIG. 11 is a schematic view of a setting model of a setting heart-shaped facet cut gemstone according to yet another embodiment of the present application.

Reference numerals:

1-precious stone; 101-a gemstone table; 102-precious stone star facets; 103—a gemstone crown main facet; 104-waist faceting of the gemstone; 105-gemstone setting grooves;

3-embedding the mouth; 301-a metal active layer; 302-metal substrate.

Detailed Description

In order that the above objects, features and advantages of the application will be readily understood, a more particular description of the application will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In addition, in this document, terms such as front, rear, upper, lower, etc. are defined by the positions of the components in the drawings and the positions of the components with respect to each other, and are only used for clarity and convenience in expressing the technical scheme. It should be understood that the use of such orientation terms should not limit the scope of the claimed application.

The embodiments described above and features of the embodiments herein may be combined with each other without conflict.

Division of faceted gemstone structures was done according to us Ji Erde gemstone laboratory (hereinafter guid) and us gemstone college (hereinafter GIA): a complete faceted precious stone is made up of crown, girdle, pavilion. The crown is the most important and intuitive part showing the characteristics of the maximum diameter of the precious stone (namely the maximum area of the precious stone observed from the top view), color, luster, fire color and the like, and is also the most important consideration when a consumer appreciates and purchases the precious stone.

According to the relationship from the visual center to the outer edge of the gemstone, the crown part sequentially comprises a table surface, star facets, crown part main facets and upper waist facets.

Referring to fig. 1, in the embodiment of the present application, the gemstone 1 sequentially includes a crown a, a waist C and a pavilion B from top to bottom, and a gemstone setting groove 105 is formed in the outer circumferential direction of the pavilion B, wherein:

a represents the crown of gemstone 1; b represents the pavilion of the gemstone 1; c represents the waist of gemstone 1; d represents the height of the pavilion tip to the stone setting groove 105.

The crown a comprises, in order from top to bottom, a gemstone table 101, a gemstone star facet 102, a gemstone crown main facet 103 and a gemstone upper girdle facet 104.

Referring to FIG. 2, in the embodiment of the present application, B represents the pavilion of gemstone 1; m represents the distance from the upper side surface of the setting groove 105 to the pavilion B surface of the gemstone; g represents the height of the groove in which the gemstone setting groove 105 is formed; n represents the distance from the underside of the set gemstone setting groove 105 to the surface of the pavilion B.

Referring to fig. 3, in the embodiment of the present application, the structure of the bezel 3 includes a metal active layer 301 (i.e., the diagonally hatched portion shown in fig. 3) and a metal substrate 302 (i.e., the vertically hatched portion shown in fig. 3) from top to bottom.

Referring to fig. 4, in the embodiment of the present application, E represents the depth of the inner side of the metal base 302 in the bezel 3; q represents the wall thickness of the metal base 302 in the bezel 3.

Referring to FIG. 6, in the embodiment of the present application, W represents the striking force direction when setting the gemstone 1.

Example 1

Referring to fig. 1 to 9, an embodiment of the present application provides a concealed setting method for a pavilion of a gemstone, the concealed setting method comprising the steps of:

S ₁ : cutting and grinding precious stone:

S ₁₁ : setting a precious stone setting groove 105;

the gemstone pavilion B is cut by using a flying disk-shaped K needle, and a gemstone setting groove 105 is formed around the gemstone pavilion B horizontally to the gemstone table 101.

In step S ₁₁ In the above, the distance from the lower side of the gemstone setting groove 105 to the surface of the pavilion B must be less than 0.3mm.

Illustratively, in the embodiment of the present application, gemstone 1 is a round diamond with a crown diameter of 6.5mm and a pavilion height of 2.8mm, and gemstone setting grooves 105 are formed in a circular ring shape in a top view according to the shape of gemstone 1.

The specific position of the gemstone setting groove 105 at the gemstone pavilion portion B is that the gemstone pavilion tip is used as a reference, the gemstone setting groove 105 is located at a distance of 37% of the depth of the gemstone pavilion portion B moving upwards in the vertical direction, that is, the calculation method of the height D from the gemstone pavilion tip to the gemstone setting groove 105 is 2.8x37% =1.036 mm, that is, the setting position of the gemstone setting groove 105 is located at a position of 1.0mm moving upwards in the vertical direction from the gemstone pavilion tip, that is, the height D from the gemstone pavilion tip to the gemstone setting groove is 1.0mm.

Thus, the distance M from the upper side surface of the gemstone setting groove 105 to the surface of the gemstone pavilion B is 0.45mm; the distance N from the lower side surface of the gemstone setting groove 105 to the surface of the gemstone pavilion B is 0.3mm; the height G of the gemstone setting groove 105 is 0.3mm.

In addition, as a modification of the present example, the setting position of the gemstone setting groove 105 is 35% to 40% of the depth of the pavilion section B, where the pavilion tip is vertically moved upward.

S ₁₂ : polishing the gemstone setting groove 105;

the diamond setting grooves 105 are polished with a flying disc tungsten steel needle and diamond paste.

Therefore, in the embodiment of the present application, the precious stone setting groove 105 is formed on the precious stone pavilion B, and compared with the setting groove formed on the girdle in the prior art, the precious stone has the least weight loss, that is, the technical scheme of the present embodiment is that the loss occurring when the setting groove is formed is the smallest scheme for ensuring that the setting condition is satisfied.

S ₂ : and manufacturing a computer digital inlay model.

Specifically, referring to fig. 3, in the embodiment of the present application, in step S ₂ Wherein, the making of the computer digital inlay model specifically comprises the following steps:

S ₂₁ : implanting an electronic model of the gemstone into three-dimensional modeling software through 3D scanning;

in the embodiment of the application, the adopted three-dimensional modeling software is Jetel CAD, and of course, the three-dimensional modeling software can also be Rhino3D, solidworks and the like.

S ₂₂ : manufacturing a metal acting layer 301;

according to the gemstone setting groove 105 formed in the gemstone setting groove 105, a metal action layer 301 with a shape matching that of the gemstone setting groove 105 is formed, the section of the metal action layer 301 is rectangular, the length of the section is the same as the distance M from the upper side surface of the gemstone setting groove 105 to the surface of the gemstone setting groove 105, the width is the same as the height G in the groove of the gemstone setting groove 105, and the length of the metal action layer 301 surrounds the gemstone along the horizontal direction.

Specifically, in this embodiment, according to the shape of the gemstone 1, the metal working layer 301 has a circular ring shape in plan view, a rectangular cross-sectional shape, and the distance M from the upper side surface of the gemstone setting groove 105 to the pavilion surface of the gemstone setting groove is 0.45mm, that is, the length of the rectangular cross-section is also 0.45mm, and the height G in the groove of the gemstone setting groove 105 is 0.3mm, that is, the width of the rectangular cross-section is also 0.3mm.

S ₂₃ : manufacturing a metal substrate 302;

and manufacturing a metal substrate 302 surrounding the periphery of the precious stone on the outer side of the metal action layer 301, and connecting the metal action layer 301 and the metal substrate 302 into a whole to finish the manufacture of the computer digital model of the concealed embedded rabbet for the pavilion of the precious stone.

Because the setting is positioned on the pavilion part and below the waist of the gemstone 1, compared with the prior art, the manufacturing cost is lower because less metal is needed.

Specifically, in this embodiment, according to the shape of the gemstone 1, the metal substrate 302 has a triangular hollow bowl-shaped structure, the thickness of the metal substrate in the bezel must not be lower than 0.7mm at the minimum, preferably the wall thickness Q of the metal substrate 302 is 0.7mm, and the depth E of the inner side of the metal substrate 302 is the height D from the pavilion tip to the precious stone setting groove 105 plus the height from the pavilion tip to the bottom of the metal substrate 302.

The height of the inner side of the metal base 302 in the setting is not lower than the sum of the distance from the setting groove 105 to the tip of the gemstone Dan Ting formed in the pavilion B and the distance further extended by 1.5mm in the vertical direction. As the most preferable mode of this embodiment, the height from the pavilion tip to the bottom of the metal base 302 in this embodiment is 1.5mm, and then the calculation method of the depth E of the inner side of the metal base 302 in the setting 3 is 1.0+1.5=2.5 mm.

Referring to fig. 9, in the embodiment of the present application, if the depth E of the inner side of the metal base 302 is equal to the height D from the pavilion tip to the stone setting groove 105 is 1.0mm, the stone will not fall into the setting 3, and finally the stone setting process will not be completed.

S ₃ : manufacturing a mouth-inlaid die;

according to step S ₂ The obtained computer digital inlay model adopts a 3D wax-spraying printer to manufacture the inlay die.

S ₄ : pouring with a inlaid opening:

for step S ₃ And (3) pouring the obtained insert die to obtain the integrally formed insert.

In this embodiment, the metal used for pouring the inlay port is gold, that is, the material of the metal acting layer 301 and the metal substrate 302 is gold, the purity of gold is 18K, and the purity of gold may be 14K or 9K.

It should be further explained that the metal may be silver, platinum, etc. according to the custom requirement of the customer, and the metal material used in this embodiment is not limited.

S _5： Polishing and polishing the inlaid opening for the first time;

for step S ₄ The first grinding and polishing are carried out on the outer part of the obtained inlay port, and the first grinding and polishing method for the outer part of the inlay port is as follows:

P ₁ : filing and repairing

Sequentially using a file No. 2 and a file No. 5 to trim the outside of the cutting insert;

P ₂ : polishing

Sequentially using 320-mesh sand paper, 600-mesh sand paper and 1200-mesh sand paper to perform the step P ₁ Polishing the outside of the obtained inlay port;

P ₃ : polishing

Using polishing cloth wheelsPolishing wax vs step P ₂ The outside of the resulting insert was polished.

S ₆ : and expanding, grinding and polishing the inside of the inlaid opening until the precious stone subjected to cutting and grinding can fall into the inlaid opening.

For step S ₅ Expanding, grinding and polishing the inner part of the obtained inlay port until the step S ₁ The gem with the middle cut and ground can be placed in the setting. In this embodiment, the method for expanding, grinding, polishing and falling stone in the insert opening is as follows:

S ₆₁ : the first attempt to fall the stone;

observing and marking the distance between the gemstone setting groove 105 and the metal working layer 301 by attempting to place the gemstone in the setting;

S ₆₂ : performing first diameter expansion on the metal action layer 301;

referring to fig. 6, fig. 6 shows the structural effect of the metal working layer 301 after expanding the surface, and the following steps are adopted ₅ The metal working layer 301 inside the obtained inlay port always keeps teeth in the vertical parallel direction to expand the diameter of the metal working layer 301, wherein the diameter of the dental needle is selected to be 0.6mm.

S ₆₃ : a second attempted stone fall;

by trial and error placing the gemstone in step S ₅₂ Observing and marking the distance between the precious stone setting groove 105 and the metal action layer 301 in the obtained setting mouth;

S ₆₄ : performing second diameter expansion on the metal action layer 301;

adopting and step S ₅₃ The metal working layer 301 inside the obtained inlay port is always kept vertically parallel and the diameter of the dental needle is 0.6mm, the metal working layer 301 is subjected to the second diameter expansion until the step S is predicted ₁ The cut and ground precious stone obtained in the process can fall into the setting.

S ₆₅ : polishing;

sequentially using 320-mesh sand paper, 600-mesh sand paper and 1200-mesh sand paper to perform the step S ₅₄ Polishing the inside of the obtained inlay opening.

S ₆₆ : polishing;

step S is conducted by using polishing cloth wheel and polishing wax ₅₅ The inside of the obtained insert was polished.

S ₆₇ : falling rocks;

step S is carried out ₁ The precious stone obtained in the process is placed in the setting.

Therefore, the inlaid opening in the embodiment of the application is an independent unit, has stronger flexibility, and can be automatically combined and molded according to the requirements of design and manufacturing parties.

S ₇ : and (3) embedding the cut and ground precious stone into the embedded opening to obtain the embedded opening embedded with the precious stone.

Therefore, the precious stone inlaying method can furthest show the magnificence of the pavilion of the precious stone.

In this embodiment, the method for setting the gemstone is as follows:

S ₇₁ : wrapping edges;

referring to FIG. 6, a horizontal chisel and hammer are used to strike the top of the metal substrate 302 in the bezel 3 with a force direction W, a striking step S ₆ The metal action layer 301 is completely embedded into the precious stone setting groove 105 formed in the precious stone pavilion part by the top of the metal base 302 with the obtained setting opening, and the top of the metal base 302 is attached to the precious stone pavilion part to fix the precious stone.

S ₇₂ : and polishing the outer part of the inlaid opening inlaid with the precious stone for the second time.

For step S ₇ And (3) polishing the outside of the obtained setting with the gem for the second time to obtain a final product with the setting with the gem. In the present embodiment, in step S ₇ Then, the polishing process also comprises secondary grinding and polishing; the method for carrying out secondary polishing on the outside of the diamond-embedded rabbet comprises the following steps:

S ₇₂₁ : filing and repairing

Sequentially using a file No. 2 and a file No. 5, and performing the step S ₇₁ Trimming the outside of the obtained diamond-embedded port;

S ₇₂₂ : polishing

Sequentially using 320-mesh sand paper, 600-mesh sand paper and 1200-mesh sand paper to perform the step S ₇₂₁ Polishing the outside of the obtained diamond-embedded rabbet;

S ₇₂₃ : polishing

Step S is conducted by using polishing cloth wheel and polishing wax ₇₂₂ The outside of the obtained setting with the gem is polished to achieve the mirror effect, thereby obtaining the final product with the setting with the gem.

It should be noted that, in the embodiment of the present application, the metal substrate 302 may be specifically shaped according to the user's requirement on the basis of the above-mentioned principle.

In addition, the concealed inlaying method can be applied to various products such as rings, pendants, bracelets and the like.

Therefore, the hidden type inlaying method in the embodiment of the application can enable 100% of the crown of the inlaid precious stone to be visible, so as to solve the problem that the prior inlaying technology cannot fully display the crown of the precious stone, realize that the crown of the precious stone is free from metal covering, enable the inlaid metal used for fixing the precious stone not to have adverse effects on the shape and the display area of the crown of the precious stone, furthest present the actual maximum size of the crown of the precious stone, and give consumers more novel product forms and better use experience.

Example 2

Referring to fig. 10, the difference between the present embodiment 2 and the embodiment 1 is that the shape of the crown a of the gemstone is square, and the shapes of the metal acting layer 301 and the metal substrate 302 are matched with the shape of the crown a of the gemstone.

Example 3

Referring to fig. 11, the difference between the present embodiment 3 and the embodiment 1 is that the shape of the crown a of the gemstone is heart-shaped, and the shapes of the metal acting layer 301 and the metal substrate 302 are matched with the shape of the crown a of the gemstone.

It should be further noted that the above is applicable to the prior art, unless otherwise mentioned.

Although the present disclosure is disclosed above, the scope of the present disclosure is not limited thereto. Various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the disclosure, and these changes and modifications will fall within the scope of the application.

Claims (8)

1. A concealed setting method for a pavilion of a gemstone, comprising the steps of:

S ₁ cutting and grinding precious stones;

the gemstone cutting grinding tool body comprises the following steps:

S ₁₁ : setting a precious stone setting groove;

the position of the precious stone embedded groove is located at 35% -40% of the depth of the precious stone pavilion part which is moved upwards in the vertical direction by taking the precious stone pavilion tip as a reference, and the height of the precious stone embedded groove is 0.3mm;

S ₁₂ : polishing the gemstone setting groove;

S ₂ manufacturing a computer digital inlay model;

S ₃ manufacturing an inlay die;

S ₄ pouring through a inlaid opening;

S ₅ polishing the inlaid opening for the first time;

S ₆ expanding, grinding and polishing the inside of the inlaid opening until the cut and ground precious stone can fall into the inlaid opening;

S ₇ : and (3) embedding the cut and ground precious stone into the embedded opening to obtain the embedded opening embedded with the precious stone.

2. The concealed setting method for a pavilion according to claim 1, wherein in step S ₂ Wherein, the making of the computer digital inlay model specifically comprises the following steps:

S ₂₁ : implanting an electronic model of the gemstone into three-dimensional modeling software through 3D scanning;

S ₂₂ : manufacturing a metal acting layer;

S ₂₃ : and manufacturing a metal substrate.

3. The concealed setting method for a pavilion according to claim 2, wherein in step S ₂₃ The thickness of the metal substrate in the inlaid opening is not less than 0.7mm.

4. The concealed setting method for a pavilion according to claim 2, wherein in step S ₂₃ Wherein the height of the inner side of the metal substrate in the setting is not lower than the sum of the vertical distance from the setting groove to the pavilion tip of the gemstone plus a distance elongated by 1.5mm in the vertical direction.

5. The concealed setting method for a pavilion according to claim 1, wherein in step S ₆ Wherein, the specific steps of expanding, grinding and polishing the inside of the inlay port comprise:

S ₆₁ : the first attempt to fall the stone;

S ₆₂ : performing primary diameter expansion on the metal action layer;

S ₆₃ : a second attempted stone fall;

S ₆₄ : performing second diameter expansion on the metal acting layer;

S ₆₅ : polishing;

S ₆₆ : polishing;

S ₆₇ : and (5) falling rocks.

6. The concealed setting method for a pavilion according to claim 1, wherein in step S ₇ Wherein, inlay the precious stone that the cutting and grinding is accomplished in the mouth of inlaying, the concrete step of obtaining the mouth of inlaying with precious stone includes:

S ₇₁ : wrapping edges;

S ₇₂ : and polishing the outer part of the inlaid opening inlaid with the precious stone for the second time.

7. The concealed setting method for a pavilion according to claim 6, wherein in the step ofS ₇₂ Wherein, the specific step of polishing the outside of the diamond-embedded diamond comprises the following steps:

S ₇₂₁ : filing and repairing

Sequentially using a file No. 2 and a file No. 5, and performing the step S ₇₁ Trimming the outside of the obtained diamond-embedded port;

S ₇₂₂ : polishing

Sequentially using 320-mesh sand paper, 600-mesh sand paper and 1200-mesh sand paper to perform the step S ₇₂₁ Polishing the outside of the obtained diamond-embedded rabbet;

S ₇₂₃ : polishing

Step S is conducted by using polishing cloth wheel and polishing wax ₇₂₂ The outside of the obtained setting with the gem is polished to achieve the mirror effect, thereby obtaining the final product with the setting with the gem.

8. The concealed setting method for a pavilion according to claim 2, wherein the metal working layer and the metal base are made of silver, gold or platinum.